LAN91C111I-NS - MICROCHIP - Datasheet.Directory

SMSC LAN91C111 REV C DATASHEET Revision 1.92 (06-27-11)

Datasheet

PRODUCT FEATURES

LAN91C111

10/100 Non-PCI Ethernet

Single Chip MAC + PHY

Single Chip Ethernet Controller

Dual Speed - 10/100 Mbps

Fully Supports Full Duplex Switched Ethernet

Supports Burst Data Transfer

8 Kbytes Internal Memory for Receive and Transmit

FIFO Buffers

Enhanced Power Management Features

Optional Configuration via Serial EEPROM Interface

Supports 8, 16 and 32 Bit CPU Accesses

Internal 32 Bit Wide Data Path (Into Packet Buffer

Memory)

Built-in Transparent Arbitration for Slave Sequential

Access Architecture

Flat MMU Architecture with Symmetric Transmit and

Receive Structures and Queues

3.3V Operation with 5V Tolerant IO Buffers (See Pin

List Description for Additional Details)

Single 25 MHz Reference Clock for Both PHY and

MAC

External 25Mhz-output pin for an external PHY

supporting PHYs physical media.

Low Power CMOS Design

Supports Multiple Embedded Processor Host

Interfaces

—ARM

—SH

— Power PC

— Coldfire

— 680X0, 683XX

— MIPS R3000

3.3V MII (Media Independent Interface) MAC-PHY

Interface Running at Nibble Rate

MII Management Serial Interface

128-Pin QFP lead-free RoHS compliant package

128-Pin TQFP 1.0 mm height lead-free RoHS

compliant package

Commercial Temperature Range from 0°C to 70°C

(LAN91C111)

Industrial Temperature Range from -40°C to 85°C

(LAN91C111i)

Network Interface

Fully Integrated IEEE 802.3/802.3u-100Base-TX/

10Base-T Physical Layer

Auto Negotiation: 10/100, Full / Half Duplex

On Chip Wave Shaping - No External Filters

Required

Adaptive Equalizer

Baseline Wander Correction

LED Outputs (User selectable – Up to 2 LED

functions at one time)

—Link

—Activity

— Full Duplex

— 10/100

— Transmit

— Receive

Order Numbers:

LAN91C111-NS, LAN91C111i-NS (Industrial Temperature)

for 128-Pin QFP Lead-free RoHS Compliant packages

LAN91C111-NU (1.0mm height); LAN91C111i-NU (Industrial Temperature)

for 128-pin TQFP Lead-free RoHS Compliant packages

This product meets the halogen maximum concentration values per IEC61249-2-21

For RoHS compliance and environmental information, please visit www.smsc.com/rohs

10/100 Non-PCI Ethernet Single Chip MAC + PHY

Datasheet

Revision 1.92 (06-27-11) 2 SMSC LAN91C111 REV C

DATASHEET

80 ARKAY DRIVE, HAUPPAUGE, NY 11788 (631) 435-6000 or 1 (800) 443-SEMI

Circuit diagrams and other information relating to SMSC products are included as a means of illustrating typical applications. Consequently, complete information sufficient for

construction purposes is not necessarily given. Although the information has been checked and is believed to be accurate, no responsibility is assumed for inaccuracies. SMSC

reserves the right to make changes to specifications and product descriptions at any time without notice. Contact your local SMSC sales office to obtain the latest specifications

before placing your product order. The provision of this information does not convey to the purchaser of the described semiconductor devices any licenses under any patent

rights or other intellectual property rights of SMSC or others. All sales are expressly conditional on your agreement to the terms and conditions of the most recently dated

version of SMSC's standard Terms of Sale Agreement dated before the date of your order (the "Terms of Sale Agreement"). The product may contain design defects or errors

known as anomalies which may cause the product's functions to deviate from published specifications. Anomaly sheets are available upon request. SMSC products are not

designed, intended, authorized or warranted for use in any life support or other application where product failure could cause or contribute to personal injury or severe property

damage. Any and all such uses without prior written approval of an Officer of SMSC and further testing and/or modification will be fully at the risk of the customer. Copies of

this document or other SMSC literature, as well as the Terms of Sale Agreement, may be obtained by visiting SMSC’s website at http://www.smsc.com. SMSC is a registered

trademark of Standard Microsystems Corporation (“SMSC”). Product names and company names are the trademarks of their respective holders.

SMSC DISCLAIMS AND EXCLUDES ANY AND ALL WARRANTIES, INCLUDING WITHOUT LIMITATION ANY AND ALL IMPLIED WARRANTIES OF MERCHANTABILITY,

FITNESS FOR A PARTICULAR PURPOSE, TITLE, AND AGAINST INFRINGEMENT AND THE LIKE, AND ANY AND ALL WARRANTIES ARISING FROM ANY COURSE

OF DEALING OR USAGE OF TRADE. IN NO EVENT SHALL SMSC BE LIABLE FOR ANY DIRECT, INCIDENTAL, INDIRECT, SPECIAL, PUNITIVE, OR CONSEQUENTIAL

DAMAGES; OR FOR LOST DATA, PROFITS, SAVINGS OR REVENUES OF ANY KIND; REGARDLESS OF THE FORM OF ACTION, WHETHER BASED ON CONTRACT;

TORT; NEGLIGENCE OF SMSC OR OTHERS; STRICT LIABILITY; BREACH OF WARRANTY; OR OTHERWISE; WHETHER OR NOT ANY REMEDY OF BUYER IS HELD

TO HAVE FAILED OF ITS ESSENTIAL PURPOSE, AND WHETHER OR NOT SMSC HAS BEEN ADVISED OF THE POSSIBILITY OF SUCH DAMAGES.

10/100 Non-PCI Ethernet Single Chip MAC + PHY

Datasheet

SMSC LAN91C111 REV C 3 Revision 1.92 (06-27-11)

DATASHEET

Table of Contents

Chapter 1 General Description. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8

Chapter 2 Pin Configurations. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9

Chapter 3 Block Diagrams . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11

Chapter 4 Signal Descriptions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14

Chapter 5 Description of Pin Functions. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15

Chapter 6 Signal Description Parameters . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 19

6.1 Buffer Types . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 19

Chapter 7 Functional Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 20

7.1 Clock Generator Block . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 20

7.2 CSMA/CD Block . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 20

7.2.1 DMA Block. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 20

7.2.2 Arbiter Block . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 20

7.3 MMU Block . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 20

7.4 BIU Block . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21

7.5 MAC-PHY Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21

7.5.1 Management Data Software Implementation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21

7.5.2 Management Data Timing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 22

7.5.3 MI Serial Port Frame Structure . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 22

7.5.4 MII Packet Data Communication with External PHY . . . . . . . . . . . . . . . . . . . . . . . . . . . . 24

7.6 Serial EEPROM Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 25

7.7 Internal Physical Layer . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 25

7.7.1 MII Disable. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 27

7.7.2 Encoder . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 27

7.7.3 Decoder . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 27

7.7.4 Clock and Data Recovery . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 28

7.7.5 Scrambler . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 29

7.7.6 Descrambler . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 29

7.7.7 Twisted Pair Transmitter . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 30

7.7.8 Twisted Pair Receiver . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 33

7.7.9 Collision . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 35

7.7.10 Start of Packet . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 35

7.7.11 End of Packet . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 36

7.7.12 Link Integrity & AutoNegotiation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 37

7.7.13 Jabber . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 40

7.7.14 Receive Polarity Correction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 40

7.7.15 Full Duplex Mode. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 41

7.7.16 Loopback . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 41

7.7.17 PHY Powerdown . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 41

7.7.18 PHY Interrupt. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 42

7.8 Reset . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 42

Chapter 8 MAC Data Structures and Registers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 43

8.1 Frame Format In Buffer Memory . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 43

10/100 Non-PCI Ethernet Single Chip MAC + PHY

Datasheet

Revision 1.92 (06-27-11) 4 SMSC LAN91C111 REV C

DATASHEET

8.2 Receive Frame Status . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 45

8.3 I/O Space . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 46

8.4 Bank Select Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 47

8.5 Bank 0 - Transmit Control Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 48

8.6 Bank 0 - EPH Status Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 49

8.7 Bank 0 - Receive Control Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 50

8.8 Bank 0 - Counter Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 51

8.9 Bank 0 - Memory Information Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 52

8.10 Bank 0 - Receive/Phy Control Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 52

8.11 Bank 1 - Configuration Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 55

8.12 Bank 1 - Base Address Register. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 56

8.13 Bank 1 - Individual Address Registers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 57

8.14 Bank 1 - General Purpose Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 58

8.15 Bank 1 - Control Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 58

8.16 Bank 2 - MMU Command Register. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 60

8.17 Bank 2 - Packet Number Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 62

8.18 Bank 2 - FIFO Ports Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 63

8.19 Bank 2 - Pointer Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 64

8.20 Bank 2 - Data Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 65

8.21 Bank 2 - Interrupt Status Registers. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 66

8.22 Bank 3 - Multicast Table Registers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 70

8.23 Bank 3 - Management Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 71

8.24 Bank 3 - Revision Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 72

8.25 Bank 3 - RCV Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 72

8.26 Bank 7 - External Registers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 73

Chapter 9 PHY MII Registers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 74

9.1 Register 0. Control Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 78

9.2 Register 1. Status Register. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 79

9.3 Register 2&3. PHY Identifier Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 80

9.4 Register 4. Auto-Negotiation Advertisement Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 80

9.5 Register 5. Auto-Negotiation Remote End Capability Register . . . . . . . . . . . . . . . . . . . . . . . . . . . 81

9.6 Register 16. Configuration 1- Structure and Bit Definition . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 82

9.7 Register 17. Configuration 2 - Structure and Bit Definition . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 83

9.8 Register 18. Status Output - Structure and Bit Definition . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 84

9.9 Register 19. Mask - Structure and Bit Definition . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 86

9.10 Register 20. Reserved - Structure and Bit Definition . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 87

Chapter 10 Software Driver and Hardware Sequence Flow . . . . . . . . . . . . . . . . . . . . . . . . . 88

10.1 Software Driver and Hardware Sequence Flow for Power Management . . . . . . . . . . . . . . . . . . . . 88

10.2 Typical Flow of Events for Transmit (Auto Release = 0). . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 89

10.3 Typical Flow of Events for Transmit (Auto Release = 1). . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 90

10.4 Typical Flow of Event For Receive . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 91

Chapter 11 Board Setup Information . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 100

Chapter 12 Application Considerations. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 103

Chapter 13 Operational Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 110

13.1 Maximum Guaranteed Ratings* . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 110

13.2 DC Electrical Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 110

13.3 Twisted Pair Characteristics, Transmit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 113

13.4 Twisted Pair Characteristics, Receive . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 114

10/100 Non-PCI Ethernet Single Chip MAC + PHY

Datasheet

SMSC LAN91C111 REV C 5 Revision 1.92 (06-27-11)

DATASHEET

Chapter 14 Timing Diagrams . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 115

Chapter 15 Package Outlines . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 131

Chapter 16 Datasheet Revision History . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 133

10/100 Non-PCI Ethernet Single Chip MAC + PHY

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Revision 1.92 (06-27-11) 6 SMSC LAN91C111 REV C

DATASHEET

List of Figures

Figure 2.1 Pin Configuration - LAN91C111-FEAST 128 PIN TQFP . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9

Figure 2.2 Pin Configuration - LAN91C111-FEAST 128 PIN QFP . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10

Figure 3.1 Basic Functional Block Diagram . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11

Figure 3.2 Block Diagram . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12

Figure 3.3 LAN91C111 Physical Layer to Internal MAC Block Diagram. . . . . . . . . . . . . . . . . . . . . . . . . 13

Figure 7.1 MI Serial Port Frame Timing Diagram . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 23

Figure 7.2 MII Frame Format & MII Nibble Order . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 24

Figure 7.3 TX/10BT Frame Format . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 26

Figure 7.4 TP Output Voltage Template - 10 MBPS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 31

Figure 7.5 TP Input Voltage Template -10MBPS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 34

Figure 7.6 SOI Output Voltage Template - 10MBPS. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 37

Figure 7.7 Link Pulse Output Voltage Template - NLP, FLP. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 38

Figure 7.8 NLP VS. FLP Link Pulse . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 39

Figure 8.1 Data Frame Format . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 43

Figure 8.2 Interrupt Structure . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 69

Figure 10.1 Interrupt Service Routine . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 93

Figure 10.2 RX INTR. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 94

Figure 10.3 TX INTR . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 95

Figure 10.4 TXEMPTY INTR (Assumes Auto Release Option Selected) . . . . . . . . . . . . . . . . . . . . . . . . . 96

Figure 10.5 Drive Send and Allocate Routines . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 97

Figure 10.6 Interrupt Generation for Transmit, Receive, MMU . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 99

Figure 11.1 64 X 16 Serial EEPROM Map . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 102

Figure 12.1 LAN91C111 on VL BUS. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 105

Figure 12.2 LAN91C111 on ISA BUS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 107

Figure 12.3 LAN91C111 on EISA BUS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 109

Figure 14.1 Asynchronous Cycle - nADS=0 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 115

Figure 14.2 Asynchronous Cycle - Using nADS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 116

Figure 14.3 Asynchronous Cycle - nADS=0 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 117

Figure 14.4 Asynchronous Ready . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 117

Figure 14.5 Burst Write Cycles - nVLBUS=1 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 118

Figure 14.6 Burst Read Cycles - nVLBUS=1 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 119

Figure 14.7 Address Latching for All Modes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 120

Figure 14.8 Synchronous Write Cycle - nVLBUS=0 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 120

Figure 14.9 Synchronous Read Cycle - nVLBUS=0 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 121

Figure 14.10MII Timing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 122

Figure 14.11Transmit Timing. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 123

Figure 14.12Receive Timing, End of Packet - 10 MBPS. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 124

Figure 14.13Collision Timing, Receive . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 125

Figure 14.14Collision Timing, Transmit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 126

Figure 14.15Jam Timing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 127

Figure 14.16Link Pulse Timing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 129

Figure 14.17FLP Link Pulse Timing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 130

Figure 15.1 128 Pin TQFP Package Outline, 14X14X1.0 Body . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 131

Figure 15.2 128 Pin QFP Package Outline, 3.9 MM Footprint . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 132

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Datasheet

SMSC LAN91C111 REV C 7 Revision 1.92 (06-27-11)

DATASHEET

List of Tables

Table 4.1 LAN91C111 Pin Requirements (128 Pin QFP and 1.0mm TQFP package) . . . . . . . . . . . . . . 14

Table 7.1 4B/5B Symbol Mapping . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 27

Table 7.2 Transmit Level Adjust . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 32

Table 8.1 Internal I/O Space Mapping . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 46

Table 9.1 MII Serial Frame Structure. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 75

Table 9.2 MII Serial Port Register MAP. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 77

Table 10.1 Typical Flow Of Events For Placing Device In Low Power Mode . . . . . . . . . . . . . . . . . . . . . . 88

Table 10.2 Flow Of Events For Restoring Device In Normal Power Mode . . . . . . . . . . . . . . . . . . . . . . . . 89

Table 12.1 VL Local Bus Signal Connections . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 103

Table 12.2 High-End ISA or Non-Burst EISA Machines Signal Connectors . . . . . . . . . . . . . . . . . . . . . . 105

Table 12.3 EISA 32 Bit Slave Signal Connections . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 107

Table 14.1 Transmit Timing Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 123

Table 14.2 Receive Timing Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 124

Table 14.3 Collision and Jam Timing Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 124

Table 14.4 Link Pulse Timing Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 128

Table 15.1 128 Pin TQFP Package Parameters . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 131

Table 15.2 128 Pin QFP Package Parameters . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 132

Table 16.1 Customer Revision History . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 133

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Datasheet

Revision 1.92 (06-27-11) 8 SMSC LAN91C111 REV C

DATASHEET

Chapter 1 General Description

The SMSC LAN91C111 is designed to facilitate the implementation of a third generation of Fast

Ethernet connectivity solutions for embedded applications. For this third generation of products,

flexibility and integration dominate the design requirements. The LAN91C111 is a mixed signal

Analog/Digital device that implements the MAC and PHY portion of the CSMA/CD protocol at 10 and

100 Mbps. The design will also minimize data throughput constraints utilizing a 32-bit, 16-bit or 8-bit

bus Host interface in embedded applications.

The total internal memory FIFO buffer size is 8 Kbytes, which is the total chip storage for transmit and

receive operations.

The SMSC LAN91C111 is software compatible with the LAN9000 family of products.

Memory management is handled using a patented optimized MMU (Memory Management Unit)

architecture and a 32-bit wide internal data path. This I/O mapped architecture can sustain back-to-

back frame transmission and reception for superior data throughput and optimal performance. It also

dynamically allocates buffer memory in an efficient buffer utilization scheme, reducing software tasks

and relieving the host CPU from performing these housekeeping functions.

The SMSC LAN91C111 provides a flexible slave interface for easy connectivity with industry-standard

buses. The Bus Interface Unit (BIU) can handle synchronous as well as asynchronous transfers, with

different signals being used for each one. Asynchronous bus support for ISA is supported even though

ISA cannot sustain 100 Mbps traffic. Fast Ethernet data rates are attainable for ISA-based nodes on

the basis of the aggregate traffic benefits.

Two different interfaces are supported on the network side. The first Interface is a standard Magnetics

transmit/receive pair interfacing to 10/100Base-T utilizing the internal physical layer block. The second

interface follows the MII (Media Independent Interface) specification standard, consisting of 4 bit wide

data transfers at the nibble rate. This interface is applicable to 10 Mbps standard Ethernet or 100 Mbps

Ethernet networks. Three of the LAN91C111’s pins are used to interface to the two-line MII serial

management protocol.

The SMSC LAN91C111 integrates IEEE 802.3 Physical Layer for twisted pair Ethernet applications.

The PHY can be configured for either 100 Mbps (100Base-TX) or 10 Mbps (10Base-T) Ethernet

operation. The Analog PHY block consists of a 4B5B/Manchester encoder/decoder, scrambler/de-

scrambler, transmitter with wave shaping and output driver, twisted pair receiver with on chip equalizer

and baseline wander correction, clock and data recovery, Auto-Negotiation, controller interface (MII),

and serial port (MI). Internal output wave shaping circuitry and on-chip filters eliminate the need for

external filters normally required in 100Base-TX and 10Base-T applications.

The LAN91C111 can automatically configure itself for 100 or 10 Mbps and Full or Half Duplex operation

with the on-chip Auto-Negotiation algorithm. The LAN91C111 is ideal for media interfaces for

embedded application desiring Ethernet connectivity as well as 100Base-TX/10Base-T adapter cards,

motherboards, repeaters, switching hubs. The LAN91C111 operates from a single 3.3V supply. The

inputs and outputs of the host Interface are 5V tolerant and will directly interface to other 5V devices.

10/100 Non-PCI Ethernet Single Chip MAC + PHY

Datasheet

SMSC LAN91C111 REV C 9 Revision 1.92 (06-27-11)

DATASHEET

Chapter 2 Pin Configurations

Figure 2.1 Pin Configuration - LAN91C111-FEAST 128 PIN TQFP

128

127

126

125

124

123

122

121

120

119

118

117

116

115

114

113

112

111

110

109

108

107

106

105

104

103

102

101

100

Pin Configuration

nBE2

nBE1

nBE0

GND

A15

A14

A13

A12

A11

A10

VDD

D10

D11

GND

D12

D13

D14

D15

GND

D16

D17

VDD

nCSOUT

IOS0

IOS1

IOS2

ENEEP

EEDO

EEDI

EESK

EECS

AVDD

RBIAS

AGND

TPO+

TPO-

AVDD

TPI+

TPI-

AGND

nLNK

LBK

nLEDA

nLEDB

GND

MDI

MDO

MCLK

nCNTRL

INTR0

RESET

nRD

nWR

XTAL2

XTAL1

RX_ER

RX_DV

RXD0

RXD1

RXD2

RXD3

VDD

CRS100

RX25

GND

TXD0

TXD1

TXD2

TXD3

COL100

TXEN100

VDD

TX25

GND

VDD

nBE3

VDD

nDATACS

nCYCLE

W/nR

nADS

ARDY

GND

nVLBUS

AEN

LCLK

nSRDY

VDD

nLDEV

nRDYRTN

X25OUT

D31

D30

D29

D28

GND

D27

D26

D25

D24

GND

D23

D22

D21

D20

VDD

D19

D18

LAN91C111-

FEAST

128 PIN TQFP

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Datasheet

Revision 1.92 (06-27-11) 10 SMSC LAN91C111 REV C

DATASHEET

Figure 2.2 Pin Configuration - LAN91C111-FEAST 128 PIN QFP

128

127

126

125

124

123

122

121

120

119

118

117

116

115

114

113

112

111

110

109

108

107

106

105

104

103

102

101

100

Pin Configuration

LAN91C111-

FEAST

128 PIN QFP

XTAL1

XTAL2

VDD

nCSOUT

IOS0

IOS1

IOS2

ENEEP

EEDO

EEDI

EESK

EECS

AVDD

RBIAS

AGND

TPO+

TPO-

AVDD

TPI+

TPI-

AGND

nLNK

LBK

nLEDA

nLEDB

GND

MDI

MDO

MCLK

nCNTRL

INTR0

RESET

nRD

nWR

VDD

nDATACS

nCYCLE

W/nR

RX_ER

RX_DV

RXD0

RXD1

RXD2

RXD3

VDD

CRS100

RX25

GND

TXD0

TXD1

TXD2

TXD3

COL100

TXEN100

VDD

TX25

GND

VDD

nBE3

nBE2

nBE1

nBE0

GND

A15

A14

A13

A12

A11

A10

VDD

D10

D11

GND

D12

D13

D14

D15

GND

D16

D17

D18

D19

nADS

ARDY

GND

nVLBUS

AEN

LCLK

nSRDY

VDD

nLDEV

nRDYRTN

X25OUT

D31

D30

D29

D28

GND

D27

D26

D25

D24

GND

D23

D22

D21

D20

VDD

10/100 Non-PCI Ethernet Single Chip MAC + PHY

Datasheet

SMSC LAN91C111 REV C 11 Revision 1.92 (06-27-11)

DATASHEET

Chapter 3 Block Diagrams

The diagram shown in Figure 3.1, "Basic Functional Block Diagram", describes the device basic

functional blocks. The SMSC LAN91C111 is a single chip solution for embedded designs with minimal

Host and external supporting devices required to implement 10/100 Ethernet connectivity solutions.

The optional Serial EEPROM is used to store information relating to default IO offset parameters as

well as which of the Interrupt line are used by the host.

Figure 3.1 Basic Functional Block Diagram

PHY

Core

Ethernet

MAC

LAN91C111

Internal IEEE 802.3 MII (Media

Independent Interface)

Serial

EEProm

(Optional)

ISA,Embedded

Processor

Transformer

RJ45

Minimal LAN91C111

Configuration

Host System

TX/RX Buffer (8K)

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Datasheet

Revision 1.92 (06-27-11) 12 SMSC LAN91C111 REV C

DATASHEET

The diagram shown in Figure 3.2 describes the supported Host interfaces, which include ISA or

Generic Embedded. The Host interface is an 8, 16 or 32 bit wide address / data bus with extensions

for 32, 16 and 8 bit embedded RISC and ARM processors.

The figure shown next page describes the SMSC LAN91C111 functional blocks required to integrate

a 10/100 Ethernet Physical layer framer to the internal MAC.

Figure 3.2 Block Diagram

8-32 bit

Bus

Interface

Unit

Arbiter

DMA

MMU

Ethernet

Protocol

Handler

(EPH)

10/100

PHY

8K Byte

Dynamically

Allocated

SRAM

FIFO

Control

RX Data

TX Data

Control

MII

Address

Data

Control Control

RXD[0-3]

TXD[0-3]

Control

TX/RX

FIFO

Pointer

TPI

TPO

Control

EEPROM

INTERFACE

32-bit Data

10/100 Non-PCI Ethernet Single Chip MAC + PHY

Datasheet

SMSC LAN91C111 REV C 13 Revision 1.92 (06-27-11)

DATASHEET

Figure 3.3 LAN91C111 Physical Layer to Internal MAC Block Diagram

COLLISION

4B5B

DECODER

DESCRAMBL

CLOCK &

DATA

RECOVERY

AUTO

NEGOTIATION

& LINK

SQUELCH

CLOCK &

DATA

Recovery

(Manchester

Decoder)

FILTER

ROMDAC+

10BASE-T

TRANSMITTER

CLOCK

GEN

(PLL)

MANCHESTER

4B5B

ENCODERSCRAMBLER

TPO+

SWITCHED

CURRENT

SOURCE

100BASE-TX

TRANSMITTER

CLOCK

GEN

(PLL)

TPO-

FILTER

TPI+

TPI-

FILTER

+/- Vth

10BASE-T

RECEIVER

MLT3

ENCODER

ADAPTIVE

EQUALIZER

+/- Vth

100BASE-TX

RECEIVER

MLT

ENCODER

SQUELCH

RBIAS

CSMA/CD

Multiplexer

LS[2-0]B

LEDA

LEDB

nPLED[0-5]

LS[2-0]A

LED

Control

Power

Reset

PHY

CONTROLS

TXD[3:0]

TX_ER

TXEN100

TX25

CRS100

COL100

RXD[3:0]

RX_ER

RX_DV

RX25

MCLK

MDO

EECS

EESK

EEDO

To MII External Signals

MII

AUTONEG

LOGIC

EEPROM

CONTROL

MDI

MII

SERIAL

Manage

-ment

MII External

Signals

EEDI

Multiplexer

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Datasheet

Revision 1.92 (06-27-11) 14 SMSC LAN91C111 REV C

DATASHEET

Chapter 4 Signal Descriptions

Table 4.1 LAN91C111 Pin Requirements (128 Pin QFP and 1.0mm TQFP package)

FUNCTION PIN SYMBOLS NUMBER OF PINS

System Address Bus A1-A15, AEN, nBE0-nBE3 20

System Data Bus D0-D31 32

System Control Bus RESET, nADS, LCLK, ARDY,

nRDYRTN, nSRDY, INTR0, nLDEV,

nRD, nWR, nDATACS, nCYCLE, W/nR,

nVLBUS

Serial EEPROM EEDI, EEDO, EECS, EESK, ENEEP,

IOS0-IOS2

LEDs nLEDA, nLEDB 2

PHY TPO+, TPO-, TPI+, TPI-, nLNK, LBK,

nCNTRL, RBIAS

Crystal Oscillator XTAL1, XTAL2 2

Power VDD, AVDD 10

Ground GND, AGND 12

Physical Interface (MII) TXEN100, CRS100, COL100, RX_DV,

RX_ER, TXD0-TXD3, RXD0-RXD3,

MDI, MDO, MCLK, RX25, TX25

MISC nCSOUT, X25OUT 2

TOTAL 128

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Datasheet

SMSC LAN91C111 REV C 15 Revision 1.92 (06-27-11)

DATASHEET

Chapter 5 Description of Pin Functions

PIN NO.

NAME SYMBOL BUFFER

TYPE DESCRIPTION

TQFP QFP

81-92 83-94 Address A4-A15 I** Input. Decoded by LAN91C111 to

determine access to its registers.

78-80 80-82 Address A1-A3 I** Input. Used by LAN91C111 for internal

41 43 Address Enable AEN I** Input. Used as an address qualifier.

Address decoding is only enabled when

AEN is low.

94-97 96-99 nByte Enable nBE0-

nBE3

I** Input. Used during LAN91C111 register

accesses to determine the width of the

access and the register(s) being

accessed. nBE0-nBE3 are ignored when

nDATACS is low (burst accesses)

because 32 bit transfers are assumed.

107-104,

102-99, 76-

73, 71-68,

66-63, 61-

58, 56-53,

51-48

109-106,

104-101,

78-75, 73-

70, 68-65,

63-60, 58-

55, 53-50

Data Bus D0-D31 I/O24** Bidirectional. 32 bit data bus used to

access the LAN91C111’s internal

registers. Data bus has weak internal

pullups. Supports direct connection to the

system bus without external buffering.

For 16 bit systems, only D0-D15 are

used.

30 32 Reset RESET IS** Input. When this pin is asserted high, the

controller performs an internal system

(MAC & PHY) reset. It programs all the

registers to their default value, the

controller will read the EEPROM device

through the EEPROM interface (Note 5.1).

This input is not considered active unless

it is active for at least 100ns to filter

narrow glitches.

37 39 nAddress

Strobe

nADS IS** Input. For systems that require address

latching, the rising edge of nADS

indicates the latching moment for A1-A15

and AEN. All LAN91C111 internal

functions of A1-A15, AEN are latched

except for nLDEV decoding.

35 37 nCycle nCYCLE I** Input. This active low signal is used to

control LAN91C111 EISA burst mode

synchronous bus cycles.

36 38 Write/

nRead

W/nR IS** Input. Defines the direction of

synchronous cycles. Write cycles when

high, read cycles when low.

40 42 nVL Bus Access nVLBUS I with

pullup**

Input. When low, the LAN91C111

synchronous bus interface is configured

for VL Bus accesses. Otherwise, the

LAN91C111 is configured for EISA DMA

burst accesses. Does not affect the

asynchronous bus interface.

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Datasheet

Revision 1.92 (06-27-11) 16 SMSC LAN91C111 REV C

DATASHEET

42 44 Local Bus Clock LCLK I** Input. Used to interface synchronous

buses. Maximum frequency is 50 MHz.

Limited to 8.33 MHz for EISA DMA burst

mode. This pin should be tied high if it is

in asynchronous mode.

38 40 Asynchronous

Ready

ARDY OD16 Open drain output. ARDY may be used

when interfacing asynchronous buses to

extend accesses. Its rising (access

completion) edge is controlled by the

XTAL1 clock and, therefore,

asynchronous to the host CPU or bus

clock. ARDY is negated during

Asynchronous cycle when one of the

following conditions occurs:

No_Wait Bit in the Configuration Register

is cleared.

Read FIFO contains less than 4 bytes

when read.

Write FIFO is full when write.

43 45 nSynchronous

Ready

nSRDY O16 Output. This output is used when

interfacing synchronous buses and

nVLBUS=0 to extend accesses. This

signal remains normally inactive, and its

falling edge indicates completion. This

signal is synchronous to the bus clock

LCLK.

46 48 nReady Return nRDYRTN I** Input. This input is used to complete

synchronous read cycles. In EISA burst

mode it is sampled on falling LCLK

edges, and synchronous cycles are

delayed until it is sampled high.

29 31 Interrupt INTR0 O24 Interrupt Output – Active High, it’s used to

interrupt the Host on a status event.

Note: The selection bits used to

determined by the value of INT SEL 1-0

bits in the Configuration Register are no

longer required and have been set to

reserved in this revision of the FEAST

family of devices.

45 47 nLocal Device nLDEV O16 Output. This active low output is asserted

when AEN is low and A4-A15 decode to

the LAN91C111 address programmed

into the high byte of the Base Address

decode of unlatched address and AEN

signals.

31 33 nRead Strobe nRD IS** Input. Used in asynchronous bus

interfaces.

32 34 nWrite Strobe nWR IS** Input. Used in asynchronous bus

interfaces.

34 36 nData Path

Chip Select

nDATACS I with

pullup**

Input. When nDATACS is low, the Data

Path can be accessed regardless of the

values of AEN, A1-A15 and the content of

the BANK SELECT Register. nDATACS

provides an interface for bursting to and

from the LAN91C111 32 bits at a time.

PIN NO.

NAME SYMBOL BUFFER

TYPE DESCRIPTION

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9 11 EEPROM Clock EESK O4 Output. 4 μsec clock used to shift data in

and out of the serial EEPROM.

10 12 EEPROM

Select

EECS O4 Output. Serial EEPROM chip select.

Used for selection and command framing

of the serial EEPROM.

7 9 EEPROM Data

Out

EEDO O4 Output. Connected to the DI input of the

serial EEPROM.

8 10 EEPROM Data

EEDI I with

pulldown **

Input. Connected to the DO output of the

serial EEPROM.

3-5 5-7 I/O Base IOS0-IOS2 I with

pullup**

Input. External switches can be

connected to these lines to select

between predefined EEPROM

configurations.

68Enable

EEPROM

ENEEP I with

pullup**

Input. Enables (when high or open)

LAN91C111 accesses to the serial

EEPROM. Must be grounded if no

EEPROM is connected to the

LAN91C111.

127, 128 1, 2 Crystal 1

Crystal 2

XTAL1

XTAL2

Iclk** An external 25 MHz crystal is connected

across these pins. If a TTL clock is

supplied instead, it should be connected

to XTAL1 and XTAL2 should be left open.

XTAL1 is the 5V tolerant input of the

internal amplifier and XTAL2 is the output

of the internal amplifier.

1, 33, 44,

62, 77, 98,

110, 120

3, 35, 46,

64, 79,

100, 112,

122

Power VDD +3.3V Power supply pins.

11, 16 13, 18 Analog Power AVDD +3.3V Analog power supply pins.

24, 39, 52,

57, 67, 72,

93, 103,

108, 117

26, 41, 54,

59, 69, 74,

95, 105,

110, 119

Ground GND Ground pins.

13, 19 15, 21 Analog Ground AGND Analog Ground pins

21 23 Loopback LBK O4 Output. Active when LOOP bit is set

(TCR bit 1).

20 22 nLink Status nLNK I with

pullup

Input. General-purpose input port used to

convey LINK status (EPHSR bit 14).

28 30 nCNTRL nCNTRL O12 General Purpose Control Pin

47 49 X25out X25out O12 25Mhz Output to external PHY

111 113 Transmit Enable

100 Mbps

TXEN100 O12 Output to MII PHY. Envelope to 100

Mbps transmission.

119 121 Carrier Sense

100 Mbps

CRS100 I with

pulldown

Input from MII PHY. Envelope of packet

reception used for deferral and backoff

purposes.

PIN NO.

NAME SYMBOL BUFFER

TYPE DESCRIPTION

TQFP QFP

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Note 5.1 If the EEPROM is enabled.

125 127 Receive Data

Valid

RX_DV I with

pulldown

Input from MII PHY. Envelope of data

valid reception. Used for receive data

framing.

112 114 Collision Detect

100 Mbps

COL100 I with

pulldown

Input from MII PHY. Collision detection

input.

113-116 115-118 Transmit Data TXD3-

TXD0

O12 Outputs. Transmit Data nibble to MII

PHY.

109 111 Transmit Clock TX25 I with

pullup

Input. Transmit clock input from MII.

Nibble rate clock (25MHz for 100Mbps &

2.5MHz for 10Mbps).

118 120 Receive Clock RX25 I with

pullup

Input. Receive clock input from MII PHY.

Nibble rate clock. (25MHz for 100Mbps &

2.5MHz for 10Mbps).

121-124 123-126 Receive Data RXD3-

RXD0

I with

pullup

Inputs. Received Data nibble from MII

PHY.

25 27 Management

Data Input

MDI I with

pulldown

MII management data input.

26 28 Management

Data Output

MDO O4 MII management data output.

27 29 Management

Clock

MCLK O4 MII management clock.

126 128 Receive Error RX_ER I with

pulldown

Input. Indicates a code error detected by

PHY. Used by the LAN91C111 to discard

the packet being received. The error

indication reported for this event is the

same as a bad CRC (Receive Status

Word bit 13).

2 4 nChip Select

Output

nCSOUT O4 Output. Chip Select provided for

mapping of PHY functions into

LAN91C111 decoded space. Active on

accesses to LAN91C111’s eight lower

addresses when the BANK SELECTED is

12 14 External

Resistor

RBIAS NA Transmit Current Set. An external

resistor connected between this pin and

GND will set the output current for the TP

transmit outputs

14 16 TPO+ O/I Twisted Pair Transmit Output, Positive.

15 17 TPO- O/I Twisted Pair Transmit Output, Negative

17 19 TPI+ I/O Twisted Pair Receive Input, Positive

18 20 TPI- I/O Twisted Pair Receive Input, Negative.

22 24 nLEDA OD24 PHY LED Output

23 25 nLEDB OD24 PHY LED Output

PIN NO.

NAME SYMBOL BUFFER

TYPE DESCRIPTION

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Chapter 6 Signal Description Parameters

This section provides a detailed description of each SMSC LAN91C111 signal. The signals are

arranged in functional groups according to their associated function.

The ‘n’ symbol at the beginning of a signal name indicates that it is an active low signal. When ‘n’ is

not present before the signal name, it indicates an active high signal.

The term “assert” or “assertion” indicates that a signal is active; independent of whether that level is

represented by a high or low voltage. The term negates or negation indicates that a signal is inactive.

The term High-Z means tri-stated.

The term Undefined means the signal could be high, low, tri-stated, or in some in-between level.

6.1 Buffer Types

DC levels and conditions defined in the DC Electrical Characteristics section.

O4 Output buffer with 2mA source and 4mA sink

O12 Output buffer with 6mA source and 12mA sink

O16 Output buffer with 8mA source and 16mA sink

O24 Output buffer with 12mA source and 24mA sink

OD16 Open drain buffer with 16mA sink

OD24 Open drain buffer with 24mA sink

I/O4 Bidirectional buffer with 2mA source and 4mA sink

I/O24 Bidirectional buffer with 12mA source and 24mA sink

I/OD Bidirectional Open drain buffer with 4mA sink

I Input buffer

IS Input buffer with Schmitt Trigger Hysteresis

Iclk Clock input buffer

I/O Differential Input

O/I Differential Output

** 5V tolerant. Input pins are able to accept 5V signals

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Chapter 7 Functional Description

7.1 Clock Generator Block

1. The XTAL1 and XTAL2 pins are to be connected to a 25 MHz crystal.

2. TX25 is an input clock. It will be the nibble rate of the particular PHY connected to the MII (2.5

MHz for a 10 Mbps PHY, and 25 MHz for a 100 Mbps PHY).

3. RX25 - This is the MII nibble rate receive clock used for sampling received data nibbles and

running the receive state machine. (2.5 MHz for a 10 Mbps PHY, and 25 MHz for a 100 Mbps PHY).

4. LCLK - Bus clock - Used by the BIU for synchronous accesses. Maximum frequency is 50 MHz

for VL BUS mode, and 8.33 MHz for EISA slave DMA.

7.2 CSMA/CD Block

This is a 16 bit oriented block, with fully- independent Transmit and Receive logic. The data path in

and out of the block consists of two 16-bit wide uni-directional FIFOs interfacing the DMA block. The

DMA port of the FIFO stores 32 bits to exploit the 32 bit data path into memory, but the FIFOs

themselves are 16 bit wide. The Control Path consists of a set of registers interfaced to the CPU via

the BIU.

7.2.1 DMA Block

This block accesses packet memory on the CSMA/CD’s behalf, fetching transmit data and storing

received data. It interfaces the CSMA/CD Transmit and Receive FIFOs on one side and the Arbiter

block on the other. To increase the bandwidth into memory, a 50 MHz clock is used by the DMA block,

and the data path is 32 bits wide.

For example, during active reception at 100 Mbps, the CSMA/CD block will write a word into the

Receive FIFO every 160ns. The DMA will read the FIFO and accumulate two words on the output port

to request a memory cycle from the Arbiter every 320ns.

The DMA machine is able to support full duplex operation. Independent receive and transmit counters

are used. Transmit and receive cycles are alternated when simultaneous receive and transmit

accesses are needed.

7.2.2 Arbiter Block

The Arbiter block sequences accesses to packet RAM requested by the BIU and by the DMA blocks.

BIU requests represent pipelined CPU accesses to the Data Register, while DMA requests represent

CSMA/CD data movement.

Internal SRAM read accesses are always 32 bit wide, and the Arbiter steers the appropriate byte(s) to

the appropriate lanes as a function of the address.

The CPU Data Path consists of two uni-directional FIFOs mapped at the Data Register location. These

FIFOs can be accessed in any combination of bytes, word, or doublewords. The Arbiter will indicate

'Not Ready' whenever a cycle is initiated that cannot be satisfied by the present state of the FIFO.

7.3 MMU Block

The Hardware Memory Management Unit allocates memory and transmit and receive packet queues.

It also determines the value of the transmit and receive interrupts as a function of the queues. The

page size is 2048 bytes, with a maximum memory size of 8kbytes. MIR values are interpreted in 2048

byte units.

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7.4 BIU Block

The Bus Interface Unit can handle synchronous as well as asynchronous buses; different signals are

used for each one. Transparent latches are added on the address path using rising nADS for latching.

When working with an asynchronous bus like ISA, the read and write operations are controlled by the

edges of nRD and nWR. ARDY is used for notifying the system that it should extend the access cycle.

The leading edge of ARDY is generated by the leading edge of nRD or nWR while the trailing edge

of ARDY is controlled by the internal LAN91C111 clock and, therefore, asynchronous to the bus.

In the synchronous VL Bus type mode, nCYCLE and LCLK are used to for read and write operations.

Completion of the cycle may be determined by using nSRDY. nSRDY is controlled by LCLK and

synchronous to the bus.

Direct 32 bit access to the Data Path is supported by using the nDATACS input. By asserting

nDATACS, external DMA type of devices will bypass the BIU address decoders and can sequentially

access memory with no CPU intervention. nDATACS accesses can be used in the EISA DMA burst

mode (nVLBUS=1) or in asynchronous cycles. These cycles MUST be 32 bit cycles. Please refer to

the corresponding timing diagrams for details on these cycles.

The BIU is implemented using the following principles:

a. Address decoding is based on the values of A15-A4 and AEN.

b. Address latching is performed by using transparent latches that are transparent when nADS=0 and

nRD=1, nWR=1 and latch on nADS rising edge.

c. Byte, word and doubleword accesses to all registers and Data Path are supported except a

doubleword write to offset Ch will only write the BANK SELECT REGISTER (offset 0x0Fh).

d. No bus byte swapping is implemented (no eight bit mode).

e. Word swapping as a function of A1 is implemented for 16 bit bus support.

f. The asynchronous interface uses nRD and nWR strobes. If necessary, ARDY is negated on the

leading edge of the strobe. The ARDY trailing edge is controlled by CLK.

g. The VLBUS synchronous interface uses LCLK, nADS, and W/nR as defined in the VESA

specification as well as nCYCLE to control read and write operations and generate nSRDY.

h. EISA burst DMA cycles to and from the DATA REGISTER are supported as defined in the EISA

Slave Mode "C" specification when nDATACS is driven by nDAK.

i. Synchronous and asynchronous cycles can be mixed as long as they are not active simultaneously.

j. Address and bank selection can be bypassed to generate 32 bit Data Path accesses by activating

the nDATACS pin.

7.5 MAC-PHY Interface

The LAN91C111 integrates the IEEE 802.3 Physical Layer (PHY) and Media Access Control (MAC)

into the same silicon. The data path connection between the MAC and the internal PHY is provided

by the internal MII. The LAN91C111 also supports the EXT_PHY mode for the use of an external PHY,

such as HPNA. This mode isolates the internal PHY to allow interface with an external PHY through

the MII pins. To enter this mode, set EXT PHY bit to 1 in the Configuration Register.

7.5.1 Management Data Software Implementation

The MII interface contains of a pair of signals that physically transport the management information

across the MII, a frame format and a protocol specification for exchanging management frames, and

a register set that can be read and written using these frames. MII management refers to the ability

of a management entity to communicate with PHY via the MII serial management interface (MI) for the

purpose of displaying, selecting and/or controlling different PHY options. The host manipulates the

MAC to drive the MII management serial interface. By manipulating the MAC's registers, MII

management frames are generated on the management interface for reading or writing information

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from the PHY registers. Timing and framing for each management command is to be generated by

the CPU (host).

The MAC and external PHY communicate via MDIO and MDC of the MII Management serial interface.

MDIO:Management Data input/output. Bi-directional between MAC and PHY that carries management

data. All control and status information sent over this pin is driven and sampled synchronously to the

rising edge of MDC signal.

MDC:Management Data Clock. Sourced by the MAC as a timing reference for transfer of information

on the MDIO signal. MDC is a periodic signal with no maximum high or low times. The minimum high

and low times should be 160ns each and the minimum period of the signal should be 400ns. These

values are regardless of the nominal period of the TX and RX clocks.

7.5.2 Management Data Timing

A timing diagram for a Ml serial port frame is shown in Figure 7.1. The Ml serial port is idle when at

least 32 continuous 1's are detected on MDIO and remains idle as long as continuous 1's are detected.

During idle, MDIO is in the high impedance state. When the Ml serial port is in the idle state, a 01

pattern on the MDIO initiates a serial shift cycle. Data on MDIO is then shifted in on the next 14 rising

edges of MDC (MDIO is high impedance). If the register access mode is not enabled, on the next 16

rising edges of MDC, data is either shifted in or out on MDIO, depending on whether a write or read

cycle was selected with the bits READ and WRITE. After the 32 MDC cycles have been completed,

one complete register has been read/written, the serial shift process is halted, data is latched into the

device, and MDIO goes into high impedance state. Another serial shift cycle cannot be initiated until

the idle condition (at least 32 continuous 1's) is detected.

7.5.3 MI Serial Port Frame Structure

The structure of the PHY serial port frame is shown in Table 9.1 and timing diagram of a frame is

shown in Figure 7.1. Each serial port access cycle consists of 32 bits (or 192 bits if multiple register

access is enabled and REGAD[4:0]=11111), exclusive of idle. The first 16 bits of the serial port cycle

are always write bits and are used for addressing. The last 16/176 bits are from one/all of the 11 data

registers.

The first 2 bit in Table 9.1and Figure 7.1 are start bits and need to be written as a 01 for the serial port

cycle to continue. The next 2 bits are a read and write bit which determine if the accessed data register

bits will be read or write. The next 5 bits are device addresses. The next 5 bits are register address

select bits, which select one of the five data registers for access. The next 1 bit is a turnaround bit

which is not an actual register bit but extra time to switch MDIO from write to read if necessary, as

shown in Figure 7.1. The final 16 bits of the PHY Ml serial port cycle (or 176 bits if multiple register

access is enabled and REGAD[4:0]=11111) come from the specific data register designated by the

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Figure 7.1 MI Serial Port Frame Timing Diagram

MDIO

MDC02

1347

58910111213141516171819202122232425262728293031

11P4P1

P3P0R4R3R2R1R010D15D14D13D12D11D10D9D8D7D6D5D4D3D2D1D0

ST[1:0]OP[1:0]PHYAD[4:0]REGAD[4:0]TA[1:0]DATA[15:0]

WRITE

BITS

PHY CLOCKS IN DATA ON RISING EDGES OF MDC

WRITE CYCLE

MDIO

MDC02

1347

58910111213141516171819202122232425262728293031

10P4P1

P3P0R4R3R2R1R0Z0D15D14D13D12D11D10D9D8D7D6D5D4D3D2D1D0

ST[1:0]OP[1:0]PHYAD[4:0]REGAD[4:0]TA[1:0]DATA[15:0]

WRITE

BITS

PHY CLOCKS IN DATA ON RISING EDGES OF MDC

READ CYCLE

READ BITS

PHY CLOCKS OUT DATA ON RISING EDGES OF MDC

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7.5.4 MII Packet Data Communication with External PHY

The MIl is a nibble wide packet data interface defined in IEEE 802.3. The LAN91C111 meets all the

MIl requirements outlined in IEEE 802.3 and shown in Figure 7.2.

The Mll consists of the following signals: four transmit data bits (TXD[3:0]), transmit clock

(TX25),transmit enable (TXEN100), four receive data bits(RXD[3:0]), receive clock(RX25), carrier

sense (CRS100), receive data valid (RX_DV), receive data error (RX_ER), and collision (COL100).

Transmit data is clocked out using the TX25 clock input, while receive data is clocked in using RX25. The

transmit and receive clocks operate at 25 MHz in 100Mbps mode and 2.5 MHz in 10Mbps.

In 100 Mbps mode, the LAN91C111 provides the following interface signals to the PHY:

For transmission: TXEN100, TXD0-3, TX25

For reception: RX_DV, RX_ER, RXD0-3, RX25

For CSMA/CD state machines: CRS100, COL100

A transmission begins by TXEN100 going active (high), and TXD0-TXD3 having the first valid

preamble nibble. TXD0 carries the least significant bit of the nibble (that is the one that would go first

out of the EPH at 100 Mbps), while TXD3 carries the most significant bit of the nibble. TXEN100 and

TXD0-TXD3 are clocked by the LAN91C111 using TX25 rising edges. TXEN100 goes inactive at the

end of the packet on the last nibble of the CRC.

During a transmission, COL100 might become active to indicate a collision. COL100 is asynchronous

to the LAN91C111’s clocks and will be synchronized internally to TX25.

Reception begins when RX_DV (receive data valid) is asserted. A preamble pattern or flag octet will

be present at RXD0-RXD3 when RX_DV is activated. The LAN91C111 requires no training sequence

Figure 7.2 MII Frame Format & MII Nibble Order

IDLE PREAMBLE

PRMBLE SFD DATA 1 DATA N-1 DATA N

START

FRAME

DELIM.

62 BT

DATA 2

DATA NIBBLES

2 BT

IDLE

TX_EN = 0 TX_EN = 0

TX_EN = 1

FIRST

NIBBLE

FIRST BIT MAC's SERIAL BIT STREAM

D0 D1 D2 D3 D4 D5 D6 D7

TXD0 / RXD0

TXD3 / RXD3

TXD2 / RXD2

TXD1 / RXD1

MSB

SECOND

NIBBLE

MII

NIBBLE

STREAM

LSB

= [ BETWEEN 64-1518 DATA BYTES ]

= [ 1 1 ]

= [ 1 0 1 0 ... ] 62 BITS LONG

IDLE = TX_EN = 0

DATAn

SFD

PREAMBLE

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beyond a full flag octet for reception. RX_DV as well as RXD0-RXD3 are sampled on RX25 rising

edges. RXD0 carries the least significant bit and RXD3 the most significant bit of the nibble. RX_DV

goes inactive when the last valid nibble of the packet (CRC) is presented at RXD0-RXD3.

RX_ER might be asserted during packet reception to signal the LAN91C111 that the present receive

packet is invalid. The LAN91C111 will discard the packet by treating it as a CRC error.

RXD0-RXD3 should always be aligned to packet nibbles, therefore, opening flag detection does not

consider misaligned cases. Opening flag detection expects the 5Dh pattern and will not reject the

packet on non-preamble patterns.

CRS100 is used as a frame envelope signal for the CSMA/CD MAC state machines (deferral and

backoff functions), but it is not used for receive framing functions. CRS100 is an asynchronous signal

and it will be active whenever there is activity on the cable, including LAN91C111 transmissions and

collisions.

7.6 Serial EEPROM Interface

This block is responsible for reading the serial EEPROM upon hardware reset (or equivalent

command) and defining defaults for some key registers. A write operation is also implemented by this

block, that under CPU command will program specific locations in the EEPROM. This block is an

autonomous state machine and controls the internal Data Bus of the LAN91C111 during active

operation.

7.7 Internal Physical Layer

The LAN91C111 integrates the IEEE 802.3 physical layer (PHY) internally. The EXT PHY bit in the

Configuration Register is 0 as the default configuration to set the internal PHY enabled. The internal

PHY address is 00000, the driver must use this address to talk to the internal PHY. The internal PHY

is placed in isolation mode at power up and reset. It can be removed from isolation mode by clearing

the MII_DIS bit in the PHY Control Register. If necessary, the internal PHY can be enabled by clearing

the EXT_PHY bit in the Configuration Register.

The internal PHY of LAN91C111 has nine main sections: controller interface, encoder, decoder,

scrambler, descrambler, clock and data recovery, twisted pair transmitter, twisted pair receiver, and MI

serial port.

The LAN91C111 can operate as a 100BASE-TX device (hereafter referred to as 100Mbps mode) or

as a 10BASE-T device (hereafter referred to as 10Mbps mode). The difference between the 100Mbps

mode and the 10Mbps mode is data rate, signaling protocol, and allowed wiring. The 100Mbps TX

mode uses two pairs of category 5 or better UTP or STP twisted pair cable with 4B5B encoded,

scrambled, and MLT-3 coded 62.5 MHz ternary data to achieve a throughput of 100Mbps. The 10Mbps

mode uses two pairs of category 3 or better UTP or STP twisted pair cable with Manchester encoded,

10MHz binary data to achieve a 10Mbps throughput. The data symbol format on the twisted pair cable

for the 100 and 10Mbps modes are defined in IEEE 802.3 specifications and shown in Figure 7.3.

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On the transmit side for 100Mbps TX operation, data is received on the controller and then sent to the

4B5B encoder for formatting. The encoded data is then sent to the scrambler. The scrambled and

encoded data is then sent to the TP transmitter. The TP transmitter converts the encoded and

scrambled data into MLT-3 ternary format, reshapes the output, and drives the twisted pair cable.

On the receive side for 100Mbps TX operation, the twisted pair receiver receives incoming encoded

and scrambled MLT-3 data from the twisted pair cable, remove any high frequency noise, equalizes

the input signal to compensate for the effects of the cable, qualifies the data with a squelch algorithm,

and converts the data from MLT-3 coded twisted pair levels to internal digital levels. The output of the

twisted pair receiver then goes to a clock and data recovery block which recovers a clock from the

incoming data, uses the clock to latch in valid data into the device, and converts the data back to NRZ

format. The NRZ data is then unscrambled and decoded by the 4B5B decoder and descrambler,

respectively, and outputted to the Ethernet controller.

10Mbps operation is similar to the 100Mbps TX operation except, (1) there is no

scrambler/descrambler, (2) the encoder/decoder is Manchester instead of 4B5B, (3) the data rate is

10Mbps instead of 100Mbps, and (4) the twisted pair symbol data is two level Manchester instead of

ternary MLT-3.

The Management Interface, (hereafter referred to as the MI serial port), is a two pin bi-directional link

through which configuration inputs can be set and status outputs can be read. Each block plus the

operating modes are described in more detail in the following sections.

Figure 7.3 TX/10BT Frame Format

PREAMBLE SFD DA LLC DATA FCS

INTERFRAME

GAP

ETHERNET MAC

FRAME

INTERFRAME

GAP

SSD PREAMBLE SFD LLC DATA FCS

IDLE

100 BASE-TX DATA SYMBOLS

SA IDLE

LN ESD

= [ 1 1 1 1...]

= [ 0 1 1 0 1 0 0 1 1 1]

= [ DATA]

= [ 1 1]

= [ 1 0 1 0 ...] 62 BITS LONG

= [ 1 1 0 0 0 1 0 0 0 1]

ESD

DA, SA, LN, LLC DATA, FCS

SSD

PREAMBLE

SFD

IDLE

BEFORE / AFTER

4B5B ENCODING,

SCRAMBLING,

AND MLT3

CODING

PREAMBLE SFD LLC DATA FCS

IDLE

10 BASE-T DATA SYMBOLS

SA IDLE

LN SOI

= [ NO TRANSITIONS]

= [ 1 1 ] WITH NO MID BIT TRANSITION

= [ DATA]

= [ 1 1]

= [ 1 0 1 0 ... ] 62 BITS LONG

SOI

DA, SA, LN, LLC DATA, FCS

SFD

PREAMBLE

IDLE

BEFORE / AFTER

MANCHESTER

ENCODING

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7.7.1 MII Disable

The internal PHY MII interface can be disabled by setting the MII disable bit in the MI serial port Control

impedance state, and the TP output is high impedance.

7.7.2 Encoder

4B5B Encoder - 100 Mbps

100BASE-TX requires that the data be 4B5B encoded. 4B5B coding converts the 4-Bit data nibbles

into 5-Bit date code words. The mapping of the 4B nibbles to the 5B code words is specified in IEEE

802.3. The 4B5B encoder on the LAN91C111 takes 4B nibbles from the controller interface, converts

them into 5B words and sends the 5B words to the scrambler. The 4B5B encoder also substitutes the

first 8 bits of the preamble with the SSD delimiters (a.k.a. /J/K/ symbols) and adds an ESD delimiter

(a.k.a. MR/ symbols) to the end of every packet, as defined in IEEE 802.3. The 4B5B encoder also

fills the period between packets, called the idle period, with the continuous stream of idle symbols.

Manchester Encoder - 10 Mbps

The Manchester encoding process combines clock and NRZ data such that the first half of the data

bit contains the complement of the data, and the second half of the data bit contains the true data, as

specified in IEEE 802.3. This guarantees that a transition always occurs in the middle of the bit call.

The Manchester encoder on the LAN91C111 converts the 10Mbps NRZ data from the controller

interface into a Manchester Encoded data stream for the TP transmitter and adds a start of idle pulse

(SOI) at the end of the packet as specified in IEEE 802.3. The Manchester encoding process is only

done on actual packet data, and the idle period between packets is not Manchester encoded and filled

with link pulses.

7.7.3 Decoder

4B5B Decoder - 100 Mbps

Since the TP input data is 4B5B encoded on the transmit side, it must also be decoded by the 4B5B

decoder on the receive side. The mapping of the 5B nibbles to the 4B code words is specified in IEEE

802.3. The 4B5B decoder on the LAN91C111 takes the 5B code words from the descrambler, converts

them into 4B nibbles per Table 2, and sends the 4B nibbles to the controller interface. The 4B5B

decoder also strips off the SSD delimiter (a.k.a. /J/K/ symbols) and replaces them with two 4B Data 5

nibbles (a.k.a. /5/ symbol), and strips off the ESD delimiter (a.k.a. /T/R/ symbols) and replaces it with

two 4B Data 0 nibbles (a.k.a. /I/symbol), per IEEE 802.3 specifications and shown in Figure 7.3.

Table 7.1 4B/5B Symbol Mapping

SYMBOL NAME DESCRIPTION 5B CODE 4B CODE

0 Data 0 11110 0000

1 Data 1 01001 0001

2 Data 2 10100 0010

3 Data 3 10101 0011

4 Data 4 01010 0100

5 Data 5 01011 0101

6 Data 6 01110 0110

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* These 5B codes are not used. For decoder, these 5B codes are decoded to 4B 0000. For encoder,

4B 0000 is encoded to 5B 11110, as shown in symbol Data 0.

The 4B5B decoder detects SSD, ESD and codeword errors in the incoming data stream as specified

in IEEE 802.3. These errors are indicated by asserting RX_ER output while the errors are being

transmitted across RXD[3:0], and they are also indicated in the serial port by setting SSD, ESD, and

codeword error bits in the PHY MI serial port Status Output register.

Manchester Decoder - 10 Mbps

In Manchester coded data, the first half of the data bit contains the complement of the data, and the

second half of the data bit contains the true data. The Manchester decoder in the LAN91C111 converts

the Manchester encoded data stream from the TP receiver into NRZ data for the controller interface

by decoding the data and stripping off the SOI pulse. Since the clock and data recovery block has

already separated the clock and data from the TP receiver, the Manchester decoding process to NRZ

data is inherently performed by that block.

7.7.4 Clock and Data Recovery

Clock Recovery - 100 Mbps

Clock recovery is done with a PLL. If there is no valid data present on the TP inputs, the PLL is locked

to the 25 MHz TX25. When valid data is detected on the TP inputs with the squelch circuit and when

the adaptive equalizer has settled, the PLL input is switched to the incoming data on the TP input.

The PLL then recovers a clock by locking onto the transitions of the incoming signal from the twisted

pair wire. The recovered dock frequency is a 25 MHz nibble dock, and that clock is outputted on the

controller interface signal RX25.

7 Data 7 01111 0111

8 Data 8 10010 1000

9 Data 9 10011 1001

A Data A 10110 1010

B Data B 10111 1011

C Data C 11010 1100

D Data D 11011 1101

E Data E 11100 1110

F Data F 11101 1111

I Idle 11111 0000

J SSD #1 11000 0101

K SSD #2 10001 0101

T ESD #1 01101 0000

R ESD #2 00111 0000

H Halt 00100 Undefined

--- Invalid codes All others* 0000*

Table 7.1 4B/5B Symbol Mapping (continued)

SYMBOL NAME DESCRIPTION 5B CODE 4B CODE

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Data Recovery - 100 Mbps

Data recovery is performed by latching in data from the TP receiver with the recovered clock extracted

by the PLL. The data is then converted from a single bit stream into nibble wide data word according

to the format shown in Figure 7.2.

Clock Recovery - 10 Mbps

The clock recovery process for 10Mbps mode is identical to the 100Mbps mode except, (1) the

recovered clock frequency is 2.5 MHz nibble clock, (2) the PLL is switched from TX25 to the TP input

when the squelch indicates valid data, (3) The PLL takes up to 12 transitions (bit times) to lock onto

the preamble, so some of the preamble data symbols are lost, but the dock recovery block recovers

enough preamble symbols to pass at least 6 nibbles of preamble to the receive controller interface as

shown in Figure 7.2.

Data Recovery - 10 Mbps

The data recovery process for 10Mbps mode is identical to the 100Mbps mode. As mentioned in the

Manchester Decoder section, the data recovery process inherently performs decoding of Manchester

encoded data from the TP inputs.

7.7.5 Scrambler

100 Mbps

100BASE-TX requires scrambling to reduce the radiated emissions on the twisted pair. The

LAN91C111 scrambler takes the encoded data from the 4B5B encoder, scrambles it per the IEEE

802.3 specifications, and sends it to the TP transmitter.

10 Mbps

A scrambler is not used in 10Mbps mode.

Scrambler Bypass

The scrambler can be bypassed by setting the bypass scrambler/descrambler bit in the PHY Ml serial

port Configuration 1 register. When this bit is set, the 5B data bypasses the scrambler and goes

directly from the 4B5B encoder to the twisted pair transmitter.

7.7.6 Descrambler

100 Mbps

The LAN91C111 descrambler takes the scrambled data from the data recovery block, descrambles it

per the IEEE 802.3 specifications, aligns the data on the correct 5B word boundaries, and sends it to

the 4B5B decoder.

The algorithm for synchronization of the descrambler is the same as the algorithm outlined in the IEEE

802.3 specification. Once the descrambler is synchronized, it will maintain synchronization as long as

enough descrambled idle pattern 1's are defected within a given interval. To stay in synchronization,

the descrambler needs to detect at least 25 consecutive descrambled idle pattern 1's in a 1ms interval.

If 25 consecutive descrambled idle pattern 1's are not detected within the 1ms interval, the descrambler

goes out of synchronization and restarts the synchronization process.

If the descrambler is in the unsynchronized state, the descrambler loss of synchronization detect bit is

set in the Ml serial port Status Output register to indicate this condition. Once this bit is set, it will stay

set until the descrambler achieves synchronization.

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10 Mbps

A descrambler is not used in 10 Mbps mode.

Descrambler Bypass

The descrambler can be bypassed by setting the bypass scrambler/descrambler bit in the PHY MI

serial port Configuration 1 register. When this bit is set, the data bypasses the descrambler and goes

directly from the TP receiver to the 4B5B decoder.

7.7.7 Twisted Pair Transmitter

Transmitter - 100 Mbps

The TX transmitter consists of MLT-3 encoder, waveform generator and line driver.

The MLT-3 encoder converts the NRZ data from the scrambler into a three level MLT-3 code required

by IEEE 802.3. MLT-3 coding uses three levels and converts 1's to transitions between the three levels,

and converts 0's to no transitions or changes in level.

The purpose of the waveform generator is to shape the transmit output pulse. The waveform generator

takes the MLT-3 three level encoded waveform and uses an array of switched current sources to

control the rise/fall time and level of the signal at the Output. The output of the switched current

sources then goes through a low pass filter in order to "smooth" the current output and remove any

high frequency components. In this way, the waveform generator preshapes the output waveform

transmitted onto the twisted pair cable to meet the pulse template requirements outlined in IEEE 802.3.

The waveform generator eliminates the need for any external filters on the TP transmit output.

The line driver converts the shaped and smoothed waveform to a current output that can drive 100

meters of category 5 unshielded twisted pair cable or 150 Ohm shielded twisted pair cable.

Transmitter - 10 Mbps

The transmitter operation in 10 Mbps mode is much different than the 100 Mbps transmitter. Even so,

the transmitter still consists of a waveform generator and line driver.

The purpose of the waveform generator is to shape the output transmit pulse. The waveform generator

consists of a ROM, DAC, dock generator, and filter. The DAC generates a stair-stepped representation

of the desired output waveform. The stairstepped DAC output then goes through a low pass filter in

order to "smooth' the DAC output and remove any high frequency components. The DAC values are

determined from the ROM outputs; the ROM contents are chosen to shape the pulse to the desired

template and are clocked into the DAC at high speed by the clock generator. In this way, the waveform

generator preshapes the output waveform to be transmitted onto the twisted pair cable to meet the

pulse template requirements outlined in IEEE 802.3 Clause 14 and also shown in Figure 7.4. The

waveshaper replaces and eliminates external filters on the TP transmit output.

The line driver converts the shaped and smoothed waveform to a current output that can drive 100

meters of category 3/4/5 100 Ohm unshielded twisted pair cable or 150 Ohm shielded twisted pair

cable tied directly to the TP output pins without any external filters. During the idle period, no output

signal is transmitted on the TP outputs (except link pulse).

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Figure 7.4 TP Output Voltage Template - 10 MBPS

REFERENCE TIME (NS) INTERNAL MAU VOLTAGE (V)

A00

B151.0

C150.4

D250.55

E320.45

F390

G57-1.0

H480.7

I670.6

J890

K74-0.55

L73-0.55

M610

N851.0

O1000.4

0 102030405060708090100110

-1.0

-0.8

-0.6

-0.4

-0.2

0.0

0.2

0.4

0.6

0.8

1.0

TIME (ns)

Voltage (V)

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Transmit Level Adjust

The transmit output current level is derived from an internal reference voltage and the external resistor

on RBIAS pin. The transmit level can be adjusted with either (1) the external resistor on the RBIAS

pin, or (2) the four transmit level adjust bits in the PHY Ml serial port Configuration 1 register as shown

in Ta b l e 7 . 2 . The adjustment range is approximately -14% to +16% in 2% steps.

P 110 0.75

Q 111 0.15

R1110

S111-0.15

T110-1.0

U100-0.3

V110-0.7

W90-0.7

Table 7.2 Transmit Level Adjust

TLVL[3:0] GAIN

0000 1.16

0001 1.14

0010 1.12

0011 1.10

0100 1.08

0101 1.06

0110 1.04

0111 1.02

1000 1.00

1001 0.98

1010 0.96

1011 0.94

1100 0.92

1101 0.90

1110 0.88

1111 0.86

REFERENCE TIME (NS) INTERNAL MAU VOLTAGE (V)

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Transmit Rise and Fall Time Adjust

The transmit output rise and fall time can be adjusted with the two transmit rise/fall time adjust bits in

the PHY Ml serial port Configuration 1. The adjustment range is -0.25ns to +0.5ns in 0.25ns steps.

STP (150 Ohm) Cable Mode

The transmitter can be configured to drive 150 Ohm shielded twisted pair cable. The STP mode can

be selected by appropriately setting the cable type select bit in the PHY MI serial port Configuration 1

802.3 levels.

Transmit Disable

The TP transmitter can be disabled by setting the transmit disable bit in the PHY Ml serial port

Configuration 1 register. When the transmit disable bit is set, the TP transmitter is forced into the idle

state, no data is transmitted, no link pulses are transmitted, and internal loopback is disabled.

Transmit Powerdown

The TP transmitter can be powered down by setting the transmit powerdown bit in the PHY Ml serial

port Configuration 1 register. When the transmit powerdown bit is set, the TP transmitter is powered

down, the TP transmit outputs are high impedance, and the rest of the LAN91C111 operates normally.

7.7.8 Twisted Pair Receiver

Receiver - 100 Mbps

The TX receiver detects input signals from the twisted pair input and converts it to a digital data bit

stream ready for dock and data recovery. The receiver can reliably detect data from a 100BASE-TX

transmitter that has been passed through 0-100 meters of 100-Ohm category 5 UTP or 150 Ohm STP.

The TX receiver consists of an adaptive equalizer, baseline wander correction circuit, comparators, and

MLT-3 decoder. The TP inputs first go to an adaptive equalizer. The adaptive equalizer compensates

for the low pass characteristic of the cable, and it has the ability to adapt and compensate for 0-100

meters of category 5, 100 Ohm UTP or 150 Ohm STP twisted pair cable. The baseline wander

correction circuit restores the DC component of the input waveform that was removed by external

transformers. The comparators convert the equalized signal back to digital levels and are used to

qualify the data with the squelch circuit. The MLT-3 decoder takes the three level MLT-3 digital data

from the comparators and converts it to back to normal digital data to be used for dock and data

recovery.

Receiver - 10 Mbps

The 10 Mbps receiver is able to detect input signals from the twisted pair cable that are within the

template shown in Figure 7.5. The inputs are biased by internal resistors. The TP inputs pass through

a low pass filter designed to eliminate any high frequency noise on the input. The output of the receive

filter goes to two different types of comparators, squelch and zero crossing. The squelch comparator

determines whether the signal is valid, and the zero crossing comparator is used to sense the actual

data transitions once the signal is determined to be valid. The output of the squelch comparator goes

to the squelch circuit and is also used for link pulse detection, SOI detection, and reverse polarity

detection; the output of the zero crossing comparator is used for clock and data recovery in the

Manchester decoder.

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TP Squelch - 100 Mbps

The squelch block determines if the TP input contains valid data. The 100 Mbps TP squelch is one

of the criteria used to determine link integrity. The squelch comparators compare the TP inputs against

fixed positive and negative thresholds, called squelch levels. The output from the squelch comparator

goes to a digital squelch circuit which determines if the receive input data on that channel is valid. If

the data is invalid, the receiver is in the squelched state. If the input voltage exceeds the squelch

levels at least 4 times with alternating polarity within a 10 μS interval, the data is considered to be

valid by the squelch circuit and the receiver now enters into the unsquelch state. In the unsquelch

state, the receive threshold level is reduced by approximately 30% for noise immunity reasons and is

called the unsquelch level. When the receiver is in the unsquelch state, then the input signal is

deemed to be valid. The device stays in the unsquelch state until loss of data is detected. Loss of

data is detected if no alternating polarity unsquelch transitions are detected during any 10 μS interval.

When the loss of data is detected, the receive squelch is turned on again.

TP Squelch, 10 Mbps

The TP squelch algorithm for 10 Mbps mode is identical to the 100 Mbps mode except, (1) the 10

Mbps TP squelch algorithm is not used for link integrity but to sense the beginning of a packet, (2) the

receiver goes into the unsquelch state if the input voltage exceeds the squelch levels for three bit times

with alternating polarity within a 50-250 nS interval, (3) the receiver goes into the squelch state when

idle is detected, (4) unsquelch detection has no affect on link integrity, link pulses are used for that in

10 Mbps mode, (5) start of packet is determined when the receiver goes into the unsquelch state an

Figure 7.5 TP Input Voltage Template -10MBPS

3.1V

a. Short Bit

585mV

585 mV sin ( t/PW)

Slope 0.5 V/ ns

3.1V

b. Long Bit

585mV

585 mV sin [2 (t - PW/2)/PW]

PW/4

0PW3PW/4

Slope 0.5 V/ ns

585 mV sin (2 t/PW)

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a CRS100 is asserted, and (6) the receiver meets the squelch requirements defined in IEEE 802.3

Clause 14.

Equalizer Disable

The adaptive equalizer can be disabled by setting the equalizer disable bit in the PHY Ml serial port

Configuration 1 register. When disabled, the equalizer is forced into the response it would normally

have if zero cable length was detected.

Receive Level Adjust

The receiver squelch and unsquelch levels can be lowered by 4.5 dB by setting the receive level adjust

bit in the PHY Ml serial port Configuration 1 register. By setting this bit, the device may be able to

support longer cable lengths.

7.7.9 Collision

100 Mbps

Collision occurs whenever transmit and receive occur simultaneously while the device is in Half

Duplex.

Collision is sensed whenever there is simultaneous transmission (packet transmission on TPO±) and

reception (non-idle symbols detected on TP input). When collision is detected, the MAC is notified.

Once collision starts, the receive and transmit packets that caused the collision are terminated by their

respective MACs until the responsible MACs terminate the transmission, the PHY continues to pass

the data on.

The collision function is disabled if the device is in the Full Duplex mode, is in the Link Fail State, or

if the device is in the diagnostic loopback mode.

10 Mbps

Collision in 10Mbps mode is identical to the 100Mbps mode except, (1) reception is determined by the

10Mbps squelch criteria, (2) data being passed to the MAC are forced to all 0's, (3) MAC is notified of

the collision when the SQE test is performed, (4) MAC is notified of the collision when the jabber

condition has been detected.

Collision Test

The MAC and PHY collision indication can be tested by setting the collision test register bit in the PHY

MI serial port Control register. When this bit is set, internal TXEN from the MAC is looped back onto

COL and the TP outputs are disabled.

7.7.10 Start of Packet

100 Mbps

Start of packet for 100 Mbps mode is indicated by a unique Start of Stream Delimiter (referred to as

SSD). The SSD pattern consists of the two /J/K/ 5B symbols inserted at the beginning of the packet

in place of the first two preamble symbols, as defined in IEEE 802.3 Clause 24.

The transmit SSD is generated by the 4B5B encoder and the /J/K/ symbols are inserted by the 4B5B

encoder at the beginning of the transmit data packet in place of the first two 5B symbols of the

preamble.

The receive pattern is detected by the 4B5B decoder by examining groups of 10 consecutive code bits

(two 5B words) from the descrambler. Between packets, the receiver will be detecting the idle pattern,

which is 5B /I/ symbols. While in the idle state, the MAC is notified that no data/invalid data is received.

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If the receiver is in the idle state and 10 consecutive code bits from the receiver consist of the /J/K/

symbols, the start of packet is detected, data reception is begun, the MAC is notified that valid data is

received, and 5/5/ symbols are substituted in place of the /J/K/ symbols.

If the receiver is in the idle state and 10 consecutive code bits from the receiver consist of a pattern

that is neither /I/I/ nor /J/K/ symbols but contains at least 2 non contiguous 0's, then activity is detected

but the start of packet is considered to be faulty and a False Carrier Indication (also referred to as bad

SSD) is signaled to the controller interface. When False Carrier is detected, the MAC is notified of

false carrier and invalid received, and the bad SSD bit is set in the PHY Ml serial port Status Output

before any new SSD's can be sensed.

If the receiver is in the idle state and 10 consecutive code bits from the receiver consist of a pattern

that is neither /l/l/ nor /J/K/ symbols but does not contain at least 2 non-contiguous 0's, the data is

ignored and the receiver stays in the idle state.

10 Mbps

Since the idle period in 10 Mbps mode is defined to be the period when no data is present on the TP

inputs, then the start of packet for 10 Mbps mode is detected when valid data is detected by the TP

squelch circuit. When start of packet is detected, carrier sense signal at internal MII is asserted as

described in the Controller Interface section. Refer to the TP squelch section for 10 Mbps mode for

the algorithm for valid data detection.

7.7.11 End of Packet

100 Mbps

End of packet for 100 Mbps mode is indicated by the End of Stream Delimiter (referred to as ESD).

The ESD pattern consists of the two /T/R/ 4B5B symbols inserted after the end of the packet, as

defined in IEEE 802.3 Clause 24.

The transmit ESD is generated by the 4B5B encoder and the /T/R/ symbols are inserted by the 4B5B

encoder after the end of the transmit data packet.

The receive ESD pattern is detected by the 4B5B decoder by examining groups of 10 consecutive

code bits (two 5B words) from the descrambler during valid packet reception to determine if there is

an ESD.

If the 10 consecutive code bits from the receiver during valid packet reception consist of the /T/R/

symbols, the end of packet is detected, data reception is terminated, the MAC is notified of valid data

received, and /I/I/ symbols are substituted in place of the /T/R/ symbols.

If 10 consecutive code bits from the receiver during valid packet reception do not consist of /T/R/

symbols but consist of /I/I/ symbols instead, then the packet is considered to have been terminated

prematurely and abnormally. When this premature end of packet condition is detected, the MAC is

notified of invalid data received for the nibble associated with the first /I/ symbol. Premature end of

packet condition is also indicated by setting the bad ESD bit in the PHY Ml serial port Status Output

10 Mbps

The end of packet for 10 Mbps mode is indicated with the SOI (Start of Idle) pulse. The SOI pulse is

a positive pulse containing a Manchester code violation inserted at the end of every packet.

The transmit SOI pulse is generated by the TP transmitter and inserted at the end of the data packet

after TXEN is deasserted. The transmitted SOI output pulse at the TP output is shaped by the transmit

waveshaper to meet the pulse template requirements specified in IEEE 802.3 Clause 14 and shown

in Figure 7.6.

The receive SOI pulse is detected by the TP receiver by sensing missing data transitions. Once the

SOI pulse is detected, data reception is ended and the MAC is notified of no data/invalid data received.

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7.7.12 Link Integrity & AutoNegotiation

General

The LAN91C111 can be configured to implement either the standard link integrity algorithms or the

AutoNegotiation algorithm.

The standard link integrity algorithms are used solely to establish an active link to and from a remote

device. There are different standard link integrity algorithms for 10 and 100 Mbps modes. The

AutoNegotiation algorithm is used for two purposes: (1) To automatically configure the device for either

10/100 Mbps and Half/Full Duplex modes, and (2) to establish an active link to and from a remote

device. The standard link integrity and AutoNegotiation algorithms are described below.

AutoNegotiation is only specified for 100BASE-TX and 10BASE-T operation.

10BASE-T Link Integrity Algorithm - 10Mbps

The LAN91C111 uses the same 10BASE-T link integrity algorithm that is defined in IEEE 802.3 Clause

14. This algorithm uses normal link pulses, referred to as NLP's and transmitted during idle periods,

to determine if a device has successfully established a link with a remote device (called Link Pass

State). The transmit link pulse meets the template defined in IEEE 802.3 Clause 14 and shown in

Figure 7.7. Refer to IEEE 802.3 Clause 14 for more details if needed.

Figure 7.6 SOI Output Voltage Template - 10MBPS

0 BT 4.5 BT

6.0 BT

+50 mV

45.0 BT

4.5 BT2.5 BT

2.25 BT

0.25 BT

0.5 V/ns

3.1 V

-50 mV

585 mV

-3.1 V

585 mV sin(2 (t/1BT))

0 t 0.25 BT and

2.25 t 2.5 BT

***

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100BASE-TX Link Integrity Algorithm -100Mbps

Since 100BASE-TX is defined to have an active idle signal, then there is no need to have separate

link pulses like those defined for 10BASE-T. The LAN91C111 uses the squelch criteria and

descrambler synchronization algorithm on the input data to determine if the device has successfully

established a link with a remote device (called Link Pass State). Refer to IEEE 802.3 for both of these

algorithms for more details.

AutoNegotiation Algorithm

As stated previously, the AutoNegotiation algorithm is used for two purposes: (1) To automatically

configure the device for either 10/100 Mbps and Half/ Full Duplex modes, and (2) to establish an active

link to and from a remote device. The AutoNegotiation algorithm is the same algorithm that is defined

in IEEE 802.3 Clause 28. AutoNegotiation uses a burst of link pulses, called fast link pulses and

referred to as FLP'S, to pass up to 16 bits of signaling data back and forth between the LAN91C111

and a remote device. The transmit FLP pulses meet the templated specified in IEEE 802.3 and shown

in Figure 7.7. A timing diagram contrasting NLP's and FLP's is shown in Figure 7.8.

Figure 7.7 Link Pulse Output Voltage Template - NLP, FLP

1.3

2.0

4.0

BT +50 mV

-50 mV

4.0

42.0

3.1 V

0.5 V/ns

0.5

BT 0.6

300 mV

200 mV

585 mV

+50 mV

-50 mV

2.0

0.85

-3.1 V

0.25

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The AutoNegotiation algorithm is initiated by any of these events: (1) AutoNegotiation enabled, (2) a

device enters the Link Fail State, (3) AutoNegotiation Reset. Once a negotiation has been initiated,

the LAN91C111 first determines if the remote device has AutoNegotiation capability. If the remote

device is not AutoNegotiation capable and is just transmitting either a 10BASE-T or 100BASE-TX

signal, the LAN91C111 will sense that and place itself in the correct mode. If the LAN91C111 detects

FLP's from the remote device, then the remote device is determined to have AutoNegotiation capability

and the device then uses the contents of the Ml serial port AutoNegotiation Advertisement register and

FLP's to advertise its capabilities to a remote device. The remote device does the same, and the

capabilities read back from the remote device are stored in the PHY Ml serial port AutoNegotiation

Remote End Capability register. The LAN91C111 negotiation algorithm then matches it's capabilities

to the remote device's capabilities and determines what mode the device should be configured to

according to the priority resolution algorithm defined in IEEE 802.3 Clause 28. Once the negotiation

process is completed, the LAN91C111 then configures itself for either 10 or 100 Mbps mode and either

Full or Half Duplex modes (depending on the outcome of the negotiation process), and it switches to

either the 100BASETX or 10BASE-T link integrity algorithms (depending on which mode was enabled

by AutoNegotiation). Refer to IEEE 802.3 Clause 28 for more details.

AutoNegotiation Outcome Indication

The outcome or result of the AutoNegotiation process is stored in the speed detect and duplex detect

bits in the PHY MI serial port Status Output register.

AutoNegotiation Status

The status of the AutoNegotiation process can be monitored by reading the AutoNegotiation

acknowledgement bit in the Ml serial port Status register. The Ml serial port Status register contains

a single AutoNegotiation acknowledgement bit which indicates when an AutoNegotiation has been

initiated and successfully completed.

Figure 7.8 NLP VS. FLP Link Pulse

TPO±

a.) Normal Link Pulse (NLP)

b.) Fast Link Pulse (FLP)

D0 D15D14D3D2D1

Clock Clock Clock Clock Clock Clock Clock

Data Data Data Data Data Data

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AutoNegotiation Enable

The AutoNegotiation algorithm can be enabled by setting both the ANEG bit in the MAC Receive/PHY

Control Register and the ANEG_EN bit in the MI PHY Register 0 (Control register). Clearing either of

these two bits will turn off AutoNegotiation mode. When the AutoNegotiation algorithm is enabled, the

device halts all transmissions including link pulses for 1200-1500 ms, enters the Link Fail State, and

restarts the negotiation process. When AutoNegotiation mode is turned on or reset, software driver

should wait for at least 1500ms to read the ANEG_ACK bit in the MI PHY Status Register to determine

whether the AutoNegotiation process has been completed. When the ANEG bit in the Receive/PHY

Control Register is cleared, AutoNegotiation algorithm is disabled, the selection of 10/100 Mbps mode

and duplex mode is determined by the SPEED bit and the DPLX bit in the MAC Receive/PHY Control

MI PHY Register 0 (Control Register) is cleared, AutoNegotiation algorithm is disabled, the selection

of 10/100 Mbps mode and duplex mode is determined by the SPEED bit and the DPLX bit in the MI

PHY Register 0 (Control Register).

AutoNegotiation Reset

The AutoNegotiation algorithm can be initiated at any time by setting the AutoNegotiation reset bit in

the PHY MI serial port Control register.

Link Disable

The link integrity function can be disabled by setting the link disable bit in the PHY Ml serial port

Configuration 1 register. When the link integrity function is disabled, the device is forced into the Link

Pass state, configures itself for Half/Full Duplex based on the value of the duplex bit in the PHY MI

serial port Control register, configures itself for 100/10 Mbps operation based on the values of the

speed bit in the Ml serial port Control register, and continues to transmit NLP'S or TX idle patterns,

depending on whether the device is in 10 or 100 Mbps mode.

7.7.13 Jabber

100 Mbps

Jabber function is disabled in the 100 Mbps mode.

10 Mbps

Jabber condition occurs when the transmit packet exceeds a predetermined length. When jabber is

detected, the TP transmit outputs are forced to the idle state, collision is asserted, and register bits in

the PHY Ml serial port Status and Status Output registers are set.

Jabber Disable

The jabber function can be disabled by setting the jabber disable bit in the PHY MI serial port

Configuration 2 register.

7.7.14 Receive Polarity Correction

100 Mbps

No polarity detection or correction is needed in 100Mbps mode.

10 Mbps

The polarity of the signal on the TP receive input is continuously monitored. If either 3 consecutive

link pulses or one SOI pulse indicates incorrect polarity on the TP receive input, the polarity is internally

determined to be incorrect, and a reverse polarity bit is set in the PHY Ml serial port Status Output

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The LAN91C111 will automatically correct for the reverse polarity condition provided that the

autopolarity feature is not disabled.

Note: The first 3 received packets must be discarded after the correction of a reverse polarity

condition.

Autopolarity Disable

The autopolarity feature can be disabled by setting the autopolarity disable bit in the PHY MI serial

port Configuration 2 register.

7.7.15 Full Duplex Mode

100 Mbps

Full Duplex mode allows transmission and reception to occur simultaneously. When Full Duplex mode

is enabled, collision is disabled.

The device can be either forced into Half or Full Duplex mode, or the device can detect either Half or

Full Duplex capability from a remote device and automatically place itself in the correct mode.

The device can be forced into the Full or Half Duplex modes by either setting the duplex bit in the MI

serial port Control register.

The device can automatically configure itself for Full or Half Duplex modes by using the

AutoNegotiation algorithm to advertise and detect Full and Half Duplex capabilities to and from a

remote terminal. All of this is described in detail in the Link Integrity and AutoNegotiation section.

10 Mbps

Full Duplex in 10 Mbps mode is identical to the 100 Mbps mode.

100/10 Mbps SELECTION

General

The device can be forced into either the 100 or 10 Mbps mode, or the device also can detect 100 or

10 Mbps capability from a remote device and automatically place itself in the correct mode.

The device can be forced into either the 100 or 10 Mbps mode by setting the speed select bit in the

PHY MI serial port Control register assuming AutoNegotiation is not enabled.

The device can automatically configure itself for 100 or 10 Mbps mode by using the AutoNegotiation

algorithm to advertise and detect 100 and 10 Mbps capabilities to and from a remote terminal. All of

this is described in detail in the Link Integrity & AutoNegotiation section.

7.7.16 Loopback

Diagnostic Loopback

A diagnostic loopback mode can also be selected by setting the loopback bit in the MI serial port

Control register. When diagnostic loopback is enabled, transmit data at internal MII is looped back

onto receive data output at internal MII, transmit enable signal is looped back onto carrier sense output

at internal MII, the TP receive and transmit paths are disabled, the transmit link pulses are halted, and

the Half/Full Duplex modes do not change.

7.7.17 PHY Powerdown

The internal PHY of LAN91C111 can be powered down by setting the powerdown bit in the PHY Ml

serial port Control register. In powerdown mode, the TP outputs are in high impedance state, all

functions are disabled except the PHY Ml serial port, and the power consumption is reduced to a

minimum. To restore PHY to normal power mode, set the PDN bit in PHY MI Register 0 to 0. The PHY

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is then in isolation mode (MII_DIS bit is set); This MII_DIS bit is needed to be cleared. The device is

guaranteed to be ready for normal operation 500mS after powerdown is de-asserted.

Note: The PDN bit must not be set when the device is in external PHY mode.

7.7.18 PHY Interrupt

The LAN91C111 PHY has interrupt capability. The interrupt is triggered by certain output status bits

(also referred to as interrupt bits) in the serial port. R/LT bits are read bits that latch on transition.

R/LT bits are also interrupt bits if they are not masked out with the Mask register bits. Interrupt bits

automatically latch themselves into their register locations and assert the interrupt indication when they

change state. Interrupt bits stay latched until they are read. When interrupt bits are read, the interrupt

indication is deasserted and the interrupt bits that caused the interrupt to happen are updated to their

current value. Each interrupt bit can be individually masked and subsequently be removed as an

interrupt bit by setting the appropriate mask register bits in the Mask register.

lnterrupt indication is done in two ways: (1) MDINT bit in Interrupt Status Register, (2) INT bit in the

PHY Ml Serial Port Status Output register. The INT bit is an active high interrupt register bit that

resides in the PHY MI Serial Port Status Output register.

7.8 Reset

The chip (MAC & PHY) performs an internal system reset when either (1) the RESET pin is asserted

high for at least 100ns, (2) writing “1” to the SOFT_RST bit in the Receive Control Register, this reset

bit is not a self-clearing bit, reset can be terminated by writing the bit low. It programs all registers to

their default value. When reset is initiated by (1) and the EEPROM is presented and enabled, the

controller will load the EEPROM to obtain the following configurations: 1) Configuration Register, 2)

BASE Register, or/and 3) MAC Address. The internal MAC is not a power on reset device, thus reset

is required after power up to ensure all register bits are in default state.

The internal PHY is reset when either (1) VDD is applied to the device, (2) the RST bit is set in the

PHY Ml serial port Control register, this reset bit is a self-clearing bit, and the PHY will return a “1” on

reads to this bit until the reset is completed, 3) the RESET pin is asserted high, (4) the SOFT_RST

bit is set high and then cleared. When reset is initiated by (1) or (2), an internal power-on reset pulse

is generated which resets all internal circuits, forces the PHY Ml serial port bits to their default values,

and latches in new values for the MI address. After the power-on reset pulse has finished, the reset

bit in the PHY Ml serial port Control registers cleared and the device is ready for normal operation.

When reset is initiated by (3), the same procedure occurs except the device stays in the reset state

as long as the RESET pin is held high. The internal PHY is guaranteed to be ready for normal

operation 50 mS after the reset pin was de-asserted or the reset bit is set. Software driver requires

to wait for 50mS after setting the RST bit to high to access the internal PHY again.

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Chapter 8 MAC Data Structures and Registers

8.1 Frame Format In Buffer Memory

The frame format in memory is similar for the Transmit and Receive areas. The first word is reserved

for the status word. The next word is used to specify the total number of bytes, and it is followed by

the data area. The data area holds the frame itself. By default, the last byte in the receive frame format

is followed by the CRC, and the Control byte follows the CRC.

Figure 8.1 Data Frame Format

TRANSMIT PACKET RECEIVE PACKET

STATUS WORD Written by CSMA upon transmit

completion (see Status Register)

Written by CSMA upon receive

completion (see RX Frame Status

Word)

BYTE COUNT Written by CPU Written by CSMA

DATA AREA Written/modified by CPU Written by CSMA

CONTROL BYTE Written by CPU to control odd/even

data bytes

Written by CSMA; also has odd/even

bit

RESERVED BYTE COUNT (always even)

STATUS WORD

DATA AREA

LAST DATA BYTE (if odd)

bit0

bit15

RAM

OFFSET

(DECIMAL)

2046 Max

CONTROL BYTE

Last Byte

1st Byte2nd Byte

CRC (4 BYTES)

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BYTE COUNT - Divided by two, it defines the total number of words including the STATUS WORD,

the BYTE COUNT WORD, the DATA AREA, the CRC, and the CONTROL BYTE. The CRC is not

included if the STRIP_CRC bit is set. The maximum number of bytes in a RAM page is 2048 bytes.

The receive byte count always appears as even; the ODDFRM bit of the receive status word indicates

if the low byte of the last word is relevant.

The transmit byte count least significant bit will be assumed 0 by the controller regardless of the value

written in memory.

DATA AREA - The data area starts at offset 4 of the packet structure and can extend up to 2043 bytes.

The data area contains six bytes of DESTINATION ADDRESS followed by six bytes of SOURCE

ADDRESS, followed by a variable-length number of bytes. On transmit, all bytes are provided by the

CPU, including the source address. The LAN91C111 does not insert its own source address. On

receive, all bytes are provided by the CSMA side.

The 802.3 Frame Length word (Frame Type in Ethernet) is not interpreted by the LAN91C111. It is

treated transparently as data both for transmit and receive operations.

CONTROL BYTE - For transmit packets the CONTROL BYTE is written by the CPU as:

ODD - If set, indicates an odd number of bytes, with the last byte being right before the CONTROL

BYTE. If clear, the number of data bytes is even and the byte before the CONTROL BYTE is not

transmitted.

CRC - When set, CRC will be appended to the frame. This bit has meaning only if the NOCRC bit in

the TCR is set.

For receive packets the CONTROL BYTE is written by the controller as:

ODD - If set, indicates an odd number of bytes, with the last byte being right before the CONTROL

BYTE. If clear, the number of data bytes is even and the byte before the CONTROL BYTE should be

ignored.

XXODDCRC0000

01ODD00000

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8.2 Receive Frame Status

This word is written at the beginning of each receive frame in memory. It is not available as a register.

ALGNERR - Frame had alignment error.

BROADCAST - Receive frame was broadcast. When a broadcast packet is received, the MULTCAST

bit may be also set on the status word in addition to the BRODCAST bit. The software implement may

just ignore the MULTCAST bit if for BRODCAST packet.

BADCRC - Frame had CRC error, or RX_ER was asserted during reception.

ODDFRM - This bit when set indicates that the received frame had an odd number of bytes.

TOOLNG - Frame length was longer than 802.3 maximum size (1518 bytes on the cable).

TOOSHORT - Frame length was shorter than 802.3 minimum size (64 bytes on the cable).

HASH VALUE - Provides the hash value used to index the Multicast Registers. Can be used by

receive routines to speed up the group address search. The hash value consists of the six most

significant bits of the CRC calculated on the Destination Address, and maps into the 64 bit multicast

table. Bits 5,4,3 of the hash value select a byte of the multicast table, while bits 2,1,0 determine the

bit within the byte selected. Examples of the address mapping:

MULTCAST - Receive frame was multicast. If hash value corresponds to a multicast table bit that is

set, and the address was a multicast, the packet will pass address filtering regardless of other filtering

criteria.

HIGH

BYTE

ALGN

ERR

BROD

CAST

BAD

CRC

ODD

FRM

TOOLNG TOO

SHORT

LOW

BYTE

HASH VALUE MULT

CAST

Reserved543210

ADDRESS HASH VALUE 5-0 MULTICAST TABLE BIT

ED 00 00 00 00 00

0D 00 00 00 00 00

01 00 00 00 00 00

2F 00 00 00 00 00

000 000

010 000

100 111

111 111

MT-0 bit 0

MT-2 bit 0

MT-4 bit 7

MT-7 bit 7

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8.3 I/O Space

The base I/O space is determined by the IOS0-IOS2 inputs and the EEPROM contents. To limit the

I/O space requirements to 16 locations, the registers are assigned to different banks. The last word of

the I/O area is shared by all banks and can be used to change the bank in use. Registers are

described using the following convention:

FFSET - Defines the address offset within the IOBASE where the register can be accessed at,

provided the bank select has the appropriate value.

The offset specifies the address of the even byte (bits 0-7) or the address of the complete word.

The odd byte can be accessed using address (offset + 1).

Some registers (like the Interrupt Ack., or like Interrupt Mask) are functionally described as two eight

bit registers, in that case the offset of each one is independently specified.

Regardless of the functional description, all registers can be accessed as doublewords, words or bytes.

The default bit values upon hard reset are highlighted below each register.

A special BANK (BANK7) exists to support the addition of external registers.

OFFSET NAME TYPE SYMBOL

HIGH

BYTE

bit 15 bit 14 bit 13 bit 12 bit 11 bit 10 bit 9 bit 8

XXXXXXXX

LOW

BYTE

bit 7 bit 6 bit 5 bit 4 bit 3 bit 2 bit 1 bit 0

XXXXXXXX

Table 8.1 Internal I/O Space Mapping

BANK0 BANK1 BANK2 BANK3

0 TCR CONFIG MMU COMMAND MT0-1

2 EPH STATUS BASE PNR MT2-3

4 RCR IA0-1 FIFO PORTS MT4-5

6 COUNTER IA2-3 POINTER MT6-7

8 MIR IA4-5 DATA MGMT

A RPCR GENERAL PURPOSE DATA REVISION

C RESERVED CONTROL INTERRUPT RCV

E BANK BANK BANK BANK

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8.4 Bank Select Register

BS2, BS1, BS0 Determine the bank presently in use. This register is always accessible and is used

to select the register bank in use.

The upper byte always reads as 33h and can be used to help determine the I/O location of the

LAN91C111.

The BANK SELECT REGISTER is always accessible regardless of the value of BS0-2

Note: The bank select register can be accessed as a doubleword at offset 0x0Ch, as a word at offset

0x0Eh, or as a byte at offset 0x0Eh, A doubleword write to offset 0x0Ch will write the BANK

SELECT REGISTER but will not write the registers 0x0Ch and 0x0Dh, but will only write to

BANK 7 has no internal registers other than the BANK SELECT REGISTER itself. On valid cycles

where BANK7 is selected (BS0=BS1=BS2=1), and A3=0, nCSOUT is activated to facilitate

implementation of external registers.

Note: BANK7 does not exist in LAN91C9x devices. For backward S/W compatibility BANK7 accesses

should be done if the Revision Control register indicates the device is the LAN91C111.

Bank 7 is a new register Bank to the SMSC LAN91C111 device. This bank has extended registers that

allow the extended feature set of the SMSC LAN91C111.

OFFSET NAME TYPE SYMBOL

E BANK SELECT REGISTER READ/WRITE BSR

HIGH

BYTE

Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved

00110011

LOW

BYTE

BS2 BS1 BS0

XXXXX000

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8.5 Bank 0 - Transmit Control Register

This register holds bits programmed by the CPU to control some of the protocol transmit options.

SWFDUP - Enables Switched Full Duplex mode. In this mode, transmit state machine is inhibited from

recognizing carrier sense, so deferrals will not occur. Also inhibits collision count, therefore, the

collision related status bits in the EPHSR are not valid (CTR_ROL, LATCOL, SQET, 16COL, MUL COL,

and SNGL COL). Uses COL100 as flow control, limiting backoff and jam to 1 clock each before inter-

frame gap, then retry will occur after IFG. If COL100 is active during preamble, full preamble will be

output before jam. When SWFDUP is high, the values of FDUPLX and MON_CSN have no effect.

EPH_LOOP - Internal loopback at the EPH block. Serial data is internally looped back when set.

Defaults low. When EPH_LOOP is high the following transmit outputs are forced inactive: TXD0-TXD3

= 0h, TXEN100 = 0. The following and external inputs are blocked: CRS100=0, COL100=0, RX_DV=

RX_ER=0.

STP_SQET - STP_SQET - Stop transmission on SQET error. If this bit is set, LAN91C111 will stop

and disable the transmitter on SQE test error. If the external SQET generator on the network generates

the SQET pulse during the IPG (Inter Frame Gap), this bit will not be set and subsequent transmits

will occur as in the case of implementing “Auto Release” for multiple transmit packets. If this bit is

cleared, then the SQET bit in the EPH Status register will be cleared. Defaults low.

FDUPLX - When set the LAN91C111 will cause frames to be received if they pass the address filter

regardless of the source for the frame. When clear the node will not receive a frame sourced by itself.

This bit does not control the duplex mode operation, the duplex mode operation is controlled by the

SWFDUP bit.

MON_CSN - When set the LAN91C111 monitors carrier while transmitting. It must see its own carrier

by the end of the preamble. If it is not seen, or if carrier is lost during transmission, the transmitter

aborts the frame without CRC and turns itself off and sets the LOST CARR bit in the EPHSR. When

this bit is clear the transmitter ignores its own carrier. Defaults low. Should be 0 for MII operation.

NOCRC - Does not append CRC to transmitted frames when set. Allows software to insert the desired

CRC. Defaults to zero, namely CRC inserted.

PAD_EN - When set, the LAN91C111 will pad transmit frames shorter than 64 bytes with 00. For TX,

CPU should write the actual BYTE COUNT before padded by the LAN91C111 to the buffer RAM,

excludes the padded 00. When this bit is cleared, the LAN91C111 does not pad frames.

FORCOL - When set, the FORCOL bit will force a collision by not deferring deliberately. This bit is set

and cleared only by the CPU. When TXENA is enabled with no packets in the queue and while the

FORCOL bit is set, the LAN91C111 will transmit a preamble pattern the next time a carrier is seen on

OFFSET NAME TYPE SYMBOL

TRANSMIT CONTROL

HIGH

BYTE

SWFDUP Reserved EPH

LOOP

STP

SQET

FDUPLX MON_

CSN

Reserved NOCRC

00000000

LOW

BYTE

PAD_EN Reserved Reserved Reserved Reserved FORCOL LOOP TXENA

00000000

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the line. If a packet is queued, a preamble and SFD will be transmitted. This bit defaults low to normal

operation. NOTE: The LATCOL bit in the EPHSR, setting up as a result of FORCOL, will reset TXENA

to 0. In order to force another collision, TXENA must be set to 1 again.

LOOP - Loopback. General purpose output port used to control the LBK pin. Typically used to put the

PHY chip in loopback mode.

TXENA - Transmit enabled when set. Transmit is disabled if clear. When the bit is cleared the

LAN91C111 will complete the current transmission before stopping. When stopping due to an error,

this bit is automatically cleared.

8.6 Bank 0 - EPH Status Register

This register stores the status of the last transmitted frame. This register value, upon individual

transmit packet completion, is stored as the first word in the memory area allocated to the packet.

Packet interrupt processing should use the copy in memory as the register itself will be updated by

subsequent packet transmissions. The register can be used for real time values (like TXENA and LINK

OK). If TXENA is cleared the register holds the last packet completion status.

LINK_OK - General purpose input port driven by nLNK pin inverted. Typically used for Link Test. A

transition on the value of this bit generates an interrupt.

CTR_ROL - Counter Roll Over. When set one or more 4 bit counters have reached maximum count

(15). Cleared by reading the ECR register.

EXC_DEF - Excessive Deferral. When set last/current transmit was deferred for more than 1518 * 2

byte times. Cleared at the end of every packet sent.

LOST_CARR - Lost Carrier Sense. When set indicates that Carrier Sense was not present at end of

preamble. Valid only if MON_CSN is enabled. This condition causes TXENA bit in TCR to be reset.

Cleared by setting TXENA bit in TCR.

LATCOL - Late collision detected on last transmit frame. If set a late collision was detected (later than

64 byte times into the frame). When detected the transmitter jams and turns itself off clearing the

TXENA bit in TCR. Cleared by setting TXENA in TCR.

TX_DEFR - Transmit Deferred. When set, carrier was detected during the first 6.4 μs of the inter frame

gap. Cleared at the end of every packet sent.

LTX_BRD - Last transmit frame was a broadcast. Set if frame was broadcast. Cleared at the start of

every transmit frame.

OFFSET NAME TYPE SYMBOL

2 EPH STATUS REGISTER READ ONLY EPHSR

HIGH

BYTE

Reserved LINK_

Reserved CTR

_ROL

EXC

_DEF

LOST

CARR

LATCOL Reserved

0 -nLNK pin 0 0 0 0 0 0

LOW

BYTE

DEFR

LTX

BRD

SQET 16COL LTX

MULT

MUL

COL

SNGL

COL

TX_SUC

00 000000

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SQET - Signal Quality Error Test. This bit is set under the following conditions:

1. LAN91C111 is set to operate in Half Duplex mode (SWFDUP=0);

2. When STP_SQET=1 and SWFDUP=0, SQET bit will be set upon completion of a transmit

operation and no SQET Pulse has occurred during the IPG (Inter Frame Gap). If a pulse has

occurred during the IPG, SQET bit will not get set.

3. Once SQET bit is set, setting the TXENA bit in TCR register, or via hardware /software reset can

clear this bit.

16COL - 16 collisions reached. Set when 16 collisions are detected for a transmit frame. TXENA bit

in TCR is reset. Cleared when TXENA is set high.

LTX_MULT - Last transmit frame was a multicast. Set if frame was a multicast. Cleared at the start

of every transmit frame.

MULCOL - Multiple collision detected for the last transmit frame. Set when more than one collision

was experienced. Cleared when TX_SUC is high at the end of the packet being sent.

SNGLCOL - Single collision detected for the last transmit frame. Set when a collision is detected.

Cleared when TX_SUC is high at the end of the packet being sent.

TX_SUC - Last transmit was successful. Set if transmit completes without a fatal error. This bit is

cleared by the start of a new frame transmission or when TXENA is set high. Fatal errors are:

16 collisions (1/2 duplex mode only)

SQET fail and STP_SQET = 1 (1/2 duplex mode only)

Carrier lost and MON_CSN = 1 (1/2 duplex mode only)

Late collision (1/2 duplex mode only)

8.7 Bank 0 - Receive Control Register

SOFT_RST - Software-Activated Reset. Active high. Initiated by writing this bit high and terminated by

writing the bit low. The LAN91C111’s configuration is not preserved except for Configuration, Base,

and IA0-IA5 Registers. EEPROM is not reloaded after software reset.

FILT_CAR - Filter Carrier. When set filters leading edge of carrier sense for 12 bit times (3 nibble

times). Otherwise recognizes a receive frame as soon as carrier sense is active. (Does NOT filter RX

DV on MII!)

OFFSET NAME TYPE SYMBOL

RECEIVE CONTROL

HIGH

BYTE

SOFT

RST

FILT

CAR

ABORT_E

Reserved Reserved Reserved STRIP

CRC

RXEN

00000000

LOW

BYTE

Reserved Reserved Reserved Reserved Reserved ALMUL PRMS RX_

ABORT

00000000

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ABORT_ENB - Enables abort of receive when collision occurs. Defaults low. When set, the

LAN91C111 will automatically abort a packet being received when the appropriate collision input is

activated. This bit has no effect if the SWFDUP bit in the TCR is set.

STRIP_CRC - When set, it strips the CRC on received frames. As a result, both the Byte Count and

the frame format do not contain the CRC. When clear, the CRC is stored in memory following the

packet. Defaults low.

RXEN - Enables the receiver when set. If cleared, completes receiving current frame and then goes

idle. Defaults low on reset.

ALMUL - When set accepts all multicast frames (frames in which the first bit of DA is '1'). When clear

accepts only the multicast frames that match the multicast table setting. Defaults low.

PRMS - Promiscuous mode. When set receives all frames. Does not receive its own transmission

unless it is in Full Duplex!

RX_ABORT - This bit is set if a receive frame was aborted due to length longer than 2K bytes. The

frame will not be received. The bit is cleared by RESET or by the CPU writing it low.

Reserved - Must be 0.

8.8 Bank 0 - Counter Register

Counts four parameters for MAC statistics. When any counter reaches 15 an interrupt is issued. All

counters are cleared when reading the register and do not wrap around beyond 15.

Each four bit counter is incremented every time the corresponding event, as defined in the EPH

STATUS REGISTER bit description, occurs. Note that the counters can only increment once per

enqueued transmit packet, never faster, limiting the rate of interrupts that can be generated by the

counters. For example if a packet is successfully transmitted after one collision the SINGLE

COLLISION COUNT field is incremented by one. If a packet experiences between 2 to 16 collisions,

the MULTIPLE COLLISION COUNT field is incremented by one. If a packet experiences deferral the

NUMBER OF DEFERRED TX field is incremented by one, even if the packet experienced multiple

deferrals during its collision retries.

The COUNTER REGISTER facilitates maintaining statistics in the AUTO RELEASE mode where no

transmit interrupts are generated on successful transmissions.

Reading the register in the transmit service routine will be enough to maintain statistics.

OFFSET NAME TYPE SYMBOL

6 COUNTER REGISTER READ ONLY ECR

HIGH

BYTE

NUMBER OF EXC. DEFFERED TX NUMBER OF DEFFERED TX

00000000

LOW

BYTE

MULTIPLE COLLISION COUNT SINGLE COLLISION COUNT

00000000

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8.9 Bank 0 - Memory Information Register

FREE MEMORY AVAILABLE - This register can be read at any time to determine the amount of free

memory. The register defaults to the MEMORY SIZE upon POR (Power On Reset) or upon the RESET

MMU command.

MEMORY SIZE - This register can be read to determine the total memory size.

All memory related information is represented in 2K * M byte units, where the multiplier M is 1 for

LAN91C111.

8.10 Bank 0 - Receive/Phy Control Register

SPEED – Speed select Input. This bit is valid and selects 10/100 PHY operation only when the ANEG

Bit = 0, this bit overrides the SPEED bit in the PHY Register 0 (Control Register) and determine the

speed mode. When this bit is set (1), the Internal PHY will operate at 100Mbps. When this bit is

cleared (0), the Internal PHY will operate at 10Mbps. When the ANEG bit = 1, this bit is ignored and

10/100 operation is determined by the outcome of the Auto-negotiation or this bit is overridden by the

SPEED bit in the PHY Register 0 (Control Register) when the ANEG_EN bit in the PHY Register 0

(Control Register) is clear.

OFFSET NAME TYPE SYMBOL

MEMORY INFORMATION

HIGH

BYTE

FREE MEMORY AVAILABLE (IN BYTES * 2K * M)

00000100

LOW

BYTE

MEMORY SIZE (IN BYTES *2K * M)

00000100

OFFSET NAME TYPE SYMBOL

RECEIVE/PHY CONTROL

HIGH

BYTE

Reserved Reserved SPEED DPLX ANEG Reserved Reserved Reserved

000000 00

LOW

BYTE

LS2A LS1A LS0A LS2B LS1B LS0B Reserved Reserved

000000 00

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DPLX – Duplex Select - This bit selects Full/Half Duplex operation. This bit is valid and selects duplex

operation only when the ANEG Bit = 0, this bit overrides the DPLX bit in the PHY Register 0 (Control

full duplex mode. When this bit is cleared (0), the Internal PHY will operate at half Duplex mode. When

the ANEG bit = 1, this bit is ignored and duplex mode is determined by the outcome of the Auto-

negotiation or this bit is overridden by the DPLX bit in the PHY Register 0 (Control Register) when the

ANEG_EN bit in the PHY Register 0 (Control Register) is clear.

ANEG – Auto-Negotiation mode select - The PHY is placed in Auto-Negotiation mode when the ANEG

bit and the ANEG_EN bit in PHY Register 0 (Control Register) both are set. When either of these bits

is cleared (0), the PHY is placed in manual mode.

WHAT DO YOU

WANT TO DO?

AUTO-

NEGOTIATION

CONTROL BITS

AUTO-NEGOTIATION ADVERTISEMENT

DUPLEX

MODE

CONTROL

FOR THE

MAC

Try to Auto-Negotiate

to ……

ANEG

Bit

ANEG_E

Bit

TX_FDX

Bit

TX_HDX

Bit

10_FDX

Bit

10_HDX

Bit

SWFDUP

Bit

RPCR

(MAC)

(PHY)

Transmit

Control

(MAC)

100 Full Duplex 1 1 1 1 1 1 1

100 Half Duplex 1 1 0 1 1 1 0

10 Full Duplex 1 1 0 0 1 1 1

10 Half Duplex 1 1 0 0 0 1 0

WHAT DO YOU

WANT TO DO?

AUTO-NEGOTIATION

CONTROL BITS

SPEED AND DUPLEX MODE CONTROL

FOR THE PHY

DUPLEX

MODE

CONTROL

FOR THE

MAC

Try to Manually Set to

……

ANEG

Bit

ANEG_E

Bit

SPEED

Bit

DPLX

Bit

SPEED

Bit

DPLX

Bit

SWFDUP

Bit

RPCR

(MAC

Bank 0

Offset A)

(PHY)

RPCR

(MAC

Bank 0

Offset A)

RPCR

(MAC

Bank 0

Offset A)

(PHY)

Transmit

Control

(MAC)

100 Full Duplex 0 0 1 1 X X 1

0111XX 1

10XX11 1

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LS2A, LS1A, LS0A – LED select Signal Enable. These bits define what LED control signals are routed

to the LEDA output pin on the LAN91C111 Ethernet Controller. The default is 10/100 Link detected.

LS2B, LS1B, LS0B – LED select Signal Enable. These bits define what LED control signals are routed

to the LEDB output pin on the LAN91C111 Ethernet Controller. The default is 10/100 Link detected.

100 Half Duplex 0 0 1 0 X X 0

0110XX 0

10XX10 0

10 Full Duplex 0 0 0 1 X X 1

0101XX 1

10XX01 1

10 Half Duplex 0 0 0 0 X X 0

0100XX 0

10XX00 0

LS2A LS1A LS0A LED SELECT SIGNAL – LEDA

0 0 0 nPLED3+ nPLED0 – Logical OR of 100Mbps Link detected 10Mbps Link detected

(default)

0 0 1 Reserved

0 1 0 nPLED0 - 10Mbps Link detected

0 1 1 nPLED1 - Full Duplex Mode enabled

1 0 0 nPLED2 - Transmit or Receive packet occurred

1 0 1 nPLED3 - 100Mbps Link detected

1 1 0 nPLED4 - Receive packet occurred

1 1 1 nPLED5 - Transmit packet occurred

LS2B LS1B LS0B LED SELECT SIGNAL – LEDB

0 0 0 nPLED3+ nPLED0 – Logical OR of 100Mbps Link detected 10Mbps Link detected

(default)

0 0 1 Reserved

0 1 0 nPLED0 - 10Mbps Link detected

0 1 1 nPLED1 – Full Duplex Mode enabled

WHAT DO YOU

WANT TO DO?

AUTO-NEGOTIATION

CONTROL BITS

SPEED AND DUPLEX MODE CONTROL

FOR THE PHY

DUPLEX

MODE

CONTROL

FOR THE

MAC

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Reserved – Must be 0.

8.11 Bank 1 - Configuration Register

The Configuration Register holds bits that define the adapter configuration and are not expected to

change during run-time. This register is part of the EEPROM saved setup.

EPH Power EN - Used to selectively power transition the EPH to a low power mode. When this bit is

cleared (0), the Host will place the EPH into a low power mode. The Ethernet MAC will gate the 25Mhz

TX and RX clock so that the Ethernet MAC will no longer be able to receive and transmit packets. The

Host interface however, will still be active allowing the Host access to the device through Standard IO

access. All LAN91C111 registers will still be accessible. However, status and control will not be allowed

until the EPH Power EN bit is set AND a RESET MMU command is initiated.

NO WAIT - When set, does not request additional wait states. An exception to this are accesses to

the Data Register if not ready for a transfer. When clear, negates ARDY for two to three clocks on

any cycle to the LAN91C111.

GPCNTRL - This bit is a general purpose output port. Its inverse value drives pin nCNTRL and it is

typically connected to a SELECT pin of the external PHY device such as a power enable. It can be

used to select the signaling mode for the external PHY or as a general purpose non-volatile

configuration pin. Defaults low.

EXT PHY – External PHY Enabled.

This bit, when set (1):

a. Enables the external MII.

b. The Internal PHY is disabled and is disconnected (Tri-stated from the internal MII along with any

sideband signals (such as MDINT) going to the MAC Core).

1 0 0 nPLED2 – Transmit or Receive packet occurred

1 0 1 nPLED3 - 100Mbps Link detected

1 1 0 nPLED4 - Receive packet occurred

1 1 1 nPLED5 - Transmit packet occurred

OFFSET NAME TYPE SYMBOL

CONFIGURATION

HIGH

BYTE

EPH

Power

Reserved Reserved NO

WAIT

Reserved GPCNTRL EXT PHY Reserved

10 100 0 0 0

LOW

BYTE

Reserved Reserved Reserved Reserved Reserved Reserved

10 110 0 0 1

LS2B LS1B LS0B LED SELECT SIGNAL – LEDB

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When this bit is cleared (0 - Default):

a. The internal PHY is enabled.

b. The external MII pins, including the MII Management interface pins are tri-stated.

Reserved – Reserved bits.

8.12 Bank 1 - Base Address Register

This register holds the I/O address decode option chosen for the LAN91C111. It is part of the EEPROM

saved setup and is not usually modified during run-time.

A15 - A13 and A9 - A5 - These bits are compared against the I/O address on the bus to determine

the IOBASE for the LAN91C111‘s registers. The 64k I/O space is fully decoded by the LAN91C111

down to a 16 location space, therefore the unspecified address lines A4, A10, A11 and A12 must be

all zeros.

All bits in this register are loaded from the serial EEPROM. The I/O base decode defaults to 300h

(namely, the high byte defaults to 18h).

Reserved – Reserved bits.

Below chart shows the decoding of I/O Base Address 300h:

OFFSET NAME TYPE SYMBOL

BASE ADDRESS

HIGH

BYTE

A15A14A13A9A8A7A6A5

00011000

LOW

BYTE

Reserved Reserved

00000001

A15 A14 A13 A12 A11 A10 A9 A8 A7 A6 A5 A4 A3 A2 A1 A0

0000001100000000

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8.13 Bank 1 - Individual Address Registers

These registers are loaded starting at word location 20h of the EEPROM upon hardware reset or

EEPROM reload. The registers can be modified by the software driver, but a STORE operation will not

modify the EEPROM Individual Address contents. Bit 0 of Individual Address 0 register corresponds

to the first bit of the address on the cable.

OFFSET NAME TYPE SYMBOL

4 THROUGH 9

INDIVIDUAL ADDRESS

REGISTERS READ/WRITE IAR

LOW

BYTE

ADDRESS 0

00000000

HIGH

BYTE

ADDRESS 1

00000000

LOW

BYTE

ADDRESS 2

00000000

HIGH

BYTE

ADDRESS 3

00000000

LOW

BYTE

ADDRESS 4

00000000

HIGH

BYTE

ADDRESS 5

00000000

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8.14 Bank 1 - General Purpose Register

This register can be used as a way of storing and retrieving non-volatile information in the EEPROM

to be used by the software driver. The storage is word oriented, and the EEPROM word address to

be read or written is specified using the six lowest bits of the Pointer Register.

This register can also be used to sequentially program the Individual Address area of the EEPROM,

that is normally protected from accidental Store operations.

This register will be used for EEPROM read and write only when the EEPROM SELECT bit in the

Control Register is set. This allows generic EEPROM read and write routines that do not affect the

basic setup of the LAN91C111.

8.15 Bank 1 - Control Register

RCV_BAD - When set, bad CRC packets are received. When clear bad CRC packets do not generate

interrupts and their memory is released.

AUTO RELEASE - When set, transmit pages are released by transmit completion if the transmission

was successful (when TX_SUC is set). In that case there is no status word associated with its packet

number, and successful packet numbers are not even written into the TX COMPLETION FIFO. A

sequence of transmit packets will generate an interrupt only when the sequence is completely

OFFSET NAME TYPE SYMBOL

GENERAL PURPOSE

HIGH

BYTE

HIGH DATA BYTE

00000000

LOW

BYTE

LOW DATA BYTE

00000000

OFFSET NAME TYPE SYMBOL

C CONTROL REGISTER READ/WRITE CTR

HIGH

BYTE

Reserved RCV_

BAD

Reserved Reserved AUTO

RELEASE

Reserved Reserved Reserved

00010010

LOW BYTE LE

ENABLE

Reserved Reserved EEPROM

SELECT

RELOAD STORE

00010000

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transmitted (TX EMPTY INT will be set), or when a packet in the sequence experiences a fatal error

(TX INT will be set). Upon a fatal error TXENA is cleared and the transmission sequence stops. The

packet number that failed, is present in the FIFO PORTS register, and its pages are not released,

allowing the CPU to restart the sequence after corrective action is taken.

LE ENABLE - Link Error Enable. When set it enables the LINK_OK bit transition as one of the

interrupts merged into the EPH INT bit. Clearing the LE ENABLE bit after an EPH INT interrupt, caused

by a LINK_OK transition, will acknowledge the interrupt. LE ENABLE defaults low (disabled).

CR ENABLE - Counter Roll over Enable. When set, it enables the CTR_ROL bit as one of the

interrupts merged into the EPH INT bit. Reading the COUNTER register after an EPH INT interrupt

caused by a counter rollover, will acknowledge the interrupt. CR ENABLE defaults low (disabled).

TE ENABLE - Transmit Error Enable. When set it enables Transmit Error as one of the interrupts

merged into the EPH INT bit. An EPH INT interrupt caused by a transmitter error is acknowledged by

setting TXENA bit in the TCR register to 1 or by clearing the TE ENABLE bit. TE ENABLE defaults

low (disabled). Transmit Error is any condition that clears TXENA with TX_SUC staying low as

described in the EPHSR register.

EEPROM SELECT - This bit allows the CPU to specify which registers the EEPROM RELOAD or

STORE refers to. When high, the General Purpose Register is the only register read or written. When

low, RELOAD reads Configuration, Base and Individual Address, and STORE writes the Configuration

and Base registers.

RELOAD - When set it will read the EEPROM and update relevant registers with its contents. Clears

upon completing the operation.

STORE - When set, stores the contents of all relevant registers in the serial EEPROM. Clears upon

completing the operation.

Note: When an EEPROM access is in progress the STORE and RELOAD bits will be read back as

high. The remaining 14 bits of this register will be invalid. During this time attempted read/write

operations, other than polling the EEPROM status, will NOT have any effect on the internal

registers. The CPU can resume accesses to the LAN91C111 after both bits are low. A worst

case RELOAD operation initiated by RESET or by software takes less than 750 μs.

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8.16 Bank 2 - MMU Command Register

This register is used by the CPU to control the memory allocation, de-allocation, TX FIFO and RX

FIFO control.

The three command bits determine the command issued as described below:

COMMAND SET:

OFFSET NAME TYPE SYMBOL

MMU COMMAND

WRITE ONLY

BUSY BIT

READABLE MMUCR

HIGH

BYTE

LOW

BYTE

COMMAND Reserved Reserved Reserved Reserved BUSY

Operation Code

OPERATION

CODE

DECIMAL

VALUE COMMAND

000 0 NOOP - NO OPERATION

001 1 ALLOCATE MEMORY FOR TX

010 2 RESET MMU TO INITIAL STATE - Frees all memory allocations, clears relevant

interrupts, resets packet FIFO pointers.

011 3 REMOVE FRAME FROM TOP OF RX FIFO - To be issued after CPU has

completed processing of present receive frame. This command removes the

receive packet number from the RX FIFO and brings the next receive frame (if

any) to the RX area (output of RX FIFO).

100 4 REMOVE AND RELEASE TOP OF RX FIFO - Like 3) but also releases all

memory used by the packet presently at the RX FIFO output. The MMU busy

time after issuing REMOVE and RELEASE command depends on the time when

the busy bit is cleared. The time from issuing REMOVE and RELEASE command

on the last receive packet to the time when receive FIFO is empty depends on

RX INT bit turning low. An alternate approach can be checking the read RX FIFO

101 5 RELEASE SPECIFIC PACKET - Frees all pages allocated to the packet specified

in the PACKET NUMBER REGISTER. Should not be used for frames pending

transmission. Typically used to remove transmitted frames, after reading their

completion status. Can be used following 3) to release receive packet memory

in a more flexible way than 4).

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Note:

When using the RESET TX FIFOS command, the CPU is responsible for releasing the memory

associated with outstanding packets, or re-enqueuing them. Packet numbers in the completion

FIFO can be read via the FIFO ports register before issuing the command.

MMU commands releasing memory (commands 4 and 5) should only be issued if the

corresponding packet number has memory allocated to it.

COMMAND SEQUENCING

A second allocate command (command 1) should not be issued until the present one has completed.

Completion is determined by reading the FAILED bit of the allocation result register or through the

allocation interrupt.

A second release command (commands 4, 5) should not be issued if the previous one is still being

processed. The BUSY bit indicates that a release command is in progress. After issuing command 5,

the contents of the PNR should not be changed until BUSY goes low. After issuing command 4,

command 3 should not be issued until BUSY goes low.

BUSY BIT - Readable at bit 0 of the MMU command register address. When set indicates that MMU

is still processing a release command. When clear, MMU has already completed last release

command. BUSY and FAILED bits are set upon the trailing edge of command.

110 6 ENQUEUE PACKET NUMBER INTO TX FIFO - This is the normal method of

transmitting a packet just loaded into RAM. The packet number to be enqueued

is taken from the PACKET NUMBER REGISTER.

111 7 RESET TX FIFOs - This command will reset both TX FIFOs: The TX FIFO

holding the packet numbers awaiting transmission and the TX Completion FIFO.

This command provides a mechanism for canceling packet transmissions, and

reordering or bypassing the transmit queue. The RESET TX FIFOs command

should only be used when the transmitter is disabled. Unlike the RESET MMU

command, the RESET TX FIFOs does not release any memory.

OPERATION

CODE

DECIMAL

VALUE COMMAND

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8.17 Bank 2 - Packet Number Register

PACKET NUMBER AT TX AREA - The value written into this register determines which packet number

is accessible through the TX area. Some MMU commands use the number stored in this register as

the packet number parameter. This register is cleared by a RESET or a RESET MMU Command.

This register is updated upon an ALLOCATE MEMORY MMU command.

FAILED - A zero indicates a successful allocation completion. If the allocation fails the bit is set and

only cleared when the pending allocation is satisfied. Defaults high upon reset and reset MMU

command. For polling purposes, the ALLOC_INT in the Interrupt Status Register should be used

because it is synchronized to the read operation. Sequence:

1. Allocate Command

2. Poll ALLOC_INT bit until set

3. Read Allocation Result Register

ALLOCATED PACKET NUMBER - Packet number associated with the last memory allocation request.

The value is only valid if the FAILED bit is clear.

Note: For software compatibility with future versions, the value read from the ARR after an allocation

request is intended to be written into the PNR as is, without masking higher bits (provided

FAILED = 0).

OFFSET NAME TYPE SYMBOL

PACKET NUMBER

Reserved Reserved PACKET NUMBER AT TX AREA

00000000

OFFSET NAME TYPE SYMBOL

ALLOCATION RESULT

FAILED Reserved ALLOCATED PACKET NUMBER

10000000

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8.18 Bank 2 - FIFO Ports Register

This register provides access to the read ports of the Receive FIFO and the Transmit completion FIFO.

The packet numbers to be processed by the interrupt service routines are read from this register.

REMPTY - No receive packets queued in the RX FIFO. For polling purposes, uses the RCV_INT bit

in the Interrupt Status Register.

TOP OF RX FIFO PACKET NUMBER - Packet number presently at the output of the RX FIFO. Only

valid if REMPTY is clear. The packet is removed from the RX FIFO using MMU Commands 3) or 4).

TEMPTY - No transmit packets in completion queue. For polling purposes, uses the TX_INT bit in the

Interrupt Status Register.

TX FIFO PACKET NUMBER - Packet number presently at the output of the TX FIFO. Only valid if

TEMPTY is clear. The packet is removed when a TX INT acknowledge is issued.

Note: For software compatibility with future versions, the value read from each FIFO register is

intended to be written into the PNR as is, without masking higher bits (provided TEMPTY and

REMPTY = 0 respectively).

OFFSET NAME TYPE SYMBOL

4 FIFO PORTS REGISTER READ ONLY FIFO

HIGH

BYTE

REMPTY Reserved RX FIFO PACKET NUMBER

10000000

LOW

BYTE

TEMPTY Reserved TX FIFO PACKET NUMBER

10000000

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8.19 Bank 2 - Pointer Register

POINTER REGISTER - The value of this register determines the address to be accessed within the

transmit or receive areas. It will auto-increment on accesses to the data register when AUTO INCR.

is set. The increment is by one for every byte access, by two for every word access, and by four for

every double word access. When RCV is set the address refers to the receive area and uses the

output of RX FIFO as the packet number, when RCV is clear the address refers to the transmit area

and uses the packet number at the Packet Number Register.

READ - Determines the type of access to follow. If the READ bit is high the operation intended is a

read. If the READ bit is low the operation is a write. Loading a new pointer value, with the READ bit

high, generates a pre-fetch into the Data Register for read purposes.

Readback of the pointer will indicate the value of the address last accessed by the CPU (rather than

the last pre-fetched). This allows any interrupt routine that uses the pointer, to save it and restore it

without affecting the process being interrupted. The Pointer Register should not be loaded until the

Data Register FIFO is empty. The NOT EMPTY bit of this register can be read to determine if the

FIFO is empty. On reads, if ARDY is not connected to the host, the Data Register should not be read

before 370ns after the pointer was loaded to allow the Data Register FIFO to fill.

If the pointer is loaded using 8 bit writes, the low byte should be loaded first and the high byte last.

Reserved - Must be 0

NOT EMPTY - When set indicates that the Write Data FIFO is not empty yet. The CPU can verify that

the FIFO is empty before loading a new pointer value. This is a read only bit.

Note: If AUTO INCR. is not set, the pointer must be loaded with a dword aligned value.

OFFSET NAME TYPE SYMBOL

6 POINTER REGISTER

READ/WRITE

NOT EMPTY IS

A READ ONLY

BIT PTR

HIGH

BYTE

RCV AUTO

INCR.

READ Reserved NOT

EMPTY

POINTER HIGH

00000000

LOW

BYTE

POINTER LOW

00000000

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8.20 Bank 2 - Data Register

DATA REGISTER - Used to read or write the data buffer byte/word presently addressed by the pointer

This register is mapped into two uni-directional FIFOs that allow moving words to and from the

LAN91C111 regardless of whether the pointer address is even, odd or dword aligned. Data goes

through the write FIFO into memory, and is pre-fetched from memory into the read FIFO. If byte

accesses are used, the appropriate (next) byte can be accessed through the Data Low or Data High

registers. The order to and from the FIFO is preserved. Byte, word and dword accesses can be mixed

on the fly in any order.

This register is mapped into two consecutive word locations to facilitate double word move operations

regardless of the actual bus width (16 or 32 bits). The DATA register is accessible at any address in

the 8 through Bh range, while the number of bytes being transferred is determined by A1 and nBE0-

nBE3. The FIFOs are 12 bytes each.

OFFSET NAME TYPE SYMBOL

8 THROUGH

BH DATA REGISTER READ/WRITE DATA

DATA HIGH

XXXXXXXX

DATA LOW

XXXXXXXX

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8.21 Bank 2 - Interrupt Status Registers

This register can be read and written as a word or as two individual bytes.

The Interrupt Mask Register bits enable the appropriate bits when high and disable them when low. A

MASK bit being set will cause a hardware interrupt.

MDINT - Set when the following bits in the PHY MI Register 18 (Serial Port Status Output Register)

change state.

1. LNKFAIL, 2) LOSSSYNC, 3) CWRD, 4) SSD, 5) ESD, 6) PROL, 7) JAB, 8) SPDDET, 9) DPLXDET.

OFFSET NAME TYPE SYMBOL

INTERRUPT STATUS

MDINT Reserved EPH INT RX_OVRN

INT

ALLOC INT TX EMPTY

INT

TX INT RCV INT

00000100

OFFSET NAME TYPE SYMBOL

INTERRUPT

ACKNOWLEDGE

MDINT Reserved RX_OVRN

INT

TX EMPTY

INT

TX INT

OFFSET NAME TYPE SYMBOL

INTERRUPT MASK

MDINT

MASK

Reserved EPH INT

MASK

RX_OVRN

INT

MASK

ALLOC INT

MASK

TX EMPTY

INT

MASK

TX INT

MASK

RCV INT

MASK

00000000

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These bits automatically latch upon changing state and stay latched until they are read. When they

are read, the bits that caused the interrupt to happen are updated to their current value. The MDINT

bit will be cleared by writing the acknowledge register with MDINT bit set.

Reserved - Must be 0

EPH INT - Set when the Ethernet Protocol Handler section indicates one out of various possible

special conditions. This bit merges exception type of interrupt sources, whose service time is not

critical to the execution speed of the low level drivers. The exact nature of the interrupt can be obtained

from the EPH Status Register (EPHSR), and enabling of these sources can be done via the Control

LINK - Link Test transition

CTR_ROL - Statistics counter roll over

TXENA cleared - A fatal transmit error occurred forcing TXENA to be cleared. TX_SUC will be low and

the specific reason will be reflected by the bits:

SQET - SQE Error

LOST CARR - Lost Carrier

LATCOL - Late Collision

16COL - 16 collisions

Any of the above interrupt sources can be masked by the appropriate ENABLE bits in the Control

1. 1) LE ENABLE (Link Error Enable), 2) CR ENABLE (Counter Roll Over), 3) TE ENABLE (Transmit

Error Enable)

EPH INT will only be cleared by the following methods:

Clearing the LE ENABLE bit in the Control Register if an EPH interrupt is caused by a LINK_OK

transition.

Reading the Counter Register if an EPH interrupt is caused by statistics counter roll over.

Setting TXENA bit high if an EPH interrupt is caused by any of the fatal transmit error listed above

(3.1 to 3.5).

RX_OVRN INT - Set when 1) the receiver aborts due to an overrun due to a failed memory allocation,

2) the receiver aborts due to a packet length of greater than 2K bytes, or 3) the receiver aborts due

to the RCV DISCRD bit in the RCV register set. The RX_OVRN INT bit latches the condition for the

purpose of being polled or generating an interrupt, and will only be cleared by writing the acknowledge

ALLOC INT - Set when an MMU request for TX ram pages is successful. This bit is the complement

of the FAILED bit in the ALLOCATION RESULT register. The ALLOC INT bit is cleared by the MMU

when the next allocation request is processed or allocation fails.

TX EMPTY INT - Set if the TX FIFO goes empty, can be used to generate a single interrupt at the

end of a sequence of packets enqueued for transmission. This bit latches the empty condition, and

the bit will stay set until it is specifically cleared by writing the acknowledge register with the TX EMPTY

INT bit set. If a real time reading of the FIFO empty is desired, the bit should be first cleared and then

read.

The TX_EMPTY MASK bit should only be set after the following steps:

A packet is enqueued for transmission

The previous empty condition is cleared (acknowledged)

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TX INT - Set when at least one packet transmission was completed or any of the below transmit fatal

errors occurs:

SQET - SQE Error

LOST CARR - Lost Carrier

LATCOL - Late Collision

16COL - 16 collisions

The first packet number to be serviced can be read from the FIFO PORTS register. The TX INT bit is

always the logic complement of the TEMPTY bit in the FIFO PORTS register. After servicing a packet

number, its TX INT interrupt is removed by writing the Interrupt Acknowledge Register with the TX INT

bit set.

RCV INT - Set when a receive interrupt is generated. The first packet number to be serviced can be

read from the FIFO PORTS register. The RCV INT bit is always the logic complement of the REMPTY

bit in the FIFO PORTS register.

Receive Interrupt is cleared when RX FIFO is empty.

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Figure 8.2 Interrupt Structure

TX FIFO EMPTY

DQS

IntAck1

DQS

IntAck2

DQS

IntAck4

DQS

IntAck7

RX_OVRN

MDINT

nWRACK

TX Complete

Fatal TX Error

SQET

LOST CARR

LATCOL

16COL

Interrupt Status Register

76543210

nRDIST Interrupt Mask Register

76543210

OE nOE

Edge Detector on Link Err

LEMASK

CTR-ROL

CRMASK

TEMASK

TXENA

TX_SVC

EPHSR INTERRUPTS

MERGED INTO EPH INT

ALLOCATION

FAILED

RX_OVRN INT

EPH INT

MDINT

ALLOC INT

TX EMPTY INT

TX INT

RCV INT

INT

RCV FIFO

NOT EMPTY

D[7:0] D[15:8]

DATA BUS

D[15:0]

MAIN INTERRUPTS

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8.22 Bank 3 - Multicast Table Registers

The 64 bit multicast table is used for group address filtering. The hash value is defined as the six most

significant bits of the CRC of the destination addresses. The three msb's determine the register to be

used (MT0-MT7), while the other three determine the bit within the register.

If the appropriate bit in the table is set, the packet is received.

If the ALMUL bit in the RCR register is set, all multicast addresses are received regardless of the

multicast table values.

Hashing is only a partial group addressing filtering scheme, but being the hash value available as part

of the receive status word, the receive routine can reduce the search time significantly. With the proper

OFFSET NAME TYPE SYMBOL

THROUG

H 7 MULTICAST TABLE READ/WRITE MT

LOW

BYTE

MULTICAST TABLE 0

0000000

HIGH

BYTE

MULTICAST TABLE 1

0000000

LOW

BYTE

MULTICAST TABLE 2

0000000

HIGH

BYTE

MULTICAST TABLE 3

0000000

LOW

BYTE

MULTICAST TABLE 4

0000000

HIGH

BYTE

MULTICAST TABLE 5

0000000

LOW

BYTE

MULTICAST TABLE 6

0000000

HIGH

BYTE

MULTICAST TABLE 7

0000000

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memory structure, the search is limited to comparing only the multicast addresses that have the actual

hash value in question.

8.23 Bank 3 - Management Interface

MSK_CRS100 - Disables CRS100 detection during transmit in half duplex mode (SWFDUP=0).

MDO - MII Management output. The value of this bit drives the MDO pin.

MDI - MII Management input. The value of the MDI pin is readable using this bit.

MDCLK - MII Management clock. The value of this bit drives the MDCLK pin.

MDOE - MII Management output enable. When high pin MDO is driven, when low pin MDO is tri-

stated.

The purpose of this interface, along with the corresponding pins is to implement MII PHY management

in software.

OFFSET NAME TYPE SYMBOL

MANAGEMENT

INTERFACE READ/WRITE MGMT

HIGH

BYTE

Reserved MSK_

CRS100

Reserved Reserved Reserved Reserved Reserved Reserved

00110011

LOW

BYTE

Reserved MDOE MCLK MDI MDO

001100MDI Pin0

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8.24 Bank 3 - Revision Register

CHIP - Chip ID. Can be used by software drivers to identify the device used.

REV - Revision ID. Incremented for each revision of a given device.

8.25 Bank 3 - RCV Register

RCV DISCRD - Set to discard a packet being received. Will discard packets only in the process of

being received. When set prior to the end of receive packet, bit 4 (RXOVRN) of the interrupt status

normally and bit 0 set (RCVINT) in the interrupt status register. RCV DISCRD is self clearing.

MBO - Must be 1.

OFFSET NAME TYPE SYMBOL

A REVISION REGISTER READ ONLY REV

HIGH

BYTE

00110011

LOW

BYTE

CHIP REV

10010010

OFFSET NAME TYPE SYMBOL

C RCV REGISTER READ/WRITE RCV

HIGH

BYTE

Reserved

00000000

LOW

BYTE

RCV

DISCRD

Reserved Reserved MBO MBO MBO MBO MBO

00011111

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8.26 Bank 7 - External Registers

nCSOUT is driven low by the LAN91C111 when a valid access to the EXTERNAL REGISTER range

occurs.

OFFSET NAME TYPE SYMBOL

THROUG

H 7 EXTERNAL REGISTERS

HIGH

BYTE

EXTERNAL R/W REGISTER

LOW

BYTE

EXTERNAL R/W REGISTER

CYCLE NCSOUT LAN91C111 DATA BUS

AEN=0

A3=0

A4-15 matches I/O BASE

BANK SELECT = 7

Driven low. Transparently latched on nADS

rising edge.

Ignored on writes.

Tri-stated on reads.

BANK SELECT = 4,5,6 High Ignore cycle.

Otherwise High Normal LAN91C111 cycle.

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Chapter 9 PHY MII Registers

Multiple Register Access

Multiple registers can be accessed on a single PHY Ml serial port access cycle with the multiple

access is enabled, multiple registers can be accessed on a single PHY Ml serial port access cycle by

setting the register address to 11111 during the first 16 MDC clock cycles. There is no actual register

residing in register address location 11111, so when the register address is then set to 11111, all eleven

registers are accessed on the 176 rising edges of MDC that occur after the first 16 MDC clock cycles

of the PHY Ml serial port access cycle. The registers are accessed in numerical order from 0 to 20.

After all 192 MDC clocks have been completed, all the registers have been read/written, and the serial

shift process is halted, data is latched into the device, and MDIO goes into high impedance state.

Another serial shift cycle cannot be initiated until the idle condition (at least 32 continuous 1's) is

detected.

Bit Types

Since the serial port is bi-directional, there are many types of bits. Write bits (W) are inputs during a

write cycle and are high impedance during a read cycle. Read bits (R) are outputs during a read cycle

and high impedance during a write cycle. Read/Write bits (RW) are actually write bits, which can be

read out during a read cycle. R/WSC bits are R/W bits that are self-clearing after a set period of time

or after a specific event has completed. R/LL bits are read bits that latch themselves when they go

low, and they stay latched low until read. After they are read, they are reset high. R/LH bits are the

same as R/LL bits except that they latch high. R/LT are read bits that latch themselves whenever they

make a transition or change value, and they stay latched until they are read. After R/LT bits are read,

they are updated to their current value. R/LT bits can also be programmed to assert the interrupt

function.

Bit Type Definition

R: Read Only R/WSC: Read/Write

Self Clearing

W: Write Only R/LH: Read/Latch

high

RW: Read/Write R/LL: Read/Latch

low

R/LT: Read/Latch on Transition

0Control

1Status

2,3 PHY ID

4 Auto-Negotiation Advertisement

5 Auto-Negotiation Remote End Capability

6....15 Reserved

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PHY Register Description

D[15:0]

↓

16 Configuration 1

17 Configuration 2

18 Status Output

19 Mask

20 Reserved

Table 9.1 MII Serial Frame Structure

IDLE ST[1:0] READ WRITE PHYAD[4:0] REGAD[4:0] TA[1:0] D[15:0]

SYMBOL NAME DEFINITION R/W

IDLE Idle Pattern These bits are an idle pattern. Device will not initiate an MI cycle until

it detects at least 32 1's

ST1

ST0

Start Bits When ST[1:0]=01, a MI Serial Port access cycle starts. W

READ Read Select 1 = Read Cycle W

WRITE Write Select 1 = Write Cycle W

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PHYAD[4:0] Physical

Device

Address

PHYSICAL ADDRESS R

REGAD[4:0] Register

Address

If REGAD[4:0] = 00000-11110, these bits determine the specific

is enabled and REGAD[4:0] = 11111, all registers are read/written in

a single cycle.

TA1

TA0

Turnaround

Time

These bits provide some turnaround time for MDIO

When READ = 1, TA[1:0] = Z0

When WRITE = 1, TA[1:0] = 10

The turnaround time is a 2 bit time spacing between the Register

Address field and the Data field of a management frame to avoid

contention during a read transaction. For a read transaction, both the

STA and the PHY shall remain in a high impedance state for the first

bit time of the turnaround. The PHY shall drive a zero bit during the

second bit time of the turnaround of a read transaction. During a

write transaction, the STA shall drive a one bit for the first bit time of

the turnaround and a zero bit for the second bit time of the

turnaround.

R/W

D[15:0].... Data These 16 bits contain data to/from one of the eleven registers

selected by register address bits REGAD[4:0].

Any

SYMBOL NAME DEFINITION R/W

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Table 9.2 MII Serial Port Register MAP

R/LTR/LT R RR/LT R/LT RR

R/LTR/LTR/LT R/LTR R/LT R/LTR/LT

00000000000 00

x.6x.7x.8x.9x.13 x.10x.15 x.14 x.11x.12 x.3 x.0x.5 x.4 x.1x.2

R/WR/W R/W R/WR/W R/W R/WR/W

R/WR/WSCR/W R/WR/WSC R/W R/WR/W

0011 or 000 010000 00

Control

Status

AutoNegot.

PHY ID #2

PHY ID #1

AutoNegot.

Remote

Capability

Status

Output

Configuration 2

Configuration 1

Mask

Reserved

COLTSTDPLXANEG_RSTSPEEDRST LPBK PDNANEG_EN MII_DIS

CAP_SUPR

CAP_TXHCAP_T4 CAP_TXF CAP_THCAP_TF CAP_ANEG JABANEG_ACK REM_FLT EXREGLINK

RRRRR R/LH R/LHR/LL

RRRRRR RR

001001 111100 00

OUI12OUI11OUI10OUI9OUI5OUI3 OUI4 OUI7OUI6 OUI15 OUI17OUI13 OUI14 OUI18OUI16OUI8

RRRRRR RR

000000 000001 11

PART2PART3PART4PART5OUI21OUI19 OUI20 OUI23OUI22 REV3 REV1PART1 PART0 REV0REV2OUI24

RRRRRR RR

001011 110000 00

10_FDXTX_HDXTX_FDXT4RFNP ACK 10_HDX CSMA

R/WR/W R/W R/WR/W R/W R/WR/W

R/WR/WR/W R/WR/W R R/WR/W

100000 000110 00

10_FDXTX_HDXTX_FDXT4RFNP ACK 10_HDX CSMA

RRRRRR RR

000000 0000000

RLVL0CABLEEQLZRUNSCDSXMTPDNLNKDIS XMTDIS ReservedReserved TLVL1 TRF1TLVL3 TLVL2 TRF0TLVL0BYPSCR

R/WR/W R/W R/WR/W R/W R/WR/W

R/WR/WR/W R/WR/W R/W R/WR/W

000000 000010 10

R/WR/W R/W R/WR/W R/W

R/W

111 11

DPLXDETSPDDETJABRPOL

LOSSSYNC

INT LNKFAIL SSDCWRD ESD

MDPLDTMSPDDT

MJAB

MRPOLMLOSSSYNMLNKFAIL MSSDMCWRD MESD

R/W

R/W R/W R/W

R/W R/WR/W

R/WR/WR/W R/WR/W R/WR/W

11111110000 00

R/WR/W R/W R/W

R/WR/WR/W R/WR/WR/W

0000

R/W

000

R/W

010

R/W

APOLDIS JABDIS MREG INTMDIO

MINT

R/W

R/WR/W

ReservedReserved Reserved Reserved Reserved Reserved

ReservedReservedReservedReserved

Reserved Reserved

Reserved

Reserved Reserved Reserved Reserved

Reserved Reserved ReservedReserved

Reserved Reserved Reserved Reserved

ReservedReserved

Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved

Reserved Reserved

Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved

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9.1 Register 0. Control Register

RST - Reset

A ‘1’ written to this bit will initiate a reset of the PHY. The bit is self-clearing, and the PHY will return

a ‘1’ on reads to this bit until the reset is completed. Write transactions to this register may be ignored

while the PHY is processing the reset. All PHY registers will be driven to their default states after a

reset. The internal PHY is guaranteed to be ready for normal operation 50 mS after the RST bit is

set. Software driver requires to wait for 50mS after setting the RST bit to high to access the internal

PHY again.

LPBK - Loopback

Writing a ‘1’ will put the PHY into loopback mode.

Speed (Speed Selection)

When Auto Negotiation is disabled this bit can be used to manually select the link speed. Writing a

‘1’ to this bit selects 100 Mbps, a ‘0’ selects 10 Mbps.

When Auto-Negotiation is enabled reading or writing this bit has no meaning/effect.

ANEN_EN - Auto-Negotiation Enable

Auto-negotiation (ANEG) is on when this bit is ‘1’. In that case the contents of bits Speed and Duplex

are ignored and the ANEG process determines the link configuration.

PDN - Power down

Setting this bit to ‘1’ will put the PHY in PowerDown mode. In this state the PHY will respond to

management transactions.

Note: This bit must not be set when the device is in external PHY mode.

MII_DIS - MII DISABLE

Setting this bit will set the PHY to an isolated mode in which it will respond to MII management frames

over the MII management interface but will ignore data on the MII data interface. The internal PHY

is placed in isolation mode at power up and reset. It can be removed from isolation mode by clearing

the MII_DIS bit in the PHY Control Register. If necessary, the internal PHY can be enabled by clearing

the EXT_PHY bit in the Configuration Register.

ANEG_RST - Auto-Negotiation Reset

This bit will return 0 if the PHY does not support ANEG or if ANEG is disabled through the ANEG_EN

bit. If neither of the previous is true, setting this bit to ‘1’ resets the ANEG process. This bit is self

RST LPBK SPEED ANEG_EN PDN MII_DIS ANEG_RST DPLX

RW, SC RW RW RW RW RW RW. SC RW

001 101 00

COLST Reserved Reserved Reserved Reserved Reserved Reserved Reserved

RW RW RW RW RW RW RW RW

00000000

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clearing and the PHY will return a ‘1’ until ANEG is initiated, writing a ‘0’ does not affect the ANEG

process.

DPLX - Duplex mode

When Auto Negotiation is disabled this bit can be used to manually select the link duplex state. Writing

a ‘1’ to this bit selects full duplex while a ‘0’ selects half duplex.

When Auto-Negotiation is enabled reading or writing this bit has no effect.

COLTST - Collision test

Setting a ‘1’ allows for testing of the MII COL signal. ‘0’ allows normal operation.

Reserved:Reserved, Must be 0 for Proper Operation

9.2 Register 1. Status Register

CAP_T4 - 100BASE-T4 Capable

‘1’ Indicates 100Base-T4 capable PHY, ‘0’ not capable.

CAP_TXF - 100BASE-TX Full Duplex Capable

‘1’ Indicates 100Base-X full duplex capable PHY, ‘0’ not capable.

CAP_TXH - 100BASE-TX Half Duplex Capable

‘1’ Indicates 100Base-X alf duplex capable PHY, ‘0’ not capable.

CAP_TF - 10BASE-T Full Duplex Capable

‘1’ Indicates 10Mbps full duplex capable PHY, ‘0’ not capable.

CAP_TH - 10BASE-T Half Duplex Capable

‘1’ Indicates 10Mbps half duplex capable PHY, ‘0’ not capable.

Reserved:Reserved, Must be 0 for Proper Operation.

CAP_SUPR - MI Preamble Suppression Capable

‘1’ indicates the PHY is able to receive management frames even if not preceded by a preamble. ‘0’

when it is not able.

CAP_T4 CAP_TXF CAP_TXH CAP_TF CAP_TH Reserved Reserved. Reserved

RRRRRRRR

01111000

Reserved CAP_SUPR ANEG_ACK REM_FLT CAP_ANEG LINK JAB EXREG

R R R R, LH R R, LL R, LH R

00 0 0 1001

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ANEG_ACK - Auto-Negotiation Acknowledgment

When read as ‘1’ indicate ANEG has been completed and that contents in registers 4,5,6 and 7 are

valid. ‘0’ means ANEG has not completed and contents in registers 4,5,6 and 7 are meaningless. The

PHY returns zero if ANEG is disabled.

REM_FLT- Remote Fault Detect

‘1’ indicates a Remote Fault. Latches the ‘1’ condition and is cleared by reading this register or

resetting the PHY.

CAP_ANEG - AutoNegotiation Capable

Indicates the ability (‘1’) to perform ANEG or not (‘0’).

LINK - Link Status

A ‘1’ indicates a valid Link and a ‘0’ and invalid Link. The ‘0’ condition is latched until this register is

read.

JAB - Jabber Detect

Jabber condition detected when ‘1’ for 10Mbps. ‘1’ latched until this register is read or the PHY is reset.

Always ‘0’ for 100Mbps

EXREG - Extended Capability register

‘1’ Indicates extended registers are implemented

9.3 Register 2&3. PHY Identifier Register

These two registers (offsets 2 and 3) provide a 32-bit value unique to the PHY.

9.4 Register 4. Auto-Negotiation Advertisement Register

REG BITS NAME DEFAULT VALUE R/W SOFT RESET

2 15-0 Company ID 0000000000010110 R Retains Original Value

3 15-10 Company ID 111110 R Retains Original Value

3 9-4 Manufacturer's ID 000100 R Retains Original Value

3 3-0 Manufacturer's Revision # - - - - R Retains Original Value

NP ACK RF Reserved Reserved Reserved T4 TX_FDX

RW R RW RW RW RW RW RW

00 0 00001

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This register control the values transmitted by the PHY to the remote partner when advertising its

abilities

NP - Next Page

A ‘1’ indicates the PHY wishes to exchange Next Page information.

ACK - Acknowledge

It is used by the Auto-negotiation function to indicate that a device has successfully received its Link

Partner’s Link code Word.

RF - Remote Fault

When set, an advertisement frame will be sent with the corresponding bit set. This in turn will cause

the PHY receiving it to set the Remote Fault bit in its Status register

T4 - 100BASE-T4

A '1' indicates the PHY is capable of 100BASE-T4

TX_FDX - 100BASE-TX Full Duplex Capable

A '1' indicates the PHY is capable of 100BASE-TX Full Duplex

TX_HDX - 100BASE-TX Half Duplex Capable

A '1' indicates the PHY is capable of 100BASE-TX Half Duplex

10_FDX - 10BASE-T Full Duplex Capable

A '1' indicates the PHY is capable of 10BASE-T Full Duplex

10_HDX - 10BASE-T Half Duplex Capable

A '1' indicates the PHY is capable of 10BASE-T Half Duplex

The management entity sets the value of this field prior to AutoNegotiation.

‘1’ in these bit indicates that the mode of operation that corresponds to these will be acceptable to be

auto-negotiated to. Only modes supported by the PHY can be set.

CSMA

A '1' indicates the PHY is capable of 802.3 CSMA Operation

9.5 Register 5. Auto-Negotiation Remote End Capability Register

TX_HDX 10_FDX 10_HDX Reserved Reserved Reserved Reserved CSMA

RW RW RW RW RW RW RW RW

11 1 00001

NP ACK RF Reserved Reserved Reserved T4 TX_FDX

RR R RRRRR

00 0 00000

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The bit definitions are analogous to the Auto Negotiation Advertisement Register.

9.6 Register 16. Configuration 1- Structure and Bit Definition

TX_HDX 10_FDX 10_HDX Reserved Reserved Reserved Reserved CSMA

RR R RRRRR

00 0 00000

LNKDIS XMTDIS XMTPDN Reserved Reserved BYPSCR UNSCDS EQLZR

RW RW RW RW RW RW RW RW

00 0 00000

CABLE RLVL0 TLVL3 TLVL2 TLVL1 TLVL0 TRF1 TRF0

RW RW RW RW RW RW RW RW

00 1 00010

LNKDIS: Link Disable 1 = Receive Link

Detect Function

Disabled (Force Link

Pass)

0 = Normal

XMTDIS: TP Transmit 1 = TP Transmitter

Disabled

0 = Normal

XMTPDN: TP Transmit 1 = TP Transmitter

Powered Down

Powerdown 0 = Normal

RESERVED: RESERVED Reserved, Must be 0

for Proper Operation

BYPSCR:Bypass 1 = Bypass

Scrambler/Descram

bler

Scrambler/Descr- 0 = No Bypass

ambler Select

UNSCDS: Unscrambled Idle 1 = Disable

AutoNegotiation with

devices that transmit

unscrambled

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9.7 Register 17. Configuration 2 - Structure and Bit Definition

Reception Disable idle on powerup and

various instances

0 = Enables

AutoNegotiation with

devices that transmit

unscrambled idle on

powerup and various

instances

EQLZR:Receive Equalizer 1 = Receive

Equalizer Disabled,

Set To 0 Length

Select 0 = Receive

Equalizer On (For

100MB Mode Only)

CABLE Cable Type Select 1 = STP (150 Ohm)

0 = UTP (100 Ohm)

RLVL0 Receive Input 1 = Receive Squelch

Levels Reduced By

4.5 dB R/W

Level Adjust 0 = Normal

TLVL0-3 Transmit Output See Ta b l e 7 . 2

Level Adjust

TRF0-1 Transmitter 11 = -0.25nS

Rise/Fall Time 10 = +0.0nS

Adjust 01 = +0.25nS

00 = +0.50nS

Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved

RR R RRRRR

11 1 11111

Reserved Reserved APOLDIS JABDIS MREG INTMDIO Reserved Reserved

R R RW RW RW RW RW RW

00 0 00000

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9.8 Register 18. Status Output - Structure and Bit Definition

APOLDIS: Auto Polarity

Disable

1 = Auto

Polarity

Correction

Function

Disabled

1 = Auto

Polarity

Correction

Function

Disabled

0 = Normal 0 = Normal

JABDIS: Jabber Disable

Select

1 = Jabber

Disabled RW

1 = Jabber

Disabled

0 = Enabled 0 = Enabled

MREG: Multiple Register

Access Enable

1 = Multiple

Enabled

0 = No Multiple

0 = No

Multiple

Access

INTMDIO: Interrupt

Scheme Select

1 = Interrupt

Signaled With

MDIO Pulse

During Idle

1 = Interrupt

Signaled

With MDIO

Pulse During

Idle

0 = Interrupt

Not Signaled

On MDIO

0 = Interrupt

Not Signaled

On MDIO

Reserved: Reserved for

Factory Use

INT LNKFAIL LOSSSYNC CWRD SSD ESD RPOL JAB

R R/LT R/LT R/LT R/LT R/LT R/LT R/LT

00 0 000 0 0

SPDDET DPLXDET Reserved Reserved Reserved Reserved Reserved Reserved

R/LT R/LT R R R R R R

10 0 00000

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INT: Interrupt Detect 1 = Interrupt Bit(s)

Have Changed

Since Last Read

Operation.

0 = No Change

LNKFAIL: Link Fail Detect 1 = Link Not

Detected

0 = Normal

LOSSSYNC: Descrambler Loss of 1 = Descrambler

Has Lost

Synchronization

Detect

0 = Normal

CWRD: Codeword Error 1 = Invalid 4B5B

Code Detected On

Receive Data

0 = Normal

SSD: Start Of Stream Error 1 = No Start Of

Stream Delimiter

Detected on Receive

Data

0 = Normal

ESD: End Of Stream Error 1 = No End Of

Stream Delimiter

Detected on Receive

Data

0 = Normal

RPOL: Reverse Polarity

Detect

1 = Reverse Polarity

Detected

JAB: Jabber Detect 1 = Jabber Detected

0 = Normal

SPDDET: 100/10 Speed Detect 1 = Device in

100Mbps Mode

(100BASE-TX)

0 = Device in

10Mbps Mode

(10BASE-T)

DPLXDET: Duplex Detect 1 = Device In Full

Duplex

0 = Device In Half

Duplex

Reserved: Reserved Reserved for Factory

Use

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9.9 Register 19. Mask - Structure and Bit Definition

MINT MLNKFAIL MLOSSSYN MCWRD MSSD MESD MRPOL MJAB

RW RW RW RW RW RW RW RW

11 1 11111

MSPDDT MDPLDT Reserved Reserved Reserved Reserved Reserved Reserved

RW RW RW RW RW RW RW RW

11 0 00000

MINT: Interrupt Mask

Interrupt Detect

1 = Mask Interrupt

For INT In Register

0 = No Mask

MLNKFAIL: Interrupt Mask Link

Fail Detect

1 = Mask Interrupt

For LNKFAIL In

0 = No Mask

MLOSSSYN: Interrupt Mask

Descrambler Loss

1 = Mask Interrupt

For LOSSSYNC In

of Synchronization

Detect

0 = No Mask

MCWRD: Interrupt Mask

Codeword Error

1 = Mask Interrupt

For CWRD In

0 = No Mask

MSSD: Interrupt Mask Start

Of Stream Error

1 = Mask Interrupt

For SSD In Register

0 = No Mask

MESD: Interrupt Mask End Of

Stream Error

1 = Mask Interrupt

For ESD In Register

0 = No Mask

MRPOL: Interrupt Mask

Reverse Polarity

Detect

1 = Mask Interrupt

For RPOL In

0 = No Mask

MJAB: Interrupt Mask Jabber

Detect

1 = Mask Interrupt

For JAB In Register

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9.10 Register 20. Reserved - Structure and Bit Definition

Reserved:Reserved for Factory Use.

0 = No Mask

MSPDDT: Interrupt Mask 100/10

Speed Detect

1 = Mask Interrupt

For SPDDET In

0 = No Mask

MDPLDT:Interrupt Mask Duplex

Detect

1 = Mask Interrupt

For DPLXDET In

0 = No Mask

Reserved: Reserved Reserved for Factory

Use

Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved

RW RW RW RW RW RW RW RW

00 0 00000

Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved

RW RW RW RW RW RW RW RW

10 1 00000

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Chapter 10 Software Driver and Hardware Sequence

Flow

10.1 Software Driver and Hardware Sequence Flow for Power

Management

This section describes the sequence of events and the interaction between the Host Driver and the

Ethernet controller to perform power management. The Ethernet controller has the ability to reduce its

power consumption when the Device is not required to receive or transmit Ethernet Packets.

Power Management is obtained by disabling the EPH clocks, including the Clocks derived from the

Internal PHY block to reduce internal switching, this reducing current consumption.

The Host interface however, will still be accessible. As discussed in Table 10.1 and Table 10.2, the

tables describe the interaction between the EPH and Host driver allowing the Device to transition from

low power state to normal functionality and vice versa.

Table 10.1 Typical Flow Of Events For Placing Device In Low Power Mode

S/W DRIVER CONTROLLER FUNCTION

1 Disable Transmitter – Clear the TXENA bit of the

Transmit Control Register

Ethernet MAC finishes packet currently being

transmitted.

2 Remove and release all TX completion packet

numbers on the TX completion FIFO.

3 Disable Receiver – Clear the RXEN bit of the

Receive Control Register.

The receiver completes receiving the current frame, if

any, and then goes idle. Ethernet MAC will no longer

receive any packets.

4 Process all Received packets and Issue a Remove

and Release command for each respective RX

packet buffer.

RX and TX completion FIFO’s are now Empty and

all MMU packet numbers are now free.

5 Disable Interrupt sources – Clear the Interrupt

Status Register

Save Device Context – Save all Specific Register

Values set by the driver.

6 Set PDN bit in PHY MI Register 0 to 1

Note: This bit must not be set when the device is

in external PHY mode.

7 The internal PHY entered in powerdown mode, the

TP outputs are in high impedance state.

8 Write to the “EPH Power EN” Bit located in the

configuration register, Bank 1 Offset 0.

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10.2 Typical Flow of Events for Transmit (Auto Release = 0)

9 Ethernet MAC gates the RX Clock, TX clock derived

from the Internal PHY. The EPH Clock is also

disabled.

10 The Ethernet MAC is now in low power mode. The

Host may access all Runtime IO mapped registers.

All IO registers are still accessible. However, the

Host should not read or write to the registers with

the exception of:

Configuration Register

Control Register

Bank Register

Table 10.2 Flow Of Events For Restoring Device In Normal Power Mode

S/W DRIVER CONTROLLER FUNCTION

1 Write and set (1) the “EPH Power EN” Bit, located in

the configuration register, Bank 1 Offset 0.

2 Ethernet MAC Enables the RX Clock, TX clock

derived from the Internal PHY. The EPH Clock is

also enabled.

3 Write the PDN bit in PHY MI Register 0 to 0

Note: Only performed when device is in internal

PHY mode.

The PHY is then set in isolation mode (MII_DIS bit

is set). Need to clear this MII_DIS bit; and, need to

wait for 500 ms for the PHY to restore normal.

4 Internal PHY entered normal operation mode

5 Issue MMU Reset Command

6 Restore Device Register Level Context.

7 Enable Transmitter – Set the TXENA bit of the

Transmit Control Register

Ethernet MAC can now transmit Ethernet Packets.

8 Enable Receiver – Set (1) the RXEN bit of the

Receive Control Register.

Ethernet MAC is now able to receive Packets.

9 Ethernet MAC is now restored for normal operation.

S/W DRIVER MAC SIDE

1 ISSUE ALLOCATE MEMORY FOR TX - N BYTES -

the MMU attempts to allocate N bytes of RAM.

2 WAIT FOR SUCCESSFUL COMPLETION CODE -

Poll until the ALLOC INT bit is set or enable its mask

bit and wait for the interrupt. The TX packet number

is now at the Allocation Result Register.

Table 10.1 Typical Flow Of Events For Placing Device In Low Power Mode (continued)

S/W DRIVER CONTROLLER FUNCTION

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10.3 Typical Flow of Events for Transmit (Auto Release = 1)

3 LOAD TRANSMIT DATA - Copy the TX packet

number into the Packet Number Register. Write the

Pointer Register, then use a block move operation

from the upper layer transmit queue into the Data

4 ISSUE "ENQUEUE PACKET NUMBER TO TX FIFO"

- This command writes the number present in the

Packet Number Register into the TX FIFO. The

transmission is now enqueued. No further CPU

intervention is needed until a transmit interrupt is

generated.

5 The enqueued packet will be transferred to the MAC

block as a function of TXENA (nTCR) bit and of the

deferral process (1/2 duplex mode only) state.

6 Upon transmit completion the first word in memory is

written with the status word. The packet number is

moved from the TX FIFO into the TX completion

FIFO. Interrupt is generated by the TX completion

FIFO being not empty.

If a TX failure occurs on any packets, TX INT is

generated and TXENA is cleared, transmission

sequence stops. The packet number of the failure

packet is presented at the TX FIFO PORTS Register.

7 SERVICE INTERRUPT - Read Interrupt Status

Packet Number from the FIFO Ports Register. Write

the packet number into the Packet Number Register.

The corresponding status word is now readable from

memory. If status word shows successful

transmission, issue RELEASE packet number

command to free up the memory used by this packet.

Remove packet number from completion FIFO by

writing TX INT Acknowledge Register.

Option 1) Release the packet.

Option 2) Check the transmit status in the EPH

STATUS Register, write the packet number of the

current packet to the Packet Number Register, re-

enable TXENA, then go to step 4 to start the TX

sequence again.

S/W DRIVER MAC SIDE

1 ISSUE ALLOCATE MEMORY FOR TX - N BYTES -

the MMU attempts to allocate N bytes of RAM.

2 WAIT FOR SUCCESSFUL COMPLETION CODE -

Poll until the ALLOC INT bit is set or enable its mask

bit and wait for the interrupt. The TX packet number

is now at the Allocation Result Register.

3 LOAD TRANSMIT DATA - Copy the TX packet

number into the Packet Number Register. Write the

Pointer Register, then use a block move operation

from the upper layer transmit queue into the Data

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10.4 Typical Flow of Event For Receive

4 ISSUE "ENQUEUE PACKET NUMBER TO TX FIFO"

- This command writes the number present in the

Packet Number Register into the TX FIFO. The

transmission is now enqueued. No further CPU

intervention is needed until a transmit interrupt is

generated.

5 The enqueued packet will be transferred to the MAC

block as a function of TXENA (nTCR) bit and of the

deferral process (1/2 duplex mode only) state.

6 Transmit pages are released by transmit completion.

7 The MAC generates a TXEMPTY interrupt upon a

completion of a sequence of enqueued packets.

If a TX failure occurs on any packets, TX INT is

generated and TXENA is cleared, transmission

sequence stops. The packet number of the failure

packet is presented at the TX FIFO PORTS Register.

8 SERVICE INTERRUPT – Read Interrupt Status

Option 1) Release the packet.

Option 2) Check the transmit status in the EPH

STATUS Register, write the packet number of the

current packet to the Packet Number Register, re-

enable TXENA, then go to step 4 to start the TX

sequence again.

S/W DRIVER MAC SIDE

1 ENABLE RECEPTION - By setting the RXEN bit.

2 A packet is received with matching address. Memory

is requested from MMU. A packet number is

assigned to it. Additional memory is requested if

more pages are needed.

3 The internal DMA logic generates sequential

addresses and writes the receive words into memory.

The MMU does the sequential to physical address

translation. If overrun, packet is dropped and

memory is released.

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4 When the end of packet is detected, the status word

is placed at the beginning of the receive packet in

memory. Byte count is placed at the second word. If

the CRC checks correctly the packet number is

written into the RX FIFO. The RX FIFO, being not

empty, causes RCV INT (interrupt) to be set. The

RCV_BAD bit of the Bank 1 Control Register controls

whether or not to generate interrupts when bad CRC

packets are received.

5 SERVICE INTERRUPT - Read the Interrupt Status

receive packet is at receive area. (Its packet number

can be read from the FIFO Ports Register). The

software driver can process the packet by accessing

the RX area, and can move it out to system memory

if desired. When processing is complete the CPU

issues the REMOVE AND RELEASE FROM TOP OF

RX command to have the MMU free up the used

memory and packet number.

S/W DRIVER MAC SIDE

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Figure 10.1 Interrupt Service Routine

ISR

Save Bank Select & Address

Ptr Registers

Mask SMC91C111

Interrupts

Read Interrupt Register

Call TX INTR or TXEMPTY

INTR

TX INTR?

Get Next TX

RX INTR?

Yes

No Yes

Call RXINTR

ALLOC INTR?

No Yes

Write Allocated Pkt # into

Packet Number Reg.

Write Ad Ptr Reg. & Copy Data

& Source Address

Enqueue Packet

Packet

Available for

Transmission?

Yes No

Call ALLOCATE

EPH INTR?

NoYes

Call EPH INTR

Set "Ready for Packet" Flag

Return Buffers to Upper Layer

Disable Allocation Interrupt

Mask

Restore Address Pointer &

Bank Select Registers

Unmask SMC91C111

Interrupts

Exit ISR

MDINT?

Yes

Call MDINT

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Figure 10.2 RX INTR

RX INTR

Write Ad. Ptr. Reg. & Read

Word 0 from RAM

Destination

Multicast?

Read Words 2, 3, 4 from RAM

for Address Filtering

Address

Filtering Pass?

Status Word

OK?

Do Receive Lookahead

Get Copy Specs from Upper

Layer

Okay to

Copy?

Copy Data Per Upper Layer

Specs

Issue "Remove and Release"

Command

Return to ISR

Yes No

YesNo

No Yes

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Figure 10.3 TX INTR

TX Interrupt With AUTO_RELEASE = FALSE

1. Save the Packet Number Register

Saved_PNR = Read Byte (Bank 2, Offset 2)

2. Read the EPH Status Register

Temp = Read (Bank 0, Offset 2)

3. Acknowledge TX Interrupt

Write Byte (0x02, (Bank 2, Offset C));

4. Check for Status of Transmission

If ( Temp AND 0x0001)

{

//If Successful Transmission

Step 4.1.1: Issue MMU Release (Release Specific Packet)

Write (0x00A0, (Bank2, Offset 0));

Step 4.1.2: Return from the routine

}

else

{

//Transmission has FAILED

// Now we can either release or re-enqueue the packet

Step 4.2.1: Get the packet to release/re-enqueue, stored in FIFO

Temp = Read (Bank 2, Offset 4)

Temp = Temp & 0x003F

Step 4.2.2: Write to the PNR

Write (Temp, (Bank2, Offset 2))

Step 4.2.3

// Option 1: Release the packet

Write (0x00A0, (Bank2, Offset 0));

//Option 2: Re-Enqueue the packet

Write (0x00C0, (Bank2, Offset 0));

Step 4.2.4: Re-Enable Transmission

Temp = Read(Bank0, Offset 0);

Temp = Temp2 OR 0x0001

Write (Temp2, (Bank 0, Offset 0));

Step 4.2.5: Return from the routine

}

5. Restore the Packet Number Register

Write Byte (Saved_PNR, (Bank 2, Offset 2))

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Figure 10.4 TXEMPTY INTR (Assumes Auto Release Option Selected)

TXEMPTY INTR

Write Acknowledge Reg. with

TXEMPTY Bit Set

Read TXEMPTY & TX INTR

Acknowledge TXINTR

Re-Enable TXENA

Return to ISR

Issue "Release" Command

Restore Packet Number

TXEMPTY = 0

TXINT = 0

(Waiting for Completion)

TXEMPTY = X

TXINT = 1

(Transmission Failed)

TXEMPTY = 1

TXINT = 0

(Everything went through

successfully)

Read Pkt. # Register & Save

Write Address Pointer

Read Status Word from RAM

Update Statistics

Update Variables

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MEMORY PARTITIONING

Unlike other controllers, the LAN91C111 does not require a fixed memory partitioning between transmit

and receive resources. The MMU allocates and de-allocates memory upon different events. An

additional mechanism allows the CPU to prevent the receive process from starving the transmit

memory allocation.

Memory is always requested by the side that needs to write into it, that is: the CPU for transmit or the

MAC for receive. The CPU can control the number of bytes it requests for transmit but it cannot

determine the number of bytes the receive process is going to demand. Furthermore, the receive

Figure 10.5 Drive Send and Allocate Routines

ALLOCATE

Issue "Allocate Memory"

Command to MMU

Read Interrupt Status Register

Enqueue Packet

Set "Ready for Packet" Flag

Return

Copy Remaining TX Data

Packet into RAM

Return Buffers to Upper Layer

W rite A lloca ted Packet into

Packet # Register

Write Address Pointer Register

Copy Part of TX Data Packet

into RAM

Write Source Address into

Proper Location

Store Data Buffer Pointer

Clear "Ready for Packet" Flag

Enable Allocation Interrupt

Allocatio n

Passed?

Ye s N o

DRIVER SEND

Choose Bank Select

Call ALLOCATE

Exit Driver Send

Read Allocation Result

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process requests will be dependent on network traffic, in particular on the arrival of broadcast and

multicast packets that might not be for the node, and that are not subject to upper layer software flow

control.

INTERRUPT GENERATION

The interrupt strategy for the transmit and receive processes is such that it does not represent the

bottleneck in the transmit and receive queue management between the software driver and the

controller. For that purpose there is no register reading necessary before the next element in the

queue (namely transmit or receive packet) can be handled by the controller. The transmit and receive

results are placed in memory.

The receive interrupt will be generated when the receive queue (FIFO of packets) is not empty and

receive interrupts are enabled. This allows the interrupt service routine to process many receive

packets without exiting, or one at a time if the ISR just returns after processing and removing one.

There are two types of transmit interrupt strategies:

1. One interrupt per packet.

2. One interrupt per sequence of packets.

The strategy is determined by how the transmit interrupt bits and the AUTO RELEASE bit are used.

TX INT bit - Set whenever the TX completion FIFO is not empty.

TX EMPTY INT bit - Set whenever the TX FIFO is empty.

AUTO RELEASE - When set, successful transmit packets are not written into completion FIFO, and

their memory is released automatically.

1. One interrupt per packet: enable TX INT, set AUTO RELEASE=0. The software driver can find the

completion result in memory and process the interrupt one packet at a time. Depending on the

completion code the driver will take different actions. Note that the transmit process is working in

parallel and other transmissions might be taking place. The LAN91C111 is virtually queuing the

packet numbers and their status words.

In this case, the transmit interrupt service routine can find the next packet number to be serviced by

reading the TX FIFO PACKET NUMBER at the FIFO PORTS register. This eliminates the need for the

driver to keep a list of packet numbers being transmitted. The numbers are queued by the LAN91C111

and provided back to the CPU as their transmission completes.

2. One interrupt per sequence of packets: Enable TX EMPTY INT and TX INT, set AUTO

RELEASE=1. TX EMPTY INT is generated only after transmitting the last packet in the FIFO.

TX INT will be set on a fatal transmit error allowing the CPU to know that the transmit process has

stopped and therefore the FIFO will not be emptied.

This mode has the advantage of a smaller CPU overhead, and faster memory de-allocation. Note that

when AUTO RELEASE=1 the CPU is not provided with the packet numbers that completed

successfully.

Note: The pointer register is shared by any process accessing the LAN91C111 memory. In order to

allow processes to be interruptible, the interrupting process is responsible for reading the

pointer value before modifying it, saving it, and restoring it before returning from the interrupt.

Typically there would be three processes using the pointer:

1. Transmit loading (sometimes interrupt driven)

2. Receive unloading (interrupt driven)

3. Transmit Status reading (interrupt driven).

1) and 3) also share the usage of the Packet Number Register. Therefore saving and restoring the

PNR is also required from interrupt service routines.

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Figure 10.6 Interrupt Generation for Transmit, Receive, MMU

FIFO

TX COMPLETION

FIFO

CSMA/CD

LOGICAL

ADDRESS

ACKET #

MMU

PHYSICAL ADDRESS

RAM

CPU ADDRESS CSMA ADDRESS

RX PACKET

NUMBER

RX FIFO

PACKET NUMBER

PAC K # OU T

M.S. BIT ONLY

'EMPTY'

'NOT EMPTY'

TX DONE

PACKET NUMBER

'NOT EMPTY'

INTERRUPT

STATUS REGISTER

RCV

INT

TX EMPTY

INT

ALLOC

INT

TWO

OPTIONS

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Chapter 11 Board Setup Information

The following parameters are obtained from the EEPROM as board setup information:

ETHERNET INDIVIDUAL ADDRESS

I/O BASE ADDRESS

MII INTERFACE

All the above mentioned values are read from the EEPROM upon hardware reset. Except for the

INDIVIDUAL ADDRESS, the value of the IOS switches determines the offset within the EEPROM for

these parameters, in such a way that many identical boards can be plugged into the same system by

just changing the IOS jumpers.

In order to support a software utility based installation, even if the EEPROM was never programmed,

the EEPROM can be written using the LAN91C111. One of the IOS combination is associated with a

fixed default value for the key parameters (I/O BASE) that can always be used regardless of the

EEPROM based value being programmed. This value will be used if all IOS pins are left open or pulled

high.

The EEPROM is arranged as a 64 x 16 array. The specific target device is the 9346 1024-bit Serial

EEPROM. All EEPROM accesses are done in words. All EEPROM addresses in the spec are

specified as word addresses.

INDIVIDUAL ADDRESS 20-22 hex

If IOS2-IOS0 = 7, only the INDIVIDUAL ADDRESS is read from the EEPROM. Currently assigned

values are assumed for the other registers. These values are default if the EEPROM read operation

follows hardware reset.

The EEPROM SELECT bit is used to determine the type of EEPROM operation: a) normal or b)

general purpose register.

1. NORMAL EEPROM OPERATION - EEPROM SELECT bit = 0

On EEPROM read operations (after reset or after setting RELOAD high) the CONFIGURATION

IOS2-0 pins. The INDIVIDUAL ADDRESS registers are updated with the values stored in the

INDIVIDUAL ADDRESS area of the EEPROM.

On EEPROM write operations (after setting the STORE bit) the values of the CONFIGURATION

pins.

The three least significant bits of the CONTROL REGISTER (EEPROM SELECT, RELOAD and

STORE) are used to control the EEPROM. Their values are not stored nor loaded from the EEPROM.

2. GENERAL PURPOSE REGISTER - EEPROM SELECT bit = 1

On EEPROM read operations (after setting RELOAD high) the EEPROM word address defined by the

POINTER REGISTER 6 least significant bits is read into the GENERAL PURPOSE REGISTER.

On EEPROM write operations (after setting the STORE bit) the value of the GENERAL PURPOSE

significant bits.

Configuration Register

Base Register

IOS Value * 4

(IOS Value * 4) + 1

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RELOAD and STORE are set by the user to initiate read and write operations respectively. Polling the

value until read low is used to determine completion. When an EEPROM access is in progress the

STORE and RELOAD bits of CTR will readback as both bits high. No other bits of the LAN91C111 can

be read or written until the EEPROM operation completes and both bits are clear. This mechanism is

also valid for reset initiated reloads.

Note: If no EEPROM is connected to the LAN91C111, for example for some embedded applications,

the ENEEP pin should be grounded and no accesses to the EEPROM will be attempted.

Configuration, Base, and Individual Address assume their default values upon hardware reset

and the CPU is responsible for programming them for their final value.

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Figure 11.1 64 X 16 Serial EEPROM Map

CONFIGURATION REG.

BASE REG.

CONFIGURATION REG.

BASE REG.

CONFIGURATION REG.

BASE REG.

CONFIGURATION REG.

BASE REG.

CONFIGURATION REG.

BASE REG.

CONFIGURATION REG.

BASE REG.

CONFIGURATION REG.

BASE REG.

IA0-1

IA2-3

IA4-5

IOS2-0

WORD ADDRESS

000 0h

10h

11h

14h

15h

18h

19h

20h

21h

22h

001

010

011

100

101

110

XXX

16 BITS

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Chapter 12 Application Considerations

The LAN91C111 is envisioned to fit a few different bus types. This section describes the basic

guidelines, system level implications and sample configurations for the most relevant bus types. All

applications are based on buffered architectures with a private SRAM bus.

FAST ETHERNET SLAVE ADAPTER

Slave non-intelligent board implementing 100 Mbps and 10 Mbps speeds.

Adapter requires:

1. LAN91C111 chip

2. Serial EEPROM (93C46)

3. Some bus specific glue logic

Target systems:

1. VL Local Bus 32 bit systems

2. High-end ISA or non-burst EISA machines

3. EISA 32 bit slave

VL Local Bus 32 Bit Systems

On VL Local Bus and other 32 bit embedded systems the LAN91C111 is accessed as a 32 bit

peripheral in terms of the bus interface. All registers except the DATA REGISTER will be accessed

using byte or word instructions. Accesses to the DATA REGISTER could use byte, word, or dword

instructions.

Table 12.1 VL Local Bus Signal Connections

VL BUS

SIGNAL

LAN91C111

SIGNAL NOTES

A2-A15 A2-A15 Address bus used for I/O space and register decoding, latched by nADS

rising edge, and transparent on nADS low time.

M/nIO AEN Qualifies valid I/O decoding - enabled access when low. This signal is

latched by nADS rising edge and transparent on nADS low time.

W/nR W/nR Direction of access. Sampled by the LAN91C111 on first rising clock that

has nCYCLE active. High on writes, low on reads.

nRDYRTN nRDYRTN Ready return. Direct connection to VL bus.

nLRDY nSRDY and some

logic

nSRDY has the appropriate functionality and timing to create the VL

nLRDY except that nLRDY behaves like an open drain output most of

the time.

LCLK LCLK Local Bus Clock. Rising edges used for synchronous bus interface

transactions.

nRESET RESET Connected via inverter to the LAN91C111.

nBE0 nBE1

nBE2 nBE3

nBE0 nBE1 nBE2

nBE3

Byte enables. Latched transparently by nADS rising edge.

nADS nADS, nCYCLE Address Strobe is connected directly to the VL bus. nCYCLE is created

typically by using nADS delayed by one LCLK.

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IRQn INTR0 Typically uses the interrupt lines on the ISA edge connector of VL bus

D0-D31 D0-D31 32 bit data bus. The bus byte(s) used to access the device are a function

of nBE0-nBE3:

Not used = tri-state on reads, ignored on writes. Note that nBE2 and

nBE3 override the value of A1, which is tied low in this application.

nLDEV nLDEV nLDEV is a totem pole output. nLDEV is active on valid decodes of A15-

A4 and AEN=0.

UNUSED PINS

VCC nRD nWR

GND A1 nVLBUS

OPEN nDATCS

Table 12.1 VL Local Bus Signal Connections (continued)

VL BUS

SIGNAL

LAN91C111

SIGNAL NOTES

nBE0 nBE1 nBE2 nBE3

0 0 0 0 Double word access

0 0 1 1 Low word access

1 1 0 0 High word access

0 1 1 1 Byte 0 access

1 0 1 1 Byte 1 access

1 1 0 1 Byte 2 access

1 1 1 0 Byte 3 access

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HIGH-END ISA OR NON-BURST EISA MACHINES

On ISA machines, the LAN91C111 is accessed as a 16 bit peripheral. The signal connections are listed

in the following table:

Figure 12.1 LAN91C111 on VL BUS

Table 12.2 High-End ISA or Non-Burst EISA Machines Signal Connectors

ISA BUS

SIGNAL

LAN91C111

SIGNAL NOTES

A1-A15 A1-A15 Address bus used for I/O space and register decoding.

AEN AEN Qualifies valid I/O decoding - enabled access when low.

nIORD nRD I/O Read strobe - asynchronous read accesses. Address is valid before

leading edge.

W/nR

A2-A15

LCLK

AEN

RESET

INTR0

D0-D31

nRDYRTN

nBE0-nBE3

nADS

nCYCLE

nSRDY nLDEV

LAN91C111

W/nR

A2-A15

LCLK

M/nIO

nRESET

IRQn

D0-D31

nRDYRTN

nBE0-nBE3

nADS

nLRDY

nLDEV

Delay 1 LCLK

O.C.

simulated

O.C.

VLBUS

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nIOWR nWR I/O Write strobe - asynchronous write access. Address is valid before

leading edge. Data is latched on trailing edge.

IOCHRDY ARDY This signal is negated on leading nRD, nWR if necessary. It is then

asserted on CLK rising edge after the access condition is satisfied.

RESET RESET

A0 nBE0

nSBHE nBE1

IRQn INTR0

D0-D15 D0-D15 16 bit data bus. The bus byte(s) used to access the device are a function

of nBE0 and nBE1:

Not used = tri-state on reads, ignored on writes

nIOCS16 nLDEV buffered nLDEV is a totem pole output. Must be buffered using an open collector

driver. nLDEV is active on valid decodes of A15-A4 and AEN=0.

UNUSED PINS

GND nADS

VCC nBE2, nBE3,

nCYCLE, W/nR,

nRDYRTN, LCLK

No upper word access.

Table 12.2 High-End ISA or Non-Burst EISA Machines Signal Connectors (continued)

ISA BUS

SIGNAL

LAN91C111

SIGNAL NOTES

nBE0 nBE1 D0-D7 D8-D15

0 0 Lower Upper

0 1 Lower Not used

1 0 Not used Upper

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EISA 32 BIT SLAVE

On EISA the LAN91C111 is accessed as a 32 bit I/O slave, along with a Slave DMA type "C" data

path option. As an I/O slave, the LAN91C111 uses asynchronous accesses. In creating nRD and nWR

inputs, the timing information is externally derived from nCMD edges. Given that the access will be at

least 1.5 to 2 clocks (more than 180ns at least) there is no need to negate EXRDY, simplifying the

EISA interface implementation. As a DMA Slave, the LAN91C111 accepts burst transfers and is able

to sustain the peak rate of one doubleword every BCLK. Doubleword alignment is assumed for DMA

transfers. The LAN91C111 will sample EXRDY and postpone DMA cycles if the memory cycle solicits

wait states.

Figure 12.2 LAN91C111 on ISA BUS

Table 12.3 EISA 32 Bit Slave Signal Connections

EISA BUS

SIGNAL

LAN91C111

SIGNAL NOTES

LA2-LA15 A2-A15 Address bus used for I/O space and register decoding, latched by

nADS (nSTART) trailing edge.

M/nIO

AEN

AEN Qualifies valid I/O decoding - enabled access when low. These

signals are externally ORed. Internally the AEN pin is latched by

nADS rising edge and transparent while nADS is low.

A1-A15, AEN

RESET

nBE2, nBE3

D0-D15

INTR0

nRD

nWR

nBE0

nBE1

nLDEV

LAN91C111

A1-A15, AEN

RESET

VCC

D0-D15

IRQ

nIORD

nIOWR

nSBHE

nIOCS16

O.C.

ISA BUS

10/100 Non-PCI Ethernet Single Chip MAC + PHY

Datasheet

Revision 1.92 (06-27-11) 108 SMSC LAN91C111 REV C

DATASHEET

Latched W-R

combined with

nCMD

nRD I/O Read strobe - asynchronous read accesses. Address is valid

before its leading edge. Must not be active during DMA bursts if

DMA is supported.

Latched W-R

combined with

nCMD

nWR I/O Write strobe - asynchronous write access. Address is valid

before leading edge . Data latched on trailing edge. Must not be

active during DMA bursts if DMA is supported.

nSTART nADS Address strobe is connected to EISA nSTART.

RESDRV RESET

nBE0 nBE1 nBE2

nBE3

nBE0 n BE1 nBE2

nBE3

Byte enables. Latched on nADS rising edge.

IRQn INTR0 Interrupts used as active high edge triggered

D0-D31 D0-D31 32 bit data bus. The bus byte(s) used to access the device are a

function of nBE0-nBE3:

Not used = tri-state on reads, ignored on writes. Note that nBE2 and

nBE3 override the value of A1, which is tied low in this application.

Other combinations of nBE are not supported by the LAN91C111.

Software drivers are not anticipated to generate them.

nEX32

nNOWS

(optional additional

logic)

nLDEV nLDEV is a totem pole output. nLDEV is active on valid decodes of

LAN91C111 pins A15-A4, and AEN=0. nNOWS is similar to nLDEV

except that it should go inactive on nSTART rising. nNOWS can be

used to request compressed cycles (1.5 BCLK long, nRD/nWR will

be 1/2 BCLK wide).

THE FOLLOWING SIGNALS SUPPORT SLAVE DMA TYPE "C" BURST CYCLES

BCLK LCLK EISA Bus Clock. Data transfer clock for DMA bursts.

nDAK<n> nDATACS DMA Acknowledge. Active during Slave DMA cycles. Used by the

LAN91C111 as nDATACS direct access to data path.

nIORC W/nR Indicates the direction and timing of the DMA cycles. High during

LAN91C111 writes, low during LAN91C111 reads.

nIOWC nCYCLE Indicates slave DMA writes.

nEXRDY nRDYRTN EISA bus signal indicating whether a slave DMA cycle will take place

on the next BCLK rising edge, or should be postponed. nRDYRTN

is used as an input in the slave DMA mode to bring in EXRDY.

UNUSED PINS

Table 12.3 EISA 32 Bit Slave Signal Connections (continued)

EISA BUS

SIGNAL

LAN91C111

SIGNAL NOTES

nBE0 nBE1 nBE2 nBE3

0 0 0 0 Double word access

0 0 1 1 Low word access

1 1 0 0 High word access

0 1 1 1 Byte 0 access

1 0 1 1 Byte 1 access

1 1 0 1 Byte 2 access

1 1 1 0 Byte 3 access

10/100 Non-PCI Ethernet Single Chip MAC + PHY

Datasheet

SMSC LAN91C111 REV C 109 Revision 1.92 (06-27-11)

DATASHEET

VCC nVLBUS

GND A1

Figure 12.3 LAN91C111 on EISA BUS

Table 12.3 EISA 32 Bit Slave Signal Connections (continued)

EISA BUS

SIGNAL

LAN91C111

SIGNAL NOTES

A2-A15

RESET

AEN

INTR0

nRD

nWR

LCLK

nADS

nLDEV

LAN91C111

LA2- LA15

RESET

O.C.

EISA BUS

AEN

M/nIO

D0-D31

IRQn

nBE[0:3]

LATCH

gates

nCMD

nWR

BCLK

nSTART

nEX32

nBE[0:3]

D0-D31

10/100 Non-PCI Ethernet Single Chip MAC + PHY

Datasheet

Revision 1.92 (06-27-11) 110 SMSC LAN91C111 REV C

DATASHEET

Chapter 13 Operational Description

13.1 Maximum Guaranteed Ratings*

*Stresses above those listed above could cause permanent damage to the device. This is a stress

rating only and functional operation of the device at any other condition above those indicated in the

operation sections of this specification is not implied.

Note: When powering this device from laboratory or system power supplies, it is important that the

Absolute Maximum Ratings not be exceeded or device failure can result. Some power supplies

exhibit voltage spikes on their outputs when the AC power is switched on or off. In addition,

voltage transients on the AC power line may appear on the DC output. If this possibility exists,

it is suggested that a clamp circuit be used.

13.2 DC Electrical Characteristics

(VCC = +3.3.0 V ± 10%)

Operating Temperature Range 0°C to +70°C for LAN91C111 (-40°C to 85°C for

LAN91C111I)

Storage Temperature Range -55C° to + 150°C

Lead Temperature Range (soldering, 10

seconds)

+325°C

Positive Voltage on any pin, with respect to

Ground

VCC + 0.3V

Negative Voltage on any pin, with respect to

Ground

-0.3V

Maximum VCC +5V

PARAMETER SYMBOL MIN TYP MAX UNITS COMMENTS

I Type Input Buffer

Low Input Level

High Input Level

VILI

VIHI 2.0

0.8 V

TTL Levels

IS Type Input Buffer

Low Input Level

High Input Level

Schmitt Trigger Hysteresis

VILIS

VIHIS

VHYS

2.2

250

0.8 V

Schmitt Trigger

ICLK Input Buffer

Low Input Level

High Input Level

VILCK

VIHCK 2.2

0.8 V

10/100 Non-PCI Ethernet Single Chip MAC + PHY

Datasheet

SMSC LAN91C111 REV C 111 Revision 1.92 (06-27-11)

DATASHEET

Input Leakage

(All I and IS buffers except

pins with

pullups/pulldowns)

Low Input Leakage

High Input Leakage

IIL

IIH

-10

+10

µA

VIN = 0

VIN = VCC

IP Type Buffers

Input Current IIL -110 -45 μAV

IN = 0

ID Type Buffers

Input Current IIH +45 +110 μAV

IN = VCC

O4 Type Buffer

Low Output Level

High Output Level

Output Leakage

VOL

VOH

IOL

2.4

-10

0.4

+10

µA

IOL = 6 mA

IOH = -4 mA

VIN = 0 to VCC

I/O4 Type Buffer

Low Output Level

High Output Level

Output Leakage

VOL

VOH

IOL

2.4

-10

0.4

+10

µA

IOL = 6 mA

IOH = -4 mA

VIN = 0 to VCC

O12 Type Buffer

Low Output Level

High Output Level

Output Leakage

VOL

VOH

IOL

2.4

-10

0.4

+10

µA

IOL = 20 mA

IOH = -10 mA

VIN = 0 to VCC

O16 Type Buffer

Low Output Level

High Output Level

Output Leakage

VOL

VOH

IOL

2.4

-10

0.4

+10

µA

IOL = 35 mA

IOH = -15 mA

VIN = 0 to VCC

O24 Type Buffer

Low Output Level

High Output Level

Output Leakage

VOL

VOH

IOL

2.4

-10

0.4

+10

µA

IOL = 35 mA

IOH = -15 mA

VIN = 0 to VCC

PARAMETER SYMBOL MIN TYP MAX UNITS COMMENTS

10/100 Non-PCI Ethernet Single Chip MAC + PHY

Datasheet

Revision 1.92 (06-27-11) 112 SMSC LAN91C111 REV C

DATASHEET

CAPACITANCE TA = 25°C; fc = 1MHz; VCC = 3.3V

CAPACITIVE LOAD ON OUTPUTS

I/O24 Type Buffer

Low Output Level

High Output Level

Output Leakage

VOL

VOH

IOL

2.4

-10

0.4

+10

µA

IOL = 35 mA

IOH = -15 mA

VIN = 0 to VCC

I/OD Type Buffer

Low Output Level

High Output Level

Output Leakage

VOL

VOH

IOL

2.4

-10

0.4

+10

µA

IOL = 4 mA

VIN = 0 to VCC

Supply Current Active

ICC 100 140 mA

Dynamic Current

(Assuming internal PHY is

used)

Powerdown Supply Current IPDN 15 38 mA Internal PHY in

Powerdown mode

14 36 mA Internal MAC+PHY in

Powerdown mode

LIMITS

PARAMETER SYMBOL MIN TYP MAX UNIT TEST CONDITION

Clock Input Capacitance CIN 20 pF All pins except pin

under test tied to

AC ground

Input Capacitance CIN 10 pF

Output Capacitance COUT 20 pF

ARDY, D0-D31 (non VLBUS) 45 pF

D0-D31 in VLBUS 45 pF

All other outputs 45 pF

PARAMETER SYMBOL MIN TYP MAX UNITS COMMENTS

10/100 Non-PCI Ethernet Single Chip MAC + PHY

Datasheet

SMSC LAN91C111 REV C 113 Revision 1.92 (06-27-11)

DATASHEET

13.3 Twisted Pair Characteristics, Transmit

VDD = 3.3v +/- 5%

RBIAS = 11K +/- 1 %, no load

SYM PARAMETER

LIMIT

UNIT CONDITIONS

MIN TYP MAX

ov TP Differential Output

Voltage

0.950 1.000 1.050 Vpk 100 Mbps, UTP Mode,

100 Ohm Load

1.165 1.225 1.285 Vpk 100 Mbps, STP Mode,

150 Ohm Load

2.2 2.5 2.8 Vpk 10 Mbps, UTP Mode,

100 Ohm Load

2.694 3.062 3.429 Vpk 10 Mbps, STP Mode,

150 Ohm Load

ovs TP Differential Output

Voltage Symmetry

98 102 % 100 Mbps, Ratio of Positive And

Negative Amplitude Peaks on TPO±

TORF TP Differential Output

Rise And Fall Time

3.0 5.0 nS 100 Mbps

TRFADJ [1:0] = 10

TORFS TP Differential Output

Rise And Fall Time

Symmetry

+/-0.5 nS 100 Mbps, Difference Between Rise

and Fall Times on TPO±

oDC TP Differential Output

Duty Cycle Distortion

+/-

0.25

nS 100 Mbps, Output Data=0101... NRZ

Pattern Unscrambled, Measure At

50% Points

oJ TP Differential Output

Jitter

+/-1.4 nS 100 Mbps, Output Data=scrambled /H/

oo TP Differential Output

Overshoot

5.0 % 100 Mbps

TOVT TP Differential Output

Voltage Template

See Figure 7.4 10 Mbps

SOI TP Differential Output

SOI Voltage

Template

See Figure 7.6 10 Mbps

TLPT TP Differential Output

Link Pulse Voltage

Template

See Figure 7.7 10 Mbps, NLP and FLP

OIV TP Differential Output

Idle Voltage

+/-50 mV 10 Mbps.

OIA TP Output Current 38 40 42 mA pk 100 Mbps, UTP with TLVL[3:0]=1000

31.06 32.66 34.26 mA pk 100 Mbps, STP with TLVL[3:0]=1000

88 100 112 mA pk 10 Mbps, UTP with TLVL[3:0]=1000

71.86 81.64 91.44 mA pk 10 Mbps, STP with TLVL[3:0]=1000

10/100 Non-PCI Ethernet Single Chip MAC + PHY

Datasheet

Revision 1.92 (06-27-11) 114 SMSC LAN91C111 REV C

DATASHEET

13.4 Twisted Pair Characteristics, Receive

Unless otherwise noted, all test conditions are as follows:

Vcc = 3.3V +/-5%

RBIAS = 11K +/- 1 %, no load

62.5/10 Mhz Square Wave on TP inputs in 100/10 Mbps

OIR TP Output Current

Adjustment Range

0.80 1.2 VDD = 3.3V, Adjustable with RBIAS,

relative to TOIA with RBIAS=11K

0.86 1.16 VDD = 3.3V, Adjustable with LVL[3:0]

Relative to Value at TLVL[3:0]=1000

ORA TP Output Current

TLVL Step Accuracy

+/-50 % Relative to Ideal Values in Table 3.

Table 3 Values Relative to Output with

TLVL[3:0]=1000.

OR TP Output

Resistance

10K Ohm

OC TP Output

Capacitance

15 pF

SYM PARAMETER

LIMIT

UNIT CONDITIONS

MIN TYP MAX

RST TP Input Squelch

Threshold

166 500 mV pk 100 Mbps, RLVL=0

310 540 mV pk 10 Mbps, RLVL=0

60 200 mV pk 100 Mbps, RLVL=1

186 324 mV pk 10 Mbps, RLVL=1

RUT TP Input Unsquelch

Threshold

100 300 mV pk 100 Mbps, RLVL=0

186 324 mV pk 10 Mbps, RLVL=0

20 90 mV pk 100 Mbps, RLVL=1

112 194 mV pk 10 Mbps, RLVL=1

TP Input Open Circuit

Voltage

VDD- 2.4

± 0.2

Volt Voltage on Either TPI+ or TPI- with

Respect to GND.

RCMR TP Input Common

Mode Voltage Range

ROCV

± 0.25

Volt Voltage on TPI± with Respect to

GND.

RDR TP Input Differential

Voltage Range

VDD Volt

RIR TP Input Resistance 5K Ohm

RIC TP Input Capacitance 10 pF

SYM PARAMETER

LIMIT

UNIT CONDITIONS

MIN TYP MAX

10/100 Non-PCI Ethernet Single Chip MAC + PHY

Datasheet

SMSC LAN91C111 REV C 115 Revision 1.92 (06-27-11)

DATASHEET

Chapter 14 Timing Diagrams

Figure 14.1 Asynchronous Cycle - nADS=0

PARAMETER MIN TYP MAX UNITS

t1 A1-A15, AEN, nBE[3:0] Valid to nRD, nWR Active 2 ns

t2 A1-A15, AEN, nBE[3:0] Hold After nRD, nWR Inactive (Assuming

nADS Tied Low)

5ns

t3 nRD Low to Valid Data 15 ns

t4 nRD High to Data Invalid 2 15 ns

t5 Data Setup to nWR Inactive 10 ns

t5A Data Hold After nWR Inactive 5 ns

t6 nRD Strobe Width 15 ns

t5A

t5t1

t4t3

t6t6

Valid

Address, AEN, nBE[3:0]

nADS

Read Data

nRD, nWR

Write Data

10/100 Non-PCI Ethernet Single Chip MAC + PHY

Datasheet

Revision 1.92 (06-27-11) 116 SMSC LAN91C111 REV C

DATASHEET

Figure 14.2 Asynchronous Cycle - Using nADS

PARAMETER MIN TYP MAX UNITS

t1 A1-A15, AEN, nBE[3:0] Valid to nRD, nWR Active 2 ns

t3 nRD Low to Valid Data 15 ns

t4 nRD High to Data Invalid 2 15 ns

t5 Data Setup to nWR Inactive 10 ns

t5A Data Hold After nWR Inactive 5 ns

t6 nRD Strobe Width 15 ns

t8 A1-A15, AEN, nBE[3:0] Setup to nADS Rising 8 ns

t9 A1-A15, AEN, nBE[3:0] Hold after nADS Rising 5 ns

t5A

t5t1

t4t3

valid

0ns 50ns 100ns 150ns 200ns

250

ddr,AEN,nBE[1:0]

nADS

Read Data

nRD,nWR

Write Data

Asynchronous Cycle -- Using nADS

10/100 Non-PCI Ethernet Single Chip MAC + PHY

Datasheet

SMSC LAN91C111 REV C 117 Revision 1.92 (06-27-11)

DATASHEET

Figure 14.3 Asynchronous Cycle - nADS=0

PARAMETER MIN TYP MAX UNITS

t1A nDATACS Setup to nRD, nWR Active 2 ns

t2 nDATACS Hold After nRD, nWR Inactive (Assuming nADS Tied

Low)

5ns

t3A nRD Low to Valid Data 30 ns

t4 nRD High to Data Invalid 2 15 ns

t5 Data Setup to nWR Inactive 10 ns

t5A Data Hold After nWR Inactive 5 ns

t6A nRD Strobe Width 30 ns

Figure 14.4 Asynchronous Ready

t5A

t6A

t1A

t4t3A

valid

D0~D31 valid

0ns 50ns 100ns 150ns 200ns

250

nDATACS

Read Data

nRD,nWR

Write Data

Asynchronous Cycle - nADS=0

t26A t13

t26t26

Valid Data

Valid Address Valid Address

Valid

Address, AEN, nBE[3:0]

nRD, nWR

ARDY

Data

10/100 Non-PCI Ethernet Single Chip MAC + PHY

Datasheet

Revision 1.92 (06-27-11) 118 SMSC LAN91C111 REV C

DATASHEET

PARAMETER MIN TYP MAX UNITS

t26 ARDY Low Pulse Width 100 150 ns

t26A Control Active to ARDY Low 10 ns

t13 Valid Data to ARDY High 10 ns

Figure 14.5 Burst Write Cycles - nVLBUS=1

PARAMETER MIN TYP MAX UNITS

t12 nDATACS Setup to LCLK Rising 20 ns

t12A nDATACS Hold After LCLK Rising 0 ns

t14 nRDYRTN Setup to LCLK Falling 10 ns

t15 nRDYRTN Hold after LCLK Falling 10 ns

t17 W/nR Setup to LCLK Falling 15 ns

t17A W/nR Hold After LCLK Falling 3 ns

t18 Data Setup to LCLK Rising (Write) 15 ns

t20 Data Hold from LCLK Rising (Write) 4 ns

t15

t20t20t20

t22A

t17A

t12A

t18t14t18

t12

t22t17

ab c

Clock

nDATACS

W/nR

nCYCLE

Write Data

nRDYRTN

10/100 Non-PCI Ethernet Single Chip MAC + PHY

Datasheet

SMSC LAN91C111 REV C 119 Revision 1.92 (06-27-11)

DATASHEET

t22 nCYCLE Setup to LCLK Rising 5 ns

t22A nCYCLE Hold After LCLK Rising 10 ns

Figure 14.6 Burst Read Cycles - nVLBUS=1

PARAMETER MIN TYP MAX UNITS

t12 nDATACS Setup to LCLK Rising 20 ns

t12A nDATACS Hold after LCLK Rising 0 ns

t14 nRDYRTN Setup to LCLK Falling 10 ns

t15 nRDYRTN Hold after LCLK Falling 10 ns

t17 W/nR Setup to LCLK Falling 15 ns

t17A W/nR Hold After LCLK Falling 3 ns

t19 Data Delay from LCLK Rising (Read) 5 15 ns

PARAMETER MIN TYP MAX UNITS

t15

t19t19

t17A

t12A

t14t12t17

abc

Clock

nDATACS

W/nR

nCYCLE

Read Data

nRDYRTN

10/100 Non-PCI Ethernet Single Chip MAC + PHY

Datasheet

Revision 1.92 (06-27-11) 120 SMSC LAN91C111 REV C

DATASHEET

Figure 14.7 Address Latching for All Modes

PARAMETER MIN TYP MAX UNITS

t8 A1-A15, AEN, nBE[3:0] Setup to nADS Rising 8 ns

t9 A1-A15, AEN, nBE[3:0] Hold After nADS Rising 5 ns

t25 A4-A15, AEN to nLDEV Delay 30 ns

Figure 14.8 Synchronous Write Cycle - nVLBUS=0

t25

Valid

nADS

Address, AEN, nBE[3:0]

nLDEV

t21t21

t11

t17A

t16

t20

t18

t10

Valid

Clock

Address, AEN, nBE[3:0]

nADS

W/nR

nCYCLE

Write Data

nSRDY

10/100 Non-PCI Ethernet Single Chip MAC + PHY

Datasheet

SMSC LAN91C111 REV C 121 Revision 1.92 (06-27-11)

DATASHEET

PARAMETER MIN TYP MAX UNITS

t8 A1-A15, AEN, nBE[3:0] Setup to nADS Rising 8 ns

t9 A1-A15, AEN, nBE[3:0] Hold After nADS Rising 5 ns

t10 nCYCLE Setup to LCLK Rising 5 ns

t11 nCYCLE Hold after LCLK Rising (Non-Burst Mode) 3 ns

t16 W/nR Setup to nCYCLE Active 0 ns

t17A W/nR Hold after LCLK Rising with nSRDY Active 3 ns

t18 Data Setup to LCLK Rising (Write) 15 ns

t20 Data Hold from LCLK Rising (Write) 4 ns

t21 nSRDY Delay from LCLK Rising 7 ns

Figure 14.9 Synchronous Read Cycle - nVLBUS=0

t21t21

t11

t16

t23

t24

t20

t10

Valid

Clock

Address, AEN, nBE[3:0]

nADS

W/nR

nCYCLE

Read Data

nSRDY

nRDYRTN

10/100 Non-PCI Ethernet Single Chip MAC + PHY

Datasheet

Revision 1.92 (06-27-11) 122 SMSC LAN91C111 REV C

DATASHEET

PARAMETER MIN TYP MAX UNITS

t8 A1-A15, AEN, nBE[3:0] Setup to nADS Rising 8 ns

t9 A1-A15, AEN, nBE[3:0] Hold After nADS Rising 5 ns

t10 nCYCLE Setup to LCLK Rising 5 ns

t11 nCYCLE Hold after LCLK Rising (Non-Burst Mode) 3 ns

t16 W/nR Setup to nCYCLE Active 0 ns

t20 Data Hold from LCLK Rising (Read) 4 ns

t21 nSRDY Delay from LCLK Rising 7 ns

t23 nRDYRTN Setup to LCLK Rising 3 ns

t24 nRDYRTN Hold after LCLK Rising 3 ns

Figure 14.10 MII Timing

PARAMETER MIN TYP MAX UNITS

t27 TXD0-TXD3, TXEN100 Delay from TX25 Rising 0 15 ns

t28 RXD0-RXD3, RX_DV, RX_ER Setup to RX25 Rising 10 ns

t29 RXD0-RXD3, RX_DV, RX_ER Hold After RX25 Rising 10 ns

t28

t28 t28

t27

t29

TXD0-TXD3

TXEN100

RXD0-RXD3

RX25

RX_DV

RX_ER

10/100 Non-PCI Ethernet Single Chip MAC + PHY

Datasheet

SMSC LAN91C111 REV C 123 Revision 1.92 (06-27-11)

DATASHEET

AC TEST TIMING CONDITIONS

Unless otherwise noted, all test conditions are as follows:

1. VDD = 3.3V +/-5%

2. RBIAS = 11K +/- 1%, no load

3. Measurement Points:

4. TPO±, TPI±: 0.0 V During Data, ±0.3V at start/end of packet

5. All other inputs and outputs: 1.4 Volts

Table 14.1 Transmit Timing Characteristics

SYM PARAMETER

LIMIT

UNIT CONDITIONS

MIN TYP MAX

t30 Transmit Propagation Delay 60 140 nS 100Mbps

600 nS 10Mbps

t31 Transmit Output Jitter ±0.7 nS pk-pk 100Mbps

±5.5 nS pk-pk 10Mbps

t32 Transmit SOI Pulse Width to

0.3V

250 nS 10Mbps

t33 Transmit SOI Pulse Width to

40mV

4500 nS 10Mbps

t34 LEDn Delay Time 25 mS

t35 LEDn Pulse Width 80 105 mS

Figure 14.11 Transmit Timing

LEDn

TPO±

t34

t30

t35

SOI

t31

TXEN Bit is Set

t33

t32

PREAMBLE PREAMBLE DATADATA

TPO±

t30

/J/K/ IDLE/T/R/

t31

DATAIDLEIDLE

FXO±

100Mbps

10Mbps

10/100 Non-PCI Ethernet Single Chip MAC + PHY

Datasheet

Revision 1.92 (06-27-11) 124 SMSC LAN91C111 REV C

DATASHEET

Table 14.2 Receive Timing Characteristics

SYM PARAMETER

LIMIT

UNIT CONDITIONS

MIN TYP MAX

t36 Receive Input Jitter ±3.0 nS pk-pk 100Mbps

±13.5 nS pk-pk 10Mbps

t37 SOI Pulse Minimum Width

Required for Idle Detection

125 200 nS 10Mbps

Measure TPI± from last zero

cross to 0.3V point

Figure 14.12 Receive Timing, End of Packet - 10 MBPS

Table 14.3 Collision and Jam Timing Characteristics

SYM PARAMETER

LIMIT

UNIT CONDITIONS

MIN TYP MAX

t38 Rcv Packet Start to COL

Assert Time

200 nS 100Mbps

700 nS 10Mbps

300 nS 10Mbps

t39 Xmt Packet Start to COL

Assert Time

200 nS 100Mbps

700 nS 10Mbps

t40 Start of Packet to Transmit

JAM Packet Start During JAM

500 nS 100Mbps

1500 nS 10Mbps

t41 Xmt Packet Start to COL

Assert Time

200 nS 100Mbps

700 nS 10Mbps

TPI±

DATA DATADATADATADATA

t37

SOI

t36

10/100 Non-PCI Ethernet Single Chip MAC + PHY

Datasheet

SMSC LAN91C111 REV C 125 Revision 1.92 (06-27-11)

DATASHEET

Figure 14.13 Collision Timing, Receive

t34

LEDn

t35

t34 t35

LEDn

TPI± I

TPO± I DATA DATADATADATADATADATA DATADATADATADATADATA

IKJII DATA IIRTDATADATA DATA

DATADATA

t38

MII 100 Mbps

MII 10 Mbps

TPI±

TPO±

t38

Collision Observed

by Physical Layer

Collision Observed

by Physical Layer

10/100 Non-PCI Ethernet Single Chip MAC + PHY

Datasheet

Revision 1.92 (06-27-11) 126 SMSC LAN91C111 REV C

DATASHEET

Figure 14.14 Collision Timing, Transmit

t34 t35

LEDn

TPO± I

TPI± I DATA DATADATADATADATADATA DATADATADATADATADATA

IKJII DATA IIRTDATADATA DATA

DATADATA

t39

MII 100 Mbps

MII 10 Mbps

TPO±

TPI±

t39

Collision Observed

by Physical Layer

Collision Observed

by Physical Layer

10/100 Non-PCI Ethernet Single Chip MAC + PHY

Datasheet

SMSC LAN91C111 REV C 127 Revision 1.92 (06-27-11)

DATASHEET

Figure 14.15 Jam Timing

t41

t40

MII 100 Mbps

MII 10 Mbps

TPI±

TPO± II DATA DATADATA DATAKJ DATA DATA

TPO± II JAM IIRJAMJAMK JAMIIIJ T I

DATA DATADATA DATA DATA DATA

JAMJAMJAM JAM

t40

TPO±

Collision Observed

by Physical Layer

10/100 Non-PCI Ethernet Single Chip MAC + PHY

Datasheet

Revision 1.92 (06-27-11) 128 SMSC LAN91C111 REV C

DATASHEET

Table 14.4 Link Pulse Timing Characteristics

SYM PARAMETER

LIMIT UNIT CONDITIONS

MIN TYP MAX

t42 NLP Transmit Link Pulse Width See Figure 7.8 nS

t43 NLP Transmit Link Pulse Period 8 24 mS

t44 NLP Receive Link Pulse Width Required

For Detection

50 nS

t45 NLP Receive Link Pulse Minimum Period

Required For Detection

6 7 mS link_test_min

t46 NLP Receive Link Pulse Maximum

Period Required For Detection

50 150 mS link_test_max

t47 NLP Receive Link Pulse Required To

Exit Link Fail State

333Link

Pulses

lc_max

t48 FLP Transmit Link Pulse Width 100 150 nS

t49 FLP Transmit Clock Pulse to Data Pulse

Period

55.5 62.5 69.5 μS interval_timer

t50 FLP Transmit Clock Pulse to Clock Pulse

Period

111 125 139 μS

t51 FLP Transmit Link Pulse Burst Period 8 22 mS transmit_link_burst_time

t52 FLP Receive Link Pulse Width Required

For Detection

50 nS

t53 FLP Receive Link Pulse Minimum Period

Required For Clock Pulse Detection

525μS flp_test_min_timer

t54 FLP Receive Link Pulse Maximum

Period Required For Clock Pulse

Detection

165 185 μS flp_test_max_timer

t55 FLP Receive Link Pulse Minimum Period

Required For Data Pulse Detection

15 47 μS data_detect_min_timer

t56 FLP Receive Link Pulse Maximum

Period Required For Data Pulse

Detection

78 100 μS data_detect_max_timer

t57 FLP Receive Link Pulse Burst Minimum

Period Required For Detection

5 7 mS nlp_test_min_timer

t58 FLP Receive Link Pulse Burst Maximum

Period Required For Detection

50 150 mS nlp_test_max_timer

t59 FLP Receive Link Pulses Bursts

Required To Detect AutoNegotiation

Capability

333Link

Pulses

10/100 Non-PCI Ethernet Single Chip MAC + PHY

Datasheet

SMSC LAN91C111 REV C 129 Revision 1.92 (06-27-11)

DATASHEET

Figure 14.16 Link Pulse Timing

TPO±

t42

a.) Transmit NLP

t43

TPI±

t44

b.) Receive NLP

t45

t47

t46

LEDn

10/100 Non-PCI Ethernet Single Chip MAC + PHY

Datasheet

Revision 1.92 (06-27-11) 130 SMSC LAN91C111 REV C

DATASHEET

Figure 14.17 FLP Link Pulse Timing

TPO±

t48

a.) Transmit FLP and Transmit FLP Burst

t49

TPI±

t52

b.) Receive FLP

t54

TPI±

CLK DATACLKDATA DATACLKCLK

t51

CLK DATA DATACLK

t53

31.25 62.5 93.75 125 156.25

t55

t56

c.) Receive FLP Burst

LEDn

t57 t58

t59

t50

10/100 Non-PCI Ethernet Single Chip MAC + PHY

Datasheet

SMSC LAN91C111 REV C 131 Revision 1.92 (06-27-11)

DATASHEET

Chapter 15 Package Outlines

Notes:

1. Controlling Unit: millimeter

2. Tolerance on the position of the leads is ± 0.035 mm maximum

3. Package body dimensions D1 and E1 do not include the mold protrusion.

Maximum mold protrusion is 0.25 mm

4. Dimension for foot length L measured at the gauge plane 0.25 mm above the seating plane is 0.78-1.08 mm.

5. Details of pin 1 identifier are optional but must be located within the zone indicated.

6. Shoulder widths must conform to JEDEC MS-026 dimension 'S' of a minimum of 0.20mm.

Figure 15.1 128 Pin TQFP Package Outline, 14X14X1.0 Body

Table 15.1 128 Pin TQFP Package Parameters

MIN NOMINAL MAX REMARK

A ~ ~ 1.20 Overall Package Height

A1 0.05 ~ 0.15 Standoff

A2 0.95 1.00 1.05 Body Thickness

D 15.80 16.00 16.20 X Span

D/2 7.90 8.00 8.10 1/2 X Span Measure from Centerline

D1 13.80 14.00 14.20 X body Size

E 15.80 16.00 16.20 Y Span

E/2 7.90 8.00 8.10 1/2 Y Span Measure from Centerline

E1 13.80 14.00 14.20 Y body Size

H 0.09 ~ 0.20 Lead Frame Thickness

L 0.45 0.60 0.75 Lead Foot Length from Centerline

L1 ~ 1.00 ~ Lead Length

e 0.40 Basic Lead Pitch

o~7

oLead Foot Angle

W 0.13 0.18 0.23 Lead Width

R1 0.08 ~ ~ Lead Shoulder Radius

R2 0.08 ~ 0.20 Lead Foot Radius

ccc ~ ~ 0.0762 Coplanarity (Assemblers)

ccc ~ ~ 0.08 Coplanarity (Test House)

10/100 Non-PCI Ethernet Single Chip MAC + PHY

Datasheet

Revision 1.92 (06-27-11) 132 SMSC LAN91C111 REV C

DATASHEET

Notes:

1. Controlling Unit: millimeter

2. Tolerance on the position of the leads is + 0.04 mm maximum.

3. Package body dimensions D1 and E1 do not include the mold protrusion.

Maximum mold protrusion is 0.25 mm.

4. Dimension for foot length L measured at the gauge plane 0.25 mm above the seating plane.

5. Details of pin 1 identifier are optional but must be located within the zone indicated.

Figure 15.2 128 Pin QFP Package Outline, 3.9 MM Footprint

Table 15.2 128 Pin QFP Package Parameters

MIN NOMINAL MAX REMARKS

A ~ ~ 3.4 Overall Package Height

A1 0.05 ~ 0.5 Standoff

A2 2.55 ~ 3.05 Body Thickness

D 23.70 23.90 24.10 X Span

D/2 11.85 11.95 12.05 1/2 X Span Measured from Centerline

D1 19.90 20.0 20.10 X body Size

E 17.70 17.90 18.10 Y Span

E/2 8.85 8.95 9.05 1/2 Y Span Measured from Centerline

E1 13.90 14.00 14.10 Y body Size

H ~ ~ ~ Lead Frame Thickness

L 0.73 0.88 1.03 Lead Foot Length

L1 ~ 1.95 ~ Lead Length

e 0.5 Basic Lead Pitch

o~7

oLead Foot Angle

W 0.10 ~ 0.30 Lead Width

R1 0.13 ~ ~ Lead Shoulder Radius

R2 0.13 ~ 0.30 Lead Foot Radius

ccc ~ ~ 0.0762 Coplanarity (Assemblers)

ccc ~ ~ 0.08 Coplanarity (Test House)

10/100 Non-PCI Ethernet Single Chip MAC + PHY

Datasheet

SMSC LAN91C111 REV C 133 Revision 1.92 (06-27-11)

DATASHEET

Chapter 16 Datasheet Revision History

Table 16.1 Customer Revision History

REVISION LEVEL & DATE SECTION/FIGURE/ENTRY CORRECTION

Rev. 1.92

(06-27-11)

Section 7.7.17, "PHY

Powerdown," on page 41

Added note stating that the PDN bit must not be

set when the device is in external PHY mode.

Rev. 1.92

(04-27-11)

Table 10.1, “Typical Flow Of

Events For Placing Device

In Low Power Mode,” on

page 88

Added note to step 6 stating that the bit (PDN)

must not be set when the device is in external PHY

mode.

Rev. 1.92

(04-27-11)

Table 10.2, “Flow Of Events

For Restoring Device In

Normal Power Mode,” on

page 89

Added note to step 3 stating that the step is only

performed when the device is in internal PHY

mode.

Rev. 1.92

(04-27-11)

Table 9.1, “Register 0.

Control Register,” on

page 78

Added note to PDN bit definition stating that the bit

must not be set when the device is in external PHY

mode.

Rev. 1.91

(06-01-09)

The following ordering information has been removed: “LAN91C111-NC,

LAN91C111i-NC (Industrial Temperature) for 128 pin QFP packages”,

“LAN91C111-NE, LAN91C111i-NE (Industrial Temperature) for 128-pin TQFP

packages” as these has been discontinued.

Rev. 1.9

(07-17-08)

All Updated document references to Rev. C.

Rev. 1.9

(07-17-08)

Section 13.1, "Maximum

Guaranteed Ratings*," on

page 110

Fixed commercial temp range to state “0°C to

+70°C for LAN91C111”

Rev. 1.9

(07-17-08)

Cover Added bullet: “Commercial Temperature Range

from 0°C to 70°C (LAN91C111)”

Rev. 1.9

(07-17-08)

Section 8.24, "Bank 3 -

Revision Register," on

page 72

Changed REV default from “0001” to “0010”

Rev. 1.9

(07-17-08)

Table 14.3, “Asynchronous

Cycle - nADS=0,” on

page 117

Changed T1A time in table under figure from 10nS

min to 2nS min.

Rev. 1.9

(07-17-08)

Section 10.4, "Typical Flow

of Event For Receive," on

page 91

In step 4, changed last sentence from “If CRC is

incorrect the packet memory is released and no

interrupt will occur.”, to “The RCV_BAD bit of the

Bank 1 Control Register controls whether or not to

generate interrupts when bad CRC packets are

received.”

Rev. 1.9

(07-17-08)

Section 7.7.14, "Receive

Polarity Correction," on

page 40

Added note at end of 10 Mbps subsection stating

“The first 3 received packets must be discarded

after the correction of a reverse polarity condition.”