TC59LM906AMG-45 - Toshiba America Electronic Components, Inc.

TC59LM914/06AMG-37,-45,-50

2004-03-16 1/58

Rev 0.91

TENTATIVE TOSHIBA MOS D IGITAL INT EGRATED CIRCUIT SILICON MONOLITHIC

512Mbits Network FCRAM1 (SSTL_18 / HSTL_Interface)

− 4,194,304-WORDS × 8 BANKS × 16-BITS

− 8,388,608-WORDS × 8 BANKS × 8-BITS

DESCRIPTION

Network FCRAMTM is Double Data Rate Fast Cycle Ra ndom Access Memory. TC59LM914/06AMG is Fast Cycl e

Random Access Memory (Network FCRAMTM) containing 536,870,912 memory cells. TC59LM914AMG is org an ized

as 4,194,304-words × 8 banks × 16 bits, TC59LM906AMG is organized as 8,388,608-words × 8 banks × 8 bits.

TC59LM914/06AMG feature a fully synchronous operation referenced to clock edge whereby all operations are

synchronized at a clock input which enables high performance and simple user interface coexistence.

TC59LM914/06AMG can operate fast core cycle compared with regular DDR SDRAM.

TC59LM914/06AMG is suitable for Network, Server and other applications where large memory density and low

power consumption are required. The Output Driver for Network FCRAMTM is capable of high quality fast data

transfer under light loading condition.

FEATURES

TC59LM914/06

PARAMETER -37 -45 -50

CL = 3 5.5 ns 5.5 ns 6.0 ns

CL = 4 4.5 ns 5.0 ns 5.5 ns

tCK Clock Cycle Time (min) CL = 5 3.75 ns 4.5 ns 5.0 ns

tRC Random Read/Write Cycle Time (min) 22.5 ns 25 ns 27.5 ns

tRAC Random Access Time (max) 22.0 ns 22.0 ns 24.0 ns

IDD1S Operating Current (single bank) (max) 280 mA 260 mA 240 mA

lDD2P Power Down Current (max) 90 mA 85 mA 80 mA

lDD6 Self-Refresh Current (max) 20 mA 20 mA 20 mA

• Fully Synchronous Operation

• Double Data Rate (DDR)

Data input/output are synchronized with both edges of DQS.

• Differential Clock (CLK and CLK ) inputs

CS , FN and all address input signals ar e sampled on the positive edge of CLK.

Output data (DQs and DQS) is aligned to the crossings of CLK and CLK .

• Fast clock cycle time of 3.75 ns minimum

Clock: 266 MHz maximum

Data: 533 Mbps/pin maximum

• Fast cycle and Short Latency

• Eight independent banks operation

When BA2 input assign to A14 inpu t, TC59LM914/06AMG can function as 4 ban k device

(Keep backward compatibility to 256Mb)

• Bidirectional differential data strobe signal : TC59LM906AMG

• Bidirectional data s tr o be signal per byte : TC59LM914AMG

• Distributed Auto-Refresh cycle in 7.8 µs

• Self-Refresh

• Power Down Mode

• Variable Write Length Control

• Write Latency = CAS Latency-1

• Programable CAS Latency and Burst Length

CAS Latency = 3, 4, 5

Burst Length = 2, 4

• Organization: TC59LM914AMG : 4,194,304 words × 8 banks × 16 bits

TC59LM906AMG : 8,388,608 words × 8 banks × 8 bits

• Power Supply Voltage VDD: 2.5 V ± 0.15V

VDDQ: 1.4 V ∼ 1.9 V

• 1.8 V CMOS I/O comply with SSTL_1.8 (half strength driver) and HSTL

• Package: 60Ball BGA, 1mm × 1mm Ball pitch

Notice : FCRAM is trademark of Fujitsu Limited, Japan.

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TC59LM906AMB

PIN NAMES

PIN NAME PIN NAME

A0~A13 Address Input DQS / DQS Write/Read Data Strobe

BA0~BA2 Bank Address VDD Power (+2.5 V)

DQ0~DQ7 Data Input / Output VSS Ground

CS Chip Select VDDQ Power (+1.5 V / +1.8 V)

(for I/O buffer)

FN Function Control VSSQ Ground (for I/O buffer)

PD Power Down Control VREF Reference Voltage

CLK, CLK Clock Input NC Not Connected

4 bank operation can be performed using BA2 as A14.

PIN ASSIGNMENT (TOP VIEW)

: Depopulated ball

ball pitch=1.0 x 1.0mm 5

1 3 642

x 8

VDD

DQ1

DQ3

BA2

A13

BA0

A10

VDD

VSS

DQ6

DQ4

VREF

CLK

A12

A11

VSS

DQ7

VSSQ

VDDQ

DQ5

VSSQ

VDDQ

VSSQ

VSS

CLK

DQ0

VDDQ

VSSQ

DQ2

VDDQ

VSSQ

VDDQ

VDD

BA1

DQS DQS

Inde

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Rev 0.91

TC59LM914AMB

PIN NAMES

PIN NAME PIN NAME

A0~A13 Address Input UDQS/LDQS Write/Read Data Strobe

BA0~BA2 Bank Address VDD Power (+2.5 V)

DQ0~DQ15 Data Input / Output VSS Gorund

CS Chip Select VDDQ Power (+1.5 V / +1.8 V)

(for I/O buffer)

FN Function Control VSSQ Power

(for I/O buffer)

PD Power Down Control VREF Reference Voltage

CLK, CLK Clock Input NC Not Conneted

4 bank operation can be performed using BA2 as A14.

PIN ASSIGNMENT (TOP VIEW)

: Depopulated ball

ball pitch=1.0 x 1.0mm 5

1 3 642

x 16

VDD

DQ1

DQ2

DQ3

DQ5

DQ6

DQ7

BA2

A13

BA0

A10

VDD

VSS

DQ14

DQ13

DQ12

DQ10

DQ9

DQ8

VREF

CLK

A12

A11

VSS

DQ15

VSSQ

VDDQ

DQ11

VSSQ

VDDQ

VSSQ

VSS

CLK

DQ0

VDDQ

VSSQ

DQ4

VDDQ

VSSQ

VDDQ

VDD

BA1

LDQS

UDQS

Inde

TC59LM914/06AMG-37,-45,-50

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Rev 0.91

BLOCK DIAGRAM

Note: The TC59LM906AMG configuration is 8 Bank of 16384 × 512 × 8 of cell array with the DQ pins numbered DQ0~DQ7.

The TC59LM914AMG configuration is 8 Bank of 16384 × 256 × 16 of cell array with the DQ pins numbered DQ0~DQ15.

TC59LM906AMG has

DQS pin for Differential Data Strobe.

TC59LM914AMG has UDQS and LDQS.

DQ0~DQn

DLL

CLOCK

BUFFER

CLK

PD To each block

COMMAND

DECODER

ADDREE

BUFFER

CONTROL

SIGNAL

GENERATOR

MODE

REFRESH

COUNTER

A0~A13

BA0~BA2

BURST

COUNTER

WRITE ADDRESS

LATCH/

ADDRESS

COMPARATOR

DATA

CONTROL AND LA TCH

CIRCUIT

UPPER ADDRESS

LATCH

READ

DATA

BUFFER

DQ BUFFER

DQS

LOWER ADDRESS

LATCH

DQS

WRITE

DATA

BUFFER

BANK #7

BANK #6

BANK #5

BANK #4

BANK #3

BANK #2

BANK #1

BANK #0

MEMORY

CELL ARRA Y

COLUMN DECODER

ROW DECODER

TC59LM914/06AMG-37,-45,-50

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Rev 0.91

ABSOLUTE MAXIMUM RATINGS

SYMBOL PARAMETER RATING UNIT NOTES

VDD Power Supply Voltage −0.3~ 3.3 V

VDDQ Power Supply Voltage (for I/O buffer) −0.3~VDD+ 0.3 V

VIN Input Voltage −0.3~VDD+ 0.3 V

VOUT Output and I/O pin Voltage −0.3~VDDQ + 0.3 V

VREF Input Reference Voltage −0.3~VDD+ 0.3 V

Topr Operating Temperature (case) 0~85 °C

Tstg Storage Temperature −55~150 °C

Tsolder Soldering Temperature (10 s) 260 °C

PD Power Dissipation 2 W

IOUT Short Circuit Output Current ±50 mA

Caution: Conditions outside the limits listed under “ABSOLUTE MAXIMUM RATINGS” may cause permanent damage to the device.

The device is not meant to be operated under conditions outside the limits described in the operational section of this

specification.

Exposure to “ABSOLUTE MAXIMUM RATINGS” conditions for extended periods may affect device reliability.

RECOMMENDED DC, AC OPERATING CONDITIONS (Notes: 1)(TCASE = 0~85°C)

SYMBOL PARAMETER MIN TYP. MAX UNIT NOTES

VDD Power Supply Voltage 2.35 2.5 2.65 V

VDDQ Power Supply Voltage (for I/O buffer) 1.4 ⎯ 1.9 V

VREF Input Reference Voltage VDDQ/2 × 95% VDDQ/2 VDDQ/2 × 105% V 2

VIH (DC) Input DC High Voltage VREF + 0.125 ⎯ V

DDQ + 0.2 V 5

VIL (DC) Input DC Low Voltage −0.1 ⎯ V

REF − 0.125 V 5

VICK (DC) Differential Clock DC Input Voltage −0.1 ⎯ V

DDQ + 0.1 V 10

VID (DC) Input Differential Voltage.

CLK and CLK inputs (DC) 0.4 ⎯ V

DDQ + 0.2 V 7, 10

VIH (AC) Input AC High Voltage VREF + 0.2 ⎯ V

DDQ + 0.2 V 3, 6

VIL (AC) Input AC Low Voltage −0.1 ⎯ V

REF − 0.2 V 4, 6

VID (AC) Input Differential Voltage.

CLK and CLK inputs (AC) 0.55 ⎯ V

DDQ + 0.2 V 7, 10

VX (AC) Differential AC Input Cross Point Voltage VDDQ/2 − 0.125 ⎯ V

DDQ/2 + 0.125 V 8, 10

VISO (AC) Differential Clock AC Middle Level VDDQ/2 − 0.125 ⎯ V

DDQ/2 + 0.125 V 9, 10

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Rev 0.91

Note:

(1) All voltages referenced to VSS, VSSQ.

(2) VREF is expected to track variations in VDDQ DC level of the transmitting device.

Peak to peak AC noise on VREF may not exceed ±2% VREF (DC).

(3) Overshoot limit: VIH (max) = VDDQ + 0.7 V with a pulse width ≤ 5 ns.

(4) Undershoot limit: VIL (min) = −0.7 V with a pulse width ≤ 5 ns.

(5) VIH (DC) and VIL (DC) are levels to maintain the current logic state.

(6) VIH (AC) and VIL (AC) are levels to change to the new logic state.

(7) VID is magnitude of the difference between CLK input level and CLK input level.

(8) The value of VX (AC) is expected to equal VDDQ/2 of the transmitting device.

(9) VISO means {VICK (CLK) + VICK (CLK )} /2

(10) Refer to the figure below.

(11) In the case of external termination, VTT (termination voltage) should be gone in the range of VREF (DC) ±

0.04 V.

CAPACITANCE (VDD = 2.5V, VDDQ = 1.8 V, f = 1 MHz, Ta = 25°C)

SYMBOL PARAMETER MIN MAX Delta UNIT

CIN Input pin Capacitance 1.5 2.5 0.25 pF

CINC Clock pin (CLK, CLK ) Capacitance 1.5 2.5 0.25 pF

CI/O DQ, DQS, UDQS, LDQS, DQS Capacitance 2.5 4 0.5 pF

CNC NC pin Capacitance ⎯ 4 ⎯ pF

Note: These parameters are periodically sampled and not 100% tested.

VISO

(

min

)

VISO

(

max

)

VICK VICK

CLK

VSS

|VID (AC)|

0 V Differential

VISO

VSS

VID (AC)

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Rev 0.91

RECOMMENDED DC OPERATING CONDITIONS

(VDD=2.5V ± 0.125V, VDDQ=1.4V ~ 1.9V, TCASE = 0~85°C)

MAX

SYMBOL PARAMETER -37 -45 -50

UNIT NOTES

IDD1S

Operating Current

tCK = min, IRC = min ;

Read/Write command cycling ;

0 V ≤ VIN ≤ VIL (AC) (max), VIH (AC) (min) ≤ VIN ≤ VDDQ ;

1 bank operation, Burst length = 4 ;

Address change up to 2 times during minimum IRC.

280 260 240 1, 2

IDD2N

Standby Current

tCK = min, CS = VIH, PD = VIH ;

0 V ≤ VIN ≤ VIL (AC) (max), VIH (AC) (min) ≤ VIN ≤ VDDQ ;

All banks: inactive state ;

Other input signals are changed one time during 4 × tCK.

120 110 100 1

IDD2P

Standby (Power Down) Current

tCK = min, CS = VIH, PD = VIL (Power Down) ;

0 V ≤ VIN ≤ VDDQ ;

All banks: inactive state

90 85 80 1

IDD4W

Write Operating Current (4 Banks)

8 Bank Interleaved continuos burst wirte operation ;

tCK = min, IRC = min

Burst Length = 4, CAS Latency = 5

0 V ≤ VIN ≤ VIL (AC) (max), VIH (AC) (min) ≤ VIN ≤ VDDQ ;

Address inputs change once per clock cycle ;

DQ and DQS inputs change twice per clock cycle.

450 400 350 1

IDD4R

Read Operating Current (4 Banks)

8 Bank Interleaved continuos burst wirte operation ;

tCK = min, IRC = min, IOUT = 0mA ;

Burst Length = 4, CAS Latency = 5 ;

0 V ≤ VIN ≤ VIL (AC) (max), VIH (AC) (min) ≤ VIN ≤ VDDQ ;

Address inputs change once per clock cycle ;

Read data change twice per clock cycle.

450 400 350 1,2

IDD5B

Burst Auto Refresh Current

Refresh command at every IREFC at interval ;

tCK = min、IREFC = min

CAS Latency = 5

0 V ≤ VIN ≤ VIL (AC) (max), VIH (AC) (min) ≤ VIN ≤ VDDQ ;

Address inputs change up to 2 times during minimum IREFC.

DQ and DQS inputs change twice per clock cycle.

280 265 250 1,5

IDD6

Self-Refresh Current

Self-Refresh mode

PD = 0.2 V, 0 V ≤ VIN ≤ VDDQ 20 20 20

TC59LM914/06AMG-37,-45,-50

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Rev 0.91

RECOMMENDED DC OPERATING CONDITIONS (continued)

(VDD=2.5V ± 0.125V, VDDQ=1.4V ~ 1.9V, TCASE = 0~85°C)

SYMBOL PARAMETER MIN MAX UNIT NOTES

ILI Input Leakage Current

( 0 V ≤ VIN ≤ VDDQ, all other pins not under test = 0 V) −5 5 µA

ILO Output Leakage Current

(Output disabled, 0 V ≤ VOUT ≤ VDDQ) −5 5 µA

IREF VREF Current −5 5 µA

IOH (DC) VOH = 1.420V −5.6 ⎯

IOL (DC) Normal Output Driver VOL = 0.280V 5.6 ⎯

IOH (DC) VOH = 1.420V −9.8 ⎯

IOL (DC) Strong Output Driver VOL = 0.280V 9.8 ⎯

IOH (DC) VOH = 1.420V −2.8 ⎯

IOL (DC) Weak Output Driver VOL = 0.280V 2.8 ⎯

IOH (DC) VOH = 1.420V −13.4 ⎯

IOL (DC)

Full Strength Output

Driver

Output Source DC Current

(VDDQ = 1.7V ~ 1.9V)

VOL = 0.280V 13.4 ⎯

mA 3

IOH (DC) VOH = VDDQ−0.4V −4 ⎯

IOL (DC) Normal Output Driver VOL = 0.4V 4 ⎯

IOH (DC) VOH = VDDQ−0.4V −8 ⎯

IOL (DC) Strong Output Driver VOL = 0.4V 8 ⎯

IOH (DC) Not defined ⎯ ⎯

IOL (DC) Weak Output Driver Not defined ⎯ ⎯

IOH (DC) VOH = VDDQ−0.4V −10 ⎯

IOL (DC)

Full Strength Output

Driver

Output Source DC Current

(VDDQ = 1.4V ~ 1.6V)

VOL = 0.4V 10 ⎯

mA 3

Notes: 1. These parameters depend on the cycle rate and these values are measured at a cycle rate with the minimum values o f

tCK, tRC and IRC.

2. These parameters depend on the output loading. The specified values are obtained with the output open.

3. Refer to output driver characteristics for the detail. Output Driver Strength is selected by Extended Mode Register.

4. In case of Full Strength Output Driver, OCD calibration (Off chip Driver impedance adjustment) can be used. The

specification of Full Strength Output Driver defines the default value after power-up.

5. IDD5B is specified under burst refresh condition. Actual system should use distributed refresh that meet tREFI

specification.

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Rev 0.91

AC CHARACTERISTICS AND OPERATING CONDITIONS (Notes: 1, 2)

-37 -45 -50

SYMBOL PARAMETER MIN MAX MIN MAX MIN MAX

UNIT NOTES

tRC Random Cycle Time 22.5 ⎯ 25 ⎯ 27.5 ⎯ 3

CL = 3 5.5 8.5 5.5 8.5 6.0 8.5 3

CL = 4 4.5 8.5 5.0 8.5 5.5 8.5 3

tCK Clock Cycle Time

CL = 5 3.75 8.5 4.5 8.5 5.0 8.5 3

tRAC Random Access Time ⎯ 22.0 ⎯ 22.0 ⎯ 24 3

tCH Clock High Time 0.45 × tCK ⎯ 0.45 × tCK ⎯ 0.45 × tCK ⎯ 3

tCL Clock Low Time 0.45 × tCK ⎯ 0.45 × tCK ⎯ 0.45 × tCK ⎯ 3

tCKQS QS Access Time from CLK −0.45 0.45 −0.5 0.5 −0.6 0.6 3, 8

tQSQ Data Output Skew from QS ⎯ 0.25 ⎯ 0.3 ⎯ 0.35 4

tAC Data Access Time from CLK −0.5 0.5 −0.6 0.6 −0.65 0.65 3, 8

tOH Data Output Hold Time from CLK −0.5 0.5 −0.6 0.6 −0.65 0.65 3, 8

tQSPRE QS (read) PreAMGle Pulse

Width 0.9 × tCK 1.1 × tCK 0.9 × tCK 1.1 × tCK 0.9 × tCK 1.1 × tCK 3, 8

tHP CLK half period (minimum of

Actual tCH, tCL) min(tCH,

tCL) ⎯ min(tCH,

tCL) ⎯ 3

tQSP QS (read) Pulse Width tHP−tQHS ⎯ t

HP−tQHS ⎯ t

HP−tQHS ⎯ 4, 8

tQSQV Data Output Valid Time from QS tHP−tQHS ⎯ t

HP−tQHS ⎯ t

HP−tQHS ⎯ 4, 8

tQHS DQ, QS Hold Skew factor ⎯ 0.055 ×

tCK +0.17

⎯ 0.055 ×

tCK +0.17

⎯ 0.055 ×

tCK +0.17

tDQSS DS (write) Low to High Setup Time 0.7 5 × tCK 1.25 × tCK 0.75 × tCK 1.25 × tCK 0.75 × tCK 1.25 × tCK 3

tDSPRE DS (write) PreAMGle Pulse Width 0.25 ×

tCK ⎯ 0.25 ×

tCK ⎯ 4

tDSPRES DS First Input Setup Time 0 ⎯ 0 ⎯ 0 ⎯ 3

tDSPREH DS First Low Input Hold Time 0.25 × tCK ⎯ 0.25 × tCK ⎯ 0.25 × tCK ⎯ 3

tDSP DS High or Low Input Pulse Wid th 0 .4 × tCK 0.6 × tCK 0.4 × tCK 0.6 × tCK 0.4 × tCK 0.6 × tCK 4

CL = 3 0.75 ⎯ 0.9 ⎯ 1.0 ⎯ 3, 4

CL = 4 0.75 ⎯ 0.9 ⎯ 1.0 ⎯ 3, 4

tDSS DS Input Falling Edge

to Clock Setup Time

CL = 5 0.75 ⎯ 0.9 ⎯ 1.0 ⎯ 3, 4

tDSPST DS (write) PostAMGle Pulse Width 0.4 × tCK ⎯ 0.4 × tCK ⎯ 0.4 × tCK ⎯ 4

CL = 3 0.75 ⎯ 0.9 ⎯ 1.0 ⎯ 3, 4

CL = 4 0.75 ⎯ 0.9 ⎯ 1.0 ⎯ 3, 4

tDSPSTH DS (write) PostAMGle

Hold T ime CL = 5 0.75 ⎯ 0.9 ⎯ 1.0 ⎯ 3, 4

tDSSK UDQS – LDQS Skew (×16) −0.5× tCK 0.5× tCK

−0.5× tCK 0.5× tCK

tDS Data Input Setup Time from DS 0.35 ⎯ 0.4 ⎯ 0.45 ⎯ 4

tDH Dat a Input H old Time from DS 0.35 ⎯ 0.4 ⎯ 0.45 ⎯ 4

tIS Command/Address Input Setup

Time 0.6 ⎯ 0.7 ⎯ 0.8 ⎯ 3

tIH Command/Address Input Hold

Time 0.6 ⎯ 0.7 ⎯ 0.8 ⎯

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Rev 0.91

AC CHARACTERISTICS AND OPERATING CONDITIONS (Notes: 1, 2) (continued)

-37 -45 -50

SYMBOL PARAMETER MIN MAX MIN MAX MIN MAX

UNIT NOTES

tLZ Data-out Low Impedance Time

from CLK −0.5 ⎯ −0.6 ⎯ −0.65 ⎯ 3,6,8

tHZ Data-out High Impedance Time

from CLK ⎯ 0.5 ⎯ 0.6 ⎯ 0.65 3,7,8

tQSLZ QS-out Low Impedance Time from

CLK −0.5 ⎯ −0.6 ⎯ −0.65 ⎯ 3,6,8

tQSHZ QS-out High Impedance Time

from CLK −0.5 0.5 −0.6 0.6 −0.65 0.65 3,7,8

tQPDH Last output to PD High Hold

Time 0 ⎯ 0 ⎯ 0 ⎯

tPDEX Power Down Exit Time 0.6 ⎯ 0.7 ⎯ 0.8 ⎯ 3

tT Input Transition Time 0.1 1 0.1 1 0.1 1

tFPDL PD Low Input Window for

Self-Refresh Entry −0.5 × tCK 5 −0.5 × tCK 5 −0.5 × tCK 5

tREFI Auto-Refresh Average Interval 0.4 7.8 0.4 7.8 0.4 7.8 5

tPAUSE Pause Time after Power-up 200 ⎯ 200 ⎯ 200 ⎯ µs

CL = 3 5 ⎯ 5 ⎯ 5 ⎯

CL = 4 5 ⎯ 5 ⎯ 5 ⎯

IRC

Random Read/Write

Cycle Time

(applicable to same

bank) CL = 5 6 ⎯ 6 ⎯ 6 ⎯

IRCD RDA/WRA to LAL Command Input

Delay

(applicable to same bank) 1 1 1 1 1 1

CL = 3 4 ⎯ 4 ⎯ 4 ⎯

CL = 4 4 ⎯ 4 ⎯ 4 ⎯

IRAS

LAL to RDA/WR A

Command Input Delay

(applicable to same

bank) CL = 5 5 ⎯ 5 ⎯ 5 ⎯

IRBD Random Bank Access Delay

(applicable to other bank) 2 ⎯ 2 ⎯ 2 ⎯

BL = 2 2 ⎯ 2 ⎯ 2 ⎯

IRWD

LAL following RDA to

WRA Delay

(applicable to other

bank) BL = 4 3 ⎯ 3 ⎯ 3 ⎯

IWRD LAL following WRA to RDA Delay

(applicable to other bank) 1 ⎯ 1 ⎯ 1 ⎯

CL = 3 5 ⎯ 5 ⎯ 5 ⎯

CL = 4 5 ⎯ 5 ⎯ 5 ⎯

IRSC Mode Register Set

Cycle Time CL = 5 6 ⎯ 6 ⎯ 6 ⎯

IPD PD Low to Inactive State of Input

Buffer ⎯ 1 ⎯ 1 ⎯ 1

IPDA PD High to Active State of Input

Buffer ⎯ 1 ⎯ 1 ⎯ 1

CL = 3 15 ⎯ 15 ⎯ 15 ⎯

CL = 4 18 ⎯ 18 ⎯ 18 ⎯

IPDV Power down mode valid

from REF command CL = 5 22 ⎯ 22 ⎯ 22 ⎯

CL = 3 15 ⎯ 15 ⎯ 15 ⎯

CL = 4 18 ⎯ 18 ⎯ 18 ⎯

IREFC Auto-Refresh Cycle

Time CL = 5 22 ⎯ 22 ⎯ 22 ⎯

ICKD REF Command to Clock Input

Disable at Self-Refresh Entry IREFC ⎯ I

REFC ⎯ I

REFC ⎯

ILOCK DLL Lock-on Time (applicable to

RDA command) 200 ⎯ 200 ⎯ 200 ⎯

cycle

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Rev 0.91

AC TEST CONDITIONS

SYMBOL PARAMETER VALUE UNIT NOTES

VIH (min) Input High Voltage (minimum) VREF + 0.2 V

VIL (max) Input Low Voltage (maximum) VREF − 0.2 V

VREF Input Reference Voltage VDDQ/2 V

VTT Termination Voltage VREF V

VSWING Input Signal Peak to Peak Swing 0.7 V

Vr Differential Clock Input Reference Level VX (AC) V

VID (AC) Input Differential Voltage 1.0 V

SLEW Input Signal Minimum Slew Rate 2.5 V/ns

VOTR Output Timing Measurement Reference Voltage VDDQ/2 V 9

Note:

(1) Transition times are measured between VIH min (DC) and VIL max (DC).

Transition (rise and fall) of input signals have a fixed slope.

(2) If the result of nominal calculation with regard to tCK contains more than one decimal place, the result is

rounded up to the nearest decimal place.

(i.e., tDQSS = 0.75 × tCK, tCK = 5 ns, 0.75 × 5 ns = 3.75 ns is rounded up to 3.8 ns.)

(3) These parameters are measured from the differential clock (CLK and CLK ) AC cross point.

(4) These parameters are measured from signal transition point of DQS crossing VREF level.

In case of DQS enable mode, these parameters are measured from the crossing point of DQS and DQS.

(5) The tREFI (max) applies to equally distributed refresh method.

The tREFI (min) applies to both burst refresh method and distributed refresh method.

In such case, the average interval of eight consecutive Auto-Refresh commands has to be more than 400 ns

always. In other words, the number of Auto-Refresh cycles which can be performed within 3.2 µs (8 × 400 ns)

is to 8 times in the maximu m.

(6) Low Impedance State is specified at VDDQ/2 ± 0.2 V from steady state.

(7) High Impedance State is specified where output buffer is no longer driven.

(8) These parameters depend on the clock jitter. These parameters are measured at stable clock.

(9) Output timing is measu red by using Normal driver strength at VDDQ = 1.7V∼1.9V.

Output timing is measured by using Strong driver strength at VDDQ = 1.4V∼1.6V.

SLEW = (VIH min (AC) − VIL max ( AC))/∆T

VIH min (AC)

∆T

VREF

VIL max (AC)

VSWING

∆T

VSS

VDDQ

AC Test Load

Measurement point

Output

VTT

25 Ω

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Rev 0.91

POWER UP SEQUENCE

(1) As for

PD , being maintained by the low state (≤ 0.2 V) is desirable before a power-supply injection.

(2) Apply VDD before or at the same time as VDDQ.

(3) Apply VDDQ before or at the same time as VREF.

(4) Start clock (CLK, CLK ) and maintain stable condition for 200 µs (min).

(5) After stable power and clock, apply DESL and take PD =H.

(6) Issue EMRS to enable DLL and to define driver strength. (Note: 1, 2)

(7) Issue MRS for set CAS latency (CL), Burst Type (BT), and Burst Length (BL). (Note: 1)

(8) Issue two or more Auto-Refresh commands (Note: 1).

(9) Ready for normal operation after 200 clocks from Extended Mo de Register programming.

Notes:

(1) Sequence 6, 7 and 8 c an be issued in random order.

(2) Set

DQS mode for TC59LM906AMG.

(3) L

= Logic Low, H = Logic High

CLK

Command

Address

VDD

VDDQ

VREF

CLK

2.5V

(

TYP

)

1.5V or 1.8V

(

TYP

)

0.9V

(

TYP

)

200us

(

min

)

tPDEX lPDA lRSC lRSC lREFC lREFC

200clock c

cle

(

min

)

DESL RDA MRS DESL RDA MRS DESL WRAREF DESL WRA REF DESL

op-code

EMRS

op-code

MRS

Hi-Z

DQS

EMRS MRS Auto Refresh cycle Normal Operation

Hi-Z

DQS

TC59LM914/06AMG-37,-45,-50

2004-03-16 13/58

Rev 0.91

TIMING DIAGRAMS

Input Timing

Timing of the CLK, CLK

tCK

CLK

VIH

VIL

VIH

VIL

tCL

tCH

VIH (AC)

VIL (AC)

CLK

CLK VX VX VX

VID (AC)

tIH

tIS

tIH

tCK tCL

tCH

CLK

tCK

1st 2nd

tIS tIH

1st 2nd

tIH

tIS tIH

UA, BA LA

tIS

A0~A14

BA0, BA1

Command and Address

DQ (input)

tDS tDH tDS tDH

DQS

Data

• TC59LM906AMG DQS enable mode

DQ (input)

Refer to the Command Truth Table.

tDS tDH tDS tDH

DQS

Data

• TC59LM906AMG DQS disable mode

• TC59LM914AMG

TC59LM914/06AMG-37,-45,-50

2004-03-16 14/58

Rev 0.91

Read Timing (Burst Length = 4)

CLK

Inpu

(control &

addresses)

DQS/DQS

(output)

CAS latency = 3

DQS/DQS

(output)

CAS latency = 4

DQS/DQS

(output)

CAS latency = 5

Hi-Z

LAL (after RDA)

tIS tIH

Hi-Z

tCH tCL tCK

Hi-Z

tQSLZ

tQSPRE

tCKQS

tQSP tQSP

tCKQS

tQSHZ

tQSQ

tQSQV

tQSQ tHZ

tLZ

tOH

tAC

PreAMGle PostAMGle

tQSLZ

tQSPRE

tCKQS

tQSP tQSP

tCKQS

tQSHZ

PreAMGle PostAMGl

Q0 Q1 Q2 Q3

tQSQ

tQSQV

tQSQ

tHZ

tLZ

tOH

tAC

Q0 Q1 Q2 Q3

tQSLZ

tQSPRE

tCKQS

tQSP tQSP

tCKQS

tQSHZ

PreAMGle PostAMGl

tQS

tQSQ

tQSQV

tQSQ

tHZ

tLZ

tAC tAC

tAC

Q0 Q1 Q2 Q3

Hi-Z

DESL

Note: TC59LM914AMG doesn’t have DQS .

The correspondence of LDQS, UDQS to DQ. (TC59LM914AMG)

LDQS DQ0∼DQ7

UDQS DQ8∼DQ15

DQS is Hi-Z in DQS disable mode.

DQS mode is chosen by EMRS. (TC59LM906AMG)

tOH

tQSQ

tAC

TC59LM914/06AMG-37,-45,-50

2004-03-16 15/58

Rev 0.91

Write Timing (Burst Length = 4)

(input)

DQS/DQS

(input)

CAS latency = 4

DQS/DQS

(input)

CAS latency = 3

tDSPRE

tDS

tDH

D0 D1

tDS tDH

tDS

tDH

tDSS

tDQSS

tDSPREH tDSP tDSP

tDS

PreAMGle PostAMGl

tDSP

tDQS

tDSPRES

tDSPST

tDSPSTH

tDH

tDS tDH

tDSS

tDQS

tDSPREH tDSP tDSP

PreAMGle PostAMGle

tDSP

tDSS

tDSPRES

tDSPST

tDSS

tDSPSTH

tDQSS

CLK

Inpu

(control &

addresses)

LAL (after WRA)

tIS tIH

tCH tCL tCK

tDSPRE

DQS/DQS

(input)

CAS latency = 5

tDSPRE

tDSS

tDSPREH tDSP tDSP

tDS

PreAMGle PostAMGl

tDSP

tDQSS

tDSPRES

tDSPST

tDSPSTH

tDH

D0 D1

tDS tDH

tDSS

tDQSS

DESL

Note: TC59LM914AMG doesn’t have DQS .

The correspondence of LDQS, UDQS to DQ. (TC59LM914AMG)

LDQS DQ0∼DQ7

UDQS DQ8∼DQ15

DQS is ignored in DQS disable mode.

DQS mode is chosen by EMRS. (TC59LM906AMG)

D0 D1 D2 D3

TC59LM914/06AMG-37,-45,-50

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Rev 0.91

tREFI, tPAUSE, Ixxxx Timing

CLK

Inpu

(control &

addresses)

Command

tIS t

Note: “IXXXX” means “IRC”, “IRCD”, “IRAS”, etc.

tREFI, tPAUSE, IXXXX

Command

tIS tIH

TC59LM914/06AMG-37,-45,-50

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Rev 0.91

Write Timing (x16 device) (Burst Length =4)

CLK

Inpu

(control &

addresses)

LDQS

DQ0~DQ7

CAS latency = 3

UDQS

DQ8~DQ15

LDQS

DQ0~DQ7

CAS latency = 4

UDQS

DQ8~DQ15

PreAMGl

LAL WRA

tDS

tDSSK

tDH

D0 D1

tDStDH

D2 D3

tDS tDH

tDS

PreAMGle PostAMGl

tDH

D0 D1

tDS tDH

D2 D3

tDS tDH

tDStDH

tDSSK tDSSK tDSSK

tDH

tDS

tDSSK

D0 D1

tDS tDH

D2 D3

tDS tDH

tDS

PreAMGle

D0 D1

tDS tDH

D2 D3

tDS tDH

tDSSK tDSSK tDSSK

tDS

(DESL)

PostAMGl

tDH

LDQS

DQ0~DQ7

CAS latency = 5

UDQS

DQ8~DQ15

PostAMGl

tDS

PreAMGle

tDSSK

tDH

D0 D1

tDS tDH

D2 D3

tDS tDH

tDS

PreAMGle

D0 D1

tDS tDH

D2 D3

tDS tDH

tDSSK tDSSK tDSSK

tDS PostAMGl

tDH tDH

tDH

PostAMGl

PreAMGle

tDH

TC59LM914/06AMG-37,-45,-50

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Rev 0.91

FUNCTION TRUTH TABLE (Notes: 1, 2, 3)

Command T r uth Table (Notes: 4)

• The First Command

SYMBOL FUNCTION CS FN BA2~BA0 A13~A9 A8 A7 A6~A0

DESL Device Deselect H × × × × × ×

RDA Read with Auto-close L H BA UA UA UA UA

WRA Write with Auto-close L L BA UA UA UA UA

• The Second Command (The next clock of RDA or WRA command)

SYMBOL FUNCTION CS FN

BA1~

BA0 BA2 A13 A12~

A11 A10~A

9 A8 A7 A6~A0

LAL Lower Address Latch (x16) H × × V V V × × LA LA

LAL Lower Address Latch (x8) H × × V V × × LA LA LA

REF Auto-Refresh L × × × × × × × × ×

MRS Mode Register Set L × V L L L L L V V

Notes: 1. L = Logic Low, H = Logic High, × = either L or H, V = Valid (specified value), BA = Bank Address, UA = Upper Add ress,

LA = Lower Address

2. All commands are assumed to issue at a valid state.

3. All inputs for command (excluding SELFX and PDEX) are latched on the crossing point of differential clock input where

CLK goes to High.

4. Operation mode is decided by the combination of 1st command and 2nd command. Refer to “STATE DIAGRAM” and

the command table below.

Read Command Table

COMMAND (SYMBOL) CS FN BA2~BA0 A13~A9 A8 A7 A6~A0 NOTES

RDA (1st) L H BA UA UA UA UA

LAL (2nd) H × × × LA LA LA 5

Note 5 : For x16 device, A8 is “X” (either L or H).

Write Command Table

• TC59LM914AMG

COMMAND(SYMBOL) CS FN

BA1~

BA0 BA2 A13 A12 A11

A10~

A9 A8 A7 A6~A0

WRA (1st) L L BA UA UA UA UA UA UA UA UA

LAL (2nd) H × × LVW0 LVW1 UVW0 UVW1 × × LA LA

• TC59LM906AMG

COMMAND(SYMBOL) CS FN

BA1~

BA0 BA2 A13 A12 A11

A10~

A9 A8 A7 A6~A0

WRA (1st) L L BA UA UA UA UA UA UA UA UA

LAL (2nd) H × × VW0 VW1 × × × LA LA LA

Notes: 6. A14 and A11 are used for Variable Write Length (VW) control at Write Operation.

TC59LM914/06AMG-37,-45,-50

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Rev 0.91

FUNCTION TRUTH TABLE (continued)

VW T r uth Table

Burst Length Function VW0 VW1

Write All Words L ×

BL=2 Write First One Word H ×

Reserved L L

Write All Words H L

Write First Two Words L H

BL=4

Write First One Word H H

Note 7 : For x16 device, LVW0 and LVW1 control DQ0~DQ7.

UVW0 and UVW1 control DQ8~DQ15.

Mode Register Set Command Table

COMMAND (SYMBOL) CS FN BA2~BA0 A13~A9 A8 A7 A6~A0 NOTES

RDA (1st) L H × × × × ×

MRS (2nd) L × V V V V V 8

Notes: 8. Refer to “MODE REGISTER TABLE”.

Auto-Refresh Command Table

FUNCTION COMMAND

(SYMBOL) CURRENT

STATE n − 1n CS FN BA2~BA0 A13~A9 A8 A7 A6~A0 NOTES

Active WRA (1st) Standby H H L L × × × × ×

Auto-Refresh REF (2nd) Active H H L × × × × × ×

Self-Refresh Command Table

FUNCTION COMMAND

(SYMBOL) CURRENT

STATE n − 1n CS FN BA2~BA0 A13~A9 A8 A7 A6~A0 NOTES

Active WRA (1st) Standby H H L L × × × × ×

Self-Refresh Entry REF (2nd) Active H L L × × × × × × 9, 10

Self-Refresh Continue ⎯ Self-Refresh L L × × × × × × ×

Self-Refresh Exit SELFX Self-Refresh L H H × × × × × × 11

Power Down Table

FUNCTION COMMAND

(SYMBOL) CURRENT

STATE n − 1n CS FN BA1~BA0 A14~A9 A8 A7 A6~A0 NOTES

Power Down Entry PDEN Standby H L H × × × × × × 10

Power Down Continue ⎯ Power Down L L × × × × × × ×

Power Down Exit PDEX Power Down L H H × × × × × × 11

Notes: 9. PD has to be brought to Low within tFPDL from REF command.

10.

PD should be brought to Low after DQ’s state turned high impedance.

11. When

PD is brought to High from Low, this function is executed asynchronously.

TC59LM914/06AMG-37,-45,-50

2004-03-16 20/58

Rev 0.91

FUNCTION TRUTH TABLE (continued)

CURRENT STATE n − 1 n CS FN ADDRESS COMMAND ACTION NOTES

H H H × × DESL NOP

H H L H BA, UA RDA Row activate for Read

H H L L BA, UA WRA Row activate for Write

H L H × × PDEN Power Down Entry 12

H L L × × ⎯ Illegal

Idle

L × × × × ⎯ Refer to Power Down State

H H H × LA LAL Begin Read

H H L × Op-code MRS/EMRS Access to Mode Register

H L H × × PDEN Illegal

H L L × × MRS/EMRS Illegal

Row Active for Read

L × × × × ⎯ Invalid

H H H × LA LAL Begin Write

H H L × × REF Auto-Refresh

H L H × × PDEN Illegal

H L L × × REF (self) Self-Refresh Entry

Row Active for Write

L × × × × ⎯ Invalid

H H H × × DESL Continue Burst Read to End

H H L H BA, UA RDA Illegal 13

H H L L BA, UA WRA Illegal 13

H L H × × PDEN Illegal

H L L × × ⎯ Illegal

Read

L × × × × ⎯ Invalid

H H H × × DESL

Data Write & Continue Burst Write to

End

H H L H BA, UA RDA Illegal 13

H H L L BA, UA WRA Illegal 13

H L H × × PDEN Illegal

H L L × × ⎯ Illegal

Write

L × × × × ⎯ Invalid

H H H × × DESL NOP → Idle after IREFC

H H L H BA, UA RDA Illegal

H H L L BA, UA WRA Illegal

H L H × × PDEN Self-Refresh Entry 14

H L L × × ⎯ Illegal

Auto-Refreshing

L × × × × ⎯ Refer to Self-Refreshing State

H H H × × DESL NOP → Idle after IRSC

H H L H BA, UA RDA Illegal

H H L L BA, UA WRA Illegal

H L H × × PDEN Illegal

H L L × × ⎯ Illegal

Mode Register

Accessing

L × × × × ⎯ Invalid

H × × × × ⎯ Invalid

L L × × × ⎯ Maintain Power Down Mode

L H H × × PDEX

Exit Power Down Mode → Idle after

tPDEX

Power Down

L H L × × ⎯ Illegal

H × × × × ⎯ Invalid

L L × × × ⎯ Maintain Self-Refresh

L H H × × SELFX Exit Self-Refresh → Idle after IREFC

Self-Refreshing

L H L × × ⎯ Illegal

Notes: 12. Illegal if any bank is not idle.

13. Illegal to bank in specified states; Function may be legal in the bank inidicated by Bank Address (BA).

14. Illegal if tFPDL is not satisfied.

TC59LM914/06AMG-37,-45,-50

2004-03-16 21/58

Rev 0.91

MODE REGISTER TABLE

Regular Mode Register (Notes: 1)

ADDRESS BA1*1 BA0*1 BA2, A13~A8 A7*3 A6~A4 A3 A2~A0

A7 TEST MODE (TE) A3 BURST TYPE (BT)

0 Regular (default)

0 Sequential

1 Test Mode Entry 1 Interleave

A6 A5 A4 CAS LATENCY (CL) A2 A1 A0 BURST LENGTH (BL)

0 0 × Reserved*2 0 0 0 Reserved*2

0 1 0 Reserved*2 0 0 1 2

0 1 1 3 0 1 0 4

1 0 0 4 0 1 1

1 0 1 5 1 × × Reserved*2

1 1 0 Reserved*2

1 1 1 Reserved*2

Extended Mode Register (Notes: 4)

ADDRESS BA1*4 BA0*4 BA2,

A13~A12 A11*6A10*7A9~A7 A6 A5~A2 A1 A0*5

A9 A8 A7 Driver Impedance Adjustment A6 A1 OUTPUT DRIVE IMPEDANCE CONTROL

(DIC)

0 0 0 OCD Calibration default 0 0 Normal Output Driver

0 0 1 Drive (1) 0 1 Strong Output Driver

0 1 0 Drive (0) 1 0 Weak Output Driver

1 0 0 Adjust mode

1 1 Reserved

1 1 1 OCD Calibration mode exit

A10 DQS Enable A0 DLL SWITCH (DS)

0 Disable 0 DLL Enable

1 Enable

1 DLL Disable

Notes: 1. Regular Mode Register is chosen using the combination of BA0 = 0 and BA1 = 0.

2. “Reserved” places in Regular Mode Register should not be set.

3. A7 in Regular Mode Register must be set to “0” (low state).

Because Test Mode is specific mode for supplier.

4. Extended Mode Register is chosen using the combination of BA0 = 1 and BA1 = 0.

5. A0 in Extended Mode Register must be set to "0" to enable DLL for normal operation.

6. A11 in Extended Mode Register must be set to “0”.

7. TC59LM914AMG, A10 in Extended Mode Register is ignored. DQS is available only TC59LM906AMG.

TC59LM914/06AMG-37,-45,-50

2004-03-16 22/58

Rev 0.91

STATE DI AGRAM

STANDBY

(IDLE)

SELF-

REFRESH POWER

DOWN

PDEN

(PD = L)

PDEX

(PD = H)

SELFX

(PD = H)

MODE

AUTO-

REFRESH

ACTIVE

(RESTORE)

READ

WRITE

(BUFFER)

PD = L

PD = H

WRA RDA

MRSREF

Command input

LAL

utomatic return

The second command at Active state

must be issued 1 clock after RDA or

WRA command input.

LAL

TC59LM914/06AMG-37,-45,-50

2004-03-16 23/58

Rev 0.91

TIMING DIAGRAMS

SINGLE BANK READ TIMING (CL = 3)

CLK

Hi-Z

(output)

BL = 2

IRC = 5 cycles

Hi-Z

CL = 3

Command

IRC = 5 cycles

0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15

RDA LAL DESL RDA LAL RDA LALDESL DESL

IRC = 5 cycles

Address UA LA UA LA UA LA

IRAS = 4 cycles IRCD=1 cycle IRAS = 4 cyclesIRCD=1 cycle IRCD=1 cycle IRAS = 4 cycles

Bank Add. #0 #0 #0

DQS/DQS

(output)

Hi-Z

(output)

BL = 4

Hi-Z

DQS/DQS

(output)

RDA

CL = 3 CL = 3

CL = 3 CL = 3 CL = 3

Note : TC59LM914AMG doesn’t have DQS .

Q0 Q1 Q0 Q1 Q0 Q1

Q0 Q1 Q0 Q1 Q0Q2 Q3 Q2 Q3 Q1 Q2

TC59LM914/06AMG-37,-45,-50

2004-03-16 24/58

Rev 0.91

SINGLE BANK READ TIMING (CL = 4)

CLK

Hi-Z

(output)

BL = 2

IRC = 5 cycles

Hi-Z

CL = 4

Command

IRC = 5 cycles

0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15

RDA LAL DESL RDA LAL RDA LALDESL DESL

IRC = 5 cycles

Address UA LA UA LA UA LA

IRAS = 4 cycles IRCD=1 cycle IRAS = 4 cyclesIRCD=1 cycle IRCD=1 cycle IRAS = 4 cycles

Bank Add. #0 #0 #0

DQS/DQS

(output)

CL = 4 CL = 4

Hi-Z

(output)

BL = 4

Hi-Z

CL = 4

DQS/DQS

(output)

CL = 4 CL = 4

RDA

Note : TC59LM914AMG doesn’t have DQS .

Q0 Q1 Q0 Q1 Q0

Q0 Q1 Q0 Q1 Q0Q2 Q3 Q2 Q3

TC59LM914/06AMG-37,-45,-50

2004-03-16 25/58

Rev 0.91

SINGLE BANK READ TIMING (CL = 5)

IRC = 6 cycles

CLK

Hi-Z

(output)

BL = 2

Hi-Z

CL = 5

Command

IRC = 6 cycles

0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15

RDA LAL DESL RDA LAL RDA LALDESL

Address UA LA UA LA UA LA

IRAS = 5 cycles IRCD=1 cycle IRAS = 5 cyclesIRCD=1 cycle IRCD=1 cycle

Bank Add. #0 #0 #0

DQS/DQS

(output) CL = 5

Hi-Z

(output)

BL = 4

Hi-Z

CL = 5

DQS/DQS

(output) CL = 5

DESL

Note : TC59LM914AMG doesn’t have DQS .

Q0 Q1 Q0 Q1

Q0 Q1 Q0 Q1 Q2 Q3 Q2 Q3

TC59LM914/06AMG-37,-45,-50

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Rev 0.91

SINGLE BANK WRITE TIMING (CL = 3)

CLK

DQS/DQS

(input)

BL = 2

IRC = 5 cycles

WL = 2

Command

IRC = 5 cycles

0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15

WRA LAL DESL WRA LAL WRA LALDESL DESL

IRC = 5 cycles

Address LA UA LA UA LA

IRAS = 4 cycles IRCD=1 cycle IRAS = 4 cyclesIRCD=1 cycle IRCD=1 cycle IRAS = 4 cycles

Bank Add. #0 #0 #0

D0 D1

DQS/DQS

(input)

BL = 4

D0 D1 D2 D3

D0 D1 D0 D1

D0 D1 D2 D3

WRA

WL = 2 WL = 2

WL = 2 WL = 2 WL = 2

D0 D1 D2 D3

Note : TC59LM914AMG doesn’t have DQS .

TC59LM914/06AMG-37,-45,-50

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Rev 0.91

SINGLE BANK WRITE TIMING (CL = 4)

CLK

DQS/DQS

(input)

BL = 2

IRC = 5 cycles

WL = 3

Command

IRC = 5 cycles

0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15

WRA LAL DESL WRA LAL WRA LALDESL DESL

IRC = 5 cycles

Address UA LA UA LA UA LA

IRAS = 4 cycles IRCD=1 cycle IRAS = 4 cyclesIRCD=1 cycle IRCD=1 cycle IRAS = 4 cycles

Bank Add. #0 #0 #0

WL = 3

D0 D1

WL = 3

DQS/DQS

(input)

BL = 4

WL = 3 WL = 3 WL = 3

D2 D3

Note : TC59LM914AMG doesn’t have DQS .

D0 D1 D0 D1

D0 D1 D2 D3 D0 D1 D2

WRA

D3D0 D1

TC59LM914/06AMG-37,-45,-50

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Rev 0.91

SINGLE BANK WRITE TIMING (CL = 5)

IRC = 6 cycles

CLK

DQS/DQS

(input)

BL = 2

WL = 4

Command

IRC = 6 cycles

WRA LAL DESL WRA LAL WRA LALDESL

Address UA LA UA LA UA LA

IRAS = 5 cycles IRCD=1 cycle IRAS = 5 cyclesIRCD=1 cycle IRCD=1 cycle

Bank Add. #0 #0 #0

WL = 4

DQS/DQS

(input)

BL = 4

DESL

D0 D1 D0 D1

WL = 4 WL = 4

D0 D1 D0 D1 D2 D3 D2 D3

0 1 2 3 5678 9 10 11 12 13 14 154

Note : TC59LM914AMG doesn’t have DQS .

TC59LM914/06AMG-37,-45,-50

2004-03-16 29/58

Rev 0.91

SINGLE BANK READ-WRITE TIMING (CL = 3)

CLK

Hi-Z

DQS

BL = 2

IRC = 5 cycles

Hi-Z

CL = 3

Command

IRC = 5 cycles

0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15

RDA LAL DESL RDA LAL WRA LALDESL DESL

IRC = 5 cycles

Address UA LA UA LA UA LA

Bank Add. #0 #0 #0

DQS

WL = 2 CL = 3

Hi-Z

DQS

BL = 4

Hi-Z

WRA

CL = 3 WL = 2 CL = 3

Hi-Z

Note : TC59LM914AMG doesn’t have DQS .

DQS

Q0 Q1 D0 D1

Q0 Q1 D0 D1Q2 Q3 D2 D3

Q0 Q1

Q0 Q1 Q2

TC59LM914/06AMG-37,-45,-50

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Rev 0.91

SINGLE BANK READ-WRITE TIMING (CL = 4)

CLK

Hi-Z

DQS

BL = 2

IRC = 5 cycles

Hi-Z

CL = 4

Command

IRC = 5 cycles

0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15

RDA LAL DESL RDA LAL WRA LALDESL DESL

IRC = 5 cycles

Address UA LA UA LA UA LA

Bank Add. #0 #0 #0

DQS

WL = 3 CL = 4

Hi-Z

DQS

BL = 4

Hi-Z

CL = 4

DQS

WL = 3 CL = 4

WRA

Hi-Z

Note : TC59LM914AMG doesn’t have DQS .

Q0 Q1 D0 D1 Q0

Q0 Q1 D0 D1Q2 Q3 D2 D3 Q0

TC59LM914/06AMG-37,-45,-50

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Rev 0.91

SINGLE BANK READ-WRITE TIMING (CL = 5)

CLK

DQS

BL = 2

Command

0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15

Address

Bank Add.

DQS

BL = 4

DQS

IRC = 6 cycles

Hi-Z

CL = 5

IRC = 6 cycles

RDA LAL RDA LAL WRA LALDESL

UA LA UA LA UA LA

#0 #0 #0

WL = 4

Hi-Z

CL = 5

DESL

WL = 4

Hi-Z

Note : TC59LM914AMG doesn’t have DQS .

Q0 Q1 D0 D1

Q0 Q1 Q2 Q3 D0 D1 D2 D3

DESL

TC59LM914/06AMG-37,-45,-50

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Rev 0.91

MULTIPLE BANK READ TIMING (CL = 3)

RDA

Bank

"b"

CLK

Hi-Z

(output)

BL = 2

IRBD = 2 cycles

Hi-Z

CL = 3

Command

0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15

LAL RDA RDA LAL RDA LAL

Address UA LA UA LA UA LA

Bank Add. Bank

"a"

DQS/DQS

(output) CL = 3

(output)

BL = 4

Hi-Z

DQS/DQS

(output)

RDA LAL DESL

IRBD = 2 cycles

RDA LAL RDA

IRBD = 2 cycles IRBD =2 cycles

LAL RDA LAL

UA LA UA LA UA LA UA

Bank

"b" Bank

"a" Bank

"b" Bank

"c" Bank

"d" Bank

"a"

IRC (Bank"a") = 5 cycles

IRC (Bank"b") = 5 cycles

Hi-Z

Note: lRC to the same bank must be satisfied.

TC59LM914AMG doesn’t have DQS .

IRBD = 2 cycles

CL = 3

Qa0 Qa1Qa2Qa3Qb0Qb1Qb2Qb3 Qa0Qa1Qa2Qa3Qb0 Qb1 Qb2 Qb3 Qc0 Qc1Qc2Qc3Qd0

Qa0 Qa1 Qb0Qb1 Qa0Qa1 Qb0 Qb1 Qc0 Qc1 Qd0Qd1

Qd1

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Rev 0.91

MULTIPLE BANK READ TIMING (CL = 4)

RDA

Bank

"b"

CLK

Hi-Z

(output)

BL = 2

IRBD = 2 cycles

Hi-Z CL = 4

Command

0 1 23 4 56789101112 13 1415

LAL RDA RDA LAL RDA LAL

Address UA LA UA LA UA LA

Bank Add. Bank

"a"

DQS/DQS

(output) CL = 4

(output)

BL = 4

Hi-Z

DQS/DQS

(output)

RDA LAL DESL

IRBD = 2 cycles

RDA LAL RDA

IRBD = 2 cycles IRBD =2 cycles

LAL RDA LAL

UA LA UA LA UA LA UA

Bank

"b" Bank

"a" Bank

"b" Bank

"c" Bank

"d" Bank

"a"

IRC (Bank"a") = 5 cycles

IRC (Bank"b") = 5 cycles

Hi-Z

CL = 4

Note: lRC to the same bank must be satisfied.

TC59LM914AMG doesn’t have DQS .

IRBD = 2 cycles

Qa0Qa1 Qb0Qb1 Qa0Qa1 Qb0 Qb1 Qc0Qc1

Qa0Qa1Qa2Qa3Qb0Qb1Qb2Qb3 Qa0Qa1Qa2 Qa3 Qb0 Qb1 Qb2 Qb3Qc0Qc1Qc2

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Rev 0.91

MULTIPLE BANK READ TIMING (CL = 5)

CLK

(output)

BL = 2

Hi-Z

CL = 5

Command

0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15

RDA LAL RDA LAL RDA

Address UA LA UA LA UA

Bank Add. Bank

"a"

DQS/DQS

(output) CL = 5

(output)

BL = 4

Hi-Z

DQS/DQS

(output)

RDA LAL LAL RDA LAL RDA LAL RDA

UA LA LA UA LA UA LA UA

Bank

"b" Bank

"a"

Bank

"b" Bank

"c" Bank

"d"

IRC (Bank"a") = 6 cycles

IRC (Bank"b") = 6 cycles

Hi-Z

CL = 5

DESL

Bank

"a"

IRBD = 2 cycles IRBD = 2 cycles IRBD = 2 cycles IRBD = 2 cycles IRBD = 2 cycles

LAL

Note: lRC to the same bank must be satisfied.

TC59LM914AMG doesn’t have DQS .

Qa0Qa1Qa2Qa3Qb0Qb1Qb2Qb3 Qa0 Qa1 Qa2 Qa3Qb0Qb1Qb2

Qa0Qa1 Qb0Qb1 Qa0 Qa1 Qb0Qb1

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Rev 0.91

MULTIPLE BANK WRITE TIMING (CL = 3)

CLK

DQS/DQS

(input)

BL = 2

WL = 2

Command

0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15

LAL WRA WRA LAL WRA LAL

Address UA LA UA LA UA LA

Bank Add. Bank

"a"

WL = 2

DQS/DQS

(input)

BL = 4

WRA LAL DESL WRA LAL WRA LAL WRA LAL

UA LA UA LA UA LA UA LA

Bank

"b" Bank

"a" Bank

"b" Bank

"c" Bank

"d" Bank

"a"

IRC (Bank"a") = 5 cycles

IRC (Bank"b") = 5 cycles

Db0Db1 Da0Da1 Db0Db1 Dc0 Dc1

Da0 Da1 Da2 Da3Db0Db1Db2Db3 Da0Da1Da2Da3Db0Db1Db2 Db3 Dc0 Dc1 Dc2 Dc3

Note: lRC to the same bank must be satisfied.

TC59LM914AMG doesn’t have DQS .

IRBD = 2 cycles IRBD = 2 cycles IRBD = 2 cycles IRBD = 2 cycles IRBD = 2 cycles

Da0 Da1 Dd0Dd1

Dd0Dd1

WRA

Bank

"b"

WL = 2

Dd2Dd3

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Rev 0.91

MULTIPLE BANK WRITE TIMING (CL = 4)

CLK

DQS/DQS

(input)

BL = 2

WL = 3

Command

0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15

LAL WRA WRA LAL WRA LAL

Address UA LA UA LA UA LA

Bank Add. Bank

"a"

WL = 3

DQS/DQS

(input)

BL = 4

WRA LAL DESL WRA LAL WRA LAL WRA LAL

UA LA UA LA UA LA UA LA

Bank

"b" Bank

"a" Bank

"b" Bank

"c" Bank

"d" Bank

"a"

IRC (Bank"a") = 5 cycles

IRC (Bank"b") = 5 cycles

Db0Db1 Da0Da1 Db0 Db1 Dc0 Dc1

Da0 Da1Da2Da3Db0Db1Db2Db3 Da0Da1Da2Da3Db0 Db1 Db2 Db3 Dc0 Dc1 Dc2Dc3

Note: lRC to the same bank must be satisfied.

TC59LM914AMG doesn’t have DQS .

IRBD = 2 cycles IRBD = 2 cycles IRBD = 2 cycles IRBD = 2 cyclesIRBD = 2 cycles

Da0 Da1 Dd0Dd1

WL = 3

Dd0Dd1

WRA

Bank

"b"

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Rev 0.91

MULTIPLE BANK WRITE TIMING (CL = 5)

CLK

DQS/DQS

(input)

BL = 2

WL = 4

Command

0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15

Address

Bank Add.

WL = 4

DQSDQS

(input)

BL = 4

IRC (Bank"a") = 6 cycles

IRC (Bank"b") = 6 cycles

Db0Db1 Da0 Da1 Db0 Db1 Dc0Dc1

Da0Da1Da2Da3Db0Db1Db2Db3 Da0 Da1 Da2 Da3 Db0 Db1 Db2Db3Dc0Dc1

Note: lRC to the same bank must be satisfied.

TC59LM914AMG doesn’t have DQS .

IRBD = 2 cycles IRBD = 2 cycles IRBD = 2 cyclesIRBD = 2 cycles IRBD = 2 cycles

Da0Da1

WL = 4

WRA LAL WRA LAL WRAWRA LAL LAL WRA LAL WRA LAL WRA

DESL LAL

UA LA UA LA UA LAUA LA UA LA UA LA UA LA

Bank

"a" Bank

"b" Bank

"a" Bank

"b" Bank

"c" Bank

"d" Bank

"a"

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Rev 0.91

MULTIPLE BANK READ-WRITE TIMING (BL = 2)

CLK

DQS

CL = 4

IRBD = 2 cycles

WL = 3

Command

0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15

Address

Bank Add.

CL =4

IRC (Bank"a")

IRC (Bank"b")

DQS

CL = 5

WL = 4

DQS

CL = 5

Note: lRC to the same bank must be satisfied.

TC59LM914AMG doesn’t have DQS .

DQS

CL = 3

WL = 2 CL = 3

DQS

IWRD = 1 cycle IRWD

2 cycles WRADESLWRAWRA RDA LAL LAL DESLRDALAL LAL RDA LAL LAL WRADESL

UA LA UA LA LA UA LA UA LA UA LA UAUA

Bank

"a" Bank

"b" Bank

"a" Bank

"d" Bank

"a" Bank

"b" Bank

"c"

Qb0Qb1 Dc0Dc1 Qd0 Qd1 Da0 Da1 Da0 Da1

Qb0Qb1 Dc0Dc1 Qd0 Qd1 Da0Da1Da0 Da1

Qb0Qb1 Dc0Dc1 Qd0 Qd1 Da0Da1Da0Da1

IWRD = 1 cycle IRWD = 2 cycles IWRD

1 cycle IRWD

2 cycles

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Rev 0.91

MULTIPLE BANK READ-WRITE TIMING (BL = 4)

CLK

DQS

CL = 4

IRBD = 2 cycles

WL = 3

Command

0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15

Address

Bank Add.

CL = 4

IRC (Bank"a")

IRC (Bank"b")

IWRD = 1 cycle IRWD = 3 cycles IWRD

1 cycle IRWD

3 cycles

DQS

CL = 5

WL = 4

DQS

CL = 5

Note: lRC to the same bank must be satisfied.

TC59LM914AMG doesn’t have DQS .

IWRD = 1 cycle

DQS

CL = 3

WL = 2 CL = 3

DQS

IWRD = 1 cycle IRWD

2 cycles WRA WRA RDA LAL LAL DESLRDALAL LAL RDALAL LALWRADESL

UA LA UA LA LA UA LA UA LA UAUA LA

Bank

"a" Bank

"b" Bank

"c" Bank

"d" Bank

"a" Bank

"b"

Qb0Qb1 Dc0Dc1 Qd0 Qd1 Qd2 Qd3Da0 Da1 Da2 Da3 Qb2Qb3 Dc2Dc3

Qb0Qb1 Dc0Dc1 Qd0 Qd1Qd2Qd3Da0 Da1Da2Da3 Qb2Qb3 Dc2 Dc3

Qb0Qb1 Dc0 Dc1 Qd0Qd1Qd2Da0Da1Da2Da3 Qb2Qb3 Dc2 Dc3 Qd3

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Rev 0.91

WRITE with VARIAVLE WRITE LENGTH (VW) CONTROL (CL = 4)

CLK

DQS/DQS

(input)

Command

0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15

WRA LAL WRA LALDESL

Address UA LA=#3

VW=All UA

Bank Add. Bank

"a" Bank

"a"

BL = 2, SEQUENTIAL MODE

DESL

LA=#1

VW=1

VW0 = Low

VW1 = don't care VW0 = High

VW1 = don't care

(input) D0D0 D1

Lower Address #3 #2 #1

(

)

Last one data is masked.

DQS/DQS

(input)

Command WRA LAL WRA LALDESL

Address UA LA=#3

VW=All UA

Bank Add. Bank

"a" Bank

"a"

BL = 4, SEQUENTIAL MODE

DESL

LA=#1

VW=1

(input) D0D0 D1

Lower Address #3 #0 #1

(

)(

)

Last three data are masked.

DESL WRA LAL

VW0 = Hig h

VW1 = Low VW0 = High

VW1 = Hig h

UA LA=#2

VW=2

VW0 = Low

VW1 = High

Bank

"a"

D2 D3 D0 D1

#1 #2

Last two data are masked.

(

)(

)

#2 #3

Note: DQS (DQS ) input must be continued till end of burst count even if some of laster data is masked.

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Rev 0.91

POWER DOWN TIMING (CL = 4, BL = 4)

Read cycle to Power Do wn Mode

CLK

0 1 2 3 4 5 6 7 8 9 10 n-1 n n+1 n+2 n+3

IPDA

tIH tIS IPD = 1 cycle

tPDEX

Power Down Entry Power Down Exit

Note: PD must be kept "High" level until end of Burst data output.

PD should be brought to "High" within tREFI(max.) to maintain the data written into cell.

In Power Down Mode, PD "Low" and a stable clock signal must be maintained.

When PD is brought to "High", a valid executable command may be applied lPDA cycles later.

TC59LM914AMG doesn’t have DQS .

DQS

(output)

Command RDA LAL DESL

Address UA UA

DESL RDA

WRA

lRC(min) , tREFI(max)

tQPDH

DQS

(output)

Hi-Z

CL = 4

Hi-Z

(output)

Hi-Z

Q0 Q1 Q2 Q3

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Rev 0.91

POWER DOWN TIMING (CL = 4, BL = 4)

Write cycle to Power Down Mode

CLK

0 1 2 3 4 5 6 7 8 9 10 n-1 n n+1 n+2 n+3

IPDA

tIH tIS IPD = 1 cycle

tPDEX

Note: PD must be kept "High" level until WL+2 clock cycles from LAL command.

PD should be brought to "High" within tREFI(max.) to maintain the data written into cell.

In Power Down Mode, PD "Low" and a stable clock signal must be maintained.

When PD is brought to "High", a valid executable command may be applied lPDA cycles later.

TC59LM914AMG doesn’t have DQS .

DQS

(input)

Command WRA LAL DESL

Address UA UA

DESL RDA

WRA

lRC(min) , tREFI(max)

DQS

(input)

WL = 3

D0 D1 D2 D3

(input)

2 clock cyclesWL = 3

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Rev 0.91

MODE REGISTER SET TIMING (CL = 4, BL = 2)

From Read operation to Mode Register Set operation.

CLK

DQS

(output)

Command

0 1 2 3 4 5 6 7 8 9 10 11 12 13 14

RDA LAL RDA MRSDESL

A13~A0 UA Valid

(opcode)

DQS

IRSC

DESL RD

LA UA

BA0~BA2 BA BA0="0"

BA1="0"

BA2="0" BA

LAL

(output)

CL + BL/2

Hi-Z

Q0 Q1

Note: Minimum delay from LAL following RDA to RDA of MRS operation is CL+BL/2.

TC59LM914AMG doesn’t have DQS .

Hi-Z

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Rev 0.91

MODE REGISTER SET TIMING (CL = 4, BL = 4)

From Write operation to Mode Register Set operation.

CLK

DQS

(input)

Command

0 1 2 3 4 5 6 7 8 9 10 11 12 13 14

WRA LAL RDA MRSDESL

A13~A0 UA Valid

(opcode)

DQS

(input)

IRSC

DESL RD

LA UA

BA0~BA2 BA BA0="0"

BA1="0"

BA2="0" BA

D0 D1 D2 D3

(input)

WL+BL/2

LAL

Note: Minimum delay from LAL following WRA to RDA of MRS operation is WL+BL/2.

TC59LM914AMG doesn’t have DQS .

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Rev 0.91

EXTENDED MODE REGISTER SET TIMING (CL = 4, BL = 2)

From Read operation to Extended Mod e Register Set operation.

CLK

DQS

(output)

Command

0 1 2 3 4 5 6 7 8 9 10 11 12 13 14

RDA LAL RDA MRSDESL

A13~A0 UA Valid

(opcode)

DQS

(output)

IRSC

DESL RD

LA UA

BA0~BA2 BA BA0="1"

BA1="0"

BA2="0" BA

(output)

CL + BL/2

Hi-Z

Q0 Q1

Note: Minimum delay from LAL following RDA to RDA of EMRS operation is CL+BL/2.

DLL switch in Extended Mode Register must be set to enable mode for normal operation.

DLL lock-on time is needed after initial EMRS operation. See Power Up Sequence.

TC59LM914AMG doesn’t have DQS .

LAL

Hi-Z

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Rev 0.91

EXTENDED MODE REGISTER SET TIMING (CL = 4, BL = 4)

From Write operation to Extended Mode Register Set operation.

CLK

DQS

(input)

Command

0 1 2 3 4 5 6 7 8 9 10 11 12 13 14

WRA LAL RDA MRSDESL

A13~A0 UA Valid

(opcode)

DQS

(input)

WL+BL/2

IRSC

DESL RD

LA UA

BA0~BA2 BA BA0="1"

BA1="0"

BA2="0" BA

D0 D1 D2 D3

(input)

Note: DLL switch in Extended Mode Register must be set to enable mode for normal operation.

DLL lock-on time is needed after initial EMRS operation. See Power Up Sequence.

Minimum delay from LAL following WRA to RDA of EMRS operation is WL+BL/2.

TC59LM914AMG doesn’t have DQS .

LAL

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Rev 0.91

AUTO-REFRESH TIMING (CL = 4, BL = 4)

WRA REF WRA REF WRA REF WRA REF WRA REF

t1 t2 t3t7t8

8 Refresh cycle

tREFI =Total time of 8 Refresh cycle

t1 + t2 + t3 + t4 + t5 + t6 + t7 + t8

tREFI is specified to avoid partly concentrated current of Refresh operation that is activated larger area

than Read / Write operation.

CLK

Hi-Z DQS/DQS

(output)

0 1 2 3 4 5 6 7 n − 1n n + 1 n + 2

RDA LAL

Hi-Z Hi-Z

CL = 4

Command

IRC = 5 cycles

DESL RD

LAL o

MRS or

REF

IRCD = 1 cycle

Note: In case of CL = 4, IREFC must be meet 18 clock cycles.

When the Auto-Refresh operation is performed, the synthetic average interval of Auto-Refresh

command specified by tREFI must be satisfied.

tREFI is average interval time in 8 Refresh cycles that is sampled randomly.

TC59LM914AMG doesn’t have DQS .

WRA REF

IREFC = 18 cycles

Hi-Z

IRAS = 4 cycles IRCD = 1 cycle

DESL

Bank,

UA LA Bank, Address

Q0 Q1 Q2 Q3

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Rev 0.91

SELF-REFRESH ENTRY TIMING

SELF-REFRESH EXIT TIMING

Notes: 1. is don’t care.

2. Clock should be stable prior to PD = “High” if clock input is suspended in Self-Refresh mode.

3. DESL command must be asserted during IREFC after PD is brought to “High”.

4. IPDA is defined from the first clock rising edge after PD is brought to “High”.

5. It is desirable that one Auto-Refresh command is issued just after Self-Refresh Exit before any

other operation.

6. Any command (except Read command) can be issued after IREFC.

7. Read command (RDA + LAL) can be issued after ILOCK.

8. TC59LM914AMG doesn’t have DQS .

CLK

Hi-Z

DQS/DQS

(output)

0 1 2 m − 1mm + 1m + 2

Hi-Z

Command

ILOCK

tPDEX

IPD

1 cycles

DESL*3 LAL*7

WRA*5REF*5DESL RDA*7

n − 1nn + 1 p − 1 p

Command (1st)

Command (2nd)

IRCD

1 cycle

Self-Refresh Exit

REFC

IREFC

IRCD

1 cycle

Notes: 1. is don’t care.

2. PD must be brought to "Low" within the timing between tFPDL(min) and tFPDL(max) to Self

Refresh mode. When PD is brought to "Low" after lPDV, FCRAM perform Auto Refresh and enter

Power down mode. In case of PD fall between tFPDL(max) and lPDV, FCRAM will either entry

Self-Refresh mode or Power down mode after Auto-Refresh operation. It can’t be specified which

mode FCRAM operates.

3. It is desirable that clock input is continued at least lCKD from REF command even though PD is

brought to “Low” for Self-Refresh Entry.

4. TC59LM914AMG doesn’t have DQS .

CLK

Hi-Z

DQS/DQS

(output)

0 1 2 3 4 5 m − 1mm + 1

WRA REF

Qx Hi-Z

Command

IRCD = 1 cycle I

REFC

DESL

tFPDL (min) tFPDL (max)

IPDV

ICKD

tQPDH

Auto Refresh

Self Refresh Entry

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Rev 0.91

FUNCTIONAL DESCRIPTION

Network FCRAMTM

FCRAMTM is an acronym of Fast Cycle Random Access Memory. The Network FCRAMTM is competent to

perform fast random core access, low latency and high-speed data transfer.

PIN FUNCTIONS

CLOCK INPUTS: CLK &

The CLK and CLK inputs are used as the reference for synchronous operation. CLK is master clock input. The

CS , FN and all address input signals are sampled on the crossing of the positive edge of CLK and the negative

edge of CLK . The DQS and DQ output are aligned to the crossing point of CLK and CLK . The timing reference

point for the differential clock is when the CLK and CLK signals cross during a transition.

POWER DOWN:

The PD input controls the entry to the Power Down or Self-Refresh modes. The PD input does not have a Clock

Suspend function like a CKE input of a standard SDRAMs, therefore it is illegal to bring PD pin into low state if

any Read or Write operation is being performed.

CHIP SELECT & FUNCTION CONTROL: & FN

The CS and FN inputs are a control signal fo r forming the operation commands on FCRAMTM. Each operation

mode is decided by the combination of the two consecutive operation commands using the CS and FN inputs.

BANK ADDRESSES: BA0~BA2

The BA0 to BA2 inputs are latched at the time of assertion of the RDA or WRA command and are selected the

bank to be used for the operation. BA0 and BA1 also define which mode register is loaded during the Mode Register

Set command (MRS or EMRS).

BA0 BA1 BA2

Bank #0 0 0 0

Bank #1 1 0 0

Bank #2 0 1 0

Bank #3 1 1 0

Bank #4 0 0 1

Bank #5 1 0 1

Bank #6 0 1 1

Bank #7 1 1 1

Also, when BA2 input assign to A14 input, TC59LM914/06AMG can func tion as 4 bank devices and can keep

backward compatibili ty to 256Mb (4bank) Network FCRAM.

ADDRESS INPUTS: A0~A13

Address inputs are used to access the arbitrary address of the memory cell array within each bank. The

Upper Addresses with Bank addresses are latched at the RDA or WRA command and the Lower Addresses are

latched at the LAL command. The A0 to A13 inputs are also used for setting the data in the Regular or

Extended Mode Register set cycle.

I/O organization UPPER ADDRESS LOWER ADDRESS

8 bits A0~A13 A0~A8

8 bank operation 16 bits A0~A13 A0~A7

8 bits A0~A13, BA2(A14) A0~A8

4 bank operation 16 bits A0~A13, BA2(A14) A0~A7

CLK

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Rev 0.91

DATA INPUT/OUTPUT: DQ0~DQ7 or DQ15

The input data of DQ0 to DQ15 are taken in synchronizing with the both edges of DQS input signal. The output

data of DQ0 to DQ15 are outputted synchronizing with the both edges of DQS output signal.

DATA STROBE: DQS, DQS

The DQS is bi-directional signal. Both edge of DQS are used as the reference of data input or output. In write

operation, the DQS used as an input signal is utilized for a latch of write data. In read operation, the DQS is an

output signal provides the read data strobe.

TC59LM906AMG has differential data strobe pin ( DQS ). When DQS is enable mode, DQS is differential

output signal for DQS in read operation, data input are latched at the crossing point of DQS and DQS in Write

operation. When DQS is disable mode, DQS is always Hi-Z, and data input are latched at the crossing point of

DQS and VREF level. DQS mode is set at Ex tended Mode Register Set Cycle.

TC59LM914AMG doesn’t have DQS pin. Data input are latched at the crossing point of L/UDQS and VREF

level in Write operation. LDQS is strobe signal for DQ0-DQ7. UDQS is strobe signal for DQ8-DQ15.

POWER SUPPLY: VDD, VDDQ, VSS, VSSQ

VDD and VSS are power supply pins for memory core and peripheral circuits.

VDDQ and VSSQ are power supply pins for the output buffer.

REFERENCE VOLTAGE: VREF

VREF is reference voltage for all input signals.

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Rev 0.91

COMMAND FUNCTIONS and OPERATIONS

TC59LM914/06AMG are introduced the two consecutive command input method. Therefore, except for Power

Down mode, each operation mode decided by the combination of the first command and the second command from

stand-by states of the bank to be accessed.

Read Operation (1st command + 2nd command = RDA + LAL)

Issuing the RDA command with Bank Addresses and Upper Addresses to the idle bank puts the bank

designated by Bank Addr ess in a re ad mod e. Wh en th e LAL command with Lower Addresses i s i ssu ed at the ne xt

clock of the RDA command, the data is read out sequentially synchronizing with the both edges of DQS/DQS

output signal (Burst Read Oper ation). The initial valid read data appe ars after CAS latency from the issuing of

the LAL command. The valid data is outputted for a burst length. The CAS latency, the burst length of read

data and the burst type must be set in the Mode Register beforehand. The read operated bank goes back

automatically to the idle state after lRC. DQS is differen tial data strobe signal su pported TC59LM906AMG.

Write Operation (1st command + 2nd command = WRA + LAL)

Issuing the WRA command with Bank Addresses and Upper Addresses to the idle bank puts the bank

designated by Bank Address in a write mode. When the LAL command with Lower Addresses is issued at the

next clock of the WRA command, the input data is latched sequentially synchronizing with the both edges of

DQS/DQS input signal (Bu rst Write Operation). Th e data and DQS/DQS inputs have to be asserted in keeping

with clock input after CAS latency-1 from the issuing of the LAL command. The DQS/DQS h as to be provided

for a burst length. Th e CAS latency and th e burst type must be set in the Mo de Register beforehand. Th e write

operated bank goes back automatically to the idle state after lRC. Write Burst Length is controlled by VW0 and

VW1 inputs with LAL command. See VW truth table. DQS is differential data strobe signal supported

TC59LM906AMG.

Auto-Refresh Operation (1st command + 2nd command = WRA + REF)

TC59LM914/06AMG are r e quired to refresh like a standard SDRAM. The Auto-Refresh operation is beg un with

the REF command following to the WRA command. The Auto-Refresh mode can be effective only when all banks

are in the idle state. In a point to notice, the write mode started with the WRA command is canceled by the REF

command having gone into the next clock of the WRA command instead of the LAL command. The minimum

period between the Auto-Refresh command and the next command is specified by lREFC. However, about a

synthetic average interval of Auto-Refresh command, it must be careful. In case of equally distributed refresh,

Auto-Refresh command h as to be issued within once for every 7.8 µs by the maxi mum. In case of burst refresh or

random distributed refr esh, the average interv al of eight consecutiv e Auto-Refresh command h as to be more than

400 ns always. In other words, th e number of Auto-Refresh cycles that be perfor med within 3.2 µs (8 × 400 ns) is

to 8 times in the maximu m.

Self-Refresh Operation (1st command + 2nd command = WRA + REF with = “L”)

In case of Self-Refresh operation, refresh operation can be performed automatically by u sing an internal timer.

When all banks are in the idle state and all outputs are in Hi-Z states, the TC59LM914/06AMG become

Self-Refresh mode by issu ing the Self-Refresh command. PD has to be brought to “Low” within tFPDL from the

REF command following to the WRA command for a Self-Refresh mode entry. In order to satisfy the refresh

period, the Self-Refresh entry command should be asserted within 7.8 µs after the latest Auto-Refresh command.

Once the device enters Self-Refresh mode, the DESL command must be continued for lREFC period. In addition, it

is desirable that clock input is kept in lCKD period. The device is in Self-Refresh mode as long as PD held “Low”.

During Self-Refresh mode, all input and output buffers are disabled except for PD , therefore the power

dissipation lowers. Regarding a Self-Refresh mode exit, PD has to be changed over from “Low” to “High” along

with the DESL command, and the DESL command has to be continuously issued in the number of clocks specified

by lREFC. The Self-Refresh exit function is asynchronous operation. It is required that one Auto-Refresh

command is issued to avoid the violation of the refresh period just after lREFC from Self-Refresh exit.

Power Down Mode ( = “L”)

When all banks are in th e idle state an d DQ outputs are in Hi-Z states, th e TC59LM914/06 AMG become Powe r

Down Mode by asserting PD is “Low”. When the device enters the Power Down Mode, all input and output

buffers are disabled after specified time except for PD . Therefore, the power dissipation lowers. To exit the

Power Down Mode, PD h as to be brought to “High” and the DESL command has to be issued for two clock cycle

after PD goes high. The Power Down exit function is asynchronous operation.

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Mode Register Set (MRS) and Extended Mode Register Set (EMRS)

(1st command + 2nd command = RDA + MRS)

When all banks are in the idle state, issuing the MRS command following to the RDA command can program

the Mode Register. In a point to notice, the read mode started with the RDA command is canceled by the MRS

command having gone into the next clock of the RDA command instead of the LAL command. The data to be set

in the Mode Register is transferred using A0 to A14, BA0 to BA1 address inputs. The TC59LM914/06AMG have

two mode registers. These are Regular and Extended Mode Register. The Regular or Extended Mode Register is

chosen by BA0 and BA1 in the MRS command. The Regular Mode Register designates the operation mode for a

read or write cycle. The Regular Mode Register has four function fields.

The four fields are as follows:

(R-1) Burst Length field to set the length of burst data

(R-2) Burst Type field to designate the lower address access sequence in a bur st cycle

(R-3) CAS Latency field to set the access time in clock cycle

(R-4) Test Mode field to use for supplier only.

The Extended Mode Register has five function fields.

The five fields are as follows:

(E-1) DLL Switch field to choose either DLL enable or DLL disable

(E-2) Output Driver Impedance Control field.

(E-3) Off-Chip Driver (OCD) Impedance Adjustment

(E-4)DQS enable field

(E-5) Interface mode select

Once those fields in the Mode Register are set up, the register contents are maintained until the Mode Register

is set up again by another MRS command or power supply is lost. The initial value of the Regular or Extended

Mode Register after power-up is undefined, therefore the Mode Register Set command must be issued before

proper operation.

• Regular Mode Register/Extended Mode Register change bits (BA0, BA1)

These bits are used to choose either Regular MRS or Extended MRS

BA1 BA0 Mode Register Set

0 0 Regular MRS

0 1 Extended MRS

1 × Reserved

Regular Mode Register Fields

(R-1) Burst Length field (A2 to A0), (BL)

This field specifies the data length for column access using the A2 to A0 pins and sets the Burst Length

to be 2 or 4 words.

A2 A1 A0 BURST LENGTH

0 0 0 Reserved

0 0 1 2 words

0 1 0 4 words

0 1 1 Reserved

1 × × Reserved

(R-2) Burst Type field (A3), (BT)

The Burst Type can be chosen Interleave mode or Sequential mode. When the A3 bit is “0”, Sequential

mode is selected. When the A3 bit is “1”, Interleave mode is selected. Both burst types support burst

length of 2 and 4 words.

A3 BURST TYPE

0 Sequential

1 Interleave

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• Addressing sequence of Sequential mode

A column access is started from the inputted lower address and is performed by incrementing the lower

address input to the device.

Addressing sequence for Sequential mode

DATA ACCESS ADDRESS BURST LENGTH

Data 0 n

Data 1 n + 1

Data 2 n + 2

Data 3 n + 3

2 words (address bits is LA0)

not carried from LA0~LA1

4 words (address bits is LA1, LA0)

not carried from LA1~LA2

• Addressing sequence of Interleave mode

A column ac cess is started from the inpu tted lower address and is perf ormed by interleav ing the address bits

in the sequence shown as th e following.

Addressing sequence for Interleave mode

DATA ACCESS ADDRESS BURST LENGTH

Data 0 ּּּA8 A7 A6 A5 A4 A3 A2 A1 A0

Data 1 ּּּA8 A7 A6 A5 A4 A3 A2 A1 0A

Data 2 ּּּA8 A7 A6 A5 A4 A3 A2 1A A0

Data 3 ּּּA8 A7 A6 A5 A4 A3 A2 1A 0A

2 words

4 words

(R-3) CAS Latency field (A6 to A4), (CL)

This field specifies the number of clock cycles from the assertion of the LAL command following the

RDA command to the first data read. The minimum values of CAS Latency depends on the frequency

of CLK. In a write mode, the place of clock that should input write data is CAS Latency cycles − 1.

A6 A5 A4 CAS LATENCY

0 0 0 Reserved

0 0 1 Reserved

0 1 0 Reserved

0 1 1 3

1 0 0 4

1 0 1 5

1 1 0 Reserved

1 1 1 Reserved

(R-4) Test Mode field (A7), (TE)

This bit is used to enter Test Mode for supplier only and must be set to “0” for normal operation.

(R-5) Reserved field in the Regular Mode Register

• Reserved bits (A8 to A14, B A1)

These bits are reserved for future operations. They must be set to “0” for normal operation.

CLK

Command

DQS/ DQS

DQ Data

Data

RDA LAL

CAS Latency = 4

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Extended Mode Register fields

(E-1) DLL Switch field (A0), (DS)

This bit is used to enable D LL. When the A0 bit is set “0”, DLL is enabled. This bit must set to “ 0” for

normal operation.

(E-2) Output Driver Impedance Control field (A1, A6) (DIC)

This field is used to choose Output Driver Strength. Three types of Driver Strength are supported.

Output Driver Strength can be set by field in EMRS with OCD calibration default (A7~A9=0 at EMRS).

A6 A1 OUTPUT DRIVER IMPEDANCE CONTROL

0 0 Normal Output Driver

0 1 Strong Output Driver

1 0 Weak Output Driver

1 1 Reserved

(E-3) Off-Chip Driver (OCD) Impedance Adjustment (A7 to A9) (OCD)

Output Driver Strength can be set by DIC field (E-2). This Driver strength is initial driver level at OCD

Impedance Adjustment. When OCD Impedance Adjustment cycle (A7 or A8 or A9 = 1 in EMRS), DIC filed

(A6 and A1) is ignored.

The Network FCRAMTM supports driver calibration feature and the flow chart below is an example of

sequence. Every calibration mode command should be followed by “OCD calibration mode exit” before

any other command being issued. MRS should be set before entering OCD impedance adjustment.

EMRS: OCD calibration mode exit

MRS should be set before entering OCD impedance adjustment.

EMRS: Drive(1)

DQ &DQS High; DQS Low

Tes t

Start

EMRS: OCD calibration mode exit

EMRS:

Enter Adjust Mode

BL=4 code Input to all DQs

Inc, Dec, or NOP

EMRS: OCD calibration mode exit

EMRS: Drive(0)

DQ &DQS Low; DQS High

LL OK Tes t

EMRS: OCD calibration mode exit

EMRS:

Enter Adjust Mode

BL=4 code Input to all DQs

Inc, Dec, or NOP

EMRS: OCD calibration mode exit

LL OK

Need Calibration Need Calibration

EMRS: OCD calibration mode exit

End

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Extended Mode Register Set for OCD Impedance adjustment

OCD impedance adjustment can be done using the following EMRS mode. In drive mode all outputs are

driven out by Network FCRAM. In drive (1) mode, all DQ, DQS signals are driven high and DQS signals are

driven low. In drive (0) mode, all DQ, DQS signals are driven low and DQS signals are driv en high. In adjust

mode, BL=4 of operation code data must be used

A9 A8 A7 Operation

0 0 0 OCD calibration default

0 0 1 Drive (1) DQ, DQS high and DQS low

0 1 0 Drive (0) DQ, DQS low and DQS high

1 0 0 Adjust mode

1 1 1 OCD calibration mode exit

OCD impedance adjust

To adjust output driver impedance, controllers must issue the ADJUST EMRS command along with a 4bit

burst code to Network FCRAM. For this operation, Burst Length has to be set to BL=4 via MRS command

before activating OCD and controllers must drive this burst code to all DQs at the same time. DT0 means all

DQ bits at bit time 0, DT1 at bit time 1, and so forth. The driver output impedance is adjusted for all DQs

simultaneously and after OCD calibration, all DQs of a given Network FCRAM will be adjusted to the same

driver strength setting. The maximum step count for adjustment is 16 and when the limit is reached, further

increment or decrement code has no effect.

Off-Chip Driver Program

4bit burst code inputs to all DQs Operation

DT0 D

T1 D

T2 D

T3 Pull-up driver strength Pull-down driver strentgth

0 0 0 0 NOP (No operation) NOP (No operation)

0 0 0 1 Increase by 1 step NOP

0 0 1 0 Decrease by 1 step NOP

0 1 0 0 NOP Increase by 1 step

1 0 0 0 NOP Decrease by 1 step

0 1 0 1 Increase by 1 step Increase by 1 step

0 1 1 0 Decrease by 1 step Increase by 1 step

1 0 0 1 Increase by 1 step Decrease by 1 step

1 0 1 0 Decrease by 1 step Decrease by 1 step

Other Combinations Reserved

For proper operation of adjust mode, WL=CL-1 clocks and tDS / tDH should be met as the following timing

diagram. For input data pattern for adjustment, DT0~DT3 is a fixed order and “not affected by MRS

addressing mode (i.e. Sequential or interleave).

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Drive mode

Drive mode, both Drive (1) and Drive (0), is used for controllers to measure Network FCRAM Driver

impedance. In this mode, all outputs are driven out tOIT after “enter drive mode” command and all output

drivers are turned-off tOIT after “OCD calibration mode exit” command as the following timing diagram.

(E-4) DQSenable field (A10), ( DQS)

This bit is used to enable Differential Data strobe.

DQS is available on TC59LM 906AMG. This field of TC59LM914AMG is igno red.

A10 DQS Enable

0 Disable

1 Enable

(E-5) Interface mode select (A11)

This bit must be always set “0”.

(E-6) Reserved field (A2 to A5, A12 to A14)

These bits are reserved for future operations and mu st be set to “0” for normal operation.

Command RDA EMRS

OCD adjust mode

NOP NOP NOP NOP RDA EMRS NOP

DQS_in

DQ_in DT0 DT1 DT2 DT3

DQS

tDS tDH

CLK

OCD calibration mode exit

WL 1clock

Command

Enter Drive mode

DQS,

DQS

CLK

OCD calibration mode exit

RDA EMRS NOP NOP RDA EMRS NOP

tOIT

DQs high for Drive (1), DQs low for Drive (0)

DQS high & DQS low for Drive (1), DQS low & DQS high for Drive (0)

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Rev 0.91

PACKAGE DIMENSIONS

0.2 SB

0.2 SA

0.08 SAB

13.086

-0.15

16.5

10.975

-0.15

12.7

0.15 0.1

0.2 S

0.15MIN

1.20MAX 0.4 0.05

1.5 1.5

123456

INDEX

1.0

2.0

1.25

3.85 3.85

1.85

1.0

0.5 0.05

P-BGA64-1317-1.00AZ

Note: In order to support a package, four outer balls located on F and K row are required to assembly to board.

These four ball is not connected to any electrical level.

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Rev 0.91

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(computer, personal equipment, office equipment, measuring equipment, industrial robotics, domestic appliances,

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• The information contained herein is subject to change without notice.

000707EB

RESTRICTIONS ON P RODUCT USE