1/3January 2002
PSD3XX ZPSD3XX ZPSD3XXV
PSD3XXR ZPSD3XXR ZPSD3XXRV
Low Cost Field Programmable Microcontroller Peripherals
FEATURES SUM M ARY
Single Supply Voltage:
5 V±10% for PSD3xx, ZPSD3xx, PSD3xxR,
ZPSD3xxR
2 .7 to 5 .5 V for ZP SD3 xxV, ZP SD3 x xRV
Up to 1 Mbit of E PR OM
Up to 16 Kbit SRAM
Input Latches
Program mab le I/O ports
Page Logic
Program mable Se curity
Figure 1. Packages
PLDCC44 (J)
CLDCC44 (L)
PQFP44 (M)
TQFP44 (U)
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i
PSD3XX Family
PSD3XX ZPSD3XX ZPSD3XXV
PSD3XXR ZPSD3XXR ZPSD3XXRV
Low Cost Microcontroller Peripherals
Table of Contents
1 Introduction...........................................................................................................................................................1
2 Notation ................................................................................................................................................................2
3 Key Features ........................................................................................................................................................4
4 PSD3XX Family Feature Summary ......................................................................................................................5
5 Partial Listing of Microcontrollers Supported ........................................................................................................6
6 Applications ..........................................................................................................................................................6
7 ZPSD Background................................................................................................................................................6
7.1 Integrated Power ManagementTM Operation.............................................................................................7
8 Operating Modes (MCU Configurations) ............................................................................................................10
9 Programmable Address Decoder (PAD).............................................................................................................12
10 I/O Port Functions...............................................................................................................................................15
10.1 CSIOPORT Registers..............................................................................................................................15
10.2 Port A (PA0-PA7).....................................................................................................................................16
10.2.1 Port A (PA0-PA7) in Multiplexed Address/Data Mode................................................................16
10.2.2 Port A (PA0-PA7) in Non-Multiplexed Address/Data Mode........................................................17
10.3 Port B (PB0-PB7).....................................................................................................................................18
10.3.1 Port B (PA0-PA7) in Multiplexed Address/Data Mode................................................................18
10.3.2 Port B (PA0-PA7) in Non-Multiplexed Address/Data Mode........................................................19
10.4 Port C (PC0-PC2)....................................................................................................................................20
10.5 ALE/AS Input Pin.....................................................................................................................................20
11 PSD Memory ......................................................................................................................................................21
11.1 EPROM....................................................................................................................................................21
11.2 SRAM (Optional)......................................................................................................................................21
11.3 Page Register (Optional).........................................................................................................................21
11.4 Programming and Erasure.......................................................................................................................21
12 Control Signals ...................................................................................................................................................22
12.1 ALE or AS................................................................................................................................................22
12.2 WR or R/W...............................................................................................................................................22
12.3 RD/E/DS (DS option not available on 3X1 devices)................................................................................22
12.4 PSEN or PSEN........................................................................................................................................22
12.5 A19/CSI ...................................................................................................................................................23
12.6 Reset Input ..............................................................................................................................................24
13 Program/Data Space and the 8031....................................................................................................................26
14 Systems Applications..........................................................................................................................................27
15 Security Mode.....................................................................................................................................................30
16 Power Management............................................................................................................................................30
16.1 CSI Input..................................................................................................................................................30
16.2 CMiser Bit................................................................................................................................................30
16.3 Turbo Bit (ZPSD Only).............................................................................................................................31
16.4 Number of Product Terms in the PAD Logic............................................................................................31
16.5 Composite Frequency of the Input Signals to the PAD Logic..................................................................32
16.6 Loading on I/O Pins.................................................................................................................................33
17 Calculating Power...............................................................................................................................................34
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PSD3XX Family
PSD3XX ZPSD3XX ZPSD3XXV
PSD3XXR ZPSD3XXR ZPSD3XXRV
Low Cost Microcontroller Peripherals
Table of Contents
(cont.)
18 Specifications......................................................................................................................................................37
18.1 Absolute Maximum Ratings.....................................................................................................................37
18.2 Operating Range .....................................................................................................................................37
18.3 Recommended Operating Conditions......................................................................................................37
18.4 Pin Capacitance.......................................................................................................................................37
18.5 AC/DC Characteristics – PSD3XX/ZPSD3XX (All 5 V devices)..............................................................38
18.6 AC/DC Characteristics – PSD3XXV (3 V devices only)...........................................................................39
18.7 Timing Parameters – PSD3XX/ZPSD3XX (All 5 V devices)....................................................................40
18.8 Timing Parameters – ZPSD3XXV (3 V devices only)..............................................................................42
18.9 Timing Diagrams for PSD3XX Parts.......................................................................................................44
18.10 AC Testing...............................................................................................................................................65
19 Pin Assignments.................................................................................................................................................66
20 Package Information...........................................................................................................................................67
21 Package Drawings..............................................................................................................................................68
22 PSD3XX Product Ordering Information ..............................................................................................................72
22.1 PSD3XX Selector Guide..........................................................................................................................72
22.2 Part Number Construction.......................................................................................................................73
22.3 Ordering Information................................................................................................................................73
23 Data Sheet Revision History...............................................................................................................................80
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1
1.0
Introduction
Programmable Peripheral
PSD3XX Family
Field-Programmable Microcontroller Peripheral
The low cost PSD3XX family integrates high-performance and user-configurable blocks of
EPROM, programmable logic, and optional SRAM into one part. The PSD3XX products
also provide a powerful microcontroller interface that eliminates the need for external
“glue logic”. The part’s integration, small form factor, low power consumption, and ease of
use make it the ideal part for interfacing to virtually any microcontroller.
The major functional blocks of the PSD3XX include:
Two programmable logic arrays
256Kb to 1 Mb of EPROM
Optional 16 Kb SRAM
Input latches
Programmable I/O ports
Page logic
Programmable security.
The PSD3XX family architecture (Figure 1) can efficiently interface with, and enhance,
almost any 8- or 16-bit microcontroller system. This solution provides microcontrollers the
following:
Chip-select logic, control logic, and latched address signals that are otherwise
implemented discretely
Port expansion (reconstructs lost microcontroller I/O)
Expanded microcontroller address space (up to 16 times)
An EPROM (with security) and optional SRAM
Compatible with 8031-type architectures that use separate Program and Data Space
Interface to shared external resources.
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2.
Notation
For a complete product comparison, refer to Table 1.
PSD3XX references the standard version of the PSD3XX family, which are ideal for
general-purpose embedded control applications.
PSD3XXR SRAM-less version of the PSD3XX. If you don’t require the 16 Kb SRAM or
need a larger external SRAM, go with this part to save cost.
ZPSD3XX has improved technology that helps reduce current consumption using the Turbo
bit. Excellent if you require a 5 V version of the PSD3XX that uses less power.
ZPSD3XXR SRAM-less version of the ZPSD3XX.
ZPSD3XXV 2.7 V to 5.5 V operation, ideal for very low-power and low-voltage
applications.
ZPSD3XXRV SRAM-less version of the ZPSD3XXV.
Throughout this data sheet, references are made to the PSD3XX. In most cases, these
references also cover the entire family. Exceptions will be noted. References, such as
“3X1 only” cover all parts that have a 301 or 311 in the part number. Use the following table
to determine what references cover which product versions:
Reference PSD3XX PSD3XXR ZPSD3XX ZPSD3XXR ZPSD3XXV ZPSD3XXRV
PSD3XX XXX X X X
PSD
PSD3XX only X X
Non-ZPSD X X
ZPSD only
ZPSD3XX X X X X
Non-V versions X X X X
V versions only
V suffix X X
ZPSD3XXV only
SRAM-less XX X
Non-R
The PSD3XX I/O ports can be used for:
Standard I/O ports
Programmable chip select outputs
Address inputs
Demultiplexed address outputs
A data bus port for non-multiplexed MCU applications
A data bus “repeater” port that shares and arbitrates the local MCU data bus with
external devices.
Implementing your design has never been easier than with PSDsoftST’s software
development suite. Using PSDsoft, you can do the following:
Configure your PSD3XX to work with virtually any microcontroller
Specify what you want implemented in the programmable logic using a high-level
Hardware Description Language (HDL)
Simulate your design
Download your design to the part using a programmer.
1.0
Introduction
(cont.)
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PROG.
PORT
EXP.
PORT
C
PC0–
PC2
ES0
ES1
ES2
ES3
ES4
ES5
ES6
ES7
PROG.
CONTROL
SIGNALS
A19/CSI
RESET
WR/R/W
RD/E/DS
ALE/AS
BHE/PSEN
PAD A
RESET
WR
ALE/AS
RD PAD B
A11–A15
PROG.
PORT
EXP.
PORT
B
PB0–
PB7
PROG.
PORT
EXP.
PORT
A
PA0–
PA7
A19/CSI
RESET
ALE/AS
A19/CSI
A8–A10
WR
RD
ALE/AS
L
A
T
C
H
L
A
T
C
H
AD8–AD15
AD0–AD7
D8–D15
13 P.T. 27 P.T.
OPTIONAL
PAGE LOGIC*
LOGIC IN
EPROM
256Kb TO 1Mb
A16–A18
CS8–
CS10
CS0–
CS7
OPTIONAL
SRAM
16K BIT
**
D0–D7
RS0
A0–A7
AD0–AD7/D0–D7
D8–D15
CSIOPORT
PROG. CHIP
CONFIGURATION
X8, X16
MUX or NON–MUX BUSSES
SECURITY MODE
16/8
MUX
CSIOPORT
TRACK MODE
SELECTS
P3–P0
Figure 1.
PSD3XX
Family
Architecture
**Not available for 3X1 devices.
**SRAM not available on “R” versions.
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3.0
Key Features
Single-chip programmable peripheral for microcontroller-based applications
256K to 1 Mbit of UV EPROM with the following features:
Configurable as 32, 64, or 128 K x 8; or as 16, 32, or 64 K x 16
Divided into eight equally-sized mappable blocks for optimized address mapping
As fast as 70 ns access time, which includes address decoding
Optional 16 Kbit SRAM is configurable as 2K x 8 or 1K x 16. The access time can be
as quick as 70 ns, including address decoding.
19 I/O pins that can be individually configured for :
Microcontroller I/O port expansion
Programmable Address decoder (PAD) I/O
Latched address output
Open-drain or CMOS output
Two Programmable Arrays (PAD A and PAD B) replace your PLD or decoder, and have
the following features:
Up to 18 Inputs and 24 outputs
40 Product terms (13 for PAD A and 27 for PAD B)
Ability to decode up to 1 MB of address without paging
Microcontroller logic that eliminates the need for external “glue logic” has the following
features:
Ability to interface to multiplexed and non-multiplexed buses
Built-in address latches for multiplexed address/data bus
ALE and Reset polarity are programmable (Reset polarity not programmable on
V-versions)
Multiple configurations are possible for interface to many different microcontrollers
Optional built-in page logic expands the MCU address space by up to 16 times
Programmable power management with standby current as low as 1µA for low-voltage
version
CMiser bitprogrammable option to reduce AC power consumption in memory
Turbo Bit (ZPSD only)programmable bit to reduce AC and DC power consumption
in the PADs.
Track Mode that allows other microcontrollers or host processors to share access to the
local data bus
Built-in security locks the device and PAD decoding configuration
Wide Operating Voltage Range
V-versions: 2.7 to 5.5 volts
Others: 4.5 to 5.5 volts
Available in a variety of packaging (44-pin PLDCC, CLDCC, TQFP, and PQFP)
Simple, menu-driven software (PSDsoft) allows configuration and design entry on a PC.
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Use the following table to determine which PSD product will fit your needs. Refer back to
this page whenever there is confusion as to which part has what features.
4.0
PSD3XX Family
Feature
Summary
Typical
# PLD EPROM SRAM Page Turbo Bus Standby
Part Inputs Size Size Reg Voltage Bit Width Current
PSD301R 14 256 Kb 5 V x8 or x16 50 µA
PSD311R 14 256 Kb 5 V x8 50 µA
PSD302R 18 512 Kb X 5 V x8 or x16 50 µA
PSD312R 18 512 Kb X 5 V x8 50 µA
PSD303R 18 1 Mb X 5 V x8 or x16 50 µA
PSD313R 18 1 Mb X 5 V x8 50 µA
ZPSD301R 14 256 Kb 5 V X x8 or x16 10 µA
ZPSD311R 14 256 Kb 5 V X x8 10 µA
ZPSD302R 18 512 Kb X 5 V X x8 or x16 10 µA
ZPSD312R 18 512 Kb X 5 V X x8 10 µA
ZPSD303R 18 1 Mb X 5 V X x8 or x16 10 µA
ZPSD313R 18 1 Mb X 5 V X x8 10 µA
PSD301 14 256 Kb 16 Kb 5 V x8 or x16 50 µA
PSD311 14 256 Kb 16 Kb 5 V x8 50 µA
PSD302 18 512 Kb 16 Kb X 5 V x8 or x16 50 µA
PSD312 18 512 Kb 16 Kb X 5 V x8 50 µA
PSD303 18 1 Mb 16 Kb X 5 V x8 or x16 50 µA
PSD313 18 1 Mb 16 Kb X 5 V x8 50 µA
ZPSD301 14 256 Kb 16 Kb 5 V X x8 or x16 10 µA
ZPSD311 14 256 Kb 16 Kb 5 V X x8 10 µA
ZPSD302 18 512 Kb 16 Kb X 5 V X x8 or x16 10 µA
ZPSD312 18 512 Kb 16 Kb X 5 V X x8 10 µA
ZPSD303 18 1 Mb 16 Kb X 5 V X x8 or x16 10 µA
ZPSD313 18 1 Mb 16 Kb X 5 V X x8 10 µA
ZPSD301V114 256 Kb 16 Kb 2.7 V X x8 or x16 1 µA
ZPSD311V114 256 Kb 16 Kb 2.7 V X x8 1 µA
ZPSD302V118 512 Kb 16 Kb X 2.7 V X x8 or x16 1 µA
ZPSD312V118 512 Kb 16 Kb X 2.7 V X x8 1 µA
ZPSD303V118 1 Mb 16 Kb X 2.7 V X x8 or x16 1 µA
ZPSD313V118 1 Mb 16 Kb X 2.7 V X x8 1 µA
NOTES: 1. Low power versions of the ZPSD3XX (ZPSD3XXV) can only accept an active-low level Reset input.
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5.0
Partial Listing
of
Microcontrollers
Supported
PSD3XX Family
6
Motorola family: 68HC11, 68HC16, M68000/10/20, M68008, M683XX, 68HC05C0
Intel family: 80C31, 80C51, 80C196/198, 80C186/188
Philips family: 80C31 and 80C51 based MCUs
Zilog: Z8, Z80, Z180
National: HPC16000, HPC46400
Echelon/Motorola/Toshiba: NEURON®3150Chip
6.0
Applications
Telecommunications:
Cellular phone
Digital PBX
Digital speech
FAX
Digital Signal Processing (DSP)
Portable Industrial Equipment:
Industrial control
Measurement meters
Data recorders
Instrumentation
Medical Instrumentation:
Hearing aids
Monitoring equipment
Diagnostic tools
Computersnotebooks, portable PCs, and palm-top computers:
Peripheral control (fixed disks, laser printers, etc.)
Modem Interface
MCU peripheral interface
Portable and battery-powered systems have recently become major embedded control
application segments. As a result, the demand for electronic components having extremely
low power consumption has increased dramatically. Recognizing this trend, ST
developed a new lower power 3XX part, denoted ZPSD3XX. The Z stands for Zero-power
because ZPSD products virtually eliminate the DC component of power consumption,
reducing it to standby levels. Virtual elimination of the DC component is the basis for the
words “Zero-power” in the ZPSD name. ZPSD products also minimize the AC power
component when the chip is changing states. The result is a programmable microcontroller
peripheral family that replaces discrete circuit components, while drawing less power.
7.0
ZPSD
Background
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7.0
ZPSD
Background
(cont.)
Integrated Power Management
TM
Operation
Upon each address or logic input change to the ZPSD, the device powers up from low
power standby for a short time. Then the ZPSD consumes only the necessary power to
deliver new logic or memory data to its outputs as a response to the input change. After the
new outputs are stable, the ZPSD latches them and automatically reverts back to standby
mode. The ICC current flowing during standby mode and during DC operation is identical
and is only a few microamperes.
The ZPSD automatically reduces its DC current drain to these low levels and does not
require controlling by the CSI (Chip Select Input). Disabling the CSI pin unconditionally
forces the ZPSD to standby mode independent of other input transitions.
The only significant power consumption in the ZPSD occurs during AC operation.
The ZPSD contains the first architecture to apply zero power techniques to memory and
logic blocks.
Figure 2 compares ZPSD zero power operation to the operation of a discrete solution.
A standard microcontroller (MCU) bus cycle usually starts with an ALE (or AS) pulse and
the generation of an address. The ZPSD detects the address transition and powers up for a
short time. The ZPSD then latches the outputs of the PAD, EPROM and SRAM to the new
values. After finishing these operations, the ZPSD shuts off its internal power, entering
standby mode. The time taken for the entire cycle is less than the ZPSD’s “access time.”
The ZPSD will stay in standby mode while its inputs are not changing between bus cycles.
In an alternate system implementation using discrete EPROM, SRAM, and other discrete
components, the system will consume operating power during the entire bus cycle. This
is because the chip select inputs on the memory devices are usually active throughout
the entire cycle. The AC power consumption of the ZPSD may be calculated using the
composite frequency of the MCU address and control signals, as well as any other logic
inputs to the ZPSD.
ALE
DISCRETE EPROM, SRAM & LOGIC
ADDRESS EPROM
ACCESS SRAM
ACCESS EPROM
ACCESS
ICC ZPSD ZPSD ZPSD
TIME
Figure 2. ZPSD Power Operation vs. Discrete Implementation
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8
Name Type Description
When the data bus is 8 bits:
This pin is for 8031 or compatible MCUs that use PSEN to
separate program space from data space. In this case, PSEN is
BHE/ used for reads from the EPROM. Note: if your MCU does not
PSEN Ioutput a PSEN signal, pull up this pin to VCC.
When the data bus is 16 bits:
This pin is BHE. When low, D8-D15 are read from or written to.
Note: in programming mode, this pin is pulsed between VPP and 0 V.
The following control signals can be connected to this port, based on
WR/VPP your MCU (and the way you configure the PSD in PSDsoft):
or I 1. WRactive-low write pulse.
R/W/VPP 2. R/Wactive-high read/active-low write input.
Note: in programming mode, this pin must be tied to VPP.
The following control signals can be connected to this port, based on
RD/E/DS I your MCU (and the way you configure the PSD in PSDsoft):
1. RDactive-low read input.
2. EE clock input.
3. DS—active-low data strobe input (3X2/3X3 devices only)
The following control signals can be connected to this port:
1. CSI—Active-low chip select input. If your MCU supports a chip
select output, and you want the PSD to save power when not
A19/CSI I selected, use this pin as a chip select input.
2. If you don’t wish to use the CSI feature, you may use this pin as
an additional input (logic or address) to the PAD. A19 can be
latched (with ALE/AS), or a transparent logic input.
PSD3XX/ZPSD3XX:
This pin is user-programmable and can be configured to reset on a
high- or low-level input. Reset must be applied for at least 100 ns.
Reset I ZPSD3XXV:
This pin is not configurable, and the chip will only reset on an
active-low level input. Reset must be applied for at least 500 ns,
and no operations may take place for an additional 500 ns minimum.
(See Figure 8.)
If you use an MCU that has a multiplexed bus:
Connect ALE or AS to this pin. The polarity of this pin is configurable.
The trailing edge of ALE/AS latches all multiplexed address inputs
ALE/AS I (and BHE where applicable).
If you use an MCU that does not have a multiplexed bus:
If your MCU uses ALE/AS, connect the signal to this pin.
Otherwise, use this pin for a generic logic input to the PAD.
(Non-3X1 devices only.)
These pins make up Port A. These port pins are configurable, and
PA0 can have the following functions: (see Figure 5A and 5B)
PA1 1. Track AD7-AD0. This feature repeats the MCU address and data
PA2 I/O bus on all Port A pins.
PA3 2. MCU I/Oin this mode, the direction of the pin is defined by its
PA4 direction bit, which resides in the direction register.
PA5 3. Latched address output.
PA6 4. CMOS or open-drain output.
PA7 5. If your MCU is non-multiplexed: data bus input—connect your
data bus (D0-7) to these pins. See Figure 3.
Legend:
The Type column abbreviations are: I = input only; I/O = input/output; P = power.
Table 2.
PSD3XX Pin
Descriptions
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Table 2.
PSD3XX Pin
Descriptions
(cont.)
Name Type Description
These pins make up Port B. These port pins are configurable, and
PB0 can have the following functions: (see Figure 6)
PB1 1. MCU I/Oin this mode, the direction of the pin is defined by its
PB2 direction bit, which resides in the direction register.
PB3 2. Chip select outputeach of PB0-3 has four product terms
PB4 I/O available per pin, while PB4-7 have 2 product terms each.
PB5 See Figure 4.
PB6 3. CMOS or open-drain.
PB7 4. If your MCU is non-multiplexed, and the data bus width is
16 bits: data bus input—connect your data bus (D8-D15) to these
pins. See Figure 3.
These pins make up Port C. These port pins are configurable, and
can have the following functions (see Figure 7):
1. PAD input—when configured as an input, a bit individually
PC0 becomes an address or a logic input, depending on your PSDsoft
PC1 I/O design file. When declared as an address, the bit(s) can be latched
PC2 with ALE/AS.
2. PAD output—when configured as an output (i.e. there is an
equation written for it in your PSDsoft design file), there is one
product term available to it.
AD0/A0 If your MCU is multiplexed:
AD1/A1 These pins are the multiplexed, low-order address/data byte
AD2/A2 (AD0-AD7). As inputs, address information is latched by the ALE/AS
AD3/A3 I/O signal and used internally by the PSD. The pins also serve as MCU
AD4/A4 data bus inputs or outputs, depending on the MCU control signals
AD5/A5 (RD, WR, etc.).
AD6/A6 If your MCU is non-multiplexed:
AD7/A7 These pins are the low-order address inputs (A0-A7)
AD8/A8 If your MCU is multiplexed with a 16-bit data bus:
AD9/A9 These pins are the multiplexed, high-order address/data byte
AD10/A10 (AD8-AD15). As inputs, address information is latched by the
AD11/A11 I/O ALE/AS signal and used internally the PSD. The pins also
AD12/A12 serve as MCU data bus inputs or outputs, depending on the MCU
AD13/A13 control signals (RD, WR, etc.).
AD14/A14 If your MCU is non-multiplexed or has a 8-bit data bus:
AD15/A15 These pins are the high-order address inputs (A8-A15).
GND P Ground Pin
VCC P Supply voltage input.
Legend:
The Type column abbreviations are: I = input only; I/O = input/output; P = power.
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PSD3XX Family
10
8.0
Operating
Modes (MCU
Configurations)
The PSD3XX’s four operating modes enable it to interface directly to most 8- and 16-bit
microcontrollers with multiplexed and non-multiplexed address/data busses. The 16-bit
modes are not available to some devices; see Table 1. The following are the four operating
modes available:
Multiplexed 8-bit address/data bus
Multiplexed 16-bit address/data bus
Non-multiplexed 8-bit data bus
Non-multiplexed 16-bit data bus
Please read the section below that corresponds to your type of MCU. Then check the
appropriate Figure (3A/3B/3C/3D) to determine your pin connections. Table 3 lists the Port
connections in tabular form.
Multiplexed 8-bit address/data bus (Figure 3A)
This mode is used to interface to microcontrollers with a multiplexed 8-bit data bus. Since
the low-order address and data are multiplexed together, your MCU will output an ALE
or AS signal. The PSD3XX contains a transparent latch to demultiplex the address/data
lines internally. All you have to do is connect the ALE/AS signal and select 8-bit multiplexed
bus mode in PSDsoft. If your MCU outputs more than 16 bits of address, and you
wish to connect them to the PSD, connect A16-A18 to Port C and A19 to A19/CSI, where
applicable.
Multiplexed 16-bit address/data bus (Figure 3B)
This mode is used to interface to microcontrollers with a multiplexed 16-bit data bus. Since
the low address bytes and data are multiplexed together, your MCU will output an ALE
or AS signal. The PSD3XX contains a transparent latch to demultiplex the address/data
lines internally. All you have to do is connect the ALE/AS signal and select 8-bit multiplexed
bus mode in PSDsoft. If your MCU outputs more than 16 bits of address, and you
wish to connect them to the PSD, connect A16-A18 to Port C and A19 to A19/CSI, where
applicable.
Non-multiplexed 8-bit data bus (Figure 3C)
This mode is used to interface to microcontrollers with a non-multiplexed 8-bit data bus.
Connect the MCU’s address bus to AD0/A0-AD15/A15 on the PSD. Connect the data bus
signals of your MCU to Port A of the PSD. If your MCU outputs more than 16 bits of
address, and you wish to connect them to the PSD, connect A16-A18 to Port C and A19 to
A19/CSI, where applicable.
Non-multiplexed 16-bit data bus (Figure 3D)
This mode is used to interface to microcontrollers with a non-multiplexed 16-bit data bus.
Connect the MCU’s address bus to AD0/A0-AD15/A15 on the PSD. Connect the low byte
data bus signals of your MCU to Port A, and the high byte data output of your MCU to Port
B of the PSD. If your MCU outputs more than 16 bits of address, and you wish to connect
them to the PSD, connect A16-A18 to Port C and A19 to A19/CSI, where applicable.
For users with multiplexed MCUs that have data multiplexed on address lines other
than A0-A7 note: You can still use the PSD3XX, but you will have to connect your
data to Port A (and Port B where required), as shown in Figure 3C or 3D. That is, you will
be connecting it as if you were using a non-multiplexed MCU. In this case, you must
connect the ALE/AS signal so that the address will still be properly latched. This option is
not available on the 3X1 versions.
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PSD3XX Family
11
Figure 3A. Connecting a PSD3XX to an 8-Bit Multiplexed-Bus MCU
Your
8-bit
MCU
PSD3XX
PA
PB
PC
AD0-AD7
A8-A15
ALE/AS
PSEN
R/W or WR
RD/E/DS1
A19/CSI
RESET
A16-A182
Figure 3B. Connecting a PSD3XX to a 16-Bit Multiplexed-Bus MCU
Your
16-bit
MCU
PSD3XX
PA
PB
PC
AD0-AD7
AD8-AD15
ALE/AS
BHE/PSEN
R/W or WR
RD/E/DS1
A19/CSI
RESET
A16-A182
Figure 3C. Connecting a PSD3XX to an 8-Bit Non-Multiplexed-Bus MCU
Your
8-bit
MCU
PSD3XX
PA
PB
PC
D0-D7
A0-A15
ALE/AS
PSEN
R/W or WR
RD/E/DS1
A19/CSI
RESET
A16-A182
Figure 3D. Connecting a PSD3XX to a 16-Bit Non-Multiplexed-Bus MCU
Your
16-bit
MCU
PSD3XX
PA
PB
PC
D0-D15
A0-A15
ALE/AS
BHE/PSEN
R/W or WR
RD/E/DS1
A19/CSI
RESET
A16-A182
D0-D7
D8-D15
NOTES: 1. DS is a valid input on 3X2/3X3 and devices only.
2. Connect A16-A18 to Port C if your MCU outputs more than 16 bits of address.
8.0
Operating Modes
(MCU
Configurations)
(cont.)
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PSD3XX Family
12
Multiplexed Address/Data Non-Multiplexed Address/Data
8-bit Data Bus
I/O or low-order address
Port A lines or Low-order multiplexed D0–D7 data bus byte
address/data byte
Port B I/O and/or CS0–CS7 I/O and/or CS0–CS7
AD0/A0–AD7/A7 Low-order multiplexed
address/data byte Low-order address bus byte
AD8/A8–AD15/A15 High-order address High-order address bus byte
bus byte
16-bit Data Bus
I/O or low-order address
Port A lines or low-order multiplexed Low-order data bus byte
address/data byte
Port B I/O and/or CS0–CS7 High-order data bus byte
AD0/A0–AD7/A7 Low-order multiplexed
address/data byte Low-order address bus byte
AD8/A8–AD15/A15 High-order multiplexed
address/data byte High-order address bus byte
8.0
Operating
Modes (MCU
Configurations)
(cont.)
Table 3. Bus and Port Configuration Options
9.0
Programmable
Address
Decoder (PAD)
The PSD3XX contains two programmable arrays, referred to as PAD A and PAD B
(Figure 4). PAD A is used to generate chip select signals derived from the input address to
the internal EPROM blocks, SRAM, I/O ports, and Track Mode signals.
PAD B outputs to Ports B and C for off-chip usage. PAD B can also be used to extend the
decoding to select external devices or as a random logic replacement.
PAD A and PAD B receive the same inputs. The PAD logic is configured by PSDsoft
based on the designers input. The PAD’s non-volatile configuration is stored in a
re-programmable CMOS EPROM. Windowed packages are available for erasure by the
user. See Table 4 for a list of PAD A and PAD B functions.
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NOTES: 1. CSI is a power-down signal. When high, the PAD is in stand-by mode and all its outputs
become non-active. See Tables 12 and 13.
2. RESET deselects all PAD output signals. See Tables 10 and 11.
3. A18, A17, and A16 are internally multiplexed with CS10, CS9, and CS8, respectively.
Either A18 or CS10, A17 or CS9, and A16 or CS8 can be routed to the external pins of
Port C. Port C pins can be configured as either input or output, individually.
4. P0–P3are not included on 3X1 devices.
5. DS is not available on 3X1 devices.
Figure 4.
PAD Description
ALE or AS
WR or R/W
A19
A18
A17
A16
A15
A14
A13
A12
A11
ES0
ES1
ES2
ES3
ES4
ES5
ES6
ES7
RS0
CSIOPORT
CSADIN
CSADOUT1
CSADOUT2
CS0/PB0
CS1/PB1
CS2/PB2
CS3/PB3
CS4/PB4
CS5/PB5
CS6/PB6
CS7/PB7
CS8/PC0
CS9/PC1
CS10/PC2
RD/E/DS
8 EPROM BLOCK
SELECT LINES
CSI
RESET
SRAM BLOCK SELECT*
TRACK MODE
CONTROL SIGNALS
P0
P1
P2
P3
I/O BASE ADDRESS
PAD
B
PAD
A
PSD3XX Family
13
*SRAM no available on “R” versions
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PSD3XX Family
14
Function
PAD A and PAD B Inputs
A19/CSI When the PSD is configured to use CSI and while CSI is a logic 1, the PAD
deselects all of its outputs and enters a power-down mode (see Tables 12
and 13). When the PSD is configured to use A19, this signal is another
input to the PAD.
A16–A18 These are general purpose inputs from Port C. See Figure 4, Note 3.
A11–A15 These are address inputs.
P0–P3 These are inputs from the page register (not available on 3X1 versions).
RD/E/DS This is the read pulse or strobe input. (DS not available on 3X1 versions).
WR or R/W This is the write pulse or R/W select signal.
ALE/AS This is the ALE or AS input to the chip. Use to demultiplex address
and data.
RESET This deselects all outputs from the PAD; it can not be used in product
term equations.See Tables 10 and 11.
PAD A Outputs
These are internal chip-selects to the 8 EPROM banks. Each bank can
ES0–ES7 be located on any boundary that is a function of one product term of the
PAD address inputs.
RS0 This is an internal chip-select to the SRAM. Its base address location is
a function of one term of the PAD address inputs.
This internal chip-select selects the I/O ports. It can be placed on any
CSIOPORT boundary that is a function of one product term of the PAD inputs. See
Tables 5A and 5B.
This internal chip-select, when Port A is configured as a low-order
address/data bus in the track mode controls the input direction of Port A.
CSADIN is gated externally to the PAD by the internal read signal. When
CSADIN CSADIN and a read operation are active, data presented on Port A
flows out of AD0/A0–AD7/A7. This chip-select can be placed on any
boundary that is a function of one product term of the PAD inputs.
See Figure 5B.
This internal chip-select, when Port A is configured as a low-order
address/data bus in track mode, controls the output direction of Port A.
CSADOUT1 is gated externally to the PAD by the ALE signal. When
CSADOUT1 CSADOUT1 and the ALE signal are active, the address presented on
AD0/A0–AD7/A7 flows out of Port A. This chip-select can be placed on
any boundary that is a function of one product term of the PAD inputs.
See Figure 5B.
This internal chip-select, when Port A is configured as a low-order
address/data bus in the track mode, controls the output direction of Port A.
CSADOUT2 must include the write-cycle control signals as part of its
CSADOUT2 product term. When CSADOUT2 is active, the data presented on
AD0/A0–AD7/A7 flows out of Port A. This chip-select can be placed on
any boundary that is a function of one product term of the PAD inputs.
See Figure 5B.
PAD B Outputs
CS0–CS3 These chip-select outputs can be routed through Port B. Each of them is
a function of up to four product terms of the PAD inputs.
CS4–CS7 These chip-select outputs can be routed through Port B. Each of them is
a function of up to two product terms of the PAD inputs.
CS8–CS10 These chip-select outputs can be routed through Port C. See Figure 4,
Note 3. Each of them is a function of one product term of the PAD inputs.
Table 4.
PSD3XX
PAD A and
PAD B
Functions
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15
PSD3XX Family
10.0
I/O Port
Functions
The PSD3XX has three I/O ports (Ports A, B, and C) that are configurable at the bit level.
This permits great flexibility and a high degree of customization for specific applications.
The next section describes the control registers for the ports. Following that are sections
that describe each port. Figures 5 through 7 show the structure of Ports A through C,
respectively.
Note: any unused input should be connected directly to ground or pulled up to VCC
(using a 10Kto 100Kresistor).
10.1 CSIOPORT Registers
Control of the ports is primarily handled through the CSIOPORT registers. There are 24
bytes in the address space, starting at the base address labeled CSIOPORT. Since the
PSD3XX uses internal address lines A15-A8 for decoding, the CSIOPORT space will
occupy 2 Kbytes of memory, on a 2 Kbyte boundary. This resolution can be improved to
reduce wasted address space by connecting lower order address lines (A7 and below)
to Port C. Using this method, resolution down to 256 Kbytes may be achieved. The
CSIOPORT space must be defined in your PSDsoft design file. The following tables list
the registers located in the CSIOPORT space.
16-Bit Users Note
When referring to Table 5B, realize that Ports A and B are still accessible on a byte basis.
Note: When accessing Port B on a 16-bit data bus, BHE must be low.
Table 5A. CSIOPORT Registers for 8-Bit Data Busses
NOTE: 1. ZPSD only.
Offset (in hex) Type of
from CSIOPORT Access
Register Name Base Address Allowed
Port A Pin Register +2 Read
Port A Direction Register +4 Read/Write
Port A Data Register +6 Read/Write
Port B Pin Register +3 Read
Port B Direction Register +5 Read/Write
Port B Data Register +7 Read/Write
Power Management Register (Note 1) +10 Read/Write
Page Register +18 Read/Write
Table 5B. CSIOPORT Registers for 16-Bit Data Busses
NOTE: 1. ZPSD only.
Offset (in hex) Type of
from CSIOPORT Access
Register Name Base Address Allowed
Port A/B Pin Register +2 Read
Port A/B Direction Register +4 Read/Write
Port A/B Data Register +6 Read/Write
Power Management Register (Note 1) +10 Read/Write
Page Register +18 Read/Write
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PSD3XX Family
16
PSD3XX Family
10.0
I/O Port
Functions
(
cont.)
10.2 Port A (PA0-PA7)
The control registers of Port A are located in CSIOPORT space; see Table 5.
10.2.1 Port A (PA0-PA7) in Multiplexed Address/Data Mode
Each pin of Port A can be individually configured. The following table summarizes what the
control registers (in CSIOPORT space) for Port A do:
NOTE: 1. Default value is the value after reset.
Default
Value
Register Name 0 Value 1 Value
(Note 1)
Port A Pin Register Sampled logic level Sampled logic level X
at pin = ‘0’ at pin = ‘1’
Port A Direction Register Pin is configured Pin is configured 0
as input as output
Port A Data Register Data in DFF = ‘0’ Data in DFF = ‘1’ 0
MCU I/O Mode
The default configuration of Port A is MCU I/O. In this mode, every pin can be set (at run-
time) as an input or output by writing to the respective pin’s direction flip-flop (DIR FF,
Figure 5A). As an output, the pin level can be controlled by writing to the respective pin’s
data flip-flop (DFF, Figure 5A). The Pin Register can be read to determine logic level of the
pin. The contents of the Pin Register indicate the true state of the PSD driving the pin
through the DFF or an external source driving the pin. Pins can be configured as CMOS
or open-drain using ST’s PSDsoft software. Open-drain pins require external pull-up
resistors.
Latched Address Output Mode
Alternatively, any bit(s) of Port A can be configured to output low-order demultiplexed
address bus bit. The address is provided by the internal PSD address latch, which latches
the address on the trailing edge of ALE/AS. Port A then outputs the desired demultiplexed
address bits. This feature can eliminate the need for an external latch (for example:
74LS373) if you have devices that require low-order latched address bits. Although any pin
of Port A may output an address signal, the pin is position-dependent. In other words, pin
PA0 of Port A may only pass A0, PA1 only A1, and so on.
Track Mode
Track Mode sets the entire port to track the signals on AD0/A0-AD7/A7, depending on
specific address ranges defined by the PAD’s CSADIN, CSADOUT1, and CSADOUT2
signals. This feature lets the user interface the microcontroller to shared external resources
without requiring external buffers and decoders. In Track Mode, Port A effectively operates
as a bi-directional buffer, allowing external MCUs or host processors to access the local
data bus. Keep the following information in mind when setting up Track Mode:
The direction is controlled by:
ALE/AS
RD/E or RD/E/DS (DS on non-3X1 devices only)
WR or R/W
PAD outputs CSADOUT1, CSADOUT2, and CSADIN defined in PSDsoft design.
When CSADOUT1 and ALE/AS are true, the address on AD0/A0-AD7/A7 is output on
Port A. Note: carefully check the generation of CSADOUT1 to ensure that it is stable
during the ALE/AS pulse.
When CSADOUT2 is active and a write operation is performed, the data on the
AD0/A0-AD7/A7 input pins flows out through Port A.
When CSADIN is active and a read operation is performed, the data on Port A flows
out through the AD0/A0-AD7/A7 pins.
Port A is tri-stated when none of the above conditions exist.
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NOTE: 1. The expression for CSADOUT2 must include the following write operation cycle signals:
For CRRWR = 0, CSADOUT2 must include WR = 0.
For CRRWR = 1, CSADOUT2 must include E = 1 and R/W = 0.
PSD3XX Family
17
INTERNAL
READ
CSADIN
INTERNAL
ALE
PA0PA7
A11A15
A16A19
AD8AD15
CSADOUT1
CSADOUT2 (1)
ALE or AS
AD0–AD7
RD/E
WR or R/W
CONTROL
DECODER
LATCH PAD
I
O
NOTE: 1. CMOS/OD determines whether the output is open drain or CMOS.
READ PIN
PORT A PIN
ENABLE
LATCHED
ADDR OUT
MCU
I/O
OUT
ADn/Dn
READ DATA
WRITE DATA
ALE
READ DIR
WRITE DIR
RESET
CK
DR
G
DR
D
CK R
CMOS/OD(1)
I
N
T
E
R
N
A
L
A
D
D
R
/
D
A
T
A
B
U
S
A
D
0
/
A
D
7
DFF
LATCH
DIR
FF CONTROL
MUX
10.2.2 Port A (PA0-PA7) in Non-Multiplexed Address/Data Mode
In this mode, Port A becomes the low-order data bus byte of the chip. When reading an
internal location, data is presented on Port A pins to the MCU. When writing to an internal
location, data present on Port A pins from the MCU is written to the desired location.
10.0
I/O Port
Functions
(
cont.)
Figure 5A. Port A Pin Structure
Figure 5B. Port A Track Mode
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PSD3XX Family
18
PSD3XX Family
10.
I/O Port
Functions
(
cont.)
10.3 Port B (PB0-PB7)
The control registers of Port B are located in CSIOPORT space; see Table 5A and 5B.
10.3.1 Port B (PB0-PB7) in Multiplexed Address/Data Mode
Each pin of Port B can be individually configured. The following table summarizes what the
control registers (in CSIOPORT space) for Port B do:
NOTE: 1. Default value is the value after reset.
Default
Value
Register Name 0 Value 1 Value
(Note 1)
Port B Pin Register Sampled logic level Sampled logic level X
at pin = ‘0’ at pin = ‘1’
Port B Direction Register Pin is configured Pin is configured 0
as input as output
Port B Data Register Data in DFF = ‘0’ Data in DFF = ‘1’ 0
MCU I/O Mode
The default configuration of Port B is MCU I/O. In this mode, every pin can be set
(at run-time) as an input or output by writing to the respective pin’s direction flip-flop (DIR
FF, Figure 6). As an output, the pin level can be controlled by writing to the respective pin’s
data flip-flop (DFF, Figure 6). The Pin Register can be read to determine logic level of the
pin. The contents of the Pin Register indicate the true state of the PSD driving the pin
through the DFF or an external source driving the pin. Pins can be configured as CMOS
or open-drain using ST’s PSDsoft software. Open-drain pins require external pull-up
resistors.
Chip Select Output
Alternatively, each bit of Port B can be configured to provide a chip-select output signal
from PAD B. PB0-PB7 can provide CS0-CS7, respectively. The functionality of these pins is
not limited to chip selects only; they can be used for generic combinatorial logic as well.
Each of the CS0-CS3 signals is comprised of four product terms, and each of the CS4-CS7
signals is comprised of two product terms.
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PSD3XX Family
19
PSD3XX Family
READ PIN
READ DATA
PORT B PIN
CMOS/OD(1)
MCU
I/O
OUT
WRITE DATA CK
DR
DFF
ENABLE
MUX
Dn
CSn
CONTROL
DIR
FF
D
CK
R
WRITE DIR
RESET
READ DIR
I
N
T
E
R
N
A
L
I
N
T
E
R
N
A
L
C
S
O
U
T
D
A
T
A
B
U
S
B
U
S
C
S
0
7
D
8
D
1
5
NOTE: 1. CMOS/OD determines whether the output is open drain or CMOS.
Figure 6. Port B Pin Structure
10.3.2 Port B (PB0-PB7) in 16-bit Multiplexed Address/Data Mode
In this mode, Port B becomes the low-order data bus byte to the MCU chip. When reading
an internal high-order location, data is presented on Port B pins to the MCU. When writing
to an internal high-order location, data present on Port B pins from the MCU is written to the
desired location.
10.
I/O Port
Functions
(
cont.)
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PSD3XX Family
20
CS8/CS9/CS10
From PAD
To PAD
A16/A17/A18
Latched Address
Input QD
En
Logic Input
D
E
M
U
X
Address In or
Chip Select Out
Input or Output
Set by PSDsoft2
PSDsoft2
Port C I/O1
(PC0/PC1/PC2)
ALE
NOTES: 1. Port C pins can be individually configured as inputs or outputs, but not both. Pins can be individually
configured as address or logic and latched or transparent, except for the 3X1 devices, which must be
set to all address or all logic.
2. PSDsoft sets this configuration prior to run-time based on your PSDsoft design file.
Figure 7. Port C (PC0-PC2) Pin Structure
10.4 Port C (PC0-PC2)
Each pin of Port C (Figure 7) can be configured as an input to PAD A and PAD B, or as an
output from PAD B. As inputs, the pins are referenced as A16-A18. Although the pins are
given this reference, they can be used for any address or logic input. [For example, A8-A10
could be connected to those pins to improve the resolution (boundaries) of CS0-CS7 to 256
bytes.] How they are defined in the PSDsoft design file determines:
Whether they are address or logic inputs
Whether the input is transparent or latched by the trailing edge of ALE/AS.
Notes:
1) If the inputs are addresses, they are routed to PAD A and PAD B, and can be used in
any or all PAD equations.
2) A logic input is routed to PAD B and can be used for Boolean equations that are
implemented in any or all of the CS0-CS10 PAD B outputs.
Alternately, PC0-PC2 can become CS8-CS10 outputs, respectively, providing the user with
more external chip-select PAD outputs. Each of the signals (CS8-CS10) is comprised of
one product term.
10.
I/O Port
Functions
(
cont.)
10.5 ALE/AS Input Pin
The ALE/AS pin may be used as a generic logic input signal to the PADs if a
non-multiplexed MCU configuration is chosen in PSDsoft.
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PSD3XX Family
21
11.
PSD Memory
The following sections explain the various memory blocks and memory options within the
PSD3XX.
11.1 EPROM
For all of the PSD3XX devices, the EPROM is built using Zero-power technology. This
means that the EPROM powers up only when the address changes. It consumes power for
the necessary time to latch data on its outputs. After this, it powers down and remains in
Standby Mode until the next address change. This happens automatically, and the designer
has to do nothing special.
The EPROM is divided into eight equal-sized banks. Each bank can be placed in any
address location by programming the PAD. Bank0-Bank7 are selected by PAD A outputs
ES0-ES7, respectively. There is one product term for each bank select (ESi).
Refer to Table 1 to see the size of the EPROM for each PSD device.
11.2 SRAM (Optional)
Like the EPROM, the optional SRAM in the PSD3XX devices is built using Zero-power
technology.
All PSD3XX parts which do not have an R suffix contain 2 Kbytes of SRAM (Table 1). The
SRAM is selected by the RS0 output of the PAD. There is one product term dedicated to
RS0.
If your design requires a SRAM larger than 2K x 8, then use one of the RAMless
(R versions) of the 3XX devices with an external SRAM. The external SRAM can be
addressed trhough Port A and all require logic will be taken care of by the PSD3XXR.
11.3 Page Register (Optional)
All PSD3XX parts, except 3X1devices, have a four-bit page register. Thus the effective
address space of your MCU can be enlarged by a factor of 16. Each bit of the Page
Register can be individually read or written. The Page Register is located in CSIOPORT
space (at offset 18h); see Table 5. The Page Register is connected to the lowest nibble of
the data bus (D3-D0). The outputs of the Page Register, P3-P0, are connected to PAD A,
and therefor can be used in any chip select (internal or external) equations. The contents of
the page register are reset to zero at power-up and after any chip-level reset.
11.4 Programming and Erasure
Programming the device can be done using the following methods:
ST’s main programmerPSDprowhich is accessible through a parallel port.
ST’s programmer used specifically with the PSD3XXPEP300.
ST’s discontinued programmerMagic Pro.
A 3rd party programmer, such as Data I/O.
Information for programming the device is available directly from ST. Please contact your
local sales representative. Also, check our web site (www.st.com/psm) for information related
to 3rd party programmers.
Upon delivery from ST or after each erasure (using windowed part), the PSD3XX device
has all bits in PAD and EPROM in the HI state (logic 1). The configuration bits are in the LO
state (logic 0).
To clear all locations of their programmed contents (assuming you have a windowed
version), expose the windowed device to an Ultra-Violet (UV) light source. A dosage of
30 W second/cm2is required for PSD3XX devices, and 40 W second/cm2for low-voltage
(V suffix) devices. This dosage can be obtained with exposure to a wavelength of 2537 Å
and intensity of 12000 µW/cm2for 40 to 45 minutes for the PSD3XX and 55 to 60 minutes
for the low-voltage (V suffix) devices. The device should be approximately 1 inch (2.54 cm)
from the source, and all filters should be removed from the UV light source prior to erasure.
The PSD3XX devices will erase with light sources having wavelengths shorter than 4000 Å.
However, the erasure times will be much longer than when using the recommended 2537 Å
wavelength. Note: exposure to sunlight will eventually erase the device. If used in such an
environment, the package window should be covered with an opaque substance.
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PSD3XX Family
22
12.0
Control Signals
Consult your MCU data sheet to determine which control signals your MCU generates, and
how they operate. This section is intended to show which control signals should be
connected to what pins on the PSD3XX. You will then use PSDsoft to configure the
PSD3XX, based on the combination of control signals that your MCU outputs, for example
RD, WR, and PSEN.
The PSD3XX is compatible with the following control signals:
ALE or AS (polarity is programmable)
WR or R/W
RD/E or RD/E/DS (DS for non-3X1 devices only)
BHE or PSEN
A19/CSI
RESET (polarity is programmable except on low voltage versions with the V suffix).
12.1 ALE or AS
Connect the ALE or AS signal from your MCU to this pin where applicable, and program
the polarity using PSDsoft. The trailing edge (when the signal goes inactive) of ALE or AS
latches the address on any pins that have an address input. If you are using a
non-multiplexed-bus MCU that does not output an ALE or AS signal, this pin can be used
for a generic input to the PAD. Note: if your data is multiplexed with address lines other
than A0-A7, connect your address pins to AD0/A0-AD15/A15, and connect your data to
Port A (and Port B where applicable), and connect the ALE/AS signal to this pin.
12.2 WR or R/W
Your MCU should output a stand-alone write signal (WR) or a multiplexed read/write signal
(R/W). In either case, the signal should be connected to this pin.
12.3 RD/E/DS (DS option not available on 3X1 devices)
Your MCU should output any one of RD, E (clock), or DS. In any case, connect the
appropriate signal to this pin.
12.4 BHE or PSEN
If your MCU does not output either of these signals, tie this pin to Vcc
(through a series resistor), and skip to the next signal.
If you use an 8-bit 8031 compatible MCU that outputs a separate signal when
accessing program space, such as PSEN, connect it to this pin. You would then use
PSDsoft to configure the EPROM in the PSD3XX to respond to PSEN only or PSEN
and RD. If you have an 8031 compatible MCU, refer to the “Program/Data Space and
the 8031” section for further information.
If you are using a 16-bit MCU, connect the BHE (or similar signal) output to this pin.
BHE enables accessing of the upper byte of the data bus. See Table 6 for information
on how this signal is used in conjunction with the A0 address line.
BHE A
0
Operation
0 0 Whole Word
0 1 Upper Byte From/To Odd Address
1 0 Lower Byte From/To Even Address
1 1 None
Table 6. Truth Table for BHE and Address Bit A0 (16-bit MCUs only)
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PSD3XX Family
23
12.0
Control Signals
(cont.)
12.5 A19/CSI
This pin is configured using PSDsoft to be either a chip select for the entire PSD device or
an additional PAD input. If your MCU can generate a chip-select signal, and you wish to
save power, use the PSD chip select feature. Otherwise, use this pin as an address or logic
input.
When configured as CSI (active-low PSD chip select): a low on this pin keeps the PSD
in normal operation. However, when a high is detected on the pin, the PSD
enters Power-down Mode. See Tables 7A and 7B for information on signal states
during Power-down Mode. See section 16 for details about the reduction of power
consumption.
When configured as A19, the pin can be used as an additional input to the PADs.
It can be used for address or logic. It can also be ALE/AS dependent or a transparent
input, which is determined by your PSDsoft design file. In A19 mode, the PSD is always
enabled.
Port Configuration Mode(s) State
AD0–A0/AD15/A15 All Input (Hi-Z)
MCU I/O Unchanged
Port Pins PA0–PA7 Tracking AD0/A0-AD7/A7 Input (Hi-Z)
Latched Address Out Logic 1
MCU I/O Unchanged
Port Pins PB0–PB7 Chip Select Outputs, CS0–CS7, CMOS Logic 1
Chip Select Outputs, CS0–CS7, Open Drain Hi-Z
Port Pins PC0–PC2 Address or Logic Inputs, A16-A18 Input (Hi-Z)
Chip Select Outputs, CS8–CS10, CMOS only Logic 1
Table 7A. Signal States During Power-Down Mode
Internal Signal State
Component Internal Signal During Power-Down
PAD A and PAD B CS0–CS10 Logic 1 (inactive)
CSADIN, CSADOUT1,
CSADOUT2, CSIOPORT, Logic 0 (inactive)
ES0-ES7, RS0
All registers in CSIOPORT N/A
address space, including:
Direction
Data All unchanged
Page
PMR (turbo bit, ZPSD only)
Table 7B. Internal States During Power-down
NOTE: N/A = Not Applicable
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12.0
Control Signals
(cont.)
12.6 Reset Input
This is an asynchronous input to initialize the PSD device.
Refer to tables 8A and 8B for information on device status during and after reset.
The standard-voltage PSD3XX and ZPSD3XX (non-V) devices require a reset input that
is asserted for at least 100 nsec. The PSD will be functional immediately after reset is
de-asserted. For these standard-voltage devices, the polarity of the reset input signal is
programmable using PSDsoft (active-high or active-low), to match the functionality of your
MCU reset.
Note: It is not recommended to drive the reset input of the MCU and the reset input of the
PSD with a simple RC circuit between power on ground. The input threshold of the MCU
and the PSD devices may differ, causing the devices to enter and exit reset at different
times because of slow ramping of the signal. This may result in the PSD not being
operational when accessed by the MCU. It is recommended to drive both devices actively.
A supervisory device or a gate with hysteresis is recommended.
For low-voltage ZPSD3XXV devices only, the reset input must be asserted for at least
500 nsec. The ZPSD3XXV will not be functional for an additional 500 nsec after reset is
de-asserted (see Figure 8). These low voltage ZPSD3XXV devices must use an active-low
polarity signal for reset. Unlike the standard PSDs, the reset polarity for the ZPSD3XXV is
not programmable. If your MCU operates with an active high reset, you must invert this
signal before driving the ZPSD3XXV reset input.
You must design your system to ensure that the PSD comes out of reset and the PSD is
active before the MCU makes its first access to PSD memory. Depending on the
characteristics and speed of your MCU, a delay between the PSD reset and the MCU reset
may be needed.
Signal State Just
Signal State After Reset
Port Configured Mode of Operation During Reset
(Note 1)
AD0/A0- All Input (Hi-Z) MCU address
AD15/A15 and/or data
MCU I/O Input (Hi-Z) Input (Hi-Z)
Tracking Input (Hi-Z) Active Track
Port Pins AD0/A0-AD7/A7 Mode
PA0-PA7 PSD3XX, Logic 0 MCU address
Latched Address Out ZPSD3XX
ZPSD3XXV Hi-Z MCU address
MCU I/O Input (Hi-Z Input (Hi-Z)
Chip Select Outputs, PSD3XX, Logic 1 Per CS equations
Port Pins CS0-CS7, CMOS ZPSD3XX
PB0-PB7 ZPSD3XXV Hi-Z Per CS equations
Chip Select Outputs, PSD3XX, Hi-Z Per CS equations
CS0-CS7, Open Drain ZPSD3XX
ZPSD3XXV Hi-Z Per CS equations
Address or Logic Inputs, A16-A18 Input (Hi-Z) Input (Hi-Z)
Port Pins Chip Select Outputs, PSD3XX, Logic 1 Per CS equations
PC0-PC2 CS8-CS10, CMOS ZPSD3XX
ZPSD3XXV Hi-Z Per CS equations
Table 8A. External PSD Signal States During and Just After Reset
NOTE: 1. Signal is valid immediately after reset for PSD3XX and ZPSD3XX devices. ZPSD3XXV devices need an
additional 500 nsec after reset before signal is valid.
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25
12.0
Control Signals
(cont.)
Internal
Internal Signal Signal State
State During During
Component Internal Signal Reset Power-Down
CS0-CS10 Logic 1 (inactive) Per CS Equations
CSADIN,
CSADOUT1, Per equations
PAD A and PAD B CSADOUT2, Logic 0 (inactive) for each
CSIOPORT, internal signal
ES0-ES7, RS0
All registers in CSIOPORT
address space, including:
Direction Logic 0 in all bit of Logic 0 until
Data N/A all registers changed by MCU
Page
PMR (turbo bit,
ZPSD3XX only)
Table 8B. Internal PSD Signal States During and Just After Reset
NOTE: N/A = Not Applicable
RESET LOW
VIH
RESET HIGH ZPSD3XXV
IS OPERATIONAL
500 ns 500 ns
VIL
Figure 8. The Reset Cycle (RESET) (ZPSD3XXV Versions)
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PSD3XX Family
26
13.0
Program/Data
Space and the
8031
This section only applies to users who have an 8031 or compatible MCU that outputs a
signal such as PSEN when accessing program space. If this applies to you, be aware of the
following:
The PSD3XX can be configured using PSDsoft such that the EPROM is either
1) accessed by PSEN only (Figure 10); or 2) accessed by PSEN or RD (Figure 9).
The default is PSEN only unless changed in PSDsoft.
The SRAM and I/O Ports (including CSIOPORT) can not be placed in program space
only. By default, they are in data space only (Figure 10). However, the SRAM may
be placed in Program and Data Space, as shown in Figure 9.
Figure 9. Combined Address Space
INTERNAL
OE
OE
OE
CS
CS
CS
RD
ADDRESS
PSEN
I/O PORTS
PAD SRAM*
EPROM
INTERNAL
OE
OE
OE
CS
CS
CS
RD
ADDRESS
PSEN
I/O PORTS
PAD SRAM*
EPROM
Figure 10. 8031-Compatible Separate Code and Data Address Spaces
*Not available on “R” versions.
*Not available on “R” versions.
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27
14.0
System
Applications
In Figure 11, the PSD3XX is configured to interface with Intel’s 80C31, which is a 16-bit
address/8-bit data bus microcontroller. Its data bus is multiplexed with the low-order
address byte. The 80C31 uses signals RD to read from data memory and PSEN to read
from code memory. It uses WR to write into the data memory. It also uses active high reset
and ALE signals. The rest of the configuration bits, as well as the unconnected signals,
are application specific, and thus, user dependent.
MICROCONTROLLER
31
19
18
9
12
13
14
15
1
2
3
4
5
6
7
8
23
24
25
26
27
28
29
30
31
32
33
35
36
37
38
39
22
2
1
13
3
P0.0
P0.1
P0.2
P0.3
P0.4
P0.5
P0.6
P0.7
P2.0
P2.1
P2.2
P2.3
P2.4
P2.5
P2.6
P2.7
RD
WR
PSEN
ALE
TXD
RXD
PA0
PA1
PA2
PA3
PA4
PA5
PA6
PA7
PB0
PB1
PB2
PB3
PB4
PB5
PB6
PB7
PC0
PC1
PC2
A19/CSI
39
38
37
36
35
34
33
32
21
22
23
24
25
26
27
28
17
16
29
30
11
10
21
20
19
18
17
16
15
14
11
10
9
8
7
6
5
4
40
41
42
43
EA/VP
X1
X2
RESET
INT0
INT1
T0
T1
P1.0
P1.1
P1.2
P1.3
P1.4
P1.5
P1.6
P1.7
AD0/A0
AD1/A1
AD2/A2
AD3/A3
AD4/A4
AD5/A5
AD6/A6
AD7/A7
AD8/A8
AD9/A9
AD10/A10
AD11/A11
AD12/A12
AD13/A13
AD14/A14
AD15/A15
RD
WR/VPP
BHE/PSEN
ALE
RESET GND
PSD3XX
80C31 34 12
VCC
44 0.1µF
Reset
NOTE: RESET to the PSD3XX must be the output of a RESET chip or buffer.
If RESET to the 80C31 is the output of an RC circuit, a separate buffered RC RESET to the
PSD3XX (shorter than the 80C31 RC RESET) must be provided to avoid a race condition.
Figure 11. PSD3XX Interface With Intel’s 80C31
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28
14.0
System
Applications
(cont.)
In Figure 12, the PSD3XX is configured to interface with Motorola’s 68HC11, which is a
16-bit address/8-bit data bus microcontroller. Its data bus is multiplexed with the low-order
address byte. The 68HC11 uses E and R/W signals to derive the read and write strobes.
It uses the Address Strobe (AS) for the address latch pulse. RESET is an active-low signal.
The rest of the configuration bits, as well as the unconnected signals, are specific, and thus,
user dependent.
MICROCONTROLLER
20
21
22
23
24
25
43
45
47
49
44
46
48
50
34
33
32
31
30
29
28
27
52
51
23
24
25
26
27
28
29
30
31
32
33
35
36
37
38
39
22
2
13
3
1
PC0
PC1
PC2
PC3
PC4
PC5
PC6
PC7
PB0
PB1
PB2
PB3
PB4
PB5
PB6
PB7
E
R/W
AS
RESET
XIRQ
IRQ
MODB
MODA
PA0
PA1
PA2
PA3
PA4
PA5
PA6
PA7
PB0
PB1
PB2
PB3
PB4
PB5
PB6
PB7
PC0
PC1
PC2
A19/CSI
9
10
11
12
13
14
15
16
42
41
40
39
38
37
36
35
5
6
4
17
18
19
2
3
21
20
19
18
17
16
15
14
11
10
9
8
7
6
5
4
40
41
42
43
PD0
PD1
PD2
PD3
PD4
PD5
PE0
PE1
PE2
PE3
PD4
PE5
PE6
PE7
PA0
PA1
PA2
PA3
PA4
PA5
PA6
PA7
VRH
VRL
AD0/A0
AD1/A1
AD2/A2
AD3/A3
AD4/A4
AD5/A5
AD6/A6
AD7/A7
AD8/A8
AD9/A9
AD10/A10
AD11/A11
AD12/A12
AD13/A13
AD14/A14
AD15/A15
E
R/W/VPP
AS
RESET
BHE/PSEN
GND
RESET
PSD3XX 34 12
VCC
VCC
68HC11
XTAL EXTAL
44 0.1µF
Figure 12. PSD3XX Interface With Motorola’s 68HC11
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29
14.0
System
Applications
(cont.)
In Figure 13, the PSD3XX is configured to work directly with Intel’s 80C196KB
microcontroller, which is a 16-bit address/16-bit data bus processor. The Address and data
lines multiplexed. The PSD3XX is configured to use PC0, PC1, PC2, and A19/CSI as logic
inputs. These signals are independent of the ALE pulse (latch-transparent). They are used
as four general-purpose inputs that take part in the PAD equations.
Port A is configured to work in Track Mode, in which (for certain conditions) PA0–PA7 tracks
lines AD0/A0–AD7/A7. Port B is configured to generate CS0–CS7. In this example, PB2
serves as a WAIT signal that slows down the 80C196KB during the access of external
peripherals. These 8-bit wide peripherals are connected to the shared bus of Port A. The
WAIT signal also drives the buswidth input of the microcontroller, so that every external
peripheral cycle becomes an 8-bit data bus cycle. PB3 and PB4 are open-drain output
signals; thus, they are pulled up externally.
67
68 36
NMI
RxD
TxD
+5V
RST
66
XTAL1
AD[0..15]AD[0..15]
XTAL2
3
43
64
14
16
NMI
READY
BUSWIDTH
CDE
RESET
6
5
7
4
11
10
8
9
P0.0
P0.1
P0.2
P0.3
P0.4
P0.5
P0.6
P0.7
18
17
15
44
42
39
33
38
P2.0/TXD
P2.1/RXD
P2.2/EXINT
P2.3/T2CLK
P2.4/T2RST
P2.5/PWM
P2.6/T2 UP/DN
P2.7/T2 CAPTR
AD0/A0
AD1/A1
AD2/A2
AD3/A3
AD4/A4
AD5/A5
AD6/A6
AD7/A7
AD8/A8
AD9/A9
AD10/A10
AD11/A11
AD12/A12
AD13/A13
AD14/A14
AD15/A15
21
20
19
18
17
16
15
14
11
10
9
8
7
6
5
4
PA0
PA1
PA2
PA3
PA4
PA5
PA6
PA7
PB0
PB1
PB2
PB3
PB4
PB5
PB6
PB7
AD0/A0
AD1/A1
AD2/A2
AD3/A3
AD4/A4
AD5/A5
AD6/A6
AD7/A7
AD8/A8
AD9/A9
AD10/A10
AD11/A11
AD12/A12
AD13/A13
AD14/A14
AD15/A15
AD0/A0
AD1/A1
AD2/A2
AD3/A3
AD4/A4
AD5/A5
AD6/A6
AD7/A7
AD8/A8
AD9/A9
AD10/A10
AD11/A11
AD12/A12
AD13/A13
AD14/A14
AD15/A15
23
24
25
26
27
28
29
30
31
32
33
35
36
37
38
39
40
41
42
43
1
2
22
13
3
PC0
PC1
PC2
A19/CSI
BHE/PSEN
WR/VPP
RD
ALE
RESET
24
25
26
27
HSI.0
HSI.1
HSI.2/HSO.4
HSI.3/HSO.5
13
37
12
2
VREF
VPP
ANGND
EA
19
20
21
22
23
30
31
32
60
59
58
57
56
55
54
53
52
51
50
49
48
47
46
45
65
41
40
61
62
63
28
29
34
35
P1.0
P1.1
P1.2
P1.3
P1.4
P1.5
P1.6
P1.7
P3.0/AD0
P3.1/AD1
P3.2/AD2
P3.3/AD3
P3.4/AD4
P3.5/AD5
P3.6/AD6
P3.7/AD7
P4.0/AD8
P4.1/AD9
P4.2/AD10
P4.3/AD11
P4.4/AD12
P4.5/AD13
P4.6/AD14
P4.7/AD15
CLKOUT
BHE/WRH
WR/WRL
RD
ALE/ADV
INST
HSO.0
HSO.1
HSO.2
HSO.3
0.1µF
0.1µF
FOUR
GENERAL
PURPOSE
INPUTS
GND GND
12 34
+5V +5V
+5V
4.7K4.7K
0.1µF
ALE
WAIT
SHARED
BUS
PORT 1
I/O PINS
44
VCC
VCC
VSS VSS
ADDRESS/DATA
MULTIPLEXED BUS
80C196KB PSD3XX
Figure 13. PSD3XX Interface With Intel’s 80C196KB
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PSD3XX Family
30
15.0
Security Mode
Security Mode in the PSD3XX locks the contents of PAD A, PAD B, and all the configuration
bits. The EPROM, optional SRAM, and I/O contents can be accessed only through the
PAD. The Security Mode must be set by PSDsoft prior to run-time. The Security Bit can only
be erased on the UV parts using a full-chip erase. If Security Mode is enabled, the contents
of the PSD3XX can not be uploaded (copied) on a device programmer.
16.0
Power
Management
PSDs from all PSD3XX families use Zero-power memory techniques that place memory
into Standby Mode between MCU accesses. The memory becomes active briefly after an
address transition, then delivers new data to the outputs, latches the outputs, and returns to
Standby. This is done automatically and the designer has to do nothing special to benefit
from this feature.
In addition to the benefits of Zero-power memory technology, there are ways to gain addi-
tional savings. The following factors determine how much current the entire PSD device
uses:
Use of CSI (Chip Select Input)
Setting of the CMiser bit
Setting of the Turbo Bit (ZPSD only)
The number of product terms used in the PAD
The composite frequency of the input signals to the PAD
The loading on I/O pins.
The total current consumption for the PSD is calculated by summing the currents from
memory, PAD logic, and I/O pins, based on your design parameters and the power
management options used.
16.1 CSI Input
Driving the CSI pin inactive (logic 1) disables the inputs of the PSD and forces the entire
PSD to enter Power-down Mode, independent of any transition on the MCU bus (address
and control) or other PSD inputs. During this time, the PSD device draws only standby
current (micro-amps). Alternately, driving a logic 0 on the CSI pin returns the PSD to normal
operation. See Tables 7A and 7B for information on signal states during Power-down Mode.
The CSI pin feature is available only if enabled in the PSDsoft Configuration utility.
16.2 CMiser bit
In addition to power savings resulting from the Zero-power technology used in the memory,
the CMiser feature saves even more power under certain conditions. Savings are significant
when the PSD is configured for an 8-bit data path because the CMiser feature turns off half
of the array when memory is being accessed (the memory is divided internally into odd and
even arrays). See the DC characteristics table for current usage related to the CMiser bit.
You should keep the following in mind when using this bit:
Setting of this bit is accomplished with PSDsoft at the design stage, prior to run-time.
Memory access times are extended by 10 nsec for standard voltage (non-V) devices,
and 20 nsec for low voltage (V) devices.
EPROM access: although CMiser offers significant power savings in 8-bit mode
(~50%), CMiser contributes no additional power savings when the PSD is configured
for 16-bits.
SRAM access: CMiser reduces power consumption of PSDs configured for either 8-bit
or 16-bit operation.
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31
16.
Power
Management
(cont.)
16.3 Turbo Bit (ZPSD only)
The turbo bit is controlled by the MCU at run-time and is accessed through bit zero of the
Power Management Register (PMR). The PMR is located in CSIOPORT space at offset 10h.
Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0
*******
Turbo bit
1=OFF 1=OFF 1=OFF 1=OFF 1=OFF 1=OFF 1=OFF 1=OFF
Power Management Register (PMR)
*Future Configuration bits are reserved and should be set to one when writing to this register.
The default value at reset of all bits in the PMR is logic 0, which means the Turbo feature is
enabled. The PAD logic (PAD A and PAD B) of the PSD will operate at full speed and full
power. When the Turbo Bit is set to logic 1, the Turbo feature is disabled. When disabled,
the PAD logic will draw only standby current (micro-amps) while no PAD inputs change.
Whenever there is a transition on any PAD input (including MCU address and control
signals), the PAD logic will power up and will generate new outputs, latch those outputs,
then go back to Standby Mode. Keep in mind that the signal propagation delay through the
PAD logic increases by 10 nsec for non-V devices, and 20 nsec for V devices while in
non-turbo mode. Use of the Turbo Bit does not affect the operation or power consumption
of memory.
Tremendous power savings are possible by setting the Turbo Bit and going into non-turbo
mode. This essentially reduces the DC power consumption of the PAD logic to zero. It also
reduces the AC power consumption of PAD logic when the composite frequency of all PAD
inputs change at a rate less than 40 MHz for non-V devices, and less than 20 MHz for V
devices. Use Figures 14 and 15 to calculate AC and DC current usage in the PAD with the
Turbo Bit on and off. You will need to know the number of product terms that are used in
your design and you will have to calculate the composite frequency of all signals entering
the PAD logic.
16.4 Number of Product Terms in the PAD Logic
The number of product terms used in your design relates directly to how much current the
PADs will draw. Therefore, minimizing this number will be in your best interest if power is a
concern for you. Basically, the amount of product terms your design will use is based on the
following (see Figure 4):
Each of the EPROM block selects, ES0-ES7 uses one product term (for a total of 8).
The CSIOPORT select uses one product term.
If your part has SRAM (non-R versions), the SRAM select RS0 uses one product term.
The Track Mode control signals (CSADIN, CSADOUT1, and CSADOUT2) each use
one product term if you use these signals.
Port B, pins PB0-PB3 are allocated four product terms each if used as outputs.
Port B, pins PB4-PB7 are allocated two product terms each if used as outputs.
Port C, pins PC0-PC2 are allocated one product term each if used as outputs.
Given the above product term allocation, keep the following points in mind when calculating
the total number of product terms your design will require:
1) The EPROM block selects, CSIOPORT select, and SRAM select will use a product term
whether you use these blocks or not. This means you start out with 10 product terms,
and go up from there.
2) For Port B, if you use a pin as an output and your logic equation requires only one
product term, you still have to include all the available product terms for that pin for
power consumption, even though only one product term is specified. For example, if the
output equation for pin PB0 uses just one product term, you will have to count PB0 as
contributing four product terms to the overall count. With this in mind, you should use
Port C for the outputs that only require one product term and PB4-7 for outputs that
require two product terms. Use pins PB0-3 if you need outputs requiring more than two
product terms or you have run out of outputs.
3) The following PSD functions do not consume product terms: MCU I/O mode, Latched
Address Output, and PAD inputs (logic or address).
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16.0
Power
Management
(cont.)
16.5 Composite Frequency of the Input Signals to the PAD Logic
The composite frequency of the input signals to the PADs is calculated by considering all
transitions on any PAD input signal (including the MCU address and control inputs). Once
you have calculated the composite frequency and know the number of product terms used,
you can determine the total AC current consumption of the PAD by using Figure 14 or
Figure 15. From the figures, notice that the DC component (f = 0 MHz) of PAD current is
essentially zero when the turbo feature is disabled, and that the AC component increases
as frequency increases.
When the turbo feature is disabled, the PAD logic can achieve low power consumption by
becoming active briefly, only when inputs change. For standard voltage (non-V) devices,
the PAD logic will stay active for 25 nsec after it detects a transition on any input. If there
are more transitions on any PAD input within the 25 nsec period, these transitions will not
add to power consumption because the PAD logic is already active. This effect helps
reduce the overall composite frequency value. In other words, narrowly spaced groups of
transitions on input signals may count as just one transition when estimating the composite
frequency.
Note that the “knee” frequency in Figure 14 is 40 MHz, which means that the PAD will
consume less power only if the composite frequency of all PAD inputs is less than 40 MHz.
When the composite frequency is above 40 MHz, the PAD logic never gets a chance to shut
down (inputs are spaced less than 25 nsec) and no power savings can be achieved. Figure
15 is for low-voltage devices in which the “knee” frequency is 20 MHz.
Take the following steps to calculate the composite frequency:
1) Determine your highest frequency input for either PAD A or PAD B.
2) Calculate the period of this input and use this period as a basis for determining the
composite frequency.
3) Examine the remaining PAD input signals within this base period to determine the
number of distinct transitions.
4) Signal transitions that are spaced further than 25 nsec apart count as a distinct transition
(50 nsec for low-voltage V devices). Signal transitions spaced closer than 25 nsec count
as the same transition.
5) Count up the number of distinct transitions and divide that into the value of the base
period.
6) The result is the period of the composite frequency. Divide into one to get the composite
frequency value.
Unfortunately, this procedure is complicated and usually not deterministic since different
inputs may be changing in various cycles. Therefore, we recommend you think of the
situation that has the most activity on the inputs to the PLD and use this to calculate the
composite frequency. Then you will have a number that represents your best estimate at
the worst case scenario.
Since this is a complicated process, the following example should help.
Example Composite Frequency Calculation
Suppose you had the following circuit:
80C31
(12 MHz
Crystal)
PSD3XX
PA
PB
PC
AD0-AD7 Latched Address
Output (LA0-LA7)
A8-A15
ALE
RD
WR
PSEN
CSI
3 Inputs: Int, Sel, Rdy
5 MCU I/O Outputs
3 Chip-Select Outputs
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33
All the inputs shown, except CSI, go to the PAD logic. These signals must be taken into
consideration when calculating the composite frequency. Before we make the calculation,
let’s establish the following conditions:
The input with the highest frequency is ALE, which is 2 MHz. So our base period is
500 nsec for this example.
Only the address information from the multiplexed signals AD0-AD7 reach the PAD
logic because of the internal address latch. Signal transitions from data on AD0-AD7
do not reach the PADs.
The three inputs (Int, Sel, or Rdy) change state very infrequently relative to the 80C31
bus signals.
Now, lets assume the following is a snapshot in time of all the input signals during a typical
80C31 bus cycle. We’ll use a code fetch as an example since that happens most often.
16.0
Power
Management
(cont.)
ONE TYPICAL 80C31 BUS CYCLE (2 MHz, 500 nsec)
ALE
PSEN
AD0-AD7
A8-A15
INT
SEL
RDY
FOUR DISTINCT
TRANSITIONS
<25 nsec
ADDR DATA
1
2
3
The calculation of the composite frequency is as follows:
There are four distinct transitions (first four dotted lines) within the base period of
500 nsec. These first four transitions all count toward the final composite frequency.
The transition at (1) in the diagram does not count as a distinct transition because it is
within 25 nsec of a neighboring transition (use 50 nsec for a ZPSD3XXV device).
Transition (2) above does not add to the composite frequency because only the
internally latched address signals reach the PADs, the data signal transitions do not.
The transition at (3) just happens to appear in this snapshot, but its frequency is so
low that it is not a significant contributor to the overall composite frequency, and will
not be used.
Divide the 500 nsec base period by the four (distinct transitions), yielding 125 nsec.
1/125 nsec = 8 MHz.
Use 8 MHz as the composite frequency of PAD inputs when calculating current
consumption. (See the next section for a sample current calculation.)
16.6 Loading on I/O pins
A final consideration when calculating the current usage for the entire PSD device is the
loading on I/O pins. All specifications for PSD current consumption in this document
assume zero current flowing through PSD I/O pins (including ADIO). I/O current is dictated
by the individual design implementation, and must be calculated by the designer. Be aware
that I/O current is a function of loading on the pins and the frequency at which the signals
toggle.
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Conditions
Part Used = ZPSD3XX (VCC = 5.0 V)
MCU ALE Clock Frequency = 2.0 MHz
Composite ZPLD Input Frequency = 8.0 MHz (see example in above section)
% EPROM Access = 80%
% SRAM Access = 15%
% I/O access = 5%
%Time CSI is high (standby mode) = 90%
%Time CSI is low (normal operation mode) = 10%
# Product terms used (see previous section) = 13 (13/40 = 33%)
Turbo bit = OFF (Turbo Mode disabled)
CMiser bit = ON
MCU Bus Configuration = 8-bit multiplexed bus mode
Calculation (Based on Typical AC and DC Currents)
ICC total = Istandby x % time CSI is high + [ICC (AC) + ICC (DC)]x % time CSI is low.
= Istandby x % time CSI is high +
[% EPROM Access x 0.8 mA/MHz x Freq. of ALE
+ % SRAM x 1.4 mA/MHz x Freq of ALE
+ ZPLD AC current (Figure 14: 13 PTs, 8 MHz, Non-Turbo)]
x % time CSI is low
= 10 µA x 0.9 + (0.8 x 0.8 mA/MHz x 2 MHz + 0.15 x 1.4 mA/MHz x 2 MHz
+ 5.0 mA) x 0.1
= 9.0 µA + (1.28 mA + 0.42 mA + 5.0 mA) x 0.1
= 679 µA, based on the system operating in standby 90% of the time
Once you have read the “Power Management” section, you should be able to calculate
power. The following is a sample power calculation:
17.
Calculating
Power
NOTES: 1. Calculation is based on the assumption that IOUT = 0 mA (no I/O pin loading)
2. ICC(DC) is zero for all ZPSD devices operating in non-turbo mode.
3. 13 product terms: 8 for EPROM, 3 for Chip Selects, 1 for SRAM, 1 for CSIOPORT.
4. The 5% I/O access in the conditions section is when the MCU accesses CSIOPORT space.
5. Standby Mode can also be achieved without using the CSI pin. The ZPSD device will automatically
go into Standby while no inputs are changing on any pin, and Turbo Mode is disabled.
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17.0
Calculating
Power
(cont.)
00 5 10 15 20 25 30 35 40 45 50
5
10
15
20
25
30
35
40
45
ICC (mA
Composite Frequency at PAD Inputs (MHz)
40 PT Turbo
40 PT Non-Turbo
10 PT Turbo
10 PT Non-Turbo
Figure 14. Typical I
CC
vs. Frequency for the PAD (V
CC
= 5 V)
00 5 10 15 20 25
2
4
6
8
10
12
14
ICC (mA
Composite Frequency at PAD Inputs (MHz)
40 PT Turbo
40 PT Non-Turbo
10 PT Turbo
10 PT Non-Turbo
Figure 15. Typical I
CC
vs. Frequency (V
CC
= 3 V)
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Figure 18. Normalized I
CC
(AC)
(VCC = 3.0 V)
Figure 19. Normalized Access Time (T6)
(VCC = 3.0 V)
Figure 16. I
OL
vs. V
OL
(5 V ± 10%)
Figure 17. Normalized I
CC
(DC vs. V
CC
)
(VCC = 3.0 V)
ZPSD3XXV
ZPSD3XXV ZPSD3XXV
ZPSD3XXV
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Symbol Parameter Condition Min Max Unit
TSTG Storage Temperature CERDIP – 65 + 150 °C
PLASTIC – 65 + 125 °C
Voltage on any Pin With Respect to GND – 0.6 + 7 V
VPP Programming
Supply Voltage With Respect to GND – 0.6 + 14 V
VCC Supply Voltage With Respect to GND – 0.6 + 7 V
ESD Protection >2000 V
18.1 Absolute Maximum Ratings
1
NOTE: 1. Stresses above those listed under Absolute Maximum Ratings may cause permanent damage to the
device. This is a stress rating only and functional operation of the device at these or any other
conditions above those indicated in the operational sections of this specification is not implied.
Exposure to Absolute Maximum Rating conditions for extended periods of time may affect device
reliability.
Range Temperature V
CC
V
CC
Tolerance
Commercial C to +70°C + 3 V1, + 5 V ± 10%
Industrial 40° C to +85°C + 3 V1, + 5 V ± 10%
Symbol Parameter Conditions Min Typ Max Unit
VCC Supply Voltage ZPSD Versions, All Speeds 4.5 5 5.5 V
VCC Supply Voltage ZPSD V Versions Only, 2.7 3.0 5.5 V
All Speeds
18.2 Operating Range
18.3 Recommended Operating Conditions
NOTES: 1. 3 V version available for ZPSD3XXV devices only.
Symbol Parameter Conditions Typical
2
Max Unit
CIN Capacitance (for input pins only) VIN = 0 V 4 6 pF
COUT Capacitance (for input/output pins) VOUT = 0 V 8 12 pF
CVPP Capacitance (for WR/VPP or R/W/VPP)V
PP = 0 V 18 25 pF
NOTES: 1. This parameter is only sampled and is not 100% tested.
2. Typical values are for TA= 25°C and nominal supply voltages.
18.4 Pin Capacitance
1
18.0
Specifications
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NOTES: 1. CMOS inputs: GND ± 0.3 V or VCC ± 0.3V.
2. TTL inputs: VIL 0.8 V, VIH 2.0 V.
3. IOUT = 0 mA.
4. CSI/A19 is high and the part is in a power-down configuration mode.
5. All other cases include CMiser = On and 16-bit bus mode and CMiser = Off and 8- or 16-bit bus mode.
Symbol Parameter Conditions Min Typ Max Unit
VCC Supply Voltage All Speeds 4.5 5 5.5 V
VIH High-Level Input Voltage 4.5 V < VCC > 5.5 V 2 VCC +.1 V
V
IL Low-Level Input Voltage 4.5 V < VCC > 5.5 V 0.5 0.8 V
IOH = –20 µA, VCC = 4.5 V 4.4 4.49 V
VOH Output High Voltage IOH = –2 mA, VCC = 4.5 V 2.4 3.9 V
Output Low Voltage IOL = 20 µA, VCC = 4.5 V 0.01 0.1 V
VOL (See Figure 16) IOL = 8 mA, VCC = 4.5 V 0.15 0.45 V
ZPSD3XX 10 20 µA
ISB Standby Supply Current
(Notes 1,4) PSD3XX
Standby Supply Current 50 100 µA
ILI Input Leakage Current VSS < VIN > VCC –1 ±.1 1 µA
ILO Output Leakage Current .45 < VIN > VCC –10 ±5 10 µA
ZPLD Turbo Mode = Off, f = 0 MHz See ISB µA
ZPSD3XX ZPLD Turbo Mode = On, f = 0 MHz 0.5 1 mA/PT
Operating Suppy Current EPROM, f = 0 MHz 0 0 µA
ICC (DC) SRAM, f = 0 MHz 0 0 µA
(Note 3) PLD, f = 0 MHz 0.5 1 mA/PT
PSD3XX EPROM, f = 0 MHz 0 0 µA
Operating Supply Current SRAM, f = 0 MHz 0 0 µA
ZPLD AC Base See 1.0 mA/MHz
Fig. 14
EPROM Access CMiser = On and 8-Bit Bus Mode 0.8 2.0 mA/MHz
ICC (AC) AC Adder All Other Cases (Note 5) 1.8 4.0 mA/MHz
(Note 3) CMiser = On and 8-Bit Bus Mode 1.4 2.7 mA/MHz
SRAM Access CMiser = On and 16-Bit Bus Mode 2 4 mA/MHz
AC Adder
CMiser = Off 3.8 7.5 mA/MHz
18.5 AC/DC Characteristics – PSD3XX/ZPSD3XX (All 5 V devices)
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Symbol Parameter Conditions Min Typ Max Unit
VCC Supply Voltage All Speeds 2.7 3 5.5 V
VIH High-Level Input Voltage 2.7 V < VCC > 5.5 V .7 VCC VCC +.5 V
V
IL Low-Level Input Voltage 2.7 V < VCC > 5.5 V 0.5 .3 VCC V
IOH = –20 µA, VCC = 2.7 V 2.6 2.69 V
VOH Output High Voltage IOH = –1 mA, VCC = 2.7 V 2.3 2.4 V
IOL = 20 µA, VCC = 2.7 V 0.01 0.1 V
VOL Output Low Voltage IOL = 4 mA, VCC = 2.7 V 0.15 0.45 V
ISB Standby Supply Current VCC = 3.0 V 1 5 µA
(Notes 1,4)
ILI Input Leakage Current VIN = VCC or GND –1 ±.1 1 µA
ILO Output Leakage Current VOUT = VCC or GND –1 .1 1 µA
ZPLD Turbo Mode = Off,
f = 0 MHz, VCC = 3.0 V See ISB µA
ICC (DC) Operating Supply Current ZPLD Turbo Mode = On,
(Note 3) f = 0 MHz, VCC = 3.0 V 0.17 0.35 mA/PT
EPROM, f = 0 MHz,
VCC = 3.0 V 00µA
ZPLD AC Base See Figure 15 (VCC = 3.0 V) See 0.5 mZ/MHz
Fig. 15
CMiser = On and 8-Bit Bus
EPROM Access Mode (VCC = 3.0 V) 0.4 1 mA/MHz
AC Adder All Other Cases (Note 5)
ICC (AC) (VCC = 3.0 V) 0.9 1.7 mA/MHz
(Note 3) CMiser = On and 8-Bit Bus 0.7 1.4 mA/MHz
Mode (VCC = 3.0 V)
SRAM Access AC Adder CMiser = On and 16-Bit Bus 1 2 mA/MHz
Mode (VCC = 3.0 V)
CMiser = Off (VCC = 3.0 V) 1.9 3.8 mA/MHz
18.6 AC/DC DC Characteristics – ZPSD3XXV (3 V devices only)
NOTES: 1. CMOS inputs: GND ± 0.3 V or VCC ± 0.3V.
2. TTL inputs: VIL 0.8 V, VIH 2.0 V.
3. IOUT = 0 mA.
4. CSI/A19 is high and the part is in a power-down configuration mode.
5. All other cases include CMiser = On and 16-bit bus mode and CMiser = Off and 8- or 16-bit bus mode.
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-70 -90* -15
CMiser Turbo
Symbol Parameter On = Off = Unit
Min Max Min Max Min Max Add Add
T1 ALE or AS Pulse Width 18 20 40 0 0 ns
T2 Address Set-up Time 5 5 12 0 0 ns
T3 Address Hold Time 7 8 10 0 0 ns
T4 Leading Edge of Read
to Data Active 000 00ns
T5 ALE Valid to Data Valid 80 100 160 10 0 ns
T6 Address Valid to Data Valid 70 90 150 10 0 ns
T7 CSI Active to Data Valid 80 100 160 10 0 ns
T8 Leading Edge of Read
to Data Valid 20 32 55 0 0 ns
Leading Edge of Read to
Data Valid in 8031-Based
T8A Architecture Operating with 32 32 55 0 0 ns
PSEN and RD in Separate
Mode
T9 Read Data Hold Time 0 0 0 0 0 ns
T10 Trailing Edge of Read to
Data High-Z 20 32 35 0 0 ns
Trailing Edge of ALE or AS
T11 to Leading Edge of Write 000 00ns
T12 RD, E, PSEN, or DS Pulse Width 35 40 60 0 0 ns
T12A WR Pulse Width 18 20 35 0 0 ns
Trailing Edge of Write or Read
T13 to Leading Edge of ALE or AS 555 00ns
T14 Address Valid to Trailing Edge
of Write 70 90 150 0 0 ns
CSI Active to Trailing Edge
T15 of Write 80 100 160 0 0 ns
T16 Write Data Set-up Time 18 20 30 0 0 ns
T17 Write Data Hold Time 5 5 10 0 0 ns
T18 Port to Data Out Valid
Propagation Delay 25 30 35 0 0 ns
T19 Port Input Hold Time 0 0 0 0 0 ns
T20 Trailing Edge of Write to Port
Output Valid 30 40 50 0 0 ns
T21 ADi1or Control to CSOi2Valid 6 20 6 25 6 35 0 10 ns
T22 ADi1or Control to CSOi2Invalid 5 20 5 25 4 35 0 10 ns
18.7 Timing Parameters – PSD3XX/ZPSD3XX (All 5 V devices)
*-90 speed available only on Industrial Temperature versions.
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-70 -90* -15
CMiser Turbo
Symbol Parameter On = Off = Unit
Min Max Min Max Min Max Add Add
Track Mode Address
Propagation Delay: 22 22 28 0 0 ns
T23 CSADOUT1 Already True
Latched Address Outputs,
Port A 22 22 28 0 0
Track Mode Address
Propagation Delay:
T23A CSADOUT1 Becomes True 33 33 50 0 10 ns
During ALE or AS
Track Mode Trailing Edge of
T24 ALE or AS to Address High-Z 30 32 35 0 0 ns
T25 Track Mode Read Propagation
Delay 27 29 35 0 0 ns
T26 Track Mode Read Hold Time 5 29 11 29 11 29 0 0 ns
T27 Track Mode Write Cycle,
Data Propagation Delay 18 20 30 0 0 ns
Track Mode Write Cycle,
T28 Write to Data Propagation Delay 630830940 0 10ns
Hold Time of Port A Valid
T29 During Write CSOi2Trailing Edge 222 00ns
T30 CSI Active to CSOi2Active 8 37 9 40 9 50 0 0 ns
T31 CSI Inactive to CSOi2Inactive 8 37 9 40 9 50 0 0 ns
T32 Direct PAD Input3as Hold Time 0 10 12 0 0 ns
T33 R/W Active to E or DS Start 18 20 30 0 0 ns
T34 E or DS End to R/W 18 20 30 0 0 ns
T35 AS Inactive to E high 0 0 0 0 0 ns
T36 Address to Leading Edge
of Write 18 20 25 0 0 ns
18.7 Timing Parameters – PSD3XX/ZPSD3XX (All 5 V devices)
(cont.)
NOTES: 1. ADi = any address line.
2. CSOi = any of the chip-select output signals coming through Port B (CS0–CS7) or through Port C (CS8–CS10).
3. Direct PAD input = any of the following direct PAD input lines: CSI/A19 as transparent A19, RD/E/DS, WR or
R/W, transparent PC0–PC2, ALE (or AS).
4. Control signals RD/E/DS or WR or R/W.
*-90 speed available only on Industrial Temperature versions.
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42
-15* -20 -25
CMiser Turbo
Symbol Parameter On = Off = Unit
Min Max Min Max Min Max Add Add
T1 ALE or AS Pulse Width 40 50 60 0 0 ns
T2 Address Set-up Time 12 15 20 0 0 ns
T3 Address Hold Time 10 15 20 0 0 ns
T4 Leading Edge of Read
to Data Active 000 00ns
T5 ALE Valid to Data Valid 170 200 250 20 0 ns
T6 Address Valid to Data Valid 150 200 250 20 0 ns
T7 CSI Active to Data Valid 160 200 250 20 0 ns
T8 Leading Edge of Read
to Data Valid 45 50 60 0 0 ns
Leading Edge of Read to
Data Valid in 8031-Based
T8A Architecture Operating with 65 70 80 0 0 ns
PSEN and RD in Separate
Mode
T9 Read Data Hold Time 0 0 0 0 0 ns
T10 Trailing Edge of Read to
Data High-Z 45 50 55 0 0 ns
Trailing Edge of ALE or AS
T11 to Leading Edge of Write 000 00ns
T12 RD, E, PSEN, or DS Pulse Width 60 75 85 0 0 ns
T12A WR Pulse Width 35 45 55 0 0 ns
Trailing Edge of Write or Read
T13 to Leading Edge of ALE or AS 555 00ns
T14 Address Valid to Trailing Edge
of Write 150 200 250 0 0 ns
CSI Active to Trailing Edge
T15 of Write 160 200 250 0 0 ns
T16 Write Data Set-up Time 30 40 50 0 0 ns
T17 Write Data Hold Time 10 12 15 0 0 ns
T18 Port to Data Out Valid
Propagation Delay 45 50 60 0 0 ns
T19 Port Input Hold Time 0 0 0 0 0 ns
T20 Trailing Edge of Write to Port
Output Valid 50 60 70 0 0 ns
T21 ADi1or Control to CSOi2Valid 6 50 5 55 5 60 0 20 ns
T22 ADi1or Control to CSOi2Invalid 4 50 4 55 4 60 0 20 ns
18.8 Timing Parameters – ZPSD3XXV (3 V devices only)
*-15 speed available only on ZPSD311V.
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43
NOTES: 1. ADi = any address line.
2. CSOi = any of the chip-select output signals coming through Port B (CS0–CS7) or through Port C (CS8–CS10).
3. Direct PAD input = any of the following direct PAD input lines: CSI/A19 as transparent A19, RD/E/DS, WR or
R/W, transparent PC0–PC2, ALE (or AS).
4. Control signals RD/E/DS or WR or R/W.
*-15 speed available only on ZPSD311V.
-15* -20 -25
CMiser Turbo
Symbol Parameter On = Off = Unit
Min Max Min Max Min Max Add Add
Track Mode Address
Propagation Delay: 50 60 60 0 0 ns
T23 CSADOUT1 Already True
Latched Address Outputs,
Port A 50 60 60 0 0
Track Mode Address
Propagation Delay:
T23A CSADOUT1 Becomes True 70 80 90 0 20 ns
During ALE or AS
Track Mode Trailing Edge of
T24 ALE or AS to Address High-Z 50 60 60 0 0 ns
T25 Track Mode Read Propagation
Delay 45 55 60 0 0 ns
T26 Track Mode Read Hold Time 10 70 10 70 10 70 0 0 ns
T27 Track Mode Write Cycle,
Data Propagation Delay 45 55 60 0 0 ns
Track Mode Write Cycle,
T28 Write to Data Propagation Delay 865875880 0 20ns
Hold Time of Port A Valid
T29 During Write CSOi2Trailing Edge 233 00ns
T30 CSI Active to CSOi2Active 9 70 9 80 9 90 0 0 ns
T31 CSI Inactive to CSOi2Inactive 9 70 9 80 9 90 0 0 ns
T32 Direct PAD Input3as Hold Time 0 0 0 0 0 ns
T33 R/W Active to E or DS Start 30 40 50 0 0 ns
T34 E or DS End to R/W 30 40 50 0 0 ns
T35 AS Inactive to E high 0 0 0 0 0 ns
T36 Address to Leading Edge
of Write 30 35 40 0 0 ns
18.8 Timing Parameters – ZPSD3XXV (3 V devices only)
(cont.)
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18.9 Timing Diagrams for all PSD3XX Parts
Figure 20. Timing of 8-Bit Multiplexed Address/Data Bus Using RD, WR (PSD3X1)
18
DATA VALID
CSI/A19
as CSI
DATA
IN
812
1
715
32
32
14
14
6
6
10
9
ADDRESS A ADDRESS B
23
413
32
5
2
16 17
12A
19
13
20
2323
ADDRESS A ADDRESS B
INPUT
INPUT OUTPUT
OUTPUT
READ CYCLE WRITE CYCLE
STABLE INPUT STABLE INPUT
Direct (1)
PAD Input
Multiplexed (2)
Inputs
A0/AD0-
A7/AD7
Active Low
ALE
Active High
ALE
RD/E as RD
BHE/PSEN
as PSEN
WR/VPP or
RW as WR
Any of
PA0-PA7
as I/O Pin
Any of
PA0-PA7 Pins
as Address
Outputs
Any of
PB0-PB7
as I/O Pin
1
3
11
36
See referenced notes on page 64.
PSD3XX Family
44
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PSD3XX Family
45
Figure 21. Timing of 8-Bit Multiplexed Address/Data Bus Using RD, WR (PSD3X2/3X3)
18
DATA VALID
CSI/A19
as CSI
DATA
IN
812
1
715
32
32
14
14
6
6
10
9
ADDRESS A ADDRESS B
23
413
32
5
2
16 17
12A
19
13
20
2323
ADDRESS A ADDRESS B
INPUT
INPUT OUTPUT
OUTPUT
READ CYCLE WRITE CYCLE
STABLE INPUT STABLE INPUT
Direct (1)
PAD Input
Multiplexed (2)
Inputs
A0/AD0-
A7/AD7
Active Low
ALE
Active High
ALE
RD/E/DS as RD
BHE/PSEN
as PSEN
WR/VPP or
RW as WR
Any of
PA0-PA7
as I/O Pin
Any of
PA0-PA7 Pins
as Address
Outputs
Any of
PB0-PB7
as I/O Pin
1
3
11
36
See referenced notes on page 64
Obsolete Product(s) - Obsolete Product(s)
Obsolete Product(s) - Obsolete Product(s) Obsolete Product(s) - Obsolete Product(s)
PSD3XX Family
46
Figure 22. Timing of 8-Bit Multiplexed Address/Data Bus Using R/W, E or R/W, DS (PSD3X1)
18
33
34
36
19
DATA VALID
CSI/A19
as CSI
DATA
IN
8
12
5
1
32
715
32
32
14
14
6
6
10
9
ADDRESS A ADDRESS B
23
4
33
13
2
16 17
12
13
20
2323
ADDRESS A ADDRESS B
INPUT
INPUT OUTPUT
OUTPUT
READ CYCLE WRITE CYCLE
STABLE INPUT STABLE INPUT
Direct (1)
PAD Input
Multiplexed (2)
Inputs
A0/AD0-
A7/AD7
Active Low
AS
Active High
AS
RD/E as E
WR/VPP or
R/W as R/W
Any of
PA0-PA7
as I/O Pin
Any of
PA0-PA7 Pins
as Address
Outputs
Any of
PB0-PB7
as I/O Pin
1
3
34
35
35
See referenced notes on page 64.
Obsolete Product(s) - Obsolete Product(s)
Obsolete Product(s) - Obsolete Product(s) Obsolete Product(s) - Obsolete Product(s)
PSD3XX Family
47
Figure 23. Timing of 8-Bit Multiplexed Address/Data Bus Using R/W E or R/W, DS
(PSD3X2/3X3)
18
33
34
36
19
DATA VALID
CSI/A19
as CSI
DATA
IN
8
12
5
1
32
715
32
32
14
14
6
6
10
9
ADDRESS A ADDRESS B
23
4
33
13
2
16 17
12 13
20
2323
ADDRESS A ADDRESS B
INPUT
INPUT OUTPUT
OUTPUT
READ CYCLE WRITE CYCLE
STABLE INPUT STABLE INPUT
Direct (1)
PAD Input
Multiplexed (2)
Inputs
A0/AD0-
A7/AD7
Active Low
AS
Active High
AS
RD/E/DS as E
WR/VPP or
R/W as R/W
Any of
PA0-PA7
as I/O Pin
Any of
PA0-PA7 Pins
as Address
Outputs
Any of
PB0-PB7
as I/O Pin
1
3
34
35
RD/E/DS as DS
35
See referenced notes on page 64.
Obsolete Product(s) - Obsolete Product(s)
Obsolete Product(s) - Obsolete Product(s) Obsolete Product(s) - Obsolete Product(s)
PSD3XX Family
48
Figure 24. Timing of 16-Bit Multiplexed Address/Data Bus Using RD, WR (PSD3X1)
18
36
4
19
DATA VALID
CSI/A19
as CSI
12
5
1
715
32
32
14
14
6
6
10
9
ADDRESS A ADDRESS B
23
813
2
16 17
12A 13
20
2323
ADDRESS A ADDRESS B
INPUT
INPUT OUTPUT
OUTPUT
READ CYCLE WRITE CYCLE
STABLE INPUT STABLE INPUT
Direct (1)
PAD Input
Multiplexed (2)
Inputs
DATA
IN
A0/AD0-
A15/AD15
Active Low
ALE
Active High
ALE
RD/E as RD
BHE/PSEN
as BHE
Any of
PA0-PA7
as I/O Pin
Any of
PA0-PA7 Pins
as Address
Outputs
Any of
PB0-PB7
as I/O Pin
1
3
11
WR/VPP or
R/W as WR
32
See referenced notes on page 64.
Obsolete Product(s) - Obsolete Product(s)
Obsolete Product(s) - Obsolete Product(s) Obsolete Product(s) - Obsolete Product(s)
PSD3XX Family
49
Figure 25. Timing of 16-Bit Multiplexed Address/Data Bus Using RD, WR (PSD3X2/3X3)
18
36
4
19
DATA VALID
CSI/A19
as CSI
12
5
1
715
32
32
14
14
6
6
10
9
ADDRESS A ADDRESS B
23
8
13
2
16 17
12A 13
20
2323
ADDRESS A ADDRESS B
INPUT
INPUT OUTPUT
OUTPUT
READ CYCLE WRITE CYCLE
STABLE INPUT STABLE INPUT
Direct (1)
PAD Input
Multiplexed (2)
Inputs
DATA
IN
A0/AD0-
A15/AD15
Active Low
ALE
Active High
ALE
RD/E/DS as RD
BHE/PSEN
as BHE
Any of
PA0-PA7
as I/O Pin
Any of
PA0-PA7 Pins
as Address
Outputs
Any of
PB0-PB7
as I/O Pin
1
3
11
WR/VPP or
R/W as WR
32
See referenced notes on page 64.
Obsolete Product(s) - Obsolete Product(s)
Obsolete Product(s) - Obsolete Product(s) Obsolete Product(s) - Obsolete Product(s)
PSD3XX Family
50
Figure 26. Timing of 16-Bit Multiplexed Address/Data Bus Using R/W, E or R/W, DS (PSD3X1)
18 19
33
DATA VALID
CSI/A19
as CSI
1
32
715
32
32
14
14
6
6
10
9
ADDRESS A ADDRESS B
23
35 13
4
2
16 17
20
2323
ADDRESS A ADDRESS B
INPUT
INPUT OUTPUT
OUTPUT
READ CYCLE WRITE CYCLE
STABLE INPUT STABLE INPUT
Direct (1)
PAD Input
Multiplexed (2)
Inputs
DATA
IN
A0/AD0-
A15/AD15
Active Low
AS
Active High
AS
BHE/PSEN
as BHE
Any of
PA0-PA7
as I/O Pin
Any of
PA0-PA7 Pins
as Address
Outputs
Any of
PB0-PB7
as I/O Pin
1
3
35
34 34
33
8
12
512 13
as ERD/E as E as E
WR/VPP or
R/W as R/W 36
See referenced notes on page 64.
Obsolete Product(s) - Obsolete Product(s)
Obsolete Product(s) - Obsolete Product(s) Obsolete Product(s) - Obsolete Product(s)
PSD3XX Family
51
Figure 27. Timing of 16-Bit Multiplexed Address/Data Bus Using R/W, E or R/W, DS
(PSD3X2/3X3)
18 19
33
DATA VALID
CSI/A19
as CSI
1
32
715
32
32
14
14
6
6
10
9
ADDRESS A ADDRESS B
23
35 13
4
2
16 17
20
2323
ADDRESS A ADDRESS B
INPUT
INPUT OUTPUT
OUTPUT
READ CYCLE WRITE CYCLE
STABLE INPUT STABLE INPUT
Direct (1)
PAD Input
Multiplexed (2)
Inputs
DATA
IN
A0/AD0-
A15/AD15
Active Low
AS
Active High
AS
BHE/PSEN
as BHE
Any of
PA0-PA7
as I/O Pin
Any of
PA0-PA7 Pins
as Address
Outputs
Any of
PB0-PB7
as I/O Pin
1
3
35
34 34
33
8
12
5
12 13
RD/E/DS as ERD/E/DS as ERD/E/DS as ERD/E/DS as E
WR/VPP or
R/W as R/W
RD/E/DS as DS 36
See referenced notes on page 64.
Obsolete Product(s) - Obsolete Product(s)
Obsolete Product(s) - Obsolete Product(s) Obsolete Product(s) - Obsolete Product(s)
PSD3XX Family
52
Figure 28. Timing of 8-Bit Non-Multiplexed Address/Data Bus Using RD, WR (PSD3X1)
18
8
19
DATA VALID
CSI/A19
as CSI
12
5
1
715
32
14
14
6
6
10
9
23
4
32
13
2
16
17
12A 13
20
INPUT OUTPUT
READ CYCLE WRITE CYCLE
STABLE INPUT STABLE INPUT
A0/AD0-
A15/AD15
as A0-A15
STABLE INPUT STABLE INPUT
Direct (1)
PAD Input
PC0-PC2,
CSI/A19 as
Multiplexed
Inputs DATA
IN
PA0-PA7
Active Low
ALE
Active High
ALE
RD/E as RD
Any of
PB0-PB7
as I/O Pin
1
3
11
32
32
WR/VPP or
R/W as WR
36
See referenced notes on page 64.
Obsolete Product(s) - Obsolete Product(s)
Obsolete Product(s) - Obsolete Product(s) Obsolete Product(s) - Obsolete Product(s)
PSD3XX Family
53
Figure 29. Timing of 8-Bit Non-Multiplexed Address/Data Bus Using RD, WR (PSD3X2/3X3)
18
8
19
DATA VALID
CSI/A19
as CSI
12
5
1
715
32
14
14
6
6
10
9
23
4
32
13
2
16
17
12A 13
20
INPUT OUTPUT
READ CYCLE WRITE CYCLE
STABLE INPUT STABLE INPUT
A0/AD0-
A15/AD15
as A0-A15
STABLE INPUT STABLE INPUT
Direct (1)
PAD Input
Multiplexed (2)
Inputs DATA
IN
PA0-PA7
Active Low
ALE
Active High
ALE
RD/E/DS as RD
Any of
PB0-PB7
as I/O Pin
1
3
11
32
32
WR/VPP or
R/W as WR
36
See referenced notes on page 64.
Obsolete Product(s) - Obsolete Product(s)
Obsolete Product(s) - Obsolete Product(s) Obsolete Product(s) - Obsolete Product(s)
PSD3XX Family
54
Figure 30. Timing of 8-Bit Non-Multiplexed Address/Data Bus Using R/W, E or R/W, DS
(PSD3X1)
8
DATA VALID
CSI/A19
as CSI
1
715
32
32
14
14
6
6
10
9
23
35
32
32
2
16 17
READ CYCLE WRITE CYCLE
STABLE INPUT STABLE INPUT
A0/AD0-
A15/AD15
as A0-A15
STABLE INPUT STABLE INPUT
Direct (1)
PAD Input
PC0-PC2,
CSI/A19 as
Multiplexed
Inputs DATA
IN
PA0-PA7
Active Low
ALE
Active High
ALE 1
3
35
18
12
19
33
13
20
INPUT OUTPUT
Any of
PB0-PB7
as I/O Pin
4
34 34
33 12 13
RD/E as E as E as E as E
WR/VPP or
R/W as R/W
36
See referenced notes on page 64.
Obsolete Product(s) - Obsolete Product(s)
Obsolete Product(s) - Obsolete Product(s) Obsolete Product(s) - Obsolete Product(s)
PSD3XX Family
55
Figure 31. Timing of 8-Bit Non-Multiplexed Address/Data Bus Using R/W, E or R/W, DS
(PSD3X2/3X3)
8
DATA VALID
CSI/A19
as CSI
1
715
32
32
14
14
6
6
10
9
23
35
32
32
2
16 17
READ CYCLE WRITE CYCLE
STABLE INPUT STABLE INPUT
A0/AD0-
A15/AD15
as A0-A15
STABLE INPUT STABLE INPUT
Direct (1)
PAD Input
Multiplexed (2)
Inputs DATA
IN
PA0-PA7
Active Low
ALE
Active High
ALE 1
3
35
36
18 19
33
13
20
INPUT OUTPUT
Any of
PB0-PB7
as I/O Pin
4
34 34
33
12
512
13
RD/E/DS as ERD/E/DS as ERD/E/DS as ERD/E/DS as E
WR/VPP or
R/W as R/W
RD/E/DS as DS
See referenced notes on page 64.
Obsolete Product(s) - Obsolete Product(s)
Obsolete Product(s) - Obsolete Product(s) Obsolete Product(s) - Obsolete Product(s)
PSD3XX Family
56
Figure 32. Timing of 16-Bit Non-Multiplexed Address/Data Bus Using RD, WR (PSD3X1)
8
CSI/A19
as CSI
1
32
715
32
32
14
6
6
4
32
READ CYCLE WRITE CYCLE
STABLE INPUT STABLE INPUT
A0/AD0-
A15/AD15
as A0-A15
STABLE INPUT STABLE INPUT
Direct (1)
PAD Input
PC0-PC2,
CSI/A19 as
Multiplexed
Inputs
DATA
IN
Active Low
ALE
Active High
ALE 1
3
32
2
11
13
12
12A 13
RD/E as RD
WR/VPP or
R/W as WR
DATA VALID
14
10
9
9
PA0-PA7
(Low Byte)
DATA
IN
DATA VALID
17
16
PB0-PB7
(High Byte)
BHE/PSEN
as BHE
36
See referenced notes on page 64.
Obsolete Product(s) - Obsolete Product(s)
Obsolete Product(s) - Obsolete Product(s) Obsolete Product(s) - Obsolete Product(s)
PSD3XX Family
57
Figure 33. Timing of 16-Bit Non-Multiplexed Address/Data Bus Using RD, WR (PSD3X2/3X3)
8
CSI/A19
as CSI
1
32
715
32
32
14
6
6
4
32
READ CYCLE WRITE CYCLE
STABLE INPUT STABLE INPUT
A0/AD0-
A15/AD15
as A0-A15
STABLE INPUT STABLE INPUT
Direct (1)
PAD Input
Multiplexed (2)
Inputs
DATA
IN
Active Low
ALE
Active High
ALE 1
3
32
2
11
13
12
512A 13
RD/E/DS as RD
WR/VPP or
R/W as WR
DATA VALID
14
10
9
PA0-PA7
(Low Byte)
DATA
IN
DATA VALID
17
16
PB0-PB7
(High Byte)
BHE/PSEN
as BHE
36
See referenced notes on page 64.
Obsolete Product(s) - Obsolete Product(s)
Obsolete Product(s) - Obsolete Product(s) Obsolete Product(s) - Obsolete Product(s)
PSD3XX Family
58
Figure 34. Timing of 16-Bit Non-Multiplexed Address/Data Bus Using R/W, E or R/W, DS
(PSD3X1)
CSI/A19
as CSI
1
32
715
32
32
14
6
6
4
35
32
READ CYCLE WRITE CYCLE
STABLE INPUT STABLE INPUT
A0/AD0-
A15/AD15
as A0-A15
STABLE INPUT STABLE INPUT
Direct (1)
PAD Input
PC0-PC2,
CSI/A19 as
Multiplexed
Inputs
DATA
IN
Active Low
AS
Active High
AS 1
3
3
8
2
2
35
33
DATA VALID
14
10
9
PA0-PA7
(Low Byte)
DATA
IN
DATA VALID
17
16
PB0-PB7
(High Byte)
BHE/PSEN
as BHE
13
34 34
33
12
13
RD/E as Eas E as Eas E
WR/VPP or
R/W as R/W
36
See referenced notes on page 64.
Obsolete Product(s) - Obsolete Product(s)
Obsolete Product(s) - Obsolete Product(s) Obsolete Product(s) - Obsolete Product(s)
PSD3XX Family
59
Figure 35. Timing of 16-Bit Non-Multiplexed Address/Data Bus Using R/W, E or R/W, DS
(PSD3X2/3X3)
CSI/A19
as CSI
1
32
715
32
32
14
6
6
4
35
32
READ CYCLE WRITE CYCLE
STABLE INPUT STABLE INPUT
A0/AD0-
A15/AD15
as A0-A15
STABLE INPUT STABLE INPUT
Direct (1)
PAD Input
Multiplexed (2)
Inputs
DATA
IN
Active Low
AS
Active High
AS 1
3
3
8
2
2
35
33
DATA VALID
14
10
9
PA0-PA7
(Low Byte)
DATA
IN
DATA VALID
17
16
PB0-PB7
(High Byte)
BHE/PSEN
as BHE
13
34 34
33
12
512
13
RD/E/DS as ERD/E/DS as ERD/E/DS as ERD/E/DS as E
WR/VPP or
R/W as R/W
RD/E/DS as DS
36
See referenced notes on page 64.
Obsolete Product(s) - Obsolete Product(s)
Obsolete Product(s) - Obsolete Product(s) Obsolete Product(s) - Obsolete Product(s)
PSD3XX Family
60
Figure 36.
Chip-Select
Output Timing
30
21
31
A19/CSI
as CSI
Direct PAD (1)
Input
Multiplexed (2)
PAD Inputs
CSOi (3,8)
ALE
(Multiplexed
Mode Only)
or ALE
(Multiplexed
Mode Only) 22
1
23
INPUT STABLE
See referenced notes on page 64.
Obsolete Product(s) - Obsolete Product(s)
Obsolete Product(s) - Obsolete Product(s) Obsolete Product(s) - Obsolete Product(s)
PSD3XX Family
61
Figure 37. Port A as AD0AD7 Timing (Track Mode) Using RD, WR (PSD3X1)
25
32
32
12A
28
24
11
DATA VALID
12
1
32
32
24
26 2
ADDRESS ADDRESS
23
22
4
READ CYCLE WRITE CYCLE
STABLE INPUT
STABLE INPUT STABLE INPUT
STABLE INPUT
Direct
PAD Input
(1,4)
Multiplexed
PAD Inputs
(5,7)
A0/AD0-
A7/AD7
or ALE
ALE
RD/E as RD
WR/VPP or
R/W as WR
1
3
27
PA0-PA7
29
CSOi
(3,6)
DATA IN DATA
OUT
WRITTEN
DATA
23
ADR OUT
23
ADR OUT
See referenced notes on page 64.
Obsolete Product(s) - Obsolete Product(s)
Obsolete Product(s) - Obsolete Product(s) Obsolete Product(s) - Obsolete Product(s)
PSD3XX Family
62
Figure 38. Port A as AD0AD7 Timing (Track Mode) Using RD, WR (PSD3X2/3X3)
25
32
32
12A
28
24
11
DATA VALID
12
1
32
32
24
26 2
ADDRESS ADDRESS
23
22
4
READ CYCLE WRITE CYCLE
STABLE INPUT
STABLE INPUT STABLE INPUT
STABLE INPUT
Direct
PAD Input
(1,4)
Multiplexed
PAD Inputs
(5,7)
A0/AD0-
A7/AD7
or ALE
ALE
RD/E/DS as RD
WR/VPP or
R/W as WR
1
3
27
PA0-PA7
29
CSOi
(3,6)
DATA IN DATA
OUT
WRITTEN
DATA
23
ADR OUT
23
ADR OUT
See referenced notes on page 64.
Obsolete Product(s) - Obsolete Product(s)
Obsolete Product(s) - Obsolete Product(s) Obsolete Product(s) - Obsolete Product(s)
PSD3XX Family
63
Figure 39. Port A as AD0–AD7 Timing (Track Mode) Using R/W, E or R/W, DS (PSD3X1)
33
25
33
32
12
28
24
34
35
DATA VALID
12
1
32
32
32
23
24
26 2
ADDRESS ADDRESS
23
2
35
READ CYCLE WRITE CYCLE
STABLE INPUT
STABLE INPUT STABLE INPUT
STABLE INPUT
Direct
PAD Input
(1,4)
Multiplexed
PAD Inputs
(5,7)
A0/AD0-
A7/AD7
or AS
AS
RD/E as Eas E as E as E
WR/VPP or
R/W as R/W
1
3
34
27
23
PA0-PA7
29
CSOi
(3,6)
ADR OUT DATA IN DATA
OUT
WRITTEN
DATA
ADR OUT
See referenced notes on page 64.
Obsolete Product(s) - Obsolete Product(s)
Obsolete Product(s) - Obsolete Product(s) Obsolete Product(s) - Obsolete Product(s)
PSD3XX Family
64
Figure 40. Port A as AD0–AD7 Timing (Track Mode) Using R/W, E or R/W, DS (PSD3X2/3X3)
33
25
33
32
12
28
24
34
35
DATA VALID
12
1
32
32
32
23
24
26 2
ADDRESS ADDRESS
23
2
35
READ CYCLE WRITE CYCLE
STABLE INPUT
STABLE INPUT STABLE INPUT
STABLE INPUT
Direct
PAD Input
(1,4)
Multiplexed
PAD Inputs
(5,7)
A0/AD0-
A7/AD7
or AS
AS
RD/E/DS as ERD/E/DS as ERD/E/DS as ERD/E/DS as E
WR/VPP or
R/W as R/W
1
3
34
27
23
RD/E/DS as DS
PA0-PA7
29
CSOi
(3,6)
ADR OUT DATA IN DATA
OUT
WRITTEN
DATA
ADR OUT
1. Direct PAD input = any of the following direct PAD input lines: CSI/A19 as transparent A19, RD/E/DS, WR or
R/W, transparent PC0–PC2, ALE in non-multiplexed modes.
2. Multiplexed inputs: any of the following inputs that are latched by the ALE (or AS): A0/AD0–A15/AD15,
CSI/A19 as ALE dependent A19, ALE dependent PC0–PC2.
3. CSOi = any of the chip-select output signals coming through Port B (CS0–CS7) or through Port C
(CS8–CS10).
4. CSADOUT1, which internally enables the address transfer to Port A, should be derived only from direct PAD
input signals, otherwise the address propagation delay is slowed down.
5. CSADIN and CSADOUT2, which internally enable the data-in or data-out transfers, respectively, can be
derived from any combination of direct PAD inputs and multiplexed PAD inputs.
6. The write operation signals are included in the CSOi expression.
7. Multiplexed PAD inputs: any of the following PAD inputs that are latched by the ALE (or AS) in the multiplexed
modes: A11/AD11–A15/AD15, CSI/A19 as ALE dependent A19, ALE dependent PC0–PC2.
8. CSOi product terms can include any of the PAD input signals shown in Figure 3, except for reset and CSI.
Notes for
Timing
Diagrams
Obsolete Product(s) - Obsolete Product(s)
Obsolete Product(s) - Obsolete Product(s) Obsolete Product(s) - Obsolete Product(s)
PSD3XX Family
65
Figure 41A. AC Testing Input/Output Waveform (5 V Versions)
Figure 41B. AC Testing Input/Output Waveform (3 V Versions)
3.0V
0V
TEST POINT 1.5V
DEVICE
UNDER TEST
2.01 V
195
CL = 30 pF
(INCLUDING
SCOPE AND JIG
CAPACITANCE)
0.9 VCC
0V
TEST POINT 1.5V
Figure 42A. AC Testing Load Circuit (5 V Versions)
DEVICE
UNDER TEST
2.0 V
400
CL = 30 pF
(INCLUDING
SCOPE AND JIG
CAPACITANCE)
Figure 42B. AC Testing Load Circuit (3 V Versions)
18.10
AC Testing
Obsolete Product(s) - Obsolete Product(s)
Obsolete Product(s) - Obsolete Product(s) Obsolete Product(s) - Obsolete Product(s)
PSD3XX Family
66
44-Pin 44-Pin
Pin Name PLDCC/CLDCC PQFP/TQFP
Package Package
BHE/PSEN 1 39
WR/VPP or R/W 2 40
RESET 3 41
PB7 4 42
PB6 5 43
PB5 6 44
PB4 7 1
PB3 8 2
PB2 9 3
PB1 10 4
PB0 11 5
GND 12 6
ALE or AS 13 7
PA7 14 8
PA6 15 9
PA5 16 10
PA4 17 11
PA3 18 12
PA2 19 13
PA1 20 14
PA0 21 15
RD/E 22 16
AD0/A0 23 17
AD1/A1 24 18
AD2/A2 25 19
AD3/A3 26 20
AD4/A4 27 21
AD5/A5 28 22
AD6/A6 29 23
AD7/A7 30 24
AD8/A8 31 25
AD9/A9 32 26
AD10/A10 33 27
GND 34 28
AD11/A11 35 29
AD12/A12 36 30
AD13/A13 37 31
AD14/A14 38 32
AD15/A15 39 33
PC0 40 34
PC1 41 35
PC2 42 36
A19/CSI 43 37
VCC 44 38
19.0
Pin
Assignments
Obsolete Product(s) - Obsolete Product(s)
Obsolete Product(s) - Obsolete Product(s) Obsolete Product(s) - Obsolete Product(s)
PSD3XX Family
67
Figure 44.
Drawing M1 –
44 Pin Plastic Quad
Flatpack (PQFP)
(Package Type M)
OR
Drawing U1 –
44 Pin Plastic
Thin Quad Flatpack
(TQFP)
(Package Type U)
39 AD15/A15
38 AD14/A14
37 AD13/A13
36 AD12/A12
35 AD11/A11
34 GND
33 AD10/A10
32 AD9/A9
31 AD8/A8
30 AD7/A7
29 AD6/A6
PB4 7
PB3 8
PB2 9
PB1 10
PB0 11
GND 12
ALE or AS 13
PA7 14
PA6 15
PA5 16
PA4 17
PA3 18
PA2 19
PA1 20
PA0 21
RD/E 22
AD0/A0 23
AD1/A1 24
AD2/A2 25
AD3/A3 26
AD4/A4 27
AD5/A5 28
6 PB5
5 PB6
4 PB7
3 RESET
2 WR/V or R/W
1 BHE/PSEN
44 V
43 A19/CSI
42 PC2
41 PC1
40 PC0
PP
CC
PB4
PB3
PB2
PB1
PB0
GND
ALE or AS
PA7
PA6
PA5
PA4
AD15/A15
AD14/A14
AD13/A13
AD12/A12
AD11/A11
GND
AD10/A10
AD9/A9
AD8/A8
AD7/A7
AD6/A6
1
2
3
4
5
6
7
8
9
10
11
33
32
31
30
29
28
27
26
25
24
23
12
13
14
15
16
17
18
19
20
21
22
PA3
PA2
PA1
PA0
RD/E
AD0/A0
AD1/A1
AD2/A2
AD3/A3
AD4/A4
AD5/A5
PB5
PB6
PB7
RESET
WR/VPP or R/W
BHE/PSEN
VCC
A19/CSI
PC2
PC1
PC0
44
43
42
41
40
39
38
37
36
35
34
(TOP VIEW)
20.0
Package
Information
Figure 43.
Drawing J2 –
44 Pin Plastic
Leaded Chip
Carrier (PLDCC)
without Window
(Package Type J)
OR
Drawing L4 –
44 Pin Ceramic
Leaded Chip
Carrier (CLDCC)
with Window
(Package Type L)
Obsolete Product(s) - Obsolete Product(s)
Obsolete Product(s) - Obsolete Product(s) Obsolete Product(s) - Obsolete Product(s)
PSD3XX Family
68
Family: Plastic Leaded Chip Carrier
Millimeters Inches
Symbol Min Max Notes Min Max Notes
A 4.19 4.57 0.165 0.180
A1 2.54 2.79 0.100 0.110
A2 3.76 3.96 0.148 0.156
B 0.33 0.53 0.013 0.021
B1 0.66 0.81 0.026 0.032
C 0.246 0.262 0.0097 0.0103
D 17.40 17.65 0.685 0.695
D1 16.51 16.61 0.650 0.654
D2 14.99 16.00 0.590 0.630
D3 12.70 Reference 0.500 Reference
E 17.40 17.65 0.685 0.695
E1 16.51 16.61 0.650 0.654
E2 14.99 16.00 0.590 0.630
E3 12.70 Reference 0.500 Reference
e1 1.27 Reference 0.050 Reference
N44 44
030195R6
Drawing J2 – 44-Pin Plastic Leaded Chip Carrier (PLDCC) (Package Type J)
D3
BA1 A2
E1 E
D2
A
E2
C
D
D144123
E3
e1
B1
21.0 Package Drawings
Obsolete Product(s) - Obsolete Product(s)
Obsolete Product(s) - Obsolete Product(s) Obsolete Product(s) - Obsolete Product(s)
PSD3XX Family
69
Family: Ceramic Leaded Chip Carrier – CERQUAD
Millimeters Inches
Symbol Min Max Notes Min Max Notes
A 3.94 4.57 0.155 0.180
A1 2.29 2.92 0.090 0.115
A2 3.05 3.68 0.120 0.145
B 0.43 0.53 0.017 0.021
B1 0.66 0.81 0.026 0.032
C 0.15 0.25 0.006 0.010
D 17.40 17.65 0.685 0.695
D1 16.31 16.66 0.642 0.656
D2 14.73 16.26 0.580 0.640
D3 12.70 Reference 0.500 Reference
E 17.40 17.65 0.685 0.695
E1 16.31 16.66 0.642 0.656
E2 14.73 16.26 0.580 0.640
E3 12.70 Reference 0.500 Reference
e1 1.27 Reference 0.050 Reference
N44 44
030195R8
Drawing L4 – 44-Pin Pocketed Ceramic Leaded Chip Carrier (CLDCC) – CERQUAD (Package Type L)
D3
B1
B
A1 A
E1 E
44
D2
A2
C
123
E2
D1
D
E3
e1
View A
Commercial and Industrial
packages include the lead pocket
on the underside of the package
but Military packages do not.
View A
Obsolete Product(s) - Obsolete Product(s)
Obsolete Product(s) - Obsolete Product(s) Obsolete Product(s) - Obsolete Product(s)
PSD3XX Family
70
Drawing M1 – 44-Pin Plastic Quad Flatpack (PQFP) (Package Type M)
B
E1 E
1
D3
E3
D1
D
L
a
2
3
44
A2
A
A1 C
Index
Mark
e1
Standoff:
0.10 mm Min
0.25 mm Max
Family: Plastic Quad Flatpack (PQFP)
Millimeters Inches
Symbol Min Max Notes Min Max Notes
α
A 2.35 0.092
A1 1.075 Reference 0.042 Reference
A2 1.95 2.10 0.077 0.083
B 0.30 0.45 0.012 0.018
C 0.13 0.23 0.005 0.009
D 13.20 0.520
D1 10.00 0.394
D3 8.00 Reference 0.315 Reference
E 13.20 0.520
E1 10.00 0.394
E3 8.00 Reference 0.315 Reference
e1 0.80 Reference 0.031 Reference
L 0.73 1.03 0.029 0.040
N44 44
030195R4
Obsolete Product(s) - Obsolete Product(s)
Obsolete Product(s) - Obsolete Product(s) Obsolete Product(s) - Obsolete Product(s)
PSD3XX Family
71
Drawing U1 – 44-Pin Plastic Thin Quad Flatpack (TQFP) (Package Type U)
B
E1 E
1
D3
E3
D1
D
L
a
2
3
44
A2
A
A1 C
Index
Mark
e1
Standoff:
0.05 mm Min
Lead
Coplanarity:
0.102 mm Max.
Family: Plastic Thin Quad Flatpack (TQFP)
Millimeters Inches
Symbol Min Max Notes Min Max Notes
α
A 1.60 0.063
A1 0.54 0.74 0.021 0.029
A2 1.15 1.55 0.045 0.061
B 0.35 Reference 0.014 Reference
C 0.09 0.20 0.004 0.008
D 15.75 16.25 0.620 0.640
D1 13.90 14.10 0.547 0.555
D3 10.00 Reference 0.394 Reference
E 15.75 16.25 0.620 0.640
E1 13.90 14.10 0.547 0.555
E3 10.00 Reference 0.394 Reference
e1 1.00 Reference 0.039 Reference
L 0.35 0.65 0.014 0.026
N44 44
030195R4
Obsolete Product(s) - Obsolete Product(s)
Obsolete Product(s) - Obsolete Product(s) - ObsoletObsolete Product(s) - Obsolete Product(s) - Obsolet
ST Part # MCU PLDs/Decoders I/O Memory Other
PSD ZPSD ZPSD 8-Bit 16-Bit Interface Inputs Product PLD Page Ports Open EPROM SRAM Peripheral Security
@ @ @ Data Data Terms Outputs Reg. Drain Mode
5 V 5 V 2.7 V
PSD311R ZPSD311R X STD 14 40 11 19 X 256Kb X X
PSD301R ZPSD301R X X STD 14 40 11 19 X 256Kb X X
PSD312R ZPSD312R X STD 18 40 11 X 19 X 512Kb X X
PSD302R ZPSD302R X X STD 18 40 11 X 19 X 512Kb X X
PSD313R ZPSD313R X STD 18 40 11 X 19 X 1024Kb X X
PSD303R ZPSD303R X X STD 18 40 11 X 19 X 1024Kb X X
PSD311 ZPSD311 ZPSD311V X STD 14 40 11 19 X 256Kb 16Kb X X
PSD301 ZPSD301 ZPSD301V X X STD 14 40 11 19 X 256Kb 16Kb X X
PSD312 ZPSD312 ZPSD312V X STD 18 40 11 X 19 X 512Kb 16Kb X X
PSD302 ZPSD302 ZPSD302V X X STD 18 40 11 X 19 X 512Kb 16Kb X X
PSD313 ZPSD313 ZPSD313V X STD 18 40 11 X 19 X 1024Kb 16Kb X X
PSD303 ZPSD303 ZPSD303V X X STD 18 40 11 X 19 X 1024Kb 16Kb X X
PSD3XX Family
72
22.1 PSD3XX Family – Selector Guide
22.0
PSD3XX
Ordering
Information
Obsolete Product(s) - Obsolete Product(s)
Obsolete Product(s) - Obsolete Product(s) Obsolete Product(s) - Obsolete Product(s)
PSD3XX Family
73
PSD3XX
Ordering
Information
(cont.)
Temperature (Blank = Commercial,
I = Industrial, M = Military)
Package Type
Speed (-70 = 70ns, -90 = 90ns, -15 = 150ns
-20 = 200ns, -25 = 250ns)
Revision (Blank = No Revision)
Supply Voltage (Blank = 5V, V = 3 Volt)
Base Part Number - see Selector Guide
PSD (ST Programmable System Device) Fam.
Power Down Feature (Blank = Standard,
Z = Zero Power Feature)
Z PSD -A -20 J I
413A2 V
22.2 Part Number Construction
Operating
Speed Temperature
Part Number (ns) Package Type Range
PSD301-B-70J 70 44 Pin PLDCC Comm’l
PSD301-B-70L 70 44 Pin CLDCC Comm’l
PSD301-B-70M 70 44 Pin PQFP Comm’l
PSD301-B-70U 70 44 Pin TQFP Comm’l
PSD301-B-90JI 90 44 Pin PLDCC Industrial
PSD301-B-90LI 90 44 Pin CLDCC Industrial
PSD301-B-90MI 90 44 Pin PQFP Industrial
PSD301-B-90UI 90 44 Pin TQFP Industrial
PSD301-B-15J 150 44 Pin PLDCC Comm’l
PSD301-B-15L 150 44 Pin CLDCC Comm’l
PSD301-B-15M 150 44 Pin PQFP Comm’l
PSD301-B-15U 150 44 Pin TQFP Comm’l
PSD301R-B-70J 70 44 Pin PLDCC Comm’l
PSD301R-B-90JI 90 44 Pin PLDCC Industrial
PSD301R-B-15J 150 44 Pin PLDCC Comm’l
22.3 Ordering Information
Obsolete Product(s) - Obsolete Product(s)
Obsolete Product(s) - Obsolete Product(s) Obsolete Product(s) - Obsolete Product(s)
PSD3XX Family
74
Operating
Speed Temperature
Part Number (ns) Package Type Range
PSD302-B-70J 70 44 Pin PLDCC Comm’l
PSD302-B-70L 70 44 Pin CLDCC Comm’l
PSD302-B-70M 70 44 Pin PQFP Comm’l
PSD302-B-70U 70 44 Pin TQFP Comm’l
PSD302-B-90JI 90 44 Pin PLDCC Industrial
PSD302-B-90LI 90 44 Pin CLDCC Industrial
PSD302-B-90MI 90 44 Pin PQFP Industrial
PSD302-B-90UI 90 44 Pin TQFP Industrial
PSD302-B-15J 150 44 Pin PLDCC Comm’l
PSD302-B-15L 150 44 Pin CLDCC Comm’l
PSD302-B-15M 150 44 Pin PQFP Comm’l
PSD302-B-15U 150 44 Pin TQFP Comm’l
PSD302R-B-70J 70 44 Pin PLDCC Comm’l
PSD302R-B-90JI 90 44 Pin PLDCC Industrial
PSD302R-B-15J 150 44 Pin PLDCC Comm’l
PSD303-B-70J 70 44 Pin PLDCC Comm’l
PSD303-B-70L 70 44 Pin CLDCC Comm’l
PSD303-B-70M 70 44 Pin PQFP Comm’l
PSD303-B-70U 70 44 Pin TQFP Comm’l
PSD303-B-90JI 90 44 Pin PLDCC Industrial
PSD303-B-90LI 90 44 Pin CLDCC Industrial
PSD303-B-90MI 90 44 Pin PQFP Industrial
PSD303-B-90UI 90 44 Pin TQFP Industrial
PSD303-B-15J 150 44 Pin PLDCC Comm’l
PSD303-B-15L 150 44 Pin CLDCC Comm’l
PSD303-B-15M 150 44 Pin PQFP Comm’l
PSD303-B-15U 150 44 Pin TQFP Comm’l
PSD303R-B-70J 70 44 Pin PLDCC Comm’l
PSD303R-B-90JI 90 44 Pin PLDCC Industrial
PSD303R-B-15J 150 44 Pin PLDCC Comm’l
PSD311-B-70J 70 44 Pin PLDCC Comm’l
PSD311-B-70L 70 44 Pin CLDCC Comm’l
PSD311-B-70M 70 44 Pin PQFP Comm’l
PSD311-B-70U 70 44 Pin TQFP Comm’l
PSD311-B-90JI 90 44 Pin PLDCC Industrial
PSD311-B-90LI 90 44 Pin CLDCC Industrial
PSD311-B-90MI 90 44 Pin PQFP Industrial
PSD311-B-90UI 90 44 Pin TQFP Industrial
PSD311-B-15J 150 44 Pin PLDCC Comm’l
PSD311-B-15L 150 44 Pin CLDCC Comm’l
PSD311-B-15M 150 44 Pin PQFP Comm’l
PSD311-B-15U 150 44 Pin TQFP Comm’l
PSD311R-B-70J 70 44 Pin PLDCC Comm’l
PSD311R-B-90JI 90 44 Pin PLDCC Industrial
PSD311R-B-15J 150 44 Pin PLDCC Comm’l
Ordering InformationPSD3XX
Ordering
Information
(cont.)
Obsolete Product(s) - Obsolete Product(s)
Obsolete Product(s) - Obsolete Product(s) Obsolete Product(s) - Obsolete Product(s)
PSD3XX Family
75
PSD3XX
Ordering
Information
(cont.)
Operating
Speed Temperature
Part Number (ns) Package Type Range
PSD312-B-70J 70 44 Pin PLDCC Comm’l
PSD312-B-70L 70 44 Pin CLDCC Comm’l
PSD312-B-70M 70 44 Pin PQFP Comm’l
PSD312-B-70U 70 44 Pin TQFP Comm’l
PSD312-B-90JI 90 44 Pin PLDCC Industrial
PSD312-B-90LI 90 44 Pin CLDCC Industrial
PSD312-B-90MI 90 44 Pin PQFP Industrial
PSD312-B-90UI 90 44 Pin TQFP Industrial
PSD312-B-15J 150 44 Pin PLDCC Comm’l
PSD312-B-15L 150 44 Pin CLDCC Comm’l
PSD312-B-15M 150 44 Pin PQFP Comm’l
PSD312-B-15U 150 44 Pin TQFP Comm’l
PSD312R-B-70J 70 44 Pin PLDCC Comm’l
PSD312R-B-90JI 90 44 Pin PLDCC Industrial
PSD312R-B-15J 150 44 Pin PLDCC Comm’l
PSD313-B-70J 70 44 Pin PLDCC Comm’l
PSD313-B-70L 70 44 Pin CLDCC Comm’l
PSD313-B-70M 70 44 Pin PQFP Comm’l
PSD313-B-70U 70 44 Pin TQFP Comm’l
PSD313-B-90JI 90 44 Pin PLDCC Industrial
PSD313-B-90LI 90 44 Pin CLDCC Industrial
PSD313-B-90MI 90 44 Pin PQFP Industrial
PSD313-B-90UI 90 44 Pin TQFP Industrial
PSD313-B-15J 150 44 Pin PLDCC Comm’l
PSD313-B-15L 150 44 Pin CLDCC Comm’l
PSD313-B-15M 150 44 Pin PQFP Comm’l
PSD313-B-15U 150 44 Pin TQFP Comm’l
PSD313R-B-70J 70 44 Pin PLDCC Comm’l
PSD313R-B-90JI 90 44 Pin PLDCC Industrial
PSD313R-B-15J 150 44 Pin PLDCC Comm’l
Ordering Information
Obsolete Product(s) - Obsolete Product(s)
Obsolete Product(s) - Obsolete Product(s) Obsolete Product(s) - Obsolete Product(s)
PSD3XX Family
76
PSD3XX
Ordering
Information
(cont.)
Operating
Speed Temperature
Part Number (ns) Package Type Range
ZPSD301-B-70J 70 44 Pin PLDCC Comm’l
ZPSD301-B-70L 70 44 Pin CLDCC Comm’l
ZPSD301-B-70M 70 44 Pin PQFP Comm’l
ZPSD301-B-70U 70 44 Pin TQFP Comm’l
ZPSD301-B-90JI 90 44 Pin PLDCC Industrial
ZPSD301-B-90LI 90 44 Pin CLDCC Industrial
ZPSD301-B-90MI 90 44 Pin PQFP Industrial
ZPSD301-B-90UI 90 44 Pin TQFP Industrial
ZPSD301-B-15J 150 44 Pin PLDCC Comm’l
ZPSD301-B-15L 150 44 Pin CLDCC Comm’l
ZPSD301-B-15M 150 44 Pin PQFP Comm’l
ZPSD301-B-15U 150 44 Pin TQFP Comm’l
ZPSD301R-B-70J 70 44 Pin PLDCC Comm’l
ZPSD301R-B-90JI 90 44 Pin PLDCC Industrial
ZPSD301R-B-15J 150 44 Pin PLDCC Comm’l
ZPSD301V-B-15J 150 44 Pin PLDCC Comm’l
ZPSD301V-B-15L 150 44 Pin CLDCC Comm’l
ZPSD301V-B-15U 150 44 Pin TQFP Comm’l
ZPSD301V-B-20J 200 44 Pin PLDCC Comm’l
ZPSD301V-B-20JI 200 44 Pin PLDCC Industrial
ZPSD301V-B-20L 200 44 Pin CLDCC Comm’l
ZPSD301V-B-20M 200 44 Pin PQFP Comm’l
ZPSD301V-B-20MI 200 44 Pin PQFP Industrial
ZPSD301V-B-20U 200 44 Pin TQFP Comm’l
ZPSD301V-B-20UI 200 44 Pin TQFP Industrial
ZPSD301V-B-25J 250 44 Pin PLDCC Comm’l
ZPSD301V-B-25L 250 44 Pin CLDCC Comm’l
ZPSD301V-B-25M 250 44 Pin PQFP Comm’l
ZPSD301V-B-25U 250 44 Pin TQFP Comm’l
ZPSD302-B-70J 70 44 Pin PLDCC Comm’l
ZPSD302-B-70L 70 44 Pin CLDCC Comm’l
ZPSD302-B-70M 70 44 Pin PQFP Comm’l
ZPSD302-B-70U 70 44 Pin TQFP Comm’l
ZPSD302-B-90JI 90 44 Pin PLDCC Industrial
ZPSD302-B-90LI 90 44 Pin CLDCC Industrial
ZPSD302-B-90MI 90 44 Pin PQFP Industrial
ZPSD302-B-90UI 90 44 Pin TQFP Industrial
ZPSD302-B-15J 150 44 Pin PLDCC Comm’l
ZPSD302-B-15L 150 44 Pin CLDCC Comm’l
ZPSD302-B-15M 150 44 Pin PQFP Comm’l
ZPSD302-B-15U 150 44 Pin TQFP Comm’l
ZPSD302R-B-70J 70 44 Pin PLDCC Comm’l
ZPSD302R-B-90JI 90 44 Pin PLDCC Industrial
ZPSD302R-B-15J 150 44 Pin PLDCC Comm’l
Ordering Information
Obsolete Product(s) - Obsolete Product(s)
Obsolete Product(s) - Obsolete Product(s) Obsolete Product(s) - Obsolete Product(s)
PSD3XX Family
77
PSD3XX
Ordering
Information
(cont.)
Operating
Speed Temperature
Part Number (ns) Package Type Range
ZPSD302V-B-20J 200 44 Pin PLDCC Comm’l
ZPSD302V-B-20JI 200 44 Pin PLDCC Industrial
ZPSD302V-B-20L 200 44 Pin CLDCC Comm’l
ZPSD302V-B-20M 200 44 Pin PQFP Comm’l
ZPSD302V-B-20MI 200 44 Pin PQFP Industrial
ZPSD302V-B-20U 200 44 Pin TQFP Comm’l
ZPSD302V-B-20UI 200 44 Pin TQFP Industrial
ZPSD302V-B-25J 250 44 Pin PLDCC Comm’l
ZPSD302V-B-25L 250 44 Pin CLDCC Comm’l
ZPSD302V-B-25M 250 44 Pin PQFP Comm’l
ZPSD302V-B-25U 250 44 Pin TQFP Comm’l
ZPSD303-B-70J 70 44 Pin PLDCC Comm’l
ZPSD303-B-70L 70 44 Pin CLDCC Comm’l
ZPSD303-B-70M 70 44 Pin PQFP Comm’l
ZPSD303-B-70U 70 44 Pin TQFP Comm’l
ZPSD303-B-90JI 90 44 Pin PLDCC Industrial
ZPSD303-B-90LI 90 44 Pin CLDCC Industrial
ZPSD303-B-90MI 90 44 Pin PQFP Industrial
ZPSD303-B-90UI 90 44 Pin TQFP Industrial
ZPSD303-B-15J 150 44 Pin PLDCC Comm’l
ZPSD303-B-15L 150 44 Pin CLDCC Comm’l
ZPSD303-B-15M 150 44 Pin PQFP Comm’l
ZPSD303-B-15U 150 44 Pin TQFP Comm’l
ZPSD303R-B-70J 70 44 Pin PLDCC Comm’l
ZPSD303R-B-90JI 90 44 Pin PLDCC Industrial
ZPSD303R-B-15J 150 44 Pin PLDCC Comm’l
ZPSD303V-B-20J 200 44 Pin PLDCC Comm’l
ZPSD303V-B-20JI 200 44 Pin PLDCC Industrial
ZPSD303V-B-20L 200 44 Pin CLDCC Comm’l
ZPSD303V-B-20M 200 44 Pin PQFP Comm’l
ZPSD303V-B-20MI 200 44 Pin PQFP Industrial
ZPSD303V-B-20U 200 44 Pin TQFP Comm’l
ZPSD303V-B-20UI 200 44 Pin TQFP Industrial
ZPSD303V-B-25J 250 44 Pin PLDCC Comm’l
ZPSD303V-B-25L 250 44 Pin CLDCC Comm’l
ZPSD303V-B-25M 250 44 Pin PQFP Comm’l
ZPSD303V-B-25U 250 44 Pin TQFP Comm’l
Ordering Information
Obsolete Product(s) - Obsolete Product(s)
Obsolete Product(s) - Obsolete Product(s) Obsolete Product(s) - Obsolete Product(s)
PSD3XX Family
78
PSD3XX
Ordering
Information
(cont.)
Operating
Speed Temperature
Part Number (ns) Package Type Range
ZPSD311-B-70J 70 44 Pin PLDCC Comm’l
ZPSD311-B-70L 70 44 Pin CLDCC Comm’l
ZPSD311-B-70M 70 44 Pin PQFP Comm’l
ZPSD311-B-70U 70 44 Pin TQFP Comm’l
ZPSD311-B-90JI 90 44 Pin PLDCC Industrial
ZPSD311-B-90LI 90 44 Pin CLDCC Industrial
ZPSD311-B-90MI 90 44 Pin PQFP Industrial
ZPSD311-B-90UI 90 44 Pin TQFP Industrial
ZPSD311-B-15J 150 44 Pin PLDCC Comm’l
ZPSD311-B-15L 150 44 Pin CLDCC Comm’l
ZPSD311-B-15M 150 44 Pin PQFP Comm’l
ZPSD311-B-15U 150 44 Pin TQFP Comm’l
ZPSD311R-B-70J 70 44 Pin PLDCC Comm’l
ZPSD311R-B-70M 70 44 Pin PQFP Comm’l
ZPSD311R-B-90JI 90 44 Pin PLDCC Industrial
ZPSD311R-B-90MI 90 44 Pin PQFP Industrial
ZPSD311R-B-15J 150 44 Pin PLDCC Comm’l
ZPSD311R-B-15M 150 44 Pin PQFP Comm’l
ZPSD311V-B-15J 150 44 Pin PLDCC Comm’l
ZPSD311V-B-15L 150 44 Pin CLDCC Comm’l
ZPSD311V-B-15M 150 44 Pin PQFP Comm’l
ZPSD311V-B-15U 150 44 Pin TQFP Comm’l
ZPSD311V-B-20J 200 44 Pin PLDCC Comm’l
ZPSD311V-B-20JI 200 44 Pin PLDCC Industrial
ZPSD311V-B-20L 200 44 Pin CLDCC Comm’l
ZPSD311V-B-20M 200 44 Pin PQFP Comm’l
ZPSD311V-B-20MI 200 44 Pin PQFP Industrial
ZPSD311V-B-20U 200 44 Pin TQFP Comm’l
ZPSD311V-B-20UI 200 44 Pin TQFP Industrial
ZPSD311V-B-25J 250 44 Pin PLDCC Comm’l
ZPSD311V-B-25L 250 44 Pin CLDCC Comm’l
ZPSD311V-B-25M 250 44 Pin PQFP Comm’l
ZPSD311V-B-25U 250 44 Pin TQFP Comm’l
Ordering Information
Obsolete Product(s) - Obsolete Product(s)
Obsolete Product(s) - Obsolete Product(s) Obsolete Product(s) - Obsolete Product(s)
PSD3XX Family
79
PSD3XX
Ordering
Information
(cont.)
Operating
Speed Temperature
Part Number (ns) Package Type Range
ZPSD312-B-70J 70 44 Pin PLDCC Comm’l
ZPSD312-B-70L 70 44 Pin CLDCC Comm’l
ZPSD312-B-70M 70 44 Pin PQFP Comm’l
ZPSD312-B-70U 70 44 Pin TQFP Comm’l
ZPSD312-B-90JI 90 44 Pin PLDCC Industrial
ZPSD312-B-90LI 90 44 Pin CLDCC Industrial
ZPSD312-B-90MI 90 44 Pin PQFP Industrial
ZPSD312-B-90UI 90 44 Pin TQFP Industrial
ZPSD312-B-15J 150 44 Pin PLDCC Comm’l
ZPSD312-B-15L 150 44 Pin CLDCC Comm’l
ZPSD312-B-15M 150 44 Pin PQFP Comm’l
ZPSD312-B-15U 150 44 Pin TQFP Comm’l
ZPSD312R-B-70J 70 44 Pin PLDCC Comm’l
ZPSD312R-B-70M 70 44 Pin PQFP Comm’l
ZPSD312R-B-90JI 90 44 Pin PLDCC Industrial
ZPSD312R-B-90MI 90 44 Pin PQFP Industrial
ZPSD312R-B-15J 150 44 Pin PLDCC Comm’l
ZPSD312R-B-15M 150 44 Pin PQFP Comm’l
ZPSD312V-B-20J 200 44 Pin PLDCC Comm’l
ZPSD312V-B-20JI 200 44 Pin PLDCC Industrial
ZPSD312V-B-20L 200 44 Pin CLDCC Comm’l
ZPSD312V-B-20M 200 44 Pin PQFP Comm’l
ZPSD312V-B-20MI 200 44 Pin PQFP Industrial
ZPSD312V-B-20U 200 44 Pin TQFP Comm’l
ZPSD312V-B-20UI 200 44 Pin TQFP Industrial
ZPSD312V-B-25J 250 44 Pin PLDCC Comm’l
ZPSD312V-B-25L 250 44 Pin CLDCC Comm’l
ZPSD312V-B-25M 250 44 Pin PQFP Comm’l
ZPSD312V-B-25U 250 44 Pin TQFP Comm’l
ZPSD313-B-70J 70 44 Pin PLDCC Comm’l
ZPSD313-B-70L 70 44 Pin CLDCC Comm’l
ZPSD313-B-70M 70 44 Pin PQFP Comm’l
ZPSD313-B-70U 70 44 Pin TQFP Comm’l
ZPSD313-B-90JI 90 44 Pin PLDCC Industrial
ZPSD313-B-90LI 90 44 Pin CLDCC Industrial
ZPSD313-B-90MI 90 44 Pin PQFP Industrial
ZPSD313-B-90UI 90 44 Pin TQFP Industrial
ZPSD313-B-15J 150 44 Pin PLDCC Comm’l
ZPSD313-B-15L 150 44 Pin CLDCC Comm’l
ZPSD313-B-15M 150 44 Pin PQFP Comm’l
ZPSD313-B-15U 150 44 Pin TQFP Comm’l
Ordering Information
Obsolete Product(s) - Obsolete Product(s)
Obsolete Product(s) - Obsolete Product(s) Obsolete Product(s) - Obsolete Product(s)
PSD3XX Family
80
PSD3XX
Ordering
Information
(cont.)
Operating
Speed Temperature
Part Number (ns) Package Type Range
ZPSD313R-B-70J 70 44 Pin PLDCC Comm’l
ZPSD313R-B-70M 70 44 Pin PQFP Comm’l
ZPSD313R-B-90JI 90 44 Pin PLDCC Industrial
ZPSD313R-B-90MI 90 44 Pin PQFP Industrial
ZPSD313R-B-15J 150 44 Pin PLDCC Comm’l
ZPSD313R-B-15M 150 44 Pin PQFP Comm’l
ZPSD313V-B-20J 200 44 Pin PLDCC Comm’l
ZPSD313V-B-20JI 200 44 Pin PLDCC Industrial
ZPSD313V-B-20L 200 44 Pin CLDCC Comm’l
ZPSD313V-B-20M 200 44 Pin PQFP Comm’l
ZPSD313V-B-20MI 200 44 Pin PQFP Industrial
ZPSD313V-B-20U 200 44 Pin TQFP Comm’l
ZPSD313V-B-20UI 200 44 Pin TQFP Industrial
ZPSD313V-B-25J 250 44 Pin PLDCC Comm’l
ZPSD313V-B-25L 250 44 Pin CLDCC Comm’l
ZPSD313V-B-25M 250 44 Pin PQFP Comm’l
ZPSD313V-B-25U 250 44 Pin TQFP Comm’l
Ordering Information
Parts Data Sheet
Date Affected Changes
May, 1995 PSD3XX Initial Release
May, 1998 ZPSD3XX SRAM-less (R suffix) version
added.
PQFP package added.
May, 1998 PSD3XX PQFP package added,
Specifications updated,
PSD3XXL discontinued,
Some speed grades eliminated.
February, 1999 PSD3XXR, ZPSD3XXR Combined Data Sheets
Updated Specifications
23.
Revisions
History
Obsolete Product(s) - Obsolete Product(s)
Obsolete Product(s) - Obsolete Product(s) Obsolete Product(s) - Obsolete Product(s)
PSD3XX, ZPSD3XX, ZP SD3XXV, PSD3XXR, ZPSD3XXR, ZPSD3XXRV
2/3
RE VISION HISTORY
Table 1. Document Revi sion History
Date Rev. Description of Revision
May-1995 1.0 Documents written in the WSI format. Initial release
May-1998 1.1
ZPSD3XX SRAM-less (R suffix) version added. PQFP package added.
PSD3XX PQFP package added, Specifications updated, PSD3XXL discontinued, Some speed
grades eliminated.
February, 1999 PSD3XXR, ZPSD3XXR Combined Data Sheets
Updated Specifications
Feb-1999 1.2 PSD3XX ZPSD3XX ZPSD3XXV, PSD3XXR ZPSD3XXR ZPSD3XXRV Combined Data
Sheets Updated Specifications
31-Jan-2002 1.3
PSD3XX, ZPSD3XX, ZPSD3XXV, PSD3XXR, ZPSD3XXR, ZPSD3XXRV: Low Cost Field
Programmable Microcontroller Peripherals
Front page, and back two pages, in ST format, added to the PDF file
Any references to Waferscale, WSI, EasyFLASH and PSDsoft 2000
updated to ST, ST, Flash+PSD and PSDsoft Express
Obsolete Product(s) - Obsolete Product(s)
Obsolete Product(s) - Obsolete Product(s) Obsolete Product(s) - Obsolete Product(s)
3/3
PSD3XX, ZPSD3XX, Z PSD3XXV, PSD3XXR, ZPS D3XXR, ZPSD3XXRV
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Obsolete Product(s) - Obsolete Product(s)