PSD501B1-C-70U [STMICROELECTRONICS]
Low Cost Field Programmable Microcontroller Peripherals; 低成本现场可编程微控制器外设型号: | PSD501B1-C-70U |
厂家: | ST |
描述: | Low Cost Field Programmable Microcontroller Peripherals |
文件: | 总153页 (文件大小:1029K) |
中文: | 中文翻译 | 下载: | 下载PDF数据表文档文件 |
PSD5XX
ZPSD5XX
Low Cost Field Programmable Microcontroller Peripherals
NOT FOR NEW DESIGN
FEATURES SUMMARY
■ Single Supply Voltage:
– 5 V±10% for PSD5XX
– 2.7 to 5.5 V for PSD5XX-V
■ Up to 1 Mbit of UV EPROM
■ Up to 16 Kbit SRAM
■ Input Latches
Figure 1. Packages
■ Programmable I/O ports
■ Page Logic
■ Programmable Security
PLDCC68 (J)
CLDCC68 (L)
TQFP68 (U)
January 2002
1/3
This is information on a product still in production but not recommended for new designs.
PSD5XX Family
PSD5XX/ZPSD5XX
Field-Programmable Microcontroller Peripherals
Table of Contents
1
2
3
4
5
6
7
8
9
Introduction...........................................................................................................................................................1
Key Features ........................................................................................................................................................3
Notation ................................................................................................................................................................4
ZPSD Background................................................................................................................................................4
Integrated Power ManagementTM Operation........................................................................................................6
Design Flow..........................................................................................................................................................7
PSD5XX Family....................................................................................................................................................8
Table 2. PSD5XX Pin Descriptions......................................................................................................................9
The PSD5XX Architecture ..................................................................................................................................11
9.1 The ZPLD Block..........................................................................................................................................11
9.1.1 The DPLD.........................................................................................................................................14
9.1.2 The GPLD.........................................................................................................................................14
9.1.2.1 Por A Macrocell Structure ..................................................................................................16
9.1.2.2 Port B Macrocell Structure .................................................................................................20
9.1.2.3 Port E Macrocell Structure .................................................................................................23
9.1.3 The PPLD.........................................................................................................................................26
9.1.4 The ZPLD Power Management........................................................................................................26
9.2 Bus Interface...............................................................................................................................................29
9.2.1 Bus Interface Configuration..............................................................................................................29
9.2.2 PSD5XX Interface to a Multiplexed Bus...........................................................................................29
9.2.3 PSD5XX Interface to Non-Multiplexed Bus ......................................................................................30
9.2.4 Data Byte Enable..............................................................................................................................30
9.2.5 Optional Features.............................................................................................................................34
9.2.6 Bus Interface Examples....................................................................................................................34
9.3 I/O Ports......................................................................................................................................................39
9.3.1 Standard MCU I/O............................................................................................................................39
9.3.2 PLD I/O ...........................................................................................................................................39
9.3.3 Address Out......................................................................................................................................40
9.3.4 Address In ........................................................................................................................................40
9.3.5 Data Port ..........................................................................................................................................40
9.3.6 Special Function Out ........................................................................................................................40
9.3.7 Alternate Function In ........................................................................................................................41
9.3.8 Peripheral I/O ...................................................................................................................................41
9.3.9 Open Drain Outputs..........................................................................................................................41
9.3.10 Port Registers...................................................................................................................................42
9.3.11 Port A – Functionality and Structure.................................................................................................45
9.3.12 Port B – Functionality and Structure.................................................................................................45
9.3.13 Port C and Port D – Functionality and Structure ..............................................................................48
9.3.14 Port E – Functionality and Structure.................................................................................................48
9.4 Memory Block .............................................................................................................................................52
9.4.1 EPROM ............................................................................................................................................52
9.4.2 SRAM ...............................................................................................................................................52
9.4.3 Memory Select Map..........................................................................................................................52
9.4.4 Memory Select Map for 8031 Application.........................................................................................54
9.4.5 Peripheral I/O ...................................................................................................................................56
i
PSD5XX Family
PSD5XX/ZPSD5XX
Field-Programmable Microcontroller Peripherals
Table of Contents (cont.)
9.5 Power Management Unit ............................................................................................................................58
9.5.1 Standby Mode ..................................................................................................................................58
9.5.2 Power Down .....................................................................................................................................58
9.5.3 Sleep Mode ......................................................................................................................................58
9.5.4 Other Power Saving Options............................................................................................................61
9.6 PSD5XX Counter/Timer ..............................................................................................................................63
9.6.1 Counter/Timer Operation..................................................................................................................66
9.6.2 Counter/Timer Registers ..................................................................................................................81
9.7 Interrupt Controller ......................................................................................................................................95
9.7.1 Interrupt Operation ...........................................................................................................................95
9.7.2 Input/Output....................................................................................................................................100
9.7.3 PPLD Macrocell..............................................................................................................................100
9.7.4 Interrupt Flowchart..........................................................................................................................100
10.0 Page Register...................................................................................................................................................103
11.0 Security Protection............................................................................................................................................103
12.0 System Configuration .......................................................................................................................................104
12.1 Reset Input ............................................................................................................................................108
12.2 ZPLD and Memory During Reset...........................................................................................................108
12.3 Register Values During and After Reset................................................................................................108
12.4 ZPLD Macrocell Initialization .................................................................................................................108
13.0 Specifications....................................................................................................................................................109
13.1 Absolute Maximum Ratings...................................................................................................................109
13.2 Operating Range ...................................................................................................................................109
13.3 Recommended Operating Conditions....................................................................................................109
13.4 AC/DC Parameters................................................................................................................................110
13.5 Example of PSD5XX Typical Power Calculation at V = 5.0 V...........................................................111
CC
13.6 DC Characteristics (5 V ± 10% versions) ..............................................................................................112
13.7 AC/DC Parameters – ZPLD Timing Parameters ...................................................................................113
13.8 Microcontroller Interface – AC/DC Parameters .....................................................................................115
13.9 DC Characteristics (ZPSD5XXV Versions) (3.0 V ± 10% versions)......................................................120
13.10 AC/DC Parameters – ZPLD Timing Parameters (3.0 V ± 10% versions)..............................................121
13.11 Microcontroller Interface – AC/DC Parameters (3.0 V± 10% versions).................................................121
14.0 Timing Diagrams...............................................................................................................................................128
15.0 Pin Capacitance................................................................................................................................................134
16.0 AC Testing........................................................................................................................................................134
17.0 Erasure and Programming................................................................................................................................134
18.0 PSD5XX Pin Assignments................................................................................................................................135
19.0 Package Information.........................................................................................................................................137
20.0 PSD5XX Product Ordering Information ............................................................................................................142
20.1 PSD5XX Family – Selector Guide .........................................................................................................142
20.2 Part Number Construction .....................................................................................................................143
20.3 Ordering Information..............................................................................................................................143
21.0 Process Change Notice, October 1, 1998 ........................................................................................................148
ii
Programmable Peripheral
PSD5XX Family
Field-Programmable Microcontroller Peripherals
The PSD5XX family is a microcontroller peripheral that integrates high-performance and
user-configurable blocks of EPROM, programmable logic, and SRAM into one part. The
PSD5XX is also loaded with a variety of features, such as Counter/Timers, Interrupt
controller, power management, and page logic. The PSD5XX products also provide a
powerful microcontroller interface that eliminates the need for external “glue logic”. The no
“glue logic” concept provides a user-programmable interface to a variety of 8- and 16-bit
(multiplexed or non-multiplexed) microcontrollers that is easy to use. 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.
1.0
Introduction
The PSD5XX provides three Zero-power PLDs (ZPLDs): a Decode PLD (DPLD), a
General-purpose PLD (PLD), and a Peripheral PLD (PPLD). The ZPLDs have a total of 61
inputs, 140 product terms, 30 macrocells, and 24 I/O connections. A configuration bit
(Turbo) can be set by the MCU, and will automatically place the ZPLDs into standby if
no inputs are changing. The ZPLDs are designed to consume minimum power using Zero
Power CMOS technology that uses low standby current. Unused product terms are
automatically disabled, also reducing power, regardless of the Turbo bit setting.
The main function of the DPLD is to perform address decoding for the internal I/O ports,
EPROM, and SRAM. The address decoding can be based on up to 24 bits of address
inputs, control signals (RD, WR, PSEN, etc.), and internal page logic. The DPLD supports
separate program and data spaces (for 8031 compatible MCUs).
The General-purpose PLD (GPLD) can be used to implement various logic defined by the
user, such as:
• State machines
• Loadable counters and shift registers
• Inter-processor mailbox
• External control logic (chip selects, output enables, etc.).
The GPLD has access to up to 61 inputs, 118 product terms, 24 macrocells, and 24 I/O
pins.
1
PSD5XX Family
The Peripheral PLD (PPLD) generates outputs to the Counter/Timer unit and the Interrupt
Controller. The PPLD outputs to the Counter/Timer enable, disable, or trigger counting or
time capture. The PPLD outputs to the Interrupt Controller enables the user to define
conditions for interrupt generation.
Introduction
(cont.)
The Counter/Timer unit provides four 16-bit highly flexible Counter/Timers. Each has five
modes of operation: pulse, waveform, event counting, time capture, and watchdog
(real-time clock). Each Counter/Timer can be programmed to count up or down. The inputs
to the Counter/Timer, which enable/disable counting or trigger an operation, can originate
from the PPLD directly or directly from the pins. The maximum operating frequency of each
counter is 7.5 MHz. The input clock can be divided (by up to 280) before driving the
Counter/Timer unit using the 4 to 280 prescaler.
The Interrupt Controller has eight levels of priority encoding. It accepts four user-defined
interrupts and four terminal counts from the Counter/Timer. Each interrupt can be
individually masked and configured to be level or edge sensitive. A 3-bit interrupt vector is
generated that can be read by the microcontroller. The serviced interrupt will be cleared
automatically after the microcontroller has read the interrupt vector.
The PSD5XX has 40 I/O pins that are divided among 5 ports. Each I/O pin can be
individually configured to provide many functions, including the following:
• MCU I/O
• ZPLD I/O
• Latched address output (for MCUs with multiplexed data bus)
• Special function I/O (Counter/Timer and Interrupts)
• Data bus (for MCUs with non-multiplexed data bus).
The PSD5XX can easily interface with virtually any 8- or 16-bit microcontroller with a
multiplexed or non-multiplexed bus. All of the MCU control signals are connected to the
ZPLDs, enabling the user to generate signals for external devices. The PSD5XX can
generate a reset output based on the RESET input (includes hysteresis).
The PSD5XX provides between 256 Kbits and 1 Mbit of EPROM that is divided in to four
equal-sized blocks. Each block can occupy a different address location, allowing for
versatile address mapping. The access time of the EPROM includes the address latching
and DPLD decoding.
The PSD5XX has an optional 16 Kbit SRAM that can be battery-backed by connecting a
battery to the Vstby pin. The battery will protect the contents of the SRAM in the event of a
power failure. Therefore, you can place data in the optional SRAM that you want to keep
after the power is switched off. Power switch-over to the battery automatically occurs when
Vcc drops below Vstby.
A four-bit Page Register enables easy access to the I/O section, EPROM, and SRAM for
microcontrollers with limited address space. The Page Register outputs are connected to
the ZPLDs and thus can also be used for external paging schemes.
Please refer to the revision block at
the end of this document for updated
information.
2
PSD5XX Family
The Power Management Unit (PMU) of the PSD5XX enables the user to control the
power consumption on selected functional blocks, based on system requirements. For
microcontrollers that do not generate a chip select input for the PSD, the Automatic
Power-Down (APD) unit of the PMU can be setup to enable the PSD to enter Power Down
or Sleep Mode, based on the inactivity of ALE (or AS).
Introduction
(cont.)
Implementing your design has never been easier than with PSDsoft—WSI’s software
development suite. Using PSDsoft, you can do the following:
• Configure your PSD5XX to work with virtually any microcontroller
• Specify what you want implemented in the programmable logic using a design file
• Simulate your design
• Download your design to the part using a programmer.
2.0
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 four equally-sized mappable blocks for optimized address mapping
• As fast as 70 ns access time, which includes address decoding
• Built-in Zero-power technology
❏ 16 Kbits SRAM is configurable as 2K x 8 or 1K x 16. The access time can be
as quick as 70 ns, including address decoding. The contents of the SRAM can be
battery-backed by connecting a battery to the Vstby pin. The SRAM was also designed
using Zero-power technology
❏ 40 I/O pins (divided into five 8-bit ports) that can be individually configured for:
• Standard MCU I/O
• PLD/macrocell I/O
• Latched address output
• High-order address inputs
• Special function I/O
• Open-drain output
❏ Three Zero-power Programmable Logic Devices (ZPLDs): the Decode PLD (DPLD), the
General-purpose PLD (GPLD), and the Peripheral PLD (PPLD) can be used for:
• Up to 61 input and 140 output product terms
• 24 Macrocells and I/O
• Decode up to 16 MB of address
• State machines and state logic
• Generate external signals (chip selects, bus interface, etc.)
❏ 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
• Multiple configurations are possible for interface to many different microcontrollers
❏ Four 16-bit Counter/Timers that have five modes of operation and can be controlled by
the PPLD macrocells. Modes of operation are: pulse and waveform generation, time
capture, event counting, and a watchdog timer (real time clock).
❏ Eight input priority encoded Interrupt Controller. Four interrupts are generated by
the PPLD and are user defined. The other four interrupts are generated by the
Counter/Timer’s terminal count flags. Each interrupt can be individually masked and
configured as edge or level sensitive.
❏ Page logic is connected to the ZPLDs and expands the MCU address space to up to
16 times
3
PSD5XX Family
Key Features
(cont.)
❏ Programmable power management allows:
• SRAM, EPROM, and ZPLDs to enter standby mode automatically
• Disabling of the clock input to the ZPLDs
• ZPLDs to enter a special low power mode (Sleep Mode), based on Turbo bit setting
❏ A security bit prevents reading the PSD5XX configuration and the ZPLD contents.
Setting this bit will prevent the device from being copied on a device programmer.
❏ Built-in security enables the user to block read accesses from a device programmer
❏ Package choices include a 68-pin PLCC and CLDCC, and an 80-pin TQFP.
❏ Programmable polarity Reset output (includes hysteresis), based on Reset input
❏ Simple, menu-driven software (PSDsoft) allows configuration and design entry on a PC.
Throughout this data sheet, references are made to the PSD5XX. In most cases, these
references also cover the ZPSD5XX and ZPSD5XXV products. Exceptions will be noted.
3.0
Notation
The main difference between the ZPSD5XX and the PSD5XX is the standby current (Isb).
The ZPSD5XX devices have been rated for a lower standby current. Also, there is no
low-voltage version of the PSD5XX. There is only the low-voltage version of the ZPSD5XX,
which has a V suffix.
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 need, WSI, Inc.
has developed a new Zero-Power technology. ZPSD products virtually eliminate the DC
component of power consumption reducing it to standby levels. Eliminating the DC
component is the basis for the words “Zero Power”. 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 functions while drawing
minimal power.
4.0
ZPSD
Background
4
PSD5XX Family
Figure 1. PSD5XX Block Diagram
5
PSD5XX Family
Upon each address or logic input change to the PSD, the device powers up from low power
standby for a short time. Then the PSD 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 PSD latches them and automatically reverts back to standby mode.
The ICC current flowing during standby mode and during DC operation is identical.
5.0
Integrated
Power
Management
Operation
TM
The PSD 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 PSD to standby mode independent of other input transitions.
The only significant power consumption in the PSD occurs during AC operation.
The PSD contains the first architecture to apply Zero-power techniques to memory circuit
blocks as well as logic.
Figure 2 compares PSD 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 PSD detects the address transition and powers up for a
short time. The PSD then latches the outputs of the PAD, EPROM and SRAM to the new
values. After finishing these operations, the PSD shuts off its internal power, entering
standby mode. The time taken for the entire cycle is less than the PSD’s “access time.”
The PSD will stay in standby mode if the inputs do not change 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 PSD may be calculated using the composite
frequency of the MCU address and control inputs, as well as any other logic inputs to the
ZPLD.
NOTE: The ZPSD5XX parts have been rated for a lower standby current (ISB) than the
PSD5XX parts.
Figure 2. ZPSD Power Operation vs. Discrete Implementation
ALE
SRAM
ACCESS
EPROM
ACCESS
EPROM
ACCESS
ADDRESS
DISCRETE EPROM, SRAM & LOGIC
ZPSD
ICC
ZPSD
ZPSD
TIME
6
PSD5XX Family
Shown in Figure 3 (below) is the software design flow for a PSD5XX device.
6.0
Design Flow
PSDsoft—WSI’s software development suite—is used throughout the design phase. You
start with a design file that is written in PSDabel-a high-level hardware description language
(HDL). Before you compile your design, you must also configure the PSD5XX so it knows
what signals to expect from your microprocessor and what pre-runtime options should be
set (such as the security bit).
Once you have a design file and have configured the device, you are ready to run the Fitter
and Address Translator. The Fitter accepts input from PSDabel and PSD Configuration,
synthesizes this user logic and configuration, and fits the design to the PSD silicon.
The Address Translator process allows the user to map the MCU firmware from a
cross-compiler (in Intel HEX or S-Record format) into the NVM memory blocks within the
PSD. As a result, the MCU firmware is merged with the logic and configuration definition of
the PSD.
The output of the Address Translator and the Fitter is the required object file that is used by
a programmer to program the PSD device. The object file includes chip configuration, the
PLD fusemap, and MCU firmware information.
PSDsilosIII is an optional program that provides functional chip-level simulation of the
PSD5XX. PSDsoft automatically creates files for input to the simulator. These files convey
relevant design information to the simulator. As a result, the user only has to create a stim-
ulus file since all of the signals and node names are taken from the design file.
Figure 3. PSDsoft Development Tools
PSDsoft
Development Software
PSD Configuration
PSDabel™
ZPLD DESCRIPTION
(STATE MACHINE, DECODING)
CHIP CONFIGURATION
CODE FILE
PSD Compiler
THIRD PARTY
(ZPLD FITTING, ADDRESS TRANSLATION)
PROGRAMMERS
PSD Programmer
PSDsilos III™
®
SILOSIII
PSDpro/MagicPro
CHIP SIMULATION
CHIP PROGRAMMING
7
PSD5XX Family
There are 7 unique devices in the PSD5XX family. The part classifications are based on
EPROM size and data bus width. The features of each part are listed in Table 1.
7.0
PSD5XX
Family
Table 1. PSD5XX Product Matrix
DPLD + GPLD + PPLD
Part
#
Bus
Bit
I/O Timers Inter. WD PMU EPROM SRAM
*
Inputs Product Registered
Terms Macrocells
Pins
Contr.
K bit
K bit
501B1 x8/x16
511B1 x8
61
61
140
140
30
30
40
40
4
4
16
16
8
8
1
1
16 Yes
16 Yes
256
256
16
16
*
*
*
*
502B1 x8/x16
512B0 x8
512B1 x8
61
61
61
140
140
140
30
30
30
40
40
40
4
4
4
16
16
16
8
8
8
1
1
1
16 Yes
16 Yes
16 Yes
512
512
512
16
–
*
*
*
*
*
*
16
503B1 x8/x16
513B1 x8
61
61
140
140
30
30
40
40
4
4
16
16
8
8
1
1
16 Yes
16 Yes
1024
1024
16
16
*
*
*
*
WD = WatchDog Timer.
PMU = Power Management Unit.
*One of the four 16-Bit Timers.
8
PSD5XX Family
The following table describes the pin names and pin functions of the PSD5XX. Pins that
have multiple names and/or functions are defined by user configuration.
8.0
Table 2.
PSD5XX Pin
Descriptions
Pin Name
Pin Function
Type
Function Descriptions
ADIO0 – ADIO15 Address/ data bus
I/O
1. Address/data bus, multiplexed
bus mode
2. Address bus, non-multiplexed
bus mode
RD
Multiple Names
1. Read
2. E
3. DS
4. LDS
I
I
Multiple functions
1. Read signal
2. E signal (Clock)
3. Data strobe signal
4. Low byte data strobe
WR
Multiple Names
1. WR
Multiple functions
1. Write signal
2. R/W
3. WRL
2. Read-write signal
3. Low byte write signal
CSI
Chip Select Input
I
I
Active low, select PSD5XX.
standby mode if high.
RESET
Reset Input
Reset I/O ports, ZPLD/macrocells,
Timers and Configuration
Registers. Active low.
CLKIN
Input clock
I/O Port A
I
Clock input to Timers, ZPLD
macrocells, ZPLD array, and APD
counter; connect to ground if clock
input not used.
PA0 – PA7
I/O
Multiple functions
1. I/O port
2. ZPLD/macrocell I/O port
3. Latched address outputs
(PA0–PA7) → (A0–A7)
4. High address inputs (A16 – A23)
5. Timer outputs (PA0 – PA3)
PB0 – PB7
PC0 – PC7
I/O Port B
I/O Port C
I/O
I/O
Multiple functions
1. I/O port
2. ZPLD/macrocell I/O port
3. Latched address outputs
(PB0–PB7) → (A0–A7) or (A8–A15)
4. Timer outputs (PB0-PB3)
Multiple functions
CMOS 1. I/O port
or
2. ZPLD input port
OD
3. Latched address outputs
(PC0 – PC7) → (A0–A7)
4. Data Port (D0 – D7,
non-multiplexed bus)
PD0 – PD7
I/O Port D
I/O
Multiple functions
CMOS 1. I/O port
or
2. ZPLD input port
OD
3. Latched address outputs
(PD0–PD7) → (A0–A7) or (A8–A15)
4. Data Port (D8-D15,
non-multiplexed bus)
9
PSD5XX Family
Table 2.
Pin Name
Pin Function
Type
Function Descriptions
PSD5XX Pin
Descriptions
(Cont.)
PE0
Port PE, pin 0
1. BHE
2. PSEN
3. WRH
4. UDS
I/O
Multiple functions
1. High byte enable, 16 bit data
2. Read program memory, 8031 signal
write high data byte
4. Upper Data Strobe
5. SIZ0
6. PE0
5. Byte enable, 68300 signal
6. I/O pin
7. PE0
7. ZPLD I/O pin
8. PE0
8. Latched Address Out – A0
PE1
PE2
PE3
PE4
Port PE, pin 1
1. ALE
2. PE1
3. PE1
4. PE1
I/O
Multiple functions
1. Address strobe
2. I/O pin
3. ZPLD I/O pin
4. Latched Address Out – A1
Port PE, pin 2
1. Intr Out
2. PE2
3. PE2
4. PE2
Multiple functions
1. Interrupt Controller Output
2. I/O pin
3. ZPLD I/O pin
4. Latched Address Out – A2
I/O
I/O
I/O
Port PE, pin 3
1. Timer0-In
2. PE3
3. PE3
4. PE3
Multiple functions
1. Timer0 control input
2. I/O pin
3. ZPLD I/O pin
4. Latched Address Out – A3
Port PE, pin 4
1. Timer1-In
2. PE4
Multiple functions
1. Timer1 control input
2. I/O pin
3. PE4
3. ZPLD I/O pin
4. PE4
5. TC0
4. Latched Address Out – A4
5. Timer0 Terminal Count
PE5
Port PE, pin 5
1. Timer2-In
2. PE5
3. PE5
4. PE5
Multiple functions
1. Timer2 control input
2. I/O pin
3. ZPLD I/O pin
4. Latched Address Out – A5
5. Timer1 Terminal Count
I/O
I/O
5. TC1
PE6
Port PE, pin 6
1. Timer3-In
2. PE6
Multiple functions
1. Timer3 control input
2. I/O pin
3. PE6
3. ZPLD I/O pin
4. PE6
5. TC2
4. Latched Address Out – A6
5. Timer2 Terminal Count
PE7
Port PE, pin 7
1. APD CLK
2. PE7
Multiple functions
1. Automatic Power Down Clock Input
2. I/O pin
I/O
3. PE7
3. ZPLD I/O pin
4. PE7
5. TC3
4. Latched Address Out – A7
5. Timer3 Terminal Count
VSTBY
VSTBY
SRAM power pin for standby
operation (battery backup)
I
VCC
VCC
I
I
Chip VCC power pin
Chip ground pin
GND
GND
10
PSD5XX Family
PSD5XX consists of seven major functional blocks:
❏ ZPLD Blocks
9.0
The PSD5XX
Architecture
❏ Bus Interface
❏ I/O Ports
❏ Memory Block
❏ Power Management Unit
❏ Counter/Timer
❏ Interrupt Controller
The functions of each block are described in the following sections. Many of the blocks
perform multiple functions, and are user configurable. The chip configurations are specified
by the user in the PSDsoft Development Software; some are specified by setting up the
appropriate bits in the configuration registers during run time.
9.1 ZPLD Block
Key Features
❏ 3 Embedded ZPLD devices
❏ Maximum 30 macrocells
❏ Combinatorial/registered outputs
❏ Maximum 140 product terms
❏ Programmable output polarity
❏ User configured register clear/preset
❏ User configured register clock input
❏ 61 Inputs
❏ Accessible via 24 I/O pins
❏ Power Saving Mode
❏ UV-Erasable
❏ Generate user defined interrupts to Interrupt Controller
and controls to Counter/Timer
General Description
The ZPLD block has 3 embedded PLD devices:
❏ DPLD
The Address Decoding PLD, generating select signals to internal I/O or memory blocks.
❏ GPLD
The General Purpose PLD provides 24 programmable macrocells for general or
complex logic implementation; dedicated to user application.
❏ PPLD
The Peripheral PLD, includes 6 programmable macrocells. The PPLD provides control
to the operation of the Counter/Timer and Interrupt Controller.
Figure 4 shows the architecture of the ZPLD. The PLD devices all share the same
input bus. The true or complement of the 61 input signals are fed to the programmable
AND-ARRAY. Names and source of the input signals are shown in Table 3. The PA, PB, PE
signals, depending on user configuration, can either be macrocell feedbacks or inputs from
Port A, B or E.
11
PSD5XX Family
Figure 4. ZPLD Block Diagram
The PSD5XX
Architecture
12
PSD5XX Family
Table 3. ZPLD Input Signals
Signal Name
The PSD5XX
Architecture
(cont.)
From
PA0 – PA7
PB0 – PB7
PE0 – PE7
PC0 – PC7
PD0 - PD7
PGR0 – PGR3
WDOG2PLD
INTR2PLD
A8 – A15, A0, A1
RD/E/DS
Port A inputs or Macrocell PA feedback
Port B inputs or Macrocell PB feedback
Port E inputs or Macrocell PE feedback
Port C inputs
Port D inputs
Page Mode Register
Counter/Timer
Interrupt Controller
MCU Address Lines
MCU bus signal
WR/R_W
MCU bus signal
CLKIN
Input Clock
RESET
Reset input
CSI
CSI input (ORed with power down from PMU)
13
PSD5XX Family
9.1.1 The DPLD
The PSD5XX
Architecture
The DPLD is used for internal address decoding generating the following eight
chip select signals:
❏ ES0 – ES3
EPROM selects, block 0 to block 3
❏ RS0
SRAM block select
❏ CSIOP
I/O Decoder chip select
❏ PSEL0 – PSEL1
Peripheral I/O mode select signals
The I/O Decoder enabled by the CSIOP generates chip selects for on-chip registers or I/O
ports based on address inputs A[7:0].
As shown in Figure 5, the DPLD consists of a large programmable AND ARRAY. There are
a total of 61 inputs and 8 outputs. Each output consists of a single product term. Although
the user can generate select signals from any of the inputs, the select signals are typically a
function of the address and Page Register inputs. The select signals, which are active High,
are defined by the user in the ABEL file (PSDabel).
The address line inputs to the DPLD include A0, A1 and A8 – A15. If more address lines
are needed, the user can bring in the lines through Port A to the DPLD.
9.1.2 The GPLD
The structure of the General Purpose PLD consists of a programmable AND ARRAY and
3 sets of I/O Macrocells. The ARRAY has 61 input signals, same as the DPLD. From these
inputs, “ANDed” functions are generated as product term inputs to the macrocells. The I/O
Macrocell sets are named after the I/O Ports they are linked to, e.g., the macrocells
connected to Port A are named PA Macrocells. The 3 sets of macrocells, PA, PB and PE,
are similar in structure and function.
Figure 6 shows the output/input path of a GPLD macrocell to the Port pin with which it is
associated. If the Port pin is specified as a GPLD output pin in PSDsoft, the MUX in the I/O
Port Cell selects the GPLD macrocell as an output of the Port pin. The output enable signal
to the buffer in the I/O cell can be controlled by a product term from the AND ARRAY.
If the Port pin is specified as a ZPLD input pin, the MUX in the GPLD macrocell selects the
Port input signal to be one of the 61 signals in the ZPLD Input Bus.
14
PSD5XX Family
Figure 5. DPLD Logic Array
The PSD5XX
Architecture
(cont.)
15
PSD5XX Family
The PSD5XX
Architecture
(cont.)
9.1.2.1 Port A Macrocell Structure
Figure 6a shows the PA Macrocell block, which consists of 8 identical macrocells.
Each macrocell output can be connected to its own I/O pin on Port A. There are 3 user
programmable global product terms output from the GPLD’s AND ARRAY which are
shared by all the macrocells in Port A:
❏ PA.OE
Enable or tri-state Port A output pins
❏ PA.PR
Preset D flip flop in the macrocells
❏ PA.RE
Reset/Clear D flip flop in the macrocells
Two other inputs, CLKIN and MACRO-RST, are used as clock and clear inputs to the D flip
flop. The CLKIN comes directly from the CLKIN input pin. The MACRO-RST is the same as
the Reset input pin except it is user configurable.
The circuit of a Port A Macrocell is shown in Figure 7. There are 6 product terms from the
GPLD’s AND ARRAY as inputs to the macrocell. Users can select the polarity of the output,
and configure the macrocell to operate as:
❏ Registered Output
Select output from D flip flop
❏ Combinatorial Output
Select output from OR gate
❏ GPLD Input
Use Port A pin as dedicated input
❏ GPLD Output
Use Port A pin as dedicated output
❏ GPLD I/O
Use Port A pin as bidirectional pin
❏ Macrocell Feedback
Register feedback for state machine implementations or expander feedback
from the combinatorial output, to expand the number of product terms available to
another macrocell.
In case of "Buried Feedback", where the output of the macrocell is not connected to a
Port A pin, Port A can be configured to perform other user defined I/O functions.
The two global product terms assigned for asynchronous clear (PA.RE) and preset (PA.PR)
are mainly for proper Port A Macrocell initialization. The macrocell flip-flop can also be
cleared during reset by MACRO-RST, if such an option is chosen. The clock source is
always the input clock CLKIN.
16
PSD5XX Family
Figure 6. GPLD Macrocell Input/Output Port
The PSD5XX
Architecture
(cont.)
17
PSD5XX Family
Figure 6a. PA Macrocell Block Diagram
The PSD5XX
Architecture
(cont.)
18
PSD5XX Family
Figure 7. PA Macrocell
The PSD5XX
Architecture
(cont.)
19
PSD5XX Family
The PSD5XX
Architecture
(cont.)
9.1.2.2 Port B Macrocell Structure
Figure 8 shows the PB Macrocell block, which consists of 8 identical macrocells. Each
macrocell output can be connected to its own I/O pin on Port B. The two inputs, CLKIN and
MACRO-RST, are used as clock and clear inputs to all the macrocells. The CLKIN comes
directly from the CLKIN input pin. The MACRO-RST is the same as the Reset input pin
except it is user configurable.
The circuit of a PB Macrocell is shown in Figure 9. There are 10 product terms from the
GPLD’s AND ARRAY as inputs to the macrocell. Users can select the polarity of the output,
and configure the macrocell to operate as:
❏ Registered Output
Select output from D flip flop.
❏ Combinatorial Output
Select output from OR gate.
❏ GPLD Input
Use Port B pin as dedicated input.
❏ GPLD Output
Use Port B pin as dedicated output.
❏ GPLD I/O
Use Port B pin as bidirectional pin.
❏ Macrocell Feedback
Register feedback for state machine implementations or expander feedback
from the combinatorial output, to possibly expand the number of product terms
available to another macrocell.
In case of "Buried Feedback", where the output of the macrocell is not
connected to a Port B pin, Port B can be configured to perform other user
defined I/O functions.
Each D flip flop in the macrocells has its own dedicated asynchronous clear, preset and
clock input. The signals are defined as follow:
❏ PRESET
Active only if defined by a product term (PBx.PR)
❏ CLEAR
Two selectable inputs: Reset input or user defined product term (PBx.RE)
❏ CLK
Two selectable inputs – CLKIN input or user defined product term (PBx.CLK).
The macrocell is operated in Synchronous Mode if the clock input is CLKIN, and is in
Asynchronous Mode if the clock is a product-term clock defined by the user.
20
PSD5XX Family
Figure 8. PB Macrocell Block Diagram
The PSD5XX
Architecture
(cont.)
21
PSD5XX Family
Figure 9. PB Macrocell
The PSD5XX
Architecture
(cont.)
22
PSD5XX Family
The PSD5XX
Architecture
(cont.)
9.1.2.3 Port E Macrocell Structure
Figure 10 shows the PE Macrocell block, which consists of 8 identical macrocells. Each
macrocell output can be connected to its own I/O pin on Port E. There are 3 user
programmable global product terms output from the GPLD’s AND ARRAY which are shared
by all the macrocells in Port E:
❏ PE.OE
Enable or tri-state Port PE output pins
❏ PE.PR
Preset D flip flop in the macrocells
❏ PE.RE
Reset/Clear D flip flop in the macrocells
Two other inputs, CLKIN and MACRO-RST, are used as clock and clear inputs to the D flip
flop. The CLKIN comes directly from the CLKIN input pin. The MACRO-RST is the same as
the Reset input pin except it is user configurable.
The circuit of a PE Macrocell is shown in Figure 11. There are 4 product terms from the
GPLD’s AND ARRAY as input to the macrocell. Users can select the polarity of the output
and configure the macrocell to operate as:
❏ Registered Output
Select output from D flip flop
❏ Combinatorial Output
Select output from OR gate
❏ GPLD Input
Use Port E pin as dedicated input
❏ GPLD Output
Use Port E pin as dedicated output
❏ GPLD I/O
Use Port E pin as bidirectional pin
❏ Macrocell Feedback
Register feedback for state machine implementations or expander feedback from the
combinatorial output, to possibly expand the number of product terms available to
another macrocell.
In case of "Buried Feedback", where the output of the macrocell is not connected
to Port E pin, Port E can be configured to perform other user defined I/O functions.
If pins PE0 and PE1 are used as bus control signal inputs (ALE, PSEN/BHE), the
corresponding macrocells' feedbacks are disabled. The bus control signals are
connected to the ZPLD Input Bus.
The two global product terms assigned for asynchronous clear (PE.RE) and preset (PE.PR)
are mainly for proper PE Macrocell initialization.
The macrocell flip-flop can also be cleared during reset by MACRO-RST, if such an option
is chosen. The clock source is always the input clock CLKIN.
23
PSD5XX Family
Figure 10. PE Macrocell Block Diagram
The PSD5XX
Architecture
(cont.)
24
PSD5XX Family
Figure 11. PE Macrocell
The PSD5XX
Architecture
(cont.)
25
PSD5XX Family
The PSD5XX
Architecture
(cont.)
9.1.3 The PPLD
The Peripheral Programmable Logic Device (PPLD) provides a powerful mechanism for
the user to control the operations of the Counter/Timer and Interrupt Controller. Figure 12 is
the PPLD block diagram. There are six Peripheral Macrocells, four are dedicated to the
Counter/Timer, and two to the Interrupt Controller.
The outputs from the four Peripheral Macrocells, MC2TMR[3:0], are used as
load/store/enable inputs to the Counter/Timer (multiplexed with pin inputs TIMER[3:0]_IN).
The remaining two macrocell outputs (MC2INT[6:7]), together with two other product terms
(PT2INT4, PT2INT5), can generate up to 4 user defined interrupts to the Interrupt
Controller. The watch-dog output of the Timer (WDOG2PLD) and Interrupt Controller
(INTR2PLD) are available as inputs to the ZPLD’s AND ARRAY.
The structure of a Peripheral Macrocell is shown in Figure 13. The cell has two product term
inputs from the AND ARRAY. The user can select the registered or combinatorial output of
the macrocell, as well as the output polarity. The registers are clocked by the CLKIN clock,
and are cleared by the RESET input during power up.
9.1.4 The ZPLD Power Management
The ZPLD implements a Zero Power Mode, which provides considerable power savings
for low to medium frequency operations. To enable this feature, the ZPLD Turbo bit in the
Power Management Mode Register 0 (PMMR0) has to be turned off.
If none of the 61 inputs to the ZPLD are switching for a time period of 70ns, the ZPLD puts
itself into Zero Power Mode and the current consumption is minimal. The ZPLD will resume
normal operation as soon as one or more of the inputs change state.
Two other features of the ZPLD provide additional power savings:
1. Clock Disable:
Users can disable the clock input to the ZPLD and/or macrocells, thereby reducing AC
power consumption.
2. Product Term Disable:
Unused product terms in the ZPLD are disabled by the PSDsoft Software automatically
for further power savings.
The ZPLD power configuration is described in the Power Management Unit section.
26
PSD5XX Family
Figure 12. PPLD Block Diagram
The PSD5XX
Architecture
(cont.)
27
PSD5XX Family
Figure 13. Peripheral Macrocell
The PSD5XX
Architecture
(cont.)
28
PSD5XX Family
The Bus Interface is very flexible and can be configured to interface to most
microcontrollers with no glue logic. Table 4 lists some of the bus types to which the Bus
Interface is able to interface.
9.2
Bus
Interface
Table 4. Typical Microcontroller Bus Types
Multiplexed
Data Bus
Width
Bus Control
Signals
Microcontroller
Mux
8
8/16
8/16
16
WR, RD, PSEN, A0
R/W, E, BHE, A0
WR, RD, BHE, A0
WRL, RD, WRH, A0
R/W, LDS, UDS
R/W, DS, SIZ0, A0
R/W, DS, BHE, BLE
RD, WR
8031/80C51
68HC11
Mux/Non-mux
Mux
80C196/80C186
80C196SP
68302
Mux
Non-mux
Non-mux
Non-mux
Non-mux
Non-mux
Non-mux
16
8/16
16
68340
68330, 68331
68HC05C
68HC12
8
16
R/W, E, LSTRB, A0
R/W, DS
16
68HC16
9.2.1 Bus Interface Configuration
The Bus Interface Logic is user configurable. The type of bus interface is specified by
the user in the PSDsoft software (PSD configuration). The bus control input pins have
multi-function capabilities. By choosing the right configuration, the PSD5XX is able to
interface to most microcontrollers, including the ones listed in Table 4. In Table 5, the
names of the bus control input signal pins and their multiple functions are shown. For
example, Pin PE0 can be configured by the PSD configuration software to perform any one
of the five functions. Examples on the interface between the PSD5XX and some typical
microcontrollers are shown in following sections.
Table 5. Alternate Pin Functions
Pin Name
Pin
Function
1
Pin
Function
2
Pin
Function
3
Pin
Function
4
Pin
Function
5
RD
WR
PE0
PE1
AD0
RD
WR
BHE
ALE
A0
E
DS
LDS
R/W
PSEN
WRL
WRH
UDS
SIZ0
BLE
9.2.2 PSD5XX Interface To a Multiplexed Bus
Figure 14 shows a typical connection to a microcontroller with a multiplexed bus. The ADIO
port of the PSD5XX is connected directly to the microcontroller address/data bus
(AD0-AD15 for 16 bit bus). The ALE input signal latches the address lines internally. In a
read bus cycle, data is driven out through the ADIO Port transceivers after the specified
access time. The internal ADIO Port connection for a 16 bit multiplexed bus is shown in
Figure 15. The ADIO port is in tri-state mode if none of the PSD5XX internal devices are
selected.
29
PSD5XX Family
9.2.3 PSD5XX Interface To Non-Multiplexed Bus
Bus
Figure 16 shows a PSD5XX interfacing to a microcontroller with a non-multiplexed
address/data bus. The address bus is connected to the ADIO Port, and the data bus is
connected to Port C and/or Port D, depending on the bus width. There is no need for the
ADIO Port to latch the address internally, but the user is offered the option to do so in the
PSD5XX PSDsoft Software. The data ports are in tri-state mode when the PSD5XX is not
accessed by the microcontroller.
Interface
(Cont.)
9.2.4 Data Byte Enable
Microcontrollers have different data byte orientations with regard to the data bus. The
following tables show how the PSD5XX handles the byte enable under different bus
configurations. Even byte refers to locations with address A0 equal to “0”, and odd byte as
locations with A0 equal to “1”.
Table 6. 8-Bit Data Bus
BHE
X
A0
0
D7 – D0
Even Byte
Odd Byte
X
1
Table 7. 16-Bit Data Bus With BHE
BHE
A0
D15 – D8
D7 – D0
0
0
1
0
1
0
Odd byte
Odd byte
–
Even byte
–
Even byte
Table 8. 16-Bit Data Bus With WRH and WRL
WRH
WRL
D15 – D8
D7 – D0
0
0
1
0
1
0
Odd byte
Odd byte
–
Even byte
–
Even byte
Table 9. 16-Bit Data Bus With SIZ0, A0
SIZ0
A0
0
D15 – D8
Even byte
Even byte
–
D7 – D0
Odd byte
–
0
1
1
0
1
Odd byte
Table 10. 16-Bit Data Bus With UDS, LDS
LDS
0
UDS (A0)
D15 – D8
Even byte
Even byte
–
D7 – D0
Odd byte
–
0
0
1
1
0
Odd byte
30
PSD5XX Family
Figure 14. Bus Interface – Multiplexed Bus, 8 or 16-Bit Data Bus
Bus
Interface
(Cont.)
31
PSD5XX Family
Figure 15. ADIO Port, 16-Bit Multiplexed Bus Interface
Bus
Interface
(Cont.)
PSD5XX
INTERNAL
ADDRESS BUS
AD0
AD1
AD2
AD3
AD4
AD5
AD6
AD7
A0
ADIO–0
ADIO–1
ADIO–2
ADIO–3
ADIO–4
ADIO–5
ADIO–6
ADIO–7
A1
A2
A3
A4
A5
A6
A7
LATCH
G
AD8
AD9
A8
A9
ADIO–8
ADIO–9
AD10
AD11
AD12
AD13
AD14
AD15
A10
A11
A12
A13
A14
A15
ADIO–10
ADIO–11
ADIO–12
ADIO–13
ADIO–14
ADIO–15
LATCH
G
PSD5XX
INTERNAL
DATA BUS
ALE/AS
AD0
AD1
AD2
AD3
AD4
AD5
AD6
AD7
D0
D1
D2
D3
D4
D5
D6
D7
AD8
D8
AD9
D9
AD10
AD11
AD12
AD13
AD14
AD15
D10
D11
D12
D13
D14
D15
R_W
32
PSD5XX Family
Figure 16. Bus Interface – Non-Multiplexed, 8 or 16-Bit Data
Bus
Interface
(Cont.)
33
PSD5XX Family
Bus
9.2.5 Optional Features
The PSD5XX provides two optional features to add flexibility to the Bus Interface:
Interface
(Cont.)
1. Address In
Port A can be configured as high order address (A16-A23) inputs to the ZPLD for
EPROM or other decoding. Inputs are latched by ALE/AS if Multiplexed Bus is selected.
Other ports can be configured as address input ports for the ZPLD. These inputs should
not be used for EPROM decoding and are not latched internally.
2. Address Out
For multiplexed bus only. Latched address lines A0-A15 are available on
Port A, B, C, D, or E.
Details on the optional features are described in the I/O Port section.
9.2.6 Bus Interface Examples
The next four figures show the PSD5XX interfacing with some popular microcontrollers.
The examples show only the basic bus connections; some of the pin names on the
PSD5XX parts change to reflect the actual pin functions.
Figure 17 shows an interface to the 80C31. The 80C31 has a 16 bit address bus and an
8-bit data bus. The lower address byte is multiplexed with the data bus. The RD and WR
signals are used for accessing the data memory (SRAM) and the PSEN signal is for reading
program memory (EPROM). The ALE signal is active high and is used to latch the address
internally. Port C provides latched address outputs A[7:0]. Ports A, B, D, and E (PE2-PE7)
can be configured to perform other functions. The RSTOUT reset to the 80C31 is generated
by the ZPLD from the RESET input. This configuration eliminates any reset race condition
between the 80C31 and the PSD5XX.
Figure 18 shows the 68HC11 interface, which is similar to the 80C31 except the PSD5XX
generates internal RD and WR from the 68HC11’s E and R/W signals.
In Figure 19, the Intel 80C196 microcontroller is interfaced to the PSD5XX. The 80C196
has a multiplexed 16-bit address and data bus. The BHE signal is used for data byte
selection. Ports C and D are used as output ports for latched address A[15:0]. Pins PE6
and PE7 can be programmed as ZPLD outputs to provide the READY and BUSWIDTH
control signals to the 80C196.
Figure 20 shows Motorola’s MC68331 interfacing to the PSD5XX. The MC68331 has a
16-bit data bus and a 24-bit address bus. D15-D8 from the MC68331 are connected to
Port D, and D7 – D0 are connected to Port C.
34
PSD5XX Family
Figure 17. Interfacing PSD5XX With 80C31
35
PSD5XX Family
Figure 18. Interfacing PSD5XX With 68HC11
36
PSD5XX Family
Figure 19. Interfacing PSD5XX With 80C196
37
PSD5XX Family
Figure 20. Interfacing PSD5XX With Motorola 68331
38
PSD5XX Family
There are 5 programmable 8-bit I/O ports: Port A, Port B, Port C, Port D and Port E. These
ports all have multiple operating modes, depending on the configuration. Some of the basic
functions are providing input/output for the ZPLD, the Counter/Timer, or can be used for
standard I/O. Each port pin is individually configurable, thus enabling a single 8-bit port to
perform multiple functions. The I/O ports occupy 256 bytes of memory space as defined by
“CSIOP”. Refer to the System Configuration section for I/O register address offset.
9.3
I/O Ports
To set up the port configuration the user is required to:
1. Define I/O port chip select (CSIOP) in the ABEL file.
2. Initialize certain port configuration registers in the user’s program and/or
3. Specify the configuration in the PSD5XX PSDsoft Software.
4. Unused input pins should be tied to VCC or GND.
The following is a description of the operating modes of the I/O ports. The functions of the
port registers are described in later sections.
9.3.1 Standard MCU I/O
The Standard MCU I/O Mode provides additional I/O capability to the microcontroller.
In this mode, the ports can perform standard I/O functions such as sensing or controlling
various external I/O devices. Operation options of this mode are as follows:
❏ Configuration
1. Declare pins or signals which are used as I/O in the ABEL file (PSDsoft).
2. Set the bit or bits in the Control Register to "1".
3. As Output Port
– Write output data to Data Out Register
– Set Direction Register to output mode
4. As Input Port
– Set Direction Register to input mode
– Read input from Data In Register
The port remains an output or input port as long as the Direction Register is not changed.
9.3.2 PLD I/O
The PLD I/O mode enables the port to be configured as an input to the ZPLD, or as an
output from the GPLD macrocell. The output can be tri-stated with a control signal defined
by a product term from the ZPLD. This mode is configured by the user in the PSD5XX
PSDsoft Software, and is enabled upon power up. For a detailed description, see the
section on the ZPLD.
❏ Configuration
1. Declare pins or signals in the ABEL file (PSDsoft)
2. Write logic equations in the ABEL file.
3. PSDcompiler maps the PLD function to the PSD.
39
PSD5XX Family
9.3.3 Address Out
I/O Ports
(Cont.)
For microcontrollers with a multiplexed address/data bus, the I/O ports in Address-Out
mode are able to provide latched address outputs (A0 – A15) to external devices. This
mode of operation requires the user to:
❏ Configuration
1. Declare the pins used as address line outputs in the ABEL file PSDsoft.
2. Write “0” to the corresponding bit in the Control Register associated
with each I/O port.
3. Set the Direction Register to Output Mode.
9.3.4 Address In
1. For Port A – as other address line (A2 – A7 and A16 – A23) inputs to the DPLD.
Additional address inputs included in the EPROM decoding must come from Port A.
The address inputs are latched internally by ALE/AS if Multiplexed Bus is specified in
PSDsoft.
2. For Ports C and D – as adress inputs to the ZPLD for general decoding, should not be
used in EPROM decoding.
❏ Configuration
1. Declare pins or signals used as Address In in the ABEL file (PSDsoft).
2. Write latch equations in the ABL file, e.g., A16.LE = ALE
3. Include latched address in logic equations.
9.3.5 Data Port
In this mode, the port is acting as a data bus port for a microcontroller which has a
non-multiplexed address/data bus. In this configuration, the Data Port is connected to the
data bus of the microcontroller and the ADIO port is connected to the address bus.
❏ Configuration
Select the non-multiplexed bus option in PSD configuration (PSDsoft).
9.3.6 Special Function Out
This mode is per-pin configurable. When enabled, the special function assigned to the
particular pin is driven out. Special functions consist of Timer and Interrupt outputs.
❏ Configuration
1. Specify the output function in the PSD configuration (PSDsoft).
2. PSD compiler assigns pins for the selected function.
3. Write “1” to the corresponding bit in the Special Function Register.
40
PSD5XX Family
I/O Ports
(Cont.)
9.3.7 Alternate Function In
This mode is per-pin configurable and enables the user to define the pins in Port E to
perform Alternate function. Alternate Function includes inputs to Counter/Timers and APD
clock.
❏ Configuration
1. Select input functions in PSD configuration
2. PSD compiler assigns pins for the selected function.
9.3.8 Peripheral I/O
This mode enables the microcontroller to read or write to a peripheral though Port A.
When there is no read/write operation, Port A is tri-stated. One of the applications of
Peripheral I/O is in a DMA based design.
❏ Configuration
1. Declare the pins used as Peripheral I/O in the ABEL file.
2. Write logic equations for PSEL0 and PSEL1.
3. Write a “1” to the PIO bit in the VM Register to activate the Peripheral I/O operation.
See the section on Peripheral I/O for a detailed description.
9.3.9 Open Drain Outputs
This mode enables the user to configure Port C and D pins as open drain outputs. CMOS
output is the default configuration. Writing “1” to the corresponding bit in the Open Drain
Register changes the pin to open drain output.
The following table summarizes the operating modes of the I/O ports. Not all functions are
available to every port.
Table 11. Operating Modes of the I/O Ports
Port Mode
Port A
Port B
Port C
Port D
Port E
Standard MCU I/O
PLD I/O
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes*
Yes
Yes
Yes
Yes
Yes
Yes*
Input Only Input Only
Address Out
Yes
Yes*
Yes
Yes
Yes*
Yes
Address In
Data Port
Special Function Out
Alternate Function In
Peripheral I/O
Open Drain
Yes
Yes
Yes
Yes
Yes
Yes
Yes
*For external decoding. Cannot be latched by ALE.
41
PSD5XX Family
9.3.10 Port Registers
I/O Ports
(Cont.)
There are two sets of registers per I/O port: the Port Configuration Registers (PCR) which
consist of four 8-bit registers; and the Port Data Registers (PDR) which include three 8-bit
registers. The PCR is used for setting up the port configuration, while the PDR enables the
microcontroller to write or read port data or status bits. Tables 12 and 13 show the names
and the registers and the ports to which they belong.
All the registers in the PCR and PDR are 8-bits wide and each bit is associated with a pin in
the I/O port. In Table 14, the LSB of the Data In Register of Port A is connected to pin PA0,
and the MSB is connected to PA7. This pin configuration also applies to other registers and
ports. For example, in the Direction Register of Port A, writing a hex value of 07 to the
register configures pins PA0 – PA2 as output pins, while PA3 – PA7 remain as input pins.
Registers can be accessed by the microcontroller during normal read/write bus cycles.
The I/O address offset of the registers are listed in the System Configuration section.
Table 12. Port Configuration Registers (PCR)
Register Name
Port
A,B,C,D,E
A,B,C,D,E
C,D
Write/Read
Write/Read
Write/Read
Write/Read
Write/Read
Read
Control Register
Direction Register
Open Drain Register
Special Function Register
PLD – I/O Register
A,B,E
A,B,E
Table 13. Port Data Registers (PDR)
Register Name
Data In Register
Port
Read/Write
Read
A,B,C,D,E
A,B,C,D,E
A,B,E
Data Out Register
Macrocell Out Register
Write/Read
Read
Table 14.
Data In Register – Port A
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
PA7 Pin
PA6 Pin
PA5 Pin
PA4 Pin
PA3 Pin
PA2 Pin
PA1 Pin PA0 Pin
Direction Register – Port A
(Example: Pins PA0 – PA2 as Output, PA3 – PA7 as Input)
Bit 7
PA7 Pin
= 0
Bit 6
PA6 Pin
= 0
Bit 5
PA5 Pin
= 0
Bit 4
PA4 Pin
= 0
Bit 3
PA3 Pin
= 0
Bit 2
PA2 Pin
= 1
Bit 1
PA1 Pin PA0 Pin
= 1 = 1
Bit 0
42
PSD5XX Family
Control Register
I/O Ports
(Cont.)
This register is used in both Standard MCU I/O Mode and Address Out modes. For setting
a Standard MCU I/O Mode, a “1” must be written to the corresponding bit in the register.
Writing a “0” to the register is required for the Address Out mode. The register has a default
value of “0” after reset.
Direction Register
This register is used to control the direction of data flow in the I/O ports. Writing a “1” to
the corresponding bit in the register configures the port to be an output port, and a “0”
forces the port to be an input port. The I/O configuration of the port pins can be determined
by reading the Direction Register. After reset, the pins are in input mode.
Open Drain Register
This register determines whether the output pin driver of Port C or D is a CMOS driver or
an Open Drain driver. Writing a “0” to the register selects a CMOS driver, while a “1” selects
an Open Drain driver.
Special Function Register
Writing a “1” bit to this register sets up the corresponding pin to operate in Special Function
Out mode.
PLD – I/O Register
This is a read only status register. Reading a "1" indicates the corresponding pin is
configured as a PLD pin. A "0" indicates the pin is an I/O pin.
Data In Register
This register is used in the Standard MCU I/O Mode configuration to read the input pins.
Data Out Register
This register holds the output data in the Standard MCU I/O Mode. The contents of the
register can also be read.
Macrocell Out Register
This register enables the user to read the outputs of the GPLD macrocell (PA, PB, and PE
macrocells).
I/O Register Address Offset
The I/O Register can be accessed by the microcontroller during normal read/write bus
cycles. The address of a register is defined as:
CSIOP + register address offset
The CSIOP is the base address that is defined in the ABEL file and occupies a 256 byte
space. The register address offset lies within this 256 byte space. Tables 15 and 15a are
the address offset of the registers.
43
PSD5XX Family
Table 15. Register Address Offset
I/O Ports
(Cont.)
Address Offset
Port C
Register Name
Data In
Port A
00
Port B
01
Port D
11
Port E
20
10
12
14
16
18
Control
02
03
13
22
Data Out
04
05
15
24
Direction
06
07
17
26
Open Drain
Special Function
PLD – I/O
19
08
0A
0C
09
0B
0D
28
2A
2C
Macrocell Out
Table 15a. Register Address Offset
(For 16-bit Motorola Microcontrollers in 16-bit mode. Use Table 15 if 8-bit mode is selected.)
Address Offset
Register Name
Data In
Port A
01
Port B
00
Port C
11
Port D
10
Port E
21
Control
03
02
13
12
23
Data Out
05
04
15
14
25
Direction
07
06
17
16
27
Open Drain
Special Function
PLD – I/O
19
18
09
0B
0D
08
0A
0C
29
2B
2D
Macrocell Out
44
PSD5XX Family
9.3.11 Port A – Functionality and Structure
Port A is the most flexible of all the I/O ports. It can be configured to perform one or more
of the following functions:
I/O Ports
(Cont.)
❏ Standard MCU I/O Mode
❏ PLD I/O
❏ Address Out – latched address lines assigned to pins PA[0-7]
❏ Address In – input port for other lines, inputs can be latched by ALE.
❏ Special Function Out – pins PA0 – PA3 can be configured as dedicated timer outputs.
❏ Peripheral I/O
Figure 21 shows the structure of a Port A pin. If the pin is configured as an output port, the
multiplexer selects one of its four inputs as output. If the pin is configured as an input, the
input connects to :
1. Data In Register as input in Standard MCU I/O Mode
or
2. PA Macrocell as PLD input
or
3. PA Macrocell as Address In input (latched for multiplexed bus).
9.3.12 Port B – Functionality and Structure
Port B is similar to Port A in structure. It can be configured to perform one or more of the
following functions:
❏ Standard MCU I/O Mode
❏ PLD I/O
❏ Address Out – address lines A[0-7] for 8-bit multiplexed bus, or address lines
A[8-15] for 16-bit multiplexed bus are assigned to pins PB[0-7].
❏ Special Function Out – pins PB0 - PB3 are configured as dedicated Timer outputs.
Figure 22 shows the structure of a Port B pin. If the pin is configured as an output port, the
multiplexer selects one of its four inputs as output. If the pin is configured as input, the input
connects to :
❏ Data In Register as input in Standard MCU I/O Mode
or
❏ PB Macrocell as PLD input
45
PSD5XX Family
Figure 21. Port A Pin Structure
The PSD5XX
Architecture
(cont.)
46
PSD5XX Family
Figure 22. Port B Pin Structure
The PSD5XX
Architecture
(cont.)
47
PSD5XX Family
9.3.13 Port C and Port D – Functionality and Structure
Port C and D are identical in function and structure and each can be configured to perform
one or more of the following operating modes:
I/O Ports
(Cont.)
❏ Standard MCU I/O Mode
❏ PLD Input – direct input to ZPLD
❏ Address Out – latched address outputs
– Port C: A[0-7] are asigned to pins PC[0-7]
– Port D: A[0-7] for 8-bit multiplexed bus, or A[8-15] for 16-bit multiplexed bus are
assigned to pins PD[0-7]
❏ Data Port
– Port C: D[0-7] for 8-bit non-multiplexed bus
– Port D: D[8-15] for 16-bit non-multiplexed bus
❏ Open Drain – select CMOS or Open Drain driver
Figures 23 and 24 show the structure of a Port C or D pin. If the pin is configured as output
port, the multiplexer selects one of the two inputs as output. If the pin is configured as input,
the input connects to :
❏ Data In Register as input in the Standard MCU I/O Mode
or
❏ ZPLD input
9.3.14 Port E – Functionality and Structure
Port E can be configured to perform one or more of the following functions:
❏ Standard MCU I/O Mode
❏ PLD I/O
❏ Address Out – latched address lines A[0-7] are assigned to pins PE[0-7].
❏ Special Function Out – in this mode, Port E pin is configured as an output port for the
following signals:
PE2 – INTERRUPT – interrupt output from Interrupt Controller
PE4 – Terminal Count output, Timer0
PE5 – Terminal Count output, Timer1
PE6 – Terminal Count output, Timer2
PE7 – Terminal Count output, Timer3
❏ Alternate Function In – in this mode, the inputs to Port E pins are:
PE0 – BHE/ or PSEN/ or WRH/ or UDS/ or SIZ0
PE1 – ALE
PE3 – TIMER0-IN :load/store/enable/ disable input to Timer 0
PE4 – TIMER1-IN :load/store/enable/disable input to Timer 1
PE5 – TIMER2-IN :load/store/enable/disable input to Timer 2
PE6 – TIMER3-IN :load/store/enable/disable input to Timer 3
PE7 – APD CLK
:clock input for Automatic Power Down Counter
Figure 25 shows the structure of a Port E pin. The Control Logic block selects one of four
sources through the multiplexer for pin output. If the pin is configured as input, the input
goes to:
❏ Data In Register as input in Standard MCU I/O Mode
or
❏ PE Macrocell as PLD input
or
❏ Alternate Function In
48
PSD5XX Family
Figure 23. Port C Pin Structure
I/O Ports
(Cont.)
49
PSD5XX Family
Figure 24. Port D Pin Structure
I/O Ports
(Cont.)
50
PSD5XX Family
Figure 25. Port E Pin Structure
I/O Ports
(Cont.)
51
PSD5XX Family
The PSD5XX provides EPROM memory for code storage and SRAM memory for scratch
pad usage. Chip selects for the memory blocks come from the DPLD decoding logic and are
defined by the user in the PSDsoft Software. Figure 26 shows the organization of the
Memory Block.
9.4
Memory
Block
All PSD families use Zero-power memory techniques that place memory into standby
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.
9.4.1 EPROM
The PSD5XX provides three EPROM densities: 256Kbit, 512Kbit or 1Mbit. The EPROM
is divided into four 8K, 16K or 32K byte blocks. Each block has its own chip select signals
(ES0 – ES3). The EPROM can be configured as 32K x 8, 64K x 8 or 128K x 8 for
microcontrollers with an 8-bit data bus. For 16-bit data buses, the EPROM is configured as
16K x 16, 32K x 16, or 64K x 16.
9.4.2 SRAM
The SRAM has 16Kbits of memory, organized as 2K x 8 or 1K x 16. The SRAM is enabled
by the chip select signal RS0 from the DPLD. The SRAM has a battery back-up (STBY)
mode. This back-up mode is invoked when the VCC voltage drops under the VSTBY voltage
by 0.6 V. The VSTBY voltage is connected only to the SRAM and cannot be lower than
2.7 volts. The SRAM Data Retention voltage is 2 volts.
9.4.3 Memory Select Map
The EPROM and SRAM chip select equations are defined in the ABEL file in terms of
address and other DPLD inputs. The memory space for the EPROM chip select
(ES0 – ES3) should not be larger than the EPROM block (8KB, 16KB or 32KB) it is
selecting.
The following rules govern how the internal PSD5XX memory selects/space are defined:
❏ The EPROM blocks address space cannot overlap
❏ SRAM, internal I/O and Peripheral I/O space cannot overlap
❏ SRAM, internal I/O and Peripheral I/O space can overlap EPROM space, with priority
given to SRAM or I/O. The portion of EPROM which is overlapped cannot be accessed.
The Peripheral I/O space refers to memory space occupied by peripherals when Port A is
configured in the Peripheral I/O Mode.
52
PSD5XX Family
Figure 26. Memory Block Diagram (128KB EPROM)
Memory
Block
(Cont.)
53
PSD5XX Family
9.4.4 Memory Select Map For 8031 Application
Memory
The 8031 family of microcontrollers has separate code memory space and data memory
space. This feature requires a different Memory Select Map. Two modes of operation are
provided for 8031 applications. The selection of the modes is specified in the PSD5XX
PSDsoft Software (PSDconfiguration):
Block
(Cont.)
❏ Separate Space Mode
In this mode, the PSEN signal is used to access code from EPROM, and the RD signal
is used to access data from SRAM. The code memory space is separated from the data
memory space.
❏ Combined Space Mode
In this mode, the EPROM can be accessed by PSEN or RD. The EPROM is used for
code and data storage. The memory block's address space cannot overlap.
If data and code memory blocks must overlap each other, the RD signal can be included as
an additional address input in generating the EPROM chip select signals (ES0 – ES3). In
this case the EPROM access time is from the RD valid to data valid. Figures 27a and 27b
show the memory configuration in the two modes.
In some applications it is desirable to execute program codes in SRAM. The PSD5XX
provides this option by enabling PSEN to access SRAM. To activate this option, the
SRCODE bit of the VM Register must be set to “1” (see Table 16). SRAM space can
overlap EPROM space and has priority when PSEN is used.
Table 16. VM Register
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
PIO
SRCODE
1 = ON
*
*
*
*
*
*
1 = ON
= Reserved for future use, bits set to zero.
*
54
PSD5XX Family
Figure 27a. 8031 Memory Modes
Memory
Block
(Cont.)
ES0
ES1
ES2
ES3
RS0
SRAM
EPROM
OE
DPLD
OE
PSEN
RD
SRCODE–EN
SEPARATE SPACE MODE
Figure 27b. 8031 Memory Modes
ES0
ES1
ES2
ES3
RS0
EPROM
OE
SRAM
OE
DPLD
RD
PSEN
RD
PSEN
RD
SRCODE–EN
COMBINED SPACE MODE
55
PSD5XX Family
9.4.5 Peripheral I/O
Peripheral I/O
The Peripheral I/O Mode is one of the operating modes of Port A. In this mode, Port A
is connected to the data bus of peripheral devices. Port A is enabled only when the
microcontroller is accessing the devices, otherwise the Port is tri-stated. This feature
enables the microcontroller to access external devices without requiring buffers and
decoders. Figure 28 shows the structure of Port A in the Peripheral I/O Mode.
The memory address space occupied by the devices are defined by two signals: PSEL0
and PSEL1. The signals are direct outputs from the DPLD. Whenever any of the signals is
active, the Port A driver is enabled, and the direction of the data flow is determined by the
RD/WR signals.
The Peripheral I/O Mode and the peripheral select signals are configured and defined in the
PSDsoft Software (see the section on I/O Port for configurations). The PIO bit in the VM
Register (see Table 16) also needs to be set to “1” by the user to initialize the Peripheral I/O
Mode.
The Peripheral I/O mode can be used, for example, in DMA applications where the
microcontroller does not support DMA operations, such as tri-stating the address/data bus.
Figure 29 shows a block diagram of a microcontroller and PSD5XX based design that
makes use of this mode. In this application, the microcontroller has a multiplexed bus which
is connected to the ADIO port. The C and D ports connect to the peripheral address bus
and are both configured in Address Out Mode. Port A is configured in the Peripheral I/O
mode and is connected to the peripheral data bus. Port B and E are used to generate
control signals.
During normal activity, the microcontroller has access to any peripheral (memory or I/O
device) through the PSD5XX device. When there is a DMA request, the microcontroller
tri-states the address bus on Port C and D by writing a “0” to the port Direction Registers.
The DMA controller then takes over the data and address buses after receiving
acknowledgement from the microcontroller.
Figure 28. Port A In Peripheral I/O Mode
RD
PSEL0
PSEL1
PA0 – PA7
D0 – D7
WR
56
PSD5XX Family
Figure 29. PSD5XX Peripheral I/O Configuration
Peripheral I/O
57
PSD5XX Family
The PSD5XX provides many power saving options. By configuring the PMMRs (Power
Management Mode Registers), the user can reduce power consumption. Table 17 shows
the bit configuration of the PMMR0 and PMMR1. The microcontroller is able to control the
power consumption by changing the PMMR bits at run time.
9.5
Power
Management
Unit
9.5.1 Standby Mode
There are two Standby Modes in the PSD5XX:
❏ Power Down Mode
❏ Sleep Mode
9.5.2 Power Down
In this mode, the internal devices are shut down except for the I/O ports. There are three
ways the PSD5XX can enter into the Power Down Mode: by controlling the CSI input,
by activating the Automatic Power Down (APD) Logic, or when none of the inputs are
changing and the turbo bit is off.
❏ The CSI
The CSI input pin is an active low signal. When low, the signal selects and enables the
PSD5XX. The PSD5XX enters into Power Down Mode immediately when the signal
turns high. This signal can be controlled by the microcontroller, external logic or it can
be grounded.
The CSI turns off the internal bus buffers in standby mode. The address and control
signals from the microcontroller are blocked from entering the ZPLD as inputs.
❏ The APD Logic
The APD unit enables the user to enter a power down mode independent of controlling
the CSI input. This feature eliminates the need for external logic (decoders and latches)
to power down the PSD. The APD unit concept is based on tracking the activity on the
ALE pin. If the APD unit is enabled and ALE is not active, the 4-bit APD counter starts
counting and will overflow after 15 clocks, generating a PD (Power Down) signal
powering down the PSD. If sleep mode is enabled, then PD signal will also activate the
sleep mode. Immediately after ALE starts pulsing the PSD will get out of the power
down or sleep mode.
The operation of APD is controlled by the PMMR (see Figure 30a). PMMR1 bit 0 selects
the source of the APD counter clock. After reset the APD counter clock is connected to
PE7 (APD_CLK) on the PSD. In order to guarantee that the APD will not overflow there
should be less than 15 APD clocks between two ALE pulses. If CLKIN frequency is
adequate, then it can be connected to the APD and PE7 is used for other functions.
The next step is to select the ALE power down polarity. Usually, MCUs entering power
down will freeze their ALE at logic high or low. By programming bit 1 of PMMR0 the
power down polarity can be defined for the APD. If the APD detects that the ALE is
in the power down polarity for 15 APD counter clocks then the PSD will enter a power
down mode. To enable the APD operation, bit 2 in the PMMR0 should be set high.
9.5.3 Sleep Mode
The Sleep Mode is activated if the SLEEP EN bit, the APD EN bit, and the ALE Polarity bit
in the PMMR are set, and the APD Counter has overflowed after 15 clocks (see Figure 30).
In Sleep Mode the PSD5XX consumes less power than the Power Down Mode, with typical
ICC reduced to 10 µA (1 µA for ZPSD5XX devices).
In this mode, the Counter/Timers, the Interrupt Controller and the ZPLD still monitor their
inputs and respond to them. As soon as the ALE starts pulsing, the PSD5XX exits the
Sleep Mode.
The PSD access time from Sleep Mode is specified by tLVDV1. The ZPLD response time to
an input transition is specified by tLVDV2
.
58
PSD5XX Family
Figure 30. Power Management Unit
Power
Management
Unit
TO OTHER
CIRCUITS
(Cont.)
SLEEP–ENABLE
PMMR1 - BIT 1
APD ENABLE
PMMR0 - BIT 2
ALE POLARITY
PMMR0 - BIT 1
SLEEP
MODE
APD
CLEAR
LOGIC
ALE
CLR
APD
PD
EPROM
SELECT
COUNTER
Z
P
L
D
RESET
CLK
SRAM
SELECT
APD CLK
CLKIN
I/O
SELECT
MUX
POWER
DOWN
CSI
APD CLK
PMMR1 - BIT 0
Figure 30a. Automatic Power Down Unit (APD) Flow Chart
RESET
CSI = "1"
APD DISABLED
YES
NEED
APD CLK
SET APD CLK IN PMMR1 BIT 0
NO
SET ALE PD POLARITY
IN PMMRO BIT 1
NEED
SLEEP
MODE
YES
SET SLEEP MODE IN PMMR1 BIT 1
NO
• SET ENABLE APD IN PMMR0 BIT 2
• SET PMMR0 BIT 0
• SET ENABLE APD IN PMMR0 BIT 2
• SET PMMR0 BIT 0
DISABLE CLOCKS
ZPLD ACLK, ZPLD RCLK, TMR ZPLD
DISABLE CLOCKS
ZPLD ACLK, ZPLD RCLK, TMR ZPLD
ALE IDLE and
15 APD CLOCK
ALE IDLE and
15 APD CLOCK
PSD IN POWER DOWN MODE
PSD IN SLEEP MODE
59
PSD5XX Family
Table 17. Power Management Mode Registers (PMMR0, PMMR1)
PMMR0
Power
Management
Unit
(Cont.)
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
TMR CLK
ZPLD
RCLK
ZPLD
ACLK
ZPLD
TURBO
APD
ENABLE
ALE PD
Polarity
*
CMISER
1 = ON
1 = OFF
1 = OFF
1 = OFF
1 = OFF
1 = ON
1 = HIGH
Bit 0
= Should be set to High (1) to operate the APD.
*
Bit 1 0 = ALE Power Down (PD) Polarity Low.
1 = ALE Power Down (PD) Polarity High.
Bit 2 0 = Automatic Power Down (APD) Disable.
1 = Automatic Power Down (APD) Enable.
Bit 3 0 = EPROM/SRAM CMiser is OFF.
1 = EPROM/SRAM CMiser is ON.
Bit 4 0 = ZPLD Turbo is ON. ZPLD is always ON.
1 = ZPLD Turbo is OFF. ZPLD will Power Down when inputs are not changing.
Bit 5 0 = ZPLD Clock Input into the Array from the CLKIN pin input is connected. Every
Clock change will Power Up the ZPLD when Turbo bit is OFF.
1 = ZPLD Clock Input into the Array from the CLKIN pin input is disconnected.
Bit 6 0 = ZPLD Clock Input into the the MacroCell registers from the CLKIN pin input
is connected.
1 = ZPLD Clock Input into the the MacroCell registers from the CLKIN pin input
is disconnected.
Bit 7 0 = In the PSD5XX Clock Input is connected to the Timer.
1 = In the PSD5XX Clock Input is disconnected from the Timer.
PMMR1
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
Sleep
Mode
APD CLK
*
*
*
*
*
*
1 = ON 1 = CLKIN
Bit 0
0 = Automatic Power Down Unit Clock is connected to Port E7 (PE7) alternate
function input.
1 = Automatic Power Down Unit Clock is connected to the PSD Clock
input (CLKIN).
Bit 1
0 = Sleep Mode Disabled.
1 = Sleep Mode Enabled.
Bit 2–7 0 = Reserved for future use, should be set to zero.
Table 18. APD Counter Operation
ALE Power
APD EN Bit
ALE Status
APD Counter
Down Polarity
0
1
X
X
Not Counting
X
Pulsing
Not Counting
Counting (Activates Standby
Mode After 15 Clocks)
1
1
1
0
1
0
Counting (Activates Standby
Mode After 15 Clocks)
60
PSD5XX Family
9.5.4 Other Power Saving Options
Power
The PSD5XX provides additional power saving options. These options, except the SRAM
Standby Mode, can be enabled/disabled by setting up the corresponding bit in the PMMR.
Management
Unit
(Cont.)
❏ EPROM
The EPROM power consumption in the PSD is controlled by bit 3 in the
PMMR0 – EPROM CMiser. Upon reset the CMiser bit is OFF. This will cause the
EPROM to be ON at all times as long as CSI is enabled (low). The reason this mode is
provided is to reduce the access time of the EPROM by 10 ns relative to the low power
condition when CMiser is ON. If CSI is disabled (high) the EPROM will be deselected
and will enter standby mode (OFF) overriding the state of the CMiser.
If CMiser is set (ON) then the EPROM will enter the standby mode when not selected.
This condition can take place when CSI is high or when CSI is low and the EPROM is
not accessed. For example, if the MCU is accessing the SRAM, the EPROM will be
deselected and will be in low power mode.
An additional advantage of the CMiser is achieved when the PSD is configured in the
by 8 mode (8 bit data bus). In this case an additional power savings is achieved in the
EPROM (and also in the SRAM) by turning off 1/2 of the array even when the EPROM
is accessed (the array is divided internally into odd and even arrays).
The power consumption for the different EPROM modes is given in the DC
Characteristics table under ICC (DC) EPROM Adder.
❏ SRAM Standby Mode
The SRAM has a dedicated supply voltage VSTBY that can be used to connect a
battery. When VCC becomes lower than VSTBY –0.6 then the PSD will automatically
connect the VSTBY as a power source to the SRAM. The SRAM Standby Current (ISTBY
)
is typically 0.5 µA.
SRAM data retention voltage VDF is 2 V minimum.
❏ Zero Power ZPLD
ZPLD power/speed is controlled by the ZPLD_Turbo bit (bit 4) in the PMMR0. After
reset the ZPLD is in Turbo mode and runs at full power and speed. By setting the bit to
“1”, the Turbo mode is disabled and the ZPLD is consuming Zero Power current if the
inputs are not switching for an extended time of 100 ns. The propagation delay time will
be increased by 10ns after the Turbo bitis set to “1” (turned off) if the inputs change at a
frequency of less than 15 MHz.
61
PSD5XX Family
Power
Management
Unit
(Cont.)
❏ Input Clock
The PSD5XX provides the option to turn off the clock inputs to save AC power
consumption. The clock input (CLKIN) is used as a source for driving the following
modules:
❏ ZPLD Array Clock Input
❏ ZPLD MacroCell Clock Flip Flop
❏ APD Counter Clock
❏ Counter/Timers Clock
During power down or if any of the modules are not being used the clock to these
modules should be disabled. To reduce AC power consumption, it is especially important
to disable the clock input to the ZPLDS array if it is not used as part of a logic equation.
The ZPLD Array Clock can be disabled by setting PMMR0 bit 5 (ZPLD ACLK). The ZPLD
MacroCell Clock Input can be disabled by setting PMMR0 bit 6 (ZPLD RCLK). The Timer
Clock can be disabled by setting PMMR0 bit 7 (TMR CLK). The APD Counter Clock
will be disabled automatically if Power Down or Sleep Mode is entered through the APD
unit. The input buffer of the CLKIN input will be disabled if bits 5 – 7 PMMR0 are set and
the APD has overflowed.
The Counter/Timers can operate in Sleep Mode if the TMR CLK bit is low, but the power
consumption will be based on the frequency of operation (CLKIN frequency).
Summary of PSD5XX Timing and Standby Current During Power Down
and Sleep Modes
PLD
Propagation
Delay
PLD
Access
Time
Access
Recovery
Time To
Normal
Recovery
Time To
Normal
Operation
Access
Power Down
Sleep
Normal tPD
(Note 1)
0
No Access
No Access
tLVDV
tLVDV2
tLVDV3
tLVDV1
(Note 2)
(Note 3)
NOTES: 1. Power Down does not affect the operation of the ZPLD. The ZPLD operation in this mode is based
only on the ZPLD_Turbo Bit.
2. In Sleep Mode any input to the ZPLD will have a propagation delay of tLVDV2
3. PLD recovery time to normal operation after exiting Sleep Mode. An input to the ZPLD during the
transition will have a propagation delay time of tLVDV3
.
.
Table 20. I/O Pin Status During Power Down And Sleep Mode
Port Configuration
Pin Status
I/O Port
Unchanged
ZPLD Output
Address Out
Data Port
Depend on Inputs to the ZPLD
Undefined
Tri-stated
Special Function Out
Peripheral I/O
Depending on Status of Clock Input
Tri-stated
62
PSD5XX Family
General Description
9.6
PSD5XX
Counter/Timer
The PSD5XX contains a powerful set of four 16 bit Counter/Timers, each controlled by
either PPLD outputs, external pins or Software. The Counter/Timers aid the user in
counting external events and/or generating accurate delays. These can be operated
as Counters or Timers. In Event-count, time capture and WatchDog modes, the
Counter/Timers work as Counters, whereas in Waveform and Pulse modes they work as
Timers. All Counter/Timers are capable of generating interrupts through the On-Board
Interrupt Controller. Each of the Counter/Timers consist of a Counter/Timer Command
register, Counter/Timer Image register and Counter/Timer register. All four Counter/Timers
share a Global command register, a Software Load/Store register, a Freeze command
register and the Status register. Counter/Timer 2 can support WatchDog operations.
All Counter/Timers share a common clock input and Delay Cycle register used in scaling
down the input clock to the Counter/Timer. The maximum resolution of the Counter/Timer
is the input clock of the PSD5XX divided by four. The maximum input clock frequency to
the PSD5XX is 30 MHz. Figures 31 and 32 describe the general features of the
Counter/Timers.
Features
❏ Four 16 bit Counter/Timers.
❏ Five modes of operation
– Waveform Mode
– Pulse Mode
– Event Counter Mode
– Time Capture Mode
– WatchDog Mode
*
❏ Each Counter/Timer can be controlled by an input pin, dedicated PPLD macrocell or
software.
❏ Each Counter/Timer has an output to the Interrupt Controller.
❏ The WatchDog output is routed through the PLD and can be programmed to be
output at any PLD output pin.
❏ Programmable input and output polarity.
❏ Counter/Timer can be programmed as UP or DOWN Counter, except in
WatchDog mode.
❏ All Counters have the operating frequency range of DC to 7.0 MHz
(i.e 143 ns maximum resolution at 7.0 MHz). Higher resolution can be achieved
by using in conjunction with the GPLD macrocells.
❏ High resolution Divisor unit for Counter clocking purposes.
❏ Can easily interface with any 8 or 16 bit Microcontroller or Microprocessor.
See Process Change Notice related to Event Count Mode on page 148.
( ) Counter/Timer-2 can operate in WatchDog mode.
*
63
PSD5XX Family
Figure 31. Counter/Timer Block Diagram
PSD5XX
Counter/Timer
(Cont.)
64
PSD5XX Family
Figure 32.
Counter/Timer and Interrupt Controller Interface with Other Internal Blocks
PSD5XX
Counter/Timer
(Cont.)
65
PSD5XX Family
PSD5XX
9.6.1 Counter/Timer Operation
There are four identical 16 bit Counter/Timers CNTR0,CNTR1,CNTR2 and CNTR3 and
associated Counter/Timer image registers IMG0,IMG1,IMG2 and IMG3. Refer to Table 21
for counter name and register correspondence. All Counter/Timers share a common clock
source. Each Counter/Timer can be operated in either WAVEFORM / PULSE mode or
EVENT COUNTER/TIME CAPTURE mode. Counter 2 can be set up as a Watchdog timer in
both modes. Note that in Event Counter/Time Capture mode COUNTER 2 can only be set
up as a Watch Dog Counter/Timer, whereas in the Waveform/Pulse mode Counter 2 can be
configured as a Pulse or Waveform generator or as a Watchdog timer. Refer to Table 24 for
possible combinations of Counter/Timer modes and refer to Figure 33 for additional details.
Counter/Timer
Operation
(Cont.)
Each Counter/Timer can be controlled by an input pin or through a dedicated PPLD
macrocell output or by software. Counter/Timer outputs are available through port A or
port B pins in alternate function mode (Refer to the chapter on I/O ports). Polarity of
these inputs/outputs is software programmable. The following sections describe various
command and data registers that need to be initialized for proper function of these
Counter/Timers.
9.6.1.1 Counter/Timer Operating Modes
The PSD5XX Counter/Timer has five basic modes of operation: The Waveform and Pulse
or Event Counter, Time Capture, and Watchdog. The Waveform and Pulse modes cannot
be used in conjunction with Event and Time Capture modes. Both Waveform/Pulse or
Event Count/Time Capture modes can set Counter 2 into the fifth mode of operation, the
“WatchDog” mode.
The basic functional element used in all these modes is the Counter/Timer unit (CTU)
illustrated in Figure 33. This block consists of a 16 bit increment/decrement Counter, and a
16 bit image register with various control signals. The key function of the image register is
to enable microcontroller access of the Counter without asynchronously interrupting the
Counter. Software can configure each Counter/Timer using the associated Command
register. The Counter/Timer of the PSD5XX employs four CTUs to realize the various
modes of operation.
Table 21. Registers Used By Counters
Counter Name
Counter 0
Counting Register
CNTR0
Image Register
IMG0
Counter 1
CNTR1
IMG1
Counter 2
CNTR2
IMG2
Counter 3
CNTR3
IMG3
66
PSD5XX Family
Figure 33. Inside of Each CTUx (x = 0, 1, 2, 3)
PSD5XX
Counter/Timer
Operation
(Cont.)
67
PSD5XX Family
9.6.1.2 Waveform Mode
Counter/Timer
In Waveform mode, the Counter/Timer is capable of producing various pulse-width
modulated (PWM) signals. The Waveform mode in the PSD5XX is realized using two CTUs
(COUNTER/TIMER UNITs) in the following combinations:
Operation
(Cont.)
CTU0 & CTU1 or CTU2 & CTU3.
The outputs of CTU0 and CTU2 are available at Port A and Port B. Refer to Tables 25 and
26 for further details and configuration of these ports. CTU1 and CTU3 are internally
connected to CTU0 and CTU2. The Waveform mode is illustrated in Figure 34 which shows
a typical PWM waveform and the time slots in which two CTUs are active. The Waveform
period is the sum of the counts for CTU0 and CTU1 (see equation 1), while the duty cycle is
given by equation 2. The Duty cycle of a waveform can be changed by loading a new value
into the corresponding IMAGE register, and as soon as a Terminal Count is generated this
new value gets loaded into the CTU. Note that the end of a CTU time slot is indicated with
Terminal Count signal of the active CTU. The Terminal Count signals are used to signal the
transfer of active status between CTUs. The Terminal Count is true whenever the Counter
underflows while decrementing or when the Counter overflows while incrementing.
PERIOD of the waveform generated
= COUNT HIGH + COUNT LOW..(1)
DUTY Cycle of the Waveform Generated
COUNT HIGH
=
COUNT HIGH + COUNT LOW......(2)
The timing of various pulses that create a Waveform signal in the above example is defined
by the Microcontroller via image register updates of the CTU0 and CTU1. The contents of
an image register are loaded or copied to the associated Counter under any of the following
conditions:
❏ Terminal Count of CTU1 and/or CTU3 pulses to transfer active status to CTU0
and/or CTU2.
❏ An input pin (port E) pulses (If enabled by software).
❏ A PPLD macrocell output pulses (If enabled by software).
❏ A command register bit is written to by the Microcontroller, i.e., a software
Load/Store (load).
A Waveform output is first initialized and then later modified by setting its two corresponding
software Load/Store bits after loading of the Image Registers. If the Counter/Timer register
is directly loaded by the MCU, it gets overwritten by the associated Image register contents
as soon as the Counter/Timer is active. The configuration of the CTU in the waveform mode
is schematically illustrated in Figure 35.
The output polarity during the CTU0 time slot is controlled by bit 3 in the Counter/Timer
command register. The output polarity during the CTU1 time slot is defined as the
complement of the CTU0 polarity. Similarly, the polarity of the input pin is controlled by bit 4
in the Counter/Timer command register. This description of the waveform mode of operation
applies to CTU2 and CTU3 also.
In order to change the image register values, use the Freeze/Freeze Acknowledge protocol
as described in the Freeze Command Register section.
68
PSD5XX Family
Figure 34. Sample Waveform (PWM) and CTU Time Slots
(Using Counters/Timers 0 and 1)
Counter/Timer
Operation
(Cont.)
69
PSD5XX Family
Figure 35. CTU Control Signals For Waveform Mode
Counter/Timer
Operation
(Cont.)
70
PSD5XX Family
Counter/Timer
Operation
(Cont.)
9.6.1.3 Pulse Mode
In Pulse mode, the Counter/Timer is capable of generating a one shot pulse. The Pulse
width of the generated pulse is defined by the value loaded into the associated Image
register of the timer. If the Counter/Timer register is directly loaded by the MCU, it gets
overwritten by the associated Image register contents as soon as the Counter/Timer
is active. Each CTU is capable of pulse mode. As soon as the Timer is active,
i.e. decrementing or incrementing, a pulse is output until the Timer underflows or overflows.
The pulse waveform is illustrated in Figure 36. The active level of this pulse is defined
again by a command register bit. As can be seen in Figure 37, the pulse is triggered by any
of the following events:
❏ Transition on the input pin (Port E) (If enabled by software).
❏ PPLD macrocell output pulses (If enabled by software).
❏ Command register bit is written to by a Microcontroller (Software load).
As in the waveform mode, the polarity of the input pin is defined by a command register
bit and the Freeze/Freeze Acknowledge must be used whenever the image register is
modified.
The outputs of CTU0, CTU1, CTU2 and CTU3 are available at Port A and Port B. Refer to
Tables 25 and 26 for further details and configuration of these ports.
9.6.1.4 Event Counter Mode
In this mode, the Counter/Timer uses the CTU to count a number of events. An event is
defined as a signal-transition on the Counter’s input pin as defined by the input polarity
configuration bit in the Command Registers or a Low to High transition on the PPLD
Macrocell output. In this mode, the image register of the CTU is used to store the contents
of the Counter at the rising edge of the Load/Store signal. This is opposed to the previous
two modes in which the image register was used to load the Counter. Figure 38 shows the
configuration of the CTU for the event-Counter mode. Notice that the enable signal is edge
sensitive. Its source is either:
❏ Pin Driven.
❏ PPLD Macrocell Driven.
All Counter/Timer registers must be assigned values during initialization in the Event
Counter mode. During normal operation, the CTU increments or decrements its count
when an event occurs. The image register is then immediately updated with the current
count. The microcontroller can read the contents of the image register by first setting the
command-register Freeze bit in order to disable count updates of the image register during
its read operation. The microcontroller waits for a freeze acknowledge and then accesses
the image register in the usual fashion. The Freeze signal effectively guarantees stable
image register data during microcontroller read access, even though the CTU continues to
count events. During the Freeze Acknowledge active state, the counter continues counting.
Note that for an event to be counted the events must be separated by at least one timer
clock period plus two CLKIN clock periods.
71
PSD5XX Family
Figure 36. Sample Pulse-Mode Waveform
Counter/Timer
Operation
(Cont.)
OUTPUT
WAVEFORM
TERMINAL
COUNT
PULSE
TRIGGER
EVENT
CTU ACTIVED BY A
LOAD/STORE PULSE
CTU INACTIVE
CTU INACTIVE
72
PSD5XX Family
Figure 37. CTU Control Signals For Pulse Mode
Counter/Timer
Operation
(Cont.)
73
PSD5XX Family
Figure 38. CTU Control Signals For Event Count Mode
Counter/Timer
Operation
(Cont.)
74
PSD5XX Family
9.6.1.5 Time Capture Mode
Counter/Timer
In the time capture mode, the Counter/Timer is capable of measuring the time
Operation
(Cont.)
(by counting clock pulses) between events. Figure 39 shows the CTU configuration for
time capture. All the Counter/Timer registers must be cleared during initialization of the
Time Capture mode. Here the Counter is enabled to count via software only. The CTUs
continuously count. A Load/Store pulse triggers the storing of the Counter’s contents into
the associated image register. The image register effectively contains a “snap shot” of the
Counter at the time of the pulse. The CTU Store input is edge-triggered by events, the
events being:
❏ Pin Driven.
❏ PPLD Macrocell Driven.
❏ Software Driven.
A Freeze signal is used to ensure that image data is stable during Microcontroller reads
which is similar to the description of event Counter Microcontroller read accesses. Two
CTUs in time capture mode can be used to capture the rising and the falling edges of a
pulse, the difference of the measurements being the pulse width. The counter continues to
count regardless of the Freeze Acknowledge state.
Note that the time span between two consecutive edges of Time Capture must be greater
than one timer clock cycle in order to be captured.
9.6.1.6 WatchDog Counter/Timer
Counter/Timer-2 can be operated as a WatchDog Timer in both Waveform/Pulse and Event
count/time capture modes. In Event count/time capture mode, Counter/Timer-2 can be
configured only as WatchDog. Figure 40 shows the control signals of the CTU when in
WatchDog mode. When the WatchDog mode is active, CTU2 counts down and at the
terminal count of Counter-2 a WatchDog condition occurs. To avoid the WatchDog from
occurring, a "Write" to the Software Load/Store Bit-2 in the "Software Load/Store Register"
has to take place before the Counter-2 underflows. This action reloads the Counter-2 with
the initial count value in the Image Register-2. Note that this initial count value cannot be
changed after the WatchDog mode is enabled.
The Terminal Count signal of a WatchDog could result in a pulse width that is equal to the
count value loaded into the Image Register of Counter/Timer-2. The active high WatchDog
pulse from Counter 2 is routed through the PPLD, enabling the user to inverse its polarity or
implement any other logic before driving the WatchDog output on a user defined I/O pin.
This signal could be used to drive a RESET pin or trigger a Non-Maskable interrupt on a
processor. Once Counter/Timer-2 is set to the WatchDog mode, it cannot be reconfigured
by software and it can get out of the WatchDog mode only by a RESET.
When the WatchDog is enabled in Power Down and Sleep modes, it remains active
regardless of the state of bit 7 (TMR CLK) in Power Management Mode Register PMMR0.
The WatchDog mode is enabled by setting the WatchDog bit in the global command
register. Setting up the command register for CTU2 is not required except when CTU3 is
configured in pulse mode. In this case, bit 0 of the command register for CTU2 is set to “1”.
75
PSD5XX Family
Figure 39. CTU Control Signals For Time Capture Mode
Counter/Timer
Operation
(Cont.)
76
t
i
Counter
Timer
o
WATCHDOG
GPLD
OUTPUT
COUNTER OUTPUT
(ACTIVE HIGH)
OUTPUT
PIN
GPLD
WDOG2PLD
TERMINAL COUNT TO
INTERRUPT CONTROLLER
TERMINAL COUNT TO
PORT E
SET WATCHDOG BIT
EN/DIS
(BIT 3 OF GLOBAL COMMAND REGISTER)
(SELF LATCHING BIT)
C
O
U
N
T
I
M
A
G
E
SOFTWARE LOAD
(BIT 2 OF SOFTWARE LOAD/STORE REGISTER)
E
R
LOAD
2
2
m
TIMER_CLOCK
7
PSD5XX Family
9.6.1.7 Terminal Counts (TCs)
Counter/Timer
The terminal counts (TC0 – TC3) generated by the Counter/Timers are made available
at Port E as outputs or as feedbacks to the ZPLD. Refer to Table 27a for pin assignments.
The terminal counts can be used to concatenate the 16-bit Counter/Timers into a
larger counter. Only the trailing edge of the TC signal can be used as input to another
Counter/Timer. For example, concatenating CTU0 and CTU1 requires the following
PPLD equation in the PSDabel file:
Operation
(Cont.)
mc2tmr1 = tc0;
In order for a TC signal to come out, its respective bit in the Port E Special Function Out
Register must be set to 1. TC signals on Port E pins can be used as inputs to the ZPLD.
A TC signal goes high for the duration of at least four CLKIN periods whenever its
corresponding Timer Counting-Register overflows or underflows.
Figure 41 gives the timing relationship between CLKIN and the TC signal.
Figure 41. Timing Relationship Between CLKIN and the TC Signal.
4 CLKIN PERIODS
CLKIN
30ns
30ns
TC - SIGNAL
NOTES: 1. Overflow occurs when a counter value changes from FFFFh to 0000h during incrementing.
2. Underflow occurs when a counter value changes from 0000h to FFFFh during decrementing.
9.6.1.8 Counter/Timer Clock Input
All Counter/Timers 0 through 3 have a common clock source. The Counter/Timers are
clocked from the output of a highly flexible and high resolution Divisor unit. The Divisor’s
input is the external Clock input pin. The Divisor DIV is a number in the range of
4 <= DIV <= 280. Refer to Table 22 for exact values of DIV for different clock values.
Figure 42 details the PSD5XX Counter clock generation.
The Counter/Timer CLOCK input
(External Clock input)
=
(DIV)
where DIV = N K and N = (4 + DLCY).
*
The value of K depends on the Scale-Bit (Bit 0 in the Global Command Register) in the
“Global Command Register” , K = 8 when Scale-Bit is set to 1 and K = 1 when Scale-Bit is
set to 0. DLCY is the number of Delay Cycles in the range of 0 <= DLCY <= 31 set up in the
Delay Cycle Register. The fastest clock to service the Counter/Timer is = (Clock input / 4).
The maximum External Clock input value is 28 MHz and the fastest internal count frequency
is 7.0 MHz, i.e., a resolution of 143 ns. (Higher resolution can be achieved by using in
conjunction with GPLD macrocells). The default value of DIV is 4 (following a reset both K
and DLCY contain zeroes).
78
PSD5XX Family
Counter/Timer Clock Input (Cont.)
Table 22. DLCY, Scale Bit and DIV to Generate Different Clock Divisions
Counter/Timer
Operation
(Cont.)
DLCY
Scale Bit
DIV
DLCY
Scale Bit
DIV
0
1
2
3
4
5
6
7
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
4
5
6
7
8
9
1
2
3
4
5
6
7
8
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
40
48
56
64
72
80
88
96
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
8
9
9
104
112
120
128
136
144
152
160
168
176
184
192
200
208
216
224
232
240
248
256
264
272
280
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
Sample Calculation of Timer Input Clock
External input clock to the PSD5XX is 8 MHz.
If required Counter/Timers 0 – 3 count frequency is 1 MHz then
The Counter/Timer CLOCK Input
(External Clock input)
=
(DIV)
8 MHz
1 MHz =
=>
(DIV) = 8
(DIV)
Therefore from Table 22 when (DIV) = 8, the Scale-Bit in the “Global Command Register” is
set to a 0 and the DLCY register to a value of 4.
79
PSD5XX Family
Figure 42. Counter Clock Generation
Counter/Timer
Operation
(Cont.)
SCALE BIT
IN GLOBAL CMD
REGISTER
RESULTING
DIVISOR VALUE
4 < = DIV < = 280
TIMER CLOCK TO
COUNTERS / TIMERS 0 – 3
CLKIN
PIN
DELAY CYCLE
REGISTER
0 < = DLCY < = 31
80
PSD5XX Family
9.6.2 Counter/Timer Registers
Counter/Timer
Registers CNTR0,CNTR1,CNTR2 and CNTR3 serve as actual counting logic. Registers
IMG0,IMG1,IMG2 and IMG3 serve as images of these Counter/Timers. Depending upon the
selected mode of operation, a Counter can load a new value or transfer its content to the
image register. Registers IMG0 - IMG3 and CNTR0 - CNTR3 are accessible to the
Microcontroller only before setting the start bit (Bit 1 in the Global Command Register).
When CNTR0-CNTR3 are active, the value in the read operation is not guaranteed to be
stable and during a write operation there could be contention between the image register
write and microcontroller write. Therefore the access of registers CNTR0-CNTR3 should
be suspended when the Counter/Timers are active. Only IMG0, IMG1, IMG2 and IMG3
registers are accessible when the Counter/Timers are active.
Operation
(Cont.)
Tables 23 and 23a give the address map for the various port and Counter/Timer-unit
registers. This address offset map is of the host processor, relative to CSIOP (Chip Select
Input Output Port) i.e. address space allocated by the host Microcontroller to access all the
PSD5XX embedded peripherals.
Table 23a is for 16-bit Motorola Microcontrollers which require different address offsets.
Table 23. Offset Address Map of Counter/Timer-Unit Registers
Address
Offset
Address
Offset
Register Name
Register Name
+A9h
STATUS FLAGS
+A8h
+A6h
+A4h
+A2h
+A0h
+9Eh
+9Ch
+9Ah
+98h
+96h
+94h
+92h
+90h
GLOBAL COMMAND
DLCY
+A5h
+A3h
+A1h
+9Fh
+9Dh
+9Bh
+99h
+97h
+95h
+93h
+91h
SOFTWARE LOAD/STORE
FREEZE COMMAND
CMD2
CMD3
CMD1
CNTR3
CNTR2
CNTR1
CNTR0
IMG3
CMD0
CNTR3
CNTR2
CNTR1
CNTR0
IMG3
IMG2
IMG2
IMG1
IMG1
IMG0
IMG0
81
PSD5XX Family
Table 23a. Offset Address Map of Counter/Timer-Unit Registers
(For 16-Bit Motorola MCUs in 16-Bit Mode. If 8-Bit Mode is selected, use Table 23.)
Counter/Timer
Registers
(Cont.)
Address
Offset
Address
Offset
Register Name
Register Name
+A8h
STATUS FLAGS
+A9h
+A7h
+A5h
+A3h
+A1h
+9Fh
+9Dh
+9Bh
+99h
+97h
+95h
+93h
+91h
GLOBAL COMMAND
DLCY
+A4h
+A2h
+A0h
+9Eh
+9Ch
+9Ah
+98h
+96h
+94h
+92h
+90h
SOFTWARE LOAD/STORE
FREEZE COMMAND
CMD2
CMD3
CMD1
CNTR3
CNTR2
CNTR1
CNTR0
IMG3
CMD0
CNTR3
CNTR2
CNTR1
CNTR0
IMG3
IMG2
IMG2
IMG1
IMG1
IMG0
IMG0
Registers IMG0 through IMG3 are written to by the microcontroller to load the
Counter/Timers with required values in Waveform, Pulse and WatchDog mode only.
To retrieve the count or time in Event count or Time capture modes, Counter/Timers store
their values into IMG0 through IMG3.
Any access to the Image Registers must conform to the Freeze/Freeze Acknowledge
protocol, described later in the Freeze Command paragraph.
82
PSD5XX Family
Counter/Timer
Registers
(Cont.)
9.6.2.1 Global Command Register
This is used to specify the operation mode of the Counter/Timer and to start or stop the
Counter/Timer. Therefore during the initialization of the Counter/Timer registers, the Global
Command Register should always be configured last.
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
Watch
Dog
Global
Mode
Counter
Start
Scale
*
*
*
*
NOTE:
= Not used.
*
At RESET all bits come up as 0’s.
Watch Dog Bit:
When this bit is
0: Watch Dog mode is NOT selected.
1: Watch Dog Counter/Timer (Counter 2) is active. This bit can be
turned off by RESET only.
NOTE: Whenever this bit is set to 1, the COUNTER START bit should
also be set to 1. Otherwise the Counter/Timer will always be off,
i.e., once this bit is set, access to Counter 2 Registers and the Global
Command Registers are blocked.
Global Mode Bit: When this bit is set to a
0: All Timers/Counters are set to Waveform or Pulse Mode.
1: All Timers/Counters are set to operate in Event Counter or Time
Capture Mode.
NOTE: Further selection of modes is done in individual CMD registers.
Counter Start Bit: When this bit is set to
0: ALL CTUs are disabled and can be re-initialized.
1: ALL CTUs are enabled.
Scale Bit:
When this bit is set to
0: The clock to all Counter/Timers is divided by 1.
1: The clock to all Counter/Timers is divided by 8.
83
PSD5XX Family
Counter/Timer
Registers
(Cont.)
9.6.2.2 Command Registers for Counter/Timers CMD0, CMD1, CMD2, CMD3:
Each of the Counter/Timer units (CTU) has one Command Register associated with it.
A description of these various CTU command bits is provided below. Refer to CSIOP
Tables 23 and 24 for their addresses and selection details. Figure 43 describes the
Command Register bits.
The following is the description of Counter/Timer0 CMD0 register bits. Bits in CMD1, CMD2
and CMD3 have similar descriptions. Refer to Figure 43 also.
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
Enable/
Disable
Using
Pin,
Software
Gating
Bit for
Pin/
PPLD
Macrocell
Input
Polarity
Output
Polarity
Select
Counter Decrement
Increment/
Mode
Select
Load/
PPLD
Store cmd
Macrocell Using Pin
or or PPLD
Software Macrocell
NOTES: 1. At RESET these bits come up as 0s.
2. In WatchDog Mode, CMD2 register bits are Don’t Cares.
Mode Select Bit (0):
This bit selects the Counter/Timer0 operation mode. After
RESET Counter/Timer0 initializes in waveform/event count
mode. When this bit is set to
1: The Counter/Timer0 operates in Pulse/Time capture
modes.
0: The Counter/Timer0 operates in Waveform/Event count
modes.
NOTE: See Table 24 for details of Timer mode set up.
Increment/Decrement Bit (1): This bit is used to set the Counter/Timer in increment or
decrement mode. The RESET state is Decrement mode.
When this bit is set to
1: The Counter/Timer0 is in increment mode.
0: The Counter/Timer0 is in decrement mode.
NOTE: In WatchDog mode Counter #2 is in decrement
mode only.
Select Counter Bit (2):
This bit is used to select or deselect Counter/Timer0.
At RESET this bit initializes as 0 which means
Counter/Timer0 is deselected. When this bit is set to
1: Counter/Timer0 is selected (counting enabled).
0: Counter/Timer0 is deselected (counting disabled).
After a Counter/Timer is started by the Global Command Register, it can be re-configured by
changing the individual Command Register. The steps to re-configure a Counter/Timer are:
1. Disable the Counter/Timer by writing a “0” to the Select Counter Bit (bit 2) of the
Command Register.
2. Change the Counter/Timer configuration by writing the new value (bit 2 remains at “0”)
to the Command Register.
3. Enable the Counter/Timer again by writing the new value with bit 2 set to “1” to the
Command Register.
84
PSD5XX Family
Counter/Timer
Registers
(Cont.)
Command Registers for Counter/Timers CMD0, CMD1, CMD2, CMD3 (Cont.)
Output Polarity Bit (3):
This bit is valid only in Waveform or Pulse mode and is
used to select the polarity of the Active output signal
of the Counter/Timer0. At RESET this bit initializes as 0
which means the Active output state is LOW. When this bit
is set to a
1: The Active output state is HIGH.
0: The Active output state is LOW.
Input Polarity Bit (4):
The state of this bit determines the polarity of the Active
input control signal to the Counter/Timer0 and is valid only
for input pin. At RESET this bit initializes as 0 which means
that the input Active is HIGH. When this bit is set to a
1: The input Active is LOW.
0: The input Active is HIGH.
Pin / PPLD Macrocell Bit (5): This bit determines whether the Counter/Timer0 gets its
input command for Load/Store and Enable/Disable from
the PSD5XX PIN or from the PPLD macrocell output.
At RESET this bit initializes as 0 which means that the
input command is coming from the PSD5XX PPLD
macrocell. When this bit is set to a
1: The Counter/Timer0 input command is coming from
the PIN.
0: The Counter/Timer0 input command is coming
from the PPLD macrocell output.
Software Gating Bit for
This bit gates the Load/Store command activated by the
Load/Store Commands (6): PSD5XX PIN or PPLD macrocell. At RESET this bit
initializes as 0 which means that the Load/Store command
activated by the PIN or macrocell is permitted through.
When this bit is set to
1: Load/Store operation activated by PIN or Macrocell is
NOT permitted through.
0: Load/Store operation activated by PIN or macrocell is
permitted through. To further decide between the PIN
and PPLD macrocell, use bit 5 (PIN/PPLD macrocell).
Enable/Disable Using PIN,
This bit determines whether the Enable/Disable
PPLD Macrocell or Software command is activated by the PSD5XX Pin, PPLD macrocell
Bit (7):
or by Software. At RESET this bit initializes as 0, which
means that the Enable/Disable command is activated by
the PIN or PPLD macrocell. When this bit is set to
1: Enable/Disable command by PIN or macrocell is
overridden by Software (only Bit 2 of this register will
enable or disable the counter).
0: Enable/Disable command is activated by PIN or
Macrocell output. To further decide between the PIN and
PPLD macrocell use bit 5 (PIN / PPLD macrocell bit).
85
PSD5XX Family
Figure 43. Enable/Disable and Load/Store Generation
Counter/Timer
Registers
(Cont.)
86
PSD5XX Family
9.6.2.3 Configuring the Mode of Operation of the Counter/Timers:
Counter/Timer
Using the GLOBAL MODE bit of the Global Command register and MODE SELECT bit of
the Command register of Counter/Timers 0–3, individual Counter/Timer modes of operation
can be set up. Refer to Table 24. Notice that all the Counter/Timers can either operate in
Waveform/Pulse or Event Count/Time Capture modes, but not in all four modes at the same
time.
Registers
(Cont.)
Table 24. Counter/Timer Modes
Mode Select Bit
(Command
Registers of
Counter/Timers
0 – 3 CMD0, CMD1,
CMD2 and CMD3)
Modes
of
Counter/Timers
0, 1 and 3
Global Mode Bit
(Global Command
Register)
Modes
of
Counter/Timer2
Waveform or
WatchDog
0
0
0
1
Waveform
Pulse
Pulse or
WatchDog
1
1
0
1
Event Counter
Time Capture
WatchDog Only
WatchDog Only
9.6.2.4 Freeze Command Register
When a Microcontroller needs to access the contents of the Image Registers (IMG0-IMG3)
it does so by first setting the Command Register Freeze bit in order to disable the timer
state-machine accesses of the Image Register. The Microcontroller waits for the Freeze
Acknowledge bit in the Counter/Timer Status Register to be set to 1 and then it accesses
the Image Register as an address location. The freeze acknowledge signal effectively guar-
antees stable Image Register data during Microcontroller read/write cycles even though the
Counter/Timer continues to count. The Freeze Acknowledge bit gets cleared after the
negation of Freeze. The Freeze Command bits are set and cleared by the microcontroller
software.
The Freeze Command Register and the software Load/Store Register should not be set at
the same time. It is recommended that the registers be accessed individually.
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
Freeze
CTU3
Freeze
CTU2
Freeze
CTU1
Freeze
CTU0
*
*
*
*
NOTE:
= Not used.
*
87
PSD5XX Family
Counter/Timer
Registers
(Cont.)
9.6.2.5 Software Load/Store Register:
Each bit in this register enables a load to the corresponding Counter/Timer from its
associated Image Register in Waveform, Pulse or WatchDog modes. The actual counts
are stored in their corresponding Image Register in event Counter or time capture modes.
Bit 6 of the Command Register must be set to “1” before writing to the software load/store
register.
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
Software
Software
Software
Software
*
*
*
*
Load/Store 3 Load/Store 2 Load/Store 1 Load/Store 0
NOTE:
= Not used.
*
Software Load/Store 0 Bit: If this bit is set to
1: Counter/Timer0 CNTR0 gets loaded from the Image
Register IMG0 or CNTR0 stores into IMG0 based on the
mode of operation**.
Software Load/Store 1 Bit: If this bit is set to
1: Counter/Timer1 CNTR1 gets loaded from the Image
Register IMG1 or CNTR1 stores into IMG1 based on the
mode of operation**.
Software Load/Store 2 Bit: If this bit is set to
1: Counter/Timer2 CNTR2 gets loaded from the Image
Register IMG2.
Software Load/Store 3 Bit: If this bit is set to
1: Counter/Timer3 CNTR3 gets loaded from the Image
Register IMG3 or CNTR3 stores into IMG3 based on the
mode of operation**.
Load operation takes place in Waveform, Pulse and WatchDog mode.
Store operation takes place in Event Count and Time Capture mode.
**
The Software load/store bits are automatically cleared by the served Counter.
In addition to four CTU registers, there are delay cycle and Counter/Timer status registers.
These are summarized on the following pages.
88
PSD5XX Family
Counter/Timer
Registers
(Cont.)
9.6.2.6 Status Flags Register
There are eight READ-ONLY status flags. The lower four bits represent Freeze
Acknowledge bits.
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
FrezAck3
FrezAck2
FrezAck1
FrezAck0
*
*
*
*
NOTES: At RESET all these bits intialize as 0's.
= Not used.
*
FrezAck Bits
These Freeze Acknowledge bits are useful in the Freeze/Freeze Acknowledge protocol.
After the Microcontroller senses that the FrezAck bit is being set it proceeds to access the
Image Register for a read or write operation.
FrezAck0 Bit: When this bit is
1:
0:
Image Register Access is granted.
Image Register Access is not granted.
FrezAck1 Bit: When this bit is
1:
0:
Image Register Access is granted.
Image Register Access is not granted.
FrezAck2 Bit: When this bit is
1:
0:
Image Register Access is granted.
Image Register Access is not granted.
FrezAck3 Bit: When this bit is
1:
0:
Image Register Access is granted.
Image Register Access is not granted.
DLCY Register:
Bits <4:0> of the DLCY register are used to assign Delay Cycles to the Counter/Timer.
Various Clock Scaling values possible are 0 through 31 (decimal).
At RESET these bits initialize as 0. If necessary, the user has the option to set these bits up
to generate Delay Cycles (DLCY) to scale down the Counter/Timer clock (see Table 24).
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
DLCY4
DLCY3
DLCY2
DLCY1
DLCY0
*
*
*
NOTE:
= Not used.
*
89
PSD5XX Family
9.6.2.7 Load/Store
Counter/Timer
(Cont.)
The Load operation transacts an Image Register (e.g. IMG0) write into its Counter/Timer
Register (e.g. CNTR0), whereas in the Store operation the Counter/Timer Register (e.g.
CNTR0) writes back into the Image Register (e.g. IMG0).
These signals are valid only when a Counter/timer is active. They are rising edge sensitive
and are used to Load a Counter with a required value or to Store the Counter value in the
associated Image Register.
In Waveform, Pulse and WatchDog modes the microcontroller writes into an Image
Register. The respective Counter/Timer uses that value as its initial counting value. The
data transfer operation from an Image Register into its corresponding counter is called
LOAD. In Event Counting and Time Capture modes the Counter/Timer counts event pulses
or timer clock cycles, respectively. An external event or a software command can cause a
data transfer from the counting element into its Image Register. This operation is defined as
STORE.
These operations are triggered by:
❏ Software command
❏ Terminal count (in Waveform mode only)
❏ PPLD macrocell output
❏ Input Pin
Refer to Counter/Timer Command Register and Figure 43 for specific details.
9.6.2.8 Enable/Disable
These signals are used to enable or disable the counting of the Counter/Timers. These
signals are controlled by:
❏ Software command (Bits 2 and 7 of the Command Registers).
❏ PPLD macrocell output
❏ Input Pin
Event Count Mode:
In Event Count mode the Enable/Disable signal is edge sensitive and is connected to the
event input signal through the PPLD or pin. In Time Capture mode the Enable/Disable
signal can be set by a software command only.
Refer to Counter/Timer Command Register and Figure 43 for specific details.
9.6.2.9 Counter/Timer Input/Output
Each Counter can use individual control inputs in port E as input Load/Store or
Enable/Disable signals, and Counter/Timer outputs in port A or port B by selecting alternate
and special functions on the pins assigned to them. The outputs are used in waveform and
pulse modes in which the Counters generate output waveforms or pulses. The inputs can
be used in all modes of operation except WatchDog to create the LOAD/STORE and/or
ENABLE/DISABLE control signals. Port E can be configured as outputs for Terminal Count.
Terminal Count is also available as ZPLD inputs (via pin feedback). Refer to Tables 25, 26
and 27 for further details and configuration of these ports.
9.6.2.10 PPLD Macrocell
The enable/disable or load/store inputs of each Counter/Timer can be selected through a
PPLD macrocell, whose inputs are two product terms PTT0 and PTT1 from the PPLD’s
AND-array. The polarity of the PPLD macrocell output is programmable. The output of the
PPLD macrocell which is the enable/disable and/or Load/Store input to the Counter/Timer
can be in a Combinatorial mode or Register mode. Figure 44 shows the details of the PPLD
macrocell. Refer to the “ZPLD” section for further information on the PPLD.
90
PSD5XX Family
Figure 44. PPLD Macrocell For Each Counter/Timer
Counter/Timer
(Cont.)
91
PSD5XX Family
9.6.2.11 I/O – Port A, B, E
Counter/Timer
(Cont.)
Ports A, B and E have the capabilities for counter/timer alternate and special functions,
e.g. Counter/Timer out, load/store, enable/disable, etc. Refer also to the chapter on I/O
ports for further details.
Special Function Assignment
Port A:
Timer outputs in Pulse or Waveform modes can be tapped out of these pins: PA0 – PA3.
In order for the following timer outputs to drive their corresponding port pins, set the
respective bits in the Special Function Register of Port A to ones.
Table 25.
Port Pin
Special Function Out
PA0
PA1
PA2
PA3
Timer0_out
Timer1_out
Timer2_out
Timer3_out
Port B:
Timer outputs in Pulse or Waveform modes can be tapped out of these pins: PB0 – PB3.
In order for the following timer outputs to drive their corresponding port pins, set the
respective bits in the Special Function Register of Port B to ones.
Table 26.
Port Pin
Special Function Out
PB0
PB1
PB2
PB3
Timer0_out
Timer1_out (in Pulse Mode Only)
Timer2_out
Timer3_out (in Pulse Mode Only)
The decision which of Port A or B pins are used as timer outputs is done by the
PSDsoft fitter.
92
PSD5XX Family
I/O – Port A, B, E (Cont.)
Port E:
Counter/Timer
(Cont.)
Timer[3:0]_inputs can have different control functions such as timer LOAD/STORE and/or
ENABLE/DISABLE, based on how these pins are configured in the Timer Command
Registers.
Table 27.
Port Pin
PE3
Alternate Function In
Timer0_in
PE4
Timer1_in
PE5
Timer2_in
PE6
Timer3_in
The Terminal Counts (TC0 – TC3) generated by each Counter/Timer are available at Port E
(pins PE4 – PE7) as shown in Table 27a.
Table 27a.
Port Pin
PE4
Special Function Out
TC0
TC1
TC2
TC3
PE5
PE6
PE7
To Connect TC0 – TC3 to Port E pins, set the corresponding bits in the Special Function
Register to “1”.
93
PSD5XX Family
9.6.2.12 Sample Counter/Timer0 Initialization In PULSE Mode
Counter/Timer
(Cont.)
Following is a sample initialization routine for Counter/Timer0 to operate in PULSE mode.
The assembly language commands do not correspond to any particular microcontroller.
Configure CSIOP for Microcontroller access to Counter/Timer registers and I/O ports for
initialization of Counter/Timers. For the values of each register, refer to Tables 30 and 31.
Use PSDsoft supplied by WSI to configure the portion related to Counter/Timers. Also refer
to the Section on the PSD5XX I/O Ports.
Clear All Counter/Timers
LOAD CNTR0, 0000h
LOAD CNTR1, 0000h
LOAD CNTR2, 0000h
LOAD CNTR3, 0000h
; Clear Counter/Timer 0
; Clear Counter/Timer 1
; Clear Counter/Timer 2
; Clear Counter/Timer 3
Scaling of Clock (common to all Counter/Timers)
LOAD DLCY, 02h
;Delay Cycles(DLCY) = 2, k value is selected in
;Global Register by setting Scale-Bit
Counter/Timer 0 Initialization (Command Register0 CMD0)
LOAD CMD0, 6Fh
;Pulse mode (D0 = 1)
;Increment (D1 = 1)
;Select Counter/Timer (D2 = 1)
;Output Pulse Active High (D3 = 1)
;Load Signal on Input pin High going transition (D4 = 0)
;Input control from PIN (not PPLD macrocell) (D5 = 1)
;Load&Store control activated by Pin (D6 = 0)
;Enable count (D7 = 1)
LOAD IMG0,FFF7h
;Load Counter/Timer0 Image Register with count (pulse width)
;needed (pulse duration of 8 timer clock cycles)
LOAD Special Reg A,1 ;Configure PA0 as A timer = 0 output by writing a “1” to Port A
;Special Function Register
Global Register Configuration
LOAD Global, 03h
;Non WatchDog mode
;Pulse mode
;All CTUs enabled
;Scale-Bit = 1
;Input clock is divided by 6
Now if Pin PE3 on port E is input with a high going signal:
❏ This signal causes Counter/Timer0 to get a value (FFF7h) loaded from its
associated image register (IMG0) and causes the Counter/Timer0 to start counting
from FFF7h (increment) until it overflows and issues a Terminal Count0 (TC0).
❏ During counting Port A pin (PA0) outputs a high going one-shot pulse with a width
equal to (Max count possible – initial count value loaded, i.e. 8 timer clock cycles
in this example).
❏ If the interrupt controller is configured to receive TC0, it will cause the interrupt
INT0 to occur.
94
PSD5XX Family
General Description
9.7
The PSD5XX includes logic for sensing, masking, priority decoding and identifying up to
eight internal interrupts. The PSD5XX interrupt controller can generate interrupts from two
dedicated PPLD product terms, two PPLD Macrocell outputs and four terminal-count
outputs of the Counter/Timer unit.
Interrupt
Controller
The four interrupts generated by the PPLD can be user defined using the WSI PSDsoft
Windows compatible PC based software. Figure 45 details the basic building blocks
of the PSD5XX Interrupt Controller and Figure 46 shows its interface with other sections of
the PSD5XX.
Features
The PSD5XX interrupt controller has the following features:
❏ Can accept eight interrupt inputs
❏ PPLD product terms, PPLD Macrocell outputs and Terminal Counts (TCs) of
Counter/Timers can cause interrupts.
❏ Interrupts generated from the PPLD canbe user defined.
❏ All interrupt inputs are priority decoded, IR7 has highest priority and IR0 the
lowest priority.
❏ Each interrupt can be configured as either EDGE or LEVEL sensitive using the
EDGE/LEVEL register.
❏ Each interrupt can be individually masked using a mask register.
❏ At RESET all interrupts are MASKED.
❏ Interrupt Request Latch provides the status of all interrupts.
❏ Reading an Interrupt vector location clears the corresponding pending interrupt.
❏ Any of these interrupts trigger a GLOBAL interrupt output available as an output at port
E (PE2) and/or as an input to the PPLD.
9.7.1 Interrupt Operation
On RESET all Registers and Latches are cleared and all interrupts are masked. During
initialization of the interrupt controller, relevant interrupts are un-masked and defined
whether EDGE or LEVEL sensitive. When one or more interrupts are raised high,
the “interrupt request latch” latches in all the non-masked interrupts. A 3-bit priority encoder
assigns the priority to the non-masked pending interrupts. The MCU (microcontroller)
can clear the Edge-sensitive pending interrupts by reading the “Interrupt Read Clear
Register”. Level-sensitive interrupts continue to be pending even after the MCU reads the
“Interrupt Read Clear Register”. The MCU would typically service each interrupt in
sequence according to priority. Refer to Table 28 regarding priorities of various interrupts.
Any of these interrupts trigger a GLOBAL interrupt output available as an input to the PPLD
(INTR2PLD) and as output at port E (PE2). Refer to Figures 45 and 46 for details of the
interrupt architecture.
Table 28. Interrupt Priority Table
Interrupt
Priority
IR 7
IR 6
IR 5
IR 4
IR 3
IR 2
IR 1
IR 0
HIGHEST
^
^
^
^
^
^
LOWEST
95
PSD5XX Family
Figure 45. Interrupt Controller Block Diagram
Interrupt
Controller
(Cont.)
96
PSD5XX Family
Figure 46. Interrupt Controller Interface With Other Internal Blocks
Interrupt
Controller
(Cont.)
97
PSD5XX Family
Interrupt
Controller
(Cont.)
Interrupt Operation (Cont.)
9.7.1.1 Command Registers
All the eight interrupts can be individually masked using a mask register. Writing “ones”
into these mask bits enables the associated interrupts. RESET masks all interrupts.
Interrupts can also be defined as either LEVEL sensitive or EDGE sensitive using a
sensitivity bit in the interrupt edge/level sensitivity select register.
Tables 29 and 29a give the address map for various port and interrupt Command/Status
Registers. This address offset map is of the host processor, relative to the CSIOP
(Chip Select Input Output Port) i.e., address space allocated by the host Microcontroller to
access all the PSD embedded peripherals.
Table 29. Offset Address Map of Interrupt Registers
Address
Offset
Register Name
Address
Offset
Register Name
+D4h
+D2h
+D0h
Interrupt Read Clear
Interrupt Edge/Level
Select
+D3h
+D1h
Interrupt Mask
Interrupt Request Latch
Interrupt Priority Status
Table 29a. Offset Address Map of Interrupt Registers
(For 16-Bit Motorola MCUs in 16-Bit Mode. If 8-Bit Mode is selected, use Table 29.)
Address
Offset
Register Name
Address
Offset
Register Name
+D5h
+D3h
+D1h
Interrupt Read Clear
Interrupt Edge/Level
Select
+D2h
+D0h
Interrupt Mask
Interrupt Request Latch
Interrupt Priority Status
The Interrupt Registers listed in Tables 29 and 29a are described below.
Interrupt Mask Register
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
Mask7
Mask6
Mask5
Mask4
Mask3
Mask2
Mask1
Mask0
Bits mask 0 ... mask 7 correspond to interrupt 0 ... interrupt 7.
When these bits are set to
1 = Unmasked
0 = Masked
At RESET these bits initialize as 0 and all interrupts are masked.
98
PSD5XX Family
Interrupt Operation (cont.)
Interrupt
Controller
(Cont.)
Interrupt Edge/Level Select Register
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
Sense7
Sense6
Sense5
Sense4
Sense3
Sense2
Sense1 Sense0
Bits sense 0 ... sense 7 correspond to interrupt 0 ... interrupt 7.
When these bits are set to
1 = LEVEL sensitive
0 = EDGE sensitive (positive edge)
At RESET these bits initialize as 0 i.e., all interrupts come up as Edge sensitive.
Interrupt Read Clear Register
This is a read only register. Reading this register during initialization clears all the pending
edge sensitive interrupts.
Interrupt Request Latch Register
Bit 7
ir 7
Bit 6
ir 6
Bit 5
ir 5
Bit 4
ir 4
Bit 3
ir 3
Bit 2
ir 2
Bit 1
ir 1
Bit 0
ir 0
Bits ir 0...ir 7 correspond to interrupt 0 ... interrupt 7.
When any of these bits are set by the interrupt controller to a “1”, the corresponding
Interrupt is pending service.
The MCU can read the interrupt request latch which shows the status of all interrupts. The
entire interrupt request latch can be cleared by reading the Interrupt Read Clear Register,
but Level sensitive interrupts cannot be cleared.
Interrupt Priority Status Register
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
vect 2
vect 1
vect 0
*
*
*
*
*
NOTE:
= Reserved for future use, bits set to zero.
*
The value of these 3 bits (vect2, vect1 and vect0) indicates the highest priority of the
interrupt to be serviced among multiple interrupts pending. Refer to the table above for
priorities of various interrupts. Reading this register clears the highest pending interrupt.
99
PSD5XX Family
Interrupt
Controller
(Cont.)
Interrupt Operation (Cont.)
9.7.2 Input/Output
Interrupt inputs INT4 and INT5 originate from two dedicated PPLD product terms PT2INT4
and PT2INT5. Interrupt inputs INT6 and INT7 originate from the outputs of the PPLD
Macrocells MC2INT6 and MC2INT7 as described in the next section and the remaining
interrupt inputs INT0 through INT3 originate from four Terminal-Count (TC) outputs of the
Counter/Timers. If an External event has to cause an interrupt in the PSD5XX, it has to be
routed through the PPLD.
Regarding output from the Interrupt Controller, whenever an unmasked interrupt occurs, a
Global Interrupt signal is generated. The Global Interrupt signal can be used as a ZPLD
input (INTR2PLD). Refer to Figure 45 for details. It can also be driven off the chip by using
the special-function out capability of Port E (PE2) as INTR_OUT. In either case, the Global
Interrupt indicates to the MCU that an internal PSD5XX interrupt has occurred. Refer to the
section on I/O ports for specific details of setting up the port functions.
9.7.3 PPLD Macrocell
Interrupt inputs INT6 and INT7 originate two dedicated PPLD Macrocells. Each of these
PPLD Macrocells have two product terms as inputs that are inputted into a PPLD Macrocell
as shown in Figure 47. The outputs of both PPLD Macrocells MC2INT6 and MC2INT7 are
either Combinatorial or Register mode. The polarity of the product terms is programmable.
Refer to the section on “ZPLD” for further reference on the PPLD.
9.7.4 Interrupt Flowchart
The flowchart in Figure 48 explains the overall initialization and the servicing
of the interrupts.
100
PSD5XX Family
Figure 47. PPLD Interrupt Macrocell
Interrupt
Controller
(Cont.)
101
PSD5XX Family
Figure 48. Interrupt Flowchart
Interrupt
Controller
(Cont.)
CONTINUE
EXECUTING
MAIN LOOP
UNTIL INTERRUPT
OCCURS
INTERRUPT
INITIALIZATION
NO
INTERRUPT
OCCURRED ?
YES
CLEAR ALL
PENDING BITS
(READ CLEAR
REGISTER
DETERMINE
PRIORITY
OF THE
INTERRUPT
DEFINE EDGE
OR LEVEL
SENSITIVE
KEEP LOW
PRIORITY
INTERRUPTS
PENDING
SERVICE
HIGH PRIORITY
INTERRUPT
CONFIGURE
INTERRUPT
SOURCE PLD
AND / OR
TIMER COUNT
i.e. UNMASK
REQD INTRPT
ARE
ALL
INTERRUPTS
SERVICED ?
NO
YES
102
PSD5XX Family
The Page Register is 4 bits wide and consists of four D flip flops.The outputs of the Register
(PGR0 – PGR3) are connected to the input bus of the ZPLD. By including the four outputs
as inputs to the DPLD, the addressing capability of the microcontroller is increased by a
factor of 16.
10.0
Page
Register
Figure 49 shows the Page Register block diagram. Inputs to the four flip flops are connected
to data bus D0-D3. The output of the Register can be read by the microcontroller. The
Register can operate as an independent register to the microcontroller if page mode is not
implemented.
Figure 49. Page Register
RESET
ES0 – 3
DPLD
RS0
PGR0
D0
D1
D2
D3
Q0
Q1
Q2
Q3
PGR1
PGR2
PGR3
GPLD
D0 – D3
R/W
PPLD
ZPLD
PAGE
REGISTER
The PSD5XX has a programmable security bit which offers protection from unauthorized
duplication. When the security bit is set, the contents of the EPROM, the PSD5XX
non-volatile configuration bits and ZPLD data are prevented from being read by EPROM
programmers.
11.0
Security
Protection
The security bit is set through the PSDsoft Software and is embedded in the compiled
output file. The security bit is UV erasable and a secured part can be erased and then
re-programmed.
103
PSD5XX Family
The CSIOP signal, which is generated by the DPLD, selects the internal I/O devices or
registers. The CSIOP signal takes up 256 bytes of address space and is defined by the user
in the PSDSoft Software. The following is an address offset map for the various devices
relative to the CSIOP base address.
12.0
System
Configuration
Some Motorola 16-bit microcontrollers have a different data bus/data byte orientation. This
requires a different address offset for the internal PSD5XX I/O devices or registers. Tables
30a and 31a in this section are for this group of microcontrollers which include the
M68HC16, M68302 and M683XX.
The following table is the address map offset of the I/O port registers.
Table 30. I/O Register Address Offset
Address Offset
Register Name
Data In
Port A
00
Port B
01
Port C
10
Port D
11
Port E
20
Control
02
03
12
13
22
Data Out
04
05
14
15
24
Direction
06
07
16
17
26
Open Drain
Special Function
PLD – I/O
18
19
08
0A
0C
09
0B
0D
28
2A
2C
Macrocell Out
Table 30a. I/O Register Address Offset
(For 16-Bit Motorola MCUs in 16-Bit Mode. If 8-Bit Mode is selected, use Table 30.)
Address Offset
Register Name
Data In
Port A
01
Port B
00
Port C
11
Port D
10
Port E
21
Control
03
02
13
12
23
Data Out
05
04
15
14
25
Direction
07
06
17
16
27
Open Drain
Special Function
PLD – I/O
19
18
09
0B
0D
08
0A
0C
29
2B
2D
Macrocell Out
104
PSD5XX Family
Table 31. Other Register Address Offset
System
Configuration
(Cont.)
Address
Offset
Address
Offset
Register Name
Register Name
PAGE REGISTER
INTR. READ CLEAR
INTR. EDGE/LEVEL
E0
D4
D2
INTR. MASK
D3
D1
INTR. REQUEST
LATCH
INTR. PRIORITY
STATUS
D0
VM
C0
B0
A8
A6
PMMR1
B1
A9
PMMR0
STATUS FLAGS
GLOBAL COMMAND
DLCY
SOFTWARE
LOAD/STORE
A5
FREEZE COMMAND
A4
CMD3
CMD1
CNTR3
CNTR2
CNTR1
CNTR0
IMG3
A3
A1
9F
9D
9B
99
97
95
93
91
CMD2
CMD0
CNTR3
CNTR2
CNTR1
CNTR0
IMG3
A2
A0
9E
9C
9A
98
96
94
92
90
IMG2
IMG2
IMG1
IMG1
IMG0
IMG0
105
PSD5XX Family
Table 31a. Other Register Address Offset
System
Configuration
(Cont.)
(For 16-Bit Motorola MCUs in 16-Bit Mode. If 8-Bit Mode is selected, use Table 31.)
Address
Offset
Address
Register Name
Register Name
Offset
PAGE REGISTER
INTR. READ CLEAR
INTR. EDGE/LEVEL
E1
D5
D3
INTR. MASK
D2
D0
INTR. REQUEST
LATCH
INTR. PRIORITY
STATUS
D1
VM
C1
B1
A9
A7
PMMR1
B0
A8
PMMR0
STATUS FLAGS
GLOBAL COMMAND
DLCY
SOFTWARE
LOAD/STORE
A4
FREEZE COMMAND
A5
CMD3
CMD1
CNTR3
CNTR2
CNTR1
CNTR0
IMG3
A2
A0
9E
9C
9A
98
96
94
92
90
CMD2
CMD0
CNTR3
CNTR2
CNTR1
CNTR0
IMG3
A3
A1
9F
9D
9B
99
97
95
93
91
IMG2
IMG2
IMG1
IMG1
IMG0
IMG0
Table 32. I/O Register Function
Register Name
Register Function
Data In
Control
This Register is used to read the input on the port pins.
A “0” sets the corresponding port pin in Address Out Mode.
A “1” sets the pin in MCU I/O Mode.
Data Out
Direction
Holds the output data in the MCU I/O Mode.
This register is used to control the data flow in the I/O ports.
A “0” sets the corresponding pin as an input pin.
A “1” sets the pin as an output pin.
Open Drain
A “0” sets the corresponding pin driver as a CMOS driver.
A “1” sets the pin driver as an Open Drain Driver.
Special Function
PLD – I/O
A “1” sets the corresponding port pin as Timer or Interrupt Output.
A read only status register; a “1” indicates the corresponding pin
is configured as a PLD pin.
Macrocell Out
This register holds the outputs of the GPLD macrocells.
106
PSD5XX Family
Table 33. Other Register Function
Register Name
System
Configuration
(Cont.)
Register Function
PAGE REGISTER
A 4-bit register that supports paging.
INTR. READ
CLEAR
Reading this register clears all the pending edge sensitive
interrupts.
INTR.
Define interrupt input as level or edge sensitive.
EDGE/LEVEL
INTR. MASK
Mask selected interrupt input.
INTR.
A “1” in the register indicates the corresponding interrupt is
REQUEST LATCH
pending.
INTR.
PRIORITY STATUS
The register indicates which pending interrupt has the highest
priority.
1. Configures the PSD SRAM to be accessed by “PSEN” as
VM
program space (8031 design).
2. Enable the Peripheral I/O Mode of Port A.
PMMR0
PMMR1
Power management registers; enable the PSD Power Down Mode
and other power saving configurations.
STATUS FLAGS
Counter/Timer Freeze Acknowledge bits.
GLOBAL
COMMAND
Specifies the Counter/Timer operation mode; and to start or stop
the Counter/Timers.
DLCY
Specifies the delay cycles to the Counter/Timers.
SOFTWARE
LOAD/STORE
This register enables a load (to the Counter/Timer) or store
(in the Image Register) operation.
FREEZE
COMMAND
This register disables the timer state-machine before access to the
Image Register is allowed.
CMD3 – 0
CNTR3 – 0
IMG3 – 0
Command Registers for the configuration of the Counter/Timers.
The four 16-bit Counter/Timers.
The Image Registers for CNTR3 – 0.
107
PSD5XX Family
12.1 Reset Input
System
The reset input to the PSD5XX (RESET) is an active low signal which resets some of
the internal devices and configuration registers. The Timing Diagram in the AC/DC
characterization section shows the reset signal timing requirement. The active low range has
a minimum T1 duration. After the rising edge of RESET, the PSD5XX remains in
reset during T2 range. (See Figure 59). The PSD5XX must be reset at power up before it
can be used.
Configuration
(Cont.)
12.2 ZPLD and Memory During Reset
While the Reset Input is active, the ZPLD generates outputs as defined in the PSDabel
equations. The EPROM and SRAM blocks respond to the microcontroller bus cycle during
reset, but the data is not guaranteed.
12.3 Register Values During and After Reset
Table 34 summarizes the status of the volatile register values during and after reset. The
default values of the volatile registers are “0” after reset.
12.4 ZPLD Macrocell Initialization
The D flip flops in the macrocells in the GPLD can be cleared by:
❏ A product term (.RE) defined by the user, in PSDabel or
❏ The MACRO-RST (Reset) input, enabled and defined in PSDabel.
The Timer and Interrupt Controller macrocells in the PPLD are always cleared by the
Reset input.
Table 34. Registers Reset Values
Register Name
Device
Reset State
Set to “0” (Address Out Mode)
Set to “0”
Control
Port A, B, C, D, E
Data Out (data or address) Port A, B, C, D, E
Direction
Port A, B, C, D, E
Port C, D
Set to “0” – Input Mode
Set to “0” – CMOS Outputs
Set to “0”
Open Drain
Page Register
PMMR0, PMMR1
VM
Page Logic
Power Management Unit
Volatile Memory
Timer
Set to “0”
Set to “0”
DLCY
Set to “0”
CMD0 – CMD3
Status Flags
Global Command
Timer
Set to “0”, Clear
Set to “0”, Clear
Set to “0”, Clear
Timer
Timer
IMG0 – IMG3,
CNTR0 – CNTR3
Timer
Undefined
Interrupt
Interrupt Controller
Set to “0”, Disabled
Table 35. I/O Pin Status During Reset and Standby Mode
Port Configuration
Port I/O
Reset
Standby Mode
Input
Unchanged
ZPLD Output
Address Out
Data Port
Active
Depend on Inputs to the ZPLD
Not Defined
Tri-stated
Tri-stated
Tri-stated
Depending on Status of
Clock Input to the Counter/Timer
Special Function Out
Peripheral I/O
Tri-stated
Tri-stated
Tri-state
108
PSD5XX Family
13.1 Absolute Maximum Ratings
13.0
Specifications
Symbol
Parameter
Condition
CLDCC
Min
– 65
– 65
0
Max
Unit
°C
°C
°C
°C
°C
V
+ 150
+ 125
+ 70
+ 85
+ 125
+ 7
TSTG
Storage Temperature
PLDCC
Commercial
Operating Temperature Industrial
Military
– 40
– 55
– 0.6
Voltage on any Pin
With Respect to GND
Programming
Supply Voltage
VPP
VCC
With Respect to GND
With Respect to GND
– 0.6
+ 14
+ 7
V
Supply Voltage
ESD Protection
– 0.6
V
V
>2000
NOTE: 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.
13.2 Operating Range
Speed Grades Available
-70 -90 -15 -20 -25
Type
Temperature
0° C to +70°C
–40° C to +85°C
V
V Tolerance
CC
CC
+ 5 V
+ 3 V
+ 5 V
+ 3 V
± 10%
± 10%
± 10%
± 10%
X
X
Commercial
Industrial
X
X
X
X
13.3 Recommended Operating Conditions
Symbol
Parameter
Condition
Min
Typ Max
Unit
VCC
Supply Voltage
All Speeds
4.5
5.0
3.0
5.5
5.5
V
V
ZPSD5XXV Versions
Only, All Speeds
VCC
Supply Voltage
2.7
109
PSD5XX Family
Specifications
(cont.)
13.4 AC/DC Parameters
The following tables describe the AC/DC parameters of the PSD5XX family:
❏ DC Electrical Specification
❏ AC Timing Specification
• ZPLD Timing
– Combinatorial Delays
– Synchronous Clock Mode
– Asynchronous Clock Mode
• Microcontroller Timing
– Read Timing
– Write Timing
– Peripheral Mode Timing
– Power Down and Reset Timing
• PSD5XX Specific Timings
– Counter/Timer Timing
– Interrupt Controller Timing
Following are some issues concerning the parameters presented:
❏ In the DC specification, the Supply Current is given for different modes of operation.
Before calculating the total power consumption, determine the percentage of time that
the PSD5XX is in each mode. Also the current is considerably different if the
ZPLD_TURBO bit is "OFF" and EPROM_CMISER is "ON".
❏ The AC power component provides the ZPLD, EPROM, SRAM and TIMER mA/MHz
specification. Figure 50 shows the ZPLD mA/MHz as a function of the number
of Product Terms (PT) used.
❏ In the ZPLD timing parameters add the required delay when ZPLD_TURBO is "OFF".
❏ In the MCU timing specification, add the required time delay when EPROM_CMISER
is "ON".
Figure 50. ZPLD Typical ICC/Frequency Consumption (5 V)
PT100%
PT25%
120
100
80
60
40
20
0
0
5
10
15
20
25
COMPOSITE FREQUENCY AT PLD INPUTS (MHz)
110
PSD5XX Family
Figure 51. ZPLD Typical ICC/Frequency Consumption (ZPSD5XXV Devices) (3 V)
Specifications
(cont.)
PT100%
PT25%
50
40
30
20
10
0
0
5
10
15
20
25
COMPOSITE FREQUENCY AT PLD INPUTS (MHz)
13.5 Example of PSD5XX Typical Power Calculation at V = 5.0 V
CC
Conditions
Composite PLD input frequency (Freq PLD) = 8 MHz
MCU ALE frequency (Freq ALE)
% EPROM Access
% SRAM access
% I/O access
= 4 MHz
= 80%
= 15%
= 5% (no additional power above base)
Operational Modes
% Normal
= 10%
= 90%
% Sleep
Number of product terms used
(from fitter report)
% of total product terms
Turbo = off
= 45 PT
= 29/118 = 24.6%
CMiser = on
8-bit bus mode
Calculation (typical numbers used)
ICC total = Isleep x %sleep + %normal x (ICC (ac) + ICC (dc))
= Isleep x %sleep + % normal x (%EPROM x 0.8 mA/MHz x Freq ALE
+ %SRAM x 1.4 mA/MHz x Freq ALE
+ %PLD x (from graph using Freq PLD))
= 10 µA x 0.90 + 0.1 x (0.8 x 0.8 mA/MHz x 4 MHz
+ 0.15 x 1.4 mA/MHz x 4 MHz + 0.95 x 23
= 0.9 µA + 0.1 x (2.56 + 0.84 + 21.85)
= 0.9 µA + 0.1 x 25.3
= 0.9 µA + 2.53 mA
= 2.53 mA
Standby current consumption is handled similarly to sleep mode shown above.
Calculation based on IOUT = 0 mA.
111
PSD5XX Family
13.6 DC Characteristics (5 V ± 10% Versions)
Symbol
Parameter
Conditions
Min
Typ
Max
Unit
VCC
VIH
Supply Voltage
All Speeds
4.5
2
5
5.5
VCC + 0.5
0.8
V
V
V
V
V
V
V
High Level Input Voltage
Low Level Input Voltage
Reset High Level Input Voltage
Reset Low Level Input Voltage
Reset Pin Hysteresis
4.5 V < VCC < 5.5 V
4.5 V < VCC < 5.5 V
(Note 1)
VIL
–0.5
0.8 VCC
–0.5
0.3
VIH1
VIL1
VHYS
VCC + 0.5
0.2 VCC –0.1
(Note 1)
IOL = 20 µA, VCC = 4.5 V
0.01
0.1
VOL
Output Low Voltage
Output High Voltage
IOL = 8 mA, VCC = 4.5 V
IOH = –20 µA, VCC = 4.5 V
0.15
4.49
0.45
V
V
4.4
VOH
IOH = –2 mA, VCC = 4.5 V
2.4
2.7
3.9
V
V
VSBY
ISBY
IIDLE
VDF
SRAM Standby Voltage
SRAM Standby Current
Idle Current (VSTDBY Pin)
SRAM Data Retention Voltage
VCC
1
VCC = 0 V
0.5
µA
µA
V
VCC > VSBY
–0.1
2
0.1
Only on VSTBY
CSI >VCC –0.3 V (Note 2)
Power Down Mode
50
20
25
100
40
µA
Standby Supply
Current
ISB1
(PSD5XX)
Sleep Mode
CSI >VCC –0.3 V (Note 3)
CSI >VCC –0.3 V (Note 2)
µA
µA
Power Down Mode
Sleep Mode
50
Standby Supply
Current
ISB2
(ZPSD5XX)
CSI >VCC –0.3 V (Note 3)
VSS < VIN < VCC
10
±0.1
± 5
20
1
µA
µA
µA
ILI
Input Leakage Current
–1
ILO
Output Leakage Current
0.45 < VIN < VCC
–10
10
ZPLD_TURBO = OFF,
f = 0 MHz (Note 4)
See ISB1
and ISB2
µA
ZPLD Adder
ZPLD_TURBO = ON,
f = 0 MHz
ICC (DC)
(Note 4a)
Operating
Supply Current
400
700
µA/PT
EPROM Adder
SRAM Adder
f = 0 MHz
f = 0 MHz
0
0
mA
mA
See
Fig. 50
ZPLD AC Adder
Note 4
4.0
mA/MHz
CMiser = ON and
(8-bit bus mode)
0.8
1.8
1.4
2
4
mA/MHz
mA/MHz
mA/MHz
EPROM AC Adder
All other cases
ICC (AC)
(Note 4a)
CMiser = ON and
(8-bit bus mode)
2.7
SRAM AC Adder
CMiser = ON and
(16-bit bus mode)
2
4
mA/MHz
mA/MHz
CMiser = OFF
3.8
7.5
NOTES: 1. Reset input has hysteresis. VIL1 is valid at or below 0.2VCC –0.1. VIH1 is valid at or above 0.8VCC
2. CSI is high or internal Power Down mode is active.
.
3. Sleep mode bit is set and internal Power Down is active.
4. See ZPLD ICC/Frequency Power Consumption graph for details.
4a. IOUT = 0 mA.
112
PSD5XX Family
13.7 AC/DC Parameters – ZPLD Timing Parameters (5 V ± 10% Versions)
Combinatorial Delays (5 V ± 10% Versions)
-70
-90**
-15
ZPLD_TURBO
Symbol
Parameter
Conditions
Min Max Min Max Min Max
OFF*
Unit
I/O Input or Feedback to
Combinatorial Output
tPD
Port B, E
25
27
30
32
34
36
Add 10
ns
Registered Input to
Combinatorial Output
tRPD
(Note 1)
Add 10
ns
tEA
tER
Input to Output Enable
Input to Output Disable
Any Input
Any Input
25
25
28
28
32
32
Add 10
Add 10
ns
ns
Register Clear or Preset
Delay
tARP
Any Input
Any Input
27
30
34
Add 10
ns
Register Clear or Preset
Pulse Width
tARPW
tARD
20
25
29
ns
ns
Array Delay
16
18
22
NOTE: 1. Ports A, C, D and latched address from ADIO (A0, A1, A8-A15).
**If ZPLD_TURBO is off and the ZPLD is operating above 15 MHz, there is no need to add 10 ns to the timing parameters.
**The -90 speed is available only on Industrial Temperature Range product.
Synchronous Clock Mode (5 V ± 10%)
-70
-90**
-15
ZPLD_TURBO
OFF*
Symbol
Parameter
Conditions
Min Max Min Max Min Max
Unit
Maximum Frequency
External Feedback
1/(tS + tCO
)
30.30
43.48
50.00
27.03
37.04
41.67
25.00
31.25
35.71
MHz
Maximum Frequency
Internal Feedback (fCNT)
1/(tS+tCO–10)
MHz
MHz
fMAX
Maximum Frequency
Pipelined Data
1/(tCH + tCL
)
tS
Input Setup Time
Input Hold Time
Any Input
15
0
17
0
20
0
Add 10
ns
ns
ns
ns
ns
tH
Any Input
0
0
0
0
tCH
tCL
tCO
tARD
Clock High Time
Clock Low Time
Clock to Output Delay
Clock Input
Clock Input
Clock Input
10
10
12
12
15
15
18
16
20
18
22
22
Array Delay for Product
Term Expansion
Any Macrocell
tCH + tCL
0
0
ns
ns
tMIN
Minimum Clock Period
20
24
29
**If ZPLD_TURBO is off and the ZPLD is operating above 15 MHz, there is no need to add 10 ns to the timing parameters.
**The -90 speed is available only on Industrial Temperature Range product.
113
PSD5XX Family
AC/DC Parameters – ZPLD Timing Parameters (5 V ± 10% Versions)
Asynchronous Clock Mode (5 V ± 10% , Note 1)
-70
-90**
-15
ZPLD_TURBO
OFF*
Symbol
Parameter
Conditions
Min Max Min Max Min Max
Unit
Maximum Frequency
External Feedback
1/(tSA + tCOA
)
26.32
35.71
41.67
25.00
33.33
41.67
21.74
27.78
35.71
MHz
Maximum Frequency
Internal Feedback
1/(tSA+tCOA–10)
(Note 1)
fMAXA
MHz
MHz
(fCNTA
)
Maximum Frequency
Pipelined Data
1/(tCH + tCL
)
tSA
Input Setup Time
Input Hold Time
Clock High Time
Clock Low Time
Any Input
Any Input
Any Input
Any Input
8
8
8
8
12
12
15
15
Add 10
ns
ns
ns
ns
tHA
0
0
0
tCHA
tCLA
tCOA
12
12
12
12
Clock to Output
Delay
Any Input
to Port B
30
16
32
18
37
22
Add 10
ns
ns
ns
tARD
Array Delay for
Product Term
Expansion
Any Macrocell
1/fCNT
0
0
tMINA
Minimum Clock
Period
28
30
43
NOTE: 1. Only Port B has asynchronous outputs. Clock into Macrocell Flip Flop is generated by a product term.
**If ZPLD_TURBO is off and the ZPLD is operating above 15 MHz, there is no need to add 10 ns to the timing parameters.
**The -90 speed is available only on Industrial Temperature Range product.
114
PSD5XX Family
13.8 Microcontroller Interface – AC/DC Parameters (5 V ± 10% Versions)
Explanation of AC Symbols for Non ZPLD Timing.
Example:
tAVLX Time from Address Valid to ALE Invalid.
A – Address
C – Power Down
D– Input Data
E – E
H – Logic Level High
I – Interrupt
L – Logic Level Low or ALE
N – Reset
P – Port Signal
Q – Output Data
R – WR, UDS, LDS, DS, IORD, PSEN
S – Chip Select
T – R/W
t – Time
V – Valid
X – No Longer a Valid Logic Level
Z – Float
Read Timing (5 V ± 10% Versions)
-70
-90*
-15
EPROM_CMiser
ON
Symbol
Parameter
Conditions Min Max Min Max Min Max
Unit
tLVLX
tAVLX
tLXAX
tAVQV
ALE or AS Pulse Width
Address Setup Time
Address Hold Time
18
5
20
6
28
10
11
0
0
0
ns
ns
ns
(Note 4)
(Note 4)
7
8
Address Valid to Data
Valid
(Note 4)
70
80
20
90
100
32
150
150
40
Add 10
Add 10
0
ns
ns
ns
tSLQV
CS Valid to Data Valid
RD to Data Valid
8/16-Bit Bus
(Note 1)
RD to Data Valid 8-Bit
Bus, 8031 Separate
Mode
tRLQV
(Note 2)
(Note 3)
32
32
38
38
45
45
0
0
ns
ns
RD to Data Valid from
Interrupt Controller
tRHQX
tRLRH
tRHQZ
tEHEL
tTHEH
RD Data Hold Time
RD Pulse Width
RD to Data High-Z
E Pulse Width
(Note 1)
(Note 1)
(Note 1)
0
0
0
0
0
0
0
ns
ns
ns
ns
30
32
38
22
25
33
30
8
32
10
38
18
R/W Setup Time
to Enable
0
0
0
0
ns
ns
ns
ns
tELTL
R/W Hold Time After
Enable
0
0
0
In 16-Bit Data Bus
Mode (Note 5)
20
22
30
32
38
48
tAVPV
Address Input Valid to
Address Output Delay
In 8-Bit Data Bus
Mode (Note 5)
NOTES: 1. RD timing has the same timing as PSEN, DS, LDS, UDS signals.
2. RD and PSEN have the same timing for 8031 mode.
3. Read to Data Valid of the Interrupt Request Latch and Interrupt Priority Status. RD timing has the same timing as PSEN, DS,
LDS, UDS signals.
4. Any input used to select an internal PSD5XX function.
5. In multiplexed mode latched address generated from ADIO delay to address output on any Port.
*The -90 speed is available only on Industrial Temperature Range product.
115
PSD5XX Family
Microcontroller Interface – AC/DC Parameters (5 V ± 10% Versions)
Write Timing (5 V ± 10%)
-70
-90*
-15
EPROM_CMiser
ON
Symbol
tLVLX
Parameter
ALE or AS Pulse Width
Address Setup Time
Address Hold Time
Conditions Min Max Min Max Min Max
Unit
ns
18
5
20
6
28
10
11
tAVLX
(Note 1)
(Note 1)
ns
tLXAX
7
8
ns
Address Valid to
Leading Edge of WR
tAVWL
tSLWL
(Notes 1 and 3)
(Note 3)
18
22
20
25
30
35
ns
ns
CS Valid to Leading
Edge of WR
tDVWH
tWHDX
tWLWH
WR Data Setup Time
WR Data Hold Time
WR Pulse Width
(Note 3)
(Note 3)
(Note 3)
12
5
15
5
22
5
ns
ns
ns
18
20
28
Trailing Edge of WR to
Address Invalid
tWHAX
tWHPV
(Note 3)
(Note 3)
0
0
0
ns
ns
ns
ns
Trailing Edge of WR to
Port Output Valid
25
20
22
30
30
32
38
38
48
In 16-Bit Data Bus
Mode (Note 2)
Address Input Valid to
Address Output Delay
tAVPV
In 8-Bit Data Bus
Mode (Note 2)
NOTES: 1. Any input used to select an internal PSD5XX function.
2. In multiplexed mode latched address generated from ADIO delay to address output on any Port.
3. WR timing has the same timing as E, DS, LDS, UDS, WRL, WRH signals.
*The -90 speed is available only on Industrial Temperature Range product.
116
PSD5XX Family
Microcontroller Interface – AC/DC Parameters (5 V ± 10% Versions)
Port A Peripheral Data Mode Read Timing (5 V ± 10%)
-70
-90**
-15
ZPLD_TURBO
Symbol
Parameter
Conditions
Min Max Min Max Min Max
OFF*
Unit
tAVQV (PA) Address Valid to
Data Valid
(Note 3)
45
55
62
Add 10
ns
tSLQV (PA)
CS Valid to Data
Valid
55
22
32
55
26
38
62
45
45
Add 10
ns
ns
ns
RD to Data Valid
(Notes 1 and 4)
0
0
tRLQV (PA)
RD to Data Valid
8031 Mode
tDVQV (PA) Data In to Data Out
Valid
22
22
26
0
ns
tQXRH (PA) RD Data Hold Time (Note 1)
0
0
0
0
0
0
ns
ns
ns
tRLRH (PA) RD Pulse Width
tRHQZ (PA) RD to Data High-Z
(Note 1)
(Note 1)
25
30
38
20
25
33
Port A Peripheral Data Mode Write Timing (5 V ± 10%)
-70
-90**
-15
ZPLD_TURBO
OFF*
Symbol
Parameter
Conditions
Min Max Min Max Min Max
Unit
tWLQV (PA) WR to Data
Propagation Delay
(Note 2)
25
22
20
27
22
25
35
26
33
0
0
ns
Data to Port A Data
Propagation Delay
tDVQV (PA)
(Note 5)
(Note 2)
ns
ns
tWHQZ (PA) WR Invalid to
Port A Tri-state
NOTES: 1. RD timing has the same timing as PSEN, DS, LDS, UDS signals.
2. WR timing has the same timing as E, DS, LDS, UDS, WRL, WRH signals.
3. Any input used to select Port A Data Peripheral Mode.
4. Data is already stable on Port A.
5. Data stable on ADIO pins to data on Port A.
**If ZPLD_TURBO is off and the ZPLD is operating above 15 MHz, there is no need to add 10 ns to the timing parameters.
**The -90 speed is available only on Industrial Temperature Range product.
117
PSD5XX Family
Microcontroller Interface – AC/DC Parameters (5 V ± 10% Versions)
Power Down and Reset Timing (5 V ± 10%)
-70
-90**
-15
ZPLD_TURBO
OFF*
Symbol
Parameter
Conditions Min Max Min Max Min Max
Unit
tLVDV
ALE Access Time from
Power Down
100
120
600
250
120
150
600
250
150
200
600
250
Add 10
ns
ALE or CSI Access Time
from Sleep
tLVDV1
tLVDV2
tLVDV3
0
0
0
ns
ns
ns
ZPLD Propagation Delay
in Sleep Mode
ZPLD Recovery Time
after Sleep Mode
tCHCL
tCLCH
fMAX
t1
APD Clock High Time
APD Clock Low Time
Using PE7
Using PE7
10
10
12
12
15
15
0
0
0
0
ns
ns
APD Maximum Frequency Using PE7
RESET Active Low Time
35.00
150
30.00
200
22.00
300
MHz
ns
150
200
300
RESET High to
Operational Device
t2
0
ns
**If ZPLD_TURBO is off and the ZPLD is operating above 15 MHz, there is no need to add 10 ns to the timing parameters.
**The -90 speed is available only on Industrial Temperature Range product.
118
PSD5XX Family
AC/DC Parameters – ZPLD Timing Parameters (5 V ± 10% Versions)
Counter/Timer Timing (5 V ± 10%)
-70
-90**
-15
ZPLD_TURBO
OFF*
Symbol
fMAX
Parameter
Maximum Frequency
Clock High Time
Conditions
Min Max Min Max Min Max
Unit
MHz
ns
36.00
30.00
22.00
0
0
0
0
tCHCL
tCLCH
tCHPV
10
10
12
12
15
15
Clock Low Time
ns
Clock to Output Delay
28
50
30
50
33
58
ns
tCHPV1 Clock to Watchdog
Output Dealy
Add 10
ns
tLVCH
Input Setup Time
Relative to Rising
Clock Edge
15
17
20
Add 10
(Note 2)
Pin Input
ns
ns
ns
tLVCH1 Input Setup Time
Relative to Rising
Clock Edge
PLD
Combinatorial
Input
25
28
27
33
31
45
(Note 2)
0
tMIN
Minimum Clock
Period
1/fMAX
Interrupt Timing (5 V ± 10%)
-70
-90**
-15
ZPLD_TURBO
OFF*
Symbol
Parameter
Conditions
Min Max Min Max Min Max
Unit
Interrupt Request
Input to Interrupt
Output
tIVIV
(Note 3)
40
30
50
40
65
55
0
0
ns
Read Vector to
Interrupt Request
Clear
tRXIX
ns
Interrupt Request
Minimum Pulse
Width
tILIL
18
20
35
0
0
ns
ns
tRLQV
RD to Data Valid
Interrupt Controller
(Note 1)
32
38
45
NOTES: 1. Read to Data Valid of the Interrupt Request Latch and Interrupt Priority Status. RD timing has the same timing as PSEN, DS,
LDS, UDS signals.
2. For inputs which use PPLD only.
3. This timing is only valid when read to the interrupt request latch and priority status latch are not valid.
**If ZPLD_TURBO is off and the ZPLD is operating above 15 MHz, there is no need to add 10 ns to the timing parameters.
**The -90 speed is available only on Industrial Temperature Range product.
119
PSD5XX Family
13.9 DC Characteristics (ZPSD5XXV Versions)
(3.0 V ± 10%)
Symbol
Parameter
Conditions
Min
Typ
Max
Unit
VCC
VIH
Supply Voltage
All Speeds
2.7
.7 VCC
–0.5
.8 VCC
–.5
3
5.5
V
V
High Level Input Voltage
Low Level Input Voltage
Reset High Level Input Voltage
Reset Low Level Input Voltage
Reset Pin Hysteresis
2.7 V < VCC < 5.5 V
2.7 V < VCC < 5.5 V
(Note 1)
VCC +.5
.3 VCC
VIL
V
VIH1
VIL1
VHYS
VCC +.5
.2 VCC –.1
V
(Note 1)
V
0.3
V
IOL = 20 µA, VCC = 2.7 V
IOL = 4 mA, VCC = 2.7 V
IOH = –20 µA, VCC = 2.7 V
IOH = –1 mA, VCC = 2.7 V
0.01
0.15
2.99
2.6
0.1
V
VOL
Output Low Voltage
Output High Voltage
0.45
V
2.9
2.4
2.7
V
VOH
V
VSBY
ISBY
IIDLE
VDF
SRAM Standby Voltage
SRAM Standby Current
Idle Current (VSTBY Pin)
SRAM Data Retention Voltage
VCC
1
V
VCC = 0 V
0.5
µA
µA
V
VCC > VSBY
–0.1
2
0.1
Only on VSTBY
Power Down Mode
Sleep Mode
CSI >VCC –.3 V (Note 2)
CSI >VCC –.3 V (Note 3)
VSS < VIN < VCC
0.45 < VIN < VCC
5
1
15
5
µA
µA
µA
µA
Standby Supply
Current
ISB
ILI
Input Leakage Current
Output Leakage Current
–1
±.1
± 5
1
ILO
–10
10
ZPLD_TURBO = OFF,
f = 0 MHz (Note 4)
See ISB
µA
ICC (DC)
(Note 5)
Operating
Supply Current
ZPLD Only
ZPLD_TURBO = ON,
f = 0 MHz
200
400
2.0
µA/PT
mA/MHz
ZPLD AC Base
See
(Note 4)
Fig. 51
CMiser = ON
(8-Bit Bus Mode)
0.4
0.9
0.7
1.0
1.7
1.3
mA/MHz
mA/MHz
mA/MHz
EPROM AC Adder
SRAM AC Adder
All Other Cases
ICC (AC)
(Note 5)
CMiser = ON and
8-Bit Bus Mode
CMiser = ON and
16-Bit Bus MoDe
1
2
mA/MHz
mA/MHz
CMiser = OFF
1.9
3.8
NOTES: 1. Reset input has hysteresis. VIL1 is valid at or below .2VCC –.1. VIH1 is valid at or above .8VCC
2. CSI deselected or internal PD is active.
.
3. Sleep mode bit is set and internal PD is active.
4. See ZPLD ICC/Frequency Power Consumption graph for details.
5. IOUT = 0 mA.
120
PSD5XX Family
13.10 AC/DC Parameters – ZPLD Timing Parameters
(ZPSD5XXV Versions)
Combinatorial Delays (3.0 V ± 10%)
-20
-25
ZPLD_TURBO
Symbol
Parameter
Conditions
Min Max Min Max
OFF*
Unit
I/O Input or Feedback to
Combinatorial Output
tPD
Port B, E
55
55
80
85
Add 20
ns
Registered Input to
Combinatorial Output
tRPD
(Note 1)
Add 20
ns
tEA
Input to Output Enable
Any Input
Any Input
Any Input
50
50
55
80
80
80
Add 20
Add 20
Add 20
ns
ns
ns
tER
Input to Output Disable
tARP
Register Clear or Preset Delay
Register Clear or Preset
Pulse Width
tARPW
tARD
Any Input
30
60
ns
ns
Array Delay
33
35
NOTE: 1. Port A and latched address from ADIO (A0, A1, A8 – A15).
*NOTE: If ZPLD_TURBO is off and the ZPLD is operating above 15 MHz, there is no need to add 20 ns to the timing parameters.
Synchronous Clock Mode (3.0 V ± 10%)
-20
-25
ZPLD_TURBO
OFF*
Symbol
Parameter
Conditions
Min Max Min Max
Unit
Maximum Frequency
External Feedback
1/(tS + tCO
)
28.57
17.24
31.25
11.11
12.50
18.52
MHz
Maximum Frequency
Internal Feedback (fCNT)
1/(tS+tCO–10)
MHz
MHz
fMAX
Maximum Frequency
Pipelined Data
1/(tCH + tCL
)
tS
Input Setup Time
Input Hold Time
Any Input
45
0
60
0
Add 20
ns
ns
ns
ns
ns
tH
Any Input
0
0
0
0
tCH
tCL
tCO
tARD
Clock High Time
Clock Low Time
Clock to Output Delay
Clock Input
Clock Input
Clock Input
16
16
27
27
30
24
33
35
Array Delay for Product
Term Expansion
Any Macrocell
tCH + tCL
0
0
ns
ns
tMIN
Minimum Clock Period
30
30
*NOTE: If ZPLD_TURBO is off and the ZPLD is operating above 15 MHz, there is no need to add 20 ns to the timing parameters.
121
PSD5XX Family
AC/DC Parameters – ZPLD Timing Parameters
(ZPSD5XXV Versions)
Asynchronous Clock Mode (3.0 V ± 10%, Note 1)
-20
-25
ZPLD_TURBO
OFF*
Symbol
Parameter
Conditions
Min Max Min Max
Unit
Maximum Frequency
External Feedback
1/(tSA + tCOA
)
14.49
16.95
31.25
11.11
12.50
18.52
MHz
Maximum Frequency
Internal Feedback (fCNTA)
1/(tSA+tCOA–10)
(Note 1)
MHz
MHz
fMAXA
Maximum Frequency
Pipelined Data
1/(tCH + tCL
)
tSA
Input Setup Time
Input Hold Time
Any Input
Any Input
Any Input
Any Input
13
13
25
16
30
30
27
27
Add 20
ns
ns
ns
ns
ns
tHA
0
tCHA
tCLA
tCOA
Clock High Time
Clock Low Time
Clock to Output Delay
0
0
Any Input to Port B
Any Macrocell
1/fCNT
56
33
60
35
Add 20
Array Delay for Product
Term Expansion
tARD
0
0
ns
ns
tMINA
Minimum Clock Period
59
80
NOTE: 1. Only Port B has asynchronous outputs. Clock into macrocell Flip Flop is generated by a product term.
*NOTE: If ZPLD_TURBO is off and the ZPLD is operating above 15 MHz, there is no need to add 20 ns to the timing parameters.
122
PSD5XX Family
13.11 Microcontroller Interface –AC/DC Parameters
(ZPSD5XXV Versions)
Explanation of AC Symbols for Non ZPLD Timing.
Example:
tAVLX Time from Address Valid to ALE Invalid.
A – Address
C – Power Down
D– Input Data
E – E
H – Logic Level High
I – Interrupt
L – Logic Level Low or ALE
N – Reset
P – Port Signal
Q – Output Data
R – WR, UDS, LDS, DS, IORD, PSEN
S – Chip Select
T – R/W
t – Time
V – Valid
X – No Longer a Valid Logic Level
Z – Float
Read Timing (3.0 V ± 10%)
-20
-25
EPROM_CMiser
ON
Symbol
tLVLX
Parameter
Conditions
Min Max Min Max
Unit
ALE or AS Pulse Width
Address Setup Time
30
12
12
30
15
17
0
ns
ns
ns
ns
ns
ns
tAVLX
(Note 4)
0
0
tLXAX
tAVQV
tSLQV
Address Hold Time
(Note 4)
(Note 4)
Address Valid to Data Valid
CS Valid to Data Valid
RD to Data Valid 8/16-Bit Bus
200
200
50
250
275
80
Add 20
Add 20
0
(Note 1)
(Note 2)
RD to Data Valid 8-Bit Bus,
8031 Separate Mode
57
50
90
90
0
ns
tRLQV
RD to Data Valid from Interrupt Controller (Note 3)
0
0
0
0
0
0
0
ns
ns
ns
ns
ns
ns
ns
tRHQX
tRLRH
tRHQZ
tEHEL
tTHEH
tELTL
RD Data Hold Time
RD Pulse Width
(Note 1)
(Note 1)
(Note 1)
0
0
40
70
RD to Data High-Z
45
45
E Pulse Width
40
20
0
70
22
0
R/W Setup Time to Enable
R/W Hold Time After Enable
In 16-Bit Data Bus
Mode (Note 5)
40
50
60
60
0
0
ns
ns
Address Input Valid to
Address Output Delay
tAVPV
In 8-Bit Data Bus
Mode (Note 5)
NOTES: 1. RD timing has the same timing as PSEN, DS, LDS, UDS signals (in 8031 combined mode).
2. RD and PSEN have the same timing for 8031 separate mode.
3. Read to Data Valid of the Interrupt Request Latch and Interrupt Priority Status. RD timing has the same timing as PSEN, DS, LDS,
UDS signals.
4. Any input used to select an internal ZPSD5XX function.
5. In multiplexed mode latched address generated from ADIO delay to address output on any Port.
123
PSD5XX Family
Microcontroller Interface – AC/DC Parameters
(ZPSD5XXV Versions)
Write Timing (3.0 V ± 10%)
-20
-25
EPROM_CMiser
ON
Symbol
tLVLX
Parameter
ALE or AS Pulse Width
Address Setup Time
Address Hold Time
Conditions
Min Max Min Max
Unit
ns
30
12
12
30
15
17
tAVLX
(Note 1)
ns
tLXAX
(Note 1)
ns
Address Valid to Leading
Edge of WR
tAVWL
(Notes 1 and 3)
35
50
ns
tSLWL
CS Valid to Leading Edge of WR (Note 3)
40
25
5
60
35
10
30
ns
ns
ns
ns
tDVWH WR Data Setup Time
tWHDX WR Data Hold Time
tWLWH WR Pulse Width
(Note 3)
(Note 3)
(Note 3)
30
Trailing Edge of WR to Address
Invalid
tWHAX
tWHPV
(Note 3)
(Note 3)
0
0
ns
ns
ns
ns
Trailing Edge of WR to Port
Output Valid
50
40
50
60
60
60
In 16-Bit Data Bus
Mode (Note 2)
Address Input Valid to
Address Output Delay
tAVPV
In 8-Bit Data Bus
Mode (Note 2)
NOTES: 1. Any input used to select an internal ZPSD5XX function.
2. In multiplexed mode latched address generated from ADIO delay to address output on any Port.
3. WR timing has the same timing as E, DS, LDS, UDS, WRL, WRH signals.
124
PSD5XX Family
Microcontroller Interface – AC/DC Parameters
(ZPSD5XXV Versions)
Port A Peripheral Data Mode Read Timing (3.0 V ± 10%)
-20
-25
ZPLD_TURBO
Symbol
Parameter
Conditions
Min Max Min Max
OFF*
Unit
tAVQV (PA)
tSLQV (PA)
tRLQV (PA)
tDVQV (PA)
tQXRH (PA)
tRLRH (PA)
tRHQZ (PA)
Address Valid to Data Valid
CS Valid to Data Valid
RD to Data Valid
(Note 3)
95
100
50
120
120
90
Add 20
ns
ns
ns
ns
ns
ns
ns
Add 20
(Notes 1 and 4)
0
0
0
0
0
Data In to Data Out Valid
RD Data Hold Time
RD Pulse Width
35
50
(Note 1)
(Note 1)
(Note 1)
0
0
40
70
RD to Data High-Z
35
60
Port A Peripheral Data Mode Write Timing (3.0 V ± 10%)
-20
-25
ZPLD_TURBO
OFF*
Symbol
Parameter
Conditions
Min Max Min Max
Unit
tWLQV (PA) WR to Data Propagation Delay
(Note 2)
60
60
0
ns
Data to Port A Data
tDVQV (PA)
(Note 5)
(Note 2)
40
35
50
60
0
0
ns
ns
Propagation Delay
tWHQZ (PA) WR Invalid to Port A Tri-state
NOTES: 1. Any input used to select an internal ZPSD5XX function.
2. WR timing has the same timing as E, DS, LDS, UDS, WRL, WRH signals.
3. Any input used to select Port A Data Peripheral Mode.
4. Data is already stable on Port A.
5. Data stable on ADIO pins to data on Port A.
*NOTE: If ZPLD_TURBO is off and the ZPLD is operating above 15 MHz, there is no need to add 20 ns to the timing parameters.
125
PSD5XX Family
Microcontroller Interface – AC/DC Parameters
(ZPSD5XXV Versions)
Power Down and Reset Timing (3.0 V ± 10%)
-20
-25
ZPLD_TURBO
OFF*
Symbol
Parameter
Conditions Min Max Min Max
Unit
ALE Access Time from
Power Down
tLVDV
Add 20
ns
170
250
ALE or CSI Access Time
from Sleep
tLVDV1
tLVDV2
tLVDV3
200
600
250
900
0
0
ns
ns
ZPLD Propagation Delay
in Sleep Mode
ZPLD Recovery Time after
Sleep Mode
250
400
0
ns
tCHCL
tCLCH
fMAX
t1
APD Clock High Time
Using PE7
Using PE7
Using PE7
16
16
27
27
0
0
0
0
0
ns
ns
APD Clock Low Time
APD Maximum Frequency
RESET Active Low Time
RESET High to Operational Device
20.00
300
18.52
400
MHz
ns
300
400
t2
ns
*NOTE: If ZPLD_TURBO is off and the ZPLD is operating above 15 MHz, there is no need to add 20 ns to the timing parameters.
126
PSD5XX Family
AC/DC Parameters – ZPLD Timing Parameters
(ZPSD5XXV Versions)
Counter/Timer Timing (3.0 V ± 10%)
-20
-25
ZPLD_TURBO
Symbol
Parameter
Conditions Min Max Min Max
OFF*
Unit
fMAX
Maximum Frequency
Clock High Time
20.00
12.50
0
MHz
ns
tCHCL
tCLCH
tCHPV
tCHPV1
16
16
22
22
0
Clock Low Time
0
0
ns
Clock to Output Delay
Clock to Watchdog Output Delay
50
90
55
ns
100
Add 20
ns
Input Setup Time Relative
to Rising Level Clock
Add 20
(Note 2)
tLVCH
tMIN
Any Input
1/fMAX
45
50
60
80
ns
ns
Minimum Clock Period
0
Interrupt Timing (3.0 V ± 10%)
-20
-25
ZPLD_TURBO
OFF*
Symbol
Parameter
Conditions Min Max Min Max
Unit
tIVIV
Interrupt Request Input to
Interrupt Output
(Note 3)
(Note 1)
70
60
120
100
0
0
0
0
ns
tRXIX
tILIL
Read Vector to Interrupt
Request Clear
ns
ns
ns
Interrupt Request Minimum
Pulse Width
40
45
tRLQV
RD to Data Valid Interrupt
Controller
50
90
NOTES: 1. Read to Data Valid of the Interrupt Request Latch and Interrupt Priority Status. RD timing has the same timing as PSEN, DS, LDS,
UDS signals.
2. For inputs which use PPLD only.
3. This timing is only valid when read to the interrupt request latch and priority status latch are not valid.
*If ZPLD_TURBO is off and the ZPLD is operating above 15 MHz, there is no need to add 20 ns to the timing parameters.
127
PSD5XX Family
14.0 Timing Diagrams
Figure 52. Read Timing
t
t
LXAX
AVLX
ALE/AS
t
LVLX
A/D (BHE)
MULTIPLEXED
BUS
ADDRESS
VALID
DATA
VALID
t
AVQV
ADDRESS
(BHE/SIZ0)
NON-MULTIPLEXED
BUS
ADDRESS
VALID
DATA
NON-MULTIPLEXED
BUS
DATA
VALID
t
SLQV
CSI
t
t
RLQV
t
RHQX
RLRH
RD
(PSEN, DS)
(LDS, UDS)
tRHQZ
t
EHEL
E
t
THEH
t
ELTL
R/W
t
AVPV
ADDRESS OUT
128
PSD5XX Family
Figure 53. Write Timing
t
t
LXAX
AVLX
ALE/AS
t
LVLX
A/D (BHE)
MULTIPLEXED
BUS
ADDRESS
VALID
DATA
VALID
t
AVWL
ADDRESS
(BHE, SIZ0)
NON-MULTIPLEXED
BUS
ADDRESS
VALID
DATA
NON-MULTIPLEXED
BUS
DATA
VALID
t
SLWL
CSI
t
t
DVWH
WHDX
WR
(WRH, WRL)
(LDS, UDS)
(DS)
t
WLWH
t
WHAX
t
EHEL
E
t
t
THEH
ELTL
R/ W
t
t
AVPV
WHPV
STANDARD
MCU I/O OUT
ADDRESS OUT
129
PSD5XX Family
Figure 54. Peripheral I/O Read Timing
ALE/AS
ADDRESS
DATA VALID
A/D BUS
t
(PA)
(PA)
AVQV
t
SLQV
CSI
RD
t
t
(PA)
(PA)
RLQV
t
t
(PA)
(PA)
QXRH
RHQZ
RLRH
t
(PA)
DVQV
DATA ON PORT A
Figure 55. Peripheral I/O Write Timing
ALE/AS
ADDRESS
DATA OUT
A/D BUS
tWHQZ (PA)
tWLQL (PA)
WR
tDVQV (PA)
PORT A
DATA OUT
130
PSD5XX Family
Figure 56. Combinatorial Timing – ZPLD
INPUT
(FROM PORT B, C, D, E)
tPD
ANY OUTPUT
INPUT
(FROM PORT A)
tRPD
ANY
OUTPUT
Figure 57. Synchronous Clock Mode Timing – ZPLD
t
t
CL
CH
CLKIN
INPUT
t
S
t
H
t
CO
REGISTERED
OUTPUT
121
PSD5XX Family
Figure 58. Asynchronous Clock Mode Timing (Product-Term Clock, PB Macrocell Only)
tCHA
tCLA
CLOCK
INPUT
tSA
tHA
tCOA
REGISTERED
OUTPUT
Figure 59. Input to Output Disable/Enable
INPUT
tER
tEA
INPUT TO
OUTPUT
ENABLE/DISABLE
Figure 60. Asynchronous Reset/Preset
tARPW
RESET/PRESET
INPUT
tARP
REGISTER
OUTPUT
132
PSD5XX Family
Figure 61. Reset Timing
T1
T2
Figure 62. Key to Switching Waveforms
INPUTS
OUTPUTS
WAVEFORMS
STEADY INPUT
STEADY OUTPUT
MAY CHANGE FROM
HI TO LO
WILL BE CHANGING
FROM HI TO LO
MAY CHANGE FROM
LO TO HI
WILL BE CHANGING
LO TO HI
DON'T CARE
CHANGING, STATE
UNKNOWN
OUTPUTS ONLY
CENTER LINE IS
TRI-STATE
133
PSD5XX Family
TA = 25 °C, f = 1 MHz
15.0
Pin
Capacitance
Symbol
Parameter1
Conditions Typical2 Max Unit
CIN
Capacitance (for input pins only)
Capacitance (for input/output pins)
Capacitance (for WR/VPP or R/W/VPP
VIN = 0 V
VOUT = 0 V
VPP = 0 V
4
8
6
pF
pF
pF
COUT
CVPP
12
25
)
18
NOTES: 1. These parameters are only sampled and are not 100% tested.
2. Typical values are for TA = 25°C and nominal supply voltages.
Figure 63. AC Testing Input/Output Waveform
16.0
AC Testing
3.0V
TEST POINT
1.5V
0V
Figure 64. AC Testing Load Circuit
2.01 V
195 Ω
DEVICE
UNDER TEST
CL = 30 pF
(INCLUDING
SCOPE AND JIG
CAPACITANCE)
To clear all locations of their programmed contents, expose the window packaged device
to an ultra-violet light source. A dosage of 30 W second/cm2 is required (40 W second/cm2
for ZPSD5XXV versions). This dosage can be obtained with exposure to a wavelength of
2537 Å and intensity of 12000 µW/cm2 for 40 to 45 minutes (55 to 60 minutes for
ZPSD5XXV versions). The device should be about 1 inch from the source, and all filters
should be removed from the UV light source prior to erasure.
17.0
Erasure and
Programming
The PSD5XX and similar devices will erase with light sources having wavelengths shorter
than 4000 Å. Although the erasure times will be much longer than with UV sources at 2537
Å, exposure to fluorescent light and sunlight eventually erases the device. For maximum
system reliability, these sources should be avoided. If used in such an environment, the
package windows should be covered by an opaque substance.
Upon delivery from WSI, or after each erasure, the PSD5XX device has all bits in the PAD
and EPROM in the “1” or high state. The configuration bits are in the “0” or low state. The
code, configuration, and PAD MAP data are loaded through the procedure of programming
Information for programming the device is available directly from WSI. Please contact your
local sales representative.
134
PSD5XX Family
18.0
PSD5XX
Pin
68-Pin
PLDCC/CLDCC
Package
68-Pin
PLDCC/CLDCC
Package
Pin No.
Pin No.
Assignments
1
GND
ADIO_7
ADIO_6
ADIO_5
ADIO_4
ADIO_3
ADIO_2
ADIO_1
ADIO_0
PC7
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
GND
2
PE2
3
PE1
4
PE0
5
CSI
6
RESET
RD
7
8
CLKIN
PB7
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
PB6
PC6
PB5
PC5
PB4
PC4
PB3
PC3
PB2
PC2
PB1
PC1
PB0
PC0
GND
VCC
GND
PA7
VCC
PD7
PD6
PA6
PD5
PA5
PD4
PA4
PD3
PA3
PD2
PA2
PD1
PA1
PD0
PA0
ADIO_15
ADIO_14
ADIO_13
ADIO_12
ADIO_11
ADIO_10
ADIO_9
ADIO_8
Vstby
WR
PE7
PE6
PE5
PE4
PE3
135
PSD5XX Family
PSD5XX
Pin
Assignments
80-Pin
TQFP
Package
80-Pin
TQFP
Package
Pin No.
Pin No.
1
PC7
PC6
PC5
PC4
PC3
PC2
PC1
PC0
VCC
41
42
43
44
45
46
47
48
49
59
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
PB7
2
PB6
3
PB5
4
PB4
5
PB3
6
PB2
7
PB1
8
PB0
9
GND
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
VCC
GND
GND
GND
PA7
PA6
PA5
PA4
PA3
PA2
PA1
PA0
NC
VCC
VCC
PD7
PD6
PD5
PD4
PD3
PD2
PD1
PD0
NC
NC
ADIO_15
ADIO_14
ADIO_13
ADIO_12
ADIO_11
ADIO_10
ADIO_9
ADIO_8
GND
Vstdby
WR
PE7
PE6
PE5
PE4
PE3
GND
GND
PE2
PE1
PE0
CSI
GND
ADIO_7
ADIO_6
ADIO_5
ADIO_4
ADIO_3
ADIO_2
ADIO_1
ADIO_0
NC
RESET
RD
CLKIN
NC
NC
136
PSD5XX Family
19.0
Package
Information
Figure 65.
Drawing J5 –
68-Pin
Plastic Leaded
Chip Carrier
(PLDCC)
9
10
8
7
6
5
4
3
2
68 67 66 65 64 63 62 61
1
PC7
PC6
60
PD0
PD1
11
12
13
14
15
16
17
18
19
20
21
22
59
PC5
PC4
58
57
PD2
PD3
PC3
PC2
56
55
PD4
PD5
PC1
PC0
54
53
52
51
50
49
48
47
46
PD6
PD7
(Package
Type J)
V
V
CC
CC
GND
PA7
PA6
PA5
PA4
PA3
GND
PB0
PB1
PB2
PB3
PB4
23
24
PA2
PA1
25
26
45
PB5
PB6
44
27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43
Figure 66.
Drawing L5 –
68-Pin
Ceramic Leaded
Chip Carrier
(CLDCC)
with Window
(Package
9
8
7
6
5
4
3
2
68 67 66 65 64 63 62 61
1
10
PC7
60
PD0
PC6
11
12
13
14
15
16
17
18
19
20
21
22
59
PD1
PC5
PC4
58
57
PD2
PD3
PC3
PC2
56
55
PD4
PD5
Type L)
PC1
PC0
54
53
52
51
50
49
48
47
46
PD6
PD7
V
V
CC
CC
GND
PA7
PA6
PA5
PA4
PA3
GND
PB0
PB1
PB2
PB3
PB4
23
24
PA2
PA1
25
26
45
PB5
PB6
44
27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43
137
PSD5XX Family
Figure 67.
Drawing U2 –
80-Pin
Plastic Thin
Quad Flatpack
(TQFP)
(Package
Type U)
PC7
PC6
PC5
PC4
PC3
PC2
PC1
PC0
1
2
3
4
5
6
7
8
9
10
60 PD0
59 PD1
58 PD2
57 PD3
56 PD4
55 PD5
54 PD6
53 PD7
V
52 V
CC
CC
V
51 V
CC
CC
GND 11
GND 12
PA7 13
PA6 14
PA5 15
PA4 16
PA3 17
PA2 18
PA1 19
PA0 20
50 GND
49 GND
48 PB0
47 PB1
46 PB2
45 PB3
44 PB4
43 PB5
42 PB6
41 PB7
(TOP VIEW)
138
PSD5XX Family
Drawing J5 – 68-Pin Plastic Leaded Chip Carrier (PLDCC) (Package Type J)
D
D1
3 2 1 68
E1
E
C
B1
A
e1
B
A2
A1
E3
E2
D3
D2
Family: Plastic Leaded Chip Carrier
Millimeters
Max
Inches
Max
Symbol
Min
Notes
Min
Notes
A
4.19
2.41
4.57
3.00
0.165
0.095
0.146
0.013
0.026
0.0077
0.985
0.950
0.890
0.180
0.118
0.154
0.021
0.032
0.0083
0.995
0.954
0.930
A1
A2
B
3.71
3.91
0.33
0.53
B1
C
0.66
0.81
0.196
25.02
24.13
22.61
0.262
25.27
24.23
23.62
D
D1
D2
D3
E
20.32
Reference
0.800
Reference
25.02
24.13
22.61
25.27
24.23
23.62
0.985
0.950
0.890
0.995
0.954
0.930
E1
E2
E3
e1
N
20.32
1.27
68
Reference
Reference
0.800
0.050
68
Reference
Reference
030195R6
139
PSD5XX Family
Drawing L5 – 68-Pin Pocketed Ceramic Leaded Chip Carrier (CLDCC) – CERQUAD (Package Type L)
D
D1
2 1 68
3
To reduce lead damage,
lead tips reside in
pockets on the bottom
of the package.
E1
E
View A
B1
C
A2
View A
e1
B
D3
D2
E3
E2
A
A1
Family: Ceramic Leaded Chip Carrier – CERQUAD
Millimeters
Inches
Max
Symbol
Min
Max
Notes
Min
Notes
A
3.94
2.29
4.57
2.92
0.155
0.090
0.120
0.017
0.026
0.006
0.985
0.942
0.880
0.180
0.115
0.145
0.021
0.032
0.010
0.995
0.956
0.940
A1
A2
B
3.05
3.68
0.43
0.53
B1
C
0.66
0.81
0.15
0.25
D
25.02
23.93
22.35
25.27
24.28
23.88
D1
D2
D3
E
20.32
Reference
0.800
Reference
25.02
23.93
22.35
25.27
24.28
23.88
0.985
0.942
0.880
0.995
0.956
0.940
E1
E2
E3
e1
N
20.32
1.27
68
Reference
Reference
0.800
0.050
68
Reference
Reference
030195R6
140
PSD5XX Family
Drawing U2 – 80-Pin Plastic Thin Quad Flatpack (TQFP) (Package Type U)
D
D1
D3
80
1
2
3
Index
Mark
E
E3
E1
Standoff:
0.05 mm Min.
C
A1 A2
A
α
L
Load Coplanarity:
0.102 mm Max.
B
e1
Family: Plastic Thin Quad Flatpack (TQFP)
Millimeters
Inches
Symbol
Min
0°
Max
8°
Notes
Min
0°
Max
8°
Notes
α
A
–
1.60
–
0.063
A1
A2
B
0.54
1.15
0.74
1.55
0.021
0.045
0.029
0.061
0.30
Reference
Reference
0.012
0.486
Reference
Reference
C
0.09
15.75
13.90
0.20
16.25
14.10
0.004
0.620
0.547
0.008
0.640
0.555
D
D1
D3
E
12.35
15.75
13.90
16.25
14.10
0.620
0.547
0.640
0.555
E1
E3
e1
L
12.35
0.65
Reference
Reference
0.486
0.026
Reference
Reference
0.35
0.75
0.014
0.030
N
80
80
030195R1
141
t
r
5
0
142
m
20.1 PSD5XX Family – Selector Guide
Part #
MCU
PLDs/Decoders
I/O
Memory
Other
PSD
ZPSD
ZPSDV
Data Path
Inputs
Ports EPROM SRAM Four 16-Bit Timer/Counters
Interface
Product Terms
(w/BB)
WatchDog (16-Bit)
Inter. Contr.
Input Micro Cells
Output Micro Cells
Periph. Mode
Security
APD
Outputs
Page
Reg.
PSD511B1 ZPSD511B1 ZPSD511B1V
8
PLUS2
61
61
140
140
24
24
24
24
X
X
40
40
256Kb 16Kb
256Kb 16Kb
X
X
X
X
X
X
X
X
X
X
X
X
PSD501B1 ZPSD501B1 ZPSD501B1V 16/8 PLUS2
ZPSD512B0
8
8
PSD512B1 ZPSD512B1 ZPSD512B1V
PLUS2
61
61
61
61
140
140
140
140
24
24
24
24
24
24
24
24
X
X
X
X
40
40
40
40
512Kb 16Kb
512Kb 16Kb
1024Kb 16Kb
1024Kb 16Kb
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
PSD502B1 ZPSD502B1 ZPSD502B1V 16/8 PLUS2
PSD513B1 ZPSD513B1 ZPSD513B1V PLUS2
PSD503B1 ZPSD503B1 ZPSD503B1V 16/8 PLUS2
8
PSD5XX Family
PSD5XX
20.2 Part Number Construction
Ordering
Information
I
Z
PSD 413A2 V -A -20 J
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 (WSI Programmable System Device) Fam.
Power Down Feature (Blank = Standard,
Z = Zero Power Feature)
20.3 Ordering Information
Speed
Operating
Temperature
Part Number
(ns)
Package Type
Range
PSD501B1-C-70J
PSD501B1-C-70L
PSD501B1-C-70U
70
70
70
68 Pin PLDCC
68 Pin CLDCC
68 Pin TQFP
Comm’l
Comm’l
Comm’l
PSD501B1-C-90JI
PSD501B1-C-90UI
90
90
68 Pin PLDCC
68 Pin TQFP
Industrial
Industrial
PSD501B1-C-15J
PSD501B1-C-15L
PSD501B1-C-15U
150
150
150
68 Pin PLDCC
68 Pin CLDCC
68 Pin TQFP
Comm’l
Comm’l
Comm’l
PSD502B1-C-70J
PSD502B1-C-70L
PSD502B1-C-70U
70
70
70
68 Pin PLDCC
68 Pin CLDCC
68 Pin TQFP
Comm’l
Comm’l
Comm’l
PSD502B1-C-90JI
PSD502B1-C-90UI
90
90
68 Pin PLDCC
68 Pin TQFP
Industrial
Industrial
PSD502B1-C-15J
PSD502B1-C-15L
PSD502B1-C-15U
150
150
150
68 Pin PLDCC
68 Pin CLDCC
68 Pin TQFP
Comm’l
Comm’l
Comm’l
143
PSD5XX Family
Ordering Information
Part Number
PSD5XX
Ordering
Information
(cont.)
Operating
Temperature
Range
Speed
(ns)
Package Type
PSD503B1-C-70J
PSD503B1-C-70L
PSD503B1-C-70U
70
70
70
68 Pin PLDCC
68 Pin CLDCC
68 Pin TQFP
Comm’l
Comm’l
Comm’l
PSD503B1-C-90JI
PSD503B1-C-90UI
90
90
68 Pin PLDCC
68 Pin TQFP
Industrial
Industrial
PSD503B1-C-15J
PSD503B1-C-15L
PSD503B1-C-15U
150
150
150
68 Pin PLDCC
68 Pin CLDCC
68 Pin TQFP
Comm’l
Comm’l
Comm’l
PSD511B1-C-70J
PSD511B1-C-70L
PSD511B1-C-70U
70
70
70
68 Pin PLDCC
68 Pin CLDCC
68 Pin TQFP
Comm’l
Comm’l
Comm’l
PSD511B1-C-90JI
PSD511B1-C-90UI
90
90
68 Pin PLDCC
68 Pin TQFP
Industrial
Industrial
PSD511B1-C-15J
PSD511B1-C-15L
PSD511B1-C-15U
150
150
150
68 Pin PLDCC
68 Pin CLDCC
68 Pin TQFP
Comm’l
Comm’l
Comm’l
PSD512B1-C-70J
PSD512B1-C-70L
PSD512B1-C-70U
70
70
70
68 Pin PLDCC
68 Pin CLDCC
68 Pin TQFP
Comm’l
Comm’l
Comm’l
PSD512B1-C-90JI
PSD512B1-C-90UI
90
90
68 Pin PLDCC
68 Pin TQFP
Industrial
Industrial
PSD512B1-C-15J
PSD512B1-C-15L
PSD512B1-C-15U
150
150
150
68 Pin PLDCC
68 Pin CLDCC
68 Pin TQFP
Comm’l
Comm’l
Comm’l
PSD513B1-C-70J
PSD513B1-C-70L
PSD513B1-C-70U
70
70
70
68 Pin PLDCC
68 Pin CLDCC
68 Pin TQFP
Comm’l
Comm’l
Comm’l
PSD513B1-C-90JI
PSD513B1-C-90UI
90
90
68 Pin PLDCC
68 Pin TQFP
Industrial
Industrial
PSD513B1-C-15J
PSD513B1-C-15L
PSD513B1-C-15U
150
150
150
68 Pin PLDCC
68 Pin CLDCC
68 Pin TQFP
Comm’l
Comm’l
Comm’l
144
PSD5XX Family
Ordering Information
Part Number
PSD5XX
Product
Ordering
Information
(cont.)
Operating
Temperature
Range
Speed
(ns)
Package Type
ZPSD501B1-C-70J
ZPSD501B1-C-70L
ZPSD501B1-C-70U
70
70
70
68 Pin PLDCC
68 Pin CLDCC
80 Pin TQFP
Comm’l
Comm’l
Comm’l
ZPSD501B1-C-90JI
ZPSD501B1-C-90UI
90
90
68 Pin PLDCC
80 Pin TQFP
Industrial
Industrial
ZPSD501B1-C-15J
ZPSD501B1-C-15L
ZPSD501B1-C-15U
150
150
150
68 Pin PLDCC
68 Pin CLDCC
80 Pin TQFP
Comm’l
Comm’l
Comm’l
ZPSD501B1V-C-20J
ZPSD501B1V-C-20JI
ZPSD501B1V-C-20L
ZPSD501B1V-C-20U
ZPSD501B1V-C-20UI
200
200
200
200
200
68 Pin PLDCC
68 Pin PLDCC
68 Pin CLDCC
80 Pin TQFP
80 Pin TQFP
Comm’l
Industrial
Comm’l
Comm’l
Industrial
ZPSD501B1V-C-25J
ZPSD501B1V-C-25L
ZPSD501B1V-C-25U
250
250
250
68 Pin PLDCC
68 Pin CLDCC
80 Pin TQFP
Comm’l
Comm’l
Comm’l
ZPSD502B1-C-70J
ZPSD502B1-C-70L
ZPSD502B1-C-70U
70
70
70
68 Pin PLDCC
68 Pin CLDCC
80 Pin TQFP
Comm’l
Comm’l
Comm’l
ZPSD502B1-C-90JI
ZPSD502B1-C-90UI
90
90
68 Pin PLDCC
80 Pin TQFP
Industrial
Industrial
ZPSD502B1-C-15J
ZPSD502B1-C-15L
ZPSD502B1-C-15U
150
150
150
68 Pin PLDCC
68 Pin CLDCC
80 Pin TQFP
Comm’l
Comm’l
Comm’l
ZPSD502B1V-C-20J
ZPSD502B1V-C-20JI
ZPSD502B1V-C-20L
ZPSD502B1V-C-20U
ZPSD502B1V-C-20UI
200
200
200
200
200
68 Pin PLDCC
68 Pin PLDCC
68 Pin CLDCC
80 Pin TQFP
80 Pin TQFP
Comm’l
Industrial
Comm’l
Comm’l
Industrial
ZPSD502B1V-C-25J
ZPSD502B1V-C-25L
ZPSD502B1V-C-25U
250
250
250
68 Pin PLDCC
68 Pin CLDCC
80 Pin TQFP
Comm’l
Comm’l
Comm’l
ZPSD503B1-C-70J
ZPSD503B1-C-70L
ZPSD503B1-C-70U
70
70
70
68 Pin PLDCC
68 Pin CLDCC
80 Pin TQFP
Comm’l
Comm’l
Comm’l
ZPSD503B1-C-90JI
ZPSD503B1-C-90LI
ZPSD503B1-C-90UI
90
90
90
68 Pin PLDCC
68 Pin CLDCC
80 Pin TQFP
Industrial
Industrial
Industrial
ZPSD503B1-C-15J
ZPSD503B1-C-15L
ZPSD503B1-C-15U
150
150
150
68 Pin PLDCC
68 Pin CLDCC
80 Pin TQFP
Comm’l
Comm’l
Comm’l
145
PSD5XX Family
Ordering Information
Part Number
PSD5XX
Product
Ordering
Information
(cont.)
Operating
Temperature
Range
Speed
(ns)
Package Type
ZPSD503B1V-C-20J
ZPSD503B1V-C-20JI
ZPSD503B1V-C-20L
ZPSD503B1V-C-20U
ZPSD503B1V-C-20UI
200
200
200
200
200
68 Pin PLDCC
68 Pin PLDCC
68 Pin CLDCC
80 Pin TQFP
80 Pin TQFP
Comm’l
Industrial
Comm’l
Comm’l
Industrial
ZPSD503B1V-C-25J
ZPSD503B1V-C-25L
ZPSD503B1V-C-25U
250
250
250
68 Pin PLDCC
68 Pin CLDCC
80 Pin TQFP
Comm’l
Comm’l
Comm’l
ZPSD511B1-C-70J
ZPSD511B1-C-70L
ZPSD511B1-C-70U
70
70
70
68 Pin PLDCC
68 Pin CLDCC
80 Pin TQFP
Comm’l
Comm’l
Comm’l
ZPSD511B1-C-90JI
ZPSD511B1-C-90UI
90
90
68 Pin PLDCC
80 Pin TQFP
Industrial
Industrial
ZPSD511B1-C-15J
ZPSD511B1-C-15L
ZPSD511B1-C-15U
150
150
150
68 Pin PLDCC
68 Pin CLDCC
80 Pin TQFP
Comm’l
Comm’l
Comm’l
ZPSD511B1V-C-20J
ZPSD511B1V-C-20JI
ZPSD511B1V-C-20L
ZPSD511B1V-C-20U
ZPSD511B1V-C-20UI
200
200
200
200
200
68 Pin PLDCC
68 Pin PLDCC
68 Pin CLDCC
80 Pin TQFP
80 Pin TQFP
Comm’l
Industrial
Comm’l
Comm’l
Industrial
ZPSD511B1V-C-25J
ZPSD511B1V-C-25L
ZPSD511B1V-C-25U
250
250
250
68 Pin PLDCC
68 Pin CLDCC
80 Pin TQFP
Comm’l
Comm’l
Comm’l
ZPSD512B0-C-70J
ZPSD512B0-C-70L
ZPSD512B0-C-70U
70
70
70
68 Pin PLDCC
68 Pin CLDCC
80 Pin TQFP
Comm’l
Comm’l
Comm’l
ZPSD512B0-C-90JI
ZPSD512B0-C-90UI
90
90
68 Pin PLDCC
80 Pin TQFP
Industrial
Industrial
ZPSD512B0-C-15J
ZPSD512B0-C-15L
ZPSD512B0-C-15U
150
150
150
68 Pin PLDCC
68 Pin CLDCC
80 Pin TQFP
Comm’l
Comm’l
Comm’l
ZPSD512B1-C-70J
ZPSD512B1-C-70L
ZPSD512B1-C-70U
70
70
70
68 Pin PLDCC
68 Pin CLDCC
80 Pin TQFP
Comm’l
Comm’l
Comm’l
ZPSD512B1-C-90JI
ZPSD512B1-C-90UI
90
90
68 Pin PLDCC
80 Pin TQFP
Industrial
Industrial
ZPSD512B1-C-15J
ZPSD512B1-C-15L
ZPSD512B1-C-15U
150
150
150
68 Pin PLDCC
68 Pin CLDCC
80 Pin TQFP
Comm’l
Comm’l
Comm’l
146
PSD5XX Family
Ordering Information
Part Number
PSD5XX
Product
Ordering
Information
(cont.)
Operating
Temperature
Range
Speed
(ns)
Package Type
ZPSD512B1V-C-20J
ZPSD512B1V-C-20JI
ZPSD512B1V-C-20L
ZPSD512B1V-C-20U
ZPSD512B1V-C-20UI
200
200
200
200
200
68 Pin PLDCC
68 Pin PLDCC
68 Pin CLDCC
80 Pin TQFP
80 Pin TQFP
Comm’l
Industrial
Comm’l
Comm’l
Industrial
ZPSD512B1V-C-25J
ZPSD512B1V-C-25L
ZPSD512B1V-C-25U
250
250
250
68 Pin PLDCC
68 Pin CLDCC
80 Pin TQFP
Comm’l
Comm’l
Comm’l
ZPSD513B1-C-70J
ZPSD513B1-C-70L
ZPSD513B1-C-70U
70
70
70
68 Pin PLDCC
68 Pin CLDCC
80 Pin TQFP
Comm’l
Comm’l
Comm’l
ZPSD513B1-C-90JI
ZPSD513B1-C-90UI
90
90
68 Pin PLDCC
80 Pin TQFP
Industrial
Industrial
ZPSD513B1-C-15J
ZPSD513B1-C-15L
ZPSD513B1-C-15U
150
150
150
68 Pin PLDCC
68 Pin CLDCC
80 Pin TQFP
Comm’l
Comm’l
Comm’l
ZPSD513B1V-C-20J
ZPSD513B1V-C-20JI
ZPSD513B1V-C-20L
ZPSD513B1V-C-20U
ZPSD513B1V-C-20UI
200
200
200
200
200
68 Pin PLDCC
68 Pin PLDCC
68 Pin CLDCC
80 Pin TQFP
80 Pin TQFP
Comm’l
Industrial
Comm’l
Comm’l
Industrial
ZPSD513B1V-C-25J
ZPSD513B1V-C-25L
ZPSD513B1V-C-25U
250
250
250
68 Pin PLDCC
68 Pin CLDCC
80 Pin TQFP
Comm’l
Comm’l
Comm’l
147
PSD5XX Family
21.0
PSD5XX Functional Change:
A change has been implemented in the most recent silicon that improves the way that the
Image Register is updated. This change only applies to Event Count Mode for counter units
CTU0, CTU1, and CTU3.
Process
Change Notice,
October 1, 1998
Previous PSD5XX Silicon:
The Image Register was not updated with the actual event count upon exiting Freeze
mode. As a result, in certain circumstances, the Image Register may not have reflected the
actual event count. Although an incorrect count may have been read from the Image
Register at a given time, no event counts were ever lost because the microcontroller would
eventually read the correct value in the Image Register on subsequent freeze and read
cycles.
Current PSD5XX Silicon:
The Image register is now automatically updated with the actual count upon exiting the
Freeze mode. This ensures that on the very next freeze and read cycle, the microcontroller
will read the actual count from the Image register. There are two restrictions however:
1. If an event occurs within one timer clock period plus two CLKIN periods after the image
register is unfrozen, then the Image Register will not reflect that event on the very next
freeze and read cycle (timer clock period is defined on page 6-79 of the 1996 PSD data
book). Instead, the event will appear in the Image Register on the subsequent freeze
and read cycle.
2. The time between an unfreeze and the beginning of the next freeze has the same time
constraint as number one. There must be at least one timer clock period plus two CLKIN
periods between the end of one freeze cycle and the beginning of the next. This timing
can be controlled by software design.
To reduce the chance of getting a delayed count in the Image Register due to restriction
number 1, execute a software Load/Store command just prior to freezing and reading the
Image Register to force an update to the Image count.
Backwards Compatibility:
This improvement should have no impact on current designs unless these designs
were compensating for lost events. In such cases, compatibility is dependent on the
compensation method that was used. Please contact WSI at apphelp@wsiusa.com if you
think you have an issue or have any questions.
148
PSD5XX, ZPSD5XX
REVISION HISTORY
Table 1. Document Revision History
Date
Rev.
Description of Revision
Apr-1994
Jun-1995
Mar-1997
1.0 PSD5XX: Document written in the WSI format. Initial release
1.1 ZPSD5XX: Updated Specifications
1.2
1.3
ZPSD5XX Updated specifications
May-1998
Feb-1999
PSD5XX, ZPSD5XX Updated specifications, various speed grades removed
PSD5XX, ZPSD5XX Combined Data Sheets, eliminated military parts, eliminated various
speed grades, updated specifications.
1.4
1.5
PSD5XX, ZPSD5XX: 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
31-Jan-2002
2/3
PSD5XX, ZPSD5XX
Information furnished is believed to be accurate and reliable. However, STMicroelectronics assumes no responsibility for the consequences
of use of such information nor for any infringement of patents or other rights of third parties which may result from its use. No license is granted
by implication or otherwise under any patent or patent rights of STMicroelectronics. Specifications mentioned in this publication are subject
to change without notice. This publication supersedes and replaces all information previously supplied. STMicroelectronics products are not
authorized for use as critical components in life support devices or systems without express written approval of STMicroelectronics.
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