Datasheet X86C64SM, X86C64SI, X86C64S, X86C64PM, X86C64PI Datasheet (XICOR)

Preliminary Information

X86C64

Z8® Microcontroller Family Compatible

64K X86C64 8192 x 8 Bit

E2 Micro-Peripheral

FEATURES

• CONCURRENT READ WRITE

™

—Dual Plane Architecture

Isolates Read/Write Functions
Between Planes
Allows Continuous Execution of Code
From One Plane While Writing in the Other
Plane

• Multiplexed Address/Data Bus

—Direct Interface to Popular 8-bit

Microcontrollers, e.g. Zilog Z8 Family

• High Performance CMOS

—Fast Access Time, 120 ns
—Low Power

60 mA Maximum Active
200 µA Maximum Standby

• Software Data Protection

• Block Protect Register

—Individually Set Write Lock Out in 1K Blocks

• Toggle Bit

—Early End of Write Detection

• Page Mode Write

—Allows up to 32 Bytes to be Written in

One Write Cycle

• High Reliability

—Endurance: 10,000 Write Cycle
—Data Retention: 100 Years

DESCRIPTION

The X86C64 is an 8K x 8 E2PROM fabricated with
advanced CMOS Textured Poly Floating Gate Technol­ogy. The X86C64 features a Multiplexed Address and
Data bus allowing direct interface to a variety of popular
single-chip microcontrollers operating in expanded mul­tiplexed mode without the need for additional interface
circuitry.

The X86C64 is internally configured as two indepen­dent 4K x 8 memory arrays. This feature provides the
ability to perform nonvolatile memory updates in one
array and continue operation out of code stored in the
other array; effectively eliminating the need for an aux­iliary memory device for code storage.

To write to the X86C64, a three byte command
sequence must precede the byte(s) being written. The
X86C64 also provides a second generation software
data protection scheme called Block Protect. Block
Protect can provide write lockout of the entire device or
selected 1K blocks. There are eight, 1K x 8 blocks that
can be write protected individually in any combination
required by the user. Block Protect, in addition to Write
Control input, allows the different segments of the
memory to have varying degrees of alterability in nor­mal system operation.

FUNCTIONAL DIAGRAM

CE
R/W

DS
SEL

A8–A11

AS

Z8® is a registered trademark of Zilog Corporation
CONCURRENT READ WRITE™ is a trademark of Xicor, Inc.

© Xicor, 1991 Patents Pending Characteristics subject to change without notice

3819-2.1 7/29/96 T0/C1/D1 SH

CONTROL

LOGIC

L
A
T
C
H
E
S

Y DECODE

X
D

E
C
O
D
E

I/O & ADDRESS LATCHES AND BUFFERS

WC

SOFTWARE

DATA

PROTECT

1K BYTES
1K BYTES
1K BYTES
1K BYTES

1

A12

A12
A12

M
U

X

A/D0–A/D7

1K BYTES
1K BYTES
1K BYTES
1K BYTES

3819 FHD F02

X86C64

PIN DESCRIPTIONS
Address/Data (A/D0–A/D7)

Multiplexed low-order addresses and data. The ad­dresses flow into the device while AS is LOW. After AS
transitions from a LOW to HIGH the addresses are
latched. Once the addresses are latched these pins input
data or output data depending on DS, R/W, and CE.

Addresses (A8–A12)

High order addresses flow into the device when AS = V
and are latched when AS goes HIGH.

Chip Enable (CE)

The Chip Enable input must be HIGH to enable all read/
write operations. When CE is LOW and AS is HIGH, the
X86C64 is placed in the low power standby mode.

Data Strobe (DS)

When used with a Z8 the DS input is tied directly to the
DS output of the microcontroller.

Read/Write (R/W)

When used with a Z8 the R/W input is tied directly to the
R/W output of the microcontroller.

Address Strobe (AS)

Addresses flow through the latches to address decoders
when AS is LOW and are latched when AS transitions
from a LOW to HIGH.

Device Select (SEL)

Must be connected to VSS.

Write Control (WC)

The Write Control allows external circuitry to abort a
page load cycle once it has been initiated. This input is
useful in applications in which a power failure or proces­sor RESET could interrupt a page load cycle. In this
case, the microcontroller might drive all signals HIGH,
causing bad data to be latched into the E2PROM. If the
Write Control input is driven HIGH (before t

TBLC

Max)
after Read/Write (R/W) goes HIGH, the write cycle will
be aborted.

PIN CONFIGURATION

DIP/SOIC

NC

1

A12

IL

SEL
A/D0
A/D1
A/D2
A/D3
A/D4

V

NC
NC

WC

SS

2
3
4
5
6
7
8
9
10
11
12

X86C64

24
23
22
21
20
19
18
17
16
15
14
13

V

CC

R/W
AS
A8
A9
A11
DS
A10
CE
A/D7
A/D6
A/D5

3819 FHD F01

PIN NAMES

Symbol Description

AS Address Strobe
A/D0–A/D
A8–A

12

7

Address Inputs/Data I/O

Address Inputs
DS Data Strobe Input
R/W Read/Write Input
CE Chip Enable

WC Write Control
SEL Device Select—Connect to V

V

SS

V

CC

Ground

Supply Voltage

SS

3819 PGM T01

When WC is LOW (tied to VSS) the X86C64 will be
enabled to perform write operations. When WC is HIGH
normal read operations may be performed, but all at­tempts to write to the device will be disabled.

2

X86C64

PRINCIPLES OF OPERATION

The X86C64 is a highly integrated peripheral device for
a wide variety of single-chip microcontrollers. The
X86C64 provides 8K bytes of 5-volt E2PROM which can
be used either for Program Storage, Data Storage or a
combination of both in systems based upon Von
Neumann (86XX) architectures. The X86C64 incorpo­rates the interface circuitry normally needed to decode
the control signals and demultiplex the Address/Data
bus to provide a “ Seamless” interface.

The interface inputs on the X86C64 are configured such
that it is possible to directly connect them to the proper
interface signals of the appropriate single-chip
microcontroller.

The X86C64 is internally organized as two independent
planes of 4K bytes of memory with the A12 input select­ing which of the two planes of memory are to be
accessed. While the processor is executing code out of
one plane, write operations can take place in the other
plane, allowing the processor to continue execution of
code out of the X86C64 during a byte or page write to the
device.

The X86C64 also features an advanced implementation
of the Software Data Protection scheme, called Block
Protect, which allows the device to be broken into 8
independent sections of 1K bytes. Each of these sec­tions can be independently enabled for write operations;
thereby allowing certain sections of the device to be
secured so that updates can only occur in a controlled
environment (e.g. in an automotive application, only at
an authorized service center). The desired set-up con­figuration is stored in a nonvolatile register, ensuring the
configuration data will be maintained after the device is
powered down.

The X86C64 also features a Write Control input (WC),
which serves as an external control over the completion
of a previously initiated page load cycle.

DEVICE OPERATION

Zilog Z8 operation requires the microcontroller’s AS, DS
and R/W outputs tied to the X86C64 AS, DS and
R/W inputs respectively.

The rising edge of AS will latch the addresses for both a
read and write operation. The state of R/W output
determines the operation to be performed, with the DS
signal acting as a data strobe.

If R/W is HIGH and CE HIGH (read operation) data will
be output on A/D0–A/D7 after DS transitions LOW. If
R/W is LOW and CE is HIGH (write operation) data
presented at A/D0–A/D7 will be strobed into the X86C64
on the LOW to HIGH transition of DS.

Typical Application

X86C64Z8

24

V

CC

V

SS

12

3819 FHD F03

21

P10

22

P11

23

P12

24

P13

25

2

XTAL

3

EXTAL

P14
P15
P16
P17
P00
P01
P02
P03
P04
P07

AS
DS

R/W

26
27
28
13
14
15
16
17
20

9
8
7

7

A/D0

8

A/D1

9

A/D2

10

A/D3

11

A/D4

13

A/D5

14

A/D6

15

A/D7

21

A8

20

A9

17

A10

19

A11

2

A12

16

CE

5

WC

22

AS

18

DS

23

R/W

6

SEL

The X86C64 also features the industry standard 5-volt
E2PROM characteristics such a byte or page mode write
and toggle-bit polling.

3

X86C64

MODE SELECTION

CE DS R/W Mode I/O Power

V

SS

V

IL

V

IH

V

IH

X X Standby High Z Standby (CMOS)
X X Standby High Z Standby (TTL)

V

IL

V

IH

V

IL

Read D
Write D

PAGE WRITE OPERATION

Regardless of the microcontroller employed, the X86C64
supports page mode write operations. This allows the
microcontroller to write from one to thirty-two bytes of
data to the X86C64. Each individual write within a page
write operation must conform to the byte write timing

requirements. The falling edge of DS starts a timer
delaying the internal programming cycle 100 µs. There­fore, each successive write operation must begin within
100 µs of the last byte written. The following waveforms
illustrate the sequence and timing requirements.

Page Write Timing Sequence for DS Controlled Operation

OPERATION

CE

AS

A/D0–A/D

7

BYTE 0

A

IN

D

IN

BYTE 1

A

IN

BYTE 2 LAST BYTE READ (1)(2) AFTER tWC READY FOR

D

IN

A

D

IN

IN

A

OUT

IN

D

IN

IN

A

D

IN

IN

Active
Active

NEXT WRITE OPERATION

A

IN

A

IN

3819 PGM T08

A8–A

R/W

DS

12

A12=n

t

A12=n

BLC

A12=n

A12=n

A12=x

t

ADDR

WC

Notes: (1) For each successive write within a page write cycle A5–A12 must be the same.

(2) Although it is not illustrated, the microcontroller may interleave read operations between the individual byte writes within the page

write operation. Two responses are possible.
a. Reading from the same plane being written (A12 of Read = A12 of Write) is effectively a Toggle Bit Polling operation.
b. Reading from the opposite plane being written (A12 of Read ≠ A12 of Write) true data will be returned, facilitating the use of a
single memory component as both program and data store.

Next Address

3819 FHD F07

3819 FHD F07

4

X86C64

Toggle Bit Polling

Because the X86C64 typical write timing is less than the
specified 5 ms, Toggle Bit Polling has been provided to
determine the early end of write. During the internal
programming cycle I/O6 will toggle from one to zero and
zero to one on subsequent attempts to read the device.

Toggle Bit Polling DS Control

OPERATION

CE

AS

A/D0–A/D

A8–A

7

12

DS

LAST BYTE

WRITTEN

A

D

IN

A12=n

I/O6=X

A

D

IN

IN

A12=n

OUT

I/O6=X

A

IN

D

A12=n

When the internal cycle is complete the toggling will
cease and the device will be accessible for additional
read or write operations. Due to the dual plane architec­ture, reads for polling must occur in the plane that was
written; that is, the state of A12 during write must match
the state of A12 during polling.

OUT

I/O6=X

A

IN

A12=n

D

OUT

I/O6=X X68C64 READY FOR

A

D

IN

OUT

A12=n

NEXT OPERATION

A

IN

ADDR

R/W

3819 FHD F08

5

X86C64

DATA PROTECTION

The X86C64 provides two levels of data protection
through software control. There is a global software data
protection feature similar to the industry standard for
E2PROMs and a new Block Protect write lock out
protection providing a second level data security option.

Writing with SDP

WRITE AA

TO X555

WRITE 55

TO XAAA

WRITE A0

TO X555

X = A12:
A

= 1 IF DATA TO BE WRITTEN IS WITHIN

12

ADDRESS 1000 TO 1FFF.
A12 = 0 IF DATA TO BE WRITTEN IS WITHIN
ADDRESS 0000 TO 0FFF.

PERFORM BYTE
OR PAGE WRITE

OPERATIONS

WAIT t

WC

EXIT ROUTINE

3819 FHD F09

Software Data Protection

Software data protection (SDP) is employed to protect
the entire array against inadvertent writes. To write to
the X86C64, a three byte command sequence must
precede the byte(s) being written.

All write operations, both the command sequence and
any data write operations must conform to the page write
timing requirements.

Block Protect Write Lockout

The X86C64 provides a second level of data security
referred to as Block Protect write lockout. This is ac­cessed through an extension of the SDP command
sequence. Block Protect allows the user to lock out
writes to 1K x 8 blocks of memory. Unlike SDP which
prevents inadvertent writes, but still allows easy system
access to writing the memory, Block Protect will lock out
all attempts unless it is specifically disabled by the host.
This could be used to set a higher level of protection in
a system where a portion of the memory is used for
Program Store and another portion is used as Data
Store.

Setting write lockout is accomplished by writing a five
byte command sequence opening access to the Block
Protect Register (BPR). After the fifth byte is written the
user writes to the BPR selecting which blocks to protect
or unprotect. All write operations, both the command
sequence and writing the data to the BPR, must conform
to the page write timing requirements.

Block Protect Register Format

MSB LSB

7

1 = Protect, 0 = Unprotect Block Specified

5

6

43

2

1

0

BLOCK

ADDRESS
0000–03FF
0400–07FF
0800–0BFF
0C00–0FFF
1000–13FF
1400–17FF
1800–1BFF
1C00–1FFF

3819 FHD F11

Setting BPR Command Sequence

WRITE AA

TO X555

WRITE 55

TO XAAA

WRITE A0

TO X555

WRITE AA

TO X555

X = A12:
A

= 1 IF PROGRAM BEING EXECUTED IS

12

WITHIN 0000 TO 0FFF.
A

= 0 IF PROGRAM BEING EXECUTED

12

RESIDES WITHIN 1000 TO 1FFF.

WRITE C0

TO XAAA

WRITE BPR

MASK VALUE TO

ANY ADDRESS

WAIT t

WC

EXIT ROUTINE

3819 FHD F12

6

X86C64

ABSOLUTE MAXIMUM RATINGS*

Temperature Under Bias

X86C64........................................ –10°C to +85°C

X86C64I..................................... –65°C to +135°C

Storage Temperature ....................... –65°C to +150°C

Voltage on any Pin with

Respect to VSS............................... –1.0V to +7V

D.C. Output Current ............................................ 5 mA

Lead Temperature

*COMMENT

Stresses above those listed under “Absolute Maximum
Ratings” may cause permanent damage to the device.
This is a stress rating only and the 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 may affect device reli­ability.

(Soldering, 10 Seconds) ............................. 300°C

RECOMMENDED OPERATING CONDITIONS

Temperature Min. Max.

Commercial 0°C70°C

Industrial –40°C +85°C

Supply Voltage Limits

X86C64 5V ± 10%

3819 PGM T03

Military –55°C +125°C

3819 PGM T02

D.C. OPERATING CHARACTERISTICS (Over recommended operating conditions unless otherwise specified.)

Limits

Symbol Parameter Min. Max. Units Test Conditions

I

CC

I

SB1(CMOS)VCC

I

SB2(TTL)

I

LI

I

LO

(1)

V

lL

(1)

V

IH

V

OL

V

OH

VCC Current (Active) 60 mA CE = VIL, All I/O’s = Open,

Other Inputs = VCC, AS = V

IL

Current (Standby) 500 µA CE = VSS, All I/O’s = Open,Other

Inputs = V

CC

– 0.3V

VCC Current (Standby) 6 mA CE = VIH, All I/O’s = Open, Other

Inputs = V
Input Leakage Current 10 µAV
Output Leakage Current 10 µAV

= GND to V

IN
OUT

IH

CC

= GND to VCC, DS = V

IH

Input Low Voltage –1.0 0.8 V
Input High Voltage 2.0 VCC + 0.5 V
Output Low Voltage 0.4 V IOL = 2.1 mA
Output High Voltage 2.4 V IOH = –400 µA

3819 PGM T04

CAPACITANCE TA = 25°C, F = 1.0MHZ, VCC = 5V

Symbol Test Max. Units Conditions

(2)

C

I/O

(2)

C

IN

Input/Output Capacitance 10 pF V
Input Capacitance 6 pF V

POWER-UP TIMING

Symbol Parameter Max. Units

(2)

t

PUR

(2)

t

PUW

Notes: (1) VIL MIN and VIH MAX are for reference only and are not tested.

(2) This parameter is periodically sampled and not 100% tested.

Power-Up to Read 1 ms

Power-Up to Write 5 ms

7

I/O

IN

= 0V

= 0V

3819 PGM T05

3819 PGM T06

X86C64

A.C. CONDITIONS OF TEST

Input Pulse Levels 0V to 3.0V

EQUIVALENT A.C. TEST CIRCUIT

5.0V

Input Rise and
Fall Times 10ns

Input and Output
Timing Levels 1.5V

3819 PGM T07

Output

1370Ω

1923Ω

100pF

A.C. CHARACTERISTICS (Over the recommended operating conditions unless otherwise specified.)

DS Controlled Read Cycle

Symbol Parameter Min. Max. Units

PW
t

AS

t

AH

t

ACC

t

DHR

t

CS

PW
t

DSS

t

DSH

t

RWS

t

HZ

t

LZ

ASL

DSH

(3)

(3)

Address Strobe Pulse Width 80 ns
Address Setup Time 20 ns
Address Hold Time 30 ns
Data Access Time 120 ns
Data Hold Time 0 ns
CE Setup Time 7 ns

DS Pulse Width 150 ns
DS Setup Time 30 ns
DS Hold Time 20 ns
R/W Setup Time 20 ns
DS High to High Z Output 50 ns
DS Low to Low Z Output 0 ns

DS Controlled Read Cycle

3819 FHD F04

3819 PGM T09

CE

t

A

IN

A8–A

CS

t

AH

12

t

DSS

PW

ASL

AS

t

AS

A/D0–A/D

Note: (3) This parameter is periodically sampled and not 100% tested.

A8–A

12

R/W

DS

7

t

RWS

8

t

ACC

PW

DSH

D

OUT

t

DSH

t

DSH

t

DSH

t

DHR

t

HZ

3819 FHD F05

X86C64

DS Controlled Write Cycle

Symbol Parameter Min. Max. Units

PW
t

AS

t

AH

t

DSW

t

DHW

t

CS

PW
t

WC

t

DSS

t

RWS

t

DSH

t

BLC

ASH

DSH

Address Strobe Pulse Width 80 ns
Address Setup Time 20 ns
Address Hold Time 30 ns
Data Setup Time 50 ns
Data Hold Time 30 ns
CE Setup Time 7 ns
DS Pulse Width 120 ns
Write Cycle Time 5 ms
Enable Setup Time 30 ns
R/W Setup Time 20 ns
DS Hold Time 20 ns
Byte Load Time (Page Write) 0.5 100 µs

DS Controlled Write Cycle

CE

PW

AS

A/D0–A/D

A8–A

7

12

ASH

t

AS

t

RWS

t

A

IN

A8–A

CS

t

AH

12

t

DSS

t

DSW

3819 PGM T10

t

DSH
t

DSH

D

IN

t

DHW

t

DSH

R/W

DS

PW

DSH

Note: (4) tWC is the minimum cycle time to be allowed from the system perspective unless polling techniques are used. It is the maximum

time the device requires to automatically complete the internal write operation.

9

3819 FHD F06

X86C64

PACKAGING INFORMATION

PIN 1 INDEX

PIN 1

24-LEAD PLASTIC DUAL IN-LINE PACKAGE TYPE P

1.265 (32.13)

1.230 (31.24)

1.100 (27.94)
REF.

0.557 (14.15)

0.530 (13.46)

0.080 (2.03)

0.065 (1.65)

SEATING

PLANE

0.150 (3.81)

0.125 (3.18)

0.110 (2.79)

0.090 (2.29)

0.065 (1.65)

0.040 (1.02)

0.625 (15.87)

0.600 (15.24)

TYP. 0.010 (0.25)

0°

15°

NOTE:

1. ALL DIMENSIONS IN INCHES (IN PARENTHESES IN MILLIMETERS)

2. PACKAGE DIMENSIONS EXCLUDE MOLDING FLASH

0.162 (4.11)

0.140 (3.56)

0.030 (0.76)

0.015 (0.38)

0.022 (0.56)

0.014 (0.36)

3926 FHD F03

10

X86C64

PACKAGING INFORMATION

24-LEAD PLASTIC SMALL OUTLINE GULL WING PACKAGE TYPE S

0° – 8°

PIN 1 INDEX

(4X) 7°

0.050 (1.27)

0.010 (0.25)

0.020 (0.50)

0.015 (0.40)

0.050 (1.27)

PIN 1

X 45°

0.014 (0.35)

0.020 (0.50)

0.598 (15.20)

0.610 (15.49)

0.009 (0.22)

0.013 (0.33)

0.420"

0.290 (7.37)

0.299 (7.60)

0.092 (2.35)

0.105 (2.65)

0.003 (0.10)

0.012 (0.30)

0.050" TYPICAL

0.393 (10.00)

0.420 (10.65)

0.050"

TYPICAL

0.030" TYPICAL

FOOTPRINT

24 PLACES

NOTE: ALL DIMENSIONS IN INCHES (IN PARENTHESES IN MILLIMETERS)

3926 FHD F24

11

X86C64

ORDERING INFORMATION

X86C64 X X X

Device

VCC Limits

Blank = 5V ± 10%

Temperature Range

Blank = Commercial = 0°C to +70°C
I = Industrial = –40°C to +85°C
M = Military = –55°C to +128°C

Package

P = 24-Lead Plastic DIP
S = 24-Lead Plastic SOIC

LIMITED WARRANTY

Devices sold by Xicor, Inc. are covered by the warranty and patent indemnification provisions appearing in its Terms of Sale only. Xicor, Inc. makes no warranty,
express, statutory, implied, or by description regarding the information set forth herein or regarding the freedom of the described devices from patent infringement.
Xicor, Inc. makes no warranty of merchantability or fitness for any purpose. Xicor, Inc. reserves the right to discontinue production and change specifications and
prices at any time and without notice.

Xicor, Inc. assumes no responsibility for the use of any circuitry other than circuitry embodied in a Xicor, Inc. product. No other circuits, patents, licenses are
implied.

U.S. PATENTS

Xicor products are covered by one or more of the following U.S. Patents: 4,263,664; 4,274,012; 4,300,212; 4,314,265; 4,326,134; 4,393,481; 4,404,475;
4,450,402; 4,486,769; 4,488,060; 4,520,461; 4,533,846; 4,599,706; 4,617,652; 4,668,932; 4,752,912; 4,829, 482; 4,874, 967; 4,883, 976. Foreign patents and
additional patents pending.

LIFE RELATED POLICY

In situations where semiconductor component failure may endanger life, system designers using this product should design the system with appropriate error
detection and correction, redundancy and back-up features to prevent such an occurence.

Xicor's products are not authorized for use in critical components in life support devices or systems.

1. Life support devices or systems are devices or systems which, (a) are intended for surgical implant into the body, or (b) support or sustain life, and whose
failure to perform, when properly used in accordance with instructions for use provided in the labeling, can be reasonably expected to result in a significant
injury to the user.

2. A critical component is any component of a life support device or system whose failure to perform can be reasonably expected to cause the failure of the life
support device or system, or to affect its safety or effectiveness.

12