CATALYST CAT28C64BLA-90T

H
EE
GEN FR
ALO
CAT28C64B
64K-Bit CMOS PARALLEL EEPROM
LE
A D F R E ETM
FEATURES
■ Fast read access times:
■ Commercial, industrial and automotive
– 90/120/150ns
temperature ranges
■ Low power CMOS dissipation:
■ Automatic page write operation:
– Active: 25 mA max.
– Standby: 100 µA max.
– 1 to 32 bytes in 5ms
– Page load timer
■ Simple write operation:
■ End of write detection:
– On-chip address and data latches
– Self-timed write cycle with auto-clear
– Toggle bit
– DATA polling
■ Fast write cycle time:
■ 100,000 program/erase cycles
– 5ms max.
■ 100 year data retention
■ CMOS and TTL compatible I/O
■ Hardware and software write protection
DESCRIPTION
The CAT28C64B is manufactured using Catalyst’s
advanced CMOS floating gate technology. It is designed
to endure 100,000 program/erase cycles and has a data
retention of 100 years. The device is available in JEDECapproved 28-pin DIP, TSOP, SOIC, or, 32-pin PLCC
package .
The CAT28C64B is a fast, low power, 5V-only CMOS
Parallel EEPROM organized as 8K x 8-bits. It requires a
simple interface for in-system programming. On-chip
address and data latches, self-timed write cycle with
auto-clear and VCC power up/down write protection
eliminate additional timing and protection hardware.
DATA Polling and Toggle status bits signal the start and
end of the self-timed write cycle. Additionally, the
CAT28C64B features hardware and software write
protection.
BLOCK DIAGRAM
A5–A12
ADDR. BUFFER
& LATCHES
ROW
DECODER
VCC
INADVERTENT
WRITE
PROTECTION
HIGH VOLTAGE
GENERATOR
CE
OE
WE
CONTROL
LOGIC
32 BYTE PAGE
REGISTER
I/O BUFFERS
TIMER
A0–A4
8,192 x 8
EEPROM
ARRAY
DATA POLLING
AND
TOGGLE BIT
ADDR. BUFFER
& LATCHES
© 2005 by Catalyst Semiconductor, Inc.
Characteristics subject to change without notice
I/O0–I/O7
COLUMN
DECODER
1
Doc. No. 1011, Rev. F
CAT28C64B
PIN CONFIGURATION
DIP Package (P, L)
SOIC Package (J, W) (K, X)
NC
A12
A7
A6
1
2
3
4
28
27
26
25
VCC
WE
NC
A8
A5
5
6
7
8
24
A9
A11
9
10
11
12
20
13
14
16
15
A4
A3
A2
A1
A0
I/O0
I/O1
I/O2
VSS
23
22
21
19
18
17
NC
1
28
VCC
A12
A7
2
3
27
26
WE
NC
A6
4
25
A8
A5
A4
5
6
24
23
A9
A11
A3
7
22
OE
A2
A1
8
9
21
20
A10
A0
10
19
I/O6
I/O5
I/O0
I/O1
11
12
18
17
I/O6
I/O4
I/O3
I/O2
13
16
I/O4
VSS
14
15
I/O3
OE
A10
CE
I/O7
NC
A7
A12
NC
NC
VCC
WE
4 3 2 1 32 31 30
5
29
6
28
7
27
8
26
9
25
TOP VIEW
10
24
11
23
12
22
13
21
14 15 16 17 18 19 20
A8
A9
A11
NC
OE
A10
CE
I/O7
I/O6
OE
A11
A9
A8
NC
WE
VCC
NC
A12
A7
A6
A5
A4
A3
28
27
26
25
24
23
22
21
20
19
18
17
16
15
1
2
3
4
5
6
7
8
9
10
11
12
13
14
I/O1
I/O2
VSS
NC
I/O3
I/O4
I/O5
A2
A1
A0
NC
I/O0
PIN FUNCTIONS
Pin Name
Function
Pin Name
Function
A0–A12
Address Inputs
WE
Write Enable
I/O0–I/O7
Data Inputs/Outputs
VCC
5 V Supply
CE
Chip Enable
VSS
Ground
OE
Output Enable
NC
No Connect
Doc. No. 1011, Rev. F
I/O5
TSOP Package (8mm x 13.4mm) (T13, H13)
PLCC Package (N, G)
A6
A5
A4
A3
CE
I/O7
2
A10
CE
I/O7
I/O6
I/O5
I/O4
I/O3
GND
I/O2
I/O1
I/O0
A0
A1
A2
CAT28C64B
ABSOLUTE MAXIMUM RATINGS*
*COMMENT
Temperature Under Bias ................. –55°C to +125°C
Stresses above those listed under “Absolute Maximum
Ratings” may cause permanent damage to the device.
These are stress ratings only, and functional operation
of the device at these or any other conditions outside of
those listed in the operational sections of this specification is not implied. Exposure to any absolute maximum
rating for extended periods may affect device performance and reliability.
Storage Temperature ....................... –65°C to +150°C
Voltage on Any Pin with
Respect to Ground(2) ........... –2.0V to +VCC + 2.0V
VCC with Respect to Ground ............... –2.0V to +7.0V
Package Power Dissipation
Capability (Ta = 25°C) ................................... 1.0W
Lead Soldering Temperature (10 secs) ............ 300°C
Output Short Circuit Current(3) ........................ 100 mA
RELIABILITY CHARACTERISTICS
Symbol
NEND(1)
TDR
(1)
VZAP(1)
ILTH
(1)(4)
Parameter
Min.
Max.
Units
Test Method
Endurance
105
Cycles/Byte
MIL-STD-883, Test Method 1033
Data Retention
100
Years
MIL-STD-883, Test Method 1008
ESD Susceptibility
2000
Volts
MIL-STD-883, Test Method 3015
Latch-Up
100
mA
JEDEC Standard 17
MODE SELECTION
Mode
CE
WE
OE
Read
L
H
Byte Write (WE Controlled)
L
Byte Write (CE Controlled)
I/O
Power
L
DOUT
ACTIVE
H
DIN
ACTIVE
L
H
DIN
ACTIVE
Standby, and Write Inhibit
H
X
X
High-Z
STANDBY
Read and Write Inhibit
X
H
H
High-Z
ACTIVE
CAPACITANCE TA = 25°C, f = 1.0 MHz, VCC = 5V
Symbol
Test
Max.
Units
Conditions
CI/O(1)
Input/Output Capacitance
10
pF
VI/O = 0V
CIN(1)
Input Capacitance
6
pF
VIN = 0V
Note:
(1) This parameter is tested initially and after a design or process change that affects the parameter.
(2) The minimum DC input voltage is –0.5V. During transitions, inputs may undershoot to –2.0V for periods of less than 20 ns. Maximum DC
voltage on output pins is VCC +0.5V, which may overshoot to VCC +2.0V for periods of less than 20 ns.
(3) Output shorted for no more than one second. No more than one output shorted at a time.
(4) Latch-up protection is provided for stresses up to 100mA on address and data pins from –1V to VCC +1V.
3
Doc. No. 1011, Rev. F
CAT28C64B
D.C. OPERATING CHARACTERISTICS
VCC = 5V ±10%, unless otherwise specified.
Limits
Symbol
Parameter
Min.
Typ.
Max.
Units
Test Conditions
ICC
VCC Current (Operating, TTL)
30
mA
CE = OE = VIL,
f = 1/tRC min, All I/O’s Open
ICCC(1)
VCC Current (Operating, CMOS)
25
mA
CE = OE = VILC,
f = 1/tRC min, All I/O’s Open
ISB
VCC Current (Standby, TTL)
1
mA
CE = VIH, All I/O’s Open
ISBC(2)
VCC Current (Standby, CMOS)
100
µA
CE = VIHC,
All I/O’s Open
ILI
Input Leakage Current
–10
10
µA
VIN = GND to VCC
ILO
Output Leakage Current
–10
10
µA
VOUT = GND to VCC,
CE = VIH
VIH(2)
High Level Input Voltage
2
VCC +0.3
V
VIL(1)
Low Level Input Voltage
–0.3
0.8
V
VOH
High Level Output Voltage
2.4
VOL
Low Level Output Voltage
VWI
Write Inhibit Voltage
0.4
3.5
IOH = –400µA
V
IOL = 2.1mA
V
Note:
(1) VILC = –0.3V to +0.3V.
(2) VIHC = VCC –0.3V to VCC +0.3V.
Doc. No. 1011, Rev. F
V
4
CAT28C64B
A.C. CHARACTERISTICS, Read Cycle
VCC = 5V ±10%, unless otherwise specified.
28C64B-90
Symbol Parameter
Min.
Max.
90
28C64B-12
Min.
Max.
120
28C64B-15
Min.
Max.
150
Units
tRC
Read Cycle Time
ns
tCE
CE Access Time
90
120
150
ns
tAA
Address Access Time
90
120
150
ns
tOE
OE Access Time
50
60
70
ns
CE Low to Active Output
0
0
0
ns
tOLZ(1)
OE Low to Active Output
0
0
0
ns
tHZ(1)(2)
CE High to High-Z Output
50
50
50
ns
tOHZ(1)(2)
OE High to High-Z Output
50
50
50
ns
tOH(1)
Output Hold from Address Change
tLZ
(1)
0
0
0
ns
Figure 1. A.C. Testing Input/Output Waveform(3)
VCC - 0.3V
2.0 V
INPUT PULSE LEVELS
REFERENCE POINTS
0.8 V
0.0 V
Figure 2. A.C. Testing Load Circuit (example)
1.3V
1N914
3.3K
DEVICE
UNDER
TEST
OUT
CL = 100 pF
CL INCLUDES JIG CAPACITANCE
Note:
(1) This parameter is tested initially and after a design or process change that affects the parameter.
(2) Output floating (High-Z) is defined as the state when the external data line is no longer driven by the output buffer.
(3) Input rise and fall times (10% and 90%) < 10 ns.
5
Doc. No. 1011, Rev. F
CAT28C64B
A.C. CHARACTERISTICS, Write Cycle
VCC = 5V ±10%, unless otherwise specified.
28C64B-90
Parameter
tWC
Write Cycle Time
tAS
Address Setup Time
0
0
0
ns
tAH
Address Hold Time
100
100
100
ns
tCS
CE Setup Time
0
0
0
ns
CE Hold Time
0
0
0
ns
CE Pulse Time
110
110
110
ns
tOES
OE Setup Time
0
0
0
ns
tOEH
OE Hold Time
0
0
0
ns
tWP(2)
WE Pulse Width
110
110
110
ns
tDS
Data Setup Time
60
60
60
ns
tDH
Data Hold Time
0
0
0
ns
tINIT(1)
Write Inhibit Period After Power-up
5
10
5
10
5
10
ms
tBLC(1)(3)
Byte Load Cycle Time
.05
100
.05
100
.05
100
µs
tCW
(2)
Max.
Min.
5
Max.
28C64B-15
Symbol
tCH
Min.
28C64B-12
Min.
5
Max.
5
Units
ms
Note:
(1) This parameter is tested initially and after a design or process change that affects the parameter.
(2) A write pulse of less than 20ns duration will not initiate a write cycle.
(3) A timer of duration tBLC max. begins with every LOW to HIGH transition of WE. If allowed to time out, a page or byte write will begin;
however a transition from HIGH to LOW within tBLC max. stops the timer.
Doc. No. 1011, Rev. F
6
CAT28C64B
Byte Write
DEVICE OPERATION
A write cycle is executed when both CE and WE are low,
and OE is high. Write cycles can be initiated using either
WE or CE, with the address input being latched on the
falling edge of WE or CE, whichever occurs last. Data,
conversely, is latched on the rising edge of WE or CE,
whichever occurs first. Once initiated, a byte write cycle
automatically erases the addressed byte and the new
data is written within 5 ms.
Read
Data stored in the CAT28C64B is transferred to the data
bus when WE is held high, and both OE and CE are held
low. The data bus is set to a high impedance state when
either CE or OE goes high. This 2-line control architecture can be used to eliminate bus contention in a system
environment.
Figure 3. Read Cycle
tRC
ADDRESS
tCE
CE
tOE
OE
VIH
tLZ
WE
tOHZ
DATA OUT
tHZ
tOH
tOLZ
HIGH-Z
DATA VALID
DATA VALID
tAA
Figure 4. Byte Write Cycle [WE Controlled]
tWC
ADDRESS
tAS
tAH
tCH
tCS
CE
OE
tOES
tWP
tOEH
WE
tBLC
DATA OUT
DATA IN
HIGH-Z
DATA VALID
tDS
tDH
7
Doc. No. 1011, Rev. F
CAT28C64B
Page Write
(which can be loaded in any order) during the first and
subsequent write cycles. Each successive byte load
cycle must begin within tBLC MAX of the rising edge of the
preceding WE pulse. There is no page write window
limitation as long as WE is pulsed low within tBLC MAX.
The page write mode of the CAT28C64B (essentially an
extended BYTE WRITE mode) allows from 1 to 32 bytes
of data to be programmed within a single EEPROM write
cycle. This effectively reduces the byte-write time by a
factor of 32.
Upon completion of the page write sequence, WE must
stay high a minimum of tBLC MAX for the internal automatic program cycle to commence. This programming
cycle consists of an erase cycle, which erases any data
that existed in each addressed cell, and a write cycle,
which writes new data back into the cell. A page write will
only write data to the locations that were addressed and
will not rewrite the entire page.
Following an initial WRITE operation (WE pulsed low, for
tWP, and then high) the page write mode can begin by
issuing sequential WE pulses, which load the address
and data bytes into a 32 byte temporary buffer. The page
address where data is to be written, specified by bits A5
to A12, is latched on the last falling edge of WE. Each
byte within the page is defined by address bits A0 to A4
Figure 5. Byte Write Cycle [CE Controlled]
tWC
ADDRESS
tAS
tAH
tBLC
tCW
CE
tOEH
OE
tCS
tOES
tCH
WE
HIGH-Z
DATA OUT
DATA IN
DATA VALID
tDS
tDH
Figure 6. Page Mode Write Cycle
OE
CE
t BLC
t WP
WE
ADDRESS
t WC
I/O
LAST BYTE
BYTE 0
Doc. No. 1011, Rev. F
BYTE 1
BYTE 2
8
BYTE n
BYTE n+1
BYTE n+2
CAT28C64B
DATA Polling
Toggle Bit
DATA polling is provided to indicate the completion of
write cycle. Once a byte write or page write cycle is
initiated, attempting to read the last byte written will
output the complement of that data on I/O7 (I/O0–I/O6
are indeterminate) until the programming cycle is complete. Upon completion of the self-timed write cycle, all
I/O’s will output true data during a read cycle.
In addition to the DATA Polling feature, the device offers
an additional method for determining the completion of
a write cycle. While a write cycle is in progress, reading
data from the device will result in I/O6 toggling between
one and zero. However, once the write is complete, I/O6
stops toggling and valid data can be read from the
device.
Figure 7. DATA Polling
ADDRESS
CE
WE
tOEH
tOES
tOE
OE
tWC
I/O7
DIN = X
DOUT = X
DOUT = X
Figure 8. Toggle Bit
WE
CE
tOEH
tOES
tOE
OE
I/O6
(1)
(1)
tWC
Note:
(1) Beginning and ending state of I/O6 is indeterminate.
9
Doc. No. 1011, Rev. F
CAT28C64B
HARDWARE DATA PROTECTION
(4) Noise pulses of less than 20 ns on the WE or CE
inputs will not result in a write cycle.
The following is a list of hardware data protection features
that are incorporated into the CAT28C64B.
SOFTWARE DATA PROTECTION
(1) VCC sense provides for write protection when VCC
falls below 3.5V min.
The CAT28C64B features a software controlled data
protection scheme which, once enabled, requires a data
algorithm to be issued to the device before a write can be
performed. The device is shipped from Catalyst with the
software protection NOT ENABLED (the CAT28C64B is
in the standard operating mode).
(2) A power on delay mechanism, tINIT (see AC
characteristics), provides a 5 to 10 ms delay before
a write sequence, after VCC has reached 3.5V min.
(3) Write inhibit is activated by holding any one of OE
low, CE high or WE high.
Figure 9. Write Sequence for Activating Software
Data Protection
WRITE DATA:
ADDRESS:
WRITE DATA:
ADDRESS:
WRITE DATA:
ADDRESS:
Figure 10. Write Sequence for Deactivating
Software Data Protection
WRITE DATA:
AA
ADDRESS:
1555
WRITE DATA:
55
ADDRESS:
0AAA
WRITE DATA:
A0
ADDRESS:
1555
WRITE DATA:
SOFTWARE DATA
(1)
PROTECTION ACTIVATED
ADDRESS:
XX
WRITE DATA:
TO ANY ADDRESS
ADDRESS:
WRITE LAST BYTE
TO
LAST ADDRESS
WRITE DATA:
WRITE DATA:
ADDRESS:
AA
1555
55
0AAA
80
1555
AA
1555
55
0AAA
20
1555
Note:
(1) Write protection is activated at this point whether or not any more writes are completed. Writing to addresses must occur within tBLC
Max., after SDP activation.
Doc. No. 1011, Rev. F
10
CAT28C64B
To activate the software data protection, the device must
be sent three write commands to specific addresses with
specific data (Figure 9). This sequence of commands
(along with subsequent writes) must adhere to the page
write timing specifications (Figure 11). Once this is done,
all subsequent byte or page writes to the device must be
preceded by this same set of write commands. The data
protection mechanism is activated until a deactivate
sequence is issued regardless of power on/off transitions.
This gives the user added inadvertent write protection
on power-up in addition to the hardware protection
provided.
To allow the user the ability to program the device with
an EEPROM programmer (or for testing purposes) there
is a software command sequence for deactivating the
data protection. The six step algorithm (Figure 10) will
reset the internal protection circuitry, and the device will
return to standard operating mode (Figure 12 provides
reset timing). After the sixth byte of this reset sequence
has been issued, standard byte or page writing can
commence.
Figure 11. Software Data Protection Timing
DATA
ADDRESS
AA
1555
55
0AAA
tWC
A0
1555
CE
tWP
tBLC
BYTE OR
PAGE
WRITES
ENABLED
WE
Figure 12. Resetting Software Data Protection Timing
DATA
ADDRESS
AA
1555
55
0AAA
80
1555
AA
1555
55
0AAA
20
1555
tWC
SDP
RESET
CE
DEVICE
UNPROTECTED
WE
Speed
90: 90ns
12: 120ns
15: 150ns
11
Doc. No. 1011, Rev. F
CAT28C64B
ORDERING INFORMATION
Prefix
Device #
Suffix
CAT
28C64B
N
Optional
Company
ID
Product
Number
I
Temperature Range
Blank = Commercial (0˚C to +70˚C)
I = Industrial (-40˚C to +85˚C)
A = Automotive (-40˚ to +105˚C)*
Package
P: PDIP
J: SOIC (JEDEC)
K: SOIC (EIAJ)
N: PLCC
T13: TSOP (8mmx13.4mm)
L: PDIP (Lead free, Halogen free)
W: SOIC (JEDEC) (Lead free, Halogen free)
X: SOIC (EIAJ) (Lead free, Halogen free)
G: PLCC (Lead free, Halogen free)
H13: TSOP (8mmx13.4mm) (Lead free, Halogen free)
-15
T
Tape & Reel
Speed
90: 90ns
12: 120ns
15: 150ns
* -40˚C to +125˚C is available upon request
Notes:
(1) The device used in the above example is a CAT28C64BNI-15T (PLCC, Industrial temperature, 150 ns Access Time, Tape & Reel).
Doc. No. 1011, Rev. F
12
REVISION HISTORY
Date
3/29/2004
Revision Comments
B
Added Green packages in all areas.
04/19/04
C
Delete data sheet designation
Update Block Diagram
Update Ordering Information
Update Revision History
Update Rev Number
11/16/04
D
Add 90: 90ns speed to Ordering Information
02/28/05
E
Edit Ordering Information
03/18/05
F
Edit Description
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Publication #:
Revison:
Issue date:
1011
F
03/18/05