AEC Q100 Grade 1 Compliant
This product conforms to specifications per the terms of the Ramtron Ramtron International Corporation
standard warranty. The product has completed Ramtron‟s internal 1850 Ramtron Drive, Colorado Springs, CO 80921
qualification testing and has reached production status. (800) 545-FRAM, (719) 481-7000
Rev. 3.0 http://www.ramtron.com
Sept. 2011 Page 1 of 13
FM25CL64B – Automotive Temp.
64Kb FRAM Serial 3V Memory
Features
64K bit Ferroelectric Nonvolatile RAM
Organized as 8,192 x 8 bits
High Endurance 10 Trillion (1013) Read/Writes
NoDelay™ Writes
Advanced High-Reliability Ferroelectric Process
Fast Serial Peripheral Interface - SPI
Up to 16 MHz Frequency
Direct Hardware Replacement for EEPROM
SPI Mode 0 & 3 (CPOL, CPHA=0,0 & 1,1)
Sophisticated Write Protection Scheme
Hardware Protection
Software Protection
Low Power Consumption
Low Voltage Operation 3.0-3.6V
6 A Standby Current (+85C)
Industry Standard Configuration
Automotive Temperature -40C to +125C
o Qualified to AEC Q100 Specification
“Green”/RoHS 8-pin SOIC
Description
The FM25CL64B is a 64-kilobit nonvolatile memory
employing an advanced ferroelectric process. A
ferroelectric random access memory or FRAM is
nonvolatile and performs reads and writes like a
RAM. It provides reliable data retention for years
while eliminating the complexities, overhead, and
system level reliability problems caused by
EEPROM and other nonvolatile memories.
The FM25CL64B performs write operations at bus
speed. No write delays are incurred. Data is written to
the memory array immediately after each byte has
been transferred to the device. The next bus cycle
may commence without the need for data polling.
The FM25CL64B is capable of supporting 1013
read/write cycles, or 10 million times more write
cycles than EEPROM.
These capabilities make the FM25CL64B ideal for
nonvolatile memory applications requiring frequent
or rapid writes. Examples range from data collection,
where the number of write cycles may be critical, to
demanding automotive controls where the long write
time of EEPROM can cause data loss.
The FM25CL64B provides substantial benefits to
users of serial EEPROM as a hardware drop-in
replacement. The FM25CL64B uses the high-speed
SPI bus, which enhances the high-speed write
capability of FRAM technology. Device
specifications are guaranteed over the automotive
temperature range of -40°C to +125°C.
Pin Configuration
Pin Name
Function
/CS
Chip Select
/WP
Write Protect
/HOLD
Hold
SCK
Serial Clock
SI
Serial Data Input
SO
Serial Data Output
VDD
Supply Voltage
VSS
Ground
Ordering Information
FM25CL64B-GA
“Green”/RoHS 8-pin SOIC,
Automotive Grade 1
FM25CL64B-GATR
“Green”/RoHS 8-pin SOIC,
Automotive Grade 1,
Tape & Reel
CS
SO
WP
VSS
VDD
HOLD
SCK
SI
1
2
3
4
8
7
6
5
FM25CL64B - Automotive Temp.
Rev. 3.0
Sept. 2011 Page 2 of 13
Instruction Decode
Clock Generator
Control Logic
Write Protect
Instruction Register
Address Register
Counter
`
1,024 x 64
FRAM Array
13
Data I/O Register
8
Nonvolatile Status
Register
3
WP
CS
HOLD
SCK
SOSI
Figure 1. Block Diagram
Pin Descriptions
Pin Name
I/O
Description
/CS
Input
Chip Select: This active low input activates the device. When high, the device enters
low-power standby mode, ignores other inputs, and all outputs are tri-stated. When
low, the device internally activates the SCK signal. A falling edge on /CS must occur
prior to every op-code.
SCK
Input
Serial Clock: All I/O activity is synchronized to the serial clock. Inputs are latched on
the rising edge and outputs occur on the falling edge. Since the device is static, the
clock frequency may be any value between 0 and 16 MHz and may be interrupted at
any time.
/HOLD
Input
Hold: The /HOLD pin is used when the host CPU must interrupt a memory operation
for another task. When /HOLD is low, the current operation is suspended. The device
ignores any transition on SCK or /CS. All transitions on /HOLD must occur while
SCK is low.
/WP
Input
Write Protect: This active low pin prevents write operations to the Status Register.
This is critical since other write protection features are controlled through the Status
Register. A complete explanation of write protection is provided below. *Note that the
function of /WP is different from the FM25040 where it prevents all writes to the part.
SI
Input
Serial Input: All data is input to the device on this pin. The pin is sampled on the
rising edge of SCK and is ignored at other times. It should always be driven to a valid
logic level to meet IDD specifications.
* SI may be connected to SO for a single pin data interface.
SO
Output
Serial Output: This is the data output pin. It is driven during a read and remains tri-
stated at all other times including when /HOLD is low. Data transitions are driven on
the falling edge of the serial clock.
* SO may be connected to SI for a single pin data interface.
VDD
Supply
Power Supply (3.0V to 3.6V)
VSS
Supply
Ground
FM25CL64B - Automotive Temp.
Rev. 3.0
Sept. 2011 Page 3 of 13
Overview
The FM25CL64B is a serial FRAM memory. The
memory array is logically organized as 8,192 x 8 and
is accessed using an industry standard Serial
Peripheral Interface or SPI bus. Functional operation
of the FRAM is similar to serial EEPROMs. The
major difference between the FM25CL64B and a
serial EEPROM with the same pinout is the FRAM‟s
superior write performance.
Memory Architecture
When accessing the FM25CL64B, the user addresses
8,192 locations of 8 data bits each. These data bits
are shifted serially. The addresses are accessed using
the SPI protocol, which includes a chip select (to
permit multiple devices on the bus), an op-code, and
a two-byte address. The upper 3 bits of the address
range are „don‟t care‟ values. The complete address
of 13-bits specifies each byte address uniquely.
Most functions of the FM25CL64B either are
controlled by the SPI interface or are handled
automatically by on-board circuitry. The access time
for memory operation is essentially zero, beyond the
time needed for the serial protocol. That is, the
memory is read or written at the speed of the SPI bus.
Unlike an EEPROM, it is not necessary to poll the
device for a ready condition since writes occur at bus
speed. So, by the time a new bus transaction can be
shifted into the device, a write operation will be
complete. This is explained in more detail in the
interface section.
Users expect several obvious system benefits from
the FM25CL64B due to its fast write cycle and high
endurance as compared with EEPROM. In addition
there are less obvious benefits as well. For example
in a high noise environment, the fast-write operation
is less susceptible to corruption than an EEPROM
since it is completed quickly. By contrast, an
EEPROM requiring milliseconds to write is
vulnerable to noise during much of the cycle.
Note that the FM25CL64B contains no power
management circuits other than a simple internal
power-on reset. It is the user‟s responsibility to
ensure that VDD is within datasheet tolerances to
prevent incorrect operation.
Serial Peripheral Interface – SPI Bus
The FM25CL64B employs a Serial Peripheral
Interface (SPI) bus. It is specified to operate at speeds
up to 16 MHz. This high-speed serial bus provides
high performance serial communication to a host
microcontroller. Many common microcontrollers
have hardware SPI ports allowing a direct interface.
It is quite simple to emulate the port using ordinary
port pins for microcontrollers that do not. The
FM25CL64B operates in SPI Mode 0 and 3.
The SPI interface uses a total of four pins: clock,
data-in, data-out, and chip select. It is possible to
connect the two data pins together. Figure 2
illustrates a typical system configuration using the
FM25CL64B with a microcontroller that offers an
SPI port. Figure 3 shows a similar configuration for a
microcontroller that has no hardware support for the
SPI bus.
Protocol Overview
The SPI interface is a synchronous serial interface
using clock and data pins. It is intended to support
multiple devices on the bus. Each device is activated
using a chip select. Once chip select is activated by
the bus master, the FM25CL64B will begin
monitoring the clock and data lines. The relationship
between the falling edge of /CS, the clock and data is
dictated by the SPI mode. The device will make a
determination of the SPI mode on the falling edge of
each chip select. While there are four such modes, the
FM25CL64B supports modes 0 and 3. Figure 4
shows the required signal relationships for modes 0
and 3. For both modes, data is clocked into the
FM25CL64B on the rising edge of SCK and data is
expected on the first rising edge after /CS goes
active. If the clock begins from a high state, it will
fall prior to beginning data transfer in order to create
the first rising edge.
The SPI protocol is controlled by op-codes. These
op-codes specify the commands to the device. After
/CS is activated the first byte transferred from the bus
master is the op-code. Following the op-code, any
addresses and data are then transferred. Note that the
WREN and WRDI op-codes are commands with no
subsequent data transfer.
Important: The /CS pin must go inactive after an
operation is complete and before a new op-code
can be issued. There is one valid op-code only per
active chip select.
FM25CL64B - Automotive Temp.
Rev. 3.0
Sept. 2011 Page 4 of 13
FM25CL64B
MOSI: Master Out, Slave In
MISO: Master In, Slave Out
SS: Slave Select
SO SI SCK
CS HOLD
FM25CL64B
SO SI SCK
CS HOLD
SPI
Microcontroller
SS1
SS2
HOLD1
HOLD2
MISO
MOSI
SCK
Figure 2. System Configuration with SPI port
Microcontroller
FM25CL64B
SO SI SCK
CS HOLD
Figure 3. System Configuration without SPI port
SPI Mode 0: CPOL=0, CPHA=0
01234567
SPI Mode 3: CPOL=1, CPHA=1
01234567
Figure 4. SPI Modes 0 & 3
FM25CL64B - Automotive Temp.
Rev. 3.0
Sept. 2011 Page 5 of 13
Data Transfer
All data transfers to and from the FM25CL64B occur
in 8-bit groups. They are synchronized to the clock
signal (SCK), and they transfer most significant bit
(MSB) first. Serial inputs are registered on the rising
edge of SCK. Outputs are driven from the falling
edge of SCK.
Command Structure
There are six commands called op-codes that can be
issued by the bus master to the FM25CL64B. They
are listed in the table below. These op-codes control
the functions performed by the memory. They can be
divided into three categories. First, there are
commands that have no subsequent operations. They
perform a single function such as to enable a write
operation. Second are commands followed by one
byte, either in or out. They operate on the Status
Register. The third group includes commands for
memory transactions followed by address and one or
more bytes of data.
Table 1. Op-code Commands
Name
Description
Op-code
WREN
Set Write Enable Latch
0000 0110b
WRDI
Write Disable
0000 0100b
RDSR
Read Status Register
0000 0101b
WRSR
Write Status Register
0000 0001b
READ
Read Memory Data
0000 0011b
WRITE
Write Memory Data
0000 0010b
WREN - Set Write Enable Latch
The FM25CL64B will power up with writes
disabled. The WREN command must be issued prior
to any write operation. Sending the WREN op-code
will allow the user to issue subsequent op-codes for
write operations. These include writing the Status
Register and writing the memory.
Sending the WREN op-code causes the internal
Write Enable Latch to be set. A flag bit in the Status
Register, called WEL, indicates the state of the
latch. WEL=1 indicates that writes are permitted.
Attempting to write the WEL bit in the Status
Register has no effect. Completing any write
operation will automatically clear the write-enable
latch and prevent further writes without another
WREN command. Figure 5 below illustrates the
WREN command bus configuration.
WRDI - Write Disable
The WRDI command disables all write activity by
clearing the Write Enable Latch. The user can verify
that writes are disabled by reading the WEL bit in
the Status Register and verifying that WEL=0.
Figure 6 illustrates the WRDI command bus
configuration.
Figure 5. WREN Bus Configuration
Figure 6. WRDI Bus Configuration
FM25CL64B - Automotive Temp.
Rev. 3.0
Sept. 2011 Page 6 of 13
RDSR - Read Status Register
The RDSR command allows the bus master to verify
the contents of the Status register. Reading Status
provides information about the current state of the
write protection features. Following the RDSR op-
code, the FM25CL64B will return one byte with the
contents of the Status register. The Status register is
described in detail in a later section.
WRSR – Write Status Register
The WRSR command allows the user to select
certain write protection features by writing a byte to
the Status register. Prior to issuing a WRSR
command, the /WP pin must be high or inactive.
Note that on the FM25CL64B, /WP only prevents
writing to the Status register, not the memory array.
Prior to sending the WRSR command, the user must
send a WREN command to enable writes. Note that
executing a WRSR command is a write operation
and therefore clears the Write Enable Latch.
Figure 7. RDSR Bus Configuration
Figure 8. WRSR Bus Configuration
(WREN not shown)
Status Register & Write Protection
The write protection features of the FM25CL64B are
multi-tiered. First, a WREN op-code must be issued
prior to any write operation. Assuming that writes are
enabled using WREN, writes to memory are
controlled by the Status register. As described above,
writes to the Status Register are performed using the
WRSR command and subject to the /WP pin. The
Status register is organized as follows.
Table 2. Status Register
Bit
7
6
5
4
3
2
1
0
Name
WPEN
0
0
0
BP1
BP0
WEL
0
Bits 0 and 4-6 are fixed at 0 and cannot be modified.
Note that bit 0 (“Ready” in EEPROMs) is
unnecessary as the FRAM writes in real-time and is
never busy. The WPEN, BP1 and BP0 control write
protection features. They are nonvolatile (shaded
yellow). The WEL flag indicates the state of the
Write Enable Latch. Attempting to directly write the
WEL bit in the Status Register has no effect on its
state. This bit is internally set and cleared via the
WREN and WRDI commands, respectively.
BP1 and BP0 are memory block write protection
bits. They specify portions of memory that are write
protected as shown in the following table.
Table 3. Block Memory Write Protection
BP1
BP0
Protected Address Range
0
0
None
0
1
1800h to 1FFFh (upper ¼)
1
0
1000h to 1FFFh (upper ½)
1
1
0000h to 1FFFh (all)
FM25CL64B - Automotive Temp.
Rev. 3.0
Sept. 2011 Page 7 of 13
The BP1 and BP0 bits and the Write Enable Latch
are the only mechanisms that protect the memory
from writes. The remaining write protection features
protect inadvertent changes to the block protect bits.
The WPEN bit controls the effect of the hardware
/WP pin. When WPEN is low, the /WP pin is
ignored. When WPEN is high, the /WP pin controls
write access to the Status Register. Thus the Status
register is write protected if WPEN=1 and /WP=0.
This scheme provides a write protection mechanism,
which can prevent software from writing the
memory under any circumstances. This occurs if the
BP1 and BP0 are set to 1, the WPEN bit is set to 1,
and /WP is set to 0. This occurs because the block
protect bits prevent writing memory and the /WP
signal in hardware prevents altering the block
protect bits (if WPEN is high). Therefore in this
condition, hardware must be involved in allowing a
write operation. The following table summarizes the
write protection conditions.
Table 4. Write Protection
WEL
WPEN
/WP
Protected Blocks
Unprotected Blocks
Status Register
0
X
X
Protected
Protected
Protected
1
0
X
Protected
Unprotected
Unprotected
1
1
0
Protected
Unprotected
Protected
1
1
1
Protected
Unprotected
Unprotected
Memory Operation
The SPI interface, which is capable of a relatively
high clock frequency, highlights the fast write
capability of the FRAM technology. Unlike SPI-bus
EEPROMs, the FM25CL64B can perform sequential
writes at bus speed. No page register is needed and
any number of sequential writes may be performed.
Write Operation
All writes to the memory array begin with a WREN
op-code. The next op-code is the WRITE instruction.
This op-code is followed by a two-byte address
value. The upper 3-bits of the address are ignored. In
total, the 13-bits specify the address of the first data
byte of the write operation. Subsequent bytes are data
and they are written sequentially. Addresses are
incremented internally as long as the bus master
continues to issue clocks. If the last address of 1FFFh
is reached, the counter will roll over to 0000h. Data is
written MSB first. A write operation is shown in
Figure 9.
Unlike EEPROMs, any number of bytes can be
written sequentially and each byte is written to
memory immediately after it is clocked in (after the
8th clock). The rising edge of /CS terminates a
WRITE op-code operation.
Read Operation
After the falling edge of /CS, the bus master can issue
a READ op-code. Following this instruction is a two-
byte address value. The upper 3-bits of the address
are ignored. In total, the 13-bits specify the address of
the first byte of the read operation. After the op-code
and address are complete, the SI line is ignored. The
bus master issues 8 clocks, with one bit read out for
each. Addresses are incremented internally as long as
the bus master continues to issue clocks. If the last
address of 1FFFh is reached, the counter will roll
over to 0000h. Data is read MSB first. The rising
edge of /CS terminates a READ op-code operation.
A read operation is shown in Figure 10.
Hold
The /HOLD pin can be used to interrupt a serial
operation without aborting it. If the bus master pulls
the /HOLD pin low while SCK is low, the current
operation will pause. Taking the /HOLD pin high
while SCK is low will resume an operation. The
transitions of /HOLD must occur while SCK is low,
but the SCK pin can toggle during a hold state.
FM25CL64B - Automotive Temp.
Rev. 3.0
Sept. 2011 Page 8 of 13
0 1 2 3 4 5 6 7 0 1 2 3 4 5 3 4 5 6 7 0 1 2 3 4 5 6 7
op-code
0 0 0 0 0 0 1 0 MSB
13-bit Address
X X X 12 11 10 4 3 2 1 0 7 6 5 4 3 2 1 0
LSB MSB LSB
CS
SCK
SI
SO
Data
Figure 9. Memory Write
(WREN not shown)
01234567012345 3456701234567
op-code
0000001 MSB
13-bit Address
X X X 12 11 10 4 3 2 1 0
7 6 5 4 3 2 1 0
LSB MSB LSB
CS
SCK
SI
SO Data
1
Figure 10. Memory Read
Endurance
The FM25CL64B devices are capable of being
accessed at least 1013 times, reads or writes. An F-
RAM memory operates with a read and restore
mechanism. Therefore, an endurance cycle is applied
on a row basis for each access (read or write) to the
memory array. The F-RAM architecture is based on
an array of rows and columns. Rows are defined by
A12-A3 and column addresses by A2-A0. See Block
Diagram (pg 2) which shows the array as 1K rows of
64-bits each. The entire row is internally accessed
once whether a single byte or all eight bytes are read
or written. Each byte in the row is counted only once
in an endurance calculation. The table below shows
endurance calculations for 64-byte repeating loop,
which includes an op-code, a starting address, and a
sequential 64-byte data stream. This causes each byte
to experience one endurance cycle through the loop.
F-RAM read and write endurance is virtually
unlimited even at 10MHz clock rate.
Table 5. Time to Reach Endurance Limit for Repeating 64-byte Loop
SCK Freq
(MHz)
Endurance
Cycles/sec.
Endurance
Cycles/year
Years to Reach
Limit
10
18,660
5.88 x 1011
17.0
5
9,330
2.94 x 1011
34.0
1
1,870
5.88 x 1010
170.1
FM25CL64B - Automotive Temp.
Rev. 3.0
Sept. 2011 Page 9 of 13
Electrical Specifications
Absolute Maximum Ratings
Symbol
Description
Ratings
VDD
Power Supply Voltage with respect to VSS
-1.0V to +5.0V
VIN
Voltage on any pin with respect to VSS
-1.0V to +5.0V
and VIN < VDD+1.0V
TSTG
Storage Temperature
-55C to + 125C
TLEAD
Lead Temperature (Soldering, 10 seconds)
260 C
VESD
Electrostatic Discharge Voltage
- Human Body Model (AEC-Q100-002 Rev. E)
- Charged Device Model (AEC-Q100-011 Rev. B)
- Machine Model (AEC-Q100-003 Rev. E)
4kV
1.25kV
300V
Package Moisture Sensitivity Level
MSL-1
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 listed in the operational section of this
specification is not implied. Exposure to absolute maximum ratings conditions for extended periods may affect device reliability.
DC Operating Conditions (TA = -40 C to +125 C, VDD = 3.0V to 3.6V unless otherwise specified)
Symbol
Parameter
Min
Typ
Max
Units
Notes
VDD
Power Supply Voltage
3.0
3.3
3.6
V
IDD
VDD Supply Current
@ SCK = 1.0 MHz
@ SCK = 16.0 MHz
-
-
0.3
3
mA
mA
1
ISB
Standby Current
@ +85C
@ +125C
-
-
6
20
A
A
2
ILI
Input Leakage Current
-
1
A
3
ILO
Output Leakage Current
-
1
A
3
VIH
Input High Voltage
0.75 VDD
VDD + 0.3
V
VIL
Input Low Voltage
-0.3
0.25 VDD
V
VOH
Output High Voltage
@ IOH = -2 mA
VDD – 0.8
-
V
VOL
Output Low Voltage
@ IOL = 2 mA
-
0.4
V
VHYS
Input Hysteresis
0.05 VDD
-
V
4
Notes
1. SCK toggling between VDD-0.3V and VSS, other inputs VSS or VDD-0.3V.
2. SCK = SI = /CS=VDD. All inputs VSS or VDD.
3. VSS VIN VDD and VSS VOUT VDD.
4. Characterized but not 100% tested in production. Applies only to /CS and SCK pins.
FM25CL64B - Automotive Temp.
Rev. 3.0
Sept. 2011 Page 10 of 13
AC Parameters (TA = -40 C to +125 C, VDD = 3.0V to 3.6V unless otherwise specified)
Symbol
Parameter
Min
Max
Units
Notes
fCK
SCK Clock Frequency
0
16
MHz
tCH
Clock High Time
25
ns
1
tCL
Clock Low Time
25
ns
1
tCSU
Chip Select Setup
10
ns
tCSH
Chip Select Hold
10
ns
tOD
Output Disable Time
20
ns
2
tODV
Output Data Valid Time
25
ns
tOH
Output Hold Time
0
ns
tD
Deselect Time
60
ns
tR
Data In Rise Time
50
ns
2,3
tF
Data In Fall Time
50
ns
2,3
tSU
Data Setup Time
5
ns
tH
Data Hold Time
5
ns
tHS
/HOLD Setup Time
10
ns
tHH
/HOLD Hold Time
10
ns
tHZ
/HOLD Low to Hi-Z
20
ns
2
tLZ
/HOLD High to Data Active
20
ns
2
Notes
1. tCH + tCL = 1/fCK.
2. Characterized but not 100% tested in production.
3. Rise and fall times measured between 10% and 90% of waveform.
Capacitance (TA = 25 C, f=1.0 MHz, VDD = 3.3V)
Symbol
Parameter
Min
Max
Units
Notes
CO
Output Capacitance (SO)
-
8
pF
1
CI
Input Capacitance
-
6
pF
1
Notes
1. This parameter is periodically sampled and not 100% tested.
AC Test Conditions
Input Pulse Levels 10% and 90% of VDD Input and output timing levels 0.5 VDD
Input rise and fall times 5 ns Output Load Capacitance 30 pF
Power Cycle Timing
VDD min
tPU
VDD
CS
tVR
tPD
tVF
Power Cycle Timing (TA = -40 C to +125 C, VDD = 3.0V to 3.6V unless otherwise specified)
Symbol
Parameter
Min
Max
Units
Notes
tPU
VDD(min) to First Access Start
10
-
ms
tPD
Last Access Complete to VDD(min)
0
-
s
tVR
VDD Rise Time
30
-
s/V
1
tVF
VDD Fall Time
100
-
s/V
1
Notes
1. Slope measured at any point on VDD waveform.
FM25CL64B - Automotive Temp.
Rev. 3.0
Sept. 2011 Page 11 of 13
Serial Data Bus Timing
1/fCK tCL tCH tCSH
tODV tOH tOD
tCSU
tSU tH
tD
tRtF
/Hold Timing
Data Retention (VDD = 3.0V to 3.6V unless otherwise specified)
Parameter
Min
Max
Units
Notes
Data Retention
@ TA = +55C
@ TA = +105C
@ TA = +125C
17
10,000
1,000
-
-
-
Years
Hours
Hours
Note : Data retention qualification tests are accelerated tests and are performed such that all three conditions have been
applied : (1) 17 years at a temperature of +55C, (2) 10,000 hours at +105C, and (3) 1,000 hours at +125C.
Typical Grade 1 Operating Profile
0
200
400
600
800
1000
1200
1400
1600
70 75 80 85 90 95 100 105 110 115 120 125
Temperature (°C)
Hours
Typical Grade 1 Storage Profile
0
5000
10000
15000
20000
25000
0 5 10 15 20 25 30 35 40 45 50 55 60 65 70 75 80
Temperature (°C)
Hours
FM25CL64B - Automotive Temp.
Rev. 3.0
Sept. 2011 Page 12 of 13
Mechanical Drawing
8-pin SOIC (JEDEC Standard MS-012 variation AA)
Pin 1
3.90 ±0.10 6.00 ±0.20
4.90 ±0.10
0.10
0.25
1.35
1.75
0.33
0.51
1.27 0.10 mm
0.25
0.50 45
0.40
1.27
0.19
0.25
0- 8
Recommended PCB Footprint
7.70
0.65
1.27
2.00
3.70
Refer to JEDEC MS-012 for complete dimensions and notes.
All dimensions in millimeters.
SOIC Package Marking Scheme
Legend:
XXXXXX= part number, P= package type (G=SOIC),
T= temp (A=automotive grade, blank=ind.)
R=rev code, LLLLLLL= lot code
RIC=Ramtron Int‟l Corp, YY=year, WW=work week
Example: FM25CL64B, “Green” SOIC, Automotive Temperature,
Rev A, Lot L3502G1, Year 2011, Work Week 04
25CL64BGA
AL3502G1
RIC1104
XXXXXXXPT
RLLLLLLL
RICYYWW
FM25CL64B - Automotive Temp.
Rev. 3.0
Sept. 2011 Page 13 of 13
Revision History
Revision
Date
Summary
1.0
2/18/2011
Initial release.
1.1
5/3/2011
Added ESD ratings.
3.0
9/12/2011
Changed to Production status.
