CYPRESS STK22C48-NF45

STK22C48
16 Kbit (2K x 8) AutoStore nvSRAM
Features
Functional Description
■
25 ns and 45 ns access times
■
Hands off automatic STORE on power down with external 68
µF capacitor
■
STORE to QuantumTrap™ nonvolatile elements is initiated by
software, hardware, or AutoStore™ on power down
■
RECALL to SRAM initiated by software or power up
■
Unlimited Read, Write, and Recall cycles
■
1,000,000 STORE cycles to QuantumTrap
The Cypress STK22C48 is a fast static RAM with a nonvolatile
element in each memory cell. The embedded nonvolatile
elements incorporate QuantumTrap technology producing the
world’s most reliable nonvolatile memory. The SRAM provides
unlimited read and write cycles, while independent nonvolatile
data resides in the highly reliable QuantumTrap cell. Data
transfers from the SRAM to the nonvolatile elements (the
STORE operation) takes place automatically at power down. On
power up, data is restored to the SRAM (the RECALL operation)
from the nonvolatile memory. A hardware STORE is initiated with
the HSB pin.
■
100 year data retention to QuantumTrap
■
Single 5V+10% operation
■
Commercial and industrial temperatures
■
28-pin 300 mil and (330 mil) SOIC package
■
RoHS compliance
Logic Block Diagram
VCC
Quantum Trap
32 X 512
A5
A7
A8
A9
DQ 0
DQ 2
DQ 3
DQ 4
DQ 5
DQ 6
STATIC RAM
ARRAY
32 X 512
RECALL
STORE/
RECALL
CONTROL
HSB
COLUMN I/O
INPUT BUFFERS
DQ 1
POWER
CONTROL
STORE
ROW DECODER
A6
VCAP
COLUMN DEC
A 0 A 1 A 2 A 3 A 4 A 10
DQ 7
OE
CE
WE
Cypress Semiconductor Corporation
Document Number: 001-51000 Rev. **
•
198 Champion Court
•
San Jose, CA 95134-1709
•
408-943-2600
Revised January 30, 2009
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STK22C48
Pin Configurations
Figure 1. Pin Diagram - 28-Pin SOIC
V CC
V CAP
1
28
NC
2
27
WE
A7
3
26
HSB
25
A8
A6
4
A5
5
A4
6
A3
7
A2
8
24
A9
23
NC
Top View
22
OE
(Not To Scale)
21
A 10
28-SOIC
A1
9
20
CE
A0
10
19
DQ7
DQ0
11
18
DQ6
DQ1
12
17
DQ5
DQ2
13
16
DQ4
V SS
14
15
DQ3
Table 1. Pin Definitions
Pin Name
Alt
A0–A10
IO Type
Input
DQ0-DQ7
Description
Address Inputs. Used to select one of the 2,048 bytes of the nvSRAM.
Input or Output Bidirectional Data IO Lines. Used as input or output lines depending on operation.
WE
W
Input
Write Enable Input, Active LOW. When the chip is enabled and WE is LOW, data on the IO
pins is written to the specific address location.
CE
E
Input
Chip Enable Input, Active LOW. When LOW, selects the chip. When HIGH, deselects the chip.
OE
G
Input
Output Enable, Active LOW. The active LOW OE input enables the data output buffers during
read cycles. Deasserting OE HIGH causes the IO pins to tri-state.
VSS
Ground
Ground for the Device. The device is connected to ground of the system.
VCC
Power Supply Power Supply Inputs to the Device.
HSB
Input or Output Hardware Store Busy (HSB). When LOW, this output indicates a Hardware Store is in progress.
When pulled low external to the chip, it initiates a nonvolatile STORE operation. A weak internal
pull up resistor keeps this pin high if not connected (connection optional).
VCAP
Power Supply AutoStore Capacitor. Supplies power to nvSRAM during power loss to store data from SRAM
to nonvolatile elements.
NC
No Connect
No Connect. This pin is not connected to the die.
Document Number: 001-51000 Rev. **
Page 2 of 14
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STK22C48
SRAM Read
The STK22C48 performs a Read cycle whenever CE and OE are
LOW while WE and HSB are HIGH. The address specified on
pins A0–10 determines the 2,048 data bytes accessed. When the
Read is initiated by an address transition, the outputs are valid
after a delay of tAA (Read cycle 1). If the Read is initiated by CE
or OE, the outputs are valid at tACE or at tDOE, whichever is later
(Read cycle 2). The data outputs repeatedly respond to address
changes within the tAA access time without the need for transitions on any control input pins, and remains valid until another
address change or until CE or OE is brought HIGH, or WE or
HSB is brought LOW.
SRAM Write
A Write cycle is performed whenever CE and WE are LOW and
HSB is HIGH. The address inputs must be stable prior to entering
the Write cycle and must remain stable until either CE or WE
goes HIGH at the end of the cycle. The data on the common IO
pins DQ0–7 are written into the memory if it has valid tSD, before
the end of a WE controlled Write or before the end of an CE
controlled Write. Keep OE HIGH during the entire Write cycle to
avoid data bus contention on common IO lines. If OE is left LOW,
internal circuitry turns off the output buffers tHZWE after WE goes
LOW.
AutoStore Operation
During normal operation, the device draws current from VCC to
charge a capacitor connected to the VCAP pin. This stored
charge is used by the chip to perform a single STORE operation.
If the voltage on the VCC pin drops below VSWITCH, the part
automatically disconnects the VCAP pin from VCC. A STORE
operation is initiated with power provided by the VCAP capacitor.
:(
N2KP
9FF
N2KP
9&$3
+6%
5)
%\SDVV
The STK22C48 nvSRAM is made up of two functional components paired in the same physical cell. These are an SRAM
memory cell and a nonvolatile QuantumTrap cell. The SRAM
memory cell operates as a standard fast static RAM. Data in the
SRAM is transferred to the nonvolatile cell (the STORE
operation) or from the nonvolatile cell to SRAM (the RECALL
operation). This unique architecture enables the storage and
recall of all cells in parallel. During the STORE and RECALL
operations, SRAM Read and Write operations are inhibited. The
STK22C48 supports unlimited reads and writes similar to a
typical SRAM. In addition, it provides unlimited RECALL operations from the nonvolatile cells and up to one million STORE
operations.
Figure 2. AutoStore Mode
5)
Y
Device Operation
9VV
In system power mode, both VCC and VCAP are connected to the
+5V power supply without the 68 μF capacitor. In this mode, the
AutoStore function of the STK22C48 operates on the stored
system charge as power goes down. The user must, however,
guarantee that VCC does not drop below 3.6V during the 10 ms
STORE cycle.
To prevent unneeded STORE operations, automatic STOREs
and those initiated by externally driving HSB LOW are ignored,
unless at least one WRITE operation takes place since the most
recent STORE or RECALL cycle. An optional pull up resistor is
shown connected to HSB. This is used to signal the system that
the AutoStore cycle is in progress.
AutoStore Inhibit mode
If an automatic STORE on power loss is not required, then VCC
is tied to ground and +5V is applied to VCAP (Figure 3). This is
the AutoStore Inhibit mode, where the AutoStore function is
disabled. If the STK22C48 is operated in this configuration, references to VCC are changed to VCAP throughout this data sheet.
In this mode, STORE operations are triggered with the HSB pin.
It is not permissible to change between these three options “on
the fly”.
Figure 2 shows the proper connection of the storage capacitor
(VCAP) for automatic store operation. A charge storage capacitor
between 68 µF and 220 µF (+20%) rated at 6V should be
Document Number: 001-51000 Rev. **
Page 3 of 14
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STK22C48
Data Protection
9FF
:(
N2KP
9&$3
N2KP
5)
%\SDVV
Figure 3. AutoStore Inhibit Mode
+6%
The STK22C48 protects data from corruption during low voltage
conditions by inhibiting all externally initiated STORE and Write
operations. The low voltage condition is detected when VCC is
less than VSWITCH. If the STK22C48 is in a Write mode (both CE
and WE are low) at power up after a RECALL or after a STORE,
the Write is inhibited until a negative transition on CE or WE is
detected. This protects against inadvertent writes during power
up or brown out conditions.
Noise Considerations
The STK22C48 is a high speed memory. It must have a high
frequency bypass capacitor of approximately 0.1 µF connected
between VCC and VSS, using leads and traces that are as short
as possible. As with all high speed CMOS ICs, careful routing of
power, ground, and signals reduce circuit noise.
9VV
Hardware STORE (HSB) Operation
The STK22C48 provides the HSB pin for controlling and
acknowledging the STORE operations. The HSB pin is used to
request a hardware STORE cycle. When the HSB pin is driven
LOW, the STK22C48 conditionally initiates a STORE operation
after tDELAY. An actual STORE cycle only begins if a Write to the
SRAM takes place since the last STORE or RECALL cycle. The
HSB pin also acts as an open drain driver that is internally driven
LOW to indicate a busy condition, while the STORE (initiated by
any means) is in progress. Pull up this pin with an external 10K
ohm resistor to VCAP if HSB is used as a driver.
SRAM Read and Write operations, that are in progress when
HSB is driven LOW by any means, are given time to complete
before the STORE operation is initiated. After HSB goes LOW,
the STK22C48 continues SRAM operations for tDELAY. During
tDELAY, multiple SRAM Read operations take place. If a Write is
in progress when HSB is pulled LOW, it allows a time, tDELAY to
complete. However, any SRAM Write cycles requested after
HSB goes LOW are inhibited until HSB returns HIGH.
During any STORE operation, regardless of how it is initiated,
the STK22C48 continues to drive the HSB pin LOW, releasing it
only when the STORE is complete. After completing the STORE
operation, the STK22C48 remains disabled until the HSB pin
returns HIGH.
If HSB is not used, it is left unconnected.
Hardware Protect
The STK22C48 offers hardware protection against inadvertent
STORE operation and SRAM Writes during low voltage conditions. When VCAP<VSWITCH, all externally initiated STORE
operations and SRAM Writes are inhibited. AutoStore can be
completely disabled by tying VCC to ground and applying +5V to
VCAP. This is the AutoStore Inhibit mode; in this mode, STOREs
are only initiated by explicit request using either the software
sequence or the HSB pin.
Low Average Active Power
CMOS technology provides the STK22C48 the benefit of
drawing significantly less current when it is cycled at times longer
than 50 ns. Figure 4 shows the relationship between ICC and
Read or Write cycle time. Worst case current consumption is
shown for both CMOS and TTL input levels (commercial temperature range, VCC = 5.5V, 100% duty cycle on chip enable). Only
standby current is drawn when the chip is disabled. The overall
average current drawn by the STK22C48 depends on the
following items:
■
The duty cycle of chip enable
■
The overall cycle rate for accesses
■
The ratio of Reads to Writes
■
CMOS versus TTL input levels
■
The operating temperature
■
The VCC level
■
IO loading
Hardware RECALL (Power Up)
During power up or after any low power condition (VCC <
VRESET), an internal RECALL request is latched. When VCC
once again exceeds the sense voltage of VSWITCH, a RECALL
cycle is automatically initiated and takes tHRECALL to complete.
Document Number: 001-51000 Rev. **
Page 4 of 14
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STK22C48
device drives HSB LOW for 20 ns at the onset of a STORE.
When the STK22C48 is connected for AutoStore operation
(system VCC connected to VCC and a 68 μF capacitor on VCAP)
and VCC crosses VSWITCH on the way down, the STK22C48
attempts to pull HSB LOW. If HSB does not actually get below
VIL, the part stops trying to pull HSB LOW and abort the STORE
attempt.
Figure 4. Current Versus Cycle Time (Read)
Best Practices
nvSRAM products have been used effectively for over 15 years.
While ease of use is one of the product’s main system values,
experience gained working with hundreds of applications has
resulted in the following suggestions as best practices:
■
The nonvolatile cells in an nvSRAM are programmed on the
test floor during final test and quality assurance. Incoming
inspection routines at customer or contract manufacturer’s
sites sometimes reprogram these values. Final NV patterns are
typically repeating patterns of AA, 55, 00, FF, A5, or 5A. The
end product’s firmware should not assume that an NV array is
in a set programmed state. Routines that check memory
content values to determine first time system configuration,
cold or warm boot status, and so on must always program a
unique NV pattern (for example, complex 4-byte pattern of 46
E6 49 53 hex or more random bytes) as part of the final system
manufacturing test to ensure these system routines work
consistently.
■
Power up boot firmware routines should rewrite the nvSRAM
into the desired state. While the nvSRAM is shipped in a preset
state, best practice is to again rewrite the nvSRAM into the
desired state as a safeguard against events that might flip the
bit inadvertently (program bugs, incoming inspection routines,
and so on).
■
The VCAP value specified in this data sheet includes a minimum
and a maximum value size. The best practice is to meet this
requirement and not exceed the maximum VCAP value because
the higher inrush currents may reduce the reliability of the
internal pass transistor. Customers who want to use a larger
VCAP value to make sure there is extra store charge should
discuss their VCAP size selection with Cypress.
Figure 5. Current Versus Cycle Time (Write)
Preventing Store
The STORE function is disabled by holding HSB high with a
driver capable of sourcing 30 mA at a VOH of at least 2.2V,
because it must overpower the internal pull down device. This
Table 2. Hardware Mode Selection
CE
WE
HSB
A10–A0
Mode
IO
Power
H
X
H
X
Not Selected
Output High Z
Standby
L
H
H
X
Read SRAM
Output Data
Active[1]
L
L
H
X
Write SRAM
Input Data
Active
X
X
L
X
Nonvolatile STORE
Output High Z
ICC2[2]
Notes
1. I/O state assumes OE < VIL. Activation of nonvolatile cycles does not depend on state of OE.
2. HSB STORE operation occurs only if an SRAM Write is done since the last nonvolatile cycle. After the STORE (If any) completes, the part goes into standby mode,
inhibiting all operations until HSB rises.
Document Number: 001-51000 Rev. **
Page 5 of 14
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STK22C48
Maximum Ratings
Voltage on DQ0-7 or HSB .......................–0.5V to Vcc + 0.5V
Exceeding maximum ratings may shorten the useful life of the
device. These user guidelines are not tested.
Storage Temperature ................................. –65°C to +150°C
Temperature under bias.............................. –55°C to +125°C
Supply Voltage on VCC Relative to GND ..........–0.5V to 7.0V
Voltage on Input Relative to Vss............ –0.6V to VCC + 0.5V
Power Dissipation ......................................................... 1.0W
DC Output Current (1 output at a time, 1s duration).... 15 mA
Operating Range
Range
Commercial
Industrial
Ambient Temperature
VCC
0°C to +70°C
4.5V to 5.5V
-40°C to +85°C
4.5V to 5.5V
DC Electrical Characteristics
Over the operating range (VCC = 4.5V to 5.5V) [3]
Parameter
Description
Average VCC Current
ICC1
ICC2
ICC3
ICC4
Average VCC Current during
STORE
Average VCC Current at tRC=
200 ns, 5V, 25°C Typical
ISB1[4]
Average VCAP Current during
AutoStore Cycle
Average Vcc Current
(Standby, Cycling TTL Input
Levels)
ISB2[4]
VCC Standby Current
IILK
IOLK
VIH
Input Leakage Current
Off State Output Leakage
Current
Input HIGH Voltage
VIL
VOH
VOL
VBL
VCAP
Input LOW Voltage
Output HIGH Voltage
Output LOW Voltage
Logic ‘0’ Voltage on HSB Output
Storage Capacitor
Test Conditions
Min
Max
85
65
90
65
Unit
mA
mA
mA
mA
3
mA
10
mA
2
mA
25
18
26
19
1.5
mA
mA
mA
mA
mA
-1
-5
+1
+5
μA
μA
2.2
VCC +
0.5
0.8
V
tRC = 25 ns
Commercial
tRC = 45 ns
Dependent on output loading and cycle
Industrial
rate. Values obtained without output loads.
IOUT = 0 mA.
All Inputs Do Not Care, VCC = Max
Average current for duration tSTORE
WE > (VCC – 0.2V). All other inputs cycling.
Dependent on output loading and cycle rate. Values
obtained without output loads.
All Inputs Do Not Care, VCC = Max
Average current for duration tSTORE
tRC = 25 ns, CE > VIH
Commercial
tRC = 45 ns, CE > VIH
Industrial
CE > (VCC – 0.2V). All others VIN < 0.2V or > (VCC – 0.2V).
Standby current level after nonvolatile cycle is complete.
Inputs are static. f = 0 MHz.
VCC = Max, VSS < VIN < VCC
VCC = Max, VSS < VIN < VCC, CE or OE > VIH or WE < VIL
IOUT = –4 mA except HSB
IOUT = 8 mA except HSB
IOUT = 3 mA
Between VCAP pin and Vss, 6V rated. 68 uF -10%, +20%
nom.
VSS – 0.5
2.4
61
0.4
0.4
220
V
V
V
V
µF
Data Retention and Endurance
Parameter
Description
DATAR
Data Retention
NVC
Nonvolatile STORE Operations
Min
Unit
100
Years
1,000
K
Notes
3. VCC reference levels throughout this data sheet refer to VCC if that is where the power supply connection is made, or VCAP if VCC is connected to ground.
4. CE > VIH does not produce standby current levels until any nonvolatile cycle in progress has timed out.
Document Number: 001-51000 Rev. **
Page 6 of 14
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STK22C48
Capacitance
In the following table, the capacitance parameters are listed.[5]
Parameter
Description
CIN
Input Capacitance
COUT
Output Capacitance
Test Conditions
Max
Unit
8
pF
7
pF
28-SOIC
(300 mil)
28-SOIC
(330 mil)
Unit
TBD
TBD
°C/W
TBD
TBD
°C/W
TA = 25°C, f = 1 MHz,
VCC = 0 to 3.0V
Thermal Resistance
In the following table, the thermal resistance parameters are listed.[5]
Parameter
ΘJA
ΘJC
Description
Thermal Resistance
(Junction to Ambient)
Thermal Resistance
(Junction to Case)
Test Conditions
Test conditions follow standard test methods
and procedures for measuring thermal
impedance, per EIA / JESD51.
Figure 6. AC Test Loads
R1 963Ω
R1 963Ω For Tri-state Specs
5.0V
5.0V
Output
Output
30 pF
R2
512Ω
5 pF
R2
512Ω
AC Test Conditions
Input Pulse Levels .................................................... 0V to 3V
Input Rise and Fall Times (10% to 90%) ...................... <5 ns
Input and Output Timing Reference Levels .................... 1.5V
Note
5. These parameters are guaranteed by design and are not tested.
Document Number: 001-51000 Rev. **
Page 7 of 14
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STK22C48
AC Switching Characteristics
SRAM Read Cycle
Parameter
Cypress
Alt
Parameter
tELQV
tACE
tAVAV, tELEH
tRC [6]
tAVQV
tAA [7]
tGLQV
tDOE
tAXQX
tOHA [7]
tELQX
tLZCE [8]
tEHQZ
tHZCE [8]
[8]
tGLQX
tLZOE
tGHQZ
tHZOE [8]
tELICCH
tPU [5]
[5]
tEHICCL
tPD
25 ns
Description
Chip Enable Access Time
Read Cycle Time
Address Access Time
Output Enable to Data Valid
Output Hold After Address Change
Chip Enable to Output Active
Chip Disable to Output Inactive
Output Enable to Output Active
Output Disable to Output Inactive
Chip Enable to Power Active
Chip Disable to Power Standby
Min
45 ns
Max
Min
25
Max
45
25
45
25
10
45
20
5
5
5
5
10
15
0
0
10
15
0
0
25
45
Unit
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
Switching Waveforms
Figure 7. SRAM Read Cycle 1: Address Controlled [6, 7]
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'$7$9$/,'
Figure 8. SRAM Read Cycle 2: CE and OE Controlled [6]
W5&
$''5(66
W$&(
W3'
W/=&(
&(
W+=&(
2(
W+=2(
W'2(
W/=2(
'4'$7$287
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W 38
,&&
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67$1'%<
Notes
6. WE and HSB must be High during SRAM Read cycles.
7. Device is continuously selected with CE and OE both Low.
8. Measured ±200 mV from steady state output voltage.
Document Number: 001-51000 Rev. **
Page 8 of 14
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STK22C48
SRAM Write Cycle
Parameter
Cypress
Parameter
25 ns
Description
Alt
tAVAV
tWLWH, tWLEH
tELWH, tELEH
tDVWH, tDVEH
tWHDX, tEHDX
tAVWH, tAVEH
tAVWL, tAVEL
tWHAX, tEHAX
tWLQZ
tWHQX
tWC
tPWE
tSCE
tSD
tHD
tAW
tSA
tHA
tHZWE [8,9]
tLZWE [8]
Min
Write Cycle Time
Write Pulse Width
Chip Enable To End of Write
Data Setup to End of Write
Data Hold After End of Write
Address Setup to End of Write
Address Setup to Start of Write
Address Hold After End of Write
Write Enable to Output Disable
Output Active After End of Write
45 ns
Max
25
20
20
10
0
20
0
0
Min
Max
45
30
30
15
0
30
0
0
10
5
14
5
Unit
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
Switching Waveforms
Figure 9. SRAM Write Cycle 1: WE Controlled [10, 11]
tWC
ADDRESS
tHA
tSCE
CE
tAW
tSA
tPWE
WE
tSD
tHD
DATA VALID
DATA IN
tHZWE
DATA OUT
tLZWE
HIGH IMPEDANCE
PREVIOUS DATA
Figure 10. SRAM Write Cycle 2: CE Controlled [10, 11]
tWC
ADDRESS
CE
WE
tHA
tSCE
tSA
tAW
tPWE
tSD
DATA IN
DATA OUT
tHD
DATA VALID
HIGH IMPEDANCE
Notes
9. If WE is Low when CE goes Low, the outputs remain in the high impedance state.
10. HSB must be high during SRAM Write cycles.
11. CE or WE must be greater than VIH during address transitions.
Document Number: 001-51000 Rev. **
Page 9 of 14
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STK22C48
AutoStore or Power Up RECALL
Parameter
Alt
tHRECALL [12]
tSTORE [14, 15]
tDELAY [13]
VSWITCH
VRESET
tVSBL[10]
tRESTORE
tHLHZ
tHLQZ , tBLQZ
Description
Power up RECALL Duration
STORE Cycle Duration
Time Allowed to Complete SRAM Cycle
Low Voltage Trigger Level
Low Voltage Reset Level
Low Voltage Trigger (VSWITCH) to HSB Low
STK22C48
Min
Max
550
10
1
4.0
4.5
3.6
300
Unit
μs
ms
μs
V
V
ns
Switching Waveform
Figure 11. AutoStore/Power Up RECALL
WE
Notes
12. tHRECALL starts from the time VCC rises above VSWITCH.
13. CE and OE low for output behavior.
14. CE and OE low and WE high for output behavior.
15. HSB is asserted low for 1us when VCAP drops through VSWITCH. If an SRAM Write has not taken place since the last nonvolatile cycle, HSB is released and no store
takes place.
Document Number: 001-51000 Rev. **
Page 10 of 14
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STK22C48
Hardware STORE Cycle
Parameter
Alt
Description
tDHSB [13, 16]
tRECOVER, tHHQX Hardware STORE High to Inhibit Off
tPHSB
tHLHX
tHLBL
Hardware STORE Pulse Width
Hardware STORE Low to STORE Busy
STK22C48
Min
Max
Unit
700
ns
300
ns
15
ns
Switching Waveform
Figure 12. Hardware STORE Cycle
Note
16. tDHSB is only applicable after tSTORE is complete.
Document Number: 001-51000 Rev. **
Page 11 of 14
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STK22C48
STK22C48 - N F 45 I TR
Packaging Option:
TR = Tape and Reel
Blank = Tube
Temperature Range:
Blank - Commercial (0 to 70°C)
I - Industrial (-40 to 85°C)
Speed:
25 - 25 ns
45 - 45 ns
Lead Finish
F = 100% Sn (Matte Tin)
Package:
N = Plastic 28-pin 300 mil SOIC
S = Plastic 28-pin 330 mil SOIC
Ordering Information
Speed (ns)
25
45
Ordering Code
Package Diagram
Package Type
STK22C48-NF25TR
51-85026
28-pin SOIC (300 mil)
STK22C48-NF25
51-85026
28-pin SOIC (300 mil)
STK22C48-SF25TR
51-85058
28-pin SOIC (330 mil)
STK22C48-SF25
51-85058
28-pin SOIC (330 mil)
STK22C48-NF25ITR
51-85026
28-pin SOIC (300 mil)
STK22C48-NF25I
51-85026
28-pin SOIC (300 mil)
STK22C48-SF25ITR
51-85058
28-pin SOIC (330 mil)
STK22C48-SF25I
51-85058
28-pin SOIC (330 mil)
STK22C48-NF45TR
51-85026
28-pin SOIC (300 mil)
STK22C48-NF45
51-85026
28-pin SOIC (300 mil)
STK22C48-SF45TR
51-85058
28-pin SOIC (330 mil)
STK22C48-SF45
51-85058
28-pin SOIC (330 mil)
STK22C48-NF45ITR
51-85026
28-pin SOIC (300 mil)
STK22C48-NF45I
51-85026
28-pin SOIC (300 mil)
STK22C48-SF45ITR
51-85058
28-pin SOIC (330 mil)
STK22C48-SF45I
51-85058
28-pin SOIC (330 mil)
Operating Range
Commercial
Industrial
Commercial
Industrial
All parts are Pb-free. The above table contains Final information. Please contact your local Cypress sales representative for availability of these parts
Document Number: 001-51000 Rev. **
Page 12 of 14
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STK22C48
Package Diagrams
Figure 13. 28-Pin (300 mil) SOIC (51-85026)
NOTE :
PIN 1 ID
1. JEDEC STD REF MO-119
2. BODY LENGTH DIMENSION DOES NOT INCLUDE MOLD PROTRUSION/END FLASH,BUT
14
DOES INCLUDE MOLD MISMATCH AND ARE MEASURED AT THE MOLD PARTING LINE.
1
MOLD PROTRUSION/END FLASH SHALL NOT EXCEED 0.010 in (0.254 mm) PER SIDE
3. DIMENSIONS IN INCHES
0.291[7.39]
MIN.
MAX.
4. PACKAGE WEIGHT 0.85gms
0.300[7.62]
0.394[10.01]
*
0.419[10.64]
15
28
PART #
S28.3 STANDARD PKG.
SZ28.3 LEAD FREE PKG.
0.026[0.66]
0.032[0.81]
SEATING PLANE
0.697[17.70]
0.713[18.11]
0.092[2.33]
0.105[2.67]
0.004[0.10]
0.050[1.27]
0.013[0.33]
0.004[0.10]
0.019[0.48]
0.0118[0.30]
*
TYP.
0.015[0.38]
0.050[1.27]
0.0091[0.23]
0.0125[3.17]
*
51-85026-*D
Figure 14. 28-Pin (330 mil) SOIC (51-85058)
51-85058-*A
Document Number: 001-51000 Rev. **
Page 13 of 14
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STK22C48
Document History Page
Document Title: STK22C48 16 Kbit (2K x 8) AutoStore nvSRAM
Document Number: 001-51000
Rev.
ECN No.
Orig. of
Change
Submission
Date
**
2625139
GVCH/PYRS
01/30/09
Description of Change
New data sheet
Sales, Solutions, and Legal Information
Worldwide Sales and Design Support
Cypress maintains a worldwide network of offices, solution centers, manufacturer’s representatives, and distributors. To find the office
closest to you, visit us at cypress.com/sales.
Products
PSoC
Clocks & Buffers
PSoC Solutions
psoc.cypress.com
clocks.cypress.com
General
Low Power/Low Voltage
psoc.cypress.com/solutions
psoc.cypress.com/low-power
Wireless
wireless.cypress.com
Precision Analog
Memories
memory.cypress.com
LCD Drive
psoc.cypress.com/lcd-drive
image.cypress.com
CAN 2.0b
psoc.cypress.com/can
USB
psoc.cypress.com/usb
Image Sensors
psoc.cypress.com/precision-analog
© Cypress Semiconductor Corporation, 2006-2009. The information contained herein is subject to change without notice. Cypress Semiconductor Corporation assumes no responsibility for the use of
any circuitry other than circuitry embodied in a Cypress product. Nor does it convey or imply any license under patent or other rights. Cypress products are not warranted nor intended to be used for
medical, life support, life saving, critical control or safety applications, unless pursuant to an express written agreement with Cypress. Furthermore, Cypress does not authorize its products for use as
critical components in life-support systems where a malfunction or failure may reasonably be expected to result in significant injury to the user. The inclusion of Cypress products in life-support systems
application implies that the manufacturer assumes all risk of such use and in doing so indemnifies Cypress against all charges.
Any Source Code (software and/or firmware) is owned by Cypress Semiconductor Corporation (Cypress) and is protected by and subject to worldwide patent protection (United States and foreign),
United States copyright laws and international treaty provisions. Cypress hereby grants to licensee a personal, non-exclusive, non-transferable license to copy, use, modify, create derivative works of,
and compile the Cypress Source Code and derivative works for the sole purpose of creating custom software and or firmware in support of licensee product to be used only in conjunction with a Cypress
integrated circuit as specified in the applicable agreement. Any reproduction, modification, translation, compilation, or representation of this Source Code except as specified above is prohibited without
the express written permission of Cypress.
Disclaimer: CYPRESS MAKES NO WARRANTY OF ANY KIND, EXPRESS OR IMPLIED, WITH REGARD TO THIS MATERIAL, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES
OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE. Cypress reserves the right to make changes without further notice to the materials described herein. Cypress does not
assume any liability arising out of the application or use of any product or circuit described herein. Cypress does not authorize its products for use as critical components in life-support systems where
a malfunction or failure may reasonably be expected to result in significant injury to the user. The inclusion of Cypress’ product in a life-support systems application implies that the manufacturer
assumes all risk of such use and in doing so indemnifies Cypress against all charges.
Use may be limited by and subject to the applicable Cypress software license agreement.
Document Number: 001-51000 Rev. **
Revised January 30, 2009
Page 14 of 14
AutoStore and QuantumTrap are registered trademarks of Cypress Semiconductor Corporation. All products and company names mentioned in this document may be the trademarks of their respective
holders.
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