CYPRESS CY7C443-30JC

43
CY7C441
CY7C443
Clocked 512 x 9, 2K x 9 FIFOs
Features
lutions for a wide variety of data buffering needs, including
high-speed data acquisition, multiprocessor interfaces, and
communications buffering.
• High-speed, low-power, first-in first-out (FIFO)
memories
• 512 x 9 (CY7C441)
• 2,048 x 9 (CY7C443)
• 0.65 micron CMOS for optimum speed/power
• High-speed 83-MHz operation (12 ns read/write cycle
time)
• Low power — ICC=70 mA
• Fully asynchronous and simultaneous read and write
operation
• Empty, Almost Empty, and Almost Full status flags
• TTL compatible
• Parity generation/checking
• Independent read and write enable pins
• Supports free-running 50% duty cycle clock inputs
• Center power and ground pins for reduced noise
• Width Expansion Capability
• Available in PLCC packages
Both FIFOs have 9-bit input and output ports that are controlled by separate clock and enable signals. The input port is
controlled by a free-running clock (CKW) and a write enable
pin (ENW). When ENW is asserted, data is written into the
FIFO on the rising edge of the CKW signal. While ENW is held
active, data is continually written into the FIFO on each CKW
cycle. The output port is controlled in a similar manner by a
free-running read clock (CKR) and a read enable pin (ENR).
The read (CKR) and write (CKW) clocks may be tied together
for single-clock operation or the two clocks may be run independently for asynchronous read/write applications. Clock frequencies up to 83.3 MHz are acceptable.
Functional Description
The CY7C441 and CY7C443 clocked FIFOs provide two status flag pins (F1 and F2). These flags are decoded to determine one of four states: Empty, Almost Empty, Intermediate,
and Almost Full (Table 1). The flags are synchronous; i.e.,
change state relative to either the read clock (CKR) or the write
clock (CKW). The Empty and Almost Empty states are updated exclusively by the CKR while Almost Full is updated exclusively by CKW. The synchronous flag architecture guarantees
that the flags maintain their status for some minimum time.
The CY7C441 and CY7C443 are high-speed, low-power,
first-in first-out (FIFO) memories with clocked read and write
interfaces. Both FIFOs are 9 bits wide. The CY7C441 has a
512 word by 9 bit memory array, while the CY7C443 has a
2048 word by 9 bit memory array. These devices provide so-
The CY7C441 and the CY7C443 use center power and
ground for reduced noise. Both configurations are fabricated
using an advanced.65µm CMOS technology. Input ESD protection is greater than 2001V, and latch-up is prevented by
reliable layout techniques and guard rings.
Logic Block Diagram
CKW
ENW
Pin Configuration
D0– 8
PLCC
Top View
D 1 D 2 D 3 NCD 4 D 5 D 6
INPUT
REGISTER
FLAG
LOGIC
WRITE
CONTROL
LOGIC
WRITE
POINTER
MR
RAM
ARRAY
512 x 9
2048x 9
F1
F2
READ
POINTER
RESET
LOGIC
D0
ENW
CKW
VCC
VSS
F1
F2
NC
Q0
READ
CONTROL
LOGIC
5
6
7
8
9
10
11
12
13
4 3 2 1 32 31 30
29
28
27
26
7C441
25
7C443
24
23
22
21
14 15 16 17 1819 20
Q1 Q 2 Q 3 NC Q 4 Q5 Q 6
D7
D8
NC
MR
VSS
CKR
ENR
Q8
Q7
C441-2
OUTPUT
REGISTER
CKR
C441-1
Q0– 8
Cypress Semiconductor Corporation
Document #: 38-06032 Rev. *A
ENR
•
3901 North First Street
•
San Jose
•
CA 95134 • 408-943-2600
Revised December 26, 2002
CY7C441
CY7C443
Selection Guide
7C441–12
7C443–12
7C441–14
7C443–14
7C441–20
7C443–20
7C441–30
7C443–30
83.3
71.4
50
33.3
Maximum Access Time (ns)
9
10
15
20
Minimum Cycle Time (ns)
12
14
20
30
Minimum Clock HIGH Time (ns)
5
6.5
9
12
Minimum Clock LOW Time (ns)
5
6.5
9
12
Minimum Data or Enable Set-Up (ns)
4
5
6
7
Minimum Data or Enable Hold (ns)
0
0
0
0
Maximum Frequency (MHz)
Maximum Flag Delay (ns)
Maximum Current (mA)
9
10
15
20
Commercial
140
140
120
100
Military/Industrial
150
150
130
110
Selection Guide (continued)
CY7C441
CY7C443
Density
512 x 9
2,048 x 9
Package
32-Pin PLCC
32-Pin PLCC
Maximum Ratings[1](Above which the useful life
may be impaired. For user guidelines, not tested.)
Static Discharge Voltage........................................... > 2001V
(per MIL-STD-883, Method 3015)
Storage Temperature .................................–65°C to +150°C
Operating Range
Ambient Temperature with
Power Applied.............................................–55°C to +125°C
Supply Voltage to Ground Potential ............... –0.5V to +7.0V
DC Input Voltage............................................ –3.0V to +7.0V
Output Current into Outputs (LOW) .............................20 mA
Latch-Up Current.................................................... > 200 mA
Range
Ambient
Temperature
VCC
Commercial
0°C to +70°C
5V ± 10%
–40°C to +85°C
5V ± 10%
Industrial
Pin Definitions
I/O
Description
D0–8
Signal Name
I
Data Inputs: when the FIFO is not full and ENW is active, CKW (rising edge) writes data (D0 – D8)
into the FIFO’s memory
Q0–8
O
Data Outputs: when the FIFO is not empty and ENR is active, CKR (rising edge) reads data (Q0 –
Q8) out of the FIFO’s memory
ENW
I
Enable Write: enables the CKW input
ENR
I
Enable Read: enables the CKR input
CKW
I
Write Clock: the rising edge clocks data into the FIFO when ENW is LOW and updates the Almost
Full flag state
CKR
I
Read Clock: the rising edge clocks data out of the FIFO when ENR is LOW and updates the Almost
Empty and Empty flag states
F1
O
Flag 1: is used in conjunction with Flag 2 to decode which state the FIFO is in (see Table 1)
F2
O
Flag 2: is used in conjunction with Flag 1 to decode which state the FIFO is in (see Table 1)
MR
I
Master Reset: resets the device to an empty condition
Document #: 38-06032 Rev. *A
Page 2 of 15
CY7C441
CY7C443
Electrical Characteristics Over the Operating Range
7C441–12
7C443–12
Parameter
Description
Test Conditions
7C441–14
7C443–14
7C441–20
7C443–20
7C441–30
7C443–30
Min. Max. Min. Max. Min. Max. Min. Max. Unit
VOH
Output HIGH
Voltage
VCC = Min., IOH = –2.0 mA
VOL
Output LOW
Voltage
VCC = Min., IOL = 8.0 mA
VIH
Input HIGH Voltage
2.2
VCC
2.2
VCC
2.2
VCC
VIL
Input LOW Voltage
–0.5
0.8
–0.5
0.8
–0.5
IIX
Input Leakage
Current
VCC = Max.,
GND < VI < VCC
–10
+10
–10
+10
–10
IOS[2]
Output Short
Circuit Current
VCC = Max., VOUT = GND
–90
ICC1[3]
Operating Current
VCC = Max.,
IOUT = 0 mA
Com’l
140
140
120
100
mA
Mil/Ind
150
150
130
110
mA
VCC = Max.,
IOUT = 0 mA
Com’l
70
70
70
70
mA
Mil/Ind
80
80
80
80
mA
VCC = Max.,
IOUT = 0 mA
Com’l
30
30
30
30
mA
Mil/Ind
30
30
30
30
mA
ICC2
[4]
Operating Current
ISB[5]
Standby Current
2.4
2.4
0.4
2.4
2.4
0.4
–90
0.4
V
0.4
V
2.2
VCC
V
0.8
–0.5
0.8
V
+10
–10
+10
µA
–90
–90
mA
Capacitance[6]
Parameter
Description
CIN
Input Capacitance
Test Conditions
TA = 25°C, f = 1 MHz,
VCC = 5.0V
Max.
Unit
10
pF
AC Test Loads and Waveform[7,8]
R1 500Ω
5V
ALL INPUT PULSES
OUTPUT
3.0V
CL
INCLUDING
JIG AND
SCOPE
Equivalent to:
THÉVENIN EQUIVALENT
200Ω
OUTPUT
R2
333Ω
GND
≤ 3 ns
C441-4
90%
10%
90%
10%
≤ 3 ns
C441-5
2V
Notes:
1. The Voltage on any input or I/O pin cannot exceed the power pin during power-up.
2. Test no more than one output at a time and do not test any output for more than one second.
3. Input signals switch from 0V to 3V with a rise/fall time of 3 ns or less, clocks and clock enables switch at maximum frequency (fMAX), while data inputs switch
at fMAX/2. Outputs are unloaded.
4. Input signals switch from 0V to 3V with a rise/fall time less than 3 ns, clocks and clock enables switch at 20 MHz, while the data inputs switch at 10 MHz.
Outputs are unloaded.
5. All inputs signals are connected to VCC. All outputs are unloaded. Read and write clocks switch at maximum frequency (fMAX).
6. Tested initially and after any design or process changes that may affect these parameters.
7. CL = 30 pF for all AC parameters.
8. All AC measurements are referenced to 1.5V.
Document #: 38-06032 Rev. *A
Page 3 of 15
CY7C441
CY7C443
Switching Characteristics Over the Operating Range[9]
7C441–12
7C443–12
Parameter
Description
Min.
Max.
7C441–14
7C443–14
Min.
Max.
7C441–20
7C443–20
Min.
Max.
7C441–30
7C443–30
Min.
Max.
Unit
tCKW
Write Clock Cycle
12
14
20
30
ns
tCKR
Read Clock Cycle
12
14
20
30
ns
tCKH
Clock HIGH
5
6.5
9
12
ns
tCKL
Clock LOW
5
6.5
9
12
ns
tA[10]
Data Access Time
tOH
Previous Output Data Hold After Read HIGH
0
0
0
0
ns
tFH
Previous Flag Hold After Read/Write HIGH
0
0
0
0
ns
tSD
Data Set-Up
4
5
6
7
ns
tHD
Data Hold
0
0
0
0
ns
tSEN
Enable Set-Up
4
5
6
7
ns
tHEN
Enable Hold
0
0
0
0
ns
tFD
tSKEW1
9
Flag Delay
[11]
10
9
15
10
20
15
20
ns
ns
Opposite Clock After Clock
0
0
0
0
ns
tSKEW2[12]
Opposite Clock Before Clock
12
14
20
30
ns
tPMR
Master Reset Pulse Width (MR LOW)
12
14
20
30
ns
tSCMR
Last Valid Clock LOW Set-Up to MR LOW
0
0
0
0
ns
tOHMR
Data Hold From MR LOW
0
0
0
0
ns
tMRR
Master Reset Recovery (MR HIGH Set-Up to
First Enabled Write/Read)
12
14
20
30
ns
tMRF
MR HIGH to Flags Valid
12
14
20
30
ns
tAMR
MR HIGH to Data Outputs LOW
12
14
20
30
ns
Notes:
9. Test conditions assume signal transition time of 3 ns or less, timing reference levels of 1.5V, and output loading as shown in the AC Test Loads and Waveforms
and capacitance as in Note 7, unless otherwise specified.
10. Access time includes all data outputs switching simultaneously.
11. tSKEW1 is the minimum time an opposite clock can occur after a clock and still be guaranteed not to be included in the current clock cycle (for purposes of
flag update). If the opposite clock occurs less than tSKEW1 after the clock, the decision of whether or not to include the opposite clock in the current clock
cycle is arbitrary. Note: The opposite clock is the signal to which a flag is not synchronized; i.e., CKW is the opposite clock for Empty and Almost Empty flags,
CKR is the opposite clock for the Almost Full flag. The clock is the signal to which a flag is synchronized; i.e., CKW is the clock for the Almost Full flag, CKR
is the clock for Empty and Almost Empty flags.
12. tSKEW2 is the minimum time an opposite clock can occur before a clock and still be guaranteed to be included in the current clock cycle (for purposes of flag
update). If the opposite clock occurs less than tSKEW2 before the clock, the decision of whether or not to include the opposite clock in the current clock cycle
is arbitrary. See Note 11 for definition of clock and opposite clock.
Document #: 38-06032 Rev. *A
Page 4 of 15
CY7C441
CY7C443
Switching Waveforms
Write Clock Timing Diagram
tCKW
tCKH
CKW
tCKL
ENABLED WRITE
tSD
D0 – 8
DISABLED WRITE
tHD
VALID DATA IN
tSEN
tHEN
ENW
tSEN
tFH
tHEN
F1
tFH
tFD
tFD
C441-6
Read Clock Timing Diagram
tCKR
tCKH
CKR
ENABLED READ
DISABLED READ
tA
tOH
Q0 – 8
tCKL
PREVIOUS WORD
NEW WORD
tSEN
tHEN
ENR
tSEN
tFH
tHEN
F1, F2
tFD
Document #: 38-06032 Rev. *A
tFH
tFD
C441-7
Page 5 of 15
CY7C441
CY7C443
Switching Waveforms (continued)
Master Reset Timing Diagram[13, 14, 15, 16]
tPMR
MR
tSCMR
tMRR
tSCMR
tMRR
CKW
ENW
CKR
ENR
tOHMR
Q0 – 8
tAMR
ALL DATA
OUTPUTS LOW
VALID DATA
tMRF
F1, F2
C441-8
[17, 18, 19]
Read to Empty Timing Diagram
COUNT
3
2
1
0
1
1 (no change)
0
LATENT CYCLE
CKR
R1
ENABLED
READ
R2
ENABLED
READ
R3
ENABLED
READ
R4
FLAG
UPDATE
READ
R5
ENABLED
READ
ENR
tSKEW1
W1
ENABLED
WRITE
CKW
ENW
tSKEW2
LOW
tFD
tFD
tFD
F1
F2
LOW
C441-10
Notes:
13. ENW or CKW must be inactive while MR is LOW.
14. ENR or CKR must be inactive while MR is LOW.
15. All data outputs (Q0 – 8) go LOW as a result of the rising edge of MR.
16. In this example, Q0 – 8 will remain valid until tOHMR if the first read shown did not occur or if the read occurred soon enough such that the valid data was
caused by it.
17. “Count” is the number of words in the FIFO.
18. CKR is clock and CKW is opposite clock.
19. R3 updates the flags to the Empty state by bringing F1 LOW. Because W1 occurs greater than tSKEW1 after R3, R3 does not recognize W1 when updating
flag status. But because W1 occurs greater than tSKEW2 before R4, R4 includes W1 in the flag update and therefore updates the FIFO to the Almost Empty
state. It is important to note that R4 is a latent cycle; i.e., it only updates the flag status, regardless of the state of ENR. It does not change the count or the
FIFO’s data outputs.
Document #: 38-06032 Rev. *A
Page 6 of 15
CY7C441
CY7C443
Switching Waveforms (continued)
[17, 18, 20]
Read to Empty Timing Diagram with Free-Running Clocks
COUNT
1
CKR
0
1
R1
ENABLED
READ
R2
IGNORED
READ
0
LATENT CYCLE
R3
IGNORED
READ
tSKEW2
tSKEW2
R4
FLAG
UPDATE
READ
R5
ENABLED
READ
R6
IGNORED
READ
ENR
tSKEW1
W1
CKW
tSKEW2
W2
W3
ENABLED
WRITE
W4
W5
W6
ENW
tFD
tFD
tFD
F
F11
F2
F2
LOW
C441-9
Read to Almost Empty Timing Diagram with Free-Running Clocks[17, 18]
COUNT
17
CKR
16
17
R1
ENABLED
READ
18
R2
17
R3
16
R4
ENABLED
READ
15
R5
ENABLED
READ
R6
ENABLED
READ
ENR
tSKEW1
CKW
tSKEW2
W2
ENABLED
WRITE
W1
W3
ENABLED
WRITE
W4
W5
W6
ENW
F1
HIGH
tFD
tFD
tFD
F2
C441-11
Note:
20. R2 is ignored because the FIFO is empty (count = 0). It is important to note that R3 is also ignored because W3, the first enabled write after empty, occurs
less than tSKEW2 before R3. Therefore, the FIFO still appears empty when R3 occurs. Because W3 occurs greater than tSKEW2 before R4, R4 includes W3
in the flag update.
Document #: 38-06032 Rev. *A
Page 7 of 15
CY7C441
CY7C443
Switching Waveforms (continued)
Read to Almost Empty Timing Diagram with Read Flag Update Cycle and Free-Running Clocks[17, 18, 21, 22]
18 (no change)
COUNT
CKR
17
16
17
R1
ENABLED
READ
FLAG UPDATE CYCLE
18
R2
R4
FLAG
UPDATE
READ
R3
17
16
15
R5
ENABLED
READ
R6
ENABLED
READ
R7
ENABLED
READ
W5
W6
W7
ENR
tSKEW1
CKW
W1
tSKEW2
W2
ENABLED
WRITE
W3
ENABLED
WRITE
W4
ENW
F1
HIGH
tFD
tFD
tFD
F2
C441-12
[17, 23, 24, 25, 26]
Write to Almost Full Timing Diagram
COUNT
2030
[494]
CKW
2031
[495]
W1
ENABLED
WRITE
2032
[496]
2031
[495]
2030
[494]
W2
ENABLED
WRITE
2031
[497]
2032
[498]
2033
[497]
2030
[494]
2031
[495]
2032
[498]
W3
ENABLED
WRITE
W4
ENABLED
WRITE
W5
ENABLED
WRITE
FLAG UPDATE
ENW
LOW
tSKEW1
CKR
ENR
tSKEW2
R1
ENABLED
READ
R2
ENABLED
READ
LOW
tFD
tFD
tFD
tFD
F1
F2
HIGH
C441-14
Notes:
21. R4 only updates the flag status. It does not affect the count because ENR is HIGH.
22. When making the transition from Almost Empty to Intermediate, the count must increase by two (16 Á18; two enabled writes: W2, W3) before a read (R4)
can update flags to the Intermediate state.
23. CKW is clock and CKR is opposite clock.
24. Count = 2032 indicates Almost Full for CY7C443 and count = 496 indicates Almost Full for CY7C441. Values for the CY7C441 count are shown in brackets.
25. The dashed lines show W3 as flag update write rather than an enabled write because ENW is deasserted.
26. W2 updates the flags to the Almost Full state by bringing F1 LOW. Because R1 occurs greater than tSKEW1 after W2, W2 does not recognize R1 when
updating the flag status. W3 includes R2 in the flag update because R2 occurs greater than tSKEW2 before W3. Note that W3 does not have to be enabled
to update flags.
Document #: 38-06032 Rev. *A
Page 8 of 15
CY7C441
CY7C443
Switching Waveforms (continued)
Write to Almost Full
COUNT
2031
[495]
CKW
Timing Diagram with Free-Running Clocks
2032
[496]
2030
[494]
2031
[495]
W1
ENABLED
WRITE
W2
[17, 23, 24]
2032
[496]
2031
[495]
W3
2033
[497]
W4
ENABLED
WRITE
W5
ENABLED
WRITE
R4
R5
W6
ENABLED
WRITE
ENW
tSKEW1
R1
CKR
tSKEW2
R2
ENABLED
READ
R3
ENABLED
READ
R6
ENR
tFD
tFD
tFD
F1
F2
HIGH
C441-13
Write to Almost Full Timing Diagram with Write Flag Update Cycle and Free-Running Clocks[17, 23, 24, 27]
COUNT 2031
[495]
CKW
2032
[496]
2030
[494]
2031
[495]
W1
ENABLED
WRITE
2030 (no change)
[494]
FLAG UPDATE CYCLE
W2
W3
W4
FLAG
UPDATE
WRITE
2031
[495]
W5
ENABLED
WRITE
2032
[496]
2033
[497]
W6
ENABLED
WRITE
W7
ENABLED
WRITE
ENW
tSKEW1
CKR
tSKEW2
R2
ENABLED
READ
R1
R3
ENABLED
READ
R4
R5
R6
R7
ENR
tFD
tFD
tFD
F1
F2
HIGH
C441-15
Note:
27. When making the transition from Almost Full to Intermediate, the count must decrease by two (2032 Á 2030; two enabled reads: R2, R3) before a write (W4)
can update flags to Intermediate state.
Architecture
Resetting the FIFO
The CY7C441/443 consist of an array of 512/2048 words of 9
bits each (implemented by an array of dual-port RAM cells), a
read pointer, a write pointer, control signals (CKR, CKW, ENR,
ENW, MR), and flags (F1, F2).
Upon power-up, the FIFO must be reset with a Master Reset
(MR) cycle. This causes the FIFO to enter the Empty condition
signified by both flags F1 and F2 being LOW. All data outputs
(Q0–8) go LOW at the rising edge of MR. In order for the FIFO
to reset to its default state, a falling edge must occur on MR
and the user must not read or write while MR is LOW (unless
Document #: 38-06032 Rev. *A
Page 9 of 15
CY7C441
CY7C443
ENR and ENW are HIGH). Upon completion of the Master
Reset cycle, all data outputs will go LOW tAMR after MR is
deasserted. F1 and F2 are guaranteed to be valid tMRF after
MR is taken HIGH.
FIFO Operation
When the ENW signal is active (LOW), data on the D0–8 pins
is written into the FIFO on each rising edge of the CKW signal.
Similarly, when the ENR signal is active, data in the FIFO
memory will be presented on the Q0–8 outputs. New data will
be presented on each rising edge of CKR while ENR is active.
ENR must set up tSEN before CKR for it to be a valid read.
ENW must occur tSEN before CKW for it to be a valid write.
The FIFO contains overflow circuitry to disallow additional
writes when the FIFO is full, and underflow circuitry to disallow
additional reads when the FIFO is empty. An empty FIFO
maintains the data of the last valid read on its Q0–8 outputs
even after additional reads occur.
Flag Operation
The CY7C441/3 provide two flags, F1 and F2, which are used
to decode four FIFO states (see Table 1). All flags are synchronous, meaning that the change of states is relative to one of
the clocks (CKR or CKW, as appropriate; see Figure 1). The
synchronous architecture guarantees some minimum valid
time for the flags.
The Empty and Almost Empty flag states are exclusively updated by each rising edge of the read clock (CKR). For example, when the FIFO contains 1 word, the next read (rising edge
of CKR while ENR=LOW) causes the F1 and F2 pins to output
a state signifying the Empty condition. The Almost Full flag is
updated exclusively by the write clock (CKW). For example, if
the CY7C443 FIFO contains 2031 words (2032 words or
greater indicates Almost Full in the CY7C443), the next write
(rising edge of CKW while ENW=LOW) causes the F1 and F2
pins to output the Almost Full state.
Table 1. Flag Truth Table
State
CY7C441
Number of
Words in FIFO
CY7C443
Number of
Words in FIFO
F1
F2
0
0
Empty
0
0
1
0
Almost
Empty
1 – 16
1 – 16
1
1
Intermediate
Range
17 – 495
17 – 2031
0
1
Almost Full
or Full
496 – 512
2032 – 2048
E
CKR
F1
AF
CKW
F2
AE
CKR
INTERNAL LOGIC
PINS
C441-16
Figure 1. Flag Logic Diagram
Flag Operation (continued)
Since the flags denoting emptiness (Empty, Almost Empty) are
only updated by CKR and the Almost Full flag is only updated
by the CKW, careful attention must be given to the flag operation. The user must be aware that if a flag boundary (Empty,
Almost Empty, and Almost Full) is crossed due to an operation
from a clock that the flag is not synchronized to (i.e.,CKR does
not effect Almost Full), a flag update is necessary to represent
the FIFO’s new state. This signal to which a flag is not synchronized will be referred to as the opposite clock (CKW is opposite
clock for Empty and Almost Empty flags; CKR is the opposite
clock for the Almost Full flag).
Until the flag update cycle is executed, the synchronous flags
do not show the true state of the FIFO. For example, if 2,040
Document #: 38-06032 Rev. *A
writes are performed to an empty CY7C443 without a single
read, F1 and F2 will still exhibit an Empty flag. This is because
F2 is exclusively updated by the CKR, therefore, a single read
(flag update cycle) is necessary to update flags to Almost Full
state. It should be noted that this flag update read does not
require ENR = LOW, so a free-running read clock will initiate
the flag update cycle.
When updating the flags, the CY7C441/443 decide whether or
not the opposite clock was recognized when a clock updates
the flag. For example, if a write occurs at least tSKEW1 after a
read when updating the Empty flag, the write is guaranteed not
to be included when CKR updates the flag. If a write occurs at
least tSKEW2 before a read, the write is guaranteed to be included when CKR updates the flag. If a write occurs within
tSKEW1/tSKEW2 after or before CKR, then the decision of
Page 10 of 15
CY7C441
CY7C443
whether or not to include the write when the flag is updated by
CKR is arbitrary.
The update cycle for non-boundary flags (Almost Empty, Almost Full) is different from that used to update the boundary
flag (Empty). Both operations are described below.
Boundary Flag (Empty)
The Empty flag is synchronized to the CKR signal. The Empty
flag can only be updated by a clock pulse on the CKR pin. An
empty FIFO that is written to will be described with an Empty
flag state until a clock pulse is presented on the CKR pin.
When making the transition from Empty to Almost Empty (or
Empty to Intermediate or Empty to Almost Full), a clock cycle
on the CKR is necessary to update the flags to the current
state. Such a state (flags displaying empty even though data
has been written to the FIFO) would require two read cycles to
read data out of FIFO. The first read serves only to update the
flags to the Almost Empty, Intermediate, or Almost Full state,
and the second read outputs the data. This first read cycle is
known as the latent or flag update cycle because it does not
affect the data in the FIFO or the count (number of words in
FIFO). It simply deasserts the Empty flag. The flags are updated regardless of the ENR state. Therefore the update occurs
even when ENR is deasserted (HIGH) so that a valid read is
not necessary to update the flags to correctly describe the
FIFO. With a free-running clock connected to CKR, the flag
updates with each cycle. Table 2 shows sample operations
that update the Empty flag.
Although a Full flag is not supplied externally on the
CY7C441/CY7C443, a Full flag exists internally. The operation
of the FIFO at the Full boundary is analogous to its operation
at the Empty boundary. See the text section “Boundary Flags
(Full)” in the CY7C451/CY7C453 datasheet.
Non-Boundary Flags (Almost Empty, Almost Full)
The flag status pins, F1 and F2, exhibit the Almost Empty status when both the CY7C441 and the CY7C443 contain 16
words or less. The Almost Full Flag becomes active when the
FIFO contains 16 or less empty locations. The CY7C441 becomes Almost Full when it contains 496 words. The CY7C443
becomes Almost Full when it contains 2032 words. The Almost
Empty flag (like the Empty flag) is synchronous to the CKR
signal, whereas the Almost Full flag is synchronous to the
CKW signal. Non-boundary flags employ flag update cycles
similar to the boundary flag latent cycles in order to update the
FIFO state. For example, if the FIFO just reaches the Almost
Document #: 38-06032 Rev. *A
Empty state (16 words) and then two words are written, a read
clock (CKR) will be required to update the flags to the Intermediate state. However, unlike the boundary (Empty) flag’s update cycle, the state of the enable pin (ENR in this case) affects the operation. Therefore, ENR set-up (tSEN) and hold
(tHEN) times must be met. If ENR is asserted (ENR=LOW) during the latent cycle, the count and data update in addition to
F1 and F2. If ENR is not active (ENR=1) during the flag update
cycle, only the flag is updated.
The same principles apply for updating the flags when a transition from the Almost Full to the Intermediate state occurs. If
the CY7C443 just reaches the Almost Full state (2032 words)
and then two words are read, a write clock (CKW) will be required to update the flag to the Intermediate state. If ENW is
LOW during the flag update cycle, the count and data update
in addition to the flags. If ENW is HIGH, only the flag is updated. Therefore, ENW set-up (tSEN) and hold (tHEN) times must
be met. Tables 3 and 4 show examples for a sequence of operations that affect the Almost Empty and Almost Full flags,
respectively.
Width Expansion
The CY7C441/3 can be expanded in width to provide word
width greater than 9 in increments of 9. During width expansion mode, all control inputs are common. When the FIFO is
being read near the Empty boundary, it is important to note that
both sets of flags should be checked to see if they have been
updated to the Not Empty condition on all devices.
Checking all sets of flags is critical so that data is not read from
the FIFOs “staggered” by one clock cycle. This situation could
occur when the first write to an empty FIFO and a read are very
close together. If the read occurs less than tSKEW2 after the first
write to two width expanded devices (A and B), device A may
go Almost Empty (read recognized as flag update) while device B stays Empty (read ignored).The first write occurs because a read within tSKEW2 of the first write is only guaranteed
to be either recognized or ignored, but which of the two is not
guaranteed. The next read cycle outputs the first half of the
first word on device A while device B updates its flags to Almost Empty. Subsequent reads will continue to output “staggered” data assuming more data has been written to the
FIFOs.
In the width expansion configuration, any of the devices’ flags
may be monitored for the composite Almost Full status.
Page 11 of 15
CY7C441
CY7C443
Table 2. Empty Flag Operation Example [28]
Status Before Operation
Status After Operation
F1
F2
Number
of Words
in FIFO
F1
F2
Number
of Words
in FIFO
Empty
0
0
0
Write
(ENW = LOW)
Empty
0
0
1
Write
Empty
0
0
1
Write
(ENW = LOW)
Empty
0
0
2
Write
Empty
0
0
2
Read
(ENR = HIGH)
AE
1
0
2
Flag Update
AE
1
0
2
Read
(ENR = LOW)
AE
1
0
1
Read
AE
1
0
1
Read
(ENR = LOW)
Empty
0
0
0
Read (Transition for
Almost Empty to Empty)
Empty
0
0
0
Write
(ENW = LOW)
Empty
0
0
1
Write
Empty
0
0
1
Read
(ENR = X)
AE
1
0
1
Flag Update
AE
1
0
1
Read
(ENR = LOW)
Empty
0
0
0
Read (Transition from
Almost Empty to Empty)
Current
State of FIFO
Operation
Next State
of FIFO
Table 3. Almost Empty Flag Operation Example[28]
Status Before Operation
Current
State of FIFO
F1
F2
Number of
Words
in FIFO
AE
1
0
16
Write
(ENW = LOW)
AE
1
0
17
AE
1
0
Intermediate
1
AE
1
Comments
Status After Operation
F1
F2
Number of
Words in
FIFO
AE
1
0
17
Write
Write
(ENW = LOW)
AE
1
0
18
Write
18
Read
(ENR = LOW)
Intermediate
1
1
17
Flag Update
and Read
1
17
Read
(ENR = LOW)
AE
1
0
16
Read (Transition
from Intermediate
to Almost Empty)
0
16
Read
(ENR = HIGH)
AE
1
0
16
Ignored Read
Operation
Next State
of FIFO
Comments
Note:
28. Applies to both the CY7C441 and CY7C443 operations.
Document #: 38-06032 Rev. *A
Page 12 of 15
CY7C441
CY7C443
Table 4. Almost Full Flag Operation Example[29,30]
Status Before Operation
Status After Operation
Number Number
of Words of Words
Current State
in FIFO
in FIFO
of FIFO
F1 F2 CY7C441 CY7C443
Number of Number of
Words in Words in
FIFO
FIFO
F1 F2 CY7C441 CY7C443 Comments
Operation
Next State
of FIFO
AF
0
1
496
2032
Read
(ENR=LOW)
AF
0
1
495
2031
Read
AF
0
1
495
2031
Read
(ENR=LOW)
AF
0
1
494
2030
Read
AF
0
1
494
2030
Write
Intermediate
(ENW=HIGH)
1
1
494
2030
Flag
Update
Intermediate
1
1
494
2030
Write
(ENW=LOW)
Intermediate
1
1
495
2031
Write
Intermediate
1
1
495
2031
Write
(ENW=LOW)
AF
0
1
496
2032
Write
(Transition
from Intermediate
toAlmost
Full)
Note:
29. The CY7C441 Almost Full state is represented by 496 or more words.
30. The CY7C443 Almost Full state is represented by 2032 or more words.
Ordering Information
512x9 Clocked FIFO
Speed
(ns)
12
14
20
30
Ordering Code
Package
Name
Package Type
Operating
Range
CY7C441–12JC
J65
32-Lead Plastic Leaded Chip Carrier
Commercial
CY7C441–12JI
J65
32-Lead Plastic Leaded Chip Carrier
Industrial
CY7C441–14JC
J65
32-Lead Plastic Leaded Chip Carrier
Commercial
CY7C441–14JI
J65
32-Lead Plastic Leaded Chip Carrier
Industrial
CY7C441–20JC
J65
32-Lead Plastic Leaded Chip Carrier
Commercial
CY7C441–20JI
J65
32-Lead Plastic Leaded Chip Carrier
Industrial
CY7C441–30JC
J65
32-Lead Plastic Leaded Chip Carrier
Commercial
CY7C441–30JI
J65
32-Lead Plastic Leaded Chip Carrier
Industrial
2Kx9 Clocked FIFO
Speed
(ns)
12
14
20
30
Ordering Code
Package
Name
Package Type
Operating
Range
CY7C443–12JC
J65
32-Lead Plastic Leaded Chip Carrier
Commercial
CY7C443–12JI
J65
32-Lead Plastic Leaded Chip Carrier
Industrial
CY7C443–14JC
J65
32-Lead Plastic Leaded Chip Carrier
Commercial
CY7C443–14JI
J65
32-Lead Plastic Leaded Chip Carrier
Industrial
CY7C443–20JC
J65
32-Lead Plastic Leaded Chip Carrier
Commercial
CY7C443–20JI
J65
32-Lead Plastic Leaded Chip Carrier
Industrial
CY7C443–30JC
J65
32-Lead Plastic Leaded Chip Carrier
Commercial
CY7C443–30JI
J65
32-Lead Plastic Leaded Chip Carrier
Industrial
Document #: 38-06032 Rev. *A
Page 13 of 15
CY7C441
CY7C443
Package Diagrams
32-Lead Plastic Leaded Chip Carrier J65
Document #: 38-06032 Rev. *A
Page 14 of 15
© Cypress Semiconductor Corporation, 2001. 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 Semiconductor product. Nor does it convey or imply any license under patent or other rights. Cypress Semiconductor 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
Semiconductor products in life-support systems application implies that the manufacturer assumes all risk of such use and in doing so indemnifies Cypress Semiconductor against all charges.
CY7C441
CY7C443
Document Title: CY7C441 / CY7C443 Clocked 512 x 9, 2K x 9 FIFOs
Document Number: 38-06032
REV.
ECN NO.
Issue
Date
Orig. of
Change
Description of Change
**
110173
09/29/01
SZV
Change from Spec number: 38-00124 to 38-06032
*A
122283
12/26/02
RBI
Power up requirements added to Maximum Ratings Information
Document #: 38-06032 Rev. *A
Page 15 of 15