OKI MS8104160A-XXTB Dual fifo (262,214 words ã 8 bits) ã 2 Datasheet

OKI Semiconductor
MS8104160A
FEDS8104160A-01
This version: Nov. 21, 2002
Dual FIFO (262,214 Words × 8 Bits) × 2
GENERAL DESCRIPTION
The MS8104160A is a single-chip 4Mb FIFO functionally composed of two OKI 2Mb FIFO (First-In First-Out)
memories which were designed for 262,214 x 8-bit high-speed asynchronous read/write operation.
The read clocks and the write clocks of each of the 2Mb FIFO memories are connected in common. The
MS8104160A, functionally compatible with Oki's 2Mb FIFO memory (MSM518222A), can be used as a x16
configuration FIFO.
The MS8104160A is a field memory for wide or low end use in general commodity TVs and VTRs exclusively
and is not designed for high end use in professional graphics systems, which require long term picture storage, data
storage, medical use and other storage systems.
The MS8104160A provides independent control clocks to support asynchronous read and write operations.
Different clock rates are also supported, which allow alternate data rates between write and read data streams.
The MS8104160A provides high speed FIFO (First-in First-out) operation without external refreshing:
MS8104160A refreshes its DRAM storage cells automatically, so that it appears fully static to the users.
Moreover, fully static type memory cells and decoders for serial access enable the refresh free serial access
operation, so that serial read and/or write control clock can be halted high or low for any duration as long as the
power is on. Internal conflicts of memory access and refreshing operations are prevented by special arbitration
logic.
The MS8104160A’s function is simple, and similar to a digital delay device whose delay-bit- length is easily set by
reset timing. The delay length and the number of read delay clocks between write and read, is determined by
externally controlled write and read reset timings.
Additional SRAM serial registers, or line buffers for the initial access of 71 x 16-bit enable high speed
first-bit-access with no clock delay just after the write or read reset timings.
Additionally, the MS8104160A has a write mask function or input enable function (IE), and read- data skipping
function or output enable function (OE). The differences between write enable (WE) and input enable (IE), and
between read enable (RE) and output enable (OE) are that WE and RE can stop serial write/read address
increments, but IE and OE cannot stop the increment, when write/read clocking is continuously applied to
MS8104160A. The input enable (IE) function allows the user to write into selected locations of the memory only,
leaving the rest of the memory contents unchanged. This facilitates data processing to display a “picture in picture”
on a TV screen.
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FEDS8104160A-01
OKI Semiconductor
MS8104160A
FEATURES
•
•
•
•
•
•
•
•
•
262,214 words × 8 bits × 2
Fast FIFO (First-In First-Out) Operation: 25 ns cycle time
Self refresh (No refresh control is required)
High speed asynchronous serial access
Read/Write Cycle Time
20 ns/25 ns
Access Time
18 ns/22 ns
Variable length delay bit (150 to 262214)
Write mask function (Output enable control)
Cascading capability by mode setting
Single power supply: 5.0 V ± 0.5V
Package:
100-Pin plastic TQFP (TQFP 100-P-1414-0.50-k) (Product: MS8104160A-xxTB)
xx indicates speed rank.
Parameter
Access Time
Symbol
tAC
MS8104160A-xxTB
–20
–25
18 ns
22 ns
20 ns
25 ns
Read/Write
tSWC
Cycle Time
tSRC
Operation current
ICC1
170 mA
170 mA
Standby current
ICC2
5 mA
5 mA
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FEDS8104160A-01
OKI Semiconductor
MS8104160A
100
99
98
97
96
95
94
93
92
91
90
89
88
87
86
85
84
83
82
81
80
79
78
77
76
NC
DI22
DI21
DI20
RSTW2
IE2
WE2
VSS
VCC
VSS
NC
VCC
NC
VSS
NC
MODE1
NC
VCC
RSTR2
RE2
OE2
NC
VSS
VSS
NC
PIN CONFIGURATION (TOP VIEW)
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
75
74
73
72
71
70
69
68
67
66
65
64
63
62
61
60
59
58
57
56
55
54
53
52
51
100 PIN TQFP
TOP VIEW
VCC
DO20
DO21
VSS
DO22
DO23
DO24
DO25
VSS
DO26
DO27
VCC
SRCK
VCC
DO17
DO16
VSS
DO15
DO14
DO13
DO12
VSS
DO11
DO10
VCC
NC
DI12
DI11
DI10
RSTW1
IE1
WE1
VSS
VCC
VSS
NC
VCC
NC
VSS
NC
MODE2
NC
VCC
RSTR1
RE1
OE1
NC
VSS
VSS
NC
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
NC
DI23
VSS
DI24
DI25
DI26
DI27
NC
VSS
VSS
VCC
VCC
SWCK
VCC
VCC
VSS
VSS
NC
DI17
DI16
DI15
DI14
VSS
DI13
NC
Pin Name
SWCK
Function
Pin Name
Function
Serial Write clock
SRCK
Serial Read Clock
Port1 Write Enable
WE2
Port2 Write Enable
RE1
Port1 Read Enable
RE2
Port2 Read Enable
IE1
Port1 Input Enable
IE2
Port2 Input Enable
OE1
Port1 Output Enable
OE2
Port2 Output Enable
WE1
RSTW1
Port1 Reset Write
RSTW2
Port2 Reset Write
RSTR1
Port1 Reset Read
RSTR2
Port2 Reset Read
DI10 to 17
Port1 Data Input
DI20 to 27
Port2 Data Input
DO10 to 17
Port1 Data Output
DO20 to 27
Port2 Data Output
MODE1,2
VCC
Note:
Mode Input
NC
No Connection
Power Supply (5.0 V)
VSS
Ground (0 V)
The same power supply voltage must be provided to every VCC pin, and the same GND
voltage level must be provided to every VSS pin.
3/24
DI (×8)
Data-In
Buffer (×8)
71 Word
Sub-Register (×8)
71 Word
Sub-Register (×8)
Data-Out
Buffer (×8)
DO (×8)
×8
Memory
Array
256k (×8)
×8
WE1
×
Decoder
SWCK
Controller
RSTW1
Write
Serial Read Register (×8)
Serial
IE1
SRCK
Controller
RSTR1
Read
RE1
Serial Read Register (×8)
Serial
OE1
Read/Write
and Refresh
Controller
VBB
Generator
MODE1,2
Clock
Oscillator
Read/Write
and Refresh
Controller
OE2
Controller
RE2
×8
×8
Memory
Array
256k (×8)
Serial
RSTW2
Write
WE2
IE2
Controller
Serial Write Register (×8)
SWCK
Decoder
×
Read
RSTR2
Serial Read Register (×8)
Serial
SRCK
DI (×8)
Data-In
Buffer (×8)
71 Word
Sub-Register (×8)
71 Word
Sub-Register (×8)
Data-Out
Buffer (×8)
DO (×8)
FEDS8104160A-01
OKI Semiconductor
MS8104160A
BLOCK DIAGRAM
4/24
FEDS8104160A-01
OKI Semiconductor
MS8104160A
PIN DESCRIPTION
Data Inputs: (DIN10 to 17)
These pins are used for serial data inputs.
Write Reset: RSTW1
The first positive transition of SWCK after RSTW becomes high resets the write address pointers to zero. RSTW1
setup and hold times are referenced to the rising edge of SWCK. Because the write reset function is solely
controlled by the SWCK rising edge after the high level of RSTW1, the states of WE1 and IE1 are ignored in the
write reset cycle. Before RSTW1 may be brought high again for a further reset operation, it must be low for at least
two SWCK cycles.
Write Enable: WE1
WE1 is used for data write enable/disable control. WE1 high level enables the input, and WE1 low level disables
the input and holds the internal write address pointer. There are no WE1 disable time (low) and WE1 enable time
(high) restrictions, because the MS8104160A is in fully static operation as long as the power is on. Note that WE1
setup and hold times are referenced to the rising edge of SWCK.
Input Enable: IE1
IE1 is used to enable/disable writing into memory. IE1 high level enables writing. The internal write address
pointer is always incremented by cycling SWCK regardless of the IE1 level. Note that IE1 setup and hold times are
referenced to the rising edge of SWCK.
Data Out: (DOUT0 to 11)
These pins are used for serial data outputs.
Read Reset: RSTR1
The first positive transition of SRCK after RSTR1 becomes high resets the read address pointers to zero. RSTR1
setup and hold times are referenced to the rising edge of SRCK. Because the read reset function is solely controlled
by the SRCK rising edge after the high level of RSTR, the states of RE1 and OE1 are ignored in the read reset cycle.
Before RSTR may be brought high again for a further reset operation, it must be low for at least *two SRCK
cycles.
Read Enable: RE1
The function of RE1 is to gate of the SRCK clock for incrementing the read pointer. When RE1 is high before the
rising edge of SRCK, the read pointer is incremented. When RE1 is low, the read pointer is not incremented. RE1
setup times (tRENS and tRDSS) and RE1 hold times (tRENH and tRDSH) are referenced to the rising edge of the SRCK
clock.
Output Enable: OE1
OE1 is used to enable/disable the outputs. OE1 high level enables the outputs. The internal read address pointer is
always incremented by cycling SRCK regardless of the OE1 level. Note that OE1 setup and hold times are
referenced to the rising edge of SRCK.
Serial Write: Clock SWCK
The SWCK latches the input data on chip when WE1,2 and IE1,2 are high, and also increments the internal write
address pointer when WE1,2 is high. Data-in setup time tDS, and hold time tDH are referenced to the rising edge of
SWCK.
Serial Read Clock: SRCK
Data is shifted out of the data registers. It is triggered by the rising edge of SRCK when RE1, 2 is high during a
read operation. The SRCK input increments the internal read address pointer when RE1, 2 is high.
The three-state output buffer provides direct TTL compatibility (no pullup resistor required). Data out is the same
polarity as data in. The output becomes valid after the access time interval tAC that begins with the rising edge of
SRCK.
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FEDS8104160A-01
OKI Semiconductor
MS8104160A
Data Input: (DIN20 to 27)
These pins are used for serial data inputs.
Write Reset: RSTW2
The first positive transition of SWCK after RSTW becomes high resets the write address pointers to zero. RSTW2
setup and hold times are referenced to the rising edge of SWCK. Because the write reset function is solely
controlled by the SWCK rising edge after the high level of RSTW2, the states of WE2 and IE2 are ignored in the
write reset cycle. Before RSTW2 may be brought high again for a further reset operation, it must be low for at least
two SWCK cycles.
Write Enable: WE2
WE is used for data write enable/disable control. WE2 high level enables the input, and WE2 low level disables the
input and holds the internal write address pointer. There are no WE2 disable time (low) and WE2 enable time
(high) restrictions, because the MS8104160A is in fully static operation as long as the power is on. Note that WE2
setup and hold times are referenced to the rising edge of SWCK.
Input Enable: IE2
IE2 is used to enable/disable writing into memory. IE2 high level enables writing. The internal write address
pointer is always incremented by cycling SWCK regardless of the IE2 level. Note that IE2 setup and hold times are
referenced to the rising edge of SWCK.
Data Out: (DOUT20 to 27)
These pins are used for serial data outputs.
Read Reset: RSTR2
The first positive transition of SRCK after RSTR2 becomes high resets the read address pointers to zero. RSTR2
setup and hold times are referenced to the rising edge of SRCK. Because the read reset function is solely controlled
by the SRCK rising edge after the high level of RSTR2, the states of RE2 and OE2 are ignored in the read reset
cycle. Before RSTR2 may be brought high again for a further reset operation, it must be low for at least *two
SRCK cycles.
Output Enable: OE2
OE2 is used to enable/disable the outputs. OE2 high level enables the outputs. The internal read address pointer is
always incremented by cycling SRCK regardless of the OE2 level. Note that OE2 setup and hold times are
referenced to the rising edge of SRCK.
Mode Setting1: MODE1
The Cascade/Non cascade select pin. Setting the MODE1 pin to the VCC level configures this memory device as
cascade type and setting the pin to the VSS level configures this memory device as non cascade. During memory
operation, the pin must be permanently connected to VCC or VSS. If a MODE1 level is changed during memory
operation, memory data is not guaranteed.
Mode Setting2: MODE2
MODE2 selects whether the control input signals are enabled at a high level or a low level. Setting MODE2 to the
Vcc level enables the control input signals at a low level and setting MODE2 to the Vss level enables the control
input signals at a high level.
Note: Cascade/Non cascade
When MODE1 is set to the VSS level, memory accessing starts in the cycle in which the control signals are input
(Non cascade type). When MODE1 is set to the VCC level, memory accessing starts in the cycle subsequent to the
cycle in which the control signals are input (Cascade type). This type is used for consecutive memory accessing.
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FEDS8104160A-01
OKI Semiconductor
MS8104160A
ELECTRICAL CHARACTERISTICS
Absolute Maximum Ratings
Parameter
Symbol
Condition
Rating
Input Output Voltage
VT
at Ta = 25°C, VSS
–1.0 to +7.0
V
Output Current
IOS
Ta = 25°C
50
mA
Power Dissipation
Unit
PD
Ta = 25°C
1
W
Operating Temperature
TOPR
—
0 to 70
°C
Storage Temperature
TSTG
—
–55 to +150
°C
Recommended Operating Conditions
Parameter
Symbol
Min.
Typ.
Max.
Unit
Power Supply Voltage
VCC
4.5
5.0
5.5
V
Power Supply Voltage
VSS
0
0
0
V
Input High Voltage
VIH
2.4
VCC
VCC +0.5
V
Input Low Voltage
VIL
–0.3
0
+0.8
V
DC Characteristics
Parameter
Symbol
Condition
Min.
Max.
Unit
Input Leakage Current
ILI
0<VI<VCC, Other input pins at V = 0
V
–10
+10
µA
Output Leakage Current
ILO
0<VO<VCC
–10
+10
µA
Output “H” Level Voltage
VOH
IOH = –1 mA
2.4
—
V
Output “L” Level Voltage
VOL
IOL = 2 mA
—
0.4
V
Operating Current
ICC1
Minimum Cycle Time, Output Open
—
170
mA
Standby Current
ICC2
Input Pin = VIH/VIL
—
5
mA
Capacitance
(Ta = 25°C, f = 1 MHz)
Symbol
Max.
Unit
Input Capacitance (DI, SWCK, SRCK, RSTW, RSTR, WE, RE, IE, OE)
Parameter
CI
7
pF
Output Capacitance (DO)
CO
7
pF
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FEDS8104160A-01
OKI Semiconductor
MS8104160A
AC Characteristics
(VCC = 5.0 V ±0.5 V, Ta = 0 to 70°C)
Parameter
Access Time from SRCK
DOUT Hold Time from SRCK
DOUT Enable Time from SRCK
SWCK “H” Pulse Width
SWCK “L” Pulse Width
Input Data Setup Time
Input Data Hold Time
WE Enable Setup Time
WE Enable Hold Time
WE Disable Setup Time
WE Disable Hold Time
IE Enable Setup Time
IE Enable Hold Time
IE Disable Setup Time
IE Disable Hold Time
WE “H” Pulse Width
WE “L” Pulse Width
IE “H” Pulse Width
IE “L” Pulse Width
RSTW Setup Time
RSTW Hold Time
SRCK “H” Pulse Width
SRCK “L” Pulse Width
RE Enable Setup Time
RE Enable Hold Time
RE Disable Setup Time
RE Disable Hold Time
OE Enable Setup Time
OE Enable Hold Time
OE Disable Setup Time
OE Disable Hold Time
RE “H” Pulse Width
RE “L” Pulse Width
OE “H” Pulse Width
OE “L” Pulse Width
RSTR Setup Time
RSTR Hold Time
SWCK Cycle Time
SRCK Cycle Time
Transition Time (Rise and Fall)
Symbol
tAC
tDDCK
tDECK
tWSWH
tWSWL
tDS
tDH
tWENS
tWENH
tWDSS
tWDSH
tIENS
tIENH
tIDSS
tIDSH
tWWEH
tWWEL
tWIEH
tWIEL
tRSTWS
tRSTWH
tWSRH
tWSRL
tRENS
tRENH
tRDSS
tRDSH
tOENS
tOENH
tODSS
tODSH
tWREH
tWREL
tWOEH
tWOEL
tRSTRS
tRSTRH
tSWC
tSRC
tT
MS8104160A-20
Min.
Max.
—
18
6
—
6
20
9
—
9
—
3
—
5
—
5
—
5
—
5
—
5
—
5
—
5
—
5
—
5
—
5
—
5
—
5
—
5
—
3
—
10
—
9
—
9
—
5
—
5
—
5
—
5
—
5
—
5
—
5
—
5
—
5
—
5
—
5
—
5
—
3
—
10
—
20
—
20
—
3
30
MS8104160A-25
Min.
Max.
—
22
6
—
6
25
12
—
12
—
3
—
5
—
5
—
5
—
5
—
5
—
5
—
5
—
5
—
5
—
5
—
5
—
5
—
5
—
3
—
10
—
12
—
12
—
5
—
5
—
5
—
5
—
5
—
5
—
5
—
5
—
5
—
5
—
5
—
5
—
3
—
10
—
25
—
25
—
3
30
Unit
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
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FEDS8104160A-01
OKI Semiconductor
MS8104160A
AC Characteristics Measuring Conditions
Output Compare Level
Output Load
Input Signal Level
1.5 V / 1.5 V
1 TTL + 30 pF
3.0 V / 0.0 V
Input Signal Rise/Fall Time
3 ns
Input Signal Measuring Reference Level
1.5 V
1. Input voltage levels for the AC characteristic measurement are VIH = 3.0 V and VIL= 0 V.
The transition time tT is defined to be a transition time that signal transfers between VIH = 3.0 V and
VIL = 0 V.
2. AC measurements assume tT = 3 ns.
3. Read address must have more than a 150 address delay than write address in every cycle when
asynchronous read/write is performed.
4. Read must have more than a 150 address delay than write in order to read the data written in a
current series of write cycles which has been started at last write reset cycle: this is called “new data
read”. When read has less than a 20 address delay than write, the read data are the data written in
a previous series of write cycles which had been written before at last write reset cycle: this is called
“old data read”.
5. When the read address delay is between more than 21 and less than 149 or more than 262,214, read
data will be undetermined. However, normal write is achieved in this address condition.
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FEDS8104160A-01
OKI Semiconductor
MS8104160A
OPERATION MODE
Write Operation Cycle (MODE2 = VSS)
The write operation is controlled by seven control signals, SWCK, RSTW1, RSTW2, WE1, WE2 and IE1, IE2.
Port1 write operation is accomplished by cycling SWCK, and holding WE1 and IE1 high after the write address
pointer reset operation or RSTW1. RSTW1 must be preformed for internal circuit initialization before Write
operation.
Each write operation, which begins after RSTW1, must contain at least 140 active write cycles, i.e. SWCK cycles
while WE1 and IE1 are high. To transfer the last data to the DRAM array, which at that time is stored in the serial
data registers attached to the DRAM array, an RSTW1 operation is required after the last SWCK cycle.
Note that every write timing of MS8104160A is delayed by one clock compared with read timings for easy
cascading without any interface delay devices.
Setting MODE1 to the VSS level starts write data accessing in the cycle in which RSTW1, WE1, and IE1 control
signals are input.
Setting MODE1 to the VCC level starts write data accessing in the cycle subsequent to the cycle in which RSTW1,
WE1, and IE1 control signals are input.
These operation are the same for Port1 and Port2.
Settings of WE1, 2 and IE1, 2 to the operation mode of Write address pointer and Data input.
WE1, 2
IE1, 2
H
H
H
L
L
X
Internal Write address pointer
Incremented
Halted
Data input
Input
Not input
X indicates “don’t care”
Write Operation Cycle (MODE2=VCC)
The write operation is controlled by seven control signals, SWCK, RSTW1, RSTW2, WE1, WE2, and IE1, IE2.
Port1 write operation is accomplished by cycling SWCK and holding WE1 and IE1 low after the write address
pointer reset operation or RSTW1. RSTW1 must be performed for internal circuit initialization before write
operation.
Each write operation, which begins after RSTW1, must contain at least 140 active write cycle, i.e. SWCK cycles
while WE1 and IE1 are high. To transfer the last data to the DRAM array, which at that time is stored in the serial
data registers attached to the DRAM array, an RSTW1 operation is required after the last SWCK cycle.
Note that every write timing of MS8104160A is delayed by one clock compared with read timings for easy
cascading without any interface delay devices.
Setting MODE1 to the VSS level starts write data accessing in the cycle in which RSTW1.WE1, and IE1 control
signals are input.
Setting MODE1 to the VCC level starts write data accessing in the cycle in which RSTW1, WE1, and IE1 control
signals are input.
Setting MODE1 to the VCC level starts write data accessing in the cycle subsequent to the cycle in which RSTW1,
WE1, and IE1 control signals are input.
These operations are the same for port1 and Port2.
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FEDS8104160A-01
OKI Semiconductor
MS8104160A
Read Operation Cycle (MODE2=VSS)
The read operation is controlled by seven control signals, SRCK, RSTR1, RSTR2, RE1, RE2, and OE1, OE2.
Port1 read operation is accomplished by cycling SRCK, and holding RE1 and OE1 high after the read address
pointer reset operation or RSTR1.
Each read operation, which begins after RSTR1, must contain at least 140 active read cycles, i.e. SRCK cycles
while RE1 and OE1 are high.
These operations are the same for Port1 and Port2.
Settings of RE1, 2 and OE1, 2 to the operation mode of read address pointer and Data output.
WE1, 2
IE1, 2
H
H
H
L
L
X
L
L
Internal Write address pointer
Incremented
Halted
Data output
Output
High impedance
Output
High impedance
Read Operation Cycle (MODE2=VCC)
The read operation is controlled by seven control signals, SRCK, RSTR1, RSTR2, RE1, RE2, and OE1, OE2.
Port1 read operation is accomplished by cycling SRCK, and holding RE1 and OE1 low after the read address
pointer reset operation or RSTR1.
Each read operation, which begins after RSTR1, must contain at least 140 active read cycles, i.e. SRCK cycles
while RE1 and OE1 are low.
These operations are the same for Port1 and Port2.
Settings of RE1, 2 and OE1, 2 to the operation mode of read address pointer and Data output.
RE1,2
L
L
H
H
OE1,2 Internal Write address pointer
L
Incremented
H
L
Halted
H
Data output
Output
High impedance
Output
High impedance
11/24
FEDS8104160A-01
OKI Semiconductor
MS8104160A
Power-up and Initialization
On power-up, the device is designed to begin proper operation after at least 100 µs after VCC has stabilized to a
value within the range of recommended operating conditions. After this 100 µs stabilization interval, the following
initialization sequence must be performed.
Because the read and write address pointers are undefined after power-up, a minimum of 80 dummy write
operations (SWCK cycles) and read operations (SRCK cycles) must be performed, followed by an RSTW1, 2
operation and an RSTR1, 2 operation, to properly initialize the write and the read address pointer. Dummy write
cycles/RSTW1, 2 and dummy read cycles/RSTR1, 2 may occur simultaneously.
If these dummy read and write operations start while VCC and/or the substrate voltage has not stabilized, it is
necessary to perform an RSTR1, 2 operation plus a minimum of 80 SRCK cycles plus another RSTR1, 2 operation,
and an RSTW1, 2 operation plus a minimum of 80 SWCK cycles plus another RSTW1, 2 operation to properly
initialize read and write address pointers.
Old/New Data Access
There must be a minimum delay of 150 SWCK cycles between writing into memory and reading out from memory.
If reading from the first field starts with an RSTR1, 2 operation, before the start of writing the second field (before
the next RSTW1, 2 operation), then the data just written will be read out.
The start of reading out the first field of data may be delayed past the beginning of writing in the second field of
data for as many as 20 SWCK cycles. If the RSTR1, 2 operation for the first field read-out occurs less than 20
SWCK cycles after the RSTW1, 2 operation for the second field write-in, then the internal buffering of the device
assures that the first field will still be read out. The first field of data that is read out while the second field of data
is written is called “old data”. In order to read out “new data”, i.e., the second field written in, the delay between an
RSTW1, 2 operation and an RSTR1, 2 operation must be at least 150 SRCK cycles. If the delay between RSTW1,
2 and RSTR1, 2 operations is more than 21 but less than 149 cycles, then the data read out will be undetermined. It
may be “old data” or “new data”, or a combination of old and new data. Such a timing should be avoided.
12/24
FEDS8104160A-01
OKI Semiconductor
MS8104160A
TIMING WAVEFORM
Write Cycle Timing (Write Reset): MODE1 = VCC, MODE2 =VSS
0 cycle
n cycle
1 cycle
2 cycle
VIH
SWCK
VIL
tRSTWS
tRSTWH
tWSWH
tWSWL
tSWC
VIH
RSTW1, 2
VIL
tDS
tDH
VIH
DI
10-17/20-27
n–1
n
0
1
2
VIL
VIH
IE1, 2
VIL
VIH
WE1, 2
VIL
Write Cycle Timing (Write Enable): MODE1 = VCC, MODE2 =VSS
n cycle
Disable cycle
Disable cycle
n + 1 cycle
VIH
SWCK
tWENH
tWDSH
tWDSS
VIL
tWENS
VIH
tWWEL
WE1, 2
VIL
tWWEH
VIH
DI
10-17/20-27
n–1
n
n+1
VIL
VIH
IE1, 2
VIL
VIH
RSTW1, 2
VIL
13/24
FEDS8104160A-01
OKI Semiconductor
MS8104160A
Write Cycle Timing (Input Enable): MODE1 = VCC, MODE2 =VSS
n cycle
n + 1 cycle
n + 3 cycle
n + 2 cycle
VIH
SWCK
tIENH
tIDSH
tIDSS
VIL
tIENS
VIH
tWIEL
IE1, 2
VIL
tWIEH
VIH
DI
10-17/20-27
n–1
n+3
n
VIL
VIH
WE1, 2
VIL
VIH
RSTW1, 2
VIL
Write Cycle Timing (Write Reset): MODE1 = VCC, MODE2 =VCC
0 cycle
n cycle
1 cycle
2 cycle
VIH
SWCK
VIL
tRSTWS
tRSTWH
tWSWH
RSTW1, 2
tWSWL
VIH
tSWC
tDS
VIL
tDH
VIH
DI
10-17/20-27
n–1
n
0
1
2
VIL
VIH
IE1, 2
VIL
VIH
WE1, 2
VIL
14/24
FEDS8104160A-01
OKI Semiconductor
MS8104160A
Write Cycle Timing (Write Enable): MODE1 = VCC, MODE2 =VCC
n cycle
Disable cycle
n + 1 cycle
Disable cycle
VIH
SWCK
tWENH
tWDSH
VIL
tWENS
tWDSS
VIH
tWWEL
WE1, 2
VIL
tWWEH
VIH
DI
10-17/20-27
n–1
n+1
n
VIL
VIH
IE1, 2
VIL
VIH
RSTW1, 2
VIL
Write Cycle Timing (Input Enable): MODE1 = VCC, MODE2 =VCC
n cycle
n + 1 cycle
n + 2 cycle
n + 3 cycle
VIH
SWCK
tIENH
tIDSH
tIDSS
VIL
tIENS
VIH
tWIEL
IE1, 2
VIL
tWIEH
VIH
DI
10-17/20-27
n–1
n
n+3
VIL
VIH
WE1, 2
VIL
VIH
RSTW1, 2
VIL
15/24
FEDS8104160A-01
OKI Semiconductor
MS8104160A
Write Cycle Timing (Write Reset): MODE1 = VSS, MODE2 =VSS
n cycle
1 cycle
0 cycle
2 cycle
VIH
SWCK
tRSTWS
VIL
tRSTWH
tWSWH
tWSWL
VIH
tSWC
RSTW1, 2
VIL
tDS
tDH
VIH
DI
10-17/20-27
n
0
1
2
3
VIL
VIH
WE1, 2
VIL
VIH
IE1, 2
VIL
Write Cycle Timing (Write Enable): MODE1 = VSS, MODE2 =VSS
n cycle
Disable cycle
n + 1 cycle
Disable cycle
VIH
SWCK
tWENH
tWDSH
tWDS
VIL
tWENS
VIH
tWWEL
WE1, 2
VIL
tWWEH
VIH
DI
10-17/20-27
n
n+1
n
VIL
VIH
IE1, 2
VIL
VIH
RSTW1, 2
VIL
16/24
FEDS8104160A-01
OKI Semiconductor
MS8104160A
Write Cycle Timing (Input Enable): MODE1 = VSS, MODE2 =VSS
n cycle
n + 1 cycle
n + 2 cycle
n + 3 cycle
VIH
SWCK
tIDSH
tIENH
VIL
tIENS
tIDSS
tWIEL
VIH
IE1, 2
VIL
tWIEH
VIH
DI
10-17/20-27
n
n+3
n
n+4
VIL
VIH
WE1, 2
VIL
VIH
RSTW1, 2
VIL
Write Cycle Timing (Write Reset): MODE1 = VSS, MODE2 =VCC
n cycle
1 cycle
0 cycle
2 cycle
VIH
SWCK
VIL
tRSTWS
tWSWH
tRSTWH
tWSWL
VIH
RSTW1, 2
tSWC
VIL
tDS
tDH
VIH
DI
10-17/20-27
n
0
1
2
3
VIL
VIH
WE1, 2
VIL
VIH
IE1, 2
VIL
17/24
FEDS8104160A-01
OKI Semiconductor
MS8104160A
Write Cycle Timing (Write Enable): MODE1 = VSS, MODE2 =VCC
n cycle
Disable cycle
n + 1 cycle
Disable cycle
VIH
SWCK
tWENH
tWDSH
VIL
tWENS
tWDS
VIH
tWWEL
WE1, 2
VIL
tWWEH
VIH
DI
10-17/20-27
n
n+1
n
VIL
VIH
IE1, 2
VIL
VIH
RSTW1, 2
VIL
Write Cycle Timing (Input Enable): MODE1 = VSS, MODE2 =VCC
n cycle
n + 1 cycle
n + 2 cycle
n + 3 cycle
VIH
SWCK
tIDSH
tIENH
tIDSS
VIL
tIENS
VIH
tWIEL
IE1, 2
VIL
tWIEH
VIH
DI
10-17/20-27
n
n
n+3
n+4
VIL
VIH
WE1, 2
VIL
VIH
RSTW1, 2
VIL
18/24
FEDS8104160A-01
OKI Semiconductor
MS8104160A
Read Cycle Timing (Read Reset): MODE1 = VCC/VSS, MODE2 =VSS
n
cycle
0 cycle
2 cycle
1 cycle
VIH
SRCK
VIL
tRSTRS
tRSTRH
tWSRH
tWSRL
VIH
tSRC
RSTR1, 2
VIL
tDDCK
tAC
VIH
DO
10-17/20-27
n–1
n
0
1
2
VIL
VIH
RE1, 2
VIL
VIH
OE1, 2
VIL
Read Cycle Timing (Read Enable): MODE1 = VCC/VSS, MODE2 =VSS
n cycle
Disable cycle
Disable cycle
n + 1 cycle
VIH
SRCK
tRDSH
tREN
tRDSS
VIL
tRENS
VIH
tWREL
RE1, 2
VIL
tWREH
DO
10-17/20-27
VIH
n–1
n
n+1
VIL
VIH
OE1, 2
VIL
VIH
RSTR1, 2
VIL
19/24
FEDS8104160A-01
OKI Semiconductor
MS8104160A
Read Cycle Timing (Output Enable): MODE1 = VCC/VSS, MODE2 =VSS
n cycle
n + 2 cycle
n + 1 cycle
n + 3 cycle
VIH
SRCK
tOENH
tODSH
tODSS
VIL
tOENS
VIH
tWOEL
OE1, 2
tDECK
VIL
tWOEH
DO
10-17/20-27
VIH
n–1
n
Hi-Z
n+3
VIL
VIH
RE1, 2
VIL
VIH
RSTR1, 2
VIL
Read Cycle Timing (Read Reset): MODE1 = VCC/VSS, MODE2 =VCC
n cycle
0 cycle
2 cycle
1 cycle
VIH
SRCK
VIL
tRSTRS
tWSRH
tRSTRH
tWSRL
VIH
tSRC
RSTR1, 2
VIL
tDDCK
tAC
VIH
DO
10-17/20-27
n–1
n
0
1
2
VIL
VIH
RE1, 2
VIL
VIH
OE1, 2
VIL
20/24
FEDS8104160A-01
OKI Semiconductor
MS8104160A
Read Cycle Timing (Read Enable): MODE1 = VCC/VSS, MODE2 =VCC
n cycle
Disable cycle
Disable cycle
n + 1 cycle
VIH
SRCK
tRDSS
tRDSH
tREN
VIL
tRENS
VIH
RE1, 2
tWREL
VIL
tWREH
DO
10-17/20-27
VIH
n+1
n
n–1
VIL
VIH
OE1, 2
VIL
VIH
RSTR1, 2
VIL
Read Cycle Timing (Output Enable): MODE1 = VCC/VSS, MODE2 =VCC
n cycle
n + 1 cycle
n + 2 cycle
n + 3 cycle
VIH
SRCK
tOENH
tODSH
tODSS
VIL
tOENS
VIH
OE1, 2
tWOEL
tWOEH
DO
10-17/20-27
VIL
tDECK
VIH
n–1
n
Hi-Z
n+3
VIL
VIH
RE1, 2
VIL
VIH
RSTR1, 2
VIL
21/24
FEDS8104160A-01
OKI Semiconductor
MS8104160A
PACKAGE DIMENSIONS
(Unit: mm)
TQFP100-P-1414-0.50-K
Mirror finish
5
Package material
Lead frame material
Pin treatment
Package weight (g)
Rev. No./Last Revised
Epoxy resin
42 alloy
Solder plating (≥5µm)
0.55 TYP.
4/Oct. 28, 1996
Notes for Mounting the Surface Mount Type Package
The surface mount type packages are very susceptible to heat in reflow mounting and humidity
absorbed in storage.
Therefore, before you perform reflow mounting, contact Oki’s responsible sales person for the product
name, package name, pin number, package code and desired mounting conditions (reflow method,
temperature and times).
22/24
FEDS8104160A-01
OKI Semiconductor
MS8104160A
REVISION HISTORY
Document
No.
Date
FEDS8104160A-01
Nov. 21, 2002
Page
Previous Current
Edition
Edition
–
–
Description
Final edition 1
23/24
FEDS8104160A-01
OKI Semiconductor
MS8104160A
NOTICE
1. The information contained herein can change without notice owing to product and/or technical improvements.
Before using the product, please make sure that the information being referred to is up-to-date.
2.
The outline of action and examples for application circuits described herein have been chosen as an
explanation for the standard action and performance of the product. When planning to use the product, please
ensure that the external conditions are reflected in the actual circuit, assembly, and program designs.
3.
When designing your product, please use our product below the specified maximum ratings and within the
specified operating ranges including, but not limited to, operating voltage, power dissipation, and operating
temperature.
4.
Oki assumes no responsibility or liability whatsoever for any failure or unusual or unexpected operation
resulting from misuse, neglect, improper installation, repair, alteration or accident, improper handling, or
unusual physical or electrical stress including, but not limited to, exposure to parameters beyond the specified
maximum ratings or operation outside the specified operating range.
5.
Neither indemnity against nor license of a third party’s industrial and intellectual property right, etc. is
granted by us in connection with the use of the product and/or the information and drawings contained herein.
No responsibility is assumed by us for any infringement of a third party’s right which may result from the use
thereof.
6.
The products listed in this document are intended for use in general electronics equipment for commercial
applications (e.g., office automation, communication equipment, measurement equipment, consumer
electronics, etc.). These products are not authorized for use in any system or application that requires special
or enhanced quality and reliability characteristics nor in any system or application where the failure of such
system or application may result in the loss or damage of property, or death or injury to humans.
Such applications include, but are not limited to, traffic and automotive equipment, safety devices, aerospace
equipment, nuclear power control, medical equipment, and life-support systems.
7.
Certain products in this document may need government approval before they can be exported to particular
countries. The purchaser assumes the responsibility of determining the legality of export of these products
and will take appropriate and necessary steps at their own expense for these.
8.
No part of the contents contained herein may be reprinted or reproduced without our prior permission.
Copyright 2002 Oki Electric Industry Co., Ltd.
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