Datasheet IDT70825L35GB, IDT70825L35PF, IDT70825L35PFB, IDT70825L45G, IDT70825L45GB Datasheet (Integrated Device Technology Inc)

Integrated Device Technology, Inc.

HIGH-SPEED 8K x 16
SEQUENTIAL ACCESS
RANDOM ACCESS MEMORY (SARAM™)

IDT70825S/L

FEATURES:

• 8K x 16 Sequential Access Random Access Memory
(SARAM™)

- Sequential Access from one port and standard Random

Access from the other port

- Separate upper-byte and lower-byte control of the

Random Access Port

• High-speed operation

- 20ns tAA for random access port

- 20ns tCD for sequential port

- 25ns clock cycle time

• Architecture based on Dual-Port RAM cells

• Electrostatic discharge > 2001V, Class II

• Compatible with Intel BMIC and 82430 PCI Set

• Width and Depth Expandable

• Sequential side

- Address based flags for buffer control

- Pointer logic supports two internal buffers

• Battery backup operation—2V data retention

• TTL-compatible, single 5V (±10%) power supply

• Available in 80-pin TQFP and 84-pin PGA

• Military product compliant to MIL-STD-883.

• Industrial temperature range (–40°C to +85°C) is available,
tested to military electrical specifications.

DESCRIPTION:

The IDT70825 is a high-speed 8K x 16-bit Sequential
Access Random Access Memory (SARAM). The SARAM
offers a single-chip solution to buffer data sequentially on one
port, and be accessed randomly (asynchronously) through
the other port. The device has a Dual-Port RAM based
architecture with a standard SRAM interface for the random
(asynchronous) access port, and a clocked interface with
counter sequencing for the sequential (synchronous) access
port.

Fabricated using CMOS high-performance technology,
this memory device typically operates on less than 900mW of
power at maximum high-speed clock-to-data and Random
Access. An automatic power down feature, controlled by CE,
permits the on-chip circuitry of each port to enter a very low
standby power mode.

The IDT70825 is packaged in a 80-pin Thin Plastic Quad
Flatpack (TQFP) or 84-pin Ceramic Pin Grid Array (PGA).
Military grade product is manufactured in compliance with the
latest revision of MIL-STD-883, Class B, making it ideally
suited to military temperature applications demanding the
highest level of performance and reliability.

FUNCTIONAL BLOCK DIAGRAM

13

A

0-12

Random

R/

I/O0-15

LSB

MSB

Access

Port

Controls

16

13

Start Address for Buffer #1
End Address for Buffer #1
Start Address for Buffer #2
End Address for Buffer #2

Flow Control Buffer

Flag Status

SCLK

Sequential

Access

Port

Controls

8K X 16
Memory

Array

Data

Addr

R

R

Data

L

13

Addr

L

13

13

13

16

13

COMPARATOR

Reg.

13

Pointer/
Counter

16

RST

1
2

SR/

SI/O0-15

1

2

3016 drw 01

The IDT logo is a registered trademark and SARAM is a trademark of Integrated Device Technology, Inc.

MILITARY AND COMMERCIAL TEMPERATURE RANGES OCTOBER 1996

©1996 Integrated Device Technology, Inc. DSC-3016/6

For latest information contact IDT’s web site at www.idt.com or fax-on-demand at 408-492-8391.

6.31 1

IDT70825S/L
HIGH-SPEED 8K x 16 SEQUENTIAL ACCESS RANDOM ACCESS MEMORY MILITARY AND COMMERCIAL TEMPERATURE RANGES

PIN CONFIGURATIONS

(1,2)

INDEX

SI/O
SI/O

GND

N/C

SCE

SR/

RST

SLD

SSTRT

SSTRT

GND
GND

CNTEN

SOE

SCLK

GND

EOB

EOB

V
I/O

2

SI/O

80 79 78 77 76 75 74 73 72 71

1

1

0

2
3
4
5

W

6
7
8

2

9

1

10
11
12
13
14
15
16

2

17

1

18

CC

19

0

20

21 22 36 37 38 39 40

1

I/O

GND

5

3

4

CC

V

SI/O

SI/O

SI/O

23 24 25 26 27 28 29 30 31 32 33 34 35

4

2

3

CC

V

I/O

I/O

I/O

6

SI/O

5

I/O

7

SI/O

6

I/O

GND

8

10

9

SI/O

SI/O

SI/O

70 69 68 67 66 65

IDT70825

PN80-1

TQFP

TOP

(3)

VIEW

7

8

I/O

I/O

GND

11

SI/O

9

I/O

10

I/O

CC

V

11

I/O

12

SI/O

CC

V

13

SI/O

12

I/O

14

SI/O

13

I/O

15

SI/O

6364

14

I/O

GND

N/C

62 61

15

I/O

12

A

60

59
58
57
56
55
54
53
52

51
50

49

48
47
46
45

44
43
42

41

3016 drw 02

GND

11

A
A

10

A

9

A

8

A

7

A

6

A

5

A

4

A

3

A

2

V

CC

V

CC

A

1

A

0

CMD

CE

LB

UB

R/

W

OE

63 61 60 58 55 54

V

CC

646562

NC

GND

68

V

CC

71

EOB1GND

0

I/O

73

66

67

69

72

I/O

I/O

I/O

I/O

1

2

3

4

I/O7I/O6GND SI/O

75

I/O

9

76

I/O

10

79

I/O

12

818283

70

77

80

I/O

I/O

I/O

74

5

I/O

8

78

V

CC

11

13

I/O14NC V

125

OE

GND

I/O

15

8434 6915131618

NC

R/

W

UB

CNTEN

GND

59 56 49

EOB2SOE

RST

57 53

SCLK GND

IDT70825

G84-3

84-PIN PGA

TOP VIEW

7

CMD

811101214 17 20

LB

CE

CC

A

0

CC

V

A

5

1

A

48 46 45

51

SSTRT

50

SLD

52

SSTRT

2

1

NC

SR/W GND NC

47 44

SCE

SI/O

33 35

32 31

SI/O

(3)

28 29

SI/O

2

A

A

7

4

A

A

3

A

A

6

12

10

A

8

ABCDEFGHJKL

INDEX

43

SI/O

0

41

SI/O

38

SI/O4SI/O

8

SI/O

9

SI/O

V

CC

26

SI/O

23

NC SI/O

22 24

A

12

19 21

A9A

10

14

1

2

7

42

40

SI/O

39

V

37

34

GND

36

SI/O

30

SI/O

27

SI/O

25

GND

CC

3

5

6

11

13

15

11

3016 drw 03

11

10

09

08

07

06

05

04

03

02

01

NOTES:

1. All V

CC pins must be connected to power supply.

2. All GND pins must be connected to ground supply.

3. This text does not indicate orientation of the actual part-marking.

6.31 2

IDT70825S/L
HIGH-SPEED 8K x 16 SEQUENTIAL ACCESS RANDOM ACCESS MEMORY MILITARY AND COMMERCIAL TEMPERATURE RANGES

PIN DESCRIPTIONS: RANDOM ACCESS PORT

SYMBOL NAME I/O

A

0-A12 Address Lines I Address inputs to access the 8192-word (16 bit) memory array.

I/

O0-I/O15 Inputs/Outputs I Random access data inputs/outputs for 16-bit wide data.

CE

CMD

Chip Enable I When CE is LOW, the random access port is enabled. When CE is HIGH, the random access

Control Register I When
Enable access the control register, the flag register, and the start and end of buffer registers.

R/

W

OE

LB,UB

Read/Write Enable I If CE is LOW and

Output Enable I When OE is LOW and R/W is HIGH, I/O0-I/O15 outputs are enabled. When OE is HIGH, the I/O

Lower Byte, Upper I When LB is LOW, I/O0-I/O7 are accessible for read and write operations. When LB is HIGH, I/
Byte Enables I/

V

CC Power Supply Seven +5V power supply pins. All Vcc pins must be connected to the same +5V VCC supply.

GND Ground Ten Ground pins. All Ground pins must be connected to the same Ground supply.

(1)

DESCRIPTION

port is disabled into power-down mode and the I/O outputs are in the high-impedance state. All
data is retained during

CE

= VIH, unless it is altered by the sequential port. CE and

CMD

be LOW at the same time.

CMD

is LOW, Address lines A

0-A2, R/

W

, and inputs/outputs I/O0-I/O11, are used to

CMD

CE

may not be LOW at the same time.

CMD

is HIGH, data is written into the array when R/W is LOW and read out of the
array when R/W is HIGH. If CE is HIGH and
mand registers. CE and

CMD

may not be LOW at the same time.

CMD

is LOW, R/W is used to access the buffer com-

outputs are in the high-impedance state.

O7 are tri-stated and blocked during read and write operations.

I/

O15 in the same manner and is asynchronous from

LB

.

UB

controls access for I/O8-

may not

and

O0-

3016 tbl 01

PIN DESCRIPTIONS: SEQUENTIAL ACCESS PORT

SYMBOL NAME I/O

SI/O0-15 Inputs I/O Sequential data inputs/outputs for 16-bit wide data.
SCLK Clock I SI/

SCE

CNTEN

SR/

SLD

Chip Enable I When

Counter Enable I When

W

Read/Write Enable I When SR/W and

Address Pointer I When
Load Control changes. When

SSTRT

1, Load Start of I When

SSTRT

2 Address Register address pointer on the LOW-to-HIGH transition of SCLK. The start addresses are stored in

EOB

1, End of Buffer Flag O

EOB

2 stored in the end of buffer registers. The flags can be cleared by either asserting

SOE

RST

NOTE:

1. "I/O" is bidirectional Input and Output. "I" is Input and "O" is Output.

Output Enable I

Reset I When

(1)

O0-SI/O15,

SCE

, SR/W, and

DESCRIPTION

SLD

are registered on the LOW-to-HIGH transition of SCLK.
Also, the sequential access port address pointer increments by 1 on each LOW-to-HIGH
transition of SCLK when

SCE

is LOW, the sequential access port is enabled on the LOW-to-HIGH transition of

SCLK. When

SCE

CNTEN

is LOW.

is HIGH, the sequential access port is disabled into powered-down mode on
the LOW-to-HIGH transition of SCLK, and the SI/O outputs are in the high-impedance state. All
data is retained, unless altered by the random access port.

CNTEN

is LOW, the address pointer increments on the LOW-to-HIGH transition of SCLK.

This function is independant of

SCE

are LOW, a write cycle is initiated on the LOW-to-HIGH transition of

SCLK. When SR/W is HIGH, and

SCE

.

SCE

and

SOE

are LOW, a read cycle is initiated on the
LOW-to-HIGH transition of SCLK. Termination of a Write cycle is done on the Low-to-High
transistion of SCLK if SR/W or

SLD

is sampled LOW, there is an internal delay of one cycle before the address pointer

SLD

is LOW, data on the inputs SI/
on the LOW-to-HIGH transition of SCLK. On the cycle following
changes to the address location contained in the data-in register.
not be LOW while

SSTRT

internal registers.
following

EOB

1 or

SLD

EOB

SLD

is LOW or during the cycle following

1 or

SSTRT

SSTRT

.

2 is output LOW when the address pointer is incremented to match the address

by writing zero into bit 0 and/or bit 1 of the control register at address 101.

SCE

is High.

O0-SI/O11 is loaded into a data-in register

SLD

, the address pointer

SSTRT

1 and

SSTRT

2 may

SLD

.

2 is LOW, the start of address register #1 or #2 is loaded into the

1 and

SSTRT

2 may not be LOW while

SLD

is LOW or during the cycle

RST

EOB

1 and

LOW or

EOB

dependent on separate internal registers, and therefore separate match addresses.

SOE

controls the data outputs and is independent of SCLK. When
and the sequentially addressed data is output. When
the high-impedance state.

RST

is LOW, all internal registers are set to their default state, the address pointer is set

to zero and the

EOB

1 and

SOE

is asynchronous to SCLK.

EOB

2 flags are set HIGH.

SOE

RST

is HIGH, the SI/O output bus is in

is asynchronous to SCLK.

SOE

is LOW, output buffers

2 are

3016 tbl 02

6.31 3

IDT70825S/L
HIGH-SPEED 8K x 16 SEQUENTIAL ACCESS RANDOM ACCESS MEMORY MILITARY AND COMMERCIAL TEMPERATURE RANGES

ABSOLUTE MAXIMUM RATINGS

(1)

Symbol Rating Commercial Military Unit

(2)

V

TERM

Terminal Voltage –0.5 to +7.0 –0.5 to +7.0 V
with Respect
to GND

T

A Operating 0 to +70 –55 to +125 ° C

Temperature

T

BIAS Temperature –55 to +125 –65 to +135 °C

Under Bias

T

STG Storage –55 to +125 –65 to +150 °C

Temperature

I

OUT DC Output 50 50 mA

Current

NOTES: 3016 tbl 03

1. Stresses greater than those listed under ABSOLUTE MAXIMUM RAT­INGS may cause permanent damage to the device. This is a stress rating
only and functional operation of the device at these or any other conditions
above those indicated in the operational sections of this specification is not
implied. Exposure to absolute maximum rating conditions for extended
periods may affect reliability.

TERM must not exceed Vcc + 0.5V for more than 25% of the cycle time

2. V
or 10ns maximum, and is limited to
+ 0.5V.

< 20mA for the period of VTERM > Vcc

RECOMMENDED OPERATING
TEMPERATURE AND SUPPLY VOLTAGE

Ambient

Grade Temperature GND VCC

Military –55°C to +125°C 0V 5.0V ± 10%
Commercial 0°C to +70°C 0V 5.0V ± 10%

3016 tbl 04

RECOMMENDED DC OPERATING
CONDITIONS

Symbol Parameter Min. Typ. Max. Unit

V

CC Supply Voltage 4.5 5.0 5.5 V

GND Supply Voltage 0 0 0 V
V

IH Input High Voltage 2.2 — 6.0

V

IL Input Low Voltage –0.5

NOTES: 3016 tbl 05

1. VIL > –1.5V for pulse width less than 10ns.

TERM must not exceed Vcc + 0.5V.

2. V

CAPACITANCE

(1)

(1)

— 0.8 V

(TA = +25°C, F = 1.0MHz)TQFP ONLY

Symbol Parameter Conditions

C

IN Input Capacitance VIN = 3dV 9 pF

C

OUT Output VOUT = 3dV 10 pF

Capacitance

NOTES: 3016 tbl 06

1. This parameter is determined by device characterization, but is not
production tested.

2. 3dV references the interpolated capacitance when the input and output

signals switch from 0V to 3V or from 3V to 0V.

(2)

(2)

V

Max. Unit

DC ELECTRICAL CHARACTERISTICS OVER THE OPERATING TEMPERATURE
AND SUPPLY VOLTAGE RANGE (V

Symbol Parameter Test Conditions Min. Max. Min. Max. Unit

LI| Input Leakage Current

|I
|I

LO| Output Leakage Current VCC = Max.

VOL Output Low Voltage IOL = 4mA, VCC = Min. — 0.4 — 0.4 V
V

OH Output High Voltage IOH = –4mA, VCC = Min. 2.4 — 2.4 — V

NOTE:

1. At Vcc ≤ 2.0V input leakages are undefined.

(1)

CC = 5.0V ± 10%)

IDT70825S IDT70825L

VCC = Max. VIN = GND to VCC — 5.0 — 1.0 µA

CE

and

SCE

= VIH — 5.0 — 1.0 µA

V

OUT = GND to VCC

3016 tbl 07

6.31 4

IDT70825S/L
HIGH-SPEED 8K x 16 SEQUENTIAL ACCESS RANDOM ACCESS MEMORY MILITARY AND COMMERCIAL TEMPERATURE RANGES

DC ELECTRICAL CHARACTERISTICS OVER THE OPERATING TEMPERATURE

(1)

AND SUPPLY VOLTAGE RANGE

Symbol Parameter Condition Version Typ.

I

CC Dynamic Operating

Current Open,
(Both Ports Active) f = f

SB1 Standby Current

I

(Both Ports - TTL Level
Inputs) f = f

I

SB2 Standby Current

(One Port - TTL Level Active Port Outputs L —— — — 95 250 90 250
Input) Open, f = f

I

SB3 Full Standby Current Both Ports

(Both Ports - CMOS
Level Inputs) V

I

SB4 Full Standby Current One Port

(One Port - CMOS
Level Inputs) Outputs Open

NOTES:

1. "X" in part number indicates power rating (S or L).

2. V

CC = 5V, Ta = +25°C; guaranteed by device characterization but not production tested.

3. At f = f

4. f = 0 means no address or control lines change.

5.

6.

7. If one port is enabled (either CE or

MAX, address, control lines (except Output Enable), and SCLK are cycling at the maximum frequency read cycle of 1/tRC.

SCE

may transition, but is Low (

SCE

may be ≤ 0.2V, after it is clocked in, since SCLK=V

< 0.2V, and TTL High = VIH and Low = VIL.

Low

CE

= VIL, Outputs MIL. S — — — — 160 400 155 400 mA

MAX

SCE

and CE > VIH

CMD

= V

MAX

CE

or

SCE

≥ V

IN ≥ VCC - 0.2V or COM’L.S 1.0 15 1.0 15 1.0 15 1.0 15

V

IN ≤ 0.2V, f = 0

SCE

≥ V

(Active port), f
V

IN ≥ VCC - 0.2V or

V

IN ≤ 0.2V L 110 200 100 190 90 180 85 180

IL) when clocked in by SCLK.

SCE

=V

SCE

= Low) then the other port is disabled (

(VCC = 5.0V ± 10%)

70825X20 70825X25 70825X35 70825X45

Test Com'l. Only Com'l. Only

SCE

(3)

= V

IL

COM’L. S 180 380 170 360 160 340 155 340

L — — — — 160 340 155 340

(5)

L 180 330 170 310 160 290 155 290

(7)

MIL. S — — — — 20 85 16 85 mA

IH L— — — — 20 6516 65

(3)

COM’L. S 25 70 25 70 20 70 16 70

L25502550 20501650

SCE

= VIH MIL. S — — — — 95 290 90 290 mA

(3)

MAX

COM’L. S 115 260 105 250 95 240 90 240

L 115 230 105 220 95 210 90 210

CE

and MIL. S — — — — 1.0 30 1.0 30 mA

CC - 0.2V

CE

CC - 0.2V

(6,7)

(4)

L — — — — 0.2 10 0.2 10

L 0.2 5 0.2 5 0.2 5 0.2 5

or MIL. S — — — — 90 260 85 260 mA

(6)

(3)

= fMAX

COM’L. S 110 240 100 230 90 220 85 220

IH must be clocked in prior to powerdown.

L — — — — 90 215 85 215

(2)

Max. Typ.

SCE

or CE = High, respectively). CMOS High

(2)

Max. Typ.

(2)

Max. Typ.

(2)

> Vcc - 0.2V and

Max. Unit

3016 tbl 08

DATA RETENTION CHARACTERISTICS OVER ALL TEMPERATURE RANGES
(L VERSION ONLY)

Symbol Parameter Test Condition Min. Typ.

V

DR VCC for Data Retention VCC = 2V 2.0 — — V

I

CCDR Data Retention Current

(3)

t

CDR

(3)

t

R

NOTES :

1. T

A = +25°C, VCC = 2V; guaranteed by device characterization but not production tested.

RC = Read Cycle Time

2. t

3. This parameter is guaranteed by device characterization, but is not production tested.

4. To initiate data retention,

Chip Deselect to Data Retention Time
Operation Recovery Time

(VLC < 0.2V, VHC > VCC - 0.2V)

IH must be clocked in.

SCE

= V

(1)

Max. Unit

CE

= VHC MIL. — 100 4000 µA

V

IN = VHC or = VLC COM’L. — 100 1500

SCE
CMD

(4)

= VHC

= VHC tRC

when SCLK= 0 — — ns

(2)

6.31 5

——ns

3016 tbl 09

IDT70825S/L

1

2

3

4

5

6

7

8

20 40 60 80 100 120 140 160 180

200

CAPACITANCE (pF)

10pF is the I/O
capacitance of
this device, and
30pF is the AC
Test Load
capacitance.

3016 drw 07

tAA/tCD/tEB
(Typical, ns)

-1

-2

-3

HIGH-SPEED 8K x 16 SEQUENTIAL ACCESS RANDOM ACCESS MEMORY MILITARY AND COMMERCIAL TEMPERATURE RANGES

DATA RETENTION AND POWER DOWN/UP WAVEFORM (RANDOM AND SEQUENTIAL PORT)

(1,2)

DATA RETENTION MODE

V

CC

CE

4.5V

t

CDR

V

IH

≥

V

DR

2V

V

DR

4.5V
t

R

V

IH

SCLK

SCE

t

I

CC

NOTES :

1.

SCE

is synchronized to the sequential clock input.

CMD

> VCC - 0.2V.

2.

PD

I

SB

t

PU

I

SB

3016 drw 04

AC TEST CONDITIONS

Input Pulse Levels GND to 3.0V
Input Rise/Fall Times 3ns Max.
Input Timing Reference Levels 1.5V
Output Reference Levels 1.5V
AC Test Load Figures 1, 2, and 3

DATA

OUT

Figure 1. AC Output Test Load

5V

893Ω

30pF347Ω

3016 drw 05

5V

893Ω

DATA

OUT

5pF347Ω

3016 drw 06

Figure 2. Output Test Load (for tCLZ, tBLZ, tOLZ, tCHZ,

3016 tbl 10

Figure 3. Lumped Capacitance Load Typical Derating Curve

6.31 6

t

BHZ, tOHZ, tWHZ, tCKHZ, and tCKLZ)

Including scope and jig.

IDT70825S/L
HIGH-SPEED 8K x 16 SEQUENTIAL ACCESS RANDOM ACCESS MEMORY MILITARY AND COMMERCIAL TEMPERATURE RANGES

TRUTH TABLE I – RANDOM ACCESS READ AND WRITE

(1,2)

Inputs/Outputs MODE

CECE

CE

CECE

CMDCMD

CMD

CMDCMD

R/

WW

OEOE

LBLB

W

OE

WW

OEOE

LB

LBLB

UBUB

UB

UBUB

I/O

0-I/O7 I/O8-I/O-

L H H L L L DATAOUT DATAOUT Read both Bytes.
L H H L L H DATA
L H H L H L High-Z DATA
LH LH
LH LH
LH LH

(3)

L L DATAIN DATAIN Write to both Bytes.

(3)

L H DATAIN High-Z Write to lower Byte only.

(3)

H L High-Z DATAIN Write to upper Byte only.

OUT High-Z Read lower Byte only.

OUT Read upper Byte only.

H H X X X X High-Z High-Z Both Bytes deselected and powered down.

L H H H X X High-Z High-Z Outputs disabled but not powered down.

L H X X H H High-Z High-Z Both Bytes deselected but not powered down.
HL LH
HL HLL

NOTES:

1. H = V

2.

3. If OE = V

4. Byte operations to control register using UB and LB separately are also allowed.

IH, L = VIL, X = Don't Care, and High-Z = High-impedance.

RST, SCE, CNTEN

operation.

IL during write, tWHZ must be added to the tWP or tCW write pulse width to allow the bus to float prior to being driven.

TRUTH TABLE II – SEQUENTIAL READ

(3)L(4)L(4)

, SR/W,

SLD, SSTRT

(4)L(4)

DATAIN DATAIN Write I/O0-I/O12 to the Buffer Command Register.

DATAOUT DATAOUT Read contents of the Buffer Command Register via I/O0-I/O12.

1,

SSTRT

2, SCLK, SI/O

(1,2,3,6,8)

0-SI/O15,

EOB

1,

EOB

2, and

SOE

are unrelated to the random access port control and

Inputs/Outputs MODE

SCLK

SCE

SCESCE

CNTENCNTEN

CNTEN

CNTENCNTEN

SR/

W

WW

WW

EOB1EOB1

EOB1

EOB1EOB1

EOB2EOB2

EOB2

EOB2EOB2

SOESOE

SOE

SOESOE

SI/O

SCESCE

L L H LOW LAST L [EOB1] Counter Advanced Sequential Read with
L H H LAST LAST L [EOB1 - 1] Non-Counter Advanced Sequential Read, without
L L H LAST LOW L [EOB2] Counter Advanced Sequential Read with
L H H LAST LAST L [EOB2 - 1] Non-Counter Advanced Sequential Read without
L L H LOW LOW H HIGH-Z Counter Advanced Sequential Non-Read with

reached.

TRUTH TABLE III – SEQUENTIAL WRITE

(1,2,3,4,5,6,7,8)

Inputs/Outputs MODE

SCESCE

SCLK

CNTENCNTEN

SCE

CNTEN

SCESCE

CNTENCNTEN

L H L LAST LAST H SI/O
L L L LOW LOW H SI/O

SR/

WW

W

WW

EOB1EOB1

EOB1

EOB1EOB1

EOB2EOB2

EOB2

EOB2EOB2

SOESOE

SOE

SOESOE

SI/O

IN Non-Counter Advanced Sequential Write, without
IN Counter Advanced Sequential Write with

EOB

1 and
H H X LAST LAST X High-Z No Write or Read due to Sequential port Deselect. No counter advance.
H L X NEXT NEXT X High-Z No Write or Read due to Sequential port Deselect. Conter does advance.

NOTES:

1. H = V

2.

3.CE, OE, R/W,

4.

5. SI/

6. "LAST" refers to the previous value still being output, no change.

7. Termination of a write is done on the Low-to-High transition of SCLK if SR/W or

8. When

IH, L = VIL, X = Don't Care, and High-Z = High-impedance. LOW = VOL.

RST, SLD, SSTRT

with the sequential port operation (due to the counter and register control).

SOE

must be HIGH (

edge of the clock during the cycle in which SR/W = V

OIN refers to SI/O0-SI/O15 inputs.

CLKEN

Enable Cycle after Reset, Read (and write) Cycle".

1,

SSTRT

2 are continuously HIGH during a sequential write access, other than pointer access operations.

CMD, LB, UB

SOE

=V

=Low, the address is incremented on the next rising edge before any operation takes place. See the diagrams called "Sequential Counter

0-I/O15 are unrelated to the sequential port control and operation except for

, and I/O

IH) prior to write conditions only if the previous cycle is a read cycle, since the data being written must be an input at the rising

IL.

CMD

should be HIGH (

SCE

is High.

CMD

CMD

which must not be used concurrently

IH) during sequential port access.

= V

EOB

EOB

EOB

EOB

1 reached.

EOB

2 reached.

EOB

2 reached.

EOB

1 and

1 or

EOB

2 reached.

3016 tbl 11

1 reached.

EOB

2

3016 tbl 12

2 reached

3016 tbl 13

6.31 7

IDT70825S/L
HIGH-SPEED 8K x 16 SEQUENTIAL ACCESS RANDOM ACCESS MEMORY MILITARY AND COMMERCIAL TEMPERATURE RANGES

TRUTH TABLE IV – SEQUENTIAL ADDRESS POINTER OPERATIONS

(1,2,3,4,5)

Inputs/Outputs

SCLK

SLD

SLDSLD

SSTRTSSTRT

SSTRT

SSTRTSSTRT

1

SSTRTSSTRT

SSTRT

SSTRTSSTRT

SOESOE

SOE

2

SOESOE

MODE

SLDSLD

H L H X Start address for Buffer #1 loaded into Address Pointer.
H H L X Start address for Buffer #2 loaded into Address Pointer.

LH HH

NOTES: 3016 tbl 14

1. H = VIH, L = VIL, X = Don't Care, and High-Z = High-impedance.

2.

RST

is continuously HIGH. The conditions of

3.CE, OE, R/W, LB, UB, and I/O
the sequential port operation (due to the counter and register control).

4. Address pointer can also change when it reaches an end of buffer address. See Flow Control Bits table.

5. When

6.

SLD

is not incremented during the two cycles.

SOE

is sampled LOW, there is an internal delay of one cycle before the address pointer changes. The state of

may be LOW with

0-I/O15 are unrelated to the sequential port control and operation, except for

SCE

deselect or in the write mode using SR/W.

(6)

Data on SI/O0-SI/O12 loaded into Address Pointer.

SCE, CNTEN

, and SR/W are unrelated to the sequential address pointer operations.

CMD

should be HIGH (CMD = V

CMD

which must not be used concurrently with

IH) during sequential port access.

CNTEN

is ignored and the address

ADDRESS POINTER LOAD CONTROL (SLD)

In

SLD

mode, there is an internal delay of one cycle before

the address pointer changes in the cycle following

SLD

is LOW, data on the inputs SI/O0-SI/O12 is loaded into a

SLD

data-in register on the LOW-to-HIGH transition of
the cycle following

SLD

, the address pointer changes to the

. When

SCLK

. On

address location contained in the data-in register.

SSTRT

2 may not be low while

following

SLD

. The

SSTRT

SLD

is LOW, or during the cycle

1 and

SSTRT

2 require only one

clock cycle, since these addresses are pre-loaded in the
registers already.

SSTRT

1,

SLDSLD

SLD

SLDSLD

MODE

(1)

SLD

(1)

SCLK

A

ADDR

0-11

SI/O

SSTRT

1,2

NOTE:

1. At SCLK edge (A), SI/O
address pointer changes). At SCLK edge (A),
(B),

SLD

and

for edge (B), while data will not be ready at edge (B) when

SSTRT

0-SI/O12 data is loaded into a data-in register. At edge (B), contents of the data-in register are loaded into the address pointer (i.e.

SSTRT

1,2 must be high to ensure for proper sequential address pointer loading. For

1 and

SSTRT

SLD

IN

2 must be high to ensure for proper sequential address pointer loading. At SCLK edge

is used, but will be ready at edge (C).

SEQUENTIAL LOAD OF ADDRESS INTO POINTER/COUNTER

B

(1)

SSTRT

1 or

C

DATA

OUT

SSTRT

2, the data to be read will be ready

3016 drw 08

MSB

NOTE:

1. "H" = V

15

14 13

H

HHH

IH for the SI/O intput state.

12 ------------------------------------------------------------------------------------------------------------

Address Loaded into Pointer

6.31 8

0

LSB SI/O BITS

3016 drw 09

IDT70825S/L
HIGH-SPEED 8K x 16 SEQUENTIAL ACCESS RANDOM ACCESS MEMORY MILITARY AND COMMERCIAL TEMPERATURE RANGES

Reset (

RST

RSTRST

RST

)

RSTRST

Setting

RST

LOW resets the control state of the SARAM.

functions asynchronously of SCLK, (i.e. not registered).

The default states after a reset operation are as follows:

Register Contents

Address Pointer 0
EOB Flags Cleared to High state
Buffer Flow Mode BUFFER CHAINING
Start Address Buffer #1 0 (1)
End Address Buffer #1 4095 (4K)
Start Address Buffer #2 4096 (4K+1)
End Address Buffer #2 8191 (8K)
Registered State

BUFFER COMMAND MODE (

Buffer Command Mode (

port to control the state of the two buffers. Address pins A0-A2
and I/O pins I/O0-I/O12 are used to access the start of buffer
and the end of buffer addresses and to set the flow control

SCE

= V

IH, SR/

CMDCMD

CMD

)

CMDCMD

CMD

) allows the random access

W

= VIL

3016 tbl 15

reading and clearing the status of the EOB flags. Seven
different CMD cases are available depending on the condi­tions of A0-A2 and R/W. Address bits A3-A12 and data I/O bits
I/O13-I/O15 are not used during this operation.

mode of each buffer. The Buffer Command Mode also allows

RANDOM ACCESS PORT

Case # A2-A0 R/

1 000 0 (1) Write (read) the start address of Buffer #1 through I/O
2 001 0 (1) Write (read) the end address of Buffer #1 through I/O
3 010 0 (1) Write (read) the start address of Buffer #2 through I/O
4 011 0 (1) Write (read) the end address of Buffer #2 through I/O
5 100 0 (1) Write (read) flow control register
6 101 0 Write only – clear EOB
7 101 1 Read only – flag status register
8 110/111 (X) (Reserved)

NOTE:

1. R/W input "0(1)" indicates a write(0) or read(1) occurring with the same address input.

CMDCMD

CMD

CMDCMD

MODE

WW

W

WW

(1)

1 and/or EOB2 flag

DESCRIPTIONS

0-I/O12.

0-I/O12.

0-I/O12.

0-I/O12.

3016 tbl 16

CASES 1 THROUGH 4: START AND END OF BUFFER REGISTER DESCRIPTION

15

14 13

MSB LSB I/O BITS

NOTES:

1. "H" = V

2. A write into the buffer occurs when R/W = V

H

OH for I/O in the output state and "Don't Cares" for I/O in the input state.

IL and

CE

= V

= VIH.

12 ------------------------------------------------------------------------------------------------------------

HH

IL and a read when R/

Address Loaded into Buffer

W

= VIH.

EOB1/SOB

1 and

EOB2/SOB

2 are chosen through address A0-A2 while

(1,2)

0

3016 drw 10

CMD

CASE 5: BUFFER FLOW MODES

Within the SARAM, the user can designate one of four

buffer flow modes for each buffer. Each buffer flow mode
defines a unique set of actions for the sequential port address
pointer and EOB flags. In BUFFER CHAINING mode, after the
address pointer reaches the end of the buffer, it sets the
corresponding EOB flag and continues from the start address

of the other buffer. In STOP mode, the address pointer stops
incrementing after it reaches the end of the buffer. In LINEAR
mode, the address pointer ignores the end of buffer address
and increments past it, but sets the EOB flag. MASK mode is
the same as LINEAR mode except EOB flags are not set.

6.31 9

IDT70825S/L
HIGH-SPEED 8K x 16 SEQUENTIAL ACCESS RANDOM ACCESS MEMORY MILITARY AND COMMERCIAL TEMPERATURE RANGES

FLOW CONTROL REGISTER DESCRIPTION

15

MSB

HHH HHH432 1 0HHHH

H

(1,2)

0

LSB I/O BITS

Counter Release
(STOP Mode Only)

NOTES:

1. "H" = V

2. Writing a 0 into bit 4 releases the address pointer after it is stopped due to the STOP mode and allows sequential write operations to resume. This occurs

OH for I/O in the output state and "Don't Cares"' for I/O in the input state.

asynchronously of SCLK, and therefore caution should be taken. The pointer will be at address EOB+2 on the next rising edge of SCLK that is enabled
by

CNTEN

. The pointer is also released by

RST, SLD, SSTRT

1 and

SSTRT

2 operations.

Buffer #2 flow control

Buffer #1 flow control

3016 drw 11

FLOW CONTROL BITS

Flow Control Bits

Bit 1 & Bit 0 Mode

(Bit 3 & Bit 2) Functional Description

00 BUFFER

CHAINING #1 (Buffer #2). The pointer value is changed to the start address of Buffer #2 (Buffer #1).

01 STOP

10 LINEAR

11 MASK

NOTES:

1.

EOB

1 and

EOB

2.

CMD

Flow Control bits are unchanged, the count does not continue advancement.

3. If

EOB

4. If counter has stopped at EOBx and was released by bit 4 of the flow control register,
the flow control will remain in the STOP mode.

2 may be asserted (set) at the same time, if both end addresses have been loaded with the same value.

1 and

EOB

2 are equal, then the pointer will jump to the start of Buffer #1.

EOB

1 (

EOB

2) is asserted (Active Low output) when the pointer matches the end address of Buffer

EOB

1 (

EOB

2) is asserted when the pointer matches the end address of Buffer #1 (Buffer #2).

The address pointer will stop incrementing when it reaches the next address (

CNTEN
EOB

released by bit 4 of the flow control register.

EOB

The pointer keeps incrementing for further operations.

EOB

is Low on the next clock's rising edge. Otherwise, the address pointer will stop incrementing on

. Sequential write operations are inhibited after the address pointer is stopped. The pointer can be

1 (

EOB

2) is asserted when the pointer matches the end address of Buffer #1 (Buffer #2).

1 (

EOB

2) is not asserted when the pointer reaches the end address of Buffer #1 (Buffer #2),

(1,2,4)

(1)

EOB

(1,3)

address + 1), if

although the flag status bits will be set. The pointer keeps incrementing for further operations.

CNTEN

must be LOW on the next rising edge of SCLK otherwise

3016 tbl 17

CASES 6 AND 7: FLAG STATUS REGISTER BIT DESCRIPTION

15

MSBHHH HHH HH HH HH H 1 0

NOTE:

1. "H" = V

OH for I/O in the output state and "Don't Cares" for I/O in the input state.

CASE 6: FLAG STATUS REGISTER WRITE CONDITIONS

H

(1)

(1)

0

End of buffer flag for Buffer #1

End of buffer flag for Buffer #2

Flag Status Bit 0, (Bit 1) Functional Description

0 Clears Buffer Flag
1 No change to the Buffer Flag.

NOTES: 3016 tbl 18

1. Either bit 0 or bit 1, or both bits, may be changed simultaneously. One may be cleared while the second is left alone or cleared.

2. Remains as it was prior to the

CMD

operation, either HIGH (1) or LOW (0).

EOB

1, (

EOB

2).

(2)

CASE 7: FLAG STATUS REGISTER READ CONDITIONS

Flag Status Bit 0, (Bit 1) Functional Description

0

1

EOB

1 (

EOB

2) flag has not been set, the

Pointer has not reached the End of the
Buffer.

EOB

1 (

EOB

2) flag has been set, the

Pointer has reached the End of the Buffer.

3016 tbl 19

LSB I/O BITS

3016 drw 12

6.31 10

IDT70825S/L
HIGH-SPEED 8K x 16 SEQUENTIAL ACCESS RANDOM ACCESS MEMORY MILITARY AND COMMERCIAL TEMPERATURE RANGES

CASES 8 AND 9: (RESERVED)

Illegal operations. All outputs will be HIGH on the I/O bus during a READ.

RANDOM ACCESS PORT: AC ELECTRICAL CHARACTERISTICS OVER THE
OPERATING TEMPERATURE AND SUPPLY VOLTAGE RANGE

IDT70825X20 IDT70825X25 IDT70825X35 IDT70825X45

Com'l. Only Com'l. Only
Symbol Parameter Min. Max. Min. Max. Min. Max. Min. Max. Unit
READ CYCLE

t

RC Read Cycle Time 20 — 25 — 35 — 45 — ns

t

AA Address Access Time — 20 — 25 — 35 — 45 ns

t

ACE Chip Enable Access Time — 20 — 25 — 35 — 45 ns

t

BE Byte Enable Access Time — 20 — 25 — 35 — 45 ns

t

OE Output Enable Access Time — 10 — 10 — 15 — 20 ns

t

OH Output Hold from Address Change 3 — 3 — 3 — 3 — ns

t

CLZ Chip Select Low-Z Time

t

BLZ Byte Enable Low-Z Time

t

OLZ Output Enable Low-Z Time

t

CHZ Chip Select High-Z Time

t

BHZ Byte Enable High-Z Time

t

OHZ Output Enable High-Z Time

t

PU Chip Select Power-Up Time 0 — 0 — 0 — 0 — ns

t

PD Chip Select Power-Down Time — 20 — 25 — 35 — 45 ns

NOTES:

1. Transition measured at ±200mV from steady state. This parameter is guaranteed with the AC Test Load (Figure 2) by device characterization, but is not
production tested.

2. "X" in part number indicates power rating (S or L).

3.

CMD

access follows standard timing listed for both read and write accesses, ( CE = V

(1)

(1)

(1)

(1)

(1)

(1)

3 —3—3—3—ns
3 —3—3—3—ns

2 —2—2—2—ns
— 10 — 12 — 15 — 15 ns
— 10 — 12 — 15 — 15 ns
— 9—11—15—15ns

IH when

(2,3)

CMD

= VIL ) or (

CMD

= VIH when CE = VIL ).

3016 tbl 20

RANDOM ACCESS PORT: AC ELECTRICAL CHARACTERISTICS
OVER THE OPERATING TEMPERATURE AND SUPPLY VOLTAGE

IDT70825X20 IDT70825X25 IDT70825X35 IDT70825X45

Com'l. Only Com'l. Only

Symbol Parameter Min. Max. Min. Max. Min. Max. Min. Max. Unit
WRITE CYCLE

t

WC Write Cycle Time 20 — 25 — 35 — 45 — ns

t

CW Chip Select to End-of-Write 15 — 20 — 25 — 30 — ns

t

AW Address Valid to End-of-Write

t

AS Address Set-up Time 0 — 0 — 0 — 0 — ns

t

WP Write Pulse Width

t

BP Byte Enable Pulse Width

t

WR Write Recovery Time 0 — 0 — 0 — 0 — ns

t

WHZ Write Enable Output High-Z Time

t

DW Data Set-up Time 13 — 15 — 20 — 25 — ns

t

DH Data Hold Time 0 — 0 — 0 — 0 — ns

t

OW Output Active from End-of-Write 3 — 3 — 3 — 3 — ns

NOTES:

1. Transition measured at ±200mV from steady state. This parameter is guaranteed with the AC Test Load (Figure 2) by device characterization, but is not
production tested.

2. "X" in part number indicates power rating (S or L).

3.OE is continuously HIGH, OE = V
drivers to turn off and on the data to be placed on the bus for the required t
not apply and the minimum write pulse is the specified t

4.

CMD

access follows standard timing listed for both read and write accesses, ( CE = V

(3)

IH. If during the R/

(3)

15 — 20 — 25 — 30 — ns

13 — 20 — 25 — 30 — ns

(3)

(1)

W

controlled write cycle the OE is LOW, tWP must be greater or equal to tWHZ + tDW to allow the I/O

15 — 20 — 25 — 30 — ns

—10—12 —15—15ns

DW. If

OE

WP. For the

CE

controlled write cycle, OE may be LOW with no degradation to tCW timing.

is HIGH during the R/W controlled write cycle, this requirement does

IH when

CMD

(2,4)

= VIL ) or (

CMD

= VIH when CE = VIL ).

3016 tbl 21

6.31 11

IDT70825S/L
HIGH-SPEED 8K x 16 SEQUENTIAL ACCESS RANDOM ACCESS MEMORY MILITARY AND COMMERCIAL TEMPERATURE RANGES

RANDOM ACCESS PORT WAVEFORM: READ CYCLES

t

RC

ADDR

t

AA

(2)

t

ACS

t

CLZ

,

t

BE

t

BLZ

t

OE

t

OLZ

I/O

OUT

Valid Data Out

(1,2)

t

OH

t

CHZ

t

BHZ

t

OHZ

3016 drw 13

NOTES:

1. R/W is HIGH for Read cycle.

2. Address valid prior to or coincident with CE transition LOW; otherwise t

AA is the limiting parameter.

RANDOM ACCESS PORT WAVEFORM: READ CYCLES BUFFER COMMAND MODE

t

RC

ADDR

t

I/O

,

OUT

(1)

t

CLZ

t

BLZ

AA

t

t

OLZ

ACS

t

BE

t

OE

Valid Data Out

t

OH

t

CHZ

t

BHZ

t

OHZ

3016 drw 14

NOTE:

1. CE = VIH when

CMD

= VIL.

6.31 12

IDT70825S/L
HIGH-SPEED 8K x 16 SEQUENTIAL ACCESS RANDOM ACCESS MEMORY MILITARY AND COMMERCIAL TEMPERATURE RANGES

RANDOM ACCESS PORT WAVEFORM: WRITE CYCLE NO.1 (R/

t

WC

ADDR

t

AW

R/

W

(2)

t

WP

t

DW

Valid Data In

CE, LB, UB

I/O

t

(8)

IN

AS

(5)

OE

t

WHZ

I/O

OUT

Data Out

(4)

t

ACS

t

BE

RANDOM ACCESS PORT WAVEFORM: WRITE CYCLE NO.2

CECE

(

CE

CECE

LBLB

,

LB

, AND/OR

LBLB

UBUB

UB

CONTROLLED TIMING)

UBUB

(1,6,7)

WW

W

CONTROLLED TIMING)

WW

t

WR

t

DH

t

OHZ

Data Out

t

OW

(1,6)

(3)

(4)

3016 drw 15

t

WC

ADDR

t

CE, LB, UB

(8)

t

AS

R/

W

I/O

IN

NOTES:

1. R/W, CE, or LB and UB must be inactive during all address transitions.

2. A write occurs during the overlap of R/W = V

3. t

WR is measured from the earlier of

4. During this period, I/O pins are in the output state and the input signals must not be applied.

5. If the CE LOW transition occurs simultaneously with or after the R/W LOW transition, the outputs remain in the High-impedance state.

6.OE is continuously HIGH, OE = V
drivers to turn off and on the data to be placed on the bus for the required t
not apply and the minimum write pulse is the specified t

OUT is never enabled, therefore the output is in High-Z state during the entire write cycle.

7. I/O

8.

CMD

access follows the standard CE access described above. If

CE

(and LB and/or UB) or R/W going HIGH to the end of the write cycle.

IH. If during the R/

(5)

IL,

CE

= VIL and

W

LB

= VIL and/or

controlled write cycle the OE is LOW, tWP must be greater or equal to tWHZ + tDW to allow the I/O

WP. For the

CMD

AW

(2)

t

CW

(2)

t

BP

t

DW

t

DH

Valid Data

UB

= VIL.

DW. If

OE

CE

controlled write cycle, OE may be LOW with no degregation to tCW timing.

= V

is HIGH during the R/W controlled write cycle, this requirement does

IL, then

CE

must = VIH or, when CE = VIL,

CMD

must = VIH.

t

WR

(3)

3016 drw 16

6.31 13

IDT70825S/L
HIGH-SPEED 8K x 16 SEQUENTIAL ACCESS RANDOM ACCESS MEMORY MILITARY AND COMMERCIAL TEMPERATURE RANGES

SEQUENTIAL PORT: AC ELECTRICAL CHARACTERISTICS OVER THE
OPERATING TEMPERATURE AND SUPPLY VOLTAGE RANGE

IDT70825X20 IDT70825X25 IDT70825X35 IDT70825X45

Com'l. Only Com'l. Only

Symbol Parameter Min. Max. Min. Max. Min. Max. Min. Max. Unit

READ CYCLE

t

CYC Sequential Clock Cycle Time 25 — 30 — 40 — 50 — ns

t

CH Clock Pulse High 10 — 12 — 15 — 18 — ns

t

CL Clock Pulse Low 10 — 12 — 15 — 18 — ns

t

ES Count Enable and Address Pointer Set-up Time 5 — 5 — 6 — 6 — ns

t

EH Count Enable and Address Pointer Hold Time 2 — 2 — 2 — 2 — ns

t

SOE Output Enable to Data Valid

t

OLZ Output Enable Low-Z Time

t

OHZ Output Enable High-Z Time

t

CD Clock to Valid Data — 20 — 25 — 35 — 45 ns

t

CKHZ Clock High-Z Time

t

CKLZ Clock Low-Z Time

t

EB Clock to EOB — 13 — 15 — 18 — 23 ns

NOTES:

1. Transition measured at ±200mV from steady state. This parameter is guaranteed with the AC Test Load (Figure 2) by device characterization, but is not
production tested.

2. "X" in part numbers indicates power rating (S or L).

(1)

(1)

(1)

(1)

—

8 — 10 — 15 — 20 ns

2—2—2—2—ns

—9—11—15—15ns

— 12 — 14 — 17 — 20 ns

3—3—3—3—ns

(2)

3016 tbl 22

SEQUENTIAL PORT: AC ELECTRICAL CHARACTERISTICS
OVER THE OPERATING TEMPERATURE AND SUPPLY VOLTAGE

IDT70825X20 IDT70825X25 IDT70825X35 IDT70825X45

Com'l. Only Com'l. Only
Symbol Parameter Min. Max. Min. Max. Min. Max. Min. Max. Unit
WRITE CYCLE

t

CYC Sequential Clock Cycle Time 25 — 30 — 40 — 50 — ns

t

FS Flow Restart Time 13 — 15 — 20 — 20 — ns

t

WS Chip Select and Read/Write Set-up Time 5 — 5 — 6 — 6 — ns

t

WH Chip Select and Read/Write Hold Time 2 — 2 — 2 — 2 — ns

t

DS Input Data Set-up Time 5 — 5 — 6 — 6 — ns

t

DH Input Data Hold Time 2 — 2 — 2 — 2 — ns

NOTE:

1. "X" in part numbers indicates power rating (S or L).

(1)

3016 tbl 23

SEQUENTIAL PORT: AC ELECTRICAL CHARACTERISTICS
OVER THE OPERATING TEMPERATURE AND SUPPLY VOLTAGE

IDT70825X20 IDT70825X25 IDT70825X35 IDT70825X45

Com'l. Only Com'l. Only
Symbol Parameter Min. Max. Min. Max. Min. Max. Min. Max. Unit
RESET CYCLE

t

RSPW Reset Pulse Width 13 — 15 — 20 — 20 — ns

t

WERS Write Enable High to Reset High 10 — 10 — 10 — 10 — ns

t

RSRC Reset High to Write Enable Low 10 — 10 — 10 — 10 — ns

t

RSFV Reset High to Flag Valid 15 — 20 — 25 — 25 — ns

NOTE:

1. "X" in part numbers indicates power rating (S or L).

(1)

3016 tbl 24

6.31 14

IDT70825S/L
HIGH-SPEED 8K x 16 SEQUENTIAL ACCESS RANDOM ACCESS MEMORY MILITARY AND COMMERCIAL TEMPERATURE RANGES

SEQUENTIAL PORT WAVEFORM: WRITE, POINTER LOAD, NON-INCREMENTING READ

t

CYC

t

CH

SCLK

CNTEN

t

CL

t

EH

t

ES

(3)

t

t

ES

EH

(2)

SLD

SI/O

SR/

W

t

DS

IN

t

WS

t

WH

t

WS

t

WH

A0Dx

(1)

t

DH

HIGH IMPEDANCE

t

WS

t

WH

t

WS

t

WH

SCE

t

CD

SI/O

SOE

OUT

t

SOE

t

OLZ

t

D0 D0

CKLZ

SEQUENTIAL PORT WAVEFORM: WRITE, POINTER LOAD, BURST READ

t

CYC

t

SCLK

CNTEN

SLD

SI/O

CH

IN

t

CL

t

EH

t

(3)

t

t

ES

t

DS

A0Dx

EH

(1)

t

DH

HIGH IMPEDANCE

ES

D0

t

DS

D2

(2)

t

CSZ

t

CKHZ

t

OHZ

3016 drw 17

t

DH

t

WS

t

WH

SR/

W

t

WS

t

WH

SCE

SOE

SI/O

OUT

NOTES:

1. If

2. If

3. Pointer is not incremented on cycle immediately following

IL, then address will be clocked in on the SCLK's rising edge.

SLD

= V

CNTEN

IH for the SCLK's rising edge, the internal address counter will not advance.

= V

t

WS

WS

t

SLD

t

WH

t

WH

t

CD

t

SOE

t

t

OLZ

D1D0

t

CKLZ

even if

CNTEN

is LOW.

6.31 15

OHZ

(2)

3016 drw 18

IDT70825S/L

CNTEN

(2)

t

OLZ

t

OHZ

D1 D2

SSTRT

1/2

SR/

W

SCE

SOE

SCLK

t

CYC

t

CH

t

CL

t

EH

t

ES

t

EH

t

ES

(4)

(1)

Dx

HIGH IMPEDANCE

t

WS

t

WH

t

WS

t

WH

t

CD

t

SOE

t

WS

t

WH

t

WS

t

WH

(2)

D3

t

DS

t

DH

D0

t

CKLZ

(3)

(5)

EOB

1/2

t

EB

SI/O

IN

SI/O

OUT

3016 drw 19

HIGH-SPEED 8K x 16 SEQUENTIAL ACCESS RANDOM ACCESS MEMORY MILITARY AND COMMERCIAL TEMPERATURE RANGES

SEQUENTIAL PORT WAVEFORM: READ STRT/EOB FLAG TIMING

NOTES:

1. If

2. If

3.

4. Unlike

5. If SR/W = V

6.

1 or

SSTRT

SSTRT
CNTEN

SOE

= V

will control the output and should be High on Power-Up. If

that cycle. If

2 = VIL, then address will be clocked in on the SCLK's rising edge.

IH for the SCLK's rising edge, the internal address counter will not advance.

IL and is clocked in while SR/

SCE

= V

W

= VIL, the data addressed will be written to if the last cycle was a Read.

the bus contention and permit a Write on this cycle.

SLD

case,

CNTEN

SOE

IL, data would be written to D0 again since

= V

IL makes no difference at this point since the SR/

is not disabled on cycle immediately following

SCE

= V

IL and is clocked in while SR/

SSTRT

CNTEN

= VIH.

W

= VIL disables the output until SR/W = VIH is clocked in on the next rising clock edge.

.

W

= VIH, the data addressed will be read out within

SOE

may be used to control

6.31 16

IDT70825S/L
HIGH-SPEED 8K x 16 SEQUENTIAL ACCESS RANDOM ACCESS MEMORY MILITARY AND COMMERCIAL TEMPERATURE RANGES

SEQUENTIAL PORT WAVEFORM: WRITE CYCLES

t

CYC

t

SCLK

CNTEN

SLD

SI/O

SR/

SCE

SOE

SI/O

OUT

CH

IN

Dx A0

t

WS

t

WH

W

t

WS

t

WH

t

CL

t

t

EH

t

ES

(3)

t

t

ES

t

DS

EH

(1)

t

t

DH

DS

t

t

WS

WS

D0

t

t

WH

WH

t

DH

HIGH IMPEDANCE

(4)

t

CKHZ

t

OHZ

(5)

t

CD

D0 D0

t

CKLZ

EH

t

ES

t

DS

t

DH

D1

HIGH IMPEDANCE

3016 drw 20

(4)

SEQUENTIAL PORT WAVEFORM: BURST WRITE CYCLES

t

CYC

t

CH

SCLK

CNTEN

SLD

SI/O

IN

t

WS

t

WH

SR/

W

t

WS

t

WH

SCE

SOE

SI/O

OUT

NOTES :

1. If

2. If

3. Pointer is not incrementing on cycle immediately following

4. If SR/W = V

5.

SOE

IL, then address will be clocked in on the SCLK's rising edge.

SLD

= V

CNTEN

= V

IH for the SCLK's rising edge, the internal address counter will not advance.

= V

IL, data would be written to D0 again since

IL makes no difference at this point since the SR/

t

CL

t

ES

t

DS

A0Dx

HIGH IMPEDANCE

t

EH

t

ES

(3)

t

EH

(1)

t

t

DH

DS

D0

t

WS

t

WS

SLD

CNTEN

= VIH.

W

= VIL disables the output until SR/W = VIH is clocked in on the next rising clock edge.

t

WH

t

WH

even if

t

DH

CNTEN

D1

is Low.

D2

(5)

(2)

(5)

t

CKLZ

t

CD

30916 drw 21

D2

6.31 17

IDT70825S/L
HIGH-SPEED 8K x 16 SEQUENTIAL ACCESS RANDOM ACCESS MEMORY MILITARY AND COMMERCIAL TEMPERATURE RANGES

SEQUENTIAL PORT WAVEFORM: WRITE CYCLES (STRT/EOB FLAG TIMING)

t

SCLK

CNTEN

SSTRT

SI/O

SR/

1/2

SCE

CH

IN

Dx

t

WS

t

WH

W

t

WS

t

WH

t

CL

t

EH

t

ES

(4)

t

ES

D0

(3)

t

EH

(1)

t

t

DS

t

D1

WS

WS

t

t

WH

WH

t

DH

D2

D3

HIGH IMPEDANCE

(2)

(5)

SOE

SI/O

OUT

EOB

1/2

NOTES:

1. If

SSTRT

1 or

SSTRT

2. If

CNTEN

3.

SOE

will control the output and should be High on Power-Up. If

that cycle. If

IH for the SCLK's rising edge, the internal address counter will not advance.

= V

SCE

the bus contention and permit a Write on this cycle.

4. Unlike

5. If SR/W = V

6.

SLD

case,

IL, data would be written to D0 again since

IL makes no difference at this point since the SR/

SOE

= V

HIGH IMPEDANCE

2 = VIL, then address will be clocked in on the SCLK's rising edge.

IL and is clocked in while SR/

= V

CNTEN

is not disabled on cycle immediately following

(6)

t

EB

IL and is clocked in while SR/

SCE

W

= VIL, the data addressed will be written to if the last cycle was a Read.

CNTEN

W

= V

SSTRT

.

= VIH.

= VIL disables the output until SR/W = VIH is clocked in on the next rising clock edge.

W

= VIH, the data addressed will be read out within

t

CKLZ

t

CD

SOE

may be used to control

D3

3016 drw 22

6.31 18

IDT70825S/L
HIGH-SPEED 8K x 16 SEQUENTIAL ACCESS RANDOM ACCESS MEMORY MILITARY AND COMMERCIAL TEMPERATURE RANGES

SEQUENTIAL COUNTER ENABLE CYCLE AFTER RESET, WRITE CYCLE

SCLK

(2)

SI/O

IN

D0

D1 D2 D3 D4

SEQUENTIAL COUNTER ENABLE CYCLE AFTER RESET, READ CYCLE

SCLK

(2, 4, 6)

3016 drw 23

(2, 4)

SR/

SI/O

OUT

NOTES:

1. 'D0' represents data input for Address=0, 'D1' represents data input for Address=1, etc.

1. If

CNTEN

3. Data output is available at a t

4.

SCE

5. If

CNTEN

6. SR/W=V

IL then 'D1' would be written into 'A1' at this point.

=V

IL throughout all cycles.

=V

IL then 'D1' would be clocked out (read) at this point.

=V

IL.

CD after the SR/

(3)

(5)

W

=VIH is clocked. The

(5)

D0

RST

sets SR/W=Low internally and therefore disables the output until the next clock.

D1

D2

D3

3016 drw 24

6.31 19

IDT70825S/L
HIGH-SPEED 8K x 16 SEQUENTIAL ACCESS RANDOM ACCESS MEMORY MILITARY AND COMMERCIAL TEMPERATURE RANGES

RANDOM ACCESS PORT WAVEFORM: RESET TIMING

t

RSPW

t

RSRC

R/ , SR/

or

(4)

+ )

(

1/2 Flag Valid

t

WERS

t

RSFV

3016 drw 25

RANDOM ACCESS PORT WAVEFORM: RESTART TIMING OF SEQUENTIAL PORT

0.5 x t

CYC

t

FS

SCLK

R/

(3)

CLR
Block

(Internal Signal)

NOTES:

1. The sequential port is in the STOP mode and is being restarted from the random port by the Bit 4 Counter Release (see Case 5).

2. "0" is written to Bit 4 from the random port at address [A2 - A0] = 100, when
(see Case 5).

3. CLR is an internal signal only and is shown for reference only.

4. Sequential port must also prohibit SR/W or

(2)

SCE

from being low for t

2-5ns

6-7ns

CMD

= V

IL and

CE

= VIH. The device is in the Buffer Command Mode

WERS and tRSRC periods, or SCLK must not toggle from Low-to-High until after tRSRC.

(1)

3016 drw 26

6.31 20

IDT70825S/L
HIGH-SPEED 8K x 16 SEQUENTIAL ACCESS RANDOM ACCESS MEMORY MILITARY AND COMMERCIAL TEMPERATURE RANGES

ORDERING INFORMATION

IDT

XXXXX

Device

Type

A

Power

999

SpeedAPackage

A

Process/

Temperature

Range

Blank

Commercial (0°C to +70°C)

B Military (–55°C to +125°C)

Compliant to MIL-STD-883, Class B

G
PF

20
25
35

84-pin PGA (G84-3)
80-pin TQFP (PN80-1)

Commercial Only
Commercial Only

Speed in nanoseconds

45

S
L

70825

Standard Power
Low Power

128K (8K x 16) Sequential Access Random Access
Memory

3016 drw 27

6.31 21