Datasheet BS616LV1010EI, BS616LV1010EC, BS616LV1010AI, BS616LV1010AC Datasheet (BSI)

BSI

Very Low Power/Voltage
64K X 16 bit

CMOS SRAM

BS616LV1010

 FEATURES

• Very low operation voltage : 2.4 ~ 5.5V

• Very low power consumption :
Vcc = 3.0V C-grade : 20mA (Max.) operating current

I- grade : 25mA (Max.) operating current

0.02uA (Typ.) CMOS standby current

Vcc = 5.0V C-grade : 35mA (Max.) operating current

I- grade : 40mA (Max.) operating current

0.4uA (Typ.) CMOS standby current

• High speed access time :

-70 70ns (Max.) at Vcc = 3.0V

• Automatic power down when chip is deselected

• Three state outputs and TTL compatible

• Fully static operation

 DESCRIPTION

The BS616LV1010 is a high performance, very low power CMOS Static
Random Access Memory organized as 65,536 words by 16 bits and
operates from a wide range of 2.4V to 5.5V supply voltage.
Advanced CMOS technology and circuit techniques provide both high
speed and low power features with a typical CMOS standby current
of 0.02uA and maximum access time of 70ns in 3V operation.
Easy memory expansion is provided by an active LOW chip
enable(CE) and active LOW output enable(OE) and three-state output
drivers.
The BS616LV1010 has an automatic power down feature, reducing the
power consumption significantly when chip is deselected.
The BS616LV1010 is available in the JEDEC standard 44-pin TSOP
Type II and 48-pin BGA package.

• Data retention supply voltage as low as 1.5V

• Easy expansion with CE and OE options

• I/O Configuration x8/x16 selectable by LB and UB pin

 PRODUCT FAMILY

PRODUCT

FAMILY

OPERATING

TEMPERATURE

Vcc

RANGE

SPEED

(ns)

Vcc=3.0V Vcc=5.0V Vcc=3.0V Vcc=5.0V Vcc=3.0V

BS616LV1010EC TSOP2-44

+0

O

C to +70

O

C 2.4V ~ 5.5V 70 3uA 0.5uA 35mA 20mA

BS616LV1010AC

BS616LV1010EI TSOP2-44

BS616LV1010AI

 PIN CONFIGURATIONS

1

A4

2

A3

3

A2

4

A1

5

A0

6

CE

7

DQ0

8

DQ1

9

DQ2
DQ3

VCC
GND
DQ4
DQ5
DQ6
DQ7

WE
A15
A14
A13
A12
NC

A

B

C

D

E

F

G

BS616LV1010EC

10
11

BS616LV1010EI

12
13
14
15
16
17
18
19
20
21
22

12345

IO8LBUBOEA3

IO9

IO10

VSS

IO11

VCC

IO12

IO14

IO13 A14

IO15 NC A12

-40

A0

A5

NC

NC

A15 IO5

A13 WE IO7

O

C to +85

44
43
42
41
40
39
38
37
36
35
34
33
32
31
30
29
28
27
26
25
24
23

A4A1CEA2IO0

A6

IO1

A7

IO3

NC

IO4

O

C 2.4V ~ 5.5V 70 5uA 1.5uA 40mA 25mA

 BLOCK DIAGRAM

A5
A6
A7
OE
UB
LB
DQ15
DQ14
DQ13
DQ12
GND
VCC
DQ11
DQ10
DQ9
DQ8
NC
A8
A9
A10
A11
NC

6

NC

IO2

VCC

VSS

IO6

POWER DISSIPATION

STANDBY

(I

, Max)

CCSB1

A8
A13

A15

A14

A12

DQ0

DQ15

Vcc
Gnd

Address

Input

Buffer

A7

A6
A5
A4

.

.

.

.

.

.

.

.

CE

WE

OE

UB

LB

Control

Operating

(ICC, Max)

PKG TYPE

BGA-48-0608

BGA-48-0608

18

16

16

Data
Input
Buffer

Data

Output

Buffer

Row

Decoder

512

16

16

Memory Array

512 x 2048

Column I/O

Write Driver

Sense Amp

Column Decoder

Address Input Buffer

A9

A3 A2 A1

A11

2048

128

14

A10

A0

H

A9A8NC

NCA11A10

Brilliance Semiconductor Inc. reserves the right to modify document contents without notice.

R0201-BS616LV1010

1

Revision 2.2
April 2001

BSI

 PIN DESCRIPTIONS

Name Function

BS616LV1010

A0-A15 Address Input

CE Chip Enable Input

WE Write Enable Input

OE Output Enable Input

LB and UB Data Byte Control Input

DQ0 - DQ15 Data Input/Output
Ports

Vcc

Gnd

 TRUTH TABLE

These 16 address inputs select one of the 65,536 x 16-bit words in the RAM.

CE is active LOW. Chip enables must be active when data read from or write to the

device. if chip enable is not active, the device is deselected and is in a standby power

mode. The DQ pins will be in the high impedance state when the device is deselected.

The write enable input is active LOW and controls read and write operations. With the

chip selected, when WE is HIGH and OE is LOW, output data will be present on the

DQ pins; when WE is LOW, the data present on the DQ pins will be written into the

selected memory location.

The output enable input is active LOW. If the output enable is active while the chip is

selected and the write enable is inactive, data will be present on the DQ pins and they

will be enabled. The DQ pins will be in the high impedance state when OE is inactive.

Lower byte and upper byte data input/output control pins.

These 16 bi-directional ports are used to read data from or write data into the RAM.

Power Supply

Ground

MODE CE WE OE LB UB DQ0~DQ7 DQ8~DQ15 Vcc CURRENT

Not selected

(Power Down)

H X X X X High Z High Z I

Output Disabled L H H X X High Z High Z I

L L Dout Dout I

Read L H L

H L High Z Dout I

L H Dout High Z I

L L Din Din I

Write L L X

H L X Din I

L H Din X I

R0201-BS616LV1010

2

CCSB

, I

CCSB1

CC

CC

CC

CC

CC

CC

CC

Revision 2.2
April 2001

BSI

BS616LV1010

 ABSOLUTE MAXIMUM RATINGS

(1)

SYMBOL PARAMETE R RATING UNITS

V

T

T

P

I

TERM

BIAS

STG

T

OUT

Terminal Voltage with
Respect to GND

Temperature Under Bias -40 to +125

Storage Temperature -60 to +150

Power Dissipation 1.0 W

DC Output Current 20 mA

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.

 DC ELECTRICAL CHARACTERISTICS ( TA = 0

PARAMETER

NAME

IL

V

IH

V

IL

I

IOL Output Leakage Current

VOL Output Low Voltage Vcc = Max, IOL = 2mA

VOH Output High Voltage Vcc = Min, IOH = -1mA

CC

I

CCSB

I

Standby Current-TTL CE = VIH, IDQ = 0mA

CCSB1

I

Standby Current-CMOS

PARAMETER TEST CONDITIONS MIN. TYP.

Guaranteed Input Low

(2)

Voltage
Guaranteed Input High

(2)

Voltage

Input Leakage Current Vcc = Max, V

Operating Power Supply
Current

-0.5 to

Vcc+0.5

V

O

C

O

C

o

C to + 70oC )

IN

= 0V to Vcc -- -- 1 uA

Vcc = Max, CE = V

I/O

V

= 0V to Vcc

IL

CE = V

, IDQ = 0mA, F = Fmax

CE Њ Vcc-0.2V,

IN

Њ Vcc - 0.2V or VINЉ 0.2V

V

 OPERATING RANGE

RANGE

Commercial 0

Industrial -40

 CAPACITANCE

SYMBOL PARAMETER CONDITIONS MAX. UNIT

C

C

1. This parameter is guaranteed and not tested.

IH

, or OE = VIH,

IN

DQ

(3)

Input
Capacitance
Input/Output
Capacitance

Vcc=3.0V

Vcc=5.0V

Vcc=3.0V

Vcc=5.0V

Vcc=3.0V

Vcc=5.0V

Vcc=3.0V

Vcc=5.0V

Vcc=3.0V

Vcc=5.0V

Vcc=3.0V

Vcc=5.0V

Vcc=3.0V

Vcc=5.0V

AMBIENT

TEMPERATURE

O

C to +70

O

(1)

-0.5 -- 0.8 V

2.0

2.2

2.4 -- -- V

O

C2.4V ~ 5.5V

C to +85

O

C2.4V ~ 5.5V

(TA = 25oC, f = 1.0 MHz)

VIN=0V 6 pF

I/O

V

=0V 8 pF

(1)

MAX.

-- Vcc+0.2 V

-- -- 1 uA

-- -- 0.4 V

-- -- 20

-- -- 35

-- -- 1

-- -- 2

-- 0.02 0.5

-- 0.4 3

Vcc

UNITS

mA

mA

uA

1. Typical characteristics are at TA = 25oC.

2. These are absolute values with respect to device ground and all overshoots due to system or tester notice are included.

3. Fmax = 1/t

 DATA RETENTION CHARACTERISTICS ( TA = 0

SYMBOL PAR AMETE R TEST CONDITIONS MIN. TYP.

V

I

CCDR

t

CDR

t

.

RC

o

C to + 70oC )

(1)

MAX. UNITS

DR

Vcc for Data Retention

Data Retention Current

CE Њ Vcc - 0.2V

Њ

IN

Vcc - 0.2V or V

V

CE Њ Vcc - 0.2V

Њ

IN

Vcc - 0.2V or V

V

Љ

IN

0.2V

Љ

IN

0.2V

Chip Deselect to Data
Retention Time

R

Operation Recovery Time

See Retention Waveform

1.5 -- -- V

-- 0.02 0.3 uA

0---- ns

(2)

T

RC

-- -- ns

1. Vcc = 1.5V, TA= + 25OC

2. t

= Read Cycle Time

RC

R0201-BS616LV1010

3

Revision 2.2
April 2001

BSI

 LOW VCCDATA RETENTION WAVEFORM ( CE Controlled )

Data Retention Mode

≥

Vcc

CE

Vcc

t CDR

VDR 1.5V

≥

CE Vcc - 0.2V

BS616LV1010

Vcc

t R

VIHVIH

 AC TEST CONDITIONS

Input Pulse Levels
Input Rise and Fall Times
Input and Output
Timing Reference Level

Vcc/0V
5ns

0.5Vcc

 AC TEST LOADS AND WAVEFORMS

3.3V

OUTPUT

INCLUDING
JIG AND
SCOPE

OUTPUT

Vcc

GND

Ω

1269

100PF

1404

FIGURE 1A

THEVENIN EQUIVALENT

ALL INPUT PULSES

10%

→

Ω

90%

←

FIGURE 2

3.3V

OUTPUT

Ω667

90%

→

INCLUDING
JIG AND
SCOPE

10%

←

1269

5PF

FIGURE 1B

1.73V

5ns

 AC ELECTRICAL CHARACTERISTICS ( TA = 0

READ CYCLE

JEDEC

PARAMETER

NAME

t

AVAX

t

AVQV

t

E1LQV

t

BA

t

GLQV

t

E1LQX

t

BE

t

GLQX

t

E1HQZ

t

BDO

t

GHQZ

t

AXOX

PARAMETER

NAME

t

RC

t

AA

t

ACS

t

BA

t

OE

t

CLZ

t

BE

t

OLZ

t

CHZ

t

BDO

t

OHZ

t

OH

Read Cycle Time

Address Access Time

Chip Select Access Time

Data Byte Control Access Time

Output Enable to Output Valid

Chip Select to Output Low Z

Data Byte Control to Output Low Z

Output Enable to Output in Low Z

Chip Deselect to Output in High Z

Data Byte Control to Output High Z

Output Disable to Output in High Z

Output Disable to Output Address Change

 KEY TO SWITCHING WAVEFORMS

WAVEFORM INPUTS OUTPUTS

Ω

Ω

1404

o

C to + 70oC, Vcc = 3.0V )

DESCRIPTION

MUST BE
STEADY

MAY CHANGE
FROM H TO L

MAY CHANGE
FROM L TO H

,

DON T CAR
ANY CHANG
PERMITTED

DOES NOT
APPLY

BS616LV1010-70

MIN. TYP. MAX.

E: CHANGE :

E STATE

MUST BE
STEADY

WILL BE
CHANGE
FROM H TO L

WILL BE
CHANGE
FROM L TO H

UNKNOWN

CENTER
LINE IS HIGH
IMPEDANCE
”OFF ”STATE

UNIT

70 -- -- ns

-- -- 70 ns

(CE) -- -- 70 ns

(LB,UB) -- -- 40 ns

-- -- 50 ns

(CE) 10 -- -- ns

(LB,UB) 10 -- -- ns

10 -- -- ns

(CE) 0 -- 35 ns

(LB,UB) 0 -- 30 ns

0--30 ns

10 -- -- ns

R0201-BS616LV1010

4

Revision 2.2
April 2001

BSI

 SWITCHING WAVEFORMS (READ CYCLE)

READ CYCLE1

ADDRESS

D

(1,2,4)

t AA

t OH

OUT

BS616LV1010

t RC

t OH

READ CYCLE2

CE

LB,UB

D

OUT

READ CYCLE3

ADDRESS

OE

(1,3,4)

(1,4)

t CLZ

t ACS

t BA

(5)

(5)

t BE

t RC

t BDO

t CHZ

t AA

t OE

t OH

CE

LB,UB

D

OUT

NOTES:

1. WE is high for read Cycle.

2. Device is continuously selected when CE = V

3. Address valid prior to or coincident with CE transition low.

4. OE = V

5. Transition is measured 500mV from steady state with CL = 5pF as shown in Figure 1B.

R0201-BS616LV1010

IL .

The parameter is guaranteed but not 100% tested.

t OLZ

(5)

t CLZ

(5)

t ACS

t OHZ

t CHZ

(1,5)

t BA

t BE

IL.

t BDO

±

5

Revision 2.2
April 2001

BSI

BS616LV1010

 AC ELECTRICAL CHARACTERISTICS ( TA = 0

WRITE CYCLE

JEDEC

PARAMETER

NAME

t

AVAX

t

E1LWH

t

AVWL

t

AVWH

t

WLWH

t

WHAX

t

BW

t

WLQZ

t

DVWH

t

WHDX

t

GHQZ

t

WHOX

PARAMETER

NAME

t

WC

t

CW

t

AS

t

AW

t

WP

t

WR

t

BW

t

WHZ

t

DW

t

DH

t

OHZ

t

OW

DESCRIPTION

Write Cycle Time

Chip Select to End of Write

Address Setup Time

Address Valid to End of Write

Write Pulse Width

Write recovery Time

Date Byte Control to End of Write

Write to Output in High Z

Data to Write Time Overlap

Data Hold from Write Time

Output Disable to Output in High Z

End of Write to Output Active

 SWITCHING WAVEFORMS (WRITE CYCLE)

WRITE CYCLE1

(1)

o

C to + 70oC, Vcc = 3.0V )

BS616LV1010-70
MIN. TYP. MAX.

70 -- -- ns

70 -- -- ns

0---- ns

70 -- -- ns

50 -- -- ns

(CE,WE) 0 -- -- ns

(LB,UB) 60 -- -- ns

0--30ns

30 -- -- ns

0---- ns

0--30ns

5---- ns

t WC

UNIT

ADDRESS

OE

CE

LB,UB

WE

D

OUT

D

IN

t AS

(4,10)

t OHZ

(3)

t WR

(11)

(5)

t CW

t BW

t AW

t WP

(2)

(3)

t DH

t DW

R0201-BS616LV1010

6

Revision 2.2
April 2001

BSI

BS616LV1010

WRITE CYCLE2

ADDRESS

CE

LB,UB

WE

D

OUT

D

IN

(1,6)

t AS

(5)

(4,10)

t WHZ

t AW

(12)

t WC

t CW

t WP

t BW

(11)

t WR

(3)

(2)

t DH

(7) (8)

t DW

t DH

(8,9)

NOTES:

1. WE must be high during address transitions.

2. The internal write time of the memory is defined by the overlap of CE and WE low. All signals
must be active to initiate a write and any one signal can terminate a write by going inactive.
The data input setup and hold timing should be referenced to the second transition edge of
the signal that terminates the write.

WR is measured from the earlier of CE or WE going high at the end of write cycle.

3. T

4. During this period, DQ pins are in the output state so that the input signals of opposite phase
to the outputs must not be applied.

5. If the CE low transition occurs simultaneously with the WE low transitions or after the WE
transition, output remain in a high impedance state.

6. OE is continuously low (OE = V

OUT is the same phase of write data of this write cycle.

7. D

OUT is the read data of next address.

8. D

9. If CE goes low during this period, DQ pins are in the output state. Then the data input signals of
opposite phase to the outputs must not be applied to them.

10. Transition is measured 500mV from steady state with C

The parameter is guaranteed but not 100% tested.

CW is measured from the later of CE going low to the end of write.

11. T

12. The change of Read/Write cycle must accompany with CE or address toggled.

IL ).

±

L = 5pF as shown in Figure 1B.

R0201-BS616LV1010

7

Revision 2.2
April 2001

BSI

 ORDERING INFORMATION

BS616LV1010 X X -- Y Y

BS616LV1010

SPEED

70: 70ns

GRADE

C: +0oC ~ +70oC

o

C ~ +85oC

I: -40

PACKAGE

E: TSOP II - 44 PIN
A: BGA - 48 PIN(6x8mm)

 PACKAGE DIMENSIONS

R0201-BS616LV1010

TSOP2-44

8

Revision 2.2
April 2001

BSI

 PACKAGE DIMENSIONS (continued)

1.4 Max.

D1

e

VIEW A

BS616LV1010

NOTES:

1: CONTROLLING DIMENSIONS ARE IN MILLIMETERS.

2: PIN#1 DOT MARKING BY LASER OR PAD PRINT.

3: SYMBOL "N" IS THE NUMBER OF SOLDER BALLS.

BALL PITCH e = 0.75

D

EN

8.0 6.0

E1

48 3.75

E1D1

5.25

48 mini-BGA (6 x 8)

R0201-BS616LV1010

9

Revision 2.2
April 2001

BSI

BS616LV1010

REVISION HISTORY

Revision Description Date Note

2.2 2001 Data Sheet release Apr. 15, 2001

R0201-BS616LV1010

10

Revision 2.2
April 2001