MITSUBISHI M5M5W816WG-10LI

1999.1.15
MITSUBISHI LSIs
Ver. 0.1
M5M5W816WG -85L, 10L, 85H, 10H
-85LI, 10LI, 85HI, 10HI
PRELIMINARY
Notice: This is not a final specification.
Some parametric limits are subject to change
8388608-BIT (524288-WORD BY 16-BIT) CMOS STATIC RAM
Those are summarized in the part name table below.
DESCRIPTION
FEATURES
The M5M5W816 is a family of low voltage 8-Mbit static RAMs
organized as 524288-words by 16-bit, fabricated by Mitsubishi's
high-performance 0.18µm CMOS technology.
The M5M5W816 is suitable for memory applications where a
simple interfacing , battery operating and battery backup are the
important design objectives.
M5M5W816WG is packaged in a CSP (chip scale package),
with the outline of 7.0mm x 8.5mm, ball matrix of 6 x 8 (48ball)
and ball pitch of 0.75mm. It gives the best solution for a compaction
of mounting area as well as flexibility of wiring pattern of printed
circuit boards.
From the point of operating temperature, the family is divided
into two versions; "Standard" and "I-version".
Version,
Power
Supply
Part name
Operating
temperature
M5M5W816WG -85L
Standard
M5M5W816WG -10L
0 ~ +70°C
M5M5W816WG -85H
-40 ~ +85°C
M5M5W816WG -85HI
85ns
100ns
85ns
100ns
85ns
100ns
85ns
100ns
1.8 ~ 2.7V
M5M5W816WG -85LI
M5M5W816WG -10LI
max.
1.8 ~ 2.7V
M5M5W816WG -10H
I-version
Access time
1.8 ~ 2.7V
1.8 ~ 2.7V
M5M5W816WG -10HI
- Single 1.8~2.7V power supply
- Small stand-by current: 0.1µA (2.7V, typ.)
- No clocks, No refresh
- Data retention supply voltage =1.0V
- All inputs and outputs are TTL compatible.
- Easy memory expansion by S1, S2, BC1 and BC2
- Common Data I/O
- Three-state outputs: OR-tie capability
- OE prevents data contention in the I/O bus
- Process technology: 0.18µm CMOS
- Package: 48ball 7.0mm x 8.5mm CSP
Stand-by current (Vcc=2.7V)
Ratings (max.)
* Typical
25°C 40°C 25°C 40°C 70°C 85°C
0.1
0.2
---
---
16
---
0.1
0.2
1
2
8
---
0.1
0.2
---
---
16
30
0.1
0.2
1
2
8
15
Active
current
Icc1
(2.7V, typ.)
40mA
(10MHz)
5mA
(1MHz)
* Typical parameter indicates the value for the center
of distribution, and not 100% tested.
PIN CONFIGURATION
(TOP VIEW)
1
2
3
4
5
6
BC1
OE
A0
A1
A2
S2
DQ9
BC2
A3
A4
S1
DQ1
C DQ10
DQ11
A5
A6
DQ2
DQ3
D
GND
DQ12
A17
A7
DQ4
VCC
E
VCC
DQ13
GND
A16
DQ5
F
DQ15
DQ14
A14
A15
G
DQ16
N.C.
A12
H
A18
A8
A9
A
B
Pin
Function
A0 ~ A18 Address input
DQ1 ~ DQ16 Data input / output
Chip select input 1
GND
S1
S2
DQ7
W
OE
Write control input
DQ6
A13
W
DQ8
A10
A11
N.C.
Chip select input 2
Output enable input
BC1
Lower Byte (DQ1 ~ 8)
BC2
Upper Byte (DQ9 ~ 16)
Vcc
Power supply
GND
Ground supply
Outline: 48FHA
NC: No Connection
MITSUBISHI ELECTRIC
1
1999.1.15
MITSUBISHI LSIs
Ver. 0.1
M5M5W816WG -85L, 10L, 85H, 10H
-85LI, 10LI, 85HI, 10HI
PRELIMINARY
Notice: This is not a final specification.
Some parametric limits are subject to change
8388608-BIT (524288-WORD BY 16-BIT) CMOS STATIC RAM
FUNCTION
The M5M5W816WG is organized as 524288-words by 16bit. These devices operate on a single +1.8~2.7V power
supply, and are directly TTL compatible to both input and
output. Its fully static circuit needs no clocks and no refresh,
and makes it useful.
The operation mode are determined by a combination of
the device control inputs BC1 , BC2 , S1, S2 , W and OE.
Each mode is summarized in the function table.
A write operation is executed whenever the low level W
overlaps with the low level BC1 and/or BC2 and the low level
S1 and the high level S2. The address(A0~A18) must be set
up before the write cycle and must be stable during the entire
cycle.
A read operation is executed by setting W at a high level
and OE at a low level while BC1 and/or BC2 and S1 and S2
are in an active state(S1=L,S2=H).
When setting BC1 at the high level and other pins are in an
active stage , upper-byte are in a selectable mode in which
both reading and writing are enabled, and lower-byte are in a
non-selectable mode. And when setting BC2 at a high level
and other pins are in an active stage, lower-byte are in a
selectable mode and upper-byte are in a non-selectable
mode.
When setting BC1 and BC2 at a high level or S1 at a high level
or S2 at a low level, the chips are in a non-selectable mode in
which both reading and writing are disabled. In this mode, the
output stage is in a high-impedance state, allowing OR-tie with
other chips and memory expansion by BC1, BC2 and S1, S2.
The power supply current is reduced as low as 0.1µA(25°C,
typical), and the memory data can be held at +1V power supply,
enabling battery back-up operation during power failure or
power-down operation in the non-selected mode.
FUNCTION TABLE
BLOCK DIAGRAM
S1
H
L
H
X
L
L
L
L
L
L
L
L
L
S2 BC1 BC2
L
X X
L
X X
H X X
X H H
H L
H
H L H
H L H
H H L
H H L
H H L
H L
L
H L
L
H L
L
W OE
X X
X X
X X
X X
L X
H L
H H
L X
H L
H H
L X
H L
H H
A0
Mode
Non selection
Non selection
Non selection
Non selection
Write
Read
Write
Read
Write
Read
DQ1~8
DQ9~16
High-Z
High-Z
High-Z
High-Z
Din
Dout
High-Z
High-Z
High-Z
High-Z
Din
Dout
High-Z
High-Z
High-Z
High-Z
High-Z
High-Z
High-Z
High-Z
Din
Dout
High-Z
Din
Dout
High-Z
Icc
Standby
Standby
Standby
Standby
Active
Active
Active
Active
Active
Active
Active
Active
Active
DQ
1
A1
MEMORY ARRAY
DQ
8
524288 WORDS
x 16 BITS
A17
-
DQ
9
A18
S1
CLOCK
GENERATOR
DQ
16
S2
BC1
Vcc
BC2
W
GND
OE
MITSUBISHI ELECTRIC
2
1999.1.15
MITSUBISHI LSIs
Ver. 0.1
M5M5W816WG -85L, 10L, 85H, 10H
-85LI, 10LI, 85HI, 10HI
PRELIMINARY
Notice: This is not a final specification.
Some parametric limits are subject to change
8388608-BIT (524288-WORD BY 16-BIT) CMOS STATIC RAM
ABSOLUTE MAXIMUM RATINGS
Symbol
Vcc
VI
VO
Pd
Ta
Tstg
Parameter
Conditions
Units
Ratings
Supply voltage
Input voltage
With respect to GND
Output voltage
With respect to GND
-0.5* ~ +4.6
-0.2* ~ Vcc + 0.2 (max. 4.6V)
0 ~ Vcc
700
0 ~ +70
- 40 ~ +85
With respect to GND
Power dissipation
Ta=25∞C
Operating
temperature
Standard
(-L, -H)
I-version
(-LI, -HI)
Storage temperature
V
mW
°C
- 65 ~ +150
°C
* -3.0V in case of AC (Pulse width <
= 30ns)
DC ELECTRICAL CHARACTERISTICS
Symbol
Parameter
VIH
VIL
VOH
VOL
II
IO
High-level input voltage
( Vcc=1.8 ~ 2.7V, unless otherwise noted)
Limits
Conditions
Min
Low-level input voltage
High-level output voltage
Low-level output voltage
Input leakage current
Output leakage current
IOH= -0.1mA
IOL=0.1mA
VI =0 ~ Vcc
BC1 and BC2<
= 0.2V, S1<
= 0.2V, S2 Vcc-0.2V
>
other inputs <
= 0.2V or = Vcc-0.2V
Output - open (duty 100%)
f= 10MHz
Active supply current
Icc2
( AC,TTL level )
BC1 and BC2=VIL , S=VIL ,S2=VIH
other pins =VIH or VIL
Output - open (duty 100%)
f= 10MHz
other inputs = 0 ~ Vcc
Icc3 Stand by supply current
( AC,MOS level )
-H, -HI
(2) S2 => 0.2V,
-0.2 *
1.6
0.4
-
40
5
40
5
0.1
0.2
-
0.2
±1
±1
50
10
50
10
1
2
8
15
16
30
(3) BC1 and BC2 => Vcc - 0.2V
-
-
0.5
-
f= 1MHz
-
~ +40°C
~ +70°C
other inputs = 0 ~ Vcc
>Vcc - 0.2V
S1 <
= 0.2V, S2 =
other inputs = 0 ~ Vcc
-HI
-L, -LI
-LI
Stand by supply current
Icc4
( AC,TTL level )
Vcc+0.2V
f= 1MHz
~ +25°C
(1) S1 => Vcc - 0.2V,
Max
0.7 x Vcc
BC1 and BC2=VIHor S1=VIHor S2=VIL or OE=VIH, VI/O=0 ~ Vcc
Icc1 Active supply current
( AC,MOS level )
Typ
~ +85°C
~ +70°C
~ +85°C
BC1 and BC2=VIH or S1=VIH or S2=VIL
Other inputs= 0 ~ Vcc
Units
V
µA
mA
µA
mA
< 30ns)
Note 1: Direction for current flowing into IC is indicated as positive (no mark)
* -1.0V in case of AC (Pulse width =
Note 2: Typical parameter indicates the value for the center of distribution at 2.7V, and not 100% tested.
CAPACITANCE
Symbol
CI
CO
Parameter
(Vcc=1.8 ~ 2.7V, unless otherwise noted)
Conditions
Min
Input capacitance
VI=GND, VI=25mVrms, f=1MHz
Output capacitance
VO=GND,VO=25mVrms, f=1MHz
MITSUBISHI ELECTRIC
Limits
Typ
Max
10
10
Units
pF
3
1999.1.15
MITSUBISHI LSIs
Ver. 0.1
M5M5W816WG -85L, 10L, 85H, 10H
-85LI, 10LI, 85HI, 10HI
PRELIMINARY
Notice: This is not a final specification.
Some parametric limits are subject to change
8388608-BIT (524288-WORD BY 16-BIT) CMOS STATIC RAM
AC ELECTRICAL CHARACTERISTICS
(1) TEST CONDITIONS
Supply voltage
Input pulse
Input rise time and fall time
Reference level
(Vcc=1.8 ~ 2.7V, unless otherwise noted)
1TTL
1.8~2.7V
VIH=0.7 x Vcc, VIL=0.2V
5ns
VOH=VOL=0.9V
DQ
CL
Transition is measured ±200mV from
steady state voltage.(for ten,tdis)
Including scope and
jig capacitance
Fig.1,CL=30pF
CL=5pF (for ten,tdis)
Output loads
Fig.1 Output load
(2) READ CYCLE
Limits
Parameter
Symbol
tCR
ta(A)
ta(S1)
ta(S2)
ta(BC1)
ta(BC2)
ta(OE)
tdis(S1)
tdis(S2)
tdis(BC1)
tdis(BC2)
tdis(OE)
ten(S1)
ten(S2)
tdis(BC1)
tdis(BC2)
ten(OE)
tV(A)
85L, 85H,
85LI, 85HI
Read cycle time
Address access time
Chip select 1 access time
Chip select 2 access time
Byte control 1 access time
Byte control 2 access time
Output enable access time
Output disable time after S1 high
Output disable time after S2 low
Output disable time after BC1 high
Output disable time after BC2 high
Output disable time after OE high
Output enable time after S1 low
Output enable time after S2 high
Output enable time after BC1 low
Output enable time after BC2 low
Output enable time after OE low
Data valid time after address
Min
85
10L, 10H,
10LI, 10HI
Max
Min
100
85
85
85
85
85
45
30
30
30
30
30
100
100
100
100
100
50
35
35
35
35
35
10
10
10
10
5
10
Units
Max
10
10
10
10
5
10
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
(3) WRITE CYCLE
Limits
Symbol
tCW
tw(W)
tsu(A)
tsu(A-WH)
tsu(BC1)
tsu(BC2)
tsu(S1)
tsu(S2)
tsu(D)
th(D)
trec(W)
tdis(W)
tdis(OE)
ten(W)
ten(OE)
85L, 85H,
85LI, 85HI
Parameter
Write cycle time
Write pulse width
Address setup time
Address setup time with respect to W
Byte control 1 setup time
Byte control 2 setup time
Chip select 1 setup time
Chip select 2 setup time
Data setup time
Data hold time
Write recovery time
Output disable time from W low
Output disable time from OE high
Output enable time from W high
Output enable time from OE low
Min
85
60
0
70
70
70
70
70
45
0
0
10L, 10H,
10LI, 10HI
Max
Min
100
75
0
85
85
85
85
85
50
0
0
30
30
35
35
5
5
5
5
MITSUBISHI ELECTRIC
Units
Max
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
4
1999.1.15
MITSUBISHI LSIs
Ver. 0.1
M5M5W816WG -85L, 10L, 85H, 10H
-85LI, 10LI, 85HI, 10HI
PRELIMINARY
Notice: This is not a final specification.
Some parametric limits are subject to change
8388608-BIT (524288-WORD BY 16-BIT) CMOS STATIC RAM
(4)TIMING DIAGRAMS
Read cycle
tCR
A0~18
tv (A)
ta(A)
ta(BC1) or ta(BC2)
BC1,BC2
(Note3)
tdis (BC1) or tdis (BC1)
(Note3)
ta(S1)
S1
(Note3)
tdis (S1)
(Note3)
tdis (S2)
(Note3)
ta(S2)
S2
(Note3)
ta (OE)
OE
(Note3)
ten (OE)
W = "H" level
DQ1~16
Write cycle ( W control mode )
tdis (OE)
ten (BC1)
ten (BC2)
ten (S1)
ten (S2)
(Note3)
VALID DATA
tCW
A0~18
tsu (BC1) or tsu(BC2)
BC1,BC2
(Note3)
(Note3)
tsu (S1)
S1
(Note3)
(Note3)
S2
tsu (S2)
(Note3)
(Note3)
OE
tsu (A)
tsu (A-WH)
tw (W)
trec (W)
tdis (W)
W
ten(OE)
ten (W)
tdis(OE)
DQ1~16
DATA IN
STABLE
tsu (D)
th (D)
MITSUBISHI ELECTRIC
5
1999.1.15
MITSUBISHI LSIs
Ver. 0.1
M5M5W816WG -85L, 10L, 85H, 10H
-85LI, 10LI, 85HI, 10HI
PRELIMINARY
Notice: This is not a final specification.
Some parametric limits are subject to change
8388608-BIT (524288-WORD BY 16-BIT) CMOS STATIC RAM
Write cycle (BC control mode)
tCW
A0~18
tsu (A)
tsu (BC1) or
tsu (BC2)
trec (W)
BC1,BC2
S1
(Note3)
(Note3)
S2
(Note3)
W
(Note3)
(Note5)
(Note4)
(Note3)
(Note3)
tsu (D)
DQ1~16
th (D)
DATA IN
STABLE
Note 3: Hatching indicates the state is "don't care".
Note 4: A Write occurs during S1 low, S2 high overlaps BC1 and/or BC2 low and W low.
Note 5: When the falling edge of W is simultaneously or prior to the falling edge of BC1 and/or BC2 or the falling edge of S1
or rising edge of S2, the outputs are maintained in the high impedance state.
Note 6: Don't apply inverted phase signal externally when DQ pin is in output mode.
MITSUBISHI ELECTRIC
6
1999.1.15
MITSUBISHI LSIs
Ver. 0.1
M5M5W816WG -85L, 10L, 85H, 10H
-85LI, 10LI, 85HI, 10HI
PRELIMINARY
Notice: This is not a final specification.
Some parametric limits are subject to change
8388608-BIT (524288-WORD BY 16-BIT) CMOS STATIC RAM
Write cycle (S1 control mode)
tCW
A0~18
BC1,BC2
(Note3)
tsu (S1)
tsu (A)
trec (W)
(Note3)
S1
S2
(Note3)
(Note3)
(Note5)
W
(Note4)
(Note3)
tsu (D)
DQ1~16
th (D)
(Note3)
DATA IN
STABLE
Write cycle (S2 control mode)
tCW
A0~18
BC1,BC2
(Note3)
tsu (A)
tsu (S2)
trec (W)
(Note3)
S1
S2
(Note3)
(Note3)
(Note5)
W
(Note4)
(Note3)
DQ1~16
tsu (D)
th (D)
(Note3)
DATA IN
STABLE
MITSUBISHI ELECTRIC
7
1999.1.15
MITSUBISHI LSIs
Ver. 0.1
M5M5W816WG -85L, 10L, 85H, 10H
-85LI, 10LI, 85HI, 10HI
PRELIMINARY
Notice: This is not a final specification.
Some parametric limits are subject to change
8388608-BIT (524288-WORD BY 16-BIT) CMOS STATIC RAM
POWER DOWN CHARACTERISTICS
(1) ELECTRICAL CHARACTERISTICS
Symbol
Parameter
Test conditions
Min
Vcc (PD) Power down supply voltage
VI (BC)
VI (S1)
VI (S2)
Byte control input BC1 & BC2
Chip select input S1
1.8V
Vcc(PD)
1.0V
Vcc(PD) 1.8V
1.8V
Vcc(PD)
1.0V
Vcc(PD) 1.8V
0.7xVcc
V
Vcc(PD)
0.7xVcc
V
Vcc(PD)
(1) S1 => Vcc - 0.2V,
-H, -HI
other inputs = 0 ~ Vcc
other inputs = 0 ~ Vcc
-HI
-L, -LI
-LI
(3) BC1 and BC2 => Vcc - 0.2V
> Vcc - 0.2V
S1 <
= 0.2V, S2 =
other inputs = 0 ~ Vcc
-
~ +25°C
~ +40°C
~ +70°C
~ +85°C
~ +70°C
~ +85°C
(2) S2 => 0.2V,
0.02
0.05
-
0.2
0.5
1
4
7.5
8
15
Limits
Parameter
tsu (PD)
trec (PD)
Power down set up time
Power down recovery time
µA
Note 2: Typical parameter of Icc(PD) indicates the value for the
center of distribution at 1.0V, and not 100% tested.
(2) TIMING REQUIREMENTS
Symbol
Units
V
Chip select input S2
Power down
supply current
Max
1.0
Vcc=1.0V
Icc (PD)
Limits
Typ
Test conditions
Min
Typ
Max
0
5
Units
ns
ms
(3) TIMING DIAGRAM
BC control mode
Vcc
tsu (PD)
1.8V
1.8V
trec (PD)
0.7 x Vcc
0.7 x Vcc
BC1
BC2
BC1 , BC2 >
=Vcc-0.2V
S1 control mode
Vcc
tsu (PD)
1.8V
1.8V
trec (PD)
0.7 x Vcc
0.7 x Vcc
S1 >
= Vcc-0.2V
S1
S2 control mode
Vcc
S2
Vcc-0.2V
tsu (PD)
1.8V
1.8V
trec (PD)
0.7 x Vcc
S2
0.2V
MITSUBISHI ELECTRIC
8