ETC M32L1632512A-8SQ

(607
SGRAM
M32L1632512A
256K x 32 Bit x 2 Banks
Synchronous Graphic RAM
FEATURES
y JEDEC standard 3.3V power supply
y LVTTL compatible with multiplexed address
y Dual bank / Pulse RAS
y MRS cycle with address key programs
y
y
y
y
y
y
- CAS Latency ( 2, 3 )
- Burst Length ( 1, 2, 4, 8 & full page )
- Burst Type ( Sequential & Interleave )
All inputs are sampled at the positive going
edge of the system clock
Burst Read Single-bit Write operation
DQM 0-3 for byte masking
Auto & self refresh
32ms refresh period (2K cycle)
100 pin QFP
Graphic Features
GENERAL DESCRIPTION
The M32L1632512A is 16, 777, 216 bits synchronous high data rate Dynamic RAM organized as 2 x
262, 144 words by 32 bits, fabricated with ESMT’s
high performance CMOS technology. Synchronous
design allows precise cycle control with the use of
system clock. I/O transactions are possible on every
clock cycle. Range of operating frequencies , programmable burst length, and programmable latencies
allows the same device to be useful for a variety of
high bandwidth, high performance memory system
applications.
Write per bit and 8 columns block write improves
performance in graphic systems.
ORDERING INFORMATION
y SMRS cycle
- Load mask register
- Load color register
y Write Per Bit
y Block Write (8 Columns)
Elite Semiconductor Memory Technology Inc.
Part NO.
Cycle
time
Clock
Access
tRDL
Frequency time@CL=3 (clk)
M32L1632512A-5Q
5ns
200MHz
4.5ns
1
M32L1632512A-5SQ
5ns
200MHz
4.5ns
2
M32L1632512A-6Q
6ns
166MHz
5.5ns
1
M32L1632512A-6SQ
6ns
166MHz
5.5ns
2
M32L1632512A-7Q
7ns
143MHz
6.0ns
1
M32L1632512A-7SQ
7ns
143MHz
6.0ns
2
M32L1632512A-8Q
8ns
125MHz
6.5ns
1
M32L1632512A-8SQ
8ns
125MHz
6.5ns
2
Publication Date : Jun. 2001
Revision : 1.6
1/54
(607
M32L1632512A
INPUT BUFFER
FUNCTIONAL BLOCK DIAGRAM
MASK
REGISTER
WRITE
CONTROL
LOGIC
MASK
DQMi
BLOCK
WRITE
CONTROL
LOGIC
COLOR
REGISTER
MUX
CLK
COLUMN
MASK
256Kx32
CELL
ARRAY
DSF
DQi
(i=0~31)
OUTPUT BUFFER
SENSE
AMPLIFIER
WE
COLUMN
DECORDER
CAS
LATENCY &
BURST LENGTH
RAS
DQMi
PROGRAMING
REGISTER
CS
TIMING REGISTER
CKE
256Kx32
CELL
ARRAY
ROW DECORDER
BANK SELECTION
DQMi
SERIAL
COUNTER
ROW ADDRESS
BUFFER
COLUMN ADDRESS
BUFFER
REFRESH
COUNTER
ADDRESS REGISTER
ADDRESS(A0~A10)
CLOCK
CLK
CKE
DSF
N. C
A9
54
53
52
51
DQ11
64
DQM1
VDD
65
55
VSS
66
DQM3
VDDQ
56
DQ12
67
N. C
DQ13
68
57
VSSQ
69
VDDQ
DQ14
71
70
DQ 8
DQ15
72
59
58
VDDQ
73
DQ 9
DQ24
74
61
DQ25
75
60
VSSQ
76
DQ10
DQ26
77
VSSQ
DQ27
78
62
VDDQ
79
63
DQ28
80
PIN CONFIGURATION (TOP VIEW)
DQ29
VSSQ
81
50
A7
82
49
A6
DQ30
83
48
A5
DQ31
VSS
84
85
47
A4
VSS
N. C
86
46
45
N. C
N. C
87
44
N. C
N. C
N. C
1 0 0
88
P in
43
N. C
41
N. C
N. C
40
N. C
N. C
93
39
38
94
95
37
36
N. C
N. C
89
90
F o rw a rd
N. C
N. C
91
2 0
N. C
92
N. C
N. C
N. C
VDD
Q F P
0 .6 5
x
42
T y p e
1 4
m m
m m p in
P itc h
N. C
20
21
22
23
24
25
26
27
28
29
30
DQ22
DQ23
VDDQ
DQM0
DQM2
WE
CAS
RAS
CS
BA(A10)
A8
19
9
18
8
VDDQ
DQ16
DQ21
VSSQ
7
DQ 7
17
6
DQ 6
DQ20
5
VSSQ
16
4
DQ5
15
3
VSS
2
DQ4
1
DQ3
VDDQ
Elite Semiconductor Memory Technology Inc.
VDD
A0
14
A1
31
DQ 2
13
A2
32
DQ19
VDDQ
33
99
10 0
12
98
DQ18
DQ 1
VSSQ
10
VDD
A3
11
34
VSSQ
35
97
DQ17
96
DQ 0
Publication Date : Jun. 2001
Revision : 1.6
2/54
(607
M32L1632512A
PIN DESCRIPTION
PIN
NAME
INPUT FUNCTION
CLK
System Clock
Active on the positive going edge to sample all inputs
CS
Chip Select
Disables or enable device operation by masking or enabling all
inputs except CLK, CKE and DQMi
CKE
Clock Enable
A0 ~ A9
Address
Row / column addresses are multiplexed on the same pins.
Row address : RA0~RA9, column address : CA0~CA7
A10(BA)
Bank Select Address
Selects bank to be activated during row address latch time.
Selects bank for read / write during column address latch time.
RAS
Row Address Strobe
Latches row addresses on the positive going edge of the CLK with
RAS low.
Enables row access & precharge.
CAS
Column Address Strobe
WE
Write Enable
Enables write operation and Row precharge.
DQMi
Data Input/Output Mask
Makes data output Hi-Z, tSHZ after the clock and masks the output.
Blocks data input when DQM active. (Byte Masking)
DQi
Data Input/Output
Data inputs/outputs are multiplexed on the same pins.
DSF
Define Special/ Function
Enables write per bit, block write and special mode register set.
VDD/VSS
Power Supply/ Ground
VDDQ/VSSQ
Data Output Power/Ground
Masks system clock to freeze operation from the next clock cycle.
CKE should be enabled at least one clock+ tss prior to new
command.
Disable input buffers for power down in standby.
Latches column address on the positive going edge of the CLK
With
CAS low.
Enables column access.
ABSOLUTE MAXIMUM RATINGS (Voltage referenced to VSS)
Parameter
Symbol
Value
Unit
Voltage on any pin relative to VSS
VIN, VOUT
-1.0 ~ 4.6
V
Voltage on VDD supply relative to VSS
VDD, VDDQ
-1.0 ~ 4.6
V
TSTG
-55 ~ +150
i
Power dissipation
PD
1
W
Short circuit current
IOS
50
mA
Storage temperature
Note : Permanent device damage may occur if “ABSOLUTE MAXIMUM RATINGS” are exceeded.
Functional operation should be restricted to recommended operating condition.
Exposure to higher than recommended voltage for extended periods of time could affect device
reliability.
Elite Semiconductor Memory Technology Inc.
Publication Date : Jun. 2001
Revision : 1.6
3/54
(607
M32L1632512A
DC OPERATING CONDITIONS
Recommended operating conditions (Voltage referenced to VSS = 0V)
Parameter
Symbol
Min
Typ
Max
Unit
VDD, VDDQ
3.0
3.3
3.6
V
Input high voltage
VIH
2.0
3.0
VDD+0.3
V
Input low voltage
VIL
-0.3
0
0.8
V
Note 1
Output high voltage
VOH
2.4
-
-
V
IOH = -2mA
Output low voltage
VOL
-
-
0.4
V
IOL = 2mA
Input leakage current
IIL
-5
-
5
µÂ
Note 2
Output leakage current
IOL
-5
-
5
µÂ
Note 3
Supply voltage
Output Loading Condition
Note
See Fig 1
Note: 1. VIL(min) = -1.5V AC (pulse width ≤ 5ns)
2. Any input 0V ≤ VIN ≤ VDD + 0.3V, all other pins are not under test = 0V.
4. Dout is disabled, 0V ≤ VOUT ≤ VDD.
CAPACITANCE (VDD/VDDQ = 3.3V, TA = 25 °C , f = 1MHZ)
Parameter
Symbol
Min
Max
Unit
CIN1
-
4
pF
CIN2
-
4
pF
COUT
-
5
pF
Symbol
Value
Unit
Decoupling Capacitance between VDD & VSS
CDC1
0.1+0.01
uF
Decoupling Capacitance between VDDQ & VSSQ
CDC2
0.1+0.01
uF
Input capacitance (A0 ~ A10)
Input capacitance
(CLK, CKE, CS , RAS , CAS , WE , DSF& DQM0-3)
Data input/output capacitance (DQ0 ~ DQ31)
DECOUPLING CAPACITANCE GUIDE LINE
Recommended decoupling capacitance added to power line at board.
Parameter
*Note: 1. VDD and VDDQ pins are separated each other.
All VDD pins are connected in chip. All VDDQ pins are connected in chip.
2. VSS and VSSQ pins are separated each other.
All VSS pins are connected in chip. All VSSQ pins are connected in chip.
Elite Semiconductor Memory Technology Inc.
Publication Date : Jun. 2001
Revision : 1.6
4/54
(607
M32L1632512A
DC CHARACTERISTICS
Recommended operating condition unless otherwise noted, TA = 0 to 70 °C VIH(min) /VIL(max) =2.0V/0.8V
Parameter
Symbol
Test Condition
Version
CAS
Unit Note
Latency -5/5S -6/6S -7/7S -8/8S
Operating Current
(One Bank Active)
Burst Length = 1
ICC1
3
230
210
195
170
2
230
210
195
170
2
2
2
2
2
2
2
2
35
35
35
35
tRC ≥ tRC(min), tCC ≥ tCC(min)
IOL = 0 mA
ICC2P CKE ≤ VIL(max), tCC = 15ns
Precharge Standby Current
in power-down mode
ICC2PS CKE ≤ VIL(max), CLK ≤ VIL(max), tCC = ∞
Precharge Standby Current
in non power-down mode
ICC2N CKE ≥ VIH(min), CS ≥ VIH(min), tCC = 15ns
Input signals are changed one time during
30ns
ICC2NS CKE ≥ VIH(min), CLK ≤ VIL(max), tCC = ∞
input signals are stable
Active Standby Current
in power-down mode
Active Standby Current
in non power-down mode
(One Bank Active)
Operating Current
(Burst Mode)
Refresh Current
Self Refresh Current
Operating Current
(One Bank Block Write)
mA
15
15
15
ICC3P CKE ≤ VIL(max), tCC = 15ns
3
3
3
3
ICC3PS CKE ≤ VIL(min), CLK ≤ VIL(max), tCC = ∞
3
3
3
3
60
60
60
60
20
20
20
20
230
210
195
170
ICC3NS CKE ≥ VIH(min), CLK ≤ VIL(max), tCC = ∞
input signals are stable
ICC4
IOL = 0 mA, Page Burst
All Banks Activated, tCCD = tCCD
3
(min)
2
230
210
195
170
3
190
170
160
150
2
190
170
160
150
tRC ≥ tRC(min)
ICC5
1
mA
15
ICC3N CKE ≥ VIH(min), CS ≥ VIH(min), tCC = 15ns
Input signals are changed one time during
30ns
mA
mA
mA
mA
1, 2
mA
3
ICC6
CKE ≤ 0.2V
2
2
2
2
mA
ICC7
tCC ≥ tCC(min), IOL = 0 mA, tBWC(min)
220
200
190
180
mA
4
*Note : 1. Measured with outputs open.
2. Assumes minimum column address update cycle tCCD(min).
3. Refresh period is 32ms.
4. Assumes minimum column address update cycle tBWC(min).
Elite Semiconductor Memory Technology Inc.
Publication Date : Jun. 2001
Revision : 1.6
5/54
(607
M32L1632512A
AC OPERATING TEST CONDITIONS (VDD = 3.3V ± 0.3V, TA = 0 to 70 °C )
Parameter
Value
AC Input levels
VIH/VIL = 2.4V/0.4V
Input timing measurement reference level
1.4V
Input rise and fall-time (See note3)
tR/tF = 1ns/1ns
Output timing measurement reference level
1.4V
Output load condition
See Fig. 2
3.3V
1200
Output
VREF = 1.4V
è
VOH (DC) =2.4V , IOH = -2 mA
è
è
Output
VOL (DC) =0.4V , IOL = 2 mA
50
è
Z0 =50
30pF
30pF
870
(Fig. 1) DC Output Load Circuit
(Fig. 2) AC Output Load Circuit
AC CHARACTERISTICS
(AC operating conditions unless otherwise noted)
-5/5S
Parameter
-6/6S
-7/7S
-8/8S
Symbol
Unit
Note
1000
ns
1
6.5
8
ns
1, 2
ns
ns
ns
2
Min Max Min Max Min Max Min Max
CAS latency =3
CAS latency =2
CLK to valid
CAS latency =3
output delay
CAS latency =2
Output data
CAS latency =3
hold time
CAS latency =2
CLK high pulse width
CLK cycle time
tCC
tSAC
tOH
CLK to output in Low-Z
tCH
tCL
tSS
tSH
tSLZ
CLK to output
In Hi-Z
tSHZ
CLK low pulse width
Input setup time
Input hold time
CAS latency =3
CAS latency =2
5
7.5
2
2
2
1000
4.5
5
6
8
2
2
2
1000
5.5
6
7
10
2
2
2.5
1000
6
7
8
12
2
2
3
3
2
2
2.5
3
ns
3
2
2
2
2.5
ns
3
1
1
1
1
ns
3
1
1
1
1
ns
2
-
5
5
-
5.5
6
-
6
7
-
6.5
8
ns
* All AC parameters are measured from half to half.
Elite Semiconductor Memory Technology Inc.
Publication Date : Jun. 2001
Revision : 1.6
6/54
(607
M32L1632512A
*Note : 1. Parameters depend on programmed CAS latency.
2. If clock rising time is longer than 1ns, (tr/2 - 0.5) ns should be added to the parameter.
3. Assumed input rising and falling time (tr & tf) = 1ns.
If tr & tf is longer 1ns, transient time compensation should be considered.
i.e., [(tr + tf)/2 - 1] ns should be added to the parameter.
OPERATING AC PARAMETER
(AC operating conditions unless otherwise noted)
Parameter
Version
Symbol
-5
Row active to row active delay
RAS to CAS delay
Row precharge time
Row active time
Row cycle time
Last data in to new col. address delay
Last data in to row precharge
Block write data-in to PRE command delay
Block write data-in to Active (REF)
command period (Auto precharge)
Last data to burst stop
tBAL(min)
tBDL(min)
tCCD(min)
tBWC(min)
Col. Address to col. Address delay
Block write cycle time
Number of valid Output data
tRRD(min)
tRCD(min)
tRP(min)
tRAS(min)
tRAS(max)
tRC(min)
tCDL(min)
tRDL(min)
tBPL(min)
-5S
-6
-6S
Unit
-7
-8
-8S
16
Note
10
12
-7S
14
15
18
20
20
ns
1
15
18
21
24
ns
1
40
40
42
48
ns
1
us
100
55
60
63
72
1
1
2
1
2
1
1
2
1
2
ns
1
CLK
2
CLK
2
10
12
14
16
ns
25
30
35
40
ns
2
1
CLK
2
1
CLK
3
CLK
4
CLK
5
2
2
CAS latency = 3
2
CAS latency = 2
1
2
Note : 1. The minimum number of clock cycles is determined by dividing the minimum time required with
clock cycle time and then rounding off to the next higher integer.
2. Minimum delay is required to complete write.
3. All parts allow every cycle column address change except block write cycle.
4. This parameter means minimum CAS to CAS delay at block write cycle only.
5. In case of row precharge interrupt, auto precharge and read burst stop.
Elite Semiconductor Memory Technology Inc.
Publication Date : Jun. 2001
Revision : 1.6
7/54
(607
M32L1632512A
FREQUENCY vs. AC PARAMETER RELATIONSHIP TABLE
M32L1632512A-5Q ( * : -5SQ )
(Unit : number of clock)
CAS
tRC
tRAS
tRP
tRRD
tRCD
tCCD
tCDL
tRDL
* tRDL
Latency
55ns
40ns
15ns
10ns
15ns
5ns
5ns
5ns
10ns
200 MHz(5.0ns)
3
11
8
3
2
3
1
1
1
2
166 MHz(6.0ns)
3
10
7
3
2
3
1
1
1
2
143 MHZ(7.0ns )
3
8
6
3
2
3
1
1
1
2
125 MHZ(8.0ns )
2
7
5
2
2
2
1
1
1
2
Frequency
M32L1632512A-6Q ( * : -6SQ )
(Unit : number of clock)
CAS
tRC
tRAS
tRP
tRRD
tRCD
tCCD
tCDL
tRDL
* tRDL
Latency
60ns
40ns
18ns
12ns
18ns
6ns
6ns
6ns
12ns
166 MHz(6.0ns)
3
10
7
3
2
3
1
1
1
2
143 MHZ(7.0ns )
3
9
6
3
2
3
1
1
1
2
125 MHZ(8.0ns )
2
8
5
3
2
3
1
1
1
2
100 MHZ(10.0ns )
2
6
4
2
2
2
1
1
1
2
Frequency
M32L1632512A-7Q ( * : -7SQ )
(Unit : number of clock)
CAS
tRC
tRAS
tRP
tRRD
TRCD
tCCD
tCDL
tRDL
* tRDL
Latency
63ns
42ns
21ns
14ns
20ns
7ns
7ns
7ns
14ns
143 MHZ(7.0ns )
3
9
6
3
2
3
1
1
1
2
125 MHZ(8.0ns )
3
8
6
3
2
3
1
1
1
2
100 MHZ(10.0ns )
2
7
5
3
2
2
1
1
1
2
83 MHZ(12.0ns )
2
6
4
2
2
2
1
1
1
2
Frequency
M32L1632512A-8Q ( * : -8SQ )
(Unit : number of clock)
CAS
tRC
tRAS
tRP
tRRD
tRCD
tCCD
tCDL
tRDL
* tRDL
Latency
72ns
48ns
24ns
16ns
20ns
8ns
8ns
8ns
16ns
125 MHZ(8.0ns )
3
9
6
3
2
3
1
1
1
2
100 MHZ(10.0ns )
3
8
5
3
2
2
1
1
1
2
83 MHZ(12.0ns )
2
6
4
2
2
2
1
1
1
2
75 MHZ(13.4ns )
2
6
4
2
2
2
1
1
1
2
Frequency
Elite Semiconductor Memory Technology Inc.
Publication Date : Jun. 2001
Revision : 1.6
8/54
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M32L1632512A
SIMPLIFIED TRUTH TABLE
COMMAND
Register
CKEn-1 CKEn
Mode Register set
H
X
CS
L
RAS CAS
L
L
WE
L
Special Mode Register Set
Entry
Self
Refresh
Bank Active
& Row Addr.
Read & Column
Address
Exit
Write Per Bit Disable
Write Per Bit Enable
Auto Precharge Disable
Auto Precharge Enable
Write & Column
Address
Auto Precharge Disable
Block Write &
Column Address
Auto Precharge Disable
Auto Precharge Enable
Auto Precharge Enable
Burst Stop
Precharge
X
OP CODE
H
Note
1, 2
1, 2, 7
H
L
H
L
H
X
L
L
L
H
L
H
H
H
H
X
X
X
L
L
H
H
L
X
X
X
X
X
H
X
X
L
H
L
H
L
X
V
H
X
L
H
L
L
L
X
V
X
L
H
L
L
H
X
L
H
H
L
L
X
H
X
L
L
H
L
L
X
L
H
H
H
Entry
H
L
H
X
X
X
X
X
Exit
L
H
X
X
X
X
X
X
L
H
H
H
Entry
H
L
H
X
X
X
X
X
L
V
V
V
V
H
X
X
X
X
Precharge Power Down Mode
Exit
L
DQM
H
No Operation Command
H
H
H
H
X
X
X
Row Address
4, 5
V
L
H
L
H
L
H
Column
Address
4
4, 6
4, 5
Column
Address
4,5,6,9
Column
Address
4,5,6,9
4, 5
X
V
L
X
H
7
X
X
X
V
X
X
X
8
H
X
H
3
X
X
L
3
4,5,9
X
Both Banks
V
H
H
3
3
L
H
Bank Selection
Clock Suspend or
Active Power Down
L
A8~A0
H
Auto Refresh
Refresh
DSF DQM A10 A9
X
(V = Valid, X = Don’t Care. H = Logic High, L = Logic Low )
Note : 1.OP Code : Operand Code
A0~A10 : Program keys. (@ MRS)
A5, A6 : LMR & LCR select. (@ SMRS)
Color register exists only one per DQi which both banks share.
So does Mask Register.
Color or mask is loaded into chip through DQ pin.
2.MRS can be issued only at both banks precharge state.
SMRS can be issued only if DQ’s are idle.
A new command can be issued at the next clock of MRS/SMRS.
Elite Semiconductor Memory Technology Inc.
Publication Date : Jun. 2001
Revision : 1.6
9/54
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M32L1632512A
3.Auto refresh functions as same as CBR refresh of DRAM.
The automatical precharge without Row precharge of command is meant by “Auto”.
Auto/self refresh can be issued only at both banks precharge state.
4.A10 : Bank select address.
If “Low” at read, (block) write, Row active and precharge, bank A is selected.
If “High” at read, (block) write, Row active and precharge, bank B is selected.
If A9 is “High” at Row precharge, A10 is ignored and both banks are selected.
5.It is determined at Row active cycle.
whether Normal/Block write operates in write per bit mode or not.
For A bank write, at A bank Row active, for B bank write, at B bank Row active.
Terminology : Write per bit = I/O mask
(Block) Write with write per bit mode = Masked (Block) Write
6.During burst read or write with auto precharge, new read/(block) write command cannot be issued.
Another bank read/(block) write command can be issued at tRP after the end of burst.
7.Burst stop command is valid for all burst length.
8.DQM sampled at positive going edge of a CLK.
masks the data-in at the very CLK (Write DQM latency is 0)
but makes Hi-Z state the data-out of 2 CLK cycles after.(Read DQM latency is 2)
9.Graphic features added to SDRAM’s original features.
If DSF is tied to low, graphic functions are disabled and chip operates as a 16M SDRAM with 32
DQ’s.
SGRAM vs SDRAM
SDRAM Function
MRS
DSF
Bank Active
L
H
L
Bank Active
With
Write per bit
Disable
If DSF is low. SGRAM functionality is identical to SDRAM functionality.
SGRAM
Function
MRS
SMRS
Write
H
L
H
Bank Active
With
Write per bit
Enable
Normal
Write
Block
Write
Æ
SGRAM can be uesed as an unified memory by the appropriate DSF control
SGRAM = Graphic Memory + Main Memory.
MODE REGISTER FIELD TABLE TO PROGRAM MODES
Register Programmed with MRS
Address
A10
A9
Function
RFU
W.B.L
(Note1)
A8
A7
TM
A6
A5
CAS Latency
A4
A3
BT
A2
A1
A0
Burst Length
(Note2)
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Test Mode
CAS Latency
Burst Type
Burst Length
A8
A7
Type
A6
A5
A4
Latency
A3
Type
A2
A1
A0
BT = 0
BT = 1
0
0
Mode Register Set
0
0
0
Reserved
0
Sequential
0
0
0
1
Reserved
0
1
Vendor
0
0
1
-
1
Interleave
0
0
1
2
Reserved
1
0
Use
0
1
0
2
0
1
0
4
4
1
1
Only
0
1
1
3
0
1
1
8
8
Write Burst Length
1
0
0
Reserved
1
0
0
Reserved Reserved
A9
Length
1
0
1
Reserved
1
0
1
Reserved Reserved
0
Burst
1
1
0
Reserved
1
1
0
Reserved Reserved
1
Single Bit
1
1
1
Reserved
1
1
1
256(Full) Reserved
(Note 3)
Special Mode Register Programmed with SMRS
Address
Function
A10
A9
A8
A7
X
A6
A5
LC
LM
Load Color
A4
A3
A2
A1
X
Load Mask
A6
Function
A5
Function
0
Disable
0
Disable
1
Enable
1
Enable
(Note 4)
POWER UP SEQUENCE
1.Apply power and start clock, Attempt to maintain CKE = ”H”, DQM = ”H” and the other pin are NOP
condition at the inputs.
2. Maintain stable power, stable clock and NOP input condition for a minimum of 200 µ s.
3. Issue precharge commands for all banks of the devices.
4. Issue 2 or more auto-refresh commands.
5. Issue a mode register set command to initialize the mode register.
cf.) Sequence of 4 & 5 may be changed.
The device is now ready for normal operation.
Note : 1. RFU(Reserved for Future Use) should stay “0” during MRS cycle.
2. If A9 is high during MRS cycle, “Burst Read Single Bit Write” function will be enabled.
3. The full column burst (256bit) is available only at Sequential mode of burst type.
4. If LC and LM both high (1), data of mask and color register will be unknown.
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BURST SEQUENCE (BURST LENGTH = 4)
Initial Address
Sequential
Interleave
A1
A0
0
0
0
1
2
3
0
1
2
3
0
1
1
2
3
0
1
0
3
2
1
0
2
3
0
1
2
3
0
1
1
1
3
0
1
2
3
2
1
0
BURST SEQUENCE (BURST LENGTH = 8)
Initial address
Sequential
Interleave
A2
A1
A0
0
0
0
0
1
2
3
4
5
6
7
0
1
2
3
4
5
6
7
0
0
1
1
2
3
4
5
6
7
0
1
0
3
2
5
4
7
6
0
1
0
2
3
4
5
6
7
0
1
2
3
0
1
6
7
4
5
0
1
1
3
4
5
6
7
0
1
2
3
2
1
0
7
6
5
4
1
0
0
4
5
6
7
0
1
2
3
4
5
6
7
0
1
2
3
1
0
1
5
6
7
0
1
2
3
4
5
4
7
6
1
0
3
2
1
1
0
6
7
0
1
2
3
4
5
6
7
4
5
2
3
0
1
1
1
1
7
0
1
2
3
4
5
6
7
6
5
4
3
2
1
0
PIXEL to DQ MAPPING (at BLOCK WRITE)
Column address
3 Byte
2 Byte
1 Byte
0 Byte
A2
A1
A0
I/O31~ I/O24
I/O23~ I/O16
I/O15~ I/O8
I/O7~ I/O0
0
0
0
DQ24
DQ16
DQ8
DQ0
0
0
1
DQ25
DQ17
DQ9
DQ1
0
1
0
DQ26
DQ18
DQ10
DQ2
0
1
1
DQ27
DQ19
DQ11
DQ3
1
0
0
DQ28
DQ20
DQ12
DQ4
1
0
1
DQ29
DQ21
DQ13
DQ5
1
1
0
DQ30
DQ22
DQ14
DQ6
1
1
1
DQ31
DQ23
DQ15
DQ7
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DEVICE OPERATIONS
CLOCK (CLK)
ADDRESS INPUTS (A0~A9)
The clock input is used as the reference for all
SGRAM
operations.
All
operations
are
synchronized to the positive going edge of the
clock. The clock transitions must be monotonic
between VIL and VIH. During operation with CKE
high all inputs are assumed to be in valid state (low
or high) for the duration of setup and hold time
around positive edge of the clock for proper
functionality and Icc specifications.
The 18 address bits are required to decode the
262,144 word locations are multiplexed into 10
address input pins (A0~A9). The 10 bit row
address is latched along with RAS and A10
during bank activate command. The 8 bit
column address is latched along with CAS,
WE and A10 during read or write command.
NOP and DEVICE DESELECT
CLOCK ENABLE(CKE)
The clock enable (CKE) gates the clock onto
SGRAM. If CKE goes low synchronously with
clock (set-up and hold time same as other inputs),
the internal clock suspended from the next clock
cycle and the state of output and burst address is
frozen as long as the CKE remains low. All other
inputs are ignored from the next clock cycle after
CKE goes low. When both banks are in the idle
state and CKE goes low synchronously with clock,
the SGRAM enters the power down mode from the
next clock cycle. The SGRAM remains in the
power down mode ignoring the other inputs as long
as CKE remains low. The power down exit is
synchronous as the internal clock is suspended.
When CKE goes high at least “tSS+1CLOCK”
before the high going edge of the clock, then the
SGRAM becomes active from the same clock edge
accepting all the input commands.
BANK SELECT (A10)
This SGRAM is organized as two independent
banks of 262, 144 words x 32 bits memory arrays.
The A10 inputs are latched at the time of assertion
of RAS and CAS to select the bank to be used
for the operation. When A10 is asserted low, bank
A is selected. When A10 is latched high, bank B is
selected. The banks select A10 is latched at bank
activate, read, write, mode register set and
precharge operations.
Elite Semiconductor Memory Technology Inc.
When RAS , CAS and WE are high, The
SGRAM performs no operation (NOP). NOP
does not initiate any new operation, but is
needed to complete operations which require
more than single clock cycle like bank activate,
burst read, auto refresh, etc. The device deselect
is also a NOP and is entered by asserting CS
high. CS high disables the command decoder
so that RAS , CAS, WE , DSF and all the
address inputs are ignored.
POWER-UP
The following sequence is recommended for
POWER UP
1.Power must be applied to either CKE and
DQM inputs to pull them high and other pins
are NOP condition at the inputs before or
along with VDD (and VDDQ) supply.
The clock signal must also be asserted at the
same time.
2.After VDD reaches the desired voltage, a
minimum pause of 200 microseconds is
required with inputs in NOP condition.
3.Both banks must be precharged now.
4.Perform a minimum of 2 Auto refresh cycles
to stabilize the internal circuitry.
5.Perform a MODE REGISTER SET cycle to
program the CAS latency, burst length and
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DEVICE OPERATIONS (Continued)
burst type as the default value of mode register is
undefined.
At the end of one clock cycle from the mode
register set cycle, the device is ready for operation.
When the above sequence is used for Power-up, all
the outputs will be in high impedance state. The
high impedance of outputs is not guaranteed in any
other power-up sequence.
cf.) Sequence of 4 & 5 may be changed.
MODE REGISTER SET (MRS)
The mode register stores the data for controlling the
various operating modes of SGRAM. It programs
the CAS latency, burst type, addressing, burst
length, test mode and various vendor specific
options to make SGRAM useful for variety of
different applications. The default value of the
mode register is not defined, therefore the mode
register must be written after power up to operate
the SGRAM. The mode register is written by
asserting low on CS , RAS , CAS, WE and
DSF (The SGRAM should be in active mode with
CKE already high prior to writing the mode
register). The state of address pins A0~A9 and A10
in the same cycle as CS , RAS , CAS, WE and
DSF going low is the data written in the mode
register. One clock cycles is required to complete
the write in the mode register. The mode register
contents can be changed using the same command
and clock cycle requirements during operation as
long as both banks are in the idle state. The mode
register is divided into various fields depending
on functionality. The burst length field uses
A0~A2, burst type uses A3, CAS latency (read
latency from column address) A4~A6, A7~A8 and
A10 are uses for vendor specific options or test
mode use. And the write burst length is
programmed using A9. A7~A8 and A10 must be
set to low for normal SGRAM operation. Refer to
the table for specific codes for various burst length,
addressing modes and CAS latencies.
BANK ACTIVATE
The bank activate command is used to select a
random row in an idle bank. By asserting low
on RAS and CS with desired row and bank
addresses, a row access is initiated. The read or
write operation can occur after a time delay of
tRCD (min) from the time of bank activation. tRCD
(min) is the internal timing parameter of SGRAM,
therefore it is dependent on operating clock
frequency. The minimum number of clock
cycles required between bank activate and read
or write command should be calculated by
dividing tRCD (min) with cycle time of the clock
and then rounding of the result to the next
higher integer. The SGRAM has two internal
banks in the same chip and shares part of the
internal circuitry to reduce chip area, therefore
it restricts the activation of both banks
immediately. Also the noise generated during
sensing of each bank of SGRAM is high
requiring some time for power supplies to
recover before another bank can be sensed
reliably. tRRD (min) specifies the minimum time
required between activating different bank. The
number of clock cycles required between
different bank activation must be calculated
similar to tRCD specification. The minimum time
required for the bank to be active to initiate
sensing and restoring the complete row of
dynamic cells is determined by tRAS (min). Every
SGRAM bank activate command must satisfy
tRAS (min) specification before a precharge
command to that active bank can be asserted.
The maximum time any bank can be in the
active state is determined by tRAS (max). The
number of cycles for both tRAS(min) and tRAS
(max) can be calculated similar to tRCD
specification.
BURST READ
The burst read command is used to access burst
of data on consecutive clock cycles from an
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DEVICE OPERATIONS (Continued)
active row in an active bank. The burst read
command is issued by asserting low on CS and
CAS with WE being high on the positive edge of
the clock. The bank must be active for at least tRCD
(min) before the burst read command is issued. The
first output appears in CAS latency number of
clock cycles after the issue of burst read command.
The burst length, burst sequence and latency from
the burst read command is determined by the mode
register which is already programmed. The burst
read can be initiated on any column address of the
active row. The address wraps around if the initial
address does not start from a boundary such that
number of outputs from each I/O are equal to the
burst length programmed in the mode register. The
output goes into high-impedance at the end of burst,
unless a new burst read was initiated to keep the
data output gapless. The burst read can be
terminated by issuing another burst read or burst
write in the same bank or the other active bank or a
precharge command to the same bank. The burst
stop command is valid for all burst length.
BURST WRITE
The burst write command is similar to burst read
command, and is used to write data into the
SGRAM on consecutive clock cycles in adjacent
addresses depending on burst length and burst
sequence. By asserting low on CS , CAS and
WE with valid column address, a write burst is
initiated. The data inputs are provided for the initial
address in the same clock cycle as the burst write
command. The input buffer is deselected at the end
of the burst length, even though the internal writing
may not have been completed yet. The writing can
not complete to burst length. The burst write can be
terminated by issuing a burst read and DQM for
blocking data inputs or burst write in the same or
the other active bank.
Elite Semiconductor Memory Technology Inc.
The write burst can also be terminated by using
DQM for blocking data and precharging the
bank “tRDL” after the last data input to be written
into the active row. See DQM OPERATION
also.
DQM OPERATION
The DQM is used mask input and output
operations. It works similar to OE during
operation and inhibits writing during write
operation. The read latency is two cycles from
DQM and zero cycle for write, which means
DQM masking occurs two cycles later in read
cycle and occurs in the same cycle during write
cycle. DQM operation is synchronous with the
clock. The DQM signal is important during
burst interrupts of write with read or precharge
in the SGRAM. Due to asynchronous nature of
the internal write, the DQM operation is critical
to avoid unwanted or incomplete writes when
the complete burst write is required. DQM is
also used for device selection and bus control in
a memory system. DQM0 controls DQ0 to
DQ7, DQM1 controls DQ8 to DQ15, DQM2
controls DQ16 to DQ23, DQM3 controls DQ24
to DQ31. DQM masks the DQ’s by a byte
regardless that the corresponding DQ’s are in a
state of WPB masking or Pixel masking. Please
refer to DQM timing diagram also.
PRECHARGE
The precharge is performed on an active bank
by asserting low on CS , RAS , WE and A9
with valid A10 of the bank to be precharged.
The precharge command can be asserted
anytime after tRAS (min) is satisfy from the bank
activate command in the desired bank. “tRP” is
defined as the minimum time required to
precharge a bank.
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DEVICE OPERATIONS (Continued)
The minimum number of clock cycles required to
complete row precharge is calculated by dividing
“tRP” with clock cycle time and rounding up to the
next higher integer. Care should be taken to make
sure that burst write is completed or DQM is used
to inhibit writing before precharge command is
asserted. The maximum time any bank can be
active is specified by tRAS (max). Therefore, each
bank has to be precharged within tRAS (max) from
the bank activate command. At the end of
precharge, the bank enters the idle state and is ready
to be activated again.
Entry to Power Down, Auto refresh, Self refresh
and Mode register Set etc. is possible only when
both banks are in idle state.
AUTO PRECHARGE
The precharge operation can also be performed by
using auto precharge. The SGRAM internally
generates the timing to satisfy tRAS (min) and “tRP” for
the programmed burst length and CAS latency.
The auto precharge command is issued at the same
time as burst read or burst write by asserting high
on A9. If burst read or burst write command is
issued with low on A9, the bank is left active until a
new command is asserted. Once auto precharge
command is given, no new command are possible
to that particular bank until the bank achieves idle
state.
BOTH BANKS PRECHARGE
Both banks can be precharged at the same time by
using Precharge all command. Asserting low on
CS , RAS and WE with high on A9 after all
banks have satisfied tRAS (min) requirement, performs
precharge on both banks. At the end of tRP after
performing precharge all, all banks are in idle state.
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AUTO REFRESH
The storage cells of SGRAM need to be
refreshed every 32ms to maintain data. An auto
refresh cycle accomplishes refresh of a single
row of storage cells. The internal counter
increments automatically on every auto refresh
cycle to refresh all the rows. An auto refresh
command is issued by asserting low on CS ,
RAS and CAS with high on CKE and WE .
The auto refresh command can only be asserted
with both banks being in idle state and the
device is not in power down mode (CKE is high
in the previous cycle). The time required to
complete the auto refresh operation is specified
by tRC (min). The minimum number of clock
cycles required can be calculated by driving tRC
with clock cycle time and them rounding up to
the next higher integer. The auto refresh
command must be followed by NOP’s until the
auto refresh operation is completed. Both banks
will be in the idle state at the end of auto refresh
operation. The auto refresh is the preferred
refresh mode when the SGRAM is being used
for normal data transactions. The auto refresh
cycle can be performed once in 15.6us or the
burst of 2048 auto refresh cycles in 32ms.
SELF REFRESH
The self refresh is another refresh mode
available in the SGRAM. The self refresh is the
preferred refresh mode for data retention and
low power operation of SGRAM. In self refresh
mode, the SGRAM disables the internal clock
and all the input buffers except CKE. The
refresh addressing and timing is internally
generated to reduce power consumption.
The self refresh mode is entered from all banks
idle state by asserting low on CS , RAS ,
CAS and CKE with high on WE . Once the
self refresh mode is entered, only CKE state
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DEVICE OPERATIONS (Continued)
being low matters, all the other inputs including
clock are ignored to remain in the refresh.
The self refresh is exited by restarting the external
clock and then asserting high on CKE. This must be
followed by NOP’s for a minimum time of tRC
before the SGRAM reaches idle state to begin
normal operation. If the system uses burst auto
refresh during normal operation, it is recommended
to use burst 2048 auto refresh cycles immediately
after exiting self refresh.
DEFINE SPECIAL FUNCTION(DSF)
The DSF controls the graphic applications of
SGRAM. If DSF is tied to low, SGRAM functions
as 256K x 32 x 2 Bank SDRAM. SGRAM can be
used as an unified memory by the appropriate DSF
command. All the graphic function mode can be
entered only by setting DSF high when issuing
commands which otherwise would be normal
SDRAM commands.
SDRAM functions such as RAS Active, Write and
WCBR change to SGRAM functions such as RAS
Active with WPB, Block Write and SWCBR
respectively, see the sessions below for the graphic
functions that DSF controls.
the condition that DQ’s are idle. As in write
operation, SMRS accepts the data needed
through DQ pins. Therefore it should be
attended not to induce bus contention. The more
detailed materials can be obtained by referring
corresponding timing diagram.
WRITE PER BIT
Write per bit(i.e. I/O mask mode) for SGRAM
is a function that selectively masks bits of data
being written to the devices. The mask is stored
in an internal register and applied to each bit of
data written when enable. Bank active command
with DSF=High enable write per bit for the
associated bank. The mask used for write per bit
operations is stored in the mask register
accessed by SWCBR (Special Mode Register
Set Command). When a mask bit=0, the
associated data bit is unaltered when a write
command is executed and the write per bit has
been enable for the bank being written. No
additional timing conditions. Write per bit
writes can be either masking is the same for
write per bit and non-WPB write.
BLOCK WRITE
SPECIAL MODE REGISTER SET(SMRS)
There are two kinds of special mode registers in
SGRAM. One is color register and the other is
mask register. Those usage will be explained at
“WRITE PER BIT” and “BLOCK WRITE”
session. When A5 and DSF goes high in the same
cycle as CS , RAS , CAS and WE going low,
load color register is filled with color data for
associated DQ’s through the DQ pins. If both A5
and A6 are high at SMRS, data of mask and color
cycle is required to complete the write in the mask
register and the color register at LMR and LCR
respectively. The next color of LMR and LCR, a
new commands can be issued. SMRS, compared
with MRS, can be issued at the active state under
Elite Semiconductor Memory Technology Inc.
Block write is a feature allowing the
simultaneous writing of consecutive 8 columns
of data within a RAM device during a single
access cycle. During block write the data to be
written comes from the internal “color” register
and DQ I/O pins are used for independent
column selection. The block of column to be
written is aligned on 8 column boundaries and is
defined by the column address with the 3 LSB’s
ignored. Write command with DSF=1 enable
block write for the associated bank. The block
width is 8 column where column =”n” bits for
by “n” part. The color register is the same width
as the data port of the chip. It is width via a
SWCBR where data present on the DQ pins is
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DEVICE OPERATIONS (Continued)
Timing Diagram to Illustrate tBWC
to be coupled into the internal color register. The
color register provides the data masked by the DQ
column select, WPB mask (if enable), and DQM
byte mask. Column data masking (Pixel masking) is
provided on an individual column basis for each
byte of data. The column mask is driven on the DQ
pins during a block write command. The DQ
column mask function is segmented on a per bit
basis (i.e. DQ [0:7] provided the column mask for
data bits [0:7], DQ [8:15] provided the column mask
for data bits [8:15], DQ0 masks column [0] for data
bits[0:7], DQ9 masks column [1] for data bits[8:15],
etc). Block writes are always non-burst independent
of the burst length that has been programmed into to
the mode register. If write per bit was enabled by the
bank active command with DSF=1, then write per
bit masking of the color register data is enabled.
If write per bit was disabled by a bank active
command with DSF=0, the write per bit masking of
the color register data is disabled. DQM masking
provides independent data byte masking during
normal write operations, except that the control is
extended to the consecutive 8 columns of the block
write.
Elite Semiconductor Memory Technology Inc.
1. 2CLK Cycle Block Write
CLOCK
CKE
HI G H
CS
RAS
CAS
WE
DSF
2 CLK BW
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SUMMARY OF 2M Byte SGRAM BASIC FEATURES AND BENEFITS
Features
256K x 32 x 2 SGRAM
Interface
Synchronous
Bank
Total Page Depth
Better interaction between memory and system without wait-state
of asynchronous DRAM.
High speed vertical and horizontal drawing.
High operation frequency allows performance gain for SCROLL,
FILL, and BitBLT.
Pseudo-infinite row length by on-chip interleaving operation.
Hidden row activation precharge.
2ea
Page Depth /1 Row
Benefits
256 bit
High speed vertical and horizontal drawing.
2048 bytes
High speed vertical and horizontal drawing.
Burst length (Read)
1, 2, 4, 8 Full Page
Programmable burst of 1, 2, 4, 8 and full page transfer per column
address.
Burst length (Write)
1, 2, 4, 8 Full Page
Programmable burst of 1, 2, 4, 8 and full page transfer per column
address.
BRSW
Burst Type
Sequential & Interleave
CAS Latency
2, 3
Block Write
8 Column
Switch to burst length of 1 at write without MRS.
Compatible with Intel and Motorola CPU based system.
Programmable CAS latency.
High speed FILL, CLEAR, Text with color registers.
Maximum 32 byte data transfer (e.g. for 8bpp : 32 pixels) with
plane and byte masking functions.
Color Register
1ea.
A and B bank share.
Mask Register
1 ea.
Write-per-bit capability (bit plane masking). A and B bank share.
DQM0~3
Mask function
Write per bit
Pixel Mask at Block Write
Byte masking (pixel masking for 8bpp system) for data-out/in
Each bit of the mask register directly controls a corresponding bit
plane.
Byte masking (pixel masking for 8bpp system) for color DQi.
BASIC FEATURE AND FUNCTION DESCRIPTION
1.CLOCK Suspend
1) C lock S uspended During W rite (BL=4)
2) Clock S uspe nded During Read (B L=4)
C LK
CMD
WR
RD
CKE
Masked by CKE
Masked by CKE
Internal
CLK
DQ( CL2)
D0
D1
D2
D3
DQ( CL 3)
D0
D1
D2
D3
N ot W r i tt en
Q0
Q1
Q2
Q3
Q0
Q1
Q2
Q3
S us p end ed D ou t
*Note : CKE to CLK disable/enable=1 clock
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2. DQM Operation
1 )Writ e M ask
2)Rea d Mask (B L=4 )
(BL=4)
CLK
CMD
WR
RD
DQM
Masked by DQM
Maske d by D QM
DQ(CL2)
D0
D1
D3
DQ( C L3 )
D0
D1
D3
Q0
Hi-Z
Hi-Z
Q2
Q3
Q1
Q2
Q3
DQM t o Da ta- o ut Ma sk= 2
DQM t o Dat a-in Ma sk=0 CLK
3 ) DQM w i th cl co k suspe n de d ( Ful l Pa g e Rea d)
Note2
CLK
CMD
RD
CKE
DQM
DQ( C L2 )
Q0
Hi-Z
Hi- Z
DQ(CL3)
Q2
Q1
Hi- Z
Hi-Z
Q4
Q3
Hi-Z
Hi-Z
Q6
Q7
Q8
Q5
Q6
Q7
*Note : 1. There are 4 DQMi (i = 0~3).
Each DQMi masks 8 DQ’s. (1 Byte, 1 Pixel for 8bpp).
2. DQM masks data out Hi-Z after 2 clocks which should masked by CKE “L”.
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3. CAS Interrupt (I)
*Note1
1)Rea d inte r rup ted by Read (B L=4)
CLK
CMD
RD
RD
AD D
A
B
QA0
DQ ( C L2 )
DQ( CL3)
QB0
QB1 QB2
QB3
QA0
QB0
QB2
QB1
QB3
tCC D
* N ot e 2
2) Wr i te in t er r upte d by( B lo ck ) W r it e ( BL= 2)
3)W r it e i n te r r upted by Re ad ( B L=2 )
CLK
CM D
WR
tCCD
AD D
WR
WR
A
BW
tCCD
* Note 2
A
B
WR
RD
tC CD
* Note 2
A
B
*No te 2
B
* N ot e 4
DQ
DA0
DB0
DB1
DC 0 Pixel
tC DL
tCDL
*N ote 3
*N ote 3
DQ(CL2)
DA0
DQ( CL 3)
DA0
DB0
D B1
D B0
D B1
tCDL
*Note 3
4) Bl ock Wr i te to B lock Wr it e
CLK
CM D
BW
NOP
BW
Note 7
AD D
A
X
B
Note 4
DQ
Pi xe l
Pixel
tBWC
*N ote 6
*Note : 1. By “Interrupt”, It is possible to stop burst read/write by external before the end of burst.
By “ CAS Interrupt”, to stop burst read/write by CAS access ; read, write and block write.
2.tCCD : CAS to CAS delay.(=1CLK)
3.tCDL : Last Data in to new column address delay.(=1CLK)
4.Pixel : Pixel mask.
5.tCC : Clock cycle time.
6.tBWC : Block write minimum cycle time.
7.Other Bank can be active or precharge.
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4. CAS Interrupt ( ) : Read Interrupted by Write & DQM
(1) CL=2, BL=4
CLK
i)CMD
RD
WR
DQ M
DQ
D0
RD
ii)CMD
D1
D2
D3
D1
D2
D3
D1
D2
D3
D1
D2
WR
DQ M
Hi- Z
DQ
iii)CMD
D0
RD
WR
D QM
Hi-Z
DQ
iv)CMD
D0
WR
RD
D QM
Q0
DQ
Hi- Z
D0
D3
*No te1
(2) CL=3 , BL=4
C LK
i)CMD
RD
WR
D QM
DQ
ii)CMD
D0
RD
D1
D2
D3
D1
D2
D3
D1
D2
D3
D1
D2
D3
D1
D2
WR
D QM
D0
DQ
iii)CMD
RD
WR
D QM
D0
DQ
RD
i v) C M D
WR
D QM
Hi-Z
DQ
D0
RD
v) C M D
WR
DQM
Hi- Z
DQ
Q0
D0
D3
* No t e 2
*Note : 1. To prevent bus contention, there should be at least one gap between data in and data out.
2. To prevent bus contention, DQM should be issued which makes at least one gap between data in and data out.
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5. Write Interrupted by Precharge & DQM
CLK
*Note2
CMD
PRE
WR
*Note 1
DQM
DQ
D0
D1
D2
D3
Maske d by DQM
*Note : 1. To inhibit invalid write, DQM should be issued.
2. This precharge command and burst write command should be of the same bank, otherwise it is not precharge interrupt
but only another bank precharge of dual banks operation.
6. Precharge
1) Normal Write (BL = 4)
2) Block Write
CLK
CLK
CMD
WR
DQ
D0
CMD
PRE
D1
D2
P i xel
DQ
D3
PRE
BW
tBPL
tRDL
*Note 1
*Note1
3) Read (BL=4)
CLK
CMD
PRE
RD
*No te 2
1
DQ(CL2)
Q0
DQ(C L3 )
Q1
Q0
Q2
Q3
Q1
Q2
Q3
2
7. Auto Precharge
1) Normal Write (BL = 4)
2) Block Write
C LK
CLK
CMD
DQ
C MD
WR
D0
D1
D2
DQ
D3
BW
P i xe l
tBPL
*Note3
Auto Precharge starts
tRP
tBAL
*Note3
Auto Precharge starts
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3) Read (BL=4)
CLK
CMD
RD
DQ ( C L 2 )
Q0
DQ(CL3 )
Q1
Q2
Q3
Q0
Q1
Q2
Q3
*Note3
Auto Precha rge sta rts
*Note : 1. tRDL : Write data-in to PRE command delay, tBPL : Block Write data-in to PRE command delay.
2. Number of valid output data after row precharge : 1, 2 for CAS Latency = 2, 3 respectively.
3. The row active command of the precharge bank can be issued after tRP from this point.
The new read/write command of other activated bank can be issued from this point.
At burst read/write with auto precharge, CAS interrupt of the same bank is illegal.
4. For -5S/-6S/-7S/-8S, auto precharge after a normal write starts at clock(n+BL+1).
8. Burst Stop & Precharge Interrupted
1) Write interrupted by Precharge (BL=4)
2) Write Burst Stop (Full Page Only)
CLK
CMD
CLK
PRE
WR
CMD
WR
DQ
D0
STOP
DQM
DQ
D0
D2
D1
D3
tRDL
D2
tB DL
3) Read interrupted by Precharge (BL=4)
4) Read Burst Stop (Full Page Only)
CLK
CMD
D1
*Note 1
CLK
RD
CMD
PRE
RD
STOP
*Note 3
Q0
DQ(CL2)
1
Q1
Q1
Q0
DQ( C L3 )
*Note 3
DQ(CL2)
2
Q0
Q1
DQ(CL3)
Q0
1
Q1
2
9. MRS & SMRS
1) Mode Register Set
2) Special Mode Register Set
CLK
CLK
*Note4
CMD
PRE
MRS
tRP
ACT
1CLK
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CMD
SMRS ACT SMR SSMR S ACT
1CLK
1 CLK
1CLK
1CLK
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*Note: 1. tRDL : 1 CLK ; Last data in to Row Precharge.
2. tBDL : 1 CLK ; Last data in to Burst Stop Delay.
3. Number of valid output data after Row Precharge or burst stop : 1, 2 for CAS latency = 2, 3 respectively.
4. PRE : Both banks precharge, if necessary.
MRS can be issued only at all banks precharge state.
10. Clock Suspend Exit & Power Down Exit
1) Clock Supend (=Active Power Down) Exit
2) Power Down (=Precharge Power Down) Exit
CLK
CLK
CKE
Internal
tS S
CKE
tSS
Inter nal
CLK
*No te 1
C LK
RD
C MD
*No te 2
CMD
NOP
AC T
11. Auto Refresh & Self Refresh
*Note3
1) Auto Refresh
CLK
*N o te 4
CMD
* No te 5
AR
PRE
CMD
CKE
tRP
tRC
1) Self Refresh *Note6
CLK
* No te 4
CMD
PRE
CMD
SR
CKE
tRP
tRC
*Note : 1. Active power down : one or more banks active state.
2. Precharge power down : both banks precharge state.
3. The auto refresh is the same as CBR refresh of conventional DRAM.
No precharge commands are required after Auto Refresh command.
During tRC from auto refresh command, any other command can not be accepted.
4. Before executing auto/self refresh command, both banks must be idle state.
5. (S)MRS, Bank Active, Auto/Self Refresh, Power Down Mode Entry.
6. During self refresh mode, refresh interval and refresh operation are performed internally.
After self refresh entry, self refresh mode is kept while CKE is low.
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During self refresh mode, all inputs expect CKE will be don’t cared, and outputs will be in Hi-Z state.
During tRC from self refresh exit command, any other command can not be accepted.
Before/After self refresh mode, burst auto refresh (2K cycles) is recommended.
12. About Burst Type Control
Basic
Mode
Sequential Counting At MRS A3=”0”. See the BURST SEQUENCE TABLE. (BL=4, 8)
BL=1, 2, 4, 8 and full page wrap around.
Interleave Counting
PseudoMODE
Random
MODE
At MRS A3=”1”. See the BURST SEQUENCE TABLE. (BL=4, 8)
BL=4, 8. At BL=1, 2 Interleave Counting = Sequential Counting
At MRS A3=”1”. (See to interleave Counting Mode)
Staring Address LSB 3 bits A 0-2 should be “000” or “111”. @BL=8
- if LSB =”000” : Increment Counting.
Pseudo- if LSB =”111” : Decrement Counting.
Document Sequential For Example, (Assume Addresses except LSB 3 bits are all 0, BL=8)
Counting
-- @ write, LSB =”000”, Accessed Column in order 0-1-2-3-4-5-6-7
-- @ read, LSB =”111”, Accessed Column in order 7-6-5-4-3-2-1-0
At BL=4, same applications are possible. As above example, at interleave Counting
mode, by confining starting address to some value, Pseudo-Decrement Counting
Mode can be realize. See the BURST SEQUENCE TABLE carefully.
PseudoBinary Counting
At MRS A3=”0”. (See to Sequential Counting Mode)
A0-2 =”111”. (See to Full Page Mode)
Using Full Page Mode and Burst Stop Command, Binary Counting Mode can be
realize.
-- @ Sequential Counting, Accessed Column in order 3-4-5-6-7-1-2-3 (BL=8)
-- @ Pseudo-Binary Counting
Accessed Column in order 3-4-5-6-7-8-9-10 (Burst Stop command)
Note. The next column address of 256 is 0.
Random column
Access
tCCD = 1 CLK
Every cycle Read/Write Command with random column address can realize
Random Column Access
That is similar to Extended Data Out (EDO) Operation of conventional DRAM.
13. About Burst Length Control
Basic
MODE
1
At MRS A2, 1, 0 =”000”.
At auto precharge, tRAS should not be violated.
2
At MRS A2, 1, 0 =”001”.
At auto precharge, tRAS should not be violated.
4
At MRS A2, 1, 0 =”010”.
8
At MRS A2, 1, 0 =”011”.
Full Page
At MRS A2, 1, 0 =”111”.
Wrap around mode (Infinite burst length) should be stopped by burst stop.
RAS interrupt or CAS interrupt.
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At MRS A9 =”1”
Read Burst =1, 2, 4, 8, full page/write Burst =1
At auto precharge of write, tRAS should not be violated.
BRSW
Special
MODE
8 Column Block Write. LSB A0-2 are ignored. Burst length =1
Block Write
Random
MODE
Burst Stop
Interrupt
MODE
tRAS should not be violated.
At auto precharge, tRAS should not be violated.
tBDL =1, Valid DQ after burst stop is 1, 2 for CL=2, 3 respectively.
Using burst stop command, random mode it is possible only at full page burst
length.
RAS interrupt
(Interrupted by
Precharge)
Before the end of burst, Row precharge command of the same bank stops read/write
burst with Row precharge.
tRDL =1 with DQM, valid DQ after burst stop is 1, 2 for CL = 2, 3 respectively
During read/write burst with auto precharge, RAS interrupt can not be issued.
CAS Interrupt
Before the end of burst, new read/write stops read/write burst and starts new
read/write burst or block write.
During read/write burst with auto precharge, CAS interrupt can not be issued.
14. Mask Function
1) Normal Write
I/O masking : By Mask at Write Per Bit Mode, the selected bit planes keep the original data.
If bit plane 0, 3, 7, 9, 19, 22, 24 and 31 keep the original value.
i) STEP
I SMRS(LMR) : Load mask [31-0]=”0111, 1110, 1011, 0111, 1111, 1101, 0111, 0110”
II Row Active with DSF “H” : Write Per Bit Mode Enable
III Perform Normal Write
i) ILLUSTRATION
I/O (=DQ)
External Data-in
DQMi
Mask Register
Before Write
After Write
31
24
11111111
DQM3=0
01111110
00000000
01111110
23
16
11111111
DQM2=0
10110111
00000000
10110111
15
8
00000000
DQM1=0
11111101
11111111
00000010
7
0
00000000
DQM0=1
01110110
11111111
11111111
Note 1
2) Block Write
Pixel masking : By Pixel Data issued through DQ pin, the selected pixels keep the original data.
See PIXEL TO DQ MAPPING TABLE.
If Pixel 0, 4, 9, 13, 18, 22, 27 and 31 keep the original white color.
Assume 8bpp
White = “0000, 0000”, Red = “1010, 0011”, Green = “1110, 0001”, Yellow = “0000, 1111”, Blue = “1100, 0011”
i) STEP
I SMRS(LCR) : Load color (for 8bpp, through x32 DQ color0-3 are loaded into color registers)
Load (color3, color2, color1, color0) = (Blue, Green, Yellow, Red)
= ”1100, 0011, 1110, 0001, 0000, 1111, 1010, 0011 ”
II Row Active with DSF “L” : I/O Mask by Write Per Bit Mode Disable
III Block write with DQ[31-0] = “0111, 0111, 1011, 1011, 1101, 1101, 1110, 1110”
* Note : 1. DQM byte masking.
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(Continued)
i) ILLUSTRATION
I/O (=DQ)
31
24
23
16
15
8
7
0
DQMi
DQM3=0
DQM2=0
DQM1=0
DQM0=1
Color Register
Color3=Blue
Color2=Green
Color1=Yellow
Color0=Red
000
White DQ24=H
White DQ16=H
White DQ8=H
White DQ0=L
001
White DQ25=H
White DQ17=H
White DQ9=L
White DQ1=H
010
White DQ26=H
White DQ18=L
White DQ10=H
White DQ2=H
011
White DQ27=L
White DQ19=H
White DQ11=H
White DQ3=H
100
White DQ28=H
White DQ20=H
White DQ12=H
White DQ4=L
101
White DQ29=H
White DQ21=H
White DQ13=L
White DQ5=H
110
White DQ30=H
White DQ22=L
White DQ14=H
White DQ6=H
111
White DQ31=L
White DQ23=H
White DQ15=H
White DQ7=H
000
Blue
Green
Yellow
White
001
Blue
Green
White
White
010
Blue
White
Yellow
White
011
White
Green
Yellow
White
100
Blue
Green
Yellow
White
101
Blue
Green
White
White
110
Blue
White
Yellow
White
111
White
Green
Yellow
White
Before
Block
Write
&
DQ
(Pixel
data)
After
Block
Write
Note 1
Pixel and I/O masking : By Mask at Write Per Bit Mode, the selected bit planes keep the original data.
By Pixel Data issued through DQ pin, the selected pixels keep the original data.
See PIXEL TO DQ MAPPING TABLE.
Assume 8bpp,
White = “0000, 0000”, Red = “1010, 0011”, Green = “1110, 0001”, Yellow = “0000, 1111”, Blue = “1100, 0011”
i) STEP
I SMRS(LCR) : Load color (for 8bpp, through x 32 DQ color0-3 are loaded into color registers)
Load (color3, color2, color1, color0, ) = (Blue, Green, Yellow, Red)
=”1100, 0011, 1110, 0001, 0000, 1111, 1010, 0011”
II SMRS(LMR) Load mask. Mask[31-0] = ”1111.1111. 1101, 1101, 0100, 0010, 0111, 0110”
Byte 3 : No I/O Masking ; Byte 2 : I/O Masking ; Byte 1 : I/O and Pixel Masking ; Byte 0 : DQM Byte Masking
III Row Active with DSF “H” : I/O mask by Write Per Bit Mode Enable
IV Block Write with DQ [31-0] = ”0111, 0111 .1111, 1111, 0101, 0101, 1110, 1110 ”(Pixel Mask)
Æ
*Note : 1. At normal write, ONE column is selected among columns decorded by A2-0 (000-111).
At block write, instead of ignored address A2-0, DQ0-31 control each pixel.
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i) ILLUSTRATION
I/O (=DQ)
31
24
23
16
15
6
7
0
Color Register
Blue
11000011
Green
11100001
Yellow
00001111
Red
10100011
DQMi
DQM3=0
DQM2=0
DQM1=0
DQM0=1
Mask Register
11111111
11011101
01000010
01110110
Before Write
Yellow
00001111
Yellow
00001111
Green
11100001
White
00000000
After Write
Blue
11000011
Blue
11000011
Red
10100011
White
00000000
I/O (=DQ)
31
23
15
24
16
6
7
0
DQMi
DQM3=0
DQM2=0
DQM1=0
DQM0=1
Color Register
Color3=Blue
Color2=Green
Color1=Yellow
Color0=Red
000
Yellow DQ24=H
Yellow DQ16=H
Green DQ8=H
White DQ0=L
001
Yellow DQ25=H
Yellow DQ17=H
Green DQ9=L
White DQ1=H
010
Yellow DQ26=H
Yellow DQ18=H
Green DQ10=H
White DQ2=H
011
Yellow DQ27=L
Yellow DQ19=H
Green DQ11=L
White DQ3=H
100
Yellow DQ28=H
Yellow DQ20=H
Green DQ12=H
White DQ4=L
101
Yellow DQ29=H
Yellow DQ21=H
Green DQ13=L
White DQ5=H
110
Yellow DQ30=H
Yellow DQ22=H
Green DQ14=H
White DQ6=H
111
Yellow DQ31=L
Yellow DQ23=H
Green DQ15=L
White DQ7=H
000
Blue
Blue
Red
White
001
Blue
Blue
Green
White
010
Blue
Blue
Red
White
011
Yellow
Blue
Green
White
100
Blue
Blue
Red
White
101
Blue
Blue
Green
White
110
Blue
Blue
Red
White
111
Yellow
Blue
Green
White
Before
Block
Write
&
DQ
(Pixel
data)
After
Block
Write
Note 2
Note 1
PIXEL MASK
I/O MASK
PIXEL & I/O MASK
BYTE MASK
*Note : 1. DQM byte masking.
2. At normal write, ONE column is selected among columns decorded by A2-0(000-111)
At block write, instead of ignored address A2-0, DQ0-31 control each pixel.
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FUNCTION TRUTH TABLE (TABLE 1)
Current
State
IDLE
Row
Active
Read
Write
CS RAS CAS WE DSF
H
L
L
L
L
L
L
L
L
L
L
L
H
L
L
L
L
L
L
L
L
L
L
L
L
H
L
L
L
L
L
L
L
L
L
L
L
H
L
L
L
L
L
L
L
X
H
H
H
L
L
L
L
L
L
L
L
X
H
H
H
H
H
H
L
L
L
L
L
L
X
H
H
H
H
H
H
H
L
L
L
L
X
H
H
H
H
H
H
H
X
H
H
L
H
H
H
H
L
L
L
L
X
H
H
L
L
L
L
H
H
H
L
L
L
X
H
H
H
L
L
L
L
H
H
H
L
X
H
H
H
L
L
L
L
X
H
L
X
H
H
L
L
H
H
L
L
X
H
L
H
H
L
L
H
L
L
H
L
L
X
H
L
L
H
H
L
L
H
L
L
X
X
H
L
L
H
H
L
L
X
X
X
X
L
H
L
H
L
H
L
H
X
X
X
L
H
L
H
X
L
H
X
L
H
X
X
L
H
L
H
L
H
X
L
H
X
X
X
L
H
L
H
L
H
Elite Semiconductor Memory Technology Inc.
BA
ADDR
(A10)
X
X
X
X
X
X
BA
CA
BA
RA
BA
RA
X
PA
BA
X
X
X
BA
X
OP Code
OP Code
X
X
X
X
X
X
BA
CA, AP
X
X
BA
CA, AP
BA
CA, AP
BA
RA
BA
RA
X
X
X
X
X
X
OP Code
X
X
X
X
X
X
X
X
BA
CA, AP
X
X
BA
CA, AP
BA
CA, AP
BA
RA
BA
PA
X
X
X
X
X
X
X
X
X
X
X
X
BA
CA, AP
X
X
BA
CA, AP
BA
CA, AP
ACTION
NOP
NOP
ILLEGAL
ILLEGAL
Row Active ; Latch Row Address ; Non-IO Mask
Row Active ; Latch Row Address ; IO Mask
Auto Refresh or Self Refresh
NOP
Auto Refresh or Self Refresh
ILLEGAL
Mode Register Access
Special Mode Register Access
NOP
NOP
ILLEGAL
Begin Read ; Latch CA ; Determine AP
ILLEGAL
Begin Write ; Latch CA ; Determine AP
Begin Write ; Latch CA ; Determine AP
ILLEGAL
Precharge
ILLEGAL
ILLEGAL
ILLEGAL
Special Mode Register Access
NOP (Continue Burst to End
Row Active)
NOP (Continue Burst to End
Row Active)
Term burst Row active
ILLEGAL
Term burst, Begin Read ; Latch CA ; Determine AP
ILLEGAL
Æ
Æ
Æ
Term burst, Begin Write ; Latch CA ; Determine AP
Term burst, Begin Write ; Latch CA ; Determine AP
ILLEGAL
Term Burst, Precharge timing for Reads
ILLEGAL
ILLEGAL
NOP (Continue Burst to End
Row Active)
NOP (Continue Burst to End
Row Active)
Term burst
Row Active
ILLEGAL
Term burst, Begin Read ; Latch CA ; Determine AP
ILLEGAL
Æ
Note
2
2
4
5
5
6
2
2
6
3
3
3
2
3
Æ
Æ
Term burst, Begin Write ; Latch CA ; Determine AP
Term burst, Begin Write ; Latch CA ; Determine AP
3
3
3
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FUNCTION TRUTH TABLE (TABLE 1, Continued)
Current
State
CS RAS CAS WE DSF
L
L
H
H
X
L
L
H
L
L
L
L
H
H
H
L
L
L
X
X
H
X
X
X
X
L
H
H
H
X
Read with
L
H
H
L
X
Auto
L
H
L
H
X
Precharge
L
H
L
L
X
L
L
H
X
X
L
L
L
X
X
H
X
X
X
X
L
H
H
H
X
Write with
L
H
H
L
X
Auto
L
H
L
H
X
Precharge
L
H
L
L
X
L
L
H
X
X
L
L
L
X
X
H
X
X
X
X
L
H
H
H
X
L
H
H
L
X
Precharging L
H
L
X
X
L
L
H
H
X
L
L
H
L
X
L
L
L
X
X
H
X
X
X
X
L
H
H
H
X
Block
L
H
H
L
X
Write
L
H
L
X
X
Recovering L
L
H
H
X
L
L
H
L
X
L
L
L
X
X
H
X
X
X
X
L
H
H
H
X
Row
L
H
H
L
X
Activating
L
H
L
X
X
L
L
H
H
X
L
L
H
L
X
L
L
L
X
X
H
X
X
X
X
L
H
H
X
X
Refreshing L
H
L
X
X
L
L
H
X
X
L
L
L
X
X
ABBREVIATIONS :
RA = Row Address (A0~A9)
NOP = No Operation Command
Write
Elite Semiconductor Memory Technology Inc.
BA
(A10)
BA
BA
X
X
X
X
X
BA
BA
BA
X
X
X
X
BA
BA
BA
X
X
X
X
BA
BA
BA
X
X
X
X
BA
BA
BA
X
X
X
X
BA
BA
BA
X
X
X
X
X
X
ADDR
RA
RA
X
X
X
X
X
CA, AP
CA, AP
RA, PA
X
X
X
X
CA, AP
CA, AP
RA, PA
X
X
X
X
CA, AP
RA
PA
X
X
X
X
CA, AP
RA
PA
X
X
X
X
CA, AP
RA
PA
X
X
X
X
X
X
ACTION
Note
ILLEGAL
Term Burst : Precharge timing for Writes
ILLEGAL
ILLEGAL
NOP(Continue Burst to End Precharge)
NOP(Continue Burst to End Precharge)
ILLEGAL
ILLEGAL
ILLEGAL
ILLEGAL
ILLEGAL
NOP(Continue Burst to End Precharge)
NOP(Continue Burst to End Precharge)
ILLEGAL
ILLEGAL
ILLEGAL
ILLEGAL
ILLEGAL
NOP Idle after tRP
NOP Idle after tRP
ILLEGAL
ILLEGAL
ILLEGAL
NOP Idle after tRP
ILLEGAL
NOP Row Active after tBWC
NOP Row Active after tBWC
ILLEGAL
ILLEGAL
ILLEGAL
2
3
Æ
Æ
Æ
Æ
Æ
Æ
Æ
Æ
Æ
Term Block Write : Precharge timing for Block Write
ILLEGAL
NOP Row Active after tRCD
NOP Row Active after tRCD
ILLEGAL
ILLEGAL
ILLEGAL
ILLEGAL
ILLEGAL
NOP Idle after tRC
NOP Idle after tRC
ILLEGAL
ILLEGAL
ILLEGAL
Æ
Æ
Æ
Æ
BA = Bank Address (A10)
CA = Column Address (A0~A7)
2
2
2
2
2
2
2
2
2
4
2
2
2
2
2
2
2
2
PA = Precharge All (A9)
AP = Auto Precharge (A9)
Publication Date : Jun. 2001
Revision : 1.6
31/54
(607
M32L1632512A
FUNCTION TRUTH TABLE (TABLE 1, Continued)
*Note : 1. All entries assume the CKE was active (High) during the preceding clock cycle and the current clock cycle.
2. Illegal to bank in specified state ; Function may be legal in the bank indicated by BA, depending on the state of that
bank.
3. Must satisfy bus contention, bus turn around, and/or write recovery requirements.
4. NOP to bank precharging or in idle state. May precharge bank indicated by BA (and PA).
5. Illegal if any bank is not idle.
6. Legal only if all banks are in idle or row active state.
FUNCTION TRUTH TABLE for CKE (TABLE2)
Current
State
Self
Refresh
CKE
( n-1 )
H
L
L
CKE
n
X
H
H
CS RAS CAS WE DSF ADDR
X
H
L
X
X
H
L
H
L
H
L
H
L
H
L
H
L
L
L
L
X
X
H
X
X
X
Both
L
H
H
X
Bank
L
H
L
H
Precharge
L
H
L
H
Power
L
H
L
H
Down
L
H
L
L
L
L
X
X
H
H
X
X
H
L
H
X
H
L
L
H
All
H
L
L
H
Banks
H
L
L
H
Idle
H
L
L
L
H
L
L
L
H
L
L
L
L
L
X
X
Any State
H
H
X
X
other than
H
L
X
X
Listed
L
H
X
X
Above
L
L
X
X
ABBREVIATIONS : ABI = All Banks Idle
X
X
H
X
X
H
X
X
X
X
X
X
H
L
X
X
X
X
H
H
L
X
X
X
X
H
H
L
H
L
L
X
X
X
X
X
L
X
X
X
X
X
H
L
X
X
X
X
X
H
L
X
X
H
L
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
ACTION
INVALID
Exit Self Refresh ÂÃÊ after tRC
Exit Self Refresh ÂÃÊ after tRC
ILLEGAL
ILLEGAL
ILLEGAL
NOP (Maintain Self Refresh)
INVALID
Exit Power Down ABI
Exit Power Down ABI
ILLEGAL
ILLEGAL
ILLEGAL
NOP (Maintain Low Power Mode)
Refer to Table 1
Enter Power Down
Enter Power Down
ILLEGAL
ILLEGAL
ILLEGAL
Enter Self Refresh
ILLEGAL
NOP
Refer to Operations in Table 1
Begin Clock Suspend next cycle
Exit Clock Suspend next cycle
Maintain Clock Suspend
Note
Æ
Æ
7
7
Æ
Æ
8
8
9
9
9
10
10
*Note : 7.After CKE’s low to high transition to exit self refresh mode. And a time of tRC(min) has to be elapse after CKE’s low to
high transition to issue a new command.
8.CKE low to high transition is asynchronous as if restart internal clock.
A minimum setup time “ tSS + one clock “ must be satisfy before any command other than exit.
9.Power down and self refresh can be entered only from the all banks idle state.
10.Must be a legal command.
Elite Semiconductor Memory Technology Inc.
Publication Date : Jun. 2001
Revision : 1.6
32/54
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M32L1632512A
Power On Sequence & Auto Refresh
0
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
CLOC K
CKE
H i g h l e v el i s n e c es s a r y
CS
tRC
tRP
RAS
CAS
ADDR
KE Y
Ra
A10 /B A
KE Y
BS
A9 /A P
KEY
Ra
WE
DSF
DQ M
H i g h l e v el i s n e c e s s a r y
High- z
DQ
Precharge
(All Bank s)
A u to R ef r e s h
A u t o R e f r es h
Mode Register Set
Row Ac tive
( W r i t e P er B i t
Enable or D isable)
:D on't C ar e
Elite Semiconductor Memory Technology Inc.
Publication Date : Jun. 2001
Revision : 1.6
33/54
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M32L1632512A
Single Bit Read-Write-Read Cycle (Same Page) @CAS Latency = 3, Burst Length = 1
tCH
1
0
2
3
4
5
6
7
9
8
10
11
12
13
14
15
16
17
18
19
CLOCK
tCL
tC C
HIGH
CKE
t RAS
tRC
t SH
*Note 1
CS
tSS
tRCD
tRP
tSH
RAS
tS S
tCCD
tSH
CAS
tSS
tS S
tSH
ADDR
Ra
Ca
Cc
Cb
Rb
tSH
tSS
*Note 2
*No t e 2, 3
*Note2, 3
A1 0
BS
BS
BS
*Not e 3
*Note 3
A9
Ra
*No t e 2, 3 *Note 4
BS
*Not e 2
BS
BS
*Not e 3 *Not e 4
Rb
tSH
WE
tS S
*Not e 5
* No t e 5
*Note6
DSF
tSS
tSH
tSH
tS S
DQM
t RAC
tSH
tSAC
Qa
DQ
tSLZ
Db
Qc
tS S
tOH
t SHZ
Row Acti ve
Read
(W rite per Bit
Enable or Dis able)
W rite
or
Bloc k W r it e
Read
Precharge
Row Ac t ive
(W ri te Per B it
E n a b l e o r D i s a bl e )
:D on't C are
Elite Semiconductor Memory Technology Inc.
Publication Date : Jun. 2001
Revision : 1.6
34/54
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M32L1632512A
* Note : 1. All input can be don’t care when CS is high at the CLK high going edge.
2. Bank active & read/write are controlled by A10.
A10
0
1
Active & Read/Write
Bank A
Bank B
3. Enable and disable auto precharge function are controlled by A9 in read/write command.
A9
0
A10
0
Operation
Disable auto precharge, leave bank A active at end of burst.
1
1
0
Disable auto precharge, leave bank B active at end of burst.
Enable auto precharge, precharge bank A at end of burst.
1
Enable auto precharge, precharge bank B at end of burst.
4. A9 and A10 control bank precharge when precharge command is asserted.
A9
0
0
1
A10
0
1
X
Precharge
Bank A
Bank B
Both Bank
5. Enable and disable Write-per Bit function are controlled by DSF in Row Active command.
A10
0
DSF
L
Operation
Bank A row active, disable write per bit function for bank A.
1
H
L
Bank A row active, enable write per bit function for bank A.
Bank B row active, disable write per bit function for bank B.
H
Bank B row active, enable write per bit function for bank B.
6. Block write/normal write is controlled by DSF.
DSF
L
Operation
Normal write
H
Block write
Elite Semiconductor Memory Technology Inc.
Minimum cycle time
tCCD
tBWC
Publication Date : Jun. 2001
Revision : 1.6
35/54
(607
M32L1632512A
Read & Write Cycle at Same Bank @ Burst Length = 4
0
1
2
3
4
5
6
9
8
7
10
11
12
13
15
16
17
D b1
D b2
Db3
14
18
19
CLOCK
HIGH
CKE
*No te 1
tRC
CS
tRC D
RAS
*Not e2
CAS
Ra
ADDR
Rb
Ca0
Cb0
A1 0
A9
Ra
Rb
WE
DSF
DQM
tOH
DQ
CL=2
Qa0
Q a1
Qa2
Qa3
D b0
tR AC
*Not e 3
tSAC
tSHZ
tRDL
*Note 4
tO H
CL = 3
Q a0
Qa1
Qa2
Q a3
Db0
Db1
tRAC
*Note3
Row Act ive
(A-Bank)
R ea d
(A-Ban k)
Precharge
( A - B an k )
Row Ac tive
(A- Bank )
Db3
tRDL
t S H Z *N ot e 4
tS AC
Db2
W rite
(A-Bank)
Pre ch arg e
( A - B an k )
:Don't C are
*Note :
1. Minimum row cycle time is required to complete internal DRAM operation.
2. Row precharge can interrupt burst on any cycle.[CAS Length - 1] valid output data available after Row. enters
precharge. Last valid output will be
Hi-Z after t SHZ from the clock.
3. Access time from Row address. t CC *( t RCD +CAS latency - 1) +
4. Output will be Hi-Z after the end of burst. (1, 2, 4 & 8)
At Full page bit burst, burst is wrap-around.
Elite Semiconductor Memory Technology Inc.
tSAC
Publication Date : Jun. 2001
Revision : 1.6
36/54
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M32L1632512A
Page Read & Write Cycle Same Bank @ Burst Length = 4
0
1
2
3
4
5
6
7
9
8
10
11
12
13
15
14
16
17
18
19
CLOCK
HIGH
CKE
CS
tRCD
RAS
*Note 2
CAS
AD DR
Ra
Ca0
Cb0
Cc0
C d0
A1 0
A9
Ra
tRDL
t CDL
WE
*Note 2
DSF
*Note 3
*Note 1
DQM
DQ
C L= 2
Qa0
CL = 3
Row Ac ti ve
( A - B an k )
Rea d
(A-Bank )
Qa1
Q b0
Q b1
Dc0
Dc1
Dd0
Dd1
Qa0
Q a1
Qb0
Dc0
Dc1
D d0
Dd1
Rea d
(A-Bank )
W rit e
(A-Bank)
Write
( A - Ba n k )
Pre char ge
( A - B an k )
:Don't C are
* Note : 1.To write data before burst read ends, DQM should be asserted three cycle prior to write command to avoid bus
contention.
2. Row precharge will interrupt writing. Last data input, tRDL before Row precharge, will be written.
3. DQM should mask invalid input data on precharge command cycle when asserting precharge before end of burst.
Input data after Row precharge cycle will be masked internally.
Elite Semiconductor Memory Technology Inc.
Publication Date : Jun. 2001
Revision : 1.6
37/54
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M32L1632512A
Block Write cycle (with Auto Precharge)
0
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
CLOCK
HIGH
CK E
CS
RAS
CAS
*Note 4
ADDR
RAa
CA b
CAa
RBa
CBa
CB b
A10
A9
RAa
RBa
WE
DSF
*Note 2
tBWC
DQM
*Not e 3
*Note1
P ixel
Mask
P i xe l
Ma sk
DQ
Ro w Ac t i ve w i t h
W ri te-per- Bit
E n ab l e
( A- Ba n k )
Mas ked
Bl o c k W r i t e
( A - B an k )
Pixel
Mask
R ow Ac t i ve
( B- Ban k )
M asked
Bl ock W r i t e w i th
Au to Pr ech ar ge
( A- Ba n k)
P ixel
Mask
Block W rit e wit h
Auto P rechar ge
( B- Ba n k )
Block W r ite
( B- Ban k )
:Don't Care
*Note : 1. Column Mask (DQi = L : Mask, DQi = H : Non Mask)
2. tBWC : Block Write Cycle time
3. At Block Write, second cycle should be in NOP.
Other Bank can be active or precharge.
4. At Block Write. CA0-2 are ignored.
Elite Semiconductor Memory Technology Inc.
Publication Date : Jun. 2001
Revision : 1.6
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M32L1632512A
SMRS and Block/Normal Write @ Burst Length = 4
0
1
2
3
4
5
6
7
9
8
10
11
12
13
14
15
16
17
18
19
CLOCK
HIGH
CKE
CS
RAS
CAS
*N ot e1
RBa
CBa
CAa
RB a
CB a
RA a
CA a
RB a
CBa
A6
RA a
CAa
RB a
CBa
A9
RAa
A0-2
RAa
A3,4 ,7, 8
RAa
A5
RBa
A9
WE
DSF
DQ M
DQ
Color
I/O
Mask
Load Color
Regis ter
L oad M as k
Regist er
Ro w A ct i ve
wi th W PB*
E n ab l e
( A - B an k )
Pi xe l
Mask
I/O
Mask
Color
D Ba 0 DB a1 D Ba 2 DB a3
Ro w A c t i v e L oa d C o l o r
w i t h W PB * R e g i s t e r
En a bl e
Masked
Ma ske d W r i t e
( B - B an k )
Bl o c k W r i t e
wi t h Au t o
( A - B an k )
P r ec h ar g e
Load Mask Regi st er
( B- Ba n k )
W P B * : W r i t e- P e r - B i t
:D on' t Car e
*Note : 1. At the next clock of special mode register set command, new command is possible.
Elite Semiconductor Memory Technology Inc.
Publication Date : Jun. 2001
Revision : 1.6
39/54
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M32L1632512A
Page Read Cycle at Different Bank @ Burst Length = 4
1
0
2
3
4
5
6
7
9
8
10
11
12
13
14
15
16
17
18
19
CLOCK
HIGH
CKE
* No t e1 `
CS
RAS
*N ot e2 `
CAS
ADDR
RAa
CAa
RBb
CAc
CBb
CB d
CA e
A1 0
A9
RAa
RBb
WE
DSF
LO W
DQ M
DQ
Q A a 0 Q Aa 1 Q A a 2 Q Aa 3 Q B b 0 Q B b 1 Q Bb 2 Q B b 3 Q A c 0 Q A c 1 Q B d 0 Q B d 1 Q A e 0 Q A e 1
CL= 2
Q Aa 0 Q A a 1 Q A a 2 Q A a 3 Q B b 0 Q B b 1 Q B b 2 Q B b 3 Q A c 0 Q A c 1 Q B d 0 Q Bd 1 Q A e 0 Q A e 1
CL = 3
Row Act i ve
( A - B an k )
Ro w A cti ve
( B - B an k )
Read
( B - Ba n k )
Read
( A - Ba n k )
Read
( B - Ba n k )
Rea d
(A-Bank)
Pr e ch a r g e
( A- B an k )
Read
( A - Ba n k )
:D on' t Car e
*Note : 1. CS can be don’t care when RAS , CAS and WE are high at the clock high going edge.
2. To interrupt a burst read by row precharge, both the read and the precharge banks must be the same.
Elite Semiconductor Memory Technology Inc.
Publication Date : Jun. 2001
Revision : 1.6
40/54
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M32L1632512A
Page Write Cycle at Different Bank @ Burst Length =4
0
1
2
3
4
5
6
9
8
7
10
11
12
13
14
15
16
17
18
19
CLOCK
HIGH
CKE
CS
RAS
CAS
ADDR
RAa
Ke y
CA a
RB b
CBb
CAc
CBd
A1 0
A9
RAa
RB b
tCDL
WE
DSF
DQ M
DQ
Mask
Load M as k
Regis t er
Ro w Ac t i ve w i t h
Wr ite-Per- Bit
enable
(A- Ba n k)
DAa0 DAa1 DAa2 DAa3 DBb0 DBb1 DBb2 D Bb3 DAc 0 D Ac 1 DAc 2 DAc 3 DBd0 DBd1 DBd2 D Bd3
Row Ac t iv e
( B- Ban k )
Mas ked W ri t e
( A- Ba n k)
Elite Semiconductor Memory Technology Inc.
W ri t e
( B- Ba n k )
M as ked W r i t e
wi th aut o
pr echar ge
( A- Ban k )
W ri te w i th aut o
Pr ech arge
( B- Bank )
: Don't Car e
Publication Date : Jun. 2001
Revision : 1.6
41/54
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M32L1632512A
Read & Write Cycle at Different Bank @ Burst Length =4
0
1
2
3
4
5
6
7
9
8
10
11
12
13
CBb
RA c
14
15
16
17
18
19
CLOCK
HIG H
CKE
CS
RAS
CAS
ADDR
RAa
CAa
RBb
CAc
A1 0
A9
RAa
RBb
RAc
t CD L
*Not e 1
WE
DSF
DQ M
DQ CL=2
Q Aa 0 Q Aa 1 Q A a2 QA a 3
Q Aa 0 Q Aa 1 Q Aa 2 Q A a3
CL=3
Row Ac t ive
(A-Bank )
Precharge
( A - B an k )
R ea d
(A-Bank )
Row Active
( B-Ban k)
DBb0 DBb1 DBb2 DBb3
QA c 0 Q A c 1 Q A c 2
DBb0 DBb1 DBb2 DBb3
QAc0 QAc1
Rea d
(A- Bank )
W rite
(B-Ban k )
Row A ctive
( A - B an k )
:Don't Car e
*Note : 1. tCDL should be met to complete write.
Elite Semiconductor Memory Technology Inc.
Publication Date : Jun. 2001
Revision : 1.6
42/54
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M32L1632512A
Read & Write Cycle with Auto Precharge @ Burst Length =4
0
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
Db0
Db1
Db2
Db3
Db0
Db1
Db2
Db3
17
18
19
CLOC K
HIGH
CKE
CS
RAS
CAS
ADDR
Ra
Rb
Ra
Rb
Ca
Cb
A1 0
A9
WE
DSF
DQ M
DQ CL= 2
Qa0
CL = 3
Ro w A ct i ve
(A-Bank)
R ea d w i t h
A u t o P r ec h ar g e
(A- Bank)
Row Active
( B - B an k )
Qa1
Q a2
Qa3
Qa0
Q a1
Qa2
A u o t P r ec h ar g e
S t a r t P oi n t
(A- Bank)
Q a3
W r i te wi t h
A u t o P r ec h ar g e
(B- Bank )
A u ot P r e c h a r g e
S t ar t P o i n t
(B-Bank )
:D on't C ar e
*Note : 1. tRDL should be controlled to meet minimum tRAS before internal precharge start.
(In the case of Burst Length = 1 & 2, BRSW mode and Block write)
Elite Semiconductor Memory Technology Inc.
Publication Date : Jun. 2001
Revision : 1.6
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Read & Write Cycle with Auto Precharge II @ Burst Length =4
0
1
2
3
4
5
6
7
9
8
10
11
12
13
14
15
16
17
18
19
CLOCK
HIGH
CK E
CS
RAS
CAS
ADDR
Ra
Rb
Ra
Rb
Ca
Ra
Cb
Ca
A1 0
A9
Ra
WE
DSF
DQM
DQ CL =2
Q a0
Row Act i ve
(A-Bank)
Q a1
Q b0
Qb1
Q a0
Qa1
Q b0
Rea d w i t h
A u t o P r ec h ar g e
( A- B a n k )
Row A cti ve
( B - B an k )
Db2
Qb1
D b3
Db2
D b3
Precharge
( B- B an k )
Row A cti ve
( A - B an k )
Da0
Da1
Da0
Da1
W r ite wi th
Au o t P r ech a r g e
( A- B a n k )
Re ad wi t h o u t A u t o
P r ec h a r g e ( B - B an k )
Au toP r e ah ar g e
St ar t Poi n t
(A-Bank)
:Don't Care
*Note : 1. When Read(Write) command with auto precharge is issued at A-Bank after A and B Bank activation.
- If Read(Write) command without auto precharge is issued at B-Bank before A Bank auto precharge starts, A Bank
auto precharge will start at the next cycle of B Bank read command input point.
- any command can not be issued at A Bank during tRP after A Bank auto precharge starts.
Elite Semiconductor Memory Technology Inc.
Publication Date : Jun. 2001
Revision : 1.6
44/54
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M32L1632512A
Read & Write Cycle with Auto Precharge ÊÊÊ @ Burst Length =4
0
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
Db0
Db1
Db2
Db3
Db0
Db1
Db2
17
18
19
CLOCK
HIG H
CKE
CS
RAS
CAS
ADDR
Ra
Ca
Rb
Cb
A1 0
A9
Ra
Rb
WE
DSF
tRC D
DQ M
DQ CL=2
Qa0
CL=3
Q a1
Q a2
Q a3
Q a0
Q a1
Qa2
Q a3
Db3
*N ot e 1
Row Ac t ive
(A-Bank )
Read w it h
Auto Precharge
(A-Bank )
R ea d w i t h
A u o t P r e c h ar g e
A u t o P r e c h ar g e
Start Poin t
(B- Bank )
(A- Bank )
Ro w A c ti ve
(B- Bank )
A u o t P r e c h ar g e
Start Poin t
(B- Bank )
:Don't Car e
*Note : 1. Any command to A Bank is not allowed in this period.
tRP is determined from at auto precharge start point.
Elite Semiconductor Memory Technology Inc.
Publication Date : Jun. 2001
Revision : 1.6
45/54
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M32L1632512A
Read Interrupted by Precharge Command & Read Burst Stop Cycle (@ Full Page Only)
0
1
2
3
4
5
6
7
8
9
11
10
12
13
14
15
16
17
19
18
CLOCK
HI GH
CKE
CS
RAS
CAS
AD DR
RAa
CA a
CAb
*N ot e 1
*Not e 1
A1 0
A9
RAa
WE
DSF
DQM
*N ot e 2
1
Q Aa 0 Q A a 1 Q A a 2 Q A a 3 Q A a 4
DQ C L=2
2
Q A a 0 Q A a 1 Q A a 2 Q A a 3 Q Aa 4
CL= 3
Row Active
( A - B an k )
Rea d
(A-Bank)
B u r st St o p
1
D Ab0 DA b1 DA b2 D Ab 3 DAb 4 DA b5
2
D Ab 0 DAb 1 DA b2 DA b3 DA b4 D Ab 5
Rea d
(A-Bank)
Precharge
(A-Bank)
:Don't Care
*Note : 1. At full page mode, burst is warp-around at the end of burst. So auto precharge is impossible.
2. About the valid DQ’s after burst stop, it is same as the case of RAS interrupt.
Both cases are illustrated above timing diagram. See the label 1, 2 on them.
But at burst write, Burst stop and RAS interrupt should be compared carefully.
Refer the timing diagram of “Full page write burst stop cycle”.
3. Burst stop is valid at full page mode.
Elite Semiconductor Memory Technology Inc.
Publication Date : Jun. 2001
Revision : 1.6
46/54
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M32L1632512A
Write Interrupted by Precharge Command & Write Burst Stop Cycle (@ Full Page Only)
0
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
CLOCK
HIGH
CKE
CS
RAS
CAS
ADDR
RA a
CAa
CAb
*N ot e 1
*N ot e 1
A1 0
A9
RA a
tRDL
tBDL
WE
D SF
*No te 3
DQ M
*No te 2
D A a0 D A a 1 D A a 2 D A a3 DA a 4
DQ
Row Ac t i ve
( A - B an k )
W rite
(A-Bank )
Burst Stop
D Ab 0 DA b 1 D A b2 DA b 3 DA b 4 D A b5
W rite
(A-Bank )
Precharge
( A - B an k )
:Don't Care
*Note : 1. At full page mode, burst is warp-around at the end of burst. So auto precharge is impossible.
2. Data-in at the cycle of burst stop command cannot be written into the corresponding memory cell.
It is defined by AC parameter of tBDL (=1CLK).
3. Data-in at the cycle interrupted by precharge cannot be written into the corresponding memory cell.
It is defined by AC parameter of tRDL (=1CLK).
DQM at write interrupted by precharge command is needed to ensure tRDL of 1CLK.
DQM should mask invalid input data on precharge command cycle when asserting precharge before end of burst.
Input data after Row precharge cycle will be masked internally.
4. Burst stop is valid only at full page burst length.
Elite Semiconductor Memory Technology Inc.
Publication Date : Jun. 2001
Revision : 1.6
47/54
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M32L1632512A
Burst Read Single bit Write Cycle @ Burst Length = 2, BRSW
1
0
2
3
4
6
5
7
8
9
10
11
12
13
14
15
16
17
18
19
CLOCK
*Not e 1
HIGH
CKE
CS
RAS
*Not e 2
CAS
ADDR
RA a
CAa
RBb
CA b
RA b
C Bc
CAd
A1 0
A9
RA a
RAc
RBb
WE
D SF
DQ M
QAa 0
CL = 3
DA b0 D Ab 1
QAa0
Row A ct i ve
( A - B an k )
D Ab 0 DA b1
Ro w Ac ti ve
( B - B an k )
W rit e
(A-Bank)
Read w ith
A u t o P r ec h a r g e
(A-Bank )
D A d0 D Ad 1
DBc0
DA d 0 DA d1
D Bc 0
Ro w Ac ti ve
( A - B an k )
R ea d
(A-Bank)
Pre ch arg e
( A - B an k )
W ri t e wi t h
A u t o P r ec h a r g e
(B-Bank )
:Don' t Car e
*Note : 1. BRSW mode is enabled by setting A9 “High” at MRS (Mode Register Set).
At the BRSW Mode, the burst length at write is fixed to “1” regardless of programed burst length.
2. When BRSW write command with auto precharge is executed, keep it in mind that tRAS should not be violated.
Auto precharge is executed at the burst-end cycle, so in the case of BRSW write command.
The next cycle is also starts the precharge.
3. WPB function is also possible at BRSW mode.
Elite Semiconductor Memory Technology Inc.
Publication Date : Jun. 2001
Revision : 1.6
48/54
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M32L1632512A
Clock suspension & DQM operation cycle @ CAS Latency = 2, Burst Length = 4
1
0
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
CLOC K
CKE
CS
RAS
CAS
ADDR
Ra
Ca
Cb
Cc
A1 0
A9
RA
WE
DSF
*Note1
DQ M
DQ
Q a0
Qa1
Qa2
Qb0
Q a3
tSHZ
Row Ac t ive
Read
Cloc k
S u s p en s i o n
Q b1
Dc 0
Dc2
tSHZ
W ri te
DQ M
R ea d
Read D QM
W r ite
Cloc k
Suspension
:Don' t C ar e
*Note : 1. DQM needed to prevent bus contention.
Elite Semiconductor Memory Technology Inc.
Publication Date : Jun. 2001
Revision : 1.6
49/54
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M32L1632512A
Active/Precharge Power Down Mode @ CAS Latency = 2, Burst Length =4
0
1
2
3
4
6
5
7
8
9
10
11
12
13
14
15
16
Q a1
Q a2
17
18
19
CLOCK
*N ot e 2
tS S
CKE
tSS
tSS
tS S
*Not e 1
*Not e 3
CS
RAS
CAS
Ra
ADDR
Ca
A1 0
A9
Ra
WE
DSF
DQ M
DQ
Qa0
P r ec h ar g e
P o w er - d o w n
Entr y
P r e ch ar g e
P o w er - d o w n
E xi t
Row Active
Active
P o w er - d o w n
Entr y
Read
Pr e ch ar ge
A cti ve
P o w er - d o w n
E xi t
:Don't C ar e
*Note : 1. All banks should be in idle state prior to entering precharge power down mode.
2. CKE should be set high at lease “1CLK + tSS” prior to Row active command.
3. Cannot violate minimum refresh specification. (32ms)
Elite Semiconductor Memory Technology Inc.
Publication Date : Jun. 2001
Revision : 1.6
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M32L1632512A
Self Refresh Entry & Exit Cycle
1
0
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
CLOCK
*Not e 2
tRCmin
*Note 4
tSS
*Note 1
CKE
*Note 6
*N ot e 3
tS S
*Note 5
CS
RAS
*Not e 7
*Not e 7
CAS
ADDR
A10
A9
WE
DSF
DQM
DQ
Hi-Z
S el f R e f r es h E n t r y
Hi-Z
S e l f R e f r e s h E xi t
A u t o R ef r e s h
:Don't Car e
*Note : TO ENTER SELF REFRESH MODE
1. CS , RAS & CAS with CKE should be low at the same clock cycle.
2. After 1 clock cycle, all the inputs including the system clock can be don’t care except for CKE.
3. The device remains in self refresh mode as long as CKE stays “Low”.
cf.) Once the device enters self refresh mode minimum tRAS is required before exit from self refresh.
TO EXIT SELF REFRESH MODE
4. System clock restart and be stable before returning CKE high.
5. CS starts from high.
6. Minimum tRC is required after CKE going high to complete self refresh exit.
7. 2K cycle of burst auto refresh is required before self refresh entry and after self refresh exit
if the system uses burst refresh.
Elite Semiconductor Memory Technology Inc.
Publication Date : Jun. 2001
Revision : 1.6
51/54
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M32L1632512A
Mode Register Set Cycle
0
1
2
3
4
Auto Refresh Cycle
5
6
0
1
2
3
4
5
6
7
8
9
10
CLOCK
HIGH
HIGH
CKE
CS
*Not e 2
tR C
RAS
*Not e 1
CAS
*N ot e 3
ADDR
Key
Ra
WE
D SF
DQ M
DQ
Hi-Z
M R S N ew
Com mand
Hi-Z
A u t o R ef r e s h
Ne w Com m an d
:Don't C ar e
*Both bank precharge should be completed Mode Register Set cycle and auto refresh cycle.
MODE REGISTER SET CYCLE
*Note : 1. CS , RAS , CAS & WE activation and DSF of low at the same clock cycle with address key will set internal mode
register.
2. Minimum 1 clock cycles should be met before new RAS activation.
3. Please refer to Mode Register Set table.
Elite Semiconductor Memory Technology Inc.
Publication Date : Jun. 2001
Revision : 1.6
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M32L1632512A
PACKING
100-LEAD
DIMENSIONS
QFP(14 x 20 mm)
SEE DETAIL "A"
D
D1
80
51
50
81
E E1
L
PIN 1
L1
DETAIL "A"
100
31
1
30
A
c
SEATING PLANE
b
Symbol
A
A1
A2
b
c
D
D1
E
E1
L
L1
e
θ
y
A1
A2
e
Dimension in mm
Dimension in inch
Min Norm Max
Min Norm Max
3.400
0.134
0.250
0.010
2.650
2.970 0.104
0.117
0.220
0.380 0.0087
0.015
0.110
0.230 0.0043
0.009
23.000 23.200 23.400 0.906 0.913 0.921
19.900 20.000 20.100 0.783 0.787 0.791
17.000 17.200 17.400 0.669 0.677 0.685
13.900 14.000 14.100 0.547 0.551 0.555
0.650 0.800 0.950 0.026 0.031 0.037
1.600 REF
0.063 REF
0.650 REF
0.026 REF
0°
0°
7°
7°
0.080
0.003
Elite Semiconductor Memory Technology Inc.
Publication Date : Jun. 2001
Revision : 1.6
53/54
θ
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M32L1632512A
Important Notice
All rights reserved.
No part of this document may be reproduced or duplicated in any form or by any
means without the prior permission of ESMT.
The contents contained in this document are believed to be accurate at the time of
publication. ESMT assumes no responsibility for any error in this document, and
reserves the right to change the products or specification in this document without
notice.
The information contained herein is presented only as a guide or examples for the
application of our products. No responsibility is assumed by ESMT for any
infringement of patents, copyrights, or other intellectual property rights of third
parties which may result from its use. No license, either express , implied or
otherwise, is granted under any patents, copyrights or other intellectual property
rights of ESMT or others.
Any semiconductor devices may have inherently a certain rate of failure. To
minimize risks associated with customer's application, adequate design and
operating safeguards against injury, damage, or loss from such failure, should be
provided by the customer when making application designs.
ESMT's products are not authorized for use in critical applications such as, but not
limited to, life support devices or system, where failure or abnormal operation may
directly affect human lives or cause physical injury or property damage. If products
described here are to be used for such kinds of application, purchaser must do its
own quality assurance testing appropriate to such applications.
Elite Semiconductor Memory Technology Inc.
Publication Date : Jun. 2001
Revision : 1.6
54/54