UT8R1M39 - Aeroflex Microelectronic Solutions

Standard Products
UT8R1M39 40Megabit SRAM MCM
UT8R2M39 80Megabit SRAM MCM
UT8R4M39 160Megabit SRAM MCM
Data Sheet
June 2015
The most important thing we build is trust
INTRODUCTION
FEATURES
 20ns Read, 10ns Write maximum access times available
 Functionally compatible with traditional 1M, 2M, or 4M x
39 SRAM devices
 CMOS compatible input and output levels, three-state
bidirectional data bus
- I/O Voltages 2.3V to 3.6V, 1.7V to 2.0V core
 Available densities:
- UT8R1M39: 40, 894, 464 bits
- UT8R2M39: 81, 788, 928 bits
- UT8R4M39: 163, 577, 856 bits
 Operational Environment:
- Total-dose: 100 krad(Si)
The UT8R1M39, UT8R2M39, and UT8R4M39 are high
performance CMOS static RAM multichip modules (MCMs)
organized as two, four or eight individual 524,288 words x 39
bits dice respectively. Easy memory expansion is provided by
active LOW chip enables (En), an active LOW output enable
(G), and three-state drivers. This device has a power-down
feature that reduces power consumption by more than 90% when
deselected.
Writing to the device is accomplished by driving one of the chip
enable (En) inputs LOW and the write enable (W) input LOW.
Data on the 39 I/O pins (DQ0 through DQ38) is then written into
the location specified on the address pins (A0 through A18).
Reading from the device is accomplished by driving one of the
chip enables (En) and output enable (G) LOW while driving
write enable (W) HIGH. Under these conditions, the contents of
the memory location specified by the address pins will appear
on the I/O pins. Note: Only one En pin may be active at any time.
- SEL Immune: <110 MeV-cm2/mg
- SEU error rate = 7.3x10-7 errors/bit-day assuming
geosynchronous orbit, Adam’s 90% worst environment.
 Packaging options:
- 132-lead side-brazed dual cavity ceramic quad flatpack
 Standard Microelectronics Drawing:
- UT8R1M39: 5962-10205
- QML Q, Q+ and V compliant
- UT8R2M39: 5962-10206
- QML Q, Q+, and Vcompliant
- UT8R4M39: 5962-10207
- QML Q and Q+ compliant part
The 39 input/output pins (DQ0 through DQ38) are placed in a
high impedance state when the device is deselected (En HIGH),
the outputs are disabled (G HIGH), or during a write operation
(En LOW, W LOW).
Figure 1. Block Diagram
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40M /80M/ 160M
2-, 4-, 8- Die
SRAM MCM Module
(0.90” Square, 132-lead Side-Brazed Dual Cavity
Ceramic Flatpack)
99
98
97
96
95
94
93
92
91
90
89
88
87
86
85
84
83
82
81
80
79
78
77
76
75
74
73
72
71
70
69
68
67
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
TOP_DQ35
BOT_DQ35
DQ16
DQ17
DQ18
DQ19
VDD2
VSS
DQ20
DQ21
DQ22
DQ23
VDD1
VSS
NC
VDD2
NC
VDD2
NC
VSS
VDD1
DQ24
DQ25
DQ26
DQ27
VSS
VDD2
DQ28
DQ29
DQ30
DQ31
BOT_DQ32
BOT_DQ33
TOP_DQ34
A11
A12
A13
VSS
NC
NC
NC
VDD2
NC
VDD1
E7# (NC)
E5# (NC)
E3# (NC)
E1#
VDD1
G#
VSS
E2#
E4# (NC)
E6# (NC)
E8# (NC)
VDD1
VDD2
VSS
VSS
NC
NC
VSS
A14
A15
A16
BOT_DQ34
TOP_DQ38
BOT_DQ38
DQ0
DQ1
DQ2
DQ3
VDD2
VSS
DQ4
DQ5
DQ6
DQ7
VDD1
VSS
NC
VDD2
NC
VDD2
NC
VSS
VDD1
DQ8
DQ9
DQ10
DQ11
VSS
VDD2
DQ12
DQ13
DQ14
DQ15
TOP_DQ32
TOP_DQ33
132
131
130
129
128
127
126
125
124
1123
122
121
120
119
118
117
116
115
114
113
112
111
110
109
108
107
106
105
104
103
102
101
100
BOT_DQ37
TOP_DQ37
A0
A1
A2
A3
VDD1
VSS
A4
A5
A17
NC
VDD1
NC
NC
VSS
NC
VDD1
NC
NC
VDD1
NC
A18
W#
A6
VSS
VDD1
A7
A8
A9
A10
TOP_DQ36
BOT_DQ36
June 2015
Notes:
1. NC=Pins are not connected on die.
2. (NC) = Depending on product version, the pin may be either an enable signal as named or NC.
3. Each TOP and BOT signal for DQ38 through DQ32 must be externally connected
by user.
Figure 2. Pin Diagram
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Table 1. Device Option: Signal and Pin Description
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Version 1.0.0
Package Pin
Number
UT8R1M39
Signal Name
UT8R2M39
Signal Name
UT8R4M39
Signal Name
Device Pin
Description
1
TOP_DQ38
TOP_DQ38
TOP_DQ38
Data I/O1
2
BOT_DQ38
BOT_DQ38
BOT_DQ38
Data I/O1
3
DQ0
DQ0
DQ0
Data I/O
4
DQ1
DQ1
DQ1
Data I/O
5
DQ2
DQ2
DQ2
Data I/O
6
DQ3
DQ3
DQ3
Data I/O
7
VDD2
VDD2
VDD2
PWR
8
VSS
VSS
VSS
PWR
9
DQ4
DQ4
DQ4
Data I/O
10
DQ5
DQ5
DQ5
Data I/O
11
DQ6
DQ6
DQ6
Data I/O
12
DQ7
DQ7
DQ7
Data I/O
13
VDD1
VDD1
VDD1
PWR
14
VSS
VSS
VSS
PWR
15
NC
NC
NC
NC
16
VDD2
VDD2
VDD2
PWR
17
NC
NC
NC
NC
18
VDD2
VDD2
VDD2
PWR
19
NC
NC
NC
NC
20
VSS
VSS
VSS
PWR
21
VDD1
VDD1
VDD1
PWR
22
DQ8
DQ8
DQ8
Data I/O
23
DQ9
DQ9
DQ9
Data I/O
24
DQ10
DQ10
DQ10
Data I/O
25
DQ11
DQ11
DQ11
Data I/O
26
VSS
VSS
VSS
PWR
27
VDD2
VDD2
VDD2
PWR
28
DQ12
DQ12
DQ12
Data I/O
29
DQ13
DQ13
DQ13
Data I/O
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Table 1. Device Option: Signal and Pin Description
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Version 1.0.0
Package Pin
Number
UT8R1M39
Signal Name
UT8R2M39
Signal Name
UT8R4M39
Signal Name
Device Pin
Description
30
DQ14
DQ14
DQ14
Data I/O
31
DQ15
DQ15
DQ15
Data I/O
32
TOP_DQ32
TOP_DQ32
TOP_DQ32
Data I/O1
33
TOP_DQ33
TOP_DQ33
TOP_DQ33
Data I/O1
34
TOP_DQ34
TOP_DQ34
TOP_DQ34
Data I/O1
35
A11
A11
A11
ADDRESS INPUT
36
A12
A12
A12
ADDRESS INPUT
37
A13
A13
A13
ADDRESS INPUT
38
VSS
VSS
VSS
PWR
39
NC
NC
NC
NC
40
NC
NC
NC
NC
41
NC
NC
NC
NC
42
VDD2
VDD2
VDD2
PWR
43
NC
NC
Nc
NC
44
VDD1
VDD1
VDD1
PWR
45
NC
NC
E7#
CONTROL INPUT2
46
NC
NC
E5#
CONTROL INPUT2
47
NC
E3#
E3#
CONTROL INPUT2
48
E1#
E1#
E1#
CONTROL INPUT
49
VDD1
VDD1
VDD1
PWR
50
G#
G#
G#
CONTROL INPUT
51
VSS
VSS
VSS
PWR
52
E2#
E2#
E2#
CONTROL INPUT
53
NC
E4#
E4#
CONTROL INPUT2
54
NC
NC
E6#
CONTROL INPUT2
55
NC
NC
E8#
CONTROL INPUT2
56
VDD1
VDD1
VDD1
PWR
57
VDD2
VDD2
VDD2
PWR
58
VSS
VSS
VSS
PWR
59
VSS
VSS
VSS
PWR
60
NC
NC
NC
NC
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Table 1. Device Option: Signal and Pin Description
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Version 1.0.0
Package Pin
Number
UT8R1M39
Signal Name
UT8R2M39
Signal Name
UT8R4M39
Signal Name
Device Pin
Description
61
NC
NC
NC
NC
62
VSS
VSS
VSS
PWR
63
A14
A14
A14
ADDRESS INPUT
64
A15
A15
A15
ADDRESS INPUT
65
A16
A16
A16
ADDRESS INPUT
66
BOT_DQ34
BOT_DQ34
BOT_DQ34
Data I/O1
67
BOT_DQ33
BOT_DQ33
BOT_DQ33
Data I/O1
68
BOT_DQ32
BOT_DQ32
BOT_DQ32
Data I/O1
69
DQ31
DQ31
DQ31
Data I/O
70
DQ30
DQ30
DQ30
Data I/O
71
DQ29
DQ29
DQ29
Data I/O
72
DQ28
DQ28
DQ28
Data I/O
73
VDD2
VDD2
VDD2
PWR1
74
VSS
VSS
VSS
PWR
75
DQ27
DQ27
DQ27
Data I/O
76
DQ26
DQ26
DQ26
Data I/O
77
DQ25
DQ25
DQ25
Data I/O
78
DQ24
DQ24
DQ24
Data I/O
79
VDD1
VDD1
VDD1
PWR
80
VSS
VSS
VSS
PWR
81
NC
NC
NC
NC
82
VDD2
VDD2
VDD2
PWR
83
NC
NC
NC
NC
84
VDD2
VDD2
VDD2
PWR
85
NC
NC
NC
NC
86
VSS
VSS
VSS
PWR
87
VDD1
VDD1
VDD1
PWR
88
DQ23
DQ23
DQ23
Data I/O
89
DQ22
DQ22
DQ22
Data I/O
90
DQ21
DQ21
DQ21
Data I/O
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Table 1. Device Option: Signal and Pin Description
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Version 1.0.0
Package Pin
Number
UT8R1M39
Signal Name
UT8R2M39
Signal Name
UT8R4M39
Signal Name
Device Pin
Description
91
DQ20
DQ20
DQ20
Data I/O
92
VSS
VSS
VSS
PWR
93
VDD2
VDD2
VDD2
PWR
94
DQ19
DQ19
DQ19
Data I/O
95
DQ18
DQ18
DQ18
Data I/O
96
DQ17
DQ17
DQ17
Data I/O
97
DQ16
DQ16
DQ16
Data I/O
98
BOT_DQ35
BOT_DQ35
BOT_DQ35
Data I/O1
99
TOP_DQ35
TOP_DQ35
TOP_DQ35
Data I/O1
100
BOT_DQ36
BOT_DQ36
BOT_DQ36
Data I/O1
101
TOP_DQ36
TOP_DQ36
TOP_DQ36
Data I/O1
102
A10
A10
A10
ADDRESS INPUT
103
A9
A9
A9
ADDRESS INPUT
104
A8
A8
A8
ADDRESS INPUT
105
A7
A7
A7
ADDRESS INPUT
106
VDD1
VDD1
VDD1
PWR
107
VSS
VSS
VSS
PWR
108
A6
A6
A6
ADDRESS INPUT
109
W#
W#
W#
CONTROL INPUT
110
A18
A18
A18
ADDRESS INPUT
111
NC
NC
NC
NC
112
VDD1
VDD1
VDD1
PWR
113
NC
NC
NC
NC
114
NC
NC
NC
NC
115
VDD1
VDD1
VDD1
PWR
116
NC
NC
NC
NC
117
VSS
VSS
VSS
PWR
118
NC
NC
NC
NC
119
NC
NC
NC
NC
120
VDD1
VDD1
VDD1
PWR
121
NC
NC
NC
NC
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Table 1. Device Option: Signal and Pin Description
Package Pin
Number
UT8R1M39
Signal Name
UT8R2M39
Signal Name
UT8R4M39
Signal Name
Device Pin
Description
122
A17
A17
A17
ADDRESS INPUT
123
A5
A5
A5
ADDRESS INPUT
124
A4
A4
A4
ADDRESS INPUT
125
VSS
VSS
VSS
PWR
126
VDD1
VDD1
VDD1
PWR
127
A3
A3
A3
ADDRESS INPUT
128
A2
A2
A2
ADDRESS INPUT
129
A1
A1
A1
ADDRESS INPUT
130
A0
A0
A0
ADDRESS INPUT
131
TOP_DQ37
TOP_DQ37
TOP_DQ37
Data I/O1
132
BOT_DQ37
BOT_DQ37
BOT_DQ37
Data I/O1
Notes:
NC pins are not connected on the die.
1. Each TOP and BOT signal pin for DQ38 through DQ32 must be externally connected together by user.
2. Control input when declared as En#, otherwise pin is NC.
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minimum time between valid address changes is specified by
the read cycle time (tAVAV1).
DEVICE OPERATION
The SRAMs have control inputs called Chip Enable (En), Write
Enable (W), and Output Enable (G); 19 address inputs, A(18:0);
and 39 bidirectional data lines, DQ(38:0). The En (chip enable)
controls selection between active and standby modes. Asserting
En enables the device, causes IDD to rise to its active value, and
decodes the 19 address inputs. Only one chip enable may be
active at anytime. W controls read and write operations. During
a read cycle, G must be asserted to enable the outputs.
SRAM Read Cycle 2, the Chip Enable-controlled Access in
Figure 3b, is initiated by a single En going active while G
remains asserted, W remains deasserted, and the addresses
remain stable for the entire cycle. After the specified tETQV is
satisfied, the 39-bit word addressed by A(18:0) is accessed and
appears at the data outputs DQ(38:0).
Table 2. SRAM Device Control Operation Truth Table
SRAM Read Cycle 3, the Output Enable-controlled Access in
Figure 3c, is initiated by G going active while a single En is
asserted, W is deasserted, and the addresses are stable. Read
access time is tGLQV unless tAVQV or tETQV (reference Figure
3b) have not been satisfied.
G
W
En
I/O Mode
Mode
X
X
H
DQ(38:0)
3-State
Standby
L
H
L
DQ(38:0)
Data Out
Word Read
WRITE CYCLE
H
H
L
DQ(38:0)
All 3-State
Word Read2
X
L
L
DQ(38:0)
Data In
Word Write
A combination of W and a single En less than VIL(max) defines
a write cycle. The state of G is a “don’t care” for a write cycle.
The outputs are placed in the high-impedance state when either
G is greater than VIH(min), or when W is less than VIL(max).
Write Cycle 1, the Write Enable-controlled Access in Figure 4a,
is defined by a write terminated by W going high, with a single
En still active. The write pulse width is defined by tWLWH when
the write is initiated by W, and by tETWH when the write is
initiated by En. To avoid bus contention tWLQZ must be satisfied
before data is applied to the 39 bidirectional pins DQ(38:0)
unless the outputs have been previously placed in high
impedance state by deasserting G.
Notes:
1. “X” is defined as a “don’t care” condition.
2. Device active; outputs disabled.
READ CYCLE
A combination of W greater than VIH (min) with a single En and
G less than VIL (max) defines a read cycle. Read access time is
measured from the latter of device enable, output enable, or valid
address to valid data output.
Write Cycle 2, the Chip Enable-controlled Access in Figure 4b,
is defined by a write terminated by a single En. The write pulse
width is defined by tWLEF when the write is initiated by W, and
by tETEF when the write is initiated by En going active. For the
W initiated write, unless the outputs have been previously placed
in the high-impedance state by G, the user must wait tWLQZ
before applying data to the 39 bidirectional pins DQ(38:0) to
avoid bus contention.
SRAM Read Cycle 1, the Address Access in Figure 3a, is
initiated by a change in address inputs after a single En is
asserted, G is asserted, W is deasserted and are all stable. Valid
data appears on data outputs DQ(38:0) after the specified tAVQV
is satisfied. Outputs remain active throughout the entire cycle.
As long as device enable and output enable are active, the
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Table 3. Operational Environment1
Total Dose
100K
radsSi)
Heavy Ion
Error Rate2
7.3x10-7
Errors/Bit-Day
Notes:
1. The SRAM is immune to latchup to particles <110MeV-cm2/mg.
2. 90% worst case particle environment, Geosynchronous orbit, 100 mils of
Aluminum.
SUPPLY SEQUENCING
No supply voltage sequencing is required between VDD1 and
VDD2.
POWER-UP REQUIREMENTS
During power-up of the SRAM devices, the power supply
voltages will traverse through voltage ranges where the device
is not guaranteed to operate before reaching final levels. Since
some circuits on the device may operate at lower voltage levels
than others, the device may power-up in an unknown state. To
eliminate this with most power-up situations, the device
employs an on-chip power-on-reset (POR) circuit. The POR,
however, requires time to complete the operation. Therefore, it
is recommended that all device activity be delayed by a
minimum of 100ms, after both VDD1 and VDD2 supplies have
reached their respective minimum operating voltages.
EXTERNAL CONNECTION REQUIREMENTS
Bidirectional data lines DQ38-DQ32 have both a TOP and BOT
pinout. TOP and BOT for each data line must be externally
connected together by user.
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ABSOLUTE MAXIMUM RATINGS1
(Referenced to VSS)
SYMBOL
PARAMETER
LIMITS
VDD1
DC supply voltage (Core)
-0.3 to 2.1V
VDD2
DC supply voltage (I/O)
-0.3 to 3.8V
VI/O
Voltage on any pin
-0.3 to 3.8V
TSTG
Storage temperature
-65 to +150°C
PD2
Maximum package power dissipation
permitted @ Tc = +105oC
UT8R1M39
UT8R2M39
UT8R4M39
TJ
ΘJC3
UT8R1M39
UT8R2M39
UT8R4M39
II
Maximum junction temperature
3.3W
2W
1.3W
+150°C
Thermal resistance, junction-to-case2
6oC/W
10oC/W
15oC/W
DC input current
±10 mA
Notes:
1. Stresses outside the listed absolute maximum ratings may cause permanent damage to the device. This is a stress rating only, and functional operation of the device
at these or any other conditions beyond limits indicated in the operational sections of this specification is not recommended. Exposure to absolute maximum rating
conditions for extended periods may affect device reliability and performance.
2. Per MIL-STD-883, Method 1012, Section 3.4.1, PD = (125oC - 105oC)
3. ΘJC varies with density due to stacked die configuration.
ΘJC
RECOMMENDED OPERATING CONDITIONS
SYMBOL
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Version 1.0.0
PARAMETER
LIMITS
VDD1
DC supply voltage (Core)
1.7 to 2.0V
VDD2
DC supply voltage (I/O)
2.3 to 3.6V
TC
Case temperature range
-55°C to +105°C
VIN
DC input voltage
- 10 -
0V to VDD2
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DC ELECTRICAL CHARACTERISTICS (Pre and Post-Radiation)*
(VDD1 = 1.7V to 2.0V, VDD2 = 2.3V to 3.6V; Unless otherwise noted, Tc is per the temperature range ordered)
SYMBOL
PARAMETER
VIH
High-level input voltage
VIL
Low-level input voltage
0.8
V
VOL1
Low-level output voltage IOL = 8mA, 3.0V<VDD2 < 3.6V
0.4
V
VOL2
Low-level output voltage IOL = 6mA, 2.3V<VDD2 < 2.7V
0.2*VDD2
VOH1
High-level output
voltage
IOH = -4mA, 3.0V<VDD2 < 3.6V
0.8*VDD2
VOH2
High-level output
voltage
IOL = -2mA, 2.3V<VDD2 < 2.7V
0.8*VDD2
IIN
Input leakage current
VIN = VDD2 and VSS
-2
2
μA
IOZ
Three-state output
leakage current
VO = VDD2 and VSS
VDD2 = VDD2 (max), G = VDD2 (max)
-2
2
μA
IOS2,3
Short-circuit output
current
VDD2 = VDD2 (max), VO = VDD2
VDD2 = VDD2 (max), VO = VSS
-100
+100
mA
IDD1(OP1)5
VDD1 Supply current
read operation
@ 1MHz
VDD1= 2.0V
Inputs: VIL = VSS + 0.2V,
VIH = VDD2 -0.2V, IOUT = 0
VDD2 = VDD2 (max)
VDD1 = 1.9V
14
mA
10
mA
VDD1 = 2.0V
Inputs: VIL = VSS + 0.2V,
VIH = VDD2 -0.2V, IOUT = 0 VDD1 = 1.9V
VDD2 = VDD2 (max)
UT8R4M39
230
215
mA
mA
VDD1 = 2.0V
VDD1 = 1.9V
UT8R1M39
UT8R2M39
225
210
mA
mA
IDD1(OP2)5,6
VDD1 Supply current
read operation
@ fmax
CONDITION
MIN
MAX
2.2
UNIT
V
V
IDD2(OP1)5
VDD2 Supply current
read operation
@ 1MHz
Inputs : VIL = VSS + 0.2V,
VIH = VDD2 -0.2V, IOUT = 0
VDD1 = VDD1 (max), VDD2 = VDD2 (max)
2
mA
IDD2(OP2)5,6
VDD2 Supply current
read operation
@ fmax
Inputs : VIL = VSS + 0.2V,
VIH = VDD2 -0.2V, IOUT = 0
VDD1 = VDD1 (max), VDD2 = VDD2 (max)
5
mA
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SYMBOL
IDD1(SB)4,7
IDD2(SB)7
IDD1(SB)4,6,7
IDD2(SB)6,7
PARAMETER
Supply current standby
@ 0Hz (per die)
Supply current standby
@ 0Hz (per die)
CONDITION
CMOS inputs, IOUT = 0
En = VDD2 -0.2
VDD1 = VDD1 (max), VDD2
= VDD2 (max)
MAX
UNIT
-55oC and
25oC
15
mA
105oC
35
mA
3
mA
-55oC and
25oC
15
mA
105oC
35
mA
3
mA
CMOS inputs, IOUT = 0
En = VDD2 -0.2
VDD1 = VDD1 (max), VDD2
= VDD2 (max)
Supply current standby CMOS inputs , IOUT = 0
A(16:0) @ fmax (per die) En = VDD2 - 0.2
VDD1 = VDD1 (max), VDD2
= VDD2 (max)
Supply current standby
A(16:0) @ fmax
(per die)
MIN
CMOS inputs, IOUT = 0
En = VDD2 - 0.2
VDD1 = VDD1 (max), VDD2
= VDD2 (max)
CAPACITANCE
SYMBOL
PARAMETER
CONDITION
UT8R1M39
MIN
MAX
UT8R2M39
MIN
MAX
UT8R4M39
MIN
UNIT
MAX
CIN1
Input capacitance
ƒ = 1MHz @ 0V
18
29
50
pF
CEn1
Input capacitance
Device Enables
ƒ = 1MHz @ 0V
10
10
10
pF
CIO1
Bidirectional I/O
capacitance
ƒ = 1MHz @ 0V
15
27
50
pF
Bidirectional I/O
CIO1
TOP and BOT capacitance
DQ(38:32)
ƒ = 1MHz @ 0V
10
20
32
pF
DQ(31:0)
Notes:
* For devices procured with a total ionizing dose tolerance guarantee, the post-irradiation performance is guaranteed at 25oC per MIL-STD-883 Method 1019, Condition
A up to the maximum TID level procured.
1. Measured only for initial qualification and after process or design changes that could affect this parameter.
2. Supplied as a design limit but not guaranteed nor tested.
3. Not more than one output may be shorted at a time for maximum duration of one second.
4. Post radiation limits are the 105oC temperature limit when specified.
5. Operating current limit does not include standby current.
6. fmax =50MHz.
7. VIH = VDD2 (max), VIL = 0V.
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AC CHARACTERISTICS READ CYCLE (Pre and Post-Radiation)*
(VDD1 = 1.7V to 2.0V, VDD2 = 2.3V to 3.6V; Unless otherwise noted, Tc is per the temperature range ordered.)
SYMBOL
PARAMETER
UT8R1M39
MIN
MAX
UT8R2M39
MIN
MAX
22
FIGURE
ns
3a
ns
3c
Read cycle time
tAVQV
Address to data valid
from address change
tAXQX2
Output hold time
3
3
3
ns
3a
tGLQX1,2
G-controlled output
enable time
2
2
2
ns
3c
tGLQV
G-controlled output
data valid
10
ns
3c
tGHQZ2
G-controlled output
three-state time
2
8
ns
3c
tETQX2
E-controlled output
enable time
5
ns
3b
tETQV
E-controlled access time
25
ns
3b
tEFQZ2
E-controlled output
7
ns
3b
20
22
8
25
8
6
2
6
5
20
2
25
UNIT
tAVAV11
three-state
20
UT8R4M39
MIN
MAX
1
5
22
7
2
7
2
time2
Notes:
* For devices procured with a total ionizing dose tolerance guarantee, the post-irradiation performance is guaranteed at 25oC per MIL-STD-883 Method 1019, Condition
A up to the maximum TID level procured
1. Guaranteed by characterization, but not tested.
2. Three-state is defined as a change from steady-state output voltage.
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tAVAV1
A(18:0)
DQ(38:0)
Previous Valid Data
Valid Data
tAVQV
tAXQX
Assumptions:
1. E and G < VIL (max) and W > VIH (min)
Figure 3a. SRAM Read Cycle 1: Address Access
A(18:0)
En
tETQV
tEFQZ
tETQX
DQ(38:0)
DATA VALID
Assumptions:
1. G < VIL (max) and W > VIH (min)
Figure 3b. SRAM Read Cycle 2: Chip Enable-Controlled Access
tAVQV
A(18:0)
G
tGHQZ
tGLQX
DATA VALID
DQ(38:0)
Assumptions:
1. E < VIL (max) and W > VIH (min)
tGLQV
Figure 3c. SRAM Read Cycle 3: Output Enable Access
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AC CHARACTERISTICS WRITE CYCLE (Pre and Post-Radiation)*
(VDD1 = 1.7V to 2.0V, VDD2 = 2.3V to 3.6V; Unless otherwise noted, Tc is per the temperature range ordered.)
SYMBOL
PARAMETER
UT8R1M39
UT8R2M39
UT8R4M39
MIN
MIN
MIN
MAX
MAX
UNIT
FIGURE
MAX
tAVAV21
Write cycle time
10
10
10
ns
4a/4b
tETWH
Device enable to
end of write
10
10
10
ns
4a
tAVET
Address setup time for
write (En- controlled)
0
0
0
ns
4b
tAVWL
Address setup time for
write (W - controlled)
0
0
0
ns
4a
tWLWH1
Write pulse width
8
8
8
ns
4a
tWHAX
Address hold time for
write (W - controlled)
0
0
0
ns
4a
tEFAX
Address hold time for
device enable (En- controlled)
0
0
0
ns
4b
tWLQZ2
W - controlled three-state time
ns
4a/4b
tWHQX2
W - controlled output
enable time
0
0
0
ns
4a
tETEF
Device enable pulse
width (En - controlled)
10
10
10
ns
4b
tDVWH
Data setup time
5
5
6
ns
4a
tWHDX
Data hold time
0
0
0
ns
4a
tWLEF1
Device enable controlled
write pulse width
8
8
8
ns
4b
tDVEF
Data setup time
5
5
6
ns
4a/4b
tEFDX
Data hold time
0
0
0
ns
4b
tAVWH
Address valid to end of write
10
10
10
ns
4a
tWHWL1
Write disable time
2
2
3
ns
4a
7
7
9
Notes:
* For devices procured with a total ionizing dose tolerance guarantee, the post-irradiation performance is guaranteed at 25oC per MIL-STD-883 Method 1019, Condition
A up to the maximum TID level procured
1. Tested with G high.
2. Three-state is defined as a change from steady-state output voltage.
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A(18:0)
tAVAV2
En
tAVWH
tETWH, tWLEF
tWHWL
W
tAVWL
tWLWH
tWHAX
Q(38:0)
tWHQX
tWLQZ
D(38:0)
APPLIED DATA
tDVWH, tDVEF
Assumptions:
1. G < VIL (max). (If G > VIH (min) then Q(31:0) and MBE will be in threestate for the entire cycle.)
tWHDX
2. SCRUB > VOH (min)
Figure 4a. SRAM Write Cycle 1: W - Controlled Access
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tAVAV2
A(18:0)
tAVET
tETEF
tEFAX
En
tWLEF
W
APPLIED DATA
D(38:0)
tDVEF
Q(38:0)
tEFDX
Assumptions & Notes:
1. G < VIL (max). (If G > VIH (min) then Q(31:0) and MBE will be in three-state for the entire cycle.)
2. Busy > VOH (min)
Figure 4b. SRAM Write Cycle 2: Enable - Controlled Access
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DATA RETENTION CHARACTERISTICS (Pre and Post-Radiation)*
(VDD2 = 2.3 to 3.6V, 1 second DR pulse)
SYMBOL
VDR
IDDR 1
tEFR1,2
tR1,2
PARAMETER
TEMP
MINIMUM
MAXIMUM
UNIT
--
1.0
--
V
-55°C
--
3
mA
25°C
--
3
mA
105°C
--
23.5
mA
Chip deselect to data retention time
--
0
--
ns
Operation recovery time
--
tAVAV1
tAVAV2
--
ns
VDD1 for data retention
Data retention current (per die)
Notes:
* Post-radiation performance guaranteed at 25°C per MIL-STD-883 Method 1019.
1. En as shown all other inputs = VDD2 or VSS.
2. Guaranteed by design neither tested nor characterized.
DATA RETENTION MODE
1.7V
1.7V
VDR > 1.0V
VDD1
tR
tEFR
En
VIN >0.7VDD2 CMOS
VIN <0.3VDD2 CMOS
Figure 5. Low VDD Data Retention Waveform
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VDD
VDD
RTERM
100ohm
CL = 40pF
DUT
Test
Point
Zo = 50ohm
RTERM
100ohm
VDD2
VSS
90%
90%
10%
< 2ns
10%
CMOS Input Pulses
< 2ns
Notes:
1. Measurement of data output occurs at the low to high or high to low transition mid-point (i.e., CMOS input = VDD2/2
Figure 6. AC Test Loads and Input Waveforms
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PACKAGING
Figure 7. 132-Lead Side-Brazed Dual Cavity Ceramic Quad Flatpack
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ORDERING INFORMATION
40Mbit (1Mx39) SRAM MCM
80Mbit (2Mx39) SRAM MCM
160Mbit (4Mx39) SRAM MCM
UT ****** - * *
* * *
Lead Finish: (Note 1)
(C) = Gold
Screening: (Notes 2, 3)
(F) = HiRel Flow
(P) = Prototype Flow
(Temperature Range: -55°C to +105°C)
(Temperature Range: 25oC only)
Package Type:
(X) = 132-lead ceramic quad flatpack, side-brazed, dual cavit y
Access Time: (Note 4)
(21) = 20ns read / 10ns write access times, 40Mbit device type
(22) = 22ns read / 10ns writeaccess times, 80Mbit device type
(25) = 25ns read / 10ns write access times, 160Mbit device type
Device Type:
(8R1M39) = 40Mbit (1Mx39) SRAM MCM
(8R2M39) = 80Mbit (2Mx 39) SRAM MCM
(8R4M39) = 160Mbit (4Mx39) SRAM MCM
Notes:
1. Lead finish is "C" (Gold) only.
2. Prototype Flow per Aeroflex Manufacturing Flows Document. Devices are tested at 25oC only. Lead finish is GOLD "C" only. Radiation is neither tested nor
guaranteed.
3. HiRel flow per Aeroflex Manufacturing Flows Document. Radiation is neither tested nor guaranteed.
4. Device option (21) applicable to 40Mbit device type only. Option (22) applicable to 80Mbit device type only. Option (25) applicable to 160Mbit device type only.
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40Mbit (1Mx39) SRAM MCM: SMD
80Mbit (2Mx39) SRAM MCM: SMD
160Mbit (4Mx39) SRAM MCM: SMD
5962 *
***** ** * * *
Lead Finish: (Note 1)
(C) = Gold
Case Outline:
(X) = 132-lead ceramic quad flatpack, side brazed, dual cavity
Class Designator:
(Q) = QML Class Q
(V) = QML Class V (10205 and 10206 device options only)
Device Type: (Note 2)
(01) = Temperature Range (-55°C to +105°C)
(02) = Assembled to Aeroflex Q+ Flow (Temperature Range -55°C to +105°C)
Drawing Number:
(10205) = 40Mbit (1Mx39) SRAM MCM
(10206) = 80Mbit (2Mx39) SRAM MCM
(10207) = 160Mbit (4Mx39)SRAM MCM
Total Dose: (Note 3)
(R) = 100 krad(Si)
Federal Stock Class Designator: No options
Notes:
1. Lead finish is "C" (Gold) only.
2. Aeroflex’s Q+ assembly flow, as defined in section 4.2.2.d of the SMD, provides QML-Q product through the SMD that is manufactured with Aeroflex’s
standard QML-V flow and has completed QML-V qualification per MIL-PRF-38535.
3. TID tolerance guarantee of 1E5 is tested in accordance with MIL-STD-883 Test Method 1019 (condition A and section 3.11.2) resulting in an effective dose
rate of 1 rad(Si)/sec.
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This product is controlled for export under the U.S. Department of Commerce (DoC). A license may be
required prior to the export of this product from the United States.
Cobham Semiconductor Solutions
4350 Centennial Blvd
Colorado Springs, CO 80907
E: [email protected]
T: 800 645 8862
Advanced Datasheets - Product is in Development
Preliminary Datasheet - Prototypes are Shipping
Datasheet - Shipping QML & Reduced Hi - Rel
Aeroflex Colorado Springs Inc., DBA Cobham Semiconductor Solutions, reserves the right to make changes to any products and services described
herein at any time without notice. Consult Aeroflex or an authorized sales representative to verify that the information in this data sheet is current
before using this product. Aeroflex does not assume any responsibility or liability arising out of the application or use of any product or service
described herein, except as expressly agreed to in writing by Aeroflex; nor does the purchase, lease, or use of a product or service from Aeroflex
convey a license under any patent rights, copyrights, trademark rights, or any other of the intellectual rights of Aeroflex or of third parties.
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Aeroflex Colorado Springs Application Note
AN-MEM-002
Low Power SRAM Read Operations
Table 1: Cross Reference of Applicable Products
Manufacturer
Part Number
SMD #
Device Type
Internal PIC
Number:*
4M Asynchronous SRAM
UT8R128K32
5962-03236
01 & 02
WC03
4M Asynchronous SRAM
UT8R512K8
5962-03235
01 & 02
WC01
16M Asynchronous SRAM
UT8CR512K32
5962-04227
01 & 02
MQ08
16M Asynchronous SRAM
UT8ER512K32
5962-06261
05 & 06
WC04/05
4M Asynchronous SRAM
UT8Q512E
5962-99607
05 & 06
WJ02
4M Asynchronous SRAM
UT9Q512E
5962-00536
05 & 06
WJ01
16M Asynchronous SRAM
UT8Q512K32E
5962-01533
02 & 03
QS04
16M Asynchronous SRAM
UT9Q512K32E
5962-01511
02 & 03
QS03
32M Asynchronous SRAM
UT8ER1M32
5962-10202
01 - 04
QS16/17
64M Asynchronous SRAM
UT8ER2M32
5962-10203
01 - 04
QS09/10
128M Asynchronous SRAM
UT8ER4M32
5962-10204
01 - 04
QS11/12
40M Asynchronous SRAM
UT8R1M39
5962-10205
01 & 02
QS13
80M Asynchronous SRAM
UT8R2M39
5962-10206
01 & 02
QS14
160M Asynchronous SRAM
UT8R4M39
5962-10207
01 & 02
QS15
Product Name:
* PIC = Aeroflex’s internal Product Identification Code
1.0 Overview
The purpose of this application note is to discuss the Aeroflex SRAMs low power read architecture and to inform users of the
affects associated with the low power read operations.
2.0 Low Power Read Architecture
The aforementioned Aeroflex designed SRAMs all employ an architecture which reduces power consumption during read
accesses. The architecture internally senses data only when new data is requested. A request for new data occurs anytime the
chip enable device pin is asserted, or any of the device address inputs transition states while the chip enable is asserted. A trigger is generated and sent to the sensing circuit anytime a request for new data is observed. Since several triggers could occur
simultaneously, these triggers are wire-ORed to result in a single sense amplifier activity for the read request. This design
method results in less power consumption than designs that continually sense data. Aeroflex’s low power SRAMs listed above
activate the sensing circuit for approximately 5ns whenever and access is requested, thereby, significantly reducing active
power.
Creation Date: 8/19/11
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AN-MEM-002
2.1 The SRAM Read Cycles.
The data sheets for all the devices noted in Table #1 discuss three methods for performing a read operation. The two most common methods for reading data are an Address Access and a Chip Enabled-Controlled Access. The third access discussed is the
Output Enable-Controlled Access. The sequence at which control lines and address inputs are toggled determines which cycle
is considered relevant. As discussed in section 2.0, an assertion of chip enable or any address transition while chip enable is
asserted, initiates a read cycle. If the device chip enable is asserted prior to any address input transitions, then the read access
is considered an Address Access. By keeping the device enabled and repeatedly switching address locations, the user retrieves
all data of interest. A Chip Enable-Controlled Access occurs when the address signals are stable prior to asserting the chip
enable. The Output Enabled-Controlled Access requires that either an Address Access or Chip Enable-Controlled Access has
already been performed and the data is waiting for the Output Enable pin to assert, driving data to the device I/O pins.
The subsequent read cycle verbiage and diagrams are based on the Aeroflex UT8R512K8 data sheet. The number of control,
input, and I/O pins will vary across the products listed in Table 1. The basic design family functionality for read operations is
common among all the devices.
2.1.0 Address Access Read Cycle
The Address Access is initiated by a change in address inputs while the chip is enabled with G asserted and W deasserted. Valid
data appears on data outputs DQ(7:0) after the specified tAVQV is satisfied. Outputs remain active throughout the entire cycle.
As long as chip enable and output enable are active, the address inputs may change at a rate equal to the minimum read cycle
time (tAVAV).
tAVAV
A(18:0)
DQ(7:0)
Previous Valid Data
Valid Data
tAVQV
Assumptions:
1. E1 and G < VIL (max) and E2 and W > VIH (min)
tAXQX
Note: No time references are relevant with respect to Chip Enable(s). Chip Enable(s) is assumed to be asserted.
SRAM Read Cycle 1: Address Access
Creation Date: 8/19/11
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AN-MEM-002
2.1.1 Chip Enable-Controlled Read Cycle
The Chip Enable-controlled Access is initiated by E1 and E2 going active while G remains asserted, W remains deasserted, and
the addresses remain stable for the entire cycle. After the specified tETQV is satisfied, the eight-bit word addressed by A(18:0)
is accessed and appears at the data outputs DQ(7:0).
A(18:0)
E1 low or
E2 high
tETQV
tETQX
DQ(7:0)
tEFQZ
DATA VALID
Assumptions:
1. G < VIL (max) and W > VIH (min)
Note: No specification is given for address set-up time with respect to chip enable assertion. The read cycle description states that
addresses are to remain stable for the entire cycle. Address set-up time relative to chip enable is assumed to be 0ns minimum.
SRAM Read Cycle 2: Chip Enable Access
2.1.1 Output Enabled-Controlled Read Cycle
The Output Enable-controlled Access is initiated by G going active while E1 and E2 are asserted, W is deasserted, and the
addresses are stable. Read access time is tGLQV unless tAVQV or tETQV have not been satisfied.
tAVQV
A(18:0)
G
tGHQZ
tGLQX
DATA VALID
DQ(7:0)
tGLQV
Assumptions:
1. E1 < VIL (max) , E2 > and W > VIH (min)
SRAM Read Cycle 3: Output Enable Access
3.0 Low Power Read Architecture Timing Consideration
The low power read architecture employed by Aeroflex designed SRAMs results in significant power reduction, especially in
applications with longer than minimum read cycle times. However, this type of architecture is responsive to excessive input
signal skew when device addressing and chip enable assertion occur simultaneously. Signal skew of greater than 4-5ns
between all of the read triggering activities is sufficient to start another read cycle.
Creation Date: 8/19/11
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AN-MEM-002
3.1 Simultaneous Control and Address Switching
Simultaneous switching of controls and address pins, alone, is not a problem; excessive skew between them is the concern.
Consider the application where several SRAM devices are connected to the same memory bus. The address bus is commonly
connected to all the devices, but the chip enable pin is singularly connected to each individual SRAM. This configuration
results in a loading difference between the address inputs and the chip enable. This lightly loaded chip enable propagates to the
memory more quickly than the heavily loaded address lines. The oscilloscope capture of Figure #1 is the actual timing of an
application which had intermittent data errors due to address transitions lagging chip enable.
Address Signal (Ax)
Chip Enable (/E)

Timing shown from VIL (yellow trace /CS) and VIH (pink for address signal) as delta X =
6ns. Even at actual internal gate switching point (~ VDD/2), the skew is still around 6ns.
Figure #1 SRAM Signal Capture
The signal transitions in the scope plot of Figure #1 appear to be fairly coincidental. A closer look however, reveals the chip
enable signal actually starts and reaches VIL approximately 6ns before the address signal reaches VIH. Even at one half VDD
(closer to actual logical gate switching of the inputs), the delta in signal times is still approximately 6ns.
Simultaneous switching of controls and address inputs is not recommended for a couple of reasons. The first is the previously
described signal skew sensitivity between controls and/or address inputs. The second reason is that activating all the controls
and address inputs simultaneously results in peak instantaneous current consumption. This condition causes maximum strain
to the power decoupling. Chip Enable activates address decoding circuits, address switching introduces input buffer switching
current, and output enable assertion turns on all the device output drivers. Peforming all three simultaneously results in worst
case transient current demand by the memory.
3.1.0 Technical Overview of Skew Sensitivity
Recall from section 2.0 that any activity requesting new data causes a read trigger. The triggers are wire-ORed together. In
order to meet the faster access times demanded by today’s applications, the ORed trigger only exists during the first 4-5ns of
the read cycle. Since the slowest of the address transitions occurs more than 5ns after the initiation of the read activity, a second read activity is initiated. The sensing circuit does not have time to normalize before the second read activity has started.
For this reason a Chip Enable-Controlled read cycle requires that address inputs remain stable for the entire cycle. Infrequent
and random sensing errors can result if the bit columns are continually pulled to one state then quickly requested to sense the
opposite state. Another effect of the low power read architecture that differs from previous generation designs (those that continually sense for data) is that the bit line will not be sensed again until another read triggering event occurs. If another read
trigger event (chip enable assertion and/or address change) does no occur for a particular address, the incorrect data remains at
the outputs.
Creation Date: 8/19/11
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AN-MEM-002
4.0 Summary and Conclusion
The Aeroflex SRAMs in Table #1 all employ a low power consumption read architecture. Power is conserved by sensing data
only when new data is requested. A request occurs anytime chip enable is asserted or any address input signal transitions while
chip enable is asserted. The data sheets for the SRAMs listed in Table #1 do not explicitly define the case of simultaneous
switching of address and control signals during read operations. Data sheet read cycle descriptions indicate that control inputs
are established prior to address changes, and address inputs are stable prior to control assertions. Simultaneous switching of
addresses and controls is tolerable, when the skew between all input signals is < 4ns. For designs that must employ the simultaneous activation of address and control signals, two important issues should be considered by the designer. The first is the
input signal skew sensitivity of the low power read architecture discussed by this application note. The second is the instantaneous current consumption that results from simultaneous access methods. Aeroflex recommends the use of only one read
access method at a time. If multiple read accesses (simultaneous chip enable assertion and address switching) cannot be
avoided, then Aeroflex recommends that the chip enable signal be delayed until all addresses have completed transitions.
Creation Date: 8/19/11
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