INFINEON HYB39S16160CT-6

HYB39S16160CT-6/-7
16MBit Synchronous DRAM
1M x 16 MBit Synchronous DRAM
for High Speed Graphics Applications
•
High Performance:
•
full page(optional) for sequencial wrap
around
•
Multiple Burst Read with Single Write
Operation
•
Automatic
Command
-6
-7
Units
fCKmax @ CL=3
166
143
MHz
tCK3
6
7
ns
tAC3
5
5.5
ns
•
Data Mask for Read / Write control
fCKmax @ CL=2
125
115
MHz
•
Dual Data Mask for byte control ( x16)
tCK2
8
9
ns
•
Auto Refresh (CBR) and Self Refresh
ns
•
Suspend Mode and Power Down Mode
•
4096 refresh cycles / 64 ms
•
Latency 2 @ 125 MHz
•
Latency 3 @ 166 MHz
•
Random Column Address every CLK
( 1-N Rule)
•
Single 3.3V +/- 0.3V Power Supply
•
LVTTL Interface
•
Plastic Packages:
P-TSOPII-50 400mil width ( x16 )
tAC2
6
6
•
Fully Synchronous to Positive Clock Edge
•
0 to 70 °C operating temperature
•
Dual Banks controlled by A11 ( Bank Select)
•
Programmable CAS Latency : 2, 3
•
Programmable Wrap Sequence : Sequential
or Interleave
•
Programmable Burst Length: 1, 2, 4, 8
and
Controlled
Precharge
The HYB39S16160CT-6/-7 are high speed dual bank Synchronous DRAM’s based on SIEMENS
0.25µm process and organized as 2 banks x 512kbit x 16. These synchronous devices achieve high
speed data transfer rates up to 166 MHz by employing a chip architecture that prefetches multiple
bits and then synchronizes the output data to a system clock. The chip is fabricated with SIEMENS’
advanced 16MBit DRAM process technology.
The device is designed to comply with all JEDEC standards set for synchronous DRAM products,
both electrically and mechanically. All of the control, address, data input and output circuits are
synchronized with the positive edge of an externally supplied clock.
Operating the two memory banks in an interleaved fashion allows random access operation to occur
at higher rate than is possible with standard DRAMs. A sequential and gapless data rate of up to 166
MHz is possible depending on burst length, CAS latency and speed grade of the device.
Auto Refresh (CBR) and Self Refresh operation are supported. These devices operate with a single
3.3V +/- 0.3V power supply and are available in TSOPII packages.
These Synchronous DRAM devices are available with LV-TTL interfaces.
Semiconductor Group
1
10.98
HYB39S16160CT-6/-7
16MBit Synchronous DRAM
Ordering Information
Type
Ordering Code
Package
Description
HYB 39S16160CT-6
P-TSOPII-50 (400mil)
166MHz 2B x 512k x 16 SDRAM
HYB 39S16160CT-7
P-TSOPII-50 (400mil)
143MHz 2B x 512k x 16 SDRAM
LVTTL-version:
Pin Description and Pinouts:
CLK
Clock Input
DQ
Data Input /Output
CKE
Clock Enable
LDQM, UDQM
Data Mask
CS
Chip Select
Vdd
Power (+3.3V)
RAS
Row Address Strobe
Vss
Ground
CAS
Column Address Strobe
Vddq
Power for DQ’s (+ 3.3V)
WE
Write Enable
Vssq
Ground for DQ’s
A0-A10
Address Inputs
NC
not connected
A11 (BS)
Bank Select
Pin-Out
Vdd
DQ0
DQ1
Vssq
DQ2
DQ3
Vddq
DQ4
DQ5
Vssq
DQ6
DQ7
Vddq
LDQM
WE
CAS
RAS
CS
A11
A10
A0
A1
A2
A3
Vdd
Semiconductor Group
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
50
49
48
47
46
45
44
43
42
41
40
39
38
37
36
35
34
33
32
31
30
29
28
27
26
2
Vss
DQ15
DQ14
Vssq
DQ13
DQ12
Vddq
DQ11
DQ10
Vssq
DQ9
DQ8
Vddq
NC
UDQM
CLK
CKE
NC
A9
A8
A7
A6
A5
A4
Vss
HYB39S16160CT-6/-7
16MBit Synchronous DRAM
Signal Pin Description
Pin
Type
Signal Polarity
Function
CLK
Input
Pulse
CKE
Input
Level
Active
High
Activates the CLK signal when high and deactivates the CLK signal when
low, thereby inititiates either the Power Down mode, Suspend mode or the
Self Refresh mode.
CS
Input
Pulse
Active
Low
CS enables the command decoder when low and disables the command
decoder when high. When the command decoder is disabled, new
commands are ignored but previous operations continue.
RAS,
CAS
WE
Input
Pulse
Active
Low
When sampled at the positive rising edge of the clock, CAS, RAS, and WE
define the command to be executed by the SDRAM.
Positive The system clock input. All of the SDRAM inputs are sampled on the rising
Edge edge of the clock.
During a Bank Activate command cycle, A0-A10 defines the row address
(RA0-RA10) when sampled at the rising clock edge.
During a Read or Write command cycle, A0-A9 defines the column
address (CA0-CAn) when sampled at the rising clock edge.CAn depends
from the SDRAM organisation.
A0 A10
1M x 16 SDRAM CAn = CA7
Input
Level
—
In addition to the column address, A10 is used to invoke autoprecharge
operation at the end of the burst read or write cycle. If A10 is high,
autoprecharge is selected and A11 defines the bank to be precharged
(low=bank A, high=bank B). If A10 is low, autoprecharge is disabled.
During a Precharge command cycle, A10 is used in conjunction with A11
to control which bank(s) to precharge. If A10 is high, both bank A and bank
B will be precharged regardless of the state of A11. If A10 is low, then A11
is used to define which bank to precharge.
A11
(BS)
Input
Level
—
Selects which bank is to be active. A11 low selects bank A and A11 high
selects bank B.
DQx
Input
Output
Level
—
Data Input/Output pins operate in the same manner as on conventional
DRAMs.
Active
High
The Data Input/Output mask places the DQ buffers in a high impedance
state when sampled high. In Read mode, DQM has a latency of two clock
cycles and controls the output buffers like an output enable. In Write
mode, DQM has a latency of zero and operates as a word mask by
allowing input data to be written if it is low but blocks the write operation if
DQM is high.
LDQM,
UDQM
Input
VDD,
VSS
Supply
VDDQ
VSSQ
Supply
Pulse
Power and ground for the input buffers and the core logic.
—
Semiconductor Group
—
Power supply and ground for the output buffers to provide improved noise
immunity.
3
HYB39S16160CT-6/-7
16MBit Synchronous DRAM
Row Decoder
Row Decoder
Row Decoder
Row Decoder
CKE Buffer
2048
Sense Amplifiers
Sense Amplifiers
Sense Amplifiers
Column Decoder
Sense
and
Amplifiers
DQ Gate
Column Decoder and DQ Gate
Column Decoder and DQ Gate
Column Decoder and DQ Gate
16
Bank A
Row/Column
Select
CLK Buffer
8
16
CS
Address Buffers (12)
3
12
Sequential
Control
Bank A
8
8
8
Data Latches
Data Latches
Data Latches
Data Latches
11 Predecode A
A0
A1
A2
A3
A4
A5
A6
A7
A8
A9
A10
A11 (BS)
256
CLK
1024
Row
Address
Counter
16
512
1024
Self
Refresh Clock
16
8
12
Mode Register
11
8
CS Buffer
3
Sequential
Control
Bank B
16
Data Latches
Data Latches
CAS
CAS Buffer
WE
WE Buffer
UDQM
DQM Buffer
LDQM
DQM Buffer
16
Bank B
Row/Column
Select
Column Decoder and DQ Gate
Column Decoder and DQ Gate
Sense Amplifiers
Sense Amplifiers
16
256
RAS Buffer
8
Row Decoder
Row Decoder
Row Decoder
Row Decoder
RAS
Command Decoder
11 Predecode B
2048
Memory Bank B
Memory Bank B
2048
x 256
Memory
Bank
B
2048
x 1024
Memory
2048Bank
x 512B
2048 x 1024
Block Diagram for HYB39S16160CT (2 banks x 512k x 16 SDRAM)
Semiconductor Group
4
Data Input/Output Buffers
CKE
2048 x 512
Memory Bank A
2048 x 256
Memory Bank A
DQ0
DQ1
DQ2
DQ3
DQ4
DQ5
DQ6
DQ7
DQ8
DQ9
DQ10
DQ11
DQ12
DQ13
DQ14
DQ15
HYB39S16160CT-6/-7
16MBit Synchronous DRAM
Operation Definition
All of SDRAM operations are defined by states of control signals CS, RAS, CAS, WE, and DQM at
the positive edge of the clock. The following list shows the most important operation commands.
Operation
CS
RAS
CAS
WE
(L/U)DQM
Standby, Ignore RAS, CAS, WE and Address
H
X
X
X
X
Row Address Strobe and Activating a Bank
L
L
H
H
X
Column Address Strobe and Read Command
L
H
L
H
X
Column Address Strobe and Write Command
L
H
L
L
X
Precharge Command
L
L
H
L
X
Burst Stop Command
L
H
H
L
X
Self Refresh Entry
L
L
L
H
X
Mode Register Set Command
L
L
L
L
X
Write Enable/Output Enable
X
X
X
X
L
Write Inhibit/Output Disable
X
X
X
X
H
No Operation (NOP)
L
H
H
H
X
Mode Register
For application flexibility, a CAS latency, a burst length, and a burst sequence can be
programmed in the SDRAM mode register. The mode set operation must be done before any
activate command after the initial power up. Any content of the mode register can be altered by reexecuting the mode set command. Both banks must be in precharged state and CKE must be high
at least one clock before the mode set operation. After the mode register is set, a Standby or NOP
command is required. Low signals of RAS, CAS, and WE at the positive edge of the clock activate
the mode set operation. Address input data at this timing defines parameters to be set as shown in
the following table.
Semiconductor Group
5
HYB39S16160CT-6/-7
16MBit Synchronous DRAM
Address Input for Mode Set (Mode Register Operation)
BS A10 A9
A8
A7
A6
Operation Mode
A5
A4
A3
A2
CAS Latency
BT
Burst Length
Operation Mode
0
X
X
0
0
1
A0
Address Bus (Ax)
Mode Register (Mx)
Burst Type
M11 M10 M9 M8 M7
0
A1
0
Mode
M3
Type
0
Normal
0
Sequential
1
Interleave
0
Multiple Burst
with Single
Write
Burst Length
CAS Latency
M6
M5
M4
Latency
0
0
0
Reserve
0
0
1
1
0
1
0
2
0
1
1
3
1
0
0
Reserve
1
0
1
Reserve
1
1
0
Reserve
1
1
1
Reserve
M2
M1
M0
0
0
0
Length
Sequential
Interleave
0
1
1
0
1
2
2
0
1
0
4
4
0
1
1
8
8
1
0
0
Reserve
Reserve
1
0
1
Reserve
Reserve
1
1
0
Reserve
Reserve
1
1
1
Full Page*)
Sequential Burst Addressing
Interleave Burst Addressing
0
1
2
3
4
5
6
7
0
1
2
3
4
5
6
7
1
2
3
4
5
6
7
0
Semiconductor Group
2
3
4
5
6
7
0
1
3
4
5
6
7
0
1
2
4
5
6
7
0
1
2
3
5
6
7
0
1
2
3
4
6
7
0
1
2
3
4
5
7
0
1
2
3
4
5
6
6
1
0
3
2
5
4
7
6
2
3
0
1
6
7
4
5
3
2
1
0
7
6
5
4
4
5
6
7
0
1
2
3
5
4
7
6
1
0
3
2
6
7
4
5
2
3
0
1
7
6
5
4
3
2
1
0
Reserve
*) optional
HYB39S16160CT-6/-7
16MBit Synchronous DRAM
Read and Write Access Mode
When RAS is low and both CAS and WE are high at the positive edge of the clock, a RAS cycle
starts. According to address data, a word line of the selected bank is activated and all of sense
amplifiers associated to the word line are fired. A CAS cycle is triggered by setting RAS high and
CAS low at a clock timing after a necessary delay, tRCD, from the RAS timing. WE is used to define
either a read (WE = H) or a write (WE = L) at this stage.
SDRAM provides a wide variety of fast access modes. In a single CAS cycle, serial data read
or write operations are allowed at up to a 166 MHz data rate. The numbers of serial data bits are the
burst length programmed at the mode set operation, i.e., one of 1, 2, 4, 8 and full page, where full
page is an optional feature in this device. Column addresses are segmented by the burst length and
serial data accesses are done within this boundary. The first column address to be accessed is
supplied at the CAS timing and the subsequent addresses are generated automatically by the
programmed burst length and its sequence. For example, in a burst length of 8 with interleave
sequence, if the first address is ‘2’, then the rest of the burst sequence is 3, 0, 1, 6, 7, 4, and 5 .
Full page burst operation is only possible using the sequential burst type and page length is
a function of the I/O organisation and column addressing. Full page burst operation do not self
terminate once the burst length has been reached. In other words, unlike burst length of 2, 3 or 8,
full page burst continues until it is terminated using another command.
Similar to the page mode of conventional DRAM’s, burst read or write accesses on any column
address are possible once the RAS cycle latches sense amplifiers. The maximum tRAS or the
refresh interval time limits the number of random column accesses. A new burst access can be
done even before the previous burst ends. The interrupt operation at every clock cycles is
supported. When the previous burst is interrupted, the remaining addresses are overridden by the
new address with the full burst length. An interrupt which accompanies with an operation change
from a read to a write is possible by exploiting DQM to avoid bus contention.
When two banks are activated sequentially, interleaved bank read or write operations are
possible. With the programmed burst length, alternate access and precharge operations on two
banks can realize fast serial data access modes among many different pages. Once two banks are
activated, column to column interleave operation can be done between two different pages.
Refresh Mode
SDRAM has two refresh modes, a CAS before RAS (CBR) automatic refresh and a self refresh.
All of banks must be precharged before applying any refresh mode. An on-chip address counter
increments the word and the bank addresses and no bank information is required for both refresh
modes. The chip enters the automatic refresh mode, when RAS and CAS are held low and CKE and
WE are held high at a clock timing. The mode restores word line after the refresh and no external
precharge command is necessary. A minimum tRC time is required between two automatic
refreshes in a burst refresh mode. The same rule applies to any access command after the
automatic refresh operation.
The chip has an on-chip timer and the self refresh mode is available. It enters the mode when
RAS, CAS, and CKE are low and WE is high at a clock timing. All of external control signals
including the clock are disabled. Returning CKE to high enables the clock and initiates the refresh
exit operation. After the exit command, at least one tRC delay is required prior to any access
command.
Semiconductor Group
7
HYB39S16160CT-6/-7
16MBit Synchronous DRAM
DQM Function
DQM has two functions for data I/O read write operations. During reads, when it turns to high
at a clock timing, data outputs are disabled and become high impedance after two clock delay (DQM
Data Disable Latency tDQZ). It also provides a data mask function for writes. When DQM is
activated, the write operation at the next clock is prohibited (DQM Write Mask Latency tDQW = zero
clocks).
Suspend Mode
During normal access mode, CKE is held high and CLK is enabled. When CKE is low, it freezes
the internal clock and extends data read and write operations. One clock delay is required for mode
entry and exit (Clock Suspend Latency tCSL).
Power Down
In order to reduce standby power consumption, a power down mode is available. Bringing CKE
low enters the power down mode and all of receiver circuits are gated. All banks must be
precharged before entering this mode. One clock delay is required for mode entry and exit. The
Power Down mode does not perform any refresh operation.
Auto Precharge
Two methods are available to precharge SDRAMs. In an automatic precharge mode, the CAS
timing accepts one extra address, CA10, to determine whether the chip restores or not after the
operation. If CA10 is high when a Read Command is issued, the Read with Auto-Precharge
function is initiated. The SDRAM automatically enters the precharge operation one clock before the
last data out for CAS latency 2 amd two clocks for CAS latency 3. If CAS10 is high when a Write
Command is issued, the Write with Auto-Precharge function is initiated. The SDRAM
automatically enters the precharge operation one clock delay form the last data-in for CAS latencies
of 1 and 2 and two clocks for CAS latencies of 3. This delay is referenced as tDPL .
Precharge Command
If CA10 is low, the chip needs another way to precharge. In this mode, a separate precharge
command is necessary. When RAS and WE are low and CAS is high at a clock timing, it triggers the
precharge operation. Two address bits, A10 and A11, are used to define banks as shown in the
following list. The precharge command may be applied coincident with the last of burst reads for
CAS Latency = 1 and with the second to the last read data for CAS Latencies = 2 & 3. Writes require
a time tWR from the last burst data to apply the precharge command.
Bank Selection by Address Bits
A10
Semiconductor Group
A11
Bank A Only
Low
Low
Bank B Only
Low
High
Both A and B
High
Don’t Care
8
HYB39S16160CT-6/-7
16MBit Synchronous DRAM
Burst Termination
Once a burst read or write operation has been initiated, there are several methods in which to
terminate the burst operation prematurely. These methods include using another Read or Write
Command to interrupt an existing burst operation, use a Precharge Command to interrupt a burst
cycle and close the active bank, or using the Burst Stop Command to terminate the existing burst
operation but leave the bank open for future Read or Write Commands to the same page of the
active bank. When interrupting a burst with another Read or Write Command care must be taken to
avoid DQ contention. The Burst Stop Command, however, has the fewest restrictions making it the
easiest method to use when terminating a burst operation before it has been completed. If a Burst
Stop command is issued during a burst write operation, then any residual data from the burst write
cycle will be ignored. Data that is presented on the DQ pins before the Burst Stop Command is
registered will be written to the memory.
Power Up Procedure
All Vdd and Vddq must reach the specified voltage no later than any of input signal voltages. An
initial pause of 200 µsec is required after power on. All banks have to be precharged and a minimum
of 8 auto-refresh cycles are required prior to the mode register set operation.
Semiconductor Group
9
HYB39S16160CT-6/-7
16MBit Synchronous DRAM
Absolute Maximum Ratings
Operating temperature range......................................................................................... 0 to + 70 °C
Storage temperature range..................................................................................... – 55 to + 150 °C
Input/output voltage .............................................................................. – 0.5 to min(Vcc+0.5, 4.6) V
Power supply voltage VDD / VDDQ.......................................................................... – 1.0 to + 4.6 V
Power Dissipation............................................. ..........................................................................1 W
Data out current (short circuit) ................................................................................................ 50 mA
Note: Stresses above those listed under “Absolute Maximum Ratings” may cause permanent
damage of the device. Exposure to absolute maximum rating conditions for extended periods
may affect device reliability.
Recommended Operation and Characteristics for LV-TTL versions:
TA = 0 to 70 °C; VSS = 0 V; VDD,VDDQ = 3.3 V ± 0.3 V
Parameter
Symbol
Limit Values
Unit Notes
min.
max.
Input high voltage
VIH
2.0
Vcc+0.3
V
1, 2, 3
Input low voltage
VIL
– 0.3
0.8
V
1, 2, 3
Output high voltage (IOUT = – 2.0 mA)
VOH
2.4
–
V
3
Output low voltage (IOUT = 2.0 mA)
VOL
–
0.4
V
3
Input leakage current, any input
(0 V < VIN < Vddq, all other inputs = 0 V)
II(L)
–5
5
µA
Output leakage current
(DQ is disabled, 0 V < VOUT < VCC)
IO(L)
–5
5
µA
Notes:
1. All voltages are referenced to VSS.
2. Vih may overshoot to Vcc + 2.0 V for pulse width of < 4ns with 3.3V. Vil may undershoot to
-2.0 V for pulse width < 4.0 ns with 3.3V. Pulse width measured at 50% points with amplitude measured peak
to DC reference.
Capacitance
TA = 0 to 70 °C; VDD = 3.3 V ± 0.3 V, f = 1 MHz
Parameter
Symbol
Values
Unit
min.
max.
Input capacitance (CLK)
CI1
2.5
4.0
pF
Input capacitance
CI2
2.5
5.0
pF
CIO
4.0
6.5
pF
(A0-A12, BA0,BA1,RAS, CAS, WE, CS, CKE, DQM,
UDQM, LDQM)
Input / Output capacitance (DQ)
Semiconductor Group
10
HYB39S16160CT-6/-7
16MBit Synchronous DRAM
Operating Currents (TA = 0 to 70oC, VCC = 3.3V ± 0.3V
(Recommended Operating Conditions unless otherwise noted)
Parameter
Symbol
Test Condition
CAS
Latency
Note
max. max.
130
mA
CKE<=VIL(max),
tck>=tck(min.)
2
2
mA
Icc2PS CKE<=VIL(max),
1
1
mA
15
15
mA CS=
Icc1
Precharge
Standby Current
in Power Down
Mode
Icc2P
Active Standby
Current in Power
Down Mode
-7
150
Operating Current
Precharge
Standby Current
in Non-power
down Mode
-6
Burst Length = 4
trc>=trc (min.)
tck>=tck(min.), Io = 0mA
2 bank interleave operation
1, 2
tCK=infinite
Icc2N
CKE>=VIH(min),
tck>=tck(min.) input signals
changed once in 3 cycles
Icc2NS CKE>=VIH(min),
High
5
5
mA
CKE<=VIL(max),
tck>=tck(min.)
3
3
mA
Icc3PS CKE<=VIL(max),
2
2
mA
25
25
mA CS=
tCK=infinite, input signals
are stable
Icc3P
tCK=infinite, inpit signals
are stable
Active Standby
Current in Nonpower Down
Mode
Icc3N
CKE>=VIH(min),
tck>=tck(min.),
changed once in 3 cycles
Icc3NS CKE>=VIH(min),
High,
1
15
15
mA
100
85
mA
1, 2
60
50
mA
mA
1, 2
1
1
mA
1, 2
tCK=infinite, input signals
are stable
Burst Operating
Current
Icc4
Burst Length = full page
trc = infinite
tck >= tck (min.), IO = 0 mA
2 banks activated
Auto (CBR)
Refresh Current
Icc5
trc>=trc(min)
Self Refresh
Icc6
CKE=<0,2V
Notes:
1. The specified values are valid when addresses are changed no more than three times during trc(min.) and
when No Operation commands are registered on every rising clock edge during tRC(min).
2. The specified values are valid when data inputs (DQ’s) are stable during tRC(min.).
Semiconductor Group
11
HYB39S16160CT-6/-7
16MBit Synchronous DRAM
AC Characteristics 1)2)3)
TA = 0 to 70 °C; VSS = 0 V; VCC = 3.3 V ± 0.3 V, tT = 1 ns
Parameter
Limit Values
Symbol
-6
Unit
-7
min
max
min
max
CAS Latency = 3 tCK
CAS Latency = 2
6
8
–
–
7
9
–
–
CAS Latency = 3 tCK
CAS Latency = 2
–
–
166
125
–
–
143
115
Access Time from Clock
CAS Latency = 3 tAC
CAS Latency = 2
–
–
5
6
–
–
5
6
ns
ns
Clock High Pulse Width
tCH
2
–
2.5
–
ns
Clock Low Pulse Width
tCL
2
–
2.5
–
ns
Transition time
tT
0.5
10
0.5
10
ns
Input Setup Time
tIS
2
–
2
–
ns
5
Input Hold Time
tIH
1
–
1
–
ns
5
CKE Setup Time
tCKS
2
–
2
–
ns
5
CKE Hold Time
tCKH
1
–
1
–
ns
5
Mode Register Set-up time
tRSC
12
–
24
–
ns
Power Down Mode Entry Time
tSB
0
6
0
7
ns
Row to Column Delay Time
tRCD
16
–
18
–
ns
Row Precharge Time
tRP
16
–
18
–
ns
Row Active Time
tRAS
36
100k
42
100k
ns
Row Cycle Time
tRC
54
–
63
–
ns
Activate(a) to Activate(b) Command
period
tRRD
12
–
14
–
ns
CAS(a) to CAS(b) Command period
tCCD
1
–
1
–
CLK
Clock and Clock Enable
Clock Cycle Time
ns
ns
Clock Frequency
MHz
MHz
2,
4
Setup and Hold Times
Common Parameters
Semiconductor Group
12
HYB39S16160CT-6/-7
16MBit Synchronous DRAM
Parameter
Limit Values
Symbol
-6
Unit
-7
min
max
min
max
64
–
64
Refresh Cycle
Refresh Period
(4096 cycles)
tREF
–
Self Refresh Exit Time
tSREX
10
Data Out Hold Time
tOH
2
–
2.5
–
ns
Data Out to Low Impedance Time
tLZ
0
–
0
–
ns
Data Out to High Impedance Time
tHZ
2
6
2
7
ns
DQM Data Out Disable Latency
tDQZ
–
2
–
2
CLK
Write Recovery Time
tWR
6
–
7
–
ns
DQM Write Mask Latency
tDQW
0
–
0
–
CLK
Write Latency
tWL
0
–
0
–
CLK
ms
10
ns
Read Cycle
2
8
Write Cycle
Frequency vs. AC Parameter Relationship Table:
-6 -parts
CL
tRCD
tRP
tRC
tRAS
tRRD
tCCD
WL
tWR
166 MHz
3
3
3
9
6
2
1
0
1
125 MHz
2
2
2
7
5
2
1
0
1
CL
tRCD
tRP
tRC
tRAS
tRRD
tCCD
WL
tWR
143 MHz
3
3
3
9
6
2
1
0
1
115 MHz
2
2
2
7
5
2
1
0
1
-7 -parts:
Semiconductor Group
13
HYB39S16160CT-6/-7
16MBit Synchronous DRAM
Notes for AC Parameters:
1. For proper power-up see the operation section of this data sheet.
2. AC timing tests for LV-TTL versions have Vil = 0.4 V and Vih = 2.4 V with the timing referenced to the 1.5 V
crossover point. The transition time is measured between Vih and Vil. All AC measurements assume tT=1ns
with the AC output load circuit shown in fig.1. Specified tac and toh parameters are measured with a 30 pF only,
without any resistive termination and with a input signal of 1V / ns edge rate between 0.8V and 2.0 V..
tCH
+ 1.5 V
2.4 V
CLOCK
0.4 V
tCL
tSETUP
50 Ohm
tT
Z=50 Ohm
tHOLD
I/O
30 pF
1.5V
INPUT
I/O
tAC
tAC
tLZ
30 pF
tOH
1.5V
OUTPUT
Measurement conditions for
tac and toh
fig.1
tHZ
3. If clock rising time is longer than 1 ns, a time (tT/2 - 0.5) ns has to be added to this parameter.
4. If tT is longer than 1 ns, a time (tT -1) ns has to be added to this parameter.
5. These parameter account for the number of clock cycle and depend on the operating frequency of the clock,
as follows:
the number of clock cycle = specified value of timing period (counted in fractions as a whole number)
Self Refresh Exit is a synchronous operation and begins on the 2nd positive clock edge after CKE returns high.
Self Refresh Exit is not complete until a time period equal to tRC is satisfied once the Self Refresh Exit
command is registered.
Semiconductor Group
14
HYB39S16160CT-6/-7
16MBit Synchronous DRAM
Package Outlines:
0.8
0.4 +- 0.05
0.1
M
50
50x
0.1
26
20.95 ± 0.131)
25
GPX05956
Index Marking
1) Does not include plastic or metal protrusion of 0.25 max. per side
Semiconductor Group
3
0.5 ± 0.1
11.76 ± 0.2
0.2
1
10.16 ± 0.13
0.06
0.15 +- 0.0
0.1± 0.05
1± 0.05
1.2 max.
Plastic Package P-TSOPII-50
(400 mil, 0.8 mm lead pitch)
Thin Small Outline Package, SMD
15