IDT IDT72T36135ML6BBG 2.5v 18m-bit high-speed terasync fifo 36-bit configurations 524,288 x 36 Datasheet

2.5V 18M-BIT HIGH-SPEED TeraSyncTM
FIFO 36-BIT CONFIGURATIONS
IDT72T36135M
524,288 x 36
FEATURES:
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Industry’s largest FIFO memory organization:
IDT72T36135  524,288 x 36 - 18M-bits
Up to 200 MHz Operation of Clocks
Functionally and pin compatible to 9Mbit IDT72T36125 TeraSync
devices
User selectable HSTL/LVTTL Input and/or Output
User selectable Asynchronous read and/or write port timing
Mark & Retransmit, resets read pointer to user marked position
Write Chip Select (WCS) input disables Write Port
Read Chip Select (RCS) synchronous to RCLK
Programmable Almost-Empty and Almost-Full flags, each flag can
default to one of eight preselected offsets
Program programmable flags by either serial or parallel means
Selectable synchronous/asynchronous timing modes for AlmostEmpty and Almost-Full flags
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Separate SCLK input for Serial programming of flag offsets
Auto power down minimizes standby power consumption
Master Reset clears entire FIFO
Partial Reset clears data, but retains programmable settings
Empty and Full flags signal FIFO status
Select IDT Standard timing (using EF[1:2] and FF[1:2] flags) or First
Word Fall Through timing (using OR[1:2] and IR[1:2] flags)
Output enable puts data outputs into high impedance state
JTAG port, provided for Boundary Scan function
Available in 240-pin (19mm x 19mm)Plastic Ball Grid Array (PBGA)
50% more space saving than the leading 9M-bit FIFOs
Independent Read and Write Clocks (permit reading and writing
simultaneously)
High-performance submicron CMOS technology
Industrial temperature range (–40°°C to +85°°C) is available
Green parts available, see ordering information
FUNCTIONAL BLOCK DIAGRAM
D0 -Dn (x36)
LD
WEN WCLK/WR
SEN SCLK
WCS
INPUT REGISTER
ASYW
WRITE CONTROL
LOGIC
PRS
TCK
TRST
TMS
TDO
TDI
Vref
WHSTL
RHSTL
SHSTL
FWFT/SI
PFM
FSEL0
FSEL1
RAM ARRAY
524,288 x 36
READ POINTER
RESET
LOGIC
JTAG CONTROL
(BOUNDARY
SCAN)
FF/IR[1:2]
PAF[1:2]
EF/OR[1:2]
PAE[1:2]
FLAG
LOGIC
WRITE POINTER
MRS
OFFSET REGISTER
OUTPUT REGISTER
RT
MARK
ASYR
READ
CONTROL
LOGIC
HSTL I/0
CONTROL
RCLK/RD
REN
RCS
6723 drw01
OE
Q0 -Qn (x36)
IDT and the IDT logo are trademarks of Integrated Device Technology, Inc. The TeraSync FIFO is a trademark of Integrated Device Technology, Inc.
COMMERCIAL AND INDUSTRIAL TEMPERATURE RANGES
1
 2006 Integrated Device Technology, Inc. All rights reserved. Product specifications subject to change without notice.
MAY 2006
DSC-6723/3
 36-BIT FIFO
IDT72T36135M 2.5V 18M-BIT TeraSync
524,288 x 36
COMMERCIAL AND INDUSTRIAL
TEMPERATURE RANGES
PIN CONFIGURATION
A1 BALL PAD CORNER
A
GND
FF1
FF2
RCLK
OE
VDDQ
VDDQ
VDDQ
VDDQ
MRS
GND
PAF1
EF1
REN
RCS
VDDQ
VDDQ
VDDQ
VDDQ
LD
GND
PAF2 PAE1
MARK
RT
VDDQ
VDDQ
VDDQ
EF2
RHSTL
ASYR
PFM
PRS
VDDQ
VCC
VCC
VCC
VCC
VCC
VCC
WCLK
VCC
VCC
VCC
VCC
VCC
VCC
WEN
VCC
VCC
VCC
VCC
VCC
VCC
WCS
VCC
VCC
VCC
VCC
VCC
VCC
GND
GND
VDDQ
VCC
VCC
VCC
GND
GND
VDDQ
VDDQ
VCC
SEN
SCLK
WHSTL
GND
VDDQ
VDDQ
VDDQ
VCC
VCC
ASYW
GND
GND
GND
GND
GND
VDDQ
VDDQ
VDDQ
VCC
VCC
VCC
VREF
GND
GND
GND
GND
GND
VDDQ
VDDQ
VDDQ
VCC
VCC
VCC
DNC
GND
GND
GND
GND
GND
VDDQ
VDDQ
VDDQ
D33
D34
D35
GND
GND
GND
GND
GND
GND
VDDQ
Q35
Q34
D30
D31
D32
GND
GND
Q33
Q32
Q31
D27
D28
D29
GND
GND
Q30
Q29
Q28
D24
D25
D26
GND
GND
Q27
Q26
Q25
D21
D22
D23
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
Q24
Q23
Q22
D19
D20
D13
D10
D5
D4
D1
TMS
TDO
GND
Q0
Q2
Q3
Q8
Q11
Q14
Q21
Q20
D18
D17
D14
D11
D7
D8
D2
TRST
TDI
GND
Q1
Q6
Q5
Q9
Q12
Q15
Q18
Q19
VCC
D16
D15
D12
D9
D6
D3
D0
TCK
GND
DNC
Q4
Q7
Q10
Q13
Q16
Q17
VDDQ
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
B
VDDQ
C
VDDQ
VDDQ
VDDQ
VDDQ
VDDQ
VDDQ
D
FWFT/SI DNC
FSEL0 SHSTL
FSEL1 GND
GND
PAE2
VDDQ
E
F
VDDQ
G
H
VCC
J
K
L
M
N
P
R
T
U
V
1
2
18
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NOTE:
1. DNC - Do Not Connect.
PBGA: 1mm pitch, 19mm x 19mm (BB240-1, order code: BB)
TOP VIEW
2
MAY 29, 2006
 36-BIT FIFO
IDT72T36135M 2.5V 18M-BIT TeraSync
524,288 x 36
COMMERCIAL AND INDUSTRIAL
TEMPERATURE RANGES
DESCRIPTION:
For applications requiring more data storage capacity than a single FIFO
can provide, the FWFT timing mode permits depth expansion by chaining FIFOs
in series (i.e. the data outputs of one FIFO are connected to the corresponding
data inputs of the next). No external logic is required.
The 18M-bit TeraSync FIFO has 8 flag pins, EF/OR[1:2] (Empty Flag or
Output Ready), FF/IR[1:2] (Full Flag or Input Ready), PAE[1:2] (Programmable Almost-Empty flag) and PAF[1:2] (Programmable Almost-Full flag). The
EF[1:2] and FF[1:2] functions are selected in IDT Standard mode. The IR[1:2]
and OR[1:2] functions are selected in FWFT mode. PAE[1:2] and PAF[1:2] are
always available for use, irrespective of timing mode. Each flag has a double
because the 18M FIFO was designed as a Multi-chip Module, so each set of
flags supports its respective internal 9M FIFO. Some extra external gating logic
will have to be used to accurately read each flag output. This will be covered
in the flagging section of the datasheet.
PAE[1:2] and PAF[1:2] can be programmed independently to switch at any
point in memory. Programmable offsets determine the flag switching threshold
and can be loaded by two methods: parallel or serial. Eight default offset settings
are also provided, so that PAE[1:2] can be set to switch at a predefined number
of locations from the empty boundary and the PAF[1:2] threshold can also be
set at similar predefined values from the full boundary. The default offset values
are set during Master Reset by the state of the FSEL0, FSEL1, and LD pins.
For serial programming, SEN together with LD on each rising edge of
SCLK, are used to load the offset registers via the Serial Input (SI). For parallel
programming, WEN together with LD on each rising edge of WCLK, are used
to load the offset registers via Dn. REN together with LD on each rising edge
of RCLK can be used to read the offsets in parallel from Qn regardless of whether
serial or parallel offset loading has been selected.
During Master Reset (MRS) the following events occur: the read and write
pointers are set to the first location of the FIFO. The FWFT pin selects IDT
Standard mode or FWFT mode.
The Partial Reset (PRS) also sets the read and write pointers to the first
location of the memory. However, the timing mode, programmable flag
programming method, and default or programmed offset settings existing before
Partial Reset remain unchanged. The flags are updated according to the timing
mode and offsets in effect. PRS is useful for resetting a device in mid-operation,
when reprogramming programmable flags would be undesirable.
It is also possible to select the timing mode of the PAE[1:2] (Programmable
Almost-Empty flag) and PAF[1:2] (Programmable Almost-Full flag) outputs. The
timing modes can be set to be either asynchronous or synchronous for the
PAE[1:2] and PAF[1:2] flags.
If asynchronous PAE/PAF[1:2] configuration is selected, the PAE[1:2] is
asserted LOW on the LOW-to-HIGH transition of RCLK. PAE[1:2] is reset to
HIGH on the LOW-to-HIGH transition of WCLK. Similarly, the PAF[1:2] is
asserted LOW on the LOW-to-HIGH transition of WCLK and PAF[1:2] is reset
to HIGH on the LOW-to-HIGH transition of RCLK.
If synchronous PAE/PAF[1:2] configuration is selected , the PAE[1:2] is
asserted and updated on the rising edge of RCLK only and not WCLK. Similarly,
PAF[1:2] is asserted and updated on the rising edge of WCLK only and not
RCLK. The mode desired is configured during MasterReset by the state of the
Programmable Flag Mode (PFM) pin.
This device includes a Retransmit from Mark feature that utilizes two control
inputs, MARK and , RT (Retransmit). If the MARK input is enabled with respect
to the RCLK, the memory location being read at that point will be marked. Any
subsequent retransmit operation, RT goes LOW, will reset the read pointer to
this ‘marked’ location.
If, at any time, the FIFO is not actively performing an operation, the chip will
automatically power down. Once in the power down state, the standby supply
current consumption is minimized. Initiating any operation (by activating control
The IDT72T36135M is an exceptionally deep, extrememly high speed,
CMOS First-In-First-Out (FIFO) memoriy with clocked read and write controls
and a wide extended x36 bus to allow ample data flow. These FIFOs offer
several key user benefits:
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High density offering of 18 Mbit
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200MHz R/W Clocks supporting 7.2Gbps of data throughput
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User selectable MARK location for retransmit
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User selectable I/O structure for HSTL or LVTTL
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Asynchronous/Synchronous translation on the read or write ports
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The first word data latency period, from the time the first word is written
to an empty FIFO to the time it can be read, is fixed and short.
TeraSync FIFOs are particularly appropriate for network, video, telecommunications, data communications and other applications that need to buffer
large amounts of data at very high performance.
The input port can be selected as either a Synchronous (clocked) interface,
or Asynchronous interface. During Synchronous operation the input port is
controlled by a Write Clock (WCLK) input and a Write Enable (WEN) input. Data
present on the Dn data inputs is written into the FIFO on every rising edge of
WCLK when WEN is asserted. During Asynchronous operation only the WR
input is used to write data into the FIFO. Data is written on a rising edge of WR,
the WEN input should be tied to its active state, (LOW).
The input port can be selected for either 2.5V LVTTL or HSTL operation,
this operation is selected by the state of the WHSTL input during a master reset.
A Write Chip Select input (WCS) is provided for use when the write port is in
both LVTTL and HSTL modes. During operation the WCS input can be used
to disable write port inputs (data only).
The output port can be selected as either a Synchronous (clocked) interface,
or Asynchronous interface. During Synchronous operation the output port is
controlled by a Read Clock (RCLK) input and Read Enable (REN) input. Data
is read from the FIFO on every rising edge of RCLK when REN is asserted.
During Asynchronous operation only the RD input is used to read data from the
FIFO. Data is read on a rising edge of RD, the REN input should be tied to its
active state, LOW. When Asynchronous operation is selected on the output port
the FIFO must be configured for Standard IDT mode, also the RCS should be
tied LOW and the OE input used to provide three-state control of the outputs, Qn.
The output port can be selected for either 2.5V LVTTL or HSTL operation,
this operation is selected by the state of the RHSTL input during a master reset.
An Output Enable (OE) input is provided for three-state control of the outputs.
A Read Chip Select (RCS) input is also provided, the RCS input is synchronized
to the read clock, and also provides three-state control of the Qn data outputs.
When RCS is disabled, the data outputs will be high impedance. During
Asynchronous operation of the output port, RCS should be enabled, held LOW.
The frequencies of both the RCLK and the WCLK signals may vary from 0
to fMAX with complete independence. There are no restrictions on the frequency
of the one clock input with respect to the other.
There are two possible timing modes of operation with these devices: IDT
Standard mode and First Word Fall Through (FWFT) mode.
In IDT Standard mode, the first word written to an empty FIFO will not appear
on the data output lines unless a specific read operation is performed. A read
operation, which consists of activating REN and enabling a rising RCLK edge,
will shift the word from internal memory to the data output lines.
In FWFT mode, the first word written to an empty FIFO is clocked directly
to the data output lines after three transitions of the RCLK signal. A REN does
not have to be asserted for accessing the first word. However, subsequent
words written to the FIFO do require a LOW on REN for access. The state of
the FWFT/SI input during Master Reset determines the timing mode in use.
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MAY 29, 2006
 36-BIT FIFO
IDT72T36135M 2.5V 18M-BIT TeraSync
524,288 x 36
COMMERCIAL AND INDUSTRIAL
TEMPERATURE RANGES
DESCRIPTION (CONTINUED)
account for JTAG testing since the device is a MCM. Please see JTAG section
for further details.
The TeraSync FIFO has the capability of operating its ports (write and/or
read) in either LVTTL or HSTL mode, each ports selection independent of the
other. The write port selection is made via WHSTL and the read port selection
via RHSTL. An additional input HSTL is also provided, this allows the user to
select HSTL operation for other pins on the device (not associated with the write
or read ports).
The IDT72T36135M is fabricated using IDT’s high speed submicron CMOS
technology.
inputs) will immediately take the device out of the power down state.
Both an Asynchronous Output Enable pin (OE) and Synchronous Read
Chip Select pin (RCS) are provided on the FIFO. The Synchronous Read Chip
Select is synchronized to the RCLK. Both the output enable and read chip select
control the output buffer of the FIFO, causing the buffer to be either HIGH
impedance or LOW impedance.
A JTAG test port is provided, here the FIFO has fully functional Boundary
Scan feature, compliant with IEEE 1449.1 Standard Test Access Port and
Boundary Scan Architecture. Special consideration should be taken into
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MAY 29, 2006
 36-BIT FIFO
IDT72T36135M 2.5V 18M-BIT TeraSync
524,288 x 36
COMMERCIAL AND INDUSTRIAL
TEMPERATURE RANGES
PARTIAL RESET (PRS)
MASTER RESET (MRS)
WRITE CLOCK (WCLK/WR)
READ CLOCK (RCLK/RD)
WRITE ENABLE (WEN)
READ ENABLE (REN)
WRITE CHIP SELECT (WCS)
OUTPUT ENABLE (OE)
LOAD (LD)
(x36) DATA IN (D0 - Dn)
SERIAL CLOCK (SCLK)
READ CHIP SELECT (RCS)
IDT
72T36135M
(x36) DATA OUT (Q0 - Qn)
RCLK
REN
SERIAL ENABLE(SEN)
FIRST WORD FALL THROUGH/
SERIAL INPUT (FWFT/SI)
MARK
RETRANSMIT (RT)
EMPTY FLAG/OUTPUT READY (EF/OR[1:2])
PROGRAMMABLE ALMOST-EMPTY (PAE[1:2])
FULL FLAG/INPUT READY (FF/IR[1:2])
PROGRAMMABLE ALMOST-FULL (PAF[1:2])
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Figure 1. Single Device Configuration Signal Flow Diagram
5
MAY 29, 2006
 36-BIT FIFO
IDT72T36135M 2.5V 18M-BIT TeraSync
524,288 x 36
COMMERCIAL AND INDUSTRIAL
TEMPERATURE RANGES
PIN DESCRIPTION
Symbol
Name
I/O TYPE
Description
ASYR(1) Asynchronous
Read Port
LVTTL
INPUT
A HIGH on this input during Master Reset will select Synchronous read operation for the output port. A LOW
will select Asynchronous operation. If Asynchronous is selected the FIFO must operate in IDT Standard mode.
ASYW(1) Asynchronous
Write Port
LVTTL
INPUT
A HIGH on this input during Master Reset will select Synchronous write operation for the input port. A LOW
will select Asynchronous operation.
D0–D35 Data Inputs
HSTL-LVTTL Data inputs for a 36-bit bus.
INPUT
EF/OR Empty Flag/
[1:2]
Output Ready
HSTL-LVTTL In the IDT Standard mode, the EF[1:2] function is selected. EF[1:2] indicates whether or not the FIFO memory
OUTPUT is empty. In FWFT mode, the OR[1:2] function is selected. OR[1:2] indicates whether or not there is valid data
available at the outputs. Please see Flagging section for external gating instructions of these flags.
FF/IR
[1:2]
HSTL-LVTTL In the IDT Standard mode, the FF[1:2] function is selected. FF[1:2] indicates whether or not the FIFO memory
OUTPUT is full. In the FWFT mode, the IR[1:2] function is selected. IR[1:2] indicates whether or not there is space available
for writing to the FIFO memory. Please see Flagging section for external gating instructions of
these flags.
Full Flag/
Input Ready
FSEL0(1) Flag Select Bit 0
LVTTL
INPUT
During Master Reset, this input along with FSEL1 and the LD pin, will select the default offset values for the
programmable flags PAE[1:2] and PAF[1:2]. There are up to eight possible settings available.
FSEL1(1) Flag Select Bit 1
LVTTL
INPUT
During Master Reset, this input along with FSEL0 and the LD pin will select the default offset values for the
programmable flags PAE[1:2] and PAF[1:2]. There are up to eight possible settings available.
FWFT/
SI
First Word Fall
Through/Serial In
HSTL-LVTTL During Master Reset, selects First Word Fall Through or IDT Standard mode. After Master Reset, this pin
INPUT
functions as a serial input for loading offset registers. If Asynchronous operation of the read port has been
selected then the FIFO must be set-up in IDT Standard mode.
LD
Load
HSTL-LVTTL This is a dual purpose pin. During Master Reset, the state of the LD input along with FSEL0 and FSEL1,
INPUT
determines one of eight default offset values for the PAE[1:2] and PAF[1:2] flags, along with the method by which
these offset registers can be programmed, parallel or serial (see Table 1). After Master Reset, this pin enables
writing to and reading from the offset registers.
MARK
Mark for Retransmit HSTL-LVTTL When this pin is asserted the current location of the read pointer will be marked. Any subsequent Retransmit
INPUT
operation will reset the read pointer to this position.
MRS
Master Reset
HSTL-LVTTL MRS initializes the read and write pointers to zero and sets the output register to all zeroes. During Master
INPUT
Reset, the FIFO is configured for either FWFT or IDT Standard mode,Synchronous/Asynchronous operation
of the read or write port, one of eight programmable flag default settings, serial or parallel programming of
the offset settings, zero latency timing mode, and synchronous versus asynchronous programmable flag
timing modes.
OE
Output Enable
HSTL-LVTTL OE provides Asynchronous three-state control of the data outputs, Qn. During a Master or Partial Reset the
INPUT
OE input is the only input that provide High-Impedance control of the data outputs.
PAE
[1:2]
Programmable
HSTL-LVTTL PAE[1:2] goes LOW if the number of words in the FIFO memory is less than offset n, which is stored in the
Almost-Empty Flag
OUTPUT Empty Offset register. PAE[1:2] goes HIGH if the number of words in the FIFO memory is greater than or
equal to offset n. Please see Flagging section for external gating instructions of these flags.
PAF
[1:2]
Programmable
Almost-Full Flag
PFM(1)
Programmable
Flag Mode
PRS
Partial Reset
HSTL-LVTTL PAF[1:2] goes HIGH if the number of free locations in the FIFO memory is more than offset m, which is stored
OUTPUT in the Full Offset register. PAF[1:2] goes LOW if the number of free locations in the FIFO memory is less than
or equal to m. Please see Flagging section for external gating instructions of these flags.
LVTTL
INPUT
During Master Reset, a LOW on PFM will select Asynchronous Programmable flag timing mode. A HIGH on
PFM will select Synchronous Programmable flag timing mode.
HSTL-LVTTL PRS initializes the read and write pointers to zero and sets the output register to all zeroes. During Partial Reset,
INPUT
the existing mode (IDT or FWFT), programming method (serial or parallel), and programmable flag settings
are all retained.
Q0–Q35 Data Outputs
HSTL-LVTTL Data outputs for an 36-bit bus.
OUTPUT
RCLK/
RD
HSTL-LVTTL If Synchronous operation of the read port has been selected, when enabled by REN, the rising edge of RCLK
INPUT
reads data from the FIFO memory and offsets from the programmable registers. If LD is LOW, the values
loaded into the offset registers is output on a rising edge of RCLK.If Asynchronous operation of the read
Read Clock/
Read Stobe
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MAY 29, 2006
 36-BIT FIFO
IDT72T36135M 2.5V 18M-BIT TeraSync
524,288 x 36
COMMERCIAL AND INDUSTRIAL
TEMPERATURE RANGES
PIN DESCRIPTION (CONTINUED)
Symbol
Name
RCLK/
Read Clock/
RD
Read Strobe
I/O TYPE
Description
HSTL-LVTTL port has been selected, a rising edge on RD reads data from the FIFO in an Asynchronous manner.
INPUT
REN should be tied LOW.
RCS
Read Chip Select
HSTL-LVTTL RCS provides synchronous control of the read port and output impedance of Qn, synchronous to RCLK. During
INPUT
a Master Reset or Partial Reset the RCS input is don’t care, if OE is LOW the data outputs will be
Low-Impedance regardless of RCS.
REN
Read Enable
HSTL-LVTTL If Synchronous operation of the read port has been selected, REN enablesRCLK for reading data from the
INPUT
FIFO memory and offset registers. If Asynchronous operation of the read port has been selected, the REN
input should be tied LOW.
RHSTL(1) Read Port HSTL
Select
LVTTL
INPUT
This pin is used to select HSTL or 2.5v LVTTL outputs for the FIFO. If HSTL inputs are required, this input
must be tied HIGH. Otherwise it should be tied LOW.
RT
Retransmit
HSTL-LVTTL RT asserted on the rising edge of RCLK initializes the READ pointer to zero, sets the EF[1:2] flag to LOW
INPUT
(OR[1:2] to HIGH in FWFT mode) and doesn’t disturb the write pointer, programming method, existing timing
mode or programmable flag settings. If a mark has been set via the MARK input pin, then the read pointer will
jump to the ‘mark’ location.
SCLK
Serial Clock
HSTL-LVTTL A rising edge on SCLK will clock the serial data present on the SI input into the offset registers providing that
INPUT
SEN is enabled.
SEN
Serial Enable
HSTL-LVTTL SEN enables serial loading of programmable flag offsets.
INPUT
SHSTL
System HSTL
Select
TCK(2)
JTAG Clock
HSTL-LVTTL Clock input for JTAG function. TMS and TDI are sampled on the rising edge of TCK. Data is output on
INPUT
TDO on the falling edge.
TRST(2)
JTAG Reset
HSTL-LVTTL TRST is an asynchronous reset pin for the JTAG controller.
INPUT
TMS
JTAG Mode
Select
HSTL-LVTTL TMS is a serial input pin. Bits are serially loaded on the rising edge of TCK, which selects 1 of 5 modes of
INPUT
operation for the JTAG boundary scan.
TDI
Test Data Input
HSTL-LVTTL During JTAG boundary scan operation test data is serially loaded via TDI on the rising edge of TCK.
INPUT
This is also the data for the Instruction Register, ID Register and Bypass Register.
TDO
Test Data Output
HSTL-LVTTL During JTAG boundary scan operation test data is serially output via TDO on the falling edge of TCK.
OUTPUT This output is in High-Z except when shifting, while in SHIFT-DR and SHIFT-IR controller states.
WEN
Write Enable
HSTL-LVTTL When Synchronous operation of the write port has been selected, WEN enables WCLK for writing data into
INPUT
theFIFO memory and offset registers. If Asynchronous operation of the write port has been selected, the
WEN input should be tied LOW.
WCS
Write Chip Select
HSTL-LVTTL This pin disables the write port data inputs when the device write port is configured for HSTL mode. This
INPUT
provides added power savings.
WCLK/
WR
Write Clock/
Write Strobe
HSTL-LVTTL If Synchronous operation of the write port has been selected, when enabled by WEN, the rising edge of
INPUT
WCLK writes data into the FIFO. If Asynchronous operation of the write port has been selected, WR writes
data into the FIFO on a rising edge in an Asynchronous manner, (WEN should be tied to its active state).
LVTTL
INPUT
All inputs not associated with the write or read port can be selected for HSTL operation via the SHSTL input.
WHSTL(1) Write Port HSTL
Select
LVTTL
INPUT
This pin is used to select HSTL or 2.5V LVTTL inputs for the FIFO. If HSTL inputs are required, this input must
be tied HIGH. Otherwise it should be tied LOW.
Vcc
+2.5v Supply
Power
These are Vcc supply inputs and must be connected to the 2.5V supply rail.
GND
Ground Pin
GND
These are Ground pins an dmust be connected to the GND rail.
Vref
Reference
Voltage
I
This is a Voltage Reference input and must be connected to a voltage level determined from the table,
“Recommended DC Operating Conditions”. This provides the reference voltage when using HSTL class
inputs. If HSTL class inputs are not being used, this pin should be tied LOW.
VDDQ
O/P Rail Voltage
I
This pin should be tied to the desired voltage rail for providing power to the output drivers.
NOTES:
1. Inputs should not change state after Master Reset.
2. If the JTAG feature is not being used, TCK and TRST should be tied LOW.
7
MAY 29, 2006
 36-BIT FIFO
IDT72T36135M 2.5V 18M-BIT TeraSync
524,288 x 36
COMMERCIAL AND INDUSTRIAL
TEMPERATURE RANGES
ABSOLUTE MAXIMUM RATINGS
CAPACITANCE (TA = +25°C, f = 1.0MHz)
Symbol
VTERM
Rating
Terminal Voltage
with respect to GND
Commercial
–0.5 to +3.6(2)
Unit
V
CIN
TSTG
Storage Temperature
–55 to +125
°C
COUT(1,2)
IOUT
DC Output Current
–50 to +50
mA
Parameter(1)
Symbol
(2,3)
Conditions
Max.
(3)
Unit
Input
Capacitance
VIN = 0V
15
pF
Output
Capacitance
VOUT = 0V
10.5
pF
NOTES:
1. With output deselected, (OE ≥ VIH).
2. Characterized values, not currently tested.
3. CIN for Vref is 40pF.
NOTES:
1. Stresses greater than those listed under ABSOLUTE MAXIMUM RATINGS may cause
permanent damage to the device. This is a stress rating only and functional operation
of the device at these or any other conditions above those indicated in the operational
sections of this specification is not implied. Exposure to absolute maximum rating
conditions for extended periods may affect reliability.
2. Compliant with JEDEC JESD8-5. VCC terminal only.
RECOMMENDED DC OPERATING CONDITIONS
Symbol
VCC
GND
Parameter
Supply Voltage
Supply Voltage
Min.
2.375
0
Typ.
2.5
0
Max.
2.625
0
Unit
V
V
VIH
Input High Voltage
 LVTTL
 eHSTL
 HSTL
1.7
VREF+0.2
VREF+0.2
—
—
—
3.45
VDDQ+0.3
VDDQ+0.3
V
V
V
VIL
Input Low Voltage
 LVTTL
 eHSTL
 HSTL
-0.3
-0.3
-0.3
—
—
—
0.7
VREF-0.2
VREF-0.2
V
V
V
Voltage Reference Input
 eHSTL
 HSTL
0.8
0.68
0.9
0.75
1.0
0.9
V
V
0
—
70
°C
-40
—
85
°C
VREF(1)
TA
Operating Temperature Commercial
TA
Operating Temperature Industrial
NOTE:
1. VREF is only required for HSTL or eHSTL inputs. VREF should be tied LOW for LVTTL operation.
2. Outputs are not 3.3V tolerant.
8
MAY 29, 2006
 36-BIT FIFO
IDT72T36135M 2.5V 18M-BIT TeraSync
524,288 x 36
COMMERCIAL AND INDUSTRIAL
TEMPERATURE RANGES
DC ELECTRICAL CHARACTERISTICS
(Commercial: VCC = 2.5V ± 0.125V, TA = 0°C to +70°C;Industrial: VCC = 2.5V ± 0.125V, TA = -40°C to +85°C)
Symbol
Parameter
ILI
Input Leakage Current
ILO
Output Leakage Current
VOH(5)
Output Logic “1” Voltage,
VOL
Output Logic “0” Voltage,
ICC1(1,2)
Active VCC Current (VCC = 2.5V)
ICC2(1)
Standby VCC Current (VCC = 2.5V)
Min.
Max.
Unit
–10
10
µA
–10
10
µA
VDDQ -0.4
VDDQ -0.4
VDDQ -0.4
—
—
—
—
—
—
0.4V
0.4V
0.4V
V
V
V
V
V
V
I/O = LVTTL
I/O = HSTL
I/O = eHSTL
—
—
—
120
180
180
mA
mA
mA
I/O = LVTTL
I/O = HSTL
I/O = eHSTL
—
—
—
40
140
140
mA
mA
mA
IOH = –8 mA
IOH = –8 mA
IOH = –8 mA
IOL = 8 mA
IOL = 8 mA
IOL = 8 mA
@VDDQ = 2.5V ± 0.125V (LVTTL)
@VDDQ = 1.8V ± 0.1V (eHSTL)
@VDDQ = 1.5V ± 0.1V (HSTL)
@VDDQ = 2.5V ± 0.125V (LVTTL)
@VDDQ = 1.8V ± 0.1V (eHSTL)
@VDDQ = 1.5V ± 0.1V (HSTL)
NOTES:
1. Both WCLK and RCLK toggling at 20MHz. Data inputs toggling at 10MHz. WCS = HIGH, REN or RCS = HIGH.
2. For the IDT72T36105/72T36115/72T36135M, typical ICC1 calculation (with data outputs in Low-Impedance):
-3. For all devices, typical IDDQ calculation: with data outputs in High-Impedance: IDDQ (mA) = 0.15 x fs, fs = WCLK = RCLK frequency (in MHz)
with data outputs in Low-Impedance: IDDQ (mA) = (CL x VDDQ x fs x N)/2000
fs = WCLK = RCLK frequency (in MHz), VDDQ = 2.5V for LVTTL; 1.5V for HSTL; 1.8V for eHSTL, CL = capacitive load (pf), tA = 25°C,
N = Number of outputs switching.
4. Total Power consumed: PT = (VCC x ICC) + VDDQ x IDDQ).
5. Outputs are not 3.3V tolerant.
9
MAY 29, 2006
 36-BIT FIFO
IDT72T36135M 2.5V 18M-BIT TeraSync
524,288 x 36
COMMERCIAL AND INDUSTRIAL
TEMPERATURE RANGES
AC ELECTRICAL CHARACTERISTICS(1) — SYNCHRONOUS TIMING
(Commercial: VCC = 2.5V ± 5%, TA = 0°C to +70°C;Industrial: VCC = 2.5V ± 5%, TA = -40°C to +85°C)
Symbol
fC
tA
tCLK
tCLKH
tCLKL
tDS
tDH
tENS
tENH
tLDS
tLDH
tWCSS
tWCSH
fS
tSCLK
tSCKH
tSCKL
tSDS
tSDH
tSENS
tSENH
tRS
tRSS
tHRSS
tRSR
tRSF
tWFF
tREF
tPAFS
tPAES
tRCSLZ
tRCSHZ
tSKEW1
tSKEW2
Parameter
Clock Cycle Frequency (Synchronous)
Data Access Time
Clock Cycle Time
Clock High Time
Clock Low Time
Data Setup Time
Data Hold Time
Enable Setup Time
Enable Hold Time
Load Setup Time
Load Hold Time
WCS setup time
WCS hold time
Clock Cycle Frequency (SCLK)
Serial Clock Cycle
Serial Clock High
Serial Clock Low
Serial Data In Setup
Serial Data In Hold
Serial Enable Setup
Serial Enable Hold
Reset Pulse Width(3)
Reset Setup Time
HSTL Reset Setup Time
Reset Recovery Time
Reset to Flag and Output Time
Write Clock to FF[1:2] or IR[1:2]
Read Clock to EF[1:2] or OR[1:2]
Write Clock to Synchronous PAF[1:2]
Read Clock to Synchronous PAE[1:2]
RCLK to Active from High-Z(3)
RCLK to High-Z(3)
Skew time between RCLK and WCLK for EF[1:2] and FF[1:2]
Skew time between RCLK and WCLK for PAE[1:2] and PAF[1:2]
Commercial
Com’l & Ind’l
IDT72T36135ML5
IDT72T36135ML6
Min.
—
0.6
5
2.5
2.5
1.5
0.5
1.5
0.5
1.5
0.5
1.5
0.5
—
100
45
45
15
5
5
5
10
15
4
10
—
—
—
—
—
—
—
—
—
Max.
200
3.6
—
—
—
—
—
—
—
—
—
—
—
10
—
—
—
—
—
—
—
—
—
—
—
15
3.6
3.6
3.6
3.6
3.6
3.6
4
5
Min.
—
0.6
6
3.0
3.0
2.0
0.5
2.0
0.5
2.0
0.5
2.0
0.5
—
100
45
45
15
5
5
5
10
15
4
10
—
—
—
—
—
—
—
—
—
Max.
166
3.8
—
—
—
—
—
—
—
—
—
—
—
10
—
—
—
—
—
—
—
—
—
—
—
15
3.7
3.7
3.7
3.7
3.7
3.7
5
6
Unit
MHz
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
MHz
ns
ns
ns
ns
ns
ns
ns
ns
ns
µs
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
NOTES:
1. All AC timings apply to both Standard IDT mode and First Word Fall Through mode.
2. Pulse widths less than minimum values are not allowed.
3. Values guaranteed by design, not currently tested.
4. Industrial temperature range product for 6ns speed grade is available as a standard device. All other speed grades are available by special order.
10
MAY 29, 2006
 36-BIT FIFO
IDT72T36135M 2.5V 18M-BIT TeraSync
524,288 x 36
COMMERCIAL AND INDUSTRIAL
TEMPERATURE RANGES
AC ELECTRICAL CHARACTERISTICS  ASYNCHRONOUS TIMING
(Commercial: VCC = 2.5V ± 5%, TA = 0°C to +70°C;Industrial: VCC = 2.5V ± 5%, TA = -40°C to +85°C)
Commercial
IDT72T36135ML5
Symbol
fA
tAA
tCYC
tCYH
tCYL
tRPE
tFFA
tEFA
tPAFA
tPAEA
tOLZ
tOE
tOHZ
tHF
Parameter
Cycle Frequency (Asynchronous)
Data Access Time
Cycle Time
Cycle HIGH Time
Cycle LOW Time
Read Pulse after EF[1:2] HIGH
Clock to Asynchronous FF[1:2]
Clock to Asynchronous EF[1:2]
Clock to Asynchronous Programmable Almost-Full Flag
Clock to Asynchronous Programmable Almost-Empty Flag
Output Enable to Output in Low Z(3)
Output Enable to Output Valid
Output Enable to Output in High Z(3)
Clock to HF
Min.
—
0.6
12
5
5
10
—
—
—
—
0
—
—
—
Max.
83
10
—
—
—
—
10
10
10
10
—
3.6
3.6
10
Com’l & Ind’l
IDT72T36135ML6
Min.
—
0.6
15
7
7
12
—
—
—
—
0
—
—
—
Max.
66
12
—
—
—
—
12
12
12
12
—
3.8
3.8
12
Unit
MHz
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
NOTES:
1. All AC timings apply to both Standard IDT mode and First Word Fall Through mode.
2. Industrial temperature range product for 6ns speed grade is available as a standard device. All other speed grades are available by special order.
3. Values guaranteed by design, not currently tested.
11
MAY 29, 2006
 36-BIT FIFO
IDT72T36135M 2.5V 18M-BIT TeraSync
524,288 x 36
COMMERCIAL AND INDUSTRIAL
TEMPERATURE RANGES
HSTL
1.5V AC TEST CONDITIONS
AC TEST LOADS
VDDQ/2
Input Pulse Levels
Input Rise/Fall Times
Input Timing Reference Levels
Output Reference Levels
0.25 to 1.25V
0.4ns
0.75
VDDQ/2
50Ω
Z0 = 50Ω
I/O
10pF
6723 drw04
NOTE:
1. VDDQ = 1.5V±.
Figure 2a. AC Test Load
EXTENDED HSTL
1.8V AC TEST CONDITIONS
0.4 to 1.4V
0.4ns
0.9
VDDQ/2
∆tCD
(Typical, ns)
Input Pulse Levels
Input Rise/Fall Times
Input Timing Reference Levels
Output Reference Levels
6
5
4
3
2
1
NOTE:
1. VDDQ = 1.8V±.
20 30 50
200
6723 drw04a
Figure 2b. Lumped Capacitive Load, Typical Derating
2.5V LVTTL
2.5V AC TEST CONDITIONS
Input Pulse Levels
Input Rise/Fall Times
Input Timing Reference Levels
Output Reference Levels
80 100
Capacitance (pF)
GND to 2.5V
1ns
VCC/2
VDDQ/2
NOTE:
1. For LVTTL VCC = VDDQ.
12
MAY 29, 2006
 36-BIT FIFO
IDT72T36135M 2.5V 18M-BIT TeraSync
524,288 x 36
COMMERCIAL AND INDUSTRIAL
TEMPERATURE RANGES
OUTPUT ENABLE & DISABLE TIMING
Output
Enable
Output
Disable
VIH
OE
VIL
tOE & tOLZ
Output VCC
Normally
2
LOW
tOHZ
VCC
2
100mV
100mV
VOL
VOH
100mV
Output
Normally VCC
2
HIGH
100mV
VCC
2
6723 drw05
NOTES:
1. REN is HIGH.
2. RCS is LOW.
READ CHIP SELECT ENABLE & DISABLE TIMING
VIH
tENH
RCS
VIL
tENS
RCLK
tRCSHZ
tRCSLZ
Output VCC
Normally
2
LOW
Output
Normally VCC
2
HIGH
VCC
2
100mV
100mV
VOL
VOH
100mV
100mV
VCC
2
6723 drw06
NOTES:
1. REN is HIGH.
2. OE is LOW.
13
MAY 29, 2006
 36-BIT FIFO
IDT72T36135M 2.5V 18M-BIT TeraSync
524,288 x 36
COMMERCIAL AND INDUSTRIAL
TEMPERATURE RANGES
FUNCTIONAL DESCRIPTION
When the FIFO is full, the Full Flag (FF[1:2]) will go LOW, inhibiting further
write operations. If no reads are performed after a reset, FF[1:2] will go LOW
after D writes to the FIFO.
If the FIFO is full, the first read operation will cause FF[1:2] to go HIGH.
Subsequent read operations will cause PAF[1:2] to go HIGH at the conditions
described in Table 2. If further read operations occur, without write operations,
PAE[1:2] will go LOW when there are n words in the FIFO, where n is the empty
offset value. Continuing read operations will cause the FIFO to become empty.
When the last word has been read from the FIFO, the EF[1:2] will go LOW
inhibiting further read operations. REN is ignored when the FIFO is empty.
When configured in IDT Standard mode, the EF[1:2] and FF[1:2] outputs
are double register-buffered outputs.
Relevant timing diagrams for IDT Standard mode can be found in Figure
10, 11, 12 and 17.
TIMING MODES: IDT STANDARD vs FIRST WORD FALL THROUGH
(FWFT) MODE
The IDT72T36135M support two different timing modes of operation: IDT
Standard mode or First Word Fall Through (FWFT) mode. The selection of
which mode will operate is determined during Master Reset, by the state of the
FWFT/SI input.
If, at the time of Master Reset, FWFT/SI is LOW, then IDT Standard mode
will be selected. This mode uses the Empty Flag (EF[1:2]) to indicate whether
or not there are any words present in the FIFO. It also uses the Full Flag function
(FF[1:2]) to indicate whether or not the FIFO has any free space for writing. In
IDT Standard mode, every word read from the FIFO, including the first, must
be requested using the Read Enable (REN) and RCLK.
If, at the time of Master Reset, FWFT/SI is HIGH, then FWFT mode will be
selected. This mode uses Output Ready (OR[1:2]) to indicate whether or not
there is valid data at the data outputs (Qn). It also uses Input Ready (IR[1:2])
to indicate whether or not the FIFO has any free space for writing. In the FWFT
mode, the first word written to an empty FIFO goes directly to Qn after three RCLK
rising edges, REN = LOW is not necessary. Subsequent words must be
accessed using the Read Enable (REN) and RCLK.
Various signals, both input and output signals operate differently depending
on which timing mode is in effect.
FIRST WORD FALL THROUGH MODE (FWFT)
In this mode, the status flags, IR[1:2], PAF[1:2], PAE[1:2], and OR[1:2]
operate in the manner outlined in Table 3. To write data into to the FIFO, WEN
must be LOW. Data presented to the DATA IN lines will be clocked into the FIFO
on subsequent transitions of WCLK. After the first write is performed, the Output
Ready (OR[1:2]) flag will go LOW. Subsequent writes will continue to fill up the
FIFO. PAE[1:2] will go HIGH after n + 2 words have been loaded into the FIFO,
where n is the empty offset value. The default setting for these values are stated
in the footnote of Table 1. This parameter is also user programmable. See section
on Programmable Flag Offset Loading.
When the FIFO is full, the Input Ready (IR[1:2]) flag will go HIGH, inhibiting
further write operations. If no reads are performed after a reset, IR[1:2] will go
HIGH after D writes to the FIFO. Note that the additional word in FWFT mode
is due to the capacity of the memory plus output register.
If the FIFO is full, the first read operation will cause the IR[1:2] flag to go LOW.
Subsequent read operations will cause the PAF[1:2] to go HIGH at the conditions
described in Table 3. If further read operations occur, without write operations,
the PAE[1:2] will go LOW when there are n + 1 words in the FIFO, where n is
the empty offset value. Continuing read operations will cause the FIFO to
become empty. When the last word has been read from the FIFO, OR[1:2] will
go HIGH inhibiting further read operations. REN is ignored when the FIFO is
empty.
When configured in FWFT mode, the OR[1:2] flag output is triple registerbuffered, and the IR[1:2] flag output is double register-buffered.
Relevant timing diagrams for FWFT mode can be found in Figure 13, 14,
15 and 18.
IDT STANDARD MODE
In this mode, the status flags, FF[1:2], PAF[1:2], PAE[1:2], and EF[1:2]
operate in the manner outlined in Table 2. To write data into to the FIFO, Write
Enable (WEN) must be LOW. Data presented to the DATA IN lines will be clocked
into the FIFO on subsequent transitions of the Write Clock (WCLK). After the first
write is performed, the Empty Flag (EF[1:2]) will go HIGH. Subsequent writes
will continue to fill up the FIFO. The Programmable Almost-Empty flag (PAE[1:2])
will go HIGH after n + 1 words have been loaded into the FIFO, where n is the
empty offset value. The default setting for these values are stated in the footnote
of Table 1. This parameter is also user programmable. See section on
Programmable Flag Offset Loading.
Continuing to write data into the FIFO will cause the Programmable AlmostFull flag (PAF[1:2]) to go LOW. Again, if no reads are performed, the PAF[1:2]
will go LOW. The offset “m” is the full offset value. The default setting for these
values are stated in the footnote of Table 1. This parameter is also user
programmable. See section on Programmable Flag Offset Loading.
14
MAY 29, 2006
 36-BIT FIFO
IDT72T36135M 2.5V 18M-BIT TeraSync
524,288 x 36
COMMERCIAL AND INDUSTRIAL
TEMPERATURE RANGES
PROGRAMMING FLAG OFFSETS
Full and Empty Flag offset values are user programmable. The
IDT72T36135M have internal registers for these offsets. There are eight default
offset values selectable during Master Reset. These offset values are shown
in Table 1. Offset values can also be programmed into the FIFO in one of two
ways; serial or parallel loading method. The selection of the loading method is
done using the LD (Load) pin. During Master Reset, the state of the LD input
determines whether serial or parallel flag offset programming is enabled. A HIGH
on LD during Master Reset selects serial loading of offset values. A LOW on LD
during Master Reset selects parallel loading of offset values.
In addition to loading offset values into the FIFO, it is also possible to read
the current offset values. Offset values can be read via the parallel output port
Q0-Qn, regardless of the programming mode selected (serial or parallel). It is
not possible to read the offset values in serial fashion.
Figure 3, Programmable Flag Offset Programming Sequence, summaries
the control pins and sequence for both serial and parallel programming modes.
For a more detailed description, see discussion that follows.
The offset registers may be programmed (and reprogrammed) any time after
Master Reset, regardless of whether serial or parallel programming has been
selected. Valid programming ranges are from 0 to D-1.
SYNCHRONOUS vs ASYNCHRONOUS PROGRAMMABLE FLAG
TIMING SELECTION
The IDT72T36135M can be configured during the Master Reset cycle with
either synchronous or asynchronous timing for PAF[1:2] and PAE[1:2] flags by
use of the PFM pin.
If synchronous PAF/PAE[1:2] configuration is selected (PFM, HIGH during
MRS), the PAF is asserted and updated on the rising edge of WCLK only and
not RCLK. Similarly, PAE[1:2] is asserted and updated on the rising edge of
RCLK only and not WCLK. For detail timing diagrams, see Figure 22 for
synchronous PAF[1:2] timing and Figure 23 for synchronous PAE[1:2] timing.
If asynchronous PAF/PAE[1:2] configuration is selected (PFM, LOW during
MRS), the PAF is asserted LOW on the LOW-to-HIGH transition of WCLK and
PAF[1:2] is reset to HIGH on the LOW-to-HIGH transition of RCLK. Similarly,
PAE[1:2] is asserted LOW on the LOW-to-HIGH transition of RCLK. PAE[1:2]
is reset to HIGH on the LOW-to-HIGH transition of WCLK. For detail timing
diagrams, see Figure 24 for asynchronous PAF[1:2] timing and Figure 25 for
asynchronous PAE[1:2] timing.
TABLE 1 — DEFAULT PROGRAMMABLE TABLE 2 — STATUS FLAGS FOR IDT
FLAG OFFSETS
STANDARD MODE
IDT72T36135M
IDT72T36135M
*LD
H
L
L
L
L
H
H
H
FSEL1
L
H
L
L
H
H
L
H
FSEL0
L
L
H
L
H
L
H
H
Offsets n,m
1,023
511
255
127
63
31
15
7
*LD
H
L
FSEL1
X
X
FSEL0
X
X
Program Mode
Serial(3)
Parallel(4)
Number of
Words in
FIFO
FF
PAF PAE
EF
0
H
H
L
1 to n (1)
H
H
L
H
H
H
H
H
H
L
H
H
L
L
H
H
n + 1 to (524,288-(m+1))
(524,288-m) to 524,287
524,288
L
NOTE:
1. See Table 1 for values for n, m.
TABLE 3 — STATUS FLAGS FOR FWFT
MODE
IDT72T36135M
Number of
Words in
FIFO
*THIS PIN MUST BE HIGH AFTER MASTER RESET TO WRITE
OR READ DATA TO/FROM THE FIFO MEMORY.
L
H
1 to n+1
L
H
L
L
L
H
H
L
L
L
H
L
H
L
H
524,289
15
OR
H
n + 1 to (524,289-(m+1))
NOTE:
1. See Table 1 for values for n, m.
PAF PAE
L
(524,289-m) to 524,288
NOTES:
1. n = empty offset for PAE[1:2].
2. m = full offset for PAF[1:2].
3. As well as selecting serial programming mode, one of the default values will also
be loaded depending on the state of FSEL0 & FSEL1.
4. As well as selecting parallel programming mode, one of the default values will
also be loaded depending on the state of FSEL0 & FSEL1.
IR
0
L
6723 drw07
MAY 29, 2006
 36-BIT FIFO
IDT72T36135M 2.5V 18M-BIT TeraSync
524,288 x 36
COMMERCIAL AND INDUSTRIAL
TEMPERATURE RANGES
WCLK
LD
WEN
REN
SEN
0
0
1
1
0
1
0
1
X
0
1
1
0
X
X
1
1
1
1
0
X
X
1
X
0
X
X
1
1
1
X
X
IDT72T36135M
RCLK
SCLK
X
X
Parallel write to registers:
Empty Offset (LSB)
Empty Offset (MSB)
Full Offset (LSB)
Full Offset (MSB)
X
Parallel read from registers:
Empty Offset (LSB)
Empty Offset (MSB)
Full Offset (LSB)
Full Offset (MSB)
Serial shift into registers:
X
X
38 bits for the IDT72T36135M
1 bit for each rising SCLK edge
Starting with Empty Offset (LSB)
Ending with Full Offset (MSB)
X
X
No Operation
X
X
Write Memory
X
Read Memory
X
No Operation
X
6723 drw08
NOTES:
1. The programming method can only be selected at Master Reset.
2. Parallel reading of the offset registers is always permitted regardless of which programming method has been selected.
3. The programming sequence applies to both IDT Standard and FWFT modes.
1st Parallel Offset Write/Read Cycle
Data Inputs/Outputs
D/Q0
EMPTY OFFSET (LSB) REGISTER
16 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1
D/Q17
D/Q16
# of Bits Used
2nd Parallel Offset Write/Read Cycle
Data Inputs/Outputs
D/Q17
D/Q16
D/Q0
EMPTY OFFSET (MSB) REGISTER
4666 drw
06
19 18 17
3rd Parallel Offset Write/Read Cycle
Data Inputs/Outputs
FULL OFFSET (LSB) REGISTER
D/Q17
D/Q16
D/Q
0
16 15 14 13 12 11 10 9 8 7 6 5 4 3
2 1
4th Parallel Offset Write/Read Cycle
D/Q17
D/Q16
Data Inputs/Outputs
FULL OFFSET (MSB) REGISTER
4666 drw
06
D/Q
0
19 18 17
6723 drw09
NOTE:
1. Consecutive reads of the offset registers is not permitted. The read operation must be disabled for a minimum of
one RCLK cycle in between offset register accesses. (Please refer to Figure 21, Parallel Read of Programmable
Flag Registers (IDT Standard and FWFT Modes) for more details).
Figure 3. Programmable Flag Offset Programming Sequence
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COMMERCIAL AND INDUSTRIAL
TEMPERATURE RANGES
writing the previous mark location. Retransmit operation is available in both IDT
standard and FWFT modes.
During IDT standard mode the FIFO is put into retransmit mode by a Lowto-High transition on RCLK when the ‘MARK’ input is HIGH and EF[1:2] is HIGH.
The rising RCLK edge ‘marks’ the data present in the FIFO output register as
the first retransmit data. The FIFO remains in retransmit mode until a rising edge
on RCLK occurs while MARK is LOW.
Once a ‘marked’ location has been set (and the device is still in retransmit
mode, MARK is HIGH), a retransmit can be initiated by a rising edge on RCLK
while the retransmit input (RT) is LOW. REN must be HIGH (reads disabled)
before bringing RT LOW. The device indicates the start of retransmit setup by
setting EF[1:2] LOW, also preventing reads. When EF[1:2] goes HIGH,
retransmit setup is complete and read operations may begin starting with the first
data at the MARK location. Since IDT standard mode is selected, every word
read including the first ‘marked’ word following a retransmit setup requires a LOW
on REN (read enabled).
Note, write operations may continue as normal during all retransmit
functions, however write operations to the ‘marked’ location will be prevented.
See Figure 17, Retransmit from Mark (IDT standard mode), for the relevant
timing diagram.
During FWFT mode the FIFO is put into retransmit mode by a rising RCLK
edge when the ‘MARK’ input is HIGH and OR[1:2] is LOW. The rising RCLK
edge ‘marks’ the data present in the FIFO output register as the first retransmit
data. The FIFO remains in retransmit mode until a rising RCLK edge occurs
while MARK is LOW.
Once a marked location has been set (and the device is still in retransmit
mode, MARK is HIGH), a retransmit can be initiated by a rising RCLK edge while
the retransmit input (RT) is LOW. REN must be HIGH (reads disabled) before
bringing RT LOW. The device indicates the start of retransmit setup by setting
OR[1:2] HIGH.
When OR[1:2] goes LOW, retransmit setup is complete and on the next rising
RCLK edge after retransmit setup is complete, (RT goes HIGH), the contents
of the first retransmit location are loaded onto the output register. Since FWFT
mode is selected, the first word appears on the outputs regardless of REN, a
LOW on REN is not required for the first word. Reading all subsequent words
requires a LOW on REN to enable the rising RCLK edge. See Figure 18,
Retransmit from Mark timing (FWFT mode), for the relevant timing diagram.
Note, there must be a minimum of 128 words of data between the write pointer
and read pointer when the MARK is asserted. Also, once the MARK is set, the
write pointer will not increment past the “marked” location until the MARK is
deasserted. This prevents “overwriting” of retransmit data.
SERIAL PROGRAMMING MODE
If Serial Programming mode has been selected, as described above, then
programming of PAE[1:2] and PAF[1:2] values can be achieved by using a
combination of the LD, SEN, SCLK and SI input pins. Programming PAE[1:2]
and PAF[1:2] proceeds as follows: when LD and SEN are set LOW, data on
the SI input are written, one bit for each SCLK rising edge, starting with the Empty
Offset LSB and ending with the Full Offset MSB. 38 bits total required. See Figure
19, Serial Loading of Programmable Flag Registers, for the timing diagram for
this mode.
Using the serial method, individual registers cannot be programmed
selectively. PAE[1:2] and PAF[1:2] can show a valid status only after the
complete set of bits (for all offset registers) has been entered. The registers can
be reprogrammed as long as the complete set of new offset bits is entered. When
LD is LOW and SEN is HIGH, no serial write to the registers can occur.
Write operations to the FIFO are allowed before and during the serial
programming sequence. In this case, the programming of all offset bits does not
have to occur at once. A select number of bits can be written to the SI input and
then, by bringing LD and SEN HIGH, data can be written to FIFO memory via
Dn by toggling WEN. When WEN is brought HIGH with LD and SEN restored
to a LOW, the next offset bit in sequence is written to the registers via SI. If an
interruption of serial programming is desired, it is sufficient either to set LD LOW
and deactivate SEN or to set SEN LOW and deactivate LD. Once LD and SEN
are both restored to a LOW level, serial offset programming continues.
From the time serial programming has begun, neither programmable flag
will be valid until the full set of bits required to fill all the offset registers has been
written. Measuring from the rising SCLK edge that achieves the above criteria;
PAF[1:2] will be valid after three more rising WCLK edges plus tPAF, PAE[1:2]
will be valid after the next three rising RCLK edges plus tPAE.
It is only possible to read the flag offset values via the parallel output port Qn.
PARALLEL MODE
If Parallel Programming mode has been selected, as described above, then
programming of PAE[1:2] and PAF[1:2] values can be achieved by using a
combination of the LD, WCLK , WEN and Dn input pins. Programming PAE[1:2]
and PAF[1:2] proceeds as follows: LD and WEN must be set LOW. When
programming the Offset Registers of the TeraSync FIFO’s the number of
programming cycles will be based on the bus width, the following rules apply:
4 enabled write cycles are required to program the offset registers, (2 per
offset). Data on the inputs Dn are written into the Empty Offset Register on the
first two LOW-to-HIGH transition of WCLK. Upon the third and fourth LOW-toHIGH transition of WCLK, data are written into the Full Offset Register. See Figure
3, Programmable Flag Offset Programming Sequence for more details.
HSTL/LVTTL I/O
Both the write port and read port are user selectable between HSTL or
LVTTL I/O, via two select pins, WHSTL and RHSTL respectively. All other
control pins are selectable via SHSTL, see Table 4 for details of groupings.
Note, that when the write port is selected for HSTL mode, the user can reduce
the power consumption (in stand-by mode by utilizing the WCS input).
All “Static Pins” must be tied to VCC or GND. These pins are LVTTL only,
and are purely device configuration pins.
RETRANSMIT FROM MARK OPERATION
The Retransmit from Mark feature allows FIFO data to be read repeatedly
starting at a user-selected position. The FIFO is first put into retransmit mode that
will ‘mark’ a beginning word and also set a pointer that will prevent ongoing FIFO
write operations from over-writing retransmit data. The retransmit data can be
read repeatedly any number of times from the ‘marked’ position. The FIFO can
be taken out of retransmit mode at any time to allow normal device operation.
The ‘mark’ position can be selected any number of times, each selection over-
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COMMERCIAL AND INDUSTRIAL
TEMPERATURE RANGES
TABLE 4 — I/O CONFIGURATION
WHSTL SELECT
WHSTL: HIGH = HSTL
LOW = LVTTL
Dn (I/P)
WCLK/WR (I/P)
WEN (I/P)
WCS (I/P)
RHSTL SELECT
RHSTL: HIGH = HSTL
LOW = LVTTL
RCLK/RD (I/P)
RCS (I/P)
MARK (I/P)
REN (I/P)
OE (I/P)
RT (I/P)
Qn (O/P)
EF/OR[1:2] (O/P)
PAF[1:2] (O/P)
PAE[1:2] (O/P)
FF/IR[1:2] (O/P)
TDO (O/P)
SHSTL SELECT
STATIC PINS
SHSTL: HIGH = HSTL
LOW = LVTTL
LVTTL ONLY
SCLK (I/P)
LD (I/P)
MRS (I/P)
TCK (I/P)
TMS (I/P)
SEN (I/P)
FWFT/SI (I/P)
18
PRS (I/P)
TRST (I/P)
TDI (I/P)
ASYR (I/P)
FSEL1 (I/P)
SHSTL (I/P)
RHSTL (I/P)
ASYW (I/P)
FSEL0 (I/P)
PFM (I/P)
WHSTL (I/P)
MAY 29, 2006
 36-BIT FIFO
IDT72T36135M 2.5V 18M-BIT TeraSync
524,288 x 36
COMMERCIAL AND INDUSTRIAL
TEMPERATURE RANGES
SIGNAL DESCRIPTION
INPUTS:
ASYNCHRONOUS READ (ASYR)
The read port can be configured for either Synchronous or Asynchronous
mode of operation. If during a Master Reset the ASYR input is LOW, then
Asynchronous operation of the read port will be selected. During Asynchronous operation of the read port the RCLK input becomes RD input, this is the
Asynchronous read strobe input. A rising edge on RD will read data from the
FIFO via the output register and Qn port. (REN must be tied LOW during
Asynchronous operation of the read port).
The OE input provides three-state control of the Qn output bus, in an
asynchronous manner. (RCS, provides three-state control of the read port in
Synchronous mode).
When the read port is configured for Asynchronous operation the device
must be operating on IDT standard mode, FWFT mode is not permissible if the
read port is Asynchronous. The Empty Flag (EF[1:2]) operates in an
Asynchronous manner, that is, the empty flag will be updated based on both
a read operation and a write operation. Refer to figures 32, 33, 34 and 35 for
relevant timing and operational waveforms.
DATA IN (D0 - Dn)
Data inputs for 36-bit wide data (D0 - D35).
CONTROLS:
MASTER RESET ( MRS )
A Master Reset is accomplished whenever the MRS input is taken to a LOW
state. This operation sets the internal read and write pointers to the first location
of the RAM array. PAE[1:2] will go LOW, PAF[1:2] will go HIGH.
If FWFT/SI is LOW during Master Reset then the IDT Standard mode,
along with EF[1:2] and FF[1:2] are selected. EF[1:2] will go LOW and FF[1:2]
will go HIGH. If FWFT/SI is HIGH, then the First Word Fall Through mode
(FWFT), along with IR[1:2] and OR[1:2], are selected. OR[1:2] will go HIGH
and IR[1:2] will go LOW.
All control settings such as RM and PFM are defined during the Master Reset
cycle.
During a Master Reset, the output register is initialized to all zeroes. A Master
Reset is required after power up, before a write operation can take place. MRS
is asynchronous.
See Figure 8, Master Reset Timing, for the relevant timing diagram.
RETRANSMIT (RT)
The Retransmit (RT) input is used in conjunction with the MARK input,
together they provide a means by which data previously read out of the FIFO
can be reread any number of times. If retransmit operation has been selected
(i.e. the MARK input is HIGH), a rising edge on RCLK while RT is LOW will reset
the read pointer back to the memory location set by the user via the MARK input.
If IDT standard mode has been selected the EF[1:2] flag will go LOW and
remain LOW for the time that RT is held LOW. RT can be held LOW for any
number of RCLK cycles, the read pointer being reset to the marked location.
The next rising edge of RCLK after RT has returned HIGH, will cause EF[1:2]
to go HIGH, allowing read operations to be performed on the FIFO. The next
read operation will access data from the ‘marked’ memory location.
Subsequent retransmit operations may be performed, each time the read
pointer returning to the ‘marked’ location. See Figure 17, Retransmit from Mark
(IDT Standard mode) for the relevant timing diagram.
If FWFT mode has been selected the OR[1:2] flag will go HIGH and remain
HIGH for the time that RT is held LOW. RT can be held LOW for any number
of RCLK cycles, the read pointer being reset to the ‘marked’ location. The next
RCLK rising edge after RT has returned HIGH, will cause OR[1:2] to go LOW
and due to FWFT operation, the contents of the marked memory location will
be loaded onto the output register, a read operation being required for all
subsequent data reads.
Subsequent retransmit operations may be performed each time the read
pointer returning to the ‘marked’ location. See Figure 18, Retransmit from Mark
(FWFT mode) for the relevant timing diagram.
PARTIAL RESET (PRS)
A Partial Reset is accomplished whenever the PRS input is taken to a LOW
state. As in the case of the Master Reset, the internal read and write pointers
are set to the first location of the RAM array, PAE[1:2] goes LOW, PAF[1:2]
goes HIGH.
Whichever mode is active at the time of Partial Reset, IDT Standard mode
or First Word Fall Through, that mode will remain selected. If the IDT Standard
mode is active, then FF[1:2] will go HIGH and EF[1:2] will go LOW. If the First
Word Fall Through mode is active, then OR[1:2] will go HIGH, and IR[1:2] will
go LOW.
Following Partial Reset, all values held in the offset registers remain
unchanged. The programming method (parallel or serial) currently active at
the time of Partial Reset is also retained. The output register is initialized to all
zeroes. PRS is asynchronous.
A Partial Reset is useful for resetting the device during the course of
operation, when reprogramming programmable flag offset settings may not be
convenient.
See Figure 9, Partial Reset Timing, for the relevant timing diagram.
ASYNCHRONOUS WRITE (ASYW)
The write port can be configured for either Synchronous or Asynchronous
mode of operation. If during Master Reset the ASYW input is LOW, then
Asynchronous operation of the write port will be selected. During Asynchronous operation of the write port the WCLK input becomes WR input, this is the
Asynchronous write strobe input. A rising edge on WR will write data present
on the Dn inputs into the FIFO. (WEN must be tied LOW when using the write
port in Asynchronous mode).
When the write port is configured for Asynchronous operation the full flag
(FF[1:2]) operates in an asynchronous manner, that is, the full flag will be
updated based in both a write operation and read operation. Note, if Asynchronous mode is selected, FWFT is not permissable. Refer to Figures 30, 31, 34
and 35 for relevant timing and operational waveforms.
MARK
The MARK input is used to select Retransmit mode of operation. An RCLK
rising edge while MARK is HIGH will mark the memory location of the data
currently present on the output register, the device will also be placed into
retransmit mode. For the IDT72T36135M a minimum of 128 words (x36). Also,
once the MARK is set, the write pointer will not increment past the “marked”
location until the MARK is deasserted. This prevents “overwriting” of retransmit
data.
The MARK input must remain HIGH during the whole period of retransmit
mode, a falling edge of RCLK while MARK is LOW will take the device out of
retransmit mode and into normal mode. Any number of MARK locations can be
set during FIFO operation, only the last marked location taking effect. Once a
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mark location has been set the write pointer cannot be incremented past this
marked location. During retransmit mode write operations to the device may
continue without hindrance.
READ STROBE & READ CLOCK (RD/RCLK)
If Synchronous operation of the read port has been selected via ASYR, this
input behaves as RCLK. A read cycle is initiated on the rising edge of the RCLK
input. Data can be read on the outputs, on the rising edge of the RCLK input.
It is permissible to stop the RCLK. Note that while RCLK is idle, the EF/OR[1:2],
and PAE[1:2] flags will not be updated. The Write and Read Clocks can be
independent or coincident.
If Asynchronous operation has been selected this input is RD (Read Strobe)
. Data is Asynchronously read from the FIFO via the output register whenever
there is a rising edge on RD. In this mode the REN and RCS inputs must be
tied LOW. The OE input is used to provide Asynchronous control of the threestate Qn outputs.
FIRST WORD FALL THROUGH/SERIAL IN (FWFT/SI)
This is a dual purpose pin. During Master Reset, the state of the FWFT/
SI input determines whether the device will operate in IDT Standard mode or
First Word Fall Through (FWFT) mode.
If, at the time of Master Reset, FWFT/SI is LOW, then IDT Standard mode
will be selected. This mode uses the Empty Flag (EF[1:2]) to indicate whether
or not there are any words present in the FIFO memory. It also uses the Full
Flag function (FF[1:2]) to indicate whether or not the FIFO memory has any
free space for writing. In IDT Standard mode, every word read from the FIFO,
including the first, must be requested using the Read Enable (REN) and
RCLK.
If, at the time of Master Reset, FWFT/SI is HIGH, then FWFT mode will be
selected. This mode uses Output Ready (OR[1:2]) to indicate whether or not
there is valid data at the data outputs (Qn). It also uses Input Ready (IR[1:2])
to indicate whether or not the FIFO memory has any free space for writing. In
the FWFT mode, the first word written to an empty FIFO goes directly to Qn after
three RCLK rising edges, REN = LOW is not necessary. Subsequent words
must be accessed using the Read Enable (REN) and RCLK.
After Master Reset, FWFT/SI acts as a serial input for loading PAE[1:2] and
PAF[1:2] offsets into the programmable registers. The serial input function can
only be used when the serial loading method has been selected during Master
Reset. Serial programming using the FWFT/SI pin functions the same way in
both IDT Standard and FWFT modes.
WRITE CHIP SELECT (WCS)
The WCS disables all Write Port inputs (data only) if it is held HIGH. To
perform normal operations on the write port, the WCS must be enabled, held LOW.
READ ENABLE (REN)
When Read Enable is LOW, data is loaded from the RAM array into the
output register on the rising edge of every RCLK cycle if the device is not empty.
When the REN input is HIGH, the output register holds the previous data
and no new data is loaded into the output register. The data outputs Q0-Qn
maintain the previous data value.
In the IDT Standard mode, every word accessed at Qn, including the first
word written to an empty FIFO, must be requested using REN provided that
RCS is LOW. When the last word has been read from the FIFO, the Empty Flag
(EF[1:2]) will go LOW, inhibiting further read operations. REN is ignored when
the FIFO is empty. Once a write is performed, EF[1:2] will go HIGH allowing
a read to occur. The EF[1:2] flag is updated by two RCLK cycles + tSKEW after
the valid WCLK cycle. Both RCS and REN must be active, LOW for data to be
read out on the rising edge of RCLK.
In the FWFT mode, the first word written to an empty FIFO automatically goes
to the outputs Qn, on the third valid LOW-to-HIGH transition of RCLK + tSKEW
after the first write. REN and RCS do not need to be asserted LOW for the First
Word to fall through to the output register. In order to access all other words,
a read must be executed using REN and RCS. The RCLK LOW-to-HIGH
transition after the last word has been read from the FIFO, Output Ready
(OR[1:2]) will go HIGH with a true read (RCLK with REN = LOW;RCS = LOW),
inhibiting further read operations. REN is ignored when the FIFO is empty.
If Asynchronous operation of the Read port has been selected, then REN
must be held active, (tied LOW).
WRITE STROBE & WRITE CLOCK (WR/WCLK)
If Synchronous operation of the write port has been selected via ASYW, this
input behaves as WCLK.
A write cycle is initiated on the rising edge of the WCLK input. Data setup
and hold times must be met with respect to the LOW-to-HIGH transition of the
WCLK. It is permissible to stop the WCLK. Note that while WCLK is idle, the FF/
IR[1:2], and PAF[1:2] flags will not be updated. The Write and Read Clocks can
either be independent or coincident.
If Asynchronous operation has been selected this input is WR (write strobe).
Data is Asynchronously written into the FIFO via the Dn inputs whenever there
is a rising edge on WR. In this mode the WEN input must be tied LOW.
WRITE ENABLE (WEN)
When the WEN input is LOW, data may be loaded into the FIFO RAM array
on the rising edge of every WCLK cycle if the device is not full. Data is stored
in the RAM array sequentially and independently of any ongoing read
operation.
When WEN is HIGH, no new data is written in the RAM array on each WCLK
cycle.
To prevent data overflow in the IDT Standard mode, FF[1:2] will go LOW,
inhibiting further write operations. Upon the completion of a valid read cycle,
FF[1:2] will go HIGH allowing a write to occur. The FF[1:2] is updated by two
WCLK cycles + tSKEW after the RCLK cycle.
To prevent data overflow in the FWFT mode, IR[1:2] will go HIGH, inhibiting
further write operations. Upon the completion of a valid read cycle, IR[1:2] will
go LOW allowing a write to occur. The IR[1:2] flag is updated by two WCLK
cycles + tSKEW after the valid RCLK cycle.
WEN is ignored when the FIFO is full in either FWFT or IDT Standard mode.
If Asynchronous operation of the write port has been selected, then WEN
must be held active, (tied LOW).
SERIAL ENABLE ( SEN )
The SEN input is an enable used only for serial programming of the offset
registers. The serial programming method must be selected during Master
Reset. SEN is always used in conjunction with LD. When these lines are both
LOW, data at the SI input can be loaded into the program register one bit for each
LOW-to-HIGH transition of SCLK.
When SEN is HIGH, the programmable registers retains the previous
settings and no offsets are loaded. SEN functions the same way in both IDT
Standard and FWFT modes.
OUTPUT ENABLE ( OE )
When Output Enable is enabled (LOW), the parallel output buffers receive
data from the output register. When OE is HIGH, the output data bus (Qn) goes
into a high impedance state. During Master or a Partial Reset the OE is the only
input that can place the output bus Qn, into High-Impedance. During Reset the
RCS input can be HIGH or LOW, it has no effect on the Qn outputs.
20
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IDT72T36135M 2.5V 18M-BIT TeraSync
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COMMERCIAL AND INDUSTRIAL
TEMPERATURE RANGES
READ CHIP SELECT ( RCS )
The Read Chip Select input provides synchronous control of the Read
output port. When RCS goes LOW, the next rising edge of RCLK causes the
Qn outputs to go to the Low-Impedance state. When RCS goes HIGH, the next
RCLK rising edge causes the Qn outputs to return to HIGH Z. During a Master
or Partial Reset the RCS input has no effect on the Qn output bus, OE is the only
input that provides High-Impedance control of the Qn outputs. If OE is LOW the
Qn data outputs will be Low-Impedance regardless of RCS until the first rising
edge of RCLK after a Reset is complete. Then if RCS is HIGH the data outputs
will go to High-Impedance.
The RCS input does not effect the operation of the flags. For example, when
the first word is written to an empty FIFO, the EF[1:2] will still go from LOW to
HIGH based on a rising edge of RCLK, regardless of the state of the RCS input.
Also, when operating the FIFO in FWFT mode the first word written to an
empty FIFO will still be clocked through to the output register based on RCLK,
regardless of the state of RCS. For this reason the user must take care when
a data word is written to an empty FIFO in FWFT mode. If RCS is disabled when
an empty FIFO is written into, the first word will fall through to the output register,
but will not be available on the Qn outputs which are in HIGH-Z. The user must
take RCS active LOW to access this first word, place the output bus in LOW-Z.
REN must remain disabled HIGH for at least one cycle after RCS has gone LOW.
A rising edge of RCLK with RCS and REN active LOW, will read out the next
word. Care must be taken so as not to lose the first word written to an empty
FIFO when RCS is HIGH. Refer to Figure 16, RCS and REN Read Operation
(FWFT Mode). The RCS pin must also be active (LOW) in order to perform
a Retransmit. See Figure 12 for Read Cycle and Read Chip Select Timing (IDT
Standard Mode). See Figure 15 for Read Cycle and Read Chip Select Timing
(First Word Fall Through Mode).
If Asynchronous operation of the Read port has been selected, then RCS
must be held active, (tied LOW). OE provides three-state control of Qn.
registers can be programmed, parallel or serial (see Table 1). After Master
Reset, LD enables write operations to and read operations from the offset
registers. Only the offset loading method currently selected can be used to write
to the registers. Offset registers can be read only in parallel.
After Master Reset, the LD pin is used to activate the programming process
of the flag offset values PAE[1:2] and PAF[1:2]. Pulling LD LOW will begin a serial
loading or parallel load or read of these offset values. THIS PIN MUST BE HIGH
AFTER MASTER RESET TO WRITE OR READ DATA TO/FROM THE FIFO
MEMORY.
PROGRAMMABLE FLAG MODE (PFM)
During Master Reset, a LOW on PFM will select Asynchronous Programmable flag timing mode. A HIGH on PFM will select Synchronous Programmable flag timing mode. If asynchronous PAF/PAE[1:2] configuration is selected
(PFM, LOW during MRS), the PAE[1:2] is asserted LOW on the LOW-to-HIGH
transition of RCLK. PAE[1:2] is reset to HIGH on the LOW-to-HIGH transition
of WCLK. Similarly, the PAF[1:2] is asserted LOW on the LOW-to-HIGH
transition of WCLK and PAF[1:2] is reset to HIGH on the LOW-to-HIGH transition
of RCLK.
If synchronous PAE/PAF[1:2] configuration is selected (PFM, HIGH during
MRS) , the PAE[1:2] is asserted and updated on the rising edge of RCLK only
and not WCLK. Similarly, PAF[1:2] is asserted and updated on the rising edge
of WCLK only and not RCLK. The mode desired is configured during master
reset by the state of the Programmable Flag Mode (PFM) pin.
OUTPUTS:
FULL FLAG ( FF/IR[1:2] )
This is a dual purpose pin. In IDT Standard mode, the Full Flag (FF[1:2])
function is selected. When the FIFO is full, FF[1:2] will go LOW, inhibiting further
write operations. When FF[1:2] is HIGH, the FIFO is not full. If no reads are
performed after a reset (either MRS or PRS), FF[1:2] will go LOW after D writes
to the FIFO (D = 524,288 for the IDT72T36135M). See Figure 10, Write Cycle
and Full Flag Timing (IDT Standard Mode), for the relevant timing information.
Please see Flagging section for external gating instructions of these flags.
In FWFT mode, the Input Ready (IR[1:2]) function is selected. IR[1:2] goes
LOW when memory space is available for writing in data. When there is no
longer any free space left, IR[1:2] goes HIGH, inhibiting further write operations.
If no reads are performed after a reset (either MRS or PRS), IR[1:2] will go HIGH
after D writes to the FIFO (D = 524,288 for the IDT72T36135M). See Figure
13, Write Timing (FWFT Mode), for the relevant timing information.
The IR[1:2] status not only measures the contents of the FIFO memory, but
also counts the presence of a word in the output register. Thus, in FWFT mode,
the total number of writes necessary to deassert IR[1:2] is one greater than
needed to assert FF[1:2] in IDT Standard mode.
FF/IR[1:2] is synchronous and updated on the rising edge of WCLK. FF/
IR[1:2] are double register-buffered outputs.
Note, when the device is in Retransmit mode, this flag is a comparison of
the write pointer to the ‘marked’ location. This differs from normal mode where
this flag is a comparison of the write pointer to the read pointer.
WRITE PORT HSTL SELECT (WHSTL)
The control inputs, data inputs and flag outputs associated with the write port
can be setup to be either HSTL or LVTTL. If WHSTL is HIGH during the Master
Reset, then HSTL operation of the write port will be selected. If WHSTL is LOW
at Master Reset, then LVTTL will be selected.
The inputs and outputs associated with the write port are listed in Table 4,
I/O Configuration.
READ PORT HSTL SELECT (RHSTL)
The control inputs, data inputs and flag outputs associated with the read port
can be setup to be either HSTL or LVTTL. If RHSTL is HIGH during the Master
Reset, then HSTL operation of the read port will be selected. If RHSTL is LOW
at Master Reset, then LVTTL will be selected for the read port.
The inputs and outputs associated with the read port are listed in Table 4,
I/O Configuration.
SYSTEM HSTL SELECT (SHSTL)
All inputs not associated with the write and read port can be setup to be either
HSTL or LVTTL. If SHSTL is HIGH during Master Reset, then HSTL operation
of all the inputs not associated with the write and read port will be selected. If
SHSTL is LOW at Master Reset, then LVTTL will be selected. The inputs
associated with SHSTL are listed in Table 4, I/O Configuration.
EMPTY FLAG ( EF/OR[1:2] )
This is a dual purpose pin. In the IDT Standard mode, the Empty Flag
(EF[1:2]) function is selected. When the FIFO is empty, EF[1:2] will go LOW,
inhibiting further read operations. When EF[1:2] is HIGH, the FIFO is not empty.
See Figure 11, Read Cycle, Empty Flag and First Word Latency Timing (IDT
Standard Mode), for the relevant timing information. Please see Flagging
section for external gating instructions of these flags.
LOAD (LD)
This is a dual purpose pin. During Master Reset, the state of the LD input,
along with FSEL0 and FSEL1, determines one of eight default offset values for
the PAE[1:2] and PAF[1:2] flags, along with the method by which these offset
21
MAY 29, 2006
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IDT72T36135M 2.5V 18M-BIT TeraSync
524,288 x 36
COMMERCIAL AND INDUSTRIAL
TEMPERATURE RANGES
If asynchronous PAF[1:2] configuration is selected, the PAF[1:2] is asserted
LOW on the LOW-to-HIGH transition of the Write Clock (WCLK). PAF[1:2] is
reset to HIGH on the LOW-to-HIGH transition of the Read Clock (RCLK). If
synchronous PAF[1:2] configuration is selected, the PAF[1:2] is updated on the
rising edge of WCLK. See Figure 24, Asynchronous Almost-Full Flag Timing
(IDT Standard and FWFT Mode).
Note, when the device is in Retransmit mode, this flag is a comparison of the
write pointer to the ‘marked’ location. This differs from normal mode where this
flag is a comparison of the write pointer to the read pointer.
In FWFT mode, the Output Ready (OR[1:2]) function is selected. OR[1:2]
goes LOW at the same time that the first word written to an empty FIFO appears
valid on the outputs. OR[1:2] stays LOW after the RCLK LOW to HIGH transition
that shifts the last word from the FIFO memory to the outputs. OR[1:2] goes HIGH
only with a true read (RCLK with REN = LOW). The previous data stays at the
outputs, indicating the last word was read. Further data reads are inhibited until
OR[1:2] goes LOW again. See Figure 14, Read Timing (FWFT Mode), for the
relevant timing information.
EF/OR[1:2] is synchronous and updated on the rising edge of RCLK.
In IDT Standard mode, EF[1:2] is a double register-buffered output. In
FWFT mode, OR[1:2] is a triple register-buffered output.
PROGRAMMABLE ALMOST-EMPTY FLAG ( PAE[1:2] )
The Programmable Almost-Empty flag (PAE[1:2]) will go LOW when the
FIFO reaches the almost-empty condition. In IDT Standard mode, PAE[1:2] will
go LOW when there are n words or less in the FIFO. The offset “n” is the empty
offset value. The default setting for this value is stated in the footnote of Table 1.
Please see Flagging section for external gating instructions of these flags.
In FWFT mode, the PAE[1:2] will go LOW when there are n+1 words or
less in the FIFO. The default setting for this value is stated in Table 1.
See Figure 23, Synchronous Programmable Almost-Empty Flag Timing
(IDT Standard and FWFT Mode), for the relevant timing information.
If asynchronous PAE[1:2] configuration is selected, the PAE[1:2] is asserted
LOW on the LOW-to-HIGH transition of the Read Clock (RCLK). PAE[1:2] is
reset to HIGH on the LOW-to-HIGH transition of the Write Clock (WCLK). If
synchronous PAE[1:2] configuration is selected, the PAE[1:2] is updated on the
rising edge of RCLK. See Figure 25, Asynchronous Programmable AlmostEmpty Flag Timing (IDT Standard and FWFT Mode).
PROGRAMMABLE ALMOST-FULL FLAG ( PAF[1:2] )
The Programmable Almost-Full flag (PAF[1:2]) will go LOW when the FIFO
reaches the almost-full condition. In IDT Standard mode, if no reads are
performed after reset (MRS), PAF[1:2] will go LOW after (D - m) words are
written to the FIFO. The PAF[1:2] will go LOW after (524,288-m) writes for the
IDT72T36135M. The offset “m” is the full offset value. The default setting for this
value is stated in the footnote of Table 2, Status Flags for IDT Standard Mode.
Please see Flagging section for external gating instructions of these flags.
In FWFT mode, the PAF[1:2] will go LOW after (524,289-m) writes for the
IDT72T36135M, where m is the full offset value. The default setting for this value
is stated in Table 3, Status Flags for FWFT Mode.
See Figure 22, Synchronous Programmable Almost-Full Flag Timing (IDT
Standard and FWFT Mode), for the relevant timing information.
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MAY 29, 2006
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IDT72T36135M 2.5V 18M-BIT TeraSync
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COMMERCIAL AND INDUSTRIAL
TEMPERATURE RANGES
CONSIDERATIONS FOR READING FLAG OUTPUTS
On this device, there are two sets of flagging outputs for the empty flag (EF1
& EF2), full flag (FF1 & FF2), Programmable Almost Empty Flag (PAE1 &
PAE2), and Programmable Almost Full Flag (PAF1 & PAF2) the user must work
with in order to be able to correctly read the status of each flag. Since this device
is a multi-chip module (MCM), both die’s flags must be read accordingly to avoid
skewing problems between the two internal die.
To remedy this function, the user must tie together FF1 & FF2, and EF1 &
EF2 flag outputs to an external gate from a neighboring programmable device
such as an FPGA or PLD and read from the output of the logical gate. An OR
gate is used for FWFT mode and an AND gate is used for IDT mode. This must
be done to avoid timing skew problems between the two sets of flags. For the
PAE[1:2] and PAF[1:2] active low output flags, the user has the option to leave
the PAE[1:2] and PAF[1:2] as is and use both pins at different programmable
water marks for measuring buffer status. Please see the section on Parallel
Programming Mode to understand how to program these two sets of flags as
different water marks in Functional Description section of the datasheet. This
gives added flexibility for queue management. Below is an example diagram
for how this is accomplished.
IDT72T36135M
EF1
EF2
FF1
FF2
PAE1
PAE2
PAF1
PAF2
OPTIONAL
GATE
(1)
GATE
(1)
EF
AND
GATE
FF
PAE
AND
GATE
PAF
6723 drw10
NOTE:
1. An “OR” Gate is used for FWFT mode, and an “AND” Gate is used for IDT Standard mode.
Figure 4. Output Flag Gating Considerations
interspersed parity. From these changes, the 18M FIFO has removed specific
inputs such as IW, OW, BM, BE, IP, while also gaining another set of output flags
as specified in Considerations for Reading Flag Outputs which are EF2,
FF2, PAE2, and PAF2.
To maintain drop-in replacement compatibility for the 18M TeraSync, the pin
changes on the pin diagram for the 18M TeraSync FIFO from the 9M TeraSync
FIFO have been identified, and listed in the table below.
PIN COMPATIBILITY WITH 9M TERASYNC (IDT72T36125) CONSIDERATIONS
The IDT72T36135M can be a drop and replacement for the 9M TeraSync
(IDT72T36125) if specific pin changes are made to the 18M FIFO. Since the
18M TeraSync is a Multi-Chip Module (MCM), containing two 9M TeraSyncs
(IDT72T18125) in width expansion mode, certain functionality can not be
offered in the 18M TeraSync such as bus matching, single flag outputs and
TABLE 5 — PIN CHANGES BETWEEN 9M TERASYNC AND 18M TERASYNC
9M TeraSync FIFO (IDT72T36125)
pins changed
18M TeraSync FIFO (IDT72T36135M)
new pins
BM
IP
IW
OW
HF
EREN
ERCLK
BE
EF2
PAE2
NC (No Connect)
NC (No Connect)
PAF2
FF2
NC (No Connect)
GND
NOTES:
1. Internally, the 9M pins on the left side of the table will be tied to the GND or VDD plane, respectively in the 18M device.
2. Please see IDT72T36125 TeraSync FIFO datasheet for additional features listed.
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COMMERCIAL AND INDUSTRIAL
TEMPERATURE RANGES
JTAG FUNCTIONALITY AND CONFIGURATION
JTAG signaling must be provided serially to each array and utilize the
information provided in the Scan Register Descriptions, JTATG Instruction
Description. Specifically, commands for Array B must precede those Array A
in any JTAG operations sent to the IDT72T36135M. Please reference
Application Note AN-411, “JTAG Testing of Multichip Modules” for specific
instructions on performing JTAG testing on the IDT72T36135M. AN-411 is
available at www.idt.com.
The IDT72T36135M is composed of two independent memory arrays, and
thus cannot be treated as a single JTAG device in the scan chain. The two arrays
(A and B) each have identical characteristics and commands but must be treated
as separate entities in JTAG operations. Please refer to Figure 5, JTAG
Configuration for IDT72T36135M.
TDI
Array A
TDOA
TDIB
Array B
TDO
TCK
TMS
TRST
6723 drw11
Figure 5. JTAG Configuration for IDT72T36135M
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MAY 29, 2006
 36-BIT FIFO
IDT72T36135M 2.5V 18M-BIT TeraSync
524,288 x 36
COMMERCIAL AND INDUSTRIAL
TEMPERATURE RANGES
JTAG TIMING SPECIFICATION
tTCK
t4
t1
t2
TCK
t3
TDI/
TMS
tDS
tDH
TDO
TDO
tDO
t6
TRST
6723 drw12
Notes to diagram:
t1 = tTCKLOW
t2 = tTCKHIGH
t3 = tTCKFALL
t4 = tTCKRISE
t5 = tRST (reset pulse width)
t6 = tRSR (reset recovery)
t5
JTAG
AC ELECTRICAL CHARACTERISTICS
(vcc = 2.5V ± 5%; Tcase = 0°C to +85°C)
Parameter
IDT72T36135M
IDT72T36135M
Max. Units
Max. Units
JTAG Clock Input Period tTCK
-
100
-
ns
JTAG Clock HIGH
tTCKHIGH
-
40
-
ns
JTAG Clock Low
tTCKLOW
-
40
-
ns
Parameter
Symbol
Data Output
tDO(1)
-
20
ns
JTAG Clock Rise Time
tTCKRISE
-
-
5(1)
ns
Data Output Hold
tDOH(1)
0
-
ns
JTAG Clock Fall Time
tTCKFALL
-
-
5(1)
ns
Data Input
tDS
tDH
10
10
-
ns
JTAG Reset
tRST
-
50
-
ns
JTAG Reset Recovery
tRSR
-
50
-
ns
trise=3ns
tfall=3ns
Min.
Test
Conditions
Min.
SYSTEM INTERFACE PARAMETERS
Test Conditions
Symbol
-
NOTE:
1. 50pf loading on external output signals.
NOTE:
1. Guaranteed by design.
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MAY 29, 2006
 36-BIT FIFO
IDT72T36135M 2.5V 18M-BIT TeraSync
524,288 x 36
COMMERCIAL AND INDUSTRIAL
TEMPERATURE RANGES
JTAG INTERFACE
•
•
•
Five additional pins (TDI, TDO, TMS, TCK and TRST) are provided to
support the JTAG boundary scan interface. The IDT72T36135M incorporates
the necessary tap controller and modified pad cells to implement the JTAG facility.
Note that IDT provides appropriate Boundary Scan Description Language
program files for these devices.
The Standard JTAG interface consists of four basic elements:
•
Test Access Port (TAP)
TAP controller
Instruction Register (IR)
Data Register Port (DR)
The following sections provide a brief description of each element. For a
complete description refer to the IEEE Standard Test Access Port Specification
(IEEE Std. 1149.1-1990).
The Figure below shows the standard Boundary-Scan Architecture
DeviceID Reg.
Mux
Boundary Scan Reg.
Bypass Reg.
TDO
TDI
T
A
TMS
TCLK
TRST
P
TAP
clkDR, ShiftDR
UpdateDR
Controller
Instruction Decode
clklR, ShiftlR
UpdatelR
Instruction Register
Control Signals
6723 drw13
Figure 6. Boundary Scan Architecture
THE TAP CONTROLLER
The Tap controller is a synchronous finite state machine that responds to
TMS and TCLK signals to generate clock and control signals to the Instruction
and Data Registers for capture and update of data.
TEST ACCESS PORT (TAP)
The Tap interface is a general-purpose port that provides access to the
internal of the processor. It consists of four input ports (TCLK, TMS, TDI, TRST)
and one output port (TDO).
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MAY 29, 2006
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IDT72T36135M 2.5V 18M-BIT TeraSync
524,288 x 36
1
COMMERCIAL AND INDUSTRIAL
TEMPERATURE RANGES
Test-Logic
Reset
0
0
Run-Test/
Idle
1
SelectDR-Scan
1
SelectIR-Scan
1
0
1
0
Capture-IR
1
Capture-DR
0
0 0
Shift-DR
1
1
Input = TMS
Exit1-DR
1
0
1
Exit2-DR
Exit2-IR
0
1
1
Update-IR
Update-DR
0
0
Pause-IR
1
1
1
Exit1-IR
0 0
Pause-DR
0
0
Shift-IR
1
0
6723 drw14
NOTES:
1. Five consecutive TCK cycles with TMS = 1 will reset the TAP.
2. TAP controller does not automatically reset upon power-up. The user must provide a reset to the TAP controller (either by TRST or TMS).
3. TAP controller must be reset before normal FIFO operations can begin.
Figure 7. TAP Controller State Diagram
Capture-IR In this controller state, the shift register bank in the Instruction
Register parallel loads a pattern of fixed values on the rising edge of TCK. The
last two significant bits are always required to be “01”.
Shift-IR In this controller state, the instruction register gets connected
between TDI and TDO, and the captured pattern gets shifted on each rising edge
of TCK. The instruction available on the TDI pin is also shifted in to the instruction
register.
Exit1-IR This is a controller state where a decision to enter either the PauseIR state or Update-IR state is made.
Pause-IR This state is provided in order to allow the shifting of instruction
register to be temporarily halted.
Exit2-DR This is a controller state where a decision to enter either the ShiftIR state or Update-IR state is made.
Update-IR In this controller state, the instruction in the instruction register is
latched in to the latch bank of the Instruction Register on every falling edge of
TCK. This instruction also becomes the current instruction once it is latched.
Capture-DR In this controller state, the data is parallel loaded in to the data
registers selected by the current instruction on the rising edge of TCK.
Shift-DR, Exit1-DR, Pause-DR, Exit2-DR and Update-DR These
controller states are similar to the Shift-IR, Exit1-IR, Pause-IR, Exit2-IR and
Update-IR states in the Instruction path.
Refer to the IEEE Standard Test Access Port Specification (IEEE Std.
1149.1) for the full state diagram
All state transitions within the TAP controller occur at the rising edge of the
TCLK pulse. The TMS signal level (0 or 1) determines the state progression
that occurs on each TCLK rising edge. The TAP controller takes precedence
over the FIFO memory and must be reset after power up of the device. See
TRST description for more details on TAP controller reset.
Test-Logic-Reset All test logic is disabled in this controller state enabling the
normal operation of the IC. The TAP controller state machine is designed in such
a way that, no matter what the initial state of the controller is, the Test-Logic-Reset
state can be entered by holding TMS at high and pulsing TCK five times. This
is the reason why the Test Reset (TRST) pin is optional.
Run-Test-Idle In this controller state, the test logic in the IC is active only if
certain instructions are present. For example, if an instruction activates the self
test, then it will be executed when the controller enters this state. The test logic
in the IC is idles otherwise.
Select-DR-Scan This is a controller state where the decision to enter the
Data Path or the Select-IR-Scan state is made.
Select-IR-Scan This is a controller state where the decision to enter the
Instruction Path is made. The Controller can return to the Test-Logic-Reset state
other wise.
27
MAY 29, 2006
 36-BIT FIFO
IDT72T36135M 2.5V 18M-BIT TeraSync
524,288 x 36
COMMERCIAL AND INDUSTRIAL
TEMPERATURE RANGES
SCAN REGISTER DESCRIPTIONS
JTAG INSTRUCTION REGISTER
The Instruction register allows instruction to be serially input into the device
when the TAP controller is in the Shift-IR state. The instruction is decoded to
perform the following:
•
Select test data registers that may operate while the instruction is
current. The other test data registers should not interfere with chip
operation and the selected data register.
•
Define the serial test data register path that is used to shift data between
TDI and TDO during data register scanning.
The Instruction Register is a 8 bit field (i.e.IR3, IR2, IR1, IR0 per die) to
decode 32 different possible instructions. Instructions are decoded as follows.
THE INSTRUCTION REGISTER
The Instruction register allows an instruction to be shifted in serially into the
processor at the rising edge of TCLK.
The Instruction is used to select the test to be performed, or the test data
register to be accessed, or both. The instruction shifted into the register is latched
at the completion of the shifting process when the TAP controller is at UpdateIR state.
The instruction register must contain 8 bit instruction register-based cells
which can hold instruction data. These mandatory cells are located nearest the
serial outputs they are the least significant bits.
Please note:
Again, since this device is a two die MCM, the JTAG instructions must be shifted
in twice during JTAG testing. To account for each dies 4bit instruction registers
for a total of 8 bits altogether.
TEST DATA REGISTER
The Test Data register contains three test data registers: the Bypass, the
Boundary Scan register and Device ID register.
These registers are connected in parallel between a common serial input
and a common serial data output.
The following sections provide a brief description of each element. For a
complete description, refer to the IEEE Standard Test Access Port Specification
(IEEE Std. 1149.1-1990).
JTAG INSTRUCTION DESCRIPTION
Hex
Value
0x00
0x22
0x11
0x33
0xFF
TEST BYPASS REGISTER
The register is used to allow test data to flow through the device from TDI
to TDO. It contains a single stage shift register for a minimum length in serial path.
When the bypass register is selected by an instruction, the shift register stage
is set to a logic zero on the rising edge of TCLK when the TAP controller is in
the Capture-DR state.
The operation of the bypass register should not have any effect on the
operation of the device in response to the BYPASS instruction.
Instruction
Function
EXTEST
IDCODE
SAMPLE/PRELOAD
HIGH-IMPEDANCE
BYPASS
Select Boundary Scan Register
Select Chip Identification data register
Select Boundary Scan Register
JTAG
Select Bypass Register
JTAG Instruction Register Decoding
The following sections provide a brief description of each instruction. For
a complete description refer to the IEEE Standard Test Access Port Specification
(IEEE Std. 1149.1-1990).
EXTEST
The required EXTEST instruction places the IC into an external boundarytest mode and selects the boundary-scan register to be connected between TDI
and TDO. During this instruction, the boundary-scan register is accessed to
drive test data off-chip via the boundary outputs and receive test data off-chip
via the boundary inputs. As such, the EXTEST instruction is the workhorse of
IEEE. Std 1149.1, providing for probe-less testing of solder-joint opens/shorts
and of logic cluster function.
THE BOUNDARY-SCAN REGISTER
The Boundary Scan Register allows serial data TDI be loaded in to or read
out of the processor input/output ports. The Boundary Scan Register is a part
of the IEEE 1149.1-1990 Standard JTAG Implementation.
THE DEVICE IDENTIFICATION REGISTER
The Device Identification Register is a Read Only 64-bit register used to
specify the manufacturer, part number and version of the processor to be
determined through the TAP in response to the IDCODE instruction.
IDT JEDEC ID number is 0xB3. This translates to 0x33 when the parity
is dropped in the 11-bit Manufacturer ID field.
For the IDT72T36135M, the Part Number field contains the following
values:
Device
Part# Field
IDT72T36135M
0417
IDCODE
The optional IDCODE instruction allows the IC to remain in its functional mode
and selects the optional device identification register to be connected between
TDI and TDO. The device identification register is a 64-bit shift register containing
information regarding the IC manufacturer, device type, and version code.
Accessing the device identification register does not interfere with the operation
of the IC. Also, access to the device identification register should be immediately
available, via a TAP data-scan operation, after power-up of the IC or after the
TAP has been reset using the optional TRST pin or by otherwise moving to the
Test-Logic-Reset state.
31(MSB)
28 27
12 11
1 0(LSB)
Version (4 bits) Part Number (16-bit) Manufacturer ID (11-bit)
0X0
0X33
1
SAMPLE/PRELOAD
The required SAMPLE/PRELOAD instruction allows the IC to remain in a
normal functional mode and selects the boundary-scan register to be connected
between TDI and TDO. During this instruction, the boundary-scan register can
be accessed via a date scan operation, to take a sample of the functional data
entering and leaving the IC. This instruction is also used to preload test data into
the boundary-scan register before loading an EXTEST instruction.
IDT72T36135M JTAG Device Identification Register
Please note:
The IDT72T36135M device is a two die MCM which means 64 bits will be
shifted out of the device when the user is in IDCODE. Since the JTAG device
identification register is 32 bits per die.
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IDT72T36135M 2.5V 18M-BIT TeraSync
524,288 x 36
COMMERCIAL AND INDUSTRIAL
TEMPERATURE RANGES
BYPASS
The required BYPASS instruction allows the IC to remain in a normal
functional mode and selects the one-bit bypass register to be connected
between TDI and TDO. The BYPASS instruction allows serial data to be transferred
through the IC from TDI to TDO without affecting the operation of the IC.
HIGH-IMPEDANCE
The optional High-Impedance instruction sets all outputs (including two-state
as well as three-state types) of an IC to a disabled (high-impedance) state and
selects the one-bit bypass register to be connected between TDI and TDO.
During this instruction, data can be shifted through the bypass register from TDI
to TDO without affecting the condition of the IC outputs.
29
MAY 29, 2006
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IDT72T36135M 2.5V 18M-BIT TeraSync
524,288 x 36
COMMERCIAL AND INDUSTRIAL
TEMPERATURE RANGES
tRS
MRS
tRSS
tRSR
tRSS
tRSR
tRSS
tRSR
tRSS
tRSR
REN
WEN
FWFT/SI
LD
tRSS
FSEL0,
FSEL1
tHRSS
WHSTL
tHRSS
RHSTL
tHRSS
SHSTL
tRSS
PFM
tRSS
RT
tRSS
SEN
tRSF
If FWFT = HIGH, OR = HIGH
EF/OR[1:2]
If FWFT = LOW, EF = LOW
tRSF
If FWFT = LOW, FF = HIGH
FF/IR[1:2]
If FWFT = HIGH, IR = LOW
tRSF
PAE[1:2]
tRSF
PAF[1:2]
tRSF
OE = HIGH
Q0 - Q n
6723 drw15
OE = LOW
NOTE:
1. During Master Reset the High-Impedance control of the Qn data outputs is provided by OE only, RCS can be HIGH or LOW until the first rising edge of RCLK
after Master Reset is complete.
Figure 8. Master Reset Timing
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524,288 x 36
COMMERCIAL AND INDUSTRIAL
TEMPERATURE RANGES
tRS
PRS
tRSS
tRSR
REN
tRSS
tRSR
WEN
tRSS
RT
tRSS
SEN
If FWFT = HIGH, OR = HIGH
tRSF
EF/OR
[1:2]
If FWFT = LOW, EF = LOW
If FWFT = LOW, FF = HIGH
tRSF
FF/IR
[1:2]
PAE
[1:2]
If FWFT = HIGH, IR = LOW
tRSF
tRSF
PAF
[1:2]
tRSF
OE = HIGH
Q0 - Qn
OE = LOW
6723 drw16
NOTE:
1. During Partial Reset the High-Impedance control of the Qn data outputs is provided by OE only, RCS can be HIGH or LOW until the first rising edge
of RCLK after Master Reset is complete.
Figure 9. Partial Reset Timing
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MAY 29, 2006
 36-BIT FIFO
IDT72T36135M 2.5V 18M-BIT TeraSync
524,288 x 36
COMMERCIAL AND INDUSTRIAL
TEMPERATURE RANGES
tCLK
tCLK
tCLKH
NO WRITE
NO WRITE
L
WCLK
2
1
(1)
tSKEW1
tDS
1
(1)
tSKEW1
tDH
2
tDH
tDS
DX+1
DX
D0 - Dn
tWFF
tWFF
tWFF
tWFF
FF[1:2]
WEN
RCLK
tENS
tENS
tENH
tENH
REN
tENS
RCS
tA
tA
Q0 - Qn
NEXT DATA READ
DATA READ
6723 drw17
tRCSLZ
NOTES:
1. tSKEW1 is the minimum time between a rising RCLK edge and a rising WCLK edge to guarantee that FF[1:2] will go HIGH (after one WCLK cycle pus tWFF). If the time between
the rising edge of the RCLK and the rising edge of the WCLK is less than tSKEW1, then the FF[1:2] deassertion may be delayed one extra WCLK cycle.
2. LD = HIGH, OE = LOW, EF[1:2] = HIGH.
3. WCS = LOW.
Figure 10. Write Cycle and Full Flag Timing (IDT Standard Mode)
tCLK
tCLKH
1
RCLK
tENS
tCLKL
2
tENH
tENS
REN
tENH
tENH
tENS
NO OPERATION
NO OPERATION
tREF
tREF
tREF
EF[1:2]
tA
tA
LAST WORD
Q0 - Qn
tOLZ
LAST WORD
tOHZ
tOE
tA
D0
D1
tOLZ
OE
(1)
tSKEW1
WCLK
tENH
tENS
tENS
tENH
WEN
tWCSS
tWCSH
WCS
tDS
D0 - Dn
D0
tDH
tDS
tDH
D1
6723 drw18
NOTES:
1. tSKEW1 is the minimum time between a rising WCLK edge and a rising RCLK edge to guarantee that EF[1:2] will go HIGH (after one RCLK cycle plus tREF). If the time between
the rising edge of WCLK and the rising edge of RCLK is less than tSKEW1, then EF[1:2] deassertion may be delayed one extra RCLK cycle.
2. LD = HIGH.
3. First data word latency = tSKEW1 + 1*TRCLK + tREF.
4. RCS is LOW.
Figure 11. Read Cycle, Output Enable, Empty Flag and First Data Word Latency (IDT Standard Mode)
32
MAY 29, 2006
 36-BIT FIFO
IDT72T36135M 2.5V 18M-BIT TeraSync
524,288 x 36
COMMERCIAL AND INDUSTRIAL
TEMPERATURE RANGES
2
1
RCLK
tENS
REN
tENS
tENS
tENH
tENS
RCS
tREF
EF[1:2]
tRCSLZ
Q0 - Qn
tRCSHZ
tA
tRCSLZ
tREF
tRCSH
tA
Z
LAST DATA-1
LAST DATA
tSKEW1(1)
WCLK
tENS
tENH
WEN
tDS
Dn
tDH
Dx
6723 drw19
NOTES:
1. tSKEW1 is the minimum time between a rising WCLK edge and a rising RCLK edge to guarantee that EF[1:2] will go HIGH (after one RCLK cycle plus tREF). If the time between
the rising edge of WCLK and the rising edge of RCLK is less than tSKEW1, then EF[1:2] deassertion may be delayed one extra RCLK cycle.
2. LD = HIGH.
3. First data word latency = tSKEW1 + 1*TRCLK + tREF.
4. OE is LOW.
Figure 12. Read Cycle and Read Chip Select (IDT Standard Mode)
33
MAY 29, 2006
34
W1
W2
1
tENS
tSKEW1(1)
tDH
2
tRCSLZ
W3
PREVIOUS DATA IN OUTPUT REGISTER
tDS
tENS
3
tREF
tA
W4
tDS
W[n +2]
W[n+3]
1
tPAES
tSKEW2(2)
2
W[n+4]
W[
D- +1
2
1
]
tDS
W[
D- +2
2
1
]
W[
D- +3
2
1
]
W1
W[D-m-2]
tDS
W[D-m-1]
W[D-m]
1
tPAFS
W[D-m+1]
W[D-m+2]
W[D-1]
WD
6723 drw20
tWFF
tENH
Figure 13. Write Timing (First Word Fall Through Mode)
NOTES:
1. tSKEW1 is the minimum time between a rising WCLK edge and a rising RCLK edge to guarantee that OR[1:2] will go LOW after two RCLK cycles plus tREF. If the time between the rising edge of WCLK and the rising edge of RCLK
is less than tSKEW1, then OR[1:2] assertion may be delayed one extra RCLK cycle.
2. tSKEW2 is the minimum time between a rising WCLK edge and a rising RCLK edge to guarantee that PAE[1:2] will go HIGH after one RCLK cycle plus tPAES. If the time between the rising edge of WCLK and the rising edge of RCLK
is less than tSKEW2, then the PAE[1:2] deassertion may be delayed one extra RCLK cycle.
3. LD = HIGH, OE = LOW
4. n = PAE[1:2] offset, m = PAF[1:2] offset and D = maximum FIFO depth.
5. D = 524,289 for the IDT72T36135M.
6. First data word latency = tSKEW1 + 2*TRCLK + tREF.
IR[1:2]
PAF[1:2]
PAE[1:2]
OR[1:2]
Q0 - Qn
REN
RCS
RCLK
D0 - Dn
WEN
WCLK
 36-BIT FIFO
IDT72T36135M 2.5V 18M-BIT TeraSync
524,288 x 36
COMMERCIAL AND INDUSTRIAL
TEMPERATURE RANGES
MAY 29, 2006
35
tDS
tENS
W1
tOHZ
WD
tENS
tWFF
tDH
tENH
W1
tOE
tA
W2
1
(1)
tSKEW1
tA
2
tWFF
W3
Wm+2
(2)
tSKEW2
W[m+3]
tA
tPAFS
W[m+4]
+ 1]
2
W[ D-1
2 + 2]
W[ D-1
tA
W[D-n-1]
tA
W[D-n]
1
tPAES
W[D-n+1]
W[D-n+2]
W[D-1]
tA
tENS
WD
6723 drw21
tREF
Figure 14. Read Timing (First Word Fall Through Mode)
NOTES:
1. tSKEW1 is the minimum time between a rising RCLK edge and a rising WCLK edge to guarantee that IR[1:2] will go LOW after one WCLK cycle plus tWFF. If the time between the rising edge of RCLK and the rising edge of WCLK
is less than tSKEW1, then the IR[1:2] assertion may be delayed one extra WCLK cycle.
2. tSKEW2 is the minimum time between a rising RCLK edge and a rising WCLK edge to guarantee that PAF[1:2] will go HIGH after one WCLK cycle plus tPAFS. If the time between the rising edge of RCLK and the rising edge of
WCLK is less than tSKEW2, then the PAF[1:2] deassertion may be delayed one extra WCLK cycle.
3. LD = HIGH.
4. n = PAE[1:2] Offset, m = PAF[1:2] offset and D = maximum FIFO depth.
5. D = 524,289 for the IDT72T36135M.
6. RCS = LOW.
IR[1:2]
PAF[1:2]
PAE[1:2]
OR[1:2]
Q0 - Qn
OE
REN
RCLK
D0 - Dn
WEN
WCLK
 36-BIT FIFO
IDT72T36135M 2.5V 18M-BIT TeraSync
524,288 x 36
COMMERCIAL AND INDUSTRIAL
TEMPERATURE RANGES
MAY 29, 2006
36
tDS
tENS
W1
tENS
WD
tRCSHZ
tENH
tENS
tWFF
tDH
tENH
W2
tRCSLZ
1
(1)
tSKEW1
tA
2
tWFF
W3
Wm+2
(2)
tSKEW2
W[m+3]
tA
tPAFS
W[m+4]
+ 1]
2
W[ D-1
+ 2]
2
W[ D-1
tA
W[D-n-1]
tA
W[D-n]
1
tPAES
W[D-n+1]
W[D-n+2]
W[D-1]
tA
tENS
WD
6723 drw22
tREF
Figure 15. Read Cycle and Read Chip Select Timing (First Word Fall Through Mode)
NOTES:
1. tSKEW1 is the minimum time between a rising RCLK edge and a rising WCLK edge to guarantee that IR[1:2] will go LOW after one WCLK cycle plus tWFF. If the time between the rising edge of RCLK and the rising edge of WCLK
is less than tSKEW1, then the IR[1:2] assertion may be delayed one extra WCLK cycle.
2. tSKEW2 is the minimum time between a rising RCLK edge and a rising WCLK edge to guarantee that PAF[1:2] will go HIGH after one WCLK cycle plus tPAFS. If the time between the rising edge of RCLK and the rising edge of
WCLK is less than tSKEW2, then the PAF[1:2] deassertion may be delayed one extra WCLK cycle.
3. LD = HIGH.
4. n = PAE[1:2] Offset, m = PAF[1:2] offset and D = maximum FIFO depth.
5. D = 524,289 for the IDT72T36135M.
6. OE = LOW.
IR[1:2]
PAF[1:2]
PAE[1:2]
OR[1:2]
Q0 - Qn
RCS
REN
RCLK
D0 - Dn
WEN
WCLK
 36-BIT FIFO
IDT72T36135M 2.5V 18M-BIT TeraSync
524,288 x 36
COMMERCIAL AND INDUSTRIAL
TEMPERATURE RANGES
MAY 29, 2006
HIGH-Z
tDS
tENS
W1
tDH
tSKEW
tDS
1
W2
tDH
tENH
2
tREF
3
1st Word falls through to
O/P register on this cycle
tENS
tRCSLZ
W1
tENS
tA
tENH
W2
tENS
tRCSHZ
tENH
tENS
tENS
tRCSLZ
tREF
W2
6723 drw13
37
Figure 16 . RCS and REN Read Operation (FWFT Mode)
NOTES:
1. It is very important that the REN be held HIGH for at least one cycle after RCS has gone LOW. If REN goes LOW on the same cycle as RCS or earlier, then Word, W1 will be lost, Word, W2 will be read on the output when the
bus goes to LOW-Z.
2. The 1st Word will fall through to the output register regardless of REN and RCS. However, subsequent reads require that both REN and RCS be active, LOW.
Dn
WEN
WCLK
Qn
OR
[1:2]
RCS
REN
RCLK
 36-BIT FIFO
IDT72T36135M 2.5V 18M-BIT TeraSync
524,288 x 36
COMMERCIAL AND INDUSTRIAL
TEMPERATURE RANGES
MAY 29, 2006
38
1
WMK-
tENS
tA
tENS
WMK
tENH
tA
WMK+1
tA
tA
tENS
tENS
tENS
WMK+n
1
tSKEW2
tREF
tENH
Figure 17. Retransmit from Mark (IDT Standard Mode)
NOTES:
1. Retransmit setup is complete when EF[1:2] returns HIGH.
2. OE = LOW;RCS = LOW.
3. RT must be HIGH when reading from FIFO.
4. Once MARK is set, the write pointer will not increment past the ‘marked’ location, preventing overwrites of Retransmit data.
5. Before a “MARK” can be set there must be at least 64 number of words of data between the Write Pointer and Read Pointer locations.
6. A transition in the PAE[1:2] flag may occur one RCLK cycle earlier than shown, (on cycle 2).
PAF
[1:2]
WEN
WCLK
PAE
[1:2]
EF
[1:2]
RT
MARK
Qn
REN
RCLK
2
tPAFS
1
tREF
tENS
tA
2
WMK
tA
3
6723 drw24
tPAES(6)
WMK+1
 36-BIT FIFO
IDT72T36135M 2.5V 18M-BIT TeraSync
524,288 x 36
COMMERCIAL AND INDUSTRIAL
TEMPERATURE RANGES
MAY 29, 2006
39
WMK-1
tENS
tA
tENS
WMK
tENH
tA
WMK+1
tA
tA
tENS
tENS
tENS
WMK+n
1
tSKEW2
tREF
tENH
Figure 18. Retransmit from Mark (First Word Fall Through Mode)
NOTES:
1. Retransmit setup is complete when OR[1:2] returns LOW.
2. OE = LOW;RCS = LOW.
3. RT must be HIGH when reading from FIFO.
4. Once MARK is set, the write pointer will not increment past the ‘marked’ location, preventing overwrites of Retransmit data.
5. Before a “MARK” can be set there must be at least 64 number of words of data between the Write Pointer and Read Pointer locations.
6. A transition in the PAE[1:2] flag may occur one RCLK cycle earlier than shown, (on cycle 2).
PAF
[1:2]
WEN
WCLK
PAE
[1:2]
OR
[1:2]
RT
MARK
Qn
REN
RCLK
2
tPAFS
tA
1
tREF
WMK
tENS
tA
2
WMK+1
tA
3
6723 drw25
tPAES(6)
WMK+2
 36-BIT FIFO
IDT72T36135M 2.5V 18M-BIT TeraSync
524,288 x 36
COMMERCIAL AND INDUSTRIAL
TEMPERATURE RANGES
MAY 29, 2006
 36-BIT FIFO
IDT72T36135M 2.5V 18M-BIT TeraSync
524,288 x 36
tSCKH
COMMERCIAL AND INDUSTRIAL
TEMPERATURE RANGES
tSCLK
tSCKL
SCLK
tSENH
tSENS
tENH
SEN
tLDS
tLDS
tLDH
LD
tSDH
tSDS
BIT 19
BIT 1
SI
BIT 19
BIT 1
EMPTY OFFSET
6723 drw26
FULL OFFSET
Figure 19. Serial Loading of Programmable Flag Registers (IDT Standard and FWFT Modes)
tCLK
tCLKH
tCLKL
WCLK
tLDH
tLDS
tLDH
LD
tENS
tENH
tDS
tDH
tENH
WEN
tDH
PAF
OFFSET
PAE
OFFSET
D0 - D n
6723 drw27
Figure 20. Parallel Loading of Programmable Flag Registers (IDT Standard and FWFT Modes)
tCLK
tCLKH
tCLKL
RCLK
tLDH
tLDS
tLDH
tLDS
tLDH
tLDS
LD
tENH
tENH
tENS
tENH
tENS
tENS
REN
tA
Q0 - Q n
DATA IN OUTPUT REGISTER
tA
PAE OFFSET VALUE
tA
PAF OFFSET VALUE
PAE OFFSET
6723 drw28
NOTES:
1. OE = LOW.
2. The offset registers cannot be read on consecutive RCLK cycles. The read must be disabled (REN = HIGH) for a minimum of one RCLK cycle in between register accesses.
Figure 21. Parallel Read of Programmable Flag Registers (IDT Standard and FWFT Modes)
40
MAY 29, 2006
 36-BIT FIFO
IDT72T36135M 2.5V 18M-BIT TeraSync
524,288 x 36
tCLKL
COMMERCIAL AND INDUSTRIAL
TEMPERATURE RANGES
tCLKL
WCLK
1
2
1
tENS
2
tENH
WEN
tPAFS
PAF
[1:2]
tPAFS
(2)
D-(m+1) words
(2)
in FIFO
D - m words in FIFO
(2)
D - (m +1) words in FIFO
(3)
tSKEW2
RCLK
tENH
tENS
REN
6723 drw29
NOTES:
1. m = PAF[1:2] offset.
2. D = maximum FIFO depth.
In IDT Standard mode: D = 524,288 for the IDT72T36135M.
In FWFT mode: D = 524,289 for the IDT72T36135M.
3. tSKEW2 is the minimum time between a rising RCLK edge and a rising WCLK edge to guarantee that PAF[1:2] will go HIGH (after one WCLK cycle plus tPAFS). If the time between
the rising edge of RCLK and the rising edge of WCLK is less than tSKEW2, then the PAF[1:2] deassertion time may be delayed one extra WCLK cycle.
4. PAF[1:2] is asserted and updated on the rising edge of WCLK only.
5. Select this mode by setting PFM HIGH during Master Reset.
Figure 22. Synchronous Programmable Almost-Full Flag Timing (IDT Standard and FWFT Modes)
tCLKH
tCLKL
WCLK
tENS
tENH
WEN
(2)
PAE
[1:2]
RCLK
(2)
n words in FIFO ,
(3)
n + 1 words in FIFO
(4)
tSKEW2
1
n words in FIFO ,
(3)
n + 1 words in FIFO
(2)
n + 1 words in FIFO ,
(3)
n + 2 words in FIFO
tPAES
2
tPAES
1
tENS
2
tENH
REN
6723 drw30
NOTES:
1. n = PAE[1:2] offset.
2. For IDT Standard mode
3. For FWFT mode.
4. tSKEW2 is the minimum time between a rising WCLK edge and a rising RCLK edge to guarantee that PAE[1:2] will go HIGH (after one RCLK cycle plus tPAES). If the time between
the rising edge of WCLK and the rising edge of RCLK is less than tSKEW2, then the PAE[1:2] deassertion may be delayed one extra RCLK cycle.
5. PAE[1:2] is asserted and updated on the rising edge of WCLK only.
6. Select this mode by setting PFM HIGH during Master Reset.
7. RCS = LOW.
Figure 23. Synchronous Programmable Almost-Empty Flag Timing (IDT Standard and FWFT Modes)
41
MAY 29, 2006
 36-BIT FIFO
IDT72T36135M 2.5V 18M-BIT TeraSync
524,288 x 36
tCLKH
COMMERCIAL AND INDUSTRIAL
TEMPERATURE RANGES
tCLKL
WCLK
tENS
tENH
WEN
tPAFA
PAF[1:2]
D - m words
in FIFO
D - (m + 1) words in FIFO
D - (m + 1) words
in FIFO
tPAFA
RCLK
tENS
REN
6723 drw31
NOTES:
1. m = PAF[1:2] offset.
2. D = maximum FIFO Depth.
In IDT Standard Mode: D = 524,288 for the IDT72T36135M.
In FWFT Mode: D = 524,289 for the IDT72T36135M.
3. PAF[1:2] is asserted to LOW on WCLK transition and reset to HIGH on RCLK transition.
4. Select this mode by setting PFM LOW during Master Reset.
5. RCS = LOW.
Figure 24. Asynchronous Programmable Almost-Full Flag Timing (IDT Standard and FWFT Modes)
tCLKH
tCLKL
WCLK
tENS
tENH
WEN
PAE[1:2]
tPAEA
n words in FIFO(2),
n + 1 words in FIFO(3)
n + 1 words in FIFO(2),
n + 2 words in FIFO(3)
n words in FIFO(2),
n + 1 words in FIFO(3)
tPAE
A
RCLK
tENS
REN
6723 drw22
NOTES:
1. n = PAE[1:2] offset.
2. For IDT Standard Mode.
3. For FWFT Mode.
4. PAE[1:2] is asserted LOW on RCLK transition and reset to HIGH on WCLK transition.
5. Select this mode by setting PFM LOW during Master Reset.
6. RCS = LOW.
Figure 25. Asynchronous Programmable Almost-Empty Flag Timing (IDT Standard and FWFT Modes)
42
MAY 29, 2006
 36-BIT FIFO
IDT72T36135M 2.5V 18M-BIT TeraSync
524,288 x 36
COMMERCIAL AND INDUSTRIAL
TEMPERATURE RANGES
RCLK
tENS
REN
tENH
tA
Qn
W0
W1
tFFA
FF[1:2]
tFFA
tFFA
tCYC
WR
tDS
Dn
tCYH
tDH
WD
WD+1
6723 drw23
NOTE:
1. OE = LOW, WEN = LOW and RCS = LOW.
Figure 26. Asynchronous Write, Synchronous Read, Full Flag Operation (IDT Standard Mode)
1
RCLK
2
tENS
REN
tEN
H
tA
tA
Qn
Last Word
W1
W0
tREF
tREF
EF[1:2]
tCYL
tSKEW
WR
tCYH
tCYC
tDH
tDS
Dn
W0
tDH
tDS
W1
6723 drw34
NOTE:
1. OE = LOW, WEN = LOW and RCS = LOW.
Figure 27. Asynchronous Write, Synchronous Read, Empty Flag Operation (IDT Standard Mode)
43
MAY 29, 2006
 36-BIT FIFO
IDT72T36135M 2.5V 18M-BIT TeraSync
524,288 x 36
COMMERCIAL AND INDUSTRIAL
TEMPERATURE RANGES
No Write
WCLK
1
2
WEN
Dn
DF
tWFF
DF+1
tWFF
FF[1:2]
tCYC
tSKEW
tCYL
tCYH
RD
tAA
tAA
Qn
Last Word
WX
WX+1
6723 drw35
NOTE:
1. OE = LOW, RCS = LOW and REN = LOW.
2. Asynchronous Read is available in IDT Standard Mode only.
Figure 28. Synchronous Write, Asynchronous Read, Full Flag Operation (IDT Standard Mode)
WCLK
tENS
tENH
WEN
tDS
Dn
EF[1:2]
tDH
W0
tEFA
tRPE
RD
tEFA
tCYH
tAA
Qn
Last Word in Output Register
W0
6723 drw36
NOTE:
1. OE = LOW, REN = LOW and RCS = LOW.
2. Asynchronous Read is available in IDT Standard Mode only.
Figure 29. Synchronous Write, Asynchronous Read, Empty Flag Operation (IDT Standard Mode)
44
MAY 29, 2006
 36-BIT FIFO
IDT72T36135M 2.5V 18M-BIT TeraSync
524,288 x 36
tCYH
tCYC
tCY
L
WR
tDH
Dn
COMMERCIAL AND INDUSTRIAL
TEMPERATURE RANGES
tDH
tDS
W0
W1
RD
tAA
tAA
Qn
W1
W0
Last Word in O/P Register
tRPE
tEFA
tEFA
EF[1:2]
6723 drw37
NOTES:
1. OE = LOW, WEN = LOW, REN = LOW and RCS = LOW
2. Asynchronous Read is available in IDT Standard Mode only.
Figure 30. Asynchronous Write, Asynchronous Read, Empty Flag Operation (IDT Standard Mode)
tCYC
tCYH
tCYL
WR
tDH
tDS
Dn
tDS
tDH
Wy+1
Wy
tCYC
tCYH
tCYL
RD
tAA
Qn
Wx
tAA
Wx+1
Wx+2
tFFA
tFFA
FF[1:2]
6723 drw38
NOTES:
1. OE = LOW, WEN = LOW, REN = LOW and RCS = LOW.
2. Asynchronous Read is available in IDT Standard Mode only.
Figure 31. Asynchronous Write, Asynchronous Read, Full Flag Operation (IDT Standard Mode)
45
MAY 29, 2006
 36-BIT FIFO
IDT72T36135M 2.5V 18M-BIT TeraSync
524,288 x 36
COMMERCIAL AND INDUSTRIAL
TEMPERATURE RANGES
OPTIONAL CONFIGURATIONS
flags should be gated using logical gates to remove the possibility of clock skew
between the two device(s) outputs.
Figure 32 demonstrates a width expansion using two IDT72T36135M
devices. D0 - D35 from each device form a 72-bit wide input bus and Q0-Q35
from each device form a 72-bit wide output bus. Any word width can be attained
by adding additional IDT72T36135M devices.
WIDTH EXPANSION CONFIGURATION
Word width may be increased by connecting together the control signals of
multiple devices plus using external gating logic. Status flags can be gated and
detected from the gate output. The EF[1:2], FF[1:2], PAE[1:2], and PAF[1:2]
PROGRAMMABLE ALMOST FULL
SERIAL CLOCK
(SCLK)
PARTIAL RESET (PRS)
FIFO#1
FIFO#2
MASTER RESET (MRS)
AND
GATE
FIFO#1 GATE
(1)
RETRANSMIT (RT)
FIFO#2 GATE
(1)
Dm+1 - Dn
m+n
D0 - Dm
m
(PAF)
FIFO#2
AND
GATE
FIRST WORD FALL THROUGH/
SERIAL INPUT (FWFT/SI)
DATA IN
FULL FLAG/INPUT READY
FIFO#1
AND
GATE
GATE
(1)
FIFO#1
GATE
(1)
(EF/OR)
FIFO#2
EMPTY FLAG/OUTPUT READY
n
READ CLOCK (RCLK)
READ CHIP SELECT (RCS)
WRITE CLOCK (WCLK)
GATE
(1)
(FF/IR)
GATE
(1)
AND
GATE
(PAE)
AND
GATE
AND
GATE
PROGRAMMABLE ALMOST
EMPTY
READ ENABLE (REN)
WRITE ENABLE (WEN)
OUTPUT ENABLE (OE)
LOAD (LD)
FULL FLAG/INPUT READY (FF/IR) #1
FULL FLAG/INPUT READY (FF/IR) #1
GATE
(1)
FULL FLAG/INPUT READY (FF/IR) #2
FULL FLAG/INPUT READY (FF/IR)) #2
IDT
72T36135M
IDT
72T36135M
FIFO
#1
FIFO
#2
PROGRAMMABLE ALMOST FULL (PAF) #1
AND
GATE
PROGRAMMABLE ALMOST FULL (PAF) #1
PROGRAMMABLE ALMOST FULL (PAF) #2
PROGRAMMABLE ALMOST FULL (PAF) #2
GATE
(1)
AND
GATE
EMPTY FLAG/OUTPUT READY (EF/OR) #1
EMPTY FLAG/OUTPUT READY (EF/OR) #2
EMPTY FLAG/OUTPUT READY (EF/OR) #1
GATE
(1)
(4)
AND
GATE
EMPTY FLAG/OUTPUT READY (EF/OR) #2
PROGRAMMABLE ALMOST EMPTY (PAE) #1
PROGRAMMABLE ALMOST EMPTY (PAE) #2
PROGRAMMABLE ALMOST EMPTY (PAE) #1
GATE
(1)
AND
GATE
(4)
PROGRAMMABLE ALMOST EMPTY (PAE) #2
m
n
Qm+1 - Qn
m+n
DATA OUT
Q0 - Qm
6723 drw39
NOTES:
1. An OR gate is used for FWFT mode, AND gate for IDT mode.
2. Do not connect any output control signals directly together.
3. FIFO #1 and FIFO #2 must be the same depth, but may be different word widths.
4. PAE/PAF[1:2] optional, see section of external gating of output flags.
5. Recommend IDT74LVC32A 2-Input Positive OR Gate. Recommend IDT74LVC08A 2-Input AND Gate.
Figure 32. Block Diagram of 524,288 x 72 Width Expansion
output OR[1:2] and IR[1:2] pins. Two sets of OR gates are used in this mode
to derive a feedback loop to the REN and WEN pins to avoid writing or reading
to/from a device when the device is not ready to accept data. The 2nd row of
OR gates take in the IR or OR pin’s status and allow for data to be written/read
to the next FIFO in the chain. If the IR or OR pins are low, this will enable the
device to accept writes or reads from the next device in line. To use this mode,
the FIFO device’s clock speed depends on the added prop delay of the “OR”
gates and setup time between the two FIFO devices. Example, if the “OR” gates
being used have a combined 10ns propagation delay, a 1ns jitter budget, and
1ns clock skew margin, 12ns must be taken into account during each clock cycle.
DEPTH EXPANSION CONFIGURATION (FWFT MODE ONLY)
The IDT72T36135M can easily be adapted to applications requiring depths
greater than and 524,288 with an 36-bit bus width. In FWFT mode, the FIFOs
can be connected in series (the data outputs of one FIFO connected to the data
inputs of the next) with no external logic necessary. The resulting configuration
provides a total depth equivalent to the sum of the depths associated with each
single FIFO. Figure 33 shows a depth expansion using two IDT72T36135M
devices.
For depth expansion mode option #1, “logical OR gates” need to be used
to drive the active low input WEN and REN pins respectively from the active low
46
MAY 29, 2006
 36-BIT FIFO
IDT72T36135M 2.5V 18M-BIT TeraSync
524,288 x 36
COMMERCIAL AND INDUSTRIAL
TEMPERATURE RANGES
For instance, a 25MHz clock has around a 40ns clock cycle. For a 45% - 55%
clock duty cycle, 18ns account for 45% of the duty cycle when the clock is high.
This means, 18ns – 12ns = 6ns of setup time for data to be available at the 2nd
IDT FIFO which is fine considering the setup time for this FIFO is around 1.5ns.
Designers must leave an adequate timing window to allow data to be captured
by the 2nd IDT FIFO. Please take this into consideration when using this depth
expansion mode to avoid data meta-stability issues. For buffering greater than
18Mbits at higher frequencies, IDT recommends using the IDT Sequential Flow
Controller (SFC). Please see IDT Flow-Control Management (FCM) product
web site for more information on the SFC.
Care should be taken to select FWFT mode during Master Reset for all FIFOs
in the depth expansion configuration. The first word written to an empty
configuration will pass from one FIFO to the next ("ripple down") until it finally
appears at the outputs of the last FIFO in the chain – no read operation is
necessary but the RCLK of each FIFO must be free-running. Each time the data
word appears at the outputs of one FIFO, that device's OR[1:2] line goes LOW,
enabling a write to the next FIFO in line. OR gates are used to take in the
considerations of the next FIFO in the chains IR pin status. If the IR pins are Low,
this will enable the device to accept writes from upstream devices.
For an empty expansion configuration, the amount of time it takes for OR[1:2]
of the last FIFO in the chain to go LOW (i.e. valid data to appear on the last FIFO's
outputs) after a word has been written to the first FIFO is the sum of the delays
for each individual FIFO and the sum of the OR gate prop delays:
The "ripple down" delay is only noticeable for the first word written to an empty
depth expansion configuration. There will be no delay evident for subsequent
words written to the configuration.
The first free location created by reading from a full depth expansion
configuration will "bubble up" from the last FIFO to the previous one until it finally
moves into the first FIFO of the chain. Each time a free location is created in one
FIFO of the chain, that FIFO's IR[1:2] line goes LOW, enabling the preceding
FIFO to write a word to fill it.
For a full expansion configuration, the amount of time it takes for IR[1:2] of the
first FIFO in the chain to go LOW after a word has been read from the last FIFO
is the sum of the delays for each individual FIFO and the sum of the OR gate
prop delays:
(N – 1)*(3*transfer clock) + 2 TWCLK + 2 *OR prop delay
where N is the number of FIFOs in the expansion and TWCLK is the WCLK
period. Note that extra cycles should be added for the possibility that the tSKEW1
specification is not met between RCLK and transfer clock, or WCLK and transfer
clock, for the IR[1:2] flag.
The Transfer Clock line should be tied to either WCLK or RCLK, whichever
is faster. Both these actions result in data moving, as quickly as possible, to the
end of the chain and free locations to the beginning of the chain.
Depth Expansion Option #2 is depicted in Figure 34, Depth Expansion
Option#2. One device will be active at a time by toggling the WCS pins. Data
will be written into FIFO in Ping Pong fashion. First data is written into FIFO#1,
second data is written into FIFO#2, third data is written into FIFO#1, fourth data
is written into FIFO#2, and so on. Data can then be read out in the same manner
on the read side by toggling the RCS1 and RCS2.
(N – 1)*(4*transfer clock) + 3*TRCLK + 2 *OR prop delay
where N is the number of FIFOs in the expansion and TRCLK is the RCLK period.
Note that extra cycles should be added for the possibility that the tSKEW1
specification is not met between WCLK and transfer clock, or RCLK and transfer
clock, for the OR[1:2] flag.
FWFT/SI
TRANSFER CLOCK
WRITE CLOCK
WRITE ENABLE
INPUT READY
FWFT/SI
WCLK
RCLK
OR1
OR2
WEN
IR
WCLK
IDT
72T36135M
REN
OR
GATE
IR1
OR
GATE
IR2
n
RCS
IDT
72T36135M
GND
n
Qn
Dn
READ CLOCK
RCLK
WEN
RCS
OE
DATA IN
OR
GATE
OR
GATE
FWFT/SI
READ CHIP SELECT
READ ENABLE
REN
OR
OUTPUT READY
OE
OUTPUT ENABLE
n
Dn
DATA OUT
Qn
6723 drw40
Figure 33. Depth Expansion Option #1
FF1
WCS1
EF1
IDT
72T36135M #1
RCS1
36
36
WEN
WCS2
REN
IDT
72T36135M #2
EF2
FF2
RCS2
6723 drw41
Figure 34. Depth Expansion Option #2
47
MAY 29, 2006
ORDERING INFORMATION
IDT
XXXXX
X
XX
Device Type Power Speed
X
Package
X
X
Process /
Temperature
Range
BLANK
I(1)
Commercial (0° C to +70° C)
Industrial (-40° C to +85° C)
G
Green
BB
Plastic Ball Grid Array (PBGA, BB240-1)
5
6
Commercial Only
Commercial and Industrial
L
Low Power
Clock Cycle Time (tCLK)
Speed in Nanoseconds
72T36135M 524,288 x 36  2.5V 18M-Bit High-Speed TeraSync FIFO
6723 drw42
NOTE:
1. Industrial temperature range product for 6ns speed grade is available as a standard device. All other speed grades are available by special order.
2. Green parts are available. For specific speeds and packages please contact your sales office.
DATASHEET DOCUMENT HISTORY
09/01/2005
02/28/2006
05/29/2006
pg. 1.
pg. 10.
pgs. 10, 21, and 23.
CORPORATE HEADQUARTERS
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800-345-7015 or 408-284-8200
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www.idt.com
48
for Tech Support:
408-360-1753
email: [email protected]
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