ChipFind - документация

Электронный компонент: 72V51443

Скачать:  PDF   ZIP
1
2003 Integrated Device Technology, Inc. All rights reserved. Product specifications subject to change without notice.
DSC-5939/8
JUNE 2003
IDT and the IDT logo are registered trademarks of Integrated Device Technology, Inc
COMMERCIAL AND INDUSTRIAL TEMPERATURE RANGES
3.3V MULTI-QUEUE FLOW-CONTROL DEVICES
(16 QUEUES) 18 BIT WIDE CONFIGURATION
589,824 bits
1,179,648 bits
2,359,296 bits
IDT72V51433
IDT72V51443
IDT72V51453
FEATURES:




Choose from among the following memory density options:
IDT72V51433
Total Available Memory = 589,824 bits
IDT72V51443
Total Available Memory = 1,179,648 bits
IDT72V51453
Total Available Memory = 2,359,296 bits




Configurable from 1 to 16 Queues




166 MHz High speed operation (6ns cycle time)




3.7ns access time




Queues may be configured at master reset from the pool of
Total Available Memory in blocks of 512 x 18 or 1,024 x 9




Independent Read and Write access per queue




User programmable via serial port




Default multi-queue device configurations
-IDT72V51433: 2,048 x 18 x 16Q or 4,096 x 9 x 16Q
-IDT72V51443: 4,096 x 18 x 16Q or 8,192 x 9 x 16Q
-IDT72V51453: 8,192 x 18 x 16Q or 16,384 x 9 x 16Q




100% Bus Utilization, Read and Write on every clock cycle




Individual, Active queue flags (
OV, FF, PAE, PAF)




8 bit parallel flag status on both read and write ports




Shows
PAE and PAF status of 8 Queues




Direct or polled operation of flag status bus




Global Bus Matching - (All Queues have same Input Bus Width
and Output Bus Width)




User Selectable Bus Matching Options:
- x18in to x18out
- x9in to x18out
- x18in to x9out
- x9in to x9out




FWFT mode of operation on read port




Partial Reset, clears data in single Queue




Expansion of up to 8 multi-queue devices in parallel is available




JTAG Functionality (Boundary Scan)




Available in a 256-pin PBGA, 1mm pitch, 17mm x 17mm




HIGH Performance submicron CMOS technology




Industrial temperature range (-40C to +85C) is available
Q
0
Q
1
Q
2
Q
15
MULTI-QUEUE FLOW-CONTROL DEVICE
FSTR
WEN
PAF
FF
WRADD
WADEN
WCLK
PAFn
x9, x18
DATA IN
ESTR
REN
PAE
RDADD
RADEN
RCLK
PAEn
x9, x18
DATA OUT
OE
OV
WRITE CONTROL
Din
Qout
8
8
8
7
READ CONTROL
WRITE FLAGS
READ FLAGS
5939 drw01
FUNCTIONAL BLOCK DIAGRAM
2
COMMERCIAL AND INDUSTRIAL
TEMPERATURE RANGES
IDT72V51433/72V51443/72V51453 3.3V, MULTI-QUEUE FLOW-CONTROL DEVICES
(16 QUEUES) 18 BIT WIDE CONFIGURATION 589,824, 1,179,648 and 2,359,296 bits
DESCRIPTION:
The IDT72V51433/72V51443/72V51453 multi-queue flow-control de-
vices are single chip within which anywhere between 1 and 16 discrete FIFO
queues can be setup. All queues within the device have a common data input
bus, (write port) and a common data output bus, (read port). Data written into
the write port is directed to a respective queue via an internal de-multiplex
operation, addressed by the user. Data read from the read port is accessed
from a respective queue via an internal multiplex operation, addressed by the
user. Data writes and reads can be performed at high speeds up to 166MHz,
with access times of 3.7ns. Data write and read operations are totally
independent of each other, a queue maybe selected on the write port and a
different queue on the read port or both ports may select the same queue
simultaneously.
The device provides Full flag and Output Valid flag status for the queue
selected for write and read operations respectively. Also a Programmable
Almost Full and Programmable Almost Empty flag for each queue is provided.
Two 8 bit programmable flag busses are available, providing status of queues
not selected for write or read operations. When 8 or less queues are configured
in the device these flag busses provide an individual flag per queue, when
more than 8 queues are used, either a Polled or Direct mode of bus operation
provides the flag busses with all queues status.
Bus Matching is available on this device, either port can be 9 bits or 18 bits
wide. When Bus Matching is used the device ensures the logical transfer of data
throughput in a Little Endian manner.
The user has full flexibility configuring queues within the device, being able
to program the total number of queues between 1 and 16, the individual queue
depths being independent of each other. The programmable flag positions are
also user programmable. All programming is done via a dedicated serial port.
If the user does not wish to program the multi-queue device, a default option is
available that configures the device in a predetermined manner.
Both Master Reset and Partial Reset pins are provided on this device. A Master
Reset latches in all configuration setup pins and must be performed before
programming of the device can take place. A Partial Reset will reset the read and
write pointers of an individual queue, provided that the queue is selected on both
the write port and read port at the time of partial reset.
A JTAG test port is provided, here the multi-queue flow-control device has a
fully functional Boundary Scan feature, compliant with IEEE 1149.1 Standard
Test Access Port and Boundary Scan Architecture.
See Figure 1, Multi-Queue Flow-Control Device Block Diagram for an outline
of the functional blocks within the device.
3
IDT72V51433/72V51443/72V51453 3.3V, MULTI-QUEUE FLOW-CONTROL DEVICES
(16 QUEUES) 18 BIT WIDE CONFIGURATION 589,824, 1,179,648 and 2,359,296 bits
COMMERCIAL AND INDUSTRIAL
TEMPERATURE RANGES
OE
x9, x18
Qout
OUTPUT
REGISTER
Q0 - Q17
WRADD
WADEN
INPUT
DEMUX
WCLK
WEN
Write Control
Logic
Din
Write Pointers
Active Q
Flags
PAF
General Flag
Monitor
FSTR
PAFn
FF
FSYNC
PAF
Reset
Logic
Serial
Multi-Queue
Programming
PAE/ PAF
Offset
TMS
TDI
TDO
TCK
TRST
FM
IW
OW
PRS
MRS
SI
SO
SCLK
SENI
RCLK
REN
Read Control
Logic
Read Pointers
Active Q
Flags
PAE
General Flag
Monitor
ESTR
OV
ESYNC
RDADD
RADEN
DF
FXO
FXI
EXI
EXO
5939 drw02
x9, x18
7
8
8
ID0
ID1
ID2
Device ID
3 Bit
JTAG
Logic
SENO
DFM
MAST
PAE
Upto 16
FIFO
Queues
0.5 Mbit
1.1 Mbit
2.3 Mbit
Dual Port
Memory
OUTPUT
MUX
D0 - D17
PAEn
8
Figure 1. Multi-Queue Flow-Control Device Block Diagram
4
COMMERCIAL AND INDUSTRIAL
TEMPERATURE RANGES
IDT72V51433/72V51443/72V51453 3.3V, MULTI-QUEUE FLOW-CONTROL DEVICES
(16 QUEUES) 18 BIT WIDE CONFIGURATION 589,824, 1,179,648 and 2,359,296 bits
D14
A
D13
D12
D10
Q9
D7
Q6
D4
Q3
D1
ID1
TCK
TDO
Q12
Q14
Q15
D15
B
D16
D11
D9
Q8
D6
Q5
D3
Q2
D0
ID0
TMS
TDI
Q11
Q13
DNC
D17
C
GND
GND
D8
Q7
D5
Q4
D2
Q1
TRST
Q0
GND
ID2
Q10
Q17
DNC
GND
D
GND
GND
VCC
VCC
VCC
VCC
VCC
VCC
VCC
VCC
VCC
VCC
Q16
DNC
DNC
GND
E
GND
GND
VCC
VCC
VCC
VCC
VCC
VCC
VCC
VCC
GND
GND
DNC
DNC
DNC
GND
F
GND
GND
VCC
VCC
VCC
VCC
GND
GND
GND
GND
GND
GND
DNC
DNC
DNC
GND
G
GND
GND
VCC
VCC
VCC
VCC
GND
GND
GND
GND
GND
GND
DNC
DNC
DNC
GND
H
GND
GND
VCC
VCC
GND
GND
GND
GND
GND
GND
GND
GND
DNC
DNC
DNC
GND
J
GND
GND
VCC
VCC
GND
GND
GND
GND
GND
GND
GND
GND
GND
DNC
DNC
GND
K
GND
GND
VCC
VCC
VCC
VCC
GND
GND
GND
GND
GND
GND
GND
MAST
FM
SI
L
DFM
DF
VCC
VCC
VCC
VCC
GND
GND
GND
GND
GND
GND
GND
IW
OW
SENO
M
SENI
SO
VCC
VCC
VCC
VCC
VCC
VCC
VCC
VCC
GND
GND
OE
RDADD0 RDADD1
WRADD1
N
WRADD0
SCLK
VCC
VCC
VCC
VCC
VCC
VCC
VCC
VCC
VCC
VCC
RDADD2
P
WRADD2
WADEN
PAE3
PAF3
PAE6
PAF6
PAE7
PAF7
PAE
FF
OV
R
FSYNC
FSTR
PAE2
PAF2
PAE5
PAF5
DNC
PAF4
DNC
PAF
DNC
RADEN
ESTR
ESYNC
T
FXI
FXO
PAF0
PAE1
PAF1
PAE4
WEN
REN
WCLK
RCLK
PRS
MRS
PAE0
1
2
3
4
13
5
12
6
11
7
10
8
9
14
15
16
5939 drw03
A1 BALL PAD CORNER
EXO
EXI
WRADD5 WRADD4
WRADD6
RDADD6 RDADD7
RDADD5
GND
WRADD3
RDADD3 RDADD4
PIN CONFIGURATION
PBGA (BB256-1, order code: BB)
TOP VIEW
NOTE:
1. DNC - Do Not Connect.
5
IDT72V51433/72V51443/72V51453 3.3V, MULTI-QUEUE FLOW-CONTROL DEVICES
(16 QUEUES) 18 BIT WIDE CONFIGURATION 589,824, 1,179,648 and 2,359,296 bits
COMMERCIAL AND INDUSTRIAL
TEMPERATURE RANGES
DETAILED DESCRIPTION
MULTI-QUEUE STRUCTURE
The IDT multi-queue flow-control device has a single data input port and
single data output port with up to 16 FIFO queues in parallel buffering between
the two ports. The user can setup between 1 and 16 Queues within the device.
These queues can be configured to utilize the total available memory, providing
the user with full flexibility and ability to configure the queues to be various depths,
independent of one another.
MEMORY ORGANIZATION/ ALLOCATION
The memory is organized into what is known as "blocks", each block being
512 x 18 or 1,024 x 9 bits. When the user is configuring the number of queues
and individual queue sizes the user must allocate the memory to respective
queues, in units of blocks, that is, a single queue can be made up from 0 to m
blocks, where m is the total number of blocks available within a device. Also the
total size of any given queue must be in increments of 512 x 18 or 1,024 x 9.
For the IDT72V51433, IDT72V51443 and IDT72V51453 the Total Available
Memory is 64, 128 and 256 blocks respectively (a block being 512 x 18 or 1,024
x 9). If any port is configured for x18 bus width, a block size is 512 x 18. If both
the write and read ports are configured for x9 bus width, a block size is 1,024
x 9. Queues can be built from these blocks to make any size queue desired and
any number of queues desired.
BUS WIDTHS
The input port is common to all queues within the device, as is the output port.
The device provides the user with Bus Matching options such that the input port
and output port can be either x9 or x18 bits wide, the read and write port widths
being set independently of one another. Because the ports are common to all
queues the width of the queues is not individually set, so that the input width of
all queues are equal and the output width of all queues are equal.
WRITING TO & READING FROM THE MULTI-QUEUE
Data being written into the device via the input port is directed to a discrete
queue via the write queue select address inputs. Conversely, data being read
from the device read port is read from a queue selected via the read queue select
address inputs. Data can be simultaneously written into and read from the same
queue or different queues. Once a queue is selected for data writes or reads,
the writing and reading operation is performed in the same manner as a
conventional IDT synchronous FIFO, utilizing clocks and enables, there is a
single clock and enable per port. When a specific queue is addressed on the
write port, data placed on the data inputs is written to that queue sequentially
based on the rising edge of a write clock provided setup and hold times are met.
Conversely, data is read on to the output port after an access time from a rising
edge on a read clock.
The operation of the write port is comparable to the function of a conventional
FIFO operating in standard IDT mode. Write operations can be performed on
the write port provided that the queue currently selected is not full, a full flag output
provides status of the selected queue. The operation of the read port is
comparable to the function of a conventional FIFO operating in FWFT mode.
When a queue is selected on the output port, the next word in that queue will
automatically fall through to the output register. All subsequent words from that
queue require an enabled read cycle. Data cannot be read from a selected
queue if that queue is empty, the read port provides an Output Valid flag indicating
when data read out is valid. If the user switches to a queue that is empty, the
last word from the previous queue will remain on the output register.
As mentioned, the write port has a full flag, providing full status of the selected
queue. Along with the full flag a dedicated almost full flag is provided, this almost
full flag is similar to the almost full flag of a conventional IDT FIFO. The device
provides a user programmable almost full flag for all 16 queues and when a
respective queue is selected on the write port, the almost full flag provides status
for that queue. Conversely, the read port has an output valid flag, providing
status of the data being read from the queue selected on the read port. As well
as the output valid flag the device provides a dedicated almost empty flag. This
almost empty flag is similar to the almost empty flag of a conventional IDT FIFO.
The device provides a user programmable almost empty flag for all 16 queues
and when a respective queue is selected on the read port, the almost empty flag
provides status for that queue.
PROGRAMMABLE FLAG BUSSES
In addition to these dedicated flags, full & almost full on the write port and output
valid & almost empty on the read port, there are two flag status busses. An almost
full flag status bus is provided, this bus is 8 bits wide. Also, an almost empty flag
status bus is provided, again this bus is 8 bits wide. The purpose of these flag
busses is to provide the user with a means by which to monitor the data levels
within queues that may not be selected on the write or read port. As mentioned,
the device provides almost full and almost empty registers (programmable by
the user) for each of the 16 queues in the device.
In the IDT72V51433/72V51443/72V51453 multi-queue flow-control de-
vices the user has the option of utilizing anywhere between 1 and 16 queues,
therefore the 8 bit flag status busses are multiplexed between the 16 queues,
a flag bus can only provide status for 8 of the 16 queues at any moment, this
is referred to as a "Sector", such that when the bus is providing status of queues
1 through 8, this is sector 1, when it is queues 9 through 16, this is sector 2. If
less than 16 queues are setup in the device, there are still 2 sectors, such that
in "Polled" mode of operation the flag bus will still cycle through 2 sectors. If for
example only 14 queues are setup, sector 1 will reflect status of queues 1 through
8. Sector 2 will reflect the status of queues 9 through 14 on the least significant
6 bits, the most significant 2 bits of the flag bus are don't care.
The flag busses are available in two user selectable modes of operation,
"Polled" or "Direct". When operating in polled mode a flag bus provides status
of each sector sequentially, that is, on each rising edge of a clock the flag bus
is updated to show the status of each sector in order. The rising edge of the write
clock will update the almost full bus and a rising edge on the read clock will update
the almost empty bus. The mode of operation is always the same for both the
almost full and almost empty flag busses. When operating in direct mode, the
sector on the flag bus is selected by the user. So the user can actually address
the sector to be placed on the flag status busses, these flag busses operate
independently of one another. Addressing of the almost full flag bus is done via
the write port and addressing of the almost empty flag bus is done via the read
port.
EXPANSION
Expansion of multi-queue devices is also possible, up to 8 devices can be
connected in a parallel fashion providing the possibility of both depth expansion
or queue expansion. Depth Expansion means expanding the depths of
individual queues. Queue expansion means increasing the total number of
queues available. Depth expansion is possible by virtue of the fact that more
memory blocks within a multi-queue device can be allocated to increase the
depth of a queue. For example, depth expansion of 8 devices provides the
possibility of 8 queues of 32K x 18 deep within the IDT72V51433, 64K x 18 deep
within the IDT72V51443, and 128K x 18 deep within the IDT72V51453, each
6
COMMERCIAL AND INDUSTRIAL
TEMPERATURE RANGES
IDT72V51433/72V51443/72V51453 3.3V, MULTI-QUEUE FLOW-CONTROL DEVICES
(16 QUEUES) 18 BIT WIDE CONFIGURATION 589,824, 1,179,648 and 2,359,296 bits
queue being setup within a single device utilizing all memory blocks available
to produce a single queue. This is the deepest queue that can setup within a
device.
For queue expansion a maximum number of 128 (8 x 16) queues may be
setup. If less queues are setup, then more memory blocks will be available to
increase queue depths if desired. When connecting multi-queue devices in
expansion mode all respective input pins (data & control) and output pins (data
& flags), should be "connected" together between individual devices.
7
IDT72V51433/72V51443/72V51453 3.3V, MULTI-QUEUE FLOW-CONTROL DEVICES
(16 QUEUES) 18 BIT WIDE CONFIGURATION 589,824, 1,179,648 and 2,359,296 bits
COMMERCIAL AND INDUSTRIAL
TEMPERATURE RANGES
D[17:0]
Data Input Bus
LVTTL
These are the 18 data input pins. Data is written into the device via these input pins on the rising edge
Din
INPUT
of WCLK provided that
WEN is LOW. Due to bus matching not all inputs may be used, any unused inputs
should be tied LOW.
DF
(1)
Default Flag
LVTTL
If the user requires default programming of the multi-queue device, this pin must be setup before Master
INPUT
Reset and must not toggle during any device operation. The state of this input at master reset determines
the value of the
PAE/PAF flag offsets. If DF is LOW the value is 8, if DF is HIGH the value is 128.
DFM
(1)
Default Mode
LVTTL
The multi-queue device requires programming after master reset. The user can do this serially via the
INPUT
serial port, or the user can use the default method. If DFM is LOW at master reset then serial mode will be
selected, if HIGH then default mode is selected.
ESTR
PAEn Flag Bus
LVTTL
If direct operation of the
PAEn bus has been selected, the ESTR input is used in conjunction with RCLK
Strobe
INPUT
and the RDADD bus to select a sector of queues to be placed on to the
PAEn bus outputs. A sector
addressed via the RDADD bus is selected on the rising edge of RCLK provided that ESTR is HIGH. If
Polled operations has been selected, ESTR should be tied inactive, LOW. Note, that a
PAEn flag bus
selection cannot be made, (ESTR must NOT go active) until programming of the part has been completed
and
SENO has gone LOW.
ESYNC
PAEn Bus Sync
LVTTL
ESYNC is an output from the multi-queue device that provides a synchronizing pulse for the
PAEn bus
OUTPUT
during Polled operation of the
PAEn bus. During Polled operation each sector of queue status flags is loaded
on to the
PAEn bus outputs sequentially based on RCLK. The first RCLK rising edge loads sector 1 on
to
PAEn, the second RCLK rising edge loads sector 2. The third RCLK rising edge will again load sector
1. During the RCLK cycle that sector 1 of a selected device is placed on to the
PAEn bus, the ESYNC output
will be HIGH. For sector 2 of that device, the ESYNC output will be LOW.
EXI
PAEn Bus
LVTTL
The EXI input is used when multi-queue devices are connected in expansion mode and Polled
PAEn
Expansion In
INPUT
bus operation has been selected . EXI of device `N' connects directly to EXO of device `N-1'. The EXI
receives a token from the previous device in a chain. In single device mode the EXI input must be tied
LOW if the
PAEn bus is operated in direct mode. If the PAEn bus is operated in polled mode the EXI input
must be connected to the EXO output of the same device. In expansion mode the EXI of the first device
should be tied LOW, when direct mode is selected.
EXO
PAEn Bus
LVTTL
EXO is an output that is used when multi-queue devices are connected in expansion mode and Polled
Expansion Out
OUTPUT
PAEn bus operation has been selected. EXO of device `N' connects directly to EXI of device `N+1'. This
pin pulses when device N has placed its 2nd sector on to the
PAEn bus with respect to RCLK. This pulse
(token) is then passed on to the next device in the chain `N+1' and on the next RCLK rising edge the first
sector of device N+1 will be loaded on to the
PAEn bus. This continues through the chain and EXO of the
last device is then looped back to EXI of the first device. The ESYNC output of each device in the chain
provides synchronization to the user of this looping event.
FF
Full Flag
LVTTL
This pin provides the full flag output for the active queue, that is, the queue selected on the input port for
OUTPUT
write operations, (selected via WCLK, WRADD bus and WADEN). On the WCLK cycle after a queue
selection, this flag will show the status of the newly selected queue. Data can be written to this queue on
the next cycle provided
FF is HIGH. This flag has High-Impedance capability, this is important during
expansion of devices, when the
FF flag output of up to 8 devices may be connected together on a common
line. The device with a queue selected takes control of the
FF bus, all other devices place their FF output
into High-Impedance. When a queue selection is made on the write port this output will switch from
High-Impedance control on the next WCLK cycle. This flag is synchronized to WCLK.
FM
(1)
Flag Mode
LVTTL
This pin is setup before a master reset and must not toggle during any device operation. The state of the
INPUT
FM pin during Master Reset will determine whether the
PAFn and PAEn flag busses operate in either Polled
or Direct mode. If this pin is HIGH the mode is Polled, if LOW then it will be Direct.
FSTR
PAFn Flag Bus
LVTTL
If direct operation of the
PAFn bus has been selected, the FSTR input is used in conjunction with WCLK
Strobe
INPUT
and the WRADD bus to select a sector of queues to be placed on to the
PAFn bus outputs. A sector
addressed via the WRADD bus is selected on the rising edge of WCLK provided that FSTR is HIGH. If
Polled operations has been selected, FSTR should be tied inactive, LOW. Note, that a
PAFn flag bus
selection cannot be made, (FSTR must NOT go active) until programming of the part has been completed
and
SENO has gone LOW.
PIN DESCRIPTIONS
Symbol
Name
I/O TYPE
Description
8
COMMERCIAL AND INDUSTRIAL
TEMPERATURE RANGES
IDT72V51433/72V51443/72V51453 3.3V, MULTI-QUEUE FLOW-CONTROL DEVICES
(16 QUEUES) 18 BIT WIDE CONFIGURATION 589,824, 1,179,648 and 2,359,296 bits
PIN DESCRIPTIONS (CONTINUED)
FSYNC
PAFn Bus Sync
LVTTL
FSYNC is an output from the multi-queue device that provides a synchronizing pulse for the
PAFn bus
OUTPUT
during Polled operation of the
PAFn bus. During Polled operation each sector of queue status flags is loaded
on to the
PAFn bus outputs sequentially based on WCLK. The first WCLK rising edge loads sector 1 on
to
PAFn, the second WCLK rising edge loads sector 2. The third WCLK rising edge will again load
sector 1. During the WCLK cycle that sector 1 of a selected device is placed on to the
PAFn bus, the
FSYNC output will be HIGH. For sector 2 of that device, the FSYNC output will be LOW.
FXI
PAFn Bus
LVTTL
The FXI input is used when multi-queue devices are connected in expansion mode and Polled
PAFn
Expansion In
INPUT
bus operation has been selected. FXI of device `N' connects directly to FXO of device `N-1'. The FXI
receives a token from the previous device in a chain. In single device mode the FXI input must be tied
LOW if the
PAFn bus is operated in direct mode. If the PAFn bus is operated in polled mode the FXI input
must be connected to the FXO output of the same device. In expansion mode the FXI of the first device
should be tied LOW, when direct mode is selected.
FXO
PAFn Bus
LVTTL
FXO is an output that is used when multi-queue devices are connected in expansion mode and Polled
Expansion Out
OUTPUT
PAFn bus operation has been selected . FXO of device `N' connects directly to FXI of device `N+1'. This
pin pulses when device N has placed its 2nd sector on to the
PAFn bus with respect to WCLK. This pulse
(token) is then passed on to the next device in the chain `N+1' and on the next WCLK rising edge the first
sector of device N+1 will be loaded on to the
PAFn bus. This continues through the chain and FXO of the
last device is then looped back to FXI of the first device. The FSYNC output of each device in the chain
provides synchronization to the user of this looping event.
ID[2:0]
(1)
Device ID Pins
LVTTL
For the 16Q multi-queue device the WRADD and RDADD address busses are 8 bits wide. When a queue
INPUT
selection takes place the 3 MSb's of this 8 bit address bus are used to address the specific device (the
5 LSb's are used to address the queue within that device). During write/read operations the 3 MSb's
of the address are compared to the device ID pins. The first device in a chain of multi-queue's (connected
in expansion mode), may be setup as `000', the second as `001' and so on through to device 8 which
is `111', however the ID does not have to match the device order. In single device mode these pins should
be setup as `000' and the 3 MSb's of the WRADD and RDADD address busses should be tied LOW. The
ID[2:0] inputs setup a respective devices ID during master reset. These ID pins must not toggle during
any device operation. Note, the device selected as the `Master' does not have to have the ID of `000'.
IW
(1)
Input Width
LVTTL
IW selects the bus width for the data input bus. If IW is LOW during a Master Reset then the bus width
INPUT
is x18, if HIGH then it is x9.
MAST
(1)
Master Device
LVTTL
The state of this input at Master Reset determines whether a given device (within a chain of devices), is the
INPUT
Master device or a Slave. If this pin is HIGH, the device is the master if it is LOW then it is a Slave. The master
device is the first to take control of all outputs after a master reset, all slave devices go to High-Impedance,
preventing bus contention. If a multi-queue device is being used in single device mode, this pin must
be set HIGH.
MRS
Master Reset
LVTTL
A master reset is performed by taking
MRS from HIGH to LOW, to HIGH. Device programming is required
INPUT
after master reset.
OE
Output Enable
LVTTL
The Output enable signal is an Asynchronous signal used to provide three-state control of the multi-queue
INPUT
data output bus, Qout. If a device has been configured as a "Master" device, the Qout data outputs will
be in a Low Impedance condition if the
OE input is LOW. If OE is HIGH then the Qout data outputs will be
in High Impedance. If a device is configured a "Slave" device, then the Qout data outputs will always be
in High Impedance until that device has been selected on the Read Port, at which point
OE provides three-
state of that respective device.
OV
Output Valid Flag
LVTTL
This output flag provides output valid status for the data word present on the multi-queue flow-control device
OUTPUT
data output port, Qout. This flag is therefore, 2-stage delayed to match the data output path delay. That
is, there is a 2 RCLK cycle delay from the time a given queue is selected for reads, to the time the
OV flag
represents the data in that respective queue. When a selected queue on the read port is read to empty,
the
OV flag will go HIGH, indicating that data on the output bus is not valid. The OV flag also has High-
Impedance capability, required when multiple devices are used and the
OV flags are tied together.
OW
(1)
Output Width
LVTTL
OW selects the bus width for the data output bus. If OW is LOW during a Master Reset then the bus width
INPUT
is x18, if HIGH then it is x9.
Symbol
Name
I/O TYPE
Description
9
IDT72V51433/72V51443/72V51453 3.3V, MULTI-QUEUE FLOW-CONTROL DEVICES
(16 QUEUES) 18 BIT WIDE CONFIGURATION 589,824, 1,179,648 and 2,359,296 bits
COMMERCIAL AND INDUSTRIAL
TEMPERATURE RANGES
PAE
Programmable
LVTTL
This pin provides the Almost-Empty flag status for the queue that has been selected on the output port
Almost-Empty Flag
OUTPUT
for read operations, (selected via RCLK, RDADD and RADEN). This pin is LOW when the selected
queue is almost-empty. This flag output may be duplicated on one of the
PAEn bus lines. This flag is
synchronized to RCLK.
PAEn
Programmable
LVTTL
On the 16Q device the
PAEn bus is 8 bits wide. This output bus provides PAE status of 8 queues (1 sector),
Almost-Empty Flag Bus OUTPUT
within a selected device, having a total of 2 sectors. During queue read/write operations these outputs
provide programmable empty flag status, in either direct or polled mode. The mode of flag operation is
determined during master reset via the state of the FM input. This flag bus is capable of High-Impedance
state, this is important during expansion of multi-queue devices. During direct operation the
PAEn bus is
updated to show the
PAE status of a sector of queues within a selected device. Selection is made using
RCLK, ESTR and RDADD. During Polled operation the
PAEn bus is loaded with the PAE status of
multi-queue flow-control sectors sequentially based on the rising edge of RCLK.
PAF
Programmable
LVTTL
This pin provides the Almost-Full flag status for the queue that has been selected on the input port for write
Almost-Full Flag
OUTPUT
operations, (selected via WCLK, WRADD and WADEN). This pin is LOW when the selected queue is
almost-full. This flag output may be duplicated on one of the
PAFn bus lines. This flag is synchronized to WCLK.
PAFn
Programmable
LVTTL
On the 16Q device the
PAFn bus is 8 bits wide. At any one time this output bus provides PAF status of
Almost-Full Flag Bus
OUTPUT
8 queues (1 sector), within a selected device, having a total of 2 sectors. During queue read/write
operations these outputs provide programmable full flag status, in either direct or polled mode. The mode
of flag operation is determined during master reset via the state of the FM input. This flag bus is capable
of High-Impedance state, this is important during expansion of multi-queue devices. During direct operation
the
PAFn bus is updated to show the PAF status of a sector of queues within a selected device. Selection
is made using WCLK, FSTR, WRADD and WADEN. During Polled operation the
PAFn bus is loaded with
the
PAF status of multi-queue flow-control sectors sequentially based on the rising edge of WCLK.
PRS
Partial Reset
LVTTL
A Partial Reset can be performed on a single queue selected within the multi-queue device. Before a Partial
INPUT
Reset can be performed on a queue, that queue must be selected on both the write port and read port
2 clock cycles before the reset is performed. A Partial Reset is then performed by taking
PRS LOW for
one WCLK cycle and one RCLK cycle. The Partial Reset will only reset the read and write pointers to
the first memory location, none of the devices configuration will be changed.
Q[17:0]
Data Output Bus
LVTTL
These are the 18 data output pins. Data is read out of the device via these output pins on the rising edge
Qout
OUTPUT
of RCLK provided that
REN is LOW, OE is LOW and the queue is selected. Due to bus matching not all
outputs may be used, any unused outputs should not be connected.
RADEN
Read Address Enable
LVTTL
The RADEN input is used in conjunction with RCLK and the RDADD address bus to select a queue to
INPUT
be read from. A queue addressed via the RDADD bus is selected on the rising edge of RCLK provided
that RADEN is HIGH. RADEN should be asserted (HIGH) only during a queue change cycle(s). RADEN
should not be permanently tied HIGH. RADEN cannot be HIGH for the same RCLK cycle as ESTR. Note,
that a read queue selection cannot be made, (RADEN must NOT go active) until programming of the part
has been completed and
SENO has gone LOW.
RCLK
Read Clock
LVTTL
When enabled by
REN, the rising edge of RCLK reads data from the selected queue via the output
INPUT
bus Qout. The queue to be read is selected via the RDADD address bus and a rising edge of RCLK
while RADEN is HIGH. A rising edge of RCLK in conjunction with ESTR and RDADD will also select the
PAEn flag sector to be placed on the PAEn bus during direct flag operation. During polled flag operation
the
PAEn bus is cycled with respect to RCLK and the ESYNC signal is synchronized to RCLK. The PAE
and
OV outputs are all synchronized to RCLK. During device expansion the EXO and EXI signals are
based on RCLK. RCLK must be continuous and free-running.
RDADD
Read Address Bus
LVTTL
For the 16Q device the RDADD bus is 8 bits. The RDADD bus is a dual purpose address bus. The first
[7:0]
INPUT
function of RDADD is to select a queue to be read from. The least significant 4 bits of the bus, RDADD[3:0]
are used to address 1 of 16 possible queues within a multi-queue device. Address pin, RDADD[4] provides
the user with a Null-Q address. If the user does not wish to address one of the 16 queues, a Null-Q can
be addressed using this pin. The Null-Q operation is discussed in more detail later. The most significant
3 bits, RDADD[7:5] are used to select 1 of 8 possible multi-queue devices that may be connected in
expansion mode. These 3 MSb's will address a device with the matching ID code. The address present
on the RDADD bus will be selected on a rising edge of RCLK provided that RADEN is HIGH, (note, that
PIN DESCRIPTIONS (CONTINUED)
Symbol
Name
I/O TYPE
Description
10
COMMERCIAL AND INDUSTRIAL
TEMPERATURE RANGES
IDT72V51433/72V51443/72V51453 3.3V, MULTI-QUEUE FLOW-CONTROL DEVICES
(16 QUEUES) 18 BIT WIDE CONFIGURATION 589,824, 1,179,648 and 2,359,296 bits
PIN DESCRIPTIONS (CONTINUED)
Symbol
Name
I/O TYPE
Description
RDADD
Read Address Bus
LVTTL
data can be placed on to the Qout bus, read from the previously selected queue on this RCLK edge). On
[7:0]
INPUT
the next rising RCLK edge after a read queue select, a data word from the previous queue will be placed
(Continued)
onto the outputs, Qout, regardless of the
REN input. Two RCLK rising edges after read queue select, data
will be placed on to the Qout outputs from the newly selected queue, regardless of
REN due to the first
word fall through effect.
The second function of the RDADD bus is to select the sector of queues to be loaded on to the
PAEn bus
during strobed flag mode. The least significant bit, RDADD[0] is used to select the sector of a device to
be placed on the
PAEn bus. The most significant 3 bits, RDADD[7:5] are again used to select 1 of 8
possible multi-queue devices that may be connected in expansion mode. Address bits RDADD[4:2] are
don't care during sector selection. The sector address present on the RDADD bus will be selected on the
rising edge of RCLK provided that ESTR is HIGH, (note, that data can be placed on to the Qout bus, read
from the previously selected queue on this RCLK edge). Please refer to Table 2 for details on RDADD bus.
REN
Read Enable
LVTTL
The
REN input enables read operations from a selected queue based on a rising edge of RCLK. A
INPUT
queue to be read from can be selected via RCLK, RADEN and the RDADD address bus regardless
of the state of
REN. Data from a newly selected queue will be available on the Qout output bus on the second
RCLK cycle after queue selection regardless of
REN due to the FWFT operation. A read enable is not
required to cycle the
PAEn bus (in polled mode) or to select the PAEn sector , (in direct mode).
SCLK
Serial Clock
LVTTL
If serial programming of the multi-queue device has been selected during master reset, the SCLK input
INPUT
clocks the serial data through the multi-queue device. Data setup on the SI input is loaded into the device
on the rising edge of SCLK provided that
SENI is enabled, LOW. When expansion of devices is performed
the SCLK of all devices should be connected to the same source.
SENI
Serial Input Enable
LVTTL
During serial programming of a multi-queue device, data loaded onto the SI input will be clocked into the
INPUT
part (via a rising edge of SCLK), provided the
SENI input of that device is LOW. If multiple devices are
cascaded, the
SENI input should be connected to the SENO output of the previous device. So when serial
loading of a given device is complete, its
SENO output goes LOW, allowing the next device in the chain
to be programmed (
SENO will follow SENI of a given device once that device is programmed). The SENI
input of the master device (or single device), should be controlled by the user.
SENO
Serial Output Enable
LVTTL
This output is used to indicate that serial programming or default programming of the multi-queue device
OUTPUT
has been completed.
SENO follows SENI once programming of a device is complete. Therefore, SENO
will go LOW after programming provided
SENI is LOW, once SENI is taken HIGH again, SENO will also
go HIGH. When the
SENO output goes LOW, the device is ready to begin normal read/write operations.
If multiple devices are cascaded and serial programming of the devices will be used, the
SENO output
should be connected to the
SENI input of the next device in the chain. When serial programming of the
first device is complete,
SENO will go LOW, thereby taking the SENI input of the next device LOW and
so on throughout the chain. When a given device in the chain is fully programmed the
SENO output
essentially follows the
SENI input. The user should monitor the SENO output of the final device in the chain.
When this output goes LOW, serial loading of all devices has been completed.
SI
Serial In
LVTTL
During serial programming this pin is loaded with the serial data that will configure the multi-queue devices.
INPUT
Data present on SI will be loaded on a rising edge of SCLK provided that
SENI is LOW. In expansion
mode the serial data input is loaded into the first device in a chain. When that device is loaded and its
SENO
has gone LOW, the data present on SI will be directly output to the SO output. The SO pin of the first device
connects to the SI pin of the second and so on. The multi-queue device setup registers are shift registers.
SO
Serial Out
LVTTL
This output is used in expansion mode and allows serial data to be passed through devices in the chain
OUTPUT
to complete programming of all devices. The SI of a device connects to SO of the previous device in the
chain. The SO of the final device in a chain should not be connected.
TCK
(2)
JTAG Clock
LVTTL
Clock input for JTAG function. One of four terminals required by IEEE Standard 1149.1-1990. Test
INPUT
operations of the device are synchronous to TCK. Data from TMS and TDI are sampled on the rising edge
of TCK and outputs change on the falling edge of TCK. If the JTAG function is not used this signal needs
to be tied to GND.
TDI
(2)
JTAG Test Data
LVTTL
One of four terminals required by IEEE Standard 1149.1-1990. During the JTAG boundary scan
Input
INPUT
operation, test data serially loaded via the TDI on the rising edge of TCK to either the Instruction Register,
ID Register and Bypass Register. An internal pull-up resistor forces TDI HIGH if left unconnected.
11
IDT72V51433/72V51443/72V51453 3.3V, MULTI-QUEUE FLOW-CONTROL DEVICES
(16 QUEUES) 18 BIT WIDE CONFIGURATION 589,824, 1,179,648 and 2,359,296 bits
COMMERCIAL AND INDUSTRIAL
TEMPERATURE RANGES
PIN DESCRIPTIONS (CONTINUED)
NOTES:
1. Inputs should not change after Master Reset.
2. These pins are for the JTAG port. Please refer to pages 45-49 and Figures 29-31.
Symbol
Name
I/O TYPE
Description
TDO
(2)
JTAG Test Data
LVTTL
One of four terminals required by IEEE Standard 1149.1-1990. During the JTAG boundary scan
Output
OUTPUT
operation, test data serially loaded output via the TDO on the falling edge of TCK from either the Instruction
Register, ID Register and Bypass Register. This output is high impedance except when shifting, while in
SHIFT-DR and SHIFT-IR controller states.
TMS
(2)
JTAG Mode Select
LVTTL
TMS is a serial input pin. One of four terminals required by IEEE Standard 1149.1-1990. TMS directs the
INPUT
device through its TAP controller states. An internal pull-up resistor forces TMS HIGH if left unconnected.
TRST
(2)
JTAG Reset
LVTTL
TRST is an asynchronous reset pin for the JTAG controller. The JTAG TAP controller does not automatically
INPUT
reset upon power-up, thus it must be reset by either this signal or by setting TMS= HIGH for five TCK cycles.
If the TAP controller is not properly reset then the outputs will always be in high-impedance. If the JTAG
function is used but the user does not want to use
TRST, then TRST can be tied with MRS to ensure
proper queue operation. If the JTAG function is not used then this signal needs to be tied to GND. An
internal pull-up resistor forces
TRST HIGH if left unconnected.
WADEN
Write Address Enable
LVTTL
The WADEN input is used in conjunction with WCLK and the WRADD address bus to select a queue to
INPUT
be written in to. A queue addressed via the WRADD bus is selected on the rising edge of WCLK provided
that WADEN is HIGH. WADEN should be asserted (HIGH) only during a queue change cycle(s). WADEN
should not be permanently tied HIGH. WADEN cannot be HIGH for the same WCLK cycle as FSTR. Note,
that a write queue selection cannot be made, (WADEN must NOT go active) until programming of the part
has been completed and
SENO has gone LOW.
WCLK
Write Clock
LVTTL
When enabled by
WEN, the rising edge of WCLK writes data into the selected queue via the input bus,
INPUT
Din. The queue to be written to is selected via the WRADD address bus and a rising edge of WCLK while
WADEN is HIGH. A rising edge of WCLK in conjunction with FSTR and WRADD will also select the flag
sector to be placed on the
PAFn bus during direct flag operation. During polled flag operation the PAFn
bus is cycled with respect to WCLK and the FSYNC signal is synchronized to WCLK. The
PAFn, PAF and
FF outputs are all synchronized to WCLK. During device expansion the FXO and FXI signals are based
on WCLK. The WCLK must be continuous and free-running.
WEN
Write Enable
LVTTL
The
WEN input enables write operations to a selected queue based on a rising edge of WCLK. A queue
INPUT
to be written to can be selected via WCLK, WADEN and the WRADD address bus regardless of the state
of
WEN. Data present on Din can be written to a newly selected queue on the second WCLK cycle after
queue selection provided that
WEN is LOW. A write enable is not required to cycle the PAFn bus (in polled
mode) or to select the
PAFn sector , (in direct mode).
WRADD
Write Address Bus
LVTTL
For the 16Q device the WRADD bus is 7 bits. The WRADD bus is a dual purpose address bus. The first
[6:0]
INPUT
function of WRADD is to select a queue to be written to. The least significant 4 bits of the bus, WRADD[3:0]
are used to address 1 of 16 possible queues within a multi-queue device. The most significant 3 bits,
WRADD[6:4] are used to select 1 of 8 possible multi-queue devices that may be connected in expansion
mode. These 3 MSb's will address a device with the matching ID code. The address present on the
WRADD bus will be selected on a rising edge of WCLK provided that WADEN is HIGH, (note, that data
present on the Din bus can be written into the previously selected queue on this WCLK edge and on the
next rising WCLK also, providing that
WEN is LOW). Two WCLK rising edges after write queue select,
data can be written into the newly selected queue.
The second function of the WRADD bus is to select the sector of queues to be loaded on to the
PAFn
bus during strobed flag mode. The least significant bit, WRADD[0] is used to select the sector of a device
to be placed on the
PAFn bus. The most significant 3 bits, WRADD[6:4] are again used to select 1 of 8 possible
multi-queue devices that may be connected in expansion mode. Address bits WRADD[3:1] are don't care
during sector selection. The sector address present on the WRADD bus will be selected on the rising edge
of WCLK provided that FSTR is HIGH, (note, that data can be written into the previously selected queue
on this WCLK edge). Please refer to Table 1 for details on the WRADD bus.
V
CC
+3.3V Supply
Power
These are V
CC
power supply pins and must all be connected to a +3.3V supply rail.
GND
Ground Pin
Ground
These are Ground pins and must all be connected to the GND supply rail.
12
COMMERCIAL AND INDUSTRIAL
TEMPERATURE RANGES
IDT72V51433/72V51443/72V51453 3.3V, MULTI-QUEUE FLOW-CONTROL DEVICES
(16 QUEUES) 18 BIT WIDE CONFIGURATION 589,824, 1,179,648 and 2,359,296 bits
Symbol
Rating
Com'l & Ind'l
Unit
V
TERM
Terminal Voltage
0.5 to +4.5
V
with respect to GND
T
STG
Storage Temperature
55 to +125
C
I
OUT
DC Output Current
50 to +50 mA
DC ELECTRICAL CHARACTERISTICS
(Commercial: V
CC
= 3.3V 0.15V, T
A
= 0
C to +70C;Industrial: V
CC
= 3.3V 0.15V, T
A
= 40
C to +85C; JEDEC JESD8-A compliant)
Symbol
Parameter
Min.
Max.
Unit
I
LI
(1)
Input Leakage Current
10
10
A
I
LO
(2)
Output Leakage Current
10
10
A
V
OH
Output Logic "1" Voltage, I
OH
= 8 mA
2.4
--
V
V
OL
Output Logic "0" Voltage, I
OL
= 8 mA
--
0.4
V
I
CC1
(3,4,5)
Active Power Supply Current
--
100
mA
I
CC2
(3,6)
Standby Current
--
25
mA
ABSOLUTE MAXIMUM RATINGS
RECOMMENDED DC OPERATING
CONDITIONS
NOTES
:
1. Measurements with 0.4
V
IN
V
CC
.
2.
OE
V
IH,
0.4
V
OUT
V
CC.
3. Tested with outputs open (I
OUT
= 0).
4. RCLK and WCLK toggle at 20 MHz and data inputs switch at 10 MHz.
5. Typical I
CC1
= 16 + 3.14*f
S
+ 0.02*C
L
*f
S
(in mA) with V
CC
= 3.3V, t
A
= 25
C, f
S
= WCLK frequency = RCLK frequency (in MHz, using TTL levels), data switching at f
S
/2,
C
L
= capacitive load (in pF).
6. RCLK and WCLK, toggle at 20 MHz.
The following inputs should be pulled to GND: WRADD, RDADD, WADEN, RADEN, FSTR, ESTR, SCLK, SI, EXI, FXI and all Data Inputs.
The following inputs should be pulled to V
CC
:
WEN, REN, SENI, PRS, MRS, TDI, TMS and TRST.
All other inputs are don't care, and should be pulled HIGH or LOW.
NOTE:
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.
NOTE:
1. V
CC
= 3.3V 0.15V, JEDEC JESD8-A compliant.
NOTES:
1. With output deselected, (
OE
V
IH
).
2. Characterized values, not currently tested.
CAPACITANCE
(T
A
= +25
C, f = 1.0MHz)
Symbol
Parameter
(1)
Conditions
Max.
Unit
C
IN
(2)
Input
V
IN
= 0V
10
pF
Capacitance
C
OUT
(1,2)
Output
V
OUT
= 0V
10
pF
Capacitance
Symbol
Parameter
Min.
Typ.
Max.
Unit
V
CC
(1)
Supply Voltage (Com'l/Ind'l)
3.15
3.3
3.45
V
GND
Supply Voltage (Com'l/Ind'l)
0
0
0
V
V
IH
Input High Voltage (Com'l/Ind'l)
2.0
--
V
CC
+0.3
V
V
IL
Input Low Voltage (Com'l/Ind'l)
--
--
0.8
V
T
A
Operating Temperature Commercial
0
--
+70
C
T
A
Operating Temperature Industrial
-40
--
+85
C
13
IDT72V51433/72V51443/72V51453 3.3V, MULTI-QUEUE FLOW-CONTROL DEVICES
(16 QUEUES) 18 BIT WIDE CONFIGURATION 589,824, 1,179,648 and 2,359,296 bits
COMMERCIAL AND INDUSTRIAL
TEMPERATURE RANGES
Input Pulse Levels
GND to 3.0V
Input Rise/Fall Times
1.5ns
Input Timing Reference Levels
1.5V
Output Reference Levels
1.5V
Output Load
See Figure 2a & 2b
AC TEST CONDITIONS
Figure 2a. AC Test Load
Figure 2b. Lumped Capacitive Load, Typical Derating
5939 drw04
50
V
CC
/2
I/O
Z
0
= 50
5939 drw04a
6
5
4
3
2
1
20 30 50
80 100
200
Capacitance (pF)
t
CD
(Typical, ns)
OUTPUT ENABLE & DISABLE TIMING
AC TEST LOADS
V
IH
OE
V
IL
t
OE &
t
OLZ
100mV
100mV
t
OHZ
100mV
100mV
Output
Normally
LOW
Output
Normally
HIGH
V
OL
V
OH
V
CC
/2
5939 drw04b
Output
Enable
Output
Disable
V
CC
/2
V
CC
/2
V
CC
/2
14
COMMERCIAL AND INDUSTRIAL
TEMPERATURE RANGES
IDT72V51433/72V51443/72V51453 3.3V, MULTI-QUEUE FLOW-CONTROL DEVICES
(16 QUEUES) 18 BIT WIDE CONFIGURATION 589,824, 1,179,648 and 2,359,296 bits
AC ELECTRICAL CHARACTERISTICS
(Commercial: V
CC
= 3.3V 0.15V, T
A
= 0
C to +70C;Industrial: V
CC
= 3.3V 0.15V, T
A
= 40
C to +85C; JEDEC JESD8-A compliant)
Commercial
Com'l & Ind'l
(1)
IDT72V51433L6
IDT72V51433L7-5
IDT72V51443L6
IDT72V51443L7-5
IDT72V51453L6
IDT72V51453L7-5
Symbol
Parameter
Min.
Max.
Min.
Max.
Unit
f
S
Clock Cycle Frequency (WCLK & RCLK)
--
166
--
133
MHz
t
A
Data Access Time
0.6
3.7
0.6
4
ns
t
CLK
Clock Cycle Time
6
--
7.5
--
ns
t
CLKH
Clock High Time
2.7
--
3.5
--
ns
t
CLKL
Clock Low Time
2.7
--
3.5
--
ns
t
DS
Data Setup Time
2
--
2.0
--
ns
t
DH
Data Hold Time
0.5
--
0.5
--
ns
t
ENS
Enable Setup Time
2
--
2.0
--
ns
t
ENH
Enable Hold Time
0.5
--
0.5
--
ns
t
RS
Reset Pulse Width
10
--
10
--
ns
t
RSS
Reset Setup Time
15
--
15
--
ns
t
RSR
Reset Recovery Time
10
--
10
--
ns
t
PRSS
Partial Reset Setup
2.0
--
2.5
--
ns
t
PRSH
Partial Reset Hold
0.5
--
0.5
--
ns
t
OLZ (
OE-
Q
n)
(2)
Output Enable to Output in Low-Impedance
0.6
3.7
0.6
4
ns
t
OHZ
(2)
Output Enable to Output in High-Impedance
0.6
3.7
0.6
4
ns
t
OE
Output Enable to Data Output Valid
0.6
3.7
0.6
4
ns
f
C
Clock Cycle Frequency (SCLK)
--
10
--
10
MHz
t
SCLK
Serial Clock Cycle
100
--
100
--
ns
t
SCKH
Serial Clock High
45
--
45
--
ns
t
SCKL
Serial Clock Low
45
--
45
--
ns
t
SDS
Serial Data In Setup
20
--
20
--
ns
t
SDH
Serial Data In Hold
1.2
--
1.2
--
ns
t
SENS
Serial Enable Setup
20
--
20
--
ns
t
SENH
Serial Enable Hold
1.2
--
1.2
--
ns
t
SDO
SCLK to Serial Data Out
--
20
--
20
ns
t
SENO
SCLK to Serial Enable Out
--
20
--
20
ns
t
SDOP
Serial Data Out Propagation Delay
1.5
3.7
1.5
4
ns
t
SENOP
Serial Enable Propagation Delay
1.5
3.7
1.5
4
ns
t
PCWQ
Programming Complete to Write Queue Selection
20
--
20
--
ns
t
PCRQ
Programming Complete to Read Queue Selection
20
--
20
ns
t
AS
Address Setup
2.5
--
3.0
--
ns
t
AH
Address Hold
1
--
1
--
ns
t
WFF
Write Clock to Full Flag
--
3.7
--
5
ns
t
ROV
Read Clock to Output Valid
--
3.7
--
5
ns
t
STS
Strobe Setup
2
--
2
--
ns
t
STH
Strobe Hold
0.5
--
0.5
--
ns
t
QS
Queue Setup
2
--
2.5
--
ns
t
QH
Queue Hold
0.5
--
0.5
--
ns
t
WAF
WCLK to
PAF flag
0.6
3.7
0.6
4
ns
t
RAE
RCLK to
PAE flag
0.6
3.7
0.6
4
ns
t
PAF
Write Clock to Synchronous Almost-Full Flag Bus
0.6
3.7
0.6
4
ns
t
PAE
Read Clock to Synchronous Almost-Empty Flag Bus
0.6
3.7
0.6
4
ns
NOTES:
1. Industrial temperature range product for the 7-5ns is available as a standard device. All other speed grades available by special order.
2. Values guaranteed by design, not currently tested.
15
IDT72V51433/72V51443/72V51453 3.3V, MULTI-QUEUE FLOW-CONTROL DEVICES
(16 QUEUES) 18 BIT WIDE CONFIGURATION 589,824, 1,179,648 and 2,359,296 bits
COMMERCIAL AND INDUSTRIAL
TEMPERATURE RANGES
AC ELECTRICAL CHARACTERISTICS (CONTINUED)
(Commercial: V
CC
= 3.3V 0.15V, T
A
= 0
C to +70C;Industrial: V
CC
= 3.3V 0.15V, T
A
= 40
C to +85C; JEDEC JESD8-A compliant)
t
PAELZ
(2)
RCLK to
PAE Flag Bus to Low-Impedance
0.6
3.7
0.6
4
ns
t
PAEHZ
(2)
RCLK to
PAE Flag Bus to High-Impedance
0.6
3.7
0.6
4
ns
t
PAFLZ
(2)
WCLK to
PAF Flag Bus to Low-Impedance
0.6
3.7
0.6
4
ns
t
PAFHZ
(2)
WCLK to
PAF Flag Bus to High-Impedance
0.6
3.7
0.6
4
ns
t
FFHZ
(2)
WCLK to Full Flag to High-Impedance
0.6
3.7
0.6
4
ns
t
FFLZ
(2)
WCLK to Full Flag to Low-Impedance
0.6
3.7
0.6
4
ns
t
OVLZ
(2)
RCLK to Output Valid Flag to Low-Impedance
0.6
3.7
0.6
4
ns
t
OVHZ
(2)
RCLK to Output Valid Flag to High-Impedance
0.6
3.7
0.6
4
ns
t
FSYNC
WCLK to
PAF Bus Sync to Output
0.6
3.7
0.6
4
ns
t
FXO
WCLK to
PAF Bus Expansion to Output
0.6
3.7
0.6
4
ns
t
ESYNC
RCLK to
PAE Bus Sync to Output
0.6
3.7
0.6
4
ns
t
EXO
RCLK to
PAE Bus Expansion to Output
0.6
3.7
0.6
4
ns
t
SKEW1
SKEW
time between RCLK and WCLK for
FF and OV
4.5
--
5.75
--
ns
t
SKEW2
SKEW
time between RCLK and WCLK for
PAF and PAE
6
--
7.5
--
ns
t
SKEW3
SKEW
time between RCLK and WCLK for
PAF[0:7] and PAE[0:7]
6
--
7.5
--
ns
t
SKEW4
SKEW
time between RCLK and WCLK for
OV
6
--
7.5
--
ns
t
XIS
Expansion Input Setup
1.0
--
1.3
--
ns
t
XIH
Expansion Input Hold
0.5
--
0.5
--
ns
Commercial
Com'l & Ind'l
(1)
IDT72V51433L6
IDT72V51433L7-5
IDT72V51443L6
IDT72V51443L7-5
IDT72V51453L6
IDT72V51453L7-5
Symbol
Parameter
Min.
Max.
Min.
Max.
Unit
NOTES:
1. Industrial temperature range product for the 7-5ns is available as a standard device. All other speed grades available by special order.
2. Values guaranteed by design, not currently tested.
16
COMMERCIAL AND INDUSTRIAL
TEMPERATURE RANGES
IDT72V51433/72V51443/72V51453 3.3V, MULTI-QUEUE FLOW-CONTROL DEVICES
(16 QUEUES) 18 BIT WIDE CONFIGURATION 589,824, 1,179,648 and 2,359,296 bits
FUNCTIONAL DESCRIPTION
MASTER RESET
A Master Reset is performed by toggling the
MRS input from HIGH to LOW
to HIGH. During a master reset all internal multi-queue device setup and control
registers are initialized and require programming either serially by the user via
the serial port, or using the default settings. During a master reset the state of
the following inputs determine the functionality of the part, these pins should be
held HIGH or LOW.
FM Flag bus Mode
IW, OW Bus Matching options
MAST Master Device
ID0, 1, 2 Device ID
DFM Programming mode, serial or default
DF Offset value for
PAE and PAF
Once a master reset has taken place, the device must be programmed either
serially or via the default method before any read/write operations can begin.
See Figure 4, Master Reset for relevant timing.
PARTIAL RESET
A Partial Reset is a means by which the user can reset both the read and write
pointers of a single queue that has been setup within a multi-queue device.
Before a partial reset can take place on a queue, the respective queue must be
selected on both the read port and write port a minimum of 2 RCLK and 2 WCLK
cycles before the
PRS goes LOW. The partial reset is then performed by toggling
the
PRS input from HIGH to LOW to HIGH, maintaining the LOW state for at least
one WCLK and one RCLK cycle. Once a partial reset has taken place a minimum
of 3 WCLK and 3 RCLK cycles must occur before enabled writes or reads can
occur.
A Partial Reset only resets the read and write pointers of a given queue, a
partial reset will not effect the overall configuration and setup of the multi-queue
device and its queues.
See Figure 5, Partial Reset for relevant timing.
SERIAL PROGRAMMING
The multi-queue flow-control device is a fully programmable device, provid-
ing the user with flexibility in how queues are configured in terms of the number
of queues, depth of each queue and position of the
PAF/PAE flags within
respective queues. All user programming is done via the serial port after a master
reset has taken place. Internally the multi-queue device has setup registers
which must be serially loaded, these registers contain values for every queue
within the device, such as the depth and
PAE/PAF offset values. The
IDT72V51433/72V51443/72V51453 devices are capable of up to 16 queues
and therefore contain 16 sets of registers for the setup of each queue.
During a Master Reset if the DFM (Default Mode) input is LOW, then the device
will require serial programming by the user. It is recommended that the user
utilize a `C' program provided by IDT, this program will prompt the user for all
information regarding the multi-queue setup. The program will then generate
a serial bit stream which should be serially loaded into the device via the serial
port. For the IDT72V51433/72V51443/72V51453 devices the serial program-
ming requires a total number of serially loaded bits per device, (SCLK cycles
with
SENI enabled), calculated by: 19+(Qx72) where Q is the number of queues
the user wishes to setup within the device. Please refer to the separate
Application Note, AN-303 for recommended control of the serial programming
port.
Once the master reset is complete and
MRS is HIGH, the device can be
serially loaded. Data present on the SI (serial in), input is loaded into the serial
port on a rising edge of SCLK (serial clock), provided that
SENI (serial in
enable), is LOW. Once serial programming of the device has been successfully
completed the device will indicate this via the
SENO (serial output enable) going
active, LOW. Upon detection of completion of programming, the user should
cease all programming and take
SENI inactive, HIGH. Note, SENO follows SENI
once programming of a device is complete. Therefore,
SENO will go LOW after
programming provided
SENI is LOW, once SENI is taken HIGH again, SENO
will also go HIGH. The operation of the SO output is similar, when programming
of a given device is complete, the SO output will follow the SI input.
If devices are being used in expansion mode the serial ports of devices should
be cascaded. The user can load all devices via the serial input port control pins,
SI &
SENI, of the first device in the chain. Again, the user may utilize the `C'
program to generate the serial bit stream, the program prompting the user for
the number of devices to be programmed. The
SENO and SO (serial out) of
the first device should be connected to the
SENI and SI inputs of the second
device respectively and so on, with the
SENO & SO outputs connecting to the
SENI & SI inputs of all devices through the chain. All devices in the chain should
be connected to a common SCLK. The serial output port of the final device should
be monitored by the user. When
SENO of the final device goes LOW, this
indicates that serial programming of all devices has been successfully com-
pleted. Upon detection of completion of programming, the user should cease all
programming and take
SENI of the first device in the chain inactive, HIGH.
As mentioned, the first device in the chain has its serial input port controlled
by the user, this is the first device to have its internal registers serially loaded
by the serial bit stream. When programming of this device is complete it will take
its
SENO output LOW and bypass the serial data loaded on the SI input to its
SO output. The serial input of the second device in the chain is now loaded with
the data from the SO of the first device, while the second device has its
SENI
input LOW. This process continues through the chain until all devices are
programmed and the
SENO of the final device goes LOW.
Once all serial programming has been successfully completed, normal
operations, (queue selections on the read and write ports) may begin. When
connected in expansion mode, the IDT72V51433/72V51443/72V51453 de-
vices require a total number of serially loaded bits per device to complete serial
programming, (SCLK cycles with
SENI enabled), calculated by: n[19+(Qx72)]
where Q is the number of queues the user wishes to setup within the device,
where n is the number of devices in the chain.
See Figure 6, Serial Port Connection and Figure 7, Serial Programming for
connection and timing information.
DEFAULT PROGRAMMING
During a Master Reset if the DFM (Default Mode) input is HIGH the multi-
queue device will be configured for default programming, (serial programming
is not permitted). Default programming provides the user with a simpler,
however limited means by which to setup the multi-queue flow-control device,
rather than using the serial programming method. The default mode will
configure a multi-queue device such that the maximum number of queues
possible are setup, with all of the parts available memory blocks being allocated
equally between the queues. The values of the
PAE/PAF offsets is determined
by the state of the DF (default) pin during a master reset.
For the IDT72V51433/72V51443/72V51453 devices the default mode will
setup 16 queues, each queue configured as follows: For the IDT72V51433 with
x9 input and x9 output ports, depth is 4,096, if one or both ports is x18, then the
depth is 2,048. For the IDT72V51443 with x9 input and x9 output ports, depth
is 8,192, if one or both ports is x18, then the depth is 4,096. For the IDT72V51453
with x9 input and x9 output ports, depth is 16,384, if one or both ports is x18,
then the depth is 8,192. For both devices the value of the
PAE/PAF offsets is
determined at master reset by the state of the DF input. If DF is LOW then both
the
PAE & PAF offset will be 8, if HIGH then the value is 128.
17
IDT72V51433/72V51443/72V51453 3.3V, MULTI-QUEUE FLOW-CONTROL DEVICES
(16 QUEUES) 18 BIT WIDE CONFIGURATION 589,824, 1,179,648 and 2,359,296 bits
COMMERCIAL AND INDUSTRIAL
TEMPERATURE RANGES
When configuring the IDT72V51433/72V51443/72V51453 devices in de-
fault mode the user simply has to apply WCLK cycles after a master reset, until
SENO goes LOW, this signals that default programming is complete. These clock
cycles are required for the device to load its internal setup registers. When a
single multi-queue device is used, the completion of device programming is
signaled by the
SENO output of a device going from HIGH to LOW. Note, that
SENI must be held LOW when a device is setup for default programming mode.
When multi-queue devices are connected in expansion mode, the
SENI of
the first device in a chain can be held LOW. The
SENO of a device should connect
to the
SENI of the next device in the chain. The SENO of the final device is used
to indicate that default programming of all devices is complete. When the final
SENO goes LOW normal operations may begin. Again, all devices will be
programmed with their maximum number of queues and the memory divided
equally between them. Please refer to Figure 8, Default Programming.
WRITE QUEUE SELECTION & WRITE OPERATION
The IDT72V51433/72V51443/72V51453 multi-queue flow-control devices
have up to 16 queues that data can be written into via a common write port using
the data inputs, Din, write clock, WCLK and write enable,
WEN. The queue
address present on the write address bus, WRADD during a rising edge on
WCLK while write address enable, WADEN is HIGH, is the queue selected for
write operations. The state of
WEN is don't care during the write queue selection
cycle. The queue selection only has to be made on a single WCLK cycle, this
will remain the selected queue until another queue is selected, the selected
queue is always the last queue selected.
The write port is designed such that 100% bus utilization can be obtained.
This means that data can be written into the device on every WCLK rising edge
including the cycle that a new queue is being addressed. When a new queue
is selected for write operations the address for that queue must be present on
the WRADD bus during a rising edge of WCLK provided that WADEN is HIGH.
A queue to be written to need only be selected on a single rising edge of WCLK.
All subsequent writes will be written to that queue until a new queue is selected.
A minimum of 2 WCLK cycles must occur between queue selections on the write
port. On the next WCLK rising edge the write port discrete full flag will update
to show the full status of the newly selected queue. On the second rising edge
of WCLK, data present on the data input bus, Din can be written into the newly
selected queue provided that
WEN is LOW and the new queue is not full. The
cycle of the queue selection and the next cycle will continue to write data present
on the data input bus, Din into the previous queue provided that
WEN is active
LOW.
If
WEN is HIGH, inactive for these 2 clock cycles, then data will not be written
in to the previous queue.
If the newly selected queue is full at the point of its selection, then writes to that
queue will be prevented, a full queue cannot be written into.
In the 16 queue multi-queue device the WRADD address bus is 7 bits wide.
The least significant 4 bits are used to address one of the 16 available queues
within a single multi-queue device. The most significant 3 bits are used when
a device is connected in expansion mode, up to 8 devices can be connected
in expansion, each device having its own 3 bit address. The selected device
is the one for which the address matches a 3 bit ID code, which is statically setup
on the ID pins, ID0, ID1, and ID2 of each individual device.
Note, the WRADD bus is also used in conjunction with FSTR (almost full flag
bus strobe), to address the almost full flag bus sector during direct mode of
operation.
Refer to Table 1, for Write Address bus arrangement. Also, refer to Figure
9, Write Queue Select, Write Operation and Full flag Operation and Figure
11, Full Flag Timing Expansion Mode for timing diagrams.
TABLE 1 -- WRITE ADDRESS BUS, WRADD[6:0]
Operation WCLK WADEN
FSTR
WRADD[6:0]
Write Queue
Select
1
0
0
1
Device Select
(Compared to
ID0,1,2)
Write Queue Address
(4 bits = 16 Queues)
6
5
4
3 2
1 0
7
6
5 4 3 2
0
Device Select
(Compared to
ID0,1,2)
X X X
Sector
Address
PAFn Sector
Select
Q0 : Q7
PAF0 : PAF7
Sector
Address
Queue Status on
PAFn Bus
0
1
Q8 : Q15
PAF0 : PAF7
5939 drw05
1
X
18
COMMERCIAL AND INDUSTRIAL
TEMPERATURE RANGES
IDT72V51433/72V51443/72V51453 3.3V, MULTI-QUEUE FLOW-CONTROL DEVICES
(16 QUEUES) 18 BIT WIDE CONFIGURATION 589,824, 1,179,648 and 2,359,296 bits
READ QUEUE SELECTION & READ OPERATION
The multi-queue flow-control device has up to 16 queues that data is read
from via a common read port using the data outputs, Qout, read clock, RCLK
and read enable,
REN. An output enable, OE control pin is also provided to allow
High-Impedance selection of the Qout data outputs. The multi-queue device
read port operates in a mode similar to "First Word Fall Through" on a traditional
IDT FIFO, but with the added feature of data output pipelining. This data
pipelining on the output port allows the user to achieve 100% bus utilization,
which is the ability to read out a data word on every rising edge of RCLK
regardless of whether a new queue is being selected for read operations.
The queue address present on the read address bus, RDADD during a rising
edge on RCLK while read address enable, RADEN is HIGH, is the queue
selected for read operations. A queue to be read from need only be selected
on a single rising edge of RCLK. All subsequent reads will be read from that
queue until a new queue is selected. A minimum of 2 RCLK cycles must occur
between queue selections on the read port. Data from the newly selected queue
will be present on the Qout outputs after 2 RCLK cycles plus an access time,
provided that
OE is active, LOW. On the same RCLK rising edge that the new
queue is selected, data can still be read from the previously selected queue,
provided that
REN is LOW, active and the previous queue is not empty on the
following rising edge of RCLK a word will be read from the previously selected
queue regardless of
REN due to the fall through operation, (provided the queue
is not empty). Remember that
OE allows the user to place the Qout, data output
bus into High-Impedance and the data can be read onto the output register
regardless of
OE.
When a queue is selected on the read port, the next word available in that
queue (provided that the queue is not empty), will fall through to the output
register after 2 RCLK cycles. As mentioned, in the previous 2 RCLK cycles to
the new data being available, data can still be read from the previous queue,
provided that the queue is not empty. At the point of queue selection, the 2-stage
internal data pipeline is loaded with the last word from the previous queue and
the next word from the new queue, both these words will fall through to the output
register consecutively upon selection of the new queue. This pipelining effect
provides the user with 100% bus utilization, but brings about the possibility that
a "NULL" queue may be required within a multi-queue device. Null queue
operation is discussed in the next section on.
If an empty queue is selected for read operations on the rising edge of RCLK,
on the same RCLK edge and the following RCLK edge, 2 final reads will be made
from the previous queue, provided that
REN is active, LOW. On the next RCLK
rising edge a read from the new queue will not occur, because the queue is
empty. The last word in the data output register (from the previous queue), will
remain there, but the output valid flag,
OV will go HIGH, to indicate that the data
present is no longer valid.
The RDADD bus is also used in conjunction with ESTR (almost empty flag
bus strobe), to address the almost empty flag bus of a respective device during
direct mode of operation. In the 16 queue multi-queue device the RDADD
address bus is 8 bits wide. The least significant 4 bits are used to address one
of the 16 available queues within a single multi-queue device. The 5th least
significant bit is used to select a "Null" Queue. During a Null-Q selection the 4
LSB's are don't care. The Null-Q is seen as an empty queue on the read port.
Null-Q operation is discussed in more detail in a separate section. The most
significant 3 bits are used when a device is connected in expansion mode, up
to 8 devices can be connected in expansion, each device having its own 3 bit
address. The selected device is the one for which the address matches a 3 bit
ID code, which is statically setup on the ID pins, ID0, ID1, and ID2 of each
individual device.
Refer to Table 2, for Read Address bus arrangement. Also, refer to Figures
12,14 & 15 for read queue selection and read port operation timing diagrams.
Operation RCLK
RADEN
ESTR
RDADD[7:0]
Read Queue
Select
1
0
0
1
Device Select
(Compared to
ID0,1,2)
Read Queue Address
(4 bits = 16 Queues)
7
6
5
4
3 2 1 0
4 3 2 1
0
Device Select
(Compared to
ID0,1,2)
X X X
Sector
Address
PAEn Sector
Select
Q0 : Q7
PAE0 : PAE7
Sector
Address
Queue Status on
PAEn Bus
0
1
Q8 : Q15
PAE0 : PAE7
5939 drw06
X
Null-Q
Select
Pin
TABLE 2 -- READ ADDRESS BUS, RDADD[7:0]
19
IDT72V51433/72V51443/72V51453 3.3V, MULTI-QUEUE FLOW-CONTROL DEVICES
(16 QUEUES) 18 BIT WIDE CONFIGURATION 589,824, 1,179,648 and 2,359,296 bits
COMMERCIAL AND INDUSTRIAL
TEMPERATURE RANGES
NULL QUEUE OPERATION (OF THE READ PORT)
Pipelining of data to the output port enables the device to provide 100% bus
utilization in standard mode. Data can be read out of the multi-queue flow-control
device on every RCLK cycle regardless of queue switches or other opera-
tions. The device architecture is such that the pipeline is constantly filled with
the next words in a selected queue to be read out, again providing 100% bus
utilization. This type of architecture does assume that the user is constantly
switching queues such that during a queue switch, the last data word required
from the previous queue will fall through the pipeline to the output.
Note, that if reads cease at the empty boundary of a queue, then the last word
will automatically flow through the pipeline to the output.
The Null-Q is selected via read port address space RDADD[4]. The
RDADD[7:0] bus should be addressed with xxx1xxxx, this address is the
Null-Q. A null queue can be selected when no further reads are required from
a previously selected queue. Changing to a null queue will continue to
propagate data in the pipeline to the previous queue's output. The Null-Q can
remain selected until a data becomes available in another queue for reading.
The Null-Q can be utilized in either standard or packet mode.
Note: If the user switches the read port to the null queue, this queue is seen
as and treated as an empty queue, therefore after switching to the null queue
the last word from the previous queue will remain in the output register and the
OV flag will go HIGH, indicating data is not valid.
The Null queue operation only has significance to the read port of the multi-
queue, it is a means to force data through the pipeline to the output. Null-Q
selection and operation has no meaning on the write port of the device. Also,
refer to Figure 16, Read Operation and Null Queue Select for diagram.
BUS MATCHING OPERATION
Bus Matching operation between the input port and output port is available.
During a master reset of the multi-queue the state of the two setup pins, IW (Input
Width) and OW (Output Width) determine the input and output port bus widths
as per the selections shown in Table 3, "Bus Matching Set-up". 9 bit bytes or
18 bit words can be written into and read from the queues. When writing to or
reading from the multi-queue in a bus matching mode, the device orders data
in a "Little Endian" format. See Figure 3, Bus Matching Byte Arrangement for
details.
The Full flag and Almost Full flag operation is always based on writes and
reads of data widths determined by the write port width. For example, if the input
port is x18 and the output port is x9, then two data reads from a full queue will
be required to cause the full flag to go HIGH (queue not full). Conversely, the
Output Valid flag and Almost Empty flag operations are always based on writes
and reads of data widths determined by the read port. For example, if the input
port is x9 and the output port is x18, two write operations will be required to cause
the output valid flag of an empty queue to go LOW, output valid (queue is not
empty).
Note, that the input port serves all queues within a device, as does the output
port, therefore the input bus width to all queues is equal (determined by the input
port size) and the output bus width from all queues is equal (determined by the
output port size).
FULL FLAG OPERATION
The multi-queue flow-control device provides a single Full Flag output,
FF.
The
FF flag output provides a full status of the queue currently selected on the
write port for write operations. Internally the multi-queue flow-control device
monitors and maintains a status of the full condition of all queues within it, however
only the queue that is selected for write operations has its full status output to the
FF flag. This dedicated flag is often referred to as the "active queue full flag".
When queue switches are being made on the write port, the
FF flag output
will switch to the new queue and provide the user with the new queue status,
on the cycle after a new queue selection is made. The user then has a full status
for the new queue one cycle ahead of the WCLK rising edge that data can be
written into the new queue. That is, a new queue can be selected on the write
port via the WRADD bus, WADEN enable and a rising edge of WCLK. On the
next rising edge of WCLK, the
FF flag output will show the full status of the newly
selected queue. On the second rising edge of WCLK following the queue
selection, data can be written into the newly selected queue provided that data
and enable setup & hold times are met.
Note, the
FF flag will provide status of a newly selected queue one WCLK
cycle after queue selection, which is one cycle before data can be written to that
queue. This prevents the user from writing data to a queue that is full, (assuming
that a queue switch has been made to a queue that is actually full).
The
FF flag is synchronous to the WCLK and all transitions of the FF flag occur
based on a rising edge of WCLK. Internally the multi-queue device monitors and
keeps a record of the full status for all queues. It is possible that the status of a
FF flag maybe changing internally even though that flag is not the active queue
flag (selected on the write port). A queue selected on the read port may
experience a change of its internal full flag status based on read operations.
See Figure 9, Write Queue Select, Write Operation and Full Flag Operation
and Figure 11, Full Flag Timing in Expansion Mode for timing information.
EXPANSION MODE - FULL FLAG OPERATION
When multi-queue devices are connected in Expansion mode the
FF flags
of all devices should be connected together, such that a system controller
monitoring and managing the multi-queue devices write port only looks at a
single
FF flag (as opposed to a discrete FF flag for each device). This FF flag
is only pertinent to the queue being selected for write operations at that time.
Remember, that when in expansion mode only one multi-queue device can be
written to at any moment in time, thus the
FF flag provides status of the active
queue on the write port.
This connection of flag outputs to create a single flag requires that the
FF flag
output have a High-Impedance capability, such that when a queue selection is
made only a single device drives the
FF flag bus and all other FF flag outputs
connected to the
FF flag bus are placed into High-Impedance. The user does
not have to select this High-Impedance state, a given multi-queue flow-control
device will automatically place its
FF flag output into High-Impedance when none
of its queues are selected for write operations.
When queues within a single device are selected for write operations, the
FF
flag output of that device will maintain control of the
FF flag bus. Its FF flag will
simply update between queue switches to show the respective queue full status.
The multi-queue device places its
FF flag output into High-Impedance based
on the 3 bit ID code found in the 3 most significant bits of the write queue address
bus, WRADD. If the 3 most significant bits of WRADD match the 3 bit ID code setup
on the static inputs, ID0, ID1 and ID2 then the
FF flag output of the respective
device will be in a Low-Impedance state. If they do not match, then the
FF flag
output of the respective device will be in a High-Impedance state. See Figure
11, Full Flag Timing in Expansion Mode for details of flag operation, including
when more than one device is connected in expansion.
I W
OW
Write Port
Read Port
0
0
x18
x18
0
1
x18
x9
1
0
x9
x18
1
1
x9
x9
TABLE 3
BUS-MATCHING SET-UP
20
COMMERCIAL AND INDUSTRIAL
TEMPERATURE RANGES
IDT72V51433/72V51443/72V51453 3.3V, MULTI-QUEUE FLOW-CONTROL DEVICES
(16 QUEUES) 18 BIT WIDE CONFIGURATION 589,824, 1,179,648 and 2,359,296 bits
OUTPUT VALID FLAG OPERATION
The multi-queue flow-control device provides a single Output Valid flag
output,
OV. The OV provides an empty status or data output valid status for the
data word currently available on the output register of the read port. The rising
edge of an RCLK cycle that places new data onto the output register of the read
port, also updates the
OV flag to show whether or not that new data word is
actually valid. Internally the multi-queue flow-control device monitors and
maintains a status of the empty condition of all queues within it, however only
the queue that is selected for read operations has its output valid (empty) status
output to the
OV flag, giving a valid status for the word being read at that time.
The nature of the first word fall through operation means that when the last
data word is read from a selected queue, the
OV flag will go HIGH on the next
enabled read, that is, on the next rising edge of RCLK while
REN is LOW.
When queue switches are being made on the read port, the
OV flag will switch
to show status of the new queue in line with the data output from the new queue.
When a queue selection is made the first data from that queue will appear on
the Qout data outputs 2 RCLK cycles later, the
OV will change state to indicate
validity of the data from the newly selected queue on this 2
nd
RCLK cycle also.
The previous cycles will continue to output data from the previous queue and
the
OV flag will indicate the status of those outputs. Again, the OV flag always
indicates status for the data currently present on the output register.
The
OV flag is synchronous to the RCLK and all transitions of the OV flag occur
based on a rising edge of RCLK. Internally the multi-queue device monitors and
keeps a record of the output valid (empty) status for all queues. It is possible that
the status of an
OV flag may be changing internally even though that respective
flag is not the active queue flag (selected on the read port). A queue selected
on the write port may experience a change of its internal
OV flag status based
on write operations, that is, data may be written into that queue causing it to
become "not empty".
See Figure 12, Read Queue Select, Read Operation and Figure 13, Output
Valid Flag Timing for details of the timing.
EXPANSION MODE OUTPUT VALID FLAG OPERATION
When multi-queue devices are connected in Expansion mode, the
OV flags
of all devices should be connected together, such that a system controller
monitoring and managing the multi-queue devices read port only looks at a
single
OV flag (as opposed to a discrete OV flag for each device). This OV flag
is only pertinent to the queue being selected for read operations at that time.
Remember, that when in expansion mode only one multi-queue device can be
read from at any moment in time, thus the
OV flag provides status of the active
queue on the read port.
This connection of flag outputs to create a single flag requires that the
OV flag
output have a High-Impedance capability, such that when a queue selection is
made only a single device drives the
OV flag bus and all other OV flag outputs
connected to the
OV flag bus are placed into High-Impedance. The user does
not have to select this High-Impedance state, a given multi-queue flow-control
device will automatically place its
OV flag output into High-Impedance when none
of its queues are selected for read operations.
When queues within a single device are selected for read operations, the
OV
flag output of that device will maintain control of the
OV flag bus. Its OV flag will
simply update between queue switches to show the respective queue output
valid status.
The multi-queue device places its
OV flag output into High-Impedance based
on the 3 bit ID code found in the 3 most significant bits of the read queue address
bus, RDADD. If the 3 most significant bits of RDADD match the 3 bit ID code setup
on the static inputs, ID0, ID1 and ID2 then the
OV flag output of the respective
device will be in a Low-Impedance state. If they do not match, then the
OV flag
output of the respective device will be in a High-Impedance state. See Figure
13, Output Valid Flag Timing for details of flag operation, including when more
than one device is connected in expansion.
ALMOST FULL FLAG
As previously mentioned the multi-queue flow-control device provides a
single Programmable Almost Full flag output,
PAF. The PAF flag output provides
a status of the almost full condition for the active queue currently selected on the
write port for write operations. Internally the multi-queue flow-control device
monitors and maintains a status of the almost full condition of all queues within
it, however only the queue that is selected for write operations has its full status
output to the
PAF flag. This dedicated flag is often referred to as the "active queue
almost full flag". The position of the
PAF flag boundary within a queue can be
at any point within that queues depth. This location can be user programmed
via the serial port or one of the default values (8 or 128) can be selected if the
user has performed default programming.
As mentioned, every queue within a multi-queue device has its own almost
full status, when a queue is selected on the write port, this status is output via the
PAF flag. The PAF flag value for each queue is programmed during multi-queue
device programming (along with the number of queues, queue depths and
almost empty values). The
PAF offset value, m, for a respective queue can be
programmed to be anywhere between `0' and `D', where `D' is the total memory
depth for that queue. The
PAF value of different queues within the same device
can be different values.
When queue switches are being made on the write port, the
PAF flag output
will switch to the new queue and provide the user with the new queue status,
on the second cycle after a new queue selection is made, on the same WCLK
cycle that data can actually be written to the new queue. That is, a new queue
can be selected on the write port via the WRADD bus, WADEN enable and a
rising edge of WCLK. On the second rising edge of WCLK following a queue
selection, the
PAF flag output will show the full status of the newly selected queue.
The
PAF is flag output is double register buffered, so when a write operation
occurs at the almost full boundary causing the selected queue status to go almost
full the
PAF will go LOW 2 WCLK cycles after the write. The same is true when
a read occurs, there will be a 2 WCLK cycle delay after the read operation.
So the
PAF flag delays are:
from a write operation to
PAF flag LOW is 2 WCLK + t
WAF
The delay from a read operation to
PAF flag HIGH is t
SKEW2
+WCLK + t
WAF
Note, if t
SKEW
is violated there will be one added WCLK cycle delay.
The
PAF flag is synchronous to the WCLK and all transitions of the PAF flag
occur based on a rising edge of WCLK. Internally the multi-queue device
monitors and keeps a record of the almost full status for all queues. It is possible
that the status of a
PAF flag maybe changing internally even though that flag is
not the active queue flag (selected on the write port). A queue selected on the
read port may experience a change of its internal almost full flag status based
on read operations. The multi-queue flow-control device also provides a
duplicate of the
PAF flag on the PAF[7:0] flag bus, this will be discussed in detail
in a later section of the data sheet.
See Figures 18 and 19 for Almost Full flag timing and queue switching.
ALMOST EMPTY FLAG
As previously mentioned the multi-queue flow-control device provides a
single Programmable Almost Empty flag output,
PAE. The PAE flag output
provides a status of the almost empty condition for the active queue currently
selected on the read port for read operations. Internally the multi-queue flow-
control device monitors and maintains a status of the almost empty condition of
all queues within it, however only the queue that is selected for read operations
has its empty status output to the
PAE flag. This dedicated flag is often referred
to as the "active queue almost empty flag". The position of the
PAE flag boundary
21
IDT72V51433/72V51443/72V51453 3.3V, MULTI-QUEUE FLOW-CONTROL DEVICES
(16 QUEUES) 18 BIT WIDE CONFIGURATION 589,824, 1,179,648 and 2,359,296 bits
COMMERCIAL AND INDUSTRIAL
TEMPERATURE RANGES
within a queue can be at any point within that queues depth. This location can
be user programmed via the serial port or one of the default values (8 or 128)
can be selected if the user has performed default programming.
As mentioned, every queue within a multi-queue device has its own almost
empty status, when a queue is selected on the read port, this status is output via
the
PAE flag. The PAE flag value for each queue is programmed during multi-
queue device programming (along with the number of queues, queue depths
and almost full values). The
PAE offset value, n, for a respective queue can be
programmed to be anywhere between `0' and `D', where `D' is the total memory
depth for that queue. The
PAE value of different queues within the same device
can be different values.
When queue switches are being made on the read port, the
PAE flag output
will switch to the new queue and provide the user with the new queue status,
on the second cycle after a new queue selection is made, on the same RCLK
cycle that data actually falls through to the output register from the new queue.
That is, a new queue can be selected on the read port via the RDADD bus,
RADEN enable and a rising edge of RCLK. On the second rising edge of RCLK
following a queue selection, the data word from the new queue will be available
at the output register and the
PAE flag output will show the empty status of the
newly selected queue. The
PAE is flag output is double register buffered, so
when a read operation occurs at the almost empty boundary causing the
selected queue status to go almost empty the
PAE will go LOW 2 RCLK cycles
after the read. The same is true when a write occurs, there will be a 2 RCLK
cycle delay after the write operation.
So the
PAE flag delays are:
from a read operation to
PAE flag LOW is 2 RCLK + t
RAE
The delay from a write operation to
PAE flag HIGH is t
SKEW2
+ RCLK + t
RAE
Note, if t
SKEW
is violated there will be one added RCLK cycle delay.
The
PAE flag is synchronous to the RCLK and all transitions of the PAE flag
occur based on a rising edge of RCLK. Internally the multi-queue device
monitors and keeps a record of the almost empty status for all queues. It is possible
that the status of a
PAE flag maybe changing internally even though that flag is
not the active queue flag (selected on the read port). A queue selected on the
write port may experience a change of its internal almost empty flag status based
on write operations. The multi-queue flow-control device also provides a
duplicate of the
PAE flag on the PAE[7:0] flag bus, this will be discussed in detail
in a later section of the data sheet.
See Figures 20 and 21 for Almost Empty flag timing and queue switching.
22
COMMERCIAL AND INDUSTRIAL
TEMPERATURE RANGES
IDT72V51433/72V51443/72V51453 3.3V, MULTI-QUEUE FLOW-CONTROL DEVICES
(16 QUEUES) 18 BIT WIDE CONFIGURATION 589,824, 1,179,648 and 2,359,296 bits
TABLE 4 -- FLAG OPERATION BOUNDARIES & TIMING
Output Valid,
OV Flag Boundary
I/O Set-Up
OV Boundary Condition
In18 to out18 or In9 to out9
OV Goes LOW after 1
st
Write
(Both ports selected for same queue
(see note below for timing)
when the 1
st
Word is written in)
In18 to out9)
OV Goes LOW after 1
st
Write
(Both ports selected for same queue
(see note below for timing)
when the 1
st
Word is written in)
In9 to out18
OV Goes LOW after 2
nd
Write
(Both ports selected for same queue
(see note below for timing)
when the 1
st
Word is written in)
NOTE:
1.
OV Timing
Assertion:
Write to
OV LOW: t
SKEW1
+ RCLK + t
ROV
If t
SKEW1
is violated there may be 1 added clock: t
SKEW1
+ 2 RCLK + t
ROV
De-assertion:
Read Operation to
OV HIGH: t
ROV
NOTE:
D = Queue Depth
FF Timing
Assertion:
Write Operation to
FF LOW: t
WFF
De-assertion:
Read to
FF HIGH: t
SKEW1
+ t
WFF
If t
SKEW1
is violated there may be 1 added clock: t
SKEW1
+WCLK +t
WFF
Full Flag,
FF Boundary
I/O Set-Up
FF Boundary Condition
In18 to out18 or In9 to out9
FF Goes LOW after D+1 Writes
(Both ports selected for same queue
(see note below for timing)
when the 1
st
Word is written in)
In18 to out18 or In9 to out9
FF Goes LOW after D Writes
(Write port only selected for queue
(see note below for timing)
when the 1
st
Word is written in)
In18 to out9
FF Goes LOW after D Writes
(Both ports selected for same queue
(see note below for timing)
when the 1
st
Word is written in)
In18 to out9
FF Goes LOW after D Writes
(Write port only selected for queue
(see note below for timing)
when the 1
st
Word is written in)
In9 to out18
FF Goes LOW after ([D+1] x 2) Writes
(Both ports selected for same queue
(see note below for timing)
when the 1
st
Word is written in)
In9 to out18
FF Goes LOW after (D x 2) Writes
(Write port only selected for queue
(see note below for timing)
when the 1
st
Word is written in)
23
IDT72V51433/72V51443/72V51453 3.3V, MULTI-QUEUE FLOW-CONTROL DEVICES
(16 QUEUES) 18 BIT WIDE CONFIGURATION 589,824, 1,179,648 and 2,359,296 bits
COMMERCIAL AND INDUSTRIAL
TEMPERATURE RANGES
TABLE 4 -- FLAG OPERATION BOUNDARIES & TIMING (CONTINUED)
NOTE:
n = Almost Empty Offset value.
Default values: if DF is LOW at Master Reset then n = 8
if DF is HIGH at Master Reset then n = 128
PAEn Timing
Assertion:
Read Operation to
PAEn LOW: 2 RCLK* + t
PAE
De-assertion: Write to
PAEn HIGH: t
SKEW3
+ RCLK* + t
PAE
If t
SKEW3
is violated there may be 1 added clock: t
SKEW3
+ 2 RCLK* + t
PAE
* If a queue switch is occurring on the read port at the point of flag assertion or de-assertion
there may be one additional RCLK clock cycle delay.
Programmable Almost Empty Flag Bus,
PAEn Boundary
I/O Set-Up
PAEn Boundary Condition
In18 to out18 or In9 to out9
PAEn Goes HIGH after
(Both ports selected for same queue when the 1
st
n+2 Writes
Word is written in until the boundary is reached)
(see note below for timing)
In18 to out18 or In9 to out9
PAEn Goes HIGH after
(Write port only selected for same queue when the n+1 Writes
1
st
Word is written in until the boundary is reached) (see note below for timing)
In18 to out9
PAEn Goes HIGH after n+1
Writes (see below for timing)
In9 to out18
PAEn Goes HIGH after
(Both ports selected for same queue when the 1
st
([n+2] x 2) Writes
Word is written in until the boundary is reached)
(see note below for timing)
In9 to out18
PAEn Goes HIGH after
(Write port only selected for same queue when the ([n+1] x 2) Writes
1
st
Word is written in until the boundary is reached) (see note below for timing)
Programmable Almost Full Flag,
PAF & PAFn Bus Boundary
I/O Set-Up
PAF & PAFn Boundary
In18 to out18 or In9 to out9
PAF/PAFn Goes LOW after
(Both ports selected for same queue when the 1
st
D+1-m Writes
Word is written in until the boundary is reached)
(see note below for timing)
In18 to out18 or In9 to out9
PAF/PAFn Goes LOW after
(Write port only selected for same queue when the D-m Writes
1
st
Word is written in until the boundary is reached) (see note below for timing)
In18 to out9
PAF/PAFn Goes LOW after
D-m Writes (see below for timing)
In9 to out18
PAF/PAFn Goes LOW after
([D+1-m] x 2) Writes
(see note below for timing)
NOTE:
D = Queue Depth
m = Almost Full Offset value.
Default values:
if DF is LOW at Master Reset then m = 8
if DF is HIGH at Master Reset then m= 128
PAF Timing
Assertion:
Write Operation to
PAF LOW: 2 WCLK + t
WAF
De-assertion: Read to
PAF HIGH: t
SKEW2
+ WCLK + t
WAF
If t
SKEW2
is violated there may be 1 added clock: t
SKEW2
+ 2 WCLK + t
WAF
PAFn Timing
Assertion:
Write Operation to
PAFn LOW: 2 WCLK* + t
PAF
De-assertion: Read to
PAFn HIGH: t
SKEW3
+ WCLK* + t
PAF
If t
SKEW3
is violated there may be 1 added clock: t
SKEW3
+ 2 WCLK* + t
PAF
* If a queue switch is occurring on the write port at the point of flag assertion or de-assertion
there may be one additional WCLK clock cycle delay.
NOTE:
n = Almost Empty Offset value.
Default values:
if DF is LOW at Master Reset then n = 8
if DF is HIGH at Master Reset then n = 128
PAE Timing
Assertion:
Read Operation to
PAE LOW: 2 RCLK + t
RAE
De-assertion: Write to
PAE HIGH: t
SKEW2
+ RCLK + t
RAE
If t
SKEW2
is violated there may be 1 added clock: t
SKEW2
+ 2 RCLK + t
RAE
Programmable Almost Empty Flag,
PAE Boundary
I/O Set-Up
PAE Assertion
In18 to out18 or In9 to out9
PAE Goes HIGH after n+2
(Both ports selected for same queue when the 1
st
Writes
Word is written in until the boundary is reached)
(see note below for timing)
In18 to out9
PAE Goes HIGH after n+1
(Both ports selected for same queue when the 1
st
Writes
Word is written in until the boundary is reached)
(see note below for timing)
In9 to out18
PAE Goes HIGH after
(Both ports selected for same queue when the 1
st
([n+2] x 2) Writes
Word is written in until the boundary is reached)
(see note below for timing)
24
COMMERCIAL AND INDUSTRIAL
TEMPERATURE RANGES
IDT72V51433/72V51443/72V51453 3.3V, MULTI-QUEUE FLOW-CONTROL DEVICES
(16 QUEUES) 18 BIT WIDE CONFIGURATION 589,824, 1,179,648 and 2,359,296 bits
PAFn FLAG BUS OPERATION
The IDT72V51433/72V51443/72V51453 multi-queue flow-control devices
can be configured for up to 16 queues, each queue having its own almost full
status. An active queue has its flag status output to the discrete flags,
FF and PAF,
on the write port. Queues that are not selected for a write operation can have
their
PAF status monitored via the PAFn bus. The PAFn flag bus is 8 bits wide,
so that 8 queues at a time can have their status output to the bus. If 9 or more
queues are setup within a device then there are 2 methods by which the device
can share the bus between queues, "Direct" mode and "Polled" mode
depending on the state of the FM (Flag Mode) input during a Master Reset. If
8 or less queues are setup within a device then each will have its own dedicated
output from the bus. If 8 or less queues are setup in single device mode, it is
recommended to configure the
PAFn bus to polled mode as it does not require
using the write address (WRADD).
PAFn - DIRECT BUS
If FM is LOW at master reset then the
PAFn bus operates in Direct (addressed)
mode. In direct mode the user can address the sector of queues they require
to be placed on to the
PAFn bus. For example, consider the operation of the
PAFn bus when 10 queues have been setup. To output status of the first sector,
Queue[0:7] the WRADD bus is used in conjunction with the FSTR (
PAF flag
strobe) input and WCLK. The address present on the significant bit of the
WRADD bus with FSTR HIGH will be selected as the sector address on a rising
edge of WCLK. So to address sector 1, Queue[0:7] the WRADD bus should be
loaded with "xxxxxx0", the
PAFn bus will change status to show the new sector
selected 1 WCLK cycle after sector selection.
PAFn[0:7] gets status of queues,
Queue[0:7] respectively.
To address the second sector, Queue[8:15], the WRADD address is
"xxxxxx1".
PAF[0:1] gets status of queues, Queue[9:10] respectively. Remem-
ber, only 10 queues were setup, so when sector 2 is selected the unused outputs
PAF[2:7] will be don't care states.
Note, that if a read or write operation is occurring to a specific queue, say
queue `x' on the same cycle as a sector switch which will include the queue `x',
then there may be an extra WCLK cycle delay before that queues status is
correctly shown on the respective output of the
PAFn bus. However, the active
PAF flag will show correct status at all times.
Sectors can be selected on consecutive clock cycles, that is the sector on the
PAFn bus can change every WCLK cycle. Also, data present on the input bus,
Din, can be written into a queue on the same WCLK rising edge that a sector
is being selected, the only restriction being that a write queue selection and
PAFn
sector selection cannot be made on the same cycle.
If 8 or less queues are setup then queues, Queue[0:7] have their
PAF status
output on
PAF[0:7] constantly.
When the multi-queue devices are connected in expansion of more than one
device the
PAFn busses of all devices are connected together, when switching
between sectors of different devices the user must utilize the 3 most significant
bits of the WRADD address bus (as well as the 2 LSB's). These 3 MSB's
correspond to the device ID inputs, which are the static inputs, ID0, ID1 & ID2.
Please refer to Figure 23
PAF
n - Direct Mode Sector Selection for timing
information. Also refer to Table 1, Write Address Bus, WRADD.
PAFn POLLED BUS
If FM is HIGH at master reset then the
PAFn bus operates in Polled (looped)
mode. In polled mode the
PAFn bus automatically cycles through the 2 sectors
within the device regardless of how many queues have been setup in the part.
Every rising edge of the WCLK causes the next sector to be loaded on the
PAFn
bus. The device configured as the master (MAST input tied HIGH), will take
control of the
PAFn after MRS goes LOW. For the whole WCLK cycle that the
first sector is on
PAFn the FSYNC (PAFn bus sync) output will be HIGH, for the
2nd sector, this FSYNC output will be LOW. This FSYNC output provides the
user with a mark with which they can synchronize to the
PAFn bus, FSYNC is
always HIGH for the WCLK cycle that the first sector of a device is present on
the
PAFn bus.
When devices are connected in expansion mode, only one device will be
set as the Master, MAST input tied HIGH, all other devices will have MAST tied
LOW. The master device is the first device to take control of the
PAFn bus and
will place its first sector on the bus on the rising edge of WCLK after the
MRS
input goes HIGH. For the next 3 WCLK cycles the master device will maintain
control of the
PAFn bus and cycle its sectors through it, all other devices hold
their
PAFn outputs in High-Impedance. When the master device has cycled its
sectors it passes a token to the next device in the chain and that device assumes
control of the
PAFn bus and then cycles its sectors and so on, the PAFn bus
control token being passed on from device to device. This token passing is done
via the FXO outputs and FXI inputs of the devices ("
PAF Expansion Out" and
"
PAF Expansion In"). The FXO output of the master device connects to the FXI
of the second device in the chain and the FXO of the second connects to the FXI
of the third and so on. The final device in a chain has its FXO connected to the
FXI of the first device, so that once the
PAFn bus has cycled through all sectors
of all devices, control of the
PAFn will pass to the master device again and so
on. The FSYNC of each respective device will operate independently and
simply indicate when that respective device has taken control of the bus and is
placing its first sector on to the
PAFn bus.
When operating in single device mode the FXI input must be connected to
the FXO output of the same device. In single device mode a token is still required
to be passed into the device for accessing the
PAFn bus.
Please refer to Figure 26,
PAF
n Bus Polled Mode for timing information.
PAEn FLAG BUS OPERATION
The IDT72V51433/72V51443/72V51453 multi-queue flow-control devices
can be configured for up to 16 queues, each queue having its own almost empty
status. An active queue has its flag status output to the discrete flags,
OV and PAE,
on the read port. Queues that are not selected for a read operation can have
their
PAE status monitored via the PAEn bus. The PAEn flag bus is 8 bits wide,
so that 8 queues at a time can have their status output to the bus. If 9 or more
queues are setup within a device then there are 2 methods by which the device
can share the bus between queues, "Direct" mode and "Polled" mode
depending on the state of the FM (Flag Mode) input during a Master Reset. If
8 or less queues are setup within a device then each will have its own dedicated
output from the bus. If 8 or less queues are setup in single device mode, it is
recommended to configure the
PAFn bus to polled mode as it does not require
using the write address (WRADD).
PAEn - DIRECT BUS
If FM is LOW at master reset then the
PAEn bus operates in Direct (addressed)
mode. In direct mode the user can address the sector of queues they require
to be placed on to the
PAEn bus. For example, consider the operation of the
PAEn bus when 10 queues have been setup. To output status of the first sector,
Queue[0:7] the RDADD bus is used in conjunction with the ESTR (
PAE flag
strobe) input and RCLK. The address present on the least significant bit of the
RDADD bus with ESTR HIGH will be selected as the sector address on a rising
edge of RCLK. So to address sector 1, Queue[0:7] the RDADD bus should be
loaded with "xxxxxx0", the
PAEn bus will change status to show the new sector
selected 1 RCLK cycle after sector selection.
PAEn[0:7] gets status of queues,
Queue[0:7] respectively.
To address the 2nd sector, Queue[8:15], the RDADD address is "xxxxxx1".
PAE[0:1] gets status of queues, Queue[9:10] respectively. Remember, only 10
25
IDT72V51433/72V51443/72V51453 3.3V, MULTI-QUEUE FLOW-CONTROL DEVICES
(16 QUEUES) 18 BIT WIDE CONFIGURATION 589,824, 1,179,648 and 2,359,296 bits
COMMERCIAL AND INDUSTRIAL
TEMPERATURE RANGES
queues were setup, so when sector 2 is selected the unused outputs
PAE[2:7]
will be don't care states.
Note, that if a read or write operation is occurring to a specific queue, say
queue `x' on the same cycle as a sector switch which will include the queue `x',
then there may be an extra RCLK cycle delay before that queues status is
correctly shown on the respective output of the
PAEn bus.
Sectors can be selected on consecutive clock cycles, that is the sector on the
PAEn bus can change every RCLK cycle. Also, data can be read out of a queue
on the same RCLK rising edge that a sector is being selected, the only restriction
being that a read queue selection and
PAEn sector selection cannot be made
on the same RCLK cycle.
If 8 or less queues are setup then queues, Queue[0:7] have their
PAE status
output on
PAE[0:7] constantly.
When the multi-queue devices are connected in expansion of more than one
device the
PAEn busses of all devices are connected together, when switching
between sectors of different devices the user must utilize the 3 most significant
bits of the RDADD address bus (as well as the 2 LSB's). These 3 MSB's
correspond to the device ID inputs, which are the static inputs, ID0, ID1 & ID2.
Please refer to Figure 22,
PAE
n - Direct Mode Sector Selection for timing
information. Also refer to Table 2, Read Address Bus, RDADD.
PAEn POLLED BUS
If FM is HIGH at master reset then the
PAEn bus operates in Polled (looped)
mode. In polled mode the
PAEn bus automatically cycles through the 2 sectors
within the device regardless of how many queues have been setup in the part.
Every rising edge of the RCLK causes the next sector to be loaded on the
PAEn
bus. The device configured as the master (MAST input tied HIGH), will take
control of the
PAEn after MRS goes LOW. For the whole RCLK cycle that the
first sector is on
PAEn the ESYNC (PAEn bus sync) output will be HIGH, for the
2nd sector, this ESYNC output will be LOW. This ESYNC output provides the
user with a mark with which they can synchronize to the
PAEn bus, ESYNC is
always HIGH for the RCLK cycle that the first sector of a device is present on
the
PAEn bus.
When devices are connected in expansion mode, only one device will be
set as the Master, MAST input tied HIGH, all other devices will have MAST tied
LOW. The master device is the first device to take control of the
PAEn bus and
will place its first sector on the bus on the rising edge of RCLK after the
MRS input
goes LOW. For the next 3 RCLK cycles the master device will maintain control
of the
PAEn bus and cycle its sectors through it, all other devices hold their PAEn
outputs in High-Impedance. When the master device has cycled its sectors it
passes a token to the next device in the chain and that device assumes control
of the
PAEn bus and then cycles its sectors and so on, the PAEn bus control
token being passed on from device to device. This token passing is done via
the EXO outputs and EXI inputs of the devices ("
PAE Expansion Out" and "PAE
Expansion In"). The EXO output of the master device connects to the EXI of the
second device in the chain and the EXO of the second connects to the EXI of
the third and so on. The final device in a chain has its EXO connected to the EXI
of the first device, so that once the
PAEn bus has cycled through all sectors of
all devices, control of the
PAEn will pass to the master device again and so on.
The ESYNC of each respective device will operate independently and simply
indicate when that respective device has taken control of the bus and is placing
its first sector on to the
PAEn bus.
When operating in single device mode the EXI input must be connected to
the EXO output of the same device. In single device mode a token is still required
to be passed into the device for accessing the
PAEn bus.
Please refer to Figure 27,
PAE
n Bus Polled Mode for timing information.
26
COMMERCIAL AND INDUSTRIAL
TEMPERATURE RANGES
IDT72V51433/72V51443/72V51453 3.3V, MULTI-QUEUE FLOW-CONTROL DEVICES
(16 QUEUES) 18 BIT WIDE CONFIGURATION 589,824, 1,179,648 and 2,359,296 bits
D17-D9
A
A
B
B
(a) x18 INPUT to x18 OUTPUT - BIG ENDIAN
(b) x18 INPUT to x18 OUTPUT - LITTLE ENDIAN
Write to Queue
Read from Queue
BYTE ORDER ON INPUT PORT:
BYTE ORDER ON OUTPUT PORT:
B
A
Read from Queue
A
(c) x18 INPUT to x9 OUTPUT - BIG ENDIAN
1st: Read from Queue
B
2nd: Read from Queue
B
(d) x18 INPUT to x9 OUTPUT - LITTLE ENDIAN
1st: Read from Queue
A
2nd: Read from Queue
A
(a) x9 INPUT to x18 OUTPUT - BIG ENDIAN
1st: Write to Queue
BYTE ORDER ON INPUT PORT:
B
2nd: Write to Queue
BYTE ORDER ON OUTPUT PORT:
A
B
Read from Queue
(a) x9 INPUT to x18 OUTPUT - LITTLE ENDIAN
B
A
Read from Queue
5939 drw07
BE IW OW
H L H
BE IW OW
L H L
BE IW OW
H H L
BE IW OW
L L H
BE IW OW
H L L
BE IW OW
L L L
D8-D0
Q17-Q9
Q8-Q0
Q17-Q9
Q8-Q0
Q17-Q9
Q8-Q0
Q17-Q9
Q8-Q0
Q17-Q9
Q8-Q0
Q17-Q9
Q8-Q0
D17-D9
D8-D0
D17-Q9
D8-Q0
Q17-Q9
Q8-Q0
Q17-Q9
Q8-Q0
Figure 3. Bus-Matching Byte Arrangement
27
IDT72V51433/72V51443/72V51453 3.3V, MULTI-QUEUE FLOW-CONTROL DEVICES
(16 QUEUES) 18 BIT WIDE CONFIGURATION 589,824, 1,179,648 and 2,359,296 bits
COMMERCIAL AND INDUSTRIAL
TEMPERATURE RANGES
t
RS
MRS
WEN
REN
t
RSS
FSTR,
ESTR
5939 drw08
DF
DFM
HIGH = Default Programming
LOW = Serial Programming
HIGH = Offset Value is 128
LOW = Offset value is 8
t
RSS
t
RSS
t
RSR
SENI
WADEN,
RADEN
t
RSS
t
RSS
t
RSS
OW, IW
FM
HIGH = Looped
LOW = Strobed (Direct)
ID0, ID1,
ID2
t
RSS
MAST
HIGH = Master Device
LOW = Slave Device
t
RSS
t
RSS
t
RSS
FF
t
RSF
OV
t
RSF
PAF
t
RSF
PAE
t
RSF
t
RSF
t
RSF
Qn
t
RSF
LOGIC "1" if
OE is LOW and device is Master
HIGH-Z if
OE is HIGH or Device is Slave
LOGIC "1" if Master Device
HIGH-Z if Slave Device
LOGIC "1" if Master Device
HIGH-Z if Slave Device
HIGH-Z if Slave Device
LOGIC "0" if Master Device
HIGH-Z if Slave Device
LOGIC "0" if Master Device
LOGIC "1" if Master Device
HIGH-Z if Slave Device
PAFn
PAEn
HIGH-Z if Slave Device
LOGIC "0" if Master Device
Figure 4. Master Reset
NOTES:
1.
OE can toggle during this period.
2.
PRS should be HIGH during a MRS.
28
COMMERCIAL AND INDUSTRIAL
TEMPERATURE RANGES
IDT72V51433/72V51443/72V51453 3.3V, MULTI-QUEUE FLOW-CONTROL DEVICES
(16 QUEUES) 18 BIT WIDE CONFIGURATION 589,824, 1,179,648 and 2,359,296 bits
Figure 6. Serial Port Connection for Serial Programming
DFM
MRS
SENI
SENO
MQ1
SI
SO
SCLK
DFM
MRS
SENI
SENO
MQ2
SI
SO
SCLK
DFM
MRS
SENI
SENO
MQn
SI
SO
SCLK
Serial Enable
Serial Input
Serial Clock
Default Mode
DFM = 0
Master Reset
Serial Loading
Complete
5939 drw10
Figure 5. Partial Reset
NOTES:
1. For a Partial Reset to be performed on a Queue, that Queue must be selected on both the write and read ports.
2. The queue must be selected a minimum of 2 clock cycles before the Partial Reset takes place, on both the write and read ports.
3. The Partial Reset must be LOW for a minimum of 1 WCLK and 1 RCLK cycle.
4. Writing or Reading to the queue (or a queue change) cannot occur until a minimum of 3 clock cycles after the Partial Reset has gone HIGH, on both the write and read ports.
5. The
PAF flag output for Qx on the PAFn flag bus may update one cycle later than the active PAF flag.
6. The
PAE flag output for Qx on the PAEn flag bus may update one cycle later than the active PAE flag.
WCLK
RCLK
RDADD
t
AH
t
AS
t
QH
t
QS
Qx
RADEN
r-2
r-1
r
PRS
r+2
r+1
t
PRSH
t
PRSS
REN
t
ENS
r+3
t
ENS
t
ROV
OV
t
RAE
PAE
5939 drw09
WEN
WADEN
t
AH
t
AS
WRADD
Qx
w-2
w-1
w
w+1
w+2
t
QH
t
QS
t
ENS
w+3
t
ENS
FF
t
WFF
PAF
t
WAF
Active Bus
PAF-Qx
(5)
t
PAF
Active Bus
PAE-Qx
(6)
t
PAE
t
PRSH
t
PRSS
29
IDT72V51433/72V51443/72V51453 3.3V, MULTI-QUEUE FLOW-CONTROL DEVICES
(16 QUEUES) 18 BIT WIDE CONFIGURATION 589,824, 1,179,648 and 2,359,296 bits
COMMERCIAL AND INDUSTRIAL
TEMPERATURE RANGES
Figure 7. Serial Programming
RCLK
WEN
SENO (MQ1)
FF
WADEN/
FSTR
RADEN/
ESTR
OV
WCLK
5939 drw11
t
WFF
t
ENS
t
ROV
t
PCWQ
t
QS
t
QH
t
QS
t
QH
t
PCRQ
HIGH - Z
HIGH - Z
(Slave Device)
(Slave Device)
SO
(MQ1)
MRS
SCLK
SENI
(MQ1)
SI
(MQ1)
t
RSR
t
SENO
1st
2nd
nth
1st
2nd
nth
1st
2nd
nth
t
SENS
SENO (MQ2)
SENO (MQ8)
B
12
B
11
t
SDS
B
1n
t
SDH
B
21
B
22
B
2n
B
81
B
82
B
8n
B
21
B
22
B
2n
B
81
B
82
B
8n
t
SENO
t
SENO
t
SCLK
t
SCKL
t
SCKH
Programming Complete
1st Device in Chain
2
nd Device in Chain
F
inal Device in Chain
t
SDO
t
SDOP
t
SENOP
t
SENOP
NOTES:
1.
SENI
can be toggled during serial loading. Once serial programming of a device is complete, the
SENI
and SI inputs become transparent.
SENI


SENO
and SI
SO.
2
.
DFM is LOW during Master Reset to provide Serial programming mode, DF is don't care.
3
.
When
SENO
of the final device is LOW no further serial loads will be accepted.
4
.
n = 19+(Qx72); where Q is the number of queues required for the IDT72V51433/72V51443/72V51453.
5
.
This diagram illustrates 8 devices in expansion.
6
.
Programming of all devices must be complete (
SENO
of the final device is LOW), before any write or read port operations can take place, this includes queue selections.
30
COMMERCIAL AND INDUSTRIAL
TEMPERATURE RANGES
IDT72V51433/72V51443/72V51453 3.3V, MULTI-QUEUE FLOW-CONTROL DEVICES
(16 QUEUES) 18 BIT WIDE CONFIGURATION 589,824, 1,179,648 and 2,359,296 bits
DFM
MRS
SENI
SENO
MQ1
WCLK
Serial Enable
(can be tied LOW)
WCLK
Default Mode
DFM = 1
Master Reset
Serial Loading
Complete
DFM
MRS
SENI
SENO
MQ2
WCLK
DFM
MRS
SENI
SENO
MQn
WCLK
RCLK
WEN
FF
WADEN/
FSTR
RADEN/
ESTR
OV
5939 drw11a
t
WFF
t
ENS
t
ROV
t
PCWQ
t
QS
t
QH
t
QS
t
QH
t
PCRQ
HIGH - Z
HIGH - Z
(Slave Device)
(Slave Device)
SENO (MQ1)
t
SENO
SENO (MQ2)
SENO (MQ8)
t
SENO
WCLK
MRS
1st Device in Chain
1st
2nd
nth
3rd
2nd Device in Chain
1st
2nd
nth
Final Device in Chain
1st
2nd
nth
Programming
Complete
t
SENO
Serial Port Connection for Default Programming
SI
S
O
XS
I
S
O
XS
I
S
O
X
Figure 8. Default Programming
NOTES:
1
.
This diagram illustrates multiple devices connected in expansion.
The
SENO
of the final device in a chain is the "programming complete" signal.
2.
SENI
of the first device in the chain can be held LOW
3
.
The
SENO
of a device should connect to the
SENI
of the next device in the chain.
The final device
SENO
is used to indicate programming complete.
4
.
When Default Programming is complete the
SENO
of the final device will go LOW.
5
.
SCLK is not used and can be tied LOW.
6
.
Programming of all devices must be complete (
SENO
of the final device is LOW),
before any write or read port operations can take place, this includes queue selections.
31
IDT72V51433/72V51443/72V51453 3.3V, MULTI-QUEUE FLOW-CONTROL DEVICES
(16 QUEUES) 18 BIT WIDE CONFIGURATION 589,824, 1,179,648 and 2,359,296 bits
COMMERCIAL AND INDUSTRIAL
TEMPERATURE RANGES
Figure 9. Write Queue Select, Write Operation and Full Flag Operation
WCLK
WADEN
t
QH
t
QS
t
AH
t
AS
WRADD
Q
x
FF
t
WFF
5939 drw12
WEN
t
ENS
t
AH
t
AS
Q
y
t
QH
t
QS
t
DH
t
DS
Q
X
W
D
t
DH
Q
y
W
D-2
W
D-1
Q
y
t
DH
Din
t
WFF
t
WFF
Previous Q Status
No Writes
Queue Full
*A*
*
B*
*C*
*
D*
*E*
*F*
*G*
t
DS
Q
y
W
D
t
DS
t
DH
t
ENH
t
WFF
t
WFF
RCLK
t
SKEW1
t
QS
t
QH
REN
t
ENS
RDADD
Q
y
RADEN
Qout
t
A
Previous Q, Word, W
Previous Q, W
+1
PFT
t
A
Qy, W
0
PFT
t
A
t
A
Qy, W
1
Qy, W
2
*H*
*
I*
*J*
t
AS
t
AH
*A
A
*
*
B
B
*
*
C
C
*
*D
D
*
*E
E
*
*F
F
*
t
DS
NOTE
:
OE
is active LOW.
Cycle
:
*A*
Queue, Qx is selected on the write port.
The
FF
flag is providing status of a previously selected queue, within the same device.
*AA*
Queue, Qy is selected for read operations.
*B*
The
FF
flag output updates to show the status of Qx, it is not full.
*BB*
Word W+1 is read from the previous queue regardless of
REN
due to FWFT.
*C*
Word, Wd is written into Qx. This causes Qx to go full.
*CC*
Word, W0 is read from Qy regardless of
REN
, this is due to the FWFT effect.
*D*
Queue, Qy is selected within the same device as Qx. A write to Qx cannot occur on this cycle because it is full,
FF
is LOW.
*DD*
No reads occur,
REN
is HIGH.
*E*
Again, a write to Qx cannot occur on this cycle because it is full,
FF
is LOW. The
FF
flag updates after time t
WFF
to show that queue, Qy is not full.
*EE*
Word, W1 is read from Qy, this causes Qy to go "not full",
FF
flag goes HIGH after time, t
SKEW1
+ t
WFF
. Note, if t
SKEW1
is violated the time
FF
HIGH will be: t
SKEW1
+ WCLK + t
WFF
.
*F*
Word, Wd-2 is written into Qy.
*FF*
Word, W2 is read from Qy.
*G*
Word, Wd-1 is written into Qy.
*H*
Word, Wd is written into Qy, this causes Qy to go full,
FF
goes LOW.
*I*
No writes occur to Qy.
*J*
Qy goes "not full" based on reading word W1 from Qy on cycle *EE*.
32
COMMERCIAL AND INDUSTRIAL
TEMPERATURE RANGES
IDT72V51433/72V51443/72V51453 3.3V, MULTI-QUEUE FLOW-CONTROL DEVICES
(16 QUEUES) 18 BIT WIDE CONFIGURATION 589,824, 1,179,648 and 2,359,296 bits
5939 drw12a
W1
W2
W3
WCLK
t
ENH
WEN
Dn
t
DH
t
DS
t
DS
t
DH
t
DS
t
DH
RCLK
t
SKEW1
1
2
t
ENS
REN
t
A
W1 Qy
FWFT
t
A
t
A
W2 Qy
FWFT
W3 Qy
Last Word Read Out of Queue
Qout
t
ROV
OV
t
ROV
t
ENS
Figure 10. Write Operations & First Word Fall Through
NOTES:
1. Qy has previously been selected on both the write and read ports.
2.
OE is LOW.
3. The First Word Latency = t
SKEW1
+ RCLK + t
A
. If t
SKEW1
is violated an additional RCLK cycle must be added.
33
IDT72V51433/72V51443/72V51453 3.3V, MULTI-QUEUE FLOW-CONTROL DEVICES
(16 QUEUES) 18 BIT WIDE CONFIGURATION 589,824, 1,179,648 and 2,359,296 bits
COMMERCIAL AND INDUSTRIAL
TEMPERATURE RANGES
WCLK
WADEN
t
QH
t
QS
t
AH
t
AS
WRADD
D
1
Q
12
FF (Device 1)
t
FFLZ
5939 drw13
WEN
t
ENS
t
AH
t
AS
t
AH
t
AS
t
QH
t
QS
D
2
Q
9
t
QH
t
QS
t
DH
t
DS
W
D
D
1 Q12
t
DH
t
DS
Din
t
WFF
t
WFF
HIGH-Z
RCLK
1
2
t
ENH
t
ENS
t
ENH
Addr=001
1100
D
1
Q
5
t
WFF
W
D
D
1 Q5
t
FFHZ
t
WFF
HIGH-Z
FF (Device 2)
t
FFHZ
HIGH-Z
t
FFLZ
t
SKEW1
Addr=001
0101
t
AH
t
AS
RDADD
D
1
Q
5
t
QH
t
QS
RADEN
*A*
*B*
*C*
*D*
*E*
*F*
*G*
*
H*
*I*
No Write
*J*
Qout
t
A
t
A
Previous Q W
X-1
Previous Q W
X
PFT
D
1
-Q
5
Word W
0
PFT
*AA*
*BB*
*CC*
Figure 11. Full Flag Timing in Expansion Mode
NOTE:
1.
REN
= HIGH.
Cycle
:
*A*
Queue, Q12 of device 1 is selected on the write port.
The
FF
flag of device 1 is in High-Impedance, the write port of device 2 was previously selected.
WEN
is HIGH so no write occurs.
*AA*
Queue, Q5 of device 1 is selected on the read port.
*B*
The
FF
flag of device 2 goes to High-Impedance and the
FF
flag of device 1 goes to Low-Impedance, logic HIGH indicating that D1 Q12 is not full.
WEN
is HIGH so no write occurs.
*BB*
Word, Wx is read from the previously selected queue, (due to FWFT).
*C*
Word, Wd is written into Q12 of D1. This write operation causes Q12 to go full,
FF
goes LOW.
*CC*
The first word from Q5 of D1 selected on cycle *AA* is read out, this occurred regardless of
REN
due to FWFT. This read caused Q5 to go not full, therefore the
FF
flag will go HIGH after: t
SKEW1
+ t
WFF
.
Note if t
SKEW1
is violated the time to
FF
flag HIGH is t
SKEW1
+ WLCK + t
WFF
.
*D*
Queue, Q5 of device 1 is selected on the write port. No write occurs on this cycle.
*E*
The
FF
flag updates to show the status of D1 Q5, it is not full,
FF
goes HIGH.
*F*
Word, Wd is written into Q5 of D1. This causes the queue to go full,
FF
goes LOW.
*G*
No write occurs regardless of
WEN
, the
FF
flag is LOW preventing writes.
*H*
The
FF
flag goes HIGH due to the read from Q5 of D1 on cycle *CC*. (This read is not an enabled read, it is due to the FWFT operation
).
*I*
Queue, Q9 of device 2 is selected on the write port.
*J*
The
FF
flag of device 1 goes to High-Impedance, this device was deselected on the write port on cycle *I*. The
FF
flag of device 2 goes to Low-Impedance and provides status of Q9 of D2.
34
COMMERCIAL AND INDUSTRIAL
TEMPERATURE RANGES
IDT72V51433/72V51443/72V51453 3.3V, MULTI-QUEUE FLOW-CONTROL DEVICES
(16 QUEUES) 18 BIT WIDE CONFIGURATION 589,824, 1,179,648 and 2,359,296 bits
Figure 12. Read Queue Select, Read Operation
RCLK
5939 drw14
t
AH
t
AS
Q
F
RDADD
t
QH
t
QS
RADEN
REN
t
ENS
t
ENH
t
ENS
t
AH
t
AS
Q
G
t
QH
t
QS
Q
OUT
Q
P
W
n-3
t
A
Q
P
W
n-2
t
A
Previous Q, Q
P
W
n-1
t
A
t
A
Q
P
W
n
t
A
Q
F
W
0
PFT
t
A
Q
F
W
1
Q
F
W
2
t
ROV
OV
Previous Q
1
2
*A*
*B*
*C*
*D*
*E*
*F*
*G*
*H*
PFT
*I*
Cycle
:
*A*
Word Wn-
3
is read from a previously selected queue Qp on the read port.
*B*
Wn-
2
is read.
*C*
Reads are disabled, Wn-
1
remains on the output bus.
*D*
A new queue, Q
F
is selected for read operations.
*E*
Due to the First Word Fall Through (FWFT) effect, a read from the previous queue Qp will take place, Wn from Qp is placed onto
the output bus regardless of
REN
.
*F*
The next word available in the new queue, Q
F
-W
0
falls through to the output bus, again this is regardless of
REN
.
*G*
A new queue, Q
G
is selected for read operations. (This queue is an empty queue). Word, W
1
is also read from Q
F
.
*H*
Word, W
1
is read from Q
F
. This occurs regardless of
REN
due to FWFT.
*I*
Word W
2
from Q
F
remains on the output bus because Q
G
is empty. The Output Valid Flag,
OV
goes HIGH to indicate that the current word is not valid, i.e. Q
G
is empty.
W
2
is the last word in Q
G
.
35
IDT72V51433/72V51443/72V51453 3.3V, MULTI-QUEUE FLOW-CONTROL DEVICES
(16 QUEUES) 18 BIT WIDE CONFIGURATION 589,824, 1,179,648 and 2,359,296 bits
COMMERCIAL AND INDUSTRIAL
TEMPERATURE RANGES
Figure 13. Output Valid Flag Timing (In Expansion Mode)
RCLK
RADEN
t
QH
t
QS
t
AH
t
AS
RDADD
D
1
Q
9
OV
(Device 1)
5939 drw15
t
ENS
REN
t
AH
t
AS
t
QH
t
QS
Qout
(Device 1)
t
ROV
HIGH-Z
WCLK
D
1
Q
15
OV
(Device 2)
t
OVHZ
t
SKEW1
t
AH
t
AS
WRADD
D
1
Q
15
t
QH
t
QS
WADEN
t
DH
t
DS
D
1
Q
15
W
0
Din
t
A
D
1
Q
9
W
D
Last Word
t
OLZ
t
A
D
1
Q
15
PFT W
e-1
t
A
D
1
Q
15
W
e
Last Word
t
A
W
0
Q
15
D
1
t
OVLZ
t
ROV
t
ROV
t
ROV
WEN
t
ENS
t
ENH
*A*
*B*
*C*
*D*
*E*
*F*
*G*
*H*
*I*
Cycle:
*A* Queue 9 of Device 1 is selected for read operations. The
OV is currently being driven by Device 2, a queue within device 2 is selected for reads. Device 2 also has control
of Qout bus, its Qout outputs are in Low-Impedance. This diagram only shows the Qout outputs of device 1. (Reads are disabled).
*B* Reads are now enabled. A word from the previously selected queue of Device 2 will be read out.
*C* The Qout of Device 1 goes to Low-Impedance and word Wd is read from Q9 of D1. This happens to be the last word of Q9. Device 2 places its Qout outputs into
High-Impedance, device 1 has control of the Qout bus. The
OV flag of Device 2 goes to High-Impedance and Device 1 takes control of OV. The OV flag of Device 1 goes LOW
to show that Wd of Q9 is valid.
*D* Queue 15 of device 1 is selected for read operations. The last word of Q9 was read on the previous cycle, therefore
OV goes HIGH to indicate that the data on the Qout is
not valid (Q9 was read to empty). Word, Wd remains on the output bus.
*E* The last word of Q9 remains on the Qout bus,
OV is HIGH, indicating that this word has been previously read.
*F* The next word (We-1), available from the newly selected queue, Q15 of device 1 is now read out. This will occur regardless of
REN, 2 RCLK cycles after queue selection
due to the FWFT operation. The
OV flag now goes LOW to indicate that this word is valid.
*G* The last word, We is read from Q15, this queue is now empty.
*H* The
OV flag goes HIGH to indicate that Q15 was read to empty on the previous cycle.
*I* Due to a write operation the
OV flag goes LOW and data word W0 is read from Q15. The latency is: t
SKEW1
+ 1*RCLK + t
ROV
.
36
COMMERCIAL AND INDUSTRIAL
TEMPERATURE RANGES
IDT72V51433/72V51443/72V51453 3.3V, MULTI-QUEUE FLOW-CONTROL DEVICES
(16 QUEUES) 18 BIT WIDE CONFIGURATION 589,824, 1,179,648 and 2,359,296 bits
Figure 14. Read Queue Selection with Reads Disabled
Figure 15. Read Queue Select, Read Operation and
OE
Timing
RCLK
5939 drw16
t
AH
t
AS
Q
n
RDADD
t
QH
t
QS
RADEN
REN
t
ENS
t
AH
t
AS
Q
P
t
QH
t
QS
Q
OUT
Q
P
W
D
t
A
Q
P
W
D+1
t
A
t
A
Q
P
W
D+2
t
A
Q
n
W
X+1
OV
t
ENS
t
ENH
t
A
Q
P
W
D+3
Q
P
W
D+4
*A*
*B*
*C*
*D*
*E*
*F*
*G*
*H*
*I*
*J*
t
A
t
ENH
Q
n
W
X
RCLK
RADEN
t
QH
t
QS
t
AH
t
AS
RDADD
Q
A
OV
5939 drw17
Qout
t
ROV
t
OLZ
t
A
Q
A
W
0
PFT
t
A
t
A
t
ENS
REN
t
AH
t
AS
Q
B
t
QH
t
QS
OE
t
OE
t
A
Previous Data in O/P Register
t
A
Q
A
W
1
No Read
Q
B
is Empty
t
ROV
*B*
*C*
*E*
*F*
*D*
*A*
*H*
*I*
*G*
t
ENH
t
ENS
Q
A
W
2
Q
A
W
3
Q
A
W
4
t
OHZ
Cycle:
*A* Word Wd+1 is read from the previously selected queue, Qp.
*B* Reads are disabled, word Wd+1 remains on the output bus.
*C* A new queue, Qn is selected for read port operations.
*D* Due to FWFT operation Word, Wd+2 of Qp is read out regardless of
REN.
*E* The next available word Wx of Qn is read out regardless of
REN, 2 RCLK cycles after queue selection. This is FWFT operation.
*F* The queue, Qp is again selected.
*G* Word Wx+1 is read from Qn regardless of
REN, this is due to FWFT.
*H* Word Wd+3 is read from Qp, this read occurs regardless of
REN due to FWFT operation.
*I* Word Wd+4 is read from Qp.
*J* Reads are disabled on this cycle, therefore no further reads occur.
NOTES:
1. The Output Valid flag,
OV is HIGH therefore the previously selected queue has been read to empty. The Output Enable input is Asynchronous, therefore the Qout output bus
will go to Low-Impedance after time t
OLZ
.
The data currently on the output register will be available on the output after time t
OE
. This data is the previous data on the output register, this is the last word read out of the
previous queue.
2. In expansion mode the
OE inputs of all devices should be connected together. This allows the output busses of all devices to be High-Impedance controlled.
Cycle:
*A* Queue A is selected for reads. No data will fall through on this cycle, the previous queue was read to empty.
*B* No data will fall through on this cycle, the previous queue was read to empty.
*C* Word, W0 from Qa is read out regardless of
REN due to FWFT operation. The OV flag goes LOW indicating that Word W0 is valid.
*D* Reads are disabled therefore word, W0 of Qa remains on the output bus.
*E* Reads are again enabled so word W1 is read from Qa.
*F* Word W2 is read from Qa.
*G* Queue, Qb is selected on the read port. This queue is actually empty. Word, W3 is read from Qa.
*H* Word, W4 falls through from Qa.
*I* Output Valid flag,
OV goes HIGH to indicate that Qb is empty. Data on the output port is no longer valid.
Output Enable is taken HIGH, this is Asynchronous so the output bus goes to High-Impedance after time, t
OHZ
.
37
IDT72V51433/72V51443/72V51453 3.3V, MULTI-QUEUE FLOW-CONTROL DEVICES
(16 QUEUES) 18 BIT WIDE CONFIGURATION 589,824, 1,179,648 and 2,359,296 bits
COMMERCIAL AND INDUSTRIAL
TEMPERATURE RANGES
RCLK
RADEN
Qout
REN
t
AH
t
AS
0001xxxx
RDADD
t
A
NULL QUEUE
SELECT
*A*
*B*
*C*
*E*
*F*
t
QH
t
ENS
Q1 Wn-3
Q1 Wn-2
Q1 Wn-1
t
A
t
A
Q1 Wn
t
A
Q4 W0
FWFT
OV
t
ROV
t
ROV
5938 drw18
SELECT
NEW QUEUE
*D*
00000100
t
AH
t
AS
t
QH
t
QS
t
ENH
t
QS
Figure 16. Read Operation and Null Queue Select
NOTES:
1. The purpose of the Null queue operation is so that the user can stop reading a block (packet) of data from a queue without filling the 2 stage output pipeline with the next words
from that queue.
2. Please see Figure 17, Null Queue Flow Diagram.
Cycle:
*A* Null Q of device 0 (32nd queue) is selected, when word Wn-1 from previously selected Q1 is read.
*B*
REN is HIGH and Wn (Last Word of the Packet) of Q1 is pipelined onto the O/P register.
Note: *B* and *C* are a minimum 2 RCLK cycles between Q selects.
*C* The Null Q is seen as an empty queue on the read side, therefore Wn of Q1 remains in the O/P register and
OV goes HIGH.
*D* A new Q, Q4 is selected and the 1st word of Q4 will fall through present on the O/P register on cycle *F*.
5939 drw19
Queue 1
Memory
*A*
Null
Queue
*B*
Null
Queue
*C*
O/P Reg.
*D*
*E*
*F*
Null
Queue
Queue 4
Memory
Q1
Wn
Queue 4
Memory
O/P Reg.
O/P Reg.
O/P Reg.
O/P Reg.
O/P Reg.
Qn
Wn-1
Q1
Wn
Q1
Wn
Q1
Wn
Q1
Wn
Q1
Wn
Q1
Wn
Q4
W0
Q1
Wn
Q4
W1
Q4
W0
Figure 17. Null Queue Flow Diagram
38
COMMERCIAL AND INDUSTRIAL
TEMPERATURE RANGES
IDT72V51433/72V51443/72V51453 3.3V, MULTI-QUEUE FLOW-CONTROL DEVICES
(16 QUEUES) 18 BIT WIDE CONFIGURATION 589,824, 1,179,648 and 2,359,296 bits
WCLK
WADEN
t
QH
t
QS
t
AH
t
AS
WRADD
D
1
Q
5
PAF
(Device 1)
t
AFLZ
5939 drw20
WEN
t
ENS
t
AH
t
AS
t
QH
t
QS
t
DH
t
DS
W
D-m
Din
t
WAF
t
WAF
HIGH-Z
t
ENH
D
1
Q
9
PAF
(Device 2)
t
FFHZ
1
2
D
1
Q
5
*B*
*C*
*E*
*F*
*D*
*A*
Figure 18. Almost Full Flag Timing and Queue Switch
Figure 19. Almost Full Flag Timing
WCLK
WEN
PAF
RCLK
t
WAF
REN
5939 drw21
D - (m+1) words in Queue
D - m words in Queue
1
2
1
D-(m+1) words
in Queue
t
WAF
t
ENH
t
ENS
t
SKEW2
t
ENH
t
ENS
t
CLKL
t
CLKL
Cycle:
*A* Queue 5 of Device 1 is selected on the write port. A queue within Device 2 had previously been selected. The
PAF output of device 1 is High-Impedance.
*B* No write occurs.
*C* Word, Wd-m is written into Q5 causing the
PAF flag to go from HIGH to LOW. The flag latency is 2 WCLK cycles + t
WAF
.
*D* Queue 9 if device 1 is now selected for write operations. This queue is not almost full, therefore the
PAF flag will update after a 2 WCLK + t
WAF
latency.
*E* The
PAF flag goes LOW based on the write 2 cycles earlier.
*F* The
PAF flag goes HIGH due to the queue switch to Q9.
NOTE:
1. The waveform here shows the
PAF flag operation when no queue switches are occurring and a queue selected on both the write and read ports is being written to then read
from at the almost full boundary.
Flag Latencies:
Assertion: 2*WCLK + t
WAF
De-assertion: t
SKEW2
+ WCLK + t
WAF
If t
SKEW2
is violated there will be one extra WCLK cycle.
39
IDT72V51433/72V51443/72V51453 3.3V, MULTI-QUEUE FLOW-CONTROL DEVICES
(16 QUEUES) 18 BIT WIDE CONFIGURATION 589,824, 1,179,648 and 2,359,296 bits
COMMERCIAL AND INDUSTRIAL
TEMPERATURE RANGES
Figure 20. Almost Empty Flag Timing and Queue Switch
Figure 21. Almost Empty Flag Timing
RCLK
RADEN
t
QH
t
QS
t
AH
t
AS
RDADD
D
1
Q
12
PAE
(Device 1)
t
AELZ
5939 drw22
REN
t
AH
t
AS
t
QH
t
QS
t
OLZ
Qout
t
RAE
t
RAE
HIGH-Z
D
1
Q
15
PAE
(Device 2)
t
AEHZ
HIGH
HIGH-Z
t
A
D
1
Q
12
W
n
HIGH-Z
*B*
*C*
*E*
*F*
*D*
*A*
t
A
D
1
Q
12
W
n+1
t
A
D
1
Q
15
W
0
t
A
D
1
Q
15
W
1
*G*
WCLK
t
ENH
t
CLKH
t
CLKL
WEN
PAE
RCLK
t
ENS
n+1 words in Queue
t
RAE
t
SKEW2
t
RAE
1
2
REN
5939 drw23
t
ENS
t
ENH
n+2 words in Queue
n+1 words in Queue
Cycle:
*A* Queue 12 of Device 1 is selected on the read port. A queue within Device 2 had previously been selected. The
PAE flag output and the data outputs of device 1 are High-Impedance.
*B* No read occurs.
*C* The
PAE flag output now switches to device 1. Word, Wn is read from Q12 due to the FWFT operation. This read operation from Q12 is at the almost empty boundary, therefore
PAE will go LOW 2 RCLK cycles later.
*D* Q15 of device 1 is selected.
*E* The
PAE flag goes LOW due to the read from Q12 2 RCLK cycles earlier. Word Wn+1 is read out due to the FWFT operation.
*F* Word, W0 is read from Q15 due to the FWFT operation. The
PAE flag goes HIGH to show that Q15 is not almost empty.
NOTE:
1. The waveform here shows the
PAE flag operation when no queue switches are occurring and a queue selected on both the write and read ports is being written to then read
from at the almost empty boundary.
Flag Latencies:
Assertion: 2*RCLK + t
RAE
De-assertion: t
SKEW2
+ RCLK + t
RAE
If t
SKEW2
is violated there will be one extra RCLK cycle.
40
COMMERCIAL AND INDUSTRIAL
TEMPERATURE RANGES
IDT72V51433/72V51443/72V51453 3.3V, MULTI-QUEUE FLOW-CONTROL DEVICES
(16 QUEUES) 18 BIT WIDE CONFIGURATION 589,824, 1,179,648 and 2,359,296 bits
Figure 22.
PAE
n - Direct Mode - Sector Selection
RCLK
t
STH
t
STS
t
QH
t
QS
001xxxx1
5939 drw24
RDADD
ESTR
Device 1
Sector 2
t
QS
t
QH
001xxxx0
Device 1
Sector 1
t
QS
t
QH
001xxxx1
Device 1
Sector 2
t
STS
t
STH
PAEn
t
PAE
t
PAE
Device 1 Sector 2
Device 1 Sector 1
t
PAE
Device 1 Sector 2
Figure 23.
PAF
n - Direct Mode - Sector Selection
WCLK
t
STH
t
STS
t
QH
t
QS
001xxx0
5939 drw25
WRADD
FSTR
Device 1
Sector 1
t
QS
t
QH
001xxx1
Device 1
Sector 2
t
QS
t
QH
001xxx0
Device 1
Sector 1
t
STS
t
STH
PAFn
t
PAF
t
PAF
Device 1 Sector 1
Device 1 Sector 3
t
PAF
Device 1 Sector 1
NOTES:
1. Sectors can be selected on consecutive cycles.
2. On an RCLK cycle that the ESTR is HIGH, the RADEN input must be LOW.
3. There is a latency of 1 RCLK for the
PAEn bus to switch.
NOTES:
1. Sectors can be selected on consecutive cycles.
2. On a WCLK cycle that the FSTR is HIGH, the WADEN input must be LOW.
3. There is a latency of 1 WCLK for the
PAFn bus to switch.
41
IDT72V51433/72V51443/72V51453 3.3V, MULTI-QUEUE FLOW-CONTROL DEVICES
(16 QUEUES) 18 BIT WIDE CONFIGURATION 589,824, 1,179,648 and 2,359,296 bits
COMMERCIAL AND INDUSTRIAL
TEMPERATURE RANGES
WCLK
Dn
Prev
PAEn
RCLK
ESTR
RDADD
D5 Sect 2
101 xxxx1
100 00100
D5Q4
t
AH
t
AS
t
AH
t
AS
1
t
SKEW3
Previous value loaded on to PAE bus
xxxx xxx0
D5 Sect 2
2
RADEN
t
QH
t
QS
t
STH
t
STS
t
PAE
5939 drw26
Device 5
PAE
t
RAE
*AA*
*BB*
*CC*
*DD*
*FF*
*EE*
t
RAE
D5 Qn Status
xxxx xxx0
D5 Sect 2
Bus
PAEn
Previous value loaded on to PAE bus
D5 Sect 2
D5 Sect 2
t
PAEHZ
t
PAEZL
xxxx xxx1
xxxx xxx1
REN
t
ENH
t
ENS
Device 5 -Qn
Wy
D5 Q4
Wy+1
D5 Q4
Wy+3
D5 Q4
Wy+2
D5 Q4
Wa+1
D5 Qn
t
A
t
A
t
A
t
A
t
A
Wa
D5 Qn
t
DH
t
DS
WEN
WADEN
FSTR
t
AH
100 0100
t
AS
WRADD
D5Q4
D3Q8
Wn
D5 Q4
Wn+1
D5Q4
Wx
D3 Q8
011 01000
D4 Sect 1
100 xxx0
*A*
*B*
*C*
*D*
*E*
*F*
t
QH
t
QS
t
QH
t
QS
t
AH
t
AS
t
AH
t
AS
t
ENS
t
ENH
t
STH
t
STS
Device 5
PAEn
1
2
t
ENS
t
ENH
Wp+1
Wp
Writes to Previous Q
t
DH
t
DS
t
RAE
D5 Q4
status
Figure 24.
PAE
n - Direct Mode, Flag Operation
Cycle:
*A*
Queue 4 of Device 5 is selected for write operations.
Word, Wp is written into the previously selected queue.
*AA* Queue 4 of Device 5 is selected for read operations.
A sector from another device has control of the
PAEn bus.
The discrete
PAE output of device 5 is currently in High-Impedance and the PAE active flag is controlled by the previously selected device.
*B*
Word Wp+1 is written into the previously selected queue.
*BB* Word, Wa+1 is read from Qn of D5, due to FWFT operation.
*C*
Word, Wn is written into the newly selected queue, Q4 of D5. This write will cause the
PAE flag on the read port to go from LOW to HIGH (not almost empty) after time,
t
SKEW3
+ RCLK + t
RAE
(if t
SKEW3
is violated one extra RCLK cycle will be added.
*CC* Word, Wy from the newly selected queue, Q4 will be read out due to FWFT operation.
Sector 2 of Device 5 is selected on the
PAEn bus. Q4 of device 5 will therefore have is PAE status output on PAE[0]. There is a single RCLK cycle latency before
the
PAEn bus changes to the new selection.
*D*
Queue 8 of Device 3 is selected for write operations.
Word Wn+1 is written into Q4 of D5.
*DD* The
PAEn bus changes control to D5, the PAEn outputs of D5 go to Low-Impedance and sector 2 is placed onto the outputs. The device of the previously selected
sector now places its
PAEn outputs into High-Impedance to prevent bus contention. Word, Wy+1 is read from Q4 of D5.
The discrete
PAE flag will go HIGH to show that Q4 of D5 is not almost empty. Q4 of device 5 will have its PAE status output on PAE[0].
*E*
No writes occur.
*EE* Word, Wy+2 is read from Q4 of D5.
*F*
Sector 1 of device 4 is selected on the write port for the
PAFn bus.
Word, Wx is written into Q8 of D3.
*FF* The
PAEn bus updates to show that Q4 of D5 is almost empty based on the reading out of word, Wy+1.
The discrete
PAE flag goes LOW to show that Q4 of D5 is almost empty based on the reading of Wy+1.
42
COMMERCIAL AND INDUSTRIAL
TEMPERATURE RANGES
IDT72V51433/72V51443/72V51453 3.3V, MULTI-QUEUE FLOW-CONTROL DEVICES
(16 QUEUES) 18 BIT WIDE CONFIGURATION 589,824, 1,179,648 and 2,359,296 bits
RCLK
OE
t
OLZ
REN
RADEN
ESTR
WRADD
t
AH
000 01111
t
AS
RDADD
D0Q16
D0 Q16
111 xxxx0
D7 sect 1
110 00010
*A*
*B*
*C*
*D*
*E*
*F*
000 xxx1
t
QH
t
QS
t
QH
t
QS
t
AH
t
AS
t
STH
t
STS
t
STH
t
STS
5939 drw27
*AA*
0xxx xxxx
D0Sect2
Device 0
PAFn
Bus
PAFn
*BB*
*CC*
*DD*
*EE*
*FF*
t
PAFLZ
1xxx xxxx
D0Sect2
D0Sect2
t
PAF
t
PAF
0xxx xxxx
0xxx xxxx
D0Sect2
1xxx xxxx
D0Sect2
D0Sect2 0xxx xxxx
D
X
Quad y
Prev.
PAFn
D
X
Quad y
t
PAFHZ
HIGH-Z
HIGH-Z
Device 0
PAF
HIGH - Z
t
PAFLZ
t
WAF
Qout
D6Q2
W
X
Prev. Q
W
D-M+1
t
A
D0 sect2
FSTR
t
A
WCLK
t
SKEW3
W
X +1
Prev. Q
1
2
D0 Q16
WEN
t
ENS
WADEN
t
QH
t
QS
t
AH
t
AS
t
AH
t
AS
W
D - M + 2
t
A
*G*
t
A
D0 Q16
W
0
D6 Q2
t
ENH
Din
t
DS
t
DH
t
DS
t
DH
t
DS
t
DH
Word W
y
D0 Q16
W
y+1
D0 Q16
W
y+2
D0 Q16
Figure 25.
PAF
n - Direct Mode, Flag Operation
Cycle:
*A*
Queue 16 of device 0 is selected for read operations.
The last word in the output register is available on Qout.
OE was previously taken LOW so the output bus is in Low-Impedance.
*AA* Sector 2 of device 0 is selected for the
PAFn bus. The bus is currently providing status of a previously selected sector, Sect Y of device X.
*B*
Word, Wx+1 is read out from the previous queue due to the FWFT effect.
*BB* Queue 16 of device 0 is selected on the write port.
The
PAFn bus is updated with the sector selected on the previous cycle, D0 Sect 2. PAF[7] is LOW showing the status of queue 16.
The
PAFn outputs of the device previously selected on the PAFn bus go to High-Impedance.
*C*
A new sector, Sect 1 of Device 7 is selected for the
PAFn bus.
Word, Wd-m+1 is read from Q16 D0 due to the FWFT operation. This read is at the
PAFn boundary of queue D0 Q16. This read will cause the PAF[7] output to go from
LOW to HIGH (almost full to not almost full), after a delay t
SKEW3
+ WCLK + t
PAF
. If t
SKEW3
is violated add an extra WCLK cycle.
*CC*
PAFn continues to show status of Sect 2 D0.
*D*
No read operations occur,
REN is HIGH.
*DD*
PAF[7] goes HIGH to show that D0 Q16 is not almost empty due to the read on cycle *C*.
The active queue
PAF flag of device 0 goes from High-Impedance to Low-Impedance.
Word, Wy is written into D0 Q16.
*E*
Queue 2 of Device 6 is selected for write operations.
*EE* Word, Wy+1 is written into D0 Q16.
*F*
Word, Wd-m+2 is read out due to FWFT operation.
*FF*
PAF[7] and the discrete PAF flag go LOW to show the write on cycle *DD* causes Q16 of D0 to again go almost full.
Word, Wy+2 is written into D0 Q16.
*G*
Word, W0 is read from Q0 of D6, selected on cycle *E*, due to FWFT.
43
IDT72V51433/72V51443/72V51453 3.3V, MULTI-QUEUE FLOW-CONTROL DEVICES
(16 QUEUES) 18 BIT WIDE CONFIGURATION 589,824, 1,179,648 and 2,359,296 bits
COMMERCIAL AND INDUSTRIAL
TEMPERATURE RANGES
WCLK
5939 drw28
t
FSYNC
t
FSYNC
FSYNC0
(MASTER)
t
FXO
t
FXO
t
FSYNC
t
FSYNC
t
FXO
t
FXO
t
FSYNC
t
FSYNC
t
FXO
t
FXO
FXO0 /
FXI1
FSYNC1
(SLAVE)
FXO1 /
FXI2
FSYNC2
(SLAVE)
FXO2 /
FXI0
PAF
n
t
PAF
t
PAF
t
PAF
t
PAF
t
PAF
t
PAF
t
PAF
t
PAF
t
FSYNC
t
FSYNC
D0Sect1
D0Sect2
D0Sect1
D1Sect2
D2Sect1
D2Sect2
D0Sect1
Figure 27.
PAE
n Bus - Polled Mode
Figure 26.
PAF
n Bus - Polled Mode
NOTE:
1. This diagram is based on 3 devices connected in expansion mode.
NOTE:
1. This diagram is based on 3 devices connected in expansion mode.
RCLK
5939 drw29
t
ESYNC
t
ESYNC
ESYNC0
t
EXO
t
EXO
t
ESYNC
t
ESYNC
t
EXO
t
EXO
t
ESYNC
t
ESYNC
t
EXO
t
EXO
EXO0 /
EXI1
ESYNC1
EXO1 /
EXI2
ESYNC2
EXO2 /
EXI0
PAE
n
t
PAE
t
PAE
t
PAE
t
PAE
t
PAE
t
PAE
t
PAE
t
PAE
t
ESYNC
t
ESYNC
D0Sect1
D0Sect2
D0Sect1
D1Sect2
D2Sect1
D2Sect2
D0Sect1
44
COMMERCIAL AND INDUSTRIAL
TEMPERATURE RANGES
IDT72V51433/72V51443/72V51453 3.3V, MULTI-QUEUE FLOW-CONTROL DEVICES
(16 QUEUES) 18 BIT WIDE CONFIGURATION 589,824, 1,179,648 and 2,359,296 bits
Figure 28. Multi-Queue Expansion Diagram
NOTES:
1. If devices are configured for Direct operation of the
PAFn/PAEn flag busses the FXI/EXI of the MASTER device should be tied LOW. All other devices tied HIGH. The FXO/EXO
outputs are DNC (Do Not Connect).
2. Q outputs must not be mixed between devices, i.e. Q0 of device 1 must connect to Q0 of device 2, etc.
WRADD
WADEN
WCLK
WEN
FSTR
PAFn
FSYNC
FF
PAF
SCLK
RCLK
REN
ESTR
PAEn
ESYNC
OV
PAE
RDADD
RADEN
SO FXO
EXO
SI

FXI
EXI
WRADD
WADEN
WCLK
WEN
FSTR
PAFn
FSYNC
FF
PAF
SCLK
RCLK
REN
ESTR
PAEn
ESYNC
OV
PAE
RDADD
RADEN
SO FXO
EXO
SI FXI
EXI
WRADD
WADEN
WCLK
WEN
FSTR
PAFn
FSYNC
FF
PAF
SCLK
RCLK
REN
ESTR
PAEn
ESYNC
OV
PAE
RDADD
RADEN
SENO
FXO EXO
Q0-Q17
SI

FXI
EXI
Data Bus
Write Clock
Write Enable
Write Queue Select
Full Strobe
Programmable Almost Full
Write Address
Full Sync1
Full Flag
Almost Full Flag
Serial Clock
Output Data Bus
Read Clock
Read Enable
Read Queue Select
Empty Strobe
Programmable Almost Empty
Read Address
Empty Sync 1
Output Valid Flag
Almost Empty Flag
Serial Programming Data Input
DEVICE
1
DEVICE
2
DEVICE
n
Full Sync2
Empty Sync 2
Full Sync n
Empty Sync n
SENO
SENI
SENO
SENI
DONE
5939 drw30
D0-D17
Q0-Q17
D0-D17
D0-D17
Q0-Q17
SENI
Serial Enable
45
IDT72V51433/72V51443/72V51453 3.3V, MULTI-QUEUE FLOW-CONTROL DEVICES
(16 QUEUES) 18 BIT WIDE CONFIGURATION 589,824, 1,179,648 and 2,359,296 bits
COMMERCIAL AND INDUSTRIAL
TEMPERATURE RANGES
T
A
P
TAP
Cont-
roller
Mux
DeviceID Reg.
Boundary Scan Reg.
Bypass Reg.
clkDR, ShiftDR
UpdateDR
TDO
TDI
TMS
TCLK
TRST
clklR, ShiftlR
UpdatelR
Instruction Register
Instruction Decode
Control Signals
5939 drw31
JTAG INTERFACE
Five additional pins (TDI, TDO, TMS, TCK and
TRST) are provided to
support the JTAG boundary scan interface. The IDT72V51433/72V51443/
72V51453 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
Figure 29. Boundary Scan Architecture
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).
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.
46
COMMERCIAL AND INDUSTRIAL
TEMPERATURE RANGES
IDT72V51433/72V51443/72V51453 3.3V, MULTI-QUEUE FLOW-CONTROL DEVICES
(16 QUEUES) 18 BIT WIDE CONFIGURATION 589,824, 1,179,648 and 2,359,296 bits
Test-Logic
Reset
Run-Test/
Idle
1
0
0
Select-
DR-Scan
Select-
IR-Scan
1
1
1
Capture-IR
0
Capture-DR
0
0
EXit1-DR
1
Pause-DR
0
Exit2-DR
1
Update-DR
1
Exit1-IR
1
Exit2-IR
1
Update-IR
1
1
0
1
1
1
5939 drw32
0
Shift-DR
0
0
0
Shift-IR
0
0
Pause-IR
0
1
Input = TMS
0
0
1
Figure 30. TAP Controller State Diagram
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 Queue 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.
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 Pause-
IR 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 Shift-
IR 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.
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 Queue operations can begin.
47
IDT72V51433/72V51443/72V51453 3.3V, MULTI-QUEUE FLOW-CONTROL DEVICES
(16 QUEUES) 18 BIT WIDE CONFIGURATION 589,824, 1,179,648 and 2,359,296 bits
COMMERCIAL AND INDUSTRIAL
TEMPERATURE RANGES
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 Update-
IR state.
The instruction register must contain 4 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.
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).
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.
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 32-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 IDT72V51433/72V51443/72V51453, the Part Number field con-
tains the following values:
Device
Part# Field (HEX)
IDT72V51433
0x431
IDT72V51443
0x432
IDT72V51453
0x433
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 4 bit field (i.e. IR3, IR2, IR1, IR0) to decode
16 different possible instructions. Instructions are decoded as follows.
JTAG INSTRUCTION REGISTER DECODING
Hex
Instruction
Function
Value
00
EXTEST
Select Boundary Scan Register
01
SAMPLE/PRELOAD
Select Boundary Scan Register
02
IDCODE
Select Chip Identification data register
04
HIGH-IMPEDANCE
JTAG
0F
BYPASS
Select Bypass Register
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 boundary-
test 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.
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 32-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.
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.
JTAG DEVICE IDENTIFICATION REGISTER
31(MSB)
28 27
12 11
1 0(LSB)
Version (4 bits)
Part Number (16-bit) Manufacturer ID (11-bit)
0X0
0X33
1
48
COMMERCIAL AND INDUSTRIAL
TEMPERATURE RANGES
IDT72V51433/72V51443/72V51453 3.3V, MULTI-QUEUE FLOW-CONTROL DEVICES
(16 QUEUES) 18 BIT WIDE CONFIGURATION 589,824, 1,179,648 and 2,359,296 bits
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.
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.
49
IDT72V51433/72V51443/72V51453 3.3V, MULTI-QUEUE FLOW-CONTROL DEVICES
(16 QUEUES) 18 BIT WIDE CONFIGURATION 589,824, 1,179,648 and 2,359,296 bits
COMMERCIAL AND INDUSTRIAL
TEMPERATURE RANGES
t
4
t
3
TDO
TDO
TDI/
TMS
TCK
TRST
t
DO
Notes to diagram:
t1 =
t
TCKLOW
t2 =
t
TCKHIGH
t3 =
t
TCKFALL
t4 = t
TCKRISE
t5 =
tRST
(reset pulse width)
t6 = tRSR (reset recovery)
5939 drw33
t
5
t
6
t
1
t
2
t
TCK
t
DH
t
DS
Figure 31. Standard JTAG Timing
SYSTEM INTERFACE PARAMETERS
Parameter
Symbol
Test
Conditions
Min.
Max. Units
JTAG Clock Input Period t
TCK
-
100
-
ns
JTAG Clock HIGH
t
TCKHIGH
-
40
-
ns
JTAG Clock Low
t
TCKLOW
-
40
-
ns
JTAG Clock Rise Time
t
TCKRISE
-
-
5
(1)
ns
JTAG Clock Fall Time
t
TCKFALL
-
-
5
(1)
ns
JTAG Reset
t
RST
-
50
-
ns
JTAG Reset Recovery
t
RSR
-
50
-
ns
JTAG
AC ELECTRICAL CHARACTERISTICS
(v
cc = 3.3V
5%; Tcase = 0C to +85C)
IDT72V51433
IDT72V51443
IDT72V51453
Parameter
Symbol
Test Conditions
Min.
Max.
Units
Data Output
t
DO
(1)
-
20
ns
Data Output Hold
t
DOH
(1)
0
-
ns
Data Input
t
DS
t
rise=3ns
10
-
ns
t
DH
t
fall=3ns
10
-
NOTE:
1. 50pf loading on external output signals.
NOTE:
1. Guaranteed by design.
50
CORPORATE HEADQUARTERS
for SALES:
for Tech Support:
2975 Stender Way
800-345-7015 or 408-727-6116
408-330-1533
Santa Clara, CA 95054
fax: 408-492-8674
email: Flow-Controlhelp@idt.com
www.idt.com
Plastic Ball Grid Array (PBGA, BB256-1)
Low Power
5939 drw34
IDT
XXXXX
Device Type
X
Power
XX
Speed
X
Package
X
Process /
Temperature
Range
72V51433
589,824 bits
3.3V Multi-Queue Flow-Control Device
72V51443
1,179,648 bits
3.3V Multi-Queue Flow-Control Device
72V51453
2,359,296 bits
3.3V Multi-Queue Flow-Control Device
BB
Commercial (0
C to +70C)
Industrial (-40
C to +85C)
Commercial Only
Commercial & Industrial
BLANK
I
(1)
Clock Cycle Time (t
CLK
)
Speed in Nanoseconds
6
7-5
L
ORDERING INFORMATION
NOTE:
1. Industrial temperature range product for the 7-5ns is available as a standard device. All other speed grades available by special order.
DATASHEET DOCUMENT HISTORY
10/12/2001
pgs. 1, 8, 10, 14, 15, 16 and 27.
11/16/2001
pgs. 1, 4, 10, 15, 17, 18, 23, 27-30 and 32.
12/19/2001
pgs. 12 and 28.
01/15/2002
pg. 47.
04/05/2002
pgs. 7, 9, 11, 13 and 48.
07/01/2002
pgs. 2, 27 and 44.
06/04/2003
pgs. 1 through 50.