ETC QLUM2208

QLUM2208-PT280C Device Data Sheet
• • • • • • Utopia Level 2 Master/Master Bridge
1.0 Utopia Level 2 (L2) Bridge Features
• Compliant with ATM-Forum af-phy-0039.000, June 1995 specification
• Implements two Utopia L2 Masters providing a solution to bridge Utopia Slave devices
• Single chip solution for improved system integration
• Supports cell level transfer mode
• Meets 50MHz performance offering up to 400Mbps cell rate transfers
• Cell and clock rate decoupling with on chip FIFOs
• Up to 1.5 KByte of on chip FIFO per data direction
• Integrated management interface and built-in errored cell discard
• ATM Cell size programmable via external pins from 16 to 128 bytes
• Optional Utopia parity generation/checking enable/disable via external pin
• Built in JTAG port (IEEE1149 compliant)
• Simulation model available for system level verification (Contact Quicklogic for details)
• Solution also available as flexible Soft-IP core, delivered with a full device modelization
and verification testbenches
QLUM2208-PT280C Device Data Sheet
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QLUM2208-PT280C Device Data Sheet
2.0 Utopia Overview
The Utopia (Universal Test & Operations PHY Interface for ATM) interface is defined by
the ATM Forum to provide a standard interface between ATM devices and ATM PHY or
SAR (segmentation and Re-assembly) devices.
Figure 1: Utopia Reference Model
The Utopia Standard defines a full duplex bus interface with a Master/Slave paradigm. The
Slave interface responds to the requests from the Master. The Master performs PHY
arbitration and initiates data transfers to and from the Slave device.
The ATM forum has standardized the Utopia Levels 1 (L1) to 3 (L3). Each level extends
the maximum supported interface speed from OC3, 155Mbps (L1) over OC12, 622Mbps
(L2) to 3.2Gbit/s (L3).
The following Table 1 gives an overview of the main differences in these three levels.
Table 1: Utopia Level Differences
Utopia Level
Interface Width
Max. Interface Speed
Maximum Throughput
1
8-bit
25 MHz
200 Mbps (typ. OC3 155 Mbps)
2
8-bit, 16-bit
50 MHz
800 Mbps (typ. OC12 622 Mbps)
3
8-bit, 32-bit
104 MHz
3.2 Gbps (typ. OC48 2.5 Gbps)
Utopia Level 1 implements an 8-bit interface running at up to 25MHz. Level 2 adds a 16
Bit interface and increases the speed to 50MHz. Level 3 extends the interface further by
a 32 Bit word-size and speeds up to 104MHz providing rates up to 3.2 Gbit/s over the
interface.
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QLUM2208-PT280C Device Data Sheet
In addition to the differences in throughput, Utopia Level 2 uses a shared bus offering to
physically share a single interface bus between one master and up to 31 slave devices
(Multi-PHY or MPHY operation). This allows the implementation of aggregation units that
multiplex several slave devices to a single Master device. The Level 2 and Level 3 are pointto-point only, whereas Level 1 has no notion of multiple slaves. Level 3 still has the notion
of multiple slaves, but they must be implemented in a single physical device connected to
the Utopia Interface.
3.0 Utopia Master/Master Bridge Application
As it is not possible to connect two Slave devices together, the Master/Master Bridge
provides the necessary interfaces to convey between two Slave devices as shown in
Figure 2.
Figure 2: Utopia Master Bridge
The Bridge automatically transfers data as soon as it becomes available from one side to
the other. Internal asynchronous FIFOs enable independent clock domains for each
interface.
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QLUM2208-PT280C Device Data Sheet
4.0 Application
Figure 3: Master/Master Bridge connecting two Slave Devices
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QLUM2208-PT280C Device Data Sheet
5.0 Bridge Core Pinout
Bridge Core implements all the required Utopia signals and provides all the Utopia optional
signals (Indicated by an 'O' in the following tables).
In addition to the Utopia Interface signals, error indication signals are available for error
monitoring or statistics. An error indication always shows that a cell has been discarded by
the bridge. Possible errors are parity or cell-length errors on the receive interface of the
corresponding Utopia Interfaces.
All Utopia interfaces work in the same transfer mode (cell level).
To identify the sides of the bridge, the notion "WEST" and "EAST" for the corresponding
interfaces will be used.
Figure 4: Utopia Level 2 Master/Master Bridge Top Entity
5.1 Signal Descriptions
Table 2: Global Signal
Pin
Mode
reset
In
QLUM2208-PT280C Device Data Sheet
Description
Active high chip reset
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QLUM2208-PT280C Device Data Sheet
Table 3: Device Management Interface
Pin
Mode
Description
wrx_err
Out
Receive error indication on west receive interface. When driven high, indicates
that an errored cell (Wrong parity or wrong length) was received from the device
connected to the west interface and is discarded.
Receive error status information for west receive interface. When wrx_err is
driven, indicates the error status of the discarded cell:
wrx_err_stat(1:0)
Out
• wrx_err_stat(0) : When set to ‘1’ indicates that a cell is discarded because of
a parity error.
• wrx_err_stat(1) : When set to ‘1’ indicates that a cell is discarded because it
has a wrong length (Consecutive assertion of ut_tx_soc on the Utopia
interface within less than a complete cell time).
erx_err(n)
Out
Receive error indication on east receive interface(s). When driven high, indicates
that an errored cell (Wrong parity or wrong length) was received from the device
connected to the east interface side.
Receive error status information for east receive interface. When erx_err is
driven, indicates the error status of the discarded cell:
erx_err_stat(n)
(1:0)
Out
• erx_err_stat(0) : When set to ‘1’ indicates that a cell is discarded because of
a parity error.
• erx_err_stat(1) : When set to ‘1’ indicates that a cell is discarded because it
has a wrong length (Consecutive assertion of ut_tx_soc on the Utopia
interface within less than a complete cell time).
Table 4: West Utopia Master Transmit Interface
Pin
Mode
Description
wtxclk
In
50MHz transmit byte clock. The Core samples all Utopia Transmit signals on txclk
rising edge.
wtxdata[7:0]
Out
Transmit data bus.
wtxprty
Out
Transmit data bus parity. Standard odd or non-standard even parity can be
optionally checked by the connected Slave.
When the parity check is disabled during the Core configuration, or not used in
the design, the pin txprty should be left open.
wtxsoc
Out
Transmit start of cell. Asserted by the Master to indicate that the current word is
the first word of a cell.
wtxenb
Out
Active low transmit data transfer enable.
wtxclav[0]
In
Cell buffer available. Asserted in octet level transfers to indicate to the Master that
the FIFO is almost full (Active low) or, in cell level transfers, to indicate to the
Master that the PHY port FIFO has space to accept one cell.
In
Extra FIFO Full / Cell buffer available. In MPHY mode and when direct status
indication is selected during the Core configuration, one txclav signal is
implemented per PHY port. The maximum number of clav signals is limited to
four.
wtxclav[3:1] (0)
wtxaddr[4:0]
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Out
Utopia transmit address. When the Core operates in MPHY mode, address bus
used during polling and slave port selection. Bit 4 is the MSB.
txaddr(4:0) becomes optional (And should be left open) when the Core does not
operate in MPHY mode.
© 2001 QuickLogic Corporation
QLUM2208-PT280C Device Data Sheet
Table 5: West Utopia Master Receive Interface
Pin
Mode
Description
wrxclk
In
50MHz receive byte clock. The Core samples all Utopia Receive signals on rxclk
rising edge.
wrxdata[7:0]
In
Receive data bus.
wrxprty(0)
In
Receive data bus parity. Standard odd or non standard even parity can be
optionally generated by the Utopia Slave Core.
When the parity generation is disabled during the Core configuration, the pin
rxprty can be let unconnected.
wrxsoc
In
Receive start of cell. Asserted to indicate that the current word is the first word of
a cell.
wrxenb
Out
wrxclav[0]
In
Cell buffer available. Asserted in octet level transfers to indicate to the Master that
the FIFO is almost empty (Active low) or, in cell level transfers, to indicate to the
Master that the PHY port FIFO has space one cell available in the FIFO.
wrxclav[3:1] (0)
In
Extra FIFO Full / Cell buffer available. In MPHY mode and when direct status
indication is selected, one rxclav signal is implemented per PHY port. The
maximum number of clav signals is limited to four.
wrxaddn(4:0)
Out
Active low transmit data transfer enable.
Utopia receive address. When the Core operates in MPHY mode, address bus
used during polling and slave port selection. Bit 4 is the MSB.
txaddr(4:0) becomes optional (And should be left open) when the Core does not
operate in MPHY mode.
NOTE: (O) indicates optional signals.
Table 6: East Utopia Master Transmit Interface
Pin
Mode
Description
etxclk
In
50MHz transmit byte clock. The Core samples all Utopia Transmit signals on txclk
rising edge.
etxdata[7:0]
Out
Transmit data bus.
etxprty
Our
Transmit data bus parity. Standard odd or non-standard even parity can be
optionally checked by the connected Slave.
When the parity check is disabled during the Core configuration, or not used in
the design, the pin txprty should be left open.
etxsoc
Out
Transmit start of cell. Asserted by the Master to indicate that the current word is
the first word of a cell.
etxenb
Out
Active low transmit data transfer enable.
etxclav[0]
In
Cell buffer available. Asserted in octet level transfers to indicate to the Master that
the FIFO is almost full (Active low) or, in cell level transfers, to indicate to the
Master that the PHY port FIFO has space to accept one cell.
In
Extra FIFO Full / Cell buffer available. In MPHY mode and when direct status
indication is selected during the Core configuration, one txclav signal is
implemented per PHY port. The maximum number of clav signals is limited to
four.
etxclav[3:1] (0)
etxaddr[4:0]
QLUM2208-PT280C Device Data Sheet
Out
Utopia transmit address. When the Core operates in MPHY mode, address bus
used during polling and slave port selection. Bit 4 is the MSB.
txaddr(4:0) becomes optional (And should be left open) when the Core does not
operate in MPHY mode.
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QLUM2208-PT280C Device Data Sheet
Table 7: East Utopia Master Receive Interface
Pin
Mode
Description
erxclk
In
50MHz receive byte clock. The Core samples all Utopia Receive signals on rxclk
rising edge.
erxdata[7:0]
In
Receive data bus.
erxprty (0)
In
Receive data bus parity. Standard odd or non standard even parity can be
optionally generated by the Utopia Slave Core.
When the parity generation is disabled during the Core configuration, the pin
rxprty can be let unconnected.
erxsoc
In
Receive start of cell. Asserted to indicate that the current word is the first word of
a cell.
erxenb
Out
erxclav[0]
In
Cell buffer available. Asserted in octet level transfers to indicate to the Master that
the FIFO is almost empty (Active low) or, in cell level transfers, to indicate to the
Master that the PHY port FIFO has space one cell available in the FIFO.
rxclav[3:1] (0)
In
Extra FIFO Full / Cell buffer available. In MPHY mode and when direct status
indication is selected, one rxclav signal is implemented per PHY port. The
maximum number of clav signals is limited to four.
erxaddr(4:0)
Out
Active low transmit data transfer enable.
Utopia receive address. When the Core operates in MPHY mode, address bus
used during polling and slave port selection. Bit 4 is the MSB.
taddr(4:0) becomes optional (And should be left open) when the Core does not
operate in MPHY mode.
Table 8: Device Configuration Pins
Pin
Mode
Description
prty_en
In
Enable parity checking on the Utopia interface.
If disabled (tied to 0), the wrx_err_stat(0) signal can be ignored and left open and
the rx parity input should be tied to 0. Also the tx parity pins can be left open.
cellsize[7:0]
In
Define cellsize: sets the size in bytes of a cell. Binary value to be set usually by
board wiring.
The configuration pins are not intended for change during operation. They are usually
board wired to configure the device for operation.
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QLUM2208-PT280C Device Data Sheet
6.0 Signal Descriptions
The externally provided Utopia Transmit and Receive clocks are connected to global
resources to provide low skew and fast chip level distribution. In both data directions, the
two corresponding Utopia Interfaces are decoupled by asynchronous FIFOs.
Therefore each interface runs completely independently each at its own tx and rx clocks
which typically are 50 MHz.
The Error indications of the two receive interfaces are always sampled within the west clock
domains. The errors of the east rx interface is available on the erx_err signal, which is
handled using the west clock domain (wtxclk). The west rx error is directly derived from the
west rx block (wrxclk).
Figure 5: Master/Master Bridge Clock Distribution
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QLUM2208-PT280C Device Data Sheet
7.0 Functional Description - Utopia Interface
The Utopia Bridge operates in single PHY mode. Therefore no address bus and only a
single status pin (clav[0]) per direction is used on the interfaces.
7.1 Utopia Interface Single PHY Transmit Interface
The Transmit interface is controlled by the Master (usually ATM layer).
The transmit interface has data flowing in the same direction as the Master's enable
ut_txenb. The Master transmit block generates all output signals on the rising edge of the
ut_txclk.
Transmit data is transferred from the Master to Slave via the following procedure. The
Slave indicates it can accept data using the ut_txclav (Mapped to ut_txfull in Octet level
transfer mode) signal, then the Master drives data onto ut_txdat and asserts ut_txenb.
The Slave controls the flow of data via the ut_txclav signal.
7.1.1 Cell Level Transfer - Single Cell
The Slave asserts ut_txclav 1 when it is capable of accepting the transfer of a whole
cell. The Master asserts ut_txenb (Low) to indicate that it drives valid data to the Slave
2. Together with the first word of a cell, the Master asserts ut_txsoc for one clock
cycle 3.
To ensure that the Master does not cause transmit overrun, the Slave must de-assert
ut_txclav at least 4 cycles before the end of a cell if it cannot accept the immediate
transfer of the subsequent cell 4.
The Master can pause the cell transfer by de-asserting ut_txenb 5. To complete the
transfer to the Slave, the Master de-asserts ut_txenb 6.
Figure 6: Single Cell Transfer - Cell Level Transfer
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QLUM2208-PT280C Device Data Sheet
7.1.2 Cell Level Transfer - Back to Back Cells
When, during a cell transfer, the Slave is able to receive a subsequent cell, the Master can
keep ut_txenb asserted between two cells 1 and asserts ut_txsoc, to start a new cell
transfer, immediately after the last word of the previous cell 2.
Figure 7: Back to Back Cell Transfer - Cell Level Transfer
7.1.3 Octet Level Transfer - Single Cell
During a time period termed the transmit window, the Slave stores data from ut_txdata,
if ut_txenb is asserted 1. The transmit window exists from the time that the Slave
indicates it can accept data by de-asserting the active low ut_txfull (Mapped to Master
signal ut_txclav), until four valid write cycles after the Slave layer asserts ut_txfull 2.
The Slave asserts the active low ut_txfull when it cannot accept data. The Master stops
sending data (ut_txenb de-asserted) three clock cycles after ut_txfull is asserted by
the Slave 3.
When the Slave is able to receive new data, it de-asserts ut_txfull 4. The Master
resumes the transfers and re-asserts ut_txenb 5.
Figure 8: Cell Transfer - Octet Level Transfer
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QLUM2208-PT280C Device Data Sheet
7.2 Utopia Interface Single PHY Receive Interface
The Receive interface is controlled by the Master interface. The receive interface has data
flowing in the opposite direction to the Master's enable ut_rxenb.
Receive data is transferred from the Slave to Master via the following procedure. The Slave
indicates it has valid data, then the Master asserts ut_rxenb to read this data from the
Slave. The Slave indicates valid data (thereby controlling the data flow) via the
ut_rxclav signal.
7.2.1 Cell Level Transfer - Single Cell
The Slave asserts ut_rxclav when it is ready to send a complete cell to the Master device
1. The Master asserts ut_rxenb to start the cell transfer. The Slave samples ut_rxenb
and start driving data 2. The Slave asserts ut_rxsoc together with the cell first word to
indicate the start of a cell 3.
The Master can pause a transfer by de-asserting ut_rxenb 4. The Slave samples high
ut_rxenb and stops driving data 5. To resume the transfer, the Master re-asserts
ut_rxenb 6. The Slave samples low ut_rxenb and starts driving valid data 7.
The Master drives ut_txenb high one before the expected end of the current cell if the
Slave has no more cell to transfer 8. The Slave de-asserts ut_rxclav to indicate that no
new cell is available 9.
Figure 9: Single Cell Transfer - Cell Level Transfer
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QLUM2208-PT280C Device Data Sheet
7.2.2 Cell Level Transfer - Back to Back Cells
The Master keeps ut_rxenb asserted at the end of a cell transfer 1 if the Slave has a new
cell to send, the Slave should then keep ut_rxclav asserted 2 and immediately drives
the new cell asserting ut_rxsoc to indicate the start of a new cell 3.
Figure 10: Back to Back Cells Transfer - Cell Level Transfer
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QLUM2208-PT280C Device Data Sheet
8.0 Core Management and Error Handling
On Ingress, the Utopia Master Blocks are designed to handle and report Utopia errors such
as Parity error or wrong cell length. Errored cells are discarded with an error status
provided on pins for use by external management facilities.
The error handling only applies to the corresponding receive parts of the core
(i.e. Ingress Ports).
When an errored cell is received on the Utopia interface, the Core discards the complete
cell and provides a cell discard indication (Signal eg_err asserted) 1 together with a cell
discard status (Signal eg_err_stat(n)(m:0)) 2.
NOTE: eg_err is routed to the corresponding wrx_err and erx_err respectively (see Figure 4).
Figure 11: Cell Discard Indication
Table 9: Error Status Word Bit Coding
Error Status Bit
Name
Description
0
PARITY_ERR
Valid when wrx/erx_err is asserted. If set to one indicates that a cell is discarded
with a parity error decoded by the Core.
1
LENGTH_ER
Valid when wrx/erx_err is asserted. If set to one indicates that a cell is discarded
with a cell length error detected on the Utopia interface.
The signals are sampled on the corresponding clocks from the west interface:
• erx_... sampled with wtxclk (west transmit clock)
• wrx_... sampled with wrxclk (west receive clock)
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QLUM2208-PT280C Device Data Sheet
9.0 Complexity and Performance Summary
9.1 Timing Parameters Definition
Figure 12: Tco Timing Parameter Definition
Figure 13: Tsu Timing Parameter Definition
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QLUM2208-PT280C Device Data Sheet
Table 10: 8-Bit Utopia Interface Timing Characteristics
Parameter
typ
Max -6
Unit
tco
7.5
6.5
ns
tsu
2.5
2.1
ns
wrxclk
50
MHz
wtxclk
50
MHz
erxclk
50
MHz
etxclk
50
MHz
minimum reset time
50
ns
NOTE: timing model "worst" case is used.
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QLUM2208-PT280C Device Data Sheet
10.0 Device Pinout
10.1 Signals Overview
Table 11: Signals Overview
Signals
Description
wrxclk, wrxclav, wrxenb*,
wrxdat, wrxsoc
West Utopia Receive Interface.
wtxclk, wtxclav, wtxenb*,
wtxdata, wtxsoc
West Utopia Transmit Interface.
wrx_err, wrx_err_stat
West Interface error indication (sampled with wrxclk).
erxclk, erxclav, erxenb*,
erxdata, erxsoc
East Utopia Receive Interface.
etxclk, etxclav, etxenb*,
etxdata, etxsoc
East Utopia Transmit Interface.
erx_err, erx_err_stat
East Interface error indication (sampled with wtxclk).
prty_en, cellsize
Configuration Pins to be board wired.
reset
Active high device reset
GND
Ground
VCC
Device Power 2.5 V
clk(x)
unused clock inputs should be tied to GND
IOCTRL(x)
VCCIO(x)
IO Power 3.3 V
INREF(x)
connect to GND
PLLRST(x)
connect to GND or VCC
PLLOUT(x)
connect to GND or VCC
VCCPLL(x)
GNDPLL(x)
TCK, TRSTB
JTAG signals. connect to GND
TMS, TDI
JTAG signals. connect to VCC
TDO
JTAG signal. leave open
iov
nc
not connected. should be left open
*: active low signal
NOTE: Unused Pins (data busses) in the following tables are to be handled like "nc".
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10.2 PT280 FPBGA Device Diagram
WEST receive error indication
device configuration
EAST receive error indication
QLUM2208
-PT280C
Figure 14: PT280 bottom view (0.8mm FPBGA)
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QLUM2208-PT280C Device Data Sheet
10.3 280 Pin FPBGA (PT280) Pinout Table
Table 12: 280 Pin FPBGA (PT280) Pinout Table
PIN
Function
PIN
Function
PIN
Function
PIN
Function
PIN
Function
A1
pllout(3)
D1
N/C
G19
N/C
N16
N/C
U6
inref(a)
A2
gndpll(0)
D2
N/C
H1
N/C
N17
N/C
U6
N/C
A3
erx_err
D3
N/C
H2
N/C
N18
ioctrl(c)
U8
N/C
A4
erx_err_stat[0]
D4
N/C
H3
N/C
N19
ioctrl(c)
U9
vccio(a)
A5
erx_err_stat[1]
D5
N/C
H4
N/C
P1
N/C
U10
erxclk
A6
ioctrl(f)
D6
nc (cellsize[0])
H5
vcc
P2
N/C
U11
vccio(b)
A7
wtxclav[0]
D7
prty_en
H15
vcc
P3
ioctrl(h)
U12
N/C
A8
wtxprty
D8
reset
H16
vcc
P4
inref(h)
U13
N/C
A9
wtxenb
D9
clk(8)
H17
N/C
P5
vcc
U14
ioctrl(b)
A10
wtxclk
D10
wrxclav[0]
H18
N/C
P15
gnd
U15
vccio(b)
A11
wtxsoc
D11
wrxprty
H19
N/C
P16
N/C
U16
etxdat[5]
A12
wtxdat[0]
D12
wrxenb
J1
N/C
P17
N/C
U17
tdo
A13
wtxdat[1]
D13
inref(e)
J2
N/C
P18
wrx_err
U18
pllrst(2)
A14
ioctrl(e)
D14
wrxsoc
J3
vccio(g)
P19
wrx_err_stat[0]
U19
etxprty
A15
wtxdat[2]
D15
wrxdat[0]
J4
N/C
R1
erxdat[7]
V1
pllout(2)
gndpll(3)
A16
wtxdat[3]
D16
wrxdat[1]
J5
gnd
R2
N/C
V2
A17
wtxdat[4]
D17
wrxdat[2]
J15
vcc
R3
vccio(h)
V3
gnd
A18
pllrst(1)
D18
wrxdat[3]
J16
N/C
R4
N/C
V4
erxprty
A19
gnd
D19
wrxdat[4]
J17
vccio(d)
R5
gnd
V5
erxenb
B1
pllrst(0)
E1
cellsize[3]
J18
N/C
R6
gnd
V6
ioctrl(a)
N/C
B2
gnd
E2
cellsize[2]
J19
N/C
R7
vcc
V7
B3
wtxdat[5]
E3
vccio(g)
K1
vcc
R8
vcc
V8
N/C
B4
wtxdat[6]
E4
cellsize[1]
K2
tck
R9
gnd
V9
N/C
B5
wtxdat[7]
E5
gnd
K3
N/C
R10
gnd
V10
clk(1)
B6
inref(f)
E6
vcc
K4
N/C
R11
vcc
V11
clk(4)
B7
N/C
E7
vcc
K5
gnd
R12
vcc
V12
N/C
B8
N/C
E8
vcc
K15
gnd
R13
vcc
V13
N/C
B9
tms
E9
vcc
K16
N/C
R14
vcc
V14
inref(b)
B10
clk(6)
E10
gnd
K17
N/C
R15
gnd
V15
N/C
B11
N/C
E11
gnd
K18
N/C
R16
etxdat[3]
V16
etxdat[6]
B12
N/C
E12
vcc
K19
trstb
R17
vccio(c)
V17
etxdat[1]
B13
ioctrl(e)
E13
vcc
L1
N/C
R18
etxenb
V18
gndpll(2)
B14
N/C
E14
gnd
L2
N/C
R19
wrx_err_stat[1]
V19
gnd
B15
N/C
E15
gnd
L3
vccio(h)
T1
erxdat[2]
W1
gnd
B16
N/C
E16
wrxdat[5]
L4
N/C
T2
erxdat[3]
W2
pllrst(3)
B17
vccpll(1)
E17
vccio(d)
L5
vcc
T3
erxdat[4]
W3
nc
B18
gndpll(1)
E18
inref(d)
L15
gnd
T4
erxdat[5]
W4
nc
B19
pllout(0)
E19
ioctrl(d)
L16
N/C
T5
erxdat[6]
W5
nc
C1
N/C
F1
inref(g)
L17
vccio(c)
T6
ioctrl(a)
W6
erxclav[0]
C2
vccpll(0)
F2
ioctrl(g)
L18
N/C
T7
N/C
W7
N/C
C3
N/C
F3
cellsize[5]
L19
N/C
T8
N/C
W8
N/C
C4
N/C
F4
cellsize[4]
M1
N/C
T9
N/C
W9
tdi
C5
vccio(f)
F5
gnd
M2
N/C
T10
N/C
W10
etxclk
C6
ioctrl(f)
F15
vcc
M3
N/C
T11
clk(3)
W11
N/C
C7
N/C
F16
ioctrl(d)
M4
N/C
T12
N/C
W12
N/C
C8
N/C
F17
wrxdat[6]
M5
vcc
T13
N/C
W13
N/C
C9
vccio(f)
F18
wrxdat[7]
M15
vcc
T14
N/C
W14
ioctrl(b)
C10
wrxclk
F19
wrxdat[8]
M16
inref(c)
T15
N/C
W15
etxdat[10]
C11
vccio(e)
G1
N/C
M17
N/C
T16
etxdat[4]
W16
etxdat[7]
C12
N/C
G2
cellsize[7]
M18
N/C
T17
vccpll(2)
W17
etxdat[2]
C13
N/C
G3
ioctrl(g)
M19
N/C
T18
etxsoc
W18
etxdat[0]
C14
N/C
G4
cellsize[6]
N1
ioctrl(h)
T19
etxclav[0]
W19
pllout(1)
C15
vccio(e)
G5
vcc
N2
N/C
U1
erxsoc
erxdat[0]
C16
N/C
G15
vcc
N3
N/C
U2
C17
N/C
G16
N/C
N4
N/C
U3
vccpll(3)
C18
N/C
G17
N/C
N5
vcc
U4
erxdat[1]
C19
N/C
G18
N/C
N15
vcc
U5
vccio(a)
QLUM2208-PT280C Device Data Sheet
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QLUM2208-PT280C Device Data Sheet
11.0 References
• ATM Forum, Utopia Level 2, af-phy-0039.000
12.0 Contact
QuickLogic Corp.
Tel
: 408 990 4000 (US)
: + 44 1932 57 9011 (Europe)
: + 49 89 930 86 170 (Germany)
: + 852 8106 9091 (Asia)
: + 81 45 470 5525 (Japan)
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www.quicklogic.com
E-mail
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