ETC IDT77V1264L200PG

IDT77V1264L200
Quad Port PHY (Physical Layer)
for 25.6, 51.2, and 204.8 Mbps
ATM Networks and Backplane
Applications
Description
Features List
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Performs the PHY-Transmission Convergence (TC) and
Physical Media Dependent (PMD) Sublayer functions for
four 204.8 Mbps ATM channels
Compliant to ATM Forum (af-phy-040.000) and ITU-T I.432.5
specifications for 25.6 Mbps physical interface
Operates at 25.6, 51.2, 102.4, 204.8 Mbps data rates
Individual Selection of Port Data Rates
Backwards Compatible with 77V1254L25
UTOPIA Level 1, UTOPIA Level 2, or DPI-4 Interface
3-Cell Transmit and Receive FIFOs
LED Interface for status signalling
Supports UTP Category 3 and 5 physical media
Low-Power CMOS
3.3V supply with 5V tolerant inputs
144-pin PQFP Package (28 x 28 mm)
Commercial and Industrial Temperature Ranges
The IDT77V1264L200 is a member of IDT's family of products
supporting Asynchronous Transfer Mode (ATM) data communications
and networking. The IDT77V1264L200 implements the physical layer for
25.6 Mbps ATM, connecting four serial copper links (UTP Category 3
and 5) to one ATM layer device such as a SAR or a switch ASIC. The
IDT77V1264L200 also operates at 51.2 Mbps and 204.8 Mbps, and is
well suited to backplane driving applications.
The 77V1264L200-ATM layer interface is selectable as either: 16-bit
UTOPIA Level 2, 8-bit UTOPIA Level 1 Multi-PHY, or quadruple 4-bit
DPI (Data Path Interface).
The IDT77V1264L200 is fabricated using IDT's state-of-the-art
CMOS technology, providing the highest levels of integration, performance and reliability, with the low-power consumption characteristics of
CMOS.
Block Diagram
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IDT and the IDT logo are registered trademarks of Integrated Device Technology, Inc.
1 of 49
 2001 Integrated Device Technology, Inc.
December 6, 2001
DSC 6029
IDT77V1264L200
Applications
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Up to 204.8Mbps backplane transmission
Rack-to-rack short links
ATM Switches
77V1264L200 Overview
The 77V1264L200 is a four port implementation of the physical layer
standard for 25.6Mbps ATM network communications as defined by
ATM Forum document af-phy-040.000 and ITU-T I.432.5. The physical
layer is divided into a Physical Media Dependent sub layer (PMD) and
Transmission Convergence (TC) sub layer. The PMD sub layer includes
the functions for the transmitter, receiver and clock recovery for operation across 100 meters of category 3 and 5 unshielded twisted pair
(UTP) cable. This is referred to as the Line Side Interface. The TC sub
layer defines the line coding, scrambling, data framing and synchronization.
On the other side, the 77V1264L200 interfaces to an ATM layer
device (such as a switch core or SAR). This cell level interface is configurable as either an 8-bit Utopia Level 1 Multi-PHY, 16-bit Utopia Level 2,
or four 4-bit DPI interface, as determined by two MODE pins. This is
referred to as the PHY-ATM Interface. The pinout and front page block
diagram are based on the Utopia 2 configuration. Table 3 shows the
corresponding pin functions for the other two modes, and Figure 2 and
Figure 3 show functional block diagrams.
The 77V1264L200 is based on the 77105, and maintains significant
register compatibility with it. The 77V1264L200, however, has additional
register features, and also duplicates most of its registers to provide
significant independence between the four ports.
Access to these status and control registers is through the utility bus.
This is an 8-bit muxed address and data bus, controlled by a conventional asynchronous read/write handshake.
Additional pins permit insertion and extraction of an 8kHz timing
marker, and provide LED indication of receive and transmit status.
Mbps, as shown in Table 3. For 204.8Mbps data rate applications,
ST6200T magnetics from Pulse Engineering can be used. These
magnetics have been tested to work over 10 meters of UTP 5 cable at
204.8Mbps. The rate is determined by the frequency of the OSC clock,
multiplied by the internal PLL clock multiplier factor (1x, 2x or 4x) as
determined in the Enhanced Control 2 Registers. Although the OSC
clock frequency is common to all ports of the PHY, the clock multiplier
factor can be set individually for each port. As an example, with a 64
MHz oscillator, this allows some ports to operate at 51.2 Mbps while
other ports are simultaneously operating at 204.8 Mbps.
When operating at clock multiples other than 1x, use of the RXREF
pin requires that the RXREF Pulse Width Select field in the LED Driver
and HEC Status/Control Registers be programmed to a value greater
than the default of 1 cycle.
Also, the PHY loopback mode without clock recovery (10) in the
Diagnostic Control Registers works only when the clock multiplier is 1x.
For higher multiples, the PHY loopback mode (01) with clock recovery
must be used.
Except as noted above, these higher speed configurations operate
exactly the same as the basic 25.6 Mbps configuration. The scrambling
and encoding are unchanged.
Table 1 shows some of the different data rates the PHY can operate
at with a 32MHz or 64MHz oscillator. Note that any oscillator frequency
between 32MHz and 64MHz can be used. For example, if a 48MHz
oscillator is used and the multiplier is set to 4x, the data rate would be
153.6Mbps.
Auto-Synchronization and Good Signal Indication
The 77V1264L200 features a new receiver synchronization algorithm
that allow it to achieve 4b/5b symbol framing on any valid data stream.
This is an improvement on earlier products which could frame only on
the escape symbol, which occurs only in start-of-cell or 8kHz (X8) timing
marker symbol pairs.
ATM25 transceivers always transmit valid 4b/5b symbols, allowing
the 77V1264L200 receive section to achieve symbol framing and properly indicate receive signal status, even in the absence of ATM cells or
8kHz (X8) timing markers in the receive data stream. A state machine
monitors the received symbols and asserts the “Good Signal” status bit
when a valid signal is being received. “Good Signal” is deasserted and
the receive FIFO is disabled when the signal is lost. This is sometimes
referred to as Loss of Signal (LOS).
Reference
Clock (OSC)
Clock Multiplier
Control Bits
(Enhanced Control 2
Registers)
Line Bit
Rate
(MHz)
Data
Rate
(Mbps)
32 MHz
00 (1x)
32
25.6
64 MHz
01 (2x)
64
51.2
10 (4x)
128
102.4
00 (1x)
64
51.2
01 (2x)
128
102.4
10 (4x)
256
204.8
Table 1 200 Speed Grade Option
Operation at Speeds Above 25 Mbps
In addition to operation at the standard rate of 25.6 Mbps, the
77V1264L200 can be operated at a range of data rates, up to 204.8
2 of 49
December 6, 2001
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3 of 49
December 6, 2001
IDT77V1264L200
Signal Descriptions
Line Side Signals
Signal Name
Pin Number
I/O
Signal Description
RX0+,-
139, 138
In
Port 0 positive and negative receive differential input pair.
RX1+,-
133, 132
In
Port 1 positive and negative receive differential input pair.
RX2+,-
121, 120
In
Port 2 positive and negative receive differential input pair.
RX3+,-
115, 114
In
Port 3 positive and negative receive differential input pair.
TX0+,-
4, 3
Out
Port 0 positive and negative transmit differential output pair.
TX1+,-
144, 143
Out
Port 1 positive and negative transmit differential output pair.
TX2+,-
110, 109
Out
Port 2 positive and negative transmit differential output pair.
TX3+,-
106, 105
Out
Port 3 positive and negative transmit differential output pair.
Utility Bus Signals
Signal Name
Pin Number
I/O
AD[7:0]
101, 100, 99, 98, 96, 95, 94, In/Out Utility bus address/data bus. The address input is sampled on the falling edge of ALE. Data is output on this
bus when a read is performed. Input data is sampled at the completion of a write operation.
93
ALE
91
CS
90
RD
89
In
Utility bus read enable. Active low asynchronous input. After latching an address, a read is performed by
deasserting WR and asserting RD and CS.
WR
88
In
Utility bus write enable. Active low asynchronous input. After latching an address, a write is performed by
deasserting RD, placing data on the AD bus, and asserting WR and CS. Data is sampled when WR or CS is
deasserted.
In
Signal Description
Utility bus address latch enable. Asynchronous input. An address on the AD bus is sampled on the falling
edge of ALE. ALE must be low when the AD bus is being used for data.
Utility bus asynchronous chip select. CS must be asserted to read or write an internal register. It may remain
asserted at all times if desired
Miscellaneous Signals
Signal Name
Pin Number
I/O
Signal Description
DA
103
In
Reserved signal. This input must be connected to logic low.
INT
85
Out
Interrupt. INT is an open-drain output, driven low to indicate an interrupt. Once low, INT remains low until the
interrupt status in the appropriate interrupt Status Register is read. Interrupt sources are programmable via
the interrupt Mask Registers.
MM
6
In
Reserved signal. This input must be connected to logic low.
MODE[1:0]
7, 8
In
Mode Selects. They determine the configuration of the PHY/ATM interface. 00 = UTOPIA Level 2. 01 = UTOPIA Level 1. 10 = DPI. 11 is reserved.
OSC
126
In
TTL line rate clock source, driven by a 100 ppm oscillator. 32 MHz or 64 MHz.
RST
87
In
Reset. Active low asynchronous input resets all control logic, counters and FIFOs. A reset must be performed after power up prior to normal operation of the part.
RXLED[3:0]
82, 81, 80, 79
Out
Receive LED drivers. Driven low for 223 cycles of OSC, beginning with RXSOC when that port receives a
good (non-null and non-errored) cell. Drives 8 mA both high and low. One per port.
RXREF
9
Out
Receive Reference. Active low, synchronous to OSC. RXREF pulses low for a programmable number of
clock cycles when an x_8 command byte is received. Register 0x40 is programmed to indicate which port is
referenced. Note that when operating the 77V1264L200 at 2x or 4x multiple of OSC (See Enhanced Control
2 Registers) the RXREF pulse width (See LED Driver and HEC Status/Control Registers) must be programmed to any value greater than the default for proper operation of RXREF.
Table 2 Signal Descriptions (Part 1 of 3)
4 of 49
December 6, 2001
IDT77V1264L200
SE
102
In
Reserved signal. This input must be connected to logic low.
TXLED[3:0]
12, 13, 14, 15
Out
Ports 3 through 0 Transmit LED driver. Goes low for 223 cycles of OSC, beginning with TXSOC when this
port receives a cell for transmission. 8 mA drive current both high and low. One per port.
TXREF
10
In
Transmit Reference. Synchronous to OSC. On the falling edge, an X_8 command byte is inserted into the
transmit data stream. Logic for this signal is programmed in register 0x40. Typical application is WAN timing.
Power Supply Signals
Signal Name
Pin Number
I/O
Signal Description
AGND
112, 117, 118, 123, 124,
____
127, 129, 130, 135, 136, 141
Analog ground. AGND supply a ground reference to the analog portion of the ship, which sources a more
constant current than the digital portion.
AVDD
113, 116, 119, 122, 125,
128, 131, 134, 137, 140
Analog power supply 3.3 ± 0.3V AVDD supply power to the analog portion of the chip, which draws a more
constant current than the digital portion.
GND
2, 11, 44, 50, 56, 67, 77, 83, ____
86, 97, 107, 111, 142
Digital Ground.
VDD
1, 5, 16, 38, 45, 57, 68, 78,
84, 92, 104, 108
Digital power supply. 3.3 ± 0.3V.
____
____
16-BIT UTOPIA 2 Signals (MODE[1:0] = 00)
Signal Name
Pin Number
I/O
Signal Description
RXADDR[4:0]
53, 52, 51, 49, 48
In
Utopia 2 Receive Address Bus. This bus is used in polling and selecting the receive port. The port addresses
are defined in bits [4:0] of the Enhanced Control Registers.
RXCLAV
54
Out
Utopia 2 Receive Cell Available. Indicates the cell available status of the addressed port. It is asserted when
a full cell is available for retrieval from the receive FIFO. When non of the four ports is addressed. RXCLAV is
high impedance.
RXCLK
46
In
Utopia 2 Receive Clock. This is a free running clock input.
RXDATA[15:0] 59, 60, 61, 62, 63, 64, 65,
66, 69, 70, 71, 72, 73, 74,
75, 76
Out
Utopia 2 Receive Data. When one of the four ports is selected, the 77V1264L200 transfers received cells to
an ATM device across this bus. Also see RXPARITY.
RXEN
47
In
Utopia 2 Receive Enable. Driven by an ATM device to indicate its ability to receive data across the RXDATA
bus.
RXPARITY
58
Out
Utopia 2 Receive Data Parity. Odd parity over RXDATA[15:0].
RXSOC
55
Out
Utopia 2 Receive Start of Cell. Asserted coincident with the first word of data for each cell on RXDATA.
TXADDR[4:0]
36, 37, 39, 40, 41
In
Utopia 2 Transmit Address Bus. This bus is used in polling and selecting the transmit port. The port
addresses are defined in bits [4:0] of the Enhanced Control Registers.
TXCLAV
42
Out
Utopia 2 Transmit Cell Available. Indicates the availability of room in the transmit FIFO of the addressed port
for a full cell. When none of the four ports is addressed, TXCLAV is high impedance.
TXCLK
43
In
Utopia Transmit Clock. This is a free running clock input.
TXDATA[15:0] 32, 31, 30, 29, 28, 27, 26,
25, 24, 23, 22, 21, 20, 19,
18, 17
In
Utopia 2 Transmit Data. An ATM device transfers cells across this bus to the 77V1264L200 for transmission.
Also see TXPARITY.
TXEN
34
In
Utopia 2 Transmit Enable. Driven by an ATM device to indicate it is transmitting data across the TXDATA
bus.
TXPARITY
33
In
Utopia 2 Transmit Data Parity. Odd parity across TXDATA[15:0]. Parity is checked and errors are indicated in
the Interrupt Status Registers, as enabled in the Master Control Registers. No other action is taken in the
event of an error. Tie high or low if unused.
TXSOC
35
In
Utopia 2 Transmit Start of Cell. Asserted coincident with the first word of data for each cell on TXDATA.
Table 2 Signal Descriptions (Part 2 of 3)
5 of 49
December 6, 2001
IDT77V1264L200
8-BIT UTOPIA Level 1 Signals (MODE[1:0] = 01)
Signal Name
Pin Number
I/O
Signal Description
RXCLAV[3:0]
64, 65, 66, 54
Out
Utopia 1 Receive Cell Available. Indicates the cell available status of the respective port. It is asserted when
a full cell is available for retrieval from the receive FIFO.
RXCLK
46
In
Utopia 1 Receive Clock. This is a free running clock input.
RXDATA[7:0]
69, 70, 71, 72, 73, 74, 75, 76 Out
Utopia 1 Receive Data. When one of the four ports is selected, the 77V1264L200 transfers received cells to
an ATM device across this bus. Bit 5 in the Diagnostic Control Registers determines whether RXDATA tristates when RXEN[3:0] are high. Also see RXPARITY.
RXEN[3:0]
51, 49, 48, 47
In
Utopia 1 Receive Enable. Driven by an ATM device to indicate its ability to receive data across the RXDATA
bus. One for each port
RXPARITY
58
Out
Utopia 1 Receive Data Parity. Odd parity over RXDATA[7:0].
RXSOC
55
Out
Utopia 1 Receive Start of Cell. Asserted coincident with the first word of data for each cell on RXDATA. Tristatable as determined by bit 5 in the Diagnostic Control Registers.
TXCLAV[3:0]
39, 40, 41, 42
Out
Utopia 1 Transmit cell Available. Indicates the availability of room in the transmit FIFO of the respective port
for a full cell.
TXCLK
43
In
Utopia 1 Transmit Clock. This is a free running clock input.
TXDATA[7:0]
24, 23, 22, 21, 20, 19, 18, 17 In
Utopia 1 Transmit Data. An ATM device transfers cells across the bus to the 77V1264L200 for transmission.
Also see TXPARITY.
TXEN[3:0]
27, 26, 25, 34
In
Utopia 1 Transmit Enable. Driven by an ATM device to indicate it is transmitting data across the TXDATA
bus. One for each port.
TXPARITY
33
In
Utopia 1 Transmit Data Parity. Odd parity across TXDATA[7:0]. Parity is checked and errors are indicated in
the Interrupt Status Registers, as enabled in the Master Control Registers. No other action is taken in the
event of an error. Tie high or low if unused.
TXSOC
35
In
Utopia 1 Transmit Start of Cell. Asserted coincident with the first word of data for each cell on TXDATA.
DPI Mode Signals (MODE[1:0] = 10)
Signal Name
Pin Number
I/O
Signal Description
DPICLK
43
In
DPI Source Clock for Transmit. This is the free-running clock used as the source to generate Pn_TCLK.
Pn_RCLK
52, 51, 49, 48
In
DPI Port ’n’ Receive Clock. Pn_RCLK is cycled to indicate that the interfacing device is ready to receive a
nibble of data on Pn_RD[3:0] of port ’n’.
Pn_RD[3:0]
59, 60, 61, 62, 63, 64, 65,
66, 69, 70, 71, 72, 73, 74,
75, 76
Out
DPI Port ’n’ Receive Data. Cells received on port ’n’ are passed to the interfacing device across this bus.
Each port has its own dedicated bus.
Pn_RFRM
53, 58, 54, 55
Out
DPI Port ’n’ Receive Frame. Pn_RFRM is asserted for one cycle immediately preceding the transfer of each
cell on Pn_RD[3:0].
Pn_TCLK
37, 39, 40, 41
Out
DPI Port ’n’ Transmit Clock. Pn_TCLK is derived from DPICLK and is cycled when the respective port is
ready to accept another 4 bits of data on Pn_TD[3:0].
Pn_TD[3:0]
32, 31, 30, 29, 28, 27, 26,
25, 24, 23, 22, 21, 20, 19,
18, 17
In
DPI Port ’n’ Transmit Data. Cells are passed across this bus to the PHY for transmission on port ’n’. Each
port has its own dedicated bus.
Pn_TFRM
36, 33, 34, 35
In
DPI Port ’n’ Transmit Frame. Start of cell signal which is asserted for one cycle immediately preceding the
first 4 bits of each cell on Pn_TD[3:0].
Table 2 Signal Descriptions (Part 3 of 3)
6 of 49
December 6, 2001
IDT77V1264L200
Signal Assignment as a Function of PHY/ATM Interface Mode
SIGNAL NAME
PIN NUMBER
16-BIT UTOPIA 2
MODE[1,0] = 00
8-BIT UTOPIA 1
MODE[1,0] = 01
DPI
MODE[1,0] = 10
VDD
1
GND
2
TX0-
3
TX0+
4
VDD
5
MM
6
MODE1
7
MODE0
8
RXREF
9
TXREF
10
GND
11
TXLED3
12
TXLED2
13
TXLED1
14
TXLED0
15
VDD
16
TXDATA0
17
TXDATA0
TXDATA0
P0_TD[0]
TXDATA1
18
TXDATA1
TXDATA1
P0_TD[1]
TXDATA2
19
TXDATA2
TXDATA2
P0_TD[2]
TXDATA3
20
TXDATA3
TXDATA3
P0_TD[3]
TXDATA4
21
TXDATA4
TXDATA4
P1_TD[0]
TXDATA5
22
TXDATA5
TXDATA5
P1_TD[1]
TXDATA6
23
TXDATA6
TXDATA6
P1_TD[2]
TXDATA7
24
TXDATA7
TXDATA7
P1_TD[3]
TXDATA8
25
TXDATA8
TXEN[1]
P2_TD[0]
TXDATA9
26
TXDATA9
TXEN[2]
P2_TD[1]
TXDATA10
27
TXDATA10
TXEN[3]
P2_TD[2]
TXDATA11
28
TXDATA11
see note 2
P2_TD[3]
TXDATA12
29
TXDATA12
see note 2
P3_TD[0]
TXDATA13
30
TXDATA13
see note 2
P3_TD[1]
TXDATA14
31
TXDATA14
see note 2
P3_TD[2]
TXDATA15
32
TXDATA15
see note 2
P3_TD[3]
TXPARITY
33
TXPARITY
TXPARITY
P2_TFRM
TXEN
34
TXEN
TXEN[0]
P1_TFRM
TXSOC
35
TXSOC
TXSOC
P0_TFRM
TXADDR4
36
TXADDR4
see note 2
P3_TFRM
Table 3 Signal Assignment as a Function of PHY/ATM Interface Mode (Part 1 of 4)
7 of 49
December 6, 2001
IDT77V1264L200
SIGNAL NAME
PIN NUMBER
TXADDR3
37
VDD
38
TXADDR2
16-BIT UTOPIA 2
MODE[1,0] = 00
8-BIT UTOPIA 1
MODE[1,0] = 01
DPI
MODE[1,0] = 10
TXADDR3
see note 2
P3_TCLK
39
TXADDR2
TXCLAV[3]
P2_TCLK
TXADDR1
40
TXADDR1
TXCLAV[2]
P1_TCLK
TXADDR0
41
TXADDR0
TXCLAV[1]
P0_TCLK
TXCLAV
42
TXCLAV
TXCLAV[0]
see note 1
TXCLK
43
TXCLK
TXCLK
DPICLK
GND
44
VDD
45
RXCLK
46
RXCLK
RXCLK
see note 2
RXEN
47
RXEN
RXEN[0]
see note 2
RXADDR0
48
RXADDR0
RXEN[1]
P0_RCLK
RXADDR1
49
RXADDR1
RXEN[2]
P1_RCLK
GND
50
RXADDR2
51
RXADDR2
RXEN[3]
P2_RCLK
RXADDR3
52
RXADDR3
see note 2
P3_RCLK
RXADDR4
53
RXADDR4
see note 2
P3_RFRM
RXCLAV
54
RXCLAV
RXCLAV[0]
P1_RFRM
RXSOC
55
RXSOC
RXSOC
P0_FRM
GND
56
VDD
57
RXPARITY
58
RXPARITY
RXPARITY
P2_RFRM
RXDATA15
59
RXDATA15
see note 1
P3_RD[3]
RXDATA14
60
RXDATA14
see note 1
P3_RD[2]
RXDATA13
61
RXDATA13
see note 1
P3_RD[1]
RXDATA12
62
RXDATA12
see note 1
P3_RD[0]
RXDATA11
63
RXDATA11
see note 1
P2_RD[3]
RXDATA10
64
RXDATA10
RXCLAV[3]
P2_RD[2]
RXDATA9
65
RXDATA9
RXCLAV[2]
P2_RD[1]
RXDATA8
66
RXDATA8
RXCLAV[1]
P2_RD[0]
GND
67
VDD
68
RXDATA7
69
RXDATA7
RXDATA7
P1_RD[3]
RXDATA6
70
RXDATA6
RXDATA6
P1_RD[2]
RXDATA5
71
RXDATA5
RXDATA5
P1_RD[1]
RXDATA4
72
RXDATA4
RXDATA4
P1_RD[0]
RXDATA3
73
RXDATA3
RXDATA3
P0_RD[3]
Table 3 Signal Assignment as a Function of PHY/ATM Interface Mode (Part 2 of 4)
8 of 49
December 6, 2001
IDT77V1264L200
SIGNAL NAME
PIN NUMBER
16-BIT UTOPIA 2
MODE[1,0] = 00
8-BIT UTOPIA 1
MODE[1,0] = 01
DPI
MODE[1,0] = 10
RXDATA2
74
RXDATA2
RXDATA2
P0_RD[2]
RXDATA1
75
RXDATA1
RXDATA1
P0_RD[1]
RXDATA0
76
RXDATA0
RXDATA0
P0_RD[0]
GND
77
VDD
78
RXLED0
79
RXLED1
80
RXLED2
81
RXLED3
82
GND
83
VDD
84
INT
85
GND
86
RST
87
WR
88
RD
89
CS
90
ALE
91
VDD
92
AD0
93
AD1
94
AD2
95
AD3
96
GND
97
AD4
98
AD5
99
AD6
100
AD7
101
SE
102
DA
103
VDD
104
TX3-
105
TX3+
106
GND
107
VDD
108
TX2-
109
TX2+
110
Table 3 Signal Assignment as a Function of PHY/ATM Interface Mode (Part 3 of 4)
9 of 49
December 6, 2001
IDT77V1264L200
SIGNAL NAME
PIN NUMBER
GND
111
AGND
112
AVDD
113
RX3-
114
RX3+
115
AVDD
116
AGND
117
AGND
118
AVDD
119
RX2-
120
RX2+
121
AVDD
122
AGND
123
AGND
124
AVDD
125
OSC
126
AGND
127
AVDD
128
AGND
129
AGND
130
AVDD
131
RX1-
132
RX1+
133
AVDD
134
AGND
135
AGND
136
AVDD
137
RX0-
138
RX0+
139
AVDD
140
AGND
141
GND
142
TX1-
143
TX1+
144
16-BIT UTOPIA 2
MODE[1,0] = 00
8-BIT UTOPIA 1
MODE[1,0] = 01
DPI
MODE[1,0] = 10
Table 3 Signal Assignment as a Function of PHY/ATM Interface Mode (Part 4 of 4)
Note: 1.This output signal is unused in this mode. It must be left unconnected.
2.This input signal is unused in this mode. It must be connected to either logic high or logic low.
10 of 49
December 6, 2001
IDT77V1264L200
Functional Description
(X _C) is NOT scrambled before it's encoded (see diagram for illustration). The PRNG is based upon the following polynomial:
Transmission Convergence (TC) Sub Layer
X10 + X7 + 1
Introduction
The TC sub layer defines the line coding, scrambling, data framing
and synchronization. Under control of a switch interface or Segmentation and Reassembly (SAR) unit, the 25.6Mbps ATM PHY accepts a 53byte ATM cell, scrambles the data, appends a command byte to the
beginning of the cell, and encodes the entire 53 bytes before transmission. These data transformations ensure that the signal is evenly distributed across the frequency spectrum. In addition, the serialized bit
stream is NRZI coded. An 8kHz timing sync pulse may be used for
isochronous communications.
Data Structure and Framing
Each 53-byte ATM cell is preceded with a command byte. This byte
is distinguished by an escape symbol followed by one of 17 encoded
symbols. Together, this byte forms one of seventeen possible command
bytes. Three command bytes are defined:
1. X_X (read: 'escape' symbol followed by another 'escape'): Startof-cell with scrambler/descrambler reset.
2. X_4 ('escape' followed by '4'): Start-of-cell without scrambler/
descrambler reset.
3. X_8 ('escape' followed by '8'): 8kHz timing marker. This
command byte is generated when the 8kHz sync pulse is
detected, and has priority over all line activity (data or command
bytes). It is transmitted immediately when the sync pulse is
detected. When this occurs during a cell transmission, the data
transfer is temporarily interrupted on an octet boundary, and the
X_8 command byte is inserted. This condition is the only allowed
interrupt in an otherwise contiguous transfer.
Below is an illustration of the cell structure and command byte usage:
{X_X} {53-byte ATM cell} {X_4} {53-byte ATM {X_8} cell}...
In the above example, the first ATM cell is preceded by the X_X startof-cell command byte which resets both the transmitter-scrambler and
receiver-descrambler pseudo-random nibble generators (PRNG) to their
initial states. The following cell illustrates the insertion of a start-of-cell
command without scrambler/descrambler reset. During this cell's transmission, an 8kHz timing sync pulse triggers insertion of the X_8 8kHz
timing marker command byte.
With this polynomial, the four output data bits (D3, D2, D1, D0) will be
generated from the following equations:
D3 = d3 xor X(t-3)
D2 = d2 xor X(t-2)
D1 = d1 xor X(t-1)
D0 = d0 xor X(t)
The following nibble is scrambled with X(t+4), X(t+3), X(t+2), and
X(t+1).
A scrambler lock between the transmitter and receiver occurs each
time an X_X command is sent. An X_X command is initiated only at the
beginning of a cell transfer after the PRNG has cycled through all of its
states (210 - 1 = 1023 states). The first valid ATM data cell transmitted
after power on will also be accompanied with an X_X command byte.
Each time an X_X command byte is sent, the first nibble after the last
escape (X) nibble is XOR'd with 1111b (PRNG = 3FFx).
Because a timing marker command (X_8) may occur at any time, the
possibility of a reset PRNG start-of-cell command and a timing marker
command occurring consecutively does exist (e.g. X_X_X_8). In this
case, the detection of the last two consecutive escape (X) nibbles will
cause the PRNG to reset to its initial 3FFx state. Therefore, the PRNG is
clocked only after the first nibble of the second consecutive escape pair.
Once the data nibbles have been scrambled using the PRNG, the
nibbles are further encoded using a 4b/5b process. The 4b/5b scheme
ensures that an appropriate number of signal transitions occur on the
line. A total of seventeen 5-bit symbols are used to represent the sixteen
4-bit data nibbles and the one escape (X) nibble. The table below lists
the 4-bit data with their corresponding 5-bit symbols:
Transmission Description
Refer to Figure 4. Cell transmission begins with the PHY-ATM Interface. An ATM layer device transfers a cell into the 77V1264L200 across
the Utopia transmit bus or DPI transmit bus. This cell enters a 3-cell
deep transmit FIFO. Once a complete cell is in the FIFO, transmission
begins by passing the cell, four bits (MSB first) at a time to the 'Scrambler'.
The 'Scrambler' takes each nibble of data and exclusive-ORs them
against the 4 high order bits (X(t), X(t-1), X(t-2), X(t-3)) of a 10 bit
pseudo-random nibble generator (PRNG). Its function is to provide the
appropriate frequency distribution for the signal across the line.
The PRNG is clocked every time a nibble is processed, regardless of
whether the processed nibble is part of a data or command byte. Note
however that only data nibbles are scrambled. The entire command byte
'DWD
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'DWD
6\PERO
'DWD
6\PERO
'DWD
6\PERO
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.
.
This encode/decode implementation has several very desirable properties. Among them is the fact that the output data bits can be represented by a set of relatively simple symbols;
‹
Run length is limited to <= 5;
‹ Disparity never exceeds +/- 1.
On the receiver, the decoder determines from the received symbols
whether a timing marker command (X_8) or a start-of-cell command was
sent (X_X or X_4). If a start-of-cell command is detected, the next 53
bytes received are decoded and forwarded to the descrambler. (See TC
Receive Block Diagram, Figure 5).
11 of 49
December 6, 2001
IDT77V1264L200
The output of the 4b/5b encoder provides serial data to the NRZI
encoder. The NRZI code transitions the wire voltage each time a '1' bit is
sent. This, together with the previous encoding schemes guarantees
that long run lengths of either '0' or '1's are prevented. Each symbol is
shifted out with its most significant bit sent first.
The IDT77V1264L200 monitors line conditions and can provide an
interrupt if the line is deemed 'bad'. The Interrupt Status Registers
(registers 0x01, 0x11, 0x21 and 0x31) contain a Good Signal Bit (bit 6,
set to 0 = Bad signal initially) which shows the status of the line per the
following algorithm:
When no cells are available to transmit, the 77V1264L200 keeps the
line active by continuing to transmit valid symbols. But it does not
transmit another start-of-cell command until it has another cell for transmission. The 77V1264L200 never generates idle cells.
To declare 'Good Signal' (from "Bad" to "Good")
There is an up-down counter that counts from 7 to 0 and is initially
set to 7. When the clock ticks for 1,024 cycles (32MHz clock, 1,024
cycles = 204.8 symbols) and no "bad symbol" has been received, the
counter decreases by one. However, if at least one "bad symbol" is
detected during these 1,024 clocks, the counter is increased by one, to
a maximum of 7. The Good Signal Bit is set to 1 when this counter
reaches 0. The Good Signal Bit could be set to 1 as quickly as 1,433
symbols (204.8 x 7) if no bad symbols have been received.
Transmit HEC Byte Calculation/Insertion
Byte #5 of each ATM cell, the HEC (Header Error Control) is calculated automatically across the first 4 bytes of the cell header, depending
upon the setting of bit 5 of registers 0x03, 0x13, 0x23 and 0x33. This
byte is then either inserted as a replacement of the fifth byte transferred
to the PHY by the external system, or the cell is transmitted as received.
A third operating mode provides for insertion of "Bad" HEC codes which
may aid in communication diagnostics. These modes are controlled by
the LED Driver and HEC Status/Control Registers.
Receiver Description
The receiver side of the TC sublayer operates like the transmitter, but
in reverse. The data is NRZI decoded before each symbol is reassembled. The symbols are then sent to the 5b/4b decoder, followed by the
Command Byte Interpreter, De-Scrambler, and finally through a FIFO to
the UTOPIA or DPI interface to an ATM Layer device.
8kHz Timing Marker
The 8kHz timing marker, described earlier, is a completely optional
feature which is essential for some applications requiring synchronization for voice or video, and unnecessary for other applications. Figure 7
shows the options available for generating and receiving the 8kHz
timing marker.
ATM Cell Format
%LW %LW +HDGHU %\WH +HDGHU %\WH +HDGHU %\WH The source of the marker is programmable in the RXREF and
TXREF Control Register (0x40). Each port is individually programmable
to either a local source or a looped remote source. The local source is
TXREF, which is an 8kHz clock of virtually any duty cycle. When
unused, TXREF should be tied high. Also note that it is not limited to
8kHz, should a different frequency be desired. When looped, a received
X_8 command byte causes one to be generated on the transmit side.
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To declare 'Bad Signal' (from "Good" to "Bad")
The same up-down counter counts from 0 to 7 (being at 0 to provide
a "Good" status). When the clock ticks for 1,024 cycles (32MHz clock,
1,024 cycles = 204.8 symbols) and there is at least one "bad symbol",
the counter increases by one. If it detects all "good symbols" and no
"bad symbols" in the next time period, the counter decreases by one.
The "Bad Signal" is declared when the counter reaches 7. The Good
Signal Bit could be set to 0 as quickly as 1,433 symbols (204.8 x 7) if at
least one "bad symbol" is detected in each of seven consecutive groups
of 204.8 symbols.
.
Note that although the IDT77V1264L200 can detect symbol and
HEC errors, it does not attempt to correct them.
Upon reset or the re-connect, each port's receiver is typically not
symbol-synchronized. When not symbol-synchronized, the receiver will
indicate a significant number of bad symbols, and will deassert the Good
Signal Bit as described below. Synchronization is established immediately once that port receives an Escape symbol, usually as part of the
start-of-cell command byte preceding the first received cell.
A received X_8 command byte causes the 77V1264L200 to issue a
negative pulse on RXREF. The source channel of the marker is
programmable. When the clock multiplier in the Enhanced Control 2
register(s) is set to 2x or 4x, it is also necessary to set the RXREF Pulse
Width Select in the LED Driver and HEC Status/Control register(s) to
any value greater than the default for proper operation of RXREF.
12 of 49
December 6, 2001
IDT77V1264L200
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13 of 49
December 6, 2001
IDT77V1264L200
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14 of 49
December 6, 2001
IDT77V1264L200
PHY-ATM Interface
The 77V1264L200 PHY offers three choices in interfacing to ATM
layer devices such as segmentation and reassembly (SAR) and
switching chips. MODE[1:0] are used to select the configuration of this
interface, as shown in the table below.
UTOPIA is a Physical Layer to ATM Layer interface standardized by
the ATM Forum. It has separate transmit and receive channels and
specific handshaking protocols. UTOPIA Level 2 has dedicated address
signals for both the transmit and receive directions that allow the ATM
layer device to specify with which of the four PHY channels it is communicating. UTOPIA Level 1 does not have address signals.
Instead, key handshaking signals are duplicated so that each
channel has its own signals. In both versions of UTOPIA, all channels
share a single transmit data bus and a single receive data bus for data
transfer.
DPI is a low-pin count Physical Layer to ATM Layer interface. The
low-pin count characteristic allows the 77V1264L200 to incorporate four
separate DPI 4-bit ports, one for each of the four serial ports. As with the
UTOPIA interfaces, the transmit and receive directions have their own
data paths and handshaking.
UTOPIA Level 2 Interface Option
The 16-bit Utopia Level 2 interface operates as defined in ATM
Forum document af-phy-0039. This PHY-ATM interface is selected by
setting the MODE[1:0] pins both low.
This mode is configured as a single 16-bit data bus in the transmit
(ATM-to-PHY) direction, and a single 16-bit data bus in the receive
(PHY-to-ATM) direction. In addition to the data bus, each direction also
includes a single optional parity bit, an address bus, and several handshaking signals. The UTOPIA address of each channel is determined by
bits 4 to 0 in the Enhanced Control Registers. Please note that the
transmit bus and the receive bus operate completely independently. The
Utopia 2 signals are summarized below:
TXDATA[15:0]
ATM to PHY
TXPARITY
ATM to PHY
TXSOC
ATM to PHY
TXADDR[4:0]
ATM to PHY
TXEN
ATM to PHY
TXCLAV
PHY to ATM
TXCLK
ATM to PHY
RXDATA[15:0]
PHY to ATM
RXPARITY
PHY to ATM
RXSOC
PHY to ATM
RXADDR[4:0]
ATM to PHY
RXEN
ATM to PHY
RXCLAV
PHY to ATM
RXCLK
ATM to PHY
To determine if any of them has room to accept a cell for transmission (TXCLAV), or has a receive cell available to pass on to the ATM
device (RXCLAV). To poll, the ATM device drives an address (TXADDR
or RXADDR) then observes TXCLAV or RXCLAV on the next cycle of
TXCLK or RXCLK. A port must tri-state TXCLAV and RXCLAV except
when it is addressed.
If TXCLAV or RXCLAV is asserted, the ATM device may select that
port, then transfer a cell to or from it. Selection of a port is performed by
driving the address of the desired port while TXEN or RXEN is high, then
driving TXEN or RXEN low. When TXEN is driven low, TXSOC (start of
cell) is driven high to indicate that the first 16 bits of the cell are being
driven on TXDATA. The ATM device may chose to temporarily suspend
transfer of the cell by deasserting TXEN. Otherwise, TXEN remains
asserted as the next 16 bits are driven onto TXDATA with each cycle of
TXCLK.
In the receive direction, the ATM device selects a port if it wished to
receive the cell that the port is holding. It does this by asserting RXEN.
The PHY then transfers the data 16 bits each clock cycle, as determined by RXEN. As in the transmit direction, the ATM device may
suspend transfer by deasserting RXEN at any time. Note that the PHY
asserts RXSOC coincident with the first 16 bits of each cell.
TXPARITY and RXPARITY are parity bits for the corresponding 16bit data fields. Odd parity is used.
Figures 9 through 14 may be referenced for Utopia 2 bus examples.
Because this interface transfers an even number of bytes, rather
than the ATM standard of 53 bytes, a filler byte is inserted between the
5-byte header and the 48-byte payload. This is shown in Figure 8.
15 of 49
December 6, 2001
IDT77V1264L200
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UTOPIA Level 1 Multi-phy Interface Option
The UTOPIA Level 1 MULTI-PHY interface is based on ATM Forum document af-phy-0017. Utopia Level 1 is essentially the same as Utopia Level
2, but without the addressing, polling and selection features.
%LW )LUVW
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Instead of addressing, this mode utilizes separate TXCLAV, TXEN, RXCLAV and RXEN signals for each channel of the 77V1264L200. There are
just one each of the TXSOC and RXSOC signals, which are shared across all four channels.
In addition to Utopia Level 2's cell mode transfer protocol, Utopia Level 1 also offers the option of a byte mode protocol. Bit 1 of the Master Control
Registers is used to program whether the UTOPIA Level 1 bus is in cell mode or byte mode. In byte mode, the PHY is allowed to control data transfer
on a byte-by-byte basis via the TXCLAV and RXCLAV signals. In cell mode, TXCLAV and RXCLAV are ignored once the transfer of a cell has begun.
In every other way the two modes are identical. Cell mode is the default configuration and is the one described later.
16 of 49
December 6, 2001
IDT77V1264L200
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The Utopia 1 signals are summarized below:
TXDATA[7:0]
ATM to PHY
TXPARITY
ATM to PHY
TXSOC
ATM to PHY
TXEN[3:0]
ATM to PHY
TXCLAV[3:0]
PHY to ATM
TXCLK
ATM to PHY
RXDATA[7:0]
PHY to ATM
RXPARITY
PHY to ATM
RXSOC
PHY to ATM
RXEN[3:0]
ATM to PHY
RXCLAV[3:0]
PHY to ATM
RXCLK
ATM to PHY
17 of 49
December 6, 2001
IDT77V1264L200
Transmit and receive both utilize free running clocks, which are inputs to the 77V1264L200. All Utopia signals are timed to these clocks.
In the transmit direction, the PHY first asserts TXCLAV (transmit cell available) to indicate that it has room in its transmit FIFO to accept at least
one 53-byte ATM cell. When the ATM layer device is ready to begin passing the cell, it asserts TXEN (transmit enable) and TXSOC (start of cell), coincident with the first byte of the cell on TXDATA. TXEN remains asserted for the duration of the cell transfer, but the ATM device may deassert TXEN at
any time once the cell transfer has begun, but data is transferred only when TXEN is asserted.
In the receive direction, RXEN indicates when the ATM device is prepared to receive data. As with transmit, it may be asserted or deasserted at
any time. Note, however, that not more than one RXEN should be asserted at a time. Also, once a given RX port is selected, that port's FIFO must be
emptied of cells (as indicated by RXCLAV) before a different RX port may be enabled.
In both transmit and receive, TXSOC and RXSOC (start of cell) is asserted for one clock, coincident with the first byte of each cell. Odd parity is
utilized across each 8-bit data field.
Figure 8 shows the data sequence for an ATM cell over Utopia Level 1, and Figures 15 through 21 are examples of the Utopia Level 1 handshake.
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23 of 49
December 6, 2001
IDT77V1264L200
DPI Interface Option
The DPI interface is relatively new and worth additional description.
The biggest difference between the DPI configurations and the UTOPIA
configurations is that each channel has its own DPI interface. Each
interface has a 4-bit data path, a clock and a start-of-cell signal, for both
the transmit direction and the receive direction. Therefore, each signal is
point-to-point, and none of these signals has high-Z capability. Additionally, there is one master DPI clock input (DPICLK) into the 77V1254L25
which is used as a source for the DPI transmit clock outputs. DPI is a
cell-based transfer scheme like Utopia Level 2, whereas UTOPIA Level
1 transfers can be either byte- or cell-based.
Another unique aspect of DPI is that it is a symmetrical interface. It is
as easy to connect two PHYs back-to-back as it is to connect a PHY to a
switch fabric chip. In contrast, Utopia is asymmetrical. Note that for the
77V1254L25 the nomenclature "transmit" and "receive" is used in the
naming of the DPI signals, whereas other devices may use more
generic "in" and "out" nomenclature for their DPI signals.
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The DPI signals are summarized below, where "Pn_" refers to the
signals for channel number "n":
DPICLK
input to PHY
Pn_TCLK
PHY to ATM
Pn_TD[3:0]
ATM to PHY
Pn_TFRM
ATM to PHY
Pn_RCLK
ATM to PHY
Pn_RD[3:0]
PHY to ATM
Pn_RFRM
PHY to ATM
In the transmit direction (ATM to PHY), the ATM layer device asserts
start-of-cell signal (Pn_TFRM) for one clock cycle, one clock prior to
driving the first nibble of the cell on Pn_TD[3:0]. Once the ATM side has
begun sending a cell, it is prepared to send the entire cell without interruption. The 77V1254L25 drives the transmit DPI clocks (Pn_TCLK)
back to the ATM device, and can modulate (gap) it to control the flow of
data. Specifically, if it cannot accept another nibble, the 77V1254L25
disables Pn_TCLK and does not generate another rising edge until it
has room for the nibble. Pn_TCLK are derived from the DPICLK free
running clock source.
The DPI protocol is exactly symmetrical in the receive direction, with
the 77V1254L25 driving the data and start-of-cell signals while receiving
Pn_RCLK as an input.
The DPI data interface is four bits, so the 53 bytes of an ATM cell are
transferred in 106 cycles. Figure 22 shows the sequence of that data
transfer. igures 23 through 31 show how the handshake operates.
24 of 49
December 6, 2001
IDT77V1264L200
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Figure 30 DPI Transmit Handshake - Neither Device Ready
26 of 49
December 6, 2001
IDT77V1264L200
Control and Status Interface
Utility Bus
The Utility Bus is a byte-wide interface that provides access to the
registers within the IDT77V1264L200. These registers are used to select
desired operating characteristics and functions, and to communicate
status to external systems.
The Utility Bus is implemented using a multiplexed address and data
bus (AD[7:0]) where the register address is latched via the Address
Latch Enable (ALE) signal.
The Utility Bus interface is comprised of the following pins:
AD[7:0], ALE, CS, RD, WR
Read Operation
Refer to the Utility Bus timing waveforms in Figures 43 - 44. A
register read is performed as follows:
1. Initial condition:
– RD, WR, CS not asserted (logic 1)
– ALE not asserted (logic 0)
2. Set up register address:
– place desired register address on AD[7:0]
– set ALE to logic 1;
– latch this address by setting ALE to logic 0.
3. Read register data:
– Remove register address data from AD[7:0]
– assert CS by setting to logic 0;
– assert RD by setting to logic 0
– wait minimum pulse width time (see AC specifications)
Write Operation
A register write is performed as described below:
1. Initial condition:
– RD, WR, CS not asserted (logic 1)
– ALE not asserted (logic 0)
2. Set up register address:
– place desired register address on AD[7:0]
– set ALE to logic 1;
– latch this address by setting ALE to logic 0.
3. Write data:
– place data on AD[7:0]
– assert CS by setting to logic 0;
– assert WR (logic 0) for minimum time (according to timing
specification); reset WR to logic 1 to complete register write
cycle.
signal control is provided by bit 5 of the Master Control Registers. When
this bit is set (=1), receive cell errors will be flagged via interrupt signalling and all other interrupt conditions are masked. These errors include:
‹
Bad receive HEC
‹ Short (fewer than 53 bytes) cells
‹
Received cell symbol error
Normal interrupt operations are performed by setting bit 0 and
clearing bit 5 in the Master Control Registers. INT (pin 85) will go to a
low state when an interrupt condition is detected. The external system
should then interrogate the 77V1264L200 to determine which one (or
more) conditions caused this flag, and reset the interrupt for further
occurrences. This is accomplished by reading the Interrupt Status
Registers. Decoding the bits in these bytes will tell which error condition
caused the interrupt. Reading these registers also:
‹ clears the (sticky) interrupt status bits in the registers that are read
‹ resets INT
This leaves the interrupt system ready to signal an alarm for further
problems.
LED Control and Signalling
The LED outputs provide bi-directional LED drive capability of 8 mA.
As an example, the RXLED outputs are described in the truth table:
State
Pin Voltage
Cells being received
Low
Cells not being received High
As illustrated in the following drawing, this could be connected to
provide for a two-LED condition indicator. These could also be different
colors to provide simple status indication at a glance. (The minimum
value for R should be 330Ω).
LED Indicator
9
5
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Interrupt Operations
The IDT77V1264L200 provides a variety of selectable interrupt and
signalling conditions which are useful both during ‘normal’ operation,
and as diagnostic aids. Refer to the Status and Control Register List
section.
Overall interrupt control is provided via bit 0 of the Master Control
Registers. When this bit is cleared (set to 0), interrupt signalling is
prevented on the respective port. The Interrupt Mask Registers allow
individual masking of different interrupt sources. Additional interrupt
27 of 49
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State
Cells being transmitted
Pin Voltage
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Cells not being transmitted High
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Figure 31 DPI Transmit Handshake - Neither Device Ready
Diagnostic Functions
Loopback
There are two loopback modes supported by the 77V1264L200. The loopback mode is controlled via bits 1 and 0 of the Diagnostic Control Registers:
Bit 1
Bit 0
Mode
0
0
Normal operating mode
1
0
PHY Loopback
1
1
Line Loopback
Normal Mode
This mode, Figure 32, supports normal operating conditions: data to be transmitted is transferred to the TC, where it is queued and formatted for
transmission by the PMD. Receive data from the PMD is decoded along with its clock for transfer to the receiving "upstream system".
PHY Loopback
As Figure 33 illustrates below, this loopback mode provides a connection within the PHY from the transmit PHY-ATM interface to the PHY-ATM
receive interface. Note that while this mode is operating, no data is forwarded to or received from the line interface. When Bits [1:0] in the Diagnostic
Control Registers are set to 10, the PHY loopback mode works only if clock multiplier is 1x. For higher multiplies, these bits must be set to 01.
Line Loopback
Figure 34 might also be called “remote loopback” since it provides for a means to test the overall system, including the line. Since this mode will
probably be entered under direction from another system (at a remote location), receive data is also decoded and transferred to the upstream system
to allow it to listen for commands. A common example would be a command asking the upstream system to direct the TC to leave this loopback state,
and resume normal operations.
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29 of 49
December 6, 2001
IDT77V1264L200
Counters
Several condition counters are provided to assist external systems
(e.g. software drivers) in evaluating communications conditions. It is
anticipated that these counters will be polled from time to time (user
selectable) to evaluate performance. A separate set of registers exists
for each channel of the PHY.
‹
Symbol Error Counters
– 8 bits
– counts all invalid 5-bit symbols received
‹
Transmit Cell Counters
– 16 bits
– counts all transmitted cells
‹
Receive Cell Counters
– 16 bits
– counts all received cells, excluding idle cells and HEC errored
cells
‹ Receive HEC Error Counters
– 5 bits
– counts all HEC errors received
Jitter in Loop Timing Mode
One of the primary concerns when using loop timing mode is the
amount of jitter that gets added each time data is transmitted. Table 4
shows the jitter measured at various data rates. The set-up shown in
Figure 35 was used to perform these tests. The maximum jitter seen
was at TX point 5 and the minimum jitter was at point 2. The loop timing
jitter is defined as the amount of jitter generated by each TX node. In
other words, the loop timing jitter or the jitter added by a loop-timed port
in the set-up below is the difference between the Total Output Jitter and
the Total Input Jitter.
The TXCell and RXCell counters are sized (16 bits) to provide a full
cell count (without roll over) if the counter is read once/second. The
Symbol Error counter and HEC Error counter were given sufficient size
to indicate exact counts for low error-rate conditions. If these counters
overflow, a gross condition is occurring, where additional counter resolution does not provide additional diagnostic benefit.
Reading Counters
1. Decide which counter value is desired. Write to the Counter
Select Register(s) (0x06, 0x16, 0x26 and 0x36) to the bit location
corresponding to the desired counter. This loads the High and
Low Byte Counter Registers with the selected counter’s value,
and resets this counter to zero.
Note: Only one counter may be enabled at any time in each
of the Counter Select Registers.
2. Read the Counter Registers (0x04, 0x14, 0x24 or 0x34 (low
byte)) and (0x05, 0x15, 0x25 or 0x35 (high byte)) to get the value.
Further reads may be accomplished in the same manner by writing
to the Counter Select Registers.
Note: The PHY takes some time to set up the low and high
byte counters after a specific counter has been selected in the
Counter Selector register. This time delay (in µS) varies with
the line rate and can be calculated as follows:
Time delay (µS) =
12.5___
line rate (Mbps)
Loop Timing Feature
The 77V1264L200 also offers a loop timing feature for specific applications where data needs to be repeated / transmitted using the recovered clock. If the loop timing mode is enabled in the Enhanced Control
Register 1 bit 6, the recovered receive clock is used as to clock out data
on transmit side. This mode is port specific, i.e., the user can select one
or more ports to be in loop timing mode. In normal mode, the transmitter
transmits data using the multiplied oscillator clock.
30 of 49
December 6, 2001
IDT77V1264L200
OSC
1
2
RX
TX
P0
TX
RX
Data
CLK
Data
P1
Loop Timing Mode
Normal Mode
3
RX
Data
CLK
TX
Data
P2
Loop Timing Mode
4
RX
Data
CLK
TX
Data
P3
Loop Timing Mode
5
SWITCH
Figure 35 Test Setup for Loop Timing Jitter Measurements
Loop Timing Jitter Specification
Line Rate
Mbps
Data Rate
Mbps
Min.
Typ.
Max.
32
25.6
--
100 ps
--
Using 32Mhz OSC, multiplier at 1x
64
51.2
--
100 ps
--
Using 64Mhz OSC, multiplier at 1x
128
102.4
--
80 ps
--
Using 32Mhz OSC, multiplier at 4x
256
204.8
--
20 ps
--
Using 64Mhz OSC, multiplier at 4x
Note
Table 4 Loop Timing Jitter
The waveforms below show some of the measurements taken with the set-up in Figure 35. Using the formula above, the jitter specification was
derived. For example, at data rate of 25.6Mbps, jitter added going through Line Card 3 is 1.5ns -1.4ns (as shown in the waveforms below).
31 of 49
December 6, 2001
IDT77V1264L200
Jitter at 25.6Mbps at point 5 with respect to point 1
Jitter at 25.6Mbps at point 4 with respect to point 1
Jitter at 51.2Mbps at point 4 with respect to point 1
Jitter at 51.2Mbps at point 5 with respect to point 1
32 of 49
December 6, 2001
IDT77V1264L200
Jitter at 102.4Mbps at point 5 with respect to point 1
Jitter at 102.4Mbps at point 4 with respect to point 1
Jitter at 256Mbps at point 5 with respect to point 1
Jitter at 256Mbps at point 4 with respect to point 1
From the above measurements taken, the amount of jitter being added at each TX point is not significant. These tests were also run at line rates of
256Mbps for extended periods of time (64 hours) and no bit errors were seen.
VPI/VCI Swapping
For compatibility with IDT's SwitchStar products (77V400 and 77V500), the 77V1254L25 has the ability to swap parts of the VPI/VCI address
space in the header of receive cells. This function is controlled by the VPI/VCI Swap bits, which are bit 5 of the Enhanced Control Registers (0x08,
0x18, 0x28 and 0x38). The portions of the VPI/VCI that are swapped are shown below. Bits X(7:0) are swapped with Y(7:0) when the VPI/VCI Swap
bit is set and the chip is in DPI mode.
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IDT77V1264L200
Line Side (Serial) Interface
Each of the four ports has two pins for differential serial transmission, and two pins for differential serial receiving.
PHY to Magnetics Interface
A standard connection to 100Ω and 120Ω unshielded twisted pair cabling is shown in Figure 36. Note that the transmit signal is somewhat attenuated in order to meet the launch amplitude specified by the standards. The external receive circuitry is designed to attenuate low frequencies in order
to compensate for the high frequency attenuation of the cable.
Also, the receive circuitry biases the positive and negative RX inputs to slightly different voltages. This is done so that the receiver does not receive
false signals in the absence of a real signal. This can be important because the 77V1264L200 does not disable error detection or interrupts when an
input signal is not present.
When connecting to UTP at 51.2Mbps and 204.8Mbps, it is necessary to use magnetics with sufficient bandwidth. Refer to Table 6 for the recommended magnetics.
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Component
Value
Tolerance
R1
47Ω
±5%
R2
47Ω
±5%
R3
620Ω
±5%
R4
110Ω
±5%
R5
2700Ω
±5%
R6
2700Ω
±5%
R7
82Ω
±5%
R8
33Ω
±5%
R9
33Ω
±5%
Table 5 Analog Component Values
34 of 49
December 6, 2001
IDT77V1264L200
Component
Value
Tolerance
C1
470pF
±20%
C2
470pF
±20%
L1
3.3µH
±20%
Table 5 Analog Component Values
Magnetics Modules for 25.6 Mbps
Pulse PE-67583 or R4005
www.pulseeng.com
TDK TLA-6M103
www.component.tdk.com
Magnetics Module for 51.2 Mbps
Pulse R4005
www.pulseeng.com
Magnetics Module for 204.8 Mbps
Pulse ST6200T
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Table 6 Magnetics Modules
Status and Control Register List
The 77V1264L200 has 41 registers that are accessible through the utility bus. Each of the four ports has 9 registers dedicated to that port. There is
only one register (0x40) which is not port specific.
For those register bits which control operation of the Utopia interface, the operation of the Utopia interface is determined by the registers corresponding to the port which is selected at that particular time. For consistent operation, the Utopia control bits should be programmed the same for all
four ports, except for the Utopia 2 port addresses in the Enhanced Control Registers.
Register Name
Register Address
Port 0
Port 1
Port 2
Port 3
Master Control Registers
0x00
0x10
0x20
0x30
Interrupt Status Registers
0x01
0x11
0x21
0x31
Diagnostic Control Registers
0x02
0x12
0x22
0x32
LED Driver and HEC Status/control
0x03
0x13
0x23
0x33
Low Byte Counter Register [7:0]
0x04
0x14
0x24
0x34
High Byte Counter Register [15:8]
0x05
0x15
0x25
0x35
Counter Registers Read Select
0x06
0x16
0x26
0x36
Interrupt Mask Registers
0x07
0x17
0x27
0x37
Enhanced Control 1 Registers
0x08
0x18
0x28
0x38
Enhanced Control 2 Registers
0x09
0x19
0x29
0x39
RXREF and TXREF Control Register
Nomenclature
"Reserved" register bits, if written, should always be written "0"
R-only or W-only = register is read-only or write-only
“0” = ‘cleared’ or ‘not set’
All Ports
0x40
R/W = register may be read and written via the utility bus
sticky = register bit is cleared after the register containing it is read; all sticky bits are read-only
“1” = ‘set’
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IDT77V1264L200
Master Control Registers
Addresses: 0x00, 0x10, 0x20, 0x30
Bit
Type
Initial State
Function
7
R/W
0
Reserved
6
R/W
1 = discard errored cells Discard Receive Error Cells - On receipt of any cell with an error (e.g. short cell, invalid command mnemonic, receive
HEC error (if enabled), this cell will be discarded and will not enter the receive FIFO.
5
R/W
0 = all interrupts
Enable Cell Error Interrupts Only - If Bit 0 in this register is set (Interrupts Enabled), setting of this bit enables only
"Received Cell Error" (as defined in bit 6) to trigger interrupt line.
4
R/W
0 = disabled
Transmit Data Parity Check - Directs TC to check parity of TXDATA against parity bit located in TXPARITY.
3
R/W
1 = discard idle cells
Discard Received Idle Cells - Directs TC to discard received idle (VPI/VCI = 0) cells from PMD without signalling
external systems.
2
R/W
0 = not halted
Halt Transmit - Halts transmission of data from TC to PMD and forces the TXD outputs to the "0" state
1
R/W
0 = cell mode
UTOPIA Level 1 mode select: - 0 = cell mode, 1 = byte mode. Not applicable for Utopia 2 or DPI modes.
0
R/W
1 = enable interrupts
Enable Interrupt Pin (Interrupt Mask Bit) - Enables interrupt output pin (pin 85). If cleared, pin is always high and
interrupt is masked. If set, an interrupt will be signaled by setting the interrupt pin to "0". It doesn’t affect the Interrupt
Status Registers.
Interrupt Status Registers
Addresses: 0x01, 0x11, 0x21, 0x31
Bit
Type
7
Initial State
Function
Reserved
6
R
0 = Bad Signal
Good Signal Bit - See definition on page 14.
1 - Good Signal 0 - Bad Signal
5
sticky
0
HEC error cell received - Set when a HEC error is detected on received cell.
4
sticky
0
"Short Cell" Received - Interrupt signal which flags received cells with fewer than 53 bytes. This condition is detected
when receiving Start-of-Cell command bytes with fewer than 53 bytes between them.
3
sticky
0
Transmit Parity Error - If Bit 4 of Register 0x00 / 0x10 / 0x20 / 0x30 is set (Transmit Data Parity Check), this interrupt
flags a transmit data parity error condition. Odd parity is used.
2
sticky
0
Receive Signal Condition change - This interrupt is set when the received ’signal’ changes either from ’bad to good’
or from ’good to bad’.
1
sticky
0
Received Symbol Error - Set when an undefined 5-bit symbol is received.
0
sticky
0
Receive FIFO Overflow - Interrupt which indicates when the receive FIFO has filled and cannot accept additional data.
Diagnostic Control Registers
Addresses: 0x02, 0x12, 0x22, 0x32
Bit
7
Type
R/W
Initial State
0 = normal
Function
Force TXCLAV deassert - (applicable only in Utopia 1 and 2 modes) Used during line loopback mode to prevent
upstream system from continuing to send data to the 77V1264L200. Not applicable in DPI mode.
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IDT77V1264L200
Addresses: 0x02, 0x12, 0x22, 0x32
Bit
Type
Initial State
Function
6
R/W
0 = UTOPIA
RXCLAV Operation Select - (for Utopia 1 mode) The UTOPIA standard dictates that during cell mode operation, if the
receive FIFO no longer has a complete cell available for transfer from PHY, RXCLAV is deasserted following transfer of
the last byte out of the PHY to the upstream system. With this bit set, early deassertion of this signal will occur coincident with the end of Payload byte 44 (as in octet mode for TXCLAV). This provides early indication to the upstream
system of this impending condition.
0 = "Standard UTOPIA RXCLAV’
1 = "Cell mode = Byte mode"
5
R/W
1 = tri-state
Single/Multi-PHY configuration select - (applicable and writable only in Utopia 1 mode)
0 = single:
Never tri-state RXDATA, RXPARITY and RXSOC
1 = Multi-PHY mode: Tri-state RXDATA, RXPARITY and RXSOC when RXEN = 1
4
R/W
0 = normal
RFLUSH = Clear Receive FIFO - This signal is used to tell the TC to flush (clear) all data in the receive FIFO. The TC
signals this completion by clearing this bit.
3
R/W
0 = normal
Insert Transmit Payload Error - Tells TC to insert cell payload errors in transmitted cells. This can be used to test
error detection and recovery systems at destination station, or, under loopback control, at the local receiving station.
This payload error is accomplished by flipping bit 0 of the last cell payload byte.
2
R/W
0 = normal
Insert Transmit HEC Error - Tells TC to insert HEC error in Byte 5 of cell. This can be used to test error detection and
recovery systems in downstream switches, or, under loopback control, the local receiving station. The HEC error is
accomplished by flipping bit 0 of the HEC byte.
1,0
R/W
00 = normal
Loopback Control
bit # 1
0
0
0 Normal mode (receive from network)
1
0 PHY Loopback (with clock recovery)1
1
1 Line Loopback
0
1 PHY Loopback (with clock recovery)1
1. When Bits [1:0] in the Diagnostic Control Registers are set to 10, the PHY loopback mode works only if clock multiplier is 1x. For higher multiplies, these bits must be set to 01.
LED Driver and HEC Status/Control Registers
Addresses: 0x03, 0x13, 0x23, 0x33
Bit
Type
7
Initial State
Function
0
Reserved
6
R/W
0 = enable checking
Disable Receive HEC Checking (HEC Enable) - When not set, the HEC is calculated on first 4 bytes of received cell,
and compared against the 5th byte. When set (= 1), the HEC byte is not checked.
5
R/W
0 = enable calculate &
replace
Disable Transmit HEC Calculate & Replace - When set, the 5th header byte of cells queued for transmit is not
replaced with the HEC calculated across the first four bytes of that cell.
4, 3
R/W
00 = 1 cycle
RXREF Pulse Width Select - See notes about 8KHz Timing Marker in the Functional Description Section.
bit # 4
3 .
0
0 RXREF active for 1 OSC cycle
0
1 RXREF active for 2 OSC cycles
1
0 RXREF active for 4 OSC cycles
1
1 RXREF active for 8 OSC cycles
2
R
1 = empty
FIFO Status
1 = TxFIFO empty
0 = TxFIFO not empty
1
R
1
TXLED Status
0 = Cell Transmitted
1 = Cell Not Transmitted
0
R
1
RXLED Status
0 = Cell Received
1 = Cell Not Received
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IDT77V1264L200
Low Byte Counter Registers [7:0]
Addresses: 0x04, 0x14, 0x24, 0x34
Bit
[7:0]
Type
R
Initial State
0x00
Function
Provides low byte of counter value selected via registers 0x06, 0x16, 0x26, and 0x36
High Byte Counter Registers [15:8]
Addresses: 0x05, 0x15, 0x25, 0x35
Bit
[7:0]
Type
R
Initial State
0x00
Function
Provides high-byte of counter value selected via registers 0x06, 0x16, 0x26, and 0x36
Counter Select Registers
Addresses: 0x06, 0x16, 0x26, 0x36
Bit
Type
Initial State
Function
7
—
—
Reserved.
6
—
—
Reserved.
5
—
—
Reserved.
4
—
—
Reserved.
3
W
0
Symbol Error Counter.
2
W
0
TXCell Counter.
1
W
0
RXCell Counter. Cells with HEC errors are never counted.
0
W
0
Receive HEC Error Counter.
Note: For proper operation, only one bit may be set in a Counter Select Register at any time.
Interrupt Mask Registers
Addresses: 0x07, 0x17, 0x27, 0x37
Bit
Type
Initial State
Function
7
0
Reserved.
6
0
Reserved.
5
R/W
0 = interrupt enabled
HEC Error Cell.
4
R/W
0 = interrupt enabled
Short Cell Error.
3
R/W
0 = interrupt enabled
Transmit Parity Error.
2
R/W
0 = interrupt enabled
Receive Signal Condition Change.
1
R/W
0 = interrupt enabled
Receive Cell Symbol Error.
0
R/W
0 = interrupt enabled
Receive FIFO Overflow.
Note: When set to "1", these bits mask the corresponding interrupts going to the interrupt pin (INT). When set to "0", the interrupts are
unmasked. These interrupts correspond to the interrupt status bits in the Interrupt Status Registers.
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IDT77V1264L200
Enhanced Control 1 Registers
Addresses: 0x08, 0x18, 0x28, 0x38
Bit
Type
Initial State
Function
7
W
0 = not reset
Individual Port Software Reset 1= Reset. This bit is self-cleaning; It isn’t necessary to write “0” to exit reset.
6
R/W
0 = OSC
Transmit Line Clock (or Loop Timing Mode). When set to 0, the OSC input is used as the transmit line clock.
When set to 1, the recovered receive clock is used as the transmit line clock.
5
R/W
0 = no swap
VPI/VCI Swap DPI mode only. Receive direction only. See description earlier.
4-0
R/W
Port 0 (Reg 0x08) 00000
Port 1 (Reg 0x18) 00001
Port 2 (Reg 0x28) 00010
Port 3 (Reg 0x38) 00011
Utopia 2 Port Address When operating in Utopia 2 Mode, these register bits determine the Utopia 2 port address
Enhanced Control 2 Registers
Addresses: 0x09, 0x19, 0x29, 0x39
Bit
Type
Initial State
Function
7-6
R/W
00
Line Rate Control These bits determine the line bit rate relative to the reference clock, as well as the pre-driver
strength for the TXD+/- outputs.
00 Clock multiplier = 1x, pre-driver strength is “standard”
01 Clock multiplier = 2x, pre-driver strength is “standard”
10 Clock multiplier = 4x, pre-driver strength is “strong”
11 Reserved
5
R/W
0
Reserved
4
R/W
0
Reserved
3
R/W
0
Reserved
2
R/W
0
Reserved
1
R/W
0
Reserved
0
R/W
0
Reserved
RXREF and TXREF Control Register
Addresses: 0x40
Bit
7-6
5
Type
R/W
W
4
3-0
Initial State
0 = RXREF0 (Port 0) RXREF Source Select Selects which of the four ports (0-3) is the source of RXREF.
0 = not reset
0
R/W
Function
0000 = not looped
Master Software Reset 1 = Reset. This bit is self-cleaning; it isn’t necessary to write “0” to exit reset.
Reserved
RXREF to TXREF Loop Select When set to 0, TXREF is used to generate X_8 timing marker commands.
When set to 1, TXREF input is ignored, and received X_8 timing commands are looped back and added to the transmit
stream of that same port. It is recommended that the RXREF pulse width be set to 2x, 4x, and 8x or greater when the
clock multiplier is set to 1x, 2x, or 4x respectively and bits 3-0 are set to 1. Refer to Figure 7.
bit 3: port 3
bit 2: port 2
bit 1: port 1
bit 0: port 0
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IDT77V1264L200
Absolute Maximum Ratings
Symbol
Rating
Value
Unit
VTERM
Terminal Voltage with Respect to GND
-0.5 to +5.5
V
TBIAS
Temperature Under Bias
-55 to +125
°C
TSTG
Storage Temperature
-55 to +120
°C
IOUT
DC Output Current
50
mA
Note: 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.
Recommended DC Operating Conditions
Symbol
Parameter
Min.
Typ.
Max.
Unit
VDD
Digital Supply Voltage
3.13
3.3
3.47
V
GND
Digital Ground Voltage
0
0
0
V
VIH
Input High Voltage
2.0
____
5.25
V
VIL
Input Low Voltage
-0.3
____
0.8
V
AVDD
Analog Supply Voltage
3.13
3.3
3.47
V
AGND
Analog Ground Voltage
0
0
0
V
VDIF
VDD - AVDD
-0.5
0
0.5
V
Capacitance (TA = +25°C, F = 1MHz)
Symbol
Parameter
Conditions
Max.
Unit
CIN1
Input Capacitance
VIN = 0V
10
pF
CIO1
I/O Capacitance
VOUT = 0V
10
pF
1.
Characterized values, not tested.
DC Electrical Characteristics (All Pins except TX+/- and RX+/-)
Symbol
Parameter
Test Conditions
Min.
Max.
Unit
ILI
Input Leakage Current
Gnd ≤ VIN ≤ VDD
-5
5
µA
ILO
/O (as input) Leakage Current
Gnd ≤ VIN ≤ VDD
-10
10
µA
VOH11
Output Logic "1" Voltage
IOH = -2mA, VDD = min.
2.4
—
V
2
OH2
V
Output Logic "1" Voltage
IOH = -8mA, VDD = min.
2.4
—
V
VOL3
Output Logic "0" Voltage
IOL = -8mA, VDD = min.
—
0.4
V
4, 5
DD1
Digital Power Supply Current - VDD
OSC = 32 MHz, all outputs unloaded
—
91
mA
OSC = 64 MHz, all outputs unloaded
—
169
mA
OSC = 256 MHz, all outputs unloaded —
197
mA
I
IDD25
Analog Power Supply Current - AVDD OSC = 32 MHz, all outputs unloaded
—
44
mA
OSC = 64 MHz, all outputs unloaded
—
54
mA
OSC = 256 MHz, all outputs unloaded —
61
mA
1. For AD[7:0] pins only.
2. For all output pins except AD[7:0], INT and TX+/-.
3. For all output pins except TX+/-.
4. Add 15mA for each TX+/- pair that is driving a load.
5. Total supply current is the sum of IDD1 and IDD2
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December 6, 2001
IDT77V1264L200
DC Electrical Characteristics (TX+/- Output Pins Only)
Symbol
Parameter
Test Conditions
Min.
Max.
Unit
VOH1
Output Logic High Voltage
IOH = -20mA
VDD - 0.5V
—
V
VOL
Output Logic Low Voltage
IOL = -20mA
—
0.5
V
DC Electrical Characteristics (RXD+/- Input Pins Only)
Symbol
Parameter
Min.
Typ
Max.
Unit
VIR
RXD+/- input voltage range
0
—
VDD
V
VIP
RXD+/- input peak-to-peak differential voltage
0.6
—
2*VDD
V
VICM
RXD+/- input common mode voltage
1.0
VDD/2
VDD-0.5
V
UTOPIA Level 2 Bus Timing Parameters
Symbol
Parameter
Min.
Max.
Unit
t1
TXCLK Frequency
0.2
50
MHz
t2
TXCLK Duty Cycle (% of t1)
40
60
%
t3
TXDATA[15:0], TXPARITY Setup Time to TXCLK
4
—
ns
t4
TXDATA[15:0], TXPARITY Hold Time to TXCLK
1.5
—
ns
t5
TXADDR[4:0], Setup Time to TXCLK
4
—
ns
t6
TXADDR[4:0], Hold Time to TXCLK
1.5
—
ns
t7
TXSOC, TXEN Setup Time to TXCLK
4
—
ns
t8
TXSOC, TXEN Hold Time to TXCLK
1.5
—
ns
t9
TXCLK to TXCLAV High-Z
2
10
ns
t10
TXCLK to TXCLAV Low-Z (min) and Valid (max)
2
10
ns
t12
RXCLK Frequency
0.2
50
MHz
t13
RXCLK Duty Cycle (% of t12)
40
60
%
t14
RXEN Setup Time to RXCLK
4
—
ns
t15
RXCLK Hold Time to RXCLK
1.5
—
ns
t16
RXADDR[4:0] Setup Time to RXCLK
4
—
ns
t17
RXADDR[4:0] Hold Time to RXCLK
1.5
—
ns
t18
RXCLK to RXCLAV High-Z
2
10
ns
t19
RXCLK to RXCLAV Low-Z (min) and Valid (max)
2
10
ns
t20
RXCLK to RXSOC High-Z
2
10
ns
t21
RXCLK to RXSOC Low-Z (min) and Valid (max)
2
10
ns
t22
RXCLK to RXDATA, RXPARITY High-Z
2
10
ns
t23
RXCLK to RXDATA, RXPARITY Low-Z (min) and Valid (max)
2
10
ns
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December 6, 2001
IDT77V1264L200
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W
W
TXEN
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GUZ Figure 37 UTOPIA Level 2 Transmit
W
W
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W
W
W
W
RXEN
5;$''5>@
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GUZ Figure 38 UTOPIA Level 2 Receive
42 of 49
.
December 6, 2001
IDT77V1264L200
UTOPIA Level 1 Bus Timing Parameters
Symbol
Parameter
Min.
Max.
Unit
t31
TXCLK Frequency
0.2
50
MHz
t32
TXCLK Duty Cycle (% of t31)
40
60
%
t33
TXDATA[7:0], TXPARITY Setup Time to TXCLK
4
—
ns
t34
TXDATA[7:0], TXPARITY Hold Time to TXCLK
1.5
—
ns
t35
TXSOC, TXEN[3:0] Setup Time to TXCLK
4
—
ns
t36
TXSOC, TXEN[3:0] Hold Time to TXCLK
1.5
—
ns
t37
TXCLK to TXCLAV[3:0] Invalid (min) and Valid (max)
2
10
ns
t39
RXCLK Frequency
0.2
50
MHz
t40
RXCLK Duty Cycle (% of t39)
40
60
%
t41
RXEN[3:0] Setup Time to RXCLK
4
—
ns
t42
RXEN[3:0] Hold Time to RXCLK
1.5
—
ns
t43
RXCLK to RXCLAV[3:0] Invalid (min) and Valid (max)
2
10
ns
t44
RXCLK to RXSOC High-Z
2
10
ns
t45
RXCLK to RXSOC Low-Z (min) and Valid (max)
2
10
ns
t46
RXCLK to RXDATA, RXPARITY High-Z
2
10
ns
t47
RXCLK to RXDATA, RXPARITY Low-Z (min) and Valid (max)
2
10
ns
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GUZ Figure 39 UTOPIA Level 1 Transmit
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W
W
RXEN[3:0]
W
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43 of 49
December 6, 2001
IDT77V1264L200
DPI Bus Timing Parameters
Symbol
Parameter
Min.
Max.
Unit
t51
DPICLK Frequency
0.2
50
MHz
t52
DPICLK Duty Cycle (% of t51)
40
60
%
t53
DPICLK to Pn_TCLK Propagation Delay
2
14
ns
t54
Pn_TFRM Setup Time to Pn_TCLK
11
—
ns
t55
Pn_TFRM Hold Time to Pn_TCLK
1
—
ns
t56
Pn_TD[3:0] Setup Time to Pn_TCLK
11
—
ns
t57
Pn_TD[3:0] Hold Time to Pn_TCLK
1
—
ns
t61
Pn_RCLK Period
25
—
ns
t62
Pn_RCLK High Time
10
—
ns
t63
Pn_RCLK Low Time
10
—
ns
t64
Pn_RCLK to Pn_TFRM Invalid (min) and Valid (max)
2
12
ns
t65
Pn_RCLK to Pn_RD Invalid (min) and Valid (max)
2
12
ns
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Figure 41 DPI Transmit
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Figure 42 DPI Receive
44 of 49
December 6, 2001
IDT77V1264L200
Utility Bus Read Cycle
Name
Min.
Max.
Unit
Description
Tas
10
—
MHz
Address setup to ALE
Tcsrd
0
—
%
Chip select to read enable
Tah
5
—
ns
Address hold to ALE
Tapw
10
—
ns
ALE min pulse width
Ttria
0
—
ns
Address tri-state to RD assert
Trdpw
20
—
ns
Min. RD pulse width
Tdh
0
—
ns
Data Valid hold time
Tch
0
—
ns
RD deassert to CS deassert
Ttrid
—
10
ns
RD deassert to data tri-state
Trd
—
18
ns
Read Data access
Tar
5
—
ns
ALE low to start of read
Trdd
0
—
ns
Start of read to Data low-Z
Min.
Max.
Utility Bus Write Cycle
Name
$'>@
LQSXW
Unit
Description
Tapw
10
—
ns
ALE min pulse width
Tas
10
—
ns
Address set up to ALE
Tah
5
—
ns
Address hold time to ALE
Tcswr
0
—
ns
CS Assert to WR
Twrpw
20
—
ns
Min. WR pulse width
Tdws
20
—
ns
Write Data set up
Tdwh
10
—
ns
Write Data hold time
Tch
0
—
ns
WR deassert to CS deassert
Taw
20
—
ns
ALE low to end of write
7DV
7DK
$GGUHVV
7DSZ
$/(
7FK
7FVUG
CS
7DU
7UGSZ
7WULG
RD
7GK
7UG
7UGG
'DWD
$'>@
RXWSXW
GUZ Figure 43 Utility Bus Read Cycle
45 of 49
December 6, 2001
IDT77V1264L200
7DV
$'>@
7DK
7GZV
7GZK
'DWD LQSXW
$GGUHVV
7DSZ
$/(
7FK
7DZ
CS
7FVZU
7ZUSZ
WR
GUZ Figure 44 Utility Bus Write Cycle
OSC, RXREF, TXREF and Reset Timing
Symbol
Parameter
Min.
Typ.
Max.
Unit
Tcyc
OSC cycle period
30
15
31.25
15.625
33
16.5
ns
ns
Tch
OSC high tim
40
—
60
%
Tcl
OSC low time
40
—
60
%
OSC cycle to cycle period variation
—
—
1
%
Trrpd
OSC to RXREF Propagation Delay
1
—
30
ns
Ttrh
TXREF High Time
35
—
—
ns
Ttrl
TXREF Low Time
35
—
—
ns
Trspw
Minimum RST Pulse Width
two OSC cycles
—
—
—
Tcc
1
1. The width of the RXREF pulse is programmable in the LED Driver and HEC Status/Control Registers.
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46 of 49
December 6, 2001
IDT77V1264L200
AC Test Conditions
Input Pulse Levels
GND to 3.0V
Input Rise/Fall Times
3ns
Input Timing Reference Levels
1.5V
Output Reference Levels
1.5V
Output Load
See Figure 46
3.3V
1.2KΩ
D.U.T.
30pF*
900Ω
* Includes jig and scope capacitances.
Figure 46 Output Load
A note about Figures 47 and 48: The ATM Forum and ITU-T standards for 25 Mbps ATM define "Network" and "User" interfaces. They are identical
except that transmit and receive are switched between the two. A Network device can be connected directly to a User device with a straight-through
cable. User-to-User or Network-to-Network connections require a cable with 1-to-7 and 2-to-8 crossovers.
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Figure 47 PC Board Layout for ATM Network
Note: 1.No power or ground plane inside this area.
2.Analog power plane inside this area.
3.Digital power plane inside this area.
4.A single ground plane should extend over the area covered by the analog and digital power planes, without breaks.
5.All analog signal traces should avoid 90° corners.
47 of 49
December 6, 2001
IDT77V1264L200
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Note: 1.No power or ground plane inside this area.
2.Analog power plane inside this area.
3.Digital power plane inside this area.
4.A single ground plane should extend over the area covered by the analog and digital power planes, without breaks.
5.All analog signal traces should avoid 90° corners.
Package Dimensions
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IDT77V1264L200
Ordering Information
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GUZ Revision History
September 20, 2001: Initial publication.
December 6, 2001: Added DPI information.
CORPORATE HEADQUARTERS
2975 Stender Way
Santa Clara, CA 95054
for SALES:
800-345-7015 or 408-727-6116
fax: 408-330-1748
www.idt.com
49 of 49
for Tech Support:
email: [email protected]
phone: 408-330-1752
December 6, 2001