VITESSE VSC838

VITESSE
SEMICONDUCTOR CORPORATION
Preliminary Data Sheet
3.2Gb/s
36x37 Crosspoint Switch
VSC838
Features
• 36 Input by 37 Output Crosspoint Switch
• 66MHz Dual Programming Port
• 3.2Gb/s NRZ Data Bandwidth
• Parallel and Serial programming modes
• Non-Blocking Architecture Broadcast and Multicast
Capabilities
• Programmable On-Chip I/O Termination
• LVTTL/2.5V CMOS Control I/O (3.3V tolerant)
• Single 2.5V Supply
• Input Signal Activity Monitoring Function
• 6W Typical—Low Drive Mode
7W Typical—High Drive Mode
• Integrated Signal Equalization (ISE) for Deterministic
Jitter Reduction
• Differential CML Output Drivers
• High Performance 37.5mm, 480 TBGA Package
General Description
The VSC838 is a monolithic 36x36 asynchronous crosspoint switch, designed to carry broadband data
streams. The VSC838 also has an internal 37th output channel which is used in conjunction with the Activity
Monitor to allow in system diagnostics.
A high degree of signal integrity is maintained throughout the chip via fully differential signal paths.
The crosspoint function is based on a multiplexer array architecture. Each data output is driven by a 36:1
multiplexer that can be programmed to one and only one of its 36 inputs. The signal path is unregistered and
fully asynchronous, so there are not any restrictions on the phase, frequency, or signal pattern at each input.
Each high-speed output is a fully differential, switched current driver with switchable on-die terminations
for maximum signal integrity. Data inputs are terminated on-die through 100Ω impedance between true and
complement inputs (see Input Termination section for further details).
A dual mode programming interface is provided that allows programming commands to be sent as serial
data or parallel data. Core programming can be random for each port address, or multiple program assignments
can be queued and issued simultaneously. The programming may be initialized to a “straight-through” configuration (A0 to Y0, A1 to Y1, etc.) using the INIT pin.
Unused channels may be powered down to allow efficient use of the switch in applications that require only
a subset of the channels. Power-down can be accomplished in hardware, via dedicated power pins for pairs of
input and output channels, or in software by programming individual unused outputs with a disable code.
VSC838 Block Diagram
A0
2
2
A35
2
2
Y0
Y35
µP
control
G52351-0, Rev 3.0
02/12/01
© VITESSE SEMICONDUCTOR CORPORATION • 741 Calle Plano • Camarillo, CA 93012
Tel: (800) VITESSE • FAX: (805) 987-5896 • Email: [email protected]
Internet: www.vitesse.com
Page 1
VITESSE
SEMICONDUCTOR CORPORATION
Preliminary Data Sheet
3.2Gb/s
36x37 Crosspoint Switch
VSC838
Functional Block Diagram
A, AN[0:35]
36 x 37 SWITCH CORE
Y, YN[0:35]
INTERNAL
37th OUTPUT
CONFIG
CORE PROGRAM REGISTERS
INIT
PROGRAM MEMORY
ACTCHAN
ACTIVITY
ALE_SCN
LOAD
CS
SERIAL
SDOUT
INCHAN [5:0]
OUTCHAN [5:0]
Page 2
ACTCLK
ACTIVITY
MONITOR
PROGRAM INTERFACE
© VITESSE SEMICONDUCTOR CORPORATION • 741 Calle Plano • Camarillo, CA 93012
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Internet: www.vitesse.com
G52351-0, Rev 3.0
02/12/01
VITESSE
SEMICONDUCTOR CORPORATION
Preliminary Data Sheet
VSC838
3.2Gb/s
36x37 Crosspoint Switch
Functional Description
Input / Output Characteristics
All input data must be differential and should be nominally biased to +2.0V or AC-coupled. Other levels
are allowed as described under the Input Termination section. On-chip terminations are provided, with a nominal impedance of 100Ω differential. All input termination resistors float with an internal bias provided for ACcoupling.
For direct interconnection of multiple VSC838 devices, a CML termination mode is provided by tying the
ITC pin to VCC, which ties the center point of the 100Ω termination to VCC, causing the terminations to act as
loads for an open-drain or open-collector differential output.
Data outputs are provided through differential current switches with on-chip back-termination. The output
circuit is capable of driving external 50Ω far-end termination (recommended). The output back-terminations are
electronically switchable to enable a power savings of 1W (max) by reducing the output driver current.
Programming Interface
Parallel Mode
In parallel mode (SERIAL=0), the binary word on INCHAN[5:0] is the numerical identifier of the input
that will be routed to the specified output. OUTCHAN[5:0] is the numerical identifier of the output being programmed. A rising edge on the LOAD signal will transfer the programming data to the shadow register in the
program memory. Raising CONFIG (asynchronously) will transfer the programming data to the main latches in
the program memory and cause the internal select signals in the core to re-configure the multiplexer. Lowering
CONFIG will latch the main latches. CONFIG may be tied HIGH to enable programming to take effect instantaneously.
This interface may be used with multiplexed address/data buses by using only INCHAN[5:0] without
OUTCHAN[5:0] and dropping ALE when the address of the output to be programmed is present on
INCHAN[5:0]. After the address is latched, the input address may be presented on INCHAN[5:0] and programming proceeds as above.
No read-back capability is provided in parallel mode. Read-back for diagnostic purposes is provided in
serial mode via the scan function.
Serial Mode
In serial mode (SERIAL=1), the INCHAN[0] pin becomes the serial data input SDIN and the INCHAN[1]
pin becomes the serial clock SCLK (rising edge triggered). A serial word of the form [Output][Input] is shifted
into the internal shift register, and the LOAD pin is asserted (HIGH) coincident with the last bit of the data word
to signal that the word is to be applied. This transfers the input identifier to the shadow register of the addressed
output. CONFIG is then applied (asynchronously) to transfer one or more program commands to the main
latches of the program memories.
The SDOUT pin follows the data on the INCHAN[0](SDIN) pin 14 clock cycles later. This enables the user
to chain the serial ports of several crosspoints, shift program data for all switches through such a chain, and
assert LOAD on all switches simultaneously to program all of the connections simultaneously.
The output field is 7 bits long, representing the binary numerical identifier of the output to be programmed.
The input field is 7 bits long, representing the numerical identifier of the input that will be routed to the specified output.
G52351-0, Rev 3.0
02/12/01
© VITESSE SEMICONDUCTOR CORPORATION • 741 Calle Plano • Camarillo, CA 93012
Tel: (800) VITESSE • FAX: (805) 987-5896 • Email: [email protected]
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Page 3
VITESSE
SEMICONDUCTOR CORPORATION
3.2Gb/s
36x37 Crosspoint Switch
Preliminary Data Sheet
VSC838
Serial Read-Back
Read-back of the program memory contents is accomplished in serial mode by setting the ALE_SCN pin
HIGH. This will serially shift out the contents of the main latches in the program memories, slice 36 first and
slice 0 last, and MSB-first, LSB-last for each 7-bit word (see Figure 3). One rising edge of INCHAN[1](SCLK)
with ALE_SCN=0 and SERIAL=1 must occur to load the entire 483-bit shift register prior to shifting out data.
At a clock rate of 66MHz, this operation takes 7.26µs.
Activity Monitoring
The activity monitor observes the output of the internal 37th output from the core. By programming the
th output to observe various inputs, the input signals can be scanned for activity or lack thereof. Each rising
37
edge of ACTCLK causes the monitor to read out the activity state from the previous ACTCLK period and clears
the internal activity state until a data transition triggers it again. There must be a minimum of one rising and one
falling edge on the observed input data pin during the ACTCLK period for activity to be detected. After poweron the output of ACTIVITY after the first ACTCLK rising edge is unknown.
To access the 37th output, ACTCHAN and INCHAN[5] must both be HIGH.
Selective Power-Down
Unused input and output channels can be made to consume little or no power via one of two methods of
selective power-down.
Software Power-Down
Using this feature, unused outputs may be disabled, saving approximately 170 mW per channel for maximum dissipation conditions. This is accomplished by programming each unused output to look at input 127 (7F
Hex), which represents a non-existent input channel. The channel may be subsequently activated by programming a valid input address. It is recommended, however, that any changes in power programming only be executed as part of an initialization sequence to guard against the effects of any switching transients that might
result from changing the power supply current suddenly. Software mode does not affect the functioning or
power of unused input channels.
Hardware Power-Down
Using this feature, the power associated with given pairs of inputs may be shut off by tying the corresponding VEE pin to VCC (see Table 10). Approximately 160 mW per input pair is saved under the maximum dissipation conditions. The power associated with given pairs of outputs, including their contribution to the core
power, can be shut off by tying the corresponding VEE pin to VCC (see Table 10). Approximately 360 mW per
output pair is saved under the maximum dissipation conditions.
Certain VEE pins must always be active. In other words, tied to the most negative supply, so the corresponding inputs and outputs will always be on and consuming power. See Figure 7 and Table 10 for the location of
these pins.
Page 4
© VITESSE SEMICONDUCTOR CORPORATION • 741 Calle Plano • Camarillo, CA 93012
Tel: (800) VITESSE • FAX: (805) 987-5896 • Email: [email protected]
Internet: www.vitesse.com
G52351-0, Rev 3.0
02/12/01
VITESSE
SEMICONDUCTOR CORPORATION
Preliminary Data Sheet
3.2Gb/s
36x37 Crosspoint Switch
VSC838
AC Characteristics
Table 1: Data Path
Parameter
Description
Min
Typ
Max
Units
fRATE
Maximum data rate
-
-
3.2
Gb/s
TSKW
Channel-to-channel delay skew
-
300
-
ps
TPDAY
Propagation Delay from an A input to a Y output
-
750
-
ps
tR, tF
High-speed input rise/fall times, 20% to 80%
-
-
150
ps
tR, tF
High-speed output rise/fall times, 20% to 80%
-
-
150
ps
-
10
ps
-
40
ps
(1, 2)
tjR
Output added delay jitter, rms
tjP
Output added delay jitter, peak-to-peak(1, 2)
23
NOTES: (1) Tested on a sample basis only. (2) Broadband (unfiltered) deterministic jitter added to a jitter-free input, 2 -1 PRBS data pattern.
Table 2: Program Interface Timing
Parameter
Description
Min
Typ
Max
Units
TsWR
Setup time from INCHAN[5:0] or OUTCHAN5:0] to rising edge of
WR.
3.35
—
—
ns
ThWR
Hold time from rising edge of WRB to INCHAN[5:0] or
OUTCHAN[5:0].
1.45
—
—
ns
TPWLW
Pulse width (HIGH or LOW) on LOAD
6.75
—
—
ns
TsCS
Setup time from CS to falling edge of LOAD or ALE_SCN in parallel or
burst mode, or rising edge of LOAD in serial mode.
0
—
—
ns
ThCSB
Hold time of CS rising edge after LOAD or ALE_SCN rising in parallel
or burst mode, or falling edge of LOAD in serial mode, or falling edge of
CONFIG in any mode.
0
—
—
ns
TPWCFG
Pulse width (HIGH or LOW) on CONFIG.
6.75
—
—
ns
TsSDIN
Setup time from INCHAN0(SDIN) to INCHAN1(SCLK) rising.
1.65
—
—
ns
ThSDIN
Hold time of INCHAN0(SDIN) after INCHAN1(SCLK) rising.
1.0
—
—
ns
TperSCLK
Minimum period of SCLK in serial mode.
15
—
—
ns
TsLOAD
Setup time from LOAD to INCHAN1(SCLK) rising.
1.85
—
—
ns
ThLOAD
Hold time of LOAD after INCHAN1(SCLK) rising.
0.95
—
—
ns
TsSERIAL
Setup time from SERIAL rising to INCHAN1(SCLK) rising when
entering serial mode or SERIAL falling to LOAD falling when entering
parallel mode or SERIAL falling to LOAD rising when entering burst
mode.
0.90
—
—
ns
ThSERIAL
Hold time from INCHAN1(SCLK) rising to SERIAL falling when
exiting serial mode.
0
—
—
ns
TdSDOUT
Delay from INCHAN1(SCLK) rising to SDOUT, 20pF load.
—
—
6.20
ns
TPWINIT
Pulse width (HIGH or LOW) on INIT.
6.75
—
—
ns
TsSCAN
Setup time from ALE_SCN to INCHAN1(SCLK) rising when starting
or completing a serial read-back sequence.
1.65
—
—
ns
ThSCAN
Hold time of ALE_SCN after INCHAN1(SCLK) rising when starting or
completing a serial read-back sequence.
1.0
—
—
ns
G52351-0, Rev 3.0
02/12/01
© VITESSE SEMICONDUCTOR CORPORATION • 741 Calle Plano • Camarillo, CA 93012
Tel: (800) VITESSE • FAX: (805) 987-5896 • Email: [email protected]
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VITESSE
SEMICONDUCTOR CORPORATION
Preliminary Data Sheet
3.2Gb/s
36x37 Crosspoint Switch
VSC838
Figure 1: Parallel Mode -- Separate Address/Data (leave ALE_SCN pin HIGH)
OUTCHAN[5:0]
Output Addr
INCHAN[5:0]
Input Addr
LOAD
ThCS
TsWR
CS
CONFIG
TsCS
TPWCFG
ThWR
TPWLW
TsSERIAL
SERIAL
Figure 2: Parallel Mode -- Multiplexed Address/Data
INCHAN[5:0]
Output Addr
Input Addr
ALE_SCN
LOAD
ThCS
TsWR
CS
CONFIG
SERIAL
Page 6
TsCS
ThWR
TPWCFG
TPWLW
TsSERIAL
© VITESSE SEMICONDUCTOR CORPORATION • 741 Calle Plano • Camarillo, CA 93012
Tel: (800) VITESSE • FAX: (805) 987-5896 • Email: [email protected]
Internet: www.vitesse.com
G52351-0, Rev 3.0
02/12/01
VITESSE
SEMICONDUCTOR CORPORATION
Preliminary Data Sheet
3.2Gb/s
36x37 Crosspoint Switch
VSC838
Figure 3: Serial Mode (leave ALE_SCN pin LOW during programming)
INCHAN0_SDIN
Y5
Y4
Y3
Y2
low
Y1
Y0
A5
A4
A3
A2
low
A1
A0
INCHAN1_SCLK
TdSDOUT
SDOUT
LOAD
Y5
TperSCLK
TsSDIN ThSDIN
TsLOAD
Y3
Y2
ThCS
ThLOAD
TsCS
CS
Y4
TPWCFG
CONFIG
SERIAL
TsSERIAL
Y(n) = Output Address Bit (n); A(n) = Input Address Bit (n)
Figure 4: Serial Read-Back
ThSCAN
ALE_SCN
TsSCAN
INCHAN1_SCLK
TperSCLK
TdSDOUT
36
b5
SDOUT
SERIAL
36
b4
36
b3
36
b2
36
low
36
b1
36
b0
35
b5
35
b4
35
b3
35
b2
35
low
35
b1
35
b0
34
b5
TsSERIAL
MSB of Program memory for
Activity Monitor Channel
MSB of Program memory for 36th
output channel
Read-back shift register (483 bits long) is loaded here
on rising edge of INCHAN1_SCLK with SERIAL HIGH
and ALE_SCN LOW
NOTE: The word pattern during serial read back will be four valid words followed by four ‘DON’T CARE’ words.
G52351-0, Rev 3.0
02/12/01
© VITESSE SEMICONDUCTOR CORPORATION • 741 Calle Plano • Camarillo, CA 93012
Tel: (800) VITESSE • FAX: (805) 987-5896 • Email: [email protected]
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VITESSE
SEMICONDUCTOR CORPORATION
Preliminary Data Sheet
3.2Gb/s
36x37 Crosspoint Switch
VSC838
DC Characteristics
All characteristics are over the specified operating conditions.
Table 3: Power Supply Requirements
Parameter
Description
ICC
VCC supply current
PT
Total chip power (with ITERM = 0 and
back-terminations ON, high drive)
Min
Typ
Max
Units
2,286
3,428
mA
6
9
W
Typ
Max
Units
VCC+1.0
V
Conditions
MAX PT is with +5%
Supply, +85°C case
temperature and high
drive
Table 4: Control Port Input Levels (LVTTL/CMOS)
Parameter
Description
Min
VIH
Input HIGH voltage
1.7
0
VIL
Input LOW voltage
IIH
Input HIGH current
IIL
Input LOW current
VOH
Output HIGH voltage
VOL
Output LOW voltage
VOHPU
VOH with external pull-up
VOLPU
VOL with external pull-up
0.8
V
TBD
mA
Conditions
TBD
mA
VCC-0.2
VCC
V
DC Load < 500µA
0
0.2
V
DC Load < 2mA
V
250Ω to 3.3V(5%)
0.4
V
250Ω to 3.3V(5%)
Max
Units
150
1100
mV
See Note 1
VCC-0.7
VCC-0.2
V
See Note 2
2.4
Table 5: Signal Input Levels (high-speed signal path)
Parameter
Description
VIN
Input voltage amplitude
VICM
Input common-mode voltage
Min
Typ
Conditions
Table 6: Signal Output Levels (high-speed signal path), TERM_CTRL=ON, DRIVE_CTRL=HI
Parameter
Description
VOUT
Output differential voltage
VOCM
Output common-mode voltage
Min
Typ
Max
Units
Conditions
400
600
mV
See Note 1, 3
VCC-0.3
VCC-0.2
V
See Note 2, 3
NOTES: (1) Mean peak-to-peak amplitude measurement of either true or complement of the differential signal.
(2) VCC = VCCP = 2.5V, VEE = 0V.
(3) Terminated in 50Ω to VCC. This termination is used for testing the part, but other terminations are allowed—see Table 9.
Page 8
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G52351-0, Rev 3.0
02/12/01
VITESSE
SEMICONDUCTOR CORPORATION
Preliminary Data Sheet
3.2Gb/s
36x37 Crosspoint Switch
VSC838
I/O Equivalent Circuits
ITC
VCC
50
TERM_CTRL
50
PAD
50
PAD
50
PAD
PAD
DRIVE_CTRL
H/S Input Equivalent Circuit
H/S Output Equivalent Circuit
Input Termination
The high-speed inputs of the VSC838 are internally terminated by a 100Ω impedance between true and
complement inputs. Termination resistors are isolated from each other on-chip. The termination will self-bias to
+2.0V (nominal) for AC-coupled applications. The ITC pin enables direct interconnection of multiple VSC838
devices. With ITC tied to VCC, the center point of the 100Ω termination impedance is tied to VCC, causing the
terminations to act as loads for an open-drain or open-collector differential output.
Table 7: Allowed Input Termination Schemes
Type
1
Description
Comments
Tie ITC LOW, 100Ω differential input termination,
input self-biased
AC-coupled input
2
DC-coupled from open-drain CML
Tie ITC HIGH, terminations acts as 50Ω load to VCC
3
DC-coupled from back-terminated 2.5V CML
Tie ITC HIGH, terminations acts as 50Ω load to VCC
4
DC-coupled from back-terminated 2.5V CML
Tie ITC LOW, 100Ω differential termination
(preferred over Type 3)
5
DC-coupled from back-terminated 3.3V LV-PECL
Tie ITC LOW, 100Ω differential termination
Some allowed termination schemes result in additional ICC current and power dissipation on-chip. See
Table 8.
Table 8: Additional Current and Power
Parameter
Description
ICC-C
Additional ICC current when receiving DCCoupled CML (ITC = HIGH)
PCC-C
Additional power dissipated on-chip for
DC terminating CML at inputs
G52351-0, Rev 3.0
02/12/01
Min
Typ
Max
Units
180
mA
0.180
W
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Conditions
Page 9
VITESSE
SEMICONDUCTOR CORPORATION
Preliminary Data Sheet
3.2Gb/s
36x37 Crosspoint Switch
VSC838
Output Termination
The high-speed outputs of the VSC838 are internally back terminated by 50 Ω to V CC when the
TERM_CTRL pin is HIGH. When this pin is LOW, the output driver functions as an open-drain CML driver.
Setting DRIVE_CTRL LOW (GND) saves 1W under maximum power dissipation conditions. See Table 9 for
allowable types of terminations and modes of operation.
Table 9: Allowed High-Speed Output Terminations and Modes of Operation
Type
Description
DRIVE_
CTRL
TERM_
CTRL
VOD(1)
(mV)
typ
VOCM(1)
(V)
typ
VCC (HIGH)
VCC (ON)
500
2.0
1
AC-coupled to 50Ω termination to any voltage
2
AC-coupled to 100Ω differential termination
VCC (HIGH)
VCC (ON)
500
2.0
3
DC-coupled, terminated in 50Ω to VCC at far-end only
GND (LOW)
GND (OFF)
500
2.25
4
DC-coupled, terminated in 50Ω to VCC at far-end only
VCC (HIGH)
GND (OFF)
1000
2.0
5
DC-coupled, source and far-end terminated in 50Ω to VCC
GND (LOW)
VCC (ON)
250
2.375
6
DC-coupled, source and far-end terminated in 50Ω to VCC
VCC (HIGH)
VCC (ON)
500
2.25
7
DC-coupled, 100Ω differential termination
GND (LOW)
VCC (ON)
250
2.25
8
DC-coupled, 100Ω differential termination
VCC (HIGH)
VCC (ON)
500
2.0
NOTE: (1) Measured at output of VSC838, with VCC = 2.5V.
Absolute Maximum Ratings(1)
Power Supply Voltage (VCC) Potential to GND ..............................................................................-0.5V to +4.0V
LVTTL Input Voltage Applied ................................................................................................-0.5V to VCC+1.0V
ECL Input Voltage Applied ....................................................................................................-0.5V to VCC +0.5V
Output Current (IOUT) .................................................................................................................................... 50mA
Case Temperature Under Bias (TC) ............................................................................................. -55oC to + 125oC
Storage Temperature (TSTG) ........................................................................................................ -65oC to + 150oC
NOTE: (1) Caution: Stresses listed under “Absolute Maximum Ratings” may be applied to devices one at a time without causing permanent damage. Functionality at or exceeding the values listed is not implied. Exposure to these values for extended periods may
affect device reliability.
Operating Conditions
Supply Voltage (VEE).......................................................................................................................................... 0V
Supply Voltage (VCC) ............................................................................................................................+2.5V ±5%
Supply Voltage (VCCP)...........................................................................................................................+2.5V ±5%
Case Temperature Operating Range (T)..................................................... 0oC to 85oCPackage Pin Descriptions
Page 10
© VITESSE SEMICONDUCTOR CORPORATION • 741 Calle Plano • Camarillo, CA 93012
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G52351-0, Rev 3.0
02/12/01
VITESSE
SEMICONDUCTOR CORPORATION
Preliminary Data Sheet
3.2Gb/s
36x37 Crosspoint Switch
VSC838
Figure 5: Pinout Diagram -- Bottom View
29
28
27
26
25
24
23
22
2
NC
NC
21
20
6
NC
NC
19
18
10
NC
NC
17
16
14
NC
NC
15
14
18
NC
NC
13
12
22
NC
NC
11
10
26
NC
NC
9
8
30
NC
NC
6
7
5
4
3
2
Ball grid
index
1
OUTCHAN4
NC
A
A
NC
34
OUTCHAN5
B
B
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
C
C
D
D
NC
NC
NC
NC
NC
16
NC
20
NC
24
NC
28
NC
32
NC
ACTCHAN
NC
Inputs [An, ANn]
11
Outputs [Yn, YNn]
Outputs [Yn, YNn]
35
CS
ACTIVITY
NC
NC
31
CMV
NC
Y
AB
AC
ACTCLK
27
35
NC
V
AA
NC
23
TERM_CTRL
NC
DRIVE_CTRL
INCHAN5
ALE_SCN
19
NC
33
34
NC
NC
NC
NC
NC
15
SERIAL
NC
31
29
30
NC
NC
T
W
NC
NC
NC
NC
NC
NC
11
NC
NC
27
25
26
NC
NC
P
U
NC
NC
NC
NC
NC
NC
7
NC
NC
23
21
22
NC
NC
M
R
NC
NC
NC
NC
NC
NC
3
NC
NC
19
17
18
INCHAN1(SCLK)
NC
K
N
NC
NC
NC
NC
NC
NC
NC
NC
15
13
14
Inputs [An, ANn]
H
L
NC
NC
NC
NC
NC
NC
Control port
NC
NC
NC
9
10
Common VEE (always On)
F
J
7
NC
NC
NC
NC
Dedicated VEE
NC
NC
NC
5
6
AE
NC
NC
NC
NC
VCC
E
G
3
1
2
INCHAN4
ITC
LOAD
AD
NC
32
NC
NC
AC
NC
28
AB
NC
NC
AA
NC
24
Y
NC
NC
W
NC
20
V
NC
NC
U
NC
16
T
NC
NC
R
NC
12
P
NC
NC
N
NC
8
M
NC
NC
L
NC
4
K
NC
NC
J
NC
0
H
CONFIG
NC
G
NC
F
OUTCHAN0
12
OUTCHAN1
8
OUTCHAN3
4
OUTCHAN2
0
E
AD
AE
AF
AF
INCHAN0(SDIN)
NC
NC
NC
NC
NC
NC
NC
NC
INCHAN2
NC
NC
NC
NC
NC
NC
NC
NC
SDOUT
AG
AG
AH
AH
INCHAN3
1
NC
5
NC
9
NC
13
NC
17
NC
21
NC
25
NC
29
NC
33
INIT
23
22
21
20
19
18
17
16
15
14
13
12
11
10
9
8
7
6
AJ
AJ
29
G52351-0, Rev 3.0
02/12/01
28
27
26
25
24
5
© VITESSE SEMICONDUCTOR CORPORATION • 741 Calle Plano • Camarillo, CA 93012
Tel: (800) VITESSE • FAX: (805) 987-5896 • Email: [email protected]
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4
3
2
1
Page 11
VITESSE
SEMICONDUCTOR CORPORATION
Preliminary Data Sheet
3.2Gb/s
36x37 Crosspoint Switch
VSC838
Table 10: Package Pin Indentifications
Signal Name
Ball
Description
Level
High-Speed Data Inputs
A0, AN0
D23, E23
High-Speed Data Input Channel 0; True, Complement
PECL
A1, AN1
AH23, AJ23
High-Speed Data Input Channel 1; True, Complement
PECL
A2, AN2
B23, A23
High-Speed Data Input Channel 2; True, Complement
PECL
A3, AN3
AF23, AE23
High-Speed Data Input Channel 3; True, Complement
PECL
A4, AN4
D21, E21
High-Speed Data Input Channel 4; True, Complement
PECL
A5, AN5
AH21, AJ21
High-Speed Data Input Channel 5; True, Complement
PECL
A6, AN6
B21, A21
High-Speed Data Input Channel 6; True, Complement
PECL
A7, AN7
AF21, AE21
High-Speed Data Input Channel 7; True, Complement
PECL
A8, AN8
D19, E19
High-Speed Data Input Channel 8; True, Complement
PECL
A9, AN9
AH19, AJ19
High-Speed Data Input Channel 9; True, Complement
PECL
A10, AN10
B19, A19
High-Speed Data Input Channel 10; True, Complement
PECL
A11, AN11
AF19, AE19
High-Speed Data Input Channel 11; True, Complement
PECL
A12, AN12
D17, E17
High-Speed Data Input Channel 12; True, Complement
PECL
A13, AN13
AH17, AJ17
High-Speed Data Input Channel 13; True, Complement
PECL
A14, AN14
B17, A17
High-Speed Data Input Channel 14; True, Complement
PECL
A15, AN15
AF17, AE17
High-Speed Data Input Channel 15; True, Complement
PECL
A16, AN16
D15, E15
High-Speed Data Input Channel 16; True, Complement
PECL
A17, AN17
AH15, AJ15
High-Speed Data Input Channel 17; True, Complement
PECL
A18, AN18
B15, A15
High-Speed Data Input Channel 18; True, Complement
PECL
A19, AN19
AF15, AE15
High-Speed Data Input Channel 19; True, Complement
PECL
A20, AN20
D13, E13
High-Speed Data Input Channel 20; True, Complement
PECL
A21, AN21
AH13, AJ13
High-Speed Data Input Channel 21; True, Complement
PECL
A22, AN22
B13, A13
High-Speed Data Input Channel 22; True, Complement
PECL
A23, AN23
AF13, AE13
High-Speed Data Input Channel 23; True, Complement
PECL
A24, AN24
D11, E11
High-Speed Data Input Channel 24; True, Complement
PECL
A25, AN25
AH11, AJ11
High-Speed Data Input Channel 25; True, Complement
PECL
A26, AN26
B11, A11
High-Speed Data Input Channel 26; True, Complement
PECL
A27, AN27
AF11, AE11
High-Speed Data Input Channel 27; True, Complement
PECL
A28, AN28
D9, E9
High-Speed Data Input Channel 28; True, Complement
PECL
A29, AN29
AH9, AJ9
High-Speed Data Input Channel 29; True, Complement
PECL
A30, AN30
B9, A9
High-Speed Data Input Channel 30; True, Complement
PECL
A31, AN31
AF9, AE9
High-Speed Data Input Channel 31; True, Complement
PECL
A32, AN32
D7, E7
High-Speed Data Input Channel 32; True, Complement
PECL
A33, AN33
AH7, AJ7
High-Speed Data Input Channel 33; True, Complement
PECL
A34, AN34
B7, A7
High-Speed Data Input Channel 34; True, Complement
PECL
A35, AN35
AF7, AE7
High-Speed Data Input Channel 35; True, Complement
PECL
Page 12
© VITESSE SEMICONDUCTOR CORPORATION • 741 Calle Plano • Camarillo, CA 93012
Tel: (800) VITESSE • FAX: (805) 987-5896 • Email: [email protected]
Internet: www.vitesse.com
G52351-0, Rev 3.0
02/12/01
VITESSE
SEMICONDUCTOR CORPORATION
Preliminary Data Sheet
3.2Gb/s
36x37 Crosspoint Switch
VSC838
Signal Name
Ball
Description
Level
High-Speed Data Outputs
Y0, YN0
G28, G29
High-Speed Data Output Channel 0; True, Complement
CML
Y1, YN1
G4, G5
High-Speed Data Output Channel 1; True, Complement
CML
Y2, YN2
G26, G25
High-Speed Data Output Channel 2; True, Complement
CML
Y3, YN3
G2, G1
High-Speed Data Output Channel 3; True, Complement
CML
Y4, YN4
J28, J29
High-Speed Data Output Channel 4; True, Complement
CML
Y5, YN5
J4, J5
High-Speed Data Output Channel 5; True, Complement
CML
Y6, YN6
J26, J25
High-Speed Data Output Channel 6; True, Complement
CML
Y7, YN7
J2, J1
High-Speed Data Output Channel 7; True, Complement
CML
Y8, YN8
L28, L29
High-Speed Data Output Channel 8; True, Complement
CML
Y9, YN9
Y10, YN10
L4, L5
High-Speed Data Output Channel 9; True, Complement
CML
L26, L25
High-Speed Data Output Channel 10; True, Complement
CML
Y11, YN11
L2, L1
High-Speed Data Output Channel 11; True, Complement
CML
Y12, YN12
N28, N29
High-Speed Data Output Channel 12; True, Complement
CML
Y13, YN13
N4, N5
High-Speed Data Output Channel 13; True, Complement
CML
Y14, YN14
N26, N25
High-Speed Data Output Channel 14; True, Complement
CML
Y15, YN15
N2, N1
High-Speed Data Output Channel 15; True, Complement
CML
Y16, YN16
R28, R29
High-Speed Data Output Channel 16; True, Complement
CML
Y17, YN17
R4, R5
High-Speed Data Output Channel 17; True, Complement
CML
Y18, YN18
R26, R25
High-Speed Data Output Channel 18; True, Complement
CML
Y19, YN19
R2, R1
High-Speed Data Output Channel 19; True, Complement
CML
Y20, YN20
U28, U29
High-Speed Data Output Channel 20; True, Complement
CML
Y21, YN21
U4, U5
High-Speed Data Output Channel 21; True, Complement
CML
Y22, YN22
U26, U25
High-Speed Data Output Channel 22; True, Complement
CML
Y23, YN23
U2, U1
High-Speed Data Output Channel 23; True, Complement
CML
Y24, YN24
W28, W29
High-Speed Data Output Channel 24; True, Complement
CML
Y25, YN25
W4, W5
High-Speed Data Output Channel 25; True, Complement
CML
Y26, YN26
W26, W25
High-Speed Data Output Channel 26; True, Complement
CML
Y27, YN27
W2, W1
High-Speed Data Output Channel 27; True, Complement
CML
Y28, YN28
AA28, AA29
High-Speed Data Output Channel 28; True, Complement
CML
Y29, YN29
AA4 , AA5
High-Speed Data Output Channel 29; True, Complement
CML
Y30, YN30
AA26, AA25
High-Speed Data Output Channel 30; True, Complement
CML
Y31, YN31
AA2, AA1
High-Speed Data Output Channel 31; True, Complement
CML
Y32, YN32
AC28, AC29
High-Speed Data Output Channel 32; True, Complement
CML
Y33, YN33
AC4, AC5
High-Speed Data Output Channel 33; True, Complement
CML
Y34, YN34
AC26, AC25
High-Speed Data Output Channel 34; True, Complement
CML
Y35, YN35
AC2, AC1
High-Speed Data Output Channel 35; True, Complement
CML
G52351-0, Rev 3.0
02/12/01
© VITESSE SEMICONDUCTOR CORPORATION • 741 Calle Plano • Camarillo, CA 93012
Tel: (800) VITESSE • FAX: (805) 987-5896 • Email: [email protected]
Internet: www.vitesse.com
Page 13
VITESSE
SEMICONDUCTOR CORPORATION
Preliminary Data Sheet
3.2Gb/s
36x37 Crosspoint Switch
Signal Name
VSC838
Ball
Description
Level
ACTCLK
AD2
Clock for Activity Monitor (<10MHz)
LVTTL
ACTIVITY
AD1
ActivityResult from Previous ACTCLK Period
LVTTL
ALE_SCN
AD25
Address Latch Enable for Multiplexed Parallel Mode; Scan
Enable for Serial Mode. See Figures 2 through 6 for proper
use.
LVTTL
CMV
AD3
Output Drive Current Control (leave floating)
ANALO
G
CONFIG
F27
Logic HIGH Transfers Programming to Main Program
Memory
LVTTL
Control Pins
CS
AF6
Chip Select (active LOW)
LVTTL
DRIVE_CTRL
AD4
Output Drive Current Switch (LOW = 10mA, HIGH = 20mA)
LVTTL
INCHAN0
(SDIN)
AG24
Input Channel, Bit 0 and Serial Data in Serial Mode
LVTTL
INCHAN1
(SCLK)
AF24
Input Channel, Bit 1 and Serial Clock in Serial Mode
LVTTL
INCHAN2
AH24
Input Channel, Bit 2
LVTTL
INCHAN3
AJ24
Input Channel, Bit 3
LVTTL
INCHAN4
AD27
Input Channel, Bit 4
LVTTL
INCHAN5
AD26
Input Channel, Bit 5
LVTTL
INIT = 0 Forces “Straight-Through” Program
LVTTL
AD29
Input Termination Control (GND = floating input termination,
VCC = CML mode. See Table 7).
ANALO
G
AD28
Rising Edge Writes Data in Parallel and Burst Modes,
See Figure 5 for Serial Mode
LVTTL
INIT
AJ6
ITC
LOAD
OUTCHAN0
F1
Output Channel, Bit 0
LVTTL
OUTCHAN1
F2
Output Channel, Bit 1
LVTTL
ACTCHAN
F5
Activity Channel Enable bit; HIGH = Enable
LVTTL
OUTCHAN2
F4
Output Channel, Bit 2
LVTTL
OUTCHAN3
F3
Output Channel, Bit 3
LVTTL
OUTCHAN4
A6
Output Channel, Bit 4
LVTTL
OUTCHAN5
B6
Output Channel, Bit 5
LVTTL
SDOUT
AG6
Serial Data Out for Serial Mode and Scan
LVTTL
SERIAL
AE6
SERIAL = 1 (Sets Serial Mode)
LVTTL
TERM_CTRL
AD5
Output Back-Termination Control (LOW = no back term;
HIGH = 50Ω back-termination to VCC. See Table 9).
LVTTL
Page 14
© VITESSE SEMICONDUCTOR CORPORATION • 741 Calle Plano • Camarillo, CA 93012
Tel: (800) VITESSE • FAX: (805) 987-5896 • Email: [email protected]
Internet: www.vitesse.com
G52351-0, Rev 3.0
02/12/01
VITESSE
SEMICONDUCTOR CORPORATION
Preliminary Data Sheet
3.2Gb/s
36x37 Crosspoint Switch
VSC838
Signal Name
Ball
Description
NC
D22, AH22, B22, AF22
D20, AH20, B20, AF20
D18, AH18, B18, AF18
D16, AH16, B16, AF16
D14, AH14, B14, AF14
D12, AH12, B12, AF12
D10, AH10, B10, AF10
D8, AH8, B8, AF8
E22, AJ22, A22, AE22
E20, AJ20, A20, AE20
E18, AJ18, A18, AE18
E16, AJ16, A16, AE16
E14, AJ14, A14, AE14
E12, AJ12, A12, AE12
E10, AJ10, A10, AE10
E8, AJ8, A8, AE8
No Connect
NC
H28, H4, H26, H2
K28, K4, K26, K2
M28, M4, M26, M2
P28, P4, P26, P2
T28, T4, T26, T2
V28, V4, V26, V2
Y28, Y4, Y26, Y2
AB28, AB4, AB26, AB2
H29, H5, H25, H1
K29, K5, K25, K1
M29, M5, M25, M1
P29, P5, P25, P1
T29, T5, T25, T1
V29, V5, V25, V1
Y29, Y5, Y25, Y1
AB29, AB5, AB25, AB1
No Connect
NC
E6, D6, C6
A24, B24, D24, E24, C24
F29, F28, F25, F26
No Connect
VEE
C23, C7, R3, AG7
AG23, R27, AH6, AE24P
Common Negative Power Supply
Level
Power Supplies
G52351-0, Rev 3.0
02/12/01
© VITESSE SEMICONDUCTOR CORPORATION • 741 Calle Plano • Camarillo, CA 93012
Tel: (800) VITESSE • FAX: (805) 987-5896 • Email: [email protected]
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GND
Page 15
VITESSE
SEMICONDUCTOR CORPORATION
Preliminary Data Sheet
3.2Gb/s
36x37 Crosspoint Switch
Signal Name
VSC838
Ball
Description
Level
VCC
A1, A2, A3, A4, A5
B1, B2, B3, B4, B5
C1, C2, C3, C4, C5
D1, D2, D3, D4, D5
E1, E2, E3, E4, E5
A25, A26, A27, A28, A29
B25, B26, B27, B28, B29
C25, C26, C27, C28, C29
D25, D26, D27, D28, D29
E25, E26, E27, E28, E29
AE1, AE2, AE3, AE4, AE5
AF1, AF2, AF3, AF4, AF5
AG1, AG2, AG3, AG4,
AG5
AH1, AH2, AH3, AH4,
AH5
AJ1, AJ2, AJ3, AJ4, AJ5
AE25,AE26,AE27,AE28,A
E29
AF25,AF26,AF27,AF28,A
F29
AG25,AG26,AG27,AG28,
AG29
AH25,AH26,AH27,AH28,
AH29
AJ25,AJ26,AJ27,AJ28,AJ2
9
Positive Power Supply
2.5V
NC
C22, C20, C18, C16, C14,
C12, C10, C8, AG22,
AG20, AG18, AG16,
AG14, AG12, AG10, AG8,
H3, K3, M3, P3, T3, V3,
Y3, AB3, H27, K27, M27,
P27, T27, V27, Y27, AB27,
No Connect
VEEP_T1
C21
Negative Power Supply for Inputs A4/AN4 + A6/AN6
GND
VEEP_T2
C19
Negative Power Supply for Inputs A8/AN8 + A10/AN10
GND
VEEP_T3
C17
Negative Power Supply for Inputs A12/AN12 + A14/AN14
GND
VEEP_T4
C15
Negative Power Supply for Inputs A16/AN16+A18/AN18
GND
VEEP_T5
C13
Negative Power Supply for Inputs A20/AN20+A22/AN22
GND
VEEP_T6
C11
Negative Power Supply for Inputs A24/AN24+A26/AN26
GND
VEEP_T7
C9
VEEP_B1
AG21
Negative Power Supply for Inputs A28/AN28+A30/AN30
GND
Negative Power Supply for Inputs A5/AN5+A7/AN7
GND
VEEP_B2
AG19
Negative Power Supply for Inputs A9/AN9+A11/AN11
GND
VEEP_B3
AG17
Negative Power Supply for Inputs A13/AN13+A15/AN15
GND
VEEP_B4
AG15
Negative Power Supply for Inputs A17/AN17+A19/AN19
GND
VEEP_B5
AG13
Negative Power Supply for Inputs A21/AN21+A23/AN23
GND
Page 16
© VITESSE SEMICONDUCTOR CORPORATION • 741 Calle Plano • Camarillo, CA 93012
Tel: (800) VITESSE • FAX: (805) 987-5896 • Email: [email protected]
Internet: www.vitesse.com
G52351-0, Rev 3.0
02/12/01
VITESSE
SEMICONDUCTOR CORPORATION
Preliminary Data Sheet
3.2Gb/s
36x37 Crosspoint Switch
VSC838
Signal Name
Ball
Description
Level
VEEP_B6
AG11
Negative Power Supply for Inputs A25/AN25+A27/AN27
GND
VEEP_B7
AG9
Negative Power Supply for Inputs A29/AN29+A31/AN31
GND
VEEP_L0
G3
Negative Power Supply for Outputs Y1/YN1+Y3/YN3
GND
VEEP_L1
J3
Negative Power Supply for Outputs Y5/YN5+Y7/YN7
GND
VEEP_L2
L3
Negative Power Supply for Outputs Y9/YN9+Y11/YN11
GND
VEEP_L3
N3
Negative Power Supply for Outputs Y13/YN13+Y15/YN15
GND
VEEP_L4
U3
Negative Power Supply for Outputs Y21/YN21+Y23/YN23
GND
VEEP_L5
W3
Negative Power Supply for Outputs Y25/YN25+Y27/YN27
GND
VEEP_L6
AA3
Negative Power Supply for Outputs Y29/YN29+Y31/YN31
GND
VEEP_L7
AC3
Negative Power Supply for Outputs Y33/YN33+Y35/YN35
GND
VEEP_R0
G27
Negative Power Supply for Outputs Y0/YN0+Y2/YN2
GND
VEEP_R1
J27
Negative Power Supply for Outputs Y4/YN4+Y6/YN6
GND
VEEP_R2
L27
Negative Power Supply for Outputs Y8/YN8+Y10/YN10
GND
VEEP_R3
N27
Negative Power Supply for Outputs Y12/YN12+Y14/YN14
GND
VEEP_R4
U27
Negative Power Supply for Outputs Y20/YN20+Y22/YN22
GND
VEEP_R5
W27
Negative Power Supply for Outputs Y24/YN24+Y26/YN26
GND
VEEP_R6
AA27
Negative Power Supply for Outputs Y28/YN28+Y30/YN30
GND
VEEP_R7
AC27
Negative Power Supply for Outputs Y32/YN32+Y34/YN34
GND
G52351-0, Rev 3.0
02/12/01
© VITESSE SEMICONDUCTOR CORPORATION • 741 Calle Plano • Camarillo, CA 93012
Tel: (800) VITESSE • FAX: (805) 987-5896 • Email: [email protected]
Internet: www.vitesse.com
Page 17
VITESSE
SEMICONDUCTOR CORPORATION
Preliminary Data Sheet
3.2Gb/s
36x37 Crosspoint Switch
VSC838
Package Information - 37.5mm 480 BGA
00.30 S
Page 18
C
A S
B
S
© VITESSE SEMICONDUCTOR CORPORATION • 741 Calle Plano • Camarillo, CA 93012
Tel: (800) VITESSE • FAX: (805) 987-5896 • Email: [email protected]
Internet: www.vitesse.com
G52351-0, Rev 3.0
02/12/01
VITESSE
SEMICONDUCTOR CORPORATION
Preliminary Data Sheet
3.2Gb/s
36x37 Crosspoint Switch
VSC838
Ordering Information
The order number for this product is formed by a combination of the device type and package type.
VSC838
XX
Device Type
OC-48 36x37 Crosspoint Switch
Package Style
UG: 480 TBGA, 37.5mm Body
Notice
Vitesse Semiconductor Corporation (“Vitesse”) provides this document for informational purposes only. This document contains pre-production
information about Vitesse products in their concept, development and/or testing phase. All information in this document, including descriptions of
features, functions, performance, technical specifications and availability, is subject to change without notice at any time. Nothing contained in this
document shall be construed as extending any warranty or promise, express or implied, that any Vitesse product will be available as described or
will be suitable for or will accomplish any particular task.
Vitesse products are not intended for use in life support appliances, devices or systems. Use of a Vitesse product in such applications without written consent is prohibited.
G52351-0, Rev 3.0
02/12/01
© VITESSE SEMICONDUCTOR CORPORATION • 741 Calle Plano • Camarillo, CA 93012
Tel: (800) VITESSE • FAX: (805) 987-5896 • Email: [email protected]
Internet: www.vitesse.com
Page 19
VITESSE
SEMICONDUCTOR CORPORATION
3.2Gb/s
36x37 Crosspoint Switch
Page 20
Preliminary Data Sheet
© VITESSE SEMICONDUCTOR CORPORATION • 741 Calle Plano • Camarillo, CA 93012
Tel: (800) VITESSE • FAX: (805) 987-5896 • Email: [email protected]
Internet: www.vitesse.com
VSC838
G52351-0, Rev 3.0
02/12/01