MAXIM VSC7173XYI

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May 23, 2005
Confidential
VSC7173 Data Sheet
Enhanced 2:1 Port Selector and 1:2 Port Multiplier for Serial ATA and Serial Attached SCSI
FEATURES
APPLICATIONS
2:1 port selector and 1:2 port multiplier for both
Serial ATA (SATA) and Serial Attached SCSI
(SAS) links
●
Active-passive redundant failover systems
●
Dual-port Serial ATA and Serial Attached SCSI
disk arrays (JBODs)
●
Serial ATA 1.0 compliant at 1.5 Gbps
(3.0 Gbps capable)
●
NAS servers
●
RAID subsystems
●
Passes Serial ATA patterns transparently
●
Disk-based backup systems
●
Programmable receiver sensitivity
●
●
High output swing mode with pre-emphasis
Serial ATA and Serial Attached SCSI routing
applications
●
Compatible with VSC7175 and VSC7177 designs
●
Buffers for externally connected links
●
0.7 W power dissipation
●
Serial ATA port replicators
●
3.3 V power supply
●
●
32-pin, 7 mm x 7 mm QFP-N package
Serial ATA Host Bus Adapters selecting between
internal and external connectors
●
To order the VSC7173 device, see “Ordering Information,” page 17.
GENERAL DESCRIPTION
The VSC7173 is a Serial ATA and Serial Attached SCSI multiplexer and buffer that implements a 2:1 port selector
function for 1.5 Gbps and 3.0 Gbps links. This function is used when dual hosts, such as I/O controllers, must access
single-port disk drives in high availability storage subsystems where redundancy and load sharing are important. The
outputs from the I/O controllers are multiplexed to a Serial ATA or Serial Attached SCSI drive. The output from the
Serial ATA drive is buffered and replicated to the I/O controllers. When switching from one I/O controller to the
other, a Serial ATA link must be re-initialized with out-of-band (OOB) signals, which are transferred through the
VSC7173 transparently. The VSC7173 provides high output swings with pre-emphasis, and programmable receiver
sensitivity that are needed to drive long backplanes and external cables.
In addition to the above features, the VSC7173 also supports a 1:2 port multiplier mode where one host can connect
two drives.
Port connectivity for the device is configured by driving external I/O pins. See the block diagram on page 2.
Maxim Integrated Products
For pricing, delivery, and ordering information, please contact Maxim Direct at 1-888-629-4642,
or visit Maxim’s website at www.maxim-ic.com.
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VSC7173
Data Sheet
VSC7173 Block Diagram
Port 0
Port 2
P0INP
P0INN
0
OOB
P2OUTP
1 S
En
P2OUTN
OOBPORT0
0
P0OUTP
1 S
En
P0OUTN
P2INP
OOB
Port 1
P1INP
P1INN
OOB
0
P1OUTP
P1OUTN
1 S
En
MODE1
Edge-Triggered
Logic
0
P0SLTD
S 1
MODE1
PORTSEL0 PORTSEL1
MODE0
OOBSEL [0:1]
HIV [0:2]
I/O Configuration
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SET
Q
RST
QN
P2INN
VSC7173
Data Sheet
Application Examples
The VSC7173 allows two Serial ATA hosts to access one Serial ATA drive. Figure 1 shows a common application
where redundant I/O controllers in disk arrays have multiplexed access to single-port Serial ATA disk drives.
VSC7173
I/O Controller A
Serial ATA Drive
(1 of n)
I/O Controller B
Backplane
"Tailgate" Board
Figure 1. Serial ATA Backplane Application
Another application example (Figure 2) is for simple port replication to enable an existing Serial ATA Host Bus
Adapter (HBA) to connect to two ports. By using the VSC7173, a single channel from the HBA may be selectively
connected to an internal connector or an external connector. The VSC7173 provides both the mulitplexing
functionality and buffering to drive external connections.
Serial ATA
Host Bus Adaptor
Port A
Internal
Connector
VSC7173
External
Connector
PCI Bus
Port B
External
Connector
Port Multiplier
Figure 2. Port Multiplier Application
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VSC7173
Data Sheet
FUNCTIONAL DESCRIPTIONS
Modes of Operation
Table 1 summarizes the VSC7173 operational mode choices. The mode of the VSC7173 is determined by the
following pins.
MODE1: Controls whether the selection of port 0 to port 1 is edge-sensitive or level-sensitive. When LOW, port
selection is level-sensitive (to enable level-sensitive port selection, pin PORTSEL1 must also be LOW). When HIGH,
port selection is edge-sensitive.
MODE0: Controls the function of the unselected port. When LOW, the output of this port is turned off. When HIGH,
the output of this unselected port is the same data as seen on the selected port.
PORTSEL0: In level-sensitive mode (MODE1 is LOW and PORTSEL1 is LOW), controls the selection of port 0 or
port 1. When LOW, port 0 is selected; when HIGH, port 1 is selected. In edge-sensitive mode (MODE1 is HIGH),
controls the selection of port 0; a rising edge on this pin selects port 0.
PORTSEL1: In level-sensitive mode (MODE1 is LOW), must be held LOW. In edge-sensitive mode (MODE1 is
HIGH), controls the selection of port 1; a rising edge on this pin selects port 1.
Table 1. Port Selection Operating Modes
Input Pins
High-Speed Connections
MODE1
MODE0
PORTSEL0
PORTSEL1
P0OUT
P1OUT
P2OUT
0 (level)
0
0
0
P2IN
OFF
P0IN
0 (level)
0
1
0
OFF
P2IN
P1IN
0 (level)
1
0
0
P2IN
P2IN
P0IN
P1IN
0 (level)
1
1
0
P2IN
P2IN
1 (edge)
0
X
↑
OFF
P2IN
P1IN
1 (edge)
0
↑
X
P2IN
OFF
P0IN
1 (edge)
1
X
↑
P2IN
P2IN
P1IN
1 (edge)
1
↑
X
P2IN
P2IN
P0IN
X = don’t care; ↑ = rising.
Status Pins
Two output pins, P0SLTD and OOBPORT0, are provided for status monitoring. Table 2 summarizes the functionality
of these two output pins. OOBPORT0 reports whether the signal on port 0 is above or below the threshold selected in
Table 5. P0SLTD, depending on the state of MODE1, can either report which port is selected or can report whether
the signal on port 1 is above or below the threshold selected in Table 5.
Table 2. Output Status Pins
Input Pins
Output Status Pins
MODE1
PORTSEL0
PORTSEL1
P0SLTD
0 (level)
X
X
OOB status port 1—1 indicates signal is
below OOB threshold, 0 indicates signal
is above OOB threshold
1 (edge)
X
↑
Indicates port selected, 0 = port 1
OOB status port 0
1 (edge)
↑
X
Indicates port selected, 1 = port 0
OOB status port 0
X = don’t care; ↑ = rising.
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OOBPORT0
OOB status port 0—1 indicates signal
is below OOB threshold, 0 indicates
signal is above OOB threshold
VSC7173
Data Sheet
Reset State
The power-up state of the VSC7173 is based on the PORTSEL0 and PORTSEL1 input signals. When in levelsensitive mode, the active port connected to port 2 is controlled directly by the PORTSEL0 input. This is the same
behavior as the normal operating condition described above. When in edge-sensitive mode, the active port connected
to port 2 is defined in Table 3. The state diagram in Figure 3 indicates the same result in a different format.
Table 3. Power-up State (Edge-Sensitive Mode)
PORTSEL0
PORTSEL1
Active Port
P0SLTD Output
0
0
Port 0 selected
1
1
0
Port 0 selected
1
0
1
Port 1 selected
0
1
1
Port 0 selected
1
Reset=1
Reset State
(PORTSEL0=1, PORTSEL1=1
or PORTSEL1=0)
and Reset=0
Reset=1
PORTSEL0=0, PORTSEL1=1
and Reset=0
PORTSEL0
Port 0 Selected
Port 1 Selected
PORTSEL1
Figure 3. Reset State Machine (Edge-Sensitive Mode)
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Data Sheet
High-Speed Outputs
Each port has a high-speed output buffer that transmits the differential serial ATA data at rates up to 3.0 Gbps. The
output pins for the ports are P0OUTP/N, P1OUTP/N, and P2OUTP/N. Each output buffer has an input to indicate
when OOB signals are being transmitted and a single input to control the output voltage amplitude and to enable preemphasis.
Output
Data
OutputN
HIV
TX Common Mode
Figure 4. High-Speed Output Buffer
Transmitting OOB Signals
Both differential output signals are at the DC-bias voltage when the output buffer is disabled. The output buffer is
disabled when OOB signals are transmitted and when an output port is turned “off.” For more information, see
“Functional Descriptions,” page 4.
Output Amplitude and Pre-Emphasis
Each of the output buffers has an amplitude control input pin, the state of which sets the differential output voltage
(within normal SATA levels). Pin HIV0 corresponds to port 0, pin HIV1 corresponds to port 1, and pin HIV2
corresponds to port 2. See Table 4. Recommended output AC-coupling capacitor values are 0.01 µF. When the
amplitude control pin is HIGH, the output is configured for high voltage swing mode, which is useful for driving
extended length media such as backplanes or external cables. Setting the output to high swing mode should be done
only in controlled environments, because the output voltage exceeds the Serial ATA 1.0 differential mode
specifications.
The output buffers have a pre-emphasis circuit that is enabled when HIVx is HIGH. Pre-emphasis accentuates higher
frequency signals in a transmitted data stream. This feature takes into consideration that a signal loses amplitude and
affects the data eye opening as it goes through long trace length runs. Figure 5 shows the effects of the pre-emphasis
feature. The amplitude increase is between 20% and 30%, and the duration of the amplitude increase is between
150 ps and 300 ps.
Table 4. Output Amplitude and Pre-Emphasis
HIVx Pin State
Output Swing Level
Pre-Emphasis
0
Normal
None
1
High
Enabled
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VSC7173
Data Sheet
Pre-Emphasis Disabled
Pre-Emphasis Enabled
VOUT
VOUT
0
0
1
1
1
1
1
0
1
0
0
0
1
1
1
1
1
0
1
0
Figure 5. Pre-Emphasis Diagram
High-Speed Inputs
The high-speed input receivers are designed to achieve Serial ATA 1.0 compliance using AC-coupling as described in
the Serial ATA 1.0 specification. Recommended input AC-coupling capacitor values are 0.01 µF. The high-speed
input receiver contains an OOB signal detector as shown in Figure 6.
Input Receiver
Input
Data
InputN
OOB Detector
OOB Status
(OOBPORTx signal)
OOBSEL0
OOBSEL1
Figure 6. High-Speed Input Receiver
OOB Transfer
The VSC7173 cleanly transfers OOB signals from high-speed inputs to outputs. Two status outputs, OOBPORT0 and
OOBPORT1, indicate whether the input signal is data or a common-mode state. OOBPORT1 and OOBPORT1
correspond to port 0 and port 1, respectively. An OOB detector monitors the amplitude of an incoming signal in
parallel with each high-speed input. When the amplitude is less than the OOB threshold, the OOB status output is
driven HIGH. When the incoming amplitude is greater than the OOB threshold, the OOB status output is driven
LOW.
Setting the OOBSEL1 and OOBSEL0 inputs as shown in the following table configures the OOB threshold level for
all three ports.
Table 5. Setting the OOB Threshold Level
OOBSEL1
OOBSEL0
1
0
OOB THRESHOLD LEVEL
Nominal setting (150 mV to 250 mV)
0
0
Decrease by ~40 mV
0
1
Decrease by ~80 mV
1
1
Increase by ~40 mV
NOTE: All values are differential peak-to-peak voltages.
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VSC7173
Data Sheet
ELECTRICAL SPECIFICATIONS
DC Characteristics
Specifications are guaranteed over the recommended operating conditions listed in Table 11.
Table 6. LVTTL Inputs and Outputs
Symbol
Parameter
VOH
Output HIGH voltage
Minimum
Typical
Maximum
Unit
Condition
2.0
2.2
VDD
V
IOH = –4 mA
0.2
IOL = 4 mA
VOL
Output LOW voltage
0.0
0.4
V
VIH
Input HIGH voltage
2.0
VDD
V
VIL
Input LOW voltage
0.0
0.8
V
II
Input current (includes a weak pull-up
resistor)
–200
+50
µA
Maximum
Unit
Condition
See Table 5 on page 7.
0V < VIL < 2.4 V
Table 7. High-Speed Inputs and Outputs
Symbol
Parameter
VTH
Input threshold voltage for OOB
detection
200
mV
VOCM
High-speed output common-mode
voltage
2.0
V
Normal Swing mode.
100 Ω termination
between true and
complement outputs.
1.7
V
High Swing mode.
100 Ω termination
between true and
complement outputs.
1.5
V
VICM
High-speed input common-mode voltage
ZIN
Differential input impedance
Minimum
Typical
85
100
115
Ω
Minimum
Typical
Maximum
Unit
3.0
3.3
3.6
V
Table 8. Power Supply Requirements
Symbol
Parameter
VDD
Power supply voltage
IDD
Power supply current (total on all supply
pins)
150
170
mA
Normal Swing mode
200
235
mA
High Swing mode
Total power dissipation
540
625
mW
Normal Swing mode
720
850
mW
High Swing mode
PD
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Condition
±10% on all supplies
VSC7173
Data Sheet
AC Characteristics
Specifications are guaranteed over the recommended operating conditions listed in Table 11 on page 11.
High-Speed Input
tOFF
tON
High-Speed Output
Figure 7. Timing Waveform
Table 9. High-Speed Inputs and Outputs
Symbol
Parameter
Minimum
Maximum
Unit
tP
Condition
Propagation delay from any high-speed input
to high-speed output
0.4
2.0
ns
tON
Propagation delay from signal present at
input to output buffer turned on
3.0
12.0
ns
tOFF
Propagation delay from no signal at input to
output buffer turned off
3.0
12.0
ns
tR, tF
Rise and fall times
67
260
ps
VOUT(1)
OUTx output differential peak-to-peak
voltage swing in normal swing mode
(HIVx is LOW)
500
700
mVp-p
Measured per Serial ATA 1.0
specification, section 6.6.3.
100 Ω termination between
true and complement outputs.
VOUT(1, 2)
OUTx output differential peak-to-peak
voltage swing in high swing mode
(HIVx is HIGH)
800
1300
mVp-p
Measured per Serial ATA 1.0
specification, section 6.6.3.
100 Ω termination between
true and complement outputs.
VIN
INx input differential peak-to-peak swing with
OOBSEL1 = 1 and OOBSEL0 = 0
(OOB nominal)
275
1600
mVp-p
Measured per Serial ATA 1.0
specification.
VIN
INx input differential peak-to-peak swing with
OOBSEL1 = 0 and OOBSEL0 = 1
(OOB minimal)
225
1600
mVp-p
Measured per Serial ATA 1.0
specification, section 6.6.3.
1.5 Gbps operation,
20% to 80%.
1. Refer to Application Note AN-37 for differential measurement techniques.
2. Output swings are higher than the Serial ATA 1.0 specification to compensate for anticipated PCB or connector losses.
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VSC7173
Data Sheet
tPW
tPW
PORTSEL0,
PORTSEL1
PORTSEL0
tPSS
tPSS
PORTSEL1
tSW
tSW
tSW
Active Host Port
(Port 0 or Port 1)
* Edge sensitive sideband operation shown in timing diagram.
Note: Edge-sensitive operation shown.
Figure 8. Timing Waveform for Port Switching
Table 10. Port Switch Timing
Symbol
Parameter
Minimum
tPW
Pulse width of the port selection pins
(PORTSEL0, PORTSEL1).
4.0
ns
tPSS
Separation between rising edge transitions of the
port selection pins.
5.0
ns
Edge-sensitive operation
tSW
Switch time. The time required to make the other
host port active following an active edge
transition of the port selection pins.
ns
Applies to both level and
edge-sensitive operations
5.0
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Unit
Condition
VSC7173
Data Sheet
Operating Conditions
Table 11. Recommended Operating Conditions
Symbol
Parameter
VDD
Power supply voltage
T
Operating
temperature(1)
Minimum
Typical
Maximum
Unit
3.0
3.3
3.6
V
+90
°C
0
1. Lower limit of specification is ambient temperature, and upper limit is case temperature.
Maximum Ratings
Table 12. Absolute Maximum Ratings
Symbol
Parameter
Minimum
Maximum
Unit
VDD
Power supply voltage
–0.5
+4.0
V
VINT
LVTTL input voltage
–0.5
VDD + 0.5
V
VOUTT
LVTTL output voltage
–0.5
VDD + 0.5
V
IOT
LVTTL output current
–50
+50
mA
VINS
Serial input voltage
–0.5
VDD + 0.5
V
VOUTS
Serial output voltage
–0.5
VDD + 0.5
V
IOS
Serial output current
–50
+50
mA
TS
Storage temperature
–65
+140
°C
VESD
Electrostatic voltage discharge, human body model
–4000
+4000
V
Stresses listed under Maximum Ratings may be applied to devices one at a time without causing permanent damage. Functionality at or above the values listed is
not implied. Exposure to these values for extended periods may affect device reliability.
ELECTROSTATIC DISCHARGE
This device can be damaged by ESD. Maxim recommends that all integrated circuits
be handled with appropriate precautions. Failure to observe proper handling and
installation procedures may adversely affect reliability of the device.
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Data Sheet
PIN DESCRIPTIONS
The VSC7173 is packaged in a 32-pin, leadless quad flat pack (QFP-N) with an exposed pad.
P0SLTD
RESERVED
25
HIV2
27
P2INP
P2INN
VSS
29
P2OUTN
P2OUTP
31
VDD2
Pin Diagram
1
OOBSEL0
HIV0
P0INP
23
3
VSS
VSC7173
Top View
P0INN
VSS
21
5
Pad(1)
MODE0
VDD1
15
P1OUTP
P1OUTN
13
PORTSEL0
PORTSEL1
17
VSS
P1INN
HIV1
OOBPORT0
P1INP
11
Exposed Die Attach
(bottom side)
9
VDD0
19
7
MODE1
VDD
P0OUTN
P0OUTP
OOBSEL1
1. The exposed Die Attach Pad (DAP) is internally connected to ground and should also be connected to VSS on
the board.
Figure 9. Pin Diagram
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VSC7173
Data Sheet
Pin Identifications
Table 13. Pin Identifications
Pin Number
Signal
Type
Level
Description
O
HighSpeed
These are the high-speed differential outputs for port 0, port 1,
and port 2. These outputs must be AC-coupled.
I
HighSpeed
These are the high-speed differential inputs for port 0, port 1, and
port 2. These inputs must be AC-coupled.
I
LVTTL
These two inputs select the active port (port 0 or port 1). For more
information on the modes of operation, see Table 1 on page 4.
I
LVTTL
When HIGH, these inputs select the high voltage swing output
mode for the corresponding output buffer and enable preemphasis. See Table 4 on page 6.
I
LVTTL
These two inputs control the OOB detector threshold voltage for
all three input ports. See Table 5 on page 7 for threshold levels.
7, 6
P0OUTP, P0OUTN
15, 14
P1OUTP, P1OUTN
31, 30
P2OUTP, P2OUTN
3, 4
P0INP, P0INN
11, 12
P1INP, P1INN
27, 28
P2INP, P2INN
19
PORTSEL0
18
PORTSEL1
2
HIV0
10
HIV1
26
HIV2
24
OOBSEL0
23
OOBSEL1
1
P0SLTD
O
LVTTL
This output reports which port is selected or OOB status of port 1,
depending on the value of MODE1. See Table 2 on page 4.
9
OOBPORT0
O
LVTTL
When HIGH, this output indicates that the input signal for port 0 is
below the OOB threshold. When LOW, the input signal for port 0
is above the OOB threshold.
17
MODE0
I
LVTTL
This input is used to select the operating mode for the VSC7173
as described in Table 1 on page 4.
21
MODE1
I
LVTTL
This input is used to select the operating mode for the VSC7173
as described in Table 1 on page 4.
20
VDD
Power
3.3 V power supply for all circuits except the high-speed output
buffers.
8, 16
VDD0, VDD1
Power
32
VDD2
3.3 V output buffer power supply for P0OUTP/N, P1OUTP/N, and
P2OUTP/N, respectively.
25
Reserved
5, 13,
VSS
22, 29
Reserved for future use. Leave unconnected.
GND
Common ground.
DAP is the exposed die attach pad on the bottom of the device.
DAP
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VSC7173
Data Sheet
PACKAGE INFORMATION
The VSC7173 device is available in a lead(Pb)-free package. VSC7173XYI is a 32-pin leadless quad flat pack
(QFP-N) with an exposed pad.
Lead(Pb)-free products from Maxim comply with the temperatures and profiles defined in the joint IPC and JEDEC
standard IPC/JEDEC J-STD-020. For more information, see the IPC and JEDEC standard.
Thermal Specifications
Thermal specifications for this device are based on the JEDEC standard EIA/JESD51-2 and have been modeled using
a four-layer test board with two signal layers, a power plane, and a ground plane (2s2p PCB). For more information,
see the JEDEC standard.
Table 14. Thermal Resistances
θ JA (°C/W) vs. Airflow (ft/min)
Part Number
θ JC
0
100
200
VSC7173XYI
18.2
30.0
28.7
27.0
To achieve results similar to the modeled thermal resistance measurements, the guidelines for board design described
in the JEDEC standard EIA/JESD51 series must be applied. For information about specific applications, see the
following:
EIA/JESD51-5, Extension of Thermal Test Board Standards for Packages with Direct Thermal Attachment
Mechanisms
EIA/JESD51-7, High Effective Thermal Conductivity Test Board for Leaded Surface Mount Packages
EIA/JESD51-9, Test Boards for Area Array Surface Mount Package Thermal Measurements
EIA/JESD51-10, Test Boards for Through-Hole Perimeter Leaded Package Thermal Measurements
EIA/JESD51-11, Test Boards for Through-Hole Area Array Leaded Package Thermal Measurement
Moisture Sensitivity
This device is rated moisture sensitivity level 3 or better as specified in the joint IPC and JEDEC standard
IPC/JEDEC J-STD-020. For more information, see the IPC and JEDEC standard.
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VSC7173
Data Sheet
Package Drawing
Top View
Bottom View
D
32
25
24
1
1
0.45
Exposed Pad
Area
D2
D
17
8
16
9
D2
12° max.
A
Side View
b
e
A3
A1
L
Item
Minimum
A
0.85 nom.
0.90
A1
0
0.05
A3
b
0.20 REF
0.23
D
D2
0.35
7.00 BSC
4.95
e
L
Maximum
5.25
0.65 BSC
0.50
0.75
NOTES: Drawing not to scale.
All units in mm unless otherwise noted.
“b” is measured 0.20 to 0.25 from the terminal tip.
Figure 10. Package Drawing
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Data Sheet
Recommended Land Pattern
A
A1
D
F
A2
E
Vias (16 places)
C
G
Stencil Openings (16 places)
B
Land Pad Detail
Item
7 mm x 7 mm x 0.9 mm
Exposed Pad QFP-N
A
7.445 maximum
A1
5.325 minimum
A2
4.92 maximum
B
0.37 maximum
C
1.06
D
4.95 minimum
Comments
Thermal land dimensions
5.075 typical
5.20 maximum
E
5.10
Solder mask opening dimension
F
1.0
Stencil opening dimensions
G
1.2
Stencil opening and via spacing
NOTES: All vias 0.30 to 0.33 diameter, plugged.
Drawing not to scale.
All dimensions are in mm unless otherwise noted.
Figure 11. Recommended Land Pattern
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VSC7173
Data Sheet
ORDERING INFORMATION
The VSC7173 device is available in a lead(Pb)-free package. VSC7173XYI is 32-pin leadless quad flat pack
(QFP-N) with an exposed pad.
Lead(Pb)-free products from Maxim comply with the temperatures and profiles defined in the joint IPC and JEDEC
standard IPC/JEDEC J-STD-020. For more information, see the IPC and JEDEC standard.
Table 15. VSC7173 Ordering Information
Part Number
Description
VSC7173XYI
Lead(Pb)-free 32-pin QFP-N, 7 mm x 7 mm x 0.9 mm body
Maxim Integrated Products
120 San Gabriel Drive
Sunnyvale, CA 94086
United States
408-737-7600
www.maxim-ic.com
Copyright © 2004 to 2005 Maxim Integrated Products
Maxim cannot assume responsibility for use of any circuitry other than circuitry entirely embodied in a Maxim product. Maxim retains
the right to make changes to its products or specifications to improve performance, reliability or manufacturability. All information in
this document, including descriptions of features, functions, performance, technical specifications and availability, is subject to
change without notice at any time. While the information furnished herein is held to be accurate and reliable, no responsibility will be
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All other products or service names used in this publication are for identification purposes only, and may be trademarks or registered
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Confidential
Revision 4.1
May 23, 2005