FAIRCHILD FMS6501MSA28

FMS6501
12 Input / 9 Output Video Switch Matrix with Input Clamp,
Input Bias Circuitry, and Output Drivers
Features
Description
■ 12 x 9 Crosspoint Matrix
The FMS6501 switch matrix provides flexible options for
today’s video applications. The 12 inputs that can be
routed to any of nine outputs. Each input can be routed
to one or more outputs, but only one input may be routed
to any one output. The input to output routing is controlled via an I2C™-compatible digital interface.
■ Supports SD, PS, and HD 1080i/1080p Video
■ Input Clamp / Bias Circuitry
■ AC or DC-Coupled Inputs
■ AC or DC-Coupled Outputs
■ Dual-Load (75Ω) Output Drivers with High-Impedance
■
■
■
■
■
Disable
One-to-One or One-to-Many Input to Output Switching
Programmable Gain: +6, +7, +8, or +9dB
I2CTM Compatible Digital Interface, Standard Mode
3.3V or 5V Single-Supply Operation
Lead-Free SSOP-28 Package
Each input supports an integrated clamp option to set the
output sync tip level of video with sync to ~300mV. Alternatively, the input may be internally biased to center signals without sync (Chroma, Pb, Pr) at ~1.25V. These DC
output levels are for the 6dB gain setting. Higher gain
settings increase the DC output levels accordingly. The
input clamp / bias mode is selected via I2C.
Unused outputs may be powered down to reduce power
dissipation.
Applications
■ Cable and Satellite Set-Top Boxes
■ TV and HDTV Sets
■ A/V Switchers
■ Personal Video Recorders (PVR)
■ Security / Surveillance
■ Video Distribution
■ Automotive (In-Cabin Entertainment)
Ordering Information
Part Number
Pb-Free
Temperature Range
Package
Container
Quantity
FMS6501MSA28
Yes
-40°C to 85°C
SSOP-28
Rail
47
FMS6501MSA28X
Yes
-40°C to 85°C
SSOP-28
Reel
2000
© 2004 Fairchild Semiconductor Corporation
FMS6501 Rev. 1.0.4
www.fairchildsemi.com
FMS6501 — 12 Input / 9 Output Video Switch Matrix with Input Clamp, Input Bias Circuitry, and Output Drivers
April 2007
IN1
C/B
IN2
C/B
IN12
C/B
SDA
SCL
ADDR
Programmable Gain
6, 7, 8, or 9dB
VCC (2)
GND (2)
OUT1
OUT2
OUT9
Programmable
Enable/Disable
Figure 1. FMS6501 Block Diagram
© 2004 Fairchild Semiconductor Corporation
FMS6501 Rev. 1.0.4
www.fairchildsemi.com
2
FMS6501 — 12 Input / 9 Output Video Switch Matrix with Input Clamp, Input Bias Circuitry, and Output Drivers
Block Diagram
IN1
1
28
OUT1
IN2
2
27
OUT2
IN3
3
26
OUT3
IN4
4
25
OUT4
FAIRCHILD
Pin#
Name
Type
Description
1
IN1
Input
Input, channel 1
2
IN2
Input
Input, channel 2
3
IN3
Input
Input, channel 3
4
IN4
Input
Input, channel 4
5
IN5
Input
Input, channel 5
6
IN6
Input
Input, channel 6
24
OUT5
23
OUT6
7
VCC
Input
Positive power supply
7
22
VCCO
8
GND
Input
Must be tied to ground
GND
8
21
GNDO
9
IN7
Input
Input, channel 7
IN7
9
20
OUT7
10
IN8
Input
Input, channel 8
11
IN9
Input
Input, channel 9
IN8
10
19
OUT8
12
IN10
Input
Input, channel 10
IN9
11
18
OUT9
13
IN11
Input
Input, channel 11
IN10
12
17
SDA
14
IN12
Input
Input, channel 12
IN11
13
16
SCL
15
ADDR
Input
Selects I2C address. “0” = 0x06
(0000 0110), ‘1” = 0x86 (1000 0110)
IN12
14
15
ADDR
16
SCL
Input
Serial clock for I2C port
17
SDA
Input
Serial data for I2C port
18
OUT9
Output
Output, channel 9
19
OUT8
Output
Output, channel 8
20
OUT7
Output
Output, channel 7
21
GNDO
Input
Must be tied to ground
22
VCCO
Input
Positive power supply for output drivers
23
OUT6
Output
Output, channel 6
24
OUT5
Output
Output, channel 5
25
OUT4
Output
Output, channel 4
26
OUT3
Output
Output, channel 3
27
OUT2
Output
Output, channel 2
28
OUT1
Output
Output, channel 1
IN5
5
IN6
6
VCC
FMS6501
28L SSOP
Figure 2. Pin Configuration
© 2004 Fairchild Semiconductor Corporation
FMS6501 Rev. 1.0.4
www.fairchildsemi.com
3
FMS6501 — 12 Input / 9 Output Video Switch Matrix with Input Clamp, Input Bias Circuitry, and Output Drivers
Pin Assignments
Pin Configuration
Stresses exceeding the absolute maximum ratings may damage the device. The device may not function or be operable above the recommended operating conditions and stressing the parts to these levels is not recommended. In addition, extended exposure to stresses above the recommended operating conditions may affect device reliability. The
absolute maximum ratings are stress ratings only.
Parameter
Min.
Max.
Unit
DC Supply Voltage
-0.3
6.0
V
Analog and Digital I/O
-0.3
Vcc + 0.3
V
40
mA
Output Current Any One Channel, Do Not Exceed
Reliability Information
Symbol
TJ
TSTG
TL
ΘJA
Parameter
Min.
Typ.
Junction Temperature
Storage Temperature Range
-65
Lead Temperature (Soldering, 10 seconds)
Thermal Resistance, JEDEC Standard Multilayer Test Board, Still Air
Max.
Unit
150
°C
150
°C
300
°C
50
°C/W
Recommended Operating Conditions
The Recommended Operating Conditions table defines the conditions for actual device operation. Recommended
operating conditions are specified to ensure optimal performance to the datasheet specifications. Fairchild does not
recommend exceeding them or designing to absolute maximum ratings.
Symbol
TA
VCC
Parameter
Min.
Operating Temperature Range
Typ.
Max.
Unit
85
°C
5.000
5.250
V
-40
Supply Voltage Range
3.135
Electrostatic Discharge Protection
Symbol
Parameter
Value
Unit
HBM
Human Body Model
5
kV
CDM
Charged Device Model
2
kV
© 2004 Fairchild Semiconductor Corporation
FMS6501 Rev. 1.0.4
www.fairchildsemi.com
4
FMS6501 — 12 Input / 9 Output Video Switch Matrix with Input Clamp, Input Bias Circuitry, and Output Drivers
Absolute Maximum Ratings
The I2C-compatible interface is used to program output
enables, input to output routing, input clamp / bias, and
output gain. The I2C address of the FMS6501 is 0x06
(0000 0110) with the ability to offset it to 0x86 (1000
0110) by tying the ADDR pin high.
same input channel for one-to-many routing. When the
outputs are disabled, they are placed in a high-impedance state. This allows multiple FMS6501 devices to be
paralleled to create a larger switch matrix. Typical output
power-up time is less than 500ns.
Both data and address data, of eight bits each, are written to the I2C address to access all the control functions.
The clamp / bias control bits are written to their own
internal address, since they should always remain the
same regardless of signal routing. They are set based on
the input signal connected to the FMS6501.
There are separate internal addresses for each output.
Each output’s address includes bits to select an input
channel, adjust the output gain, and enable or disable
the output amplifier. More than one output can select the
All undefined addresses may be written without effect.
Output Control Register Contents and Defaults
Control Name
Width
Type
Default
Bit(s)
Enable
1 bit
Write
0
7
Description
Channel Enable: 1=Enable, 0=Power Down(1)
Gain
2 bits
Write
0
6:5
Channel Gain: 00=6dB, 01=7dB, 10=8dB, 11=9dB
Inx
5 bits
Write
0
4:0
Input selected to drive this output: 00000=OFF(2),
00001=IN1, 00010=IN2... 01100=IN12
Notes:
1. Power down places the output in a high-impedance state so multiple FMS6501 devices may be paralleled. Power
down also de-selects any input routed to the specified output.
2. When all inputs are OFF, the amplifier input is tied to approximately 150mV and the output goes to approximately
300mV with the 6dB gain setting.
Output Control Register MAP
Register Register
Name
Address
Bit 7
Bit 6
Bit5
Bit4(1)
Bit3
Bit2
Bit1
Bit0
OUT1
0x01
Enable
Gain1
Gain0
IN4
IN3
IN2
IN1
IN0
OUT2
0x02
Enable
Gain1
Gain0
IN4
IN3
IN2
IN1
IN0
OUT3
0x03
Enable
Gain1
Gain0
IN4
IN3
IN2
IN1
IN0
OUT4
0x04
Enable
Gain1
Gain0
IN4
IN3
IN2
IN1
IN0
OUT5
0x05
Enable
Gain1
Gain0
IN4
IN3
IN2
IN1
IN0
OUT6
0x06
Enable
Gain1
Gain0
IN4
IN3
IN2
IN1
IN0
OUT7
0x07
Enable
Gain1
Gain0
IN4
IN3
IN2
IN1
IN0
OUT8
0x08
Enable
Gain1
Gain0
IN4
IN3
IN2
IN1
IN0
OUT9
0x09
Enable
Gain1
Gain0
IN4
IN3
IN2
IN1
IN0
Notes:
1. IN4 is provided for forward compatibility and should always be written as ‘0’ in the FMS6501.
Clamp Control Register Contents and Defaults
Control Name
Width
Type
Default
Bit(s)
Description
Clmp
1 bit
Write
0
7:0
Clamp / Bias selection: 1 = Clamp, 0 = Bias
Clamp Control Register Map
Register Name
Register
Address
Bit 7
Bit 6
Bit5
Bit4
Bit3
Bit2
Bit1
Bit0
CLAMP1
0x1D
Clmp8
Clmp7
Clmp6
Clmp5
Clmp4
Clmp3
Clmp2
Clmp1
CLAMP2
0x1E
Resv’d
Resv’d
Resv’d
Resv’d
Clmp12
Clmp11
Clmp10
Clmp9
© 2004 Fairchild Semiconductor Corporation
FMS6501 Rev. 1.0.4
www.fairchildsemi.com
5
FMS6501 — 12 Input / 9 Output Video Switch Matrix with Input Clamp, Input Bias Circuitry, and Output Drivers
Digital Interface
TA = 25°C, Vcc = 5V, VIN = 1Vpp, input bias mode, one-to-one routing, 6dB gain, all inputs AC coupled with
0.1µF, unused inputs AC-terminated through 75Ω to GND, all outputs AC coupled with 220µF into 150Ω
loads, referenced to 400kHz, unless otherwise noted.
Symbol
ICC
Parameter
Conditions
Supply Current1
Min.
No load, all outputs enabled
VOUT
Video Output Range
ROFF
Off Channel Output Impedance
Output disabled
1
Typ.
Max
Units
80
100
mA
2.8
Vpp
3.0
kΩ
Vclamp
DC Output Level
Clamp mode
0.2
0.3
0.4
V
Vbias
DC Output Level1
Bias mode
1.15
1.25
1.35
V
Power Supply Rejection Ratio
All channels, DC
PSRR
50
dB
Notes:
1. 100% tested at 25°C.
AC Electrical Characteristics
TA = 25°C, VCC = 5V, VIN = 1Vpp, input bias mode, one-to-one routing, 6dB gain, all inputs AC coupled with
0.1µF, unused inputs AC-terminated through 75Ω to GND, all outputs AC coupled with 220µF into 150Ω
loads, referenced to 400kHz, unless otherwise noted.
Symbol
AVSD
AVSTEP
Parameter
Channel
Gain
Gain(1) Error
Step(1)
Conditions
Min.
Typ.
Max
Units
All Channels, All Gain Settings, DC
-0.2
0
+0.2
dB
All Channels, DC
0.9
1.0
1.1
dB
f+1dB
1dB Peaking Bandwidth
VOUT = 1.4Vpp
65
MHz
f-1dB
-1dB Bandwidth
VOUT = 1.4Vpp
90
MHz
fC
-3dB Bandwidth
VOUT = 1.4Vpp
115
MHz
dG
Differential Gain
3.58MHz
0.1
%
dP
Differential Phase
3.58MHz
0.2
deg
THDSD
SD Output Distortion
VOUT = 1.4Vpp, 5MHz
0.05
%
THDHD
HD Output Distortion
VOUT = 1.4Vpp, 22MHz
0.6
%
XTALK1
Input Crosstalk
-72
dB
XTALK2
Input Crosstalk
-50
dB
XTALK3
Output Crosstalk
-68
dB
XTALK4
Output Crosstalk
1MHz, VOUT = 2Vpp(2)
15MHz, VOUT = 2Vpp(2)
1MHz, VOUT = 2Vpp(3)
15MHz, VOUT = 2Vpp(3)
-61
dB
-45
dB
NTC-7 Weighting, 4.2MHz LP,
100kHz HP
73
dB
400kHz to 100MHz, Input Referred
20
nV/rtHz
300
ns
XTALK5
Multi-Channel Crosstalk
SNRSD
Signal-to-Noise
Ratio(5)
VNOISE
Channel Noise
AMPON
Amplifier Recovery Time
Standard Video, VOUT = 2Vpp
Post
I 2C
Programming
(4)
Notes:
1. 100% tested at 25°C.
2. Adjacent input pair to adjacent output pair. Interfering input is through an open switch.
3. Adjacent input pair to adjacent output pair. Interfering input is through a closed switch.
4. Crosstalk of eight synchronous switching outputs onto single, asynchronous switching output.
5. Signal-to-Noise Ration (SNR) = 20 * log (714mV / rms noise).
© 2004 Fairchild Semiconductor Corporation
FMS6501 Rev. 1.0.4
www.fairchildsemi.com
6
FMS6501 — 12 Input / 9 Output Video Switch Matrix with Input Clamp, Input Bias Circuitry, and Output Drivers
DC Electrical Characteristics
TA = 25°C and VCC = 5V unless otherwise noted.
Symbol
Vil
Vih
Conditions
Min.
(1)
Parameter
SDA, SCL, ADDR
(1)
SDA, SCL, ADDR
Digital Input Low
Digital Input High
Typ.
Max
Units
0
1.5
V
3.0
Vcc
V
fscl
Clock Frequency
SCK
100
kHz
tr
Input Rise Time
1.5V to 3V
1000
ns
tf
Input Fall Time
1.5V to 3V
300
ns
4.7
µs
tlow
Clock Low Period
thigh
Clock High Period
4.0
µs
tSU,DAT
Data Set-up Time
300
ns
tHD,DAT
Data Hold Time
0
ns
tSU,STO
Set-up Time from Clock High to Stop
4
µs
4.7
µs
4
µs
4.7
µs
tBUF
Start Set-up Time Following a Stop
tHD,STA
Start Hold Time
tSU,STA
Start Set-up Time Following Clock Low to High
Notes:
1. 100% tested at 25°C.
SDA
tBUF
tf
tLOW
SCL
tHD,STA
tr
t HD,DAT
tSU,DAT
t HIGH
SDA
tSU,STA
tSU,STO
Figure 3. I2C Bus Timing
© 2004 Fairchild Semiconductor Corporation
FMS6501 Rev. 1.0.4
www.fairchildsemi.com
7
FMS6501 — 12 Input / 9 Output Video Switch Matrix with Input Clamp, Input Bias Circuitry, and Output Drivers
I2C BUS Characteristics
Operation
Bit Transfer
The I2C-compatible interface conforms to the I2C specification for Standard Mode. Individual addresses may
be written. There is no read capability. The interface
consists of two lines. These is a serial data line (SDA)
and a serial clock line (SCL), both of which must be
connected to a positive supply through an external
resistor. Data transfer may be initiated only when the
bus is not busy.
One data bit is transferred during each clock pulse.
The data on the SDA line must remain stable during
the HIGH period of the clock pulse. Changes in the line
during this time are interpreted as a control signal.
SCL
SDA
Data line
stable;
data valid
Change
of data
allowed
Figure 4. Bit Transfer
Start and Stop Conditions
The data and clock lines remain HIGH when the bus is
not busy. A HIGH-to-LOW transition of the data line,
while the clock is HIGH, is defined as START condition
SCL
(S). A LOW-to-HIGH transition of the data line, while
the clock is HIGH, is defined as STOP condition (P).
S
P
SDA
STOP condition
START condition
Figure 5. Definition of START and STOP conditions
© 2004 Fairchild Semiconductor Corporation
FMS6501 Rev. 1.0.4
www.fairchildsemi.com
8
FMS6501 — 12 Input / 9 Output Video Switch Matrix with Input Clamp, Input Bias Circuitry, and Output Drivers
I2C Interface
The data bytes transferred between the START and
STOP conditions from transmitter to receiver is unlimited. Each byte of eight bits is followed by an acknowledge bit. The acknowledge bit is a high-level signal put
on the bus by the transmitter, during which the master
generates an extra acknowledge-related clock pulse. A
slave receiver must generate an acknowledge after the
reception of each byte. A master receiver must generate
an acknowledge after the reception of each byte that has
been clocked out of the slave transmitter.
The device that acknowledges must pull down the SDA
line during the acknowledge clock pulse so the SDA line
is stable LOW during the HIGH period of the acknowledge-related clock pulse (set-up and hold times must be
taken into consideration). A master receiver must signal
an end of data to the transmitter by not generating an
acknowledge on the last byte clocked out of the slave. In
this event, the transmitter must leave the data line HIGH
to enable the master to generate a STOP condition.
START
condition
clock pulse for
acknowledgement
SCL FROM
MASTER
1
2
8
9
DATA OUTPUT
BY TRANSMITTER
DATA OUTPUT
BY RECEIVER
Figure 6. Acknowledgement on the I2C Bus
I2C Bus Protocol
Before any data is transmitted on the I2C bus, the device
that should respond is addressed first. The addressing is
always carried out with the first byte transmitted after the
start procedure. The I2C bus configuration for a data
write to the FMS6501 is shown in Figure 5.
1
9
1
9
SCL
SDA
A6
A5
START BY
MASTER
A4
A3
A2
A1
A0
FRAME1
R/W
D7
D6
ACK. BY
FMS6501
D5
D4
D3
D2
D1
D0
ACK. BY
FMS6501
FRAME 2
ADDRESS POINTER REGISTER BYTE
SERIAL BUS ADDRESS BYTE
1
9
SCL (CONTINUED)
SDA (CONTINUED)
D7
D6
D5
D4
D3
D2
FRAME 3
DATA BYTE
D1
D0
ACK. BY
FMS6501
STOP BY
MASTER
Figure 7. Write a Register Address to the Pointer Register, Then Write Data to the Selected Register
© 2004 Fairchild Semiconductor Corporation
FMS6501 Rev. 1.0.4
www.fairchildsemi.com
9
FMS6501 — 12 Input / 9 Output Video Switch Matrix with Input Clamp, Input Bias Circuitry, and Output Drivers
Acknowledge
Input Clamp / Bias Circuitry
Figure 9 shows the bias mode input circuit and internally
controlled voltage at the input pin for AC-coupled inputs.
The FMS6501 accommodates AC- or DC-coupled inputs.
Lowest voltage
set to 625mV
Internal clamping and bias circuitry are provided to support AC-coupled inputs. These are selectable through
the CLMP bits via the I2C compatible interface.
Video source must
be AC-coupled
For DC-coupled inputs, the device should be programmed to use the 'bias' input configuration. In this configuration, the input is internally biased to 625mV through
a 100kΩ resistor. Distortion is optimized with the output
levels set between 250mV above ground and 500mV
below the power supply. These constraints, along with
the desired channel gain, need to be considered when
configuring the input signal levels for input DC coupling.
Figure 9. Bias Mode Input Circuit
Output Configuration
The FMS6501 outputs may be either AC or DC coupled.
Resistive output loads can be as low as 75Ω, representing a dual, doubly terminated video load. High impedance, capacitive loads up to 20pF can also be driven
without loss of signal integrity. For standard 75Ω video
loads, a 75Ω matching resistor should be placed in
series to allow for a doubly terminated load. DC-coupled
outputs should be connected as shown in Figure 10.
If symmetric AC-coupled input signals are used
(chroma,Pb,Pr,Cb,Cr), the bias circuit described above
can be used to center them within the input common
range. The average DC value at the output is approximately 1.27V with a 6dB gain setting. This value
changes depending upon the selected gain setting.
Clamp Voltage
Bias Voltage
6dB
300mV
1.27V
7dB
330mV
1.43V
8dB
370mV
1.60V
9dB
420mV
1.80V
75
FMS6501
Output
Amplifier
If multiple low-impedance loads are DC coupled,
increased power and thermal issues need to be
addressed. In this case, the use of a multilayer board
with a large ground plane to help dissipate heat is recommended. If a two-layer board is used under these
conditions, an extended ground plane directly under the
device is recommended. This plane should extend at
least 0.5 inches beyond the device. PC board layout
issues are covered in the Layout Considerations section.
Lowest voltage
set to 125mV
0.1µF
75
Figure 10. DC-Coupled Load Connection
Figure 8 shows the clamp mode input circuit and the
internally controlled voltage at the input pin for AC-coupled inputs.
Video source must
be AC-coupled
0.1µF
75
With AC-coupled inputs, the FMS6501 uses a simple
clamp rather than a full DC-restore circuit. For video signals with and without sync (Y,CV,R,G,B), the lowest voltage at the output pins is clamped to approximately
300mV above ground when the 6dB gain setting is
selected.
Gain Setting
FMS6501
Input
Bias
FMS6501
Input
Clamp
75
AC-coupled loads should be configured as in Figure 11:
FMS6501
Output
Amplifier
Figure 8. Clamp Mode Input Circuit
75
220µF
75
Figure 11. AC-Coupled Load Connection
© 2004 Fairchild Semiconductor Corporation
FMS6501 Rev. 1.0.4
www.fairchildsemi.com
10
FMS6501 — 12 Input / 9 Output Video Switch Matrix with Input Clamp, Input Bias Circuitry, and Output Drivers
Applications Information
For input crosstalk, the switch is open. All inputs are in
bias mode. Channel 1 input is driven with a 1Vpp signal,
while all other inputs are AC terminated with 75Ω. All outputs are enabled and crosstalk is measured from IN1 to
any output.
Each of the outputs can be independently powered down
and placed in a high-impedance state with the ENABLE
bit. This function can be used to mute video signals, to
parallel multiple FMS6501 outputs, or to save power.
When the output amplifier is disabled, the high-impedance output presents a 3kΩ load to ground. The output
amplifier typically enters and recovers from the powerdown state in less than 300ns after being programmed.
For output crosstalk, the switch is closed. Crosstalk from
OUT1 to any output is measured.
Crosstalk from multiple sources into a given channel was
measured with the setup shown in Figure 6. Input IN1 is
driven with a 1Vpp pulse source and is connected to outputs Out1 to Out8. Input In9 is driven with a secondary,
asynchronous, gray-field video signal, and is connected
to Out9. All other inputs are AC terminated with 75Ω.
Crosstalk effects on the gray field are measured and calculated with respect to a standard 1Vpp output measured
at the load.
When an output channel is not connected to an input, the
input to that channel’s amplifier is forced to approximately 150mV. The output amplifier is still active unless
specifically disabled by the I2C interface. Voltage output
levels depend on the programmed gain for that channel.
Crosstalk
If not all inputs and outputs are needed, avoid using
adjacent channels, where possible, to reduce crosstalk.
Disable all unused channels to further reduce crosstalk
and power dissipation.
Crosstalk is an important consideration when using the
FMS6501. Input and output crosstalk are defined to represent the two major coupling modes in a typical application. Input crosstalk is crosstalk in the input pins and
switches when the interfering signal drives an open
switch. It is dominated by inductive coupling in the package lead frame between adjacent leads. It decreases
rapidly as the interfering signal moves farther away from
the pin adjacent to the input signal selected. Output
crosstalk is coupling from one driven output to another
active output. It decreases with increasing load impedance, as it is caused mainly by ground and power coupling between output amplifiers. If a signal is driving an
open switch, its crosstalk is mainly input crosstalk. If it is
driving a load through an active output, its crosstalk is
mainly output crosstalk.
TERMINATION
Bias
IN1
IN1 driven with
SD videio 1Vpp
IN9 driven with
asynchronous
SD video 1Vpp
IN2-8 + IN10-12
driven with
AC term to GND
with 75
IN9
Input and output crosstalk measurements are performed
with the test configuration shown in Figure 12.
IN12
Bias
Bias
TERMINATION
Bias
Gain = 6dB
OUT1 = 2.0Vpp
IN1
IN2 - IN12 are
AC-Term to
ground with
75
IN1 = 1Vpp
Measure crosstalk from
Channels 1-8 into Channel 9
OUT1
OUT9
Figure 13. Test Configuration for Multi-Channel
Crosstalk
Open switch
for input
crosstalk
Close switch
for output
crosstalk
IN12
Bias
Gain = 6dB
OUT1 = 2.0Vpp
Input crosstalk from IN1
to OUTx
OUT1
Output crosstalk from
OUT1 to OUTx
OUT9
Figure 12. Test Configuration for Crosstalk
© 2004 Fairchild Semiconductor Corporation
FMS6501 Rev. 1.0.4
www.fairchildsemi.com
11
FMS6501 — 12 Input / 9 Output Video Switch Matrix with Input Clamp, Input Bias Circuitry, and Output Drivers
Thermal issues are significantly reduced with AC-coupled outputs, alleviating special PC layout requirements.
FMS6501 Video Switch Matrix Applications
General layout and supply bypassing play major roles in
high-frequency performance and thermal characteristics.
Fairchild offers a demonstration board, FMS6501DEMO,
to use as a guide for layout and to aid in device testing
and characterization. The FMS6501DEMO is a 4-layer
board with a full power and ground plane. For optimum
results, follow the steps below as a basis for high frequency layout.
The increased demand for consumer multimedia systems has created a challenge for system designers to
provide cost-effective solutions to capitalize on the
growth potential in graphics display technologies. These
applications requires cost-effective video switching and
filtering solutions to deploy high-quality display technologies rapidly and effectively to the target audience. Areas
of specific interest include HDTV, media centers, and
automotive “infotainment” (includes navigation, in-cabin
entertainment, and back-up camera). In all cases, the
advantages an integrated video switch matrix provides
are high quality video switching specific to the application, as well as video input clamps and on-chip, lowimpedance output cable drivers with switchable gain.
■ Include 10µF and 0.1µF bypass capacitors.
■ Place the 10µF capacitor within 0.75 inches of the
power pin.
■ Place the 0.1µF capacitor within 0.1 inches of the
power pin.
■ Connect all external ground pins as tightly as possible,
preferably with a large ground plane under the
package.
■ Layout channel connections to reduce mutual trace
inductance.
■ Minimize all trace lengths to reduce series inductances. If routing across a board, place device such
that longer traces are at the inputs rather than the
outputs.
If using multiple, low-impedance, DC-coupled outputs,
special layout techniques may be employed to help dissipate heat.
Generally the largest application for a video switch is for
the front end of an HDTV, where it takes multiple inputs
and routes them to appropriate signal paths (main picture and picture in picture - PiP). These are normally
routed into ADCs followed by decoders. There are many
different technologies for HDTV; including LCD, Plasma,
and CRT, with similar analog switching circuitry.
An example of a HDTV application is shown in Figure 14.
This system combines a video switch matrix and two
three-channel switchable anti-aliasing filters. There are
two three-channel signal paths in the system; one for the
main picture, the other for “Picture in Picture” (PiP).
If a multilayer board is used, a large ground plane
directly under the device helps reduce package case
temperature.
VIPDEMOTM Control Software
The FMS6501 is configured via an I2C-compatible digital
interface. To facilitate demonstration, Fairchild Semiconductor had developed the VIPDEMOTM GUI-based control software to write to the FMS6501 register map. This
software is included in the FMS6501DEMO kit. Also
included is a parallel port I2C adapter and an interface
cable to connect to the demo board. Besides using the
full FMS6501 interface, the VIPDEMOTM can also be
used to control single-register read and writes for I2C.
For dual-layer boards, an extended plane can be used.
Worst-case, additional die power due to DC loading can
be estimated at (Vcc2/4Rload) per output channel. This
assumes a constant DC output voltage of Vcc/2. For 5V
Vcc with a dual-DC video load, add 25/(4*75) = 83mW,
per channel.
Figure 14. HDTV Application using the FMS6501 Video Switch Matrix
© 2004 Fairchild Semiconductor Corporation
FMS6501 Rev. 1.0.4
www.fairchildsemi.com
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FMS6501 — 12 Input / 9 Output Video Switch Matrix with Input Clamp, Input Bias Circuitry, and Output Drivers
Layout Considerations
FMS6501 — 12 Input / 9 Output Video Switch Matrix with Input Clamp, Input Bias Circuitry, and Output Drivers
Physical Dimensions
Dimensions are in millimeters unless otherwise noted.
SSOP-28
Figure 15. FMS6501 28-Lead Small Scale Outline Package (SSOP)
© 2004 Fairchild Semiconductor Corporation
FMS6501 Rev. 1.0.4
www.fairchildsemi.com
13
FMS6501 — 12 Input / 9 Output Video Switch Matrix with Input Clamp, Input Bias Circuitry, and Output Drivers
14
www.fairchildsemi.com
© 2004 Fairchild Semiconductor Corporation
FMS6501 Rev. 1.0.4