NSC LMH6584VV 32x16 400 mhz analog crosspoint switches, gain of 1, gain of 2 Datasheet

April 2, 2008
LMH6584/LMH6585
32x16 400 MHz Analog Crosspoint Switches, Gain of 1,
Gain of 2
General Description
Features
LMH®
The
family of products is joined by the LMH6584 and
the LMH6585 high speed, non-blocking, analog, crosspoint
switches. The LMH6584/LMH6585 are designed for high
speed, DC coupled, analog signals such as high resolution
video (UXGA and higher). The LMH6584/LMH6585 have 32
inputs and 16 outputs. The non-blocking architecture allows
an output to be connected to any input, including an input that
is already selected. With fully buffered inputs the LMH6584/
LMH6585 can be impedance matched to nearly any source
impedance. The buffered outputs of the LMH6584/LMH6585
can drive up to two back terminated video loads (75Ω load).
The outputs and inputs also feature high impedance inactive
states allowing high performance input and output expansion
for array sizes such as 32 x 32 or 64 x 16 by combining two
devices. The LMH6584/LMH6585 are controlled with a 4 pin
serial interface. Both single serial mode and addressed chain
modes are available.
The LMH6584/LMH6585 come in 144-pin LQFP packages.
They also have diagonally symmetrical pin assignments to
facilitate double sided board layouts and easy pin connections for expansion.
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32 inputs and 16 outputs
144-pin LQFP package
−3 dB bandwidth (VOUT = 2 VPP, RL = 150Ω)
400 MHz
Fast slew rate
1200 V/μs
Channel to channel crosstalk (10/100 MHz) −52/ −43 dBc
Easy to use serial programming
4 wire bus
Two programming modes
Serial & addressed modes
Symmetrical pinout facilitates expansion.
Output current
±50 mA
Applications
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Studio monitoring/production video systems
Conference room multimedia video systems
KVM (keyboard video mouse) systems
Security/surveillance systems
Multi antenna diversity radio
Video test equipment
Medical imaging
Wide-band routers & switches
Block Diagram
30045011
LMH® is a registered trademark of National Semiconductor Corporation.
TRI-STATE® is a registered trademark of National Semiconductor Corporation.
© 2008 National Semiconductor Corporation
300450
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LMH6584/LMH6585 32x16 400 MHz Analog Crosspoint Switches, Gain of 1, Gain of 2
PRELIMINARY
LMH6584/LMH6585
Storage Temperature Range
Soldering Information
Infrared or Convection (20 sec.)
Wave Soldering (10 sec.)
Absolute Maximum Ratings (Note 1)
If Military/Aerospace specified devices are required,
please contact the National Semiconductor Sales Office/
Distributors for availability and specifications.
ESD Tolerance (Note 2)
Human Body Model
Machine Model
VS
IIN (Input Pins)
IOUT
Input Voltage Range
Maximum Junction Temperature
Operating Ratings
2000V
200V
±6V
±20 mA
(Note 3)
V− to V+
+150°C
±3.3V Electrical Characteristics
−65°C to +150°C
235°C
260°C
(Note 1)
Temperature Range (Note 4)
Supply Voltage Range
Thermal Resistance
64–Pin Exposed Pad TQFP
−40°C to +85°C
±3V to ±5.5V
θJA
22°C/W
θJC
5°C/W
(Note 5)
Unless otherwise specified, typical conditions are: TA = 25°C, VS = ±3.3V, RL = 100Ω. Boldface limits apply at the temperature
extremes.
Symbol
Parameter
Conditions
Min
(Note 8)
Typ
(Note 7)
Max
(Note 8)
Units
Frequency Domain Performance
SSBW
−3 dB Bandwidth
LSBW
LMH6584, VOUT = 0.25 VPP
350
LMH6585V, VOUT = 0.5 VPP
350
LMH6584, VOUT = 1VPP, RL = 1 kΩ
375
LMH6585, VOUT = 2VPP, RL = 1 kΩ
375
LMH6584, VOUT = 1VPP, RL = 150Ω
375
LMH6585, VOUT = 2VPP, RL = 150Ω
375
50
MHz
GF
0.1 dB Gain Flatness
VOUT = 2 VPP, RL = 150Ω
DG
Differential Gain
RL = 150Ω, 3.58 MHz/4.43 MHz
%
DP
Differential Phase
RL = 150Ω, 3.58 MHz/4.43 MHz
deg
MHz
Time Domain Response
tr
Rise Time
2V Step, 10% to 90%
ns
tf
Fall Time
2V Step, 10% to 90%
ns
OS
Overshoot
2V Step
%
SR
Slew Rate
4 VPP, 40% to 60% (Note 6)
ts
Settling Time
2V Step, VOUT within 0.5%
V/µs
ns
Distortion And Noise Response
HD2
2nd Harmonic Distortion
LMH6584, 1 VPP, 10 MHz
−70
dBc
HD3
3rd
1 VPP, 10 MHz
−75
dBc
en
Input Referred Voltage Noise
>1 MHz
12
nV/
in
Input Referred Current Noise
>1 MHz
22
pA/
Harmonic Distortion
Switching Time
ns
XTLK
Crosstalk
Channel to channel, f = 100 MHz
−43
dBc
ISOL
Off Isolation
f = 100 MHz
−60
dBc
LMH6584
1.00
LMH6585
2.00
Static, DC Performance
AVOL
Open Loop Voltage Gain
VOS
Input Offset Voltage
TCVOS
Input Offset Voltage Temperature
Drift
(Note 10)
IB
Input Bias Current
Non-Inverting (Note 9)
TCIB
Input Bias Current Average Drift
Non-Inverting (Note 10)
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±3
mV
µV/°C
2
−5
µA
nA/°C
VOUT
Parameter
Output Voltage Range
Conditions
Min
(Note 8)
Typ
(Note 7)
Max
(Note 8)
Units
RL = 100Ω, LMH6584
±1.6
RL = ∞, LMH6584(Note 11)
±1.6
RL = 100Ω, LMH6585
±2.1
RL = ∞, LMH6585
±2.2
45
dB
mA
V
PSRR
Power Supply Rejection Ratio
ICC
Positive Supply Current
RL = ∞
200
IEE
Negative Supply Current
RL = ∞
194
mA
Tri State Supply Current
RST Pin > 2.0V
40
mA
Miscellaneous Performance
RIN
Input Resistance
Non-Inverting
100
kΩ
CIN
Input Capacitance
Non-Inverting
3
pF
RO
Output Resistance Enabled
Closed Loop, Enabled
300
mΩ
Output Resistance Disabled
Disabled, LMH6584
50
Output Resistance Disabled
Disabled, LMH6585
1.3
CMVR
Input Common Mode Voltage
Range
IO
Output Current
Sourcing, VO = 0 V
kΩ
±0.8
V
±45
mA
Digital Control
VIH
Input Voltage High
VIL
Input Voltage Low
2.0
V
VOH
Output Voltage High
>2.2
V
VOL
Output Voltage Low
<0.4
V
TS
Setup Time
9
ns
TH
Hold Time
9
ns
0.8
±5V Electrical Characteristics
V
(Note 5)
Unless otherwise specified, typical conditions are: TA = 25°C, AV = +2, VS = ±5V, RL = 100Ω. Boldface limits apply at the temperature extremes.
Symbol
Parameter
Conditions
Min
(Note 8)
Typ
(Note 7)
Max
(Note 8)
Units
Frequency Domain Performance
SSBW
−3 dB Bandwidth
LSBW
LMH6584, VOUT = 0.25 VPP
400
LMH6585, VOUT = 0.5 VPP
400
LMH6584, VOUT = 1VPP, RL = 1 kΩ
400
LMH6585, VOUT = 2 VPP, RL = 1 kΩ
400
LMH6584, VOUT = 1VPP, RL = 150Ω
400
LMH6585, VOUT = 2 VPP, RL = 150Ω
400
50
MHz
GF
0.1 dB Gain Flatness
VOUT = 2 VPP, RL = 150Ω
DG
Differential Gain
RL = 150Ω, 3.58 MHz/ 4.43 MHz
%
DP
Differential Phase
RL = 150Ω, 3.58 MHz/ 4.43 MHz
deg
MHz
Time Domain Response
tr
Rise Time
2V Step, 10% to 90%
1.75
ns
tf
Fall Time
2V Step, 10% to 90%
1.2
ns
OS
Overshoot
2V Step
5
%
3
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LMH6584/LMH6585
Symbol
LMH6584/LMH6585
Symbol
SR
ts
Parameter
Slew Rate
Settling Time
Conditions
Min
(Note 8)
Typ
(Note 7)
LMH6584, 2 VPP, 40% to 60%
(Note 6)
1200
LMH6585, 2 VPP, 40% to 60%
(Note 6)
1800
Max
(Note 8)
Units
V/µs
2V Step, VOUT Within 0.5%
ns
Distortion And Noise Response
HD2
2nd Harmonic Distortion
2 VPP, 5 MHz
−72
dBc
HD3
3rd
2 VPP, 5 MHz
−68
dBc
en
Input Referred Voltage Noise
>1 MHz
16
nV/
in
Input Referred Noise Current
>1 MHz
4
pA/
Harmonic Distortion
Switching Time
XTLK
Crosstalk
ISOL
Off Isolation
ns
Channel to Channel, f = 100 MHz
−43
dBc
Channel to Channel, f = 10 MHz
−52
dBc
f = 100 MHz
−60
dBc
LMH6584
1.00
LMH6585
2.00
Static, DC Performance
AVOL
Open Loop Voltage Gain
VOS
Input Offset Voltage
Input Referred
TCVOS
Input Offset Voltage Temperature
Drift
(Note 10)
IB
Input Bias Current
Non-Inverting (Note 9)
TCIB
Input Bias Current Average Drift
Non-Inverting (Note 10)
VOUT
Output Voltage Range
RL = 100Ω, LMH5484
±3.1
RL = ∞, LMH6584
±3.2
RL = 100Ω, LMH6585
±3.6
RL = ∞, LMH6585
±3.9
V/V
±2
mV
µV/°C
−7
µA
nA/°C
V
PSRR
Power Supply Rejection Ratio
DC
45
dB
XTLK
DC Crosstalk
DC, Channel to Channel
−80
dB
ISOL
DC Off Isloation
DC
−80
dB
ICC
Positive Supply Current
RL = ∞
220
mA
IEE
Negative Supply Current
RL = ∞
200
mA
Tri State Supply Current
RST Pin > 2.0V
44
mA
Miscellaneous Performance
RIN
Input Resistance
Non-Inverting
100
kΩ
CIN
Input Capacitance
Non-Inverting
1
pF
RO
Output Resistance Enabled
Closed Loop, Enabled
300
mΩ
Output Resistance Disabled
Disabled, Resistance to Ground,
LMH6584
50
Disabled, Resistance to Ground,
LMH6585
1.3
CMVR
Input Common Mode Voltage
Range
IO
Output Current
Sourcing, VO = 0 V
kΩ
±3.1
V
±60
mA
Digital Control
VIH
Input Voltage High
VIL
Input Voltage Low
VOH
Output Voltage High
>2.4
V
VOL
Output Voltage Low
<0.4
V
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2.0
V
0.8
4
V
Parameter
Conditions
Min
(Note 8)
Typ
(Note 7)
Max
(Note 8)
Units
TS
Setup Time
8
ns
TH
Hold Time
8
ns
Note 1: Absolute Maximum Ratings indicate limits beyond which damage to the device may occur. Operating Ratings indicate conditions for which the device is
intended to be functional, but specific performance is not guaranteed. For guaranteed specifications, see the Electrical Characteristics tables.
Note 2: Human Body Model, applicable std. MIL-STD-883, Method 3015.7. Machine Model, applicable std. JESD22-A115-A (ESD MM std. of JEDEC)
Field-Induced Charge-Device Model, applicable std. JESD22-C101-C (ESD FICDM std. of JEDEC).
Note 3: The maximum output current (IOUT) is determined by device power dissipation limitations.
Note 4: The maximum power dissipation is a function of TJ(MAX)and θJA. The maximum allowable power dissipation at any ambient temperature is
PD = (TJ(MAX) – TA)/ θJA. All numbers apply for packages soldered directly onto a PC Board.
Note 5: Electrical Table values apply only for factory testing conditions at the temperature indicated. No guarantee of parametric performance is indicated in the
electrical tables under conditions different than those tested.
Note 6: Slew Rate is the average of the rising and falling edges.
Note 7: Typical values represent the most likely parametric norm as determined at the time of characterization. Actual typical values may vary over time and will
also depend on the application and configuration. The typical values are not tested and are not guaranteed on shipped production material.
Note 8: Room Temperature limits are 100% production tested at 25°C. Device self heating results in TJ ≥ TA, however, test time is insufficient for TJto reach
steady state conditions. Limits over the operating temperature range are guaranteed through correlation using Statistical Quality Control (SQC) methods.
Note 9: Negative input current implies current flowing out of the device.
Note 10: Drift determined by dividing the change in parameter at temperature extremes by the total temperature change.
Note 11: This parameter is guaranteed by design and/or characterization and is not tested in production.
Ordering Information
Package
144-Pin LQFP
Part Number
Package Marking
LMH6584VV
LMH6584VV
LMH6585VV
LMH6585VV
5
Transport Media
NSC Drawing
60 Units/Tray
VNG144C
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LMH6584/LMH6585
Symbol
LMH6584/LMH6585
Block and Connection Diagram
144-Pin LQFP
30045002
Top View
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6
Unless otherwise specified, typical conditions are: TA = 25°C, AV = +1, VS = ±5V, RL = 150Ω. Boldface limits apply at the temperature extremes.
1 VPP Frequency Response
1 VPP Frequency Response
30045048
30045049
Small Signal Bandwidth
Small Signal Bandwidth
30045024
30045025
Group Delay
Group Delay Broadcast
30045041
30045054
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LMH6584/LMH6585
Typical Performance Characteristics LMH6584
LMH6584/LMH6585
Second Order Distortion (HD2) vs. Frequency
Third Order Distortion (HD3) vs. Frequency
30045026
30045028
Second Order Distortion vs. Frequency
Third Order Distortion vs. Frequency
30045029
30045027
Output Swing
Output Swing
30045031
30045030
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LMH6584/LMH6585
Output Swing over Temperature
Output Swing over Temperature
30045032
30045033
Pulse Response
Pulse Response
30045014
30045013
9
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LMH6584/LMH6585
Typical Performance Characteristics LMH6585
Unless otherwise specified, typical conditions are: TA = 25°C, AV = +2, VS = ±5V, RL = 150Ω; Boldface limits apply at the temperature extremes.
2 VPP Frequency Response
2 VPP Frequency Response
30045055
30045056
Small Signal Frequency Response
Small Signal Frequency Response
30045057
30045058
Group Delay
Group Delay
30045059
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30045060
10
LMH6584/LMH6585
Application Information
INTRODUCTION
The LMH6584/LMH6585 are high speed, fully buffered, non
blocking, analog crosspoint switches. Having fully buffered
inputs allow the LMH6584/LMH6585 to accept signals from
low or high impedance sources without the worry of loading
the signal source. The fully buffered outputs will drive 75Ω or
50Ω back terminated transmission lines with no external components other than the termination resistor. When disabled,
the outputs are in a high impedance state. The LMH6584/
LMH6585 can have any input connected to any (or all) output
(s). Conversely, a given output can have only one associated
input.
INPUT AND OUTPUT EXPANSION
The LMH6584/LMH6585 have high impedance inactive
states for both inputs and outputs allowing maximum flexibility
for Crosspoint expansion. In addition the LMH6584/LMH6585
employ diagonal symmetry in pin assignments. The diagonal
symmetry makes it easy to use direct pin to pin vias when the
parts are mounted on opposite sides of a board. As an example two LMH6584/LMH6585 chips can be combined on
one board to form either an 32 x 32 crosspoint or a 64 x 16
crosspoint. To make a 32 x 32 cross-point all 32 input pins
would be tied together (Input 0 on side 1 to input 31 on side
2 and so on) while the 16 output pins on each chip would be
left separate. To make the 64 x 16 crosspoint, the 16 outputs
would be tied together while all 64 inputs would remain independent. In the 64 x 16 configuration it is important not to have
two connected outputs active at the same time. With the 32 x
32 configuration, on the other hand, having two connected
inputs active is a valid state. Crosspoint expansion as detailed
above has the advantage that the signal path has only one
crosspoint in it at a time. Expansion methods that have cascaded stages will suffer bandwidth loss far greater than the
small loading effect of parallel expansion.
Output expansion is very straight forward. Connecting the inputs of two crosspoint switches has a very minor impact on
performance. Input expansion requires more planning. As
show in Figure 1 and Figure 2 there are two ways to connect
the outputs of the crosspoint switches. In Figure 2 the crosspoint switch outputs are connected directly together and
share one termination resistor. This is the easiest configuration to implement and has only one drawback. Because the
disabled output of the unused crosspoint (only one output can
be active at a time) has a small amount of capacitance, the
frequency response of the active crosspoint will show peaking.
As illustrated in Figure 1 each crosspoint output can be given
its own termination resistor. This results in a frequency response nearly identical to the non expansion case. There is
one drawback for the gain of 2 crosspoint, and that is gain
error. With a 75Ω termination resistor the 1250Ω resistance
of the disabled crosspoint output will cause a gain error. In
order to counteract this the termination resistors of both crosspoints should be adjusted to approximately 71Ω. This will
provide very good matching, but the gain accuracy of the system will now be dependent on the process variations of the
crosspoint resistors which have a variability of approximately
±20%.
30045042
FIGURE 1. Output Expansion
30045043
FIGURE 2. Input Expansion with Shared Termination
Resistors
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LMH6584/LMH6585
In the example in Figure 4 the resistor RL is required to provide
a load for the crosspoint output buffer. Without RLexcessive
frequency response peaking is likely and settling times of
transient signals will be poor. As the value of RL is reduced
the bandwidth will also go down. The amplifier shown in the
example is an LMH6703 this amplifier offers high speed and
flat bandwidth. Another suitable amplifier is the LMH6702.
The LMH6702 is a faster amplifier that can be used to generate high frequency peaking in order to equalize longer cable
lengths. If board space is at a premium the LMH6739 or the
LMH6734 are triple selectable gain buffers which require no
external resistors.
CROSSTALK
When designing a large system such as a video router,
crosstalk can be a very serious problem. Extensive testing in
our lab has shown that most crosstalk is related to board layout rather than the crosspoint switch. There are many ways
to reduce board related crosstalk. Using controlled
impedance lines is an important step. Using well decoupled
power and ground planes will help as well. When crosstalk
does occur within the crosspoint switch itself it is often due to
signals coupling into the power supply pins. Using appropriate
supply bypassing will help to reduce this mode of coupling.
Another suggestion is to place as much grounded copper as
possible between input and output signal traces. Care must
be taken, though, not to influence the signal trace impedances
by placing shielding copper too closely. One other caveat to
consider is that as shielding materials come closer to the signal trace the trace needs to be smaller to keep the impedance
from falling too low. Using thin signal traces will result in unacceptable losses due to trace resistance. This effect becomes even more pronounced at higher frequencies due to
the skin effect. The skin effect reduces the effective thickness
of the trace as frequency increases. Resistive losses make
crosstalk worse because as the desired signal is attenuated
with higher frequencies crosstalk increases at higher frequencies.
30045044
FIGURE 3. Input Expansion with Separate Termination
Resistors
DRIVING CAPACITIVE LOADS
Capacitive output loading applications will benefit from the
use of a series output resistor ROUT. Capacitive loads of
5 pF to 120 pF are the most critical, causing ringing, frequency
response peaking and possible oscillation. As starting values,
a capacitive load of 5 pF should have around 75 Ω of isolation
resistance. A value of 120 pF would require around 12Ω.
When driving transmission lines the 50Ω or 75Ω matching resistor normally provides enough isolation.
DIGITAL CONTROL
Block Diagram
USING OUTPUT BUFFERING TO ENHANCE RELIABILITY
The LMH6584/LMH6585 crosspoint switch can offer enhanced reliability with the use of external buffers on the
outputs. For this technique to provide maximum benefit a very
high speed amplifier such as the LMH6703 should be used,
as shown in Figure 4 .
The advantage offered by using external buffers is to reduce
thermal loading on the crosspoint switch. This reduced die
temperature will increase the life of the crosspoint. Another
advantage is enhanced ESD reliability. It is very difficult to
build high speed devices that can withstand all possible ESD
events. With external buffers the crosspoint switch is isolated
from ESD events on the external system connectors.
30045011
FIGURE 5. Block Diagram
The LMH6584/LMH6585 has internal control registers that
store the programming states of the crosspoint switch. The
logic is two staged to allow for maximum programming flexibility. The first stage of the control logic is tied directly to the
crosspoint switching matrix. This logic consists of one register
for each output that stores the on/off state and the address of
30045040
FIGURE 4. Buffered Output
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12
tion is to connect the CFG and the CS pins together for a three
wire interface. The benefit of the four wire interface is that the
chip can be configured independently of the CS pin. This
would be an advantage in a system with multiple crosspoint
chips where all of them could be programmed ahead of time
and then configured simultaneously. The four wire solution is
also helpful in a system that has a free running clock on the
CLK pin. In this case, the CS pin needs to be brought high
after the last valid data bit to prevent invalid data from being
clocked into the chip.
The three wire option provides the advantage of one less pin
to control at the expense of having less flexibility with the
configure pin. One way around this loss of flexibility would be
if the clock signal is generated by an FPGA or microcontroller
where the clock signal can be stopped after the data is
clocked in. In this case the Chip Select function is provided
by the presence or absence of the clock signal.
SERIAL PROGRAMMING MODE
Serial programming mode is the mode selected by bringing
the MODE pin low. In this mode a stream of 96-bits programs
all 16 outputs of the crosspoint. The data is fed to the chip as
shown in the Serial Mode Data Frame tables below (four tables are shown to illustrate the pattern). The tables are arranged such that the first bit clocked into the crosspoint
register is labeled bit number 0. The register labeled Load
Register in the block diagram is a shift register. If the chip
select pin is left low after the valid data is shifted into the chip
and if the clock signal keeps running then additional data will
be shifted into the register, and the desired data will be shifted
out.
Also illustrated are the timing relationships for the digital pins
in the Timing Diagram for Serial Mode shown below. It is important to note that all the pin timing relationships are important, not just the data and clock pins. One example is that the
Chip Select pin (CS) must transition low before the first rising
edge of the clock signal. This allows the internal timing circuits
to synchronize to allow data to be accepted on the next falling
edge. After the final data bit has been clocked in, the chip
select pin must go high, then the clock signal must make at
least one more low to high transition. As shown in the timing
diagram, the chip select pin state should always occur while
the clock signal is low. The configure (CFG) pin timing is not
so critical, but it does need to be kept low until all data has
been shifted into the crosspoint registers.
THREE WIRE VS. FOUR WIRE CONTROL
There are two ways to connect the serial data pins. The first
way is to control all four pins separately, and the second op-
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LMH6584/LMH6585
which input to connect to. These registers are not directly accessible by the user. The second level of logic is another bank
of registers identical to the first, but set up as shift registers.
These registers are accessed by the user via the serial input
bus. As described further below, there are two modes for programing the LMH6584/LMH6585, Serial Mode and Addressed Mode.
The LMH6584/LMH6585 are programmed via a serial input
bus with the support of four other digital control pins. The serial bus consists of a clock pin (CLK), a serial data in pin
(DIN), and a serial data out pin (DOUT). The serial bus is gated
by a chip select pin (CS). The chip select pin is active low.
While the chip select pin is high all data on the serial input pin
and clock pins is ignored. When the chip select pin is brought
low the internal logic is set to begin receiving data by the first
positive transition (0 to 1) of the clock signal. The chip select
pin must be brought low at least 5 ns before the first rising
edge of the clock signal. The first data bit is clocked in on the
next negative transition (1 to 0) of the clock signal. All input
data is read from the bus on the negative edge of the clock
signal. Once the last valid data has been clocked in, the chip
select pin must go high then the clock signal must make at
least one more low to high transition. Otherwise invalid data
will be clocked into the chip. The data clocked into the chip is
not transferred to the crosspoint matrix until the CFG pin is
pulsed high. This is the case regardless of the state of the
MODE pin. The CFG pin is not dependent on the state of the
chip select pin. If no new data is clocked into the chip subsequent pulses on the CFG pin will have no affect on device
operation.
The programming format of the incoming serial data is selected by the MODE pin. When the MODE pin is HIGH the
crosspoint can be programmed one output at a time by entering a string of data that contains the address of the output
that is going to be changed (Addressed Mode). When the
MODE pin is LOW the crosspoint is in Serial Mode. In this
mode the crosspoint accepts a 40 bit array of data that programs all of the outputs. In both modes the data fed into the
chip does not change the chip operation until the configure
pin is pulsed high. The configure and mode pins are independent of the chip select pin.
LMH6584/LMH6585
30045009
Timing Diagram for Serial Mode
Serial Mode Data Frame (First Two Words)
Output 0
Output 1
Input Address
LSB
0
Off =
1
TRI-STATE®,
2
3
On = 0
Input Address
MSB
Off = 1
LSB
4
5
6
7
On = 0
8
9
MSB
Off = 1
10
11
Bit 0 is first bit clocked into device.
Serial Mode Data Frame (Continued)
Output 2
Output 3
Input Address
LSB
12
13
14
15
On = 0
Input Address
MSB
Off = 1
LSB
16
17
18
19
On = 0
20
21
MSB
Off = 1
22
23
MSB
Off = 1
82
83
MSB
Off = 1
94
95
Serial Mode Data Frame (Continued)
Output 12
Output 13
Input Address
LSB
72
73
74
75
On = 0
Input Address
MSB
Off = 1
LSB
76
77
78
79
On = 0
80
81
Serial Mode Data Frame (Last Two Words)
Output 14
Output 15
Input Address
LSB
84
85
86
87
On = 0
Input Address
MSB
Off = 1
LSB
88
89
90
Bit 39 is last bit clocked into device.
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14
91
On = 0
92
93
30045010
Timing Diagram for Addressed Mode
Addressed Mode Word Format
Output Address
Input Address
LSB
0
1
2
MSB
LSB
3
4
5
TRISTATE
6
7
MSB
1 = TRISTATE
0 = On
8
9
Bit 0 is first bit clocked into device.
15
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LMH6584/LMH6585
the data and clock pins. One example is that the Chip Select
pin (CS) must transition low before the first rising edge of the
clock signal. This allows the internal timing circuits to synchronize to allow data to be accepted on the next falling edge.
After the final data bit has been clocked in, the chip select pin
must go high, then the clock signal must make at least one
more low to high transition. As shown in the timing diagram,
the Chip Select pin state should always occur while the clock
signal is low. The configure (CFG) pin timing is not so critical,
but it does need to be kept low until all data has been shifted
into the crosspoint registers.
ADDRESSED PROGRAMMING MODE
Addressed programming mode makes it possible to change
only one output register at a time. To utilize this mode the
mode pin must be High. All other pins function the same as
in serial programming mode except that the word clocked in
is 8 bits and is directed only at the output specified. In addressed mode the data format is shown in the table titled
Addressed Mode Word Format.
Also illustrated are the timing relationships for the digital pins
in the Timing Diagram for Addressed Mode. It is important to
note that all the pin timing relationships are important, not just
LMH6584/LMH6585
the first chip (invalid data). When a full 96 bits have been
clocked into the first chip the next clock cycle begins moving
the first frame of the new configuration data into the second
chip. With a full 192 clock cycles both chips have valid data
and the Chip Select pin of both chips should be brought high
to prevent the data from overshooting. A configure pulse will
activate the new configuration on both chips simultaneously,
or each chip can be configured separately. The mode, Chip
Select, configure, and clock pins of both chips can be tied
together and driven from the same sources.
DAISY CHAIN OPTION IN SERIAL MODE
The LMH6584/LMH6585 support daisy chaining of the serial
data stream between multiple chips. This feature is available
only in the Serial Programming Mode. To use this feature serial data is clocked into the first chip DIN pin, and the next chip
DIN pin is connected to the DOUT pin of the first chip. Both chips
may share a Chip Select signal, or the second chip can be
enabled separately. When the Chip Select pin goes low on
both chips a double length word is clocked into the first chip.
As the first word is clocking into the first chip, the second chip
is receiving the data that was originally in the shift register of
30045012
Timing Diagram for Daisy Chain Operation
SPECIAL CONTROL PINS
should be budgeted 30 mW of power. For a typical application
with one video load for each output this would be a total power
The LMH6584/LMH6585 have two special control pins that
of 2.5W. With a typical θJA of 22°C/W this will result in the
function independent of the serial control bus. One of these
silicon being 55°C over the ambient temperature. A more agpins is the reset (RST) pin. The RST pin is active high meangressive application would be two video loads per output
ing that at a logic 1 level the chip is configured with all outputs
which would result in 3W of power dissipation. This would redisabled and in a high impedance state. The RST pin prosult in a 66°C temperature rise. The QFP package thermal
grams all the registers with input address 0 and all the outputs
performance can be significantly enhanced with an external
are turned off. In this configuration the device draws only 40
heat sink and by providing for moving air ventilation. Also, be
mA. The reset pin can be used as a shutdown function to resure to calculate the increase in ambient temperature from all
duce power consumption. The other special control pin is the
devices operating in the system case. Because of the high
broadcast (BCST) pin. The BCST pin is also active high and
power output of this device, thermal management should be
sets all the outputs to the on state connected to input 0. Both
considered very early in the design process. Generous pasof these pins are level sensitive and require no clock signal.
sive venting and vertical board orientation may avoid the need
The two special control pins overwrite the contents of the
for fan cooling provided a large heat sink is used. Also, the
configuration register.
LMH6584/LMH6585 can be operated with a ±3.3V power
THERMAL MANAGEMENT
supply. This will cut power dissipation substantially while only
reducing bandwidth by about 10% (2 VPP output). The
The LMH6584/LMH6585 are high performance device that
LMH6584/LMH6585 are fully characterized and factory tested
produces a significant amount of heat. With a ±5V supply, the
at the ±3.3V power supply condition for applications where
LMH6584/LMH6585 will dissipate approximately 2W of idling
reduced power is desired.
power with all outputs enabled. Idling power is calculated
based on the typical supply current of 200 mA and a 10V
The recommended heat sink is AAVD/Thermalloy part #
supply voltage. This power dissipation will vary within the
375024B60024G. This heat sink is designed to be used with
range of 1.8W to 2.2W due to process variations. In addition,
solder anchors #125700D00000G. This heat sink is larger
each equivalent video load (150Ω) connected to the outputs
then the LMH6584/LMH6585 package in order to provide
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16
PRINTED CIRCUIT LAYOUT
Generally, a good high frequency layout will keep power supply and ground traces away from the input and output pins.
Parasitic capacitances on these nodes to ground will cause
frequency response peaking and possible circuit oscillations
(see Application Note OA-15 for more information). If digital
control lines must cross analog signal lines (particularly inputs) it is best if they cross perpendicularly. National Semiconductor suggests the following evaluation boards as a
guide for high frequency layout and as an aid in device testing
and characterization National Semiconductor offers an evaluation board which can be found on the LMH6584 and
LMH6585 Product Folder.
30045053
FIGURE 6. Maximum Dissipation vs. Ambient
Temperature
17
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LMH6584/LMH6585
maximum heat dissipation, a smaller heat sink can be selected if forced air circulation will be used. With natural convection
the heat sink will reduce the θJA from 22°C/W to approximately
11°C/W. Using a fan will increase the effectiveness of the heat
sink considerably by reducing θJA to approximately 5°C/W.
When doing thermal design it is important to note that everything from board layout to case material and case venting will
impact the actual θJA of the total system. The θJA specified in
the datasheet is for a typical board layout with external case
enclosing the board.
LMH6584/LMH6585
Physical Dimensions inches (millimeters) unless otherwise noted
144-Pin LQFP
NS Package Number VNG144C
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18
LMH6584/LMH6585
Notes
19
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LMH6584/LMH6585 32x16 400 MHz Analog Crosspoint Switches, Gain of 1, Gain of 2
Notes
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