NSC LMH0001_10

National Semiconductor
Application Note 2059
Gary Melchior
May 11, 2010
Introduction
LMH0002 HD/SD-SDI cable driver and the LMH0302 3G/HD/
SD-SDI cable driver. This allows a forward migration path
from SD to HD to 3G. The LMH0001 provides improved output
return loss along with a 46% power savings over the CLC001,
with typical power of 125 mW in comparison with 231 mW for
the CLC001.
Table 1 shows the key differences between the CLC001 and
LMH0001.
The LMH0001 SD-SDI cable driver can replace the CLC001
cable driver in many applications. The LMH0001 and CLC001
are both cable drivers designed to drive 75Ω coaxial cable,
primarily for the SMPTE 259M interface. The supported data
rates are similar between the two devices. Both cable drivers
are powered from a 3.3V supply and rated for industrial temperature range operation (-40°C to +85°C).
The LMH0001, the newer generation SDI cable driver, has
improved performance and is pin compatible with the
TABLE 1. CLC001 and LMH0001 Key Differences
CLC001
Supply Current (ICC) (Typical)
Package
Data Rates
Output Rise/Fall Time (Typical)
Output Interface
16-pin LLP
DC to 622 Mbps
DC to 540 Mbps
400 ps
560 ps
≥±5 kV HBM
0.05V to 3.25V common mode
1.6V + VSDI/2 to VCC - VSDI/2
common mode (self biased)
Requires external 75Ω resistor to GND
Requires external 75Ω resistor to VCC
1.91 kΩ to ground
750Ω to VCC
Compliant to SMPTE spec
Meets SMPTE spec with margin
using recommended network
RREF Resistor (800 mVP-P Output)
Output Return Loss
38 mA
8-pin SOIC
≥±7 kV HBM
ESD Rating
Input Interface
LMH0001
70 mA
How To Replace the CLC001 with
the LMH0001
Replacing the CLC001 with the LMH0001 requires a few simple steps. The device packages and pinouts are different so
this change requires a new PCB layout. To replace the
CLC001 with the LMH0001, follow these steps:
1. Check the output common mode voltage of the driving
device to determine if it is compatible with the LMH0001
input common mode range—if so, it is preferred to DC
couple the inputs, and if not, add AC coupling capacitors
in series with the inputs, prior to the input termination.
When AC coupling, remove any bias applied to the inputs
as this is not required for the LMH0001 since the inputs
are self-biased.
2. Replace the 75Ω resistors to ground on the output with
75Ω resistors to VCC. These pullup resistors should be
placed as close as possible to the LMH0001 output pins.
3.
In order to meet the SMPTE return loss specification, add
a return loss network in series with the LMH0001 outputs.
This network typically consists of a 5.6 nH inductor in
parallel with a 75Ω resistor, immediately following the
75Ω pullup. If only one output is used, the return loss
network is not necessary on the unused output.
4. For SMPTE applications, change the output coupling
capacitor from 1 µF to 4.7 µF. Using this larger AC
coupling capacitor value is good practice when dealing
with the large DC shifts associated with the SMPTE
pathological signals.
5. For 800 mVP-P output, change the RREF resistor from
1.91 kΩ connected to ground to 750Ω connected to
VCC. For 1.0 VP-P output, change the RREF resistor from
1.5 kΩ connected to ground to 590Ω connected to VCC.
Figure 1 shows the typical application for the CLC001, and
Figure 2 shows the typical application for the LMH0001.
Replacing the CLC001 Cable Driver with the LMH0001
Replacing the CLC001 Cable
Driver with the LMH0001
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FIGURE 1. CLC001 Typical Application
30123902
FIGURE 2. LMH0001 Typical Application
ential input amplitude as the CLC001. The LMH0001 inputs
are self-biased, so no DC bias voltage is necessary when the
inputs are AC coupled. When driven differentially, the
LMH0001 inputs are typically terminated with a 100Ω resistor
or two 50Ω resistor like the CLC001.
INPUT INTERFACE
The input common mode voltage range of the CLC001 is between 0.05V and 3.25V, and the minimum differential input
amplitude is 100 mV. The CLC001 inputs require a DC bias
voltage to be applied when the inputs are AC coupled, and
the VBB pin may be used for this. When driven differentially,
the CLC001 inputs are typically terminated with a 100Ω resistor placed across the input pins, or two 50Ω resistors with
a center tap capacitor to ground.
The LMH0001 input interface is similar to that of the CLC001,
but it does not support rail-to-rail inputs like the CLC001. The
input common mode voltage range of the LMH0001 is from
1.6V + VSDI/2 to VCC - VSDI/2, with the same minimum differwww.national.com
OUTPUT INTERFACE
The CLC001 outputs are designed to drive 75Ω AC-coupled
coaxial cable. They are current mode and ground referenced,
requiring 75Ω resistors to ground to generate the output voltage. The output level is controlled by the RREF resistor.
The LMH0001 outputs are also current mode and designed
to drive 75Ω AC-coupled coaxial cable. But the LMH0001
2
the LMH0001 to exceed the SMPTE return loss specification
on the SD001SQ evaluation board with the recommended
return loss network consisting of a 5.6 nH inductor in parallel
with a 75Ω resistor. Return loss is dependent on board design
so this return loss network may need to be optimized depending on the specific PCB design and BNC connector used.
OUTPUT LEVEL CONTROL (RREF RESISTOR)
The RREF resistor controls the output driver amplitude. The
output amplitude for both the CLC001 and LMH0001 is adjustable from below 800 mVP-P to above 1.0 VP-P. For the
CLC001, the RREF resistor is connected to ground, and for the
LMH0001, the RREF resistor is connected to VCC. The output
amplitude is inversely proportional to the value of RREF and
approximately linear. For the CLC001, RREF is 1.91 kΩ for
800 mVP-P output and 1.5 kΩ for 1.0 VP-P output. For the
LMH0001, RREF is 750Ω for 800 mVP-P output and 590Ω for
1.0 VP-P output.
LMH0001 Enhancements over the
CLC001
The LMH0001 is a solid upgrade and good replacement for
the CLC001. It is designed in a newer, more advanced process. The LMH0001 offers much lower power and better
output return loss. The LMH0001’s smaller, space-saving
package allows for more compact designs. In addition, the
LMH0001’s pin compatibility with HD-SDI and 3G-SDI cable
drivers offers an easy upgrade path and allows future-proof
designs.
OUTPUT RETURN LOSS
The LMH0001 output structure provides improved return loss
over the output structure used for the CLC001. This allows
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outputs are positive supply referenced and require 75Ω
pullups to VCC to generate the output voltage. Like the
CLC001, the LMH0001 output level is controlled by the
RREF resistor.
Replacing the CLC001 Cable Driver with the LMH0001
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