參數(shù)資料
型號: OPA642N
英文描述: Wideband, Low Distortion, Low Gain OPERATIONAL AMPLIFIER
中文描述: 寬帶,低失真,低增益運算放大器
文件頁數(shù): 9/15頁
文件大?。?/td> 243K
代理商: OPA642N
OPA642
9
is typically set up for a voltage gain of +2, compensating for
the 6dB attenuation of the voltage divider formed by the
series and shunt 75
resistors at either end of the cable. The
circuit of Figure 1 applies to this requirement if all refer-
ences to 50
resistors are replaced by 75
values. Often,
the amplifier gain is further increased to 2.2, which recovers
the additional DC loss of a typical long cable run. This
change would require the gain resistor (R
G
) in Figure 1 to be
reduced from 402
to 335
. In either case, both the gain
flatness and the differential gain/phase performance of the
OPA642 will provide exceptional results in video distribu-
tion applications. Differential Gain and Phase measure the
change in overall small-signal gain and phase for the color
subcarrier frequency (3.58MHz in NTSC systems) vs changes
in the large-signal output level (which represents luminance
information in a composite video signal). The OPA642, with
the typical 150
load of a single matched video cable,
shows less than 0.01%/0.01
°
differential gain/phase errors
over the standard luminance range for a positive video
(negative sync) signal. Similar performance would be ob-
served for negative video signals. In practice, similar perfor-
mance is achieved even with two video loads due to the
linear high-frequency output impedance of the OPA642.
SINGLE OP-AMP DIFFERENTIAL AMPLIFIER
The voltage feedback architecture of the OPA642, with its
high CMR, will provide exceptional performance in differ-
ential amplifier configurations. Figure 2 shows a typical
configuration. The starting point for this design is the selec-
tion of the R
F
value in the range of 200
to 2k
. Lower
values reduce the required R
G
increasing the load on the V
2
source and on the OPA642 output. Higher values increase
output noise and exacerbate the effects of parasitic board
and device capacitances. Following the selection of R
F
, R
G
must be set to achieve the desired inverting gain for V
2
.
Remember that the bandwidth will be set approximately by
the gain bandwidth product (GBP) divided by the noise gain
(1+ R
F
/R
G
). For accurate differential operation (i.e. good
CMR), the ratio R
2
/R
1
must be set equal to R
F
/R
G
. Usually,
it is best to set the absolute values of R
2
and R
1
equal to R
F
and R
G
respectively; this equalizes the divider resistances
and cancels the effect of input bias currents. However, it is
sometimes useful to scale the values of R
2
and R
1
in order
to adjust the loading on the driving source V
1
. In most cases,
the achievable low frequency CMR will be limited by the
accuracy of the resistor values. The 90dB CMR of the
OPA642 itself will not determine the overall circuit CMR
unless the resistor ratios are matched to better than 0.003%.
If it is necessary to trim the CMR, then R
2
is the suggested
adjustment point.
THREE OP AMP DIFFERENCING
(Instrumentation Topology)
The primary drawback of the single op-amp differential
amplifier is its relatively low input impedances. Where a
high impedance is required at the differential input, a stan-
dard instrumentation amplifier (INA) topology may be built
using the OPA642 as the differencing stage. Figure 3 shows
an example of this, in which the two input amplifiers are
packaged together as a dual voltage feedback op-amp—the
OPA2650. This approach saves board space, cost and power
compared to using two additional OPA642 devices, and still
achieves very good noise and distortion performance due to
the moderate loading on the input amplifiers. In this circuit,
the common mode gain to the output is always one due to the
four matched 1k
resistors, while the differential gain is set
by (1 + 2R
F1
/R
G
)—which is equal to 2 using the values in
Figure 3. The differential to single-ended conversion is still
performed by the OPA642 output stage. The high imped-
ance inputs allow the V
1
and V
2
sources to be terminated or
impedance matched as required without further loading by
the differential amplifier. If the V
1
and V
2
inputs are already
truly differential, such as the output from a signal trans-
former, then a single matching termination resistor may be
used between them. Remember, however, that a defined DC
signal path must always exist for the V
1
and V
2
inputs; for
the transformer case, a center-tapped secondary connected
to ground would provide an optimum DC operating point.
FIGURE 3. Wideband 3-Op Amp Differencing Amplifier.
1/2
OPA2650
1/2
OPA2650
OPA642
1k
1k
1k
R
F1
500
R
F1
500
V
1
V
2
V
O
V
O
= 2 (V
1
– V
2
)
Power Supplies and
De-coupling Not Shown
R
G
1k
1k
V
O
= R
1
– V
2
)
G
when R
R
F
2
R
1
R
F
R
G
R
F
–5V
+5V
Power Supply
De-coupling Not Shown
R
G
V
2
V
1
R
1
OPA642
R
2
FIGURE 2. High Speed, Single Amplifier Differential
Amplifier.
相關(guān)PDF資料
PDF描述
OPA642P Wideband, Low Distortion, Low Gain OPERATIONAL AMPLIFIER
OPA642PB Wideband, Low Distortion, Low Gain OPERATIONAL AMPLIFIER
OPA642U Wideband, Low Distortion, Low Gain OPERATIONAL AMPLIFIER
OPA642NB Wideband, Low Distortion, Low Gain OPERATIONAL AMPLIFIER
OPA642UB Wideband, Low Distortion, Low Gain OPERATIONAL AMPLIFIER
相關(guān)代理商/技術(shù)參數(shù)
參數(shù)描述
OPA642N/250 制造商:Rochester Electronics LLC 功能描述:- Bulk 制造商:Texas Instruments 功能描述:
OPA642N/3K 制造商:Rochester Electronics LLC 功能描述:- Bulk
OPA642N-250 制造商:未知廠家 制造商全稱:未知廠家 功能描述:Voltage-Feedback Operational Amplifier
OPA642N-3K 制造商:未知廠家 制造商全稱:未知廠家 功能描述:Voltage-Feedback Operational Amplifier
OPA642NB 制造商:BB 制造商全稱:BB 功能描述:Wideband, Low Distortion, Low Gain OPERATIONAL AMPLIFIER
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