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OPA2670IRGVR Datasheet, PDF (12/25 Pages) Texas Instruments – Single Port, High Output Current VDSL2 Line Driver with Power Control
OPA2670
SBOS434 – AUGUST 2010
APPLICATION INFORMATION
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WIDEBAND CURRENT-FEEDBACK
OPERATION
The OPA2670 provides the exceptional ac
performance of a wideband current-feedback op amp
with a highly linear, high-power output stage.
Requiring only 21mA/port quiescent current, the
OPA2670 swings to within 1V of either supply rail on
a 100Ω load and delivers in excess of 700mA at room
temperature. This low-output headroom requirement,
along with supply voltage independent biasing,
provides remarkable +12V supply operation. The
OPA2670 delivers greater than 420MHz bandwidth
driving a 2VPP output into 100Ω on a +12V supply.
Previous boosted output stage amplifiers typically
suffer from very poor crossover distortion as the
output current goes through zero. The OPA2670
achieves a comparable power gain with much better
linearity. The primary advantage of a
current-feedback op amp over a voltage-feedback op
amp is that ac performance (bandwidth and
distortion) is relatively independent of signal gain.
Figure 38 shows the dc-coupled, gain of +10V/V, dual
power-supply circuit configuration used as the basis
of the +12V Electrical and Typical Characteristics. For
test purposes, the input impedance is set to 50Ω with
a resistor to ground and the output impedance is set
to 50Ω with a series output resistor. Voltage swings
reported in the Electrical Characteristics are taken
directly at the input and output pins, whereas load
powers (dBm) are defined at a matched 50Ω load.
For the circuit of Figure 38, the total effective load is
100Ω || 750Ω || 750Ω = 78.9Ω.
+12V
1/2
OPA2670
RF
750W
VIN
RG
RF
167W 750W
RL VOUT
This approach allows the user to set a source
termination impedance at the input that is
independent of the signal gain. For instance, simple
differential filters may be included in the signal path
right up to the noninverting inputs with no interaction
with the gain setting. The differential signal gain for
the circuit of Figure 38 is:
AD = 1 + 2 ´
RF
RG
(1)
Where AD = differential gain.
Figure 38 shows a value of 167Ω for the AD = +10V/V
design. Because the OPA2670 is a current feedback
(CFB) amplifier, its bandwidth is primarily controlled
with the feedback resistor value; the differential gain,
however, may be adjusted with considerable freedom
using just the RG resistor. In fact, RG may be reduced
by a reactive network that provides a very isolated
shaping to the differential frequency response.
Various combinations of single-supply or ac-coupled
gain can also be delivered using the basic circuit of
Figure 38. Common-mode bias voltages on the two
noninverting inputs pass on to the output with a gain
of +1V/V because an equal dc voltage at each
inverting node creates no current through RG. This
circuit does show a common-mode gain of +1V/V
from input to output. The source connection should
either remove this common-mode signal if undesired
(using an input transformer can provide this function),
or the common-mode voltage at the inputs can be
used to set the output common-mode bias. If the low
common-mode rejection of this circuit is a problem,
the output interface can also be used to reject that
common-mode. For instance, most modern
differential input analog-to-digital converters (ADCs)
reject common-mode signals very well, while a line
driver application through a transformer also
attenuates the common-mode signal through to the
line.
1/2
OPA2670
GDIFF = 1 +
2 ´ RF
RG
= VOUT
VIN
Figure 38. Noninverting Differential I/O Amplifier
12
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