Datasheet
A(V/V) = K
x x
R
F
R
G
1
1 + e
N - V
G
V
C
LMH6505
SNOSAT4E –DECEMBER 2005–REVISED APRIL 2013
www.ti.com
As the I
RG_MAX
limit is approached with increasing the input voltage or with the lowering of R
G
, the device's
harmonic distortion will increase. Changes in R
F
will have a dramatic effect on the small signal bandwidth. The
output amplifier of the LMH6505 is a current feedback amplifier (CFA) and its bandwidth is determined by R
F
. As
with any CFA, doubling the feedback resistor will roughly cut the bandwidth of the device in half.
For more about CFAs, see the basic tutorial, OA-20, Current Feedback Myths Debunked, (literature number
SNOA376), or a more rigorous analysis, OA-13, Current Feedback Amplifier Loop Gain Analysis and
Performance Enhancements, (literature number SNOA366).
OTHER CONFIGURATIONS
1. Single Supply Operation
The LMH6505 can be configured for use in a single supply environment. Doing so requires the following:
(a) Bias pin 4 and R
G
to a “virtual half supply” somewhere close to the middle of V
+
and V
−
range. The other
end of R
G
is tied to pin 3. The “virtual half supply” needs to be capable of sinking and sourcing the
expected current flow through R
G
.
(b) Ensure that V
G
can be adjusted from 0V to 2V above the “virtual half supply”.
(c) Bias the input (pin 2) to make sure that it stays within the range of 2V above V
−
to 2V below V
+
. See the
Input Voltage Range specification in the Electrical Characteristics table. This can be accomplished by
either DC biasing the input and AC coupling the input signal, or alternatively, by direct coupling if the
output of the driving stage is also biased to half supply.
Arranged this way, the LMH6505 will respond to the current flowing through R
G
. The gain control relationship
will be similar to the split supply arrangement with V
G
measured with reference to pin 4. Keep in mind that
the circuit described above will also center the output voltage to the “virtual half supply voltage.”
2. Arbitrarily Referenced Input Signal
Having a wide input voltage range on the input (pin 2) (±3V typical), the LMH6505 can be configured to
control the gain on signals which are not referenced to ground (e.g. Half Supply biased circuits). This node
will be called the “reference node”. In such cases, the other end of R
G
which is the side not tied to pin 3 can
be tied to this reference node so that R
G
will “look at” the difference between the signal and this reference
only. Keep in mind that the reference node needs to source and sink the current flowing through R
G
.
GAIN ACCURACY
Gain accuracy is defined as the actual gain compared against the theoretical gain at a certain V
G
, the results of
which are expressed in dB. (See Figure 42).
Theoretical gain is given by:
where
• K = 0.940 (nominal) N = 1.01V
• V
C
= 79 mV at room temperature (3)
For a V
G
range, the value specified in the tables represents the worst case accuracy over the entire range. The
"Typical" value would be the difference between the "Typical Gain" and the "Theoretical Gain." The "Max" value
would be the worst case difference between the actual gain and the "Theoretical Gain" for the entire population.
GAIN MATCHING
As Figure 42 shows, gain matching is the limit on gain variation at a certain V
G
, expressed in dB, and is specified
as "±Max" only. There is no "Typical." For a V
G
range, the value specified represents the worst case matching
over the entire range. The "Max" value would be the worst case difference between the actual gain and the
typical gain for the entire population.
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