Datasheet
LMV793, LMV794
SNOSAX6D –MARCH 2007–REVISED MARCH 2013
www.ti.com
Figure 54. R
C
= 330Ω and C = 10 nF, Gain = +1
Figure 55. LMV796 Response Gain = +1
With no increase in power consumption the decompensated op amp offers faster speed over the compensated
equivalent part. These examples used R
F
= 2 kΩ. This value is high enough to be easily driven by the
LMV793/LMV794, yet small enough to minimize the effects from the parasitic capacitance of both the PCB and
the op amp.
Note: When using the LMV793/LMV794, proper high frequency PCB layout must be followed. The GBW of these
parts is 88 MHz, making the PCB layout significantly more critical than when using the compensated
counterparts which have a GBW of 17 MHz.
TRANSIMPEDANCE AMPLIFIER
An excellent application for either the LMV793 or the LMV794 is as a transimpedance amplifier. With a GBW
product of 88 MHz these parts are ideal for high speed data transmission by light. The circuit shown on the front
page of the datasheet is the circuit used to test the LMV793/LMV794 as transimpedance amplifiers. The only
change is that VB is tied to the V
CC
of the part, thus the direction of the diode is reversed from the circuit shown
on the front page.
Very high speed components were used in testing to check the limits of the LMV793/LMV794 in a
transimpedance configuration. The photo diode part number is PIN-HR040 from OSI Optoelectronics. The diode
capacitance for this part is only about 7 pF for the 2.5V bias used (V
CC
to virtual ground). The rise time for this
diode is 1 nsec. A laser diode was used for the light source. Laser diodes have on and off times under 5 nsec.
The speed of the selected optical components allowed an accurate evaluation of the LMV793 as a
transimpedance amplifier. TIs Evaluation Board for decompensated op amps, PN 551013271-001 A, was used
and only minor modifications were necessary and no traces had to be cut.
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