Often, when making dc and rf measurements, it's necessary to bias a transistor
at a precise collector current (IC) and collector-emitter voltage
(VCE). In reliability tests, IC and VCE should
be maintained constant even though the device's beta may be degrading with time.
Conventional bias can't maintain constant IC and VCE
if there's a wide variation in beta (such as 5 to 500). Moreover, if the emitter
must remain grounded for RF measurements, problems arise in maintaining a constant
bias.
This circuit (Fig. 1) maintains constant
IC and VCE. The device under test (DUT) is connected to
op amp A1. The bias supply (VB) is connected to the inverting input
(pin 2) of A1. Because transistor Q1 is in the feedback loop with A1, the noninverting
input (pin 3) is also at the same potential VB. The noninverting
input is connected to the DUT's collector, and VB precisely sets
VCE. In addition, because the noninverting input doesn't draw any
current, the IC should come from the collector supply (VC).
By choosing VC and RC , the IC be precisely
set, independently of beta. However, if VB is varied, IC
will change.
To make IC independent of VB, a noninverting summing
amplifier (A2) is added (Fig. 2). With
the component values chosen, the output of A2 will always be at a potential
of VC + VB. Comparing Figure 2 with Figure 1, it can be
seen that IC is now independent of VB. Since IC
is now supplied by A2, VC need not provide large currents. With VC
= 1 V and VB = 5 V, Q1 will be biased at IC = 1 mA and
VCE = 5 V. To prevent Q1 from oscillating, capacitors should be added
at the collector and base terminals of the DUT.
