Description
For a collector follower with emitter resistor, you’ll often find
that the gain per stage is no more than 10 to 50 times. The gain
increases when the emitter resistor is omitted. Unfortunately, the
distortion also increases. With a ubiquitous transistor such as the
BC547B, the gain of the transistor is roughly equal to 40 times the
collector current (Ic), provided the collector current is less than a
few milliamps. This value is in theory equal to the expression q/KT,
where q is the charge of the electron, K is Boltzmann’s constant and T
is the temperature in Kelvin.
For simplicity, and assuming room temperature, we round this value to
40. For a single stage amplifier circuit with grounded emitter it holds
that the gain Uout /Uin (for AC voltage) is in theory equal to SRc. As
we observed before, the slope S is about 40Ic. From this follows that
the gain is approximately equal to 40I cRc. What does this mean? In the
first instance this leads to a very practical rule of thumb: that gain
of a grounded emitter circuit amounts to 40·I c·Rc, which is equal to 40
times the voltage across the collector resistor.
If Ub is, for example, equal to 12 V and the collector is set to 5V,
then we know, irrespective of the values of the resistors that the gain
will be about 40R(12–5) = 280. Notable is the fact that in this way the
gain can be very high in theory, by selecting a high power supply
voltage. Such a voltage could be obtained from an isolating transformer
from the mains. An isolating transformer can be made by connecting the
secondaries of two transformers together, which results in a
galvanically isolated mains voltage.
Circuit diagram:
That means, that with a mains voltage of 240 Veff there will be about
340 V DC after rectification and filtering. If in the amplifier circuit
the power supply voltage is now 340 V and the collector voltage is 2 V,
then the gain is in theory equal to 40 x (340–2). This is more than
13,500 times! However, there are a few drawbacks in practice. This is
related to the output characteristic of the transistor. In practice, it
turns out that the transistor does actually have an output resistor
between collector and emitter.
This output resistance exists as a transistor parameter and is called
‘hoe’. In normal designs this parameter is of no consequence because it
has no noticeable effect if the collector resistor is not large. When
powering the amplifier from 340 V and setting the collector current to 1
mA, the collector resistor will have a value of 338 k. Whether the
‘hoe’-parameter has any influence depends in the type of transistor. We
also note that with such high gains, the base-collector capacitance in
particular will start to play a role.
As a consequence the input frequency may not be too high. For a
higher bandwidth we will have to use a transistor with small Cbc, such
as a BF494 or perhaps even an SHF transistor such as a BFR91A. We will
have to adjust the value of the base resistor to the new hfe. The author
has carried out measurements with a BC547B at a power supply voltage of
30 V. A value of 2 V was chosen for the collector voltage. Measurements
confirm the rule of thumb. The gain was more than 1,000 times and the
effects of ‘hoe’ and the base-collector capacitance were not noticeable
because of the now much smaller collector resistor.
Author: Gert Baars, Elektor Electronics
Source http://www.extremecircuits.net/2010/05/10000x-with-one-transistor.html
Source http://www.extremecircuits.net/2010/05/10000x-with-one-transistor.html
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