Bipolar transistors must be properly biased to operate correctly. In circuits made with individual devices (discrete circuits), biasing networks consisting of resistors are commonly employed. Much more elaborate biasing arrangements are used in integrated circuits, for example, bandgap voltage references and current mirrors. The voltage divider configuration achieves the correct voltages by the use of resistors in certain patterns. By selecting the proper resistor values, stable current levels can be achieved that vary only little over temperature and with transistor properties such as β.
The operating point of a device, also known as bias point, quiescent point, or Q-point, is the point on the output characteristics that shows the DC collector–emitter voltage (Vce) and the collector current (Ic) with no input signal applied.
A bias network is selected to stabilize the operating point of the transistor, by reducing the following effects of device variability, temperature, and voltage changes:[1]
A bias circuit may be composed of only resistors, or may include elements such as temperature-dependent resistors, diodes, or additional voltage sources, depending on the range of operating conditions expected.
For analog operation of a class-A amplifier, the Q-point is placed so the transistor stays in active mode (does not shift to operation in the saturation region or cut-off region) across the input signal's range. Often, the Q-point is established near the center of the active region of a transistor characteristic to allow similar signal swings in positive and negative directions.
For digital operation, the Q-point is instead chosen so the transistor switches from the "on" (saturation) to the "off" (cutoff) state.
At constant current, the voltage across the emitter–base junction VBE of a bipolar transistor decreases by 2 mV (silicon) and 1.8 mV (germanium) for each 1 °C rise in temperature (reference being 25 °C). By the Ebers - Moll model, if the base - emitter voltage VBE is held constant and the temperature rises, the current through the base–emitter junction IB will increase, and thus the collector current IC will also increase. Depending on the bias point, the power dissipated in the transistor may also increase, which will further increase its temperature and exacerbate the problem. This deleterious positive feedback results in thermal runaway.[2] There are several approaches to mitigate bipolar transistor thermal runaway. For example,
The following discussion treats five common biasing circuits used with class-A bipolar transistor amplifiers:
This form of biasing is also called base bias or fixed resistance biasing.
In the given fixed bias circuit,For a given transistor, Vbe doesn't vary significantly during use. And since Rb and the DC voltage source Vcc are constant, the base current Ib also doesn't vary significantly. Thus this type of biasing is called fixed bias.
The common-emitter current gain of a transistor (specified as a range on its data sheet as FE or ), allows us to obtain as well:Now Vce can be determined:Thus an operating point for a transistor can be set using Rb and Rc.
Advantages:
Disadvantages:
Usage:
Due to the above inherent drawbacks, fixed bias is rarely used in linear circuits (i.e., those circuits which use the transistor as a current source). Instead, it is often used in circuits where the transistor is used as a switch. However, one application of fixed bias is to achieve crude automatic gain control in the transistor by feeding the base resistor from a DC signal derived from the AC output of a later stage.
This configuration employs negative feedback to prevent thermal runaway and stabilize the operating point. In this form of biasing, the base resistor
Rb
Vcc
Rc
From Kirchhoff's voltage law, the voltage
V | |
Rb |
Rb
V | |
Rb |
=Vcc-d{\overbrace{(Ic+Ib)Rc
By the Ebers - Moll model,
Ic=\betaIb
V | |
Rb |
=Vcc-(\overbrace{\betaIb
From Ohm's law, the base current
Ib=
V | |
Rb |
/Rb
\overbrace{IbRb
Hence, the base current
Ib
Ib=
Vcc-Vbe | |
Rb+(\beta+1)Rc |
If
Vbe
Ic
Ic
Rc
V | |
Rb |
Rb
Ib
Ic
Advantages:
Vcc
Vcc
Disadvantages:
Rb
Ic
\beta
\beta
Rc
Rb
Rc
Vcc
Rb
Rb
Usage:In this configuration, which is known as "voltage-shunt feedback', the output voltage is sensed and the feedback signal (a current) is applied in shunt (i.e., in parallel with the input). This means that the input impedance "looking into the base" is actually reduced. This can easily be verified by application of Miller's Theorem. This situation is similar to that of an inverting op-amp circuit where the input impedance of the amplifier at the virtual earth is near zero and the overall input impedance is determined by the external series resistor. Due to the gain reduction from feedback, this biasing form is used only when the trade-off for stability is warranted. Adding an emitter resistor to this circuit will increase the input impedance
The fixed bias circuit is modified by attaching an external resistor to the emitter. This resistor introduces negative feedback that stabilizes the Q-point. From Kirchhoff's voltage law, the voltage across the base resistor isFrom Ohm's law, the base current isThe way feedback controls the bias point is as follows. If Vbe is held constant and temperature increases, emitter current increases. However, a larger Ie increases the emitter voltage Ve = IeRe, which in turn reduces the voltage VRb across the base resistor. A lower base-resistor voltage drop reduces the base current, which results in less collector current because Ic = β Ib. Collector current and emitter current are related by Ic = α Ie with α ≈ 1, so the increase in emitter current with temperature is opposed, and the operating point is kept stable.
Similarly, if the transistor is replaced by another, there may be a change in Ic (corresponding to change in β-value, for example). By similar process as above, the change is negated and operating point kept stable.
For the given circuit,Advantages:
The circuit has the tendency to stabilize operating point against changes in temperature and β-value.
Disadvantages:
Usage:
The feedback also increases the input impedance of the amplifier when seen from the base, which can be advantageous. Due to the above disadvantages, this type of biasing circuit is used only with careful consideration of the trade-offs involved.
Collector-Stabilized Biasing.
The voltage divider is formed using external resistors R1 and R2. The voltage across R2 forward biases the emitter junction. By proper selection of resistors R1 and R2, the operating point of the transistor can be made independent of β. In this circuit, the voltage divider holds the base voltage fixed (independent of base current), provided the divider current is large compared to the base current. However, even with a fixed base voltage, collector current varies with temperature (for example) so an emitter resistor is added to stabilize the Q-point, similar to the above circuits with emitter resistor. The voltage divider configuration achieves the correct voltages by the use of resistors in certain patterns. By manipulating the resistors in certain ways you can achieve more stable current levels without having β value affect it too much.
In this circuit the base voltage, , across
R2
Ib<<I1=Vb/R1
It is also known thatFor the given circuit,Advantages:
Disadvantages:
\approx \frac, which is approximately the case ifwhere R1 || R2 denotes the equivalent resistance of R1 and R2 connected in parallel.
Usage:
The circuit's stability and merits as above make it widely used for linear circuits.
The standard voltage divider circuit discussed above faces a drawback – AC feedback caused by resistor Re reduces the gain. This can be avoided by placing a capacitor (Ce) in parallel with Re, as shown in circuit diagram.
Advantages:
Rc/Re
Disadvantages:
When a split supply (dual power supply) is available, this biasing circuit is the most effective. It provides zero bias voltage at the emitter or collector for load. The negative supply Vee is used to forward-bias the emitter junction through Re. The positive supply Vcc is used to reverse-bias the collector junction.
If Rb is small enough, base voltage will be approximately zero. Therefore, emitter current is,Advantages:
Disadvantages:
Class B and AB amplifiers employ 2 active devices to cover the complete 360 deg of input signal flow. Each transistor is therefore biased to perform over approximately 180 deg of the input signal. Class B bias is when the collector current Ic with no signal is just conducting (about 1% of maximum possible value). Class-AB bias is when the collector current Ic is about of maximum possible value. The class-AB push–pull output amplifier circuit below could be the basis for a moderate-power audio amplifier.
Q3 is a common emitter stage that provides amplification of the signal and the DC bias current through D1 and D2 to generate a bias voltage for the output devices. The output pair are arranged in class-AB push–pull, also called a complementary pair. The diodes D1 and D2 provide a small amount of constant voltage bias for the output pair, just biasing them into the conducting state so that crossover distortion is minimized. That is, the diodes push the output stage into class-AB mode (assuming that the base-emitter drop of the output transistors is reduced by heat dissipation).
This design automatically stabilizes its operating point, since overall feedback internally operates from DC up through the audio range and beyond. The use of fixed diode bias requires the diodes to be both electrically and thermally matched to the output transistors. If the output transistors conduct too much, they can easily overheat and destroy themselves, as the full current from the power supply is not limited at this stage.
A common solution to help stabilize the output device operating point is to include some emitter resistors, typically an ohm or so. Calculating the values of the circuit's resistors and capacitors is done based on the components employed and the intended use of the amplifier.