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| The quiescent point of operation is typically near the middle of the dc ''load line''. <!-- reasons to be inserted here later --> The process of obtaining certain dc collector current at a certain dc collector voltage by setting up operating point is called biasing. | The quiescent point of operation is typically near the middle of the dc ''load line''. <!-- reasons to be inserted here later --> The process of obtaining certain dc collector current at a certain dc collector voltage by setting up operating point is called biasing. | ||
| '''Quiescent current''' is the current that flows in an ] when no load is present. This term is commonly used in ] of ] and voltage regulator circuits. It is basically the current which flows through a component/circuit without actually contributing in any way to the load and usually of the order of ] to microamperes. | |||
| After establishing the operating point, when input signal is applied, the Q-pt should not move either to saturation or cut-off region. However this unwanted shift might occur due to various reasons. | After establishing the operating point, when input signal is applied, the Q-pt should not move either to saturation or cut-off region. However this unwanted shift might occur due to various reasons. | ||
Revision as of 23:02, 14 May 2007
"Biasing" redirects here. For other uses, see Biasing (disambiguation).Biasing in electronics is the method of establishing predetermined voltages and/or currents at various points of a circuit to set the appropriate operating point.
Requirement
In electronics, a bias point, also known an operating point, quiescent point or Q-point, is a dc voltage which, when applied to a device, causes it to operate in a certain desired fashion. The term is normally used in connection with devices such as transistors and diodes which are used in amplification or rectification.
Linear circuits involving transistors typically require a specific P-n junction voltage to operate correctly, which can be achieved using a biasing circuit. The method of keeping a device to operate in the active region is also referred to as biasing of the circuit. In amplifiers, a small input signal gives larger output signal without any change in its general shape. Before applying ac signal, proper biasing of the transistor is necessary.
For example, for Bipolar Junction Transistors the bias point would keep the transistor operating in the active mode, drawing a DC current. A small signal is then applied on top of this bias voltage, thereby either modulating or switching the current, depending on the design of the circuit. The input dc voltage is chosen to satisfy the required large signal parameters.
The quiescent point of operation is typically near the middle of the dc load line. The process of obtaining certain dc collector current at a certain dc collector voltage by setting up operating point is called biasing.
Quiescent current is the current that flows in an electrical circuit when no load is present. This term is commonly used in circuit analysis of electronic amplifier and voltage regulator circuits. It is basically the current which flows through a component/circuit without actually contributing in any way to the load and usually of the order of milliamperes to microamperes.
After establishing the operating point, when input signal is applied, the Q-pt should not move either to saturation or cut-off region. However this unwanted shift might occur due to various reasons.
Reasons for Shift of Q-pt
The shifting of operating point is due to two major reasons -
1. Parameters of transistor depend on temperature. As it increases, leakage current due to minority charge carriers (ICBO) increases. As ICBO increases, ICEO also increases, causing increase in collector current IC. This produces heat at the collector junction. This process repeat, and finally Q-pt may shift into saturation region. Sometimes the excess heat produced at the junction may even burn the transistor. This is known as thermal runaway.
2. When a transistor is replaced by another of the same type, the Q-pt may shift, due to change in parameters of transistor such as current gain () which changes from unit to unit.
) which changes from unit to unit.
To avoid shift of Q-pt, bias-stabilization is necessary. Various biasing circuits can be used for this purpose.
Requirements of Biasing Circuit
- Q-pt is established in center of active region of transistor characteristic. It should not shift to saturation region or cut-off region, when input is applied.
- Q-pt should be independent of transistor parameters ie. should not shift if transistor is replaced by another of the same type.
- Collector current should be stabilized against changes in temperature.
- The circuit must be practical in its implementation, and cost-effective.
Types of Transistor Biasing Circuits
There are five main types of biasing circuits used with Bipolar transistors.
- Fixed bias
- Collector-to-base bias
- Fixed bias with emitter resistor
- Voltage divider bias
- Emitter bias
Configurational Bias
There are three configurations of a transistor. Configuration is the method of connecting any one terminal of transistor common to both input and output circuits. The three types are listed below.
1. Common base (Grounded base) (CB)
- Here base is common to both input and output. Emitter-base jn is fwd-biased and collector-base jn is rev-biased.
See full article: Common base
- Here base is common to both input and output. Emitter-base jn is fwd-biased and collector-base jn is rev-biased.
2. Common emitter (CE)
- Here emitter terminal is common to both input and output. Emitter-base jn is fwd-biased and collector-base jn is reverse biased.
See full article: Common emitter
- Here emitter terminal is common to both input and output. Emitter-base jn is fwd-biased and collector-base jn is reverse biased.
3. Common collector (Emitter follower) (CC)
- Here collector terminal is common to both input and output. Load is connected to emitter.
See full article: Common collector
- Here collector terminal is common to both input and output. Load is connected to emitter.
Comparison
| Parameter | CB | CE | CC |
|---|---|---|---|
| Phase shift between input and output | zero | 180 | zero |
| Current gain | less than 1 | high | high |
| Voltage gain | high | high | less than 1 |
| Power gain | moderate | high | low to moderate |
| Input resistance | low | moderate | high |
| Output resistance | high | moderate | low |
Sources
- Sedra, Adel; Smith, Kenneth (2004). Microelectronic Circuits. Oxford University Press. ISBN 0-19-514251-9.
{{cite book}}: CS1 maint: multiple names: authors list (link)