Смекни!
smekni.com

Bipolar transistors (стр. 2 из 2)

Bipolar transistors. (6.8)

The current

Bipolar transistors in a circuit of basis is guided towards to a base current of a recombination
Bipolar transistors and base current of injection
Bipolar transistors

Bipolar transistors. (6.9)

In an emitter circuit the current of injection is the total of a collector current

Bipolar transistors and base current
Bipolar transistors:

Bipolar transistors. (6.10)

The expressions (6.8) and (6.10) establish communication between currents of the transistor and valid for any circuit of insert.

The similar processes occur in n-p-n the transistor to that by variance, that instead of vacant electron sites it is necessary to speak about electrons and on the contrary. Positive directions of direct currents and supply voltages, relevant to a fissile condition, are shown in a fig. 6.3.

Reverse voltage affixed on collector junction, it is much more voltages directly switched of emitter junction, and the currents are equal emitter circuits and collector practically. Therefore load power established variable component collector current, appears much more power expended on control by a circuital current of the emitter, hence transistor has intensifying properties. These qualities in a combination to a small overall dimensions, high reliability, longevity and profitability have stipulated wide application of transistors in an electron technology.

Bipolar transistors

Fig. 6.4. Driving of carriers and currents in BT (fissile condition)

In the circuit with CE and CC (fig. 6.3) a current basises becomes control current, and the equation of a collector current (6.8) will be copied in the following aspect:

Bipolar transistors;

Bipolar transistors;

Bipolar transistors. (6.11)

where:

Bipolar transistors - transmission factor of a base current in the circuit with CE:

Bipolar transistors - unguided part of a collector current in the circuit with CE, or through current of the transistor.

For the circuit with CC an output current is the emitter current. Therefore

Bipolar transistors

or

Bipolar transistors,where
Bipolar transistors. (6.12)

4. Inverse condition. In an inverse condition emitter junction backswitched, and the collector junction is under direct voltage. Therefore in comparison with a fissile condition in an inverse condition the injection of carriers is carried out collector junction, and extractionsof carriers - emitter junction. Practically emitter and collector vary by functions and places in the circuit.

For the circuit with CB

Bipolar transistors. (6.13)

here

Bipolar transistors - inverse coefficient of transmission.

As the area of emitter junction is much less than the area collector junction and

Bipolar transistors,
Bipolar transistors

For the circuit with CC

Bipolar transistors. (6.14)

For the circuit with CE

Bipolar transistors. (6.15)

6.3. Differential coefficient of transmission of a current

In the equation (6.7) for an integrated (static) transmission factor of an emitter current

Bipolar transistors. Coefficient of injection
Bipolar transistors the efficiency of emitter junction characterizes, and coefficient of diffusive transport
Bipolar transistors characterizes processes in basis, diffusive transport and recombination of carriers, with which attends this process; coefficient M is inlet for the account of processes in collector junction and almost always M=1. The equation of a collector current
Bipolar transistors, where
Bipolar transistors is static parameter of fissile condition of insert (fissile condition), displays link between direct currents. Coefficient
Bipolar transistors is defined by the formula
Bipolar transistors and this formula displays link between stationary values of a control current
Bipolar transistors and value of an output current
Bipolar transistors.

For variable signals, which amplitude order much less grades of supply voltages, link between collector currents and emitter is defined by derivation of a relation (6.7) as functions two arguments in the conjecture

Bipolar transistors =const, i.e.

Bipolar transistors, or

Bipolar transistors. (6.16)

Bipolar transistors - differential transmission factor of an emitter current in circuit with CB, which always is more than integrated coefficient
Bipolar transistors.Calculations display, that at major levels of injection, when
Bipolar transistors (see of the formula (6.1), (6.4)), derivative
Bipolar transistors aspires to zero and
Bipolar transistors.Therefore for the analysis of a major signal integrated (static) coefficient
Bipolar transistors is always used.

In consequent viewing is not done variances between

Bipolar transistors and
Bipolar transistors.Using a label
Bipolar transistors, but in each case the applications of these magnitudes should be remembered a level of injection.

6.4. Ebers-Moll’s model

Links between currents and voltages in the transistor for four conditions of insert are well compounded with convenient and clear mathematical Ebers-Moll’s model, grounded on a dual circuit consisting of two diodes (emitter and collector), switched on meeting, and two current sources mapping interaction of these diodes (fig. 6.5).

Bipolar transistors (6.17)

Bipolar transistors. (6.18)

where

Bipolar transistors and
Bipolar transistors - thermal currents emitter and collector junctions accordingly, metered at short-circuit on exit and input accordingly (
Bipolar transistors =0 and
Bipolar transistors =0).

Bipolar transistors. (6.19)

where

Bipolar transistors and
Bipolar transistors - back currents of emitter and collector junctions measured accordingly at abruption of a collector and the emitter. With the account (6.18), (6.19) relations (6.17) are conversed to an aspect

Bipolar transistors; (6.20)

Bipolar transistors; (6.21)

Bipolar transistors. (6.22)

Bipolar transistors

Fig. 6.5. Equivalent nonlinear Ebers-Moll’s model for BT

In computing methods of the analysis of transistor circuits with the help of a computer the wide circulation was received by nonlinear model of the Gummel-Pun’s transistor, which grounded on the solution of integrated relations for charges and links exterior electrical performances a charge in basis of transistor structure. It is very precise model explaining many physical effects, but its exposition needs major number of parameters, so for the analysis in a wide frequency range 25 parameters are necessary. The sequential simplification of Gummel-Pun’s model eventually reduces in the elementary Ebers-Moll’s model. Therefore at the analysis of the concrete circuits it is necessary to search for the reasonable compromise between an exactitude of the solution and complexity of model.