1. Bipolar Junction Transistors (BJTs)
C H A P T E R 6
Bipolar Junction Transistors (BJTs)

2. Figure 6.1 A simplified structure of the npn transistor.
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3. Figure 6.2 A simplified structure of the pnp transistor.
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4. Figure 6.3 Current flow in an npn transistor biased to operate in the active mode. (Reverse current components due to drift of thermally generated minority carriers are not shown.)
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6. Figure 6.9 Modeling the operation of an npn transistor in saturation by augmenting the model of Fig. 6.5(c) with a forward conducting diode DC. Note that the current through DC increases iB and reduces iC.
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7. Figure 6.10 Current flow in a pnp transistor biased to operate in the active mode.
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8. Figure 6.12 Circuit symbols for BJTs.
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9. Figure 6.13 Voltage polarities and current flow in transistors biased in the active mode.
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12. Figure 6.18 Large-signal equivalent-circuit models of an npn BJT operating in the active mode in the common-emitter configuration with the output resistance ro included.
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13. Figure 6.32 Biasing the BJT amplifier at a point Q located on the active-mode segment of the VTC.
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15. Figure 6.34 Graphical construction for determining the VTC of the amplifier circuit of Fig. 6.33(a).
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18. Figure 6.38 Illustrating the definition of rπ and re.
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19. Figure 6. 39 The amplifier circuit of Fig. 6
Figure 6.39 The amplifier circuit of Fig. 6.36(a) with the dc sources (VBE and VCC) eliminated (short-circuited). Thus only the signal components are present. Note that this is a representation of the signal operation of the BJT and not an actual amplifier circuit.
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20. Figure 6.40 Two slightly different versions of the hybrid-π model for the small-signal operation of the BJT. The equivalent circuit in (a) represents the BJT as a voltage-controlled current source (a transconductance amplifier), and that in (b) represents the BJT as a current-controlled current source (a current amplifier).
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22. Figure 6.47 The hybrid- small-signal model, in its two versions, with the resistance ro included.
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23. Table 6.4 Small-Signal Models of the BJT
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24. Figure 6. 48 The three basic configurations of BJT amplifier
Figure 6.48 The three basic configurations of BJT amplifier. The biasing arrangements are not shown.
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27. Figure 6.51 Performing the analysis directly on the circuit with the BJT model used implicitly.
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28. Figure 6.52 The CE amplifier with an emitter resistance Re; (a) Circuit without bias details; (b) Equivalent circuit with the BJT replaced with its T model.
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29. Figure 6.59 Two obvious schemes for biasing the BJT: (a) by fixing VBE; (b) by fixing IB. Both result in wide variations in IC and hence in VCE and therefore are considered to be “bad.” Neither scheme is recommended.
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30. Figure 6.60 Classical biasing for BJTs using a single power supply: (a) circuit; (b) circuit with the voltage divider supplying the base replaced with its Thévenin equivalent.
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32. Figure 6.62 (a) A common-emitter transistor amplifier biased by a feedback resistor RB. (b) Analysis of the circuit in (a).
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33. Figure 6.64 Basic structure of the circuit used to realize single-stage, discrete-circuit BJT amplifier configurations.
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35. Figure 6.66 (a) A common-emitter amplifier with an emitter resistance Re. (b) Equivalent circuit obtained by replacing the transistor with its T model.
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36. Figure 6.69 Sketch of the magnitude of the gain of a CE amplifier versus frequency. The graph delineates the three frequency bands relevant to frequency-response determination.
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37. Figure P6.29(a)
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38. Figure P6.30
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39. Figure P6.34
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40. Figure P6.52
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41. Figure P6.62 (c)
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42. Figure P6.107
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