1. Section 5.6 Small Signal Model & Analysis

2. Quiz No 1 DE 27 (CE)
State the purpose and four steps (each) that are to be taken for carrying out
DC Analysis
(b) Small signal Analysis

3. The operation of the transistor as an amplifier.

4. Conceptual circuit with the signal source eliminated .
(vbe =0)
sedr42021_0548a.jpg

5. DC Analysis Signal source eliminated
Active Mode Verification
VC>VB-0.4 V

6. The collector Current & Trans-conductance

7. The collector Current & Trans-conductance
For vbe<< VT, the transistor behaves as a
voltage-controlled current device
The trans-conductance of the controlled source is gm
Output resistance is infinity

8. Linear operation of the transistor under the small-signal condition:
sedr42021_0549.jpg

9. Base Current & Input Resistance at the Base

10. Emitter Current & Input Resistance @ Emitter

11. Voltage Gain

12. DC-AC Models

13. Large Signal Model
Small Signal Model

14. The amplifier circuit
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15. Figure Two slightly different versions of the simplified hybrid-p model for the small-signal operation of the BJT.
sedr42021_0551a.jpg

16. Figure 5.52 Two slightly different versions of what is known as the T model of the BJT.
sedr42021_0552a.jpg

17. Small Signal Analysis Coupling Capacitors
Couples the input signal vi to the emitter while blocks the DC signals
Don’t let dc biasing established by VCC &VEE be disturbed. when vi is connected
Capacitor is of very large value –infinite, acts as short circuit at signal frequency of interest.

18. Application (Steps) : Small Signal Model
Suppress ac independent sources
ac Voltage Sources be short circuited
ac Current Sources be open circuited
Capacitors be Open circuited
Determine DC operating Point IC
Suppress DC independent sources
DC Voltage Sources be short circuited
DC Current Sources be open circuited
Capacitors be short circuited
Replace BJT with small signal Model
Analyze the resulting circuit of find voltage gain & input/output resistance
Active Mode Verification
VBE > 0.7 V
VC> VB-0.4 V
Small Signal Analysis

19. Figure 5.53 Example 5.14: (a) circuit; (b) dc analysis;
sedr42021_0553a.jpg
Β = 100 Find Voltage Gain

20. Figure 5.53 Example 5.14: (a) circuit; (c) small-signal model.

21. Figure 5.54 Signal waveforms in the circuit of Fig. 5.53.
sedr42021_0554a.jpg

22. Figure 5.55 Example 5.16: (a) Common Base circuit; (b) dc analysis;
sedr42021_0555a.jpg

23. Figure 5.55 Example 5.16: (a) circuit; (c) small-signal model;
sedr42021_0555a.jpg

24. Figure 5.55 Example 5.16: (a) circuit; (d) small-signal analysis performed directly on the circuit.
sedr42021_0555a.jpg

25. Figure 5. 56 Distortion in output signal due to transistor cutoff
Figure Distortion in output signal due to transistor cutoff. Note that it is assumed that no distortion due to the transistor nonlinear characteristics is occurring.
sedr42021_0556.jpg

26. Figure 5. 57 Input and output waveforms for the circuit of Fig. 5. 55
Figure Input and output waveforms for the circuit of Fig Observe that this amplifier is noninverting, a property of the common-base configuration.
sedr42021_0557.jpg

27. The Early Effect In real world
(a) Collector current does show some dependence on collector voltage
(b) Characteristics are not perfectly horizontal line

28. Figure (a) Conceptual circuit for measuring the iC –vCE characteristics of the BJT. (b) The iC –vCE characteristics of a practical BJT.
sedr42021_0519.jpg

29. Common Emitter Configuration
Emitter serves as a common terminal between input and output terminal
Common Emitter Characteristics (ic-vCE)
can be obtained at different value of vBE
and varying vCE (dc), Collector current can be measured

30. The Early Effect
vCE < V CBJ become forward biased & BJT leaves active mode & enters saturation mode
Characteristics is still a straight line but with a finite slope
when extra-polated, the characteristics lines meet at a point on the negative vCE vCE = -VA
Typical value of VA ranges v & called early voltage, after the name of english scientist JM Early

31. The Early Effect
At given vBE , increasing vCE increases reverse biased voltage on CBJ & thus depletion region increases, Resulting in a decrease in the effective base width W
Is is inversely proportional to the base width
Is increases , and Ic also increases proportionally
called Early Effect

32. The Early Effect

33. Figure Large-signal equivalent-circuit models of an npn BJT operating in the active mode in the common-emitter configuration.
sedr42021_0520a.jpg

34. Figure 5.58 The hybrid-pi small-signal model, in its two versions, with the resistance ro included.
sedr42021_0558a.jpg

35. The hybrid- small-signal model, with the resistance ro included.

36. Figure E5.40
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37. Table 5.4
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38. Figure Basic structure of the circuit used to realize single-stage, discrete-circuit BJT amplifier configurations.
sedr42021_0559.jpg

39. Exercise 5.41
Consider the circuit shown for the case VCC = VEE = 10V, I = 1 mA, RB = 100 kΩ , RC = 8 kΩ and β = 100.
Find all DC currents and voltages.
What are the allowable signal swings at the collector in both directions?
How do these values change as β is changed to 50? To 200?
Find the value of the BJT small-signal parameters at the bias point (with β = 100).
The Early Voltage VA = 100 V.

40. Figure E5.41
sedr42021_e0541a.jpg

41. Solution Signal swing: for β = 100, +8V, -3.4V; for β= 50, +8V, -4.4V;

42. Problem 5.112
The transistor amplifier in fig. P5.112 is biased with a current source I and has a very high B. find the dc voltage at the collector, Vc. Also, find the value of Replace the transistor with the simplified hybrid- model of Fig 5.51(a)(note that the dc current source I should be replaced with an open circuit). Hence find the voltage gain

43. Figure P5.112
sedr42021_p05112.jpg

44. Problem 5.115
For the circuit shows in Fig P5.115, draw a complete small-signal equivalent circuit utilizing an appropriate T model for the BJT (use = 0.99). Your circuit should show the value of all components, including the model parameters. What is the input resistance Rin? Calculate the overall voltage gain

45. Figure P5.115
sedr42021_p05115.jpg

46. Problem 5.116
In the circuit show in the Fig P5.116, the transistor has a of 200. What is the dc voltage at the collector? Find the input resistance Rib and Rin and the overall voltage gain
For an output signal of , what values of are required?

47. Figure P5.116
sedr42021_p05116.jpg

48. Problem 5.124
The transistor in the circuit shown in Fig. P5.124 is biased to operate in the active mode. Assuming that β is very large, find the collector bias current Ic. Replace the transistor with the small-signal equivalent circuit model of Fig 5.52(b) (remember to replace the dc power supply with a short circuit). Analyze the resulting amplifier equivalent circuit to show that
Find the value jof these voltage gain (for α = 1). Now, if the terminal labeled vo1 is connected to ground, what
does the voltage gain become?

49. Figure P5.124
sedr42021_p05124.jpg

50. sedr42021_p05126.jpg
Figure P5.126

51. Problem 5.130
Find the common-emitter amplifier shown in Fig. P5.130, Let VCC =9V, R1 = 27kΩ, R2 = 15kΩ, RE = 1.2kΩ, and Rc = 2.2kΩ. The transistor has β = 100 and VA = 100 V. Calculate the dc bias current IE. If the amplifier operates between a source for which Rsig = 10 kΩ and a load of 2kΩ replace the transistor with its hybrid-Π model, and find the value of Rm, the voltage gain and the current gain

52. Figure P5.130
sedr42021_p05130.jpg

53. Figure P5.130 DC Analysis Suppress the AC (independent Sources)
Short Circuit Voltage Sources
Open Circuit the Capacitors
Calculate DC Node Voltages & Loop Currents
sedr42021_p05130.jpg

54. Figure P5.130 DC Analysis β = 100 , α = 0.99 VA = 100V
IE = ?, Rin = ?, overall gain vo/vsig, io/i1
sedr42021_p05130.jpg

55. Solution P5.130
DC Values
1.92 mA
9.64 KΩ
3.21 V
1.94 mA

56. Solution P5.130 Check for Mode 3.21 V ACTIVE MODE VCB > - 0.4 V
1.94 mA
1.92 mA
ACTIVE MODE VCB > V

57. Solution P5.130 Small Signal Model IC = 1.92 mA VT = 25 mV
β = 100 , α = 0.99
VA = 100 V

58. Solution P5.130

59. CE with pi Model
sedr42021_p05130.jpg

60. CE with ‘T’ Model
sedr42021_p05130.jpg

61. Comparison ‘pi’ Vs ‘T’ Model
sedr42021_p05130.jpg

62. sedr42021_p05134.jpg
Figure P5.134

63. Single Stage BJT Amplifier
Three Configurations
Common Emitter (CE)
Common Emitter (CE) with Emitter Resistance
Common Base (CB)
Common Collector (CC)

64. Figure 5. 60 (a) A common-emitter amplifier using the structure of Fig
sedr42021_0560a.jpg

65. Amplifiers Configurations
Common Emitter
sedr42021_tb0506a.jpg

66. Amplifiers Configurations Common Emitter
DC Analysis
Suppress Independent ac Source
Voltage source Short Cct
Current Sources --- Open
Capacitors ---- Open Cct
Redraw the Circuit
Analysis VC VB
IE=I
IC=αIE
IB=(β+1)IE
sedr42021_tb0506a.jpg VE
VC=VCC-ICRC
VB=-IBRB
VE=VB-VBE
gm=Ic/VT
rл=β/gm
re=α/gm

67. Amplifiers Configurations Common Emitter
Small Signal Analysis
Suppress Independent DC Source
Voltage source Short Cct
Current Sources --- Open
Capacitors ---- Short Cct
Redraw the Circuit by replacing BJT
With pi Model
sedr42021_tb0506a.jpg
Analysis
gm=Ic/VT
rл=β/gm
re=α/gm
Find Rin, Rout, Voltage Gain vo/vi

68. Common Emitter Rin=RB||rл Rout=RC|RL vbe + -
Short Circuit Current Gain Ais
Ais = ios/ii
ios=-gmvbe
vbe=vi=iiRin
Ais=-gmRin
Rin=RB||rл
Rout=RC|RL

69. Summary : CE Input Resistance Output Resistance
Low to moderate typically a few kilohms
Output Resistance
Output Resistance is relatively low
Open Circuit Voltage Gain
Voltage gain of a few hundred
Short Circuit Current Gain
Current gain equal to β

70. Figure 5.61 (a) A common-emitter amplifier with an emitter resistance Re.
sedr42021_0561a.jpg

71. Quiz No 2 (DE 27 CE)
Redraw the circuit for Small Signal pi model analysis
Redraw the circuit for DC analysis

74. Figure 5.61 (a) A common-emitter amplifier with an emitter resistance Re.
sedr42021_0561a.jpg

75. Figure 5.61 (a) A common-emitter amplifier with an emitter resistance Re.
sedr42021_0561a.jpg

76. Small Signal Analysis : CE with Emitter Resistance Input Resistance
Multiplication by a factor (1+β) is known as the
Resistance Reflection Rule.
Analysis

77. Small Signal Analysis : CE with Emitter Resistance Voltage Gain
Voltage gain is lower than that of CE
because of the additional term (1+β)Re

78. Small Signal Analysis : CE with Emitter Resistance Current Gain

79. Small Signal Analysis : CE with Emitter Resistance
Summary
Re introduces negative feedback gives it the name
emitter degenerative resistance

80. Comparison ‘T’ Vs ‘pi’ Model

81. A common-base amplifier
sedr42021_0562a.jpg

82. A common-base amplifier with its T model.
sedr42021_0562a.jpg

83. Small Signal Analysis : CB
CB has low input resistance
CB is non-inverting amplifier
sedr42021_0562a.jpg

84. Summary : CB Very Low input resistance Rin=re
Short Circuit Current Gain is nearly unity
Open circuit Voltage Gain is equal to CE and is positive
gm RC
Relatively high output resistance (Rc) same as CE
Excellent high frequency performance
As short circuit current gain is unity Current Buffer, it accept an input signal current at a low input resistance and delivers equal current at a very high output resistance.

85. An emitter-follower circuit : Common Collector
sedr42021_0563a.jpg
Non-unilateral Amplifier
Input Resistance depends upon RL
Output Resistance depends upon Rsig

86. Common Collector An emitter-follower circuit : T model
sedr42021_0563a.jpg

87. An equivalent circuit of the Emitter Follower - CC
sedr42021_0564.jpg

88. Overall Voltage Gain is less than unity:
An equivalent circuit of the Emitter Follower - CC
sedr42021_0564.jpg
Overall Voltage Gain is less than unity:
RB>>Rsig, (β+1)(re+(ro||RL))>>(Rsig||RL)
The voltage at the emitter (vo) follows very closely the voltage at the input
thus give the circuit the name Emitter Follower

89. The emitter follower : Reflecting resistance into emitter
sedr42021_0565.jpg
For RB>> Rsig & ro >> RL
Gain approaches Unity when Rsig/(1+β)<<RL89
Short Circuit Current Gain = 1+β

90. Common Collector : Output Resistance
Output Resistance is low

91. Summary : Common Collector
Non-unilateral Amplifier
Input Resistance depends upon RL
Output Resistance depends upon Rsig
High Input Resistance
Low out Resistance
Voltage Gain ≈ unity
Relatively Large Current = 1+β
sedr42021_0563a.jpg

92. An equivalent circuit of the emitter follower
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93. BJT Configurations
sedr42021_tb0506a.jpg

94. Common Emitter
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95. Common Emitter with Emitter Resistance
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96. Common Base : Current Buffer
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97. Common Collector : Voltage Follower
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98. Summary & Comparison

99. Comparison of Transistor Configurationsж
 Quantity
Common Emitter (CE)
Common Collector (CC)
Common Base (CB) AI
Current Gain
High (-50)
High (50)
Low (0.98) AV
Voltage Gain
High (-136)
Low (0.99)
High (1.4) Ri
Input Resistance
Medium (1 kΩ)
High (154 kΩ)
Low (21 Ω) Ro
Output Resistance
High (∞)
Low (80 Ω)
ж re = 1.1 kΩ, β = 50, RL= Rs = 3kΩ

100. Problem 5.135
The amplifier of Fig. P5.135 consists of two identical common-emitter amplifier connected in cascade. Observe that the input resistance of the second stage, Rin2, constitutes the load resistance of the first stage.
For Vcc = 15V, R1 = 100kΩ , R2 = 47kΩ , RE = 3.9kΩ , Rc = 6.8kΩ , and β = 1000, determine the dc collector current and dc collector voltage of each transistor.
Draw the small-signal equivalent circuit of the entire amplifier and give the values of all its components. Neglect ro1 and ro2
Find Rin1 and vb1/vsig for Rsig = 5 kΩ
Find Rin2 and vb2/vb1.
For RL = 2kΩ , find vo /vb2
Find the overall voltage gain vo /vsig

101. Figure P5.135
sedr42021_p05135.jpg

102. Solution P5-135 DC Analysis
Suppress the AC (independent Sources)
Short Circuit Voltage Sources
Open Circuit the Capacitors
Calculate DC Node Voltages & Loop Currents

103. Solution P5-135 DC Analysis
β=100, α=0.99

104. Small Signal Model
Suppress the DC (independent Sources)
Short Circuit Voltage Sources
Open Circuit Current Sources
Short Circuit the Capacitors
Draw the Small Signal Model

105. Small Signal Model

106. Small Signal Model

107. Figure P5.141 Common Base For the circuit shown, Assume β=100
Find the input resistance Rin
Find the voltage gain vo/vsig
sedr42021_p05141.jpg

108. Figure P5.141 (Common Base) DC Analysis
Suppress the AC (independent Sources)
Short Circuit Voltage Sources
Open Circuit the Capacitors
Calculate DC Node Voltages & Loop Currents
sedr42021_p05141.jpg

109. Figure P5.141 (Common Base) DC Analysis
Calculate DC Node Voltages & Loop Currents
β =100
I = IB +IC=IE=0.33 mA IB IC
sedr42021_p05141.jpg IE

110. Figure P5.141 (Common Base) Small Signal Analysis
Suppress the DC (independent Sources)
Short Circuit Voltage Sources
Open Circuit Current Sources
Short Circuit the Capacitors
Draw the Small Signal Model
sedr42021_p05141.jpg

111. Small Signal Analysis C vo
ic=αie B ie ve E
Rin

112. Figure P5.143 Common Collector ( Emitter follower)
sedr42021_p05143.jpg
For the circuit shown, Assume β=40
Find IE,VE,& VB
Find the input resistance Rin
Find the voltage gain vo/vsig

113. Figure P5.143 Common Collector ( Emitter follower)
Suppress the AC (independent Sources)
Short Circuit Voltage Sources
Open Circuit the Capacitors
Calculate DC Node Voltages & Loop Currents
sedr42021_p05143.jpg

114. Figure P5.143 Common Collector ( Emitter follower)
Calculate DC Node Voltages & Loop Currents
β=40
sedr42021_p05143.jpg

115. Figure P5.143 Common Collector ( Emitter follower)
Small Signal Analysis
Suppress the DC (independent Sources)
Short Circuit Voltage Sources
Open Circuit Current Sources
sedr42021_p05143.jpg
Short Circuit the Capacitors
Draw the Small Signal Model

116. Small Signal Model P5-143
sedr42021_p05143.jpg

117. Small Signal Model P5-143 vb vo
(β+1)ib Ri

119. Figure P5.144
sedr42021_p05144.jpg

120. Problem

121. Problem

122. Problem 5.147
For the circuit in Fig P5.147, called a boot-strapped follower:
Find the dc emitter current and gm, re, and rΠ Use β = 100.
Replace the BJT with its T model (neglecting ro), and analyze the circuit to determine the input resistance Rin and the voltage gain vo/vsig.
Repeat (b) for the case when capacitor CB is open –circuited. Compare the results with those obtained in (b) to find the advantages of bootstrapping.

123. Boot-Strapped Follower
sedr42021_p05147.jpg

124. Figure P5.147 DC Analysis Suppress the AC (independent Sources)
Short Circuit Voltage Sources
Open Circuit the Capacitors
sedr42021_p05147.jpg
Calculate DC Node Voltages & Loop Currents

125. Figure P5.147 DC Analysis Calculate DC Node Voltages & Loop Currents
sedr42021_p05147.jpg

126. Solution 5-147
DC Analysis

127. Figure P5.147 Small Signal Model Suppress the DC (independent Sources)
Short Circuit Voltage Sources
Open Circuit Current Sources
sedr42021_p05147.jpg
Short Circuit the Capacitors
Draw the Small Signal Model

128. Figure P5.147
Small Signal Model B E C
αie re
sedr42021_p05147.jpg

129. Solution 5-147 B E C
αie B E C
αie ie i
Rin

130. B E C
αie ie i
Rin
Solution 5-147 vo

131. Without Boot-Strap Capacitor
Solution 5-147
Without Boot-Strap Capacitor
Rin
Rib
The value of overall voltage gain and Rin obtained by using Bootstrap
capacitor is higher than cct ,without Bootstrapping
Bootstrapping is used to avoid loading of the input cct and to have higher gain.

132. Comparison of Transistor Configurations
 Quantity
Common Emitter (CE)
Common Collector (CC)
Common Base (CB) AI
Current Gain
High
Low AV
Voltage Gain Ri
Input Resistance
Medium Ro
Out Resistance