Microelectronics: Circuit Analysis and Design
Microelectronics: Circuit Analysis and Design
4th Edition
ISBN: 9780073380643
Author: Donald A. Neamen
Publisher: McGraw-Hill Companies, The
Question
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Chapter 15, Problem 15.18P

(a)

To determine

To derive: the expression for the voltage transfer function

(a)

Expert Solution
Check Mark

Explanation of Solution

Given:

  Microelectronics: Circuit Analysis and Design, Chapter 15, Problem 15.18P , additional homework tip 1

Calculation:

Redraw the given circuit in s -domain as

  Microelectronics: Circuit Analysis and Design, Chapter 15, Problem 15.18P , additional homework tip 2

From the circuit,

  0Vi(s)R1+1sC1+0Vo(s)R21sC2=0(sC1)Vi(s)sR1C1+1=Vo(s)R21sC2R2+1sC2(sC1)Vi(s)sR1C1+1=(sR2C2+1)Vo(s)R2sR2C1(sR1C1+1)(sR2C2+1)=Vo(s)Vi(s)

Now the transfer function is

  T(s)=Vo(s)Vi(s)

Hence

  T(s)=sR2C1s2R1R2C1C2+s(R1C1+R2C2)+1=sR2C1sR1C1[sR2C2+(1+R2C2R1C1)+1sR1C1]

Thus, the required voltage transfer function is

  T(s)=R2R1{1sR2C2+(1+R2C2R1C1)+1sR1C1}

Conclusion:

Thus, the required voltage transfer function is

  T(s)=R2R1{1sR2C2+(1+R2C2R1C1)+1sR1C1}

(b)

To determine

To find: The value of C1,C2,R2

(b)

Expert Solution
Check Mark

Answer to Problem 15.18P

The required values are C2=64.92nF , C1=156.3nF and R2=510.6kΩ

Explanation of Solution

Given:

  R1=10kΩ

Magnitude of the mid band gain is 50

Cut-off frequency f3dB1=200Hz

Cut-off frequency f3dB2=5kHz

  Microelectronics: Circuit Analysis and Design, Chapter 15, Problem 15.18P , additional homework tip 3

Calculation:

Consider s=jω

The magnitude of the voltage transfer function is given by

  |T(s)|=R2R1|1jωR2C2+(1+R2C2R1C1)+1jωR1C1|

  |T(s)|=R2R1|1(1+R2C2R1C1)+j(ωR2C21ωR1C1)|

  |T(s)|=R2R1{1(1+R2C2R1C1)2+(ωR2C21ωR1C1)2}

  |T(s)|=R2R1{(1+R2C2R1C1)2+(ωR2C21ωR1C1)2}12

   When ωR2C21ωR1C1=0|T(s)|=R2R11(1+R2C2R1C1)

Given |T(s)|=50

To determine the cut-off frequency |T(s)|2 assume the equality function as

  ωR2C21ωR1C1=±(1+R2C2R1C1)

For f=200Hz

  ω1=2π(200)=1257

  =1.257kradlsec

For f=5kHz

  ω2=2π(5k)=31415.93

  =31.42kradlsec

Let us consider τ1=R1C1 and τ2=R2C2. now, substitute τ1,τ2 in equation (1) then

  |T(s)|=+R2R1(11+τ2τ1)=50

The equation (1) becomes,

  ω2τ21ω2τ1=+(1+τ2τ1)(3) And also ω1τ21ω1τ1=(1+τ2τ1)(4)

From equation (2),

  ω22τ1τ21ω2τ1=τ1+τ2τ1ω2τ1τ21ω2=τ1+τ2τ1(ω2τ21)=1ω2+τ2τ1=1ω2+τ2ω2τ21

Substituting equation (5) in equation (4),

  ω1τ21ω1[1ω2+τ2ω2τ21]=[1+τ21ω2+τ2ω2τ21]ω1τ2ω2τ21ω1[1ω2+τ2]=[1+τ2(ω2τ21)1ω2+τ2]

Substitute the values of ω1,ω2 in the above expression as it is in the form of polynomial equation as

  [τ22{(1.257×103)2(31.42×103)+(1.257×103)(31.42×103)2+τ{(1.257×103)2(31.42×103)2}+(1.257×103+31.42×103)]=0τ22(1.291×1012)(985.64×106)τ2+32.677×103=0

Hence the roots are obtained as

  τ2={(985.64×106)±(985.64×106)24(1.291×1012)(32.677×103)}2(32.677×103)=7.287×104,3.315×105

Since ω2 is larger, τ2 should be small then consider

  τ2=0.3315×104s

Now, substitute the value of τ2 in equation (5) then

  τ1=1ω2+τ2ω2τ21=131.42×103+0.3315×104(31.42×103)(0.3315×104)1=64.98×1060.04157=1.563×103s

  Mid band gain=R2R111+τ2τ150=R2R1(11+τ2τ1)

Hence, by substituting the values

  50=R2R1(11+0.3315×1041.563×103)=R2R1(11.0212)=R2R1(0.979)

Further simplify as

  R2=R1(500.979)R2=51.06R1

Given R1=10kΩ then

  R2=51.06(10×103)=510.6×103

Therefore, the required resistor value is R2=510.6kΩ

Now

  τ1=R1C1C1=τ1R1=1.563×10310×103=1.56×107

Therefore, the required capacitor C1 value is C1=156.3nF

  τ2=R2C2C2=τ2R2=0.3315×104510.6×103=6.492×1011

Conclusion:

Therefore, the required values are C2=64.92nF , C1=156.3nF and R,=510.6kΩ

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Chapter 15 Solutions

Microelectronics: Circuit Analysis and Design

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