To derive: The expression for the frequency of oscillation

Question

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Answer 1

Question

Chapter 15, Problem 15.30P

(a)

To determine

To derive: The expression for the frequency of oscillation

(a)

Expert Solution

Answer to Problem 15.30P

The expression for the frequency of oscillation is ωo=10RC

Explanation of Solution

Given:

Consider the circuit shown below.

MICROELECT. CIRCUIT ANALYSIS&DESIGN (LL), Chapter 15, Problem 15.30P , additional homework tip 1

Calculation:

The non-inverting terminal of op-amp is grounded. Hence, the voltage v4 is equal to zero.

v4=0V

From virtual ground, the voltage at non-inverting terminal is equal to voltage at inverting terminal

v4=v5v5=0

Use KCL at the node v1

v1−v1R+v1−v2R+v11sC=0

v1−v1R+v1−v2R+sCv11=0v1−v1+v1−v2+sRCv1R=0v1(2+sRC)−v2−v1R=0v1(2+sRC)−v2−v1=0v1=v1(2+sRC)−v2……(1)

Use KCL at the node v2

v2−v1R+v2−v3R+v21sC=0v2−v1R+v2−v3R+sCv21=0v2−v1+v2−v3+v2sRC=0−v1+(2+sRC)v2−v3=0v1=(2+sRC)v2−v3……. (2)

Use KCL at the node v3

v3−v2R+v3−v4R+v31sC=0

Substitute v4=0V to obtain the node equation at v3

v3−v2R+v3−0R+sCv31=0v3−v2+v3+sRCv3R=0v3(2+sRC)−v2R=0v3(2+sRC)−v2=02+sRC……(3)v3=v22

Substitute equation (3) in equation (2),

v1=(2+sRC)v2−v22+sRC=(2+sRC−12+sRC)v2v1=((2+sRC)2−12+sRC)v2…..(4)

Substitute equation (4) in equation (1),

vi=v1(2+sRC)−v2

vt=v1(2+sRC)−v2vl=(2+sRC)((2+sRC)2−12+sRC)v2−v2={((2+sRC)2−1)−1}v2=(4+s2R2C2+4sRC−1−1)v2=(s2R2C2+4sRC+2)v2v2=v1s2R2C2+4sRC+2

Use KCL at the node v4

v4−voRF+v4−v3R=00−voRF+0−v3R=0−voRF+−v3R=0vo=−RFRv3

Substitute v3=v22+sRC to obtain vo

vo=−RpR(12+sRC)v2

Substitute v2=v1s2R2C2+4sRC+2 to obtain vo

vo=−(RFR)(12+sRC)(1s2R2C2+4sRC+2)v1vovl=−(RFR)(12s2R2C2+8sRC+4+s3R3C3+4s2R2C2+2sRC)=−(RFR)(1s3R3C3+6s2R2C2+10sRC+4)

The transfer function is given by.

T(s)=vo(s)vt(s)T(s)=−(RFR)(1s3R3C3+6s2R2C2+10sRC+4)

To find the frequency oscillation, set s=jω

T(jω)=−( R F R )( 1 (jω) 3 R 3 C 3 +6 (jω) 2 R 2 C 2 +10(jω)RC+4 )

=−( R F R )( 1 −j ω 3 R 3 C 3 −6 ω 2 R 2 C 2 +10(jω)RC+4 )

=−( R F R )( 1 4−6 ω 2 R 2 C 2 +j(10ωRC− ω 3 R 3 C 3 ) )

=−( R F R )( 4−6 ω 2 R 2 C 2 −j(10ωRC− ω 3 R 3 C 3 ) ( 4−6 ω 2 R 2 C 2 ) 2 + ( (10ωRC− ω 3 R 3 C 3 ) ) 2 )

T(jω)=−( R F R )( 4−6 ω 2 R 2 C 2 ( 4−6 ω 2 R 2 C 2 ) 2 + ( (10ωRC− ω 3 R 3 C 3 ) ) 2 )+

j( R F R )( (10ωRC− ω 3 R 3 C 3 ) ( 4−6 ω 2 R 2 C 2 ) 2 + ( (10ωRC− ω 3 R 3 C 3 ) ) 2 )......................(6)

From the Barkhausen criterion, the condition for oscillation is that T(jωe)=−1

To satisfy the condition T(jωo)=−1 , equate the imaginary component of the equation (6) equal to zero.

(RFR)((10ωoRC−ωo3R3C3)(4−6ωo2R2C2)2+(10ωoRC−ωo3R3C3)2)=0(10ωoRC−ωo3R3C3)=0

ωoRC(10−ωo2R2C2)=0

(10−ωo2R2C2)=0

ωo2R2C2=10

ωo2=10R2C2

ωo=10RC

Conclusion:

Therefore, the expression for the frequency of oscillation is ωo=10RC

(b)

To determine

The condition of oscillation.

(b)

Expert Solution

Answer to Problem 15.30P

The condition of oscillation is RFR=56

Explanation of Solution

Given:

Consider the circuit shown below.

MICROELECT. CIRCUIT ANALYSIS&DESIGN (LL), Chapter 15, Problem 15.30P , additional homework tip 2 R=20kΩ , fo=22kHz

Calculation:

Substitute 2πfc for ωo to obtain frequency of oscillations.

2πfo=10RCfo=102πRC

The condition for oscillation is that |T(jωo)|=1, to satisfy this condition equate real part of the equation (6) equal to 1

−(RFR)(4−6ωo2R2C2(4−6ωo2R2C2)2+(10ωoRC−ωo3R3C3)2)=1

Substitute ωo=10RC to obtain the condition of oscillations

−(RFR)(4−6(10RC)2(4−6(10RC)2R2C2)2+(1010RCRC−(10RC)3R3C3)2)=1(RFR)(56(−56)2)=1RFR=56

Therefore, the required condition for oscillation is RFR=56

Conclusion:

Therefore, the required expression for the frequency of oscillation is RFR=56

(c)

To determine

To find: The values of capacitor and RF

(c)

Expert Solution

Answer to Problem 15.30P

The required values are C=3.1623×10−9 F , RF=11.12kΩ

Explanation of Solution

Given:

Consider the circuit shown below.

MICROELECT. CIRCUIT ANALYSIS&DESIGN (LL), Chapter 15, Problem 15.30P , additional homework tip 3 R=20kΩ , fo=22kHz

Calculation:

Substitute 20kΩ for R to obtain RF

RF=56R=56(20×103)=1120×103

Thus, the required feedback resistance is RF=11.12kΩ

Substitute 20kΩ for R,1.12kΩ for RF, and 22kHz for f0 to obtain the value of C .

fo=102πRCC=102πfoRC=102π(22×103)(20×103)=102.765×109=3.1623×10−9 F

Conclusion:

Therefore, the required values are C=3.1623×10−9 F , RF=11.12kΩ

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(a) For the circuit shown in Figure Q3(a) (RFC and Cc are forbias) (i) (ii) Draw the AC small signal equivalent circuit of the oscillator. From this equivalent circuit derive an equation for fo and the gain condition for the oscillations to start. VDD www RG eee RFC H Cc 北 5 C₁ L 000 C₂ Vo

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12.1. Find the steady-state response vo (t) for the network. 00000- 1Ω ww 12 cos(t) V + www 202 1 H 202 1 F + 1Ω νο -

Answer 2

Question

Chapter 15, Problem 15.30P

(a)

To determine

To derive: The expression for the frequency of oscillation

(a)

Expert Solution

Answer to Problem 15.30P

The expression for the frequency of oscillation is ωo=10RC

Explanation of Solution

Given:

Consider the circuit shown below.

MICROELECT. CIRCUIT ANALYSIS&DESIGN (LL), Chapter 15, Problem 15.30P , additional homework tip 1

Calculation:

The non-inverting terminal of op-amp is grounded. Hence, the voltage v4 is equal to zero.

v4=0V

From virtual ground, the voltage at non-inverting terminal is equal to voltage at inverting terminal

v4=v5v5=0

Use KCL at the node v1

v1−v1R+v1−v2R+v11sC=0

v1−v1R+v1−v2R+sCv11=0v1−v1+v1−v2+sRCv1R=0v1(2+sRC)−v2−v1R=0v1(2+sRC)−v2−v1=0v1=v1(2+sRC)−v2……(1)

Use KCL at the node v2

v2−v1R+v2−v3R+v21sC=0v2−v1R+v2−v3R+sCv21=0v2−v1+v2−v3+v2sRC=0−v1+(2+sRC)v2−v3=0v1=(2+sRC)v2−v3……. (2)

Use KCL at the node v3

v3−v2R+v3−v4R+v31sC=0

Substitute v4=0V to obtain the node equation at v3

v3−v2R+v3−0R+sCv31=0v3−v2+v3+sRCv3R=0v3(2+sRC)−v2R=0v3(2+sRC)−v2=02+sRC……(3)v3=v22

Substitute equation (3) in equation (2),

v1=(2+sRC)v2−v22+sRC=(2+sRC−12+sRC)v2v1=((2+sRC)2−12+sRC)v2…..(4)

Substitute equation (4) in equation (1),

vi=v1(2+sRC)−v2

vt=v1(2+sRC)−v2vl=(2+sRC)((2+sRC)2−12+sRC)v2−v2={((2+sRC)2−1)−1}v2=(4+s2R2C2+4sRC−1−1)v2=(s2R2C2+4sRC+2)v2v2=v1s2R2C2+4sRC+2

Use KCL at the node v4

v4−voRF+v4−v3R=00−voRF+0−v3R=0−voRF+−v3R=0vo=−RFRv3

Substitute v3=v22+sRC to obtain vo

vo=−RpR(12+sRC)v2

Substitute v2=v1s2R2C2+4sRC+2 to obtain vo

vo=−(RFR)(12+sRC)(1s2R2C2+4sRC+2)v1vovl=−(RFR)(12s2R2C2+8sRC+4+s3R3C3+4s2R2C2+2sRC)=−(RFR)(1s3R3C3+6s2R2C2+10sRC+4)

The transfer function is given by.

T(s)=vo(s)vt(s)T(s)=−(RFR)(1s3R3C3+6s2R2C2+10sRC+4)

To find the frequency oscillation, set s=jω

T(jω)=−( R F R )( 1 (jω) 3 R 3 C 3 +6 (jω) 2 R 2 C 2 +10(jω)RC+4 )

=−( R F R )( 1 −j ω 3 R 3 C 3 −6 ω 2 R 2 C 2 +10(jω)RC+4 )

=−( R F R )( 1 4−6 ω 2 R 2 C 2 +j(10ωRC− ω 3 R 3 C 3 ) )

=−( R F R )( 4−6 ω 2 R 2 C 2 −j(10ωRC− ω 3 R 3 C 3 ) ( 4−6 ω 2 R 2 C 2 ) 2 + ( (10ωRC− ω 3 R 3 C 3 ) ) 2 )

T(jω)=−( R F R )( 4−6 ω 2 R 2 C 2 ( 4−6 ω 2 R 2 C 2 ) 2 + ( (10ωRC− ω 3 R 3 C 3 ) ) 2 )+

j( R F R )( (10ωRC− ω 3 R 3 C 3 ) ( 4−6 ω 2 R 2 C 2 ) 2 + ( (10ωRC− ω 3 R 3 C 3 ) ) 2 )......................(6)

From the Barkhausen criterion, the condition for oscillation is that T(jωe)=−1

To satisfy the condition T(jωo)=−1 , equate the imaginary component of the equation (6) equal to zero.

(RFR)((10ωoRC−ωo3R3C3)(4−6ωo2R2C2)2+(10ωoRC−ωo3R3C3)2)=0(10ωoRC−ωo3R3C3)=0

ωoRC(10−ωo2R2C2)=0

(10−ωo2R2C2)=0

ωo2R2C2=10

ωo2=10R2C2

ωo=10RC

Conclusion:

Therefore, the expression for the frequency of oscillation is ωo=10RC

(b)

To determine

The condition of oscillation.

(b)

Expert Solution

Answer to Problem 15.30P

The condition of oscillation is RFR=56

Explanation of Solution

Given:

Consider the circuit shown below.

MICROELECT. CIRCUIT ANALYSIS&DESIGN (LL), Chapter 15, Problem 15.30P , additional homework tip 2 R=20kΩ , fo=22kHz

Calculation:

Substitute 2πfc for ωo to obtain frequency of oscillations.

2πfo=10RCfo=102πRC

The condition for oscillation is that |T(jωo)|=1, to satisfy this condition equate real part of the equation (6) equal to 1

−(RFR)(4−6ωo2R2C2(4−6ωo2R2C2)2+(10ωoRC−ωo3R3C3)2)=1

Substitute ωo=10RC to obtain the condition of oscillations

−(RFR)(4−6(10RC)2(4−6(10RC)2R2C2)2+(1010RCRC−(10RC)3R3C3)2)=1(RFR)(56(−56)2)=1RFR=56

Therefore, the required condition for oscillation is RFR=56

Conclusion:

Therefore, the required expression for the frequency of oscillation is RFR=56

(c)

To determine

To find: The values of capacitor and RF

(c)

Expert Solution

Answer to Problem 15.30P

The required values are C=3.1623×10−9 F , RF=11.12kΩ

Explanation of Solution

Given:

Consider the circuit shown below.

MICROELECT. CIRCUIT ANALYSIS&DESIGN (LL), Chapter 15, Problem 15.30P , additional homework tip 3 R=20kΩ , fo=22kHz

Calculation:

Substitute 20kΩ for R to obtain RF

RF=56R=56(20×103)=1120×103

Thus, the required feedback resistance is RF=11.12kΩ

Substitute 20kΩ for R,1.12kΩ for RF, and 22kHz for f0 to obtain the value of C .

fo=102πRCC=102πfoRC=102π(22×103)(20×103)=102.765×109=3.1623×10−9 F

Conclusion:

Therefore, the required values are C=3.1623×10−9 F , RF=11.12kΩ

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Answer 3

Question

Chapter 15, Problem 15.30P

(a)

To determine

To derive: The expression for the frequency of oscillation

(a)

Expert Solution

Answer to Problem 15.30P

The expression for the frequency of oscillation is ωo=10RC

Explanation of Solution

Given:

Consider the circuit shown below.

MICROELECT. CIRCUIT ANALYSIS&DESIGN (LL), Chapter 15, Problem 15.30P , additional homework tip 1

Calculation:

The non-inverting terminal of op-amp is grounded. Hence, the voltage v4 is equal to zero.

v4=0V

From virtual ground, the voltage at non-inverting terminal is equal to voltage at inverting terminal

v4=v5v5=0

Use KCL at the node v1

v1−v1R+v1−v2R+v11sC=0

v1−v1R+v1−v2R+sCv11=0v1−v1+v1−v2+sRCv1R=0v1(2+sRC)−v2−v1R=0v1(2+sRC)−v2−v1=0v1=v1(2+sRC)−v2……(1)

Use KCL at the node v2

v2−v1R+v2−v3R+v21sC=0v2−v1R+v2−v3R+sCv21=0v2−v1+v2−v3+v2sRC=0−v1+(2+sRC)v2−v3=0v1=(2+sRC)v2−v3……. (2)

Use KCL at the node v3

v3−v2R+v3−v4R+v31sC=0

Substitute v4=0V to obtain the node equation at v3

v3−v2R+v3−0R+sCv31=0v3−v2+v3+sRCv3R=0v3(2+sRC)−v2R=0v3(2+sRC)−v2=02+sRC……(3)v3=v22

Substitute equation (3) in equation (2),

v1=(2+sRC)v2−v22+sRC=(2+sRC−12+sRC)v2v1=((2+sRC)2−12+sRC)v2…..(4)

Substitute equation (4) in equation (1),

vi=v1(2+sRC)−v2

vt=v1(2+sRC)−v2vl=(2+sRC)((2+sRC)2−12+sRC)v2−v2={((2+sRC)2−1)−1}v2=(4+s2R2C2+4sRC−1−1)v2=(s2R2C2+4sRC+2)v2v2=v1s2R2C2+4sRC+2

Use KCL at the node v4

v4−voRF+v4−v3R=00−voRF+0−v3R=0−voRF+−v3R=0vo=−RFRv3

Substitute v3=v22+sRC to obtain vo

vo=−RpR(12+sRC)v2

Substitute v2=v1s2R2C2+4sRC+2 to obtain vo

vo=−(RFR)(12+sRC)(1s2R2C2+4sRC+2)v1vovl=−(RFR)(12s2R2C2+8sRC+4+s3R3C3+4s2R2C2+2sRC)=−(RFR)(1s3R3C3+6s2R2C2+10sRC+4)

The transfer function is given by.

T(s)=vo(s)vt(s)T(s)=−(RFR)(1s3R3C3+6s2R2C2+10sRC+4)

To find the frequency oscillation, set s=jω

T(jω)=−( R F R )( 1 (jω) 3 R 3 C 3 +6 (jω) 2 R 2 C 2 +10(jω)RC+4 )

=−( R F R )( 1 −j ω 3 R 3 C 3 −6 ω 2 R 2 C 2 +10(jω)RC+4 )

=−( R F R )( 1 4−6 ω 2 R 2 C 2 +j(10ωRC− ω 3 R 3 C 3 ) )

=−( R F R )( 4−6 ω 2 R 2 C 2 −j(10ωRC− ω 3 R 3 C 3 ) ( 4−6 ω 2 R 2 C 2 ) 2 + ( (10ωRC− ω 3 R 3 C 3 ) ) 2 )

T(jω)=−( R F R )( 4−6 ω 2 R 2 C 2 ( 4−6 ω 2 R 2 C 2 ) 2 + ( (10ωRC− ω 3 R 3 C 3 ) ) 2 )+

j( R F R )( (10ωRC− ω 3 R 3 C 3 ) ( 4−6 ω 2 R 2 C 2 ) 2 + ( (10ωRC− ω 3 R 3 C 3 ) ) 2 )......................(6)

From the Barkhausen criterion, the condition for oscillation is that T(jωe)=−1

To satisfy the condition T(jωo)=−1 , equate the imaginary component of the equation (6) equal to zero.

(RFR)((10ωoRC−ωo3R3C3)(4−6ωo2R2C2)2+(10ωoRC−ωo3R3C3)2)=0(10ωoRC−ωo3R3C3)=0

ωoRC(10−ωo2R2C2)=0

(10−ωo2R2C2)=0

ωo2R2C2=10

ωo2=10R2C2

ωo=10RC

Conclusion:

Therefore, the expression for the frequency of oscillation is ωo=10RC

(b)

To determine

The condition of oscillation.

(b)

Expert Solution

Answer to Problem 15.30P

The condition of oscillation is RFR=56

Explanation of Solution

Given:

Consider the circuit shown below.

MICROELECT. CIRCUIT ANALYSIS&DESIGN (LL), Chapter 15, Problem 15.30P , additional homework tip 2 R=20kΩ , fo=22kHz

Calculation:

Substitute 2πfc for ωo to obtain frequency of oscillations.

2πfo=10RCfo=102πRC

The condition for oscillation is that |T(jωo)|=1, to satisfy this condition equate real part of the equation (6) equal to 1

−(RFR)(4−6ωo2R2C2(4−6ωo2R2C2)2+(10ωoRC−ωo3R3C3)2)=1

Substitute ωo=10RC to obtain the condition of oscillations

−(RFR)(4−6(10RC)2(4−6(10RC)2R2C2)2+(1010RCRC−(10RC)3R3C3)2)=1(RFR)(56(−56)2)=1RFR=56

Therefore, the required condition for oscillation is RFR=56

Conclusion:

Therefore, the required expression for the frequency of oscillation is RFR=56

(c)

To determine

To find: The values of capacitor and RF

(c)

Expert Solution

Answer to Problem 15.30P

The required values are C=3.1623×10−9 F , RF=11.12kΩ

Explanation of Solution

Given:

Consider the circuit shown below.

MICROELECT. CIRCUIT ANALYSIS&DESIGN (LL), Chapter 15, Problem 15.30P , additional homework tip 3 R=20kΩ , fo=22kHz

Calculation:

Substitute 20kΩ for R to obtain RF

RF=56R=56(20×103)=1120×103

Thus, the required feedback resistance is RF=11.12kΩ

Substitute 20kΩ for R,1.12kΩ for RF, and 22kHz for f0 to obtain the value of C .

fo=102πRCC=102πfoRC=102π(22×103)(20×103)=102.765×109=3.1623×10−9 F

Conclusion:

Therefore, the required values are C=3.1623×10−9 F , RF=11.12kΩ

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Answer 4

Question

Chapter 15, Problem 15.30P

(a)

To determine

To derive: The expression for the frequency of oscillation

(a)

Expert Solution

Answer to Problem 15.30P

The expression for the frequency of oscillation is ωo=10RC

Explanation of Solution

Given:

Consider the circuit shown below.

MICROELECT. CIRCUIT ANALYSIS&DESIGN (LL), Chapter 15, Problem 15.30P , additional homework tip 1

Calculation:

The non-inverting terminal of op-amp is grounded. Hence, the voltage v4 is equal to zero.

v4=0V

From virtual ground, the voltage at non-inverting terminal is equal to voltage at inverting terminal

v4=v5v5=0

Use KCL at the node v1

v1−v1R+v1−v2R+v11sC=0

v1−v1R+v1−v2R+sCv11=0v1−v1+v1−v2+sRCv1R=0v1(2+sRC)−v2−v1R=0v1(2+sRC)−v2−v1=0v1=v1(2+sRC)−v2……(1)

Use KCL at the node v2

v2−v1R+v2−v3R+v21sC=0v2−v1R+v2−v3R+sCv21=0v2−v1+v2−v3+v2sRC=0−v1+(2+sRC)v2−v3=0v1=(2+sRC)v2−v3……. (2)

Use KCL at the node v3

v3−v2R+v3−v4R+v31sC=0

Substitute v4=0V to obtain the node equation at v3

v3−v2R+v3−0R+sCv31=0v3−v2+v3+sRCv3R=0v3(2+sRC)−v2R=0v3(2+sRC)−v2=02+sRC……(3)v3=v22

Substitute equation (3) in equation (2),

v1=(2+sRC)v2−v22+sRC=(2+sRC−12+sRC)v2v1=((2+sRC)2−12+sRC)v2…..(4)

Substitute equation (4) in equation (1),

vi=v1(2+sRC)−v2

vt=v1(2+sRC)−v2vl=(2+sRC)((2+sRC)2−12+sRC)v2−v2={((2+sRC)2−1)−1}v2=(4+s2R2C2+4sRC−1−1)v2=(s2R2C2+4sRC+2)v2v2=v1s2R2C2+4sRC+2

Use KCL at the node v4

v4−voRF+v4−v3R=00−voRF+0−v3R=0−voRF+−v3R=0vo=−RFRv3

Substitute v3=v22+sRC to obtain vo

vo=−RpR(12+sRC)v2

Substitute v2=v1s2R2C2+4sRC+2 to obtain vo

vo=−(RFR)(12+sRC)(1s2R2C2+4sRC+2)v1vovl=−(RFR)(12s2R2C2+8sRC+4+s3R3C3+4s2R2C2+2sRC)=−(RFR)(1s3R3C3+6s2R2C2+10sRC+4)

The transfer function is given by.

T(s)=vo(s)vt(s)T(s)=−(RFR)(1s3R3C3+6s2R2C2+10sRC+4)

To find the frequency oscillation, set s=jω

T(jω)=−( R F R )( 1 (jω) 3 R 3 C 3 +6 (jω) 2 R 2 C 2 +10(jω)RC+4 )

=−( R F R )( 1 −j ω 3 R 3 C 3 −6 ω 2 R 2 C 2 +10(jω)RC+4 )

=−( R F R )( 1 4−6 ω 2 R 2 C 2 +j(10ωRC− ω 3 R 3 C 3 ) )

=−( R F R )( 4−6 ω 2 R 2 C 2 −j(10ωRC− ω 3 R 3 C 3 ) ( 4−6 ω 2 R 2 C 2 ) 2 + ( (10ωRC− ω 3 R 3 C 3 ) ) 2 )

T(jω)=−( R F R )( 4−6 ω 2 R 2 C 2 ( 4−6 ω 2 R 2 C 2 ) 2 + ( (10ωRC− ω 3 R 3 C 3 ) ) 2 )+

j( R F R )( (10ωRC− ω 3 R 3 C 3 ) ( 4−6 ω 2 R 2 C 2 ) 2 + ( (10ωRC− ω 3 R 3 C 3 ) ) 2 )......................(6)

From the Barkhausen criterion, the condition for oscillation is that T(jωe)=−1

To satisfy the condition T(jωo)=−1 , equate the imaginary component of the equation (6) equal to zero.

(RFR)((10ωoRC−ωo3R3C3)(4−6ωo2R2C2)2+(10ωoRC−ωo3R3C3)2)=0(10ωoRC−ωo3R3C3)=0

ωoRC(10−ωo2R2C2)=0

(10−ωo2R2C2)=0

ωo2R2C2=10

ωo2=10R2C2

ωo=10RC

Conclusion:

Therefore, the expression for the frequency of oscillation is ωo=10RC

(b)

To determine

The condition of oscillation.

(b)

Expert Solution

Answer to Problem 15.30P

The condition of oscillation is RFR=56

Explanation of Solution

Given:

Consider the circuit shown below.

MICROELECT. CIRCUIT ANALYSIS&DESIGN (LL), Chapter 15, Problem 15.30P , additional homework tip 2 R=20kΩ , fo=22kHz

Calculation:

Substitute 2πfc for ωo to obtain frequency of oscillations.

2πfo=10RCfo=102πRC

The condition for oscillation is that |T(jωo)|=1, to satisfy this condition equate real part of the equation (6) equal to 1

−(RFR)(4−6ωo2R2C2(4−6ωo2R2C2)2+(10ωoRC−ωo3R3C3)2)=1

Substitute ωo=10RC to obtain the condition of oscillations

−(RFR)(4−6(10RC)2(4−6(10RC)2R2C2)2+(1010RCRC−(10RC)3R3C3)2)=1(RFR)(56(−56)2)=1RFR=56

Therefore, the required condition for oscillation is RFR=56

Conclusion:

Therefore, the required expression for the frequency of oscillation is RFR=56

(c)

To determine

To find: The values of capacitor and RF

(c)

Expert Solution

Answer to Problem 15.30P

The required values are C=3.1623×10−9 F , RF=11.12kΩ

Explanation of Solution

Given:

Consider the circuit shown below.

MICROELECT. CIRCUIT ANALYSIS&DESIGN (LL), Chapter 15, Problem 15.30P , additional homework tip 3 R=20kΩ , fo=22kHz

Calculation:

Substitute 20kΩ for R to obtain RF

RF=56R=56(20×103)=1120×103

Thus, the required feedback resistance is RF=11.12kΩ

Substitute 20kΩ for R,1.12kΩ for RF, and 22kHz for f0 to obtain the value of C .

fo=102πRCC=102πfoRC=102π(22×103)(20×103)=102.765×109=3.1623×10−9 F

Conclusion:

Therefore, the required values are C=3.1623×10−9 F , RF=11.12kΩ

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Answer 5

Chapter 15, Problem 15.30P

(a)

To determine

To derive: The expression for the frequency of oscillation

(a)

Expert Solution

Answer to Problem 15.30P

The expression for the frequency of oscillation is ωo=10RC

Explanation of Solution

Given:

Consider the circuit shown below.

MICROELECT. CIRCUIT ANALYSIS&DESIGN (LL), Chapter 15, Problem 15.30P , additional homework tip 1

Calculation:

The non-inverting terminal of op-amp is grounded. Hence, the voltage v4 is equal to zero.

v4=0V

From virtual ground, the voltage at non-inverting terminal is equal to voltage at inverting terminal

v4=v5v5=0

Use KCL at the node v1

v1−v1R+v1−v2R+v11sC=0

v1−v1R+v1−v2R+sCv11=0v1−v1+v1−v2+sRCv1R=0v1(2+sRC)−v2−v1R=0v1(2+sRC)−v2−v1=0v1=v1(2+sRC)−v2……(1)

Use KCL at the node v2

v2−v1R+v2−v3R+v21sC=0v2−v1R+v2−v3R+sCv21=0v2−v1+v2−v3+v2sRC=0−v1+(2+sRC)v2−v3=0v1=(2+sRC)v2−v3……. (2)

Use KCL at the node v3

v3−v2R+v3−v4R+v31sC=0

Substitute v4=0V to obtain the node equation at v3

v3−v2R+v3−0R+sCv31=0v3−v2+v3+sRCv3R=0v3(2+sRC)−v2R=0v3(2+sRC)−v2=02+sRC……(3)v3=v22

Substitute equation (3) in equation (2),

v1=(2+sRC)v2−v22+sRC=(2+sRC−12+sRC)v2v1=((2+sRC)2−12+sRC)v2…..(4)

Substitute equation (4) in equation (1),

vi=v1(2+sRC)−v2

vt=v1(2+sRC)−v2vl=(2+sRC)((2+sRC)2−12+sRC)v2−v2={((2+sRC)2−1)−1}v2=(4+s2R2C2+4sRC−1−1)v2=(s2R2C2+4sRC+2)v2v2=v1s2R2C2+4sRC+2

Use KCL at the node v4

v4−voRF+v4−v3R=00−voRF+0−v3R=0−voRF+−v3R=0vo=−RFRv3

Substitute v3=v22+sRC to obtain vo

vo=−RpR(12+sRC)v2

Substitute v2=v1s2R2C2+4sRC+2 to obtain vo

vo=−(RFR)(12+sRC)(1s2R2C2+4sRC+2)v1vovl=−(RFR)(12s2R2C2+8sRC+4+s3R3C3+4s2R2C2+2sRC)=−(RFR)(1s3R3C3+6s2R2C2+10sRC+4)

The transfer function is given by.

T(s)=vo(s)vt(s)T(s)=−(RFR)(1s3R3C3+6s2R2C2+10sRC+4)

To find the frequency oscillation, set s=jω

T(jω)=−( R F R )( 1 (jω) 3 R 3 C 3 +6 (jω) 2 R 2 C 2 +10(jω)RC+4 )

=−( R F R )( 1 −j ω 3 R 3 C 3 −6 ω 2 R 2 C 2 +10(jω)RC+4 )

=−( R F R )( 1 4−6 ω 2 R 2 C 2 +j(10ωRC− ω 3 R 3 C 3 ) )

=−( R F R )( 4−6 ω 2 R 2 C 2 −j(10ωRC− ω 3 R 3 C 3 ) ( 4−6 ω 2 R 2 C 2 ) 2 + ( (10ωRC− ω 3 R 3 C 3 ) ) 2 )

T(jω)=−( R F R )( 4−6 ω 2 R 2 C 2 ( 4−6 ω 2 R 2 C 2 ) 2 + ( (10ωRC− ω 3 R 3 C 3 ) ) 2 )+

j( R F R )( (10ωRC− ω 3 R 3 C 3 ) ( 4−6 ω 2 R 2 C 2 ) 2 + ( (10ωRC− ω 3 R 3 C 3 ) ) 2 )......................(6)

From the Barkhausen criterion, the condition for oscillation is that T(jωe)=−1

To satisfy the condition T(jωo)=−1 , equate the imaginary component of the equation (6) equal to zero.

(RFR)((10ωoRC−ωo3R3C3)(4−6ωo2R2C2)2+(10ωoRC−ωo3R3C3)2)=0(10ωoRC−ωo3R3C3)=0

ωoRC(10−ωo2R2C2)=0

(10−ωo2R2C2)=0

ωo2R2C2=10

ωo2=10R2C2

ωo=10RC

Conclusion:

Therefore, the expression for the frequency of oscillation is ωo=10RC

(b)

To determine

The condition of oscillation.

(b)

Expert Solution

Answer to Problem 15.30P

The condition of oscillation is RFR=56

Explanation of Solution

Given:

Consider the circuit shown below.

MICROELECT. CIRCUIT ANALYSIS&DESIGN (LL), Chapter 15, Problem 15.30P , additional homework tip 2 R=20kΩ , fo=22kHz

Calculation:

Substitute 2πfc for ωo to obtain frequency of oscillations.

2πfo=10RCfo=102πRC

The condition for oscillation is that |T(jωo)|=1, to satisfy this condition equate real part of the equation (6) equal to 1

−(RFR)(4−6ωo2R2C2(4−6ωo2R2C2)2+(10ωoRC−ωo3R3C3)2)=1

Substitute ωo=10RC to obtain the condition of oscillations

−(RFR)(4−6(10RC)2(4−6(10RC)2R2C2)2+(1010RCRC−(10RC)3R3C3)2)=1(RFR)(56(−56)2)=1RFR=56

Therefore, the required condition for oscillation is RFR=56

Conclusion:

Therefore, the required expression for the frequency of oscillation is RFR=56

(c)

To determine

To find: The values of capacitor and RF

(c)

Expert Solution

Answer to Problem 15.30P

The required values are C=3.1623×10−9 F , RF=11.12kΩ

Explanation of Solution

Given:

Consider the circuit shown below.

MICROELECT. CIRCUIT ANALYSIS&DESIGN (LL), Chapter 15, Problem 15.30P , additional homework tip 3 R=20kΩ , fo=22kHz

Calculation:

Substitute 20kΩ for R to obtain RF

RF=56R=56(20×103)=1120×103

Thus, the required feedback resistance is RF=11.12kΩ

Substitute 20kΩ for R,1.12kΩ for RF, and 22kHz for f0 to obtain the value of C .

fo=102πRCC=102πfoRC=102π(22×103)(20×103)=102.765×109=3.1623×10−9 F

Conclusion:

Therefore, the required values are C=3.1623×10−9 F , RF=11.12kΩ

Answer 6

Chapter 15, Problem 15.30P

(a)

To determine

To derive: The expression for the frequency of oscillation

(a)

Expert Solution

Answer to Problem 15.30P

The expression for the frequency of oscillation is ωo=10RC

Explanation of Solution

Given:

Consider the circuit shown below.

MICROELECT. CIRCUIT ANALYSIS&DESIGN (LL), Chapter 15, Problem 15.30P , additional homework tip 1

Calculation:

The non-inverting terminal of op-amp is grounded. Hence, the voltage v4 is equal to zero.

v4=0V

From virtual ground, the voltage at non-inverting terminal is equal to voltage at inverting terminal

v4=v5v5=0

Use KCL at the node v1

v1−v1R+v1−v2R+v11sC=0

v1−v1R+v1−v2R+sCv11=0v1−v1+v1−v2+sRCv1R=0v1(2+sRC)−v2−v1R=0v1(2+sRC)−v2−v1=0v1=v1(2+sRC)−v2……(1)

Use KCL at the node v2

v2−v1R+v2−v3R+v21sC=0v2−v1R+v2−v3R+sCv21=0v2−v1+v2−v3+v2sRC=0−v1+(2+sRC)v2−v3=0v1=(2+sRC)v2−v3……. (2)

Use KCL at the node v3

v3−v2R+v3−v4R+v31sC=0

Substitute v4=0V to obtain the node equation at v3

v3−v2R+v3−0R+sCv31=0v3−v2+v3+sRCv3R=0v3(2+sRC)−v2R=0v3(2+sRC)−v2=02+sRC……(3)v3=v22

Substitute equation (3) in equation (2),

v1=(2+sRC)v2−v22+sRC=(2+sRC−12+sRC)v2v1=((2+sRC)2−12+sRC)v2…..(4)

Substitute equation (4) in equation (1),

vi=v1(2+sRC)−v2

vt=v1(2+sRC)−v2vl=(2+sRC)((2+sRC)2−12+sRC)v2−v2={((2+sRC)2−1)−1}v2=(4+s2R2C2+4sRC−1−1)v2=(s2R2C2+4sRC+2)v2v2=v1s2R2C2+4sRC+2

Use KCL at the node v4

v4−voRF+v4−v3R=00−voRF+0−v3R=0−voRF+−v3R=0vo=−RFRv3

Substitute v3=v22+sRC to obtain vo

vo=−RpR(12+sRC)v2

Substitute v2=v1s2R2C2+4sRC+2 to obtain vo

vo=−(RFR)(12+sRC)(1s2R2C2+4sRC+2)v1vovl=−(RFR)(12s2R2C2+8sRC+4+s3R3C3+4s2R2C2+2sRC)=−(RFR)(1s3R3C3+6s2R2C2+10sRC+4)

The transfer function is given by.

T(s)=vo(s)vt(s)T(s)=−(RFR)(1s3R3C3+6s2R2C2+10sRC+4)

To find the frequency oscillation, set s=jω

T(jω)=−( R F R )( 1 (jω) 3 R 3 C 3 +6 (jω) 2 R 2 C 2 +10(jω)RC+4 )

=−( R F R )( 1 −j ω 3 R 3 C 3 −6 ω 2 R 2 C 2 +10(jω)RC+4 )

=−( R F R )( 1 4−6 ω 2 R 2 C 2 +j(10ωRC− ω 3 R 3 C 3 ) )

=−( R F R )( 4−6 ω 2 R 2 C 2 −j(10ωRC− ω 3 R 3 C 3 ) ( 4−6 ω 2 R 2 C 2 ) 2 + ( (10ωRC− ω 3 R 3 C 3 ) ) 2 )

T(jω)=−( R F R )( 4−6 ω 2 R 2 C 2 ( 4−6 ω 2 R 2 C 2 ) 2 + ( (10ωRC− ω 3 R 3 C 3 ) ) 2 )+

j( R F R )( (10ωRC− ω 3 R 3 C 3 ) ( 4−6 ω 2 R 2 C 2 ) 2 + ( (10ωRC− ω 3 R 3 C 3 ) ) 2 )......................(6)

From the Barkhausen criterion, the condition for oscillation is that T(jωe)=−1

To satisfy the condition T(jωo)=−1 , equate the imaginary component of the equation (6) equal to zero.

(RFR)((10ωoRC−ωo3R3C3)(4−6ωo2R2C2)2+(10ωoRC−ωo3R3C3)2)=0(10ωoRC−ωo3R3C3)=0

ωoRC(10−ωo2R2C2)=0

(10−ωo2R2C2)=0

ωo2R2C2=10

ωo2=10R2C2

ωo=10RC

Conclusion:

Therefore, the expression for the frequency of oscillation is ωo=10RC

Answer 7

Chapter 15, Problem 15.30P

(a)

To determine

To derive: The expression for the frequency of oscillation

Answer 8

(a)

Expert Solution

Answer to Problem 15.30P

The expression for the frequency of oscillation is ωo=10RC

Answer 9

(a)

Expert Solution

Answer 10

(a)

Expert Solution

Answer 11

Expert Solution

Answer 12

Explanation of Solution

Given:

Consider the circuit shown below.

MICROELECT. CIRCUIT ANALYSIS&DESIGN (LL), Chapter 15, Problem 15.30P , additional homework tip 1

Calculation:

The non-inverting terminal of op-amp is grounded. Hence, the voltage v4 is equal to zero.

v4=0V

From virtual ground, the voltage at non-inverting terminal is equal to voltage at inverting terminal

v4=v5v5=0

Use KCL at the node v1

v1−v1R+v1−v2R+v11sC=0

v1−v1R+v1−v2R+sCv11=0v1−v1+v1−v2+sRCv1R=0v1(2+sRC)−v2−v1R=0v1(2+sRC)−v2−v1=0v1=v1(2+sRC)−v2……(1)

Use KCL at the node v2

v2−v1R+v2−v3R+v21sC=0v2−v1R+v2−v3R+sCv21=0v2−v1+v2−v3+v2sRC=0−v1+(2+sRC)v2−v3=0v1=(2+sRC)v2−v3……. (2)

Use KCL at the node v3

v3−v2R+v3−v4R+v31sC=0

Substitute v4=0V to obtain the node equation at v3

v3−v2R+v3−0R+sCv31=0v3−v2+v3+sRCv3R=0v3(2+sRC)−v2R=0v3(2+sRC)−v2=02+sRC……(3)v3=v22

Substitute equation (3) in equation (2),

v1=(2+sRC)v2−v22+sRC=(2+sRC−12+sRC)v2v1=((2+sRC)2−12+sRC)v2…..(4)

Substitute equation (4) in equation (1),

vi=v1(2+sRC)−v2

vt=v1(2+sRC)−v2vl=(2+sRC)((2+sRC)2−12+sRC)v2−v2={((2+sRC)2−1)−1}v2=(4+s2R2C2+4sRC−1−1)v2=(s2R2C2+4sRC+2)v2v2=v1s2R2C2+4sRC+2

Use KCL at the node v4

v4−voRF+v4−v3R=00−voRF+0−v3R=0−voRF+−v3R=0vo=−RFRv3

Substitute v3=v22+sRC to obtain vo

vo=−RpR(12+sRC)v2

Substitute v2=v1s2R2C2+4sRC+2 to obtain vo

vo=−(RFR)(12+sRC)(1s2R2C2+4sRC+2)v1vovl=−(RFR)(12s2R2C2+8sRC+4+s3R3C3+4s2R2C2+2sRC)=−(RFR)(1s3R3C3+6s2R2C2+10sRC+4)

The transfer function is given by.

T(s)=vo(s)vt(s)T(s)=−(RFR)(1s3R3C3+6s2R2C2+10sRC+4)

To find the frequency oscillation, set s=jω

T(jω)=−( R F R )( 1 (jω) 3 R 3 C 3 +6 (jω) 2 R 2 C 2 +10(jω)RC+4 )

=−( R F R )( 1 −j ω 3 R 3 C 3 −6 ω 2 R 2 C 2 +10(jω)RC+4 )

=−( R F R )( 1 4−6 ω 2 R 2 C 2 +j(10ωRC− ω 3 R 3 C 3 ) )

=−( R F R )( 4−6 ω 2 R 2 C 2 −j(10ωRC− ω 3 R 3 C 3 ) ( 4−6 ω 2 R 2 C 2 ) 2 + ( (10ωRC− ω 3 R 3 C 3 ) ) 2 )

T(jω)=−( R F R )( 4−6 ω 2 R 2 C 2 ( 4−6 ω 2 R 2 C 2 ) 2 + ( (10ωRC− ω 3 R 3 C 3 ) ) 2 )+

j( R F R )( (10ωRC− ω 3 R 3 C 3 ) ( 4−6 ω 2 R 2 C 2 ) 2 + ( (10ωRC− ω 3 R 3 C 3 ) ) 2 )......................(6)

From the Barkhausen criterion, the condition for oscillation is that T(jωe)=−1

To satisfy the condition T(jωo)=−1 , equate the imaginary component of the equation (6) equal to zero.

(RFR)((10ωoRC−ωo3R3C3)(4−6ωo2R2C2)2+(10ωoRC−ωo3R3C3)2)=0(10ωoRC−ωo3R3C3)=0

ωoRC(10−ωo2R2C2)=0

(10−ωo2R2C2)=0

ωo2R2C2=10

ωo2=10R2C2

ωo=10RC

Conclusion:

Therefore, the expression for the frequency of oscillation is ωo=10RC

Answer 13

(b)

To determine

The condition of oscillation.

(b)

Expert Solution

Answer to Problem 15.30P

The condition of oscillation is RFR=56

Explanation of Solution

Given:

Consider the circuit shown below.

MICROELECT. CIRCUIT ANALYSIS&DESIGN (LL), Chapter 15, Problem 15.30P , additional homework tip 2 R=20kΩ , fo=22kHz

Calculation:

Substitute 2πfc for ωo to obtain frequency of oscillations.

2πfo=10RCfo=102πRC

The condition for oscillation is that |T(jωo)|=1, to satisfy this condition equate real part of the equation (6) equal to 1

−(RFR)(4−6ωo2R2C2(4−6ωo2R2C2)2+(10ωoRC−ωo3R3C3)2)=1

Substitute ωo=10RC to obtain the condition of oscillations

−(RFR)(4−6(10RC)2(4−6(10RC)2R2C2)2+(1010RCRC−(10RC)3R3C3)2)=1(RFR)(56(−56)2)=1RFR=56

Therefore, the required condition for oscillation is RFR=56

Conclusion:

Therefore, the required expression for the frequency of oscillation is RFR=56

Answer 14

(b)

To determine

The condition of oscillation.

Answer 15

(b)

Expert Solution

Answer to Problem 15.30P

The condition of oscillation is RFR=56

Answer 16

(b)

Expert Solution

Answer 17

(b)

Expert Solution

Answer 18

Expert Solution

Answer 19

Explanation of Solution

Given:

Consider the circuit shown below.

MICROELECT. CIRCUIT ANALYSIS&DESIGN (LL), Chapter 15, Problem 15.30P , additional homework tip 2 R=20kΩ , fo=22kHz

Calculation:

Substitute 2πfc for ωo to obtain frequency of oscillations.

2πfo=10RCfo=102πRC

The condition for oscillation is that |T(jωo)|=1, to satisfy this condition equate real part of the equation (6) equal to 1

−(RFR)(4−6ωo2R2C2(4−6ωo2R2C2)2+(10ωoRC−ωo3R3C3)2)=1

Substitute ωo=10RC to obtain the condition of oscillations

−(RFR)(4−6(10RC)2(4−6(10RC)2R2C2)2+(1010RCRC−(10RC)3R3C3)2)=1(RFR)(56(−56)2)=1RFR=56

Therefore, the required condition for oscillation is RFR=56

Conclusion:

Therefore, the required expression for the frequency of oscillation is RFR=56

Answer 20

(c)

To determine

To find: The values of capacitor and RF

(c)

Expert Solution

Answer to Problem 15.30P

The required values are C=3.1623×10−9 F , RF=11.12kΩ

Explanation of Solution

Given:

Consider the circuit shown below.

MICROELECT. CIRCUIT ANALYSIS&DESIGN (LL), Chapter 15, Problem 15.30P , additional homework tip 3 R=20kΩ , fo=22kHz

Calculation:

Substitute 20kΩ for R to obtain RF

RF=56R=56(20×103)=1120×103

Thus, the required feedback resistance is RF=11.12kΩ

Substitute 20kΩ for R,1.12kΩ for RF, and 22kHz for f0 to obtain the value of C .

fo=102πRCC=102πfoRC=102π(22×103)(20×103)=102.765×109=3.1623×10−9 F

Conclusion:

Therefore, the required values are C=3.1623×10−9 F , RF=11.12kΩ

Answer 21

(c)

To determine

To find: The values of capacitor and RF

Answer 22

(c)

Expert Solution

Answer to Problem 15.30P

The required values are C=3.1623×10−9 F , RF=11.12kΩ

Answer 23

(c)

Expert Solution

Answer 24

(c)

Expert Solution

Answer 25

Expert Solution

Answer 26

Explanation of Solution

Given:

Consider the circuit shown below.

MICROELECT. CIRCUIT ANALYSIS&DESIGN (LL), Chapter 15, Problem 15.30P , additional homework tip 3 R=20kΩ , fo=22kHz

Calculation:

Substitute 20kΩ for R to obtain RF

RF=56R=56(20×103)=1120×103

Thus, the required feedback resistance is RF=11.12kΩ

Substitute 20kΩ for R,1.12kΩ for RF, and 22kHz for f0 to obtain the value of C .

fo=102πRCC=102πfoRC=102π(22×103)(20×103)=102.765×109=3.1623×10−9 F

Conclusion:

Therefore, the required values are C=3.1623×10−9 F , RF=11.12kΩ

Answer 27

Ch. 15 - Design a twopole lowpass Butterworth filter with a...Ch. 15 - Consider the switchedcapacitor circuit in Figure...Ch. 15 - Prob. 15.3EP Ch. 15 - (a) Design a threepole highpass Butterworth active...Ch. 15 - Prob. 15.2TYU Ch. 15 - Prob. 15.3TYU Ch. 15 - Simulate a 25M resistance using the circuit in...Ch. 15 - Design the phaseshift oscillator shown in Figure...Ch. 15 - Design the Wienbridge circuit in Figure 15.17 to...Ch. 15 - Prob. 15.5TYU

To derive: The expression for the frequency of oscillation

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To derive: The expression for the frequency of oscillation

Answer to Problem 15.30P

Explanation of Solution

The condition of oscillation.

Answer to Problem 15.30P

Explanation of Solution

To find: The values of capacitor and RF

Answer to Problem 15.30P

Explanation of Solution

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