MICROELECT. CIRCUIT ANALYSIS&DESIGN (LL)
MICROELECT. CIRCUIT ANALYSIS&DESIGN (LL)
4th Edition
ISBN: 9781266368622
Author: NEAMEN
Publisher: MCG
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Chapter 15, Problem 15.31P

a.

To determine

The expression for the frequency of the oscillation in the terms of C, R and Rv.

a.

Expert Solution
Check Mark

Answer to Problem 15.31P

The frequency of oscillation:

  f0=12πRC2+4RRRV

Explanation of Solution

Given:

The circuit is given for the phase shift oscillator:

  MICROELECT. CIRCUIT ANALYSIS&DESIGN (LL), Chapter 15, Problem 15.31P , additional homework tip 1

Redrawing the given circuit

  MICROELECT. CIRCUIT ANALYSIS&DESIGN (LL), Chapter 15, Problem 15.31P , additional homework tip 2

Nodal analysis at the node v1 :

  v1v0RV+v1v2R+v11 sC=0v1(1 R V +1R+sC)v2R=v0RV...........(1)

Nodal analysis at the node v2 :

  v2v1RV+v2v3R+v21 sC=0v2+v2v3+v2sRC=v1v1=v2(2+sRC)v3..........(2)

Nodal analysis at the node v3 :

  v3v2RV+v30R+v31 sC=0v2+v2v3+v3(sRC)=0v3(2+sRC)=v2v3=v22+sRC........(5)

Now, solving the equation 2 and 3:

  v1=v2(2+sRC)v22+sRC=v2(2+sRC1 2+sRC)v1=v2( ( 2+sRC ) 2 1 2+sRC)v2=v1( 2+sRC ( 2+sRC ) 2 1).........(4)

Nodal analysis at the inverting terminal:

  0v0RF+0v3R=0v0RF=v3Rv0=RFRv3

From equation (3):

  v0=( R F R)(1 2+sRC)v2( R F R)(1 2+sRC)v2

From equation 4:

  v0=( R F R)(1 2+sRC)( 2+sRC ( 2+sRC ) 2 1)v1( R F R)(1 ( 2+sRC ) 2 1)v1

Substituting values of v0 and v2 in equation (1):

  { v 1( 1 R V + 1 R +sC) 1 R( 2+sRC ( 2+sRC ) 2 1 ) v 1}=(1 R V )( R F R)(1 ( 2+sRC ) 2 1)v11RV+1R+sC2+sRCR[ ( 2+sRC ) 21]=(1 R V )( R F R)(1 ( 2+sRC ) 2 1)

Now simplifying more:

  1[ R VR ( 2+sRC ) 2R R V]{R( 2+sRC)2RRV( 2+sRC)2RV+sRRVC( 2+sRC)2sRRVC2RVsRRVC}={( 1 R V )( R F R)( 1 ( 2+sRC ) 2 1)}

  {R(4+4sRC+ s 2 R 2 C 2)R+RV(4+4sRC+ s 2 R 2 C 2)3RV+sRVRC(4+4sRC+ s 2 R 2 C 2)2sRRVC}=RF4R+4sR2C+s2R2C2R+4RV+4sRRVC+s2R2RVC23RV+4sRRVC+4s2R2RVC2+s3R3RVC32sRRVC=RF{3R+4sR2C+s2R3C2+RV+5s2R2RVC2+s3R3RVC3+6sRRVC}=RF Evaluating the frequency of oscillation, considering s=jω :

  {3R+j4ωR2C+ω2R3C2+RV+5ω2R2RVC2+jω3R3RVC3+j6ωRRVC}=RF{3R+ω2R3C2+RV5ω2R2RVC2+j(4ω R 2C ω 3 R 3 R V C 3+6ωR R VC)}=RF

Now equating imaginary part to 0:

  4ωR2Cω3R3RVC3+6ωRRVC=0ωRC(4Rω2R2RVC2+6RV)=04Rω2R2RVC2+6RV=06RV+4R=ω2R2RVC2

Now simplifying:

  ω2=1R2C2( 2 R V +4 R V +4R R V )ω2=1R2C2(2+4R[ R V +R R R V ])ω2=1R2C2(2+ 4R R R V )

Squaring on the both sides:

  ω=1 R 2 C 2 ( 2+ 4R R R V )ω=1RC2+ 4R R R V

Since, the frequency is given as:

  2πf=1RC2+4RRRV

Hence, the required frequency of oscillation is

  f0=12πRC2+4RRRV

b.

To determine

The range in the frequency of the oscillation.

b.

Expert Solution
Check Mark

Answer to Problem 15.31P

The range of frequency of oscillation:

  19.45f022.66kHz

Explanation of Solution

Given:

The circuit is given for the phase shift oscillator:

  MICROELECT. CIRCUIT ANALYSIS&DESIGN (LL), Chapter 15, Problem 15.31P , additional homework tip 3

  R=25,C=0.001μFand15RV30

The expression for the frequency of the oscillation is given as:

  f0=12πRC2+4RRRV

Substitute the known values in the above expression:

  f0=12π( 25× 10 3 )( 0.001× 10 6 )2+4( ( 25× 10 3 25× 10 3 ×15× 10 3 25× 10 3 +15× 10 3 ))=12π( 25× 10 6 )2+4( 25× 10 3 9.375× 10 3 )=1157.08× 10 62+4( 2.667)

More simplifying:

  f0=1157.08× 10 612.667=3.599157.08× 10 6=22657.464=22.66kHz

If, RV=30 , the frequency is given as:

  f0=12πRC2+4RRRV

Substitute the known values:

  f0=12π( 25× 10 3 )( 0.001× 10 6 )2+4( ( 25× 10 3 25× 10 3 ×30× 10 3 25× 10 3 +30× 10 3 ))=12π( 25× 10 6 )2+4( 25× 10 3 13.636× 10 3 )=1157.08× 10 62+4( 1.833)

More simplifying:

  f0=1157.08× 10 69.333=3.055157.08× 10 6=0.01945×106=19.45kHz

Hence, the required range of frequency of oscillation:

  19.45f022.66kHz

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Chapter 15 Solutions

MICROELECT. CIRCUIT ANALYSIS&DESIGN (LL)

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Ch. 15 - Prob. 15.6TYUCh. 15 - Prob. 15.6EPCh. 15 - Redesign the street light control circuit shown in...Ch. 15 - A noninverting Schmitt trigger is shown m Figure...Ch. 15 - For the Schmitt trigger in Figure 15.30(a), the...Ch. 15 - Prob. 15.9TYUCh. 15 - Prob. 15.8EPCh. 15 - Prob. 15.9EPCh. 15 - Consider the 555 IC monostablemultivibrator. (a)...Ch. 15 - The 555 IC is connected as an...Ch. 15 - Prob. 15.10TYUCh. 15 - Prob. 15.11TYUCh. 15 - Prob. 15.12TYUCh. 15 - Prob. 15.12EPCh. 15 - Prob. 15.13EPCh. 15 - (a) Consider the bridge amplifier in Figure 15.46...Ch. 15 - Prob. 15.14EPCh. 15 - Prob. 15.15EPCh. 15 - Prob. 15.16EPCh. 15 - Prob. 1RQCh. 15 - Prob. 2RQCh. 15 - Consider a lowpass filter. What is the slope of...Ch. 15 - Prob. 4RQCh. 15 - Describe how a capacitor in conjunction with two...Ch. 15 - Sketch a onepole lowpass switchedcapacitor filter...Ch. 15 - Explain the two basic principles that must be...Ch. 15 - Prob. 8RQCh. 15 - Prob. 9RQCh. 15 - Prob. 10RQCh. 15 - Prob. 11RQCh. 15 - What is the primary advantage of a Schmitt trigger...Ch. 15 - Sketch the circuit and explain the operation of a...Ch. 15 - Prob. 14RQCh. 15 - Prob. 15RQCh. 15 - Prob. 16RQCh. 15 - Prob. 17RQCh. 15 - Prob. 18RQCh. 15 - Prob. D15.1PCh. 15 - Prob. 15.2PCh. 15 - The specification in a highpass Butterworth filter...Ch. 15 - (a) Design a twopole highpass Butterworth active...Ch. 15 - (a) Design a threepole lowpass Butterworth active...Ch. 15 - Prob. 15.6PCh. 15 - Prob. 15.7PCh. 15 - Prob. 15.8PCh. 15 - A lowpass filter is to be designed to pass...Ch. 15 - Prob. 15.10PCh. 15 - Prob. 15.11PCh. 15 - Prob. D15.12PCh. 15 - Prob. D15.13PCh. 15 - Prob. D15.14PCh. 15 - Prob. 15.15PCh. 15 - Prob. 15.16PCh. 15 - Prob. 15.17PCh. 15 - Prob. 15.18PCh. 15 - A simple bandpass filter can be designed by...Ch. 15 - Prob. 15.20PCh. 15 - Prob. 15.21PCh. 15 - Prob. D15.22PCh. 15 - Prob. 15.23PCh. 15 - Consider the phase shift oscillator in Figure...Ch. 15 - In the phaseshift oscillator in Figure 15.15, the...Ch. 15 - Consider the phase shift oscillator in Figure...Ch. 15 - Prob. 15.27PCh. 15 - Prob. 15.28PCh. 15 - Prob. 15.29PCh. 15 - Prob. 15.30PCh. 15 - Prob. 15.31PCh. 15 - A Wienbridge oscillator is shown in Figure P15.32....Ch. 15 - Prob. 15.33PCh. 15 - Prob. D15.34PCh. 15 - Prob. D15.35PCh. 15 - Prob. 15.36PCh. 15 - Prob. 15.37PCh. 15 - Prob. D15.38PCh. 15 - Prob. 15.39PCh. 15 - Prob. 15.40PCh. 15 - Prob. 15.41PCh. 15 - For the comparator in the circuit in Figure...Ch. 15 - Prob. 15.43PCh. 15 - Prob. 15.44PCh. 15 - Prob. 15.45PCh. 15 - Consider the Schmitt trigger in Figure P15.46....Ch. 15 - The saturated output voltages are VP for the...Ch. 15 - Consider the Schmitt trigger in Figure 15.30(a)....Ch. 15 - Prob. 15.50PCh. 15 - Prob. 15.52PCh. 15 - Prob. 15.53PCh. 15 - Prob. 15.54PCh. 15 - Prob. 15.55PCh. 15 - Prob. 15.56PCh. 15 - Prob. 15.57PCh. 15 - Prob. D15.58PCh. 15 - Prob. 15.59PCh. 15 - The saturated output voltages of the comparator in...Ch. 15 - (a) The monostablemultivibrator in Figure 15.37 is...Ch. 15 - A monostablemultivibrator is shown in Figure...Ch. 15 - Prob. D15.63PCh. 15 - Design a 555 monostablemultivibrator to provide a...Ch. 15 - Prob. 15.65PCh. 15 - Prob. 15.66PCh. 15 - Prob. 15.67PCh. 15 - Prob. 15.68PCh. 15 - An LM380 must deliver ac power to a 10 load. The...Ch. 15 - Prob. 15.70PCh. 15 - Prob. D15.71PCh. 15 - Prob. 15.72PCh. 15 - (a) Design the circuit shown in Figure P15.72 such...Ch. 15 - Prob. 15.74PCh. 15 - Prob. 15.75PCh. 15 - Prob. 15.76PCh. 15 - Prob. D15.77PCh. 15 - Prob. 15.78P
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