4. What value of filter capacitor is required to produce a 1% ripple factor for a full-wave rectifier having a load resistance of 1.5k. Assume the rectifier produces a peak output of 18 V. 5. A full-wave rectifier produces an 80 V peak rectified voltage from a 60 Hz ac source. If a filter capacitor 15μF is used, determine the ripple factor for a load resistance of 10k.
4. What value of filter capacitor is required to produce a 1% ripple factor for a full-wave rectifier having a load resistance of 1.5k. Assume the rectifier produces a peak output of 18 V. 5. A full-wave rectifier produces an 80 V peak rectified voltage from a 60 Hz ac source. If a filter capacitor 15μF is used, determine the ripple factor for a load resistance of 10k.
Introductory Circuit Analysis (13th Edition)
13th Edition
ISBN:9780133923605
Author:Robert L. Boylestad
Publisher:Robert L. Boylestad
Chapter1: Introduction
Section: Chapter Questions
Problem 1P: Visit your local library (at school or home) and describe the extent to which it provides literature...
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Solve 4,5 only
![1. A certain rectifier filter produces a dc output voltage of 75 V with a peak-to-peak ripple voltage
of 0.5 V. Calculate the ripple factor.
2.
A certain full-wave rectifier has a peak output voltage of 30 V. A 50 F capacitor-input filter is
connected to the rectifier. Calculate the peak-to-peak ripple and the dc output voltage
developed across a load resistance.
3.
What is the percentage of ripple for the rectifier filter in Problem 2?
4. What value of filter capacitor is required to produce a 1% ripple factor for a full-wave rectifier
having a load resistance of 1.5k. Assume the rectifier produces a peak output of 18 V.
5.
A full-wave rectifier produces an 80 V peak rectified voltage from a 60 Hz ac source. If a filter
capacitor 15μF is used, determine the ripple factor for a load resistance of 10k.
6. Determine the peak-to-peak ripple and dc output voltages in Figure 2-98. The transformer has
a 36 V rms secondary voltage rating, and the line voltage has a frequency of 60 Hz. Consider a
full-wave rectifier and RL=3.5k and C=100μF.
[Consider all the diodes in the problems are Si diode]](/v2/_next/image?url=https%3A%2F%2Fcontent.bartleby.com%2Fqna-images%2Fquestion%2F8fb69cb6-850d-4a3f-91d9-c6330f459c17%2Fed61668d-6347-42ea-b847-7b9f3a184bed%2Fm2na9bm_processed.jpeg&w=3840&q=75)
Transcribed Image Text:1. A certain rectifier filter produces a dc output voltage of 75 V with a peak-to-peak ripple voltage
of 0.5 V. Calculate the ripple factor.
2.
A certain full-wave rectifier has a peak output voltage of 30 V. A 50 F capacitor-input filter is
connected to the rectifier. Calculate the peak-to-peak ripple and the dc output voltage
developed across a load resistance.
3.
What is the percentage of ripple for the rectifier filter in Problem 2?
4. What value of filter capacitor is required to produce a 1% ripple factor for a full-wave rectifier
having a load resistance of 1.5k. Assume the rectifier produces a peak output of 18 V.
5.
A full-wave rectifier produces an 80 V peak rectified voltage from a 60 Hz ac source. If a filter
capacitor 15μF is used, determine the ripple factor for a load resistance of 10k.
6. Determine the peak-to-peak ripple and dc output voltages in Figure 2-98. The transformer has
a 36 V rms secondary voltage rating, and the line voltage has a frequency of 60 Hz. Consider a
full-wave rectifier and RL=3.5k and C=100μF.
[Consider all the diodes in the problems are Si diode]
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