Fig. 1 shows an oscillator circuit using 555 timer, with RA = 1.5KQ, R₁ = 2.5KQ Vcc= 12 V, and C= 0.7215uF. Assume the diode is ideal, then 1 2 3 If the diode is disconnected, then 4 5 6 The charging time (T,) (in ms) The duty cycle (ratio) The frequency of the output signal (in Hz) 10 The discharging time (T₂) (in ms) The duty cycle (ratio) The frequency of the output signal (in Hz) 15 16 RA +Vcc Discharge RR Reset Threshold Trigger Ground +Vcc 555 Output 45 vo The emitter current I (in mA) The charging time of the capacitor (in ms) Draw to scale the transfer characteristics. Drouts A 1.25 0.375 666.7 VEE 3 Fig. 1 Fig. 2 Consider the sweep generator circuit shown in Fig. 2 where RE = 4KS2, RB = 4.7K2, VEE=30.7V, VBB= 20V, and C= 0.5 uF. The control signal (v) has a pulse duration of 0.5ms, a frequency of 500Hz, and a +12V amplitude. Then 7 2.5 3.5 8 9 1.5 0.615 500 ww RE VER B 0.5 0.667 307.8 1.75 0.6 307.7 1.4 4.0 2.0 3.0 10.5 1.8 00 C 1.0 0.333 500 2.8 1.25 0.5 400 3.0 2.5 The peak voltage of the capacitor (Vp) 6.0 The minimum value of Rg that we can use and still obtain a linear sweep 1.5 waveform (in K2) Consider a Schmitt trigger circuit with ± VSAT = 12 V, Vur=4V, and Vir=0 V. This circuit is modified to be an oscillator circuit by adding C= 3.46 µF and R=2 KS2. Then 11 The charging time (Tch) of this circuit (in msec) is 12 The discharging time (Tdisch) of this circuit ( in msec ) is Consider the circuit shown in Fig. 3 where Vz1 = 3.3V, V=4.3V, and ± VSAT= ±12 V. Then 13 The maximum output voltage 4.0 5.0 14 The minimum output voltage - 4.0 - 5.0 1.5 ماذا 9.0 1.2 4.2 1.0 D 0.75 0.5 400 1.0 0.75 666.7 12 -0.7 R₂ 3.0 2.0 7.5 2.1 L 198 5.6 Your ans. 2.0 0.7 - 12
Fig. 1 shows an oscillator circuit using 555 timer, with RA = 1.5KQ, R₁ = 2.5KQ Vcc= 12 V, and C= 0.7215uF. Assume the diode is ideal, then 1 2 3 If the diode is disconnected, then 4 5 6 The charging time (T,) (in ms) The duty cycle (ratio) The frequency of the output signal (in Hz) 10 The discharging time (T₂) (in ms) The duty cycle (ratio) The frequency of the output signal (in Hz) 15 16 RA +Vcc Discharge RR Reset Threshold Trigger Ground +Vcc 555 Output 45 vo The emitter current I (in mA) The charging time of the capacitor (in ms) Draw to scale the transfer characteristics. Drouts A 1.25 0.375 666.7 VEE 3 Fig. 1 Fig. 2 Consider the sweep generator circuit shown in Fig. 2 where RE = 4KS2, RB = 4.7K2, VEE=30.7V, VBB= 20V, and C= 0.5 uF. The control signal (v) has a pulse duration of 0.5ms, a frequency of 500Hz, and a +12V amplitude. Then 7 2.5 3.5 8 9 1.5 0.615 500 ww RE VER B 0.5 0.667 307.8 1.75 0.6 307.7 1.4 4.0 2.0 3.0 10.5 1.8 00 C 1.0 0.333 500 2.8 1.25 0.5 400 3.0 2.5 The peak voltage of the capacitor (Vp) 6.0 The minimum value of Rg that we can use and still obtain a linear sweep 1.5 waveform (in K2) Consider a Schmitt trigger circuit with ± VSAT = 12 V, Vur=4V, and Vir=0 V. This circuit is modified to be an oscillator circuit by adding C= 3.46 µF and R=2 KS2. Then 11 The charging time (Tch) of this circuit (in msec) is 12 The discharging time (Tdisch) of this circuit ( in msec ) is Consider the circuit shown in Fig. 3 where Vz1 = 3.3V, V=4.3V, and ± VSAT= ±12 V. Then 13 The maximum output voltage 4.0 5.0 14 The minimum output voltage - 4.0 - 5.0 1.5 ماذا 9.0 1.2 4.2 1.0 D 0.75 0.5 400 1.0 0.75 666.7 12 -0.7 R₂ 3.0 2.0 7.5 2.1 L 198 5.6 Your ans. 2.0 0.7 - 12
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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