(a) Calculate Vout for vin=0 V.(b) Calculate Vout for Vin = 10 V.(c) Calculate Vout for Vin=-10 V.(d) Using your insights from (a) - (c), draw a graph that shows vout as a function of vin. Put vin onthe horizontal axis as it is the independent variable, with Vout on the vertical axis as it is thedependent variable.(e) Using your insights from (d) and your knowledge of resistive circuits, design a circuit thathas the relationship between Vin and Vout shown in the graph below.-10V-5VVout2.5V5V 10V-2.5VVin The circuit below has a variable voltage vin as its input. We are interested in Vout as a function ofVin. In other words, if we vary the value of the voltage source vin, what will be the effect on thevoltage Vout? The steps below will help you to investigate this question, and your answers willform the basis for a new design. Assume that the diode can be sufficiently modelled as simplediode with forward voltage of 0.7 V (you do not need Shockley's equation).Vin100ΩMVf = 0.7 V2 VV out

Answered: Image /qna-images/answer/fabb7602-a779-41b5-88bb-d6e162df07db.jpg

(b) Calculate your for Vin = 10 V. (c) Calculate your for Vin=-10 V. (d) Using your insights from (a) - (c), draw a graph that shows Vout as a function of vin. Put vin on the horizontal axis as it is the independent variable, with your on the vertical axis as it is the dependent variable. (e) Using your insights from (d) and your knowledge of resistive circuits, design a circuit that has the relationship between Vin and Vout shown in the graph below. -10V -5V Vout 2.5V 5V 10V --2.5V Vin

(b) Calculate your for Vin = 10 V. (c) Calculate your for Vin=-10 V. (d) Using your insights from (a) - (c), draw a graph that shows Vout as a function of vin. Put vin on the horizontal axis as it is the independent variable, with your on the vertical axis as it is the dependent variable. (e) Using your insights from (d) and your knowledge of resistive circuits, design a circuit that has the relationship between Vin and Vout shown in the graph below. -10V -5V Vout 2.5V 5V 10V --2.5V Vin

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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