How does the power, P, dissipated by a resistor depend on the indicated parameter (resistance, R, of the resistor, or the voltage or current of the supply) for each of the following scenarios? I am looking for a mathematical equation for power as a function of the indicated parameter followed by a description of the dependence - does the power increase, decrease, remain the same or some other dependence, as the parameter is increased? (and if other, describe.) If it is increasing or decreasing, by what factor does the power change if the parameter is increased by a factor of 3? (a) Constant R, powered by ideal voltage supply (We will examine real batteries that have internal resistance in class and the next homework.) How does P depend on the voltage, V, of the supply? (b) Constant R, powered by ideal current supply. How does power depend on the current I? (c) Ideal battery operating at a fixed voltage, powering a variable resistor R. How does P depend on the resistance, R, of the resistor? (d) Ideal current source operating at a fixed current, powering a variable resistor R. How does P depend on the resistance, R, of the resistor?

How does the power, P, dissipated by a resistor depend on the indicated parameter (resistance, R, of the resistor, or the voltage or current of the supply) for each of the following scenarios? I am looking for a mathematical equation for power as a function of the indicated parameter followed by a description of the dependence - does the power increase, decrease, remain the same or some other dependence, as the parameter is increased? (and if other, describe.) If it is increasing or decreasing, by what factor does the power change if the parameter is increased by a factor of 3? (a) Constant R, powered by ideal voltage supply (We will examine real batteries that have internal resistance in class and the next homework.) How does P depend on the voltage, V, of the supply? (b) Constant R, powered by ideal current supply. How does power depend on the current I? (c) Ideal battery operating at a fixed voltage, powering a variable resistor R. How does P depend on the resistance, R, of the resistor? (d) Ideal current source operating at a fixed current, powering a variable resistor R. How does P depend on the resistance, R, of the resistor?

College Physics

11th Edition

ISBN:9781305952300

Author:Raymond A. Serway, Chris Vuille

Publisher:Raymond A. Serway, Chris Vuille

Chapter1: Units, Trigonometry. And Vectors

Section: Chapter Questions

Problem 1CQ: Estimate the order of magnitude of the length, in meters, of each of the following; (a) a mouse, (b)...

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