PHYSICS Unit 6CINMOTION>>>>>>gpb.org/physics-motionThe Doppler EffectThe Doppler Effect LabName:Date:Questions to consider:1. How would the observed frequency compare to the emitted frequency if the observer was moving in thesame direction at the same velocity as the car? Draw a diagram to support your answer.2. Based on your findings, how would the observed frequency compare to the emitted frequency if the observerwas moving toward a stationary car? Draw a diagram to support your answer.3. How would the observed frequency compare to the emitted frequency if the observer was moving away froma stationary car? Draw a diagram to support your answer.Copyright © 2018 Georgia Public Broadcasting. All rights reserved. Use or distribution by an unintended recipient is prohibited.Unit 6C The Doppler Effect Lab

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1. How would the observed frequency compare to the emitted frequency if the observer was moving in the same direction at the same velocity as the car? Draw a diagram to support your answer. 2. Based on your findings, how would the observed frequency compare to the emitted frequency if the observe was moving toward a stationary car? Draw a diagram to support your answer. 3. How would the observed frequency compare to the emitted frequency if the observer was moving away from a stationary car? Draw a diagram to support your answer.

1. How would the observed frequency compare to the emitted frequency if the observer was moving in the same direction at the same velocity as the car? Draw a diagram to support your answer. 2. Based on your findings, how would the observed frequency compare to the emitted frequency if the observe was moving toward a stationary car? Draw a diagram to support your answer. 3. How would the observed frequency compare to the emitted frequency if the observer was moving away from a stationary car? Draw a diagram to support your answer.

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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Wave Motion

A wave motion is defined as the propagation of disturbances or transfer of energy and momentum from the state of rest or equilibrium to another point in a medium without any actual transfer of matter between them. In a simple explanation, it is the propagation of energy through a medium that is produced due to the repeated vibrations of the particles. Common things we see day to day like waves on water oscillation of a pendulum or bell, light wave, and all the subatomic particles exhibiting wavelike properties. The propagation of waves depends on the medium and their properties. The wave function is the disturbance that produces waves as a function of time. This disturbance oscillates periodically with a fixed frequency and wavelength. There are linear wave motion and non-linear wave motion based on their propagation, motion, and time period where linear wave motion is like sinusoidal waves and non-linear wave motion like a wave motion that gets interrupted in the middle of their propagation.

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