PHY 711 Classical Mechanics and Mathematical Methods

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Presentation transcript:

PHY 711 Classical Mechanics and Mathematical Methods 9-9:50 AM MWF Olin 107 Plan for Lecture 5: Reading: Chapter 2 of Fetter & Walecka Physics described in accelerated coordinate frames Linear acceleration Angular acceleration Foucault pendulum 9/06/2017 PHY 711 Fall 2017 -- Lecture 5

9/06/2017 PHY 711 Fall 2017 -- Lecture 5

9/06/2017 PHY 711 Fall 2017 -- Lecture 5

9/06/2017 PHY 711 Fall 2017 -- Lecture 5

Physics in accelerated reference frames 9/06/2017 PHY 711 Fall 2017 -- Lecture 5

Physical laws as described in non-inertial coordinate systems Newton’s laws are formulated in an inertial frame of reference For some problems, it is convenient to transform the the equations into a non-inertial coordinate system 9/06/2017 PHY 711 Fall 2017 -- Lecture 5

Comparison of analysis in “inertial frame” versus “non-inertial frame” 9/06/2017 PHY 711 Fall 2017 -- Lecture 5

Properties of the frame motion (rotation only): dW dW 9/06/2017 PHY 711 Fall 2017 -- Lecture 5

Properties of the frame motion (rotation only): dW 9/06/2017 PHY 711 Fall 2017 -- Lecture 5

Properties of the frame motion (rotation only): dW 9/06/2017 PHY 711 Fall 2017 -- Lecture 5

Properties of the frame motion (rotation only) -- continued Effects on acceleration (rotation only): 9/06/2017 PHY 711 Fall 2017 -- Lecture 5

Newton’s laws; Let r denote the position of particle of mass m: Application of Newton’s laws in a coordinate system which has an angular velocity and linear acceleration Newton’s laws; Let r denote the position of particle of mass m: Centrifugal force Coriolis force 9/06/2017 PHY 711 Fall 2017 -- Lecture 5

Motion on the surface of the Earth: Earth’s gravity Support force 9/06/2017 PHY 711 Fall 2017 -- Lecture 5

Non-inertial effects on effective gravitational “constant” 0.03 m/s2 9.80 m/s2 9/06/2017 PHY 711 Fall 2017 -- Lecture 5

Foucault pendulum http://www.si.edu/Encyclopedia_SI/nmah/pendulum.htm The Foucault pendulum was displayed for many years in the Smithsonian's National Museum of American History. It is named for the French physicist Jean Foucault who first used it in 1851 to demonstrate the rotation of the earth. 9/06/2017 PHY 711 Fall 2017 -- Lecture 5

Equation of motion on Earth’s surface w y (east) z (up) q x (south) 9/06/2017 PHY 711 Fall 2017 -- Lecture 5

Foucault pendulum continued – keeping leading terms: 9/06/2017 PHY 711 Fall 2017 -- Lecture 5

Foucault pendulum continued – keeping leading terms: 9/06/2017 PHY 711 Fall 2017 -- Lecture 5

Foucault pendulum continued – coupled equations: 9/06/2017 PHY 711 Fall 2017 -- Lecture 5

Foucault pendulum continued – coupled equations: 9/06/2017 PHY 711 Fall 2017 -- Lecture 5

9/06/2017 PHY 711 Fall 2017 -- Lecture 5

Summary of approximate solution for Foucault pendulum: 9/06/2017 PHY 711 Fall 2017 -- Lecture 5

w y (east) z (up) q x (south) 9/06/2017 PHY 711 Fall 2017 -- Lecture 5

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