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Work. Generalized Coordinates  Transformation rules define alternate sets of coordinates. 3N Cartesian coordinates x i f generalized coordinates q m.

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Presentation on theme: "Work. Generalized Coordinates  Transformation rules define alternate sets of coordinates. 3N Cartesian coordinates x i f generalized coordinates q m."— Presentation transcript:

1 Work

2 Generalized Coordinates  Transformation rules define alternate sets of coordinates. 3N Cartesian coordinates x i f generalized coordinates q m Select f degrees of freedom  Small changes in a coordinate can be expressed by the chain rule. polar coordinate example

3 Generalized Velocity  The differentials for the coordinates don’t depend on the coordinates themselves.  The time derivative gives generalized velocities. One per generalized coordinateOne per generalized coordinate  A general identity relates the generalized coordinates and velocities.

4 Generalized Force  Force acting over a small displacement is the work. Express in generalized coordinates  Rewrite the work in terms of the generalized force components, Q m, Q t Last term for time dependence

5 Constraint Forces  All the Q m are applied forces. No dependence on constraint coordinatesNo dependence on constraint coordinates Not forces of constraintNot forces of constraint Constraint forces do no workConstraint forces do no work  Forces of constraint are often unknown. Newtonian problem complicated by themNewtonian problem complicated by them

6 Potential Energy  A conservative force derives from a potential V.  The generalized force can be derived from the same potential. Work expressed in terms of potential energy if conservative forceWork expressed in terms of potential energy if conservative force

7 Acceleration and Velocity  The work can be expressed by mass and acceleration. Mass m (i) related to xi  The Cartesian coordinate is transformed to the generalized coordinate. Use the boxed identity Work expanded in terms

8 Kinetic Energy  The velocity can be used to find the kinetic energy T. Rearranging summationRearranging summation

9 Work Compared  Work in terms of the kinetic energy must equal the work in terms of the force. Each generalized component considered separatelyEach generalized component considered separately Time-dependent part just Newton’s 2 nd lawTime-dependent part just Newton’s 2 nd law trivial identity; ma=F

10 Lagrangian Function  Conservative forces depend only on position. Leave non-conservative forces on the right side of the equationLeave non-conservative forces on the right side of the equation  The quantity L = T  V is the Lagrangian.  This gives Lagrange’s equations of motion. For f equations, 2 f constantsFor f equations, 2 f constants next

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