Lagrangian Dynamics
when is F or H conserved
0 for an isolated system - an experiment done today will be equal to an experiment done tomorrow
A bead moves on a frictionless wire. How many degrees of freedom are there?
1
attwoods machine setup (inertia / DOF)
1 degree of freedom
orbit stability cont. omega value
A is positive assumed attractive central potential
lagrange, vary theta with r fixed
G = torque = generalised force dL/d theta dot = (angular momentum) rate of change of angular momentum is equal to the torque
Poisson Bracket - Transformation - symmetry
G defintion delta f chain rule sub in G
galilean relativity on H
Galileo's theory of relativity states that there is no absolute or preferred: 1. origin of time, 2. position in space, 3. orientation in space, 4. inertial frame of reference. 3. insensitive to the rotation
why you cant sub in J and get the lagrange to work
J is a generalised momenta (+combines r and phi) Lagrange should only contain generalised coordinates, generalised velocities and time
is any function of the generalised coords is time dependent
Poisson bracket + explicit dependence through partial derivative
double pendulum T
T quadratic n=2 DoF
lagrangian in polar coordinates L = T-V
Vr , theta fixed
arbitrary motion of a system
a n and phi n are determined by initial conditions
symmetries of lagrangian
adding a constant = change zero of PE multiplying by a const. = change of units can add a total derivative wrt time (use principle of least actions) parity
rewrite radius of orbit with constants
angular momentum = J A determines strength of inverse square law
Lagrangian for theta in central potential
angular momentum = J J is out of plane where motion is occurring
ball round cone L and H equations
angular momentum around axis of cone conserved
generating function
any function that is a function of coordinates momenta and time
vectors types of vector parity
axial vector (built as cross products) unchanged polar vector changes
We now consider a point particle of mass m sliding frictionlessly inside a conical vase of opening angle θ whose axis is vertical
azimuthal round the cone J is angular momentum
boost definition
brackets (X-Xdot t) is the x position of com @ t=0
[F,G]
change in F generated by the function G Poisson bracket * infinite quantity that controls the size of the transformation
virtual displacement
displacement of bead consistent with forces of constraint has to be perpendicular with the forces dot product = 0, no work is done
coupled systems
energy contribution of one part of the system depends on coords or velocities on another part of the system
bead on wire H example
energy not constant with time as driving force
generalised force Qj
force on particle dot product with derivative of position vector wrt to generalised coordinate
how is the bead held on the wire
forces of constraint - always act in direction that bead can be instantaneously moving
turning point (differentials)
function f(x) condition for max/min to first order f(x+dx)-f(x)=0 Taylor series near turning point is the position of turning point f'(x0) = 0 so it behaves quadratically near the turning point
Hamiltonian generalised
in Hamilton's we have 2N first order differential equations
find functional form of x(t) that minimises S
integrate by parts delta L
Lagrangian for r in central potential
mr𝜃˙^2 is a centrifugal term (not a real force) acts as a force in lagrange equation suppose no radial acceleration
virtual displacement equation given variation in generalised coordinate
no variation in time as forces in constraint would change
D'Alembert's Principle
only includes applied forces written as Fi or m double dot r For a system of mass of particles, the sum of the difference of the force acting on the system and the time derivatives of the momenta is zero when projected onto any virtual displacement.
lagrange in polar fixed theta
rate of change of momentum along r direction is equal to the radial force
spends more/less when lagrangian is large
spends least time when L is large
alternative from of lagrange (time independent)
total derivative dL/dt no explicit time dependence means terms in bracket is constant with time
particle of mass m in a central attractive potential
use
