1270 E Classical Mechanics
E.3 Lagrangian Mechanics
Lagrangian mechanics is a way of writing the classical mechanics of Newton in a
way that has the same form in any coordinate system. It is convenient for problems in
which Cartesian coordinates cannot conveniently be used. We specify the positions of
the particles in a system by the coordinatesq 1 ,q 2 ,q 3 ,...,qn, wherenis the number of
coordinates, equal to three times the number of particles if they are point-mass particles
that move in three dimensions. These coordinates can be any kind of coordinates, such
as spherical polar coordinates, cylindrical polar coordinates, and so on. To specify the
state of the system, some measures of the particles’ velocities are needed in addition
to coordinates. The Lagrangian method uses the time derivatives of the coordinates:
.
qi
dqi
dt
(i1, 2,...,n) (E-11)
We use a symbol with a dot over it to represent a time derivative.
The Lagrangian function is defined by
LK −V (definition of the Lagrangian) (E-12)
whereK andVare the kinetic and potential energy expressed in terms of theqsand
the
.
qs. TheLagrangian equations of motionare:
d
dt
(
∂L
∂qi
)
−
∂L
∂qi
0(i1, 2,...,n) (E-13)
These equations are equivalent to Newton’s second law and we present them without
derivation. These equations have exactly the same form for all coordinate systems, so
that the work of transforming Newton’s second law into a particular coordinate system
can be avoided, once we have expressed the kinetic and potential energy in terms of
the appropriate coordinates.^6
Particle of
massm
Plane of
orbit
Fixed
center
Orbit
Vector r
Velocity
vector
Angular
momentum
vector
Figure E.2 Diagram to Illustrate the
Definition of the Angular Momentum
Vector.The angular momentum vector,
L, is perpendicular to the vectorrand
the vectorv, and has magnitude equal
tom|r||v|.
One application of Lagrange’s equations of motion is to a particle orbiting about
a fixed point in a plane. We use plane polar coordinatesρandφ(withφmeasured in
radians), and place the origin of coordinates at the fixed point. The component of the
velocity parallel to the position vector is
.
ρ, and the component perpendicular to this
direction isρ
.
φ, so that the Lagrangian is
L
1
2
m
.
ρ^2 +
1
2
mρ^2
.
φ^2 −V(ρ,φ) (E-14)
The Lagrangian equations of motion are
d(2m
.
ρ)
dt
−mρ
.
φ
2
+
∂V
∂ρ
0 (E-15)
d(mρ^2
.
φ)
dt
+
∂V
∂φ
0 (E-16)
(^6) This fact is proved in J. C. Slater and N. Frank,Mechanics, McGraw-Hill, New York, 1947, p. 69ff, or
in any other book on the same subject.