[NOTES/CM-02002] Constrraints, Degrees of Freedom, Generalized Coordinates

Constraints
For many systems the coordinates and velocities must satisfy constraint relations. For example for a particle moving on the surface of a sphere the
constraint relation
$$x^2+y^2+z^2=R^2$$
must be imposed separately on the solutions of EOM.
Several different types of constraints are possible

1. $z=f(x,y)$ particle moves on a surface
2. $f(x,y,z,\dot{x},\dot{y},\dot{z})=0.$
3. For gas molecules in a cubical container the position coordinates satisfy \[ -L\leq x\leq L,\qquad -L\leq y\leq L \qquad -L\leq z\le L

Constraint relations involving only coordinates and possibly time, are called  holonomic  constraints. These are given by expressions of the form \begin{equation} f_j(\vec{x}_1,\vec{x}_2,\dots \vec{x}_N,t) = 0, \qquad\qquad  j=1 \dots m. \end{equation} The Lagrangian formalism is  applicable to systems  with holonomic constraints only.

Degrees of freedom
We shall be concerned only with systems having holonomic constraints. For a system with $N$ particles, $3N$ coordinates are needed. If these coordinates satisfy $m$ relations of type $f(\vec{x},t)=0$. Only $3N-m$ coordinates will be independent and we say that the system has $3N-m$ degrees of freedom.


Generalized coordinates
For a system with \(m\) degrees of freedom, one needs \(m\) independent variables to specify the configuration of the system. A set of \(m\) functions of Cartesian coordinates is called generalized coordinates if they having the following  properties: