Lagrangian
A Lagrangian of a dynamical system is a functional of the dynamical variables which concisely describes the equations of motion of the system. The equations of motion are obtained by means of an action principle, written as
denoting the set of dynamical parameters of the system.The equations of motion obtained by means of the functional derivative are identical to the usual Euler-Lagrange equations. A dynamical system whose equations of motion are obtainable by means of an action principle on a suitably chosen Lagrangian are known as Lagrangian dynamical systems. Examples of Lagrangian dynamical systems range from the Standard Model to Newton's equations to purely mathematical problems such as geodesic equations and Plateau's problem.
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2 Mathematical formalism 3 See also |
The concept of a Lagrangian was originally introduced in a reformulation of classical mechanics known as Lagrangian mechanics. In this context, the Lagrangian is usually taken to be the kinetic energy of a mechanical system minus its potential energy.
Suppose we have a three dimensional space and the Lagrangian
Using the above result we can easily show that the Lagrangian approach is equivalent to the Newtonian one by writing the force in terms of the potential , then the resulting equation is , exactly the same equation in a Newtonian approach for a constant mass object, a very similar deduction gives us the expression which is Newton's Second Law in its general form.
Suppose we have a three dimensional space in spherical coordinates, r, θ, φ with the Lagrangian
Suppose we have an n-dimensional manifold, M and a target manifold T. Let be the configuration space of smooth functions from M to T.
Before we go on, let's give some examples:
In order for the action to be local, we need additional restrictions on the action. If , we assume S(φ) is the integral over M of a function of φ, its derivative and the position called the Lagrangian, . In other words,
.
Most of the time, we will also assume in addition that the Lagrangian depends on only the field value and its first derivative but not the higher derivatives; this is only a matter of convenience, though, and is not true in general! We will make this assumption for the rest of this article.
Given boundary conditions, basically a specification of the value of φ at the boundary of M is compact or some limit on φ as x approaches (this will help in doing integration by parts), we can denote the subset of consisting of functions, φ such that all functional derivatives of S at φ are zero and φ satisfies the given boundary conditions.
The solution is given by the Euler-Lagrange equations (thanks to the boundary conditions),
.
Incidentally, the left hand side is the negative of functional derivative of the action with respect to φ.An example from classical mechanics
Then, the Euler-Lagrange equation is where the time derivative is written conventionally as a dot above the quantity being differentiated.
Then, the Euler-Lagrange equations are:
Here, the set of dynamical parameters is just the time , and the dynamical variables are the trajectories of the particle.Mathematical formalism
Now suppose there's a functional, , called the action. Note it's a mapping to , not . This has got to do with physical reasons.