Independence of Position and Velocity in Lagrangian Mechanics

In summary, both q(t) and dq/dt are treated as independent parameters in Lagrangian mechanics, while q and p are treated as independent in Hamiltonian mechanics. This is justified because the Lagrangian is a function of those variables and allows for any position and velocity at a given time. This relationship between velocity and position can also be derived from Newton's laws, but can also be obtained by examining the Lagrangian and its properties. The freedom in choosing boundary conditions also plays a role in this justification.
  • #1
quickAndLucky
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In Lagrangian mechanics, both q(t) and dq/dt are treated as independent parameters. Similarly, in Hamiltonian mechanics q and p are treated as independent. How is this justified, considering you can derive the generalized velocity from the q(t) by just taking a time derivative. Does it have anything to do with a freedom in choosing boundary conditions?
 
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  • #2
It has to do with the variational calculus of the mechanics: in a way of speaking the time is frozen and variation of variables is used to derive the L and/or H equations.
 
  • #3
quickAndLucky said:
In Lagrangian mechanics, both q(t) and dq/dt are treated as independent parameters. Similarly, in Hamiltonian mechanics q and p are treated as independent. How is this justified, considering you can derive the generalized velocity from the q(t) by just taking a time derivative. Does it have anything to do with a freedom in choosing boundary conditions?

They are independent in the sense that, in general, a particle can have any position and any velocity at a given time. The Lagrangian itself is then a function of those variables. For example, for 3D unconstrained motion, the Lagrangian is a function of 6 variables. You should think of this as an abstract mathematical object.

If you have the specific trajectory of a particle, then clearly there is a relationship between the velocity at one time and the change in position. You can get this from Newton's laws. But, you can also get this specific trajectory by looking at the properties of the Lagrangian. This, of course, depends on the initial conditions of the particle as well as the Lagrangian.
 

1. What is the concept of independence of position and velocity in Lagrangian mechanics?

The independence of position and velocity in Lagrangian mechanics refers to the fact that the equations of motion in this framework are independent of the specific coordinate system chosen to describe the system's motion. This means that the equations will hold true regardless of the origin, orientation, or scale of the coordinate system, making it a more general and powerful approach to solving mechanical problems.

2. Why is the concept of independence of position and velocity important in Lagrangian mechanics?

The independence of position and velocity is important because it allows for a more elegant and concise formulation of the equations of motion. By eliminating the dependence on specific coordinate systems, Lagrangian mechanics provides a more general and versatile approach to solving mechanical problems.

3. How does the principle of least action relate to independence of position and velocity in Lagrangian mechanics?

The principle of least action, which states that a system will follow the path that minimizes the action (a measure of the system's energy) between two points in time, is a fundamental concept in Lagrangian mechanics. The independence of position and velocity allows for the formulation of this principle, as it ensures that the equations of motion will hold true regardless of the chosen coordinate system.

4. How is the Lagrangian function used to incorporate the independence of position and velocity in Lagrangian mechanics?

The Lagrangian function, which is defined as the difference between the system's kinetic and potential energies, is a central component of Lagrangian mechanics. By using this function, the equations of motion can be derived without any reference to specific coordinate systems, thereby incorporating the concept of independence of position and velocity.

5. What advantages does the concept of independence of position and velocity offer in solving mechanical problems?

The independence of position and velocity in Lagrangian mechanics allows for a more general and powerful approach to solving mechanical problems. It eliminates the need to choose a specific coordinate system, making it easier to apply to a wide range of systems and simplifying the calculations involved. This approach also leads to more elegant and concise equations of motion, making it a preferred method in many applications.

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