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Lagrange’s and Hamilton’s equations | Basic Physics for IIT JAM PDF Download

Elegant and powerful methods have also been devised for solving dynamic problems with constraints. One of the best known is called Lagrange’s equations. The Lagrangian L is defined as L = TV, where T is the kinetic energy and V the potential energy of the system in question. Generally speaking, the potential energy of a system depends on the coordinates of all its particles; this may be written as V = V(x1, y1, z1, x2, y2, z2, . . . ). The kinetic energy generally depends on the velocities, which, using the notation vx = dx/dt = , may be written T = T(1, 1, ż1, 2, 2, ż2, . . . ). Thus, a dynamic problem has six dynamic variables for each particle—that is, x, y, z and ẋ, ẏ, ż—and the Lagrangian depends on all 6N variables if there are N particles.
In many problems, however, the constraints of the problem permit equations to be written relating at least some of these variables. In these cases, the 6N related dynamic variables may be reduced to a smaller number of independent generalized coordinates (written symbolically as q1, q2, . . . qi, . . . ) and generalized velocities (written as 1, 2, . . . i, . . . ), just as, for the rigid body, 3N coordinates were reduced to six independent generalized coordinates (each of which has an associated velocity). The Lagrangian, then, may be expressed as a function of all the qi and i. It is possible, starting from Newton’s laws only, to derive Lagrange’s equations
Lagrange’s and Hamilton’s equations | Basic Physics for IIT JAM  (94)

where the notation ∂L/∂qi means differentiate L with respect to qi only, holding all other variables constant. There is one equation of the form for each of the generalized coordinates qi (e.g., six equations for a rigid body), and their solutions yield the complete dynamics of the system. The use of generalized coordinates allows many coupled equations of the form to be reduced to fewer, independent equations of the form.
Lagrange’s and Hamilton’s equations | Basic Physics for IIT JAM  (94)

There is an even more powerful method called Hamilton’s equations. It begins by defining a generalized momentum pi, which is related to the Lagrangian and the generalized velocity i by pi = ∂L/∂i. A new function, the Hamiltonian, is then defined by H = Σi i pi − L. From this point it is not difficult to derive
Lagrange’s and Hamilton’s equations | Basic Physics for IIT JAM  (95)

and
Lagrange’s and Hamilton’s equations | Basic Physics for IIT JAM  (96)

These are called Hamilton’s equations. There are two of them for each generalized coordinate. They may be used in place of Lagrange’s equations, with the advantage that only first derivatives—not second derivatives—are involved.

The Hamiltonian method is particularly important because of its utility in formulating quantum mechanics. However, it is also significant in classical mechanics. If the constraints in the problem do not depend explicitly on time, then it may be shown that HTV, where T is the kinetic energy and V is the potential energy of the system—i.e., the Hamiltonian is equal to the total energy of the system. Furthermore, if the problem is isotropic (H does not depend on direction in space) and homogeneous (H does not change with uniform translation in space), then Hamilton’s equations immediately yield the laws of conservation of angular momentum and linear momentum, respectively.

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FAQs on Lagrange’s and Hamilton’s equations - Basic Physics for IIT JAM

1. What are Lagrange's equations in physics?
Ans. Lagrange's equations are a set of second-order differential equations used to describe the motion of particles or systems in classical mechanics. These equations are derived from the principle of least action, which states that the path taken by a particle between two points in time is the one that minimizes the action integral. Lagrange's equations provide an alternative and often more convenient approach to solving mechanical problems compared to Newton's laws of motion.
2. What are Hamilton's equations in physics?
Ans. Hamilton's equations are a set of first-order differential equations used to describe the motion of particles or systems in classical mechanics. These equations are derived from Hamilton's principle, which states that the path taken by a particle between two points in time is the one that extremizes the action integral. Hamilton's equations provide a powerful tool for studying the dynamics of systems and are particularly useful in the field of Hamiltonian mechanics.
3. How do Lagrange's equations differ from Hamilton's equations?
Ans. Lagrange's equations and Hamilton's equations are two different approaches to describing the motion of particles or systems in classical mechanics. Lagrange's equations are second-order differential equations that are derived from the principle of least action. They express the equations of motion in terms of generalized coordinates and their time derivatives. These equations are particularly useful for solving mechanical problems and for analyzing systems with constraints. On the other hand, Hamilton's equations are first-order differential equations derived from Hamilton's principle. They express the equations of motion in terms of generalized coordinates and their canonical conjugate momenta. These equations provide a convenient way to study the dynamics of systems and often simplify the mathematical analysis.
4. How are Lagrange's and Hamilton's equations related to each other?
Ans. Lagrange's equations and Hamilton's equations are mathematically related and can be derived from each other. Starting from Lagrange's equations, one can obtain Hamilton's equations by introducing the concept of generalized momenta and transforming the equations into a first-order form. This transformation is known as the Legendre transformation. Conversely, Hamilton's equations can be used to derive Lagrange's equations by eliminating the momenta from the equations. This process involves solving for the generalized velocities in terms of the generalized momenta and substituting these expressions back into Lagrange's equations. Overall, Lagrange's and Hamilton's equations provide different perspectives on the dynamics of systems in classical mechanics, but they are mathematically equivalent and can be used interchangeably depending on the problem at hand.
5. What are the advantages of using Lagrange's and Hamilton's equations in physics?
Ans. Lagrange's and Hamilton's equations offer several advantages in the field of physics: 1. Simplified mathematical analysis: Lagrange's and Hamilton's equations often lead to simpler and more elegant mathematical formulations compared to Newton's laws of motion. They allow physicists to express the equations of motion in terms of generalized coordinates and momenta, which can greatly simplify the calculations involved. 2. Handling of constraints: Lagrange's equations are particularly useful for studying systems with constraints, such as particles moving on a curved surface or connected by rigid constraints. The use of generalized coordinates allows for a more natural treatment of constraints, making Lagrange's equations well-suited for analyzing complex mechanical systems. 3. Conservation laws: Lagrange's and Hamilton's equations provide a powerful framework for studying conservation laws in classical mechanics. The symmetries and invariances of the Lagrangian or Hamiltonian can directly correspond to conserved quantities, such as energy or angular momentum. This makes it easier to identify and analyze the conservation laws governing a system. 4. Compatibility with quantum mechanics: Lagrange's and Hamilton's formulations of classical mechanics have a close relationship with quantum mechanics. The principles and techniques used in Lagrangian and Hamiltonian mechanics form the basis of quantum mechanics, making them essential tools for understanding the behavior of particles at the quantum level. 5. Flexibility in coordinate choice: Lagrange's and Hamilton's equations allow for greater flexibility in choosing appropriate coordinate systems for a given problem. This flexibility can simplify the analysis by allowing physicists to choose coordinates that align with the symmetries and constraints of the system, making the equations more manageable and intuitive.
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