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Small Oscillations - Lagrangian and Hamiltonian Equations, Classical Mechanics, CSIR-NET Physical Sc | Physics for IIT JAM, UGC - NET, CSIR NET PDF Download

Introduction

As an example of the use of the Lagrangian, we will examine the problem of small oscillations about a stable equilibrium point. The description of motion about a stable equilibrium is one of the most important problems in physics. This is true for both classical and quantum mechanics.
Although there are other means of solving this problem, the Lagrangian method results in equations of motion that emphasizes symmetries of the system.


1.1 Formulation of the Problem 

We assume that the forces acting on the system are conservative in which the potential depends only on the spatial coordinates; it is independent of the time and velocity. In addition, the transformations de¯ning the generalized coordinates are assume to not depend on the time explicitly. Hence, the constraints are time independent. For the system to be in equilibrium, the generalized force must be zero

Small Oscillations - Lagrangian and Hamiltonian Equations, Classical Mechanics, CSIR-NET Physical Sc | Physics for IIT JAM, UGC - NET, CSIR NET(1)

where q0i is the equilibrium point. Furthermore, the equilibrium point is stable if the second derivative of potential is positive; the potential is concave up at the equilibrium point.
We will be interested in small displacement about the equilibrium. Therefore, we will write the generalized coordinates in the following form qi = q0i + ηi where ηi is the displacement from the equilibrium point. Assuming the displacements are small, the potential can be expanded about q0i as follows

Small Oscillations - Lagrangian and Hamiltonian Equations, Classical Mechanics, CSIR-NET Physical Sc | Physics for IIT JAM, UGC - NET, CSIR NET(2)

The first term in the expansion is a constant, since the potential is only defined to a constant, we can ignore this term. The second term is zero, since we are expanding about the minimum. Therefore, the potential in this approximation is

Small Oscillations - Lagrangian and Hamiltonian Equations, Classical Mechanics, CSIR-NET Physical Sc | Physics for IIT JAM, UGC - NET, CSIR NET(3)

where we assume that the displacements are small such that higher order terms are negligible.

The Vij in this equation are the equivalent spring constant for the one-dimensional problem. In addition, we note that the Vij are symmetric as can be seen from the definition.
The kinetic energy, as shown earlier, can be written as the sum of three terms

Small Oscillations - Lagrangian and Hamiltonian Equations, Classical Mechanics, CSIR-NET Physical Sc | Physics for IIT JAM, UGC - NET, CSIR NET

where

Small Oscillations - Lagrangian and Hamiltonian Equations, Classical Mechanics, CSIR-NET Physical Sc | Physics for IIT JAM, UGC - NET, CSIR NET

Since we assume that the transformations are independent of time, only the Mij terms are nonzero; this is a natural system. In addition, since Mij in general is a function of the coordinates, we expand the Mij about the equilibrium point, since we are assuming small displacements about it

Small Oscillations - Lagrangian and Hamiltonian Equations, Classical Mechanics, CSIR-NET Physical Sc | Physics for IIT JAM, UGC - NET, CSIR NET(6)

We keep only the lowest order term in this expansion, since the kinetic energy is already quadratic in the coordinates (velocities). Thus, the kinetic energy becomes

Small Oscillations - Lagrangian and Hamiltonian Equations, Classical Mechanics, CSIR-NET Physical Sc | Physics for IIT JAM, UGC - NET, CSIR NET(7)

where the relation Small Oscillations - Lagrangian and Hamiltonian Equations, Classical Mechanics, CSIR-NET Physical Sc | Physics for IIT JAM, UGC - NET, CSIR NET terms are symmetric.
The Lagrangian for small oscillations about an equilibrium point is

Small Oscillations - Lagrangian and Hamiltonian Equations, Classical Mechanics, CSIR-NET Physical Sc | Physics for IIT JAM, UGC - NET, CSIR NET (8)

where Tij describes the inertia of the system, and Vij the stiffiness1 . In Cartesian coordinates, and many other case, the kinetic energy term can be reduced toSmall Oscillations - Lagrangian and Hamiltonian Equations, Classical Mechanics, CSIR-NET Physical Sc | Physics for IIT JAM, UGC - NET, CSIR NETthe very familiar form of the kinetic energy. To calculate the equations of motion, we apply the Euler-Lagrange equations to the Lagrangian

Small Oscillations - Lagrangian and Hamiltonian Equations, Classical Mechanics, CSIR-NET Physical Sc | Physics for IIT JAM, UGC - NET, CSIR NET(9)

Keep in mind that the Mij and Vij are independent of the coordinates and time, and they are symmetric.


The Eigenvalues and Eigenvectors 

The solutions to the equations of motion are of the form

Small Oscillations - Lagrangian and Hamiltonian Equations, Classical Mechanics, CSIR-NET Physical Sc | Physics for IIT JAM, UGC - NET, CSIR NET(10)

where C is an overall scale factor, ai the relative amplitude of the ith term, and the second equation comes from substituting the solutions into the equations of motion. Notice that this is a matrix equation, representing matrix multiplication between and nxn matrix and an n-dimensional column vector. This set of equations can be solved for the allowed values of ! by setting the determinant of the coefficients of ai equal to zero.

Small Oscillations - Lagrangian and Hamiltonian Equations, Classical Mechanics, CSIR-NET Physical Sc | Physics for IIT JAM, UGC - NET, CSIR NET   (11)

where we have written the equation explicitly in matrix form.
Through the manipulations we have performed, we have arrived at an eigenvalue problem

Small Oscillations - Lagrangian and Hamiltonian Equations, Classical Mechanics, CSIR-NET Physical Sc | Physics for IIT JAM, UGC - NET, CSIR NET(12)

where Va is shown to be a multiple of Ta. First we will show that the eigenvalues (λ) are real and positive, and the eigenvectors (a) are orthogonal. Start by taking the complex conjugate of Eq. 12

Small Oscillations - Lagrangian and Hamiltonian Equations, Classical Mechanics, CSIR-NET Physical Sc | Physics for IIT JAM, UGC - NET, CSIR NET(13)

where we have used the fact that V and T are real and symmetric, and in addition, j corresponds to the jth eigenvalue and eigenvector. Next, multiply Eq. 13 by ai from the right

Small Oscillations - Lagrangian and Hamiltonian Equations, Classical Mechanics, CSIR-NET Physical Sc | Physics for IIT JAM, UGC - NET, CSIR NET(14)

For the ith eigenvalue and eigenvector, multiply Eq. 12 from the left by  Small Oscillations - Lagrangian and Hamiltonian Equations, Classical Mechanics, CSIR-NET Physical Sc | Physics for IIT JAM, UGC - NET, CSIR NET

Small Oscillations - Lagrangian and Hamiltonian Equations, Classical Mechanics, CSIR-NET Physical Sc | Physics for IIT JAM, UGC - NET, CSIR NET(15)
Next, subtract the two equations

Small Oscillations - Lagrangian and Hamiltonian Equations, Classical Mechanics, CSIR-NET Physical Sc | Physics for IIT JAM, UGC - NET, CSIR NET

If we assume that the λare distinct and we consider the case  Small Oscillations - Lagrangian and Hamiltonian Equations, Classical Mechanics, CSIR-NET Physical Sc | Physics for IIT JAM, UGC - NET, CSIR NETThis states that the amplitudes are orthogonal to each other with respect to T.
Let's now consider the case where i = j . First notice that  Small Oscillations - Lagrangian and Hamiltonian Equations, Classical Mechanics, CSIR-NET Physical Sc | Physics for IIT JAM, UGC - NET, CSIR NET

implies that the matrix product is real. Next, writeSmall Oscillations - Lagrangian and Hamiltonian Equations, Classical Mechanics, CSIR-NET Physical Sc | Physics for IIT JAM, UGC - NET, CSIR NETwhere we have written ai in terms of its real and imaginary components. Then, we get

Small Oscillations - Lagrangian and Hamiltonian Equations, Classical Mechanics, CSIR-NET Physical Sc | Physics for IIT JAM, UGC - NET, CSIR NET (17)

Since the left hand side of this expression has already been shown to be real, the imaginary term is zero, thus

Small Oscillations - Lagrangian and Hamiltonian Equations, Classical Mechanics, CSIR-NET Physical Sc | Physics for IIT JAM, UGC - NET, CSIR NET(18)

Starting with Eq. 7, we see that in matrix notation the kinetic energy is

Small Oscillations - Lagrangian and Hamiltonian Equations, Classical Mechanics, CSIR-NET Physical Sc | Physics for IIT JAM, UGC - NET, CSIR NET(19)

Since Small Oscillations - Lagrangian and Hamiltonian Equations, Classical Mechanics, CSIR-NET Physical Sc | Physics for IIT JAM, UGC - NET, CSIR NET and the phase of the amplitude is arbitrary, Eq. 18 represents twice the kinetic energy. For a real velocity, the kinetic energy must be positive. Therefore, the term Small Oscillations - Lagrangian and Hamiltonian Equations, Classical Mechanics, CSIR-NET Physical Sc | Physics for IIT JAM, UGC - NET, CSIR NET must be positive (we already showed it was real), therefore   Small Oscillations - Lagrangian and Hamiltonian Equations, Classical Mechanics, CSIR-NET Physical Sc | Physics for IIT JAM, UGC - NET, CSIR NET

Since  Small Oscillations - Lagrangian and Hamiltonian Equations, Classical Mechanics, CSIR-NET Physical Sc | Physics for IIT JAM, UGC - NET, CSIR NET  is real, we can write ai as

Small Oscillations - Lagrangian and Hamiltonian Equations, Classical Mechanics, CSIR-NET Physical Sc | Physics for IIT JAM, UGC - NET, CSIR NET(20)

where N is an overall normalization factor, and φ is a real phase. The two factors can be absorbed into C of Eq. 10 making the ai real.
Starting with the eigenvalue equation (Eq. 12) and multiplying from the left bySmall Oscillations - Lagrangian and Hamiltonian Equations, Classical Mechanics, CSIR-NET Physical Sc | Physics for IIT JAM, UGC - NET, CSIR NETwe can solve for the individual eigenvalues

Small Oscillations - Lagrangian and Hamiltonian Equations, Classical Mechanics, CSIR-NET Physical Sc | Physics for IIT JAM, UGC - NET, CSIR NET(21)

The denominator is proportional to the kinetic energy, thus is must be positive. The numerator is the potential energy, which must be positive for a stable equilibrium. Therefore, λi must be positive and the frequencies are therefore real.
To remove the arbitrary normalization and phase from ai, we require Small Oscillations - Lagrangian and Hamiltonian Equations, Classical Mechanics, CSIR-NET Physical Sc | Physics for IIT JAM, UGC - NET, CSIR NET Since we have an equation for each degree of freedom, we can combine this relation with

Small Oscillations - Lagrangian and Hamiltonian Equations, Classical Mechanics, CSIR-NET Physical Sc | Physics for IIT JAM, UGC - NET, CSIR NET = 0 and write a matrix A whose columns are the individual a. This leads to the relation

Small Oscillations - Lagrangian and Hamiltonian Equations, Classical Mechanics, CSIR-NET Physical Sc | Physics for IIT JAM, UGC - NET, CSIR NET(22)

which is a congruence transformation that diagonalizes the matrix T. We take this further by noting that Eq. 12 can be written as

Small Oscillations - Lagrangian and Hamiltonian Equations, Classical Mechanics, CSIR-NET Physical Sc | Physics for IIT JAM, UGC - NET, CSIR NET(23)

where Small Oscillations - Lagrangian and Hamiltonian Equations, Classical Mechanics, CSIR-NET Physical Sc | Physics for IIT JAM, UGC - NET, CSIR NET is a diagonal matrix composed of the eigenvalues. If we multiply from the left by AT , we diagonalize V

Small Oscillations - Lagrangian and Hamiltonian Equations, Classical Mechanics, CSIR-NET Physical Sc | Physics for IIT JAM, UGC - NET, CSIR NET(24)

 Therefore, the problem of small oscillation is reduced to solving the following matrix problem

Small Oscillations - Lagrangian and Hamiltonian Equations, Classical Mechanics, CSIR-NET Physical Sc | Physics for IIT JAM, UGC - NET, CSIR NET            (25)

That is, we must find a transformation that diagonalizes the matrix T. In this form, the Lagrangian is written as

Small Oscillations - Lagrangian and Hamiltonian Equations, Classical Mechanics, CSIR-NET Physical Sc | Physics for IIT JAM, UGC - NET, CSIR NET(26)


1.3 Multiple Roots

Let's assume that two of the eigenvalues are equal Small Oscillations - Lagrangian and Hamiltonian Equations, Classical Mechanics, CSIR-NET Physical Sc | Physics for IIT JAM, UGC - NET, CSIR NET. From the formalism given above, we expect that one of the eigenvectors will be orthogonal to the remaining eigenvectors, but there is no guarantee that they will be orthogonal to each other; recall that we wish to create the matrix A, which must be orthogonal in order to diagonalize the T and V matrices. To do this, we can write one of the eigenvector as the sum of the two

Small Oscillations - Lagrangian and Hamiltonian Equations, Classical Mechanics, CSIR-NET Physical Sc | Physics for IIT JAM, UGC - NET, CSIR NET(27)

and apply the orthogonality relation

Small Oscillations - Lagrangian and Hamiltonian Equations, Classical Mechanics, CSIR-NET Physical Sc | Physics for IIT JAM, UGC - NET, CSIR NET(28)

This procedure can be generalized for n repeated roots (eigenvalues).


1.4 Example 

Let's consider a triple pendulum as shown in Fig 1. We would like to determine the eigenfrequencies and eigenvectors (normal modes) of this oscillator for small oscillations.
We start by writing the Lagrangian in rectangular coordinates

Small Oscillations - Lagrangian and Hamiltonian Equations, Classical Mechanics, CSIR-NET Physical Sc | Physics for IIT JAM, UGC - NET, CSIR NET

 where all the coordinates are measured from a coordinate system fixed to the pivot of the top pendulum as shown in the figure. Next we convert to a set of coordinates given by the angular displacement from the equilibrium point. The coordinates of the top pendulum are transformed as follows

Small Oscillations - Lagrangian and Hamiltonian Equations, Classical Mechanics, CSIR-NET Physical Sc | Physics for IIT JAM, UGC - NET, CSIR NET(30)

The kinetic and potential energies for m1 are

Small Oscillations - Lagrangian and Hamiltonian Equations, Classical Mechanics, CSIR-NET Physical Sc | Physics for IIT JAM, UGC - NET, CSIR NET(31)

where the approximation comes from expanding the potential in a Taylor series

Small Oscillations - Lagrangian and Hamiltonian Equations, Classical Mechanics, CSIR-NET Physical Sc | Physics for IIT JAM, UGC - NET, CSIR NET(32)

Next, we consider the kinetic and potential energies associated with m2 . The transformation equations are

Small Oscillations - Lagrangian and Hamiltonian Equations, Classical Mechanics, CSIR-NET Physical Sc | Physics for IIT JAM, UGC - NET, CSIR NET

Small Oscillations - Lagrangian and Hamiltonian Equations, Classical Mechanics, CSIR-NET Physical Sc | Physics for IIT JAM, UGC - NET, CSIR NET

Applying the transformations to the m2 terms, the kinetic and potential energies are

Small Oscillations - Lagrangian and Hamiltonian Equations, Classical Mechanics, CSIR-NET Physical Sc | Physics for IIT JAM, UGC - NET, CSIR NET

The kinetic and potential energies associated with m3 are arrived at in a manner similar to m. These energies are

Small Oscillations - Lagrangian and Hamiltonian Equations, Classical Mechanics, CSIR-NET Physical Sc | Physics for IIT JAM, UGC - NET, CSIR NET

Combining the kinetic and potential energy terms together, the Lagrangian becomes

Small Oscillations - Lagrangian and Hamiltonian Equations, Classical Mechanics, CSIR-NET Physical Sc | Physics for IIT JAM, UGC - NET, CSIR NET

To determine the eigenvalues, we write the kinetic and potential energies in matrix form. The mass matrix for the kinetic energy is

Small Oscillations - Lagrangian and Hamiltonian Equations, Classical Mechanics, CSIR-NET Physical Sc | Physics for IIT JAM, UGC - NET, CSIR NET(40)

and the stiffiness matrix is

Small Oscillations - Lagrangian and Hamiltonian Equations, Classical Mechanics, CSIR-NET Physical Sc | Physics for IIT JAM, UGC - NET, CSIR NET(41)

Next, we solve the eigenvalue equation

Small Oscillations - Lagrangian and Hamiltonian Equations, Classical Mechanics, CSIR-NET Physical Sc | Physics for IIT JAM, UGC - NET, CSIR NET(42)

The eigenvalues are given by setting the determinant of the coefficients of a equal to zero

Small Oscillations - Lagrangian and Hamiltonian Equations, Classical Mechanics, CSIR-NET Physical Sc | Physics for IIT JAM, UGC - NET, CSIR NET(43)

Since the algebra becomes extremely complicated for arbitrary masses and lengths, we will take all the masses and length to be equal, in this case the determinant is

Small Oscillations - Lagrangian and Hamiltonian Equations, Classical Mechanics, CSIR-NET Physical Sc | Physics for IIT JAM, UGC - NET, CSIR NET(44)

and the eigenfrequencies are

Small Oscillations - Lagrangian and Hamiltonian Equations, Classical Mechanics, CSIR-NET Physical Sc | Physics for IIT JAM, UGC - NET, CSIR NET(45)

Next, we calculate the motion of the normal modes. This is done by calculating the eigenvectors a for each eigenfrequency. We start with the the eigenfrequencySmall Oscillations - Lagrangian and Hamiltonian Equations, Classical Mechanics, CSIR-NET Physical Sc | Physics for IIT JAM, UGC - NET, CSIR NET

Small Oscillations - Lagrangian and Hamiltonian Equations, Classical Mechanics, CSIR-NET Physical Sc | Physics for IIT JAM, UGC - NET, CSIR NET(46)

We follow the same procedure for the two remaining eigenfrequencies and find the eigenvalues to be

Small Oscillations - Lagrangian and Hamiltonian Equations, Classical Mechanics, CSIR-NET Physical Sc | Physics for IIT JAM, UGC - NET, CSIR NET

where

Small Oscillations - Lagrangian and Hamiltonian Equations, Classical Mechanics, CSIR-NET Physical Sc | Physics for IIT JAM, UGC - NET, CSIR NET(48)

Finally, repeat for the remaining eigenfrequency and we get

Small Oscillations - Lagrangian and Hamiltonian Equations, Classical Mechanics, CSIR-NET Physical Sc | Physics for IIT JAM, UGC - NET, CSIR NET

where

Small Oscillations - Lagrangian and Hamiltonian Equations, Classical Mechanics, CSIR-NET Physical Sc | Physics for IIT JAM, UGC - NET, CSIR NET(50)

What we have arrived at is the following description of the motion: The mode associated with the frequencySmall Oscillations - Lagrangian and Hamiltonian Equations, Classical Mechanics, CSIR-NET Physical Sc | Physics for IIT JAM, UGC - NET, CSIR NEThas the upper mass stationary and the lower masses oscillating with the same amplitude, but π radians out of phase. The frequency  Small Oscillations - Lagrangian and Hamiltonian Equations, Classical Mechanics, CSIR-NET Physical Sc | Physics for IIT JAM, UGC - NET, CSIR NET corresponds to the two lower mass in phase and same amplitude, but π radians out of phase with the upper mass which has a smaller amplitude. The final mode corresponds to the two lower masses in phase with the upper mass, but the upper mass has a smaller amplitude.

The document Small Oscillations - Lagrangian and Hamiltonian Equations, Classical Mechanics, CSIR-NET Physical Sc | Physics for IIT JAM, UGC - NET, CSIR NET is a part of the Physics Course Physics for IIT JAM, UGC - NET, CSIR NET.
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FAQs on Small Oscillations - Lagrangian and Hamiltonian Equations, Classical Mechanics, CSIR-NET Physical Sc - Physics for IIT JAM, UGC - NET, CSIR NET

1. What are small oscillations in classical mechanics?
Ans. Small oscillations in classical mechanics refer to the motion of a system around its stable equilibrium position, where the displacements from equilibrium are small. This type of motion can typically be described by linear equations and is often studied using the techniques of Lagrangian and Hamiltonian mechanics.
2. How are Lagrangian and Hamiltonian equations used to analyze small oscillations?
Ans. Lagrangian and Hamiltonian equations provide a systematic approach to analyze small oscillations in classical mechanics. The Lagrangian equations describe the motion of a system in terms of generalized coordinates, while the Hamiltonian equations describe the motion in terms of generalized coordinates and momenta. By applying these equations to the system's equations of motion, one can determine the frequencies, amplitudes, and phases of the small oscillations.
3. What is the difference between Lagrangian and Hamiltonian mechanics?
Ans. Lagrangian and Hamiltonian mechanics are two equivalent formulations of classical mechanics. In Lagrangian mechanics, the motion of a system is described using generalized coordinates and their time derivatives, while in Hamiltonian mechanics, the motion is described using generalized coordinates and their conjugate momenta. The Lagrangian equations are derived from the principle of least action, whereas the Hamiltonian equations are derived from the Hamilton's principle.
4. How are Lagrangian and Hamiltonian equations derived for small oscillations?
Ans. To derive the Lagrangian and Hamiltonian equations for small oscillations, one starts with the system's equations of motion and makes certain approximations. These approximations include assuming small displacements from equilibrium, neglecting higher-order terms in the equations, and linearizing the equations around the equilibrium position. By applying these approximations, the resulting equations can be written in terms of generalized coordinates and their derivatives, leading to the Lagrangian and Hamiltonian formulations for small oscillations.
5. What are the advantages of using Lagrangian and Hamiltonian equations for small oscillations?
Ans. Using Lagrangian and Hamiltonian equations for small oscillations offers several advantages. Firstly, these equations provide a clear and systematic framework for analyzing the motion of a system, allowing for a deeper understanding of its behavior. Secondly, the Lagrangian and Hamiltonian approaches can simplify complex problems by reducing the number of variables and simplifying the equations of motion. Lastly, these formulations are often more general and can be easily extended to more complicated systems or situations beyond small oscillations.
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