Vibrations of a circular membrane

A two-dimensional elastic membrane under tension can support transverse vibrations. The properties of an idealized drumhead can be modeled by the vibrations of a circular membrane of uniform thickness, attached to a rigid frame. Due to the phenomenon of resonance, at certain vibration frequencies, its resonant frequencies, the membrane can store vibrational energy, the surface moving in a characteristic pattern of standing waves. This is called a normal mode. A membrane has an infinite number of these normal modes, starting with a lowest frequency one called the fundamental frequency.

One of the possible modes of vibration of an idealized circular drum head (mode with the notation below). Other possible modes are shown at the bottom of the article.

There exist infinitely many ways in which a membrane can vibrate, each depending on the shape of the membrane at some initial time, and the transverse velocity of each point on the membrane at that time. The vibrations of the membrane are given by the solutions of the two-dimensional wave equation with Dirichlet boundary conditions which represent the constraint of the frame. It can be shown that any arbitrarily complex vibration of the membrane can be decomposed into a possibly infinite series of the membrane's normal modes. This is analogous to the decomposition of a time signal into a Fourier series.

The study of vibrations on drums led mathematicians to pose a famous mathematical problem on whether the shape of a drum can be heard, with an answer (it cannot) being given in 1992 in the two-dimensional setting.

Practical significance

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Analyzing the vibrating drum head problem explains percussion instruments such as drums and timpani. However, there is also a biological application in the working of the eardrum. From an educational point of view the modes of a two-dimensional object are a convenient way to visually demonstrate the meaning of modes, nodes, antinodes and even quantum numbers. These concepts are important to the understanding of the structure of the atom.

The problem

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Consider an open disk   of radius   centered at the origin, which will represent the "still" drum head shape. At any time   the height of the drum head shape at a point   in   measured from the "still" drum head shape will be denoted by   which can take both positive and negative values. Let   denote the boundary of   that is, the circle of radius   centered at the origin, which represents the rigid frame to which the drum head is attached.

The mathematical equation that governs the vibration of the drum head is the wave equation with zero boundary conditions,

 
 

Due to the circular geometry of  , it will be convenient to use polar coordinates   Then, the above equations are written as

 
 

Here,   is a positive constant, which gives the speed at which transverse vibration waves propagate in the membrane. In terms of the physical parameters, the wave speed, c, is given by

 

where  , is the radial membrane resultant at the membrane boundary ( ),  , is the membrane thickness, and   is the membrane density. If the membrane has uniform tension, the uniform tension force at a given radius,   may be written

 

where   is the membrane resultant in the azimuthal direction.

The axisymmetric case

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We will first study the possible modes of vibration of a circular drum head that are axisymmetric. Then, the function   does not depend on the angle   and the wave equation simplifies to

 

We will look for solutions in separated variables,   Substituting this in the equation above and dividing both sides by   yields

 

The left-hand side of this equality does not depend on   and the right-hand side does not depend on   it follows that both sides must be equal to some constant   We get separate equations for   and  :

 
 

The equation for   has solutions which exponentially grow or decay for   are linear or constant for   and are periodic for  . Physically it is expected that a solution to the problem of a vibrating drum head will be oscillatory in time, and this leaves only the third case,   so we choose   for convenience. Then,   is a linear combination of sine and cosine functions,

 

Turning to the equation for   with the observation that   all solutions of this second-order differential equation are a linear combination of Bessel functions of order 0, since this is a special case of Bessel's differential equation:

 

The Bessel function   is unbounded for   which results in an unphysical solution to the vibrating drum head problem, so the constant   must be null. We will also assume   as otherwise this constant can be absorbed later into the constants   and   coming from   It follows that

 

The requirement that height   be zero on the boundary of the drum head results in the condition

 

The Bessel function   has an infinite number of positive roots,

 

We get that   for   so

 

Therefore, the axisymmetric solutions   of the vibrating drum head problem that can be represented in separated variables are

 

where  

The general case

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The general case, when   can also depend on the angle   is treated similarly. We assume a solution in separated variables,

 

Substituting this into the wave equation and separating the variables, gives

 

where   is a constant. As before, from the equation for   it follows that   with   and

 

From the equation

 

we obtain, by multiplying both sides by   and separating variables, that

 

and

 

for some constant   Since   is periodic, with period     being an angular variable, it follows that

 

where   and   and   are some constants. This also implies  

Going back to the equation for   its solution is a linear combination of Bessel functions   and   With a similar argument as in the previous section, we arrive at

     

where   with   the  -th positive root of  

We showed that all solutions in separated variables of the vibrating drum head problem are of the form

 

for  

Animations of several vibration modes

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A number of modes are shown below together with their quantum numbers. The analogous wave functions of the hydrogen atom are also indicated as well as the associated angular frequencies  . The values of   are the roots of the Bessel function  . This is deduced from the boundary condition   which yields  .

More values of   can easily be computed using the following Python code with the scipy library:[1]

from scipy import special as sc
m = 0 # order of the Bessel function (i.e. angular mode for the circular membrane)
nz = 3 # desired number of roots
alpha_mn = sc.jn_zeros(m, nz) # outputs nz zeros of Jm

See also

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References

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  • H. Asmar, Nakhle (2005). Partial differential equations with Fourier series and boundary value problems. Upper Saddle River, N.J.: Pearson Prentice Hall. p. 198. ISBN 0-13-148096-0.