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Date: 21-7-2018
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Date: 21-7-2018
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Date: 13-7-2018
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The one-dimensional wave equation is given by
(1) |
In order to specify a wave, the equation is subject to boundary conditions
(2) |
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(3) |
and initial conditions
(4) |
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(5) |
The one-dimensional wave equation can be solved exactly by d'Alembert's solution, using a Fourier transform method, or via separation of variables.
d'Alembert devised his solution in 1746, and Euler subsequently expanded the method in 1748. Let
(6) |
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(7) |
By the chain rule,
(8) |
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(9) |
The wave equation then becomes
(10) |
Any solution of this equation is of the form
(11) |
where and are any functions. They represent two waveforms traveling in opposite directions, in the negative direction and in the positive direction.
The one-dimensional wave equation can also be solved by applying a Fourier transform to each side,
(12) |
which is given, with the help of the Fourier transform derivative identity, by
(13) |
where
(14) |
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(15) |
This has solution
(16) |
Taking the inverse Fourier transform gives
(17) |
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(18) |
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(19) |
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(20) |
where
(21) |
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(22) |
This solution is still subject to all other initial and boundary conditions.
The one-dimensional wave equation can be solved by separation of variables using a trial solution
(23) |
This gives
(24) |
(25) |
So the solution for is
(26) |
Rewriting (25) gives
(27) |
so the solution for is
(28) |
where . Applying the boundary conditions to (◇) gives
(29) |
where is an integer. Plugging (◇), (◇) and (29) back in for in (◇) gives, for a particular value of ,
(30) |
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(31) |
The initial condition then gives , so (31) becomes
(32) |
The general solution is a sum over all possible values of , so
(33) |
Using orthogonality of sines again,
(34) |
where is the Kronecker delta defined by
(35) |
gives
(36) |
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(37) |
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(38) |
so we have
(39) |
The computation of s for specific initial distortions is derived in the Fourier sine series section. We already have found that , so the equation of motion for the string (◇), with
(40) |
is
(41) |
where the coefficients are given by (◇).
A damped one-dimensional wave
(42) |
given boundary conditions
(43) |
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(44) |
initial conditions
(45) |
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(46) |
and the additional constraint
(47) |
can also be solved as a Fourier series.
(48) |
where
(49) |
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(50) |
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(51) |
REFERENCES:
Abramowitz, M. and Stegun, I. A. (Eds.). "Wave Equation in Prolate and Oblate Spheroidal Coordinates." §21.5 in Handbook of Mathematical Functions with Formulas, Graphs, and Mathematical Tables, 9th printing. New York: Dover, pp. 752-753, 1972.
Morse, P. M. and Feshbach, H. Methods of Theoretical Physics, Part I. New York: McGraw-Hill, pp. 124-125 and 271, 1953.
Zwillinger, D. (Ed.). CRC Standard Mathematical Tables and Formulae. Boca Raton, FL: CRC Press, p. 417, 1995.
Zwillinger, D. Handbook of Differential Equations, 3rd ed. Boston, MA: Academic Press, p. 130, 1997.
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