Normal mode Guide, Meaning , Facts, Information and Description
Normal modes in an oscillating system are special solutions where all the parts of the system are oscillating with the same frequency (called normal frequencies or allowed frequencies). The concept of normal modes is of vital importance in wave theory, optics and quantum mechanics.Finding normal modes in harmonic oscillation utilitizes the strength of linear algebra and linear sets of differential equations. One can present the problem as a matrix-vector equation and then solve for its eigenvectors. After finding them, the normal modes are the eigenvectors where the normal frequencies are the eigenvalues.
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2 Standing waves 3 Normal modes in quantum mechanics 4 See also |
Consider two bodies (not affected by gravity), each of mass M, attached to three springs with stiffness K. They are attached in the following manner:
Example - normal modes of coupled oscillators
where the edge points are fixed and cannot move. We'll use x1(t) to denote the displacement of the leftmost mass, and x2(t) to denote the displacement of the rightmost.
If we denote the second derivative of x(t) with respect to time as x″, the equations of motion are:
The first normal mode is:
The process demonstrated here can be generalized and formulated using the formalism of Lagrangian mechanics or Hamiltonian mechanics.
A standing wave is a continuous form of normal mode. In a standing wave, all the space elements (i.e (x,y,z) coordinates) are oscillating in the same frequency and in phase (reaching the equilibrium point together), but each has a different amplitude.
The general form of a standing wave is:
Physically, standing waves are formed by the interference (superposition) of waves and their reflections (although one may also say the opposite; that a moving wave is a superposition of standing waves). The geometric shape of the medium determines what would be the interference pattern, thus determines the f(x,y,z) form of the standing wave. This space-dependence is called a normal mode.
Usually, for problems with continuous dependence on (x,y,z) there is no single or finite number of normal mode, but there are infinitely normal modes. If the problem is bounded (i.e it is defined on a finite section of space) there are countably many (a discrete infinity of ) normal modes (usually numbered n = 1,2,3,...). If the problem is not bounded, there is a continuous spectrum of normal modes.
The allowed frequencies are dependent on the normal modes, as well on physical constants of the problem (density, tension, pressure, etc.) which sets the phase velocity of the wave. The range of all possible normal frequencies is called the frequency spectrum. Usually, each frequency is modulated by the amplitude at which it has arisen, creating a graph of the power spectrum of the oscillations.
When relating to music, normal modes of a vibrating instruments (strings, air pipes, drums, etc.) are called "harmonics".
In quantum mechanics, a state of a system is described by a wavefunction |ψ> of (x, t) which solves the Schrödinger equation. The square of the absolute value of |ψ>, i.e.
Usually, when involving some sort of potential, the wavefunction is decomposed into a superposition of energy eigenstates, each oscillating with frequency of . Thus, we may write
Standing waves
where f(x,y,z) represents the dependence of amplitude on location and the cosine\\sine are the oscillations in time.Normal modes in quantum mechanics
is the probability (density) to measure the particle in place x at time t.
The eigenstates have a physical meaning further than an orthonormal basis. When a measurement takes place, the wavefunction collapses into one of its eigenstates and henceforth the particle wavefunction is described only by the eigenstate corresponding to the measured energy.