Harmonic Oscillator Full Mathematical Definition Important Terms

where k is a constant. It can also refer to any physical system that is analogous to this mechanical system, in which some other quantity behaves in the same way as x. Examples of harmonic oscillators include pendulums (in small angles), masses on springs, and RLC circuits.

Comparing a mechanical harmonic oscillator with an RLC circuit, the following correspond:

If F is the only force acting on the mechanical system, the system is called a simple harmonic oscillator. The motion of a simple harmonic oscillator, called simple harmonic motion, is essentially a sine function oscillating about the equilibrium displacement, x = 0, at which the returning force is zero.

The potential energy V associated with such a returning force is called a harmonic potential. It has the form

The simple harmonic oscillator can also be formulated in terms of the LagrangianA Lagrangian of a dynamical system, named after Joseph Louis Lagrange, is a functional of the dynamical variables which concisely describes the equations of motion of the system. The equations of motion are obtained by means of an action principle, writte

or the HamiltonianHamiltonian mechanics is a re-formulation of classical mechanics that was invented in 1833 by William Rowan Hamilton. It arose from Lagrangian mechanics, another re-formulation of classical mechanics, introduced by Joseph Louis Lagrange in 1788. It can ho

The following article discusses the harmonic oscillator in terms of classical mechanics. See the article quantum harmonic oscillatorThe quantum harmonic oscillator is the quantum mechanical analogue of the classical harmonic oscillator. It is one of the most important model systems in quantum mechanics because, as in classical mechanics, a wide variety of physical situations can be re for a discussion of the harmonic oscillator in quantum mechanicswavefunctions of an electron in a hydrogen atom possessing definite energy (increasing downward: n 1,2,3,. and angular momentum (increasing across: s p d . Brighter areas correspond to higher probability density for a position measurement. The angular mom.

1 Full mathematical definition

Most harmonic oscillators, at least approximately, solve the differential equation:

where t is time, b is the damping constant, ω_o is the characteristic angular frequencyIn physics (specifically mechanics and electrical engineering), angular frequency ω (also called angular speed is a scalar measure of rotation rate. Angular frequency is the magnitude of the vector quantity angular velocity . The term angular freque, and A_ocos(ωt) represents something driving the system with amplitude A_o and angular frequency ω. x is the measurement that is oscillating; it can be position, current, or nearly anything else. The angular frequencyIn physics (specifically mechanics and electrical engineering), angular frequency ω (also called angular speed is a scalar measure of rotation rate. Angular frequency is the magnitude of the vector quantity angular velocity . The term angular freque is related to the frequency, f, by:

1.1 Important terms

AmplitudeAmplitude is a nonnegative scalar measure of a wave's magnitude of oscillation. In the following diagram, the distance y is the amplitude of the wave. Sometimes that distance is called the "peak amplitude", distinguishing it from another concept of amplit: maximal displacement from the equilibriumFor the 2002 science fiction movie see Equilibrium (2002 movie Equilibrium or balance is any of a number of related phenomena in the natural and social sciences. In general, a system is said to be in a state of equilibrium if all influences on the system.
Period: the time it takes the system to complete an oscillation cycle.
Frequency: the number of cycles the system performs per unit time (usually measured in hertz = 1/s).
Angular frequency:
Phase: how much of a cycle the system completed (system that begins is in phase zero, system which completed half a cycle is in phase ).
Initial conditions: the state of the system at t = 0, the beginning of oscillations.

1.2 Simple harmonic oscillator

A simple harmonic oscillator is simply an oscillator that is neither damped nor driven. So the equation to describe one is:

Physically, the above never actually exists, since there will always be friction or some other resistance, but two approximate examples are a mass on a spring and an LC circuit.

In the case of a mass hanging on a spring, Newton's Laws, combined with Hooke's law for the behavior of a spring, states that:

where k is the spring constant, m is the mass, y is the position of the mass, and a is its acceleration. Noting that acceleration is the second derivative of position, we can rewrite the equation as follows:

The easiest way to solve the above equation is to recognize that when d²z/dt² ∝ -z, z is some form of sine. So we try the solution:

where A is the amplitude, δ is the phase shift, and ω is the angular frequency. Substituting, we have:

and thus (dividing both sides by -A cos(ωt + δ)):

The above formula reveals that the angular frequency of the solution is only dependent upon the physical characteristics of the system, and not the initial conditions (those are represented by A and δ). That means that what was labelled ω is in fact ω_o. This will become important later.

1.3 Driven harmonic oscillator

Satisfies equation:

Good example:

AC LC circuit.

a few notes about what the response of the circuit to different AC frequencies.

1.4 Damped harmonic oscillator

Satisfies equation:

good example:

weighted spring underwater

Note well: underdamped, critically damped

1.5 Damped, driven harmonic oscillator

equation:

The general solution is a sum of a transient (the solution for damped undriven harmonic oscillator, homogenous ODE) that depends on initial conditions, and a steady state (particular solution of the unhomogenous ODE) that is independent of initial conditions and depends only on driving frequency, driving force, restoring force, damping force, and inertial moment of the oscillator (see also kernel and image).

The steady state solution is

where

is the absolute value of the impedance

and

is the phase of the oscillation relative to the driving force.

One might see that for a certain driving frequency, , the amplitude (relative to a given ) is maximal. This occurs for the frequency

and is called resonance of displacement.

In summary: at steady state the frequency of oscillation is the same as the driving force, but the oscillation is phase offset and scaled by amounts that depend on the frequency of the driving force in relation to the preferred (resonant) frequency of the oscillating system.

example:

RLC circuit

Notes for above apply, transient vs steady state response, and quality factor.

2 A final note on mathematics

For a more complete description of how to solve the above equation, see the article on differential equations.

3 See also

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