User:Dave3457/Sandbox/General Purpose

Wavelength of a sine wave, λ, can be measured between any two points with the same phase, such as between crests, or troughs, or corresponding zero crossings as shown.

As a wave travels by, the value at a given point oscillates sinusoidally.

One of the simplest formalisms of a plane wave involves defining it along the direction of the x-axis.

${\displaystyle A(x,t)=A_{o}\sin(kx-\omega t+\varphi )}$

In the above equation…

• ${\displaystyle A(x,t)\,\!}$ is the magnitude or disturbance of the wave at a given point in space and time. For example, in the case of a sound wave, ${\displaystyle A(x,t)\,\!}$ could be chosen to represent the excess air pressure.
• ${\displaystyle A_{o}\,\!}$ is the amplitude of the wave (the peak magnitude of the oscillation).
• ${\displaystyle k\,\!}$ is the wave’s wave number or more specifically the angular wave number and equals ${\displaystyle 2\pi /\lambda \,\!}$, where ${\displaystyle \lambda \,\!}$ is the wavelength of the wave. ${\displaystyle k\,\!}$ has the units of radians per unit distance.
• ${\displaystyle x\,\!}$ is a given point along the x-axis. ${\displaystyle y\,\!}$ and ${\displaystyle z\,\!}$ are not part of the equation because the wave's magnitude is the same at every point on any given y-z plane. This equation defines what that magnitude is.
• ${\displaystyle \omega \,\!}$ is the wave’s angular frequency which equals ${\displaystyle 2\pi /T\,\!}$, where ${\displaystyle T\,\!}$ is the period of the wave. ${\displaystyle \omega \,\!}$ has the units of radians per unit time.
• ${\displaystyle t\,\!}$ is a given point in time
• ${\displaystyle \varphi \,\!}$ is the phase shift of the wave and has the units of radians. Note that a positive phase shift, at a given moment of time, shifts the wave in the negative x-axis direction. A phase shift of ${\displaystyle 2\pi \,\!}$ radians shifts it exactly one wavelength.

Other formalisms which directly use the wave’s wavelength ${\displaystyle \lambda \,\!}$, period ${\displaystyle T\,\!}$, frequency ${\displaystyle f\,\!}$ and velocity ${\displaystyle c\,\!}$ are below.

${\displaystyle A=A_{o}sin[2\pi (x/\lambda -t/T)+\varphi ]\,\!}$

${\displaystyle A=A_{o}sin[2\pi (x/\lambda -ft)+\varphi ]\,\!}$

${\displaystyle A=A_{o}sin[(2\pi /\lambda )(x-ct)+\varphi ]\,\!}$

With regards to the above set of equations it is noteworthy that ${\displaystyle f=1/T\,\!}$ and ${\displaystyle c=\lambda /T\,\!}$

For a plane wave the velocity ${\displaystyle c\,\!}$ is equal to both its phase velocity and its group velocity.