An intuitive meaning to the phase constant k?

  • Thread starter Thread starter rem1618
  • Start date Start date
  • Tags Tags
    Constant Phase
AI Thread Summary
The phase constant k in the harmonic wave equation ψ(x,t) = Asin(kx - ωt) is defined as k = 2π/λ, linking it to the wavelength λ. It serves as a spatial frequency, analogous to angular frequency ω in time, and can be interpreted as related to curvature, with k representing 1/r. The discussion highlights that k can be extended to a vector form, \vec{k}, which aids in the mathematical handling of wave propagation in three dimensions. By fixing time or space, one can better understand the roles of k and ω in wave behavior. Overall, k encapsulates the spatial characteristics of wave motion, providing a deeper insight into wave dynamics.
rem1618
Messages
14
Reaction score
0
k being the one from the harmonic wave ψ(x,t) = Asin(kx - ωt) where k = 2π/λ

The way I see it right now, k is just defined this way to get the period of sin(x) to be λ by using sin(kx), so I wondered if there's something more to it. (Though I know it can be used as an vector to declare the direction of the wave.)

I played with the trig stuff a bit. I know that a harmonic wave can be traced by a point in a circular motion. sin(x) traces the circle with a period of 2π so I take that to be a circle with 2π circumference and radius 1. Doing the same with sin(kx) gets a circle with λ circumference and radius 1/k.

So k seems to be related to 1/r or the curvature? I found it interesting too that if I directly substitute k with 1/r, the ω in ω = v/r from mechanics can be found with the ω in ω = kv from waves.

Is there some insight to take away from this?
 
Physics news on Phys.org
From that wiki, I like the phrase "spatial frequency". Thats how I internalize it. Its the spatial version of time's "omega" (angular frequency).
 
The radius and circumference of the 'generating' circle for sinusoids aren't related to either \omega, or its spatial analogue, k. The circle radius gives the amplitude of the sinusoid.

I don't think you're going to get a much better intuitive feel for k than what I've just mentioned: it's the spatial analogue of \omega. But there's rather a neat extension to the idea when you deal with waves propagating in 3 dimensions. We then define a vector, \vec{k}, having a magnitude, k, equal to \frac{2\pi}{\lambda} and direction that of the direction of wave propagation. This enables neat mathematical handling of wave propagation equations. For example, the displacement, y, at any point in the path of a plane sinusoidal wave may be written as
y =y_0 sin [\omega t - \vec{k}.\vec{r} + \epsilon].
 
For the OP.
To understand the meaning of k: fix the time t, as if you made a photo of the experiment and see what happens mathematically varying the point x of the space (you can fix t = 0).
To understand the meaning of ω: fix a point x of the space (you can choose x = 0) and see what happens varying the time.

You then understand why, as someone has already written, k can be called "spatial frequency" and ω can be called "temporal frequency".

--
lightarrow
 
Thread 'Gauss' law seems to imply instantaneous electric field'

Thread 'Gauss' law seems to imply instantaneous electric field'

Imagine a charged sphere at the origin connected through an open switch to a vertical grounded wire. We wish to find an expression for the horizontal component of the electric field at a distance ##\mathbf{r}## from the sphere as it discharges. By using the Lorenz gauge condition: $$\nabla \cdot \mathbf{A} + \frac{1}{c^2}\frac{\partial \phi}{\partial t}=0\tag{1}$$ we find the following retarded solutions to the Maxwell equations If we assume that...
View full post »

Thread 'Do electron density waves accompany EM waves in coaxial cables?'

Maxwell’s equations imply the following wave equation for the electric field $$\nabla^2\mathbf{E}-\frac{1}{c^2}\frac{\partial^2\mathbf{E}}{\partial t^2} = \frac{1}{\varepsilon_0}\nabla\rho+\mu_0\frac{\partial\mathbf J}{\partial t}.\tag{1}$$ I wonder if eqn.##(1)## can be split into the following transverse part $$\nabla^2\mathbf{E}_T-\frac{1}{c^2}\frac{\partial^2\mathbf{E}_T}{\partial t^2} = \mu_0\frac{\partial\mathbf{J}_T}{\partial t}\tag{2}$$ and longitudinal part...
View full post »

Similar threads

B How Does Phase Change Affect the Equation of a Stationary Wave?
Replies
12
Views
2K
I Find period of circular-orbiting source based on max observed freq
Replies
1
Views
1K
I Phase angle of a damped driven harmonic oscillation
Replies
12
Views
9K
B Understanding Phase Terminology in Wave Functions
Replies
9
Views
2K
Question about travelling wave equation
Replies
5
Views
4K
Amplitude of Wave at 5pi/6 Radians in Cycle, y = Asin(kx-wt)
Replies
8
Views
2K
What is the significance of phase constant in the wave equation?
Replies
4
Views
2K
Standing wave transverse motion and amplitude
Replies
5
Views
2K
Wave equation, wavelenght not given
Replies
6
Views
2K
Can the angular wave number(k) or frequency(w) be negative?
Replies
5
Views
9K

Hot Threads

Recent Insights

Back
Top