Edmund Optics

There is no higher spatial frequency. Any arbitrary waveform on the system will consist of a sum of frequencies up the maximum. There simply are no other frequencies to consider.

Can someone in simple terms why you would use Nyquist frequency limits when processing a signal? What benefit does it provide, and how does it affect the results? And how does it relate to the Nyquist rate?

Optical mounts- thorlabs

As suggested by a comment, you should give us some context. There a several ways to answer the question. I'll provide a partial answer that is particularly relevant to physics, esp discrete periodic systems such as atoms in a solid. But there are other aspects, especially as concerns continuous systems and time-domain questions.

So if you want to retain "complete" information about the signal you are sampling, you must sample above the Nyquist limit.

It's easier to visualize space rather than time :-) so let's consider spatial frequencies. Imagine a system of balls threaded on a string, with the distance between neighboring balls the same for all neighboring pairs. A low spatial frequency / long wavelength looks like a wave. As you increase the spatial frequency, the wavelength gets shorter. Continue increasing the spatial frequency until the wavelength is two times the ball spacing. At that frequency one ball is displaced "left", the next "right", the third "left" again, etc. Every other ball is displaced maximally to the left or right.

OpticalMirrorMounts

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If you sample a signal with a sample rate greater than the Nyquist limit, it is (in principle) possible to perfectly reconstruct the original continuous-time signal.

From a physics point of view, there is no consequence. From a math point of view, summations are limited, and algorithms to speed the calculation ("Fast Fourier Transform") can be used.

Kinematic MirrorMounts

Thorlabs adjustable Lens Mount

The Nyquist sampling theorem (sometimes called the Nyquist-Shannon sampling theorem) says, if you have a signal that is bandlimited with bandwidth $B$, then if you sample it with a sampling period $T_s$ strictly less than $1/2B$, then the original signal can be perfectly reconstructed from the samples.

Optical Component Mounts 4OCM can be used to hold round thin optical elements of standard sizes. Mounts vary in dimensions so as to support diameters from 10 to 50mm (0.5" to 2"). Original design allows to decrease the mount's dimensions and weight. Mounting holes: one M6 and two Ø4.5 mm. Material: black anodized aluminum.

We call the minimum sampling rate for ideal reconstruction, $f_N = 2B$ ($f_N$ being in samples per second and $B$ in hertz), the Nyquist limit.

If you sample a signal with a sample rate below the Nyquist limit, you can not perfectly reconstruct the signal due to aliasing.

For a discrete periodic system, the Nyquist frequency is the highest frequency possible. There are no higher frequencies.