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SAMPLING PART 1

Basic Definition of Sampling

Sampling is the extraction of values of a continuous signal at fixed intervals. We learn more about the frequency spectrum of a signal the faster we sample it. Naturally, if the signal changes much faster than the sampling rate, these changes will not be captured accurately and aliasing occurs.

Nyquist Sampling Theorem

The Nyquist Sampling theorem says that in order to capture all the frequency information of a bandlimited signal, the sampling frequency must be twice the maximum frequency of the signal. In other words, each frequency component must be sampled at least twice per period.

<insert nyquist sampling rate conditions here>

The Sampling Process

In theory, here is how we would like to sample our signals.

Step 1: Begin with a continuous function x(t).

Step 2: Sample x(t) using an impulse generator or comb function.

Step 3: Discretize the signal.

After Step 3, the signal is ready to be put through a discrete filter.

It is important to note that this is an idealization of the sampling process. To adhere to the Nyquist sampling theorem, the sampling frequency must be at least twice the maximum frequency. Often, we do not know what the maximum frequency. To prevent the effects of aliasing, the signal is first lowpass filtered. This allows us to base the sampling frequency off of the cutoff frequency of the filter. This will reduce the effects of aliasing, but may also distort the signal, since higher frequencies are lost.

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