Zeros and Roots of Polynomial Functions 1 New Theorem`s
Zeros and Roots of Polynomial Functions 1 New Theorem`s

THE PRIME NUMBER THEOREM AND THE
THE PRIME NUMBER THEOREM AND THE

An Explicit Rate Bound for the Over-Relaxed ADMM
An Explicit Rate Bound for the Over-Relaxed ADMM

Keep in mind that high school TMSCA is
Keep in mind that high school TMSCA is

The LASSO risk: asymptotic results and real world examples
The LASSO risk: asymptotic results and real world examples

Digital Control
Digital Control

Another version - Scott Aaronson
Another version - Scott Aaronson

Lacunary recurrences for Eisenstein series
Lacunary recurrences for Eisenstein series

SUMS OF DISTINCT UNIT FRACTIONS
SUMS OF DISTINCT UNIT FRACTIONS

On the absolute continuity of Levy processes with drift
On the absolute continuity of Levy processes with drift

Csorgo, Sandor and Simon, Gordon; (1994).A Strong Law of Large Numbers for Trimmed Sums, with Applications to Generalized St. Petersburg Games."
Csorgo, Sandor and Simon, Gordon; (1994).A Strong Law of Large Numbers for Trimmed Sums, with Applications to Generalized St. Petersburg Games."

Chapter 4 Three Famous Theorems
Chapter 4 Three Famous Theorems

DIFFERENTIABILITY OF A PATHOLOGICAL FUNCTION
DIFFERENTIABILITY OF A PATHOLOGICAL FUNCTION

Logarithmic concave measures with application to stochastic programming
Logarithmic concave measures with application to stochastic programming

Simple Continued Fractions for Some Irrational Numbers
Simple Continued Fractions for Some Irrational Numbers

LOGARITHMS OF MATRICES Theorem 1. If M=E(A), N = EiB
LOGARITHMS OF MATRICES Theorem 1. If M=E(A), N = EiB

Series Representation of Power Function
Series Representation of Power Function

Section 4-2 - winegardnermathclass
Section 4-2 - winegardnermathclass

The strong law of large numbers - University of California, Berkeley
The strong law of large numbers - University of California, Berkeley

The probability of speciation on an interaction
The probability of speciation on an interaction

Ch 5: Integration Ch5.integration
Ch 5: Integration Ch5.integration

The Fibonacci zeta function - Department of Mathematics and Statistics
The Fibonacci zeta function - Department of Mathematics and Statistics

Monte-Carlo Sampling for NP-Hard Maximization Problems in the
Monte-Carlo Sampling for NP-Hard Maximization Problems in the

Teaching Plan 1B
Teaching Plan 1B

Math 1 Mid-Term Exam Test # ______ 1. State the domain for the
Math 1 Mid-Term Exam Test # ______ 1. State the domain for the

Nyquist–Shannon sampling theorem



In the field of digital signal processing, the sampling theorem is a fundamental bridge between continuous-time signals (often called ""analog signals"") and discrete-time signals (often called ""digital signals""). It establishes a sufficient condition for a sample rate that permits a discrete sequence of samples to capture all the information from a continuous-time signal of finite bandwidth.Strictly speaking, the theorem only applies to a class of mathematical functions having a Fourier transform that is zero outside of a finite region of frequencies (see Fig 1). Intuitively we expect that when one reduces a continuous function to a discrete sequence and interpolates back to a continuous function, the fidelity of the result depends on the density (or sample rate) of the original samples. The sampling theorem introduces the concept of a sample rate that is sufficient for perfect fidelity for the class of functions that are bandlimited to a given bandwidth, such that no actual information is lost in the sampling process. It expresses the sufficient sample rate in terms of the bandwidth for the class of functions. The theorem also leads to a formula for perfectly reconstructing the original continuous-time function from the samples.Perfect reconstruction may still be possible when the sample-rate criterion is not satisfied, provided other constraints on the signal are known. (See § Sampling of non-baseband signals below, and Compressed sensing.)In some cases (when the sample-rate criterion is not satisfied), utilizing additional constraints allows for approximate reconstructions. The fidelity of these reconstructions can be verified and quantified utilizing Bochner's theorem.The name Nyquist–Shannon sampling theorem honors Harry Nyquist and Claude Shannon. The theorem was also discovered independently by E. T. Whittaker, by Vladimir Kotelnikov, and by others. It is thus also known by the names Nyquist–Shannon–Kotelnikov, Whittaker–Shannon–Kotelnikov, Whittaker–Nyquist–Kotelnikov–Shannon, and cardinal theorem of interpolation.