13.8:

Basic Discrete Time Signals

JoVE 핵심
Electrical Engineering
JoVE 비디오를 활용하시려면 도서관을 통한 기관 구독이 필요합니다.  전체 비디오를 보시려면 로그인하거나 무료 트라이얼을 시작하세요.
JoVE 핵심 Electrical Engineering
Basic Discrete Time Signals

6 Views

01:16 min

September 26, 2024

The unit step sequence is defined as 1 for zero and positive values of the integer n. This sequence can be graphically displayed using a set of eight sample points, showing a step function starting from n=0 and remaining constant thereafter.

The unit impulse or sample sequence is mathematically expressed as zero for all n values except at n=0, where it is one. The unit impulse sequence, denoted by δ(n), is the first difference of the unit step sequence, while the unit step sequence u(n) is the cumulative sum of the unit impulse sequence. This relationship can be visually demonstrated through a graph, highlighting how the unit impulse can effectively sample the signal value at n=0.

The unit ramp sequence exhibits a linear increase in value with the increase in the sample number. For instance, a sequence of 12 samples on a unit ramp will show a linear increase in amplitude with each sample number, represented graphically as a straight line.

A sinusoidal sequence is defined by its amplitude and phase parameters. This sequence can be represented as,

Equation1

where A is the amplitude, ω is the angular frequency, and Φ is the phase.

The exponential sequence is defined using complex numbers, with exponentially decaying and increasing sequences represented on a graph. An exponentially decaying sequence can be written as,

Equation2

while an exponentially increasing sequence is expressed as,

Equation3

where A is the initial amplitude and α is a positive constant. These sequences are fundamental in analyzing various signal-processing applications due to their unique properties and behaviors.