Discrete-time signal

Discrete sampled signal

Digital signal

(Discrete here means "constituting a separate entity" and is distinct from "discreet"; a "discreet signal" is one not intended to be seen by others.)

A discrete signal or discrete-time signal is a time series consisting of a sequence of qualities. In other words, it is a type series that is a function over a domain of discrete integral.

Unlike a continuous-time signal, a discrete-time signal is a function of a continuous argument; however, it may have been obtained by sampling from a continuous-time signal, and then each value in the sequence is called a sample. When a discrete-time signal obtained by sampling a sequence corresponding to uniformly spaced times, it has an associated sampling rate; the sampling rate is not apparent in the data sequence, and so needs to be associated as a separate data item.

Acquisition

Discrete signals may have several origins, but can usually be classified into one of two groups:^[1]

• By acquiring values of an analog signal at constant or variable rate. This process is called sampling.^[2]
• By recording the number of events of a given kind over finite time periods. For example, this could be the number of people taking a certain elevator every day.

Digital signals

Discrete cosine waveform with frequency of 50 Hz and a sampling rate of 1000 samples/sec, easily satisfying the sampling theorem for reconstruction of the original cosine function from samples.

A digital signal is a discrete-time signal for which not only the time but also the amplitude has been made discrete; in other words, its samples take on only values from a discrete set.

The process of converting a continuous-valued discrete-time signal to a digital (discrete-valued discrete-time) signal is known as analog-to-digital conversion. It usually proceeds by replacing each original sample value by an approximation selected from a given discrete set (for example by truncating or rounding, but much more sophisticated methods exist), a process known as quantization. This process loses information, and so discrete-valued signals are only an approximation of the converted continuous-valued discrete-time signal, itself only an approximation of the original continuous-valued continuous-time signal.

Common practical digital signals are represented as 8-bit (256 levels), 16-bit (65,536 levels), 32-bit (4.3 billion levels), and so on, though any number of quantization levels is possible, not just powers of two.

See also

• Aliasing
• Anti-aliasing filter
• Digital-to-analog converter
• Digital control
• Digital frequency
• Nyquist–Shannon sampling theorem
• Whittaker–Shannon interpolation formula
• Sampling (signal processing)
• Ideal sampler

References

1. "Digital Signal Processing" Prentice Hall - Pages 11-12
2. "Digital Signal Processing: Instant access." Butterworth-Heinemann - Page 8