Fourier Analysis

Discrete or continuous time Fourier analysis

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Library:
Simscape / Electrical / Control / General Control

Description

The Fourier Analysis block performs a Fourier analysis on the input signal in either discrete or continuous time.

Equations

A periodic function x(t) can be decomposed to an infinite sum of sine and cosine functions as

$x (t) = \frac{a_{0}}{2} + \sum_{n = 1}^{\infty} [a_{n} \cos (n t) + b_{n} \sin (n t)]$

where:

a₀ is the DC component.
a_n and b_n are constant Fourier coefficients.
n is the harmonic number.

The coefficients a_n and b_n are defined as

$a_{n} = \frac{2}{T_{0}} \int_{t_{0}}^{t_{0} + T_{0}} x (t) \cos (n Ω_{0} t) d t, n = 0, 1, ...$

$b_{n} = \frac{2}{T_{0}} \int_{t_{0}}^{t_{0} + T_{0}} x (t) \sin (n Ω_{0} t) d t, n = 1,2, ...$

$Ω_{0} = \frac{2 π}{T_{0}}$

$T_{0} = \frac{1}{f}$

where f is the fundamental frequency.

The magnitude and angle corresponding to the harmonic number are defined as:

$| X_{n} | = \sqrt{a_{n}^{2} + b_{n}^{2}}$

$θ_{n} = - \tan^{- 1} [\frac{b_{n}}{a_{n}}]$

Ports

Input

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`u` — Fourier analysis input
scalar | vector

Input signal to be analyzed. The input can be a single signal or multiple multiplexed signals. Input signals can be AC currents or voltages in an electrical system.

Data Types: single | double

Output

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`Magnitude` — Signal magnitude
scalar | vector

Signal magnitude corresponding to the harmonic number.

Data Types: single | double

`Angle` — Signal angle
scalar | vector

Signal angle corresponding to the harmonic number.

Data Types: single | double

Parameters

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`Fundamental frequency (Hz)` — Signal fundamental frequency
`60` (default) | positive scalar | vector with positive values

Fundamental frequency of the signal, in Hz. If you specify the fundamental frequency using a vector, it must match the input vector dimensions.

`Harmonic numbers` — Signal harmonic numbers
`[1 2]` (default) | vector with elements ≥ `0`

Specify signal harmonic numbers. Vector elements must be greater than or equal to 0.

`Initial magnitude` — Initial signal magnitude
`1` (default) | vector with elements ≥ `0`

Specify the initial magnitude of the signal. Vector elements must be greater than or equal to 0.

`Initial phase (rad)` — Initial signal phase
`0` (default) | vector

Initial phase angle of the signal, in rad.

`Sample time (-1 for inherited)` — Block sample time
`-1` (default) | 0 | positive scalar

Time between consecutive block executions. During execution, the block produces outputs and, if appropriate, updates its internal state. For more information, see What Is Sample Time? and Specify Sample Time.

For inherited discrete-time operation, specify -1. For discrete-time operation, specify a positive integer. For continuous-time operation, specify 0.

If this block is in a masked subsystem, or other variant subsystem that allows you to switch between continuous operation and discrete operation, promote the sample time parameter. Promoting the sample time parameter ensures correct switching between the continuous and discrete implementations of the block. For more information, see Promote Parameter to Mask.

Fourier Analysis

Description

Equations

Ports

Input

`u` — Fourier analysis input
scalar | vector

Output

`Magnitude` — Signal magnitude
scalar | vector

`Angle` — Signal angle
scalar | vector

Parameters

`Fundamental frequency (Hz)` — Signal fundamental frequency
`60` (default) | positive scalar | vector with positive values

`Harmonic numbers` — Signal harmonic numbers
`[1 2]` (default) | vector with elements ≥ `0`

`Initial magnitude` — Initial signal magnitude
`1` (default) | vector with elements ≥ `0`

`Initial phase (rad)` — Initial signal phase
`0` (default) | vector

`Sample time (-1 for inherited)` — Block sample time
`-1` (default) | 0 | positive scalar

Extended Capabilities

C/C++ Code Generation
Generate C and C++ code using Simulink® Coder™.

See Also

Blocks

Simscape Electrical Documentation

Support

10 Ways to Speed Up Power Conversion Control Design with Simulink

Fourier Analysis

Description

Equations

Ports

Input

u — Fourier analysis input scalar | vector

Output

Magnitude — Signal magnitude scalar | vector

Angle — Signal angle scalar | vector

Parameters

Fundamental frequency (Hz) — Signal fundamental frequency 60 (default) | positive scalar | vector with positive values

Harmonic numbers — Signal harmonic numbers [1 2] (default) | vector with elements ≥ 0

Initial magnitude — Initial signal magnitude 1 (default) | vector with elements ≥ 0

Initial phase (rad) — Initial signal phase 0 (default) | vector

Sample time (-1 for inherited) — Block sample time -1 (default) | 0 | positive scalar

Extended Capabilities

C/C++ Code Generation Generate C and C++ code using Simulink® Coder™.

See Also

Blocks

Simscape Electrical Documentation

Support

10 Ways to Speed Up Power Conversion Control Design with Simulink

`u` — Fourier analysis input
scalar | vector

`Magnitude` — Signal magnitude
scalar | vector

`Angle` — Signal angle
scalar | vector

`Fundamental frequency (Hz)` — Signal fundamental frequency
`60` (default) | positive scalar | vector with positive values

`Harmonic numbers` — Signal harmonic numbers
`[1 2]` (default) | vector with elements ≥ `0`

`Initial magnitude` — Initial signal magnitude
`1` (default) | vector with elements ≥ `0`

`Initial phase (rad)` — Initial signal phase
`0` (default) | vector

`Sample time (-1 for inherited)` — Block sample time
`-1` (default) | 0 | positive scalar

C/C++ Code Generation
Generate C and C++ code using Simulink® Coder™.