Normalized frequency (signal processing): Difference between revisions

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			{{Short description\|Frequency divided by a characteristic frequency}}
	In ], the reference value is usually the sampling frequency, denoted <math>f_s,\,</math>  in '''samples per second''', because the frequency content of a sampled signal is completely defined by the content within a span of <math>f_s\,</math> ], at most. In other words, the frequency distribution is periodic with period <math>f_s.\,</math>  When the actual frequency<math>, f,\,</math> has units of ] (] units), the normalized frequencies, also denoted by <math>f,\,</math>  have units of '''cycles per sample''', and the periodicity of the normalized distribution is 1.  And when the actual frequency<math>, \omega,\,</math> has units of radians per second (]), the normalized frequencies have units of '''radians per sample''', and the periodicity of the distribution is 2п.
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			In ] (DSP), a '''normalized frequency''' is a ratio of a variable ] (<math>f</math>) and a constant frequency associated with a system (such as a '']'', <math>f_s</math>). Some software applications require normalized inputs and produce normalized outputs, which can be re-scaled to physical units when necessary. Mathematical derivations are usually done in normalized units, relevant to a wide range of applications.
	If a sampled waveform is real-valued, such as a typical filter impulse response, the periodicity of the frequency distribution is still <math>f_s.\,</math>  But due to symmetry, it is completely defined by the content within a span of just <math>f_s/2.\,</math>  Accordingly, <u>some</u> filter design procedures/applications use that as the normalization reference (and the resulting units are ''half-cycles per sample''). A filter design can be used at different sample-rates, resulting in different frequency responses. Normalization produces a distribution that is independent of the sample-rate. Thus one plot is sufficient for all possible sample-rates.

			== Examples of normalization ==
	The following table shows examples of normalized frequencies for a 1 kHz signal, and a sample rate <math>f_s</math> = 44.1 kHz.
			A typical choice of characteristic frequency is the '']'' (<math>f_s</math>) that is used to create the digital signal from a continuous one. The normalized quantity, <math>f' = \tfrac{f}{f_s},</math> has the unit ''cycle per sample'' regardless of whether the original signal is a function of time or distance. For example, when <math>f</math> is expressed in ] (''cycles per second''), <math>f_s</math> is expressed in ''samples per second''.<ref name=Carlson/>

			Some programs (such as ] toolboxes) that design filters with real-valued coefficients prefer the ] <math>(f_s/2)</math> as the frequency reference, which changes the numeric range that represents frequencies of interest from <math>\left</math> ''cycle/sample'' to <math></math> ''half-cycle/sample''. Therefore, the normalized frequency unit is important when converting normalized results into physical units.
	{\| border=1 cellpadding=3

			]

			A common practice is to sample the frequency spectrum of the sampled data at frequency intervals of <math>\tfrac{f_s}{N},</math> for some arbitrary integer <math>N</math> (see {{slink\|Discrete-time_Fourier_transform\|Sampling_the_DTFT\|nopage=y}}). The samples (sometimes called frequency ''bins'') are numbered consecutively, corresponding to a frequency normalization by <math>\tfrac{f_s}{N}.</math><ref name=Harris/>{{rp\|p.56 eq.(16)}}<ref name=Taboga/> The normalized Nyquist frequency is <math>\tfrac{N}{2}</math> with the unit {{sfrac\|1\|N}}<sup>th</sup> ''cycle/sample''.

			], denoted by <math>\omega</math> and with the unit '']'', can be similarly normalized. When <math>\omega</math> is normalized with reference to the sampling rate as <math>\omega' = \tfrac{\omega}{f_s},</math> the normalized Nyquist angular frequency is {{nowrap\|''π radians/sample''}}.

			The following table shows examples of normalized frequency for <math>f = 1</math> ''kHz'', <math>f_s = 44100</math> ''samples/second'' (often denoted by ]), and 4 normalization conventions:

			{\| class="wikitable"
			\|+
			!'''Quantity'''
			!'''Numeric range'''
			!'''Calculation'''
			!'''Reverse'''
	\|-		\|-
			\|<math>f' = \tfrac{f}{f_s}</math>
	\| '''Type'''
			\|  {{math\|\|size=150%}} ''cycle/sample''
	\| '''Computation'''
		⚫	\|1000 / 44100 = 0.02268
	\| '''Value'''
			\|<math>f = f' \cdot f_s</math>
	\|-		\|-
			\|<math>f' = \tfrac{f}{f_s / 2}</math>
	\| Radians/sample
			\|   ''half-cycle/sample''
	\| 2 pi 1000 / 44100
		⚫	\|1000 / 22050 = 0.04535
	\| 0.1425
			\|<math>f = f' \cdot \tfrac{f_s}{2}</math>
	\|-		\|-
			\|<math>f' = \tfrac{f}{f_s / N}</math>
	\| w.r.t. fs
			\|  {{math\|\|size=150%}} ''bins''
⚫	\| 1000 / 44100
			\|1000 × {{mvar\|N}} / 44100 = 0.02268 {{mvar\|N}}
	\| 0.02676
			\|<math>f = f ' \cdot \tfrac{f_s}{N}</math>
	\|-		\|-
			\|<math>\omega' = \tfrac{\omega}{f_s}</math>
	\| w.r.t. Nyquist
			\|   ''radians/sample''
⚫	\| 1000 / 22050
			\|1000 × 2π / 44100 = 0.14250
	\| 0.04535
			\|<math>\omega = \omega' \cdot f_s</math>
	\|}		\|}

			==See also==
			*]

			==References==
			{{reflist\|1\|refs=
			<ref name=Carlson>
			{{cite book
			\|last=Carlson
			\|first=Gordon E.
			\|title=Signal and Linear System Analysis
			\|publisher=©Houghton Mifflin Co
			\|year=1992
			\|isbn=8170232384
			\|location=Boston, MA
			\|pages=469, 490
			}}</ref>

			<ref name=Harris>
			{{cite journal
			\|doi=10.1109/PROC.1978.10837
			\|last=Harris
			\|first=Fredric J.
			\|title=On the use of Windows for Harmonic Analysis with the Discrete Fourier Transform
			\|journal=Proceedings of the IEEE
			\|volume=66
			\|issue=1
			\|pages=51–83
			\|date=Jan 1978
			\|url=http://web.mit.edu/xiphmont/Public/windows.pdf\|citeseerx=10.1.1.649.9880
			\|bibcode=1978IEEEP..66...51H
			\|s2cid=426548
			}}</ref>

			<ref name=Taboga>
			Taboga, Marco (2021). "Discrete Fourier Transform - Frequencies", Lectures on matrix algebra. https://www.statlect.com/matrix-algebra/discrete-Fourier-transform-frequencies.
			</ref>
			}}
	]		]
			]

Latest revision as of 12:37, 18 March 2024

Frequency divided by a characteristic frequency

In digital signal processing (DSP), a normalized frequency is a ratio of a variable frequency ( $f$ ) and a constant frequency associated with a system (such as a sampling rate, $f_{s}$ ). Some software applications require normalized inputs and produce normalized outputs, which can be re-scaled to physical units when necessary. Mathematical derivations are usually done in normalized units, relevant to a wide range of applications.

Examples of normalization

A typical choice of characteristic frequency is the sampling rate ( $f_{s}$ ) that is used to create the digital signal from a continuous one. The normalized quantity, $f'={\tfrac {f}{f_{s}}},$ has the unit cycle per sample regardless of whether the original signal is a function of time or distance. For example, when $f$ is expressed in Hz (cycles per second), $f_{s}$ is expressed in samples per second.

Some programs (such as MATLAB toolboxes) that design filters with real-valued coefficients prefer the Nyquist frequency $(f_{s}/2)$ as the frequency reference, which changes the numeric range that represents frequencies of interest from $\left$ cycle/sample to $[0, 1]$ half-cycle/sample. Therefore, the normalized frequency unit is important when converting normalized results into physical units.

A common practice is to sample the frequency spectrum of the sampled data at frequency intervals of ${\tfrac {f_{s}}{N}},$ for some arbitrary integer $N$ (see § Sampling the DTFT). The samples (sometimes called frequency bins) are numbered consecutively, corresponding to a frequency normalization by ${\tfrac {f_{s}}{N}}.$ The normalized Nyquist frequency is ${\tfrac {N}{2}}$ with the unit ⁠1/N⁠ cycle/sample.

Angular frequency, denoted by $\omega$ and with the unit radians per second, can be similarly normalized. When $\omega$ is normalized with reference to the sampling rate as $\omega '={\tfrac {\omega }{f_{s}}},$ the normalized Nyquist angular frequency is π radians/sample.

The following table shows examples of normalized frequency for $f=1$ kHz, $f_{s}=44100$ samples/second (often denoted by 44.1 kHz), and 4 normalization conventions:


Quantity	Numeric range	Calculation	Reverse
$f'={\tfrac {f}{f_{s}}}$	cycle/sample	1000 / 44100 = 0.02268	$f=f'\cdot f_{s}$
$f'={\tfrac {f}{f_{s}/2}}$	half-cycle/sample	1000 / 22050 = 0.04535	$f=f'\cdot {\tfrac {f_{s}}{2}}$
$f'={\tfrac {f}{f_{s}/N}}$	bins	1000 × N / 44100 = 0.02268 N	$f=f'\cdot {\tfrac {f_{s}}{N}}$
$\omega '={\tfrac {\omega }{f_{s}}}$	radians/sample	1000 × 2π / 44100 = 0.14250	$\omega =\omega '\cdot f_{s}$

References

Carlson, Gordon E. (1992). Signal and Linear System Analysis. Boston, MA: ©Houghton Mifflin Co. pp. 469, 490. ISBN 8170232384.
Harris, Fredric J. (Jan 1978). "On the use of Windows for Harmonic Analysis with the Discrete Fourier Transform" (PDF). Proceedings of the IEEE. 66 (1): 51–83. Bibcode:1978IEEEP..66...51H. CiteSeerX 10.1.1.649.9880. doi:10.1109/PROC.1978.10837. S2CID 426548.
Taboga, Marco (2021). "Discrete Fourier Transform - Frequencies", Lectures on matrix algebra. https://www.statlect.com/matrix-algebra/discrete-Fourier-transform-frequencies.

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Latest revision as of 12:37, 18 March 2024

Examples of normalization

See also

References