Sine and cosine transformation

The sine and cosine transformations are two variants of the continuous Fourier transformation , which are only defined for real numbers , in contrast to the Fourier transformation, which is defined for complex numbers . They are integral transformations with applications in the field of signal processing . The discrete cosine transformation (DCT) and the discrete sine transformation (DST) are derived from this for time-discrete signal sequences .

General

The core of the Fourier transformation can be split into a real and an imaginary part using Euler's identity :

{\ displaystyle \ mathrm {e} ^ {\ mathrm {j} \, x} = \ cos \ left (x \ right) + \ mathrm {j} \ cdot \ sin \ left (x \ right)}

with as the imaginary unit . The real part is used as the core of the cosine transformation and the imaginary part as the core of the sine transformation. The cosine function is an even function , the cosine transformation maps the even signal component of the Fourier transform of a real signal. Analogously, the odd sine function maps the odd signal component of the Fourier transform of a real signal. ${\ displaystyle \ mathrm {j}}$

Sine transformation

The sine transformation is defined for real signals by: ${\ displaystyle y (t)}$

{\ displaystyle \ mathrm {Y_ {s}} (f) = {\ mathcal {SIN}} \ {y (t) \} = \ int _ {- \ infty} ^ {\ infty} y (t) \ sin (2 \ pi ft) \, \ mathrm {d} t.}

Cosine transformation

The cosine transformation is defined for real signals by: ${\ displaystyle y (t)}$

{\ displaystyle \ mathrm {Y_ {c}} (f) = {\ mathcal {COS}} \ {y (t) \} = \ int _ {- \ infty} ^ {\ infty} y (t) \ cos (2 \ pi ft) \, \ mathrm {d} t.}

context

The Fourier transform

{\ displaystyle \ mathrm {Y} (f) = {\ mathcal {F}} \ {y (t) \} = \ int _ {- \ infty} ^ {\ infty} y (t) \, e ^ { -2 \ pi \ mathrm {j} f \ cdot t} \, \ mathrm {d} t}

can be formed for real signals from the sine and cosine transformation: ${\ displaystyle y (t)}$

{\ displaystyle {\ mathcal {F}} \ {y (t) \} = {\ mathcal {COS}} \ {y (t) \} - \ mathrm {j} \ cdot {\ mathcal {SIN}} \ {y (t) \}.}

For the special cases of real and even signals, the Fourier transformation changes into the cosine transformation; for real and odd signals, it changes into the sine transformation, except for a constant prefactor.

literature

Fernando Puente León, Uwe Kiencke, Holger Jäkel: Signals and Systems . 5th edition. Oldenbourg, 2011, ISBN 978-3-486-59748-6 .