Doppler effect: Difference between revisions

<div class="definition"><div class="short_definition">(<br/>''Also called'' Doppler shift.) &ldquo;The change in the apparent time interval between two  events which arises from the motion of an observer together with the finite [[velocity]] of information  about the events&rdquo; (Gill 1965).</div><br/> <div class="paragraph">Doppler effect is often used to mean frequency shifts (Doppler shift) of acoustic and [[electromagnetic  waves]] because of relative motion between sources and observers. The relative magnitude  of a Doppler shift is of order of the ratio of a characteristic speed (e.g., speed of a source) to a  speed of propagation (e.g., [[speed of sound]], [[speed of light]]). A shift to lower [[frequency]] (relative  to a reference frequency) is sometimes called a red shift whereas a shift to higher frequency is  sometimes called a blue shift, although no colorimetric meaning should be attached to these terms.  [[Acoustic waves]] do not evoke sensations of color, nor do [[electromagnetic waves]] outside the  [[visible spectrum]], and even Doppler shifts of visible [[light]] are so small as to yield no visually  perceptible color changes. According to classical theory, there is no frequency shift of [[electromagnetic  radiation]] for motion of a [[transmitter]] perpendicular to the line between [[receiver]] and  transmitter. But according to relativistic theory, even for this kind of motion there is a Doppler  shift (transverse Doppler shift), although it is appreciably smaller than the longitudinal Doppler  shift. <br/>''See also'' [[Doppler frequency shift]].</div><br/> </div><div class="reference">Gill, T. P. 1965. The Doppler Effect. </div><br/> <div class="reference">Toman, K. 1984. EOS, Trans. Amer. Geophys. Union. 65. p. 1193. </div><br/> <div class="reference">Helliwell, T. M. 1966. Introduction to Special Relativity. 116&ndash;122. </div><br/>