| Revision as of 04:55, 13 August 2011 edit131.215.237.199 (talk) corrected obvious math mistake in the first 2 equations.← Previous edit | Latest revision as of 19:03, 16 May 2017 edit undoChetvorno (talk | contribs)Extended confirmed users65,424 edits Merged article into Heterodyne | ||
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| {{Technical|date=June 2011}} | |||
| {{Unreferenced|date=December 2009}} | |||
| '''Heterodyne detection''' is a method of detecting radiation by non-linear mixing with radiation of a reference frequency. It is commonly used in ] and ] for detecting and analysing signals. | |||
| The radiation in question is most commonly either radio waves (see ]) or light (see ] or ]). The reference radiation is known as the ]. The signal and the local oscillator are superimposed at a ]. The mixer, which is commonly a (photo-)], has a non-linear response to the amplitude, that is, at least part of the output is proportional to the square of the input. | |||
| Let the electric field of the received signal be | |||
| :<math>E_\mathrm{sig} = \cos(\omega_\mathrm\mathrm{sig}t+\varphi)\,</math> | |||
| and that of the local oscillator be | |||
| :<math>E_\mathrm{LO} = \cos(\omega_\mathrm{LO}t).\,</math> | |||
| For simplicity, assume that the output ''I'' of the detector is proportional to the square of the amplitude: | |||
| :<math>I\propto \left( E_\mathrm{sig}\cos(\omega_\mathrm{sig}t+\varphi) + E_\mathrm{LO}\cos(\omega_\mathrm{LO}t) \right)^2</math> | |||
| :<math> =\frac{E_\mathrm{sig}^2}{2}\left( 1+\cos(2\omega_\mathrm{sig}t+2\varphi) \right)</math> | |||
| ::<math> + \frac{E_\mathrm{LO}^2}{2}(1+\cos(2\omega_\mathrm{LO}t)) </math> | |||
| ::<math> + E_\mathrm{sig}E_\mathrm{LO} \left[ | |||
| \cos((\omega_\mathrm{sig}+\omega_\mathrm{LO})t+\varphi) | |||
| + \cos((\omega_\mathrm{sig}-\omega_\mathrm{LO})t+\varphi) | |||
| \right] | |||
| </math> | |||
| :<math> =\underbrace{\frac{E_\mathrm{sig}^2+E_\mathrm{LO}^2}{2}}_{constant\;component}+\underbrace{\frac{E_\mathrm{sig}^2}{2}\cos(2\omega_\mathrm{sig}t+2\varphi) + \frac{E_\mathrm{LO}^2}{2}\cos(2\omega_\mathrm{LO}t) + E_\mathrm{sig}E_\mathrm{LO} \cos((\omega_\mathrm{sig}+\omega_\mathrm{LO})t+\varphi)}_{high\;frequency\;component}</math> | |||
| ::<math> + \underbrace{E_\mathrm{sig}E_\mathrm{LO} \cos((\omega_\mathrm{sig}-\omega_\mathrm{LO})t+\varphi)}_{beat\;component}. | |||
| </math> | |||
| The output has high frequency (<math>2\omega_\mathrm{sig}</math> and <math>2\omega_\mathrm{LO}</math>) and constant components. In heterodyne detection, the high frequency components and usually the constant components are filtered out, leaving the intermediate (beat) frequency at <math>\omega_\mathrm{sig}-\omega_\mathrm{LO}</math>. The amplitude of this last component is proportional to the amplitude of the signal radiation. With appropriate ] the phase of the signal can be recovered as well. | |||
| ==See also== | |||
| *] | |||
| *] | |||
| *] | |||
| {{DEFAULTSORT:Heterodyne Detection}} | |||
| ] | |||
| ] | |||
| ] | |||
| ] | |||
| ] | |||
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