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Enhancing the stability of a continuous-wave terahertz system by photocurrent normalization

In a continuous-wave terahertz system based on photomixing, the measured amplitude of the terahertz signal shows an uncertainty due to drifts of the responsivities of the photomixers and of the optical power illuminating the photomixers. We report on a simple method to substantially reduce this uncertainty. By normalizing the amplitude to the DC photocurrents in both the transmitter and receiver photomixers, we achieve a significant increase of the stability. If, e.g., the optical power of one laser is reduced by 10%, the normalized signal is expected to change by only 0.3%, i.e., less than the typical uncertainty due to short-term fluctuations. This stabilization can be particularly valuable for terahertz applications in non-ideal environmental conditions outside of a temperature-stabilized laboratory.

preprint2013arXivOpen access
A. RoggenbuckM. LangenbachK. ThirunavukkuarasuH. SchmitzA. DeningerI. Camara MayorgaR. GüstenJ. HembergerM. Grüninger
physics.optics
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Open access9 authors1 topic
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A. RoggenbuckM. LangenbachK. ThirunavukkuarasuH. SchmitzA. DeningerI. Camara MayorgaR. GüstenJ. HembergerM. Grüninger

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