Photonic time-stretch technology with prismatic pulse dispersion towards fast real-time measurements

Lei Yang; Hui Chen; Jun Ma; Qian Zhu; Tong Yang; Hongbo Xie

doi:10.3390/PHOTONICS6030099

Photonic time-stretch technology with prismatic pulse dispersion towards fast real-time measurements

Lei Yang, Hui Chen, Jun Ma, Qian Zhu, Tong Yang, Hongbo Xie^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

4 Citations (Scopus)

Abstract

Photonic time-stretch (PTS) technology enables revolutionary technical breakthroughs in ultrafast electronic and optical systems. By means of employing large chromatic dispersion to map the spectrum of an ultrashort optical pulse into a stretched time-domain waveform (namely, using the dispersive Fourier transformation), PTS overcomes the fundamental speed limitations of conventional techniques. The chromatic dispersion utilized in PTS can be implemented using multiple optical prism arrays, which have the particular advantages of low loss in the extended spectrum outside of the specific telecommunication band, flexibility, and cost-effectiveness. In this article, we propose and demonstrate the PTS technology established for a pair of prisms, which works as a data acquisition approach in ultrafast digitizing, imaging, and measurement regimes.

Original language	English
Article number	99
Journal	Photonics
Volume	6
Issue number	3
DOIs	https://doi.org/10.3390/PHOTONICS6030099
Publication status	Published - 1 Sept 2019
Externally published	Yes

Keywords

Dispersive fourier transformation
Fast real-time measurement
Photonic time-stretch
Prism pair
Prismatic dispersion

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10.3390/PHOTONICS6030099

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abstract = "Photonic time-stretch (PTS) technology enables revolutionary technical breakthroughs in ultrafast electronic and optical systems. By means of employing large chromatic dispersion to map the spectrum of an ultrashort optical pulse into a stretched time-domain waveform (namely, using the dispersive Fourier transformation), PTS overcomes the fundamental speed limitations of conventional techniques. The chromatic dispersion utilized in PTS can be implemented using multiple optical prism arrays, which have the particular advantages of low loss in the extended spectrum outside of the specific telecommunication band, flexibility, and cost-effectiveness. In this article, we propose and demonstrate the PTS technology established for a pair of prisms, which works as a data acquisition approach in ultrafast digitizing, imaging, and measurement regimes.",

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T1 - Photonic time-stretch technology with prismatic pulse dispersion towards fast real-time measurements

AU - Yang, Lei

AU - Chen, Hui

AU - Ma, Jun

AU - Zhu, Qian

AU - Yang, Tong

AU - Xie, Hongbo

PY - 2019/9/1

Y1 - 2019/9/1

N2 - Photonic time-stretch (PTS) technology enables revolutionary technical breakthroughs in ultrafast electronic and optical systems. By means of employing large chromatic dispersion to map the spectrum of an ultrashort optical pulse into a stretched time-domain waveform (namely, using the dispersive Fourier transformation), PTS overcomes the fundamental speed limitations of conventional techniques. The chromatic dispersion utilized in PTS can be implemented using multiple optical prism arrays, which have the particular advantages of low loss in the extended spectrum outside of the specific telecommunication band, flexibility, and cost-effectiveness. In this article, we propose and demonstrate the PTS technology established for a pair of prisms, which works as a data acquisition approach in ultrafast digitizing, imaging, and measurement regimes.

AB - Photonic time-stretch (PTS) technology enables revolutionary technical breakthroughs in ultrafast electronic and optical systems. By means of employing large chromatic dispersion to map the spectrum of an ultrashort optical pulse into a stretched time-domain waveform (namely, using the dispersive Fourier transformation), PTS overcomes the fundamental speed limitations of conventional techniques. The chromatic dispersion utilized in PTS can be implemented using multiple optical prism arrays, which have the particular advantages of low loss in the extended spectrum outside of the specific telecommunication band, flexibility, and cost-effectiveness. In this article, we propose and demonstrate the PTS technology established for a pair of prisms, which works as a data acquisition approach in ultrafast digitizing, imaging, and measurement regimes.

KW - Dispersive fourier transformation

KW - Fast real-time measurement

KW - Photonic time-stretch

KW - Prism pair

KW - Prismatic dispersion

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Photonic time-stretch technology with prismatic pulse dispersion towards fast real-time measurements

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Keywords

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