Massively parallel coherent laser ranging using a soliton microcomb

Johann Riemensberger, Anton Lukashchuk, Maxim Karpov, Wenle Weng, Erwan Lucas, Junqiu Liu and Tobias J. Kippenberg ()
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Johann Riemensberger: Swiss Federal Institute of Technology (EPFL)
Anton Lukashchuk: Swiss Federal Institute of Technology (EPFL)
Maxim Karpov: Swiss Federal Institute of Technology (EPFL)
Wenle Weng: Swiss Federal Institute of Technology (EPFL)
Erwan Lucas: Swiss Federal Institute of Technology (EPFL)
Junqiu Liu: Swiss Federal Institute of Technology (EPFL)
Tobias J. Kippenberg: Swiss Federal Institute of Technology (EPFL)

Nature, 2020, vol. 581, issue 7807, 164-170

Abstract: Abstract Coherent ranging, also known as frequency-modulated continuous-wave (FMCW) laser-based light detection and ranging (lidar)1 is used for long-range three-dimensional distance and velocimetry in autonomous driving2,3. FMCW lidar maps distance to frequency4,5 using frequency-chirped waveforms and simultaneously measures the Doppler shift of the reflected laser light, similar to sonar or radar6,7 and coherent detection prevents interference from sunlight and other lidar systems. However, coherent ranging has a lower acquisition speed and requires precisely chirped8 and highly coherent5 laser sources, hindering widespread use of the lidar system and impeding parallelization, compared to modern time-of-flight ranging systems that use arrays of individual lasers. Here we demonstrate a massively parallel coherent lidar scheme using an ultra-low-loss photonic chip-based soliton microcomb9. By fast chirping of the pump laser in the soliton existence range10 of a microcomb with amplitudes of up to several gigahertz and a sweep rate of up to ten megahertz, a rapid frequency change occurs in the underlying carrier waveform of the soliton pulse stream, but the pulse-to-pulse repetition rate of the soliton pulse stream is retained. As a result, the chirp from a single narrow-linewidth pump laser is transferred to all spectral comb teeth of the soliton at once, thus enabling parallelism in the FMCW lidar. Using this approach we generate 30 distinct channels, demonstrating both parallel distance and velocity measurements at an equivalent rate of three megapixels per second, with the potential to improve sampling rates beyond 150 megapixels per second and to increase the image refresh rate of the FMCW lidar by up to two orders of magnitude without deterioration of eye safety. This approach, when combined with photonic phase arrays11 based on nanophotonic gratings12, provides a technological basis for compact, massively parallel and ultrahigh-frame-rate coherent lidar systems.

Date: 2020
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DOI: 10.1038/s41586-020-2239-3

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