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Abstract Arbitrary waveform synthesizers play an essential role in modern information technology, yet electronic synthesizers face limitations due to the speed of analog-to-digital converters, typically in the range of tens to hundreds of giga samples per second (GSa/s). While photonic-assisted waveform synthesizers show promise in surpassing this ceiling, but the system reconfigurability remains a challenge. Here, we propose and demonstrate a temporal point-by-point arbitrary waveform synthesizer with a sampling rate beyond tera sample per second (TSa/s), leveraging an optical temporal Vernier caliper in the photonic synthetic dimension. The temporal Vernier caliper, consisting of a mode-locked laser (MLL) and a fiber loop, utilizes a slight detuning between the optical pulse period of the MLL and the round-trip time delay of the loop to control the sampling rate of a synthesized waveform with high flexibility. The amplitude of each sampling point is manipulated at a low speed corresponding to the reciprocal of the pulse period, thus massive point-by-point waveform synthesis can be achieved with full reconfigurability. In the experiment, arbitrary waveforms with widely tunable sampling rates from 5 GSa/s to 1 TSa/s are synthesized, which is an order of magnitude higher than state-of-the-art electronic counterparts. To show the capability of massive point-by-point synthesis, communication signals for high-speed wireless communications and linearly chirped microwave waveforms for high-resolution multi-target detection are synthesized. The capabilities of tunable sampling rate and massive point-by-point synthesis make the temporal Vernier caliper a universal solution for high-speed microwave sources, offering significant promise for broad applications requiring high-speed signal sources.
Yao et al. (Fri,) studied this question.
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