Streaming Self-Corrected Dual-Comb Spectrometer

Here, we radically simplify coherently averaged dual-comb spectroscopy by introducing a real-time self-correction system: a radio frequency system-on-chip computes each incoming dual-comb interferogram's phase, frequency, and arrival time, calculates changes in the combs' carrier-envelope offset frequencies and repetition rates, and immediately phase-corrects the incoming interferogram data stream. The algorithm supports up to 0.3 GHz interferogram frequency bandwidth and thus combines fast measurement times (corresponding to high detunings) with broadband optical detection. Using the system, we achieve comb-resolved spectroscopy with Fourier-limited linewidth, coherent averaging over arbitrarily long durations, and a signal-to-noise ratio of up to 2100. Iodine and acetylene spectroscopy yields excellent agreement with literature over an optical bandwidth of more than 10 THz in the visible and near-infrared. Our approach only requires three optical and three electronic components and makes instantaneous dual-comb spectroscopy available to everyday applications.