This paper introduces a novel integrated reconstructive spectrometer with programmable photonic circuits using a few engineered MZI elements. The design creates a large number of uncorrelated sampling channels without additional hardware costs, achieving ultra-high resolution. Experimental results demonstrate a bandwidth-to-resolution ratio of over 20,000 using only 729 sampling channels, with a resolution of less than 10 picometers and a bandwidth of over 200 nanometers.
Optical spectroscopic sensors are a powerful tool to reveal light-matter interactions in many fields. Miniaturizing the currently bulky spectrometers has become imperative for the wide range of applications that demand in situ or even in vitro characterization systems, a field that is growing rapidly. In this paper, we propose a novel integrated reconstructive spectrometer with programmable photonic circuits by simply using a few engineered MZI elements. This design effectively creates an exponentially scalable number of uncorrelated sampling channels over an ultra-broad bandwidth without incurring additional hardware costs, enabling ultra-high resolution down to single-digit picometers. Experimentally, we implement an on-chip spectrometer with a 6-stage cascaded MZI structure and demonstrate <10 pm resolution with >200 nm bandwidth using only 729 sampling channels. This achieves a bandwidth-to-resolution ratio of over 20,000, which is, to our best knowledge, about one order of magnitude greater than any reported miniaturized spectrometers to date.
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