High-performance, intelligent, on-chip speckle spectrometer using 2D silicon photonic disordered microring lattice

Microspectrometers have numerous applications in mobile optical sensing due to their dramatic advantages of compact size, light weight, and low power consumption. Reconstructive spectrometers, based on computational algorithms, have garnered considerable interest as they exhibit superior resolution or spectral bandwidth. However, existing reconstructive spectrometer designs face challenges in spectral applicability, algorithm robustness, and the resolution‐bandwidth limit. Here, a reconstructive spectrometer that utilizes a microring resonator (MRR) is proposed to achieve compressed sensing in hardware by decomposing an arbitrary continuous spectrum into a series of simple comb spectra. Owing to the presparse operation of the MRR, one needs to construct the comb spectra with a known line shape, only leaving the amplitude to be solved. Consequent random gratings measure the comb spectra, which are reconstructed with high robustness. Thanks to the independent engineering of spectral resolution and bandwidth, the approach breaks the traditional resolution‐bandwidth limit. A narrowband signal of a dual peak at 0.2 nm and a broadband spectrum with a large spectral bandwidth of 60 nm and 300 spectral channels using only eight physical channels is retrieved, achieving an ultrahigh reconstructive compression ratio of 37.5. This work opens up the possibility of on‐site spectral spectroscopy applications for the lab‐on‐a‐chip system.

Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Integrated Microring Spectrometer with In‐Hardware Compressed Sensing to Break the Resolution‐Bandwidth Limit for General Continuous Spectrum Analysis

Sun,

Chen,

et al. 2023

“…However, due to the large number of design parameters involved, conventional design approaches for SWFs often rely on a brute-force random approach. While this approach, which is also commonly used in other types of broadband filters for reconstructive spectrometers, [7][8][9] can indeed generate filters with highly random and distinct spectral responses, it also leads to unpredictable and non-reproducible performance of the realized spectrometer. Moreover, without fine-tuning the design parameters, the realized spectrometer may fall short of its optimal capabilities.…”

Section: Inverse Design Of Swfsmentioning

confidence: 99%

“…[ 6 ] However, previously demonstrated SWFs are designed in a brute‐force random manner, and have no optimized and deterministic selection of the structural parameters, leading to suboptimal and non‐reproducible performance of the spectrometer. This problem also applies to other broadband filters, such as disordered photonics media, [ 7 ] random photonic crystal cavities, [ 8 ] disordered microring lattice [ 9 ], and multi‐point self‐coupling waveguide filters. [ 5 ] On the other hand, using an inverse design algorithm to optimize a large number of structural parameters across a large space has been extensively applied to integrated photonics components, but limited to single device with simple spectral response, such as waveguide bends, [ 10 ] tapers/transitions, [ 11 ] beam splitters [ 12 ] waveguide crossings [ 13 ] etc.…”

Section: Introductionmentioning

confidence: 99%

An Inversely Designed Reconstructive Spectrometer on SiN Platform

Li,

Bao,

et al. 2024

Reconstructive spectrometers, which leverage the compressive sensing technique and computational algorithm, are promising solutions for high‐performance integrated spectrometers. Among the various options for realizing reconstructive spectrometers, stratified waveguide filters (SWFs) have emerged as a particularly attractive choice due to their ultra‐compact size and high performance. However, previous demonstrations of SWFs on silicon substrates have suffered from suboptimal and non‐reproducible spectrometer performance due to the brute‐force random design approach. In this paper, applying a bio‐inspired inverse design algorithm to the system level of multiple correlated SWFs is proposed. The algorithm allows for the precise and optimized design of the SWFs in order for higher spectral resolution of each SWF and lower spectral cross‐correlations between any two SWFs, overcoming the limitations of previous methods. The effectiveness of this approach is demonstrated by implementing a reconstructive spectrometer on a silicon nitride (SiN) platform, which is more thermally stable and can support a wider optical range than silicon.

Ultra‐Fast, Fine‐Resolution Thin‐Film Lithium Niobate Spectrometer

Liang,

Lin,

Wang

et al. 2024

Achieving rapid spectroscopic characterization is highly desirable for contactless, real‐time monitoring applications. However, it is challenging due to the trade‐off between short acquisition time and fine resolution. To address this challenge, a fully active scanning Fourier transform spectrometer (FTS) using thin‐film lithium niobate (TFLN) photonics is proposed. This work theoretically reveals relations between acquisition time and resolution and finds that their trade‐off can be notably alleviated by employing Michelson interferometer architectures. The proposed device consists of two broadband edge couplers and a tunable Michelson interferometer which includes 1.02 m‐length equivalent waveguides. The fabricated waveguides can achieve a wafer‐scale optical propagation loss of 12 2.4 dB , which enables the device to maintain a low insertion loss with a 1.02 m‐length equivalent waveguide. The proposed device can achieve an acquisition time of 10 , a spectral resolution of 0.74 (i.e., 0.19 nm), and an operation wavelength range from 1260 to 1600 nm.