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1. Investigation and Mitigation of Noise Contributions in a Compact Heterodyne Interferometer

   https://doi.org/10.3390/s21175788  

   Zhang, Yanqi; Hines, Adam S.; Valdes, Guillermo; Guzman, Felipe (September 2021, Sensors)

   We present a noise estimation and subtraction algorithm capable of increasing the sensitivity of heterodyne laser interferometers by one order of magnitude. The heterodyne interferometer is specially designed for dynamic measurements of a test mass in the application of sub-Hz inertial sensing. A noise floor of 3.31×10−11m/Hz at 100 mHz is achieved after applying our noise subtraction algorithm to a benchtop prototype interferometer that showed a noise level of 2.76×10−10m/Hz at 100 mHz when tested in vacuum at levels of 3×10−5 Torr. Based on the previous results, we investigated noise estimation and subtraction techniques of non-linear optical pathlength noise, laser frequency noise, and temperature fluctuations in heterodyne laser interferometers. For each noise source, we identified its contribution and removed it from the measurement by linear fitting or a spectral analysis algorithm. The noise correction algorithm we present in this article can be generally applied to heterodyne laser interferometers. 

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2. 1/f Noise Mitigation in an Opto-Mechanical Sensor with a Fabry–Pérot Interferometer

   https://doi.org/10.3390/s24061969  

   Nelson, Andrea M; Sanjuan, Jose; Guzmán, Felipe (March 2024, Sensors)

   Low-frequency and 1/f noise are common measurement limitations that arise in a variety of physical processes. Mitigation methods for these noises are dependent on their source. Here, we present a method for removing 1/f noise of optical origin using a micro-cavity Fabry–Pérot (FP) interferometer. A mechanical modulation of the FP cavity length was applied to a previously studied opto-mechanical sensor. It effectively mimics an up-conversion of the laser frequency, shifting signals to a region where lower white-noise sources dominate and 1/f noise is not present. Demodulation of this signal shifts the results back to the desired frequency range of observation with the reduced noise floor of the higher frequencies. This method was found to improve sensitivities by nearly two orders of magnitude at 1 Hz and eliminated 1/f noise in the range from 1 Hz to 4 kHz. A mathematical model for low-finesse FP cavities is presented to support these results. This study suggests a relatively simple and efficient method for 1/f noise suppression and improving the device sensitivity of systems with an FP interferometer readout. 

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3. Optomechanical Accelerometers for Geodesy

   https://doi.org/10.3390/rs14174389  

   Hines, Adam; Nelson, Andrea; Zhang, Yanqi; Valdes, Guillermo; Sanjuan, Jose; Stoddart, Jeremiah; Guzmán, Felipe (September 2022, Remote Sensing)

   We present a novel optomechanical inertial sensor for low-frequency applications and corresponding acceleration measurements. This sensor has a resonant frequency of 4.715 (1) Hz, a mechanical quality factor of 4.76(3) × 105, a test mass of 2.6 g, and a projected noise floor of approximately 5 × 10−11 ms−2/Hz at 1 Hz. Such performance, together with its small size, low weight, reduced power consumption, and low susceptibility to environmental variables such as magnetic field or drag conditions makes it an attractive technology for future space geodesy missions. In this paper, we present an experimental demonstration of low-frequency ground seismic noise detection by direct comparison with a commercial seismometer, and data analysis algorithms for the identification, characterization, and correction of several noise sources. 

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4. Fiber-based two-wavelength heterodyne laser interferometer

   https://doi.org/10.1364/OE.466332  

   Zhang, Yanqi; Guzman, Felipe (September 2022, Optics Express)

   Displacement measuring interferometry is a crucial component in metrology applications. In this paper, we propose a fiber-based two-wavelength heterodyne interferometer as a compact and highly sensitive displacement sensor that can be used in inertial sensing applications. In the proposed design, two individual heterodyne interferometers are constructed using two different wavelengths, 1064 nm and 1055 nm; one of which measures the target displacement and the other monitors the common-mode noise in the fiber system. A narrow-bandwidth spectral filter separates the beam paths of the two interferometers, which are highly common and provide a high rejection ratio to the environmental noise. The preliminary test shows a sensitivity floor of $7.5\text{pm}/\sqrt{\text{Hz}}$at 1 Hz when tested in an enclosed chamber. We also investigated the effects of periodic errors due to imperfect spectral separation on the displacement measurement and propose algorithms to mitigate these effects. 

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5. A Compact Mm-Wave Multi-Band VCO Based on Triple-Mode Resonator for 5G and Beyond

   Chahardori, Mohammad; Hoque MD Aminul; Mokri Mohammad Ali; Heo, Deukhyoun Heo (July 2022, IEEE RFIT 2022)

   We present a low phase noise four-core triple-band voltage controlled-oscillator (VCO) with reconfigurable oscillator cores and multi-mode resonator. By activation/deactivation of oscillator cores and change of resonator impedance in three modes of operations, the proposed VCO provides complete freedom in selecting the resonance frequency for three operation bands in the mm-wave range. Compared to VCOs using switch-capacitor-bank for multi-band operation, the proposed VCO does not use any series switches with passive components in the resonator to provide a low phase noise in all three bands of operation. As a proof of concept, the proposed four-core triple-band VCO is implemented in a 65 nm CMOS process using four class-D oscillators with tail switches and a compact high-Q triple-mode resonator. The VCO oscillation frequencies center at 19, 28, and 38 GHz while providing good phase noise and low power consumption in all bands. Measured results show the total frequency tuning range (FTR) of 38.5% while the PN at 1MHz offset varies from -100.3 dBc/Hz to -106.06dBc/Hz resulting in an excellent FoMT of 199.8 dBc/Hz. 

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