Optomechanical reference accelerometer

Gerberding, Oliver; Cervantes, Felipe Guzmán; Melcher, John; Pratt, Jon R.; Taylor, Jacob M.

doi:10.1088/0026-1394/52/5/654

Cited by 56 publications

(42 citation statements)

References 32 publications

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“…S IGNIFICANT progress in the field of optomechanics has stimulated a new generation of photonic motion detectors that surpass the sensitivity of current standards, with aims to approach fundamental limits set by quantum mechanics [1]. These systems rely on the coupling between mechanical motion and light, which is enhanced when using an optical resonator such as a Fabry-Perot cavity [2], spherical cavities that support whispering gallery modes (WGMs) [1], [3]- [10], and nanocavities in the form of photonic crystals [11], [12]. Through optimization of the optical field geometry and the mechanical test-mass, sensitivities on the order of 10 −18 m·Hz − 1 2 [1], [13], [14] can be reached, allowing laser cooling of macroscopic motion [1], [15], force sensing [8], and recently the discovery of gravitational waves [13].…”

Section: Introductionmentioning

confidence: 99%

Characterization and Testing of a Micro-g Whispering Gallery Mode Optomechanical Accelerometer

Barker

2018

J. Lightwave Technol.

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Navigation, bio-tracking devices and gravity gradiometry are amongst the diverse range of applications requiring ultrasensitive measurements of acceleration. We describe an accelerometer that exploits the dispersive and dissipative coupling of the motion of an optical whispering gallery mode (WGM) resonator to a waveguide. A silica microsphere-cantilever is used as both the optical cavity and inertial test-mass. Deflections of the cantilever in response to acceleration alter the evanescent coupling between the microsphere and the waveguide, in turn causing a measurable frequency shift and broadening of the WGM resonance. The theory of this optomechanical response is outlined. By extracting the dispersive and dissipative optomechanical rates from data we find good agreement between our model and sensor response. A noise density of 4.5 µg·Hz − 1 2 with a bias instability of 31.8 µg (g = 9.81 m·s −2 ) is measured, limited by classical noise larger than the test-mass thermal motion. Closedloop feedback is demonstrated to reduce the bias instability and long term drift. Currently this sensor outperforms both commercial accelerometers used for navigation and those in ballistocardiology for monitoring blood flowing into the heart. Further optimization would enable short-range gravitational force detection with operation beyond the lab for terrestrial or space gradiometry.

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Section: Introductionmentioning

confidence: 99%

Characterization and Testing of a Micro-g Whispering Gallery Mode Optomechanical Accelerometer

Barker

2018

J. Lightwave Technol.

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“…Figure 3e illustrates the measured bias instability and VRW noise of ≈5.23 mg and 1.8 mg Hz −1/2 , respectively, which are the two very important parameters indicating the minimum achievable low‐frequency acceleration reading limited by flicker noise and the total noise density. [ 31,33 ] Figure 3f shows the converted acceleration power spectrum density (PSD) which indicates the non‐flat noise density in the low frequency range from 0.001 to 20 Hz. Theoretically, in pre‐oscillation mode, the thermal noise frequency fluctuation is given by: [ 41,42 ] δ Ω th = [( k B T / E C ) × (Ω m Δ f / Q m )] 1/2 , from the measured power spectra density and with Δ f the acquisition rate corresponding to the integration time, and E C = m x Ω m 2 〈 x c 2 〉 the energy in the carrier in the oscillator and 〈 x c 〉 the constant mean square amplitude.…”

Section: Resultsmentioning

confidence: 99%

“…The excess noises shown in the measurements, with the acceleration PSD non‐flat at the low‐frequency region, are mainly from system noise such as the laser frequency noise, parasitic displacement noise, device thermal fluctuation, and thermal expansion noise among others. [ 33 ] We note that only the first 40 RF spectra (up to 154.8 mg) are used in the analysis to be well within the linear dynamic range (<0.05% standard deviation). We also measured other inertial sensor devices in our setup with similar geometries, including an inertial sensor mounted 180° opposite from Figure 3a (i.e., acceleration in the − y ‐axis direction); the mechanical resonance frequency shift is observed in opposite direction under the same acceleration ranges as detailed in Supporting Information III.B.…”

Section: Resultsmentioning

confidence: 99%

“…With the large mass oscillator and high driving powers, the thermal Brownian noise can be largely reduced [ 41,42 ] and then the measured frequency instability and acceleration sensitivity can be strongly improved, resulting in better resolution. The optical noise bound arising from quantum backaction noise a BA [ 33 ] is estimated to be ≈184 ng Hz −1/2 for our oscillator design and implementation parameters, and is detailed in Supporting Information VI.B. We note that, with this RF transduction readout approach instead of solely the optical intensity transmission readout, optical shot noise, and photodetector shot noise do not contribute significantly to the fundamental limit in our readout scheme, allowing our measured acceleration noise floor to be close to the thermal noise limit.…”

Section: Discussionmentioning

confidence: 99%

“…Such examples include nanobeam cavities at 10 µg Hz −1/2 (1 g = 9.81 m s −2 ) resolution (sensing bandwidth 5 to 25 kHz) with lock‐in detection, [ 30 ] cantilevered whispering gallery mode spherical silica cavities at 4.5 µg Hz −1/2 resolution (sensing bandwidth 10 to 100 Hz), [ 31 ] and bulk fiber‐optic cavities at 100 ng Hz −1/2 resolution (sensing bandwidth 1 to 10 kHz). [ 32,33 ] More details about the accelerometers performance comparisons are described in Supporting Information I. Optomechanical accelerometers with external piezoelectric stages and calibration have also been tested with outdoor operation. [ 34–37 ] Unlike these previously demonstrated optomechanical accelerometers, here we demonstrate a new transduction mechanism which is not based on the optical readout through measuring the shift or broadening of optical resonances via dispersive and dissipative optomechanical coupling.…”

Section: Introductionmentioning

confidence: 99%

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A Chip‐Scale Oscillation‐Mode Optomechanical Inertial Sensor Near the Thermodynamical Limits

Huang

Flores

et al. 2020

Laser & Photonics Reviews

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Modern navigation systems integrate the global positioning system (GPS) with an inertial navigation system (INS), which complement each other for correct attitude and velocity determination. The core of the INS integrates accelerometers and gyroscopes used to measure forces and angular rate in the vehicular inertial reference frame. With the help of gyroscopes and by integrating the acceleration to compute velocity and distance, precision and compact accelerometers with sufficient accuracy can provide small-error location determination. Solid-state implementations, through coherent readout, can provide a platform for high performance acceleration detection. In contrast to prior accelerometers using piezoelectric or capacitive readout techniques, optical readout provides narrow-linewidth high-sensitivity laser detection along with low-noise resonant optomechanical transduction near the thermodynamical limits. Here an optomechanical inertial sensor with an 8.2 µg Hz −1/2 velocity random walk (VRW) at an acquisition rate of 100 Hz and 50.9 µg bias instability is demonstrated, suitable for applications, such as, inertial navigation, inclination sensing, platform stabilization, and/or wearable device motion detection. Driven into optomechanical sustained-oscillation, the slot photonic crystal cavity provides radio-frequency readout of the optically-driven transduction with an enhanced 625 µg Hz −1 sensitivity. Measuring the optomechanically-stiffened oscillation shift, instead of the optical transmission shift, provides a 220× VRW enhancement over pre-oscillation mode detection.

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