Motion and Vibration Sensing with Frequency Modulated Continuous Wave Single Photon LIDAR

Schembri, Paula, Svensson, Truls

January 2024

In this report, remote sensing with Light Detection and Ranging (LIDAR) was demonstrated. In particular, a Frequency Modulated Continuous Wave (FMCW) LIDAR was used to reconstruct the motion of a moving target. Measurements were performed at the single photon level using a Superconducting Nanowire Single Photon Detector (SNSPD) and velocity and distance time series were reconstructed. The limitations of the technique were investigated by comparing three different targets. Furthermore, vibration sensing was performed where the vibrational modes were successfully reconstructed for a speaker. Additionally, multi-pitch decomposition was demonstrated and the Signal to Noise Ratio (SNR) - dependency on speaker frequency was studied.

LIDAR

FMCW

SNSPD

Vibration Sensing

Physical Sciences

Fysik

Target recognition by vibrometry with a coherent laser radar / Måligenkänning med vibrometri och en koherent laserradar

Olsson, Andreas

January 2003

<p>Laser vibration sensing can be used to classify military targets by its unique vibration signature. A coherent laser radar receives the target´s rapidly oscillating surface vibrations and by using proper demodulation and Doppler technique, stationary, radially moving and even accelerating targets can be taken care of. </p><p>A frequency demodulation method developed at the former FOA, is for the first time validated against real data with turbulence, scattering, rain etc. The issue is to find a robust and reliable system for target recognition and its performance is therefore compared with some frequency distribution methods. The time frequency distributions have got a crucial drawback, they are affected by interference between the frequency and amplitude modulated multicomponent signals. The system requirements are believed to be fulfilled by combining the FOA method with the new statistical method proposed here, the combination being suggested as aimpoint for future investigations.</p>

Reglerteknik

target recognition

vibrometry

coherent laser radar

laser vibration sensing

Doppler technique

time-frequency analysis

Reglerteknik

Automatic control

Reglerteknik

Target recognition by vibrometry with a coherent laser radar / Måligenkänning med vibrometri och en koherent laserradar

Olsson, Andreas

January 2003

Laser vibration sensing can be used to classify military targets by its unique vibration signature. A coherent laser radar receives the target´s rapidly oscillating surface vibrations and by using proper demodulation and Doppler technique, stationary, radially moving and even accelerating targets can be taken care of. A frequency demodulation method developed at the former FOA, is for the first time validated against real data with turbulence, scattering, rain etc. The issue is to find a robust and reliable system for target recognition and its performance is therefore compared with some frequency distribution methods. The time frequency distributions have got a crucial drawback, they are affected by interference between the frequency and amplitude modulated multicomponent signals. The system requirements are believed to be fulfilled by combining the FOA method with the new statistical method proposed here, the combination being suggested as aimpoint for future investigations.

Reglerteknik

target recognition

vibrometry

coherent laser radar

laser vibration sensing

Doppler technique

time-frequency analysis

Reglerteknik

Automatic control

Reglerteknik

Poly-Vinylidene Fluoride Based Vibration Spectrum Sensors and Energy Harvestors

Nyayapati, Mahidhar Ramesh

January 2014

Mechanical vibrations in large structures such as buildings, bridges, dams and critical frequencies in large machinery generally have low frequencies (100Hz-1000Hz). To monitor large areas of such structures we need huge network of low cost, easily manufacturable, self-powered and stand-alone vibration spectrum sensors. The sensors should also consume very little power during their overall operation cycle and have moderately high frequency resoultion. The thesis provides mathematical analysis, design and development of stand-alone, low frequency vibration spectrum analyzer .A mechanically stretched polymer piezoelectric membrane, which has a fixed length and tension, can act as a single frequency detector due to its unique resonant frequency. Stretching multiple ribbons of diffferent lengths and tensions, a vibration spectrum analyzer, which gives the Fourier frequency components present in an arbitrary mechanical input vibration, can be designed. The thesis presents a detailed description of experiments to evaluate a low frequency vibration spectrum analyzer system that accepts an incoming input vibration and directly provides the spectrum as output. Polymer piezoelectric materials being easily manufacturable these sensors can be deployed in wide area sensor networks that monitor large structures. The thesis also shows design of a vibration energy harvesting system based on the concept of harvesting energy at low frequencies. The need for developing such an energy harvesting system arises from the necessity of making the vibration sensor, self-powered. Multiple experimental tests were performed before developing a prototype vibration energy harvesting circuit.

Vibration Spectrum Sensors

Vibration Energy Harvestors

Piezoeletricity

Vibration Spectrum Analyzer

Polymer Piezoelectric Materials

Mechanical Vibrations

Poly-Vinylidene Difluoride(PVDF)

Vibration Sensing

Energy Harvesting

Energy Harvestors

Vibration Spectrum Sensing

Harvesting Energy

Vibration Energy Harvesting System

Materials Science