Dual beat-frequencies laser Doppler interferometer

Takita, Akihiro; Ebara, Hironori; Fujii, Yusaku

doi:10.1063/1.3669785

Cited by 3 publications

(3 citation statements)

References 10 publications

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“…The laser heterodyne interferometer can measure the displacement, velocity, and acceleration of vibration target in real-time [1][2][3]. It has the characteristics of non-contact, anti-interference, high precision, and so on, and has been widely used in the precision displacement measurement of micronano devices [4,5].…”

Section: Introductionmentioning

confidence: 99%

Micro-Movement Measured by Laser Heterodyne Interferometer Based on Acousto-Optic Effect

et al. 2022

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In this experiment, the stable output of a dual-frequency laser source is obtained by an acousto-optic modulator due to the Bragg diffraction effect. Furthermore, the non-polarized dual-laser heterodyne interferometer is designed to measure the micro-movement of stacked piezoelectric (PZT) ceramic. This micro-movement can be dynamically determined by comparing the phase difference between the conference beam and measuring beam. The results indicate that the micro-movement of PZT ceramic changes linearly with the driven-voltage in the range of 0–30 V and the sensitivity of movement to voltage is 58.3 nm/V, which is very close to the theoretical value and this laser heterodyne interferometer can be applied for calibrating parameters of PZT ceramic.

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Section: Introductionmentioning

confidence: 99%

Micro-Movement Measured by Laser Heterodyne Interferometer Based on Acousto-Optic Effect

et al. 2022

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“…11 In DB-LDI, two laser beams with different frequencies are both used as reference and signal beams, which produce two beat signals. Although the velocity calculated from one of the beat frequencies reaches the critical velocity, the velocity calculated from the other beat frequencies is far from the critical velocity.…”

Section: Introductionmentioning

confidence: 99%

High-speed impact test using an inertial mass and an optical interferometer

Jin

Watanabe

Prayogi

et al. 2013

Review of Scientific Instruments

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A high-speed impact testing method for evaluating mechanical properties of materials is proposed using an inertial mass and a dual beat-frequencies laser Doppler interferometer (DB-LDI). In this method, an inertial mass levitated using an aerostatic linear bearing is made to collide with the material being tested at a high initial velocity. During the collision, the velocity of the mass, which is even higher than the critical velocity (±0.56 m/s) defined by the frequency difference of the Zeeman laser, is accurately measured using the DB-LDI. The position, acceleration, and impact force of the mass are calculated from the measured velocity. Using the proposed method, the mechanical properties of a visco-elastic material under a high-speed impact loading condition can be accurately evaluated.

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“…Orthogonally polarized dual-frequency lasers are widely applied in two-frequency interferometers, ellipsometers, displacement measurement, wave plate measurement, and other measuring systems [1][2][3][4][5] . However, for the He-Ne laser transitions there exists a lock-in frequency difference below which one of the polarized waves dies because of the strong competition among waves [6,7] .…”

mentioning

confidence: 99%

Frequency difference lock-in phenomenon’s weakening by transverse magnetic field in Y-shaped cavity dual-frequency laser

et al. 2015

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We report experimental progress in weakening the frequency difference lock-in phenomenon in a Y-shaped cavity dual-frequency laser. A cube coil pair is chosen to provide a uniform magnetic field for tunability and uniformity of magnetic field strength. When the transverse magnetic field intensity is 9 mT, the frequency difference lock-in phenomenon is evidently weakened and the frequency difference can be continuously tuned in the range of 0.12 MHz to 1.15 GHz. Moreover, the relationship between the minimal frequency difference and magnetic field intensity are investigated and discussed. Then a Y-shaped cavity dual-frequency laser is expected to be utilized as an optimum light source for heterodyne interferometric sensing and precise laser measurement.

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Dual beat-frequencies laser Doppler interferometer

Cited by 3 publications

References 10 publications

Micro-Movement Measured by Laser Heterodyne Interferometer Based on Acousto-Optic Effect

Micro-Movement Measured by Laser Heterodyne Interferometer Based on Acousto-Optic Effect

High-speed impact test using an inertial mass and an optical interferometer

Frequency difference lock-in phenomenon’s weakening by transverse magnetic field in Y-shaped cavity dual-frequency laser

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