Your search keyword '"lidar-radar"' showing total 3 results

1. Laser detection by electronic instead of optical heterodyne using a two-frequency laser.

Author

Li, Lei, Zhao, Changming, and Yang, Suhui

Abstract

A laser ranging system using a two-frequency laser is demonstrated, and the lidar-radar concept is introduced. A laser beam carrying 100 MHz radio frequency is obtained by a monolithic nonplanar ring single-frequency oscillator and an acousto-optical modulator, which is used as the light source of the two-frequency detecting experimental setup. With the optical transmitting and collecting system, the displacement information of a target mounted on a motorized translation stage is achieved. In signal processing, the displacement is obtained by calculating the phase difference between the reference and detection signals executed by a radio-frequency lock-in amplifier. The ranging system turns the optical heterodyne into an electronic demodulation, and the repetition error is less than 3%. The system takes advantage of the signal processing technologies of radar, and meanwhile maintains the advantages of laser detection. [ABSTRACT FROM AUTHOR]

Published

2008

2. Lidar-radar for underwater target detection using a modulated sub-nanosecond Q-switched laser.

Author

Li, Guangying, Zhou, Qiang, Xu, Guoquan, Wang, Xing, Han, Wenjie, Wang, Jiang, Zhang, Guodong, Zhang, Yifan, Yuan, Zhi'an, Song, Sijia, Gu, Shangtai, Chen, Fubin, Xu, Ke, Tian, Jinshou, Wan, Jianwei, Xie, Xiaoping, and Cheng, Guanghua

Subjects

*THREE-dimensional imaging, *POWER amplifiers, *LASER pulses, *HYBRID systems, *Q-switched lasers, *LASERS

Abstract

• The cooperation of the streak tube imaging and modulated laser source for underwater target detection experiments is the first attempt in this field. • The clear 3-D and 4-D images of the target underwater across 20 m are obtained with the spatial resolution of 9 mm. • The signal-to-clutter ratio (SCR) of echo signal can be vastly enhanced using the hybrid lidar-radar system Here we report on a modulated sub-nanosecond lidar-radar for underwater target detection. The modulated laser source is consisted of a 1064 nm master oscillator power amplifier (MOPA) and a frequency-doubling module, outputting pulse energy of 178.1 mJ at 1064 nm with 0.76 ns pulse duration and 87.6 mJ at 532 nm. By using a Fabry–Pérot cavity containing a KTP crystal and two reflectors, the 532 nm laser pulse is modulated into the burst mode with a repetition rate of 500 MHz. A streak tube camera is used as the signal receiving apparatus. An underwater target detection experiment has been carried out. The results indicate that this lidar-radar could emit a stable and powerful modulated signal, which greatly increases the underwater detection range. The cooperation of the streak tube imaging and modulated laser source for underwater target detection experiments is the first attempt in this field. The clear 3-D and 4-D images of the target underwater across 20 m are obtained in the experiments and the spatial resolution of 9 mm can be achieved. [ABSTRACT FROM AUTHOR]

Published

2021

3. Frequency synchronization in dual-polarization solid-state lasers : study of passive mode locking and frequency-shifted feedback

Author

Thévenin, Jérémie, Institut de Physique de Rennes (IPR), Université de Rennes (UR)-Centre National de la Recherche Scientifique (CNRS), Université Rennes 1, Marc Brunel, Marc Vallet(marc.brunel@univ-rennes1.fr), Université de Rennes 1 (UR1), Université de Rennes (UNIV-RENNES)-Université de Rennes (UNIV-RENNES)-Centre National de la Recherche Scientifique (CNRS), and Thévenin, Jérémie

Subjects

[SPI.OPTI] Engineering Sciences [physics]/Optics / Photonic, passive mode-locking, synchronisation, lasers bi-fréquence, rétro-injection optique, lidar-radar, verrouillage de mode passif, coupled oscillators, dual-frequency lasers, oscillateurs couplés, class B lasers, laser classe B, couplage phase-intensité, [SPI.OPTI]Engineering Sciences [physics]/Optics / Photonic, synchronization, optical feedback, phase-intensity coupling

Abstract

We explore synchronization dynamics of dual-polarization solid-state lasers. Such lasers are able to produce a stable beat frequency in a wide range from Hz up to THz. This work take advantage of it in order to study several frequency locking mecanisms in these lasers. First, we build a dual-polarization laser with a semiconductor saturable absorber miror (SESAM). It enable a pulsed operation of the laser where all longitudinal modes are phase-locked, and this on both laser eigenstates. We also demonstrate that polarization state of successive pulses forms sequences that we describes here. A particular phenomenon is observed in this laser: when the beat-frequency is chosen equal to half the free spectral range of the laser, then the two frequency combs associated with the two laser eigenstates synchronize themself. Second, we submit a two-frequency laser to a frequency-shifted feedback. Doing so, we are able to transfer the radiofrequency synthetizer stability on the laser beat-frequency. This result is obtained both in cw and Q-switched regimes. Finally, together with the frequency-shifted feedback, we use the relaxation oscillations of a class B laser to induce a regime where the laser beat-frequency is synchronized with the external reference, while their relative phase oscillates. Subsequently, particular intensity dynamics are observed at the output., Nous explorons les dynamiques de synchronisation des lasers solides fonctionnant sur deux états propres de polarisation. Ce type de laser présente l'intérêt de pouvoir générer des fréquences de battement très stables dans une gamme de fréquence du Hz au THz. Cette thèse en tire parti pour étudier plusieurs mécanismes d'accrochage de fréquence dans ces lasers. Tout d'abord, nous construisons un laser bipolarisation doté d'un miroir à réflectance saturable (SESAM). Cela lui permet de fonctionner dans un régime pulsé où tous les modes longitudinaux oscillent en phase, et ce sur les deux états propres du laser. On démontre également que les états de polarisation d'impulsions successives forment des séquences dont nous détaillons les caractéristiques. Un phénomène particulier est observé dans ce laser : si la fréquence de battement est choisie égale à la moitié de l'intervalle spectral libre du laser, les deux peignes de fréquences associés aux deux états propres se synchronisent. Dans un second temps, nous soumettons un laser bi-fréquence à une réinjection optique décalée en fréquence. De cette manière, nous sommes capable de transférer, sur la fréquence de battement du laser, la stabilité d'un synthétiseur radio-fréquence, utilisé comme référence. Ce résultat est obtenu tant en régime continu que pulsé. Enfin, conjointement à la réinjection décalée en fréquence, nous utilisons les oscillations de relaxation d'un laser de classe B pour induire un régime où la fréquence de battement est synchronisée sur une référence externe, mais pas sa phase. Incidemment, des dynamiques particulières d'intensités sont observées en sortie du laser.

Published

2012