Frequency Stabilization of Pulsed Injection-Seeded OPO Based on Optical Heterodyne Technique

A frequency stabilizing system for a pulsed injection seeded 1550 nm optical parametric oscillator(OPO) at 20 Hz repetition rate is demonstrated.The optical heterodyne method is used to measure the frequency difference between the seed laser and the OPO output.Using the frequency difference as the error signal,a proportionalintegral controller in combination with a scanner is applied to stably match the OPO cavity length to the seed laser frequency.The root-mean-square(rms) error of the frequency discrimination method is 0.07 MHz according to a ‘frequency shifting-chopping-beat' evaluation.The frequency fluctuation of the frequency-stabilized OPO is0.29 MHz(rms),and the Allan deviation is less than 20 k Hz for averaging time of more than 3 s.     

Highly efficient single longitudinal mode-pulsed green laser

A novel design for a highly efficient 1-kHz single-frequency green laser is proposed.An efficient singlefrequency laser pulse output at 532-nm wavelength may be obtained by combining the injection seeding with intracavity frequency doubling in a compact U-shaped cavity formed by two plano dichroic mirrors in an end-pumping arrangement.The laser is capable of producing green pulses with a total energy of 6.3 mJ at a pulse repetition rate of 1 kHz.The pulse width is about 10 ns and the optical-optical efficiency from the 808-nm pump source to the 532-nm green output is around 12.7%.     

Single-frequency high-energy Yb-doped pulsed all-fiber laser

A single-frequency pulsed all-fiber laser with a master oscillator power amplifier configuration is presented. While maintaining the properties of single mode, linear polarization, and narrow linewidth, a single-pulse energy of 260 μJ and over 500-W peak power is experimentally demonstrated at 1 kHz by employing tensile strain gradient and pulse-shape control methods. In addition, approximately 55 dB of optical signal to noise ratio is also achieved.     

High-energy nanosecond all-fiber Yb-doped amplifier

We demonstrate a high-energy,low-repetition-rate,all-fiber,1 064-nm Yb-doped fiber laser based on the master oscillator power amplifier structure.Pulse-pumping technology is used to suppress amplified spontaneous emission.A maximum output pulse energy of 5.97 mJ is obtained at 16-ns pulses with an M2of 2.9.     

Analysis of detection error for spot position in fiber nutation model

The influences of nutation trail accuracy,simplification of coupling model,spot position jitter,and power variation of incident light on the detection error are analyzed theoretically.Under the condition of satisfying the requirements,the nutation radius is less than 1.13μm,the accuracy of the nutation trail is less than 0.04μm,and the detection range is[?5μm,+5μm].The nutation frequency is 160 times spot position jitter frequency and 100 times intensity jitter frequency of incident light.The analysis is of great significance for determining nutation radius and frequency in the tracking system based on fiber nutation.     

Conductively cooled 1-kHz single-frequency Nd:YAG laser for remote sensing

A conductively cooled,laser diode(LD) end-pumped,injection-seeded single-frequency Nd:YAG laser is designed and implemented.The laser is capable of producing an 8-mJ Q-switched pulse with a 11-ns pulse width at 1 064 nm and at a pulse repetition rate of 1 000 Hz.At the maximum output energy of 8 mJ,the frequency jitter is less than 3.5 MHz(root mean square(RMS)) over two minutes,and the linewidth is around 54.2 MHz.The M2 of the laser beam is approximately 1.30 in both horizontal and vertical directions.The optimized ramp-fire technique is applied to build reliable single longitudinal mode oscillating.