Embodiments of this application disclose a laser frequency modulation method and device, a storage medium, and a laser device. The method includes: obtaining the current sweep mode of the laser device in a timing manner; when the current sweep mode is the single-band sweep mode, controlling the laser device to perform continuous sweeping on the preset band; and when the current sweep mode is the multi-band switching mode, obtaining the next band for the laser device to perform sweeping, and controlling the laser device to switch from the band to the next band.

A laser apparatus includes a grating system; an actuator system configured to adjust a first incident angle on the grating system and a second incident angle on the grating system, the first incident angle being an angle of a first part of an optical beam incident on the grating system, the second incident angle being an angle of a second part of the optical beam incident on the grating system; and a processor configured to control the actuator system to periodically vary the first and second incident angles so that the first and second incident angles are different from each other in at least one of phase and variation range.

A laser apparatus includes a grating system; an actuator system configured to adjust a first incident angle on the grating system and a second incident angle on the grating system, the first incident angle being an angle of a first part of an optical beam incident on the grating system, the second incident angle being an angle of a second part of the optical beam incident on the grating system; and a processor configured to control the actuator system to periodically vary the first and second incident angles so that the first and second incident angles are different from each other in at least one of phase and variation range.

In a tunable transmission-grating laser, alignment of the lasing cavity mode with the grating filter spectrum of the laser can be achieved using the position of the intracavity beam relative to the gain medium as feedback. In various embodiments, the displacements of the intracavity beam from the gain medium are monitored indirectly, using an image of the intracavity beam created outside the cavity with an additional transmission grating. Various means for measuring the position of that monitoring beam and for adjusting the tunable components of the laser based thereon are described.

In a tunable transmission-grating laser, alignment of the lasing cavity mode with the grating filter spectrum of the laser can be achieved using the position of the intracavity beam relative to the gain medium as feedback. In various embodiments, the displacements of the intracavity beam from the gain medium are monitored indirectly, using an image of the intracavity beam created outside the cavity with an additional transmission grating. Various means for measuring the position of that monitoring beam and for adjusting the tunable components of the laser based thereon are described.

A fiber laser includes: a gain fiber; a first low-reflective mirror and a second high-reflective mirror disposed in an optical path of laser light that is emitted from a first end of the gain fiber; a second low-reflective mirror and a first high-reflective mirror disposed in an optical path of laser light that is emitted from a second end of the gain fiber; a first delivery fiber that accepts the laser light emitted from the first end; a second delivery fiber that accepts the laser light emitted from the second end; and an operation mode switching mechanism that switches between a first operation mode and a second operation mode. A first resonator is constituted by the first low-reflective mirror and the first high-reflective mirror. A second resonator, which is constituted by the second low-reflective mirror and the second high-reflective mirror.

A fiber laser includes: a gain fiber; a first low-reflective mirror and a second high-reflective mirror disposed in an optical path of laser light that is emitted from a first end of the gain fiber; a second low-reflective mirror and a first high-reflective mirror disposed in an optical path of laser light that is emitted from a second end of the gain fiber; a first delivery fiber that accepts the laser light emitted from the first end; a second delivery fiber that accepts the laser light emitted from the second end; and an operation mode switching mechanism that switches between a first operation mode and a second operation mode. A first resonator is constituted by the first low-reflective mirror and the first high-reflective mirror. A second resonator, which is constituted by the second low-reflective mirror and the second high-reflective mirror.

A frequency stabilizer includes: a delay line interferometer that receives an optical signal corresponding to one frequency mode of a pulsed laser, divides and transmits the received optical signal to a reference arm and a delay arm including an optical fiber delay line, and then outputs an interference signal between signals passing through the reference arm and the delay arm; a photoelectric converter that converts the interference signal into an electrical signal; a mixer that generates a baseband signal of the electrical signal by mixing a carrier frequency signal; and a feedback controller that transmits a control signal generated based on the baseband signal to the pulsed laser. The optical signal passing through the delay arm is weighted with a delay time caused by the optical fiber delay line compared to the optical signal passing through the reference arm, and the optical signal passing through the delay arm is frequency shifted to a carrier frequency of an oscillator. A carrier-envelope offset frequency of the pulsed laser is stabilized by an offset frequency stabilizer.

A wavelength sensor for wavelength stabilization of a laser beam includes an etalon placed in the laser beam and tilted with respect to the laser beam. Reflected beams from the etalon form an interference pattern on a segmented photodetector having two detector segments. Output signals from the two detector segments are used to derive an error signal for a closed control loop to effect the wavelength stabilization.

The present application provides a radiation output device and a method. The radiation output device includes a radiation generating module configured to generate initial radiation; a filter module configured to reflect a portion of a first preset wavelength of the initial radiation to the radiation generating module and transmit a portion of a second preset wavelength of the initial radiation, the transmitted radiation is therefore used as an output radiation of the radiation output device; a detection feedback module, using a portion of or all of the output radiation as a feedback radiation, configured to instruct a modulating module to modulate the filter module according to the feedback radiation. The modulating module is connected to the filter module and configured to modulate a position and/or an angle of the filter module according to the instruction of the detection feedback module.