A radiation system for controlling bursts of pulses of radiation comprises: an optical element; a controller; an actuator; and a sensor. The optical element is configured to interact with the pulses of radiation to control a characteristic of the pulses of radiation, the characteristic of the pulses of radiation being dependent on a configuration of the optical element. The controller is operable to generate a control signal. The actuator is configured to receive the control signal from the controller and to control a configuration of the optical element in dependence on the control signal. The sensor is operable to determine the characteristic of pulses having interacted with the optical element. The control signal for a given pulse in a given burst is dependent on the determined characteristic of a corresponding pulse from a previous burst.

The present invention provides a fiber laser system, comprising: a master laser cavity for generating a master laser beam; a beam splitter for splitting the master laser beam into a first beam for generating a first color pulsed laser beam and a second beam for generating a second color pulsed laser beam; and a synchronization component configured to synchronize the first color pulsed laser beam and a second color pulsed laser beam based on coherent wavelength generation.

A transmission type adaptive optical system that can be applied to a high power laser beam beyond a limit of deformable mirrors and corrects wavefront turbulence of a laser beam with adaptation to the wavefront turbulence is provided. By using a transmission type adaptive optical element of which a refractive index distribution changes based on temperature distribution thereof, a wavefront turbulence of a laser beam is corrected with adaptation to this wavefront turbulence. The wavefront turbulence is detected by a wavefront sensor and heating light in accordance with the detected wavefront turbulence is emitted to irradiate the transmission type adaptive optical element. The transmission type adaptive optical element transmits a laser beam as a target to correct a wavefront turbulence thereof and generates temperature distribution by the heating light and as a result generates the refractive index distribution.

Methods and devices are described for performing an all-phase measurement of an ultra-fast laser pulse having a spectral range of greater than one octave. The ultra-fast laser pulse may be split into a first beam comprising a fundamental light with a wavelength λ.sub.0 and a second beam comprising a light with a wavelength 2λ.sub.0. The light with the wavelength 2λ.sub.0 may be frequency doubled to a light with a wavelength λ.sub.0 to generate an interference with the fundamental light. Fourier transform may be performed on an interference spectrum of the interference, and a relative envelope delay (RED) between the fundamental light and the frequency doubled light and a carrier envelope phase (CEP) may be acquired based on a result of the Fourier transform.

Disclosed are a control method and an optical fiber amplifier. The optical fiber amplifier is configured to execute the control method. The method comprises: initially correcting a target gain on the basis of a first compensation gain to obtain an initially corrected target gain; when the actual power of the pump laser reaches target power determined on the basis of the initially corrected target gain obtaining, on the basis of a first signal optical power and a second signal optical power, a second compensation gain and a first compensation slope through calculation; correcting the initially corrected target gain again according to the second compensation gain to obtain a corrected target gain; and correcting a target slope according to the first compensation slope to obtain a corrected target slope. This solution can provide high precision control for the gain and the slope of the optical fiber amplifier.

Light amplification devices using coupled multi-core optical fibers have a figure of merit that temporally varies, which makes it difficult to perform performance evaluation and to build a light transmission system using the same. Accordingly, a light amplification device of the present invention comprises: a band control means that controls the wavelength band of a light carrier to generate a band control light; and a band control light amplification means that has a plurality of light amplification media through which the band control light propagates, wherein the band control light amplification means amplifies the band control light in a coupled state in which the light propagating through the plurality of light amplification media induces a crosstalk and wherein the band control means controls the wavelength band such that the band control light having propagated through the plurality of light amplification media has a reduced coherence.

A system having a perception of its general environment is described. The general environment may include its surroundings, circuits, power supply, optics, emitters, software processing, and other things that may affect its perception system or sensors and biases associated with data processing. With this information, it may be able to adapt to the general environment with little human intervention. Dynamic updating and calibration of the environment or sensors in the environment may be provided. From one time frame to another, location or other information can be more efficiently rendered or decoded. Knowing the spacing of receivers may allow time delay calculations. Real world environmental changes may impact the relative location and or properties of these sensors. Observation or communication of these changes can be used to predict assembly and processing or projection of energies for a desired effect.

A system having a perception of its general environment is described. The general environment may include its surroundings, circuits, power supply, optics, emitters, software processing, and other things that may affect its perception system or sensors and biases associated with data processing. With this information, it may be able to adapt to the general environment with little human intervention. Dynamic updating and calibration of the environment or sensors in the environment may be provided. From one time frame to another, location or other information can be more efficiently rendered or decoded. Knowing the spacing of receivers may allow time delay calculations. Real world environmental changes may impact the relative location and or properties of these sensors. Observation or communication of these changes can be used to predict assembly and processing or projection of energies for a desired effect.

An apparatus for combining a plurality of coherent laser beams includes a splitting device for splitting an input laser beam into the plurality of coherent laser beams, a plurality of phase setting devices for adjusting a respective phase of one of the coherent laser beams, and a beam combining device for combining the coherent laser beams, which emanate from a plurality of grid positions of a grid arrangement, to form at least one combined laser beam. The beam combining device has a microlens arrangement with exactly one microlens array for forming the at least one combined laser beam.

A medical laser system for outputting laser pulses includes at least one laser cavity configured to generate at least one laser pulse, a rotating mirror configured to receive and reflect the at least one laser pulse, a beam splitter configured to receive and reflect a portion of the at least one laser pulse received from the rotating mirror, an energy-sensing device configured to detect the portion of the at least one laser pulse, an energy measurement assembly configured to generate a measurement signal based on the portion of the at least one laser pulse detected by the energy-sensing device, and a controller. The controller may include a calibration module. The calibration module may be configured to generate at least one categorized calibration table, determine calibration parameters, interpolate the calibration parameters, and cause the at least one laser cavity to generate at least one calibrated laser pulse.