Experimental system for laser beam measurement and steering control

What is claimed is: 1. An experimental system for laser beam measurement and steering control, characterized by comprising a high-precision optical mirror ( 1 ), a piezoelectric ceramic micro-actuator ( 2 ), a vibration exciter ( 3 ), a signal collection subsystem ( 4 ), a laser emitter ( 5 ), a beam splitter mirror ( 6 ), a fast steering mirror ( 7 ), a mechanical vibration isolation air bearing table ( 8 ), an optical vibration isolation air bearing table ( 9 ), a data processing and analyzing subsystem ( 10 ), and data transmission lines and power supply lines between subsystems and components, wherein the experimental system for laser beam measurement and steering control simulates different working environments of the high-precision optical mirror ( 1 ), precisely measure a laser beam deviation angle, and control a laser beam steering; the high-precision optical mirror ( 1 ) is composed of a first optical reflector ( 1 - 1 ) and a reflector holder platform ( 1 - 2 ); the reflector holder platform ( 1 - 2 ) is composed of a reflector holder plate ( 1 - 201 ), a reflector holder ( 1 - 202 ), a reflector holder monoblock casting ( 1 - 203 ), and a pair of passive screw thread pairs, which are all made of stainless steel; the first optical reflector ( 1 - 1 ) is installed on the reflector holder plate ( 1 - 201 ), the reflector holder plate ( 1 - 201 ) is embedded in the reflector holder ( 1 - 202 ), and the reflector holder ( 1 - 202 ) is connected to the reflector holder monoblock casting ( 1 - 203 ) via the passive screw thread pairs; the piezoelectric ceramic micro-actuator ( 2 ) is connected to the reflector holder ( 1 - 202 ) and the reflector holder monoblock casting ( 1 - 203 ), stretches and retracts under drive of a piezoelectric ceramic micro-actuator control signal, changes a posture of the reflector holder ( 1 - 202 ), and further controls a space posture of the first optical reflector ( 1 - 1 ) and changes a steering of a laser beam reflected via the first optical reflector ( 1 - 1 ); the signal collection subsystem ( 4 ) is composed of a first acceleration sensor ( 4 - 101 ), a second acceleration sensor ( 4 - 102 ), a third acceleration sensor ( 4 - 103 ), a first angle measurement photosensitive sensor ( 4 - 201 ), a second angle measurement photosensitive sensor ( 4 - 202 ), and a target photosensitive sensor ( 4 - 203 ); the beam splitter mirror ( 6 ) is composed of a first beam splitter mirror ( 6 - 1 ) and a second beam splitter mirror ( 6 - 2 ); the fast steering mirror ( 7 ) is composed of a structural frame ( 7 - 1 ), a second optical reflector ( 7 - 2 ), and four voice coil actuators ( 7 - 3 , 7 - 4 , 7 - 5 , 7 - 6 ); the four voice coil actuators ( 7 - 3 , 7 - 4 , 7 - 5 , 7 - 6 ) are symmetrically distributed on four corners of the rear part of the second optical reflector ( 7 - 2 ) and are fixed on the structural frame ( 7 - 1 ), stretch and retract forward and backward under drive of a fast steering mirror control signal, drive the second optical reflector ( 7 - 2 ) to incline in horizontal and vertical directions, control an inclined posture angle of the second optical reflector ( 7 - 2 ), and change a steering of a laser beam reflected via the fast steering mirror ( 7 ); the mechanical vibration isolation air bearing table ( 8 ) is installed on a laboratory foundation and isolates vibration transferred by the foundation and provides stable installation platforms for the high-precision optical mirror ( 1 ), the first acceleration sensor ( 4 - 101 ), the second acceleration sensor ( 4 - 102 ), the third acceleration sensor ( 4 - 103 ), and the vibration exciter ( 3 ), and the mechanical vibration isolation air bearing table vibrates under an excitation of the vibration exciter ( 3 ) simulating a working environment of the high-precision optical mirror ( 1 ); the optical vibration isolation air bearing table ( 9 ) is installed on the laboratory foundation, thereby isolating vibration transferred by the foundation and providing stable installation environments for the laser emitter ( 5 ), the first beam splitter mirror ( 6 - 1 ), the second beam splitter mirror ( 6 - 2 ), the first angle measurement photosensitive sensor ( 4 - 201 ), the second angle measurement photosensitive sensor ( 4 - 202 ), the target photosensitive sensor ( 4 - 203 ), and the fast steering mirror ( 7 ); and the data processing and analyzing subsystem ( 10 ) is composed of a dSPACE ( 10 - 1 ), a PC machine ( 10 - 2 ), and experimental system control software. 2. The experimental system for laser beam measurement and steering control according to claim 1 , characterized in that the high-precision optical mirror ( 1 ) is installed on the mechanical vibration isolation air bearing table ( 8 ) and reflects a laser emitted by the laser emitter ( 5 ); the vibration exciter ( 3 ) is installed on the mechanical vibration isolation air bearing table ( 8 ), simulates, according to a working condition of the experimental system control software, an instruction signal to excite the mechanical vibration isolation air bearing table ( 8 ) to vibrate, and simulates a working environment of the high-precision optical mirror ( 1 ). 3. The experimental system for laser beam measurement and steering control according to claim 1 , characterized in that the first beam splitter mirror ( 6 - 1 ) and the second beam splitter mirror ( 6 - 2 ) are installed on the optical vibration isolation air bearing table ( 9 ) in parallel, wherein the first beam splitter mirror ( 6 - 1 ) performs beam splitting on a laser emitted by high-precision optical mirror ( 1 ); one beam is incident on the first angle measurement photosensitive sensor ( 4 - 201 ) after being reflected, and the other beam continues being incident on the second beam splitter mirror ( 6 - 2 ) along an original optical path propagation direction; the second beam splitter mirror ( 6 - 2 ) performs beam splitting on a laser transmitted via the first beam splitter mirror ( 6 - 1 ), one beam is incident on the second angle measurement photosensitive sensor ( 4 - 202 ) after being reflected, and the other beam continues being incident on the fast steering mirror ( 7 ) along an original optical path propagation direction. 4. The experimental system for laser beam measurement and steering control according to claim 3 , characterized in that the fast steering mirror ( 7 ) is installed on the optical vibration isolation air bearing table ( 9 ); the voice coil actuators ( 7 - 3 , 7 - 4 , 7 - 5 , 7 - 6 ) are driven by the fast steering mirror control signal sent by the experimental system control software, changes an inclined posture angle of the second optical reflector ( 7 - 2 ), and the laser beam is finally projected on the target photosensitive sensor ( 4 - 203 ) via reflection of the fast steering mirror ( 7 ), thereby achieving direct control of the steering of the laser beam. 5. The experimental system for laser beam measurement and steering control according to claim 4 , characterized in that the first angle measurement photosensitive sensor ( 4 - 201 ) and the second angle measurement photosensitive sensor ( 4 - 202 ) of the signal collection subsystem ( 4 ) are installed on the optical vibration isolation air bearing table ( 9 ), respectively collect coordinate information of light spots of laser beams on which beam splitting and reflection are performed via the first beam splitter mirror ( 6 - 1 ) and the second beam splitter mirror ( 6 - 2 ) on the first angle measurement photosensitive sensor ( 4 - 201 ) and the second angle measurement photosensitive sensor ( 4 - 202 ), respectively, in horizontal and vertical directions, and the information is input into the data processing and analyzing subsystem. 6. The experimental system for laser beam measurement and steering control