CN102353343B - Synchronous detecting system and method for planet-surface geometrical-characteristic and substance component thereof - Google Patents

Abstract

The invention discloses a synchronous detecting system and method for planet-surface geometrical-characteristics and substance components thereof. A main analyzing and control system is adopted to send out control signals to start a control-signal distributor, and the control signals are respectively transmitted to an X-axis stepping motor, a Y-axis stepping motor and a laser-pulse controller by the control-signal distributor to start different characteristic points of an infrared-pulse laser device focused to a planet-surface scanning area. A 1064nm laser-reflecting signal in an echoed signal is received by a PIN (Personal Identification Number) photoelectric detector to obtain a focus-point distance, an enhanced-type imaging device ICCD is controlled for exposure after a certain time delay to obtain a plasma spectral image after the light splitting of a spectrometer, and the substance components of planet-surface focus points are analyzed according to different spectral-line distribution. After the scanning for all the points at the planet-surface scanning area is finished, the three-dimensional surface topography of the area is reconstructed, and meanwhile, the substance components of each characteristic point on the surface are calibrated.

Description

The synchronous test system of celestial body surface geometry feature and Matter Composition thereof and method

Technical field

This patent relates to the measuring technology of geometric properties and Matter Composition thereof, specifically refer to a kind of laser test system and method for obtaining simultaneously celestial body three-dimensional surface shape and Matter Composition, it is used for the Synchronization Analysis of survey of deep space China and foreign countries celestial body surface target area geometric properties and material chemical analysis.

Background technology

In survey of deep space, externally celestial body surface topography and Matter Composition analysis are important tasks.Traditional test is surface topography test and the different system of material chemical analysis analysis employing often, separately carry out, its shortcoming is can't geometric properties point is corresponding one by one with its Matter Composition, and because having adopted two cover systems to increase the load of star landing device, increased the cost of survey of deep space.Therefore how geometric properties point surface topography and the detection of its Matter Composition are combined, design new detection system and method, reduce lander load and have great importance.

This patent is for some problems that exist in celestial body surface topography and the Matter Composition analytic system, synchronous test system and the method for a kind of celestial body surface geometry feature and Matter Composition thereof are proposed, this system and method can be in same set of system, celestial body surface target area geometric properties point surface topography and Matter Composition thereof are detected simultaneously, can reduce the load of lander, improve the economy of survey of deep space.

Summary of the invention

The purpose of this patent provides in a kind of survey of deep space, the synchronous test system of celestial body surface geometry feature and Matter Composition thereof and method.The method adopts main analysis and control system to send control signal to start the control signal divider, by the control signal divider control signal is sent to respectively the X-axis Step motor, Y-axis Step motor and laser pulse controller focus to the different characteristic point in celestial body surface scan zone to start the pulsed infrared laser device.1064nm laser reflection signal in the echoed signal is received by the PIN photodetector, obtain focus point distance and after certain time-delay, control enhancement mode image device ICCD exposes, obtain the plasma spectrometry image after the spectrometer light splitting, according to different spectral profile, analyze the Matter Composition of this celestial body surface focus point.After finishing the scanning of having a few in celestial body surface scan zone, the 3 d surface topography that reconstructs the zone also calibrates the Matter Composition of each unique point of surface simultaneously.

The technical scheme of this patent is achieved like this, when arriving from top, target area, celestial body surface certain altitude, the star landing device hovers, send first aim provincial characteristics point X and Y-axis rotational angle value signal by main analysis and control system, the rotation of driven rotary Use of The Polygonal Mirror Scanner mirror is to the precalculated position and start the 1064nm pulsed laser.Pulse laser is divided into two-way: the one tunnel starts counter after directly being received by the laser sampling receiver by main beam splitter immediately begins counting; After another road is reflected by main beam splitter, after focusing on, the line focus optical system gets to celestial body surface focus point.After celestial body surface focus point was hit by pulse laser, the laser reflection signal of existing 1064nm comprised again the plasma resonance spectral signal that laser pulse is induced generation in the echoed signal.Echoed signal is reverse by be divided into the two-way of equivalent optical path behind the Focused Optical system by time beam splitter: the one tunnel directly passes through beam splitter, enter to inject optical fiber through fiber coupler, by the diffraction grating in the spectrometer plasma light spectrum signal that induced with laser produces is carried out light splitting; One the road is passed through the 1064nm narrow band pass filter after the beam splitter reflection, 1064nm laser reflection signal in the echoed signal is received by the PIN photodetector, after amplifier amplifies, control counter stops counting and starts simultaneously digital delay pulse producer DG535, after certain time-delay, control enhancement mode image device ICCD exposes, and obtains the plasma spectrometry image after the spectrometer light splitting.The laser induced plasma signal calculation circuit is analyzed the Matter Composition of this celestial body surface focus point according to different spectral profile; The laser radar computing circuit can calculate this focus point from the distance of PIN photodetector according to numeral and the light velocity in the vacuum of counter simultaneously, and obtain target area planimetric coordinates corresponding to this focus point by coordinate transform, with reconstructed object area three-dimensional surface topography; After laser induced plasma signal calculation circuit and the computing of laser radar computing circuit finish, the result is delivered to main analysis and control system, comprehensively both information can draw this focus point geometric properties and Matter Composition information synchronously.Then send next target area unique point control signal by main analysis and control system, the rotation of driven rotary Use of The Polygonal Mirror Scanner mirror is to next precalculated position; Repeat above signals collecting and analytic process, can get geometric properties and the Matter Composition information of next target area unique point.After finishing the scanning of whole target area, the 3 d surface topography that can reconstruct the zone also calibrates the Matter Composition of surperficial each point simultaneously.

Description of drawings

Fig. 1 is the schematic diagram of this patent, among the figure: 1---and the celestial body surface; 2---surperficial focus point; 3---total reflective mirror; 4---rotating multisurface swept-volume mirror; 5X axle Step motor; 6---telescopic system; 7---the 1064nm pulsed laser; 8---beam expanding lens; 9---convex lens; 10---main beam splitter; 11---inferior beam splitter; 12---fiber coupler; 13---optical fiber; 14---the 1064nm narrow band pass filter; 15---the PIN photodetector; 16---the laser sampling receiver; 17---amplifier; 18---counter; 19---digital delay pulse producer DG535; 20---the laser radar computing circuit; 21---spectrometer; 22---enhancement mode image device ICCD; 23---the laser induced plasma signal calculation circuit; 24---main analysis and control system; 25---the control signal divider; 26---laser pulse controller; 27---the Y-axis Step motor.

Embodiment

The principle of this patent as shown in Figure 1, when arriving from top, 1 target area, celestial body surface certain altitude, the star landing device hovers, send first aim provincial characteristics point X and Y-axis rotational angle value signal to control signal divider 25 by main analysis and control system 24, by control signal divider 25 control signal is sent to respectively X-axis Step motor 5, Y-axis Step motor 27 and laser pulse controller 26.X-axis Step motor 5 and Y-axis Step motor 27 are according to the control signal that receives, and 4 rotations of driven rotary Use of The Polygonal Mirror Scanner mirror are to the precalculated position; After laser pulse controller 26 receives control signal, start 1064nm pulsed laser 7.Pulse laser is divided into two-way to the main beam splitter 10 through beam expanding lens 8, convex lens 9: the one tunnel starts counter 18 after directly being received by laser sampling receiver 16 by main beam splitter 10 immediately begins counting; Celestial body surface focus point 2 is got to after being reflected by main beam splitter 10 in another road after the Focused Optical system that telescopic system 6, total reflective mirror 3, rotating multisurface swept-volume mirror 4 form focuses on.After celestial body surface focus point 2 was hit by pulse laser, the laser reflection signal of existing 1064nm comprised again the plasma resonance spectral signal that laser pulse is induced generation in the echoed signal.Echoed signal is reverse by be divided into the two-way of equivalent optical path behind the Focused Optical system by time beam splitter 11: the one tunnel directly by beam splitter 11, enter to inject optical fiber 13 through fiber coupler 12, by the diffraction grating in the spectrometer 21 the plasma light spectrum signal that induced with laser produces is carried out light splitting; One the road is passed through 1064nm narrow band pass filter 14 after beam splitter 11 reflections, 1064nm laser reflection signal in the echoed signal is received by PIN photodetector 15, after amplifier 17 amplifies, control counter 18 stops counting and starts simultaneously digital delay pulse producer DG53519, after certain time-delay, control enhancement mode image device ICCD 22 exposes, and obtains the plasma spectrometry image after spectrometer 21 light splitting.Laser induced plasma signal calculation circuit 23 is analyzed the Matter Composition of this celestial body surface focus point according to different spectral profile; Laser radar computing circuit 20 can calculate this focus point from the distance of PIN photodetector 15 according to numeral and the light velocity in the vacuum of counter 18 simultaneously, and obtain target area planimetric coordinates corresponding to this focus point by coordinate transform, with reconstructed object area three-dimensional surface topography; After laser induced plasma signal calculation circuit 23 and 20 computings of laser radar computing circuit finish, the result is delivered to main analysis and control system 24, comprehensively both information can draw this focus point geometric properties and Matter Composition information synchronously.Then send next target area unique point X and Y-axis rotational angle value signal to control signal divider 25 by main analysis and control system 24, by control signal divider 25 control signal is sent to respectively X-axis Step motor 5, Y-axis Step motor 27 and laser pulse controller 26.X-axis Step motor 5 and Y-axis Step motor 27 are according to the control signal that receives, and 4 rotations of driven rotary Use of The Polygonal Mirror Scanner mirror are to next precalculated position; Repeat above signals collecting and analytic process, can get geometric properties and the Matter Composition information of next target area unique point.After finishing the scanning of whole target area, the 3 d surface topography that can reconstruct the zone also calibrates the Matter Composition of surperficial each point simultaneously.

Claims (2)

1. the synchronous test system of a celestial body surface geometry feature and Matter Composition thereof, it comprises: total reflective mirror (3), rotating multisurface swept-volume mirror (4), X-axis Step motor (5), Y-axis Step motor (27), telescopic system (6), 1064nm pulsed laser (7), beam expanding lens (8), convex lens (9), main beam splitter (10), inferior beam splitter (11), fiber coupler (12), optical fiber (13), 1064nm narrow band pass filter (14), PIN photodetector (15), laser sampling receiver (16), amplifier (17), counter (18), digital delay pulse producer DG535 (19), laser radar computing circuit (20), spectrometer (21), enhancement mode image device ICCD (22), laser induced plasma signal calculation circuit (23), main analysis and control system (24), control signal divider (25) and laser pulse controller (26) is characterized in that:

When arriving from top, (1) target area, celestial body surface certain altitude, the star landing device hovers, send first aim provincial characteristics point X and Y-axis rotational angle value signal to control signal divider (25) by main analysis and control system (24), by control signal divider (25) control signal is sent to respectively X-axis Step motor (5), Y-axis Step motor (27) and laser pulse controller (26); X-axis Step motor (5) and Y-axis Step motor (27) are according to the control signal that receives, and driven rotary Use of The Polygonal Mirror Scanner mirror (4) rotates to the precalculated position; After laser pulse controller (26) receives control signal, start 1064nm pulsed laser (7), pulse laser is divided into two-way to the main beam splitter (10) through beam expanding lens (8), convex lens (9): the one tunnel starts counter (18) after directly being received by laser sampling receiver (16) by main beam splitter (10) immediately begins to count; After another road is reflected by main beam splitter (10), after focusing on, gets to the Focused Optical system that telescopic system (6), total reflective mirror (3), rotating multisurface swept-volume mirror (4) form celestial body surface focus point (2); After celestial body surface focus point (2) is hit by pulse laser, the laser reflection signal of existing 1064nm comprises again the plasma resonance spectral signal that laser pulse is induced generation in the echoed signal, echoed signal is reverse by be divided into the two-way of equivalent optical path behind the Focused Optical system by time beam splitter (11): the one tunnel directly by time beam splitter (11), enter to inject optical fiber (13) through fiber coupler (12), by the diffraction grating in the spectrometer (21) the plasma light spectrum signal that induced with laser produces is carried out light splitting; One the tunnel is passed through 1064nm narrow band pass filter (14) after time beam splitter (11) reflection, 1064nm laser reflection signal in the echoed signal is received by PIN photodetector (15), after amplifier (17) amplifies, control counter (18) stops counting and starts simultaneously digital delay pulse producer DG535(19), after certain time-delay, control enhancement mode image device ICCD(22) exposes, obtain the plasma spectrometry image after spectrometer (21) light splitting; Laser induced plasma signal calculation circuit (23) is analyzed the Matter Composition of this celestial body surface focus point according to different spectral profile; Laser radar computing circuit (20) can calculate this focus point from the distance of PIN photodetector (15) according to numeral and the light velocity in the vacuum of counter (18) simultaneously, and obtain target area planimetric coordinates corresponding to this focus point by coordinate transform, with reconstructed object area three-dimensional surface topography; Laser induced plasma signal calculation circuit (23) and laser radar computing circuit (20) computing are delivered to main analysis and control system (24) with the result after finishing, and comprehensively both information can draw this focus point geometric properties and Matter Composition information synchronously; Then send next target area unique point X and Y-axis rotational angle value signal to control signal divider (25) by main analysis and control system (24), by control signal divider (25) control signal is sent to respectively X-axis Step motor (5), Y-axis Step motor (27) and laser pulse controller (26), X-axis Step motor (5) and Y-axis Step motor (27) are according to the control signal that receives, and driven rotary Use of The Polygonal Mirror Scanner mirror (4) rotation is to next precalculated position; Repeat above signals collecting and analytic process, can get geometric properties and the Matter Composition information of next target area unique point; After finishing the scanning of whole target area, the 3 d surface topography that can reconstruct the zone also calibrates the Matter Composition of surperficial each point simultaneously.

2. one kind based on the celestial body surface geometry feature of the described test macro of claim 1 and the synchronous detecting method of Matter Composition thereof, it is characterized in that may further comprise the steps:

1) echoed signal is divided into two-way, and wherein the 1064nm laser reflection signal is used to measure the distance of celestial body surface focus point; The laser-induced plasma spectral signal is received by spectrometer and enhancement mode image device ICCD, according to different spectral profile, analyzes the Matter Composition of this celestial body surface focus point;

2) main analysis and control system sends X and Y-axis rotary angle signal, and control X-axis Step motor, the rotation of Y-axis Step motor make pulse laser focusing to the different unique point of scanning area;

3) repeating step 1) obtain the make new advances Matter Composition of focus point of the distance of new focus point and analysis;

4) finish the scanning of having a few in celestial body surface scan zone after, reconstruct the 3 d surface topography in zone and calibrate simultaneously the Matter Composition of surperficial each point.