CN100573080C - Utilize light-splitting device to realize the Hartmann wave front sensor and the detection method thereof of alignment function - Google Patents

Abstract

Utilize light-splitting device to realize the Hartmann wave front sensor and the detection method thereof of alignment function, coarse alignment and fine alignment two item parts in original system, have been added, wherein coarse alignment partly comprises: imaging screen with holes, light-splitting device, coarse alignment detection system, part of accurate alignment comprises: condenser lens, fine alignment spectroscope, fine alignment detection system.Incident beam can enter in the measurement visual field of microlens array efficiently and easily through after coarse alignment and two steps of fine alignment, and can with the strict same optical axis of system, thereby improved the measuring accuracy of Hartmann system; Utilize this Hartmann wave front sensor can carry out positive lens easily, negative lens, convex lens, concave mirror, the detection of level crossing etc. simultaneously.The present invention can show the result who adjusts in real time, has directly perceived, understandable characteristic, thereby has reduced the requirement to the user of service, has reduced the adjusting time; And device specification requirement used in should inventing is low, cheap, buys easily.

Description

Utilize light-splitting device to realize the Hartmann wave front sensor and the detection method thereof of alignment function

Technical field

The present invention relates to a kind of exact instrument-Hartmann wave front sensor that is used to measure wavefront shape, particularly a kind of autocollimation light beam or tested light beam can regulated simply, fast, accurately enters the Hartmann wave front sensor of measuring the visual field.

Background technology

Hartmann wave front sensor is a kind of instrument that can detect the corrugated shape, and it has obtained using widely in optical mirror plane detection, Medical Instruments and celestial body target imaging.In Hartmann wave front sensor in the past, include only measurement light source system, Beam matching system, microlens array, photodetector (being generally CCD) and data handling system usually.Hartmann wave front sensor is before using, and tested corrugated all must be adjusted in the measurement visual field of microlens array; All be to regulate by the facula position of observing in the sub-aperture in the past.With respect to input path, the measurement visual field of microlens array seems very little usually, and testee changes very little angle, and big skew will take place the hot spot in the sub-aperture, so be difficult to the incident corrugated is transferred in the measurement visual field of microlens array.Thereby in the process of using Hartmann wave front sensor, too much energy flower is being aimed at; And easily cause tested light beam and systematic optical axis to depart from, thereby cause the measuring error on corrugated to become big.

Summary of the invention

Technology of the present invention is dealt with problems and is: overcome the deficiencies in the prior art, a kind of Hartmann wave front sensor and detection method thereof of utilizing light-splitting device to realize alignment function is provided, this Hartmann's wavefront sensing utilizes coarse alignment and part of accurate alignment can make things convenient for, aim at accurately the optical axis of measured piece and system, thereby reduce measuring error, improved the measuring accuracy of Hartmann system; Utilize the detection method of this Hartmann wave front sensor to carry out positive lens easily simultaneously, negative lens, convex lens, concave mirror, the detection of level crossing etc., it is little to detect error.

Technical solution of the present invention: utilize light-splitting device to realize the Hartmann wave front sensor of alignment function, comprise: the measurement light source system, the preceding mirror group of Beam matching system, the back mirror group of Beam matching system, spectroscope, microlens array, photodetector, its characteristics are also to comprise: coarse alignment part and part of accurate alignment, coarse alignment partly comprises: imaging screen with holes, light-splitting device, the coarse alignment detection system, light-splitting device is positioned in one times of focal length of preceding mirror group of Beam matching system, play the separating incident light bundle, imaging screen with holes is placed on the preceding mirror group focal plane of Beam matching system, the hole is positioned on the focus, the coarse alignment detection system can be observed whole imaging screen, the light that is sent by the measurement light source system during work is by the hole outgoing of imaging screen, through light-splitting device, the front lens group of Beam matching system is after return behind the testee, again focus on the imaging screen, by observing the aperture that obtains by the coarse alignment detection system and the relative position of focal beam spot, the position of regulating measured piece overlaps aperture and focal beam spot, through after the coarse alignment, guaranteed that light beam can enter in the scope of fine alignment; The fine alignment spectroscope, condenser lens and fine alignment detection system, the fine alignment spectroscope is positioned at before the condenser lens, condenser lens is positioned at before the fine alignment detection system, the light that the measurement light source system sends successively passes through the coarse alignment spectroscope, behind the spectroscope, preceding mirror group outgoing by the Beam matching system, behind measured piece, return, priority is through the preceding mirror group of Beam matching system, the back mirror group of Beam matching system, spectroscope, behind the fine alignment spectroscope, the line focus lens imaging is on the fine alignment detection system again, obtain the position of focal beam spot by the centroid calculation formula, the position that it is systematic optical axis that the adjusting measured piece makes facula mass center and prior calibration point overlaps, so far the fine alignment process is finished, through behind the fine alignment, light beam has entered in the measurement visual field of microlens array, and can directly measure.

The present invention's beneficial effect compared with prior art: the present invention can adjust the position of measured piece quickly, allows tested light beam or autocollimation light beam enter in the measurement visual field of microlens array; And the adjusting direction of measured piece all is to get by the relativeness between focal beam spot and the reference point relatively, has intuitively, simply, characteristic accurately, user of service's requirement is reduced; The present invention can also be easy the aligning measured piece and the optical axis of Hartmann system; Behind coarse alignment and fine alignment, avoided the situation of the hot spot generation overall offset in the sub-aperture, thereby improved measuring accuracy; Utilize detection method of the present invention to carry out positive lens easily simultaneously, negative lens, convex lens, concave mirror, the detection of level crossing etc., it is little to detect error; Low to the specification requirement of used element among the present invention, low price is bought easily.

Description of drawings

Fig. 1 is the structural representation of original Hartmann wave front sensor;

Fig. 2 realizes the structural representation of the Hartmann wave front sensor of alignment function for the present invention utilizes light-splitting device;

Work synoptic diagram when Fig. 3 carries out coarse alignment for the Hartmann wave front sensor that utilizes light-splitting device to realize alignment function of the present invention;

Work synoptic diagram when Fig. 4 carries out fine alignment for the Hartmann wave front sensor that utilizes light-splitting device to realize alignment function of the present invention;

Fig. 5 measures the fundamental diagram of positive lens face shape for the Hartmann wave front sensor that utilizes light-splitting device to realize alignment function of the present invention;

Fig. 6 measures the fundamental diagram of negative lens face shape for the Hartmann wave front sensor that utilizes light-splitting device to realize alignment function of the present invention;

Fig. 7 measures the fundamental diagram of convex surface minute surface shape for the Hartmann wave front sensor that utilizes light-splitting device to realize alignment function of the present invention;

Fig. 8 measures the fundamental diagram of concave surface minute surface shape for the Hartmann wave front sensor that utilizes light-splitting device to realize alignment function of the present invention;

Fig. 9 is the fundamental diagram that utilizes light-splitting device to realize the Hartmann wave front sensor measurement plane minute surface shape of alignment function of the present invention;

Figure 10 is the fundamental diagram that utilizes light-splitting device to realize the Hartmann wave front sensor measuring laser beam quality of alignment function of the present invention.

Among the figure: 1. the preceding mirror group of Beam matching system (be called for short: preceding mirror group), 2. the back mirror group of Beam matching system (be called for short: back mirror group), 3. spectroscope, 4. microlens array, 5. photodetector, 6. measurement light source system, 7. standard flat mirror, 8. level crossing, 10. convex mirror, 11. concave mirror, 12. positive lens, 13. negative lenses, 14. standard spherical mirrors, 15. supplementary lens, 16. laser instrument, 17. Beam matching systems (being collectively referred to as of preceding mirror group 1 and back mirror group 2), 18. external laser instruments, C1. coarse alignment detection system, C2. light-splitting device, C3. has the imaging screen of center pit, J1. fine alignment spectroscope, J2. condenser lens, J3. coarse alignment detection system.

Embodiment

Hartmann wave front sensor needs the at first error of calibration system itself when work.

As shown in Figure 1, when function of calibrating systematic error, at first pass through spectroscope 3 by measurement light source system 6 emitted light beams, pass through the preceding mirror group 1, back mirror group 2 of Beam matching system again after, finally outgoing from system.In standard flat mirror 7 reflection back retrieval systems,, behind the microlens array 4, image on the photodetector 5 through Beam matching system, spectroscope 3.The position of adjustment criteria level crossing 7 finally makes the coincidence measurement requirement of arranging of hot spot on the photodetector 5.But the area of microlens array 4 is about 1cm ², very little with respect to whole light path, cause standard flat mirror 7 adjustable scopes less, the adjusting difficulty is very big.Adopt after 7 demarcation of standard flat mirror, measured piece is placed in the system detects again.

As shown in Figure 2, compare among Hartmann wave front sensor of the present invention and Fig. 1, increased and be used for coarse alignment and part of accurate alignment: coarse alignment partly comprises: the imaging screen C3 of coarse alignment detection system C1, light-splitting device C2, center drilling; Part of accurate alignment comprises: fine alignment spectroscope J1, condenser lens J2, fine alignment detection system J3, and wherein imaging screen C3 is positioned on the focal plane of preceding mirror group 1; Light-splitting device C2 can be beam-splitter or Amici prism etc., within one times of focal length of mirror group 1, works to cut apart light beam before being positioned at; Coarse alignment detection system C1 can be to whole imaging screen C3 imaging.During fine alignment, incident light converges to behind the line focus lens J2 on the fine alignment detection system J3 after passing light-splitting device C2, back mirror group 2, spectroscope 3, fine alignment spectroscope J1.

As shown in Figure 3, incident beam focuses on the imaging screen C3 behind preceding mirror group 1, light-splitting device C2 during coarse alignment, and coarse alignment detection system C1 can observe whole imaging screen C3, and the result is presented on the monitor; By observing the relative position of focal beam spot and imaging screen C3 center pit, the position of adjusting standard flat mirror 7 makes the two coincidence.After coarse alignment was finished, tested light beam just can enter within the scope of fine alignment.

As shown in Figure 4, when fine alignment, after the light that measurement light source system 6 sends successively passes through fine alignment spectroscope J1, spectroscope 3, light-splitting device C2, by preceding mirror group 1 outgoing, return after meeting standard flat mirror 7, successively through behind preceding mirror group 1, light-splitting device C2, back mirror group 2, spectroscope 3, the fine alignment spectroscope J1, line focus lens J2 images on the fine alignment detection system J3 again, by calculating the centroid position of launching spot, the relatively barycenter of launching spot and the relative position relation between the calibration point in advance, the position of adjusting standard flat mirror 7 is until 2 coincidences.Can guarantee that light beam enters in the measurement visual field of microlens array 4 this moment, and with the strict same optical axis of system.

Utilize the present invention to comprise that positive lens, negative lens, convex lens, concave mirror, level crossing carry out face shape and detect, but also can detect that its detection method is narrated in conjunction with Fig. 5-Figure 10 to measured piece to laser beam quality.

As shown in Figure 5, mirror group 1 and back mirror group 2 two parts before Beam matching system 17 comprises; When positive lens being carried out the detection of face shape, carry out the adjusting of following four steps:

(1) standard flat mirror 7 is placed on before the Hartmann wave front sensor system, promptly the dotted line position among the figure according to the position of the described adjustment criteria level crossing 7 of Fig. 3, Fig. 4, is noted the position of hot spot on photodetector 5 in each sub-aperture, as calibration point.

(2) remove standard flat mirror 7, laser instrument 18 is placed on before the Hartmann wave front sensor system, i.e. dotted line position among the figure, the light pencil that laser sends is through preceding mirror group 1, focus on imaging screen C3 behind the light-splitting device C2, relative position according to focal beam spot of seeing by thick detection system C1 and central small hole, regulate the position of laser instrument 18, make the two coincidence, then utilize part of accurate alignment again, further adjust the position of laser instrument 18, focal beam spot and calibration point on the fine alignment detection system J3 are overlapped.This moment the light pencil that sends of laser instrument 18 with the strict same optical axis of system.

(3) positive lens 12 is placed between laser instrument 18 and the Hartmann system, (2) are described equally set by step, according to the position of the position adjustments positive lens (12) of focal beam spot, make itself and the same optical axis of system.

(4) remove laser instrument 18 after, change standard spherical mirror 14, by the light beam of measurement light source system 6 outgoing behind positive lens 12, in standard spherical mirror 14 reflected back Hartmann wave front sensor systems, still come the position of adjustment criteria spherical mirror 14 by the facula position on coarse alignment detection system C1, the fine alignment detection system J3, last standard spherical mirror 14 will with the same optical axis of system, and and positive lens 12 same focuses, note that in each sub-aperture the position of hot spot on the photodetector 5, combined calibrating point just can calculate the incident corrugated.

As shown in Figure 6, mirror group 1 and back mirror group 2 two parts before Beam matching system 17 comprises; When negative lens being carried out face shape and detects, need four steps among Fig. 5 equally, and align lens face shape and detect and compare, difference only is that a positive lens 12 has changed negative lens 13 into.

As shown in Figure 7, mirror group 1 and back mirror group 2 two parts before Beam matching system 17 comprises; When convex mirror being carried out the detection of face shape, must increase a supplementary lens 15 in the outside of Hartmann wave front sensor, the light of Hartmann system outgoing becomes and disperses or converging beam through behind the supplementary lens 15, so just need at first regulate the same optical axis of supplementary lens 15 and system.According to the described method of step among Fig. 5 (2), at first adjust the same optical axis of light beam and system that external laser instrument 18 sends; Then supplementary lens 15 is placed between external laser instrument 18 and the Hartmann sensor system, position according to the described adjusting supplementary lens 15 of Fig. 5 step (3), after utilizing standard spherical mirror 14 to replace external laser instrument 18, adjust the position of standard spherical mirror 14 according to Fig. 5 step (4), and note on the photodetector 5 in each sub-aperture the position of hot spot as calibration point; Change standard spherical mirror 14 with convex mirror 10 at last, still utilize the accurate part of coarse alignment and precision, regulate the position of convex mirror 10, make itself and the same optical axis of system, and with supplementary lens 15 same focuses, note simultaneously that in each sub-aperture the position of hot spot on the photodetector 5, combined calibrating point just can restore the corrugated.

As shown in Figure 8, mirror group 1 and back mirror group 2 two parts before Beam matching system 17 comprises; When concave mirror being carried out the detection of face shape, the step before measuring is the same with the described step of Fig. 7, just convex mirror 10 has been changed into concave mirror 11.

As shown in Figure 9, mirror group 1 and back mirror group 2 two parts before Beam matching system 17 comprises; When level crossing being carried out the detection of face shape, need carry out two steps ground adjustings:

(1) standard flat mirror 7 is placed on the front of aforesaid Hartmann system, the light that is sent by measurement light source system 6 is reflected by standard flat mirror 7, go up the relative position of aperture according to C2 on aligning observed reflect focalization hot spot of detection system C1 and the imaging screen, the inclination of adjustment criteria level crossing 7, the two is overlapped, and the coarse adjustment of standard flat mirror 7 is at this moment finished; The further inclination of adjustment criteria level crossing 7 makes focal beam spot and calibration point coincidence in advance on the fine alignment detection system J3, and finish the adjusting of standard flat mirror 7 this moment; Note the position of hot spot on photodetector 5 in each sub-aperture, as calibration point;

(2) level crossing 8 is placed between standard flat mirror 7 and the Hartmann system, described according to step (1) equally, by accurate adjustment and two steps of coarse adjustment, according to the position relation between focal beam spot and aperture and the prior calibration point level crossing 8 is regulated, finally made focal beam spot and calibration point coincidence in advance on the fine alignment detection system J3; Note the position of hot spot on photodetector 5 in each sub-aperture, combined calibrating point just can reconstruct the corrugated.

As shown in figure 10, mirror group 1 and back mirror group 2 two parts before Beam matching system 17 comprises; When laser beam quality is detected, at first need standard flat mirror 7 is placed on the front of Hartmann system, according to the inclination of the described adjustment criteria level crossing 7 of Fig. 5 step (1), the prior calibration point of focal beam spot on the fine alignment detection system J3 is overlapped equally; Note facula position in each sub-aperture as calibration point; Replace standard flat mirrors 7 with laser instrument 16 then, equally according to the position of the described adjusting laser instrument 16 of Fig. 5 step (2), allow the same optical axis of laser beam and system, note the facula position in each sub-aperture, combined calibrating point just can restore the corrugated.

Finish behind the locating tab assembly by Fig. 5～10 are described, restore the corrugated by following steps.At first adopt discrete centroid algorithm, calculate facula position (x by formula (1) _i, y _i),

$x_i=\frac{\underset{m=1}{\overset{M}{\mathrm{\Σ}}}\underset{n=1}{\overset{N}{\mathrm{\Σ}}}{x}_{\mathrm{nm}}{I}_{\mathrm{nm}}}{\underset{m=1}{\overset{M}{\mathrm{\Σ}}}\underset{n=1}{\overset{N}{\mathrm{\Σ}}}{I}_{\mathrm{nm}}}$ $y_i=\frac{\underset{m=1}{\overset{M}{\mathrm{\Σ}}}\underset{n=1}{\overset{N}{\mathrm{\Σ}}}{y}_{\mathrm{nm}}{I}_{\mathrm{nm}}}{\underset{m=1}{\overset{M}{\mathrm{\Σ}}}\underset{n=1}{\overset{N}{\mathrm{\Σ}}}{I}_{\mathrm{nm}}}---\left(1\right)$

In the formula, m=1～M, n=1～N are that sub-aperture is mapped to pixel region corresponding on the detector target surface, I _NmBe (n, the m) signal received of individual pixel-by-pixel basis, x on the detector target surface _Nm, y _NmBe respectively (n, m) the x coordinate of individual pixel and y coordinate.

Utilization can obtain the average gradient of wavefront on each sub-aperture at two groups of facula positions demarcating constantly and measure in the sub-aperture that constantly obtains:

$g_{\mathrm{xi}}=\frac{\mathrm{\&Delta;x}}{2\mathrm{\&pi;\&lambda;f}}=\frac{x_i-{\mathrm{<figure-callout\; id="2"\; label="x\; o"\; filenames="C2006101650770014H1.png,C2006101650770014H2.png"\; state="\{\{state\}\}">x</figure-callout>}}_o}{2\mathrm{\&pi;\&lambda;f}}$ $g_{\mathrm{yi}}=\frac{\mathrm{\&Delta;<figure-callout\; id="2"\; label="y"\; filenames="C2006101650770014H1.png,C2006101650770014H2.png"\; state="\{\{state\}\}">y</figure-callout>}}{2\mathrm{\&pi;\&lambda;f}}=\frac{y_i-{\mathrm{<figure-callout\; id="2"\; label="y\; o"\; filenames="C2006101650770014H1.png,C2006101650770014H2.png"\; state="\{\{state\}\}">y</figure-callout>}}_o}{2\mathrm{\&pi;\&lambda;f}}$

In the formula, (x ₀, y ₀) for standard flat ripple timing signal, the spot center reference position that obtains on each sub-aperture utilizes the slope value on tested corrugated on each the sub-aperture that is calculated by following formula, and then restores wavefront by type method or field method.

Claims (6)

1, utilize light-splitting device to realize the Hartmann wave front sensor of alignment function, comprise: measurement light source system (6), the preceding mirror group (1) of Beam matching system, the back mirror group (2) of Beam matching system, spectroscope (3), microlens array (4), photodetector (5), it is characterized in that also comprising: coarse alignment part and part of accurate alignment, coarse alignment partly comprises: imaging screen with holes (C3), light-splitting device (C2), coarse alignment detection system (C1), light-splitting device (C2) is arranged in one times of focal length of the preceding mirror group (1) of Beam matching system, play the separating incident light bundle, imaging screen with holes (C3) is placed on the focal plane of preceding mirror group (1) of Beam matching system, the hole is positioned on the focus, coarse alignment detection system (C1) can be observed whole imaging screen (C3), the light that is sent by measurement light source system (6) during work is by the hole outgoing of imaging screen (C3), through light-splitting device (C2), the preceding mirror group (1) of Beam matching system is after return behind the measured piece, again focus on the imaging screen (C3) after passing through light-splitting device (C2) again, by observing the aperture that obtains by coarse alignment detection system (C1) and the relative position of focal beam spot, the position of regulating measured piece overlaps aperture and focal beam spot, through after the coarse alignment, guaranteed that light beam can enter in the scope of fine alignment; Part of accurate alignment comprises fine alignment spectroscope (J1), condenser lens (J2) and fine alignment detection system (J3), fine alignment spectroscope (J1) is positioned at condenser lens (J2) before, condenser lens (J2) is positioned at fine alignment detection system (J3) before, the light that measurement light source system (6) sends successively passes through fine alignment spectroscope (J1), behind the spectroscope (3), preceding mirror group (1) outgoing by the Beam matching system, Hartmann wave front sensor turns back after the measured piece reflection, priority is through the preceding mirror group (1) of Beam matching system, the back mirror group (2) of Beam matching system, spectroscope (3), behind the fine alignment spectroscope (J1), line focus lens (J2) image on the fine alignment detection system (J3) again, obtain the position of focal beam spot by the centroid calculation formula, the position that it is the Hartmann wave front sensor optical axis that the adjusting measured piece makes facula mass center and prior calibration point overlaps, so far the fine alignment process is finished, through behind the fine alignment, light beam has entered in the measurement visual field of microlens array (4), and can directly measure.

2, the Hartmann wave front sensor that utilizes light-splitting device to realize alignment function according to claim 1 is characterized in that: described coarse alignment detection system and fine alignment detection system are by photodetector, and image acquisition and display system composition.

3, adopt the described Hartmann wave front sensor that utilizes light-splitting device to realize alignment function of claim 1 that positive lens or negative lens are carried out the detection method that face shape is detected, it is characterized in that may further comprise the steps:

(1) standard flat mirror (7) is placed on the front of the described Hartmann wave front sensor of claim 1, the position of hot spot on photodetector (5) in each sub-aperture noted, as calibration point in the position of adjustment criteria level crossing (7);

(2) remove standard flat mirror (7), laser instrument (18) is placed on before the Hartmann wave front sensor, the light pencil that laser sends is through preceding mirror group (1), focus on imaging screen (C3) behind the light-splitting device (C2), according to the focal beam spot of seeing by coarse alignment detection system (C1) and the relative position of central small hole, regulate the position of laser instrument (18), make the two coincidence, then utilize part of accurate alignment again, further adjust the position of laser instrument (18), focal beam spot on the fine alignment detection system (J3) and calibration point are overlapped, the light pencil that laser instrument this moment (18) sends with the strict same optical axis of Hartmann wave front sensor;

(3) positive lens (12) or negative lens (13) are placed between laser instrument (18) and the Hartmann wave front sensor,, make itself and the same optical axis of Hartmann wave front sensor according to the position adjustments positive lens (12) of focal beam spot, the position of negative lens (13);

(4) remove laser instrument (18) after, change standard spherical mirror (14); By the light beam of measurement light source system (6) outgoing behind positive lens (12) or negative lens (13), in standard spherical mirror (14) reflected back Hartmann wave front sensor, still by coarse alignment detection system (C1), facula position on the fine alignment detection system (J3) comes the position of adjustment criteria spherical mirror (14), last standard spherical mirror (14) will with the same optical axis of Hartmann wave front sensor, and and positive lens (12) or the same focus of negative lens (13), note photodetector (5) and go up the position of hot spot in each sub-aperture, the corrugated is restored in the position of calibration point in the joint step (1).

4, adopt the described Hartmann wave front sensor that utilizes light-splitting device to realize alignment function of claim 1 that convex mirror or concave mirror are carried out the detection method that face shape is detected, it is characterized in that may further comprise the steps:

(1) when convex mirror (10) or concave mirror (11) being carried out face shape and detect, outside at the described Hartmann wave front sensor of claim 1 increases a supplementary lens (15), parallel beam by this Hartmann wave front sensor outgoing can become converging beam or divergent beams behind supplementary lens (15), so just need at first regulate supplementary lens (15) and the same optical axis of Hartmann wave front sensor;

(2) at first before Hartmann wave front sensor, place laser instrument (18), according to coarse alignment part and part of accurate alignment, the light that is sent by laser instrument (18) focuses on the prior calibration point on the fine alignment detection system (J3), laser instrument this moment (18) just with the same optical axis of Hartmann wave front sensor;

(3) then supplementary lens (15) is placed between laser instrument (18) and the Hartmann wave front sensor, the light that adjustment is sent by laser instrument (18) focuses on the prior calibration point on the fine alignment detection system (J3), the light beam of laser instrument this moment (18), supplementary lens (15) all with the same optical axis of Hartmann wave front sensor;

(4) remove laser instrument (18) after, standard spherical mirror (14) is put into the detection light path, adjustment criteria spherical mirror (14) and supplementary lens (15), the same optical axis of Hartmann wave front sensor, make standard spherical mirror (14) and the same focus of supplementary lens (15), and note the position that photodetector (5) is gone up each hot spot, as calibration point; Utilize tested convex mirror (10) or concave mirror (11) alternate standard spherical mirror (14) again, allow convex mirror (10) or concave mirror (11) and the same focus of supplementary lens (15) and the same optical axis of Hartmann wave front sensor; After finishing, facula position and calibration point that utilization photodetector (5) records restore the corrugated.

5, adopt the described Hartmann wave front sensor that utilizes light-splitting device to realize alignment function of claim 1 that level crossing is carried out the method that face shape is detected, it is characterized in that may further comprise the steps:

(1) standard flat mirror (7) is placed on the front of the described Hartmann wave front sensor of claim 1, the light that is sent by measurement light source system (6) is reflected by standard flat mirror (7), relative position according to observed reflect focalization hot spot of coarse alignment detection system (C1) and the last aperture of imaging screen (C3), the inclination of adjustment criteria level crossing (7), make the two coincidence, the coarse adjustment of standard flat mirror this moment (7) is finished; The further inclination of adjustment criteria level crossing (7) makes focal beam spot and calibration point coincidence in advance on the fine alignment detection system (J3), and finish the adjusting of standard flat mirror (7) this moment; Note the position of hot spot on photodetector (5) in each sub-aperture, as calibration point;

(2) level crossing (8) is placed between standard flat mirror (7) and the Hartmann wave front sensor, by fine alignment and two steps of coarse alignment, according to the position relation between focal beam spot and aperture and the prior calibration point level crossing (8) is regulated, finally make focal beam spot and calibration point coincidence in advance on the fine alignment detection system (J3), note the position of hot spot on photodetector (5) in each sub-aperture, combined calibrating point just can reconstruct the corrugated.

6, the method that adopts the described Hartmann wave front sensor that utilizes light-splitting device to realize alignment function of claim 1 that laser beam quality is detected, it is characterized in that: the front that standard flat mirror (7) is placed on the described Hartmann wave front sensor of claim 1, the position of adjustment criteria level crossing (7), note the position of hot spot on photodetector (5) in each sub-aperture, as calibration point; Use laser instrument (16) to replace standard flat mirror (7) then, utilize coarse alignment part and part of accurate alignment, further regulate the position of laser instrument (16) again, allow the same optical axis of laser beam and Hartmann wave front sensor, note the position of hot spot on photodetector (5) in each sub-aperture, the combined calibrating point restores the corrugated.

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