CN202362459U - Miniaturized lens-free laser three-dimensional imaging system based on MEMS (micro-electromechanical system) scanning micro-mirror - Google Patents
Miniaturized lens-free laser three-dimensional imaging system based on MEMS (micro-electromechanical system) scanning micro-mirror Download PDFInfo
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Abstract
The utility model discloses a miniaturized lens-free laser three-dimensional imaging system based on an MEMS (micro-electromechanical system) scanning micro-mirror, which adopts a red, green and blue laser device as an illuminating light source. Lasers with three colors are combined into a white light source to be projected to the surface of a target after the powers of the lasers with three colors are modulated, a red light component, a green light component and a blue light component in scattering light on the surface of the target are received by a photoelectric receiver, a distance value of a single tested pixel and amplitude values of the red light component, the green light component and the blue light component are obtained by a measuring circuit. Three color brightness values of the single tested pixel are computed according to the amplitude values of the red light component, the green light component and the blue light component by a microcontroller, and actual three color brightness values of the pixel are obtained by the aid of a real-time distance squared correction method. The microcontroller controls the MEMS micro-mirror to scan, distance values and actual brightness values of all pixels are obtained, a depth image and a gray image of the target are generated in a combined manner, and finally a three-dimensional color image of the target is obtained. The miniaturized lens-free laser three-dimensional imaging system omits optical lenses, and is high in imaging resolution, fast in speed and simple in structure, and brings convenience for miniaturization.
Description
Technical field
The utility model relates to the three-dimensional imaging technical field, and particularly a kind of miniaturization based on the MEMS scanning micro-mirror does not have camera lens laser three-dimensional imaging system.
Background technology
Compare with the traditional two-dimensional imaging technique, the three-dimensional imaging technology has comprised the distance or the depth information of the third dimension, can describe the position and the movable information of object in the true three-dimension scene more fully, therefore has many outstanding advantages and wide application prospect; Particularly in recent years, along with the continuous development of computer vision technique, very urgent to the demand of high performance three-dimensional imaging in applications such as Target Recognition, profiling in kind, crashproof, the unmanned car navigation of mobile robot, three-dimensional film, virtual realities.
Based on anallatic three-dimensional imaging technology because good directionality, measurement range is big, resolution is high, need not contact, anti-external environmental interference is strong; And become the domestic and international research focus gradually, and most of optical 3-dimensional imaging system of research all is based on trigonometry or flight time principle and comes measuring distance at present.
3-D imaging system based on triangle measurement method; For example binocular vision system and structure light imaging system; " fuzzy problem (Ambiguity problems) therefore generally can only be used in the high measurement occasion of contrast to need to handle " shade " effect (Shadow effects) or projected fringe.Compare with such imaging system; 3-D imaging system transmitting and receiving almost on same straight line based on the flight time range finding owing to light; The obvious information of " resolution " each measured point, therefore can not occur existing in the triangle measurement method " shade " or projection " fuzzy problem; In addition, have also that principle is simple, distance accuracy is high, need not advantage such as reference surface based on the 3-D imaging system of flight time range finding.
In traditional 3-D imaging system based on the flight time range finding; Most typical representative is the scanning type laser imaging radar; It realizes whole three-dimensional measurement through two-dimensional scan, for example the HDL-64E scanning laser radar of the U.S. on the basis of single-point flight time range finding.Simple, the detectable distance of this three-dimensional imaging know-why, precision height, but owing to used accurate, heavy and expensive macroscopical mechanical scanner and optical element, the general resistance to shock of this type systematic is poor, volume is big, cost is high; Simultaneously; Because mechanical scanner self sweep velocity of macroscopic view is slow, in long-time use, there are aging and wear phenomenon, use the alignment precision of the 3-D view that this method obtains low; Real-time is poor, and usually is not suitable for the measurement of dynamic object or scene; In addition, the 3-D view that traditional scan laser imaging radar obtains often all is monochromatic gray level image, and the imaging color sense of reality is relatively poor.
Summary of the invention
The purpose of the utility model is to the existing deficiency of above-mentioned conventional three-dimensional imaging technique; Provide a kind of miniaturization not have camera lens laser three-dimensional imaging system based on the MEMS scanning micro-mirror; Be used for realizing in real time, high precision and color three dimension imaging cheaply, satisfy of the active demand of existing numerous areas to the high performance three-dimensional imaging.
The technical scheme that its technical matters of the utility model solution is taked is:
A kind of miniaturization based on the MEMS scanning micro-mirror does not have camera lens laser three-dimensional imaging system, comprises laser array, photoelectricity modulation circuit, beam splitter group, reflector group, biaxial MEMS micro mirror, micro mirror driving circuit, filter set, photelectric receiver group, amplitude measurement circuit bank and amplitude-range observation circuit; Said photoelectricity modulation circuit is connected with laser array, and said photelectric receiver group is connected with microcontroller with amplitude-range observation circuit through the amplitude measurement circuit bank, and said microcontroller is connected with display alternately; Said microcontroller output terminal is connected with micro mirror driving circuit input end, and by micro mirror driving circuit drives biaxial MEMS micro mirror.
Said laser array is made up of blue laser, green (light) laser and red laser, and the three is connected with the photoelectricity modulation circuit respectively and by the photoelectricity modulation circuit three's Output optical power is modulated; Said beam splitter group is made up of first beam splitter, second beam splitter and the 3rd beam splitter; Said reflector group is made up of first catoptron and second catoptron; Said filter set is made up of first blue filter, Red lightscreening plate, green color filter and second blue color filter; Said photelectric receiver group is made up of first photelectric receiver, second photelectric receiver, the 3rd photelectric receiver and the 4th photelectric receiver; Said amplitude measurement circuit bank is made up of the first amplitude measurement circuit and the second amplitude measurement circuit; After the light modulated of said blue laser emission arrives first beam splitter in the beam splitter group; Be divided into blue light transmitted light and blu-ray reflection light; First mirror reflects of said blue light transmitted light in reflector group arrives first blue filter in the filter set, and received by first photelectric receiver in the photelectric receiver group; The light modulated of said green (light) laser and red laser emission obtains green glow reflected light and reflection to red light light through second beam splitter and the 3rd beam splitter respectively; Said blu-ray reflection light and described green glow reflected light and described reflection to red light are photosynthetic to be a branch of white light; Said white light arrives the biaxial MEMS micro mirror through second catoptron, and is projected the surface of target; Second photelectric receiver in Red lightscreening plate in the said filter set and the photelectric receiver group receives the red light component of said target surface scattered light; The 3rd photelectric receiver in green color filter in the said filter set and the photelectric receiver group receives the green component of said target surface scattered light, and second blue color filter in the said filter set and the 4th photelectric receiver in the photelectric receiver group receive the blue light components of said target surface scattered light; The said first amplitude measurement circuit and the second amplitude measurement circuit are connected and handle the photosignal of the output of the two respectively with second photelectric receiver and the 3rd photelectric receiver, obtain the said scattered light red light component of single tested pixel and the range value of green component; Said amplitude-range observation circuit is connected and handles respectively the photosignal of the two output respectively with first photelectric receiver and the 4th photelectric receiver, obtain the distance value of said single tested pixel and the range value of said scattered light blue light components simultaneously; The reference signal of the output signal amplitude of being used as of described first photelectric receiver-range observation circuit measuring pixel distance value; Said microcontroller calculates the red, green, blue three look true brightness values of said single tested pixel respectively according to described ruddiness, green glow and blue light components range value.
Said microcontroller adopts programmable single chip computer, programmable DSP chip or high-performance FPGA/CPLD chip.
Said amplitude-range observation circuit is made up of the low noise amplifier group, BPF. group and the analog to digital converter group that connect successively; Said low noise amplifier group comprises first low noise amplifier and second low noise amplifier; Said BPF. group comprises first BPF. and second BPF.; Said analog to digital converter group comprises first analog to digital converter and second analog to digital converter.
The formation method of the utility model is following:
(a), adopt red, green, blue three look laser instruments as lighting source; And respectively the Output optical power of three look laser instruments is modulated; The red, green, blue three look laser of modulating are combined into a branch of white light after reflector group and beam splitter group, said white light projects the surface of target through the biaxial MEMS micro mirror; Use photelectric receiver group ruddiness, green glow and the blue light components in the receiving target surface scattering light respectively, and obtain distance value and ruddiness, the green glow of single tested pixel, the range value of blue light components by amplitude measurement circuit bank and amplitude-range observation circuit;
(b), after microcontroller obtains the distance value of single tested pixel, utilize real-time square distance modification method to calculate the red, green, blue three look true brightness values of single tested pixel, accomplish the measurement of single pixel value;
(c), microprocessor controls micro mirror driving circuit, drive the biaxial MEMS micro mirror and carry out two-dimensional scan, repeat the measuring process of said single pixel value, obtain distance value and the true brightness value of whole pixels, and the depth image and the gray level image of combination generation target;
(d), depth image and gray level image in microcontroller, through image processing algorithm, merge and generate the Three-dimension Target coloured image, and be sent to display and show.
Owing to do not use lens in the imaging process; The red, green, blue three colour brightness values of single tested pixel can not reflect the monochrome information of measured target really; Therefore microcontroller is again according to the distance value of the said single tested pixel that records; Utilize real-time square distance modification method to calculate the red, green, blue three look true brightness values that obtain said single tested pixel, accomplish the measurement of single pixel value.
Said real-time square distance modification method is at first, to utilize the first amplitude measurement circuit and the second amplitude measurement circuit to obtain the scattered light red light component of single tested pixel and the range value of green component; Simultaneously, utilize said amplitude-range observation circuit to obtain the distance value of single tested pixel and the range value of scattered light blue light components; Then; According to no lens imaging radiometry model; The brightness value of target imaging square is inversely proportional to distance value; Utilize the distance value of single tested pixel, the brightness value of red light component, green component and the blue light components of single tested pixel is carried out real-time square of correction, obtain the red, green, blue three look true brightness values of single tested pixel.
Compared with present technology, the beneficial effect of the utility model is embodied in:
1, the 3-D imaging system of the utility model need not any optical lens, does not have the depth of field and depth of focus problem in the traditional optical imaging technique, and the imaging system light path is simple, volume is little, anti-seismic performance is good;
2, compare with the driven in rotation mirror of the double pendulum mirror, rotating multisurface body reflecting prism, two galvanometer mirror or the diaxon that use in traditional scan laser imaging radar; The biaxial MEMS micro mirror that the utility model adopts not only is convenient to accurately drive and control, also has littler volume, lower power consumption and cost simultaneously;
3, the biaxial MEMS micro mirror that little, the light weight of the utility model usable floor area, resonant frequency are high is as the high speed two-dimension scanning device, and the spatial resolution of three-dimensional imaging is high, measuring speed is fast, can be applicable to the measurement of dynamic object or scene;
4, the depth image of the utility model imaging system acquisition and two dimensional image alignment precision are high;
5, the utility model can be realized colored three-dimensional imaging, and the imaging authenticity is stronger;
6, the utility model imaging system is simple in structure, volume is little, power consumption and cost are low, is convenient to miniaturization.
Description of drawings
Fig. 1 is the structural principle synoptic diagram of the utility model.
Fig. 2 is a specific embodiments of amplitude-range observation circuit 10.
Label among the figure: 1a, blue laser; 1b, green (light) laser; 1c, red laser; 2, photoelectricity modulation circuit; 3a, first beam splitter; 3b, second beam splitter; 3c, the 3rd beam splitter; 4a, first catoptron; 4b, second catoptron; 5, biaxial MEMS micro mirror; 6, micro mirror driving circuit; 7a, first blue filter; 7b, ruddiness optical filter; 7c, green glow optical filter; 7d, second blue filter; 8a, first photelectric receiver; 8b, second photelectric receiver; 8c, the 3rd photelectric receiver; 8d, the 4th photelectric receiver; 9a, the first amplitude measurement circuit; 9b, the second amplitude measurement circuit; 10, amplitude-range observation circuit; 11, microcontroller; 12, display; 13, target; 14, target surface normal direction; 15, the angle of laser incident direction and target surface normal direction
θ i16a, first low noise amplifier; 16b, second low noise amplifier; 17a, first BPF.; 17b, second BPF.; 18a, first analog to digital converter; 18b, second analog to digital converter.
Embodiment
Below in conjunction with specific embodiment, the utility model is described in detail.
Referring to Fig. 1; Photoelectricity modulation circuit 2 is set to be modulated the Output optical power of blue laser 1a, green (light) laser 1b and red laser 1c in the laser array respectively; After the light modulated of blue laser 1a emission arrives the first beam splitter 3a in the beam splitter group; Be divided into blue light transmitted light and blu-ray reflection light; The first catoptron 4a reflection of said blue light transmitted light in reflector group reaches the first blue filter 7a in the filter set, and received by the first photelectric receiver 8a in the photelectric receiver group; The light modulated of said green (light) laser (1b) and red laser (1c) emission obtains green glow reflected light and reflection to red light light through second beam splitter (3b) and the 3rd beam splitter (3c) respectively; Said blu-ray reflection light and described green glow reflected light and described reflection to red light are photosynthetic to be a branch of white light; Said white light arrives biaxial MEMS micro mirror 5 through the second catoptron 4b, and is projected the surface of target 13; The red light component that Red lightscreening plate 7b in the use filter set and the second photelectric receiver 8b in the photelectric receiver group receive said target 13 surface scattering light; The green component of using green color filter 7c and the 3rd photelectric receiver 8c in the photelectric receiver group in the filter set to receive said target 13 surface scattering light, and the second blue color filter 7d in the use filter set and the 4th photelectric receiver 8d in the photelectric receiver group blue light components that receives said target 13 surface scattering light;
The first amplitude measurement circuit 9a and the second amplitude measurement circuit 9b in the amplitude measurement circuit bank are set; Handle the photosignal of the second photelectric receiver 8b and the 3rd photelectric receiver 8c output respectively with said amplitude measurement circuit 9a and 9b, obtain the said red light component of single tested pixel and the range value of said green component; Amplitude-range observation circuit 10 is set; Handle the photosignal of the first photelectric receiver 8a and the 4th photelectric receiver 8d output respectively with said amplitude-range observation circuit 10, obtain the distance value of said single tested pixel and the range value of said scattered light blue light components simultaneously; Microcontroller 11 utilizes real-time square distance modification method to obtain the red, green, blue three look true brightness values of said single tested pixel, accomplishes the measurement of single pixel value;
In the present embodiment, green (light) laser 1b and red laser 1c are low-power laser in the said laser array, can select the semiconductor laser of common small size for use, therefore can directly reach the purpose of intensity modulation through the working current of modulated laser; After the light modulated of blue laser 1a emission arrives the first beam splitter 3a in the said laser array, be divided into blue light transmitted light and blu-ray reflection light; Described blu-ray reflection light is incident upon the surface of target 13 through biaxial MEMS micro mirror 5 behind synthesize white light, the blue light components in its scattered light is used to the range observation of target 13; In order to improve the distance accuracy that receives the photosignal signal to noise ratio (S/N ratio) and improve final imaging system; Blue laser 1a need select high power laser for use in the said laser array; For example the solid state laser of small size need use electro-optic crystal that the emergent light of laser instrument is carried out intensity modulation simultaneously;
The modulation signal that said photoelectricity modulation circuit 2 produces is three different frequencies
f M1,
f M2,
f M3Continuous sine wave, and respectively the Output optical power of blue laser 1a, green (light) laser 1b and red laser 1c in the laser array is modulated; Consider the maximum measure distance scope and improve the requirement that receives the photosignal signal to noise ratio (S/N ratio), said modulating frequency
f M1,
f M2,
f M3Span generally between 1 ~ 20 MHz;
Described biaxial MEMS micro mirror 5 is twin shaft scanning micro-mirrors, and the areal extent of micro mirror is 10 * 10 ~ 1000 * 1000 μ m
2, can scan said target 13 at two orthogonal directionss, the sweep velocity scope is 1 frame/second ~ 85 frame/second, scanning resolution is not less than 800 * 600; In the present embodiment, the area size of this micro mirror is 700 * 700 μ m
2, the two-dimensional scan angle is 52o * 43o (horizontal angle * vertical angle), and sweep velocity was 30 frame/seconds, and resolution is 1024 * 768.
In the said laser array output wavelength scope of blue laser 1a, green (light) laser 1b and red laser 1c be in respectively typical blue wave band (455 ~ 492nm), green light band (492 ~ 577nm) and red spectral band (622 ~ 770nm); In the present embodiment, the wavelength of blue laser 1a, green (light) laser 1b and red laser 1c is respectively 488nm, 520nm and 660nm; Therefore, the printing opacity centre wavelength of the Red lightscreening plate 7b in the said filter set, green color filter 7c, blue color filter 7a and 7d chooses that the output wavelength with selected laser instrument is consistent respectively.In the present embodiment, the printing opacity centre wavelength of blue color filter, green color filter and Red lightscreening plate is respectively 488nm, 520nm and 660nm, and the bandwidth of all optical filters is ± 10nm.
In the present embodiment; Said amplitude-range observation circuit 10 is handled the photosignal of the first photelectric receiver 8a and the 4th photelectric receiver 8d output respectively; Use obtains the distance value of said single tested pixel and the range value of said scattered light blue light components simultaneously based on phase-shift type flight time (TOF) distance-finding method of " 4 algorithms " (Four-bucket algorithm).
The principle of said TOF distance-finding method is to use the light velocity
cThe flight time of constant and measuring light
tObtain tested distance, and phase-shift type TOF range finding is to use the frequency to do
f mContinuous sine wave the Output optical power of laser instrument is modulated, with the turnaround time of direct measuring light
tBe converted into indirect measurement with
tThe phase delay delta of corresponding modulation signal
ΦObtain tested distance
d:
Said " 4 algorithms " principle is: for a sine or cosine signal, if in a modulation period by continuous sampling four times, the amplitude of corresponding sampled point be (
A 0,
A 1,
A 2,
A 3), and the time interval between each sampled point be 1/4th (i.e. " 4 quadrature samplings "), the then phase places of this signal of a strict modulation period
Φ, amplitude
ACan be expressed as:
(2)
For the distance value that obtains said single tested pixel and the range value of said scattered light blue light components; Scattered light receiving end in target 13; At first use " 4 algorithms " to handle the sinusoidal wave photosignal of the first photelectric receiver 8a and the 4th photelectric receiver 8d output simultaneously, obtain the phase value of the sinusoidal wave photosignal of first photelectric receiver 8a output respectively
Φ 1, the phase value of the sinusoidal wave photosignal of the 4th photelectric receiver 8d output
Φ 2And range value
A b, calculate phase delay delta then corresponding to the modulation signal of flight time
Φ=
Φ 2–
Φ 1, obtain the distance value of single tested pixel at last according to formula (1)
d, record
A bBe the range value of said scattered light blue light components;
Fig. 2 is a specific embodiments of said amplitude-range observation circuit 10: the blue light components of said the 4th photelectric receiver 8d receiving target 13 surface scattering light; After being translated into corresponding electric signal; At first use the first low noise amplifier 16a in the low noise amplifier group that this signal is amplified; The first BPF. 17a that sends into then in the BPF. group carries out Filtering Processing; Then use the first analog to digital converter 18a (ADC) in the analog to digital converter group that this signal is carried out " 4 quadrature samplings "; The data of sampling are sent in the microcontroller 11 the most at last, and calculate the phase value of the sinusoidal wave photosignal that obtains said the 4th photelectric receiver 8d output according to formula (2), (3)
Φ 2And range value
A b
Described first photelectric receiver 8a output Signal Processing flow process is identical with said the 4th photelectric receiver 8d output Signal Processing flow process; Also be to amplify through the second low noise amplifier 16b earlier; Send into the second BPF. 17b filtering then; Then use the second analog to digital converter 18b (ADC) that this signal is carried out " 4 quadrature samplings ", but difference is only to calculate the phase value of this photosignal at last
Φ 1Get final product, need not to calculate the range value of this signal;
The output signal amplitude of being used as of the described first photelectric receiver 8a-range observation circuit 10 is measured the reference signal of pixel distance value, its objective is the error of floating the measurement introducing of adjusting the distance for the temperature that reduces circuit.In the present embodiment, it is little that the temperature of ifs circuit is floated the error that measure to introduce of adjusting the distance, and also can in system, remove the first blue filter 7a of the first photelectric receiver 8a and front end thereof, directly uses the sinusoidal modulation signal of modulation source 2 generations
f M1Reference signal as range observation.
In the present embodiment, the OPA642 chip that described low noise amplifier 16a and 16b can select for use TI to produce, the chips such as MAX4012 that also can select for use Maxim to produce; The model that described analog to digital converter 18a and 18b can select for use ADI company to produce is 14bit modulus conversion chips such as AD9251-65 or AD9640-125, and described BPF. 17a and 17b can use common LC passive filter circuit.In the present embodiment, adopt OPA642 chip, AD9251-65 chip and common LC passive filter circuit to come structure amplitude-range observation circuit 10.
The said second photelectric receiver 8b also is identical with the 3rd photelectric receiver 8c output Signal Processing flow process with said the 4th photelectric receiver 8d output Signal Processing flow process, but difference is only to calculate the range value of said red light component at last respectively
A rRange value with said green component
A g Get final product, need not to calculate the phase value of these two signals.
In the present embodiment, real-time square of modification method obtains according to no lens imaging radiometry model, referring to Fig. 1.For no lens imaging, the brightness value of each tested pixel
I pAmplitude measurement by receiving photosignal obtains:
Wherein
k 1Scale-up factor when being scaled brightness value for range value,
A mBe the measured value of photosignal amplitude,
k 2Be the scale-up factor of photoelectricity received power to signal amplitude,
S pBe the photosensitive area of photelectric receiver,
E iBe the laser optical emissive power,
ρ Be target 13 surface reflectivities,
θ iBe the angle of laser incident direction and target 13 surface normal directions 14,
dTested distance for target 13.Can know the brightness value of target 13 imagings from formula (4)
I pWith distance value
dSquare be inversely proportional to; And have the lens imaging system to compare, the luminance signal that no lens imaging system obtains is with the distance of target 13
dChange, can not reflect the monochrome information of measured target 13 really.Therefore, must be with the phase-shift type TOF resulting a certain pixel distance value of finding range
dPhotosignal amplitude to no lens imaging systematic survey obtains is carried out a square correction, that is:
Wherein
IBy certain pixel is left according to finding range
dRevised true brightness value.In the present embodiment, imaging system is at the range value of the ruddiness that obtains said single tested pixel respectively, green glow and blue light components
A r,
A gWith
A bAfter, calculate the red, green, blue three colour brightness values of said single tested pixel respectively.Then, utilize this pixel distance value that has recorded again
d, according to formula (5) the red, green, blue three colour brightness values of said single tested pixel are carried out real-time square of correction, finally obtain the true brightness value after red, green, blue three colour corrections of said single tested pixel respectively
I r,
I gWith
I b
In the present embodiment; Said microcontroller 11 can be selected programmable single chip computer, programmable DSP chip or high-performance FPGA/CPLD chip etc. for use; MSP430 series, TMS320 as TI company produces is serial, the Startix series of Altera company production; The Virtex series that Xilinx company produces etc.; It has just accomplished the measurement of single pixel value at the distance value that obtains said single tested pixel and after utilizing real-time square distance modification method to calculate the red, green, blue three look true brightness values of said single tested pixel; Microcontroller 11 is controlled micro mirror driving circuits 6 then; Drive biaxial MEMS micro mirror 5 and carry out two-dimensional scan; Repeat the measuring process of said single pixel value, obtain the distance value and the true brightness value of whole pixels, and combination generates the depth image and the gray level image of target 13; Said depth image and gray level image through the image processing algorithm of maturation, merge to generate the three-dimensional color image of target 13 in microcontroller 11, and are sent to display 12 and show.
Claims (4)
1. the miniaturization based on the MEMS scanning micro-mirror does not have camera lens laser three-dimensional imaging system, it is characterized in that: comprise laser array, photoelectricity modulation circuit (2), beam splitter group, reflector group, biaxial MEMS micro mirror (5), micro mirror driving circuit (6), filter set, photelectric receiver group, amplitude measurement circuit bank and amplitude-range observation circuit (10); Said photoelectricity modulation circuit (2) is connected with laser array; Said photelectric receiver group is connected with microcontroller (11) with amplitude-range observation circuit (10) through the amplitude measurement circuit bank, and said microcontroller (11) is connected with display (12) alternately; Said microcontroller (11) output terminal is connected with micro mirror driving circuit (6) input end, and drives biaxial MEMS micro mirror (5) by micro mirror driving circuit (6).
2. the miniaturization based on the MEMS scanning micro-mirror according to claim 1 does not have camera lens laser three-dimensional imaging system; It is characterized in that: said laser array is made up of blue laser (1a), green (light) laser (1b) and red laser (1c), and the three is connected with photoelectricity modulation circuit (2) respectively and by photoelectricity modulation circuit (2) three's Output optical power is modulated; Said beam splitter group is made up of first beam splitter (3a), second beam splitter (3b) and the 3rd beam splitter (3c); Said reflector group is made up of first catoptron (4a) and second catoptron (4b); Said filter set is made up of first blue filter (7a), Red lightscreening plate (7b), green color filter (7c) and second blue color filter (7d); Said photelectric receiver group is made up of first photelectric receiver (8a), second photelectric receiver (8b), the 3rd photelectric receiver (8c) and the 4th photelectric receiver (8d); Said amplitude measurement circuit bank is made up of the first amplitude measurement circuit (9a) and the second amplitude measurement circuit (9b); After the light modulated of said blue laser (1a) emission arrives first beam splitter (3a) in the beam splitter group; Be divided into blue light transmitted light and blu-ray reflection light; First catoptron (4a) reflection of said blue light transmitted light in reflector group arrives first blue filter (7a) in the filter set, and received by first photelectric receiver (8a) in the photelectric receiver group; The light modulated of said green (light) laser (1b) and red laser (1c) emission obtains green glow reflected light and reflection to red light light through second beam splitter (3b) and the 3rd beam splitter (3c) respectively; Said blu-ray reflection light and described green glow reflected light and described reflection to red light are photosynthetic to be a branch of white light; Said white light arrives biaxial MEMS micro mirror (5) through second catoptron (4b), and is projected the surface of target (13); Second photelectric receiver (8b) in Red lightscreening plate in the said filter set (7b) and the photelectric receiver group receives the red light component in said target (13) the surface scattering light; The 3rd photelectric receiver (8c) in green color filter in the said filter set (7c) and the photelectric receiver group receives the green component in said target (13) the surface scattering light, and second blue color filter (7d) and the 4th photelectric receiver (8d) in the photelectric receiver group in the said filter set receive the blue light components in said target (13) the surface scattering light; The said first amplitude measurement circuit (9a) and the second amplitude measurement circuit (9b) are connected and handle the photosignal of the output of the two respectively with second photelectric receiver (8b) and the 3rd photelectric receiver (8c), obtain the said scattered light red light component of single tested pixel and the range value of green component; Said amplitude-range observation circuit (10) is connected and handles respectively the photosignal of the two output respectively with first photelectric receiver (8a) and the 4th photelectric receiver (8d), obtain the distance value of said single tested pixel and the range value of said scattered light blue light components simultaneously; The output signal amplitude of being used as of said first photelectric receiver (8a)-range observation circuit (10) is measured the reference signal of pixel distance value; Microcontroller (11) calculates the red, green, blue three look true brightness values of said single tested pixel respectively according to described ruddiness, green glow and blue light components range value.
3. the miniaturization based on the MEMS scanning micro-mirror according to claim 1 and 2 does not have camera lens laser three-dimensional imaging system, it is characterized in that: said microcontroller (11) adopts programmable single chip computer, programmable DSP chip or high-performance FPGA/CPLD chip.
4. the miniaturization based on the MEMS scanning micro-mirror according to claim 1 and 2 does not have camera lens laser three-dimensional imaging system, it is characterized in that: said amplitude-range observation circuit (10) is made up of the low noise amplifier group, BPF. group and the analog to digital converter group that connect successively; Said low noise amplifier group comprises first low noise amplifier (16a) and second low noise amplifier (16b); Said BPF. group comprises first BPF. (17a) and second BPF. (17b); Said analog to digital converter group comprises first analog to digital converter (18a) and second analog to digital converter (18b).
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Cited By (5)
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CN102508259A (en) * | 2011-12-12 | 2012-06-20 | 中国科学院合肥物质科学研究院 | Miniaturization lens-free laser three-dimensional imaging system based on micro-electromechanical system (MEMS) scanning micro-mirror and imaging method thereof |
CN103954971A (en) * | 2014-05-22 | 2014-07-30 | 武汉大学 | On-board colorful three-dimensional scanning laser radar |
CN104871029A (en) * | 2012-12-21 | 2015-08-26 | 法雷奥开关和传感器有限责任公司 | Optical object-detection device having a mems and motor vehicle having such a detection device |
CN105005994A (en) * | 2015-07-22 | 2015-10-28 | 深圳市繁维科技有限公司 | 3D scanning assembly, scanning system and 3D printing system |
CN110456366A (en) * | 2019-07-19 | 2019-11-15 | 华为技术有限公司 | Location detecting apparatus and terminal |
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2011
- 2011-12-12 CN CN201120515460XU patent/CN202362459U/en not_active Expired - Lifetime
Cited By (6)
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CN102508259A (en) * | 2011-12-12 | 2012-06-20 | 中国科学院合肥物质科学研究院 | Miniaturization lens-free laser three-dimensional imaging system based on micro-electromechanical system (MEMS) scanning micro-mirror and imaging method thereof |
CN104871029A (en) * | 2012-12-21 | 2015-08-26 | 法雷奥开关和传感器有限责任公司 | Optical object-detection device having a mems and motor vehicle having such a detection device |
CN103954971A (en) * | 2014-05-22 | 2014-07-30 | 武汉大学 | On-board colorful three-dimensional scanning laser radar |
CN105005994A (en) * | 2015-07-22 | 2015-10-28 | 深圳市繁维科技有限公司 | 3D scanning assembly, scanning system and 3D printing system |
CN110456366A (en) * | 2019-07-19 | 2019-11-15 | 华为技术有限公司 | Location detecting apparatus and terminal |
CN110456366B (en) * | 2019-07-19 | 2022-01-14 | 华为技术有限公司 | Position detection device and terminal |
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