CN203981954U - One utilizes optical thin film to realize refraction-reflection blind-area-free panoramic endless belt imaging system - Google Patents

Abstract

The utility model discloses one utilizes optical thin film to realize refraction-reflection blind-area-free panoramic endless belt imaging system.Comprise coaxial mounted extrawide angle lens, be placed in follow-up lens combination and the detector at extrawide angle lens rear, be provided with in extrawide angle lens front for proofreading and correct the front lens group by optical propagation direction, front lens group is coaxial with extrawide angle lens, front lens group is proofreaied and correct the direction of propagation by front lens group front surface incident light, the second reflecting surface of extrawide angle lens is coated with one deck optical thin film, this optical thin film makes the light that is mapped to the second reflecting surface from extrawide angle lens only carry out transmission, and the light that is mapped to the second reflecting surface in extrawide angle lens is only reflected, incident light is imaged onto on the blind area of detector face through extrawide angle lens and follow-up lens combination post-concentration by the refraction of front lens group again.The utlity model has the defect that has made up the imaging of conventional refraction-reflection panoramic optical systems and exist blind area, can accomplish the function of the light of different-waveband imaging simultaneously simultaneously.

Description

One utilizes optical thin film to realize refraction-reflection blind-area-free panoramic endless belt imaging system

Technical field

The utility model relates to a kind of imaging system in optical imaging device field, specifically relates to one and utilizes optical thin film to realize refraction-reflection blind-area-free panoramic endless belt imaging system.

Background technology

Be accompanied by the development of overall view ring belt imaging technique, study and a kind ofly can replace the method for monoscopic system to become the focus that every country is competitively studied by overall view ring belt imaging system.Overall view ring belt imaging optical system is a kind of novel imaging technique that Random Curved Surface Designing process technology, digital image processing techniques and large face battle array imaging CCD/CMOS detector technology grow up that relies on.

Traditional monoscopic panoramic scanning imaging technique is to utilize the system being made up of single imaging lens to rotate a circle, obtain a series of images, or along 360 ° of all directions place one group single-lens take respectively simultaneously after, the image being spliced by computer digital image processing.The former shortcoming is synchronization camera lens to photograph the image of 360 ° of surroundings simultaneously, therefore the real-time of this method is not good enough, there will be delay inequality; And the defect of the latter's method is that active computer processes splicing time to digital picture, the more difficult control of stitching error of image boundary, the disappearance or the problem such as fuzzy that easily cause image, all decrease the stability of this monoscopic omnidirectional imaging system and operability.

Than traditional monoscopic scanning panoramic imaging lens, overall view ring belt imaging system can be at the disposable image of catching within the scope of 360 ° of surroundings of synchronization, well solve the delay inequality problem of traditional panoramic scanning imaging lens, simultaneously when process overall view ring belt imaging system image by computer digital image, only relate to the expansion technique of image, and do not relate to Image Mosaics, therefore the error problem of Image Mosaics has also obtained avoiding well.

Current, mainly contain two kinds of implementations for overall view ring belt imaging technique.One is the overall view ring belt imaging method based on reflective, and the scenery within the scope of it is characterized in that around 360 ° enters optical system by the mode of reflection, then optimizes picture element through a series of optical element, finally arrives detector surface and carries out imaging; Another is the overall view ring belt imaging method based on refraction-reflection, it is characterized in that scenery enters optical system by the mode of refraction around, in outgoing after two secondary reflections in extrawide angle lens, then optimize picture element through subsequent optical elements, finally arrive detector surface and carry out imaging.Two kinds of overall view ring belt imaging modes respectively have its relative merits, and the processing of the former reflective panoramic optical element and assembling are comparatively complicated, but it is lighter to be better than structure; The processing of the latter's refraction-reflection panoramic optical element and assembling are relatively easy, but solid material structure is heavier.

For conventional refraction-reflection overall view ring belt imaging optical system, its light path is moved towards as shown in Figure 1, and incident light enters optical system by the first transmission plane transmission, because different medium exists refringence, and light generation refractive deflection; Light, reflects after arrival the first reflecting surface along rectilinear propagation in isotropic lens inside; Continue to arrive the second reflecting surface place along rectilinear propagation reflection for the second time occurs; Arrive after the second transmission plane along rectilinear propagation again, reflect, go out to penetrate extrawide angle lens; After follow-up lens combination, be finally imaged on detector, optical design is as shown in Figure 2.

Although overall view ring belt imaging system has had many advantages that surmounts traditional view field imaging system, it still exists many still open questions, such as the blind zone problem of overall view ring belt imaging system.The existence of blind area is the inherent shortcoming of refraction-reflection overall view ring belt imaging system, and it reduces the utilization factor of detector greatly, causes the waste of detector central area, as shown in Figure 2.

In prior art, extrawide angle lens the second reflecting surface 7 is coated with reflective film, in extrawide angle lens of the present utility model, it is selective optical film that the second reflecting surface 7 places are coated with one deck optical thin film, need plate one deck reflective film at the first reflecting surface 6 places, while making light transmition to this face, reflect, one deck optical thin film in the plating of the second reflecting surface place is selective optical film, this selective optical film is a kind of to the light reflection in some wavelength band, and to the light transmissive film in other wavelength band, in the time that the illumination of different-waveband is mapped on this film, carrying out selectivity sees through.

Extrawide angle lens 1 and follow-up lens combination 2 make to be propagated by the light of extrawide angle lens the second reflecting surface incident and the luminous energy of the first transmission plane incident simultaneously.By the light of extrawide angle lens the second reflecting surface incident be respectively the light of different-waveband by the light of the first transmission plane incident.

In the utility model, front lens group can be formed by the optical lens combination that is positioned over the multi-disc different materials before extrawide angle lens, and focal power is provided, and the light transmition direction that is entered optical system by the transmission of front lens group front side surface is deflected.

The material of the each lens of front lens group need meet the condition of being propagated by front lens group front side surface incident band of light therein simultaneously.

In the utility model, optical thin film is wavelength spectro-film, be again double-colored spectro-film, it is, by wavelength region may, light beam is carried out to the selectivity optical thin film of reflection thoroughly, need to make the light that is mapped to the second reflecting surface from extrawide angle lens only carry out transmission, and the light that is mapped to the second reflecting surface in extrawide angle lens is only reflected.

Optical thin film, to carrying out selective transmission by the light of extrawide angle lens the second reflecting surface place incident, carries out selective reflecting to the light of the first transmission plane place incident.

Extrawide angle lens and follow-up lens combination are selected and can be made two materials that different-waveband light is propagated simultaneously of aforementioned optical thin film transmission and reflection.

In the utility model, front lens group is made up of a series of lens on same optical axis: produce focal power together with the extrawide angle lens of its rear side, follow-up lens combination, make, after the low field rays generation direction deflection by the incident of front lens group first lens front surface, to be finally imaged on detector photosurface place.Preferred front lens group 4 as shown in Figure 3, has front lens group front surface 13 and front lens group rear surface 14.

Follow-up lens combination is made up of a series of lens on same optical axis: for the light by enter follow-up lens combination after extrawide angle lens outgoing through air dielectric, follow-up lens combination provides certain focal power for it, make the deflection of light transmition direction generation part, from follow-up lens combination outgoing, converge at detector photosurface position (being image planes positions).Preferred follow-up lens combination 2 as shown in Figure 3, has follow-up lens combination front surface 9 and follow-up lens combination rear surface 10.

In the utility model, the detector photosurface of above-mentioned indication refers to that detector receives luminous energy, and is translated into the surface of electric signal, consistent with imaging image planes in the utility model.

Principle of work of the present utility model is as follows:

Plate the light of optical thin film selective reflecting wave band for extrawide angle lens, (be conventionally greater than 30 ° of angles of half field-of view) from compare Gao visual field, extrawide angle lens side and be radiated at extrawide angle lens the first transmission plane, owing to there is refringence between air and extrawide angle lens material medium, this band of light can reflect and enter optical system; Because extrawide angle lens material is isotropic medium, light along rectilinear propagation, arrives extrawide angle lens the first reflecting surface place in extrawide angle lens; On the first reflecting surface, be coated with reflective film, after light reflects herein, continue along rectilinear propagation, arrive the second reflecting surface place; Because the second reflecting surface is coated with the optical thin film to this wave band reflection, after light occurs to reflect for the second time herein, continue along rectilinear propagation, arrive the second transmission plane place; Light reflects herein again, leaves extrawide angle lens and enters air dielectric; Light enters follow-up lens combination along rectilinear propagation in air, the material of the each lens of follow-up lens combination is isotropic material and has refringence with air, make light that a series of refraction effects occur in follow-up lens combination, finally leave the photosurface of follow-up lens combination arrival detector;

Plate the light of optical thin film selective transmission wave band for aforementioned extrawide angle lens, be radiated at front lens group first lens front surface from compare Di visual field, front end lens combination front (being conventionally less than 30 ° of angles of half field-of view), owing to there is refringence between air and front lens group first lens material medium, this band of light can reflect and enter optical system; Because the each lens materials of front lens is isotropic medium, light along rectilinear propagation, arrives the last a slice lens rear surface of front lens group place beam projecting in front lens group, in air, after rectilinear propagation, arrives extrawide angle lens the second reflecting surface place; Owing to being coated with on extrawide angle lens the second reflecting surface the light transmissive film of this wave band, there is transmission phenomenon in light, makes light refraction enter extrawide angle lens herein, continues to arrive the second transmission plane place along rectilinear propagation, light reflects herein again, leaves extrawide angle lens and enters air dielectric; Light enters follow-up lens combination along rectilinear propagation in air afterwards, the material of the each lens of follow-up lens combination is isotropic material and has refringence with air, make light that a series of refraction effects occur in follow-up lens combination, finally leave the photosurface of follow-up lens combination arrival detector;

For the incident light of aforementioned extrawide angle lens the first transmission plane, image in the peripheral annular section of detector photosurface; For the incident light before aforementioned front lens group first lens, image in the central circular of detector photosurface; The interior radius of circle of the peripheral annular section of detector photosurface can not be less than the radius value of central circular, ensures not occur on detector photosurface the overlapping region of two different-waveband photoimagings; Simultaneously the interior radius of circle of the peripheral annular section of detector photosurface should not crossed the radius value that is greater than central circular, does not occur detector being maximized the use, as shown in Figure 5 in annular blind area avoiding on detector photosurface.

Embodiment of the present utility model is as follows:

Summary of the invention

In order to solve the problem existing in background technology, the purpose of this utility model is to propose one to utilize optical thin film to realize refraction-reflection blind-area-free panoramic endless belt imaging system, make the region that detector center originally cannot imaging be able to imaging, to improve the utilization factor of detector, and effectively utilize same set of refraction-reflection overall view ring belt imaging optical system to be imaged in the zones of different of a detector two light in different-waveband, and do not affect each other simultaneously.

For realizing above-mentioned utility model object, the utility model is achieved through the following technical solutions:

The utility model comprises coaxial mounted extrawide angle lens, is placed in follow-up lens combination and the detector at extrawide angle lens rear, and extrawide angle lens comprises the first transmission plane, the first reflecting surface, the second reflecting surface and the second transmission plane; Be provided with the front lens group for proofreading and correct optical propagation direction in extrawide angle lens front, front lens group is coaxial with extrawide angle lens, front lens group is proofreaied and correct the direction of propagation by front lens group front surface incident light, the second reflecting surface of extrawide angle lens is coated with one deck selective optical film, this optical thin film makes the light that is mapped to the second reflecting surface from extrawide angle lens only carry out transmission, and the light that is mapped to the second reflecting surface in extrawide angle lens is only reflected; The light of front lens group front end incident is imaged onto on the imaging region of detector center through the second reflecting surface and the follow-up lens combination post-concentration of extrawide angle lens more successively by the refraction of front lens group; By the light of the first transmission plane incident of extrawide angle lens in extrawide angle lens inside successively after the first reflecting surface, the second reflecting surface reflection, then reflect the then overall view ring belt imaging region to detector face through follow-up lens combination transmission imaging through the second transmission plane.

Described extrawide angle lens and follow-up lens combination make to be propagated by the light of extrawide angle lens the second reflecting surface incident and the luminous energy of the first transmission plane incident simultaneously.

The described light by extrawide angle lens the second reflecting surface incident and be respectively the light of different-waveband by the light of the first transmission plane incident.

Described front lens group is formed by the optical lens combination of multi-disc different materials, makes can be propagated by the light of extrawide angle lens the second reflecting surface place incident.

Described optical thin film adopts spectro-film, by wavelength region may, light beam is carried out to selectivity and thoroughly reflects.

Described optical thin film, to carrying out selective transmission by the light of extrawide angle lens the second reflecting surface place incident, carries out selective reflecting to the light of the first transmission plane place incident.

The utility model beneficial effect is:

The utility model makes the region that detector center originally cannot imaging be able to imaging, to improve the utilization factor of detector.

The utility model can utilize same set of refraction-reflection overall view ring belt imaging optical system to be imaged in the zones of different of a detector two light in different-waveband effectively simultaneously, and does not affect each other.

The utlity model has the defect that has made up conventional refraction-reflection panoramic optical systems imaging in prior art and exist blind area, can accomplish the function of the light of different-waveband imaging simultaneously simultaneously.

Brief description of the drawings

Fig. 1 is prior art imaging system structural representation.

Fig. 2 is prior art detector image planes regional distribution chart.

Fig. 3 is structural representation of the present utility model.

Fig. 4 is image planes regional distribution chart of the present utility model.

Fig. 5 is index path of the present utility model.

In figure: 1, extrawide angle lens, 2, follow-up lens combination, 3, detector, 4, front lens group, 5, the first transmission plane, 6, the first reflecting surface, 7, the second reflecting surface, 8, the second transmission plane, 9, follow-up lens combination front surface, 10, follow-up lens combination rear surface, 12, blind area, 13, front lens group front surface, 14, front lens group rear surface, 16, detector center imaging region, 17, overall view ring belt imaging region, 18, the non-imaging region of detector.

Embodiment

Below in conjunction with drawings and the specific embodiments, the utility model is described in further detail.

As shown in Figure 4, imaging system of the present utility model comprises coaxial mounted extrawide angle lens 1, be placed in follow-up lens combination 2 and the detector 3 at extrawide angle lens 1 rear, extrawide angle lens 1 is provided with the first reflecting surface 6, the second reflecting surface 7, the first transmission plane 5 and the second transmission plane 8, be provided with the front lens group 4 for proofreading and correct optical propagation direction in extrawide angle lens front, front lens group 4 is coaxial with extrawide angle lens 1, front lens group 4 is proofreaied and correct the direction of propagation by front lens group front surface 13 incident lights, the second reflecting surface 7 of extrawide angle lens 1 is coated with one deck selective optical film, this optical thin film makes the light that is mapped to the second reflecting surface 7 from extrawide angle lens 1 only carry out transmission, and the light that is mapped to the second reflecting surface 7 in extrawide angle lens 1 is only reflected, the light of front lens group front surface 13 incidents is reflected and is imaged onto on detector center imaging region 16 through the second reflecting surface 7 and follow-up lens combination 2 post-concentrations of extrawide angle lens 1 successively by front lens group 4, be on the blind area 12 of original detector (CCD or CMOS) face, this blind area 12 is for arriving from the light of the first transmission plane incident the blind area that detector forms in existing imaging system, by the light of the first transmission plane 5 incidents of extrawide angle lens 1 in extrawide angle lens inside successively after the first reflecting surface 6, the second reflecting surface 7 reflect, reflect through the second transmission plane 8 again, then the overall view ring belt imaging region 17 to detector face through follow-up lens combination transmission imaging.

As shown in Figure 4, extrawide angle lens 1 and 2 actings in conjunction of follow-up lens combination produce focal power, make to be deflected by the light of extrawide angle lens the first transmission plane incident, converge and are imaged on overall view ring belt imaging region 17.As shown in Figure 4, front lens group, extrawide angle lens and follow-up lens combination acting in conjunction produce focal power, make to be deflected by the light of extrawide angle lens the second reflecting surface incident, converge in the detector center imaging region 16 being imaged on detector.As shown in Figure 4, all the other peripheral regions of detector are the non-imaging region 18 of detector.

Embodiment 1:

According to the structure construction light path of the utility model system, wherein optical region is selected: A light 450nm, B light 650nm; Optical thin film adopts the cut-off of 450nm band of light, and reflects, and 650nm band of light is filtered, and the wavelength spectro-film of transmission occurs.

It is the glass of F5 that extrawide angle lens 1 is selected the trade mark, and it is two kinds of glass of QK3, F7 that follow-up lens combination 2 is selected the trade mark, and the A light of 450nm and the B light of 650nm all can be propagated in above-mentioned three kinds of glass kinds.

It is two kinds of glass of LAF3, LAK3 that front lens group 4 is selected the trade mark, and the B light of 650nm can be propagated in above-mentioned two kinds of glass.

The A light of 450nm wave band enters to inject optical system from extrawide angle lens the first transmission plane 5, after reflecting, rear chance extrawide angle lens the first reflecting surface 6 turns back, meet again extrawide angle lens the second reflecting surface 7, there is owing to being coated with one deck on extrawide angle lens the second reflecting surface 7 optical thin film reflecting by 450nm band of light, make after the reflection of this light by the second transmission plane 8 outgoing, proofread and correct light transmition direction by follow-up lens combination 2, finally converge and image in detector image planes overall view ring belt imaging region 17 in the outer part.

The B light of 650nm wave band enters to inject optical system from front end lens combination front surface 13, after front lens group 4, the deflection of radiation direction generation part, arrive extrawide angle lens the second reflecting surface 7 places, owing to being coated with the optical thin film of one deck by 650nm band of light generation transmission on extrawide angle lens the second reflecting surface 7, make this light transmission enter extrawide angle lens 1, proofread and correct light transmition direction through follow-up lens combination 2 again, finally converge and image in the blind area 12 being formed by the imaging of 450nm band of light in detector image planes.

Embodiment 2:

According to the structure construction light path of the utility model system, wherein optical region is selected: A light 355nm, B light 800nm; Optical thin film adopts the cut-off of 355nm band of light, and reflects, and 800nm band of light is filtered, and the wavelength spectro-film of transmission occurs.

It is the glass of F_SILICA that extrawide angle lens 1 is selected the trade mark, and it is three kinds of glass of CAF2, PBL1Y, SAPPHIRE that follow-up lens combination 2 is selected the trade mark, and the A light of 355nm and the B light of 800nm all can be propagated in above-mentioned four kinds of glass kinds.

It is two kinds of glass of F_SILICA, QF5 that front lens group 4 is selected the trade mark, and the B light of 800nm can be propagated in above-mentioned two kinds of glass.

The A light of 355nm wave band enters to inject optical system from extrawide angle lens the first transmission plane 5, after reflecting, rear chance extrawide angle lens the first reflecting surface 6 turns back, meet again extrawide angle lens the second reflecting surface 7, there is owing to being coated with one deck on extrawide angle lens the second reflecting surface 7 optical thin film reflecting by 355nm band of light, make after the reflection of this light by the second transmission plane 8 outgoing, proofread and correct light transmition direction by follow-up lens combination 2, finally converge and image in detector image planes overall view ring belt imaging region 17 in the outer part.

The B light of 800nm wave band enters to inject optical system from front end lens combination front surface 13, after front lens group 4, the deflection of radiation direction generation part, arrive extrawide angle lens the second reflecting surface 7 places, owing to being coated with the optical thin film of one deck by 800nm band of light generation transmission on extrawide angle lens the second reflecting surface 7, make this light transmission enter extrawide angle lens 1, proofread and correct light transmition direction through follow-up lens combination 2 again, finally converge and image in the blind area 12 being formed by the imaging of 355nm band of light in detector image planes.

Above-mentioned embodiment is used for the utility model of explaining; instead of the utility model is limited; in the protection domain of spirit of the present utility model and claim, any amendment and change that the utility model is made, all fall into protection domain of the present utility model.

Claims (6)

1. one kind is utilized optical thin film to realize refraction-reflection blind-area-free panoramic endless belt imaging system, comprise coaxial mounted extrawide angle lens (1), be placed in follow-up lens combination (2) and the detector at extrawide angle lens (1) rear, extrawide angle lens (1) comprises the first transmission plane (5), the first reflecting surface (6), the second reflecting surface (7) and the second transmission plane (8), it is characterized in that: be provided with the front lens group (4) for proofreading and correct optical propagation direction in extrawide angle lens (1) front, front lens group (4) is coaxial with extrawide angle lens (1), front lens group (4) is proofreaied and correct the direction of propagation by front lens group front surface (13) incident light, second reflecting surface (7) of extrawide angle lens (1) is coated with one deck selective optical film, this optical thin film makes the light that is mapped to the second reflecting surface (7) from extrawide angle lens (1) only carry out transmission, and the light that is mapped to the second reflecting surface (7) in extrawide angle lens (1) is only reflected, the light of front lens group front end incident is imaged onto on detector center imaging region (16) through the second reflecting surface (7) and follow-up lens combination (2) post-concentration of extrawide angle lens (1) more successively by front lens group (4) refraction, by the light of the first transmission plane (5) incident of extrawide angle lens (1) in extrawide angle lens (1) inside successively after the first reflecting surface (6), the second reflecting surface (7) reflection, reflect through the second transmission plane (8) again, then the overall view ring belt imaging region (17) to detector face through follow-up lens combination (2) transmission imaging.

2. one according to claim 1 utilizes optical thin film to realize refraction-reflection blind-area-free panoramic endless belt imaging system, it is characterized in that: described extrawide angle lens (1) and follow-up lens combination (2) make to be propagated by the light of extrawide angle lens (1) second reflecting surface (7) incident and the luminous energy of the first transmission plane (5) incident simultaneously.

3. one according to claim 1 utilizes optical thin film to realize refraction-reflection blind-area-free panoramic endless belt imaging system, it is characterized in that: the described light by extrawide angle lens (1) second reflecting surface (7) incident and be respectively the light of different-waveband by the light of the first transmission plane (5) incident.

4. one according to claim 1 utilizes optical thin film to realize refraction-reflection blind-area-free panoramic endless belt imaging system, it is characterized in that: described front lens group (4) is formed by the optical lens combination of multi-disc different materials, and the light of being located incident by extrawide angle lens (1) second reflecting surface (7) can be propagated.

5. one according to claim 1 utilizes optical thin film to realize refraction-reflection blind-area-free panoramic endless belt imaging system, it is characterized in that: described optical thin film adopts spectro-film, by wavelength region may, light beam is carried out to selectivity and thoroughly reflects.

6. one according to claim 5 utilizes optical thin film to realize refraction-reflection blind-area-free panoramic endless belt imaging system, it is characterized in that: described optical thin film carries out selective transmission to the light of being located incident by extrawide angle lens (1) second reflecting surface (7), and the light of the first transmission plane (5) being located to incident carries out selective reflecting.