CN201055372Y

CN201055372Y - Rigid pipe type common-path type endoscopic OCT parallel imaging system

Info

Publication number: CN201055372Y
Application number: CNU2007201121530U
Authority: CN
Inventors: 丁志华; 杨亚良; 吴兰
Original assignee: Zhejiang University ZJU
Current assignee: Zhejiang University ZJU
Priority date: 2007-07-20
Filing date: 2007-07-20
Publication date: 2008-05-07
Anticipated expiration: 2017-07-20

Abstract

The utility model discloses a rigid tube type common path endoscopic OCT parallel imaging system. The utility model applies the Grimm rod lens with integral multiple cycle length as the light-transmission element of an endoscopic probe, uses a cylindrical lens to realize the line-focus lighting on the cavity wall and utilizes an Matrix CCD detector to perform the parallel detection of spectral domain signals. The front side of the Grimm rod lens is arranged on the rear focal plane of the cylindrical lens, the integral multiple cycle length can ensure that the shape of the light beam transmitted to the rear side accords with the front incidence side. So the rear side can be regarded as a reference surface, which has a conjugate imaging relation with a sample. The rear side and the sample form a common path sensing interferometer, and the optical path difference between the rear side and the sample is compensated by another common path interferometer. The utility model is characterized in that the imaging quality is not affected by environment, speed is high, operation is simple, the structure of the endoscopic probe is compact, the replacement of the endoscopic probe is convenient and use is safe.

Description

Hard tube formula common path type endoscopic OCT parallel imaging system

Technical field

This utility model relates to medical science based endoscopic imaging technology and Optical Coherence Tomography Imaging Technology, especially relates in the conduct of a kind of Green's of employing rod lens spying upon the hard tube formula common path type endoscopic OCT parallel imaging system that head passes optical device.

Background technology

Medical science endoscope is a kind of noinvasive or minimally invasive medical instrument, by its doctor can the direct observation human internal organs the lesion tissue and the treatment that undergos surgery.The pathological changes on internal surface can only be observed by traditional medicine endoscope, and pathological changes often at first betides in the tomography of organ.The introducing of ultrasonic technique makes endoscope when observing the inner chamber mucosal surface, also can observe the tissue morphology of organ tomography, yet its resolution reaches the detection tissue abnormalities far away in the millimeter magnitude, the desired level of resolution of the organizational structure during as early stage canceration.

Optical coherent chromatographic imaging art (Optical Coherence Tomography, be called for short OCT) can non-invasively carry out visual observation to tomography structure, physiological function and even the molecular information of biological tissue, possess the required high-resolution of histopathological analysis (reaching 1～20 μ m), can bring into play clinical function such as pathological changes early diagnosis, process monitoring and operation mediation.OCT also have fast, the radiationless damage of image taking speed, information diversification, with the compatible advantage such as good of existing Medical Instruments, be at present by extensive imaging tool good, that can on clinical medicine, play a significant role.Therefore, the OCT technology with in the technology of the peeping endoscopic OCT technology that combines and form, can provide objective basis for doctor's correct diagnosis.

Existing endoscopic OCT system, (the Guillermo J.Tearney of Fujimoto group as U.S. MIT, et al., In vivo endoscopic optical biopsy with optical coherence tomography, Science, 1997,276:2037～2039), (the Tuqiang Xie of Chen group of University of California, et al., Fiber-optic-bundle-based optical coherence tomography, Optics Letters, 2005,30 (14): 1803～1805) system that proposes such as, generally adopt optical fiber or fibre bundle as in spy upon the biography optical device of head, and probe is placed on the sample arm of interference structure.Because system is non-common path interference structure, chromatic dispersion that optical fiber or fibre bundle exist and polarization state change, and factors such as variation of ambient temperature and vibration, and image quality is significantly descended.Therefore, must consider above-mentioned factor is accurately mated, make the formation and the dysregulation complexity of system.And each replacing of probe all need be carried out the complex operations such as light path coupling, dispersion compensation and polarization state adjusting of big stroke range.

In spy upon head branch soft, hard tube arranged, wherein spy upon head in the hard tube formula and have the characteristics of image definition height, processing ease, and be extensive use of by the medical worker.(the Tuqiang Xie of Chen group, et al., GRIN lensrod based probe for endoscopic spectral domain optical coherence tomography withfast dynamic focus tracking, Optics Express, 2006,14 (8): 3238～3246) proposed based on Green's rod lens (GRIN lens rod, gradient index rod lens) spies upon head in the hard tube formula, but be placed on the sample arm of non-common path interference structure, have identical problem with above-mentioned endoscopic OCT system.In addition, owing to adopt the crosswise spots scan mode, the system that makes needs a cover complicated sweep mechanism, imaging time elongated and need just can obtain two dimension or 3-D view through image reconstruction.

Summary of the invention

In order to overcome disadvantages of background technology, the purpose of this utility model provides a kind of hard tube formula common path type endoscopic OCT parallel imaging system.This system the end face reflection light of Green rod lens as reference light, it and constitute a sensing interferometer on road altogether from the flashlight of sample, the optical path difference between reference light and the flashlight is compensated by another common path interference instrument; The parallel spectral coverage OCT technology that adopts line focus illumination, area array CCD to survey need not to scan the two dimensional image that can obtain sample fast.

The technical scheme that its technical problem that solves this utility model adopts is:

The light that wideband light source sends meets optical circulator port a, the light that sends by optical circulator port b after first collimating lens, broadband beam split plain film to the reflecting mirror that is contained on the electronic control translation stage; The light that is returned by reflecting mirror and broadband beam split plain film is to port b, again by optical circulator port c outgoing, then behind second collimating lens and post lens, to the broadband Amici prism; By the light of broadband Amici prism transmission, successively behind Green rod lens, Green lens, corner cube prism to sample; After the light that is back to the broadband Amici prism by the rear end face of sample and Green rod lens is reflected, successively behind the 3rd collimating lens, optical fiber image transmission beam, the 4th collimating lens, diffraction grating and imaging len, to the area array CCD detector; One end of second collimating lens, post lens, broadband Amici prism, Green's rod lens, the 3rd collimating lens and optical fiber image transmission beam is installed in the supporting box; Electronic control translation stage dough-making powder battle array ccd detector is connected with control system.

Described control system comprises image pick-up card, computer and controllor for step-by-step motor, and the area array CCD detector is through image acquisition clamping computer, and computer connects electronic control translation stage through controllor for step-by-step motor.

Described reflecting mirror is the broadband high reflection mirror.

The length of described Green rod lens is the integral multiple Cycle Length, and front end face is positioned on the front focal plane of the back focal plane of post lens and the 3rd collimating lens.

The length of described Green lens is less than four/one-period length, and the rear end face of its end and Green's rod lens is bonding, and a right-angle side of the other end and corner cube prism is bonding.

The front end face of described optical fiber image transmission beam is positioned on the back focal plane of the 3rd collimating lens, and rear end face is positioned on the front focal plane of the 4th collimating lens.

Described diffraction grating is positioned on the front focal plane of the back focal plane of the 4th collimating lens and imaging len, and the groove direction is parallel to the line illumination direction on the sample.

The photosurface of described area array CCD detector is positioned on the back focal plane of imaging len.

Compare with background technology, the beneficial effect that the utlity model has is:

1, this utility model is the common path interference structure, image quality is affected by environment hardly: the rear end face of Green's rod lens and sample constitute a sensing interferometer on road altogether, optical path difference between the two is compensated by another common path interference instrument, whole system is the common path interference structure, have variation of ambient temperature, vibration, the insensitive characteristics of factor such as device chromatic dispersion, image quality is guaranteed;

2, the utlity model has image taking speed characteristics fast, simple to operate: adopt the post lens to realize the line focus of internal chamber wall is thrown light on, utilize the area array CCD detector to carry out the parallel detecting of spectral domain signal, need not to scan the two dimensional image that can obtain sample fast, avoided complicated sweep mechanism and by the image reconstruction work of one dimension to two dimension.Parallel imaging technique combines with spectral domain techniques, is the optimal path of realizing the OCT realtime imaging;

3, this utility model adopts the biography optical device of spying upon head in the conduct of Green's rod lens, it is mutually bonding with the corner cube prism of the Green lens that plays focussing force, turnover beam direction, constitute in the hard tube formula and spy upon head, have and be not subjected to inner chamber gas characteristics of interference, can obtain the picture rich in detail of internal chamber wall;

4, this utility model can be changed to use and spy upon head in different according to concrete application occasion, regulates and need not that system is carried out complexity, and the light path that only need carry out little stroke range mates and gets final product.And existing endoscopic OCT system generally need carry out the complex operations such as light path coupling such as chromatic dispersion coupling, polarization state adjusting and big stroke range;

5, this utility model design in spy upon head and have compact conformation, characteristics safe in utilization: inner number of devices processing and the assembly relation less, each device that uses of probe is simple, be convenient to realize the miniaturization of popping one's head in, make it easilier enter various organs and carry out imaging; Inner no any moving component of probe and drive current have very high safety.

Description of drawings

Fig. 1 is a system schematic of the present utility model;

Fig. 2 is used to illustrate that light beam passes through the light path expansion sketch map that changes behind the post lens in two verticals;

Fig. 3 is a control system sketch map of the present utility model.

Among the figure: 1. wideband light source, 2. optical circulator, 3. first collimating lens, 4. broadband beam split plain film, 5. reflecting mirror, 6. electronic control translation stage, 7. second collimating lens, 8. post lens, 9. broadband Amici prism, 10. supporting box, 11. Green's rod lens, 12. Green lens, 13. corner cube prisms, 14. sample, 15. the 3rd collimating lens, 16. optical fiber image transmission beams, 17. the 4th collimating lens, 18. diffraction grating, 19. imaging len, 20. area array CCD detectors, 21. image pick-up cards, 22. computer, 23. controllor for step-by-step motor.

The specific embodiment

Below in conjunction with drawings and Examples this utility model is further described:

The hard tube formula common path type endoscopic OCT parallel imaging system that the utility model proposes as shown in Figure 1, the light that wideband light source 1 sends meets optical circulator 2 port a, again by optical circulator 2 port b outgoing to the first collimating lens 3, be divided into reflected light and transillumination during collimation back parallel incident broadband beam split plain film 4, the parallel incident of transillumination is fixed on the reflecting mirror 5 on the electronic control translation stage 6.Reflecting mirror 5 adopts broadband high reflectance minute surface, specifically can be metal one deielectric-coating broadband high reflection mirror, has high energy utilization rate to guarantee system.

After the light beam after 4 reflections of mirror 5 and broadband beam split plain film of being reflected turns back to optical circulator 2 port b along former road, again by optical circulator 2 port c outgoing to the second collimating lens 7, the parallel incident post lens 8 in collimation back.Light beam is by behind the post lens 8, do not have focussing force at the post axis of lens (being made as the x-z face) in the face that constitutes with optical axis, still is parallel light emergence; And (being made as the y-z face) has focussing force in the face that the post lens radially constitute with optical axis, and light beam focuses on to its back focal plane.For intuitive display and narration convenience, the situation of change of beam shape in above-mentioned two orthogonal of having drawn respectively among Fig. 2, and launching to draw along optical axis from post lens 8 later light paths.What provide in Fig. 1 is the sketch map in the y-z face.

In Fig. 1, also promptly in the y-z face in Fig. 2, post lens 8 are equivalent to a convex lens, and on the front end face of light beam through focusing on Green's rod lens 11 after 9 transmissions of broadband Amici prism that is come by its, this end face is positioned on the front focal plane of the back focal plane of post lens 8 and the 3rd collimating lens 15.The length of Green rod lens 11 is integral multiple Cycle Length (specifically being determined by the position of required imaging), and the beam shape that can guarantee to transfer to rear end face is consistent with the incident front end face.And end face has about 2% reflectance, thus can be rear end face as reference face, it and sample 14 have the conjugate imaging relation, and the two constitutes one and approaches interferometer common road, that play the sensing effect.The light beam that transfers to Green's rod lens 11 rear end faces is divided into transillumination and reflected light.Transillumination is with bigger dispersion angle outgoing, focused on the back with less dispersion angle outgoing by Green lens 12, changed after 90 ° of directions incident sample 9 from the side by corner cube prism 13 again.The length of Green lens 12 is less than four/one-period length, and concrete numerical value determined by the length of required focal length, and its end is bonding with the rear end face of the excellent lens 11 of Green, a right-angle side of the other end and corner cube prism 13 is bonding.

By sample 14 reflection or backward scattered light with by the light of Green's rod lens 11 rear end faces reflection, Yan Yuanlu is reflected after being back to broadband Amici prism 9, again the front end face of parallel incident optical coherent fiber bundle 16 behind the 3rd collimating lens 15 collimations.Light beam by optical fiber image transmission beam 16 rear end face outgoing is focused on diffraction grating 18 by the 4th collimating lens 17.Diffraction grating 18 is positioned on the front focal plane of the back focal plane of the 4th collimating lens 17 and imaging len 19, and the grating line direction is consistent with line illumination direction y.Focused beam directly sees through along the groove slit of diffraction grating 18, is collimated into the image planes of collimated light beam plane of incidence battle array ccd detector 20 behind the arrival imaging len 19.The image planes of area array CCD detector 20 are positioned on the back focal plane of imaging len 19, and pixel count pixel column how is used to survey the spectral information that chromatic dispersion is come along x direction layout; The few pixel column of pixel count is then along the y direction, is used to survey the sample 14 field of illumination imaging of reaching the standard grade.

In x-z face shown in Figure 2, by the front end face of the light beam of post lens 8 parallel incident Green rod lens 11 after 9 transmissions of broadband Amici prism, the light beam that transfers to rear end face is divided into transillumination and reflected light.Focused on by Green lens 12 after the parallel outgoing of transillumination, changed after 90 ° of directions incident sample 9 from the side by corner cube prism 13 again.The shape of above-mentioned x-z face and y-z face inner light beam is combined, be incident on light beam on the sample 14 as can be known and be one, be the line focus illumination along the axial fine rule of y.Be back to the light beam of broadband Amici prism 9 from the former road of sample 14 and Green rod lens 11 rear end faces, parallel incident the 3rd collimating lens 15 in back that is reflected is focused on the front end face of optical fiber image transmission beam 16 again.Light beam by optical fiber image transmission beam 16 rear end face outgoing is collimated the parallel incident diffraction grating 18 in back by the 4th collimating lens 17, and the light beam that chromatic dispersion is come behind the diffraction is focused on the image planes of area array CCD detector 20 by imaging len 19.

The front end face of second collimating lens 7, post lens 8, broadband Amici prism 9, Green's rod lens 11, the 3rd collimating lens 15 and optical fiber image transmission beam 16 is fixed on the supporting box 10.Electronic control translation stage 6 dough-making powder battle array ccd detectors 20 are connected with control system.

Control system of the present utility model comprises image pick-up card 21, computer 22, controllor for step-by-step motor 23 as shown in Figure 3.Computer 22 is interfered the collection of spectral domain signal by image pick-up card 21 chain of command battle array ccd detectors 20, and the signal input computer 22 that collects is carried out information processing and pictorial display such as one dimension inverse fourier transform.Computer 22 drives electronic control translation stage 6 through controllor for step-by-step motor 23 output signals, is being with reflecting mirror 5 to move axially by it, carries out the light path coupling between flashlight and the reference light.

Area array CCD detector 20 and image pick-up card 21 can be bought from market, respectively as the CHEETAH InGaAs area array CCD detector of Belgian XenICs company and the PCI-1409 image pick-up card of American National Instrument Instruments company.Electronic control translation stage 6 and controllor for step-by-step motor 23 are auxiliary products, can buy together, as the automatically controlled translation stage of TSA25-S-DS ultraprecise and the SC series controllor for step-by-step motor of Beijing Zolix Instrument Co., Ltd..

Its concrete steps of this utility model are as follows:

1) computer drives the electronic control translation stage band by controllor for step-by-step motor and reflecting mirror and move axially, and the optical path difference of the plane of reference and sample room is compensated;

2) gather interference signal by the area array CCD detector, obtain sample wire illumination direction y and go up the light intensity of every bit (y k) distributes, and through image pick-up card input computer about the spectral domain signal I of wave number k;

3) (y k) carries out the one dimension inverse fourier transform along the spectral evolution direction, and (y z) distributes, and (y z) is the two dimensional image of sample illumination direction y along the line and depth direction z to I about the signal I of depth location z to obtain light intensity to spectral domain signal I by computer.

The above-mentioned specific embodiment is used for this utility model of explaining; rather than this utility model limited; in the protection domain of spirit of the present utility model and claim, any modification and change to this utility model is made all fall into protection domain of the present utility model.

Claims

1. hard tube formula common path type endoscopic OCT parallel imaging system, it is characterized in that: the light that wideband light source (1) sends meets optical circulator (2) port a, the light that sends by optical circulator (2) port b after first collimating lens (3), broadband beam split plain film (4) to the reflecting mirror (5) that is contained on the electronic control translation stage (6); The light that is returned by reflecting mirror (5) and broadband beam split plain film (4) is to port b, again by optical circulator (2) port c outgoing, then behind second collimating lens (7) and post lens (8), to broadband Amici prism (9).By the light of broadband Amici prism (9) transmission, successively behind Green rod lens (11), Green lens (12), corner cube prism (13) to sample (14); After the light that is back to broadband Amici prism (9) by the rear end face of sample (14) and Green rod lens (11) is reflected, successively behind the 3rd collimating lens (15), optical fiber image transmission beam (16), the 4th collimating lens (17), diffraction grating (18) and imaging len (19), to area array CCD detector (20); One end of second collimating lens (7), post lens (8), broadband Amici prism (9), Green's rod lens (11), the 3rd collimating lens (15) and optical fiber image transmission beam (16) is installed in supporting box (10) lining; Electronic control translation stage (6) dough-making powder battle array ccd detector (20) is connected with control system.

2. hard tube formula common path type endoscopic OCT parallel imaging according to claim 2 system, it is characterized in that: described control system comprises image pick-up card (21), computer (22) and controllor for step-by-step motor (23), area array CCD detector (20) connects computer (22) through image pick-up card (21), and computer (22) connects electronic control translation stage (6) through controllor for step-by-step motor (23).

3. hard tube formula common path type endoscopic OCT parallel imaging according to claim 1 system, it is characterized in that: described reflecting mirror (5) is the broadband high reflection mirror.

4. hard tube formula common path type endoscopic OCT parallel imaging according to claim 1 system, it is characterized in that: the length of described Green rod lens (11) is the integral multiple Cycle Length, and front end face is positioned on the front focal plane of the back focal plane of post lens (8) and the 3rd collimating lens (15).

5. hard tube formula common path type endoscopic OCT parallel imaging according to claim 1 system, it is characterized in that: the length of described Green lens (12) is less than four/one-period length, the rear end face of its end and Green's rod lens (11) is bonding, and a right-angle side of the other end and corner cube prism (13) is bonding.

6. hard tube formula common path type endoscopic OCT parallel imaging according to claim 1 system, it is characterized in that: the front end face of described optical fiber image transmission beam (16) is positioned on the back focal plane of the 3rd collimating lens (15), and rear end face is positioned on the front focal plane of the 4th collimating lens (17).

7. hard tube formula common path type endoscopic OCT parallel imaging according to claim 1 system, it is characterized in that: described diffraction grating (18) is positioned on the front focal plane of the back focal plane of the 4th collimating lens (17) and imaging len (19), and the groove direction is parallel to the line illumination direction on the sample (14).

8. hard tube formula common path type endoscopic OCT parallel imaging according to claim 1 system, it is characterized in that: the photosurface of described area array CCD detector (20) is positioned on the back focal plane of imaging len (19).