WO2021189451A1 - Système d'imagerie microscopique - Google Patents

Système d'imagerie microscopique Download PDF

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Publication number
WO2021189451A1
WO2021189451A1 PCT/CN2020/081793 CN2020081793W WO2021189451A1 WO 2021189451 A1 WO2021189451 A1 WO 2021189451A1 CN 2020081793 W CN2020081793 W CN 2020081793W WO 2021189451 A1 WO2021189451 A1 WO 2021189451A1
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WIPO (PCT)
Prior art keywords
lens group
microscopic imaging
unit
module
adjustable lens
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PCT/CN2020/081793
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English (en)
Chinese (zh)
Inventor
胡庆磊
黄凯
李宁
李梦婷
丁昶杰
Original Assignee
肯维捷斯(武汉)科技有限公司
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Priority to PCT/CN2020/081793 priority Critical patent/WO2021189451A1/fr
Publication of WO2021189451A1 publication Critical patent/WO2021189451A1/fr

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    • GPHYSICS
    • G02OPTICS
    • G02BOPTICAL ELEMENTS, SYSTEMS OR APPARATUS
    • G02B21/00Microscopes
    • G02B21/06Means for illuminating specimens
    • G02B21/08Condensers
    • G02B21/10Condensers affording dark-field illumination
    • GPHYSICS
    • G02OPTICS
    • G02BOPTICAL ELEMENTS, SYSTEMS OR APPARATUS
    • G02B21/00Microscopes
    • G02B21/24Base structure
    • GPHYSICS
    • G02OPTICS
    • G02BOPTICAL ELEMENTS, SYSTEMS OR APPARATUS
    • G02B21/00Microscopes
    • G02B21/36Microscopes arranged for photographic purposes or projection purposes or digital imaging or video purposes including associated control and data processing arrangements

Definitions

  • the present invention relates to the field of optical imaging technology, and more specifically, to a microscopic imaging system.
  • the traditional single microscope objective imaging solution is limited by the manufacturing process and the size of the image sensor, and cannot obtain the micron-level image resolution in the centimeter-level imaging field of view.
  • the current method for microscopic imaging of large-area samples is to move the optical system or observation samples on the basis of traditional microscopes.
  • the Chinese invention patent publication file with the application number CN201180009191.2 the solution is to add an electromechanical system such as a guide rail or a crank arm to move the optical system.
  • the Chinese utility model patent with the application number CN201420420879.0 and the application number is CN201610746297.5
  • the Chinese invention patent of, its method is to use an electromechanical device or a manual device to move the placing platform of the observed sample.
  • the array scheme can use parallel imaging modes to achieve large field of view and high-resolution imaging, but the traditional The microscope objective lens is relatively large, and the array mode will cause the imaging structure to be complex, bulky, and expensive.
  • the Chinese invention patent with application number CN201910585599.2 discloses a new type of objective lens array applied to multi-field parallel imaging. Its function realization mainly depends on the large-field high-performance small microscopic objective lens unit mentioned in its public document.
  • the Chinese invention patent No. CN201910743158.0 discloses an array type microscopic image acquisition system with a transmission illumination light source.
  • CN201910743162.7 discloses an array type microscope image acquisition system with a reflective illumination light source. Image acquisition system. This type of imaging solution realizes a small-volume, low-cost array solution by changing the structure of the traditional microscope objective lens.
  • the accuracy of focusing is the key to imaging quality assurance.
  • the depth of field of a high-resolution microscopy imaging system is within tens of microns, and the flatness of tens of microns is guaranteed in the centimeter-level field of view, which is important for the design, processing, assembly, operation, and stability of the imaging system. All are extremely demanding.
  • some samples with large fluctuations, such as stacked cell samples the sample itself has unevenness.
  • the technical problem to be solved by the present invention is to provide a microscopic imaging system in view of the above-mentioned partial technical defects of the prior art.
  • the technical solution adopted by the present invention to solve its technical problems is: constructing a microscopic imaging system; including:
  • a plurality of unit microscopic imaging modules arranged according to a preset rule, and a data acquisition card connected to the plurality of unit microscopic imaging modules;
  • each of the unit microscopic imaging modules respectively includes an adjustable lens group capable of independently adjusting focus, and a photosensitive module corresponding to the adjustable lens group;
  • the data acquisition card is provided with a plurality of image processing modules respectively corresponding to the plurality of unit microscopic imaging modules; each of the image processing modules independently controls the focus and focus of the corresponding adjustable lens group. And obtain the data corresponding to the photosensitive module.
  • the microscopic imaging system further includes a fixing mechanism provided on the data acquisition card, and each of the adjustable lens groups is independently fixed to the data acquisition card by the fixing mechanism.
  • the adjustable lens group includes a second lens group disposed close to the photosensitive module and a first lens group disposed away from the photosensitive module;
  • Each of the unit microscopic imaging modules includes a focus motor, which is connected to any one of the first lens group and the second lens group, and can adjust the first lens
  • the relative positions of the lens group and the second lens group are used to realize the focusing of the adjustable lens group.
  • the focusing motor is packaged together with any lens group connected to it into an integrated package module.
  • the other lens group of the first lens group and the second lens group is fixedly connected to the fixing mechanism;
  • the fixing mechanism includes a lens group fixing seat, and the other lens group of the first lens group and the second lens group is threadedly connected with the lens group fixing seat.
  • a microscopic imaging system of the present invention further includes an illumination module corresponding to the multiple unit microscopic imaging modules, and the illumination module includes:
  • a first illuminating light source arranged above the unit microscopic imaging module;
  • the second illuminating light source uniformly arranged around each of the unit microscopic imaging modules is fixed to the light guide structure above the second illuminating light source.
  • the first illumination light source includes a fluorescence excitation light source
  • the unit microscopic imaging module further includes a fluorescence excitation filter disposed on the lower end surface, inside or upper end surface of the adjustable lens group; or
  • the first illuminating light source includes a first dark field illuminator that is disposed above the adjustable lens group and corresponds to the adjustable lens group;
  • the second illuminating light source further includes a second dark field illuminator corresponding to the adjustable lens group and arranged above the adjustable lens group.
  • the first dark field illuminator includes an array of LED light sources with a first circular through-hole in the housing or a white backlight light source with a second circular through-hole in the housing, the first circular through-hole and the second The circular through hole is arranged opposite to the adjustable lens group;
  • the second dark field illuminator includes a bright and dark field substrate and a dark field black background patch, the dark field black background patch matches the size of the adjustable lens group, and the dark field black background patch is opposite to
  • the bright and dark field substrates are arranged close to or far from the adjustable lens group.
  • the white light backlight source includes:
  • the apertured backlight source is arranged on the upper two sides of the adjustable lens group, the opening direction of the apertured backlight source is parallel to the upper surface of the adjustable lens group;
  • the image processing module includes an image signal processing unit, a data buffer unit, a motor control unit and a data transmission interface;
  • the image signal processing unit and the motor control unit are correspondingly connected with the photosensitive module and the focusing motor through flat cables;
  • the microscopic imaging system further includes a main controller and an image display unit, the main controller is connected to the image processing unit via the data buffer unit, and the main controller is connected to the image signal processing unit via a first bus The unit is connected to the image display unit through a second bus.
  • the main controller and the image display unit are integrated in a smart terminal.
  • a microscopic imaging system implementing the present invention has the following beneficial effects: the independent adjustable focus design reduces the consistency requirement of unit module assembly and improves the production efficiency of its finished products.
  • Fig. 1 is a schematic structural diagram of a first embodiment of a microscopic imaging system of the present invention
  • Fig. 2 is a schematic structural diagram of a first embodiment of the unit microscopic imaging module in Fig. 1;
  • FIG. 3 is a schematic structural diagram of a second embodiment of the unit microscopic imaging module in FIG. 1;
  • FIG. 4 is a schematic structural diagram of a third embodiment of the unit microscopic imaging module in FIG. 1;
  • Fig. 5 is a schematic structural diagram of a second embodiment of a microscopic imaging system of the present invention.
  • Fig. 6 is a schematic structural diagram of a third embodiment of a microscopic imaging system of the present invention.
  • FIG. 7 is a schematic cross-sectional structure diagram of the first embodiment of the unit microscopic imaging module in FIG. 5 or FIG. 6; FIG.
  • FIG. 8 is a schematic cross-sectional structure diagram of the second embodiment of the unit microscopic imaging module in FIG. 5 or FIG. 6;
  • FIG. 9 is a schematic cross-sectional structure diagram of the third embodiment of the unit microscopic imaging module in FIG. 5 or FIG. 6;
  • FIG. 10 is a schematic cross-sectional structure diagram of a fourth embodiment of a microscopic imaging system of the present invention.
  • FIG. 11 is a schematic cross-sectional structure diagram of a fifth embodiment of a microscopic imaging system of the present invention.
  • Fig. 12 is a schematic structural diagram of a sixth embodiment of a microscopic imaging system of the present invention.
  • FIG. 13 is a schematic cross-sectional structure diagram of an embodiment of the microscopic imaging system of FIG. 12; FIG.
  • FIG. 14 is a schematic cross-sectional structure diagram of another embodiment of the microscopic imaging system of FIG. 12;
  • FIG. 15 is a schematic cross-sectional structure diagram of a seventh embodiment of a microscopic imaging system of the present invention.
  • FIG. 16 is a schematic cross-sectional structure diagram of an eighth embodiment of a microscopic imaging system of the present invention.
  • a microscopic imaging system of the present invention includes: a plurality of unit microscopic imaging modules 101 arranged according to a preset rule, and a plurality of unit microscopic imaging modules 101; 101 is connected to the data acquisition card 102; wherein each unit of the microscopic imaging module 101 includes an adjustable lens group that can independently adjust the focus and a photosensitive module corresponding to the adjustable lens group; the data acquisition card 102 is provided with multiple There are image processing modules respectively corresponding to the multiple unit microscopic imaging modules 101 one-to-one; each image processing module independently controls the focus of its corresponding adjustable lens group and obtains the data of the corresponding photosensitive module.
  • the multiple unit microscopic imaging modules 101 can be arranged in a preset manner, for example, in an array.
  • the distance between the display imaging modules of each unit can be set reasonably.
  • the distance between the multiple unit microscopic imaging modules 101 needs to be set as small as possible, which is usually set to the smallest physical distance on the physical structure set up.
  • Each unit microscopic imaging module 101 includes an adjustable lens group and a photosensitive module corresponding to the adjustable lens group. The adjustable lens group of each unit microscopic imaging module 101 can independently adjust the focus.
  • the data acquisition card 102 is provided with an image processing module, the image processing module corresponds to the unit microscopic imaging module 101 one-to-one, and is used to control the independent focusing of the adjustable lens groups of the multiple unit microscopic imaging modules 101 and obtain the photosensitive module at the same time Corresponding data. It uses multiple unit microscopic imaging modules 101 to construct a large centimeter-level field of view, and realizes the free adjustment of the focal plane of each unit microscopic imaging module 101, and each focal plane is in a non-parfocal discrete state.
  • the requirement for physical assembly to ensure the flatness of the multiple unit microscopic imaging modules 101 can be reduced, the pressure in the production and assembly process can be reduced, and the assembly efficiency can be improved.
  • the independent adjustable focus design of the unit microscopic imaging module 101 it can be used for high-quality imaging of uneven samples, ensuring that the focal planes in the field of view are in the best state during a single imaging process.
  • the microscopic imaging system of the present invention further includes a fixing mechanism 109 arranged on the data acquisition card 102, and each adjustable lens group is independently fixed to the data acquisition card 102 by the fixing mechanism 109.
  • a fixing mechanism 109 is provided on the data acquisition card 102, and the adjustable lens group is fixed by the fixing mechanism 109.
  • Each adjustable lens group can be independently fixed by the fixing mechanism 109 without affecting each other.
  • the adjustable lens group includes a second lens group 1012 disposed close to the photosensitive module and a first lens group 1011 disposed away from the photosensitive module; each unit microscopic imaging module 101 includes The focus motor 1013, which is connected to any one of the first lens group 1011 and the second lens group 1012, can adjust the relative position of the first lens group 1011 and the second lens group 1012 to achieve adjustment The focus of the lens group.
  • the adjustable lens group includes a first lens group 1011 and a second lens group 1012. The second lens group 1012 is arranged close to the photosensitive module, and the first lens group is arranged away from the photosensitive module.
  • the group 101 is provided with a focus motor 1013 corresponding to the adjustable lens group, and the relative positions of the first lens group 1011 and the second lens group 1012 are adjusted by the focus motor 1013 to realize the focusing of the adjustable lens group.
  • the photosensitive module includes a circuit board 1016 fixed on the data acquisition card and a photosensitive chip 1015 arranged on the circuit board 1016.
  • the circuit board 1016 includes but is not limited to a printed circuit board, a flexible circuit board, and the like.
  • the photosensitive chip 1015 is fixedly placed at the image-side focal plane of the second lens group 1012, the light condensed by the second lens group 1012 is incident on the photosensitive chip 1015, and the photosensitive chip 1015 performs photoelectric conversion on the sensed light.
  • the photosensitive chip 1015 is an area-array photoelectric device, for example, the photosensitive chip 1015 is a CMOS image sensor or a CCD image sensor.
  • the first lens group 1011 and the second lens group 1012 form an approximate infinity-corrected microscope structure, and the first lens group 1011 and the second lens group 1012 have positive refractive power.
  • the first lens group 1011 corresponds to an objective lens of a microscope
  • the second lens group 1011 corresponds to a tube lens of a microscope.
  • the focus motor 1013 drives one of the first lens group 1011 and the second lens group 1012 to achieve focus adjustment, that is, to change the object plane or image plane position of the imaging module.
  • the object surface closest to the imaging module is called the near-focus object surface, and the object surface farthest from the imaging module is called the far-focus object surface. And define the direction away from this module as the positive direction.
  • the object side surface of the protective glass is the limit surface.
  • the imaging module The end surface of the object side of the shell or other mechanical structure that cooperates with the imaging module is the limit surface.
  • the near-focus object surface is within ⁇ 50 ⁇ m of the limit surface, and the distance between the far-focus object surface and the limit surface is ⁇ 220 ⁇ m.
  • the stroke of the focusing motor 1013 is ⁇ 300 ⁇ m and ⁇ 600 ⁇ m.
  • the minimum distance between the first lens group 1011 and the second lens group 1012 (the minimum distance between the surface of the optical lens, not the distance between the mechanical housing of the lens group) ⁇ 50 ⁇ m, when there is a protective glass, the first lens group
  • the minimum distance to the protective glass is ⁇ 30 ⁇ m.
  • the near-focus object surface can cover the short-distance area of the protective glass, which can image close objects, and the far-focus object surface can surpass the cover glass commonly used in microscopes, satisfying biomedicine
  • the need for imaging can also avoid the offset of the limit surface caused by the thickness tolerance of the protective glass
  • the motor stroke can effectively cover the dimensional tolerances of the components in the module due to processing and installation, which improves the manufacturability of mass production
  • the focus motor 1013 of each unit microscopic imaging module 101 can be individually controlled and a single microscopic image can be read, thereby ensuring that the imaging focal plane of the entire array system is in a non-parfo
  • the focus motor 1013 is packaged together with any lens group connected to it as an independent packaged module.
  • the focusing motor 1013 can be packaged with the first lens group 1011 or the second lens group 1012 connected to it to form an independent packaged module.
  • the independently packaged module can be fixed directly or fixed to the data acquisition card 102 by a fixing mechanism 109 superior.
  • the independent packaged module can also be fixed to the fixing mechanism 109 in a snap-fit manner to realize independent maintenance and replacement of the packaged module.
  • the other lens group of the first lens group 1011 and the second lens group 1012 is fixedly connected to the fixing mechanism 109; specifically, the other lens group not connected to the focusing motor 1013 can be fixed to the fixing mechanism 109
  • the package of the lens group is directly and integrally designed with the fixing mechanism 109.
  • the fixing mechanism 109 includes a lens group fixing seat 1014, and the other lens group of the first lens group 1011 and the second lens group 1012 is threadedly connected to the lens group fixing seat 1014.
  • the fixing mechanism 109 may also be provided with a lens group fixing seat 1014, the lens group fixing seat 1014 is provided with threads, and another lens group not connected to the focusing motor 1013 may be provided with corresponding threads, so as to realize the connection with the lens group fixing seat. 1014 sets the threaded connection of the fixing mechanism 109.
  • the microscopic imaging system of the present invention further includes an illumination module corresponding to the multiple unit microscopic imaging modules 101.
  • the illumination module includes a first illumination light source 104 arranged above the unit microscopic imaging module 101; that is, transmissive imaging can be realized by the first illumination light source 104 arranged above the unit microscopic imaging module 101.
  • the illumination module includes a second illumination light source uniformly arranged around each unit of the microscopic imaging module 101, and the positions of the light guide structure 202 and the second illumination light source are reasonably set to realize reflective imaging or Transmission imaging.
  • the first illumination light source includes a fluorescence excitation light source
  • the unit microscopic imaging module further includes a fluorescence excitation filter 302 arranged on the lower end surface, inside or upper end surface of the adjustable lens group; as shown in FIGS. 7 to 9
  • a corresponding fluorescence excitation filter 302 is also provided in the unit microscopic imaging module 101.
  • the setting position of the fluorescence excitation filter 302 can be set on the lower end surface, inside or on the adjustable lens group.
  • the fluorescence excitation light source is a specific wavelength band of oblique incidence laser 1041 or LED lamp beads 1042, which is fixed in the microscopic imaging system through a mechanical structure.
  • the light source illuminates the fluorescence detection sample in transmission, oblique incidence, side incidence, etc., and excites the fluorescence of the sample.
  • a fluorescence excitation filter 302 for fluorescence detection is added to the unit microscopic imaging module 101, the sample excited fluorescence passes through the fluorescence excitation filter 302, and the photosensitive module collects the fluorescence detection image of the sample.
  • the oblique incidence laser 1041 is used as the light source, a laser emitter can be used to provide transmission light sources for all the unit microscopic imaging modules 101. The location of the oblique incidence laser 1041 can ensure that all unit microscopic imaging modes can be covered as much as possible. Group 101.
  • the number of oblique incidence lasers 1041 can be set to multiple, which are injected from different angles to ensure that the unit The imaging light source of the microscopic imaging module 101 meets the requirements.
  • the first illumination light source includes a first dark field illuminator arranged above the adjustable lens group and corresponding to the adjustable lens group; when the first dark field illuminator is used, the first dark field illuminator
  • the device includes a housing with a first circular through-hole array arrangement of LED light sources 4011 or a housing with a second circular through-hole white light backlight source 401, a first circular through-hole and a second circular through-hole, and an adjustable lens
  • the groups are arranged relative to each other; that is, the specific structure of the diffuse reflection illuminator adopting transmissive illumination can be an LED light source 4011 with a round hole sub-gloss black shell or a white light backlight source 4013 with a round hole.
  • the housing round holes are arranged corresponding to the unit microscopic imaging module 101, the optical axis of the adjustable lens group of each unit microscopic imaging module 101 passes through the center of each round hole of the housing, and the size of each round hole is larger than the microscopic imaging of each unit
  • the field of view range of the module 101 is 10111.
  • the LED light source 4011 is arranged in an array around the round holes in the housing 4012 on a plane at a certain distance from the surface with holes.
  • the array arrangement distance range is that most of the emitted light 40111 illuminates the sample at a large angle and obliquely does not directly enter each Adjustable lens group shall prevail.
  • the surface of the PCB substrate 40112 where the LED light source 4011 and the module form a circuit connection should be matt black, or the field cone angle 10111 of each adjustable lens group should pass through the circular hole of the housing and fall on the circuit board with a circular through hole.
  • the matt black surface of the housing 4012 is exposed.
  • the backlight source with a circular hole 4013 is used for illumination, the backlight source board is arranged on a plane within a certain distance from the surface of the shell with a circular hole, and is shielded by the stray light shielding baffle 4014, so that the backlight source 4013 emits light from the effective light-emitting plane Point to the direction of the observation sample and the lens of the module.
  • the circular through holes on the backlight 4013 are arranged corresponding to the module array, and are coaxial with the circular holes on the surface of the casing.
  • the matt black surface of the casing is exposed in the lens field of view through the circular through holes of the backlight.
  • the edges of each hole The cone angle of the lens falls outside the range of the surface of the backlight source after passing through the circular hole of the housing.
  • a complete backlight source 4016 When a complete backlight source 4016 is attached to the back of the round hole backlight source 4013, its light intensity is strong, and the effective light-emitting surface of the complete backlight source 4016 covers the translucent black diffuse reflection sheet material 4015 and faces the sample and lens direction, and the complete backlight source 4016 is exposed
  • the emitted light from the part of the light-emitting area behind the circular hole of the back light source with circular through holes can transmit and illuminate the sample through the translucent black diffuse reflection sheet 4015, then this dark field illuminator also has bright field transmitted illumination
  • the function realizes the integration and miniaturization of the dark field illuminator and the bright field illuminator.
  • the above-mentioned illuminating light source is connected to the microscopic imaging module 101 of each unit through a wire or the like.
  • the second illuminating light source is provided on the upper end surface of the fixing mechanism 109; the second illuminating light source may be LED lamp beads 201 arranged in an array around the unit microscopic imaging module 101, which The emitted light propagates through the light guide structure 202 made of transparent or semi-transparent material.
  • the object side end surface of the light guide structure 202 is provided with a positioning surface for limiting the position of the sample, so that the sample surface is located on the object side focal plane of the adjustable lens group, and a special surface-shaped light guide surface is arranged around the adjustable lens group to make the object.
  • the illumination in the observation area is sufficient and uniform and soft, the light is reflected by the surface of the sample, and the unit microscopic imaging module 101 collects the reflected illumination image of the sample.
  • the second illumination light source further includes a second dark field illuminator disposed above the adjustable lens group and corresponding to the adjustable lens group.
  • the second dark field illuminator used includes a bright and dark field substrate 4017 and a dark field black background patch 4018.
  • the dark field black background patch 4018 matches the size of the adjustable lens group, and the dark field black background patch 4018 is relatively bright and dark.
  • the field substrate 4017 is set close to or far from the adjustable lens group.
  • the second dark field illuminator that is, the reflective dark field illuminator
  • the reflective dark field illuminator is a white diffuse reflection plate with a black diffuse reflection circular surface, and a plurality of black diffuse reflection circles
  • the curved surface corresponds to the array configuration of the unit microscopic imaging module 101, the center of the circle of each black diffuse reflection surface passes through the optical axis of each adjustable lens group, and the size of the circle is larger than the field of view of the unit microscopic imaging module 101,
  • the reflective plate is close to the back of the observation sample, and the above-mentioned reflective illuminating light source is used to illuminate the white diffuse reflection surface around the black circular area.
  • Part of the large-angle diffuse reflection light 2011 again illuminates the observation sample without directly entering the adjustable lens. Group, observe the diffuse reflection generated on the surface of the sample into the lens to produce a dark-field illumination image of the sample.
  • the image processing module includes an image signal processing unit, a data buffer unit, a motor control unit, and a data transmission interface; the image signal processing unit and the on-board circuit of the data acquisition card 102 directly form a circuit connection, the data acquisition card 102 and the motor control unit It is connected to the photosensitive module and the focusing motor 1013 respectively through the cable 106; the micro imaging system also includes a main controller 105 and an image display unit 103, the main controller 105 is connected to the image processing unit via the data buffer unit, and the main controller 105 The image signal processing unit is connected through the first bus 108, and the image display unit is connected through the second bus.
  • the image signal processing unit may also be integrated into the photosensitive module, and the photosensitive module is connected to the data acquisition card 102 through the flat cable 106 and then directly connected to the main controller 105 through the interface circuit of the flat cable 108.
  • the main controller 105 and the image display unit 103 are integrated in a smart terminal. That is, the image data can be received by the smart terminal for processing and display.
  • FIGS. 1 to 16 a specific embodiment of a microscopic imaging system of the present invention will be described in detail with reference to FIGS. 1 to 16.
  • the microscopic imaging system includes six unit microscopic imaging modules 101, which are arranged in an array structure with a minimum physical spacing, and are fixed
  • the mechanism 109 is fixed on the data acquisition card 102.
  • the six-unit microscopic imaging modules 101 are respectively connected to the data acquisition card 102 through the on-board cable interface 106.
  • a carrying platform (not shown in FIG. 1) for carrying the sample to be tested is arranged above the unit microscopic imaging module 101, and the sample 107 to be tested can be arranged on the carrying platform.
  • an illumination light source 104 is provided above the carrying platform.
  • the data acquisition card 102 is provided with six independent image processing chips (not shown in FIG.
  • the image processing chip obtains the photosensitive data through the photosensitive module for corresponding processing.
  • the data acquisition card 102 is provided with an interface bus 108.
  • the data acquisition card 102 is connected to the main controller 105 through the interface bus 108.
  • the main controller 105 obtains the photosensitive data of the six-unit microscopic imaging module 101 through the interface bus 108 and performs Corresponding processing, and imaging by the image display unit 103.
  • the image processing chip on the data acquisition card 102 includes an independent RAM and an ISP chip.
  • the main controller 105 is composed of an MTK6797 chip and a data storage ROM, and is used to analyze and store image data and drive the image display unit 103 to display the results.
  • the image display unit 103 uses a 5.5-inch OLED screen with a resolution of 1920*1080.
  • the illuminating light source 104 can use two LCD backlight panels with a color temperature of 5000k and a power of 0.06W LED light-emitting chips to provide transmitted illumination to the sample 107.
  • the adjustable lens group includes a first lens group 1011 close to the photosensitive module and a second lens group 1012 far from the photosensitive module.
  • the focal length f1 of the first lens group 1011 is 2.2 mm
  • the focal length f2 of the second lens group 1012 is 3 mm.
  • the distance TTL from the object surface to the image surface of the adjustable lens group on the optical axis is 8mm
  • the distance TD from the surface of the object side (close to the measured object) to the surface of the image side (close to the photosensitive module) on the optical axis is 6mm.
  • the first lens group 1011 is installed on the movable carrier of the focus motor 1013 by dispensing glue or other fixing methods.
  • the focus motor 1013 may be a voice coil motor, an ultrasonic motor, a memory alloy motor, or the like.
  • the stroke of the focus motor 1013 is 300 ⁇ m.
  • the unit microscopic imaging module is provided with a lens fixing seat 1014, which is provided with internal threads, and the second lens group 1012 has external threads, and the two are connected by threads.
  • the focusing motor 1013 drives the first lens group 1011 to move to achieve the function of focusing, and the position of the second lens group 1012 in the imaging light path is fixed.
  • the photosensitive module is arranged on the circuit board 1016, and the circuit board includes but is not limited to a printed circuit board, a flexible circuit board, and the like.
  • the light-sensing module is fixedly placed at the image-side focal plane of the second lens group 1012, the light condensed by the second lens group 1012 is incident on the light-sensing module, and the light-sensing module performs photoelectric conversion on the sensed light.
  • the photosensitive chip 1015 used in the photosensitive module is an area-array photoelectric device, and the photosensitive chip 1015 can also be a CMOS image sensor or a CCD image sensor.
  • the focus motor 1013 is placed downward, and the second lens group 1012 is installed on the movable carrier of the focus motor 1013 by dispensing or other fixing methods.
  • the first lens group 1012 has external threads and is threadedly connected with the lens holder 1014 provided with internal threads.
  • the focus motor 1013 drives the second lens group 1012 to move to achieve the function of focusing, and the position of the first lens group 1011 in the imaging light path is fixed. As shown in FIG.
  • the first lens group 1011 is connected to the mechanical fixing mechanism 109 through its packaging, and the second lens group 1012 driven by the focusing motor 1013 is used as a separate module with it.
  • the first lens group 1011 and the second lens group 1012 can be adopted according to different actual application requirements, and are not limited to the existing integrated packaged miniature microscope Camera module.
  • the illumination light source provided above the carrying platform is a fluorescent excitation light source
  • the fluorescent excitation light source may be an oblique incident laser 1041. It can use a 488nm wavelength laser.
  • a fluorescence excitation light source is used, a corresponding fluorescence excitation filter 302 is added to the microscopic imaging module 101 of each unit.
  • the illumination light source provided above the carrying platform is a fluorescent light source
  • the fluorescent excitation light source may adopt an LED light-emitting chip 1042. It can use 488nm wavelength LED light-emitting chips.
  • a fluorescence excitation light source is used, a corresponding fluorescence excitation filter 302 is added to the microscopic imaging module 101 of each unit.
  • FIG. 7 to 9 are different embodiments of the unit microscopic imaging module 101 in the embodiment shown in FIG. 5 and FIG. 6.
  • the fluorescence excitation filter 302 is located between the first lens group 1011 and the sample 107 in the unit microscopic imaging module 101. As shown in FIG. 8, in this embodiment, the fluorescence excitation filter 302 is located between the first lens group 1011 and the second lens group 1012 in the unit microscopic imaging module 101. As shown in FIG. 9, the fluorescence excitation The filter 302 is located between the second lens group 1012 and the photosensitive module in the unit microscopic imaging module 101.
  • the illuminating light source provided above the carrying platform is a dark field illuminator.
  • the dark field illuminator adopts an array arrangement of LED light sources 4011 with circular holes in the housing, and the number of LED lamp beads arranged in a uniform array around each unit module group is ⁇ 3, and most of the light in the small angle area of its luminous angle is Covered by the housing 4012, part of the light in the large-angle area irradiates the sample through the round hole of the housing and does not directly enter the lens after exiting.
  • the diffuse reflection light generated by the edge of the sample area with a height difference enters the lens module, and the background of the field of view in the module is LED
  • the illuminating light source provided above the carrying platform is a dark field illuminator.
  • the dark field illuminator uses a high-bright white light backlight 4013 with a hole.
  • the bottom surface of the hole can be made of a black diffuse reflection surface material.
  • a stray light shielding baffle 4014 is added to part of the light-emitting ring surface of the hole wall to block the black background at the bottom of the hole. Irradiation controls the light-emitting area and the angle at which the light illuminates the sample at the same time.
  • the diffuse reflection light generated by the edge of the part with a height difference enters the lens module to obtain a dark-field illumination image.
  • the hole bottom surface of the perforated backlight 4013 of this dark field illuminator is a black diffuse reflection surface translucent sheet 4015, then a complete backlight 4016 can be added, the perforated backlight 4013 is turned off, and the complete backlight 4013 is turned on.
  • Transmitted illumination of the sample that is, the dark field illuminator also has the function of bright field illumination.
  • the illumination light source adopts the reflective illumination light source
  • the reflective illumination light source adopts the white light LED lamp bead 201 as the light source.
  • the overall PCB circuit board is fixed with the module array formed by each unit module. And the LED lamp beads are evenly distributed around each unit module on the PCB circuit board to ensure that the sample lighting conditions in the field of view of each unit module are consistent.
  • the light guide structure 202 is fixed above the reflective illuminating light source.
  • the body material has a high light transmittance. Its surface is atomized, and there is a cone around the lens group to improve the lighting effect, reduce stray light, and make the lighting more uniform. The upper end surface is the sample positioning surface. Observe samples with low light transmittance through reflected illumination to achieve good imaging results.
  • 13 to 14 are different embodiments of the unit microscopic imaging module 101 in FIG. 12.
  • the unit microscopic imaging module 101 uses a focusing motor 1013 to drive the integral package module of the first lens group 1011, and the reflective illumination light source 201 is connected to the upper end surface of the mechanical fixing structure 109 , The emitted light 2011 is emitted through the cone hole surface of the light guide structure 202 and then irradiates the sample surface (the sample surface is limited by the upper end surface of the light guide structure 202), and the sample image is obtained by the camera module. It is also possible to use a unit microscopic imaging module under the focusing motor 103 to reflect an embodiment of this illumination.
  • the unit microscopic imaging module adopts a non-integral package module, and the mechanical fixing structure 109 in this embodiment is only used to fix the lower automatic focusing module and connect the reflective illumination light source 201, the first lens group 1011 is connected to the light guide structure 202 through its packages.
  • the dark field illuminator is a reflective plate with a circular black background in the middle area, the size of which is larger than the field of view of the unit microscopic imaging module, and the surrounding is a white fully reflective surface.
  • the surface of the entire board with the black area is attached to the back of the sample slide.
  • the center of the circular black background, the center of the sample and the center of the lens are on the same axis.
  • the light source is the LED lamp of the reflective lighting unit module. Bead 201, the emitted light 2011 passes through the light guide structure 202, the air gap, and the sample glass slide, and then irradiates the white diffuse reflection surface around the circular black background.
  • the diffuse reflection light enters the glass slide and illuminates the sample. After the sample is irradiated
  • the diffuse reflection light generated by the edge of the high drop in some areas enters the lens module, while the diffuse reflection light generated by most of the other reflectors in the glass slide cannot be emitted out of the glass slide due to the total reflection caused by the large exit angle. It spreads to the edge of the slide without entering the lens, so that the system obtains a dark-field illumination image.
  • the bright-field diffuse reflection has a concave structure, and the distance between the white diffuse reflection surface and the positioning surface is 0.5-5 mm.

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  • Physics & Mathematics (AREA)
  • Chemical & Material Sciences (AREA)
  • Analytical Chemistry (AREA)
  • General Physics & Mathematics (AREA)
  • Optics & Photonics (AREA)
  • Engineering & Computer Science (AREA)
  • Multimedia (AREA)
  • Microscoopes, Condenser (AREA)

Abstract

La présente invention concerne un système d'imagerie microscopique, comprenant : une pluralité de modules d'imagerie de microscopie unitaires distribués selon une règle prédéfinie, et une carte de collecte de données connectée à la pluralité de modules d'imagerie de microscopie unitaires. Chaque module d'imagerie de microscopie unitaire comprend séparément un ensemble de lentilles ajustables ayant une focalisation réglable indépendamment, et un module photosensible. Une pluralité de modules de traitement d'image correspondant respectivement l'un à l'un de la pluralité de modules d'imagerie de microscopie unitaires sont disposés sur la carte de collecte de données, et chaque module de traitement d'image commande indépendamment le foyer de l'ensemble de lentilles réglable correspondant, et acquiert des données à partir du module photosensible correspondant. La présente invention permet de réduire le besoin d'uniformité dans l'ensemble module unitaire, et d'améliorer l'efficacité de production du produit fini.
PCT/CN2020/081793 2020-03-27 2020-03-27 Système d'imagerie microscopique WO2021189451A1 (fr)

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Citations (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US20170146806A1 (en) * 2015-11-20 2017-05-25 The Board Of Trustees Of The Leland Stanford Junior University Light-field Imaging Using a Gradient Metasurface Optical Element
CN106842529A (zh) * 2017-01-23 2017-06-13 清华大学 快速三维显微成像系统
CN107346059A (zh) * 2016-05-02 2017-11-14 株式会社三丰 可变焦距成像系统
CN108169172A (zh) * 2017-12-28 2018-06-15 清华大学 三维折射率显微成像系统及方法
CN108363196A (zh) * 2017-01-26 2018-08-03 中国科学院上海生命科学研究院 光场显微系统、光场显微镜及其光学组件

Patent Citations (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US20170146806A1 (en) * 2015-11-20 2017-05-25 The Board Of Trustees Of The Leland Stanford Junior University Light-field Imaging Using a Gradient Metasurface Optical Element
CN107346059A (zh) * 2016-05-02 2017-11-14 株式会社三丰 可变焦距成像系统
CN106842529A (zh) * 2017-01-23 2017-06-13 清华大学 快速三维显微成像系统
CN108363196A (zh) * 2017-01-26 2018-08-03 中国科学院上海生命科学研究院 光场显微系统、光场显微镜及其光学组件
CN108169172A (zh) * 2017-12-28 2018-06-15 清华大学 三维折射率显微成像系统及方法

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