CN214375562U - Double-sided film coating galvanometer, extensible high-speed scanning galvanometer group and microscope - Google Patents

Abstract

The invention relates to the technical field of microscopes, and particularly discloses a double-sided coating vibrating mirror, an extensible high-speed scanning vibrating mirror group and a microscope, wherein the double-sided coating vibrating mirror comprises a first galvanometer vibrating mirror, two surfaces of the first galvanometer vibrating mirror are polished surfaces, and coating films are covered on the two surfaces; the extensible high-speed scanning galvanometer group comprises a lens for refracting light beams, a reflecting mirror for reflecting the light beams and the double-sided coated galvanometer; the double-sided film-coating vibrating mirror is used for changing the path of a light beam irradiated on any side of the double-sided film-coating vibrating mirror after deflection, so that the frequency of the light beam passing through the double-sided film-coating vibrating mirror is more than twice. By adopting the technical scheme of the invention, the scanning speed can be improved.

Description

Double-sided film coating galvanometer, extensible high-speed scanning galvanometer group and microscope

Technical Field

The invention relates to the technical field of microscopes, in particular to a double-sided film coating galvanometer, an extensible high-speed scanning galvanometer group and a microscope.

Background

When a biological sample is imaged by a conventional scanning optical microscope, if the focal plane position of the objective lens needs to be changed to obtain signals of different layers, the objective lens is generally moved up and down instead of moving the biological sample up and down. Because some biological samples are fragile and cannot withstand rapid movement up and down. In the beginning of this century, a Remote scanning (Remote Focusing) technology was developed by Tony Wilson, university of Oxford, England, and the objective lens and the sample do not need to move up and down, but the movement of the imaging focal plane on one side of the sample is realized by changing the position of the other conjugate focal plane by axially moving one mirror. Since the weight of the mirror is light compared to that of the objective lens, high-speed vibration of the mirror can be realized by a driver such as a Voice Coil (Voice Coil), thereby realizing rapid change of the imaging focal plane on the sample side.

Based on the above principle, the scanning head of the existing spot scanning laser scanning microscope is divided into a fast scanning type and a slow scanning type. The fast scan head is typically a high speed resonant scanner for X-axis scanning and a low speed galvanometer mirror for Y-axis scanning. Currently, the resonance scanner in the world is mainly made of the following three products: 9.25mm beam diameter 26 degrees @4KHz, 5mm beam diameter 26 degrees @8KHz, and 5mm beam diameter 10 degrees @12 KHz; wherein the product with the beam diameter of 5mm of 26 degrees @8KHz is widely adopted by manufacturers of laser scanning microscopes. A resonance scanner using the above product can image a microscope to 512 x 512 pixels @30fps (bi-directional scanning). While a slow scan head based on two low speed galvanometer mirrors can provide 512 x 512 pixels @2fps (bi-directional scanning).

Subject to the beam diameter limitations of the resonance scanner (8KHz <5mm), in order to match the beam diameter requirements of about 15mm of a novel low magnification microscope objective (field diameter of about 1.6mm), existing point scanning laser scanning microscopes all have employed a focal length ratio of 1: 4-1: the combined optical path of the scanning lens and the sleeve lens of 5 realizes the transformation matching of the beam diameter, and simultaneously transforms the approximately 30-degree optical scanning angle of the resonance scanner and the galvanometer mirror into the about 6-degree field angle of the microscope objective lens.

To achieve ultra-large field-of-view imaging (field-of-view diameter about 5mm), the most common technical route is to maintain the existing field angle, enlarging the field of view by increasing the focal length. To achieve a high Numerical Aperture (NA) the beam diameter through the microscope objective needs to be increased (to 25-40 mm). And the effect of galvanometer in scanning light path is the scanning line that the quick travel resonance scanner produced, however, there is the upper limit in galvanometer's vibration speed, leads to scanning speed to have the bottleneck, and super large field of view microscope's performance promotion is limited.

Therefore, a double-sided film-coating galvanometer, an expandable high-speed scanning galvanometer group and a microscope capable of improving the scanning speed are needed.

Disclosure of Invention

The invention provides a double-sided film coating galvanometer, an extensible high-speed scanning galvanometer group and a microscope, which can improve the scanning speed.

In order to solve the technical problem, the present application provides the following technical solutions:

the utility model provides a two-sided coating film mirror that shakes, includes first galvanometer mirror that shakes, two surfaces of first galvanometer mirror that shakes are the polished surface, and two surfaces all cover and have the coating film.

The basic scheme principle and the beneficial effects are as follows:

two surfaces of the first galvanometer vibrating mirror are polished and coated to obtain a double-sided coated vibrating mirror, so that two surfaces of the double-sided coated vibrating mirror can reflect light beams, the light beams can pass through the double-sided coated vibrating mirror for many times, the deflection angle of each light beam is reduced, and the final accumulated total deflection angle of the deflected light beams is output. Because the double-sided coating film vibrating mirror has small rotation angle, high speed, large rotation angle and low speed, the scheme reduces the rotation angle of the double-sided coating film vibrating mirror at each time, so that the deflection speed of the double-sided coating film vibrating mirror under a small angle is greatly improved, and the high scanning speed is obtained.

The extensible high-speed scanning vibrating mirror group comprises a lens for refracting light beams, a reflecting mirror for reflecting the light beams, and the double-sided coated vibrating mirror; the double-sided film-coating vibrating mirror is used for changing the path of a light beam irradiated on any side of the double-sided film-coating vibrating mirror after deflection, so that the frequency of the light beam passing through the double-sided film-coating vibrating mirror is more than twice.

In the scheme, the light beam does not pass through one surface of the vibrating mirror or one surface of the double-sided film-coated vibrating mirror conventionally to complete one-time scanning, and the light beam is circulated in a vibrating mirror group consisting of the lens, the reflecting mirror and the double-sided film-coated vibrating mirror for multiple times to complete one-time scanning.

The light beam is output by accumulating the multiple deflection angles of the lens, the reflector and the double-sided film coating vibrating mirror into a total deflection angle. The rotation angle of the double-sided coating galvanometer at each time is reduced, so that the deflection speed of the double-sided coating galvanometer under a small angle is greatly improved, and a high scanning speed is obtained.

Further, the lenses comprise a first lens, a second lens, a third lens and a fourth lens, and the reflectors comprise a fifth reflector, a sixth reflector, a seventh reflector and an eighth reflector;

the double-sided film-coating vibrating mirror is positioned on the axis, the first lens and the second lens are positioned on the right side of the double-sided film-coating vibrating mirror and are coaxial with the double-sided film-coating vibrating mirror, and the first lens is closer to the double-sided film-coating vibrating mirror than the second lens; the third lens and the fourth lens are symmetrically arranged on two sides of the axis and are positioned between the double-sided film-coated galvanometer and the first lens;

the fifth mirror and the sixth mirror are located on one side of the axis, the seventh mirror and the eighth mirror are located on the other side of the axis, the fifth mirror and the seventh mirror are symmetric about the axis, and the sixth mirror and the eighth mirror are symmetric about the axis.

Further, a connecting line of the midpoints of the fifth reflector, the third lens and the sixth reflector is parallel to the axis; the connecting line of the midpoints of the fifth reflector and the double-sided coated vibrating mirror is vertical to the axis.

By adopting the double-sided coated galvanometer, the scanning speed is increased by one order of magnitude and is close to the speed level of a resonance scanner. The imaging speed of the laser scanning microscope with the slow scanning head of the preferred scheme can be obviously improved, and the imaging speed of the ultra-large field of view microscope can also be improved. And the preferred scheme has simple structure, the number of the double-sided coated vibrating mirrors and the number of the lenses are less, and the cost can be effectively reduced.

Furthermore, the number of the extensible high-speed scanning galvanometer groups is more than or equal to two, and the extensible high-speed scanning galvanometer groups are connected in series.

The number of the double-sided coating vibrating mirrors can be increased, the deflection angle of each double-sided coating vibrating mirror can be further reduced, and the scanning speed is further increased.

The microscope comprises the extensible high-speed scanning mirror group and a light source leading-in mirror group, wherein the light source leading-in mirror group comprises a second galvanometer mirror and a ninth lens group, and the second galvanometer mirror and the ninth lens group are both located on the axis.

Drawings

FIG. 1 is a schematic diagram of an extendable high-speed scanning galvanometer set according to an embodiment;

FIG. 2 is a schematic view of a second embodiment of an extendable high-speed scanning galvanometer group;

FIG. 3 is a schematic diagram of a three extendable high-speed scanning galvanometer set according to an embodiment.

Detailed Description

The following is further detailed by way of specific embodiments:

the reference numbers in the drawings of the specification include: the lens system comprises a first lens group 1, a second lens group 2, a third lens group 3, a fourth lens group 4, a fifth lens group 5, a sixth lens group 6, a seventh lens group 7, an eighth lens group 8, a first double-sided coated galvanometer 9, a second double-sided coated galvanometer 10, a first reflector 11, a second reflector 12, a third reflector 13, a fourth reflector 14, a third double-sided coated galvanometer 15, a first lens 16, a second lens 17, a third lens 18, a fourth lens 19, a fifth reflector 20, a sixth reflector 21, a seventh reflector 22, an eighth reflector 23, a second galvanometer 24, a ninth lens group 25 and a target reflector 26.

Example one

The double-sided coating vibrating mirror comprises a first galvanometer vibrating mirror, two surfaces of the first galvanometer vibrating mirror are polished surfaces, and two surfaces are covered with coatings. In other words, two surfaces of the first galvanometer vibrating mirror are polished during machining, and the two surfaces of the first galvanometer vibrating mirror are coated after polishing. In this embodiment, the existing driving device is used to drive the double-sided coated galvanometer to rotate.

As shown in fig. 1, the extendable high-speed scanning galvanometer set of the present embodiment includes a lens, a reflecting mirror and the above dual-sided coated galvanometer. In the embodiment, the number of the double-sided coated vibrating mirrors is 2, the number of the lenses is 16, and the number of the reflectors is 4; of the 16 lenses, 2 parallel lenses each constitute 1 lens group, which are respectively referred to as a first lens group 1, a second lens group 2, a third lens group 3, a fourth lens group 4, a fifth lens group 5, a sixth lens group 6, a seventh lens group 7, and an eighth lens group 8.

The 2 double-sided coated galvanometers are arranged on the axis. In this embodiment, the two-sided coated vibrating mirror on the right side is referred to as a first two-sided coated vibrating mirror 9, and the two-sided coated vibrating mirror on the left side is referred to as a second two-sided coated vibrating mirror 10. In this embodiment, the axis is a virtual reference line, which refers to a line passing through the centers of 2 double-sided coated galvanometers. The rotation angle of the first double-sided coated vibrating mirror 9 and the second double-sided coated vibrating mirror 10 is 0-120 degrees.

The first lens group 1 is located between the first double-sided coated vibrating mirror 9 and the second double-sided coated vibrating mirror 10, and the second lens group 2 is located on the left side of the second double-sided coated vibrating mirror 10.

And 3 lens groups are symmetrically arranged on two sides of the axis respectively, specifically, the third lens group 3, the fourth lens group 4 and the fifth lens group 5 are positioned on one side of the axis, and the sixth lens group 6, the seventh lens group 7 and the eighth lens group 8 are positioned on the other side of the axis. The 3 lens groups located on the same side of the axis and the first lens group 1 form a square shape as a whole. Specifically, the first lens group 1, the third lens group 3, the fourth lens group 4, and the fifth lens group 5 constitute a square shape as a whole. The first lens group 1, the sixth lens group 6, the seventh lens group 7, and the eighth lens group 8 are the same. Wherein, the fourth lens group 4 and the seventh lens group 7 are respectively positioned at the outermost sides of the axis.

The 4 mirrors are respectively denoted as a first mirror 11, a second mirror 12, a third mirror 13 and a fourth mirror 14. Two sides of the axis are symmetrically provided with 2 reflectors respectively, specifically, a first reflector 11 and a second reflector 12 are positioned on one side of the axis, and a third reflector 13 and a fourth reflector 14 are positioned on the other side of the axis.

The 2 reflectors on the same side of the axis are respectively positioned at two ends of the lens group on the outermost side of the axis. Specifically, the first reflecting mirror 11 and the second reflecting mirror 12 are located at both ends of the fourth lens group 4; the third mirror 13 and the fourth mirror 14 are located at both ends of the seventh lens group 7.

The first reflecting mirror 11 and the second reflecting mirror 12 are bilaterally symmetrical, and the acute angles of the included angles between the first reflecting mirror 11 and the second reflecting mirror 12 and the axis are both 45 degrees. The connecting line of the middle points of the first reflecting mirror 11, the second reflecting mirror 12 and the fourth lens group 4 is parallel to the axis, the connecting line of the middle points of the first reflecting mirror 11, the third lens group 3 and the first double-sided coated galvanometer 9 is perpendicular to the axis, and the connecting line of the middle points of the second reflecting mirror 12, the fifth lens group 5 and the second double-sided coated galvanometer 10 is perpendicular to the axis. The positions of the third mirror 13 and the fourth mirror 14 are the same.

The microscope of this embodiment includes the expandable high-speed scanning mirror assembly, and further includes a light source guiding mirror assembly and a target reflecting mirror 26. The light source guiding vibration mirror group is positioned on the axis on the right side of the first double-sided coated vibration mirror 9, and sequentially comprises 1 second galvanometer vibration mirror 24 and 2 parallel lenses from right to left, wherein the 2 parallel lenses are recorded as a ninth lens group 25. A target mirror 26 is provided at the observation target for reflecting the incident light beam.

When in use, an incident light beam is guided into one surface of a first double-sided coated vibrating mirror 9 through a light source guiding vibrating mirror group, the first double-sided coated vibrating mirror 9 rotates in advance, the incident light beam is guided into the lower side of an axis through 3 lens groups and 2 reflectors on the lower side of the axis, then the light beam is guided into one surface of a second double-sided coated vibrating mirror 10, the second double-sided coated vibrating mirror 10 rotates in advance, the light beam is guided into the other surface of the first double-sided coated vibrating mirror 9 through a first lens group 1 after passing through one surface of the second double-sided coated vibrating mirror 10, the first double-sided coated vibrating mirror 9 rotates in advance, the incident light beam is guided into the upper side of the axis through 3 lens groups and 2 reflectors on the upper side of the axis, then the light beam is guided onto the other surface of the second double-sided coated vibrating mirror 10, the second double-sided coated vibrating mirror 10 rotates in advance, the incident light beam is guided into the second lens group 2, the incident light beam is emitted to the target through the second lens group 2. The reflected light beam exits from the target reflecting mirror 26, enters from the second lens group 2, and finally exits after being reflected by the second galvanometer vibrating mirror 24, and the travel of the reflected light beam is similar to that of the incident light beam, which is not described in detail herein.

In this embodiment, the two double-sided film-coated galvanometers deflect simultaneously, and the angles deflected by the two double-sided film-coated galvanometers are finally accumulated into a total deflection angle for outputting. The total deflection angle is shared by the two double-sided coating galvanometers, so that the deflection angle of each double-sided coating galvanometer is greatly reduced, the deflection speed of each double-sided coating galvanometer under a small angle is greatly improved, and a high scanning speed is obtained.

By adding the double-sided coated galvanometer mirror and additional components (lenses, mirrors), the scanning speed is increased by an order of magnitude compared with the use of only the second galvanometer mirror 24, approaching the speed level of the resonant scanner. The imaging speed of the laser scanning microscope with the slow scanning head of the embodiment can be increased by more than 10 times, and the imaging speed of the ultra-large field of view microscope can be increased.

Example two

As shown in fig. 2, the difference between the present embodiment and the first embodiment is that the number of the extendable high-speed scanning mirror groups in the present embodiment is greater than or equal to two, and the extendable high-speed scanning mirror groups are distributed along the axis. In other words, it can be regarded as a series connection between the extendable high-speed scanning galvanometer sets. In this embodiment, the number of the extendable high-speed scanning mirror groups is two.

The number of the double-sided film coating vibrating mirrors is further increased, the deflection angle of each double-sided film coating vibrating mirror can be further reduced, and the scanning speed is further increased.

EXAMPLE III

As shown in fig. 3, the difference between the present embodiment and the first embodiment is that in the extendable high-speed scanning mirror group of the present embodiment, there are 1 double-sided coated mirror, 4 lenses, and 4 reflectors. The double-sided coated galvanometer in this embodiment is denoted as a third double-sided coated galvanometer 15, 4 lenses are denoted as a first lens 16, a second lens 17, a third lens 18 and a fourth lens 19, respectively, and 4 reflecting mirrors are denoted as a fifth reflecting mirror 20, a sixth reflecting mirror 21, a seventh reflecting mirror 22 and an eighth reflecting mirror 23, respectively. The third double-sided coated galvanometer 15 is positioned on the axis.

The first lens 16 and the second lens 17 are located on the right side of the third double-sided coated mirror 15 and are coaxial with the third double-sided coated mirror 15, in this embodiment, the first lens 16 is closer to the third double-sided coated mirror 15 than the second lens 17; the third lens 18 and the fourth lens 19 are symmetrically arranged on two sides of the axis and are positioned between the third double-sided coated galvanometer 15 and the first lens 16.

The fifth mirror 20 and the sixth mirror 21 are located on one side of the axis, the seventh mirror 22 and the eighth mirror 23 are located on the other side of the axis,

the fifth mirror 20 and the seventh mirror 22 are symmetrical with respect to the axis, and the sixth mirror 21 and the eighth mirror 23 are symmetrical with respect to the axis.

The line connecting the midpoints of the fifth mirror 20, the third lens 18, and the sixth mirror 21 is parallel to the axis.

The connecting line of the midpoints of the fifth reflector 20, the third double-sided coated galvanometer 15 and the seventh reflector 22 is vertical to the axis.

The microscope of this embodiment includes the expandable high-speed scanning mirror assembly, and further includes a light source guiding mirror assembly and a target reflecting mirror 26. The light source leading-in vibrating mirror group is positioned on the axis on the right side of the third double-sided coated vibrating mirror 15. A target mirror 26 is provided at the observation target for reflecting the incident light beam.

The incident light beam enters the rightmost light source and is guided into the vibrating mirror group to be incident on the third double-sided film-coated vibrating mirror 15, is reflected by the third double-sided film-coated vibrating mirror 15, is relayed by the two lenses and is reflected for 4 times, and then is incident on the reverse side of the third double-sided film-coated vibrating mirror 15. The incident beam is reflected by the third double-sided coated vibrating mirror 15, then passes through the relay of the two lenses and is reflected by the target reflecting mirror 26 positioned at the focus, and the emitted beam returns in the original path and is finally emitted by the galvanometer vibrating mirror.

In this process, the light beam passes through the second galvanometer mirror 24, 2 times and the third double-sided coating galvanometer mirror 15, 4 times, so if the optical deflection angles of the second galvanometer mirror 24 and the third double-sided coating galvanometer mirror 15 are both a degrees, the final total deflection angle is (4+2) a degrees. Because it is impossible to infinitely increase the deflection angles of the second galvanometer mirror 24 and the third double-sided coated galvanometer mirror 15 due to the limitation of the lens diameter and the focal length, the optical deflection angles of the second galvanometer mirror 24 and the third double-sided coated galvanometer mirror 15 are both a/(4+2) degrees at a deflection angle (e.g. 30 °) meeting the design requirement. The speed of the galvanometer and the third double-sided coated galvanometer 15 is improved, and high-speed scanning is realized.

Moreover, this embodiment is structurally simplified as compared with the first and second embodiments. The number of the third double-sided coated galvanometer 15 and the number of the lenses are reduced, and the cost can be effectively reduced.

Example four

The difference between this embodiment and the third embodiment is that the number of the extendable high-speed scanning mirror groups is greater than or equal to two, and the extendable high-speed scanning mirror groups are distributed along the axis. In other words, it can be regarded as a series connection between the extendable high-speed scanning galvanometer sets. For example, if the expandable high-speed scanning galvanometer group in the dashed box in fig. 3 is regarded as a module, then by connecting N such modules in series to the left side, the deflection angle of each of the second galvanometer mirror 24 and the third double-sided coating galvanometer 15 is a/(4N +2) degrees, and the larger N is, the faster the scanning speed of the system is. The limit of the single scanning speed is that the limit of the small-angle simple response time of the single second galvanometer 24 and the third double-sided coating galvanometer 15 cannot be broken through. The minimum index is about 100us (3mm lens)/200 us (5mm lens)/250 us (10mm lens)/350 us (15mm lens). This embodiment is therefore capable of achieving scan rates approximating a 3KHz @3mm lens or a 500Hz @10mm lens or a 400Hz @15mm lens.

The above are merely examples of the present invention, and the present invention is not limited to the field related to this embodiment, and the common general knowledge of the known specific structures and characteristics in the schemes is not described herein too much, and those skilled in the art can know all the common technical knowledge in the technical field before the application date or the priority date, can know all the prior art in this field, and have the ability to apply the conventional experimental means before this date, and those skilled in the art can combine their own ability to perfect and implement the scheme, and some typical known structures or known methods should not become barriers to the implementation of the present invention by those skilled in the art in light of the teaching provided in the present application. It should be noted that, for those skilled in the art, without departing from the structure of the present invention, several changes and modifications can be made, which should also be regarded as the protection scope of the present invention, and these will not affect the effect of the implementation of the present invention and the practicability of the patent. The scope of the claims of the present application shall be determined by the contents of the claims, and the description of the embodiments and the like in the specification shall be used to explain the contents of the claims.

Claims (6)

1. The utility model provides a two-sided coating film galvanometer mirror, includes first galvanometer mirror, its characterized in that, two surfaces of first galvanometer mirror of shaking are the polished surface, and two surfaces all cover and have the coating film.

2. The expansible high-speed scanning vibrating mirror group comprises a lens for refracting light beams and a reflecting mirror for reflecting the light beams, and is characterized by further comprising the double-sided coated vibrating mirror of claim 1; the double-sided film-coating vibrating mirror is used for changing the path of a light beam irradiated on any side of the double-sided film-coating vibrating mirror after deflection, so that the frequency of the light beam passing through the double-sided film-coating vibrating mirror is more than twice.

3. The expandable high-speed scanning galvanometer assembly of claim 2, wherein: the lens comprises a first lens, a second lens, a third lens and a fourth lens, and the reflecting mirror comprises a fifth reflecting mirror, a sixth reflecting mirror, a seventh reflecting mirror and an eighth reflecting mirror;

the double-sided film-coating vibrating mirror is positioned on the axis, the first lens and the second lens are positioned on the right side of the double-sided film-coating vibrating mirror and are coaxial with the double-sided film-coating vibrating mirror, and the first lens is closer to the double-sided film-coating vibrating mirror than the second lens; the third lens and the fourth lens are symmetrically arranged on two sides of the axis and are positioned between the double-sided film-coated galvanometer and the first lens;

the fifth mirror and the sixth mirror are located on one side of the axis, the seventh mirror and the eighth mirror are located on the other side of the axis, the fifth mirror and the seventh mirror are symmetric about the axis, and the sixth mirror and the eighth mirror are symmetric about the axis.

4. The expandable high-speed scanning galvanometer assembly of claim 3, wherein: the connecting line of the midpoints of the fifth reflector, the third lens and the sixth reflector is parallel to the axis; the connecting line of the midpoints of the fifth reflector and the double-sided coated vibrating mirror is vertical to the axis.

5. The expandable high-speed scanning galvanometer set of claim 4, wherein: the number of the extensible high-speed scanning vibration mirror groups is more than or equal to two, and the extensible high-speed scanning vibration mirror groups are connected in series.

6. The microscope comprising the expandable high-speed scanning mirror assembly according to any one of claims 2 to 5, further comprising a light source introduction mirror assembly, wherein the light source introduction mirror assembly comprises a second galvanometer mirror and a ninth lens assembly, and the second galvanometer mirror and the ninth lens assembly are both located on an axis.

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