KR102163216B1 - Optical detecting device and control method the same - Google Patents

Abstract

A light detection device and a control method of the light detection device are disclosed. According to the present invention, it is possible to grasp the position and focus of the subject including the light detection target using the image detection unit, and detect a waveform that is emitted or reflected from the light detection target using the waveform detection unit. Accordingly, even when the intensity of light emitted or reflected from the light detection target is weak or the light detection target is located at a long distance, the position and focus of the subject can be determined, so that the light detection process can be easily performed.

Description

Optical detecting device and control method the same

The present invention relates to a light detection device and a control method thereof, and more specifically, a light detection device capable of effectively removing a noise component located around a light detection target to detect a waveform of light of a desired light detection target, and a control method thereof It is about.

The process of measuring light is performed by using an optical device capable of measuring light after transmitting light emitted or reflected from a target object using a lens or a mirror.

More specifically, according to the traditional light measuring method, an optical device for measuring light is located in a region where an image formed by transmitted light is formed.

In this case, the image formed on the optical device is generally formed by including not only light emitted or reflected from the target subject, but also a noise component generated around the target subject.

Therefore, in the conventional method of measuring light, a method of removing noise components by covering or removing light sources such as scattered light generated around a target subject is used.

However, in the above-described method, when the intensity of light to be detected is weak, it is difficult to distinguish between scattered light and the like. In addition, there is a limitation in that it is difficult to remove noise components caused by light in the ultraviolet region or the infrared region that are not in the visible ray region that can be identified by the naked eye by a light source such as scattered light.

When it is necessary to measure the weak light emitted by a target object located at a distance, this limitation is exacerbated.

That is, when only an optical device for detecting a waveform of light is used, it is difficult to easily proceed with a process of finding the position of a target subject to be preceded for light measurement. There is a limitation in that it is difficult to block the scattered light generated in the surroundings even if the lyrics and the location of the target subject are difficult to find.

The traditional light measurement method requires the following additional steps to solve the above-described problem.

First, some of the scattered light generated around the target subject is removed by geometrically rearranging the optical device through separate optical calculation. Next, a strong light source is placed on the target object to confirm the position where the image is formed, and then an optical device for detecting the waveform of light is disposed at the corresponding position.

In summary, the traditional method of measuring light has to go through a complex process of increasing the intensity of light generated from a target object, finding the light with increased intensity, and detecting the waveform of the found light.

In the case of an optical device for determining the location of light, the location of the target subject can be easily identified, but there is a limitation in removing noise components around the target subject and detecting light of a weak signal due to a limitation of sensitivity.

In addition, in the case of a device for grasping the waveform of light, the sensitivity is high, and it is advantageous compared to the optical device for grasping the position of light when removing a noise component around a target object and detecting light of a weak signal. However, it is very difficult to determine the location of the target subject when only a device for grasping the light waveform is used.

Accordingly, the above-described process requires both an optical device for grasping the position of light and an optical device for grasping the waveform of light, respectively.

Furthermore, in order to perform the above-described traditional light measuring method, there is also a cumbersome need to perform optical calculations whenever measuring light emitted from different target objects, and to rearrange the optical devices according to the results.

Moreover, when the intensity of light emitted from the target subject is small, the optical device needs to be rearranged in more detail. Accordingly, it is difficult to accurately measure the light emitted from the target subject due to an error occurring in the process of rearranging the optical device.

Korean Patent Document No. 10-1891182 discloses an automatic focus control device having a structure capable of easily grasping the position of a focus. Specifically, an automatic focus control device is disclosed that verifies image information acquired through photographing through an image sensor to determine a focus position.

However, the automatic focus control device having such a structure has a limitation in that it is difficult to remove noise components generated around the focus. In addition, even when the focus is located at a distance or the intensity of light emitted from the focus is weak, there is a limitation in that no consideration has been made on means for easily detecting light.

Korean Patent Publication No. 10-2018-0086198 discloses a detector for optically detecting at least one object. Specifically, a detector having a structure capable of grasping the position of an object using a plurality of sensors for grasping the position of the object in the longitudinal direction and the transverse direction is disclosed.

However, the detector having such a structure has a disadvantage in that the structure becomes complicated because a plurality of sensors must be provided in order to determine the location of an object. In addition, there is a limitation in that a separate information processing device must be provided for processing location information collected from a plurality of sensors.

Korean Patent Document No. 10-1891182 (2018.08.24.) Korean Patent Publication No. 10-2018-0086198 (July 30, 2018)

An object of the present invention is to provide a light detection device and a control method of the light detection device having a structure capable of solving the above-described problems.

First, an object of the present invention is to provide a light detection device having a structure capable of easily grasping a location of a target subject and easily detecting light emitted from a target subject, and a control method of the light detection device.

In addition, an object of the present invention is to provide a light detection device and a control method of the light detection device having a structure capable of easily detecting light even when a target subject is located at a distance or the intensity of light emitted from the target subject is weak.

In addition, it is an object of the present invention to provide a light detection device and a control method of the light detection device having a structure that does not require separate optical calculation and rearrangement of the optical device accordingly even if a target subject is changed.

Another object of the present invention is to provide a light detection device and a control method of the light detection device having a structure capable of detecting only light emitted from a target object by effectively removing a noise component due to scattered light emitted from the periphery of a target object.

In addition, even when the light emitted from the target subject is not in the visible light region and it is difficult to identify it with the naked eye, it is provided that a light detection device and a control method of the light detection device are provided. It is for work purposes.

In order to achieve the above object, the present invention provides a spatial filter unit positioned on an optical path through which light reflected from an object including a light detection object passes; An optical splitting unit positioned on the optical path downstream of the spatial filter unit and configured to divide the optical path into at least two; An image detection unit positioned on one of the divided optical paths and configured to enter light passing through the one of the divided optical paths; And a waveform detection unit configured to detect a waveform of light passing through the other divided optical path by incident light passing through the other of the divided optical paths, wherein the spatial filter unit comprises: It provides a light detection device configured to block a part of the image of the subject formed by the light incident on the image detection unit, except for the image of the light detection target.

In addition, the spatial filter unit of the optical detection device may include a first state in which all of the optical paths are blocked; A second state of passing at least a portion of the optical path; And a third state through which all of the optical paths are passed may be maintained.

In addition, the phase detection unit and the waveform detection unit may be disposed so that the same phase is formed between the phase detection unit and the waveform detection unit of the photodetection device so that the distance between the phase detection unit and the waveform detection unit is the same, respectively. have.

In addition, the light detection device is located downstream of the spatial filter unit and an upstream side of the light splitting unit on the optical path, and is configured to guide the light passing through the spatial filter unit to the light splitting unit. It may include a lens unit.

In addition, the light detection device is located downstream of the optical splitting unit and upstream of the waveform detection unit on the optical path, and is configured to filter light passing through the other split optical path according to a waveform area. It may include a waveform filter module.

In addition, the light detection device may include an objective lens unit positioned downstream of the subject and an upstream side of the spatial filter unit on the optical path, and configured to guide the light to the spatial filter unit.

In addition, the present invention includes the steps of: (a) adjusting the image detection unit so that the reflected light from a subject including a light detection object is incident; (b) blocking at least a portion of light passing through an optical path from the subject toward the image detection unit by a spatial filter unit; (c) dividing the optical path through the spatial filter unit into at least two by a light splitting unit; (d) detecting an image formed by light passing through any one of the divided optical paths by the image detection unit; (e) A method of controlling a light detection device comprising the step of detecting, by a waveform detection unit, a waveform of light passing through the other of the divided optical paths.

In addition, the step (b) of the control method of the optical detection device includes: (b1) a first state in which the spatial filter unit blocks all the optical paths, a second state in which at least a part of the optical path passes, and the It may include adjusting to any one of the third states in which all the optical paths are passed.

In addition, the step (e) of the control method of the optical detection device may include: (e1) filtering the light passing through the other one of the divided optical paths by the waveform filter module; And (e2) the waveform detection unit detecting the waveform of the light filtered by the waveform filter module.

In addition, the step (a) of the control method of the light detection device may include (a1) guiding the light passing through the optical path by the objective lens unit to the spatial filter unit.

In addition, the step (a) of the control method of the light detection device may include (a2) guiding the light passing through the spatial filter unit by the transmission lens unit to the light splitting unit.

In addition, the step (c) of the control method of the photodetector may include (c1) arranging the image detection unit and the waveform detection unit to be positioned at the same distance as the optical splitting unit, respectively.

According to the present invention, the following effects can be derived.

First, after finding the location of the subject and the focus of the light detection target using the image detection unit, the waveform of light emitted from the light detection target may be detected using the waveform detection unit.

Therefore, since a separate optical device is not required to perform the above process, it is possible to easily detect an image and a waveform of light.

Further, the light path through which the light emitted from the light detection object passes is divided by the light splitting unit and incident on the image detection unit and the waveform detection unit, respectively. Further, the image detection unit and the waveform detection unit are each configured to be located at the same distance as the light splitting unit.

Accordingly, the position of the object and the focus of the light detection object acquired through the image detection unit are equally reflected in the waveform detection unit. Accordingly, after focusing the light detection target with the image detection unit, the waveform of light can be easily detected through the waveform detection unit.

In addition, the image detection unit can easily focus on the light detection object even when the light detection object is located at a long distance or the intensity of light emitted from the light detection object is weak.

Therefore, even when the intensity of light emitted from the light detection object is weak, light can be easily detected.

In addition, when the light detection target is changed, the position of the changed subject and the focus of the light detection target can be easily found simply by moving the image detection unit.

Therefore, even when the light detection target is changed, a separate optical calculation and a rearrangement process accordingly are not required.

Further, the spatial filter unit is configured to be able to block a part of the light path passing through the spatial filter unit. Accordingly, among the images formed in the image detection unit, other images other than the image to be detected may be removed.

Therefore, it is possible to effectively remove noise components caused by scattered light and the like emitted around the light detection target.

In addition, when the light emitted from the light detection target is not in the visible light region, the position of the subject may be determined using the image detection unit, and then the waveform of the light may be detected using the waveform detection unit.

Accordingly, even when the light emitted from the light detection object is not visually identified, it is possible to easily detect the light emitted from the light detection object.

1 is a block diagram showing a configuration of a photodetector according to an embodiment of the present invention.
FIG. 2 is a schematic diagram showing a process of detecting an image and a waveform of light by the light detection device of FIG. 1.
3 is a schematic diagram illustrating a process of detecting an image and a waveform of light by a light detection device according to another embodiment of the present invention.
4 is a flowchart illustrating a process of performing a method of controlling a photodetector according to an exemplary embodiment of the present invention.
5 is a flow chart showing a detailed process of step S100 of FIG. 4.
6 is a flow chart showing a detailed process of step S200 of FIG. 4.
7 is a flowchart showing a detailed process of step S300 of FIG. 4.
8 is a flow chart showing a detailed process of step S400 of FIG. 4.
9 is a flow chart showing a detailed process of step S500 of FIG. 4.
10 is a flowchart illustrating a detailed process of step S600 of FIG. 4.
11 and 12 are diagrams illustrating a process of detecting an image through a light detection device and a control method of the light detection device according to an embodiment of the present invention.

Hereinafter, a light detection device and a control method of the light detection device according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

In the following description, descriptions of some constituent elements may be omitted to aid in understanding the light detection device and the control method of the light detection device according to an embodiment of the present invention.

1. Definition of terms

The term "subject (S)" used in the following description refers to any material or object capable of emitting light or reflecting light.

The term "light detection target (T, Target)" used in the following description refers to any material or object that emits or reflects light to be detected using the light detection device according to an embodiment of the present invention.

The term “optical path (O.P)” used in the following description means a path through which light travels.

The term "1 ^st Image" used in the following description means an image that is not filtered by the spatial filter unit 600 to be described later. That is, the primary image (1 ^st Image) refers to an image formed by an unfiltered optical path OP that is emitted or reflected from the subject S.

The term "secondary images (2 ^nd Image)" used in the following description, is filtered by the to be described later spatial filter unit 600 to Rimed image onto a detection unit 400 or the waveform detecting unit 500 described below it means.

The term "waveform" used in the following description refers to a shape of a wave generated by light.

The term "information related to the waveform (W)" used in the following description includes arbitrary information capable of expressing the waveform (W) such as wavelength, frequency, period, and amplitude.

In the following description, the terms “the optical path OP is incident” and the term “light is incident” are used when the light emitted from the subject S or reflected from the subject S is incident toward an arbitrary component. I mean the situation.

The term "upstream side" used in the following description refers to a position where light passing through the optical path O.P or the optical path O.P is first incident on the optical path O.P. That is, the sentence "A member is located on the upstream side of member B" means that the optical path O.P enters the member A earlier than member B.

The term "downstream" used in the following description means a position at which light passing through the optical path O.P or the optical path O.P on the optical path O.P is later incident. That is, the sentence "the member A is located on the downstream side of the member B" means that the optical path O.P enters the member A later than the member B.

2. Description of the configuration of the optical detection device according to the embodiment of the present invention

1 to 3, the optical detection device according to the illustrated embodiment includes an objective lens unit 100, a transmission lens unit 200, a light splitting unit 300, an image detection unit 400, and a waveform detection unit. 500, a spatial filter unit 600 and an output unit 700.

In addition, in addition to the above-described configuration, a reflective member (not shown) and a refractive member (not shown) for reflecting or refracting light may be additionally provided.

In an embodiment not shown, the reflective member (not shown) may be provided as a mirror, and the refracting member (not shown) may be provided as a lens or the like.

The objective lens unit 100, the transmission lens unit 200, the optical splitting unit 300, the image detection unit 400, the waveform detection unit 500, and the spatial filter unit 600, which will be described later, are optical detection targets (T). It may be located on the light path OP through which light emitted or reflected from the subject S including a passes.

In addition, as shown in FIGS. 2 and 3, the objective lens unit 100, the spatial filter unit 600, the transmission lens unit 200, the light splitting unit 300, and the image detection unit 400 to be described below are They may be positioned on the optical path OP or physically adjacent to each other.

Further, the waveform detection unit 500 and the light splitting unit 300 to be described below may be positioned on the optical path O.P or physically adjacent to each other.

(1) Description of the objective lens unit 100

The objective lens unit 100 guides the light emitted from the subject S or reflected from the subject S (hereinafter referred to as "light emitted from the subject S") to the spatial filter unit 600 to be described later. Is configured to

More specifically, the objective lens unit 100 condenses the light emitted from the subject S toward the spatial filter unit 600 to be described later.

The objective lens unit 100 is located at the most upstream side of the optical path O.P through which the light emitted from the subject S passes. In other words, the objective lens unit 100 is located closest to the subject S in the configuration of the optical detection device.

In the illustrated embodiment, the objective lens unit 100 is provided with a total of three lenses including the first objective lens 110, the second objective lens 120, and the third objective lens 130. The number of lenses included in the objective lens unit 100 may be changed.

In addition, in the illustrated embodiment, each of the objective lenses 110, 120, and 130 is provided as a convex lens. Each of the objective lenses 110, 120, and 130 may be provided in an arbitrary shape capable of guiding the light emitted from the subject S to the spatial filter unit 600 to be described later.

A process in which the optical path O.P incident on the objective lens unit 100 is refracted so as to be guided toward a specific member is a well-known technique, so a detailed description thereof will be omitted.

A spatial filter unit 600 to be described later is positioned on the downstream side of the objective lens unit 100 on the optical path O.P. That is, the objective lens unit 100 is positioned between the subject S and the spatial filter unit 600 to be described later.

The optical path O.P through which the light emitted from the subject S passes is guided by the objective lens unit 100 and is incident on the spatial filter unit 600 to be described later. In addition, the optical path O.P is partially blocked or passed by the spatial filter unit 600 to be described later. A detailed description of this will be described later.

(2) Description of the transmission lens unit 200

The transmission lens unit 200 is configured to guide light passing through the optical path O.P that has passed through the spatial filter unit 600 to be described later to the light splitting unit 300 to be described later.

More specifically, the transmission lens unit 200 condenses the light emitted from the subject S toward the light splitting unit 300 to be described later. The transmission lens unit 200 may be provided in any form capable of guiding light passing through the optical path O.P to the light splitting unit 300 to be described later.

The transmission lens unit 200 is located on the downstream side of the objective lens unit 100 and the spatial filter unit 600 to be described later on the optical path O.P through which the light emitted from the subject S passes.

Further, the transmission lens unit 200 is located on the optical path O.P through which the light emitted from the subject S passes, upstream of the light splitting unit 300 to be described later.

That is, the transmission lens unit 200 is positioned between the spatial filter unit 600 to be described later and the light splitting unit 300 to be described later.

Transmitting a lens unit formed on the phase detecting unit 400 will be described later by the optical path (OP) having passed through the 200 up and down can be reversed (see the 2 ^nd Image of Figures 2 and 3).

Alternatively, in an embodiment not shown, the transmission lens unit 200 may include an additional lens unit (not shown) so that the image formed in the image detection unit 400 is not vertically reversed.

A process in which the optical path O.P incident on the transmission lens unit 200 is refracted to be guided toward a specific member is a well-known technique, and thus a detailed description thereof will be omitted.

An optical splitting unit 300 to be described later is positioned on the downstream side of the transmission lens unit 200 on the optical path O.P. That is, the transmission lens unit 200 is positioned between the spatial filter unit 600 to be described later and the light splitting unit 300 to be described later.

The optical path O.P is partially blocked or passed through the spatial filter unit 600 to be described later, and then is incident on the transmission lens unit 200. The optical path O.P incident on the transmission lens unit 200 is incident on the light splitting unit 300 to be described later and divided. A detailed description of this will be described later.

(3) Description of the optical splitting unit 300

The light splitting unit 300 is configured to divide the incident light path O.P into at least two or more.

In other words, the optical path O.P guided by the transmission lens unit 200 after filtering by the spatial filter unit 600 to be described later is incident on the light splitting unit 300. The light splitting unit 300 divides the incident light path O.P into at least two or more.

At least one of the plurality of optical paths divided by the light splitting unit 300 is incident on the image detection unit 400 to be described later and the waveform detection unit 500 to be described later, respectively. A detailed description of this will be described later.

The light splitting unit 300 may be provided in any form capable of dividing the incident optical path O.P into at least two or more optical paths O.P.

In the embodiment shown in FIG. 3, the light splitting unit 300 may include a first light splitting unit 300a and a second light splitting unit 300b.

The optical path O.P that has passed through the transmission lens unit 200 is incident on the first light splitting unit 300a. The incident optical path O.P is divided into a plurality of optical paths O.P, and at least one optical path O.P is incident on the second optical splitting unit 300b and the waveform detection unit 500 to be described later.

At least one optical path O.P among the plurality of optical paths O.P divided by the first optical splitting unit 300b is incident on the second light splitting unit 300b. The incident optical path OP is further divided into a plurality of optical paths OP, and is at least one in the first phase detection unit 400a and the second phase detection unit 400b of the image detection unit 400 to be described later. The optical path OP of is incident.

Alternatively, the light splitting unit 300 may be provided in a single number, and may divide the incident light path O.P into at least three or more light paths O.P.

In this case, the plurality of divided optical paths OP are at least in the first phase detection unit 400a and the second phase detection unit 400b of the image detection unit 400 to be described later, and the waveform detection unit 500 to be described later. Each optical path OP may be incident.

The plurality of optical paths O.P divided by the optical splitting unit 300 form the same image with each other. In other words, the same image is formed in the image detection unit 400 to be described later and the waveform detection unit 500 to be described later to which the divided optical paths O.P are respectively incident.

This also applies to an embodiment in which the phase detection unit 400 to be described later includes the first phase detection unit 400a and the second phase detection unit 400b. That is, the same image is formed in the first image detection unit 400a, the second image detection unit 400b, and the waveform detection unit 500 to which the divided optical paths O.P are respectively incident.

Accordingly, the light detection device according to an embodiment of the present invention uses the image detection unit 400 to determine the location and focus of the subject S and the light detection target T, and the waveform detection unit 500 to be described later. The waveform W of light emitted from the light detection target T may be detected by using. A detailed description of this will be described later.

The light splitting unit 300 is located on the optical path O.P, on the downstream side of the transmission lens unit 200.

In addition, the light splitting unit 300 is located on the optical path O.P divided toward the image detection unit 400 to be described later, on the upstream side of the image detection unit 400 to be described later. Further, the light splitting unit 300 is located on the divided optical path O.P toward the waveform detection unit 500 to be described later, on the upstream side of the waveform detection unit 500 to be described later.

That is, the light splitting unit 300 may be located between the transmission lens unit 200 and the image detection unit 400 to be described later, and also between the transmission lens unit 200 and the waveform detection unit 500 to be described later. .

The distance between the light splitting unit 300 and the image detection unit 400 to be described later and the distance between the light splitting unit 300 and the waveform detection unit 500 to be described later may be the same. That is, the light splitting unit 300 may be disposed such that the image detection unit 400 to be described later and the waveform detection unit 500 to be described later have the same distance apart.

Accordingly, images formed by the divided optical paths OP that are divided by the light splitting unit 300 and incident on the image detection unit 400 to be described later and the waveform detection unit 500 to be described later may be the same. .

(4) Description of the phase detection unit 400

The image detection unit 400 detects an image of light passing through the optical path O.P divided by the light splitting unit 300.

Specifically, one of the optical paths O.P divided by the optical splitting unit 300 is incident on the image detection unit 400. The image detection unit 400 is configured to detect an image formed by light passing through the incident optical path O.P.

In an embodiment, the image detection unit 400 may be provided with a charge coupled device (CCD) camera or the like. The image detection unit 400 may be provided in any form capable of detecting an image from light.

The image detection unit 400 is configured to detect and adjust the position and focus of the formed image. To this end, the image detection unit 400 may include a separate member (not shown) for adjusting the focal position and the focal length.

As will be described later, the image formed in the image detection unit 400 is also formed in the waveform detection unit 500 to be described later.

Accordingly, the user sets the position and focus using the image detection unit 400 in order to detect the light emitted from the light detection target T, and the waveform W of the light through the waveform detection unit 500 Can be detected. A detailed description of this will be described later.

In the embodiment shown in FIG. 2, the image detection unit 400 is provided in a single number, and is configured such that any one of the optical paths O.P divided by the light splitting unit 300 is incident.

Alternatively, the phase detection unit 400 may include a first phase detection unit 400a and a second phase detection unit 400b.

That is, as described above, the light splitting unit 300 may divide the incident optical path O.P into at least two optical paths O.P. In this case, any one of the plurality of optical paths O.P divided by the optical splitting unit 300 may be incident on the first and second phase detection units 400a and 400b, respectively.

Viewing angles of the first image detection unit 400a and the second image detection unit 400b may be configured to be different from each other. As an example, the viewing angle of the first image detection unit 400a may be configured as a telephoto angle, and the viewing angle of the second image detection unit 400b may be configured as a wide angle.

In this case, the sizes of images that can be detected by the first and second phase detection units 400a and 400b may be diversified. Accordingly, it is possible to more effectively detect the position and focus of the subject S and the light emitted from the light detection target T.

In the embodiment shown in FIG. 3, the light splitting unit 300 includes a first light splitting unit 300a and a second light splitting unit 300b.

Any one of the optical paths O.P that are incident on and divided into the first optical splitting unit 300a is incident on the waveform detection unit 500 to be described later. In addition, any one of the divided optical paths O.P is incident on the second optical splitting unit 300b and divided again.

Any one of the optical paths O.P divided by the second optical splitting unit 300b is incident on the first image detection unit 400a. In addition, the other one of the optical paths O.P divided by the second optical splitting unit 300b is incident on the second image detecting unit 400b.

That is, the number and arrangement method in which the image detection units 400 are provided may be changed to correspond to the number and arrangement method in which the light splitting units 300 are provided.

The image detected by the image detection unit 400 may be output through the image output module 710 of the output unit 700 to be described later. In an embodiment, the image output module 710 may output the detected image as visualization information.

To this end, the image detection unit 400 may be electrically or optically connected to an output unit 700 to be described later.

(5) Description of the waveform detection unit 500

The waveform detection unit 500 detects a waveform W of light passing through the optical path O.P divided by the optical splitting unit 300.

Specifically, any one of the optical paths O.P divided by the optical splitting unit 300 is incident on the waveform detection unit 500. The waveform detection unit 500 is configured to detect a waveform W of light passing through the incident optical path O.P.

As described above, the divided optical path O.P incident on the waveform detection unit 500 is a different optical path O.P from the divided optical path O.P incident on the image detection unit 400.

Further, the waveform detection unit 500 may be configured to detect not only a visible ray region of light passing through the incident light path O.P, but also a waveform W in an ultraviolet region and an infrared region.

In an embodiment, the waveform detection unit 500 may be provided with a PMT, an avalanche photodiode, or the like capable of detecting the waveform W of light. In addition, the waveform detection unit 500 may include an ultraviolet detector and an infrared detector.

In addition, the waveform detection unit 500 may be provided with an oscilloscope, an AD converter, or the like.

Light passing through the optical path O.P incident on the waveform detection unit 500 is the same as the light passing through the optical path O.P incident on the image detection unit 400.

In other words, the image on which the waveform W is detected by the waveform detection unit 500 is the same as the light forming the image detected by the image detection unit 400.

Accordingly, the user sets the position and focus of the light detection target T using the image detection unit 400, and uses the waveform detection unit 500 to detect the light emitted from the light detection target T. Thus, the waveform W of light can be detected.

In the illustrated embodiment, the number of waveform detection units 500 is provided so as to detect all the waveforms W of light passing through the incident optical path O.P. In other words, a single waveform detection unit 500 may detect all of the waveforms W in the ultraviolet region, the visible region, and the infrared region.

In an embodiment not shown, a plurality of waveform detection units 500 may be provided, and may be configured to respectively detect the waveforms W of light passing through the incident optical path O.P.

In this case, each of the plurality of waveform detection units 500 may have different regions of the waveform W to detect each other. That is, the plurality of waveform detection units 500 may be configured to detect waveforms W in the ultraviolet region, the visible region, and the infrared region, respectively.

In this case, each waveform W can be detected according to the frequency domain of the waveform W of light passing through the incident optical path O.P.

In the embodiment not shown above, in order to divide the optical path OP into a plurality of optical paths OP incident on the plurality of waveform detection units 500, an additional optical splitting unit (not shown) may be provided. have.

The waveform W detected by the waveform detection unit 500 may be output through the waveform output module 720 of the output unit 700 to be described later. In an embodiment, the waveform output module 720 may output the detected waveform W as visualization information.

To this end, the waveform detection unit 500 may be electrically or optically connected to an output unit 700 to be described later.

The waveform detection unit 500 includes a waveform filter module 510.

The waveform filter module 510 is located on the upstream side of the waveform detection unit 500 on the divided optical path O.P. In other words, the waveform filter module 510 is located between the optical splitting unit 300 and the waveform detecting unit 500 on the divided optical path O.P.

The waveform filter module 510 is configured to filter light passing through the optical path O.P incident on the waveform detection unit 500. The waveform filter module 510 may filter light passing through the incident optical path O.P based on factors such as a wavelength region, a period, or a frequency.

Accordingly, the user can filter the light passing through the optical path OP by using the waveform filter module 510 after the position and focus of the light detection target T is aligned by the image detection unit 400, The waveform W detected at 500 can be adjusted.

(6) Description of the spatial filter unit 600

The spatial filter unit 600 filters the optical path O.P incident on the image detection unit 400 and the waveform detection unit 500.

Specifically, the spatial filter unit 600 blocks at least a part of the optical path O.P that is emitted or reflected from the subject S. The optical path OP, at least partially blocked by the spatial filter unit 600, passes through the transmission lens unit 200 and then is divided by the optical splitting unit 300, and the image detection unit 400 and the waveform detection unit ( 500).

The spatial filter unit 600 is located between the objective lens unit 100 and the transmission lens unit 200 on the optical path O.P. That is, the spatial filter unit 600 is located on the downstream side of the objective lens unit 100 on the optical path O.P. Further, the spatial filter unit 600 is located on the upstream side of the transmission lens unit 200 on the optical path O.P.

Accordingly, the optical path O.P passing through the objective lens unit 100 may be filtered by the spatial filter unit 600 and then incident on the transmission lens unit 200.

It is preferable that the spatial filter unit 600 is located adjacent to the subject S. This is to filter the image of the light while observing a waveform measured by spatially filtering the light emitted or reflected from the subject S.

Accordingly, it is preferable that the objective lens unit 100 positioned on the upstream side of the spatial filter unit 600 is also positioned adjacent to the subject S. In addition, it is preferable that the spatial filter unit 600 and the objective lens unit 100 are also positioned adjacent to each other.

In an embodiment, the spatial filter unit 600 may filter the optical path O.P in a direction from the outside to the inside of the optical path O.P (see FIGS. 11 and 12 ).

In other words, the spatial filter unit 600 may block at least a part of the optical path O.P in a direction from the outside of the optical path O.P to the inside.

The location of the spatial filter unit 600 may be changed. That is, the spatial filter unit 600 may be disposed at an arbitrary position where the optical path O.P guided by the 100 may be incident.

To this end, the spatial filter unit 600 may be disposed to be repositionable. Of course, when the position of the spatial filter unit 600 is changed, the positions of the objective lens unit 100, the transmission lens unit 200, the image detection unit 400, and the waveform detection unit 500 may also be changed.

Alternatively, when the position of the spatial filter unit 600 is changed, a separate reflective member (not shown) or a refractive member (not shown) for changing the optical path O.P may be provided. In this case, it is not necessary to change the positions of the objective lens unit 100, the transmission lens unit 200, the image detection unit 400, and the waveform detection unit 500.

The spatial filter unit 600 includes a space opening 610 and a space blocking part 620.

The spatial opening 610 is a portion through which the optical path O.P passes. The optical path O.P passing through the spatial opening 610 does not undergo a separate filtering process.

That is, the optical path O.P passing through the spatial opening 610 becomes the original optical path O.P that is emitted or reflected from the subject S.

The space blocking part 620 is a part where the optical path O.P is blocked. The optical path O.P incident on the spatial filter unit 600 cannot pass through the spatial filter unit 600 by the spatial blocking unit 620 and proceed to the light splitting unit 300.

The space blocking unit 620 completely blocks the incident optical path O.P. That is, the space blocking unit 620 does not control the amount of light that the incident optical path O.P passes, but prevents the optical path O.P from proceeding any more.

Accordingly, among the optical paths O.P incident on the spatial filter unit 600, only the optical path O.P incident on the spatial opening 610 may pass through the spatial filter unit 600. The spatial filter unit 600 filters the optical path O.P incident through the above-described process.

In the illustrated embodiment, the space blocking part 620 extends from the outside to the inside of the space filter unit 600. In one embodiment, the spatial filter unit 600 may be provided in a cylindrical shape.

In the above embodiment, the space blocking part 620 may be provided as a plate-shaped member extending from the outer peripheral surface of the space filter unit 600 toward the inside.

Accordingly, the optical path O.P filtered by the spatial filter unit 600 has a shape cut from the outside to the inside of the cross section (see FIGS. 11 and 12 ).

The space opening 610 is formed by the space blocking part 620. That is, a portion of the spatial filter unit 600 in which the space blocking portion 620 is not provided is formed as the spatial opening 610.

The surface area of the space blocking part 620 may be changed. In other words, the area occupied by the space blocking unit 620 in the spatial filter unit 600 may be changed. To this end, the space blocking unit 620 may have a structure that can be unfolded or folded like a fan.

The space blocking unit 620 may be configured to increase its area in a direction from the outside to the inside of the space filter unit 600. In the above embodiment, the space opening 610 is formed as a space in which the space blocking part 620 is not located, that is, a space formed in the center of the spatial filter unit 600 surrounded by the space blocking part 620.

Accordingly, when the area of the space blocking part 620 is changed, the area of the space opening 610 may also be changed accordingly.

Specifically, the area of the space blocking part 620 and the area of the space opening 610 are maintained such that the sum of the respective areas is constant and may be changed from each other. That is, the area of the space blocking part 620 and the area of the space opening 610 have a negative correlation and may be changed.

At this time, the spatial filter unit 600 is in a first state in which the space blocking unit 620 is completely unfolded so that the spatial opening 610 is not formed to block all the optical path OP, and the spatial opening 610 is at least partially A second state in which the space blocking unit 620 is partially unfolded so that at least a portion of the optical path OP passes through, and the space blocking unit 620 is completely folded so that the space opening 610 becomes the largest area and the optical path ( OP) may be maintained in any one of the third states passing through.

By the above structure, the spatial filter unit 600 blocks at least a part of the incident light path OP, and thus the object S formed by light passing through the light path OP incident on the image detection unit 400 Among the images of ), the remaining images excluding the image of the light detection target T may be filtered.

The space filter unit 600 may be provided with a separate dial member (not shown) for changing the surface area of the space blocking unit 620.

A detailed description of the process of detecting the image and waveform W of the optical path O.P filtered by the spatial filter unit 600 will be described later.

(7) Description of the output unit 700

The output unit 700 outputs the image and the waveform W of the optical path O.P detected by the image detection unit 400 and the waveform detection unit 500.

Specifically, the output unit 700 may output an image of the optical path O.P formed in the image detection unit 400 by the optical path O.P. To this end, the output unit 700 may be electrically or optically connected to the image detection unit 400.

In addition, the output unit 700 may output a waveform W of the optical path O.P detected by the waveform detection unit 500. To this end, the output unit 700 may be electrically or optically connected to the waveform detection unit 500.

Here, the meaning that the output unit 700 is electrically connected means that the output unit 700 is provided as a display unit (not shown) and is connected to receive an electrical signal and output it as a digital signal.

That the output unit 700 is optically connected means that the output unit 700 is provided as a lens unit (not shown) and is connected to receive an optical signal and output an optical signal.

Of course, in the case of the waveform detection unit 500, since it is common to convert the waveform W of the optical path OP into an electrical signal, the output unit 700 and the waveform detection unit 500 are preferably electrically connected. Do.

In an embodiment in which the phase detection unit 400 includes a first phase detection unit 400a and a second phase detection unit 400b, the output unit 700 includes a first phase detection unit 400a and a second phase detection unit. All of the unit 400b may be electrically or optically connected.

As described above, if an image that passes through the objective lens unit 100 and is formed on the spatial filter unit 600 is referred to as a 1 ^st Image, the image detection unit ( 400) and a phase and a waveform (W) detected by the waveform detecting unit 500 can be defined as a secondary image (image 2 ^nd).

The output unit 700 includes a phase output module 710 and a waveform output module 720.

The image output module 710 outputs information related to an image formed in the image detection unit 400 by the divided optical path O.P. The image output module 710 may be provided in any form capable of outputting information related to an image formed in the image detection unit 400.

In an embodiment, the image output module 710 may be provided as a display unit (not shown) capable of outputting an image as digitized visualization information.

In another embodiment, the image output module 710 may be provided as a lens unit (not shown) capable of outputting optical visualization information, that is, the image itself.

The waveform output module 720 outputs information related to the waveform W detected by the waveform detection unit 500. The waveform output module 720 may be provided in any form capable of outputting information related to the waveform W detected by the waveform detection unit 500.

In an embodiment, the waveform output module 720 may be provided as a display unit (not shown) capable of outputting the detected waveform W as digitized visualization information.

In another embodiment, the waveform output module 720 may be provided with a lens unit (not shown) capable of outputting optical visualization information, that is, the image itself.

However, considering that the waveform detection module 600 is configured to detect not only the optical path OP in the visible light region, but also the optical path OP in the ultraviolet and infrared regions, the waveform output module 720 detects It is preferable to be configured to output the generated waveform W as digitized visualization information.

The information related to the waveform W output from the waveform output module 720 may include arbitrary information that can define the waveform W of the detected waveform W. In an embodiment, the waveform output module 720 may output information such as a wavelength region, a period, a frequency, and an amplitude of the detected waveform.

3. Description of the control method of the optical detection device according to the embodiment of the present invention

The optical detection apparatus according to an embodiment of the present invention detects the position and focus of the subject S using the image detection unit 400, and uses the spatial filter unit 600 to detect only the image of the light detection target T. Can be obtained.

In addition, the optical path O.P that forms the image of the light detection target T obtained by the image detection unit 400 is equally incident on the waveform detection unit 500. Therefore, even if an additional device is not provided, the waveform detection unit 500 can easily detect the waveform W of the light detection target T.

Hereinafter, a method of controlling a photodetector according to an embodiment of the present invention will be described in detail with reference to FIGS. 4 to 10.

Each step of the method for controlling the light detection device described below is according to an embodiment, and the order in which each step is performed may be changed.

(1) Description of the step (S100) of adjusting the image detection unit 400 so that the reflected light from the subject S including the light detection target T is incident

Hereinafter, this step will be described with reference to FIGS. 4 and 5.

As described above, light passing through the optical path O.P emitted or reflected from the subject S is incident on the image detection unit 400.

In this step, the image detection unit 400 is adjusted so that the light reflected from the subject S including the light detection target T is incident (S100).

As a method in which the image detection unit 400 is adjusted so that the light reflected from the subject S is incident, a method in which the image detection unit 400 is adjusted to face the subject S straight is exemplified.

Alternatively, an additional refractive member (not shown) or a reflective member (not shown) is provided in the light detection device so that the light path OP emitted or reflected from the subject S is directed toward the image detection unit 400. You can also consider how it is adjusted.

This step (S100) will be described in more detail as follows.

First, the objective lens unit 100 guides the light passing through the optical path O.P to the spatial filter unit 600 (S110).

To this end, the objective lens unit 100 may be disposed to face the subject S. Alternatively, a separate refractive member (not shown) or a reflective member (not shown) is provided on the front side of the objective lens unit 100, that is, on the subject S and the objective lens unit 100, and the optical path ( OP) may be configured to face the objective lens unit 100.

Accordingly, the light path OP emitted or reflected from the subject S passes through the objective lens unit 100 and is condensed, and enters the spatial filter unit 600 located on the downstream side of the objective lens unit 100 do.

As will be described later, filtering of the optical path O.P by the spatial filter unit 600 may not be performed in this step. This is because after the image detection unit 400 detects the position and focus of the object S, it is effective to filter the optical path O.P.

That is, in this step, the spatial filter unit 600 is maintained in the above-described third state, so that all optical paths O.P incident on the spatial filter unit 600 may pass.

The optical path O.P passing through the spatial filter unit 600 is incident on the transmission lens unit 200 located on the downstream side of the spatial filter unit 600.

The transmission lens unit 200 collects the light path O.P incident through the spatial filter unit 600 and guides it to the light splitting unit 300 (S120).

The optical path O.P guided to the light splitting unit 300 is incident on the light splitting unit 300. As described above, the light splitting unit 300 divides the incident optical path O.P into at least two optical paths O.P.

One of the divided optical paths O.P is incident on the image detection unit 400 and the other is incident on the waveform detection unit 500.

(2) Description of the step (S200) of blocking at least a part of the light passing through the optical path O.P from the subject S to the image detection unit 400 by the spatial filter unit 600

Hereinafter, this step will be described with reference to FIGS. 4 and 6.

In this step, the position and focus of the subject S are detected using the image formed in the image detection unit 400 by the optical path O.P emitted or reflected from the subject S.

In addition, after the position and focus of the subject S is detected, the spatial filter unit 600 is adjusted to block at least a portion of the light passing through the optical path OP from the subject S toward the image detection unit 400 , The optical path OP is filtered (S200).

First, after passing through the spatial filter unit 600 and the transmission lens unit 200 in sequence, any one of the optical paths O.P divided by the optical splitting unit 300 is incident on the image detection unit 400.

Light passing through the optical path OP incident on the image detection unit 400 forms an image of the subject S in the image detection unit 400 (S210). At this time, the image of the subject S formed in the image detection unit 400 corresponds to a primary image (1 ^st Image).

The information related to the image detected by the image detection unit 400 is transmitted to the image output module 710 of the output unit 700, so that the user can recognize information related to the image detected by the image detection unit 400. .

The user inputs information related to the image output to the image output module 710 to detect the position and focus of the subject S.

Specifically, the user may adjust the position or arrangement method of any one of the objective lens unit 100, the transmission lens unit 200, the light splitting unit 300, and the image detection unit 400 to It is adjusted so as to be formed on the detection unit 400.

Preferably, the image detection unit 400 may be adjusted so that the image of the subject S is formed in the center of the image detection unit 400. Also, the image detection unit 400 may adjust the focus of the subject S so that the light detection target T can be clearly grasped.

When the detection of the position and focus of the subject S is completed, the optical path O.P is filtered so that light emitted or reflected from the light detection target T is easily detected.

Specifically, the spatial filter unit 600 is maintained after being adjusted to any one of the above-described first state, second state, and third state, so as to detect light emitted or reflected from the light detection object T. It is adjusted (S220).

At this time, since a part of the optical path O.P emitted or reflected from the light detection object T must pass, it is preferable that the spatial filter unit 600 is adjusted and maintained in the second state.

When the spatial filter unit 600 is adjusted, a part of the optical path OP passes through the spatial filter unit 600 and the remaining part of the optical path OP is spaced according to the state in which the spatial filter unit 600 is maintained. Filtering of the optical path OP is implemented by being blocked by the filter unit 600 (S230).

(3) Description of the step (S300) of dividing the optical path (O.P) passing through the spatial filter unit 600 by the optical splitting unit 300 into at least two

Hereinafter, this step will be described with reference to FIGS. 4 and 7.

In this step, the optical path OP filtered by the spatial filter unit 600 is divided into at least two optical paths OP by the optical splitting unit 300, and the phase detection unit 400 and the waveform detection unit are respectively It is incident on 500 (S300).

First, light passing through the optical path O.P passing through the spatial filter unit 600 passes through the transmission lens unit 200 and enters the light splitting unit 300 (S310). As described above, the optical path O.P incident on the light splitting unit 300 is the optical path O.P filtered by the spatial filter unit 600.

The optical splitting unit 300 divides the incident optical path O.P into at least two optical paths O.P (S320). One of the divided optical paths O.P is incident on the image detection unit 400 and the other is incident on the waveform detection unit 500.

The distance between the image detection unit 400 and the light splitting unit 300 and between the waveform detection unit 500 and the light splitting unit 300 so that the same image is formed in the image detection unit 400 and the waveform detection unit 500 The distance of may be the same (S330).

The process of adjusting the distance between the image detection unit 400 and the light splitting unit 300 and the distance between the waveform detection unit 500 and the light splitting unit 300 is performed before the optical path OP is filtered or split. May be.

(4) Description of the step (S400) of detecting an image formed by light passing through any one of the divided optical paths by the image detection unit 400

Hereinafter, this step will be described with reference to FIGS. 4 and 8.

In this step, any one of the optical paths O.P that are filtered by the spatial filter unit 600 and then divided by the light splitting unit 300 is incident on the image detection unit 400. The image formed by the incident optical path O.P is detected by the image detection unit 400 (S400).

At that time, the secondary image (Image 2 ^nd) filtered by the phase spatial filter unit 600 is detected by the phase detection unit 400. The

First, any one of the optical paths O.P divided by the light splitting unit 300 proceeds toward the image detection unit 400 and is incident on the image detection unit 400 (S410).

Light passing through the optical path O.P incident on the image detection unit 400 forms an image on the image detection unit 400.

The image detection unit 400 detects an image formed by light passing through the incident optical path O.P (S420).

The image detected by the image detection unit 400 is transmitted to the output unit 700 so that the user can recognize it.

(5) Description of the step (S500) of detecting the waveform W of light passing through the other one of the divided optical paths by the waveform detection unit 500

Hereinafter, this step will be described with reference to FIGS. 4 and 9.

In this step, any one of the optical paths O.P that are filtered by the spatial filter unit 600 and then divided by the optical splitting unit 300 is incident on the waveform detection unit 500. The waveform W of light passing through the incident optical path O.P is detected by the waveform detection unit 500 (S500).

In this case, the waveform W detected by the waveform detection unit 500 is the waveform W of the secondary image (2 ^nd Image) filtered by the spatial filter unit 600.

First, any one of the optical paths O.P divided by the optical splitting unit 300 proceeds toward the waveform detection unit 500 and is incident (S510).

The optical path OP incident on the waveform detection unit 500 is different from the optical path OP incident on the above-described image detection unit 400, but the image and waveform W of light passing through each optical path OP The same is as described above.

In this case, the waveform filter module 510 may be positioned on the upstream side of the waveform detection unit 500 on the optical path O.P. Accordingly, the optical path O.P may be filtered by the waveform filter module 510 and then incident on the waveform detection unit 500.

The waveform filter module 510 may be changed according to a region or frequency of the waveform W to be detected by the waveform detection unit 500. That is, the waveform filter module 510 may be changed according to the detection target region of the waveform detection unit 500 among the ultraviolet region, visible ray region, and ultraviolet region of light passing through the optical path O.P.

The optical path O.P filtered by the waveform filter module 510 is incident on the waveform detection unit 500. The waveform detection unit 500 detects a waveform W of light passing through the incident optical path O.P (S520).

The image detected by the waveform detection unit 500 is transmitted to the output unit 700 so that the user can recognize it.

(6) Description of the step (S600) of outputting the image of the detected light and the waveform (W) of the detected light by the output unit 700

Hereinafter, this step will be described with reference to FIGS. 4 and 10.

In this step, information related to the image detected by the image detection unit 400 and information related to the waveform W detected by the waveform detection unit 500 are output so that the user can recognize it (S600).

Information related to the image detected by the image detection unit 400 is transmitted to the image output module 710.

The image output module 710 outputs information related to the received image so that the user can recognize it (S610).

In an embodiment, the image output module 710 may output image-related information as visualization information. In the above embodiment, the user may visually recognize information related to the location and focus of the subject S and the light detection target T included in the subject S through the image output module 710.

When a desired result is not obtained as a result of the confirmation, the user can obtain desired information by repeating the above-described process.

The waveform output module 720 outputs information related to the received waveform W so that the user can recognize it (S620).

In an embodiment, the waveform output module 720 may output information related to the waveform W as visualization information. In the above embodiment, the user may visually recognize information related to the waveform W of the light detection target T.

Accordingly, the user can easily obtain information related to the waveform W of the light detection target T.

4. Description of the effects of the light detection device and control method according to the embodiment of the present invention

The optical detection device according to an embodiment of the present invention determines the subject S using the image detection unit 400 which is advantageous for grasping the position and focus of the subject S. Further, information related to the waveform W of light emitted or reflected from the light detection target T is detected using the waveform detection unit 500 which is advantageous for detecting the waveform W of light.

Accordingly, when light is detected, it is possible to easily grasp the position and focus of the subject S and to detect information related to the waveform W of light.

In addition, the spatial filter unit 600 is configured to block some or all of the light passing through the optical path O.P. Accordingly, the image detected by the image detection unit 400 may be checked and the remaining images excluding the light detection object T may be filtered through the spatial filter unit 600.

Accordingly, the image other than the light detection object T is removed, and only information related to light emitted or reflected from the light detection object T can be easily obtained.

In addition, the image detection unit 400 and the waveform detection unit 500 are arranged so that the same image is formed, respectively.

Therefore, by filtering the remaining images except for the light detection target T using information related to the image detected by the image detection unit 400, which is easy to visually identify, the waveform detection unit 500 ) Can be adjusted to detect only the waveform (W) information.

In addition, the image detection unit 400 may easily detect information related to light even when the intensity of the light emitted or reflected from a distance, or the intensity of the emitted or reflected light is weak.

Therefore, even when the light detection target T is located at a distance or the intensity of light emitted or reflected from the light detection target T is weak, the position and focus of the light detection target T using the image detection unit 400 Can be easily obtained.

Further, the image detection unit 400 is configured to detect and adjust the position and focus of the formed image.

Therefore, even if the position and focus of the subject S is changed, the changed position and focus of the subject S can be easily performed without a separate optical calculation process by using information related to the image acquired by the image detection unit 400. Can be obtained.

In addition, the space blocking unit 620 of the spatial filter unit 600 is configured to block the optical path O.P, and the area occupied by the space blocking unit 620 is configured to be changeable.

Therefore, by adjusting the space blocking unit 620 to adjust the area of the spatial opening 610, the image of the subject S except for the light detection target T is filtered and only the image of the light detection target T Can be easily obtained.

In addition, the waveform detection unit 500 is configured to detect waveforms W of light in the ultraviolet region and the infrared region as well as the visible light region.

Accordingly, even when the light emitted from the light detection object T is not visually identified, detection by the waveform detection unit 500 is possible.

Although the above has been described with reference to preferred embodiments of the present invention, those of ordinary skill in the art will variously modify and change the present invention without departing from the spirit and scope of the present invention described in the following claims. You will understand that you can.

100: objective lens unit
110: first objective lens
120: second objective lens
130: third objective lens
200: transmission lens unit
300: optical split unit
300a: first optical splitting unit
300b: second optical splitting unit
400: phase detection unit
400a: first phase detection unit
400b: second phase detection unit
500: waveform detection unit
510: waveform filter module
600: space filter unit
610: space opening
620: space block
700: output unit
710: phase output module
720: waveform output module
S: Subject
T: Light detection target (Target)
OP: Optical path
1 ^st Image: Primary image
2 ^nd Image: 2nd image
W: Waveform

Claims (12)

A spatial filter unit positioned on an optical path through which light reflected from an object including a light detection object passes;
An optical splitting unit positioned on the optical path downstream of the spatial filter unit and configured to divide the optical path into at least two;
An image positioned on any one of the divided optical paths, and configured to detect and adjust the position and focus of the image formed by the incident light passing through the one of the divided optical paths. Detection unit;
And a waveform detection unit configured to detect a waveform of light passing through the other divided optical path by incident light passing through the other of the divided optical paths,
The spatial filter unit,
Blocking at least a part of the optical path, the image of the subject formed by the light incident on the image detection unit is configured to filter the remaining images other than the image of the light detection target,
When the position and focus of the image formed by the light incident on the image detection unit are adjusted, the position and focus of the image formed by the light incident on the waveform detection unit are adjusted,
An image formed in the image detection unit by light passing through one of the divided optical paths and an image formed by light passing through the other divided optical path in the waveform detection unit are the same,
Light detection device. The method of claim 1,
The spatial filter unit,
A first state in which all the optical paths are blocked;
A second state of passing at least a portion of the optical path; And
It may be maintained in any one of the third states in which all the optical paths pass,
Light detection device. The method of claim 1,
So that the same phase is formed in the phase detection unit and the waveform detection unit,
The image detection unit and the waveform detection unit are each disposed so as to have the same distance from the optical splitting unit,
Light detection device. The method of claim 1,
A transmission lens unit positioned on the optical path downstream of the spatial filter unit and on an upstream side of the optical splitting unit, and configured to guide light that has passed through the spatial filter unit to the optical splitting unit,
Light detection device. The method of claim 1,
Including a waveform filter module located on the optical path downstream of the optical splitting unit and upstream of the waveform detection unit, configured to filter light passing through the other divided optical path according to a waveform region,
Light detection device. The method of claim 1,
Including an objective lens unit positioned on the optical path downstream of the subject and upstream of the spatial filter unit, and configured to guide the light to the spatial filter unit,
Light detection device. (a) adjusting, by the image detection unit, so that the reflected light from the object including the light detection object is incident;
(b) blocking at least a portion of light passing through an optical path from the subject toward the image detection unit by a spatial filter unit;
(c) dividing the optical path through the spatial filter unit into at least two by a light splitting unit;
(d) detecting an image formed by light passing through any one of the divided optical paths by the image detection unit; And
(e) detecting a waveform of light passing through the other one of the divided optical paths by the waveform detection unit,
The image detection unit is configured to detect and adjust the position and focus of the image formed by the incident light,
When the position and focus of the image formed by the light incident on the image detection unit are adjusted, the position and focus of the image formed by the light incident on the waveform detection unit are adjusted,
An image formed in the image detection unit by light passing through one of the divided optical paths and an image formed in the waveform unit by light passing through another of the divided optical paths are the same,
Control method of the light detection device. The method of claim 7,
The step (b),
(b1) adjusting the spatial filter unit to any one of a first state in which all the optical paths are blocked, a second state in which at least a part of the optical path is passed, and a third state in which all the optical paths are passed. Containing,
Control method of the light detection device. The method of claim 7,
The step (e),
(e1) filtering the light passing through the other one of the divided optical paths by the waveform filter module; And
(e2) a waveform detection unit comprising the step of detecting the waveform of the light filtered by the waveform filter module,
Control method of the light detection device. The method of claim 7,
The step (a),
(a1) including the step of an objective lens unit guiding light passing through the optical path to the spatial filter unit,
Control method of the light detection device. The method of claim 7,
The step (a),
(a2) including the step of guiding the light passing through the spatial filter unit by a transmission lens unit to the light splitting unit,
Control method of the light detection device. The method of claim 7,
The step (c),
(c1) including the step of disposing the image detection unit and the waveform detection unit to be located at the same distance as the optical splitting unit, respectively,
Control method of the light detection device.

Images