KR20180104246A - Scanner - Google Patents

Abstract

A scanner according to embodiments comprises: a detector receiving light reflected from an object and generating a signal; an optical system with a state changed between a plurality of states including at least a first state and a second state by an electrical signal; and a control part controlling the detector and the optical system, wherein the control part controls the optical system and the detector to generate shape information of the object when the optical system is in the first state, and controls the optical system and the detector to generate color information of the object when the optical system is in the second state.

Description

Scanner {Scanner}

An embodiment relates to a scanner.

To produce a dental prosthesis, it is necessary to acquire the patient's tooth surface information.

Conventionally, in order to acquire the patient's tooth surface information, a substance is administered to the oral cavity of a patient and is obtained by hardening the substance.

In addition, the dental prosthesis was manufactured by processing the prosthesis manually by a dental technician through an impression model. In recent years, computer-aided design (CAD) has been used to design prosthetics, and computer-aided manufacturing (CAM) has been used to manufacture prostheses.

The method of acquiring the tooth surface information of the patient is digitized so as to be compatible with the CAD and CAM system development.

Recently, there has been a method of acquiring an impression model through a 3D scanner and a method using an oral scanner.

The method of acquiring the impression model through a 3D scanner is a method of injecting a material into a patient's mouth, curing the same, and acquiring the impression model through a 3D scanner as in the prior art. This method still needs to inject the substance into the oral cavity of the patient, which is a way of giving a sense of discomfort to the patient.

To improve this, an oral scanner was developed. The oral scanner inserts a scanner into a mouth of a patient to move the scanner, acquires an image, and reconstructs the image to acquire information on the tooth surface of the patient.

In order to implement the oral scanner, a plurality of optical systems are required, and there are a confocal method, a triangulation method, and an active wavefront sampling method according to an implementation method.

In contrast, the conforcer method does not need to apply a separate material to the teeth to average the reflectance of the teeth.

In the confocal method, only the light corresponding to a specific focal plane among the light incident on the detector is sensed by a detector, and the optical system is moved to obtain the image while changing the focal plane, thereby obtaining the surface data of the teeth. Align, 3shape, and the like are developing the above-mentioned scanner system.

However, the conventional scanner has a problem in that the optical system must be moved physically, so that vibration and noise are generated.

To improve this, a chromatic confocal method has been proposed.

1 is a conceptual diagram showing a conventional chromatic connector system.

Referring to FIG. 1, a conventional chromatic connector type oral scanner 1 includes a white light source 2, a beam splitter 3, a chromatic aberration generating lens 5, a detector 6 and a pinhole 7 can do.

The oral scanner 1 irradiates light to the object 9, receives the reflected light from the detector 6 and calculates it to obtain surface information of the object 9.

The white light source 2 emits white light to the beam splitter 3 and the white light is transmitted through the beam splitter 3 to the chromatic aberration generating lens 5. The light transmitted through the chromatic aberration generating lens 5 travels to the object in a form having different focuses depending on wavelengths. That is, light having the first wavelength? 1 of the light transmitted through the chromatic aberration generating lens 5 is focused at a position adjacent to the chromatic aberration generating lens 5, and light having the third wavelength? A focus is generated at a position away from the chromatic aberration generating lens 5 and a focus having a second wavelength lambda 2 is generated between the first wavelength lambda 1 and the third wavelength lambda 3.

Only light corresponding to the surface of the object 9 among the light transmitted through the chromatic aberration generating lens 5 is reflected by the surface of the object 9 and is reflected by the beam splitter 3, And irradiated by the detector 6. For example, in the figure, since the second wavelength? 2 of the light transmitted through the chromatic aberration generating lens 5 coincides with the surface of the object 9, light having the second wavelength? 2 is incident on the beam splitter 3 And the detector 6 calculates the wavelength of the irradiated light so that the distance between the chromatic aberration generating lens 5 and the object 9 is calculated as . The surface information of the object 9 can be obtained through the distance between the chromatic aberration generating lens 5 and the object 9.

The conventional chromatic confocal method has the advantage that the physical movement of the optical system can be omitted as compared with the confocal method, and noise and vibration can be reduced. However, since the depth information is measured through the wavelength, the color surface information of the object can not be obtained.

Embodiments provide a scanner capable of acquiring surface information and color information without noise and vibration.

A scanner according to an embodiment includes a detector for receiving light reflected from an object and generating a signal; An optical system whose state is changed between a plurality of states including at least a first state and a second state by an electric signal; And a control unit for controlling the detector and the optical system, wherein the control unit controls the optical system and the detector to generate shape information of the object when the optical system is in the first state, The controller controls the optical system and the detector to generate color information of the object.

A scanner according to an embodiment includes: a light source that outputs first light including at least a first wavelength and a second wavelength; And an optical system whose state is changed by an electrical signal, the optical system causing a chromatic aberration of the first light in the first state to output second light having a first focal depth and third light having a second focal depth , The optical system may cause the chromatic aberration of the first light in the second state to output the fourth light having the third focus depth and the fifth light having the fourth focus depth.

An embodiment is a scanner for scanning a three-dimensional shape of an object, comprising: a light source; An optical system capable of changing a state according to an electrical signal and changing an optical characteristic according to the state change; And an optical sensor in which unit color pixels including at least R pixels, G pixels, and B pixels are arranged in a two-dimensional array of N x M shapes, wherein when the scanner operates in the first mode, An electrical signal according to light reflected from the target object is detected in only a part of N x M unit color pixels included in the two-dimensional array of sensors, and when the scanner operates in the second mode, An electrical signal corresponding to the light reflected from the object is detected in all of the N x M unit color pixels included in the dimensional array, and when operating in the first mode, Wherein a two-dimensional coordinate value on the pixel array and a color value detected by the first unit color pixel are used to detect a three-dimensional shape of the target object, In operation, the two-dimensional coordinate value of the second unit color pixel on which the electrical signal is detected and the color value detected by the second unit color pixel are used to generate a two-dimensional image for the object Is used.

The scanner according to the embodiment can acquire surface information and color information without noise and vibration by changing the characteristics of light applied to the optical system by applying a voltage to the optical system according to the mode.

1 is a conceptual diagram showing a conventional chromatic connector system.
Fig. 2 is a block diagram for explaining a system including a scanner related to the embodiments of the present invention, an electronic apparatus interlocked with the scanner, and the like.
3 is a view showing a structure of a scanner according to the first embodiment.
4 is a view showing a light source according to the first embodiment.
5 is a view showing another embodiment of the light source according to the first embodiment.
6 is a view showing another embodiment of the light source according to the first embodiment.
7 is a cross-sectional view showing an optical system according to the first embodiment.
Fig. 8 is a diagram showing light that is changed and output in the optical system according to the first embodiment.
9 is a view showing another structure of the optical system according to the first embodiment.
10 is a view showing a voltage applied to the optical system of Fig.
11 is a view showing a voltage applied to the optical system of Fig.
12 is a view showing an operation of acquiring color information of the scanner according to the first embodiment.
13 is a view showing an operation of acquiring surface information of the scanner according to the first embodiment.
14 is a diagram showing an operation of acquiring the wide angle preview of the scanner according to the first embodiment.
15 is a diagram showing a method of driving the scanner according to the first embodiment.
16 is a view showing another driving method of the scanner according to the first embodiment.
17 is a view showing a scanner according to the second embodiment.
18 is a view showing a structure of a scanner according to the third embodiment.
Fig. 19 is a diagram showing a surface information acquiring operation of the scanner according to the third embodiment. Fig.
20 is a diagram showing an operation of acquiring color information of a scanner according to the third embodiment.
21 is a view showing the structure of a scanner according to the fourth embodiment.
22 is a perspective view showing a lens array according to the fourth embodiment.
23 is a perspective view showing a pinhole array according to the fourth embodiment.
Fig. 24 is a diagram showing paths of light in the lens array and the pinhole array according to the fourth embodiment. Fig.
FIG. 25 is a diagram showing an operation of acquiring surface information of the scanner according to the fourth embodiment. FIG.
FIG. 26 is a diagram showing an operation of acquiring color information of a scanner according to the fourth embodiment. FIG.
27 is a view showing an operation of acquiring wide angle preview information of the scanner according to the fourth embodiment.
28 is a view showing a surface information obtaining operation of the scanner according to the fifth embodiment.
FIG. 29 is a view showing an operation of acquiring color information of the scanner according to the fifth embodiment. FIG.
30 is a diagram showing an operation of acquiring wide angle preview information of the scanner according to the fifth embodiment.
31 is a view showing a surface information acquiring operation of the scanner according to the sixth embodiment.
32 is a view showing the dental caries information acquisition operation of the scanner according to the sixth embodiment.

Hereinafter, specific embodiments of the present invention will be described in detail with reference to the drawings. It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the inventive concept. Other embodiments falling within the scope of the inventive concept may readily be suggested, but are also considered to be within the scope of the present invention.

The same reference numerals are used to designate the same components in the same reference numerals in the drawings of the embodiments.

A scanner according to an embodiment includes a detector for receiving light reflected from an object and generating a signal; An optical system whose state is changed between a plurality of states including at least a first state and a second state by an electric signal; And a control unit for controlling the detector and the optical system, wherein the control unit controls the optical system and the detector to generate shape information of the object when the optical system is in the first state, The controller controls the optical system and the detector to generate color information of the object.

The control unit may control the optical system and the detector to generate preview information of the object when the optical system is in the second state.

The plurality of states may further include a third state, and the control unit may control the optical system and the detector to generate the wide-angle preview information when the optical system is in the third state.

The surface shape of the optical system can be kept constant regardless of whether the electric signal is applied or not.

The optical system may be a liquid crystal lens.

The control unit may apply an electric signal so that the optical system has the same optical characteristics as the convex lens when the optical system is in the first state.

The control unit may apply an electric signal to operate as a Fresnel lens having the same optical characteristics as the convex lens when the optical system is in the first state.

And a light source for emitting light to the object through the optical system, wherein the light source is capable of outputting light in the form of mixed light of a plurality of wavelength regions.

The light source may output white light.

The optical system can convert the path of light from the light source according to a plurality of states.

When the optical system is in the first state, the optical system may convert the light from the light source to have a different focal length for each wavelength region and output the converted light.

The optical system can output light from the light source without changing the characteristic when the optical system is in the second state.

When the optical system is in the third state, the optical system can diffuse and output the light from the light source.

The detector may receive light whose focus is located on the surface of the object when the optical system is in the first state.

The amount of light received by the detector when the optical system is in the first state may be smaller than the amount of light received by the detector when the optical system is in the second state.

When the optical system is in the first state, the light receiving region of the detector may be smaller than the light receiving region of the detector when the optical system is in the second state.

The optical system may be controlled so that the first state and the second state alternate with each other.

The optical system can be controlled so that the first state, the second state, and the third state are alternately changed.

A scanner according to an embodiment includes: a light source that outputs first light including at least a first wavelength and a second wavelength; And an optical system whose state is changed by an electrical signal, the optical system causing a chromatic aberration of the first light in the first state to output second light having a first focal depth and third light having a second focal depth , The optical system may cause the chromatic aberration of the first light in the second state to output the fourth light having the third focus depth and the fifth light having the fourth focus depth.

The third focus depth and the fourth focus depth may be the same.

The fourth light and the fifth light may have the form of light that diverges.

The second light may be caused by the first wavelength, and the third light may be caused by the second wavelength.

The light source may include a red light source, a blue light source, and a green light source, and the light source may output white light.

A scanner according to an embodiment is a scanner for scanning a three-dimensional shape of an object, comprising: a light source; An optical system capable of changing a state according to an electrical signal and changing an optical characteristic according to the state change; And an optical sensor in which unit color pixels including at least R pixels, G pixels, and B pixels are arranged in a two-dimensional array of N x M shapes, wherein when the scanner operates in the first mode, An electrical signal according to light reflected from the target object is detected in only a part of N x M unit color pixels included in the two-dimensional array of sensors, and when the scanner operates in the second mode, An electrical signal corresponding to the light reflected from the object is detected in all of the N x M unit color pixels included in the dimensional array, and when operating in the first mode, Wherein a two-dimensional coordinate value on the pixel array and a color value detected by the first unit color pixel are used to detect a three-dimensional shape of the target object, In operation, the two-dimensional coordinate value of the second unit color pixel on which the electrical signal is detected and the color value detected by the second unit color pixel are used to generate a two-dimensional image for the object Can be used.

A scanner according to an embodiment includes a light source that outputs first light including at least a first wavelength and a second wavelength; A lens for receiving the first light and generating a chromatic aberration of the first light to output a second light, the second light including at least third light and fourth light having different focus depths, Is caused by the first wavelength and the fourth light is caused by the second wavelength; And an optical system in which the state is changed between a plurality of states including at least a first state and a second state by an electrical signal, wherein the optical system includes: a first optical system for compensating for the chromatic aberration of the second light when in the first state; Wherein the fifth light includes at least a sixth light and a seventh light and the difference in focal depths of the sixth light and the seventh light is different from a focus of the third light and the fourth light, May be less than the difference in depth.

The focal depths of the sixth light and the seventh light may be the same.

When the optical system is in the second state, the optical system can transmit the second light to the object.

The lens may be a physical lens.

The lens may be a Fresnel lens.

The optical system may be a liquid crystal lens.

The surface shape of the optical system can be kept constant regardless of whether the electric signal is applied or not.

The optical system may have the same optical characteristics as the concave lens when in the first state.

The optical system can output without changing the optical characteristic of light from the light source when the optical system is in the second state.

A detector for detecting light reflected from the object; And a controller for controlling the optical system and the detector.

The control unit may control the optical system to the first state and generate color information of the object through the light received by the detector.

The control unit may control the optical system to the second state and may generate shape information of the object through the light received by the detector.

The control unit may generate preview information through the light received by the detector.

The optical system may be controlled so that the first state and the second state alternate with each other.

A scanner according to an embodiment includes: a light source that outputs first light including at least a first wavelength and a second wavelength; A lens that changes a first wavelength of the first light to a second light having a first focus and changes a second wavelength of the first light to third light having a second focus; An optical system whose state is changed between a plurality of states including at least a first state and a second state by an electric signal; A detector for receiving light reflected from the object; And a controller for controlling the optical system and the detector, wherein the controller generates color information of the object when the optical system is in the first state, and generates surface information of the object when the optical system is in the second state .

When the optical system is in the first state, the optical system can compensate the chromatic aberration of the second light and the third light.

And may have optical characteristics corresponding to the concave lens when the optical system is in the first state.

When the optical system is in the second state, the optical system may receive the second light and the third light and output the second light and the third light.

When the optical system is in the second state, the optical system may have an optical characteristic of the glass.

The optical system may be a liquid crystal lens.

A scanner according to an embodiment includes a detector for receiving light reflected from an object and generating a signal; An optical system whose state is changed between a plurality of states including at least a first state and a second state by an electric signal; And a controller for controlling the detector and the optical system, wherein when the optical system is in the first state, light having a first characteristic is incident on the optical system, and when the optical system is in the second state, Is incident on the optical system, and the light having the first characteristic may be a form in which the light is diffused.

The light having the second characteristic may be in the form of a plane light.

A light source for emitting light to the optical system; And a pinhole array positioned between the light source and the optical system to change characteristics of the light.

And the pinhole array can output a glow when the optical system is in the first state.

The pinhole array can output the surface light when the optical system is in the second state.

The pinhole array may be a liquid crystal panel.

In the pinhole array, when the optical system is in the first state, a light shielding region is created and a pinhole can be defined.

When the optical system is in the second state, the pinhole array may have a pinhole removed and optical characteristics corresponding to the glass.

And a lens array disposed between the light source and the pinhole array to change a path of light from the light source to output light having a plurality of focal points in the pinhole array direction.

And a first auxiliary light source for irradiating light to the optical system, wherein the first auxiliary light source can output the surface light to the optical system when the optical system is in the second state.

The light source and the first auxiliary light source may be alternately flickered.

When the optical system is in the first state, the light source is turned on, the first auxiliary light source is turned off, and when the optical system is in the second state, the light source is turned off and the first auxiliary light source can be turned on have.

And a second auxiliary light source for emitting light to the object, and the second auxiliary light source can output light to the object when the optical system is in the second state.

The light source and the second auxiliary light source may alternately flicker.

When the optical system is in the first state, the light source is turned on, the second auxiliary light source is turned off, and when the optical system is in the second state, the light source is turned off and the second auxiliary light source can be turned on have.

The second auxiliary light source may be located at the tip of the scanner.

The second auxiliary light source may output light in a blue wavelength region.

The second auxiliary light source may output quantitative light-induced fluorescence (QLF) light.

The control unit may detect dental caries when the optical system is in the second state.

A scanner according to an embodiment includes: a light source that outputs light; A pinhole array for changing characteristics of light output from the light source; An optical system for changing a focus of light from the pinhole array; And a control unit for controlling the pinhole array and the optical system, wherein the control unit controls the pinhole array to output the ghost light in the first mode, and controls the optical system to have characteristics corresponding to the convex lens.

The control unit controls the surface light output in the pinhole array in the second mode so that the optical system has characteristics corresponding to the glass.

The controller controls the surface light output in the pinhole array to be output in the third mode and controls the optical system to have characteristics corresponding to the concave lens.

A scanner according to an embodiment includes: a light source that outputs light; A pinhole array for outputting light output from the light source in a light-emitting mode; An auxiliary light source for outputting the surface light; An optical system for changing a focus of light from the pinhole array or the auxiliary light source; And a control unit for controlling the light source and the auxiliary light source, wherein the control unit is capable of controlling the light source to be turned on in the first mode and having the characteristic corresponding to the convex lens.

The controller may turn on the auxiliary light source in the second mode and control the optical system to have characteristics corresponding to the glass.

The controller may turn on the auxiliary light source in the third mode and control the optical system to have characteristics corresponding to the concave lens.

A scanner according to an embodiment includes: a light source that outputs light; A pinhole array for outputting light output from the light source in a light-emitting mode; An optical system for changing the focus of light from the pinhole array and outputting the object as an object; An auxiliary light source for emitting light to the object; And a control unit for controlling the light source and the auxiliary light source, wherein the control unit lights the light source in the first mode and controls the optical system to have characteristics corresponding to the convex lens.

The controller may turn on the auxiliary light source in the second mode and control the optical system to have characteristics corresponding to the glass.

The auxiliary light source may output quantitative light-induced fluorescence (QLF) light.

Hereinafter, embodiments will be described with reference to the drawings.

1. System Configuration

Fig. 2 is a block diagram for explaining a system including a scanner related to the embodiments of the present invention, an electronic apparatus interlocked with the scanner, and the like.

Referring to FIG. 2, a system according to an embodiment of the present invention may include a scanner 1000 and an electronic device 2000.

The scanner 1000 may include an optical system 1100, a light source 1200, a detector 1300, and a first controller 1400.

The optical system 1100, the light source 1200, the detector 1300 and the first control unit 1400 may be located inside the body 1010. The body part 1010 may provide the external shape of the scanner 1000.

The scanner 1000 irradiates light to an object and obtains surface information and color information of the object through light reflected through the object.

The light source 1200 may illuminate the optical system 1100 with light. The light source 1200 may transmit white light to the optical system 1100. The light source 1200 may be a fluorescent lamp. Or the light source 1200 may be an LED.

The optical system 1100 may transmit the light transmitted from the light source 1200 to the object. The optical system 1100 may convert light from the light source 1200 and transmit the converted light to the object.

The optical system 1100 may change the focus depth of the light transmitted from the light source 1200. The optical system 1100 may adjust chromatic aberration of light transmitted from the light source 1200 and transmit the adjusted chromatic aberration to the object. The optical system 1100 may change the path of the light transmitted from the light source 1200 and transmit the changed light to the object.

The optical system 1100 may transmit the light reflected from the object to the detector 1300.

At least a portion of the light illuminated by the object may be reflected by the object and transmitted to the detector 1300 through the optical system 1100.

The detector 1300 may convert the light transmitted through the optical system 1100 into an electrical signal and transmit the electrical signal to the first controller 1400. The detector 1300 may be a color sensor capable of sensing color. The detector 1300 may be a CMOS or a CCD.

The electric signal generated by the detector 1300 may be transmitted to the first controller 1400.

The first controller 1400 may generate surface information using the electric signal transmitted from the detector 1300. The first controller 1400 may generate color information using the electric signal received from the detector 1300.

The surface information may be a stereoscopic image of a surface of the object. The color information may be color information corresponding to the surface of the stereoscopic image for the object. The first controller 1400 may generate a stereoscopic image of an object having a color by combining the stereoscopic image and color information.

The first controller 1400 may control the optical system 1100, the light source 1200, and the detector 1300.

The first controller 1400 may control the emission timing of the light source 1200. The first controller 1400 may control the optical system 1100 to generate surface information. The first controller 1400 may control the optical system 1100 to generate color information.

The first controller 1400 may control the focal distance of the light output by the optical system 1100 in the object direction. The first controller 1400 may control the chromatic aberration of light output by the optical system 1100 in the object direction. The first controller 1400 may control the optical system 1100 to change the path of light output in the direction of the object.

The first controller 1400 can control the readout timing of the detector 1300.

The scanner 1000 may be connected to the electronic device 2000. The scanner 1000 may be connected to the electronic device 2000 in a wireless or wired manner. The scanner 1000 and the electronic device 2000 may include a communication module (not shown) when the scanner 1000 is connected to the electronic device 2000 wirelessly or by wire.

The electronic device 2000 may include a second control unit 2100 and a display unit 2200. The second control unit 2100 may control the display unit 2200. The second control unit 2100 may control the display unit 2200 to display surface information and / or color information transmitted from the scanner 1000. The second control unit 2100 may control the display unit 2200 to display stereoscopic image and / or color information transmitted from the scanner 1000. [ The second control unit 2100 may control the display unit 2200 to display a stereoscopic image of an object having a color transmitted from the scanner 1000. [

The second controller 2100 receives the surface information and the color information from the scanner 1000 and combines them to generate a stereoscopic image of an object having a color and display the stereoscopic image on the display unit 2200.

The second control unit 2100 may be omitted. If the second control unit 2100 is omitted, the first control unit 1400 may control the display unit 2200. The first controller 1400 may control the display unit 2200 to display a stereoscopic image of an object having a color by combining surface information and color information.

The first controller 1400 may be omitted. If the first control unit 1400 is omitted, the second control unit 2100 can control the detailed configuration of the scanner 1000. The second control unit 2100 may control the optical system 1100, the light source 1200, and the detector 1300.

The second controller 2100 may control the emission timing of the light source 1200. The second controller 2100 can receive the electric signal directly from the detector 1300. The second controller 2100 may generate surface information and / or color information using the electric signal received from the detector.

The second controller 2100 may output color information corresponding to a surface of the stereoscopic image and / or the stereoscopic image through the display unit 2200 using the electric signal received from the detector. The second controller 2100 may combine the electric signals received from the detector to output a stereoscopic image of a color object through the display unit 2200.

2. First Embodiment

(1) Scanner structure

3 is a view showing a structure of a scanner according to the first embodiment.

Referring to FIG. 3, the scanner 1000 according to the first embodiment may include an optical system 1100, a light source 1200, a first optical path changing unit 1201, and a detector 1300.

The optical system 1100 may include an optical system 1500, a second optical path changing unit 1501, a beam splitter 1600, and a mirror 1700.

The light source 1200, the first optical path changing unit 1201, the beam splitter 1600, the optical system 1500, the second optical path changing unit 1501, and the mirror 1700 may be aligned on the horizontal axis x . The detector 1300 may be aligned with the first longitudinal axis y1 and the object y2 may be aligned with the second longitudinal axis y2. The horizontal axis (x) may be an axis perpendicular to the first vertical axis (y1) and the second vertical axis (y2). The first longitudinal axis (y1) and the second longitudinal axis (y2) may be parallel to each other.

The light source 1200 may be disposed at one end of the horizontal axis x. The center of the light source 1200 may cross the horizontal axis x. The light source 1200 may be positioned in a direction perpendicular to the horizontal axis x. The center of the light exiting area of the light source 1200 may correspond to the horizontal axis x. The center of the light exiting area of the light source 1200 may coincide with the horizontal axis x. The light source 1200 may emit white light toward the optical system 1100.

The first optical path changing unit 1201 may be disposed between the light source 1200 and the beam splitter 1600. The first optical path changing unit 1201 can change the path of the incident light. The first optical path changing unit 1201 may include at least one lens. The first optical path changing unit 1201 may change the path of the light emitted from the light source 1200 and transmit the changed path to the beam splitter 1600.

The beam splitter 1600 may be disposed in a traveling direction of light output from the light source 1200. The beam splitter 1600 may be disposed such that its central axis is located on the horizontal axis x.

The beam splitter 1600 transmits light incident from one direction and can reflect light incident from the other direction. The beam splitter 1600 transmits light incident from the light source 1600 and reflects light incident in the direction of the light source 1600. The beam splitter 1600 may be a semi-transparent mirror.

The optical system 1500 may be disposed in an area adjacent to the beam splitter 1500. That is, the beam splitter 1500 may be disposed between the light source 1200 and the optical system 1500. The optical system 1500 may be disposed between the beam splitter 1500 and the mirror 1700.

The optical system 1500 may convert the light from the light source 1200 and output the converted light to the mirror 1700. The optical system 1500 can adjust the focal distance of the light from the light source 1200. The optical system 1500 can adjust chromatic aberration of light from the light source 1200. The optical system 1500 can adjust the path of the light from the light source 1200.

The optical system 1500 can be changed in state by an electric signal. The optical system 1500 can change the light transmitted by the electrical signal. The optical system 1500 can control the focal distance, chromatic aberration, and / or light path of the light from the light source 1200 by the electrical signal.

The optical system 1500 may be a liquid crystal lens or a liquid lens.

The optical system 1500 will be described in detail later.

The second optical path changing unit 1501 may be disposed between the optical system 1500 and the mirror 1700. The second optical path changing unit 1501 can change the path of the incident light. The second optical path changing unit 1501 may change the path of the light from the optical system 1500 and transmit the changed path to the mirror 1700. The second optical path changing unit 1501 may change the path of the light from the mirror 1700 and transmit the changed path to the optical system 1500.

The mirror 1700 reflects light from the optical system 1500 and can transmit the reflected light to the object. The mirror 1700 may be inclined with respect to the horizontal axis x. The light incidence surface of the mirror 1700 may be inclined at an angle of 45 degrees with respect to the horizontal axis x. Since the horizontal axis x is the same as the center of light traveling from the light source 1200, the mirror 1700 can be inclined from the horizontal axis x.

The mirror 1700 may be inclined from the second longitudinal axis y2. The angle between the mirror 1700 and the second longitudinal axis y2 may be 45 degrees.

The light from the optical system 1500 is reflected by the mirror 1700 and is incident on the object. A part of the light reflected by the object is incident on the mirror 1700 along the second longitudinal axis y2. The mirror reflects the light reflected from the object and transmits the reflected light to the optical system 1500.

The optical system 1500 transmits the light incident from the mirror 1700 to the beam splitter 1600.

The second optical path changing unit 1501 changes the path of the light from the mirror 1700 and transmits the changed path to the optical system 1500. The optical system 1500 converts the light incident from the mirror 1700 And may be transmitted to the beam splitter 1600. The optical system 1500 can adjust the focal distance of the light incident from the mirror 1700. The optical system 1500 can adjust chromatic aberration of light from the mirror 1700. The optical system 1500 can control the path of the light from the mirror 1700.

The beam splitter 1600 may reflect the light transmitted from the optical system 1500 and transmit the reflected light to the detector 1300.

The light reflected by the beam splitter 1600 may travel along the first longitudinal axis y1 and be incident on the detector. The angle between the beam splitter 1600 and the horizontal axis x may be 45 degrees. The angle between the beam splitter 1600 and the first longitudinal axis y1 may be 45 degrees.

A separate optical path changing unit may be disposed between the beam splitter 1600 and the detector 1300. When the optical path changing unit between the beam splitter 1600 and the detector 1300 is located, the light from the beam splitter 1600 can be changed in path and irradiated to the detector 1300.

The detector 1300 can convert the light incident from the beam splitter 1600 into an electric signal. The detector 1300 may be a color sensor that detects color. The detector 1300 may be configured as a matrix having a plurality of cells. That is, the detector 1300 may be configured as an array having NxM cells. The detector may include R pixels, G pixels, and B pixels.

Hereinafter, the detailed configuration of the scanner 1000 will be described in detail.

(2) Light source

1) Basic form of light source

4 is a view showing a light source according to the first embodiment.

Referring to FIG. 4, the light source 1200 according to the first embodiment may include a base 1210, first to third light sources 1220, 1230, and 1240, and a diffusion plate 1250.

The base 1210 may fix the first to third light sources 1220, 1230, and 1240. The base 1210 may supply power to the first to third light sources 1220, 1230, and 1240.

The first to third light sources 1220, 1230, and 1240 may be positioned on the base 1210. The first to third light sources 1220, 1230, and 1240 may be attached on the base 1210.

The first to third light sources 1220, 1230, and 1240 may be supplied with power from the outside and emit light. The first to third light sources 1220, 1230, and 1240 may receive power from the base 1210 and emit light.

The first to third light sources 1220, 1230, and 1240 may output light of different wavelength regions.

The first light source 1220 can output light in a specific wavelength range. The first light source 1220 may output light including a blue wavelength region. The first light source 1220 may output light having a maximum power within a blue wavelength region of a visible light wavelength.

The first light source 1220 may include a first light source substrate 1221 and a first light emitting diode 1223. The first light emitting diode 1223 may be mounted on the first light source substrate 1221. The first light emitting diode 1223 may receive power from the first light source substrate 1221 and emit light. The first light emitting diode 1223 may be a blue LED.

The second light source 1230 can output light in a specific wavelength range. The second light source 1230 may output light including a green wavelength region. The second light source 1230 can output light having a maximum power within a green wavelength region of a visible light wavelength.

The second light source 1230 may include a second light source substrate 1231 and a second light emitting diode 1233. The second light emitting diode 1233 may be mounted on the second light source substrate 1231. The second light emitting diode 1233 may emit light by being supplied with power from the second light source substrate 1231. The second light emitting diode 1233 may be a green LED.

The third light source 1240 can output light in a specific wavelength range. The third light source 1240 may output light including a red wavelength. The third light source 1240 may output light having a maximum output power in a red wavelength region of a visible light wavelength.

The third light source 1240 may include a third light source substrate 1241 and a third light emitting diode 1243. The third light emitting diode 1243 may be mounted on the third light source substrate 1241. The third light emitting diode 1243 may receive power from the third light source substrate 1241 and emit light. The third light emitting diode 1243 may be a red LED.

The light output from the first to third light sources 1220, 1230, and 1240 may be transmitted to the diffusion plate 1250. The diffusion plate 1250 scatters light emitted from the first to third light sources 1220, 1230 and 1240 and outputs the scattered light. The light incident from the first to third light sources 1220, 1230, and 1240 is refracted and reflected many times within the diffuser plate 1250 and output to the outside. The blue light from the first light source 1220, the green light from the second light source 1230, and the red light from the third light source 1240 are properly mixed by refraction and reflection in the diffusion plate 1250 And is output as white light. The diffusion plate 1250 receives light from the first to third light sources 1220, 1230 and 1240 and outputs white light.

As a result, the light source 1200 outputs light having a wavelength in which the red wavelength, the green wavelength, and the blue wavelength are mixed. The light source 1200 outputs white light. The light source 1200 outputs white light, so that the scanner 1000 can be realized in a chromatic conical manner through white light.

2) Different forms of light source

5 is a view showing another embodiment of the light source according to the first embodiment.

5, another type of light source 1200 according to the first embodiment may include a base 1210, a first light source 1220, and a diffusion conversion plate 1260.

The base 1210 may fix the first light source 1220. The base 1210 may supply power to the first light source 1220.

The first light source 1220 may be positioned on the base 1210. The first light source 1220 may emit light by receiving power from the outside. The first light source 1220 may receive power from the base 1210.

The first light source 1220 can output light in a specific wavelength range. The first light source 1220 may output light including a blue wavelength region. The first light source 1220 may output light having a maximum power within a blue wavelength region of a visible light wavelength.

The first light source 1220 may include a first light source substrate 1221 and a first light emitting diode 1223. The first light emitting diode 1223 may be mounted on the first light source substrate 1221. The first light emitting diode 1223 may receive power from the first light source substrate 1221 and emit light. The first light emitting diode 1223 may be a blue LED.

The light output from the first light source 1220 may be transmitted to the diffusion conversion plate 1260.

The diffusion plate 1260 may be positioned on a path through which the light from the first light source 1220 is transmitted. The diffusion conversion plate 1260 may convert the wavelength of the light incident from the first light source 1220, and may diffuse and output the light. The diffusion plate 1260 may extend the wavelength range of the light incident from the first light source 1220 and output the expanded wavelength range. That is, the light output from the diffusion conversion plate 1260 may have a wide wavelength region as compared with the light incident on the diffusion conversion plate 1260. The diffusion conversion plate 1260 can output white light.

The diffusion conversion plate 1260 may include a wavelength conversion material. The diffusion conversion plate 1260 may include at least one of a quantum dot, an inorganic fluorescent material, an organic fluorescent material, and a dye. The diffusion conversion plate 1260 may include a red phosphor and a green phosphor.

The light incident on the diffusion conversion plate 1260 can be refracted and reflected inside the diffusion conversion plate 1260 and output to the outside. The light incident into the diffusion conversion plate 1260 is refracted and reflected by the wavelength conversion material in the diffusion conversion plate 1260, and the wavelength of the light is converted and output to the outside.

5, the white light can be output using the first light source 1220 in the case of the light source of FIG. 5, so that the light source can be configured with a simple structure.

3) Another form of light source

6 is a view showing another embodiment of the light source according to the first embodiment.

6, a light source 1200 according to another embodiment of the present invention may include a plurality of first light sources 1220 and a reflective conversion member 1270.

The first light source 1220 can output light in a specific wavelength range. The first light source 1220 may output light including a blue wavelength region. The first light source 1220 may output light having a maximum power within a blue wavelength region of a visible light wavelength.

The first light source 1220 may include a first light source substrate 1221 and a first light emitting diode 1223. The first light emitting diode 1223 may be mounted on the first light source substrate 1221. The first light emitting diode 1223 may receive power from the first light source substrate 1221 and emit light. The first light emitting diode 1223 may be a blue LED. The first light source 1220 may also be fixed by a base as shown in FIGS. 4 and 5, but illustration thereof is omitted.

The first light source 1220 may output light in a direction opposite to the direction in which the light output from the light source 1200 proceeds. That is, the output direction of the light of the first light source 1220 and the output direction of the light of the light source 1200 may be opposite directions.

The reflection converting member 1270 may have a shape having a curvature. The reflection converting member 1270 may have a hemispherical shape. The reflection converting member 1270 may have an inner hemispherical shape.

The reflection converting member 1270 can reflect incident light. The reflection converting member 1270 can convert the wavelength of incident light. The reflection converting member 1270 can convert the wavelength of incident light, reflect the light, and output the reflected light. The reflection converting member 1270 can expand the wavelength range of the light incident from the first light source 1220 and output it. That is, the light reflected by the reflection converting member 1270 and output from the reflection converting member 1270 may have a wide wavelength region. The reflection converting member 1270 may reflect light from the first light source 1220 and may output light in a direction opposite to the traveling direction of the light in the first light source 1220. The reflection converting member 1270 can output white light.

An outgoing light area can be defined by the shape of the reflection converting member 1270. The reflection converting member 1270 is formed in a hemispherical shape, and an outgoing light area can be defined by an open hemispherical area. The light reflected by the reflection converting member 1270 may be output through the light outgoing area. The light exiting area may be circular.

The plurality of first light sources 1220 may be located in an area surrounding the light-exiting area. That is, the plurality of first light sources 1220 may be formed in a circular band shape surrounding the light-outgoing area.

The reflection converting member 1270 may include a material having high reflectance and a wavelength converting material. The reflection converting member 1270 may include at least one of a quantum dot, an inorganic fluorescent material, an organic fluorescent material, and a dye. The reflection converting member 1270 may include a red phosphor and a green phosphor.

The reflection converting member 1270 may have a multi-layer structure. The reflection conversion member 1270 may include a reflection layer and a wavelength conversion layer. The wavelength conversion layer may be formed closer to the first light source 1220 than the reflective layer. When the reflection conversion member 1270 includes a reflection layer and a wavelength conversion layer, light from the first light source 1220 is incident on the wavelength conversion layer of the reflection conversion member 1270, is reflected on the reflection layer, The light is transmitted through the conversion layer and output to the light-exiting area.

6, the white light reflected by the reflection converting member 1270 can be output, and the light can be prevented from being concentrated in a specific area.

(3) Optical system

1) Optical system structure

7 is a cross-sectional view showing an optical system according to the first embodiment.

Referring to FIG. 7, an optical system 1500 according to the first embodiment includes an upper electrode 1510, a lower electrode 1520, and a liquid crystal layer 1530.

The upper electrode 1510 and the lower electrode 1520 may be opposed to each other and a liquid crystal layer 1530 may be interposed between the upper electrode 1510 and the lower electrode 1520.

The upper electrode 1510 and the lower electrode 1520 may be formed of a transparent conductive material. The upper electrode 1510 and the lower electrode 1520 may transmit light and the voltage may be applied to the upper electrode 1510 and the lower electrode 1520.

The upper electrode 1510 may be divided into regions. The upper electrode 1510 may have different voltages applied to the divided regions.

The lower electrode 1520 may be divided into regions. The lower electrode 1520 may have different voltages applied to the divided regions.

The divided regions of the upper electrode 1510 and the lower electrode 1520 may correspond to each other.

An electric field may be formed by a voltage applied to the upper electrode 1510 and the lower electrode 1520.

The liquid crystal layer 1530 may include a plurality of liquid crystals 1540. The molecular arrangement of the liquid crystal 1530 may be changed according to the voltage. The molecular arrangement of the liquid crystal 1540 may be changed according to the direction of the electric field.

As the molecular arrangement of the liquid crystal 1540 changes along the electric field direction, the optical characteristics of the light transmitted through the liquid crystal layer 1530 can be changed according to the molecular arrangement. When a voltage is applied to the liquid crystal layer 1530, an electric field is formed, and characteristics of light input along the electric field direction can be converted and output.

The liquid crystal layer 1530 may output light having a controlled focal length according to an applied voltage. The liquid crystal layer 1530 can output light adjusted in chromatic aberration according to a voltage applied thereto. The liquid crystal layer 1530 may adjust the path of the input light according to the applied voltage.

Although the upper electrode 1510 and the lower electrode 1520 are disposed with the liquid crystal layer 1530 interposed therebetween, electrodes are formed on only one side of the liquid crystal layer 1530, The arrangement of the liquid crystal layer 1530 may be changed by applying different electric fields to the electrodes.

The arrangement of the liquid crystal layer 1530 is changed according to the voltage applied to the liquid crystal layer 1530 and the surface shape of the optical system 1500 does not change. That is, the surface shape of the optical system 1500 can be kept constant regardless of whether a voltage is applied or not. In other words, the surface shape of the structure for adjusting the focal distance of light can be kept constant regardless of whether or not the voltage is applied.

The conversion of light by the liquid crystal layer 1530 will be described in detail below.

2) Light output from the optical system

Fig. 8 is a diagram showing light that is changed and output in the optical system according to the first embodiment.

FIG. 8A is a diagram showing the conversion of light in the first state, FIG. 8B is a diagram showing the conversion of light in the second state, and FIG. 8C is a diagram showing the conversion of light in the third state.

Referring to FIG. 8A, the optical system 1500 according to the first embodiment operates in the first state.

A voltage may be applied to the upper electrode 1510 and the lower electrode 1520 of the optical system 1500 such that the liquid crystal layer 1530 is in the same state as the initial state. The same voltage may be applied to the divided regions of the upper electrode 1510 and the lower electrode 1520. That is, the same voltage may be applied to the upper electrode 1510 and the lower electrode 1520.

Or no voltage may be applied to the upper electrode 1510 and the lower electrode 1520. That is, the upper electrode 1510 and the lower electrode 1520 are in a floating state, and the liquid crystal 1540 may be in the same state as the initial state. No voltage is applied to the upper electrode 1510 and the lower electrode 1520 so that the liquid crystal 1540 can be arranged in the initial alignment direction.

When the optical system 1500 operates in the first state, the liquid crystal layer 1530 can output light without changing the characteristics of incident light. When the optical system 1500 operates in the first state, the optical system 1500 can operate as a glass. However, the intensity of light may be output with the liquid crystal layer 1530 being attenuated.

For example, when the first light 11 is input from one side of the optical system 1500, the first light 11 transmitted through the optical system 1500 and output to the other side is the first light 11. Conversely, when the first light 11 is input from the other side of the optical system 1500, the first light 11 is the first light 11 transmitted through the optical system 1500 and output to the other side.

Referring to FIG. 8B, the optical system 1500 according to the first embodiment operates in the second state.

Voltages of different levels are applied to the divided regions of the upper electrode 1510 and the lower electrode 1520 of the optical system 1500 so that the optical system 1500 can operate in the second state. Voltages of different levels are applied to the divided regions of the upper electrode 1510 and the lower electrode 1520 so that the liquid crystal layer 1530 can operate in the second state.

When the liquid crystal layer 1530 is operated in the second state, the liquid crystals in the outer region of the liquid crystal layer 1530 are arranged so as to have a relatively large variation amount on the basis of the initial alignment direction, The arrangement of the liquid crystal molecules in the central region of the liquid crystal molecules is changed so as to have a relatively small variation amount with respect to the initial alignment direction.

 That is, the liquid crystal is arranged so that the amount of change of the liquid crystal becomes larger from the central area to the outer area of the liquid crystal layer 1530. The amount of change of the liquid crystal may be caused by a voltage applied to the divided regions of the upper electrode 1510 and the lower electrode 1520. The amount of change of the liquid crystal may be determined by the field intensity of the divided regions of the upper electrode 1510 and the lower electrode 1520 facing each other. In other words, the amount of change of the liquid crystal may be determined by the voltage difference applied to the divided regions of the upper electrode 1510 and the lower electrode 1520 facing each other. For example, when the voltage difference between the upper electrode 1510 and the lower electrode 1520 facing each other is large, the amount of change of the liquid crystal becomes large, and when the upper electrode 1510 and the lower electrode 1520 The amount of change of the liquid crystal can be reduced. By this phenomenon, the liquid crystal can be arranged as shown by adjusting the voltage difference in the divided regions of the upper electrode 1510 and the lower electrode 1520.

The amount of change of the liquid crystal depending on the voltage difference may vary depending on the characteristics of the liquid crystal. That is, when the difference in voltage applied to the divided regions of the upper electrode 1510 and the lower electrode 1520 facing each other is small, the amount of change of the liquid crystal becomes large, and the upper electrode 1510 and the lower electrode 1520 ) Is large, the amount of change of the liquid crystal may be small.

When the optical system 1500 operates in the second state, the characteristics of light incident on the liquid crystal layer 1530 can be output in a changed state.

When the optical system 1500 operates in the second state, the liquid crystal layer 1530 may have an optical characteristic corresponding to the convex lens.

When a parallel bundle of light is incident on one side of the optical system 1500, a plurality of lights having different foci may be output to the other side of the optical system 1500. The plurality of lights output to the other side of the optical system 1500 may have different chromatic aberrations. The plurality of lights output to the other side of the optical system 1500 may have different paths.

For example, when the first light l1 is incident on one side of the optical system 1500 in the form of a parallel light bundle, the optical system 1500 transmits the second light l2, the third light l3, 4 light (14) to the other side of the optical system (1500).

Since the first light 11 is a white light formed by mixing a plurality of different wavelengths, a plurality of different wavelength components exist in the first light 11. When the first light 11 is incident on the optical system 1500 serving as a convex lens in the second state, the refractive index of the first light 11 is changed by a plurality of wavelengths through the liquid crystal layer 1530 of the optical system 1500, The second light 13, the third light 13 and the fourth light 14 form foci in a region adjacent to the other surface of the optical system 1500 so as to have different foci. That is, the refractive indexes of the second light 12, the third light 13, and the fourth light 14 are different from each other by a plurality of wavelengths passing through the liquid crystal layer 1530, To form a focus. In other words, light output to the other surface of the optical system 1500 due to the chromatic aberration of the liquid crystal layer 1530 can be separated according to the wavelength. The white light incident on the optical system 1500 may be separated into light having different colors and output.

The second light 12 outputted from the optical system 1500 is refracted and collected at the first focus f1 and the third light 13 is refracted to be collected at the second focus f2, 14 may be refracted and collected at the third focus f3. The second light 12 may have a first focus f1 and the third light 13 may have a second focus f2 and the fourth light 14 may have a third focus f3).

The second light (12) may be light having a wavelength shorter than that of the third light (13). The third light may be light having a wavelength shorter than that of the fourth light. The second light (12) may be light having a wavelength shorter than that of the fourth light (14). As the wavelengths of the plurality of lights output from the optical system 1500 become shorter, a focus is formed in a region adjacent to the optical system 1500, and a focus is formed in a region spaced apart from the optical system 1500 as the wavelength becomes longer. The relationship between the wavelength and the focus of the light output from the optical system 1500 may vary depending on the voltage applied to the optical system 1500. That is, the longer the wavelength of the light output from the optical system 1500 is, the focal point is formed in the region adjacent to the optical system 1500, and the shorter the wavelength of the light is, the focal point may be formed in the region spaced apart from the optical system 1500 .

The second light 12 may be blue light, the third light 13 may be green light, and the fourth light 14 may be red light. Although the light outputted through the optical system 1500 has three focal points in the drawing, the light output from the optical system 1500 may have less than three or more than three focal points.

On the contrary, when light having a plurality of focal points is incident on the other surface of the optical system 1500, the light output through the optical system 1500 to one surface of the optical system may be output in the form of a parallel light bundle.

Referring to FIG. 8C, the optical system 1500 according to the first embodiment operates in the third state.

In the optical system 1500, voltages of different levels are applied to the divided regions of the upper electrode 1510 and the lower electrode 1520 so that the optical system 1500 can operate in the third state. Voltages of different levels are applied to the divided regions of the upper electrode 1510 and the lower electrode 1520 so that the liquid crystal layer 1530 can operate in the third state.

When the liquid crystal layer 1530 is operated in the third state, the liquid crystals in the outer region of the liquid crystal layer 1530 are arranged so as to have a relatively large variation amount on the basis of the initial alignment direction, The arrangement of the liquid crystal molecules in the central region of the liquid crystal molecules is changed so as to have a relatively small variation amount with respect to the initial alignment direction.

That is, the liquid crystal is arranged so that the amount of change of the liquid crystal becomes larger from the central area to the outer area of the liquid crystal layer 1530. The amount of change of the liquid crystal may be caused by a voltage applied to the divided regions of the upper electrode 1510 and the lower electrode 1520.

When the optical system 1500 is operated in the third state, a voltage applied to the divided areas of the upper electrode 1510 and the lower electrode 1520 is a voltage applied when the optical system 1500 operates in the second state Lt; / RTI > That is, when the optical system 1500 operates in the second state, when the voltage difference between the upper electrode 1510 and the lower electrode 1520 in the specific region is 5V, when the optical system 1500 operates in the third state, The voltage difference between the upper electrode 1510 and the lower electrode 1520 in the region may be -5V.

When the optical system 1500 operates in the third state, the characteristics of light incident on the liquid crystal layer 1530 can be output in a changed state.

When the optical system 1500 operates in the third state, the liquid crystal layer 1530 may have an optical characteristic corresponding to the concave lens.

The light transmitted through the optical system 1500 can be output through the optical system 1500 by changing the path of the light. When a bundle of light parallel to one side of the optical system 1500 is incident, the light can be transmitted through the optical system 1500. The light transmitted through the optical system 1500 may gradually advance to the outside of the light boundary with respect to the optical axis.

For example, when the first light 11 is incident on one side of the optical system 1500 in the form of a parallel light bundle, the optical system 1500 can output the fifth light. The fifth light 15 may be output at an angle with respect to the first light 11 in an outward direction of the optical axis.

A section where the first light 11 or the fifth light 15 is cut into a plane parallel to one surface of the optical system 1500 may be defined as a light receiving area. The light receiving area of the fifth light (15) may become larger as the distance from the optical system (1500) increases.

On the other hand, when the fifth light 15 is incident on the other surface of the optical system 1500, the light path may be changed by the optical system 1500 to be output in the form of the first light 11. That is, light having an angle may be incident on the other surface of the optical system 1500 and output as parallel light.

3) Other structures of optical system

9 is a view showing another structure of the optical system according to the first embodiment.

Referring to FIG. 9, the optical system 1500 according to the first embodiment may include a plurality of upper electrodes 1510, a plurality of lower electrodes 1520, and a liquid crystal layer 1530.

The plurality of upper electrodes 1510 may be formed on the upper substrate 1511 and the plurality of lower electrodes 1520 may be formed on the lower substrate 1521.

The liquid crystal layer 1530 may be interposed between the upper substrate 1511 and the lower substrate 1521.

The upper substrate 1511 may have a shape corresponding to the lower substrate 1521. The upper substrate 1511 may have a circular shape, and the lower substrate 1521 may have a circular shape. The upper substrate 1511 and the lower substrate 1521 may have a cylindrical shape.

The liquid crystal layer 1530 may be formed in a columnar shape. One surface of the liquid crystal layer 1530 may have an area corresponding to one surface of the upper substrate 1511 and the lower substrate 1521.

The optical system 1500 may have a cylindrical shape depending on the shapes of the upper substrate 1511, the lower substrate 1521, and the liquid crystal layer 1530. The center axes of the upper substrate 1511, the lower substrate 1521, and the liquid crystal layer 1530 may be the same. The center axis of the upper substrate 1511, the lower substrate 1521 and the liquid crystal layer 1530 may be the same as the optical axis incident on the optical system 1500. When the optical system 1500 is operated in the second state, the focus of light may be positioned on the extended line of the optical axis.

A plurality of upper electrodes 1510 may be formed on the upper substrate 1511. The plurality of upper electrodes 1510 may be formed in a circular band shape having the same center. The center of the plurality of upper electrodes 1510 may be the same as the center axis of the upper substrate 1511.

The upper electrode 1510 may include first to fifth upper electrodes 1510a to 1510e. The first to fifth upper electrodes 1510a to 1510e may be electrically separated from each other. The first upper electrode 1510a may be formed in a circular band shape nearest to the center of the upper substrate 1511. [

The second upper electrode 1510b may be formed on the outer surface of the first upper electrode 1510a. The second upper electrode 1510b may be electrically isolated from the first upper electrode 1510a.

The third upper electrode 1510c may be formed on the outer surface of the second upper electrode 1510b. The third upper electrode 1510c may be electrically isolated from the second upper electrode 1510b.

The fourth upper electrode 1510d may be formed outside the third upper electrode 1510c. The fourth upper electrode 1510d may be electrically isolated from the third upper electrode 1510c.

The fifth upper electrode 1510e may be formed on the outer periphery of the fourth upper electrode 1510d. The fifth upper electrode 1510e may be electrically isolated from the fourth upper electrode 1510d. The fifth upper electrode 1510e may be formed at the outermost portion of the upper substrate 1511. [

The first through fifth upper electrodes 1510a through 1510e may be separately driven. Different voltages may be applied to the first to fifth upper electrodes 1510a to 1510e.

A plurality of lower electrodes 1520 may be formed on the lower substrate 1521. The plurality of lower electrodes 1520 may be formed in the shape of a circular band having the same center. The centers of the plurality of lower electrodes 1520 may be the same as the center axis of the lower substrate 1521.

The lower electrode 1520 may include first to fifth lower electrodes 1520a to 1520e. The first to fifth lower electrodes 1520a to 1520e may be electrically separated from each other.

The first lower electrode 1520a may have a shape corresponding to a position corresponding to the first upper electrode 1510a. The second lower electrode 1520b may have a shape corresponding to a position corresponding to the second upper electrode 1510b. The third lower electrode 1520c may have a shape corresponding to a position corresponding to the third upper electrode 1510c. The fourth lower electrode 1520d may correspond to a position corresponding to the fourth upper electrode 1510d. The fifth lower electrode 1520e may have a shape corresponding to a position corresponding to the fifth upper electrode 1510e.

An electric field may be generated by a voltage difference applied to the upper electrode and the lower electrode corresponding to each other. The arrangement of liquid crystals of the liquid crystal layer 1530 can be changed by the electric field. The plurality of upper electrodes 1510 and the plurality of lower electrodes 1520 are formed in the shape of a circular band having the same center with respect to the optical axis so that the arrangement of the liquid crystals can be changed around the optical axis. Therefore, the characteristics of light can be changed without distortion in each region.

Although the upper electrodes 1510 and the lower electrodes 1520 are illustrated as five electrodes in the drawing, the plurality of upper electrodes 1510 and the plurality of lower electrodes 1520 may be formed as necessary. As shown in FIG. As the number of the upper electrode 1510 and the lower electrode 1520 increases, fine control of the liquid crystal layer 1530 may be possible.

4) Driving of optical system

10 is a view showing a voltage applied to the optical system of Fig.

Different voltages may be applied to the upper electrode 1510 and the lower electrode 1520 of the optical system 1500 according to the first embodiment of FIG.

A first applied voltage V1 may be applied to the upper electrode 1510 and a second applied voltage V2 may be applied to the lower electrode 1520. [ The electric field formed in the liquid crystal layer 1530 between the upper electrode 1510 and the lower electrode 1520 is proportional to the magnitude of the voltage and inversely proportional to the distance between the upper electrode 1510 and the lower electrode 1520.

The distance between the upper electrode 1510 and the lower electrode 1520 is the same so that the electric field formed in the liquid crystal layer 1530 may be determined by a difference in voltage applied to the upper electrode 1510 and the lower electrode 1520 have.

In the case where the optical system 1500 is in the second state, a difference in voltage applied to the electrodes located in the central region of the plurality of upper electrodes 1510 and the plurality of lower electrodes 1520 may be different from each other, May be greater than the voltage difference applied to the electrodes. A voltage having a smaller difference may be applied to the upper electrode 1510 and the lower electrode 1520 from the center area to the outer area.

For example, the voltage difference applied to the first upper electrode 1510a and the first lower electrode 1520a may be greatest. The voltage difference applied to the second upper electrode 1510b and the second lower electrode 1520b may be smaller than the voltage difference applied to the first upper electrode 1510a and the first lower electrode 1520a. The voltage difference applied to the third upper electrode 1510c and the third lower electrode 1520c may be smaller than the voltage difference applied to the second upper electrode 1510b and the second lower electrode 1520b. The voltage difference applied to the fourth upper electrode 1510d and the fourth lower electrode 1520d may be smaller than the voltage difference applied to the third upper electrode 1510c and the third lower electrode 1520c. The voltage difference applied to the fifth upper electrode 1510e and the fifth lower electrode 1520e may be smaller than the voltage difference applied to the fourth upper electrode 1510d and the fourth lower electrode 1520d. The voltage difference applied to the fifth upper electrode 1510e and the fifth lower electrode 1520e may be the smallest.

Although five upper electrodes 1510 and a lower electrode 1520 are illustrated in the drawing, the number of the upper electrode 1510 and the lower electrode 1520 may be five or more, 1510 and the lower electrode 1520 can be made smaller. As the number of the upper electrode 1510 and the lower electrode 1520 increases and the width decreases, the voltage difference between the upper electrode 1510 and the lower electrode 1520 may have a curved shape as shown in FIG. 10 . That is, the electric field applied to the liquid crystal layer 1530 may have a curved shape having a maximum value in the central region. 10, the liquid crystal layer 1530 functions as a convex lens, and the optical system 1500 can operate in the second state.

An electric field of the type shown in FIG. 11 may be applied to the liquid crystal layer 1530. 11 is applied to the plurality of upper electrodes 1510 and the plurality of lower electrodes 1520 of FIG. 9, the liquid crystal layer 1530 can operate as a Fresnel lens. Since the optical characteristic of the Fresnel lens is the same as that of the convex lens, the optical system 1500 can operate in the second state by applying an electric field of the form as shown in FIG.

(4) Obtain color information of scanner

12 is a view showing an operation of acquiring color information of the scanner according to the first embodiment.

Referring to FIG. 12, the scanner 1000 according to the first embodiment may include an optical system 1100, a light source 1200, and a detector 1300.

The optical system 1100 may include an optical system 1500, a beam splitter 1600, and a mirror 1700.

In Fig. 12, the optical system 1500 operates in the first state.

Light having a plurality of wavelengths mixed is output from the light source 1200. The light source 1200 may output white light. The light output from the light source 1200 is transmitted to the beam splitter 1600 along the horizontal axis x.

The light output from the light source 1200 may be transmitted to the beam splitter 1600 through the first optical path changing unit 1201.

Since the beam splitter 1600 transmits light incident from the light source 1200, the light incident from the light source 1200 is transmitted to the optical system 1500 along the horizontal axis x.

When the optical system 1500 is in the first state, the optical system 1500 can output light without changing the characteristics of the input light. That is, when the optical system 1500 is in the first state, the optical system 1500 can operate as a glass.

The light incident on the optical system 1500 through the beam splitter 1600 travels to the mirror 1700 along the horizontal axis x without changing the state.

The light incident on the optical system 1500 may be transmitted to the mirror 1700 through the second optical path changing unit 1501.

The light incident on the mirror 1700 is reflected in the direction of the second vertical axis y2 and is incident on the object. The object may be a tooth.

The light reflected by the object is again incident on the inter-mirror 1700, and the mirror 1700 reflects the light incident on the mirror 1700 along the horizontal axis x in the direction of the optical system 1500.

The light reflected from the mirror 1700 may be incident on the optical system 1500. The light reflected from the mirror 1700 may be incident on the optical system 1500 through the second optical path changing unit 1501. The light incident on the optical system 1500 is incident on the beam splitter 1600 without changing the characteristics of the light. The light incident on the beam splitter 1600 may be reflected toward the detector 1300.

The light reflected in the direction of the detector 1300 proceeds in the direction of the first longitudinal axis y1 and is incident on the detector 1300.

The detector 1300 may convert the incident light into an electrical signal. The detector 1300 may convert the incident light into an electric signal to obtain color information of the object. The first controller 1400 may acquire the surface color of the object through the light incident on the detector 1300.

Alternatively, the first controller 1400 may acquire a preview image of the object through the light incident on the detector 1300. Since the detector 1300 detects the reflected light irradiated from the upper portion of the object, the detector 1300 can acquire an image of the object viewed from above the object. The first controller 1400 may obtain a preview image from the upper portion of the object and output a preview image to the user.

The color information and the preview image may be a two-dimensional image of the object.

(5) Obtain surface information of scanner

13 is a view showing an operation of acquiring surface information of the scanner according to the first embodiment.

FIG. 13A is a diagram illustrating light transmitted to the object, and FIG. 13B is a diagram illustrating a path through which light reflected through the object is transmitted to a detector.

Referring to FIG. 13, the scanner 1000 according to the first embodiment may include an optical system 1100, a light source 1200, and a detector 1300.

The optical system 1100 may include an optical system 1500, a beam splitter 1600, and a mirror 1700.

In Fig. 13, the optical system 1500 operates in the second state.

Light having a plurality of wavelengths mixed is output from the light source 1200. The light source 1200 may output white light. The light output from the light source 1200 is transmitted to the beam splitter 1600 along the horizontal axis x.

The light output from the light source 1200 may be transmitted to the beam splitter 1600 through the first optical path changing unit 1201.

The light incident on the beam splitter 1600 is transmitted to the optical system 1500 along the horizontal axis x.

When the optical system 1500 is in the second state, the optical system 1500 can operate as a convex lens. The light output from the optical system 1500 may be output so as to have different focuses for respective wavelengths.

For example, when the first light l1 is incident on the optical system 1500, the optical system 1500 can output the second light l2 and the third light l3. The second light (12) and the third light (13) may have different focal distances from each other. The second light (12) and the third light (13) may have different wavelengths. The second light (12) may have a shorter focal length than the third light (13). The focus of the second light 12 may be closer to the optical system 1500 than the focus of the third light 13.

The second light 12 and the third light 13 outputted from the optical system 1500 travel in the direction of the mirror 1700 along the horizontal axis x. The light output from the optical system 1500 may be transmitted to the mirror 1700 through the second optical path restricting unit 1501. The second light 12 and the third light 13 reaching the mirror 1700 are reflected and transmitted to the object along the second vertical axis y2. The focus of the second light 12 and the third light 13 may be located on the second longitudinal axis y2.

The focus of the second light 12 and the third light 13 may be located at different positions on the second longitudinal axis y2. The focal point of the second light 12 may be located adjacent to the mirror 1700 relative to the focal point of the third light 13.

The light that is focused on the surface of the object among the light incident on the object may be reflected. Light that is not focused on the surface of the object is also reflected from the light incident on the object, but the amount incident on the inside of the scanner 1100 is small, so that noise can be processed. In other words, only the light whose focus is located on the surface of the object is incident on the detector 1300 and can be used as information.

For example, the focus of the second light (12) among the second light (12) and the third light (13) incident on the object is located on the surface of the object, and the focus of the third light And is located inside the object. Accordingly, the third light 13 is scattered and reflected by the object, and only the second light 12 is incident on the mirror 1700.

The mirror 1700 reflects the second light 12 and transmits the reflected light toward the optical system 1500. The second light 12 reflected from the mirror 1700 may be incident on the optical system 1500 through the second optical path changing unit 1501. The second light 12 transmitted to the optical system 1500 along the horizontal axis x is transmitted to the beam splitter 1600. The light reflected by the beam splitter 1600 is transmitted along the first longitudinal axis y1 toward the detector 130. The detector 1300 converts the second light 12 into an electrical signal.

The depth information of the object can be measured through the wavelength of the light incident on the detector 1300. That is, when a different focal distance is determined for each wavelength by the optical system 1500 and the light of a specific wavelength is measured by the detector 1300, the focal distance corresponding to the specific wavelength corresponds to the depth information of the object do. Since the focal distance of the second light 12 is predetermined in the figure, when the second light 12 is detected by the detector 1300, the surface of the object is positioned at the focal point of the second light 12 As shown in FIG. Accordingly, the first controller 1400 can calculate the depth information of the object through the wavelength of the light existing in the detector 1300. Since the detector 1300 may be a color sensor, the wavelength of the light incident on the detector 1300 can be easily calculated by the color sensor, and the depth information of the object can be calculated. In other words, the detector 1300 can calculate the depth information of the object using the color value of the incident light.

When acquiring the surface information of the object, the light incident on the detector 1300 is focused light. When acquiring the color information of the object, since the light incident on the detector 1300 is light, The amount of light received by the detector 1300 may be smaller than the amount of light received by the detector 1300 when acquiring the color information of the object. Alternatively, when acquiring the surface information of the object, the light receiving area of the detector 1300 may be smaller than the light receiving area of the detector 1300 when acquiring the color information of the object.

Since the detector 1300 is formed in a matrix shape and the light source 1200 is also formed in a plurality of mattress shapes, the depth information can be calculated by irradiating light onto a two-dimensional plane of the object and measuring the reflected light , The first controller 1400 can acquire three-dimensional surface information.

That is, the detector 1300 is constituted by a pixel array including a plurality of unit pixels arranged in rows and columns, and coordinates can be given to each pixel, so that light reflected in two dimensions can be measured, The three-dimensional surface information can be obtained by the depth information.

In FIG. 12, the scanner according to the first embodiment acquires color information, and in FIG. 13, the scanner according to the first embodiment can acquire surface information. The scanner according to the first embodiment can acquire surface information and color information with a single scanner by controlling the voltage applied to the optical system 1500 without physical movement of a separate lens. Therefore, there is an effect that vibration and noise of the scanner can be prevented. In other words, a chromatic scanning type scanner capable of obtaining surface information and color information can be implemented.

In addition, the scanner according to the first embodiment can generate a stereoscopic image of an object having a color by combining surface information and color information, thereby realizing more practical modeling. In particular, since the object is a tooth in the case of an oral scanner, not only 3D surface information of the tooth but also color information can be obtained, and the tooth can be designed in consideration of the surrounding tooth color during the preparation of the implant.

(6) Wide angle of the scanner Preview  Obtain

14 is a diagram showing an operation of acquiring the wide angle preview of the scanner according to the first embodiment.

Referring to FIG. 14, the scanner 1000 according to the first embodiment may include an optical system 1100, a light source 1200, and a detector 1300.

The optical system 1100 may include an optical system 1500, a beam splitter 1600, and a mirror 1700.

In Fig. 14, the optical system 1500 operates in the third state.

Light having a plurality of wavelengths mixed is output from the light source 1200. The light source 1200 may output white light. The light output from the light source 1200 is transmitted to the beam splitter 1600 along the horizontal axis x.

The light output from the light source 1200 may be transmitted to the beam splitter 1600 through the first optical path changing unit 1201.

The light incident on the beam splitter 1600 is transmitted to the optical system 1500 along the horizontal axis x.

When the optical system 1500 is in the third state, the optical system 1500 can operate as a concave lens. The light output from the optical system 1500 can be output by changing the light path. The light output from the optical system 1500 can be diverged. The light output from the optical system 1500 can progress gradually outward with respect to the optical axis. The light receiving area of the light output from the optical system 1500 may become larger as the distance from the optical system 1500 increases.

The light output from the optical system 1500 travels in the direction of the mirror 1700 along the horizontal axis x. The light output from the optical system 1500 may be transmitted to the mirror 1700 through the second optical path changing unit 1501.

The light reaching the mirror 1700 is reflected and transmitted to the object along the second vertical axis y2. The light incident on the object may have a wider light receiving area than the light incident on the object of Fig. That is, since the light incident on the object has a wide light receiving area, a wider area of the object is illuminated.

The light reflected by the object is transmitted to the mirror 1700. The light incident on the mirror 1700 is reflected and transmitted to the optical system 1500 along the horizontal axis x. The light incident on the optical system 1500 is changed so that the light receiving area is reduced and transmitted to the beam splitter 1600. The light reflected by the mirror 1700 may be transmitted to the optical system 1500 through the second optical path changing unit 1501.

The light reaching the beam splitter 1600 is reflected and transmitted along the first longitudinal axis y1 in the direction of the detector 1300. The detector 1300 can convert the incident light into an electric signal. The detector 1300 may convert the incident light into an electric signal to obtain the wide angle preview information of the object. In the light incident from the mirror 1700 to the optical system 1500, a larger area of light is incident on the detector 1300, thereby generating a preview image of a wider range than the preview image of FIG. 12 . The first controller 1400 provides the user with a wide angle preview image, thereby improving the user's convenience.

(7) How to operate the scanner

1) Time division driving

15 is a diagram showing a method of driving the scanner according to the first embodiment.

Referring to FIG. 15, the scanner 1000 according to the first embodiment may be driven in a time-division manner.

The scanner 1000 may be repeatedly driven in a first section and a second section.

The first section may be a relatively long section as compared with the second section. Alternatively, the first section may have the same length as the second section. The first section may be a relatively short section as compared to the second section. However, it may be more suitable that the first section for acquiring the surface information has a relatively long computation time and the first section has a relatively longer time than the second section.

In the first section, the scanner 1000 can acquire surface information. In the first section, the first controller 1400 can operate the optical system 1500 in the second state. The first controller 1400 can operate the optical system 1500 in the second state in the first section and obtain the surface information of the object through the light applied to the detector 1300. [

In the second period, the scanner 1000 may acquire color information. In the second period, the first controller 1400 may operate the optical system 1500 in the first state. The first controller 1400 can operate the optical system 1500 in the first state in the second period and acquire the color information of the object through the light applied to the detector 1300. [

Also, although not shown, the scanner 1000 may additionally obtain preview information in the second section. In the second section, the first controller 1400 may operate the optical system 1500 in the first state to obtain preview information through the light applied to the detector 1300.

The first controller 1400 drives the optical system 1500 to the first state or the second state.

In order for the optical system 1500 to operate in the first state, there is a set of voltages applied to the plurality of upper electrodes 1510 and the plurality of lower electrodes 1520. The set of voltages that the optical system 1500 should apply to the plurality of upper electrodes 1510 and the plurality of lower electrodes 1520 to operate in the first state may be defined as a first set of voltages.

In order for the optical system 1500 to operate in the second state, there is a set of voltages applied to the plurality of upper electrodes 1510 and the plurality of lower electrodes 1520. The set of voltages to be applied to the plurality of upper electrodes 1510 and the plurality of lower electrodes 1520 for operating the optical system 1500 in the second state may be defined as a second set of voltages.

The first set of voltages and the second set of voltages may be stored in the form of a look-up table. The first controller 1400 can apply the first voltage set or the second voltage set stored in the lookup table form to the optical system 1500 to operate the optical system 1500 in the first state or the second state . That is, the first controller 1400 can drive the optical system 1500 to the second state by applying the second voltage set to the optical system 1500 in the first period. The first controller 1400 may apply the first voltage set to the optical system 1500 in the second period to drive the optical system 1500 to the first state.

When the optical system 1500 is in the first state, the color information and the preview information are not separately measured, but when the light applied to the detector 1300 is changed, Can be obtained.

By implementing the scanner 1000 in a time-division manner, surface information and color information can be obtained in a short time, and a stereoscopic image of an object having a color can be obtained by combining the surface information and the color information.

2) Other driving methods

16 is a view showing another driving method of the scanner according to the first embodiment.

FIG. 16 is the same as FIG. 15 except that a third section is added. Therefore, in the description of FIG. 16, detailed description of the components common to FIG. 15 will be omitted.

Referring to FIG. 16, the scanner 1000 according to the first embodiment may be driven in a time-division manner.

The scanner 1000 may be driven by repeating a first section, a second section, and a third section.

The third interval may be a relatively short interval as compared to the first interval and the second interval. The third section has a smaller amount of computation than the first section and the second section and can be processed even if the section has a relatively short section.

The scanner 1000 may be sequentially driven in the order of the first section, the second section, and the third section.

In the third section, the scanner 1000 can acquire wide angle preview information. In the third period, the first controller 1400 can operate the optical system 1500 in the third state. The first controller 1400 can operate the optical system 1500 in the third state in the third period and acquire the wide angle preview information on the object through the light applied to the detector 1300 .

The first controller 1400 may drive the optical system 1500 to a first state, a second state, or a third state.

In order for the optical system 1500 to operate in the third state, there exist a set of voltages applied to the plurality of upper electrodes 1510 and the plurality of lower electrodes 1520. A set of voltages to be applied to the plurality of upper electrodes 1510 and the plurality of lower electrodes 1520 for operating the optical system 1500 in the third state may be defined as a third set of voltages.

The third set of voltages may be stored in the form of a look-up table. The first controller 1400 applies the first voltage set, the second voltage set or the third voltage set stored in the form of the lookup table to the optical system 1500 to set the optical system 1500 in the first state, Or the third state.

That is, the first controller 1400 can drive the optical system 1500 to the second state by applying the second voltage set to the optical system 1500 in the first period. The first controller 1400 can drive the optical system 1500 to the first state by applying a first voltage set to the optical system 1500 in the second period. The first controller 1400 can drive the optical system 1500 to the third state by applying a third voltage set to the optical system 1500 in the third period.

The scanner 1000 is implemented in a time-division manner to acquire surface information, color information, and wide angle preview information in a short time.

3. Second Embodiment - auto focus

17 is a view showing a scanner according to the second embodiment.

The scanner according to the second embodiment is the same as the scanner according to the first embodiment except that the characteristics of the optical system are changed in the second state. Therefore, in describing the scanner according to the second embodiment, the same reference numerals are assigned to the same components as those in the first embodiment, and a detailed description thereof will be omitted.

Referring to FIG. 17, the scanner 1000 according to the second embodiment may include an optical system 1100, a light source 1200, and a detector 1300.

The optical system 1100 may include an optical system 1500, a beam splitter 1600, and a mirror 1700.

Light having a plurality of wavelengths mixed is output from the light source 1200. The light source 1200 may output white light. The light output from the light source 1200 is transmitted to the beam splitter 1600 along the horizontal axis x.

The light output from the light source 1200 may be transmitted to the beam splitter 1600 through the first optical path changing unit 1201.

The light incident on the beam splitter 1600 is transmitted to the optical system 1500 along the horizontal axis x.

The optical system 1500 operates in the second state. The optical system 1500 may serve as a convex lens whose focus is changed. The light output from the optical system 1500 may be output so as to have different focuses for respective wavelengths.

For example, when the first light l1 is incident on the optical system 1500, the optical system 1500 can output the second light l2 and the third light l3. The second light (12) and the third light (13) may have different focal distances from each other. The second light (12) and the third light (13) may have different wavelengths. The second light (12) may have a shorter focal length than the third light (13). The focus of the second light 12 may be closer to the optical system 1500 than the focus of the third light 13.

The focus of a plurality of lights output from the optical system 1500 can be changed. The first controller 1400 may control the focus of the plurality of lights output from the optical system 1500 to change.

That is, the focus of the second light 12 and the third light 13 can be changed. The focus of the second light 12 and the third light 13 may move in the adjacent direction from the optical system 1500 and the focus of the second light 12 and third light 13 may move in the optical system 1500 as shown in FIG.

The focal point of the second light 12 and the third light 13 may be changed according to the intensity of an electric field formed in the liquid crystal layer 1530. The greater the deviation of the electric field between the electric field in the central region of the liquid crystal layer 1530 and the outer peripheral region, the greater the refractive index can be as compared with the convex lens in the second state of the first embodiment. The focal point of the second light beam 12 and the third light beam 13 moves in the direction of the optical system 1500 as the deviation of the electric field between the electric field in the central region and the outer peripheral region of the liquid crystal layer 1530 increases.

Further, as the deviation of the electric field between the electric field in the central region of the liquid crystal layer 1530 and the outer peripheral region is smaller, the refractive index can be made smaller as compared with the convex lens in the second state of the first embodiment. The focal point of the second light beam 12 and the third light beam 13 moves in a direction away from the optical system 1500 as the deviation of the electric field between the electric field and the outer light field in the central region of the liquid crystal layer 1530 becomes smaller .

The focus of a plurality of light beams output from the optical system 1500 may be changed by changing a voltage applied to the plurality of upper electrodes 1510 and the plurality of lower electrodes 1520 of the optical system 1500. The focal point of a plurality of light beams output as the voltage difference between the upper electrode and the lower electrode in the central region of the optical system 1500 and the voltage difference between the upper electrode and the lower electrode in the outer region of the optical system 1500 are larger, ) Direction. As the voltage difference between the upper electrode and the lower electrode in the central region of the optical system 1500 and the voltage difference between the upper electrode and the lower electrode in the outer region of the optical system 1500 become smaller, 1500).

The second light 12 and the third light 13 outputted from the optical system 1500 travel in the direction of the mirror 1700 along the horizontal axis x. The light output from the optical system 1500 may be transmitted to the mirror 1700 through the second optical path changing unit 1501. The second light 12 and the third light 13 reaching the mirror 1700 are reflected and transmitted to the object along the second vertical axis y2. The focus of the second light 12 and the third light 13 may be located on the second longitudinal axis y2.

The focus of the second light 12 and the third light 13 may be located at different positions on the second longitudinal axis y2. The focal point of the second light 12 may be located adjacent to the mirror 1700 relative to the focal point of the third light 13.

The first control unit 1400 changes the focus of the second light 12 and the focus of the third light 13 so that the focus of the second light 12 and the focus of the third light 13 are different from each other. And can be moved on the second longitudinal axis y2. That is, the first controller 1400 controls the optical system 1500 in a state where the second light 12 has a first focus depth and the third light 13 has a second focus depth, The focus depth of the second light 12 can be moved to the third focus depth, and the focus depth of the third light 13 can be moved to the fourth focus depth.

The focus of the second light 12 and the focus of the third light 13 may be moved in the object direction or in the direction of the mirror 1700. [

The first controller 1400 can control the focus of the second light 12 and the focus of the third light 13 to be shifted by changing the voltage applied to the optical system 1500. [ The focus of the second light 12 and the focus of the third light 13 are shifted to realize autofocus.

Light having a focus on the surface of the object among the second light 12 and the third light 13 is reflected and transmitted through the mirror 1700, the optical system 1500 and the beam splitter 1600 to the detector 1300 ). The light reflected by the mirror 1700 may be transmitted to the optical system 1500 through the second optical path changing unit 1501.

The first control unit 1400 controls the second light 12 and the third light 13 in the case where there is no light focused on the surface of the object among the second light 12 and the third light 13, the focus of the second light 12 and the third light 13 can be shifted by changing the voltage applied to the optical system 1500 so that the light having the focus positioned on the surface of the object is present.

That is, when the surface of the object is not detected by the light output from the optical system 1500, the surface of the object can be detected by moving the focus of the light output from the optical system 1500.

When the signal generated by the detector 1300 is less than a predetermined size, the first controller 1400 changes the voltage applied to the optical system 1500 to move the focus of the light output from the optical system 1500, The signal generated by the detector 1300 is measured and the voltage applied to the optical system 1500 is fixed to that state when the signal is larger than a predetermined magnitude.

Since the scanner 1000 is implemented as autofocus, the scanner 1000 can acquire more accurate surface information.

In the case where the scanner 1000 is a mouth scanner, conventionally, a mouth scanner is brought into close contact with a tooth to obtain surface information. However, since the scanner 1000 is implemented as an autofocus, the degree of freedom of the user can be assured . That is, there is an advantage that the surface information of the tooth can be obtained even if the scanner 1000 does not move in a state in which the distance from the tooth is maintained.

Also, the surface information can be obtained by selectively using the wavelength of the light source 1200. The wavelength and the focal distance of the light output by the optical system 1500 can be determined by the wavelength of the light source 1200. Even if the distance deviation between the maximum focal length and the minimum focal length of the light output from the optical system 1500 is small Surface information can be obtained. That is, even if the object is not located between the maximum focal length and the minimum focal length of the light, the optical system 1500 has the autofocus function, so that the surface information of the object can be obtained while moving the focal distance. This means that the scanner 1000 can accurately acquire the surface information of the object even if only the light of a specific wavelength range that is relatively easy to measure among the white light sources is used.

Also, even when the size of the object is large, the scanner 1000 can acquire the surface information of the object while moving the focal distance by using the autofocus function of the optical system 1500.

4. Third Embodiment - A chromatic aberration-generating physical lens

(1) Scanner structure

18 is a view showing a structure of a scanner according to the third embodiment.

The scanner according to the third embodiment is the same as the first embodiment except that it further includes a lens as compared with the scanner of the first embodiment, and the optical system 1500 has a different role. Therefore, the same reference numerals are assigned to the components common to those of the first embodiment, and a detailed description thereof will be omitted.

Referring to FIG. 18, the scanner 1000 according to the third embodiment may include an optical system 1100, a light source 1200, a first optical path changing unit 1201, and a detector 1300.

The optical system 1100 may include an optical system 1500, a second optical path changing unit 1501, a beam splitter 1600, a mirror 1700, and a lens 1800.

The light source 1200, the beam splitter 1600, the lens 1800, the optical system 1500, and the mirror 1700 may be sequentially aligned on the horizontal axis x. The detector 1300 may be aligned with the first longitudinal axis y1 and the object y2 may be aligned with the second longitudinal axis y2.

The lens 1800 may be a physical lens. The lens 1800 may be a convex lens. The lens 1800 may be a Fresnel lens. Light transmitted through the lens 1800 may be collected on the horizontal axis x. The focal point of the light transmitted through the lens 1800 may be located on the horizontal axis x.

The lens 1800 may be a liquid crystal lens. When the lens 1800 is a liquid crystal lens, the lens 1800 may be a liquid crystal lens in a state where the second state of the optical system 1500 is maintained.

The optical system 1500 may convert the light from the lens 1800 and output the converted light to the mirror 1700. The optical system 1500 can control the focal distance of the light from the lens 1800. The optical system 1500 can adjust chromatic aberration of light from the lens 1800. The optical system 1500 can control the path of the light from the lens 1800.

The optical system 1500 can be changed in state by an electric signal. The optical system 1500 can change the light transmitted by the electrical signal. The optical system 1500 can control the focal distance, chromatic aberration, and / or light path of the light from the light source 1200 by the electrical signal.

The optical system 1500 may be a liquid crystal lens or a liquid lens.

The optical system 1500 may operate in different states from the first state and the first state. The optical system 1500 may operate in a first state and a third state.

The description of the optical system 1500 and the lens 1800 will be described later in detail.

(2) Obtain surface information of the scanner

Fig. 19 is a diagram showing a surface information acquiring operation of the scanner according to the third embodiment. Fig.

Referring to FIG. 19, the scanner 1000 according to the third embodiment may include an optical system 1100, a light source 1200, and a detector 1300.

The optical system 1100 may include an optical system 1500, a beam splitter 1600, a mirror 1700, and a lens 1800.

In Fig. 19, the optical system 1500 operates in the first state.

Light having a plurality of wavelengths mixed is output from the light source 1200. The light source 1200 may output white light. Light from the light source 1200 is transmitted through the beam splitter 1600 and is incident on the lens 1800.

The light output from the light source 1200 may be transmitted to the beam splitter 1600 through the first optical path changing unit 1201.

Since the lens 1800 is a Fresnel lens having optical characteristics corresponding to a convex lens or a convex lens, the light output from the lens 1800 may be output as light having a different focus for each wavelength.

For example, when the first light 11 is incident on the lens 1800, the lens 1800 may output the second light 12 and the third light 13. The second light (12) and the third light (13) may have different focal distances from each other. The second light (12) and the third light (13) may have different wavelengths. The second light (12) may have a shorter focal length than the third light (13). The focal point of the second light 12 may be adjacent to the lens 1800 rather than the focal point of the third light 13.

The second light 12 and the third light 13 output from the lens 1800 travel in the direction of the optical system 1500 along the horizontal axis x. When the optical system 1500 operates in the first state, the optical system 1500 transmits the incident light without changing it, so that the second light and the third light are transmitted through the optical system 1500 And proceeds to the mirror 1700. The light output from the optical system 1500 may be transmitted to the mirror 1700 through the second optical path changing unit 1501.

The second light (12) and the third light (13) reflected by the mirror (1700) are transmitted to the object.

Light having a focus on the surface of the object is reflected and then incident on the detector 1300 through the mirror 1700, the optical system 1500, the lens 1800, and the beam splitter 1600, And the detector 1300 can obtain the surface information of the object using the incident light.

(3) The object's  Obtain color information

20 is a diagram showing an operation of acquiring color information of a scanner according to the third embodiment.

Referring to FIG. 20, a scanner 1000 according to the third embodiment may include an optical system 1100, a light source 1200, and a detector 1300.

The optical system 1100 may include an optical system 1500, a beam splitter 1600, a mirror 1700, and a lens 1800.

In Fig. 20, the optical system 1500 operates in the third state.

Light having a plurality of wavelengths mixed is output from the light source 1200. The light source 1200 may output white light. The light output from the light source 1200 may be transmitted to the beam splitter 1600 through the first optical path changing unit 1201. Light from the light source 1200 is transmitted through the beam splitter 1600 and is incident on the lens 1800.

Since the lens 1800 is a Fresnel lens having optical characteristics corresponding to a convex lens or a convex lens, the light output from the lens 1800 may be output as light having a different focus for each wavelength.

For example, when the first light 11 is incident on the lens 1800, the lens 1800 may output the second light 12 and the third light 13. The second light (12) and the third light (13) may have different focal distances from each other. The second light (12) and the third light (13) may have different wavelengths. The second light (12) may have a shorter focal length than the third light (13). The focal point of the second light 12 may be adjacent to the lens 1800 rather than the focal point of the third light 13.

The second light 12 and the third light 13 output from the lens 1800 travel in the direction of the optical system 1500 along the horizontal axis x.

When the optical system 1500 operates in the third state, the optical system 1500 operates as a concave lens. The optical system 1500 can change the path of light incident from the lens 1800. The optical system 1500 may remove the focus of light incident from the lens 188. That is, the optical system 1500 can change the light incident from the lens 188 into parallel light.

The optical system 1500 can change the chromatic aberration of light incident from the lens 1800. The chromatic aberration of light incident from the optical system 1500 can be removed. The optical system 1500 can compensate for chromatic aberration of light incident from the lens 1800.

The optical system 1500 can compensate for the chromatic aberration of the second light 12 and the third light 13 transmitted from the lens 1800 and output the compensated chromatic aberration. The optical system 1500 may output the 2-1 light and the 3-1 light compensated for the chromatic aberration of the second light 12 and the third light 13. That is, the second light 12 is converted into the second-first light through the optical system 1500, and the third light 13 is converted into the third-first light through the optical system 1500 Can be output. The difference between the focal depths of the 2-1 light and the 3-1 light may be smaller than the difference between the focal depths of the second light 12 and the third light 13. The focal depths of the 2-1 light and the 3-1 light may be the same.

The optical system 1500 can output the fourth light 14 by compensating the chromatic aberration of the second light 12 and the third light 13 transmitted from the lens 1800. [ The optical system 1500 may change the path of the second light 12 and the third light 13 transmitted from the lens 1800 to output the fourth light. The optical system 1500 may convert the second light and the third light having the focal point transmitted from the lens 1800 to output the fourth light as the parallel light. The light output from the optical system 1500 may be transmitted to the mirror 1700 through the second optical path changing unit 1501.

The fourth light 14 is incident on the mirror 1700 along the horizontal axis x and the mirror 1700 may reflect the fourth light 14 to the object. The light reflected by the object is transmitted to the detector 1300 via the mirror 1700, the optical system 1500, the lens 1800, and the beam splitter 1600. When light reflected by the object is transmitted from the mirror 1700 toward the optical system 1500 in the process of being transmitted to the detector 1300 and chromatic aberration occurs again, the chromatic aberration passes through the lens 1800, So that light having no chromatic aberration can be incident on the detector 1300.

The light outputted by the object is white light, and the light reflected by the object is detected by the detector so that the scanner 1000 can obtain the color information of the object. The first controller 1400 may acquire the surface color of the object through the light incident on the detector 1300.

Alternatively, the first controller 1400 may obtain a preview image of the object through the light incident on the detector 1300. Since the detector 1300 detects the reflected light irradiated from the upper portion of the object, the detector 1300 can acquire an image of the object viewed from above the object. The first controller 1400 may obtain a preview image from the upper portion of the object and output a preview image to the user.

The scanner according to the third embodiment can acquire surface information as shown in FIG. 19 and acquire color information as shown in FIG. The scanner according to the third embodiment can acquire surface information and color information with a single scanner by controlling the voltage applied to the optical system 1500. [

Further, in the scanner including the physical lens causing the conventional chromatic aberration and the physical lens changing the focus, the physical lens that changes the focus while holding the physical lens causing the chromatic aberration is replaced by the optical system, And a scanner for acquiring color information can be implemented.

5. Fourth Embodiment - Pinhole  Adding arrays

(1) Scanner structure

21 is a view showing the structure of a scanner according to the fourth embodiment.

The scanner according to the fourth embodiment is the same as the first embodiment except that it further includes an optical path control unit as compared with the scanner according to the first embodiment. Therefore, in describing the fourth embodiment, the same reference numerals are assigned to the components common to those of the first embodiment, and a detailed description thereof will be omitted.

21, the scanner 1000 according to the fourth embodiment includes an optical system 1100, a light source 1200, a first optical path changing unit 1201, a detector 1300, and a light path control unit 1900 .

The optical system 1100 may include an optical system 1500, a second optical path changing unit 1501, a beam splitter 1600, and a mirror 1700.

The light source 1200, the optical path control unit 1900, the beam splitter 1600, the optical system 1500 and the mirror 1700 may be sequentially arranged on the horizontal axis x. The detector 1300 may be aligned with the first longitudinal axis y1 and the object y2 may be aligned with the second longitudinal axis y2.

The optical path control unit 1900 can change the characteristics of light output toward the beam splitter 1600. The light path control unit 1900 can change the characteristics of light incident on the optical system 1500 and output the light. The light path control unit 1900 may change the characteristics of light incident from the light source 1200 and output the light.

The light path control unit 1900 can selectively output light of a surface light or a light of a glow type. The light path control unit 1900 can output a plurality of light beams. The light path control unit 1900 can output a plurality of light beams in a matrix form. The light path control unit 1900 can output NxM light beams.

The optical path control unit 1900 may include a parallel lens 1910, a lens array 1920, and a pinhole array 1930.

The pinhole array 1930 is located in a region adjacent to the beam splitter 1600 and the lens array 1920 is disposed in the vicinity of the parallel lens 1910. [ And the pinhole array 1930, as shown in FIG.

The parallel lens 1910, the lens array 1920, and the pinhole array 1930 may be sequentially aligned on the horizontal axis x.

The collimating lens 1910 may be a convex lens. The parallel lens 1910 may convert light output from the light source 1200 into surface light and transmit the light to the lens array 1920. The lens array 1920 condenses the light received from the parallel lens 1910 to have a plurality of focal points and transmits the light to the pinhole array 1930.

The lens array 1920 may not be an essential configuration. The optical path control unit 1900 may include the parallel lens 1910 and the pinhole array without the lens array 1920.

The pinhole array 1930 can control the characteristics of light received from the lens array 1920 and output the light. The pinhole array 1930 can selectively output the light received from the lens array 1920 to either the surface light or the point light.

Detailed features of the lens array 1920 and the pinhole array 1930 will be described later.

(2) a lens array and Pinhole  Array

23 is a perspective view showing the pinhole array according to the fourth embodiment, and Fig. 24 is a view showing a path of light in the lens array and the pinhole array according to the fourth embodiment. Fig. 22 is a perspective view showing the lens array according to the fourth embodiment, Fig.

Referring to FIG. 22, the lens array 1920 according to the fourth embodiment may include a lens substrate 1921 and a plurality of lenses 1923.

The plurality of lenses 1923 may be formed on the lens substrate 1921. The plurality of lenses 1923 may be convex lenses. The plurality of lenses 1923 may be disposed at a predetermined position on the lens substrate 1921. The plurality of lenses 1923 may be disposed on the lens substrate 1921 with a predetermined gap therebetween.

The plurality of lenses 1923 may be arranged in a matrix on the lens substrate 1921. The plurality of lenses 1923 may be arranged in NxM. For example, nine lenses 1923 may be disposed on the lens substrate 1921. The plurality of lenses 1923 may be arranged in 3X3.

Referring to FIG. 23, the pinhole array 1930 according to the fourth embodiment may include a pinhole substrate 1931. The pinhole substrate 1931 may include a plurality of pinholes 1933 and a blocking region 1935.

The pinhole array 1930 may be a switchable pinhole array. The pinhole array 1930 may be a liquid crystal panel. A liquid crystal layer may be injected into the pinhole substrate 1931.

A voltage may be applied to the pinhole array 1930 to create a blocking region 1935 in the pinhole array 1930. A voltage is supplied to the pinhole array 1930 to displace the liquid crystal layer so that the pinhole array 1930 may have a blocking region 1935 that does not transmit light.

The plurality of pinholes 1933 may be defined by the blocking regions 1935 of the pinhole array 1930. The plurality of pinholes 1933 may be regions of the pinhole substrate 1931 excluding the blocking regions 1935. That is, the plurality of pinholes 1933 may be a region that does not block light. The plurality of pinholes 1933 may be a region through which light is transmitted. Light incident on the pinhole array 1930 through the plurality of pinholes 1933 can be output in a plurality of light shades.

The liquid crystal layer may be injected only into the blocking region 1935 in the pinhole substrate 1931. [ When a liquid crystal layer is injected only into the blocking region 1935, an electric field may be applied to the blocking region 1935 to create or remove the blocking region 1935. That is, an electric field may be applied to the blocking region 1935 to block the transmission of light to the blocking region 1935 or to transmit light. In this case, the liquid crystal layer is not injected into the plurality of pinholes 1933, and the plurality of pinholes 1933 are in a state of transmitting light.

The liquid crystal may be injected into the entire region of the pinhole substrate 1931. That is, the liquid crystal can be injected into the region where the plurality of pinholes 1933 are formed and the blocking region 1935 of the pinhole substrate 1931. The blocking region 1935 can be formed by applying an electric field to the liquid crystal layer. That is, by applying different electric fields to the liquid crystal layer in each region, light is blocked in the blocking region 1935, and light can be transmitted through the plurality of pinholes 1933.

The plurality of pinholes 1933 may be arranged in a matrix. The plurality of pinholes 1933 may be arranged in NxM. For example, nine pinholes 1933 may be disposed on the pinhole array 1930. The plurality of pinholes 1933 may be arranged in 3X3. Each of the pinholes 1933 may be located at a position corresponding to the plurality of lenses 1923 of the lens array 1920. The pinhole 1933 may be positioned on the focal point of the lens 1923.

The pinhole array 1930 can be operated in two states. The pinhole array 1930 may be operated in a first state or a second state. A state in which a blocking region is created in the pinhole array 1930 is defined as a first state, and a state in which a blocking region is not created in the pinhole array 1930 may be defined as a second state.

The light incident on the pinhole array 1930 in the first state can be outputted through the pinhole 1933 and the light incident on the pinhole array 1930 in the second state can be outputted not only to the pinhole 1933, And can also be output through the blocking area. That is, in the first state, the pinhole array 1930 functions as a general pinhole array, and in the second state, the pinhole array 1930 can function as a glass.

FIG. 24A is a diagram showing the path of light in the first state, and FIG. 24B is a diagram showing the path of light in the second state.

Referring to FIG. 24A, the lens array 1920 and the pinhole array 1930 may be disposed opposite to each other. The lens array 1920 and the pinhole array 1930 may be spaced apart from each other.

The lens 1923 of the lens array 1920 and the pinhole 1933 of the pinhole array 1930 may be positioned so as to correspond to each other. The pinhole array 1930 can operate in the first state. That is, in the pinhole array 1930, the blocking region 1935 blocks light, and the pinhole 1933 can transmit a large amount of light.

The parallel light output by the parallel lens 1920 may be incident on the lens array 1920. Each lens 1923 can refract light incident on each lens 1923 and transmit the refracted light to the pinhole array 1930. Light output from each lens 1923 may have a focal point. The focal point may be disposed on the pinhole 1933 and the lens array 1920 and the pinhole array 1930.

The light transmitted from the lens array 1920 may be transmitted through the pinhole array 1930 and output as a light. Each of the pinholes 1933 transmits light having a focus on the pinhole 1933 and outputs the light in the form of a light. Since the pinholes 1933 are arranged in a matrix, the light emitted from the pinhole array 1930 may be a plurality of point lights arranged in a matrix form. The number of the point lights may be the same as the number of the pinholes 1933 of the pinhole array 1930.

Referring to FIG. 24B, the lens array 1920 and the pinhole array 1930 may be disposed opposite to each other. The lens array 1920 and the pinhole array 1930 may be spaced apart from each other.

The lens 1923 of the lens array 1920 and the pinhole 1933 of the pinhole array 1930 may be positioned so as to correspond to each other. The pinhole array 1930 may operate in a second state. That is, the blocking region 1935 of the pinhole array 1930 transmits light and consequently the light incident on the pinhole array 1930 can be output toward the beam splitter 1600 without changing the characteristics of the light .

The light refracted by the lens array 1920 is transmitted to the beam splitter 1600 through the pinhole array 1930. Light output from the plurality of lens arrays 1920 can be mixed with each other in the course of passing through the pinhole array 1930 and reaching the beam splitter 1600. The light is mixed with each other and output in a plane light form. That is, when the pinhole array 1930 is in the second state, the light path control unit 1900 can output the surface light.

In other words, the pinhole array 1930 in the second state can output more light than the pinhole array 1930 in the first state.

(3) Obtain surface information of scanner

FIG. 25 is a diagram showing an operation of acquiring surface information of the scanner according to the fourth embodiment. FIG.

25, the scanner 1000 according to the fourth embodiment may include an optical system 1100, a light source 1200, a detector 1300, and a light path control unit 1900.

The optical system 1100 may include an optical system 1500, a beam splitter 1600, and a mirror 1700. The light path control The portion 1900 may include a parallel lens 1910, a lens array 1920, and a pinhole array 1930.

The optical system 1500 operates in the second state and the optical path control unit 1900 can operate in the first state.

Light having a plurality of wavelengths mixed is output from the light source 1200. The light source 1200 may output white light. The light output from the light source 1200 is transmitted to the light path control unit 1900.

The light path control unit 1900 may convert the light received from the light source 1200 in the first state into a light-emitting mode and output the light. The light path control unit 1900 can output a plurality of light beams in the form of a light bundle in the form of a matrix.

The light outputted from the optical path control unit 1900 may be transmitted to the optical system 1500 through the beam splitter 1600. The light outputted from the optical path control unit 1900 may be transmitted to the beam splitter 1600 through the first optical path changing unit 1201. [

The optical system 1500 can operate in the second state. When the optical system 1500 operates in the second state, the optical system 1500 may have the same optical characteristics as the convex lens.

The light output from the optical system 1500 may be output so as to have different focuses for respective wavelengths. The light output from the optical system 1500 may be reflected through the mirror 1700 and transmitted to the object. The light output from the optical system 1500 may be transmitted to the mirror 1700 through the second optical path changing unit 1501.

The light that is focused on the surface of the object among the light incident on the object may be reflected. Light having a focus on the surface of the object may be incident on the detector 1300 through the mirror 1700, the optical system 1500, and the beam splitter 1600. The detector 1300 can obtain the surface information of the object using the incident light. The light reflected from the object can be irradiated to only a part of the area of the detector 1300.

The light path control unit 1900 outputs light in the form of a light of a light-off type, thereby providing a clearer measurement without noise. The light path control unit 1900 outputs light of a light-emitting type, thereby obtaining more accurate surface information.

An additional optical member may be positioned between the detector 1300 and the beam splitter 1600. An optical filter, a pinhole array, or the like may be positioned between the detector 1300 and the beam splitter 1600. It is possible to reduce the noise of the light irradiated to the detector 1300 by the additional optical member and obtain more accurate surface information.

(4) Obtain color information of scanner

FIG. 26 is a diagram showing an operation of acquiring color information of a scanner according to the fourth embodiment. FIG.

Referring to FIG. 26, the scanner 1000 according to the fourth embodiment may include an optical system 1100, a light source 1200, a detector 1300, and a light path control unit 1900.

The optical system 1100 may include an optical system 1500, a beam splitter 1600, and a mirror 1700. The optical path control unit 1900 may include a parallel lens 1910, a lens array 1920, and a pinhole array 1930.

The optical system 1500 operates in the first state and the optical path control unit 1900 operates in the second state.

Light having a plurality of wavelengths mixed is output from the light source 1200. The light source 1200 may output white light. The light output from the light source 1200 is transmitted to the light path control unit 1900.

The light path control unit 1900 may output the light received from the light source 1200 in the second state in a plane light form.

The light output from the optical path control unit 1900 may be transmitted through the beam splitter 1600 and transmitted to the optical system 1500. The light outputted from the optical path control unit 1900 may be transmitted to the beam splitter 1600 through the first optical path changing unit 1201. [

The optical system 1500 can operate in the first state. When the optical system 1500 operates in the first state, the optical system 1500 can output without changing the characteristics of the light. When the optical system 1500 operates in the first state, the optical system 1500 may have the same optical characteristics as the glass.

The light incident on the optical system 1500 through the beam splitter 1600 travels to the mirror 1700 along the horizontal axis x without changing the state. The light output from the optical system 1500 may be transmitted to the mirror 1700 through the second optical path changing unit 1501.

The light incident on the mirror 1700 is reflected in the direction of the second vertical axis y2 and is incident on the object.

The light incident on the object is reflected by the object and is incident on the detector 1300 through the mirror 1700, the optical system 1500, and the beam splitter 1600. When the scanner 1000 acquires color information, light may be incident on the entire area of the detector 1300. When the scanner 1000 obtains color information, a region where the light of the detector 1300 is incident may be larger than a case where the scanner 1000 obtains surface information. That is, when the scanner 1000 obtains surface information, light is irradiated only to a part of the detector 1300. When the scanner 1000 acquires color information, the entire area of the detector 1300 The light can be irradiated to the light source.

Alternatively, the first controller 1400 may acquire a preview image of the object through the light incident on the detector 1300. Since the detector 1300 detects the reflected light irradiated from the upper portion of the object, the detector 1300 can acquire an image of the object viewed from above the object. The first controller 1400 may obtain a preview image from the upper portion of the object and output a preview image to the user.

(5) Wide angle of the scanner Preview  Obtain

27 is a view showing an operation of acquiring wide angle preview information of the scanner according to the fourth embodiment.

Referring to FIG. 27, the scanner 1000 according to the fourth embodiment may include an optical system 1100, a light source 1200, a detector 1300, and a light path control unit 1900.

The optical system 1100 may include an optical system 1500, a beam splitter 1600, and a mirror 1700. The optical path control unit 1900 may include a parallel lens 1910, a lens array 1920, and a pinhole array 1930.

The optical system 1500 operates in the third state and the optical path control unit 1900 can operate in the second state.

Light having a plurality of wavelengths mixed is output from the light source 1200. The light source 1200 may output white light. The light output from the light source 1200 is transmitted to the light path control unit 1900.

The light path control unit 1900 may output the light received from the light source 1200 in the second state in a plane light form.

The light output from the optical path control unit 1900 may be transmitted through the beam splitter 1600 and transmitted to the optical system 1500. The light outputted from the optical path control unit 1900 may be transmitted to the beam splitter 1600 through the first optical path changing unit 1201. [

The optical system 1500 can operate in the third state. When the optical system 1500 operates in the third state, the optical system 1500 can operate as a concave lens. The light output from the optical system 1500 can be output by changing the light path. The light output from the optical system 1500 can be diverged. The light output from the optical system 1500 can progress gradually outward with respect to the optical axis. The light receiving area of the light output from the optical system 1500 may become larger as the distance from the optical system 1500 increases.

The light output from the optical system 1500 travels in the direction of the mirror 1700 along the horizontal axis x. The light reaching the mirror 1700 is reflected and transmitted to the object along the second vertical axis y2. The light output from the optical system 1500 may be transmitted to the mirror 1700 through the second optical path changing unit 1501. The light incident on the object may have a larger light receiving area than the light incident on the object of Fig. That is, since the light incident on the object has a wide light receiving area, a wider area of the object is illuminated.

The light reflected by the object is transmitted to the mirror 1700. The light incident on the mirror 1700 is reflected and transmitted to the optical system 1500 along the horizontal axis x. The light reflected by the mirror 1700 may be transmitted to the optical system 1500 through the second optical path changing unit 1501. The light incident on the optical system 1500 is changed so that the light receiving area is reduced and transmitted to the beam splitter 1600.

The light reaching the beam splitter 1600 is reflected and transmitted along the first longitudinal axis y1 in the direction of the detector 1300. The detector 1300 can convert the incident light into an electric signal. The detector 1300 may convert the incident light into an electric signal to obtain the wide angle preview information of the object. In the light incident from the mirror 1700 to the optical system 1500, a wider area of light is incident on the detector 1300, so that a preview image of a wider range than the preview image of FIG. 26 is generated . The first controller 1400 provides the user with a wide angle preview image, thereby improving the user's convenience.

The scanner according to the fourth embodiment has the effect of obtaining more accurate surface information of the object by controlling the light path control unit 190 and controlling the light incident on the optical system 1500 as compared with the first embodiment.

6. Fifth Embodiment - First auxiliary light source

(1) Scanner structure

28 to 30 are views showing a scanner according to the fifth embodiment.

The scanner according to the fifth embodiment is the same as the scanner according to the fourth embodiment except that the state of the pinhole array is not changed and a separate light source is added. Therefore, in describing the fifth embodiment, the same reference numerals are assigned to the components common to those of the fourth embodiment, and a detailed description thereof will be omitted.

28 to 30, a scanner 1000 according to the fifth embodiment includes an optical system 1100, a light source 1200, a detector 1300, a light path limiting unit 1905, and a first auxiliary light source 1280 ).

The optical system 1100 may include an optical system 1500, a beam splitter 1600, and a mirror 1700. The optical path restricting portion 1905 may include a parallel lens 1910, a lens array 1920, and a fixed pinhole array 1940.

The optical path restricting unit 1905 may limit the path of the light output from the light source 1200 and output the path. The optical path restricting unit 1905 may output the light output from the light source 1200 in the form of a light spot.

The collimating lens 1910 may be a convex lens. The parallel lens 1910 may convert light output from the light source 1200 into surface light and transmit the light to the lens array 1920. The lens array 1920 condenses the light received from the parallel lens 1910 to have a plurality of focal points and transmits the light to the fixed pinhole array 1940.

The fixed pinhole array 1940 can output light received from the lens array 1920 in a light-emitting mode. The function of the fixed pinhole array 1940 is the same as that of the pinhole array 1930 in the first state of the fourth embodiment. The fixed pinhole array 1940 is not changed in state as in the fourth embodiment, but has fixed characteristics in the form of a first state.

The optical path limiting section 1905 is also the same as the function of the optical path control section 1900 in the first state of the fourth embodiment. However, the optical path restricting unit 1905 is not changed in state as in the optical path control unit 1900 of the fourth embodiment, but has a fixed characteristic in the form of the first state.

The first auxiliary light source 1280 may output light to the beam splitter 1600. The first auxiliary light source 1280 may output white light in the direction of the beam splitter 1600. An auxiliary collimating lens 1950 may be positioned between the first auxiliary light source 1280 and the beam splitter 1600. The auxiliary collimating lens 1950 may be a convex lens. The auxiliary collimating lens 1950 may convert the light transmitted from the first auxiliary light source 1280 into a surface light and transmit the light to the beam splitter 1600.

The light source 1200 and the first auxiliary light source 1280 may blink complementarily. The light source 1200 and the first auxiliary light source 1280 may be flickered in a time division manner. For example, when the light source 1200 is turned on, the first auxiliary light source 1280 may be turned off, and when the light source 1200 is turned off, the first auxiliary light source 1280 may be turned on have.

(2) Obtain surface information of the scanner

28 is a view showing a surface information obtaining operation of the scanner according to the fifth embodiment.

28, the scanner 1000 according to the fifth embodiment includes an optical system 1100, a light source 1200, a detector 1300, a light path limiting unit 1905, and a first auxiliary light source 1280 can do.

The optical system 1100 may include an optical system 1500, a beam splitter 1600, and a mirror 1700. The optical path restricting portion 1905 may include a parallel lens 1910, a lens array 1920, and a fixed pinhole array 1940.

In the operation of acquiring surface information of the scanner 1000, the light source 1200 may be turned on and the first auxiliary light source 1280 may be turned off. At this time, the optical system 1500 can operate in the second state.

Light having a plurality of wavelengths mixed is output from the light source 1200. The light source 1200 may output white light. The light output from the light source 1200 is transmitted to the light path limiting unit 1905.

The light path limiting unit 1905 may convert the light received from the light source 1200 into a light-emitting mode and output the light. The light path limiting unit 1905 can output a plurality of light beams in the form of a light bundle in the form of a matrix.

The light output from the optical path limiting unit 1905 may be transmitted to the optical system 1500 through the beam splitter 1600. The output light from the optical path restricting unit 1905 may be transmitted to the beam splitter 1600 through the first optical path changing unit 1201.

The optical system 1500 can operate in the second state. When the optical system 1500 operates in the second state, the optical system 1500 may have the same optical characteristics as the convex lens.

The light output from the optical system 1500 may be output so as to have different focuses for respective wavelengths. The light output from the optical system 1500 may be reflected through the mirror 1700 and transmitted to the object. The light output from the optical system 1500 may be transmitted to the mirror 1700 through the second optical path changing unit 1501.

The light that is focused on the surface of the object among the light incident on the object may be reflected. Light having a focus on the surface of the object may be incident on the detector 1300 through the mirror 1700, the optical system 1500, and the beam splitter 1600. The detector 1300 can obtain the surface information of the object using the incident light.

(3) Acquiring the color information of the scanner

FIG. 29 is a view showing an operation of acquiring color information of the scanner according to the fifth embodiment. FIG.

29, the scanner 1000 according to the fifth embodiment includes an optical system 1100, a light source 1200, a detector 1300, a light path limiting unit 1905, and a first auxiliary light source 1280 can do.

The optical system 1100 may include an optical system 1500, a beam splitter 1600, and a mirror 1700. The optical path restricting portion 1905 may include a parallel lens 1910, a lens array 1920, and a fixed pinhole array 1940.

In the color information acquisition operation of the scanner 1000, the light source 1200 may be turned off and the first auxiliary light source 1280 may be turned on. At this time, the optical system 1500 can operate in the first state.

The first auxiliary light source 1280 may be turned on to output white light. The light output from the first auxiliary light source 1280 is incident on the auxiliary collimating lens 1950. The light incident on the auxiliary collimating lens 1950 is converted into plane light and transmitted to the beam splitter 1600 along the first longitudinal axis y1.

The light incident on the beam splitter 1600 may be transmitted to the optical system 1500 by changing the path of the light. That is, light incident on the beam splitter 1600 along the first vertical axis y1 may be incident toward the optical system 1500 in the direction of the horizontal axis x.

The optical system 1500 can operate in the first state. When the optical system 1500 operates in the first state, the optical system 1500 can output without changing the characteristics of the light. When the optical system 1500 operates in the first state, the optical system 1500 may have the same optical characteristics as the glass.

The light incident on the optical system 1500 through the beam splitter 1600 travels to the mirror 1700 along the horizontal axis x without changing the state. The light output from the optical system 1500 may be transmitted to the mirror 1700 through the second optical path changing unit 1501.

The light incident on the mirror 1700 is reflected in the direction of the second vertical axis y2 and is incident on the object.

The light incident on the object is reflected by the object and is incident on the detector 1300 through the mirror 1700, the optical system 1500, and the beam splitter 1600. The first controller 1400 may obtain color information through the light incident on the detector 1300.

Alternatively, the first controller 1400 may acquire a preview image of the object through the light incident on the detector 1300. Since the detector 1300 detects the reflected light irradiated from the upper portion of the object, the detector 1300 can acquire an image of the object viewed from above the object. The first controller 1400 may obtain a preview image from the upper portion of the object and output a preview image to the user.

The scanner according to the fifth embodiment can acquire accurate surface information and color information through an on / off operation through a separate light source without using a pinhole array capable of changing the state. Further, by using a pinhole array without using a pinhole array as a liquid crystal panel, it is possible to prevent deterioration in optical efficiency, which may occur while transmitting through the liquid crystal panel.

(4) Wide angle of the scanner Preview  Obtain

30 is a diagram showing an operation of acquiring wide angle preview information of the scanner according to the fifth embodiment.

30, a scanner 1000 according to a fifth embodiment includes an optical system 1100, a light source 1200, a detector 1300, a light path limiting unit 1905, and a first auxiliary light source 1280 can do.

The optical system 1100 may include an optical system 1500, a beam splitter 1600, and a mirror 1700. The optical path restricting portion 1905 may include a parallel lens 1910, a lens array 1920, and a fixed pinhole array 1940.

In the operation of acquiring the wide angle preview of the scanner 1000, the light source 1200 may be turned off and the first auxiliary light source 1280 may be turned on. At this time, the optical system 1500 can operate in the third state.

The first auxiliary light source 1280 may be turned on to output white light. The light output from the first auxiliary light source 1280 is incident on the auxiliary collimating lens 1950. The light incident on the auxiliary collimating lens 1950 is converted into plane light and transmitted to the beam splitter 1600 along the first longitudinal axis y1.

The light incident on the beam splitter 1600 may be transmitted to the optical system 1500 by changing the path of the light. That is, light incident on the beam splitter 1600 along the first vertical axis y1 may be incident toward the optical system 1500 in the direction of the horizontal axis x.

The optical system 1500 can operate in the third state. When the optical system 1500 operates in the third state, the optical system 1500 can operate as a concave lens. The light output from the optical system 1500 can be output by changing the light path. The light output from the optical system 1500 can be diverged. The light output from the optical system 1500 can progress gradually outward with respect to the optical axis. The light receiving area of the light output from the optical system 1500 may become larger as the distance from the optical system 1500 increases.

The light output from the optical system 1500 travels in the direction of the mirror 1700 along the horizontal axis x. The light reaching the mirror 1700 is reflected and transmitted to the object along the second vertical axis y2. The light incident on the object may have a wider light receiving area than the light incident on the object of Fig. That is, since the light incident on the object has a wide light receiving area, a wider area of the object is illuminated.

The light reflected by the object is transmitted to the mirror 1700. The light incident on the mirror 1700 is reflected and transmitted to the optical system 1500 along the horizontal axis x. The light incident on the optical system 1500 is changed so that the light receiving area is reduced and transmitted to the beam splitter 1600.

The light reaching the beam splitter 1600 is reflected and transmitted along the first longitudinal axis y1 in the direction of the detector 1300. The detector 1300 can convert the incident light into an electric signal. The detector 1300 may convert the incident light into an electric signal to obtain the wide angle preview information of the object. A larger area of the light incident on the optical system 1500 from the mirror 1700 is incident on the detector 1300 to generate a preview image of a wider range than that of the preview image of FIG. . The first controller 1400 provides the user with a wide angle preview image, thereby improving the user's convenience.

7. 6th  Embodiment - Second auxiliary light source

(1) Scanner structure

31 and 32 are views showing a scanner according to the sixth embodiment.

The scanner according to the sixth embodiment is the same as the fifth embodiment except that the position of the different light source is changed as compared with the fifth embodiment. Therefore, in describing the sixth embodiment, the same reference numerals are assigned to the components common to those of the fifth embodiment, and a detailed description thereof will be omitted.

In addition, the scanner of the sixth embodiment may further include a dental caries detection function as well as surface information, color information, and wide angle preview information. In describing the scanner of the sixth embodiment, description will be given focusing on the dental caries detection function, omitting the acquisition of the wide angle preview information.

31 and 32, a scanner 1000 according to the sixth embodiment includes an optical system 1100, a light source 1200, a detector 1300, a light path limiting unit 1905, and a second auxiliary light source 1290 ).

The optical system 1100 may include an optical system 1500, a beam splitter 1600, and a mirror 1700. The optical path restricting portion 1905 may include a parallel lens 1910, a lens array 1920, and a fixed pinhole array 1940.

The second auxiliary light source 1290 may be located in an area adjacent to the mirror 1700. The second auxiliary light source 1290 may be located in an area adjacent to the object. The second auxiliary light source 1290 may be positioned at the distal end of the scanner.

The second auxiliary light source 1290 may be located at a position opposite to the mirror 1700. The second auxiliary light source 1290 may irradiate light toward the mirror 1700. The light output from the second auxiliary light source 1290 can be reflected by the mirror 1700 and incident on the object.

Although the second auxiliary light source 1290 is positioned at a position opposite to the mirror 1700 in the drawing, the second auxiliary light source 1290 may be positioned adjacent to the mirror 1700. The second auxiliary light source 1290 may directly irradiate the light to the object without reflecting the light to the mirror 1700. [

Or the second auxiliary light source 1290 may be located in the rear area of the mirror 1700. [ That is, the mirror 1700 may be positioned between the second auxiliary light source 1290 and the object. When the second auxiliary light source 1290 is positioned behind the mirror 1700, the mirror 1700 may be a transflective mirror. That is, the mirror 1700 may be configured to reflect light from the light source 1200 and transmit light from the second auxiliary light source 1290.

The light source 1200 and the second auxiliary light source 1290 may be complementarily blinked. The light source 1200 and the second auxiliary light source 1290 may be flickered in a time division manner. For example, when the light source 1200 is turned on, the second auxiliary light source 1290 may be turned off, and when the light source 1200 is turned off, the second auxiliary light source 1290 may be turned on have.

(2) Obtain surface information of the scanner

31 is a view showing a surface information acquiring operation of the scanner according to the sixth embodiment.

31, the scanner 1000 according to the sixth embodiment includes an optical system 1100, a light source 1200, a detector 1300, a light path limiting unit 1905, and a second auxiliary light source 1290 can do.

The optical system 1100 may include an optical system 1500, a beam splitter 1600, and a mirror 1700. The optical path restricting portion 1905 may include a parallel lens 1910, a lens array 1920, and a fixed pinhole array 1940.

The light source 1200 may be turned on and the second auxiliary light source 1290 may be turned off during the operation of acquiring surface information of the scanner 1000. At this time, the optical system 1500 can operate in the second state.

Light having a plurality of wavelengths mixed is output from the light source 1200. The light source 1200 may output white light. The light output from the light source 1200 is transmitted to the light path limiting unit 1905.

The light path limiting unit 1905 may convert the light received from the light source 1200 into a light-emitting mode and output the light. The light path limiting unit 1905 can output a plurality of light beams in the form of a light bundle in the form of a matrix.

The light output from the optical path limiting unit 1905 may be transmitted to the optical system 1500 through the beam splitter 1600. The light outputted from the optical path restricting unit 1905 may be transmitted to the beam splitter 1600 through the first optical path changing unit 1201.

The optical system 1500 can operate in the second state. When the optical system 1500 operates in the second state, the optical system 1500 may have the same optical characteristics as the convex lens.

The light output from the optical system 1500 may be output so as to have different focuses for respective wavelengths. The light output from the optical system 1500 may be reflected through the mirror 1700 and transmitted to the object. The light output from the optical system 1500 may be transmitted to the mirror 1700 through the second optical path changing unit 1501.

The light that is focused on the surface of the object among the light incident on the object may be reflected. Light having a focus on the surface of the object may be incident on the detector 1300 through the mirror 1700, the optical system 1500, and the beam splitter 1600. The detector 1300 can obtain the surface information of the object using the incident light.

(3) Acquired dental caries information of scanner

32 is a view showing the dental caries information acquisition operation of the scanner according to the sixth embodiment.

32, the scanner 1000 according to the sixth embodiment includes an optical system 1100, a light source 1200, a detector 1300, a light path limiting unit 1905, and a second auxiliary light source 1290 can do.

The optical system 1100 may include an optical system 1500, a beam splitter 1600, and a mirror 1700. The optical path restricting portion 1905 may include a parallel lens 1910, a lens array 1920, and a fixed pinhole array 1940.

The light source 1200 may be turned off and the second auxiliary light source 1290 may be turned on during the dental caries information acquisition operation of the scanner 1000. [ At this time, the optical system 1500 can operate in the second state.

The second auxiliary light source 1290 may output white light. Alternatively, the second auxiliary light source 1290 may output light of a specific wavelength range.

The second auxiliary light source 1290 can output light in a blue wavelength region. The second auxiliary light source 1290 can output light in a wavelength range used for quantitative light-induced fluorescence (QLF). The second auxiliary light source 1290 may output light capable of detecting dental caries prematurely. The second auxiliary light source 1290 can output light having a wavelength of 405 nm. The light in the specific wavelength region may be defined as QLF light.

When the second auxiliary light source 1290 outputs white light, the optical system 1500 can be operated in the first state to acquire color information and preview information. In addition, the optical system 1500 can be operated in the third state to obtain the wide angle preview information. The process of acquiring the color information, the preview information, or the wide angle preview information by the scanner 1000 is the same as that of the fifth embodiment described above, so a detailed description will be omitted. However, in the sixth embodiment, the second auxiliary light source 1290 can be positioned in the area adjacent to the object, and light can be irradiated to the object without passing through the beam splitter 1600 and the optical system 1500, Light that can be lost in the process of incidence can be reduced and the light efficiency can be improved.

In the dental caries acquisition mode, the second auxiliary light source 1290 can output QLF light. At this time, the optical system 1500 can operate in the first state.

The light output from the second auxiliary light source 1920 may be reflected by the mirror 1700 and incident on the object. If the object is a tooth, the tooth can change the wavelength of the light and output it. The extent to which the wavelengths of the normal region and the abnormal region of the tooth are changed may be different. For example, in a normal region of a tooth, a blue wavelength is absorbed and a green wavelength light is output, and an intensity of a green wavelength light output in an abnormal region of a tooth may be smaller than the normal region.

The light output from the object may be transmitted to the detector 1300 through the mirror 1700, the optical system 1500, and the beam splitter 1600. The detector 1300 can analyze the wavelength region of the incident light to detect dental caries early. For example, the information of the green wavelength of the light incident on the detector 1300 can be detected to detect dental caries prematurely. The first control unit 1400 can accurately determine a region in which dental caries is present using the dental caries data, the surface information of the object, and the color information.

Although not shown, an optical filter may be additionally provided between the beam splitter 1600 and the detector 1300. The optical filter may be a yellow filter. The optical filter may be a filter that transmits a long wavelength. The optical filter may be a filter that transmits light of 520 nm or more. When the optical filter is additionally mounted, the optical filter can more accurately detect light output from the object, so that the scanner 1000 can more accurately detect dental caries.

Although the dental caries detection in the sixth embodiment has been described above, the dental caries detection may be implemented by changing the wavelength of the light source in the color information and preview information acquisition modes in the first to fifth embodiments. That is, in the first to fifth embodiments, early detection of dental caries can be performed by changing the wavelength of the light source output from the light source and the first auxiliary light source.

The detailed description of the scanner according to the first to sixth embodiments can be applied to an oral scanner. However, the present invention is not limited to an oral scanner, and may be applied to other scanners for generating shape information and color information of an object.

While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, It will be apparent to those skilled in the art that changes or modifications may fall within the scope of the appended claims.

1000: Scanner
1100: Optical system
1200: light source
1300: Detector
1500: Optical system
1600: beam splitter
1700: Mirror

Claims (24)

A detector for receiving light reflected from the object and generating a signal;
An optical system whose state is changed between a plurality of states including at least a first state and a second state by an electric signal; And
And a controller for controlling the detector and the optical system,
Wherein,
Controls the optical system and the detector to generate shape information of the object when the optical system is in the first state,
And controls the optical system and the detector to generate color information of the object when the optical system is in the second state.
The method according to claim 1,
Wherein the controller controls the optical system and the detector to generate preview information of the object when the optical system is in the second state.
The method according to claim 1,
Wherein the plurality of states further comprises a third state,
Wherein the controller controls the optical system and the detector to generate the wide angle preview information when the optical system is in the third state.
The method according to claim 1,
Wherein the surface shape of the optical system is kept constant regardless of whether the electrical signal is applied or not.
The method according to claim 1,
Wherein the optical system is a liquid crystal lens.
The method according to claim 1,
Wherein the control unit applies an electric signal so that the optical system has the same optical characteristics as the convex lens when the optical system is in the first state.
The method according to claim 1,
Wherein the control unit applies an electric signal to operate as a Fresnel lens having the same optical characteristics as the convex lens when the optical system is in the first state.
The method according to claim 1,
And a light source for irradiating light to the object through the optical system,
Wherein the light source outputs light in the form of mixed light of a plurality of wavelength regions.
9. The method of claim 8,
Wherein the light source outputs white light.
9. The method of claim 8,
Wherein the optical system converts the path of light from the light source according to a plurality of states.
11. The method of claim 10,
Wherein the optical system converts the light from the light source to have a different focal length for each wavelength region when the optical system is in the first state, and outputs the converted light.
11. The method of claim 10,
Wherein the optical system outputs light from the light source without changing the characteristic when the optical system is in the second state.
11. The method of claim 10,
And the optical system diffuses and outputs the light from the light source when the optical system is in the third state.
12. The method of claim 11,
Wherein the detector receives light whose focus is located on the surface of the object when the optical system is in the first state.
The method according to claim 1,
Wherein the amount of light received by the detector when the optical system is in the first state is smaller than the amount of light received by the detector when the optical system is in the second state.
The method according to claim 1,
Wherein the light receiving area of the detector is smaller than the light receiving area of the detector when the optical system is in the second state when the optical system is in the first state.
The method according to claim 1,
Wherein the optical system is controlled such that the first state and the second state are alternately changed.
The method of claim 3,
Wherein the optical system is controlled such that the first state, the second state, and the third state are alternately changed.
A light source for outputting first light including at least a first wavelength and a second wavelength; And
And an optical system whose state changes by an electrical signal,
Wherein the optical system generates a chromatic aberration of the first light in a first state to output second light having a first focal depth and third light having a second focal depth,
Wherein the optical system causes chromatic aberration of the first light in a second state to output fourth light having a third focus depth and fifth light having a fourth focus depth.
20. The method of claim 19,
Wherein the third focus depth and the fourth focus depth are the same.

20. The method of claim 19,
And the fourth light and the fifth light have the form of light that diverges.
20. The method of claim 19,
Wherein the second light is caused by the first wavelength and the third light is caused by the second wavelength.
20. The method of claim 19,
Wherein the light source comprises a red light source, a blue light source and a green light source,
Wherein the light source outputs white light.
A scanner for scanning a three-dimensional shape of an object,
Light source;
An optical system capable of changing a state according to an electrical signal and changing an optical characteristic according to the state change; And
An optical sensor in which unit color pixels including at least R pixels, G pixels, and B pixels are arranged in a two-dimensional array of N x M shapes,
When the scanner operates in the first mode, an electrical signal corresponding to light reflected from the target object is detected in only a part of N x M unit color pixels included in the two-dimensional array of the photosensor,
When the scanner operates in the second mode, an electrical signal corresponding to the light reflected from the object is detected in all the N x M unit color pixels included in the two-dimensional array of the photosensor,
The two-dimensional coordinate value of the first unit color pixel on which the electrical signal is detected and the color value detected by the first unit color pixel on the pixel array, when operating in the first mode, Is used to detect the shape,
The two-dimensional coordinate value of the second unit color pixel on which the electrical signal is detected, and the color value detected by the second unit color pixel, when operating in the second mode, Used to generate images
A scanner for scanning a three-dimensional shape of an object.

Images