KR101455232B1 - Optical system of signal detection for near-infrared and tera hertz waves band - Google Patents

Abstract

An example of an optical system for detecting a near-infrared ray signal and a terahertz band signal includes a main reflector having a first main reflector having a light tube and a plurality of second main reflectors circumferentially arranged around the first main reflector, A first sub-reflector which is positioned to face the main reflecting portion and reflects the light reflected from the first main reflecting mirror to the optical tube portion, and a second sub reflector which reflects the light reflected from the second main reflecting mirror to the optical tube portion, An image sensor which is located at the lower end of the light tube and filters the infrared rays from the light passing through the light tube and picks up the image and outputs the signal as an electric signal; a terahertz wave detector for filtering a signal in the terahertz band from the light passing through the optical tube and detecting the image signal, An optical system for detecting a signal of the near-infrared signal, and the terahertz band including parts.

Description

TECHNICAL FIELD [0001] The present invention relates to an optical system for detecting a near-infrared signal and a terahertz signal,

The present invention relates to an optical system for detecting a near infrared ray signal and a signal in a terahertz band.

In general, optical systems with lenses and reflectors are used in aerial or satellite cameras for terrain detection and optical systems for observing objects.

Such an optical system includes a plurality of mirrors and a plurality of lenses, and collects and im- ages light reflected from a subject such as a star or a surface water.

Therefore, the observer observes the image formed by the light through the telescope directly or observes the image formed by the light using a separate device such as a camera and confirms the photographed image.

On the other hand, an astronomical telescope for reading light regions such as visible light and infrared light is also being developed to visually observe objects with different wavelengths as well as more accurate images. Quot; Giant Magellan Telescope: overview ", such as Matt Jones et al., Published in the SPIE.

However, the conventional astronomical telescope can not simultaneously observe lights of different wavelengths such as near-infrared rays and terahertz signals, which is inconvenient for the user.

Matt Johns et al., "Giant Magellan Telescope: overview ", Proc. SPIE 8444, Ground-based and Airborne Telescopes IV, 84441H (September 17, 2012); doi: 10.1117 / 12.926716; http://dx.doi.org/10.1117/12.926716

SUMMARY OF THE INVENTION The present invention has been made in view of the above circumstances, and an object of the present invention is to increase the user's satisfaction by simultaneously observing lights of different wavelengths.

According to an aspect of the present invention, there is provided an optical system for detecting a near-infrared signal and a terahertz signal, the optical system including a first main reflector having a light tube and a plurality of second main reflectors surrounding the first main reflector, A first sub-reflector which is positioned to face the main reflecting portion and reflects the light reflected from the first main reflecting mirror to the optical tube portion, and a second sub reflector which reflects the light reflected from the second main reflecting mirror to the optical tube portion An image that is filtered at the infrared light which is located at the lower end of the light tube and which has been filtered through the light tube and is picked up and output as an electrical signal; An image sensor, and a terahertz filter disposed at the lower end of the optical tube and filtering the signal of the terahertz band from the light passing through the optical tube. It comprises tsu detector.

The image sensor unit includes a first imaging optical system positioned at the lower end of the light tube unit and filtering an infrared ray from the light passing through the optical tube unit to form an image, and a second imaging optical system for imaging the image obtained by the first imaging optical system, And an image sensor for outputting the image.

The terahertz detection unit includes a second imaging optical system positioned at the lower end of the optical tube for filtering a signal in a terahertz band from the light passing through the optical tube, and a second imaging optical system for filtering the terahertz band signal filtered by the second imaging optical system. And a terahertz detector for detecting a signal of the first antenna.

The first main reflector and the second main reflector have the same shape.

The first and second main reflectors may have a shape of a circle, a polygon, or an ellipse.

The first main reflector and the second main reflector have different shapes.

Wherein one of the first and second main reflectors has a shape of a circle, a polygon, or an ellipse, and the other has a shape of a circle, a polygon, and an ellipse.

And the sub-reflecting mirror portion has the same number of sub-reflecting mirrors as the sum of the numbers of the first and second main reflecting mirrors of the main reflecting mirror portion.

The first and second sub-reflectors are identical in shape to the first and second main reflectors.

The first and second sub-reflecting mirrors have diameters smaller than the diameter of any one of the first and second main reflecting mirrors.

The first imaging optical system includes a filter for passing only infrared rays.

The image sensor is a charge-coupled device (CCD) or a complementary metal-oxide semiconductor (CMOS) image sensor.

The terahertz detector is a bolometer.

According to this feature, since the near infrared ray signal and the terahertz band signal are simultaneously observed, the satisfaction of the user is increased.

1 is a perspective view of an optical system for detecting a near-infrared signal and a terahertz band signal according to an embodiment of the present invention.
FIG. 2 is a sectional view of the optical system shown in FIG. 1 taken along the line II-II in a cutaway view of the main reflecting part, the sub-reflecting part and the detecting part located at the lower end of the main reflecting part; And schematically showing a path of light transmitted to the detection unit.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily carry out the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein.

An optical system for detecting a near-infrared signal and a terahertz signal according to an embodiment of the present invention will be described with reference to the accompanying drawings.

1 and 2, an optical system according to an embodiment includes a main reflecting part 100 for reflecting light 1, a main reflecting part 100 at an upper end of the main reflecting part 100, And a detecting unit 300 positioned at the lower end of the main reflecting mirror unit 100. As shown in FIG.

The main reflecting mirror part 100 includes a first main reflecting mirror 110 and a plurality of second main reflecting mirrors 120 located around the first main reflecting mirror 110. [

Here, the first main reflector 110 has a light tube portion 111 for passing the light 1 reflected from the sub-reflecting portion 200.

The first and second main reflectors 110 and 120 may have the same shape or different shapes. The shapes of the first and second main reflectors 110 and 120 may be circular, polygonal, or elliptical.

The second main reflector 120 configured as described above is inclined toward the sub-reflecting portion 200 in order to reflect the light 1 to the sub-reflecting portion 200 positioned opposite to the upper end of the main reflecting portion 100 .

The sub-reflecting mirror portion 200 is disposed around the first sub-reflecting mirror 210 and the first sub-reflecting mirror 210 that reflect the light reflected from the first main reflecting mirror 110 and transmit the light to the light tube portion 111, The second sub-reflector 220 has a plurality of second sub-reflectors that reflect light reflected from the two-main reflector 120 and transmit the reflected light to the light tube 111. The second sub-reflector 220 has a sum of the numbers of the second main reflectors 120 As shown in FIG.

The sub-reflecting portion 200 is inclined in the direction of the light tube 111 so as to reflect the light 1 reflected by the main reflecting portion 100 to the light tube portion 111.

The first and second sub-reflectors 210 and 220 may have the same shape as the first or second main reflectors 110 and 120 and the diameters of the first and second sub- 1 and the second main reflecting mirrors 110, 120, respectively.

The detection unit 300 includes an image sensor unit 310 positioned at the lower end of the light tube 111 and capturing infrared rays and a tera hertz sensor disposed at the lower end of the light tube unit 111 in parallel with the image sensor unit 310, And a terahertz detector 320 for detecting a signal of a band.

Here, the image sensor unit 310 receives the light 1 passing through the light tube 111 after being reflected at the first main reflector 110, secondarily reflected at the first sub-reflector 210, An image of an infrared ray obtained by the first imaging optical system 311 and the first imaging optical system 311 which filters an infrared ray through the transmitted light 1 and forms an image (not shown) And an image sensor 312 for outputting the image data.

Only the infrared rays are filtered by the first imaging optical system 310 including the filter that allows only the infrared rays to pass through the light 1 passing through the optical tube 111 as described above, The image sensor 312 located at the rear end picks up an image formed on the first imaging optical system 311 and outputs it as an electrical signal.

Here, the image sensor 312 may be a charge-coupled device (CCD) or a complementary metal-oxide semiconductor (CMOS) image sensor.

The terahertz detection unit 320 receives the light 1 passing through the light tube 111 after being reflected by the second main reflector 120 and then reflected by the second auxiliary reflector 220, A second imaging optical system 321 for filtering a signal in the terahertz band in the received light 1 and a terahertz detector 322 for detecting a signal in the terahertz band filtered by the second imaging optical system 321, Detector 322.

Where the terahertz detector 322 may be a bolometer.

The following is an operation of detecting a near-infrared ray and a terahertz band signal from light through an optical system according to an embodiment of the present invention.

When the light 1 touches the main reflecting portion 100, the light is reflected in the direction of the sub-reflecting portion 200 by the angles of the first and second main reflecting mirrors 110 and 120, The light 1 that has come into contact with the secondary reflecting mirror part 200 passes through the light tube part 111 located at the first main reflecting mirror part 110 by the angle of the secondary reflecting mirror 210. [

The light 1 having passed through the light tube 111 is transmitted to the image sensor unit 310 and the terahertz detector 320 at the lower end of the light tube 111.

Here, the light 1 transmitted to the image sensor unit 310 is filtered after the infrared ray is filtered by the filter included in the first imaging optical system 311, and then the image is formed.

Then, the image sensor 312 picks up an image formed on the first imaging optical system 311 and outputs it as an electrical signal.

In addition, the light 1 transmitted to the terahertz detector 320 is filtered by the second imaging optical system 321, and the terahertz band signal is detected by the terahertz detector 322.

The terahertz detector 322 of the terahertz detector 320 for detecting the terahertz band signal and the terahertz detector 322 of the image sensor 312 for detecting the infrared rays are present side by side and at the same time the near infrared ray signal and the teraher It is possible to efficiently detect the space of the detector 300 located at the lower end of the main reflecting mirror portion.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, It belongs to the scope of right.

100: main reflecting part 110: first main reflecting mirror
111: light tube 120: second main reflector
200: sub-reflecting portion 210: first sub-reflecting mirror
220: Second submirror 300: Detector
310: image sensor unit 311: first imaging optical system
312: image sensor 320: terahertz detector
321: Second imaging optical system 322: Terahertz detector
1: Light

Claims (13)

A main reflecting mirror 100 having a first main reflecting mirror 110 having a photoreceptor 111 and a plurality of second main reflecting mirrors 120 positioned around the first main reflecting mirror 110,
A first sub reflector 210 facing the main reflector 100 and reflecting the light reflected from the first main reflector 110 to the light tube 111, (200) having a plurality of second sub-reflectors (220) which are arranged around the first sub-reflector (210) and reflect the light reflected by the first sub-reflector
An image sensor unit 310 located at the lower end of the optical tube 111 for filtering and imaging the near-infrared light from the light passing through the optical tube 111 and outputting the electrical signal;
And a terahertz detector 320 located at the lower end of the optical tube 111 for filtering and detecting a signal of a terahertz band from the light passing through the optical tube 111,
The image sensor unit 310 filters the near infrared rays from the light reflected by the first main reflector 110 and the second light reflected by the first sub-reflector 210 after passing through the optical tube 111, And an image sensor (312) for picking up the image obtained by the first imaging optical system (311) and outputting it as an electric signal, wherein the first imaging optical system (311)
The terahertz detecting unit 320 reflects the first light reflected from the plurality of second main reflectors 120 and the second reflected light from the plurality of second sub-reflectors 220, And a terahertz detector (322) for detecting the signal of the terahertz band filtered by the second imaging optical system (321), wherein the second imaging optical system (321)
The image sensor unit 310 and the terahertz detection unit 320 are disposed at different positions on the lower end of the light tube 111 to receive the respective lights passing through the light tube 111,
The sub-reflecting mirror portion 200 has the same number of sub-reflecting mirrors as the sum of the numbers of the first and second main reflecting mirrors 110 and 120 of the main reflecting mirror portion 100,
The first and second sub-reflectors 210 and 220 may be configured to detect a near-infrared signal and a terahertz signal having a diameter smaller than that of any one of the first and second main reflectors 110 and 120, . delete delete delete delete delete delete delete delete delete delete delete delete

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