KR200496661Y1 - Fluorescent concentrator for optical communication - Google Patents

Abstract

The present invention relates to a fluorescence concentrator for optical communication that collects optical signals in an optical wireless transceiver and transmits them to a receiver.
In the fluorescent concentrator for optical communication according to the present invention, a reflector 121 is disposed on the rear surface of the fluorescent acrylic plate 110, and reflectors 125, 126, 127, and 128 are disposed on the circumferential surface of the fluorescent acrylic plate 110, respectively. , It is characterized in that a hole 130 for emitting an optical signal is formed in the center of the reflector 125 disposed on one of the circumferential surfaces.

Description

Fluorescent concentrator for optical communication {FLUORESCENT CONCENTRATOR FOR OPTICAL COMMUNICATION}

The present invention relates to a fluorescent concentrator for optical communication that collects optical signals in an optical wireless transceiver and transmits them to a receiver. A fluorescence concentrator for optical communication capable of considerably improving the signal intensity of an optical signal projected to a light-receiving element for optical communication by condensing an optical signal by a reflector.

Fifth generation (5G) wireless communication has been widely adopted and deployed with ultra-reliability for fast data rates, vast connectivity and low latency. However, 5G wireless communication is expected to face challenges due to the exponential growth of smart devices and applications requiring higher data rates. In order to meet this ever-increasing demand, research on 6th generation (6G) wireless communication is being actively conducted worldwide. 6G wireless communications and networks are expected to increase spectrum efficiency with large-scale coverage, high levels of security, and smart resource management incorporating artificial intelligence (AI). To this end, new cultures and technologies including new modulation and multiplexing technologies as well as non-terrestrial wireless networks and integrated space/air/marine/terrestrial communication networks are being researched. One of the most important elements of 6G is the exploration of new frequencies to accommodate the explosive growth in device connectivity and required data rates. Candidates for study include millimeter wave (mmWave), terahertz (THz) and the optical spectrum.

Optical wireless communications (OWC), which uses the optical spectrum of optical devices such as light emitting diodes (LEDs) and laser diodes (LDs), has been proposed as a promising candidate for next-generation wireless communication technology. It has an unlicensed and nearly unlimited spectrum region that is more than three times higher than the entire radio frequency (RF) spectrum. In addition, OWC provides a high level of security, high-speed data transmission and efficient energy consumption. For example, communication using visible light wavelengths, known as visible light communications (VLC), enables simultaneous functions of data communication and lighting, leading to high energy efficiency.

In an OWC system, a general receiver with a high bandwidth has a small light sensing area, so there is a trade-off between bandwidth and signal-to-noise ratio (SNR). Because of these limitations, optical lenses including compound parabolic concentrators (CPCs) are often used. Optical lenses focus the light into a small sensing area in the high-bandwidth receiver. However, in return, the angle of the incident light, i.e., the field of view (FOV) of the receiver is limited. Therefore, careful and precise optical system design for a specific FOV is required. For this reason, it can be difficult to use optical lenses for various applications with high mobility.

Instead of conventional optical lenses, fluorescence concentrators (FCs) are attracting attention as attractive optical concentrators that combine wide FOV and high optical gain. FCs were initially developed for solar energy harvesting. In FC, incoming light is absorbed by the fluorescent material and the absorbed light is emitted with a longer wavelength. As this process occurs, total internal reflection occurs inside the FC, and light is transmitted toward the receiver. That is, during this process, a significant portion of the light is trapped inside the FC by total internal reflection and is transmitted to the side where the receiver is located.

However, previous communication studies using general planar FCs have a problem in that a significant portion of light is lost from the side. This is because the sensing area of the high-bandwidth receiver on one side is much smaller than the total area on the side of the FC.

Korean Patent Publication No. 10-2010-0043972 (published on April 29, 2010) introduces an optical signal concentrator and an optical receiver.

The optical signal collector includes a diffusion sheet for diffusing and outputting an optical signal, and a light guide plate positioned below the diffusion sheet and guiding the light signal incident from the diffusion sheet to a side surface in a direction perpendicular to an incident direction. The light guide plate has a concentric pattern formed to face the diffusion sheet.

However, the optical signal collector has a problem in that a significant portion of light is lost at the edge.

Therefore, the object of the present invention to overcome the above conventional problems is to arrange reflectors on the back and circumferential surfaces of the fluorescent acrylic plate, and the light signal incident on the front of the fluorescent acrylic plate is condensed by the reflector, thereby receiving light for optical communication. It is to provide a fluorescence concentrator for optical communication capable of considerably improving the signal intensity of an optical signal projected onto a device.

Another object of the present invention is to provide a fluorescent concentrator for optical communication that can be used as an antenna for optical communication by adjusting the arrangement angle so that the front side of the fluorescent acrylic plate faces the direction in which the light signal is input.

An example of a fluorescent concentrator for optical communication according to the present invention for achieving the above object is a reflector disposed on the rear surface of a fluorescent acrylic plate, a reflector disposed on a circumferential surface of the fluorescent acrylic plate, respectively, and disposed on one circumferential surface of the fluorescent acrylic plate. It is characterized in that a hole for emitting an optical signal is formed in the center of the reflector.

In addition, in the optical concentrator for optical communication according to the present invention, an optical signal projected through the hole is provided to a light receiving element for optical communication, the light receiving element for optical communication is an Avalanche Photo Diode (APD), and a hole in a reflector. It is characterized in that it is mounted on the front and receives an optical signal.

The reflector disposed on the rear surface of the fluorescent acrylic plate is characterized in that a network pattern is formed on the reflecting surface, and an optical signal incident on the front surface of the fluorescent acrylic plate is reflected to the circumferential surface by the network pattern.

The reflector mounted on the circumferential surface is characterized in that any one of a Lambertian-reflector, a specular-reflector, and a retro-reflector, or a mixture of two or more reflectors.

In addition, the fluorescent concentrator for optical communication according to the present invention further includes a holder for mounting the fluorescent acrylic plate equipped with the reflector, and the reflector on the back side and the reflector on the circumferential surface are the inner and circumferential surfaces of the holder and the index matching liquid ( index matching liquid), a cutout is formed in the center of either side of the frame frame, the hole of the reflector is exposed to the outside through the cutout, and a light receiving element for optical communication for receiving an optical signal projected through the hole is formed. It is characterized in that it is mounted on the cutout.

In addition, in another example of the fluorescent concentrator for optical communication according to the present invention, reflectors are attached to the rear and circumferential surfaces of the fluorescent acrylic plate, and a hole for emitting an optical signal is formed in the center of the reflective plate disposed on either circumferential surface, ,

It is characterized in that a fluorescent acrylic plate with a reflector is mounted on a holder, and the holder is mounted on a stand to be able to adjust the arrangement angle.

The holder has a cutout formed in the center of one side of the frame frame, a hole of the reflector is exposed to the outside through the cutout, and a light receiving element for optical communication for receiving an optical signal projected through the hole is mounted on the cutout. characterized by

In addition, the holder has shaft protrusions formed on both side surfaces of the frame frame, and a first check protrusion is formed around the shaft protrusion,

The stand is equipped with a lower vertical pillar of the support on the base plate, the center of the horizontal part of the support formed in the shape of "└┘" is connected to the lower vertical pillar, and the top of the left vertical part and the top of the right vertical part built on both side ends of the horizontal part. Each mounting hole is formed, and a first concave-convex portion is formed around the mounting hole, so that the first check protrusion of the shaft protrusion is engaged with the first concave-convex portion in a state where the shaft protrusions of the holder are fitted into the mounting holes, respectively. do.

In addition, the stand has a second check protrusion formed around the lower end of the lower vertical pillar, a second concave-convex part is formed around the hole formed in the center of the support plate, and when the lower end of the lower vertical pillar is inserted into the hole of the support plate, the first It is characterized in that the 2 check protrusions are engaged with the second concave-convex portion.

Another example of a fluorescent concentrator for optical communication according to the present invention is a reflector attached to the rear and circumferential surfaces of a fluorescent acrylic plate, respectively, and a hole for emitting an optical signal is formed in the center of the reflective plate disposed on either circumferential surface, A fluorescent acrylic plate with reflectors attached to the rear and circumferential surfaces is mounted on the holder, the holder is placed in the center hole of the case, and the shaft protrusions formed in the center of both side parts of the holder are inserted into the mounting holes formed in the center of the inner vertical part of the case, It is characterized in that the arrangement angle of the holder is adjusted around the shaft protrusion.

The holder has a cutout formed in the center of one side of the frame frame, a hole of the reflector is exposed to the outside through the cutout, and a light receiving element for optical communication for receiving an optical signal projected through the hole is mounted on the cutout. characterized by

In addition, a check protrusion is formed around the shaft protrusion of the holder, and a concave-convex portion is formed in the mounting hole of the case. By being engaged, it is characterized in that the angular rotation state of the holder is maintained as it is.

Another example of a fluorescent concentrator for optical communication according to the present invention is a reflector attached to the rear and circumferential surfaces of a fluorescent acrylic plate, respectively, and a hole for emitting an optical signal is formed in the center of the reflective plate disposed on either circumferential surface, A fluorescent acrylic plate with reflectors attached to the rear and circumferential surfaces is mounted on the holder, the holder is placed in the center hole of the first case, and the first protrusions formed at the center of both side surfaces of the holder are at the center of the inner vertical portion of the first case. It is inserted into the formed first mounting hole, the holder adjusts the first disposition angle around the first shaft protrusion, the first case is disposed in the center hole of the second case, and the first case is placed in the center of the upper and lower surfaces of the first case. The formed second shaft protrusion is inserted into the second mounting hole formed in the inner upper horizontal portion and the inner lower horizontal portion of the second case, so that the second arrangement angle of the first case is adjusted around the second shaft protrusion. .

The holder has a cutout formed in the center of one side of the frame frame, a hole of the reflector is exposed to the outside through the cutout, and a light receiving element for optical communication for receiving an optical signal projected through the hole is mounted on the cutout. characterized by

A first check protrusion is formed around the first shaft protrusion of the holder, a first concave-convex portion is formed in the first mounting hole of the first case, and the first shaft protrusion of the holder is formed in the first mounting hole of the first case. In each fitted state, the first check protrusion of the first shaft protrusion is engaged with the first concave-convex portion, so that the angular rotation state of the holder is maintained as it is.

A second check protrusion is formed around the second shaft protrusion of the first case, and a second concave-convex portion is formed in the second mounting hole of the second case, so that the second shaft protrusion of the first case It is characterized in that the angular rotation state of the first case is maintained as it is by being engaged with the second concave-convex portion by the second check protrusion of the second shaft protrusion in the state of being fitted into the two mounting holes, respectively.

As a result, in the optical concentrator for optical communication according to the present invention, the light signal incident on the front surface of the fluorescent acrylic plate is condensed by the reflector disposed on the circumferential surface, so that the signal intensity of the optical signal projected to the light receiving element for optical communication is significantly improved. , the arrangement angle can be adjusted so that the front side of the fluorescent acrylic plate is directed in the direction in which the optical signal is input, so that it can be used as an antenna for optical communication.

1 is a perspective view showing a fluorescent concentrator for optical communication according to a first embodiment of the present invention.
2 is an exploded perspective view illustrating a fluorescent concentrator for optical communication according to a first embodiment of the present invention.
3 is a perspective view showing a fluorescence concentrator for optical communication according to a second embodiment of the present invention.
4 is an exploded perspective view showing a fluorescent concentrator for optical communication according to a second embodiment of the present invention.
5 and 6 are perspective views showing a fluorescent concentrator for optical communication according to a third embodiment of the present invention. FIG. 5 is before the holder is angularly rotated, and FIG. 6 is a state in which the holder is angularly rotated in the direction of the optical signal.
7 is an exploded perspective view showing a fluorescent concentrator for optical communication according to a third embodiment of the present invention.
8 and 9 are perspective views showing a fluorescent concentrator for optical communication according to a fourth embodiment of the present invention. FIG. 8 is before the holder is angularly rotated, and FIG. 9 is a state in which the holder is angularly rotated in the direction of the optical signal.
10 is an exploded perspective view illustrating a fluorescence concentrator for optical communication according to a fourth embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the drawings.

1 and 2, in the fluorescent concentrator according to the first embodiment of the present invention, a reflector 121 is disposed on the rear surface of a fluorescent acrylic plate 110, and a reflector plate ( 125, 126, 127, and 128) are disposed, respectively, and a hole 130 for emitting an optical signal is formed in the center of the reflector 125 disposed on either circumferential surface.

In the fluorescent concentrator for optical communication according to the first embodiment of the present invention configured as described above, the optical signal incident on the front of the fluorescent acrylic plate 110 is absorbed by the fluorescent material, and the light having a longer wavelength than the wavelength of the absorbed optical signal is emitted In this process, a significant part of the optical signal is confined inside the fluorescent acrylic plate 110 by total reflection inside the fluorescent acrylic plate 110 and is transmitted to the circumferential surface. At this time, reflectors 121; 125, 126, 127, and 128 are disposed on the rear and circumferential surfaces of the fluorescent acrylic plate 110, respectively, so that optical signals transmitted to the circumferential surface of the fluorescent acrylic plate 110 are reflected by the reflector 125, By being reflected by the 126, 127, and 128, the optical signals reflected by the reflectors 125, 126, 127, and 128 are projected through the hole 130, and the optical signal projected through the hole 130 is a light receiving element for optical communication. (140).

By this, the signal intensity of the optical signal provided to the light receiving element 140 for optical communication is significantly improved - about 2.5 times compared to the case without the reflector.

The fluorescent acrylic plate 110 is shown in the form of a square plate of 50 mm × 50 mm × 2 mm, but the present invention is not limited thereto, and the size of the square plate can be varied, as well as a circle or other polygonal shape rather than a square plate. can be formed as

The reflector 121 disposed on the rear surface of the fluorescent acrylic plate 110 has a network pattern formed on the reflective surface, and an optical signal incident on the front of the fluorescent acrylic plate 110 is directed to the circumferential surface by the network pattern. It is reflected.

The reflectors 125, 126, 127, and 128 may be any one of a Lambertian-reflector, a specular-reflector, and a retro-reflector, or a mixture of two or more reflectors.

The light receiving device 140 for optical communication is an Avalanche Photo Diode (APD) and is mounted in front of the hole 130 of the reflector to receive an optical signal.

In addition, the fluorescent concentrator for optical communication according to the first embodiment of the present invention includes a holder 150 for mounting a fluorescent acrylic plate 110 equipped with reflectors 121; Further, the rear reflector 121 and the circumferential reflectors 125, 126, 127, 128 are applied to the inner and circumferential surfaces of the holder 150 and the index matching liquid (not shown). and a cutout 152 is formed at the center of either side 251 of the frame frame, so that the hole 130 of the reflector 125 is exposed to the outside through the cutout 152, and the hole 130 A light receiving element 140 for optical communication for receiving an optical signal projected through is mounted on the cutout 152 .

The fluorescent concentrator for optical communication according to the first embodiment of the present invention as described above performs an antenna function of condensing the optical signal and increasing the signal strength to the light receiving element 140 for optical communication, thereby providing smart phones, IoT devices, and quantum security. (quantum security) subsystem or V2X (Vehicle-to-Everything) field.

3 and 4, the fluorescent concentrator for optical communication according to the second embodiment of the present invention, like the fluorescent concentrator for optical communication according to the first embodiment of the present invention, the rear surface and circumference of the fluorescent acrylic plate 210 A reflector 220 is attached to each surface, and a hole 230 for emitting an optical signal is formed at the center of the reflector disposed on one of the circumferential surfaces.

In addition, the fluorescent concentrator for optical communication according to the second embodiment of the present invention is applied as an antenna for optical communication, and a fluorescent acrylic plate 210 having reflectors 220 attached to the rear and circumferential surfaces is mounted on the holder 250. , The holder 250 is mounted on the stand 260 to be able to adjust the arrangement angle.

In the holder 250, a cutout 252 is formed in the center of one surface 251a of the frame frame 251, and the hole 230 of the reflector 220 is exposed to the outside through the cutout 252. A light receiving element 240 for optical communication for receiving an optical signal projected through the hole 230 is mounted on the cutout 252.

In addition, the holder 250 has protrusions 253 and 255 formed on both side portions 251b and 251c of the frame frame 251, respectively, and a first check protrusion 253a around the protrusions 253 and 255. , 255a) is formed.

In the stand 260, the lower vertical pillar 263 of the support 262 is mounted on the base plate 261, and the horizontal part 264 of the support 262 formed in the shape of "└┘" on the lower vertical pillar 263 The center is connected, and mounting holes 266 and 268 are formed at the upper end of the left vertical part 265 and the upper end of the right vertical part 267 erected at both ends of the horizontal part 264, respectively, and the mounting holes 266, 268) is formed around the shaft protrusions 266b and 268b, and in a state where the protrusions 253 and 255 of the holder 250 are fitted into the mounting holes 266 and 268, respectively, the protrusions 253 and 255 The first check protrusions 253a and 255a of ) are engaged with the first uneven portions 266b and 268b.

In addition, the stand 260 has a second check protrusion 263a formed around the lower end of the lower vertical column 263, and a second uneven portion 269b around the hole 269 formed in the center of the support plate 261. ) is formed, and when the lower end of the lower vertical column 263 is inserted into the hole 269 of the support plate 261, the second check protrusion 263a is engaged with the second uneven portion 269b.

The fluorescent acrylic plate 210, the reflector 220, and the light receiving element 240 for optical communication have the same structure as the fluorescent acrylic plate, the reflector, and the light receiving element for optical communication introduced in the fluorescent concentrator for optical communication according to the first embodiment of the present invention. same.

The fluorescent concentrator for optical communication according to the second embodiment of the present invention configured as described above is a lower vertical column inserted into the base plate 261 of the stand 260 so that the front of the fluorescent acrylic plate 210 faces the direction in which the light signal is input. When 263 is turned in the direction of arrow 271 in FIG. 3, in a state where the lower vertical pillar 263 is relatively turned in the direction of arrow 271 with respect to the pedestal 261, the second check protrusion 263a is By being engaged with the 2 concave-convex portions 269b, the lower vertical column 263 maintains an angularly rotated state as it is.

In addition, the mounting hole 266 of the left vertical part 265 of the stand 260 and the mounting hole 268 of the right vertical part 267 of the stand 260 face the front of the fluorescent acrylic plate 210 in the direction in which the light signal is input. When the holder 250 is turned in the direction of the arrow 275 in FIG. 3 in a state in which the protrusions 253 and 255 of the holder 250 are inserted into the protrusions 253 and 255 of the holder 250, the protrusions 253 and 255 of the holder 250 are left vertically. In the state where the part 265 and the mounting holes 266 and 268 of the right vertical part 267 are rotated, the first check protrusions 253a and 255a of the shaft protrusions 253 and 255 are first uneven portions 266b and 268b ) By being engaged with, the holder 250 maintains the angularly rotated state as it is.

In this way, the fluorescent concentrator for optical communication according to the second embodiment of the present invention is used as an antenna for optical communication, and can be adjusted so that the front of the fluorescent acrylic plate 210 faces the direction in which the optical signal is input, and the adjusted state remains as it is. There is a sustaining effect.

5 to 7, the fluorescent concentrator for optical communication according to the third embodiment of the present invention, like the fluorescent concentrator for optical communication according to the second embodiment of the present invention, is applied as an antenna for optical communication, and is a fluorescent acrylic plate. A reflector 312 is attached to the rear and circumferential surfaces of the 310, respectively, and a hole 314 for emitting an optical signal is formed in the center of the reflector disposed on either circumferential surface, and the reflector is formed on the rear and circumferential surfaces ( 312) is attached to the holder 320, the holder 320 is disposed in the center hole 331 of the case 330, and the axis formed in the center of both side portions of the holder 320 The protrusions 325 and 327 are inserted into the mounting holes 335 and 337 formed in the center of the inner vertical portions 332 and 333 of the case 330, so that the holder 320 is arranged at an angle around the shaft protrusions 325 and 327. (a; see Fig. 6) can be adjusted.

The holder 320 has a cutout 322 formed at the center of one surface 321a of the frame frame 321, and the hole 314 of the reflector 312 is exposed to the outside through the cutout 322. A light receiving element 340 for optical communication for receiving an optical signal projected through the hole 314 is mounted on the cutout 322 .

In addition, check protrusions 325a and 327a are formed around the shaft protrusions 325 and 327 of the holder 320, and uneven portions 335b and 337b are formed in the mounting holes 335 and 337 of the case 330. formed, in a state where the protrusions 325 and 327 of the holder 320 are fitted into the mounting holes 335 and 337 of the case 330, respectively, the check protrusions 325a and 327a of the protrusions 325 and 327 By being engaged with the uneven portions 335b and 337b, the angular rotation state of the holder 320 is maintained as it is.

The fluorescent acrylic plate 310, the reflector 312, and the light receiving element 340 for optical communication have the same structure as the fluorescent acrylic plate, the reflector, and the light receiving element for optical communication introduced in the fluorescent concentrator for optical communication according to the first embodiment of the present invention. same.

In the fluorescent concentrator for optical communication according to the third embodiment of the present invention configured as described above, the holder 320 is centered around the protrusions 325 and 327 so that the front of the fluorescent acrylic plate 310 faces the direction in which the optical signal is input. The arrangement angle (a) is adjusted, and check projections 325a and 327a are formed around the shaft projections 325 and 327, and the check projections 325a and 327a of the shaft projections 325 and 327 and the mounting hole ( The angularly rotated state of the holder 320 is maintained as it is by engaging the uneven portions 335b and 337b of the 335 and 337 .

In this way, the fluorescent concentrator for optical communication according to the third embodiment of the present invention is used as an antenna for optical communication, and can be adjusted so that the front of the fluorescent acrylic plate 310 faces the direction in which the optical signal is input, and the adjusted state remains as it is. There is a sustaining effect.

8 to 10, the fluorescence concentrator for optical communication according to the fourth embodiment of the present invention is applied as an antenna for optical communication like the fluorescence concentrator for optical communication according to the third embodiment of the present invention, and is a fluorescent acrylic plate. A reflector 412 is attached to the rear and circumferential surfaces of the 410, respectively, and a hole 414 for emitting an optical signal is formed in the center of the reflector disposed on either circumferential surface, and the reflector is formed on the rear surface and the circumferential surface ( 412) is attached to the holder 420, the holder 420 is placed in the center hole 431 of the first case 430, and the center of both sides of the holder 420 The formed first shaft protrusions 425 and 427 are inserted into the first mounting holes 435 and 437 formed in the center of the inner vertical portion of the first case 430, so that the holder 420 is attached to the first shaft protrusions 425 and 427. A first disposition angle (b; see FIG. 9) is adjusted around , the first case 430 is disposed in the center hole 441 of the second case 440, and the upper surface of the first case 430 And the second shaft protrusions 432 and 433 formed at the center of the lower surface are attached to the second mounting holes 445 and 447 formed in the inner upper horizontal portion 442 and the inner lower horizontal portion 443 of the second case 440. By being inserted, the second arrangement angle (c; see FIG. 9) of the first case 430 is adjusted around the second shaft protrusions 432 and 433.

In the holder 420, a cutout 422 is formed at the center of one surface 421a of the frame frame 421, and the hole 414 of the reflector 412 is exposed to the outside through the cutout 422. A light receiving element 450 for optical communication for receiving an optical signal projected through the hole 414 is mounted on the cutout 422 .

First check protrusions 425a and 427a are formed around the first shaft protrusions 425 and 427 of the holder 420, and the first mounting holes 435 and 437 of the first case 430 have first check protrusions 425a and 427a. In a state where the protrusions 425 and 427 of the holder 420 are fitted into the first mounting holes 435 and 437 of the first case 430, respectively, the protrusions 425 and 427 of the holder 420 are formed with the uneven portions 435b and 437b. As the first check protrusions 425a and 427a of the shaft protrusions 425 and 427 are engaged with the first uneven portions 435b and 437b, the angular rotation state of the holder 420 is maintained as it is.

Second check protrusions 432a and 433a are formed around the second shaft protrusions 432 and 433 of the first case 430, and are attached to the second mounting holes 445 and 447 of the second case 440. A state in which the second protrusions 432 and 433 of the first case 430 are fitted into the second mounting holes 445 and 447 of the second case 440, respectively, with the second concave-convex portions 445b and 447b formed. , the second check protrusions 432a and 433a of the second shaft protrusions 432 and 433 are engaged with the second uneven portions 445b and 447b, so that the angular rotation state of the first case 430 is maintained as it is.

The fluorescent acrylic plate 410, the reflector 412, and the light receiving element 450 for optical communication have the same structure as the fluorescent acrylic plate, the reflector, and the light receiving element for optical communication introduced in the fluorescent concentrator for optical communication according to the first embodiment of the present invention. same.

In the fluorescent concentrator for optical communication according to the fourth embodiment of the present invention configured as described above, the holder 420 has the first shaft protrusions 425 and 427 so that the front of the fluorescent acrylic plate 410 faces the direction in which the optical signal is input. The first arrangement angle (b) is adjusted around the first check protrusions 425a and 427a of the first shaft protrusions 425 and 427 and the first uneven portions 435b of the first mounting holes 435 and 437. , 437b), the adjustment state of the first arrangement angle (b) is maintained as it is.

In addition, the second arrangement angle c of the first case 430 is adjusted around the second shaft protrusions 432 and 433, and the second check protrusions 432a and 433a of the second shaft protrusions 432 and 433 ) and the second uneven portions 445b and 447b, the adjustment state of the second arrangement angle c is maintained.

In this way, the fluorescent concentrator for optical communication according to the fourth embodiment of the present invention is used as an antenna for optical communication, and can be adjusted so that the front of the fluorescent acrylic plate 410 faces the direction in which the optical signal is input, and the adjusted state remains as it is. There is a sustaining effect.

110: fluorescent acrylic plate 121, 125, 126, 127, 128: reflector
130: hole 140: light receiving element for optical communication

Claims (16)

In the fluorescence concentrator for optical communication,
A reflector 121 is disposed on the rear surface of the fluorescent acrylic plate 110, and reflectors 125, 126, 127, and 128 are disposed on the circumferential surface of the fluorescent acrylic plate 110, respectively, and the reflector disposed on either circumferential surface. It is characterized in that a hole 130 for emitting an optical signal is formed in the center of (125),
It further includes a holder 150 for mounting the fluorescent acrylic plate 110 to which the reflector 121; 125, 126, 127, 128 is mounted, and the rear reflector 121 and the peripheral reflector 125, 126 , 127, 128) are bonded to the inner and peripheral surfaces of the holder 150 by index matching liquid, and a cutout 152 is formed in the center of either side 251 of the frame frame, The hole 130 of the reflector 125 is exposed to the outside through the cutout 152, and a light receiving element 140 for optical communication for receiving an optical signal projected through the hole 130 is attached to the cutout 152. A fluorescence concentrator for optical communication, characterized in that mounted.
According to claim 1,
An optical signal projected through the hole 130 is provided to a light receiving element 140 for optical communication, and the light receiving element 140 for optical communication is an Avalanche Photo Diode (APD), and the hole 130 of the reflector ) A fluorescent concentrator for optical communication, characterized in that it is mounted in front and receives an optical signal.
According to claim 1,
The reflector 121 disposed on the rear surface of the fluorescent acrylic plate 110 has a network pattern formed on the reflective surface, and an optical signal incident on the front of the fluorescent acrylic plate 110 is directed to the circumferential surface by the network pattern. A fluorescence concentrator for optical communication, characterized in that it is reflective.
According to claim 1,
The reflectors (125, 126, 127, 128) are any one of a Lambertian-reflector, a specular-reflector, and a retro-reflector, or a mixture of two or more reflectors. Characterized in that Fluorescent concentrator for optical communication.
delete In the fluorescence concentrator for optical communication,
Reflectors 220 are attached to the rear and circumferential surfaces of the fluorescent acrylic plate 210, respectively, and a hole 230 for emitting an optical signal is formed in the center of the reflective plate disposed on either circumferential surface,
It is characterized in that the fluorescent acrylic plate 210 to which the reflector 220 is attached is mounted on the holder 250, and the holder 250 is mounted on the stand 260 to be able to adjust the arrangement angle,
In the holder 250, protrusions 253 and 255 are formed on both side portions 251b and 251c of the frame frame 251, respectively, and first check protrusions 253a and 255a are formed around the protrusions 253 and 255. ) is formed,
In the stand 260, the lower vertical pillar 263 of the support 262 is mounted on the base plate 261, and the horizontal part 264 of the support 262 formed in the shape of "└┘" on the lower vertical pillar 263 The center is connected, and mounting holes 266 and 268 are formed at the upper end of the left vertical part 265 and the upper end of the right vertical part 267 erected at both ends of the horizontal part 264, respectively, and the mounting holes 266, 268) is formed around the shaft protrusions 266b and 268b, and in a state where the protrusions 253 and 255 of the holder 250 are fitted into the mounting holes 266 and 268, respectively, the protrusions 253 and 255 The first check protrusions 253a and 255a of ) are engaged with the first uneven portions 266b and 268b.
According to claim 6,
In the holder 250, a cutout 252 is formed in the center of one surface 251a of the frame frame 251, and the hole 230 of the reflector 220 is exposed to the outside through the cutout 252. and a light-receiving element 240 for receiving an optical signal projected through the hole 230 is mounted on the cutout 252.
delete According to claim 6,
The stand 260 has a second check protrusion 263a formed around the lower end of the lower vertical pillar 263, and a second uneven portion 269b around the hole 269 formed in the center of the support plate 261. Formed, when the lower end of the lower vertical column 263 is inserted into the hole 269 of the support plate 261, the second check protrusion 263a is engaged with the second concave-convex portion 269b Fluorescence for optical communication, characterized in that concentrator.
In the fluorescence concentrator for optical communication,
Reflectors 312 are attached to the rear and circumferential surfaces of the fluorescent acrylic plate 310, respectively, and a hole 314 for emitting an optical signal is formed in the center of the reflector disposed on either circumferential surface, and the rear and circumferential surfaces The fluorescent acrylic plate 310 to which the reflector 312 is attached is mounted on the holder 320, the holder 320 is placed in the center hole 331 of the case 330, and the center of both sides of the holder 320. The protrusions 325 and 327 formed on the shaft are inserted into the mounting holes 335 and 337 formed in the center of the inner vertical portions 332 and 333 of the case 330, so that the holder 320 is centered on the protrusions 325 and 327. It is characterized in that the arrangement angle (a) is adjusted by
Check protrusions 325a and 327a are formed around the protrusions 325 and 327 of the holder 320, and uneven portions 335b and 337b are formed in the mounting holes 335 and 337 of the case 330. , In a state where the protrusions 325 and 327 of the holder 320 are fitted into the mounting holes 335 and 337 of the case 330, respectively, the protrusions 325a and 327a of the protrusions 325 and 327 are uneven (335b, 337b), the angular rotation state of the holder (320) is maintained as it is.
According to claim 10,
The holder 320 has a cutout 322 formed at the center of one surface 321a of the frame frame 321, and the hole 314 of the reflector 312 is exposed to the outside through the cutout 322. and a light-receiving element 340 for receiving an optical signal projected through the hole 314 is mounted on the cutout 322.
delete A reflector 412 is attached to the rear and circumferential surfaces of the fluorescent acrylic plate 410, respectively, and a hole 414 for emitting an optical signal is formed in the center of the reflector disposed on either circumferential surface, and the rear and circumferential surfaces The fluorescent acrylic plate 410 to which the reflector 412 is attached is mounted on the holder 420, the holder 420 is placed in the center hole 431 of the first case 430, the amount of the holder 420 The first shaft protrusions 425 and 427 formed in the center of the side portion are inserted into the first mounting holes 435 and 437 formed in the center of the inner vertical portion 432 and 433 of the first case 430, so that the holder 420 is The first arrangement angle (b) is adjusted around the shaft protrusions 425 and 427, the first case 430 is disposed in the center hole 441 of the second case 440, and the first case 430 ) The second shaft protrusions 432 and 433 formed at the center of the upper and lower surfaces of the second mounting hole 445 formed in the inner upper horizontal portion 442 and the inner lower horizontal portion 443 of the second case 440 , 447), the first case 430 is centered on the second shaft protrusions 432 and 433 so that the second disposition angle c is adjusted.
According to claim 13,
In the holder 420, a cutout 422 is formed at the center of one surface 421a of the frame frame 421, and the hole 414 of the reflector 412 is exposed to the outside through the cutout 422. and a light receiving element 450 for optical communication for receiving an optical signal projected through the hole 414 is mounted on the cutout 422.
According to claim 13,
First check protrusions 425a and 427a are formed around the first shaft protrusions 425 and 427 of the holder 420, and the first mounting holes 435 and 437 of the first case 430 have first check protrusions 425a and 427a. In a state where the protrusions 425 and 427 of the holder 420 are fitted into the first mounting holes 435 and 437 of the first case 430, respectively, the protrusions 425 and 427 of the holder 420 are formed with the uneven portions 435b and 437b. The first check protrusions 425a and 427a of the shaft protrusions 425 and 427 are engaged with the first uneven portions 435b and 437b, so that the angular rotation state of the holder 420 is maintained as it is. concentrator.
According to claim 13,
Second check protrusions 432a and 433a are formed around the second shaft protrusions 432 and 433 of the first case 430, and are attached to the second mounting holes 445 and 447 of the second case 440. A state in which the second protrusions 432 and 433 of the first case 430 are fitted into the second mounting holes 445 and 447 of the second case 440, respectively, with the second concave-convex portions 445b and 447b formed. In this, the second check protrusions 432a and 433a of the second shaft protrusions 432 and 433 are engaged with the second uneven portions 445b and 447b, so that the angular rotation state of the first case 430 is maintained as it is. Fluorescent concentrator for optical communication characterized by

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