MEDICAL COMPOSITE IMAGE SYSTEM FOR PHOTOGRAPHING DUAL CHANNEL NEAR INFRARED IMAGE
The present invention refers to dual channel near the displayed medical radio selective calling receiver relates to search, more particularly Image navigation surgery according to dual channel number Image under public affairs for near infrared fluorescent Image visible ray video view of the dual channel near infrared camera Image number under public affairs more specifically medical composite video system are disclosed. In the overcurrent or dog fault advances cancer surgery, the surgeon's eye only by arm location has been confirmed that the functional and at the interface with the normal tissue. The surgeon has taken before surgery such as CT or PET for analyzing various video program material draining performed live during surgical procedures but chamber number and the normal tissue at the interface with the accurate moving human organ cancer is used in identifying uninhabitable. In particular, when anatomical variation around inflammation or cancer, a cancer treatment or surgery or radiotherapy prior case, resulting in the interface with the normal tissue to identify cancer becomes more difficult. The, embodiment cancer surgery between position and its interface to be away at number and eliminating the need for liver imaging techniques can identify the embodiment. Surrounding tissue including cancer if not completely die number to avoid including cancer recurrence and sequelae occur around the upflow floatation die number current cancer die number surgical principle normal tissue are disclosed. However, recurrence is the possibility of excessive flexural rigidity around normal tissue is effected film number but, since the possibility of loss of normal organ function loss probability of recurrence unit adds all of the correlation function between and must, for this reason site can be accurately directed only number to techniques disclosed. Said require such as, fluorescent material a portion of the intact, etc. techniques not therefrom near infrared fluorescent acquires an Image number. Such an organic dye (organic dye) Inorganic quantum dots (QDs) on representative of fluorescent substance wherein for example, the materials can be used for clinical trial and a search for current monitoring lymph nodes and animal experiments disclosed. A unique Inorganic QDs with different optical properties of core (core) is configured as a sustained element (toxic element) without intending to be limited since door number still inside human body stability obtained clinically applied number 17a are used exclusively by animal experiments be drinkable. The fluorescent organic dye (organic dye) used primarily title, such that cyanine green (Indocyanine green: ICG) and methylene blue (Methylene blue) is representative clinically widely used etc.. One of the, leading cyanine green is near infrared wavelength band band has an effect on device to transmittance function in chemical analysis is better search depth deeper than an evaluation of methylene blue, fluorescent vascular agents, dye by timing recovery lymph nodes etc. and is connected to the search. Wherein, leading cyanine green (Emission light) has a wavelength 600 nm to 800 nm in the excitation light (Excitation light) and transparent and that is operable to stop operation in each exhibits a very wide spectral 780 nm to 810 nm. (Excitation light) essentially phosphor has the excitation light absorbed behind energy conversion through a emit light (Emission light). Figure 1 shows a transparent wavelength of excitation light transparent and also leading cyanine green (Excitation light) (Emission light) representing a distribution surface are disclosed. In Figure 1 the filar (Excitation light) which excitation light wavelength distribution, etc. one point chain line transparent (Emission light) wavelength distribution. The temperature, resulting in a structure or molecular distributed exactly when peripheral attenuation (Attenuation), fluorescent substances existing in the fluorescence signal reduced or fluorescing molecules is placed is independently selected, 780 nm wavelength absorbency of site higher in order to substrate. The, fluorescent Image representative of 810 nm 780 nm wavelength band when improved absorbent (Absorption) representative of the Image of the strength degree (Intensity) fixed to the substrate. When the above-mentioned falling on to two wavelengths, absorbent (Absorption) Image, emission (Emission) for simultaneously obtaining images Image processing scheme according to matching are same, and capable of improving the strength of and correlation factor of a fluorescent Image, Vasilis papers such as' reduce absorption correction (Journal of Biomedical Optics 14 (6), 064012, November/December 2009) real-time is intraoperative fluorescence imaging system using ' method in detecting the fluorescence signal was not amplifying the number. In each of two different wavelengths to said papers through two near-infrared camera acquires a number same into the near infrared Image matching method etc.. The ends, near-infrared band band quantum efficiency (Quantum Efficiency: QE) weak strength of fluorescent signals therefore enhanced high performance near infrared camera to decide, within said number two to use near-infrared camera alternately changed in papers of the system and, in addition white camera, i.e. until minimum 3 so that visible light camera to video splitting circuit, the cost for constructing the bumper powder disclosed. In addition, Korean Patent Registration Notification number 10 - 0952853 disclosure call a 'multiple infrared imaging system and imaging method' two different near infrared wavelength passing through rotation of the filter wheel mounted filter filter a contact spaced apart from the near infrared to near-infrared camera acquiring an Image method into a number different wavelengths etc.. I.e., Korean Patent Registration Notification disclosure techniques may comprise one of multiple wavelength near infrared camera to said entering into a dividing number etc. temporally introduction method. The temperature detector, said method due to the rotation of the filter wheel to Korean Patent Registration Notification disclosure time is obtained through a near-infrared camera is divided into near-infrared Image, Image processing tasks is unnecessary delay embodiment sacrificial temporal resolution so that the amount of computational resources caused door number flow tides. In addition, filter wheel rotation and Image of divisions of a near-infrared camera acquired by accurately synchronous it makes,, rotate filter is checked for dispensing a precise bevel gear of the motor due to the pin is number article size. , the present invention refers to said door such as number for establishing a communication point is provided which, by using a near-infrared camera sensor value near infrared fluorescent Image to dual channel acquires the simple optical structure design only dual channel dual-channel near infrared camera near infrared fluorescent Image acquire medical composite Image processing number under public affairs pin is used. The present invention is according to said, dual channel near the displayed medical composite video system, placed on the light paths number 1 visible light camera, optical path intersects the number 1 number 2 placed on the light paths near-infrared camera, visible light reflected from a near infrared optical path and each said number 1 for separating biological optical pathways and light splitting optics for directing said number 2; said light splitting optical system may identify the visible light reflected from a near infrared are separated from each other, said number 1 directs visible light optical path, the optical pathways for directing said number 2 passivation number 1 dichroic optical divider, said number 1 dichroic an optical splitter output from dividing number 1 and number 2 wavelength near infrared wavelength near the passivation according to wavelength, the wavelength near said number 1 and number 2 with the wavelength near said number 2 is reflected by the dichroic optical divider, said number 2 wavelength near infrared reflecting dichroic an optical splitter reflected from said number 1 and number 1 near-infrared camera directing said reflecting mirror, said number 2 dichroic splitter near said number 2 passing through the reflecting mirror reflecting said light source wavelength near-infrared camera and said number 1 and number 2 generally directing reflecting mirror, reflected by said number 1 reflecting mirrors directs said transparent layer and said number 1 passivation wavelength near-infrared camera, said number 2 is reflected by the reflecting mirror reflecting said splitter directing said number 2 wavelength near infrared and near-infrared camera; said said number 1 wavelength near infrared and near-infrared wavelength near-infrared camera images by said number 2 is an area in which the near-infrared camera division in terms of said reflecting mirror and said number 2 is calculated said number 1 being disposed in a closed 413,415 characterized dual channel near the displayed medical composite video is achieved by the system. Wherein, said number 1 wavelength near infrared and near-infrared wavelength 780 nm wavelength with one of either said number 2, while another one of the 810 nm wavelength near said number 1 wavelength near said number 2 and characterized as having a wavelength. In addition, dichroic optical divider disposed between said objective lens and said number 1 in vivo, said optical divider further comprising a near-infrared camera disposed between said magnified; said supporting surface between an objective lens and said ocular said number 1 in said Fourier plane light source wavelength near said number 1 (Fourier plane) between an objective lens and said ocular lens is positioned on the; said supporting surface between an objective lens and said ocular said number 2 in said Fourier plane between an objective lens and said ocular light source wavelength near said number 2 (Fourier plane) can be located on. And, said light splitting optical system is placed at the front end of said relayed Image size number influencing exerted by optical splitter driven according diaphragm additionally includes a number images formed holes; said diaphragm of said near-infrared wavelength light transmission hole number 1 through number Image is spatially divided the Image imaged and said near-infrared camera, said diaphragm of said light transmission hole near said wavelength number 2 through number Image is spatially divided state to other region near-infrared camera can be disclosed. And, said visible light camera and taken by visible light, near-infrared camera taken by said registering further comprises near infrared ray wavelength near infrared wavelength number 1 number 2 composite video number can be water level. Wherein, said composite video number the fisherman said visible light beam is imaged by a camera and supporting said visible light transmission area and visible ray video corresponding to light; said beam is imaged by a camera and a light transmission opening near said near infrared ray wavelength number 1 number 2 number 1 and number 2 respectively corresponding to near-infrared wavelength region near the extracted wavelength near-infrared wavelength region; said visible light region, said number 1 near-infrared wavelength region and the second wavelength region near said number 2 matches the disclosed. According to the present invention depending on the configuration such as said, a contact using a near-infrared camera acquires the dual channel near infrared fluorescent Image to acquire the dual channel design of simple optical structure only near infrared fluorescent Image a dual-channel near medical composite video system encoded ball number displayed. Figure 1 shows a transparent wavelength of excitation light transparent and also leading cyanine green (Excitation light) (Emission light) and representing a distribution plane, Figure 2 shows a dual channel near infrared camera also the present invention according to medical radio selective calling receiver of the indicating and, Figure 3 shows a dual channel near the sensitivity of medical radio selective calling receiver and also of Figure 2 and indicating examples of the light splitting optical system, Figure 4 shows a number 1 and number 2 of optical light splitting reflecting mirror reflection mirror of Figure 3 and the hole are disposed to account for principle, Figure 5 shows a dual channel near the displayed number medical radio selective calling receiver and also the present invention according to the block, Figure 7 shows a near-infrared camera dual channel 6 and also the present invention according to medical composite chemical vapor deposition device and also visible ray video, wavelength near infrared Image number 1, number 2 and wavelength near infrared Image to account for surface matching principle are disclosed. In the present invention according to in the embodiment hereinafter with reference to the attached drawing are detailed as follows. Figure 2 shows a dual channel near infrared camera also the present invention according to medical radio selective calling receiver (100) of the indicating are disclosed. As shown in fig. 2, the present invention according to medical radio selective calling receiver (100) visible light camera (110), a near-infrared camera (120) and light splitting optical system (130) having a predetermined wavelength. Wherein, the present invention according to medical radio selective calling receiver (100) includes taking into account the convenience of Korean procedure based on stand - alone clinical stability articulated arm (stand of realizing) equipment (50) form pair of substrates. Visible light camera (110) is arranged on the optical path number 1 incoming visible light along optical path number 1 is displayed visible ray video acquires a. A near-infrared camera (120) is arranged on the light path intersects the optical path number 1 number 2, number 2 acquires incoming near infrared ray images along the optical path. Wherein, the present invention according to a near-infrared camera (120) and one Image photographed by an infrared wavelength band near the wavelength number 1 number 2 Image spatially separated one frame Image photographing is set to near-infrared wavelength, the detailed description will be described later. A near infrared visible light reflected from the living body are separated from each other, the optical pathways to direct visible light number 1, number 2 passivation by directing an optical pathways, visible light camera (110) Image is visible light, near-infrared camera (120) is near infrared ray images a driving substrate. In hereinafter, with reference to the present invention according to also 3 light splitting optical system (130) for detailed example of the construction of the substrate. The present invention according to light splitting optical system (130) is number 1 dichroic an optical splitter (134a), number 2 dichroic an optical splitter (134b), number 1 reflecting mirrors (135a), number 2 reflecting mirrors (135b) and an optical splitter (136) having a predetermined wavelength. Number 1 dichroic an optical splitter (134a) and visible light reflected from passivation is biometric isolated each other. In the present invention number 1 dichroic an optical splitter (134a) is visible light reflecting layer, and a near infrared visible light transparent layer separating passivation in size to each other. Wherein, number 1 dichroic an optical splitter (134a) separated by a near infrared visible light optical path where it is directed in different directions and each optical path direction number 1 number 2, number 1 dichroic an optical splitter (134a) separated by visible light visible light camera (110) and imaged by. Number 2 dichroic an optical splitter (134b) is number 1 dichroic an optical splitter (134a) outputted from the near-infrared light source disposed thereon. And, number 2 dichroic an optical splitter (134b) is number 1 dichroic an optical splitter (134a) number 1 and number 2 outputted from the wavelength-dependent sensitivity wavelength near infrared wavelength near passivation dividing the substrate. Wherein, number 2 dichroic an optical splitter (134b) is repeatedly reflecting near infrared wavelength number 1, number 2 output wavelength transparent layer passivation in size to each other. Number 2 dichroic an optical splitter (134b) number 1 number 1 is outputted from the wavelength near infrared reflecting mirror (135a) reflected by the near-infrared camera (120) is directed to the other. And, number 2 dichroic an optical splitter (134b) number 1 number 2 output from the wavelength near infrared reflecting mirror (135a) reflected by the near-infrared camera (120) number 1 on reflecting mirror (135a) light source directed to other. An optical splitter (136) is number 1 reflecting mirrors (135a) number 1 and number 2 near a wavelength reflected by the reflecting mirror (135b) near a position where reflected by the wavelength number 2 disposed thereon. And, an optical splitter (136) is number 1 reflecting mirrors (135a) passivation number 1 wavelength reflected from the transparent layer and a near-infrared camera (120) directs, number 2 reflecting mirrors (135b) number 2 wavelength reflected from near infrared reflecting a near-infrared camera (120) toward the substrate. Wherein, number 1 reflecting mirrors (135a) number 2 on reflecting mirror (135b) reflection angle, as shown in also 3, number 2 dichroic an optical splitter (134b) number 1 and number 2 rotates the output from each wavelength near infrared wavelength near infrared (90 [...]) angle supplied from a parabolic mirror angle (reference filar of Figure 3) disposed thereon to (reference dashed lines of Figure 3). At this time, an optical splitter (136) is number 1 reflecting mirrors (135a) and number 2 reflecting mirrors (135b) has the vertically reflected when disposed thereon. Through, number 1 reflecting mirrors (135a) reflected at an angle from the light path when the near-infrared wavelength number 1 (reference filar of Figure 3) reflected at right angles at an angle offset from state (reference dashed lines of Figure 3) to an optical splitter (136) and the transmitting, a near-infrared camera (120) sensor (not shown) are radially internal Image of one of the area imaged. Similarly, number 2 reflecting mirrors (135b) angle from the angle of the reflected light path when such a near-infrared wavelength number 2 (filar of Figure 3 reference) angle offset from state (reference dashed lines of Figure 3) to an optical splitter (136) in which, depending on the relation of an incident angle light fiber senser near-infrared camera (120) state offset from the focal position of a near-infrared camera (120) are radially Image sensor to the other of the area imaged. Through, one near-infrared camera (120) of the number 1 and number 2 Image sensor wavelength near infrared wavelength near spatially change the imaging so that, one near-infrared camera (120) each other by using differing wavelengths of two near infrared fluorescent Image simultaneously in accordance with the photographing. For example, number 1 and number 2 wavelength 780 nm in wavelength near green onion symptoms near one constitutes, number 1 and number 2 while another one of the 810 nm in wavelength near infrared wavelength near infrared wavelength packs the recognized, as shown in fig. 1, two relief cyanine green wavelength properties both subdivided and the near infrared fluorescent Image, more specifically two visible ray video and near infrared view of the Image, i.e. cancer tissue and a normal tissue more specifically equal to or higher than the boundary matching etched. Again with reference to the SFC also 3, number 1 dichroic an optical splitter (134a) on biological between objective lens (131) is arranged, an optical splitter (136) on a near-infrared camera (120) between the ocular lens (133) can be arranged. Wherein, objective lens (131) is the present invention according to medical radio selective calling receiver (100) is applied as shown in open surgery also be the case 2, light splitting optical system (130) and an entrance face side (141) is installed on , the present invention according to medical radio selective calling receiver (100) if applied to a laparoscopic surgery or endoscope inserted endoscope such as human shear (142) can be installed. At this time, number 1 reflecting mirrors (135a) is objective lens (131) on ocular (133) lens between the light source wavelength near number 1 (131) on ocular (133) on the Fourier plane located on the optical path between the wavelength near number 1 (Fourier plane) can be. Similarly, number 2 reflecting mirrors (135b) is objective lens (131) on ocular (133) lens between the light source wavelength near number 2 (131) on ocular (133) on the Fourier plane located on the optical path between the wavelength near number 2 (Fourier plane) can be. With reference to the SFC also 4, two lenses (L1, L2) between, each lens focus distance (L1, L2) is not space 4f system is provided to use optical structures, the lens (L1, L2) in two between the two lens (L1, L2) which meet at one focal point of the Fourier plane (Fourier plane) is combined with a load. Wherein, number 1 reflecting mirrors (135a) number 2 on reflecting mirror (135b) each objective lens (131) on ocular (133) on the light path between the Fourier plane (Fourier plane) occupied by, a change in reflection angle only Image shift (Shift) components, angle variation according to generate distortion in Image itself not to be coated. The, Image number 1 number 2 wavelength near infrared wavelength near matching of X-ray Image, Image distortion according to the infrared ray molded with acquiring door number is equal to that the occur. A visible light camera is located front of the magnified american opinion name reference number 132 of Figure 3 are disclosed. Figure 5 shows a near-infrared camera also the present invention according to dual channel medical radio selective calling receiver (100) of a block number are disclosed. 5 also with reference to the described, the present invention according to medical radio selective calling receiver (100) complex number control unit (210) can be a. Composite video number control unit (210) comprises a light source unit (220) and to reflect the visible light from a near infrared is number, visible light camera (110) the picked-up Image by visible light, near-infrared camera (120) of the frame number 1 number 2 wavelength near infrared wavelength near the picked-up by Image and, composite video is defined. Wherein, the present invention according to medical radio selective calling receiver (100) is, as shown in fig. 3, a diaphragm Image number (160) can be a. Image number diaphragm (160) a light division optical system (130) placed at the front end of which, incident light reflected from the living body, i.e. Image sizes relayed a number-transmission hole (161) formed therein. In the present invention light transmission hole (161) as shown in the auditory canal 3, having a rectangular shape in size to each other. Such configuration, a diaphragm Image number (160) light transmissive hole (161) which pass through the near-infrared wavelength number 1 is a near-infrared camera (120) the Image imaged and functionally partitioned space, a diaphragm Image number (160) light transmissive hole (161) which pass through the near-infrared wavelength number 2 is a near-infrared camera (120) spatially divided state to other region to one near-infrared camera (120) in accordance with the photographing simultaneously two near infrared Image. Also the present invention according to Figure 7 shows a near-infrared camera dual channel 6 and also medical radio selective calling receiver (100) visible ray video in, wavelength near infrared Image number 1, number 2 and matching the drawing to explain the principle wavelength near infrared Image, a diaphragm 3 also shown in Image number (160) sensed by servomechanism to account for surface are disclosed. 7 also 6 and also with reference to the described, particular tissue of interest (ROI) in vivo when under adjusting boil Image, a diaphragm Image number (160) light transmissive hole (161) (SA) located by adaptive blocking regions other than specific organizations (ROI) of the center of the reaction chamber arranged for positioning in the entire Image. The side into a camera, as shown in (a) of Figure 6, visible light camera (110) in the case of visible ray video captured by, light transmission hole (161) are series-positioned with the specific organizations which pass through the center, blocking a black subspace information with each other. While, a near-infrared camera (120) in the case of, as shown in (b) of Figure 6, number 1 reflecting mirrors (135a) number 1 by a captured Image in a left shifted state with the input reference to near-infrared wavelength, in this case number 1 reflecting mirrors (135a) reflection angle of Figure 6 (b) as shown in the specific organizations (ROI), a near-infrared camera (120) situated on a left side of the full-area dividing replaced with controls, such as form of Figure 6 (b) photographing with each other. At this time, near-infrared wavelength region than the number of Image number 1 specific organizations (ROI) diaphragm (160) by a near-infrared camera (120) is blocked (SA) cut-off region incident to a black subspace information with each other. Similarly, number 2 reflecting mirrors (135b) number 2 by near-infrared wavelength and matched with the right shifted state based on a captured Image, in this case number 2 reflecting mirrors (135b) reflection angle (c) of Figure 6 as shown in the specific organizations (ROI), a near-infrared camera (120) a wavelength of placed to the right side. At this time, near-infrared wavelength region than the number of Image number 2 specific organizations (ROI) diaphragm (160) by a near-infrared camera (120) is blocked (SA) cut-off region incident to a black subspace information with each other. I.e., (b) as shown in (c) of Figure 6 on, near the number 1 and number 2 number 1 wavelength near infrared wavelength images simultaneously reflecting mirror (135a) and number 2 reflecting mirrors (135b) when shift by, number 1 wavelength near infrared images a near-infrared camera (120) near-infrared wavelength region of number 2 (and vice versa to relate to) extracting a low voltage can be, 7 also shown in accordance with the acquisition of X-ray Image such as near-infrared. Wherein, composite video number control unit (210) includes a visible ray video corresponding extracts only an area, near left only a simpler winding number Image's health by matching etched composite is equal to or higher. Although in the embodiment of the present invention are but some the illustrated and described, the present invention is provided to if one skilled with usual knowledge in the embodiment of the present invention may be out of the way or mental principle without the modifying can understand them are disclosed. Of the invention as defined by appended claim range and will evenly. 100: medical radio selective calling receiver 110: visible light camera 120: a near-infrared camera 130: light splitting optical system 131: objective lens 132,133: ocular 134a: number 1 dichroic an optical splitter 134b: number 2 dichroic an optical splitter 135a: number 1 reflecting mirrors 135b: number 2 reflecting mirrors 136: an optical splitter 150: stand - alone equipment 160: diaphragm 161 Image number: light transmission hole 210: composite video number control unit 220: light source unit The present invention relates to a medical composite image system for photographing a dual channel near infrared image. The system comprises: a visible camera arranged on a first optical path; a near infrared camera arranged on a second optical path intersecting with the first optical path; and a light division optical system for separating visible light and near infrared light reflected from a body, and enabling each of the visible light and the near infrared light to face the first and second optical paths. COPYRIGHT KIPO 2017 Dual channel near the displayed medical composite video system, placed on the light paths number 1 visible light camera, optical path intersects the number 1 number 2 placed on the light paths near-infrared camera, visible light reflected from a near infrared optical path and each said number 1 for separating biological optical pathways and light splitting optics for directing said number 2; said optical splitter optical total organism visible light reflected from a near infrared are separated from each other, said number 1 directs visible light optical path, the optical pathways for directing said number 2 passivation number 1 dichroic optical divider, said number 1 dichroic an optical splitter output from dividing number 1 and number 2 wavelength near infrared wavelength near the passivation according to wavelength, the wavelength near said number 1 and number 2 with the wavelength near said number 2 is reflected by the dichroic optical divider, said number 2 wavelength near infrared reflecting dichroic an optical splitter reflected from said number 1 and number 1 near-infrared camera directing said reflecting mirror, said number 2 wavelength near infrared reflecting dichroic splitter 9990001 727999 passing through the near-infrared camera and said reflecting mirror for directing said number 1 and number 2 on the light path between the reflecting mirror, reflected by said number 1 reflecting mirrors directs said transparent layer and said number 1 passivation wavelength near-infrared camera, said number 2 is reflected by the reflecting mirror reflecting said splitter directing said number 2 wavelength near infrared and near-infrared camera; said said number 1 wavelength near infrared and near-infrared wavelength near-infrared camera images by said number 2 is an area in which the near-infrared camera division in terms of said reflecting mirror and said number 2 is calculated said number 1 being disposed in a closed 413,415 characterized dual channel near the displayed medical radio selective calling receiver. According to Claim 1, said number 1 wavelength 780 nm wavelength near-infrared and near-infrared wavelength with one of either said number 2, while another one of the 810 nm wavelength band and said number 2 wavelength near infrared wavelength near said number 1 characterized in that the displayed dual channel near medical radio selective calling receiver. According to Claim 1, dichroic optical divider disposed between said objective lens and said number 1 in vivo, said optical divider further comprising a near-infrared camera disposed between said magnified; said supporting surface between an objective lens and said ocular said number 1 in said Fourier plane light source wavelength near said number 1 (Fourier plane) between an objective lens and said ocular lens is positioned on the; said supporting surface between an objective lens and said ocular said number 2 in said Fourier plane between an objective lens and said ocular light source wavelength near said number 2 (Fourier plane) characterized by near-infrared camera located on dual channel medical radio selective calling receiver. According to Claim 1, said light splitting optical system is placed at the front end of said relayed Image size number influencing exerted by optical splitter driven according diaphragm additionally includes a number images formed holes; said diaphragm of said near-infrared wavelength light transmission hole number 1 through number Image is spatially divided the Image imaged and said near-infrared camera, said diaphragm of said light transmission hole near said wavelength number 2 through number Image is imaged region characterized curve near-infrared camera spatially divided dual channel near the displayed medical radio selective calling receiver. According to Claim 4, visible light and visible light taken by said camera, said camera taken by near infrared ray wavelength near infrared wavelength near number 1 number 2 characterized further including dual channel control section number registering composite video displayed near medical radio selective calling receiver. According to Claim 5, said visible light beam is imaged by a camera and said composite video number a fisherman said visible light transmission opening area and visible ray video corresponding to light; said beam is imaged by a camera and a light transmission opening near said near infrared ray wavelength number 1 number 2 number 1 and number 2 respectively corresponding to near-infrared wavelength region near the extracted wavelength near-infrared wavelength region; said visible light region, said number 1 near-infrared wavelength region and the second region characterized by dual channel near said number 2 wavelength near matching the displayed medical radio selective calling receiver.
