Patent Application
20220218191
The present invention relates to a light emitting device, and a medical system, an electronic apparatus, and an inspection method using the light emitting device.
A method of observing lesions, called a fluorescence imaging method, has been attracting attention recently in the medical field. The fluorescence imaging method is a method of observing a lesion by administering a fluorescent drug that selectively binds to the lesion such as a tumor to a subject, exciting the fluorescent drug with a specific light, and detecting and imaging fluorescence emitted from the fluorescent drug by an image sensor. The fluorescence imaging method makes it possible to observe lesions that are difficult to observe visually.
As a typical fluorescence imaging method, a fluorescence imaging method (ICG fluorescence method) using indocyanine green (ICG) as a fluorescent drug is known. The ICG is excited by a near-infrared light (for example, fluorescence peak wavelength is 770 nm), which easily penetrates a living body, and emits a near-infrared light of a longer wavelength (for example, fluorescence peak wavelength is 810 nm). Therefore, by detecting the fluorescence emitted from the ICG, observation of a lesion inside the living body is possible. The ICG fluorescence method is a minimally invasive medical technology that achieves the observation of lesions inside the living body without damaging the living body.
The fluorescence imaging method, such as the ICG fluorescence method, uses at least a device that emits a near-infrared light. As an optoelectronic element emitting near-infrared fluorescence, Patent Literature 1 discloses an optoelectronic element that includes a semiconductor chip emitting a primary beam and a conversion material including Cr3+ ions and/or Ni2+ ions.
PTL1: Japanese Translation of PCT International Application Publication No. JP-T-2018-518046
As described above, to utilize a fluorescence imaging method, such as the ICG fluorescence method, at least a device for emitting near-infrared light is used. In contrast, to normally visually observe the state of a mucosal surface layer through an image projected by an image sensor for visible light or through a lens, it is preferable that visible light is also emitted. Therefore, if a device for simultaneously emitting visible light and near-infrared light is provided, it is possible to achieve both normal observation using visible light and special observation using near-infrared light.
However, when mixed light of visible light and near-infrared light is emitted, a light component of the visible light, which is closer to the near-infrared range, is easily detected by the near-infrared light image sensor. Therefore, a light component other than the near-infrared fluorescence emitted from, for example, a fluorescent drug, is also detected by the near-infrared light image sensor to generate noise, and it is difficult to observe the lesion with high contrast.
The present invention has been made in consideration of such an issue as described above. It is an object of the present invention to provide a light emitting device that emits near-infrared light and visible light to obtain a high-contrast observation result, and a medical system, an electronic apparatus, and an inspection method using the light emitting device.
In response to the above issue, a light emitting device according to a first aspect of the present invention includes: a light source configured to emit a primary light; a first wavelength converter including a first phosphor that absorbs the primary light and converts the primary light into a first wavelength-converted light having a wavelength longer than that of the primary light; and a second wavelength converter including a second phosphor that absorbs the primary light and converts the primary light into a second wavelength-converted light having a wavelength longer than that of the primary light. The first wavelength-converted light is a fluorescence having a light component over an entire wavelength range of 700 nm or more to 800 nm or less and having a peak where a fluorescence intensity shows a maximum value in a wavelength range of 700 nm or more, and the second wavelength-converted light is a fluorescence having a peak where a fluorescence intensity shows a maximum value in a wavelength range of 380 nm or more to less than 700 nm. The light emitting device emits a first output light including the first wavelength-converted light and a second output light including the second wavelength-converted light alternately in time.
A medical system according to a second aspect of the present invention includes the light emitting device according to the first aspect.
An electronic apparatus according to a third aspect of the present invention includes the light emitting device according to the first aspect.
An inspection method according to a fourth aspect of the present invention uses the light emitting device according to the first aspect.
A detailed description is given below of a light emitting device, and a medical system, an electronic apparatus, and an inspection method using the light emitting device according to a present embodiment. Note that dimensional ratios in the drawings are exaggerated for convenience of explanation, and are sometimes different from actual ratios.
[Light Emitting Device]
A light emitting device according to the present embodiment is described below with reference to
As illustrated in
The first wavelength-converted light 10 is a fluorescence having a light component over the entire wavelength range of 700 nm or more to 800 nm or less and having a peak where the fluorescence intensity shows a maximum value in a wavelength range of 700 nm or more. The second wavelength-converted light 11 is a fluorescence having a peak where the fluorescence intensity shows a maximum value in a wavelength range of 380 nm or more to less than 700 nm. The light emitting device 1 emits a first output light 12 including the first wavelength-converted light 10 and a second output light 13 including the second wavelength-converted light 11 alternately in time.
That is, when the primary light 3 emitted by the light source 2 enters the first wavelength converter 4, the first wavelength converter 4 emits the first wavelength-converted light 10 mainly including a near-infrared fluorescent component. In contrast, when the primary light 3 emitted by the light source 2 enters the second wavelength converter 7, the second wavelength converter 7 emits the second wavelength-converted light 11 mainly including a visible light component.
The near-infrared fluorescent component is excellent in living body permeability, has a wide fluorescence spectrum width, and excites, for example, a fluorescent drug used in a fluorescence imaging method, so that the, fluorescent drug emits a near-infrared fluorescence having a wavelength longer than that of the exciting near infrared. The near-infrared fluorescence emitted by the fluorescent drug is detected and imaged by a near-infrared light image sensor, and thus special observation is possible. In contrast, the visible fluorescent component emitted by the light emitting device 1 is highly visible and useful for normal visual observation of a diseased part of a living body.
The light emitting device 1 emits the first output light 12 including the first wavelength-converted light 10 and the second output light 13 including the second wavelength-converted light 11 alternately in time. Thus, the near-infrared fluorescence image sensor detects the near-infrared fluorescence component having a relatively high intensity ratio while the intensity of the noise component is relatively low. Therefore, the light emitting device 1 according to the present embodiment emits near-infrared light and visible light to obtain a high-contrast observation result by utilizing the time difference.
The light source 2 may be a single light source or may include at least two light sources as illustrated in
In the present embodiment, as illustrated in
As illustrated in
In the present embodiment, the primary light 3A and the primary light 3B are emitted alternately in time. That is, while the first light source 2A is turned on, the second light source 2B is turned off, and while the first light source 2A is turned off, the second light source 2B is turned on. Therefore, the light emitting device 1 emits the first output light 12 and the second output light 13 alternately in time.
Preferably, the primary light 3 is a laser light. The laser light is a high-output point light source with strong directivity, and thus it not only reduces the size of the optical system and the diameter of the light guiding part but also improves the coupling efficiency of the laser light to an optical fiber. Accordingly, the light emitting device 1 that facilitates high output is obtained. Preferably, the laser light is emitted by a semiconductor light emitting device from the viewpoint of miniaturization of the light emitting device 1.
Preferably, the spectrum of the light emitted by the light source 2 has a peak where the intensity shows a maximum value in a range of 400 nm or more to less than 500 nm. Also preferably, the spectrum of the light emitted by the light source 2 has a peak where the intensity shows a maximum value in a wavelength range of 420 nm or more to less than 480 nm, and the light emitted by the light source 2 is blue light. The spectrum of the light emitted by the light source 2 has a peak where the intensity shows a maximum value more preferably in a wavelength range of 430 nm or more to less than 480 nm, even more preferably in a wavelength range of 440 nm or more to less than 470 nm. Thus, the first phosphor 5 and the second phosphor 8 are excited with high efficiency, which enables the light emitting device 1 to emit high-output near-infrared light.
The light source 2 may include a red laser device. The light source 2 may include a blue laser device. Preferably, the red laser device is included in the first light source 2A that excites the first phosphor 5. The red laser device has a small energy difference from the near-infrared light component and a small energy loss associated with wavelength conversion, which is preferable in achieving high efficiency of the light emitting device 1. Preferably, the red laser device has a peak where the fluorescence intensity shows a maximum value in a wavelength range of 600 nm or more to less than 660 nm, particularly 610 nm or more to less than 660 nm. In contrast, a laser device with high efficiency and high output is easily available for the blue laser device, and thus the blue laser device is preferable in achieving high output of the light emitting device 1. Preferably, the light source 2 includes a blue laser device as an excitation source and emits blue laser light. Thus, the first phosphor 5 and the second phosphor 8 are excited with high efficiency and high output, which enables the light emitting device 1 to emit high-output near-infrared light.
Preferably, the light source 2 includes a solid-state light emitting device, and the above-described blue light is emitted by the solid-state light emitting device. In this way, a small-sized light emitting device with high reliability is used as a light emitting source of the above-described blue light, which provides a small-sized light emitting device 1 with high reliability.
The solid-state light emitting device is a light emitting device that emits the primary light 3. Any solid-state light emitting device is usable as long as it emits the primary light 3 with a high energy density. The solid-state light emitting device is preferably at least one of a laser device or a light-emitting diode (LED), more preferably a laser device. The light source 2 may be, for example, a surface emitting laser diode.
The rated light output of the solid-state light emitting device is preferably 1 W or more, more preferably 3 W or more. This enables the light source 2 to emit the primary light 3 with high output, and thus the light emitting device 1 that facilitates high output is obtained.
The upper limit of the rated light output is not limited, and the rated light output is increased by the light source 2 having a plurality of solid-state light emitting devices. However, for practical purposes, the rated light output is preferably less than 10 kW, more preferably less than 3 kW.
The light density of the primary light 3 is preferably more than 0.5 W/mm2, more preferably more than 3 W/mm2, still more preferably more than 10 W/mm2. The light density may exceed 30 W/mm2. In this way, the first phosphor 5 and the second phosphor 8 are photoexcited at high density, which enables the light emitting device 1 to emit a fluorescent component of high output.
Preferably, the correlated color temperature of a mixed light of the primary light 3 and the second wavelength-converted light 11 is 2500 K or more and less than 7000 K. The correlated color temperature is more preferably 2700 K or more and less than 5500 K, more preferably 2800 K or more and less than 3200 K or 4500 K or more and less than 5500 K. The output light with a correlated color temperature within the above-described range is a white output light, and a diseased part visible through an image display device or an optical device appears similar to the diseased part observed under natural light. Therefore, the light emitting device 1 is obtained that easily makes use of the medical experience of doctors, which is preferable for medical use.
Preferably, the second wavelength-converted light 11 has a light component over the entire wavelength range of 500 nm or more to less than 580 nm. Since the second wavelength-converted light 11 has such a light component, the light emitting device 1 effectively emits a fluorescent component advantageous for visual inspection. The second wavelength-converted light 11 may have a light component over the entire wavelength range of 500 nm or more to less than 600 nm.
The first wavelength-converted light 10 has a light component over the entire wavelength range of 700 nm or more to 800 nm or less. More preferably, the first wavelength-converted light 10 has a light component over the entire wavelength range of 750 nm or more to 800 nm or less. This enables the light emitting device 1 to emit a near-infrared excitation light that efficiently excites a drug, even when the drug has a near-infrared light absorption property that is likely to vary. Thus, the light emitting device 1 increases the amount of near-infrared light emitted by a fluorescent drug, or heat rays emitted by a photosensitive drug or active oxygen generated upon excitation of the photosensitive drug.
The first phosphor 5 is preferably activated with a transition metal ion, more preferably activated with Cr3+. This makes it easier to obtain a fluorescence with a broad fluorescence spectrum width and a light component over the entire wavelength range of 700 nm or more to 800 nm or less, as the first wavelength-converted light 10.
The first wavelength-converted light 10 is a fluorescence having a peak where the fluorescence intensity shows a maximum value in a wavelength range of 700 nm or more. Preferably, the first wavelength-converted light 10 has a peak where the fluorescence intensity shows a maximum value in a wavelength range of 710 nm or more. This enables the light emitting device 1 to emit a fluorescence including a large number of near-infrared light components with high living body permeability.
Preferably, the first wavelength-converted light 10 includes a fluorescence based on the electronic energy transition of Cr3+. Preferably, the fluorescence spectrum of the first wavelength-converted light 10 has a peak where the fluorescence intensity shows a maximum value in a wavelength range exceeding 720 nm. This enables the first phosphor 5 to emit a fluorescence in which a broad spectral component of a short afterglow property is more dominant than a linear spectral component of a long afterglow property. As a result, the light emitting device 1 emits a light including a large amount of the near-infrared component. The linear spectrum component is a fluorescence component based on the electron energy transition (spin-forbidden transition) of 2E→4A2(t23) of Cr3+ and has a peak where the fluorescence intensity shows a maximum value in a wavelength range of 680 nm to 720 nm. The broad spectral component is a fluorescence component based on the electron energy transition (spin-allowed transition) of 4T2(t22e)→4A2(t23) of Cr3+ and has a peak where the fluorescence intensity shows a maximum value in a wavelength range exceeding 720 nm.
The fluorescence spectrum of the first wavelength-converted light 10 may have a peak where the fluorescence intensity shows a maximum value in a wavelength range of more than 720 nm to 900 nm or less. The fluorescence spectrum of the first wavelength-converted light 10 more preferably has a peak where the fluorescence intensity shows a maximum value in a wavelength range exceeding 730 nm, further more preferably has a peak where the fluorescence intensity shows a maximum value in a wavelength range exceeding 750 nm.
The 1/10 afterglow time of the first wavelength-converted light 10 is preferably less than 1 ms, more preferably less than 300 μs, still more preferably less than 100 μs where the afterglow time is a short afterglow property. Thus, even when the light density of the excitation light for exciting the first phosphor 5 is high, the output of the first wavelength-converted light 10 hardly saturates. Thus, the light emitting device 1 capable of emitting a high output near-infrared light is obtained. Note that the 1/10 afterglow time means time -rim taken from the time when the maximum light emission intensity is shown to the time when the intensity becomes 1/10 of the maximum light emission intensity.
Preferably, the 1/10 afterglow time of the first wavelength-converted light 10 is longer than the 1/10 afterglow time of the second wavelength-converted light 11. Preferably, the 1/10 afterglow time of the first wavelength-converted light 10 is specifically 10 μs or more. Note that the 1/10 afterglow time of the first wavelength-converted light 10 activated with Cr3+ is longer than the 1/10 afterglow time of a short afterglow (less than 10 μs) fluorescence based on a parity-allowed transition of Ce3+, Eu2+, or the like. This is because the first wavelength-converted light 10 is a fluorescence based on the electron energy transition of the spin-allowed type of Cr3+, which has relatively long afterglow time.
Preferably, in the fluorescence spectrum of the first wavelength-converted light 10, the spectral width at an intensity of 80% of the maximum value of the fluorescence intensity is 20 nm or more and less than 80 nm. Thus, the main component of the first wavelength-converted light 10 becomes a broad spectrum component. Therefore, even when there is a variation in the wavelength dependence of the sensitivity of a fluorescent drug or photosensitive drug in a medical field using a fluorescence imaging method or photodynamic therapy (PDT method), the light emitting device 1 emits high output near-infrared light that enables these drugs to function sufficiently.
Preferably, in the fluorescence spectrum of the first wavelength-converted light 10, the ratio of the fluorescence intensity at a wavelength of 780 nm to the maximum fluorescence intensity exceeds 30%. The ratio of the fluorescence intensity at a wavelength of 780 nm to the maximum fluorescence intensity more preferably exceeds 60%, even more preferably exceeds 80%. This enables the first phosphor 5 to emit a fluorescence including a large amount of a fluorescent component of a near-infrared wavelength range (650 to 1000 nm) through which light easily penetrates the living body, which is called a “living body window”. Therefore, the above-described light emitting device 1 increases the light intensity of the near infrared that penetrates the living body.
Preferably, the fluorescence spectrum of the first wavelength-converted light 10 does not leave a trail of a linear spectral component derived from the electronic energy transition of Cr3+. That is, preferably, the first wavelength-converted light 10 has only a broad spectral component (short afterglow property) having a peak where the fluorescence intensity shows a maximum value in a wavelength range exceeding 720 nm. Thus, the first phosphor 5 does not include a long afterglow fluorescent component due to the spin-forbidden transition of Cr3+ but only includes a short afterglow fluorescent component due to the spin-allowed transition of Cr3+. Thus, even when the light density of the excitation light for exciting the first phosphor 5 is high, the output of the first wavelength-converted light 10 hardly saturates. Therefore, the light emitting device 1 of a point light source capable of emitting a near-infrared light of higher output is also obtained.
Preferably, the first phosphor 5 includes no activator other than Cr3+. This enables the light absorbed by the first phosphor 5 to be converted into only the fluorescence based on the electronic energy transition of Cr3+, which provides the light emitting device 1 with easy design of output light for maximizing the output ratio of the near-infrared fluorescent component.
Preferably, the first phosphor 5 includes two or more kinds of Cr3+-activated phosphors. This enables the output light component in at least the near-infrared wavelength range to be controlled, which provides the light emitting device 1 with easy adjustment of the spectral distribution in accordance with the application utilizing the near-infrared fluorescence component.
The first phosphor 5 is preferably an oxide-based phosphor, more preferably an oxide phosphor. The oxide-based phosphor means a phosphor including oxygen but not nitrogen or sulfur. The oxide-based phosphor may include at least one selected from the group consisting of an oxide, a complex oxide, and a compound including oxygen or halogen as an anion.
Since the oxide is stable in the atmosphere, even when the oxide phosphor generates heat due to high density photoexcitation by laser light, it is difficult for phosphor crystals to be altered by oxidation in the atmosphere, as occurs in nitride phosphors. Therefore, when all the phosphors in the first wavelength converter 4 are oxide phosphors, the light emitting device 1 that is highly reliable is obtained.
Preferably, the first phosphor 5 has a garnet crystal structure. Preferably, the first phosphor 5 is an oxide phosphor with a garnet crystal structure. Since a garnet phosphor is easily deformed in composition and provides a number of phosphor compounds, a crystal field around Cr3+ is easily adjusted, and the color tone of fluorescence based on the electronic energy transition of Cr3+ is easily controlled.
The phosphor with a garnet structure, especially the oxide, has a polyhedral particle shape close to a sphere and has excellent dispersibility of a phosphor particle group. Therefore, when the phosphor included in the first wavelength converter 4 has a garnet structure, the first wavelength converter 4 excellent in light transmittance is manufactured relatively easily, which enables higher output of the light emitting device 1. Further, since a phosphor with a garnet crystal structure has practical experience as a phosphor for LEDs, the light emitting device 1 that is a highly reliable is obtained when the first phosphor 5 has the garnet crystal structure.
The first phosphor 5 may include at least one phosphor selected from the group consisting of: Lu2CaMg2(SiO4)3:Cr3+, Y3Ga2(AlO4)3:Cr3+, Y3Ga2(GaO4)3:Cr3+, Gd3Ga2(AlO4)3:Cr3+, Gd3Ga2(GaO4)3:Cr3+, (Y,La)3Ga2(GaO4)3:Cr3+, (Gd,La)3Ga2(GaO4)3:Cr3+, Ca2LuZr2(AlO4)3:Cr3+, Ca2GdZr2(AlO4)3:Cr3+, Lu3SC2(GaO4)3:Cr3+, Y3Sc2(AlO4)3:Cr3+, Y3SC2(GaO4)3:Cr3+, Gd3Sc2(GaO4)3:Cr3+, La3Sc2(GaO4)3:Cr3+, Ca3Sc2(SiO4)3:Cr3+, Ca3Sc2(GeO4)3:Cr3+, BeAl2O4:Cr3+, LiAl5O8:Cr3+, LiGa5O8:Cr3+, Mg2SiO4:Cr3+, La3Ga5GeO14:Cr3+, and La3Ga5.5Nb0.5O14:Cr3+.
As described above, the first wavelength-converted light 10 has a near-infrared fluorescence component. This enables the light emitting device 1 to efficiently excite a fluorescent drug, such as ICG, or a photosensitive drug (which is also a fluorescent drug), such as phthalocyanine.
Preferably, the second phosphor 8 is activated with at least one of Ce3+ or Eu2+. This makes it easy to obtain the second wavelength-converted light 11 with a peak where the fluorescence intensity shows a maximum value in a wavelength range of 380 nm or more to less than 700 nm. Preferably, the second phosphor 8 is activated with Ce3+.
The second phosphor 8 may be at least one of an oxide-based phosphor, such as an oxide or a halogen oxide, or a nitride-based phosphor, such as a nitride or an oxynitride.
Preferably, the second phosphor 8 is a Ce3+-activated phosphor having a matrix of a compound with at least one, as a main component, selected from the compound group consisting of a garnet type crystal structure, a calcium ferrite type crystal structure, and a lanthanum silicon nitride (La3Si6N11) type crystal structure. Preferably, the second phosphor 8 is a Ce3+-activated phosphor having a matrix of at least one selected from the compound group consisting of a garnet type crystal structure, a calcium ferrite type crystal structure, and a lanthanum silicon nitride (La3Si6N11) type crystal structure. Using the above-described second phosphor 8 provides output light with a large amount of a light component from green to yellow.
Preferably, the second phosphor 8 is specifically a Ce3+-activated phosphor having a matrix of a compound with at least one, as a main component, selected from the group consisting of M3RE2(SiO4)3, RE3Al2(AlO4)3, MRE2O4, and RE3Si6Nii. Preferably, the second phosphor 8 is a Ce3+-activated phosphor having a matrix of at least one selected from the group consisting of M3RE2(SiO4)3, RE3Al2(AlO4)3, MRE2O4, and RE3Si6Ni . Preferably, the second phosphor 8 is a Ce3+-activated phosphor having a matrix of a solid solution having the above-described compound as an end component. Note that M is an alkaline earth metal, and RE is a rare earth element.
The above-described second phosphor 8 well absorbs light in a wavelength range of 430 nm or more to 480 nm or less and converts it to green to yellow light with a peak where the fluorescence intensity shows a maximum value in a wavelength range of 540 nm or more to less than 590 nm with high efficiency. Therefore, a visible light component is easily obtained by using such a phosphor as the second phosphor 8 with the light source 2 that emits cold color light in a wavelength range of 430 nm or more to 480 nm or less as the primary light 3.
At least the second wavelength converter 7 may further include a third phosphor that absorbs the primary light 3 and emits a third wavelength-converted light. Preferably, the third wavelength-converted light is included in the second output light 13, and the second output light 13 is a white output light. For example, when the primary light 3 is a blue light, such a white light is emitted by the light emitting device 1 by additive color mixing with this blue light.
Preferably, the first wavelength converter 4 includes an inorganic material. Here, the inorganic material means materials other than organic materials and includes ceramics and metals as a concept. When the first wavelength converter 4 includes an inorganic material, the first wavelength converter 4 has the heat conductivity higher than that of the wavelength converter including an organic material, such as a sealing resin, thereby facilitating the heat radiation design. Thus, the temperature rise of the first wavelength converter 4 is effectively prevented even when the phosphor is photoexcited with high density by the primary light 3 emitted from the light source 2. As a result, the temperature quenching of the phosphor in the first wavelength converter 4 is prevented, and thus higher output of light emission is possible. Accordingly, the heat dissipation of the first phosphor 5 is improved, and thus the decrease in output of the phosphor due to temperature quenching is prevented, and high output near-infrared light is emitted. For the same reason as for the first wavelength converter 4, preferably, the second wavelength converter 7 also includes an inorganic material.
Preferably, at least one of all of the first wavelength converter 4 or all of the second wavelength converter 7 is made of an inorganic material. As a result, the heat dissipation of the first phosphor 5 and/or the second phosphor 8 is improved, and thus the decrease in output of the phosphor due to temperature quenching is prevented, and the light emitting device 1 that emits a high output near-infrared fluorescence and/or visible light is obtained. Preferably, all of the first wavelength converter 4 and all of the second wavelength converter 7 are made of inorganic material.
At least one of the first phosphor 5 or the second phosphor 8 may be a ceramic. This increases the thermal conductivity of at least one of the first wavelength converter 4 or the second wavelength converter 7, which provides the light emitting device 1 with less heat generation and high output. Here, the ceramic means a sintered body in which particles are bonded to each other.
As illustrated in
Preferably, the first sealing material 6 is at least one of an organic material or an inorganic material, particularly at least one of a transparent (light transmitting) organic material or a transparent (light transmitting) inorganic material. Examples of the sealing material of the organic material include a transparent organic material, such as a silicone resin. Examples of the sealing material of the inorganic material include a transparent inorganic material, such as a low melting point glass. Preferably, the second sealing material 9 is the same as the first sealing material 6.
As described above, the first wavelength converter 4 preferably includes an inorganic material, and thus the first sealing material 6 preferably includes an inorganic material. Preferably, zinc oxide (ZnO) is used as the inorganic material. This further enhances the heat dissipation of the phosphor, which prevents the output of the phosphor from decreasing due to temperature quenching and provides the light emitting device 1 that emits high output near-infrared light. Preferably, the second sealing material 9 is the same as the first sealing material 6.
The first wavelength converter 4 may not use the first sealing material 6, and the second wavelength converter 7 may not use the second sealing material 9. In this case, the phosphor may be fixed to each other by using an organic or inorganic binder. The phosphor is fixable to each other by using the heating reaction of the phosphor. As the binder, a commonly used resin-based adhesive, ceramic fine particles, low melting point glass, or the like is usable. The first wavelength converter 4 that does not use the first sealing material 6, or the second wavelength converter 7 that does not use the second sealing material 9 is made thin, and thus it is suitably used for the light emitting device 1.
Next, the operation of the light emitting device 1 according to the present embodiment is described. As illustrated in
In this way, the first light source 2A and the second light source 2B repeatedly turn on and off alternately in time, which enables the light emitting device 1 to emit the first output light 12 and the second output light 13 alternately in time.
Next, a light emitting device 1 according to a second embodiment is described with reference to
As illustrated in
In the present embodiment, as in the first embodiment, a light source 2 includes a first light source 2A and a second light source 2B. The first light source 2A emits a primary light 3A, and the second light source 2B emits a primary light 3B. The primary light 3A for exciting a first phosphor 5 and the primary light 3B for exciting a second phosphor 8 have different optical axes. In the present embodiment, the primary light 3A and the primary light 3B are each consecutively and continuously emitted. That is, the primary light 3A and the primary light 3B are simultaneously emitted, and while the first light source 2A is on, the second light source 2B is also on.
The light emitting device 1 according to the present embodiment includes the chopper 14. The chopper 14 is disposed at a back 4B side of a first wavelength converter 4 and at a back 7B side of a second wavelength converter 7. That is, the first wavelength converter 4 is disposed between the chopper 14 and the first light source 2A, and the second wavelength converter 7 is disposed between the chopper 14 and the second light source 2B. As illustrated in
The chopper 14 includes a central portion 14A provided at the center of the disk, an outer frame portion 14B at the periphery of the disk, and shielding and non-shielding portions 14C and 14D between the central portion 14A and the outer frame portion 14B. First wavelength converters 4 and second wavelength converters 7 are alternately disposed in the circumferential direction. The chopper 14 has the shielding portion 14C provided on one side of the rotation axis C1, and the non-shielding portion 14D provided on the opposite side of the rotation axis C1 in a cross section through which the rotation axis C1 passes. The shielding portion 14C is formed of a plate-like member and is formed to shield the first output light 12 and the second output light 13. The non-shielding portion 14D is a space surrounded by the central portion 14A, the outer frame portion 14B, and the shielding portion 14C and is formed to allow the first output light 12 and the second output light 13 to pass through. By rotating the chopper 14 about the rotation axis C1, the first output light 12 and the second output light 13 are shielded by the shielding portions 14C or passed through the non-shielding portions 14D. The chopper 14 is formed so that the second output light 13 passes through the non-shielding portions 14D while the first output light 12 is shielded by the shielding portions 14C, and the first output light 12 passes through the non-shielding portions 14D while the second output light 13 is shielded by the shielding portions 14C. The central portion 14A, the outer frame portion 14B, and the shielding portions 14 C may be integrally formed from the same material.
Next, the operation of the light emitting device 1 according to the present embodiment is described. As illustrated in
Then, as the chopper 14 rotates, the first output light 12 emitted from the first wavelength converter 4 repeats being shielded by the shielding portion 14C and passing through the non-shielding portion 14D alternately in time. Similarly, the second output light 13 emitted from the second wavelength converter 7 repeats being shielded by the shielding portions 14C and passing through the non-shielding portions 14D alternately in time. While the first output light 12 is shielded by the shielding portions 14C, the second output light 13 passes through the non-shielding portions 14D, and while the second output light 13 is shielded by the shielding portions 14C, the first output light 12 passes through the non-shielding portions 14D. In this way, the first output light 12 and the second output light 13 are output alternately in time by the chopper 14, and thus the light emitting device 1 emits the first output light 12 and the second output light 13 alternately in time.
Next, a light emitting device 1 according to a third embodiment is described with reference to
As illustrated in
A first light source 2A is disposed closer to a second wavelength converter 7 than to the center of the cross sectional view of a first wavelength converter 4. A second light source 2B is disposed closer to the first wavelength converter 4 than to the center of the cross sectional view of the second wavelength converter 7. That is, the relative positions of the first light source 2A and the second light source 2B are disposed to be closer to each other than the relative positions of the center of the cross section of the first wavelength converter 4 and the center of the cross section of the second wavelength converter 7. Therefore, in the light emitting device 1 according to the present embodiment, the relative positions of the first light source 2A and the second light source 2B become closer to each other, which reduces the size of the light sources.
Therefore, the light emitting device 1 according to the present embodiment emits a first output light 12 and a second output light 13 alternately in time, as in the first embodiment.
Next, a light emitting device 1 according to a fourth embodiment is described with reference to
As illustrated in
As in the present embodiment, a primary light 3 for exciting a first phosphor 5 and a primary light 3 for exciting a second phosphor 8 may be emitted by the same light source 2. That is, the light emitting device 1 according to the present embodiment includes a single light source 2. Therefore, the number of light sources 2 is reduced to a necessary minimum, which is advantageous in terms of miniaturization and cost reduction of the light emitting device 1.
As in the present embodiment, the primary light 3 for exciting the first phosphor 5 and the primary light 3 for exciting the second phosphor 8 may have the same optical axis. This minimizes types and the number of light components, which is advantageous in terms of miniaturization and cost reduction of the light emitting device 1.
As in the present embodiment, by changing the positions of the first wavelength converter 4 and the second wavelength converter 7 with respect to the light source 2, the first output light 12 and the second output light 13 may be emitted alternately in time. This enables the primary light 3 for exciting the first phosphor 5 and the primary light 3 for exciting the second phosphor 8 to have the same optical axis. However, as is described later, even if the optical axes are different, by changing the positions of the first wavelength converter 4 and the second wavelength converter 7 with respect to the light source 2, the first output light 12 and the second output light 13 may be emitted alternately in time.
In the present embodiment, the light emitting device 1 includes a phosphor wheel 15 provided with first wavelength converters 4 and second wavelength converters 7. The phosphor wheel 15 is a disk having a central point and is provided to rotate about a rotation axis C2 passing through the central point. As illustrated in
The light source 2 is disposed radially outward from the rotation axis C2 and is provided to irradiate either the first wavelength converter 4 or the second wavelength converter 7. The direction of the optical axis of the primary light 3 is perpendicular to a front 4A of the first wavelength converter 4 or a front 7A of the second wavelength converter 7. The phosphor wheel 15 is provided so that the first wavelength converter 4 and the second wavelength converter 7 are irradiated with the primary light 3 alternately in time by rotating about the rotation axis C2. That is, the phosphor wheel 15 is formed so that the second wavelength converter 7 is not irradiated with the primary light 3 while the first wavelength converter 4 is irradiated with the primary light 3, and the first wavelength converter 4 is not irradiated with the primary light 3 while the second wavelength converter 7 is irradiated with the primary light 3. Note that a heat radiating substrate that transmits the primary light 3 may be provided on a light source 2 side of the phosphor wheel 15. This controls the temperature rise of the phosphor wheel 15 caused by the heat generation of the first phosphor 5 having large stokes loss, thus preventing luminous efficiency from decreasing due to temperature quenching of the phosphor and providing the light emitting device 1 that emits high output light. Examples of the material for forming the heat radiating substrate include sapphire.
Next, the operation of the light emitting device 1 according to the present embodiment is described. As illustrated in
The first wavelength converter 4 and the second wavelength converter 7 change their positions with respect to the light source 2 by the phosphor wheel 15 rotating about the rotation axis C2. Therefore, after the first wavelength converter 4 is irradiates with the primary light 3, the primary light 3 is emitted to the front 7A of the second wavelength converter 7, and the emitted primary light 3 passes through the second wavelength converter 7. Then, when the primary light 3 passes through the second wavelength converter 7, the second phosphor 8 included in the second wavelength converter 7 absorbs a part of the primary light 3 and emits a second wavelength-converted light 11. In this way, the first output light 12 including the primary light 3 and the first wavelength-converted light 10 is emitted from the back 4B of the first wavelength converter 4. Then, the second output light 13 including the primary light 3 and the second wavelength-converted light 11 is emitted from the back 7B of the second wavelength converter 7. As the phosphor wheel 15 rotates, the first wavelength converter 4 and the second wavelength converter 7 are irradiated with the primary light 3 alternately in time, which enables the light emitting device 1 to emit the first output light 12 and the second output light 13 alternately in time.
Next, a light emitting device 1 according to a fifth embodiment is described with reference to
As illustrated in
In the present embodiment, as illustrated in
Next, the operation of the light emitting device 1 according to the present embodiment is described. As illustrated in
Next, a light emitting device 1 according to a sixth embodiment is described with reference to
As illustrated in
As illustrated in
A reflection layer for reflecting the primary light 3, the first wavelength-converted light 10, and the second wavelength-converted light 11 may be provided at the opposite side of the phosphor wheel 15 from the light source 2. The reflective layer is not limited as long as it has a function of reflecting light and includes, for example, a resin including silver and/or titanium oxide. This enables the first wavelength-converted light 10 and the second wavelength-converted light 11 to be taken out from the front side more, which provides the light emitting device 1 that emits high output light. Further, the above-described heat radiation substrate may be provided at the back side of the phosphor wheel 15. This controls the temperature rise of the phosphor wheel 15 caused by the heat generation of the first phosphor 5 having large stokes loss, thus preventing luminous efficiency from decreasing due to temperature quenching of the phosphor and providing the light emitting device 1 that emits high output light.
Next, the operation of the light emitting device 1 according to the present embodiment is described. As illustrated in
As the phosphor wheel 15 rotates about the rotation axis C2, the first wavelength converter 4 and the second wavelength converter 7 change their positions with respect to the light source 2. Therefore, after the first wavelength converter 4 is irradiated with the primary light 3, the primary light 3 emitted by the light source 2 is emitted to the front 7A of the second wavelength converter 7. Most of the emitted primary light 3 enters the second wavelength converter 7 through the front 7A, and the remaining part is reflected by the surface of the second wavelength converter 7. In the second wavelength converter 7, the second phosphor 8 excited by the primary light 3 emits the second wavelength-converted light 11, and the second wavelength-converted light 11 is emitted from the front 7A. In this way, as the phosphor wheel 15 rotates, the first wavelength converter 4 and the second wavelength converter 7 emit the primary light 3 alternately in time, which enables the light emitting device 1 to emit the first output light 12 and the second output light 13 alternately in time.
Next, a light emitting device 1 according to a seventh embodiment is described with reference to
As illustrated in
In the present embodiment, as illustrated in
Next, the operation of the light emitting device 1 according to the present embodiment is described. As illustrated in
In the light emitting device 1 according to the present embodiment, the positions of the first wavelength converter 4 and the second wavelength converter 7 may be changed. That is, the primary light 3A may be emitted to the front 4A of the first wavelength converter 4, and the first wavelength-converted light 10 may be emitted from the front 4A of the first wavelength converter 4. The primary light 3B may be emitted to the front 7A of the second wavelength converter 7, and the second wavelength-converted light 11 may be emitted from the back 7B of the second wavelength converter 7.
Also in the present embodiment, by changing the positions of the first wavelength converter 4 and the second wavelength converter 7 with respect to the light source 2, the first output light 12 and the second output light 13 may be emitted alternately in time.
The light emitting device 1 according to the present embodiment has been described using the light emitting devices according to the first to seventh embodiments. The above-described light emitting device 1 may be used for medical purposes. That is, the light emitting device 1 may be a medical light emitting device. In other words, the light emitting device 1 may be a medical illumination device. Such a light emitting device 1 is advantageous in diagnosing disease state because it achieves the coexistence of normal observation and special observation as described above.
The light emitting device 1 may be used for optical coherence tomography (OCT) or the like. However, preferably, the light emitting device 1 is used for either a fluorescence imaging method or photodynamic therapy. The light emitting device 1 used in these methods is a light emitting device for a medical system using a drug, such as a fluorescent drug or a photosensitive drug. These methods are a promising medical technology with a wide range of applications and are highly practical. The light emitting device 1 illuminates the inside of the living body with a broad near-infrared high-output light through the “living body window” and makes the fluorescent drug or photosensitive drug taken into the living body fully functional, which is expected to have a large therapeutic effect.
The fluorescence imaging method is a method of observing a lesion by administering a fluorescent drug that selectively binds to the lesion, such as a tumor, to a subject, exciting the fluorescent drug with a specific light, and detecting and imaging fluorescence emitted from the fluorescent drug with an image sensor. The fluorescence imaging method makes it possible to observe lesions that are difficult to observe using only general illumination. As the fluorescent drug, a drug that absorbs excitation light in the near-infrared range, and emits fluorescence in the near-infrared range and at a wavelength longer than the excitation light is usable. Examples of the fluorescent drug used include at least one selected from the group consisting of indocyanine green (ICG), a phthalocyanine-based compound, a talaporfin sodium-based compound, and a dipicolylcyanine (DIPCY)-based compound.
The photodynamic therapy is a treatment method of administering a photosensitive drug that selectively binds to a target biological tissue to a subject and irradiating the photosensitive drug with near-infrared light. When the photosensitive drug is irradiated with the near-infrared light, the photosensitive drug generates active oxygen, which is usable to treat lesions, such as tumors or infections. Examples of the photosensitive drug used include at least one selected from the group consisting of a phthalocyanine-based compound, a talaporfin sodium-based compound, and a porfimer sodium-based compound.
The light emitting device 1 according to the present embodiment may be used as a light source for a sensing system or an illumination system for a sensing system. With the light emitting device 1, an orthodox light receiving element having light receiving sensitivity in the near-infrared wavelength range may be used to configure a high-sensitivity sensing system. This provides a light emitting device that facilitates miniaturization of the sensing system and broadening of the sensing range.
[Healthcare System]
Next, a medical system including the above-described light emitting device 1 is described. Specifically, as an example of the medical system, an endoscope 20 provided with the light emitting device 1 and an endoscope system 100 using the endoscope 20 are described with reference to
(Endoscope)
As illustrated in
The scope 110 is an elongated light guide member capable of guiding light from end to end and is inserted into the body when in use. The scope 110 includes an imaging window 110z at its tip. For the imaging window 110z, an optical material, such as optical glass or optical plastic, is used. The scope 110 includes an optical fiber for guiding light introduced from the light source connector 111 to the tip, and an optical fiber for transmitting an optical image that enters through the imaging window 110z.
The light source connector 111 introduces illumination light emitted to a diseased part and the like in the body from the light emitting device 1. In the present embodiment, the illumination light includes visible light and near-infrared light. The light introduced into the light source connector 111 is guided to the tip of the scope 110 through the optical fiber to be emitted to a diseased part and the like in the body from the imaging window 110z. As illustrated in
The mount adapter 112 is a member for mounting the scope 110 on the camera head 114. Various scopes 110 are detachably mountable on the mount adapter 112.
The relay lens 113 converges the optical image transmitted through the scope 110 on the imaging surface of the image sensor. The relay lens 113 may be moved in accordance with the operation amount of the operation switch 115 to perform focus adjustment and magnification adjustment.
The camera head 114 includes a color separation prism inside. The color separation prism separates the light converged by the relay lens 113 into four colors of R light (red light), G light (green light), B light (blue light), and IR light (near-infrared light). The color separation prism includes, for example, a light transmitting member, such as glass.
The camera head 114 further includes an image sensor as a detector inside. For example, four image sensors are provided, and each of the four image sensors converts an optical image formed on an imaging surface into an electric signal. The image sensor is not limited, but at least one of CCD (Charge Coupled Device) or CMOS (Complementary Metal Oxide Semiconductor) is usable. The four image sensors are dedicated sensors for receiving light of the IR component (near-infrared component), the R component (red component), the G component (green component), and the B component (blue component), respectively.
The camera head 114 may have a color filter inside instead of the color separation prism. The color filter is provided on the imaging surface of the image sensor. For example, four color filters are provided, and the four color filters receive the light converged by the relay lens 113 and selectively transmit R light (red light), G light (green light), B light (blue light), and IR light (near-infrared light), respectively.
Preferably, the color filter for selectively transmitting IR light includes a barrier film for cutting the reflection component of near-infrared light (IR light) included in the illumination light. This enables only the fluorescence composed of IR light emitted from a fluorescent drug, such as ICG, to form an image on the imaging surface of the image sensor for IR light. Therefore, the diseased part luminous with the fluorescent drug is easily observed clearly.
As illustrated in
In the endoscope 20 having such a configuration, light from a subject is guided to the relay lens 113 through the scope 110 and is further transmitted through the color separation prism in the camera head 114 to form images on the four image sensors.
As illustrated in
The CCU 21 includes at least an RGB signal processing unit, an IR signal processing unit, and an output unit. The CCU 21 executes a program stored in the internal or external memory of the CCU 21 to realize the respective functions of the RGB signal processing unit, the IR signal processing unit, and the output unit.
The RGB signal processing unit converts the R component, G component, and B component electrical signals from the image sensors into video signals that are displayable on the display device 22 and outputs the video signals to the output unit. The IR signal processing unit converts the IR component electrical signal from the image sensor into a video signal and outputs the video signal to the output unit.
The output unit outputs at least one of the video signals of respective RGB color components or the video signal of the IR component to the display device 22. For example, the output unit outputs video signals on the basis of either a simultaneous output mode or a superimposed output mode.
In the simultaneous output mode, the output unit simultaneously outputs the RGB image and the IR image on separate screens. The simultaneous output mode enables the diseased part to be observed by comparing the RGB image and the IR image on the separate screens. In the superimposed output mode, the output unit outputs a composite image in which the RGB image and the IR image are superimposed. The superimposed output mode enables the diseased part luminous with the ICG to be clearly observed, for example in the RGB image.
The display device 22 displays an image of an object, such as a diseased part, on a screen on the basis of video signals from the CCU 21. In the simultaneous output mode, the display device 22 divides the screen into multiple screens and displays the RGB image and the IR image side by side on each screen. In the superimposed output mode, the display device 22 displays a composite image in which an RGB image and an IR image are superimposed on each other on a single screen.
Next, functions of the endoscope 20 and the endoscope system 100 according to the present embodiment are described. When a subject is observed using the endoscope system 100, first, indocyanine green (ICG) as a fluorescent substance is administered to the subject. As a result, ICG accumulates at a site of lymph, tumor, or the like (diseased part).
Next, visible light and near-infrared light are introduced from the light emitting device 1 to the light source connector 111 through the transmission cable 111z. The light introduced into the light source connector 111 is guided to the tip side of the scope 110 and projected from the imaging window 110z to be emitted to the diseased part and the periphery of the diseased part. The light reflected from the diseased part and the like and the fluorescence emitted from the ICG are guided to the rear end side of the scope 110 through the imaging window 110z and the optical fiber, converged by the relay lens 113 to enter into the color separation prism inside the camera head 114.
In the color separation prism, among the incident light, the light of the IR component separated by the IR separation prism is imaged as an optical image of an infrared component by the IR light image sensor. The light of the R component separated by the red separation prism is imaged as an optical image of the red component by the R light image sensor. The light of the G component separated by the green separation prism is imaged as an optical image of the green component by the G light image sensor. The light of the B component separated by the blue separation prism is imaged as an optical image of the blue component by the B light image sensor.
The electrical signal of the IR component converted by the IR light image sensor is converted into a video signal by the IR signal processing unit in the CCU 21. The electric signals of the R component, G component, and B component converted by the RGB light image sensors are converted into respective video signals by the RGB signal processing unit in the CCU 21. The image signal of the IR component, and the image signals of the R component, G component, and B component in synchronization with each other are output to the display device 22.
When the simultaneous output mode is set in the CCU 21, the RGB image and the IR image are simultaneously displayed on two screens on the display device 22. When the superimposed output mode is set in the CCU 21, a composite image in which the RGB image and the IR image are superimposed is displayed on the display device 22.
As described above, the endoscope 20 according to the present embodiment includes the light emitting device 1. Therefore, by efficiently exciting the fluorescent drug to emit light using the endoscope 20, the diseased part is clearly observed.
Preferably, the endoscope 20 according to the present embodiment further includes a detector for detecting fluorescence emitted from a fluorescent drug that has absorbed the first wavelength-converted light 10. By providing the endoscope 20 with the detector for detecting fluorescence emitted from a fluorescent drug in addition to the light emitting device 1, the diseased part is specified only by the endoscope. This makes it possible to perform medical examination and treatment with less burden on the patient, since there is no need to open the abdomen wide to identify the diseased part as in the conventional method. This also enables the doctor using the endoscope 20 to accurately identify the diseased part, which improves the efficiency of treatment.
As described above, preferably, the medical system is used for either the fluorescence imaging method or photodynamic therapy. The medical system used in these methods is a promising medical technology with a wide range of applications and is highly practical. The medical system illuminates the inside of the living body with a broad near-infrared high-output light through the “living body window” and makes the fluorescent drug or photosensitive drug taken into the living body fully functional, which is expected to have a large therapeutic effect. Further, such a medical system uses the light emitting device 1 having a relatively simple configuration, which is advantageous in reducing the size and the cost.
[Electronic Apparatus]
Next, an electronic apparatus according to the present embodiment is described. The electronic apparatus according to the present embodiment includes a light emitting device 1. As described above, the light emitting device 1 is expected to have a large therapeutic effect, and it is easy to miniaturize the sensing system. Since the electronic apparatus according to the present embodiment uses the light emitting device 1, when it is used for a medical device or a sensing device, a large therapeutic effect, miniaturization of the sensing system, and the like are expected.
The electronic apparatus includes, for example, the light emitting device 1, and a light receiving element. The light receiving element is, for example, a sensor, such as an infrared sensor for detecting light in a near-infrared wavelength range. The electronic apparatus may be any of an information recognition device, a sorting device, a detection device, or an inspection device. As described above, these devices also facilitate miniaturization of the sensing system and broadening of the sensing range.
The information recognition device is, for example, a driver support system that recognizes the surrounding situation by detecting reflected components of emitted infrared rays.
The sorting device is, for example, a device that sorts an irradiated object into predetermined categories by using the difference in infrared light components between the irradiation light and reflected light reflected by the irradiated object.
The detection device is, for example, a device that detects a liquid. Examples of liquids include water, and flammable liquids that are prohibited from being transported in aircraft. Specifically, the detection device may be a device for detecting moisture adhering to glass, and moisture absorbed by an object, such as sponge or fine powder. The detection device may visualize the detected liquid. Specifically, the detection device may visualize the distribution information of the detected liquid.
The inspection device may be any of a medical inspection device, an agricultural and livestock inspection device, a fishery inspection device, or an industrial inspection device. These devices are useful for inspecting an inspection object in each industry.
The medical inspection device is, for example, an examination device that examines the health condition of a human or non-human animal. Non-human animals are, for example, domestic animals. The medical inspection device is, for example, a device used for a biological examination, such as a fundus examination or a blood oxygen saturation examination, and a device used for examination of an organ, such as a blood vessel or an organ. The medical inspection device may be a device for examining the inside of a living body or a device for examining the outside of a living body.
The agricultural and livestock inspection device is, for example, a device for inspecting agricultural and livestock products including agricultural products and livestock products. Agricultural products may be used as foods, for example, fruits and vegetables, or cereals, or as fuels, such as oils. Livestock products include, for example, meat and dairy products. The agricultural and livestock inspection device may be a device for non-destructively inspecting the inside or outside of the agricultural and livestock products. Examples of the agricultural and livestock inspection device includes a device for inspecting the sugar content of vegetables and fruits, a device for inspecting the acidity of vegetables and fruits, a device for inspecting the freshness of vegetables and fruits by the visualization of leaf veins, a device for inspecting the quality of vegetables and fruits by the visualization of wounds and internal defects, a device for inspecting the quality of meat, and a device for inspecting the quality of processed foods processed with milk, meat, or the like as raw materials.
The fishery inspection device is, for example, a device for inspecting the flesh quality of fish, such as tuna, or a device for inspecting the presence or absence of the contents in shells of shellfish.
The industrial inspection device is, for example, a foreign matter inspection device, a content inspection device, a condition inspection device, or a structure inspection device.
Examples of the foreign matter inspection device include a device for inspecting foreign matter in a liquid contained in a container, such as a beverage or a liquid medicine, a device for inspecting foreign matter in a packaging material, a device for inspecting foreign matter in a printed image, a device for inspecting foreign matter in a semiconductor or an electronic component, a device for inspecting foreign matter, such as residual bone in food, dust, or machine oil, a device for inspecting foreign matter in processed food in a container, and a device for inspecting foreign matter in medical devices, such as adhesive plasters, medical and pharmaceutical products, or quasi-drugs.
Examples of the content inspection device include a device for inspecting the content of a liquid contained in a container, such as a beverage or a liquid medicine, a device for inspecting the content of a processed food contained in a container, and a device for inspecting the content of asbestos in building materials.
Examples of the state inspection device include a device for inspecting packaging state of a packaging material, and a device for inspecting printing state of a packaging material.
Examples of the structure inspection device include an internal non-destructive inspection device and an external non-destructive inspection device for a composite member or a composite component, such as a resin product. A specific example of the resin product is, for example, a metal brush with a part of metal wire embedded in the resin, and the inspection device inspects the bonding state of the resin and the metal.
The electronic apparatus may use color night vision technology. Color night vision technology uses a correlation of reflection intensity between visible light and infrared rays to colorize an image by assigning infrared rays to RGB signals for each wavelength. According to the color night vision technology, a color image is obtained only by infrared rays, and it is particularly suitable for a security device.
As described above, the electronic apparatus includes the light emitting device 1. When the light emitting device 1 includes a power source, a light source 2, a first wavelength converter 4, and a second wavelength converter 7, it is not necessary to accommodate all of them in one housing. Therefore, the electronic apparatus according to the present embodiment provides a highly accurate and compact inspection method, or the like, with excellent operability.
[Inspection Method]
Next, an inspection method according to the present embodiment is described. As described above, the electronic apparatus including the light emitting device 1 is also usable as an inspection device. That is, the light emitting device 1 is usable in the inspection method according to the present embodiment. This provides a highly accurate and compact inspection method with excellent operability.
The light emitting device according to the present embodiment is described below in more detail with reference to examples, but the present embodiment is not limited thereto.
[Preparation of Phosphor]
(First Phosphor)
A first phosphor was synthesized using a preparation method utilizing a solid phase reaction. The Cr3+-activated phosphor used in the first phosphor is an oxide phosphor represented by a formula: (Gd0.75La0.25)3(Ga0.97Cr0.03)2Ga3O12. In synthesizing the first phosphor, the following compound powders were used as main raw materials.
Gadolinium oxide (Gd2O3): purity 3N, Wako Pure Chemical Corporation
Lanthanum oxide (La2O3): purity 3N, Wako Pure Chemical Corporation
Gallium oxide (Ga2O3): purity 4N, Wako Pure Chemical Corporation
Chromium oxide (Cr2O3): Purity 3N, Kojundo Chemical Laboratory Co.,Ltd.
First, the above-described raw materials were weighed to obtain a compound of a stoichiometric composition (Gd0.75La0.25)3(Ga0.97Cr0.03)2Ga3O12. The weighed raw materials were then put into a beaker containing pure water and stirred with a magnetic stirrer for 1 hour. Thus, a slurry-like mixed raw material of the pure water and raw materials was obtained. Then, the slurry-like mixed raw material was dried entirely using a dryer. The mixed raw material after drying was pulverized using a mortar and a pestle to obtain a calcined raw material.
The above-described calcined raw material was transferred to a small alumina crucible and calcined in air at 1400° C. to 1500° C. for 1 hour in a box-type electric furnace to obtain the phosphor of this example. The temperature rise and fall rate was set at 400° C./h. The body color of the obtained phosphor was light green.
(Second Phosphor)
A commercially available YAG phosphor (Y3Al2Al3O12:Ce3+) was obtained as a second phosphor. In consideration of the fluorescence peak wavelength and the like, the chemical composition of the YAG phosphor is estimated to be (Y0.97Ce0.03)3Al2Al3O12.
[Evaluation]
(Crystal Structure Analysis)
The crystal structures of the first phosphor and the second phosphor were evaluated using an X-ray diffraction apparatus (X'Pert PRO; manufactured by Spectris Co., Ltd., PANalytical).
As a result of evaluation, it was found that the first and second phosphors were mainly made from compounds with a garnet crystal structure, although the details are omitted. That is, both the first phosphor and the second phosphor were found to be garnet phosphors.
(Fluorescence Spectrum)
Next, wavelength converters including the first phosphor and the second phosphor were prepared, and the fluorescence properties were evaluated. Specifically, as for the first phosphor, the wavelength converter was produced by sintering the above-described calcined raw material, which was formed into a pellet shape using a hand press, in air at 1450° C. for 1 hour. As for the second phosphor, the wavelength converter was produced by calcining the phosphor formed into a pellet shape by hand press under a reducing atmosphere of 1600° C. to 1700° C. for 1 to 6 hours. Then, the obtained wavelength converters were excited by a laser light, and the fluorescence spectra of the fluorescence emitted from the wavelength converters were evaluated. At this time, the central wavelength of the laser light was set at 445 nm. The energy of the laser light was set to 3.87 W.
For example, a phosphor wheel separately coated with the first phosphor and the second phosphor is manufactured, and these phosphors are excited by a laser while the phosphor wheel is rotated. Then, from the above results, it is said that a light emitting device is realized in which near-infrared light emitted by the first phosphor and visible light emitted by the second phosphor are outputted alternately in time.
The entire contents of Japanese Patent Application No. 2019-082915 (filed Apr. 24, 2019) are incorporated herein by reference.
Although the contents of the present embodiment have been described in accordance with the examples above, it is obvious to those skilled in the art that the present embodiment is not limited to these descriptions, and that various modifications and improvements are possible.
In accordance with the present disclosure, there is provided a light emitting device that emits near-infrared light and visible light to obtain a high-contrast observation result, and a medical system, an electronic apparatus, and an inspection method using the light emitting device.
1 Light emitting device
2 Light source
3 Primary light
4 First wavelength converter
5 First phosphor
7 Second wavelength converter
8 Second phosphor
10 First wavelength-converted light
11 Second wavelength-converted light
12 First output light
13 Second output light
| Number | Date | Country | Kind |
|---|---|---|---|
| 2019-082915 | Apr 2019 | JP | national |
| Filing Document | Filing Date | Country | Kind |
|---|---|---|---|
| PCT/JP2020/006522 | 2/19/2020 | WO | 00 |
