This application is a national phase entry of PCT Application No. PCT/JP2019/033063, filed on Aug. 23, 2019, which application is hereby incorporated herein by reference.
The present invention relates to a wavelength checker, and more specifically, to a wavelength checker that performs, for example, confirmation of signal light in opening and failure isolation investigation of a PON system.
In an access-type passive optical network (PON) system of an optical communication system, a plurality of light beams having relatively distant wavelengths such as a wavelength of 1.3 μm and a wavelength ranging from 1.5 to 1.6 μm may be used at the same time.
According to NPL 1, in a GE-PON (G-PON) system that has already been introduced, a wavelength ranging from 1260 nm to 1360 nm (only a regular band is described in G-PON) is used as a signal from a user to a station (an uplink signal). Further, in a G-PON system, a wavelength ranging from 1480 nm to 1500 nm is used as a signal from a station to a user (a downlink signal), and a wavelength ranging from 1550 nm to 1560 nm is used as a downlink video signal.
Similarly, in a 10G-EPON (XG-PON) system, which is scheduled to be introduced in the future, a wavelength of 1.3 μm and a wavelength ranging from 1.5 to 1.6 μm are used. In an NG-PON2 system, which has been standardized recently, a wavelength ranging from 1524 nm to 1544 nm (a wide band) is used for an uplink signal, a wavelength ranging from 1596 nm to 1603 nm is used for a downlink signal, and a wavelength ranging from 1550 nm to 1560 nm is used for a downlink video signal. Description of an optional point to point wavelength division multiplex (PtP WDM) overlay is omitted. In this system, wavelength multiplexing is performed, unlike GE-PON (G-PON) and 10G-EPON (XG-PON). The wavelength allocation is illustrated in
Incidentally, in a PON system such as GE-PON, optical power is confirmed in an opening test. In the future, more various wavelengths will be used in a transition from GE-PON to 10G-EPON. In a test in such a situation, when a wavelength can be confirmed, a type of signal can be discriminated, failure can be easily isolated, and work efficiency is likely to be improved.
Incidentally, examples of means for measuring a wavelength include an optical spectrum analyzer. However, because the optical spectrum analyzer includes a movable part for allowing a detector to detect diffracted light obtained through movement of a diffraction grating, a device is large and heavy, and thus is poor in portability. Further, there is also a drawback that a power supply for 100 V is generally required. Thus, in the related art, there is a problem that it is not possible to easily perform, for example, confirmation as to whether signal light is coming in opening and failure isolation investigation of a PON system.
Embodiments of the present invention have been made in order to solve the above problem, and an object of embodiments of the present invention is to easily perform confirmation as to whether there is signal light in opening, failure isolation investigation, or the like of a PON system.
A wavelength checker according to embodiments of the present invention is a wavelength checker including an optical waveguide chip and an optical conversion unit, the optical conversion unit being composed of a conversion material that converts near-infrared light into visible light, in which the optical waveguide chip on a side connected to an optical fiber includes an arrayed waveguide grating and is mounted on a main substrate, a light emitting-side end surface of the optical waveguide chip on a side from which light is output to an external space is a reflection surface inclined to face the main substrate, and the optical conversion unit is provided at a location, on the optical waveguide chip, from which light reflected on the light emitting-side end surface is output to the external space.
As described above, according to embodiments of the present invention, the light emitting-side end surface of the optical waveguide chip located on the side from which light is output to the external space is a reflection surface inclined so as to face the main substrate, and is disposed at a portion from which light reflected at the light emitting-side end surface is output to the external space, so that confirmation as to whether there is signal light in opening, failure isolation investigation, or the like of a PON system can be easily performed.
Hereinafter, a wavelength checker according to embodiments of the present invention will be described.
First, a wavelength checker according to a first embodiment of the present invention will be described with reference to
The wavelength checker includes an optical waveguide chip 101. A known arrayed waveguide grating is formed on the optical waveguide chip 1o1 (see Reference 3). The arrayed waveguide grating includes a first arrayed waveguide 103, a first input-side slab waveguide 104, a first output-side slab waveguide 105, a first input waveguide 106, and a first output waveguide 107. In
The first arrayed waveguide 103 includes a plurality of waveguides having a constant optical path length difference. In the first arrayed waveguide 103, the optical path length difference between two adjacent waveguides is constant. The first input-side slab waveguide 104 is connected to an optical input end of the first arrayed waveguide 103. The first output-side slab waveguide 105 is connected to an optical output end of the first arrayed waveguide 103. The first input waveguide 106 is connected to an input side of the first input-side slab waveguide 104. A plurality of the first output waveguides 107 are provided and connected to an output side of the first output-side slab waveguide 105.
Furthermore, the wavelength checker includes the optical conversion unit 102 composed of a conversion material that converts infrared light to visible light. The optical conversion unit 102 is disposed to receive emitted light that is guided through the first output waveguides 107, reflected at a light emitting-side end surface 108, and emitted, on the output side (side from which light is output to an external space) of the plurality of first output waveguides 107 of the optical waveguide chip 101. The light emitting-side end surface 108 is a reflection surface that is inclined so as to face the main substrate 151.
For example, the light emitting-side end surface 108 can be used as a reflection surface (mirror) by forming a reflective film made of a dielectric multilayer film, a metal film such as an Al film, or the like on the light emitting-side end surface 108 by vapor deposition or the like. In addition, even if the reflective film is not formed, due to a refractive index difference between the light emitting-side end surface 108 composed of quartz glass or the like and air, an interface between the light emitting-side end surface and the air can be used as a reflection surface. In particular, when an angle of the light emitting-side end surface 108 with respect to a waveguide direction of light guided through the optical waveguide chip 101 satisfies a total reflection condition, it is possible to suppress leakage of light to the external space from the light emitting-side end surface 108.
The optical conversion unit 102 is formed to extend in a direction in which the plurality of first output waveguides 107 are aligned. The optical conversion unit 102 extends from one end side to the other end side of the alignment of the plurality of first output waveguides 107, for example.
The conversion material is, for example, a phosphor or fluorescent substance that converts near-infrared light to visible light. The conversion material is mixed with, for example, a thermosetting silicone resin, and the resultant mixture is heated and cured to form the optical conversion unit 102. Instead of the silicone resin, a polymer resin or an optical adhesive may be used. Alternatively, for the conversion material, for example, a phosphor made by “Lumitek International, Inc.” can be used. As an example of the phosphor, a type of phosphor to which electronic trapping is applied retains optical energy by being irradiated with sunlight or room light in advance, and then emits the retained optical energy as visible light by stimulation of irradiation with near-infrared rays. For example, there is a phosphor having a sensitivity ranging from 700 nm to 1700 nm.
According to the wavelength checker of the first embodiment, when near-infrared light that is demultiplexed for each wavelength by the arrayed waveguide grating, guided through the first output waveguides 107, reflected on and emitted from the light emitting-side end surface 108 reaches the optical conversion unit 102, visible light is generated. The generated visible light spreads isotropically, not limited to an incident direction of the near-infrared light that is guided through the first output waveguides 107 and reflected on the light emitting-side end surface 108, and can be viewed from various directions. In addition, the visible light is generated from a location where the near-infrared light reflected on the light emitting-side end surface 108 has reached, and thus it is possible to identify a first output waveguide 107 through which the near-infrared light has been guided, from the location where the visible light has been generated. Because a wavelength of the near-infrared light that is demultiplexed in and guided through each of the first output waveguides 107 is known, it is possible to confirm the wavelength by observing a location where the visible light has been generated (is visible).
Here, as illustrated in
Further, as illustrated in
As illustrated in
Here, the arrayed waveguide grating will be described in more detail. Hereinafter, a case in which the first arrayed waveguide 103 includes eight waveguides and eight first output waveguides 107 are provided will be described as an example (
First, the multiplexed light input to the first input waveguide 106 is diffracted and spread by the first input-side slab waveguide 104, and the light is coupled to the respective waveguides of the first arrayed waveguide 103 and guided. In the first arrayed waveguide 103, an optical path length is long on the upper side of a paper surface of
In a commonly used arrayed waveguide grating, an arrayed waveguide 501 is bent at one place like an arc in a plan view, as illustrated in
As an operating principle, the input light is diffracted and spread by the input-side slab waveguide 502, and the light is coupled to each of the M arrayed waveguides 501 and guided. In the M arrayed waveguides 501, an optical path length is long on the outer side and is gradually shortened by an equal optical path length difference toward the inner side. An output end of each of the M arrayed waveguides 501 has a phase difference along from the waveguide on the outer side to the waveguide on the inner side. Thus, when the light is incident on the output-side slab waveguide 503, an inclination of a fan-shaped equiphase surface caused by a shape of the output-side slab waveguide 503 in a plan view changes depending on the wavelength, and, for each wavelength, the light is condensed to each of the N output waveguides 505. Therefore, wavelength multiplexed light can be branched for each wavelength.
On the other hand, in the arrayed waveguide grating according to the embodiment, the first arrayed waveguide 103 is bent at a plurality of locations in a plan view and has a shape like a seagull wing in a plan view. This point will be described below.
Hereinafter, an optical path length of each of the waveguides constituting the first arrayed waveguide 103 of the arrayed waveguide grating according to the embodiment will be described in detail. When the optical path length difference between adjacent waveguides in the first arrayed waveguide 103 is ΔL, a central wavelength λ0 of the arrayed waveguide grating is expressed by Equation (i) below. The central wavelength λ0 is normally a central transmission wavelength of a central port among output ports of the arrayed waveguide grating. In Equation (i), nc represents an effective refractive index of the arrayed waveguide, and m represents a diffraction order.
In this example, from the upper side of the paper surface of
A free spectral range (FSR) of the arrayed waveguide grating is expressed by Expression (2) below.
See Reference 1 and Reference 2 for Equation (1) and Expression (2).
For example, when the free spectral range (FSR) of the arrayed waveguide grating is set to 400 nm or more with a wavelength of 1250 nm to 1650 nm, the central wavelength λ0 is designed to be 1450 nm, the wavelength interval is designed to be 50 nm, and the first output waveguides 107 are designed to be eight output waveguides, an entire wavelength range of the access-type PON system described above is covered. In this case, the central wavelength of FSR is 1450 nm. Thus, the diffraction order m is set to any one of 1 to 3 in view of Equation (2).
Here, the optical path length difference ΔL becomes a minute length on the order of μm in view of Equation (1), which cannot be achieved by an arc structure in which the first arrayed waveguide 103 is bent at only one place. Thus, in the embodiment, the first arrayed waveguide 103 has a structure in which the first arrayed waveguide 103 is bent at a plurality of portions including a central portion and portions on both sides (both side portions) in a plan view. In this way, by providing the plurality of bent portions, it is possible to reverse a change in the optical path length from the upper side of the paper surface of
For example, the first arrayed waveguide 103 is bent to be convex outward in a plan view at the central portion, and is bent to be convex inward in a plan view at both side portions sandwiching the central portion. With this configuration, in the central portion of the first arrayed waveguide 103, the optical path length becomes longer toward the outside (the upper side of the paper surface of
A function of a transmission spectrum of the arrayed waveguide grating (optical waveguide chip 101) is represented by a Gaussian function. An example of a calculation result is illustrated in
The function of the transmission spectrum will be described. A transmission function of the arrayed waveguide grating can be expressed by Equation (3) when a loss is ignored (see Reference 2).
In Equation (3), of is a deviation from a central transmission frequency, Δx is an interval between center positions of the first output waveguides 107 connected to the first output-side slab waveguide 105, Δf is an interval between central frequencies of adjacent channels, and ω0 is a spot size.
Here, when δλ is a deviation from a central transmission wavelength and Δλ is an interval between central wavelengths of the adjacent channels, Expression (4) below is established, and when Expression (4) is substituted into Equation (3), Expression (5) is obtained. Equation (3) represented in a frequency domain is represented in a wavelength range by Equation (5).
Next, a wavelength checker according to a second embodiment of the present invention will be described with reference to
The wavelength checker includes an optical waveguide chip 101. The optical waveguide chip 101 is the same as that of the above-described first embodiment. The wavelength checker further includes an optical waveguide chip 121 that is arranged side by side with the optical waveguide chip 101 and includes an optical waveguide through which emitted light is guided. A plurality of linear optical waveguides are formed in the optical waveguide chip 121. For example, the optical waveguide chip 121 is formed with eight linear optical waveguides corresponding to eight output waveguides of the optical waveguide chip 101. In addition, the eight linear optical waveguides are arrayed at interval of 1 mm that is the same as the interval between the output ends of the eight output waveguides of the optical waveguide chip 101.
In the second embodiment, a light emitting-side end surface 108a of the optical waveguide chip 121 on the side from which light is output to an external space is a reflection surface inclined so as to face a main substrate 151. An optical conversion unit 102 is provided at a location on the optical waveguide chip 121 from which light reflected on the light emitting-side end surface 108a is output to the external space. The optical conversion unit 102 is the same as that of the above-described first embodiment. Further, the optical waveguide chip 121 is placed in series with the optical waveguide chip 101 in the waveguide direction.
In the second embodiment, the optical waveguide chip 101 and the optical waveguide chip 121 are mounted on an optical waveguide chip 141. In other words, two layers are laminated. A lower optical waveguide chip is defined as a parent optical waveguide chip, and an upper optical waveguide chip is defined as a child optical waveguide chip. Accordingly, in the following description, optical waveguide chips will be referred to as the child optical waveguide chip 101, the child optical waveguide chip 121, and the parent optical waveguide chip 141.
The parent optical waveguide chip 141 may have a planar lightwave circuit formed thereon or may have no optical circuit (only cladding glass on the Si substrate). The child optical waveguide chip 101 and the child optical waveguide chip 121 are mounted on the parent optical waveguide chip 141 with a spacer (not illustrated) interposed therebetween such that a surface (surface on which the cladding glass is located) of each of the child optical waveguide chip 101 and the child optical waveguide chip 121, on which optical waveguides (planar lightwave circuit) are formed, is directed to (a surface, on which the cladding glass is located, of) the parent optical waveguide chip 141.
Here, an optical waveguide chip through which light is to be transmitted is the child optical waveguide chip. When the surface on which the cladding glass is located is used as a front surface, a back surface of the child optical waveguide chip, on which the Si substrate is located, is visible when the child optical waveguide chip is viewed from above. In other words, in the child optical waveguide chip, a portion of the optical circuit including a core and a clad is provided on the lower side. On the other hand, the parent optical waveguide chip 141 is mounted on the main substrate 151. For example, the parent optical waveguide chip 141 is bonded and fixed with an adhesive onto the main substrate 151. In addition, the child optical waveguide chip 101 and the child optical waveguide chip 121 are arranged vertically along the input direction of light.
For example, the optical conversion unit 102 can be formed by applying a conversion material that converts infrared light to visible light to an upper surface of the child optical waveguide chip 121 where may be the light emitting-side end surface 108a.
In the second embodiment, light is input to the child optical waveguide chip 101, dispersed by the child optical waveguide chip 101, and output through the child optical waveguide chip 121. The light emitting-side end surface 108a on the output side of the child optical waveguide chip 121 is made oblique, and light coming through the optical waveguides of the child optical waveguide chip 121 is reflected on the light emitting-side end surface 108a. The substrate of the child optical waveguide chip 121 is typically Si or quartz, through which infrared light is transmitted. Thus, light coming through the optical waveguides of the child optical waveguide chip 121 is emitted from the side on which the substrate is located.
The optical conversion unit 102 is formed at the location where light is emitted. Thus, light (near-infrared light) reflected on the light emitting-side end surface 108a and emitted (output) from the substrate is converted to visible light by the optical conversion unit 102 to become recognizable by the eye (visible). The output waveguides of the child optical waveguide chip 101 and the waveguide group of the child optical waveguide chip 121 are arranged, for example, at 1 mm intervals, and thus by confirming a shiny location, it is possible to recognize a waveguide of the child optical waveguide chip 121 and a waveguide of the child optical waveguide chip 101 through which light passes. In addition, when a relationship between port numbers of waveguides and demultiplexed wavelengths is grasped in advance, it is possible to recognize coming of light and a wavelength of the light.
Note that as described above, in the second embodiment, light reflected on the light emitting-side end surface 108a is emitted from the substrate side, so that the position of the waveguide cannot be directly confirmed visually. Accordingly, when marks corresponding to the positions of the waveguides are provided on the light emitting side (back surface) of the substrate, the position of a waveguide is easily confirmed. The marks can be formed by, for example, impressing with a laser such as YAG. Alternatively, a tape on which a 1 mm spacing scale is drawn is attached, so that the position of a waveguide is easily confirmed.
Further, a fiber block 161 is connected to an input waveguide end of the child optical waveguide chip 101. An optical fiber 162 provided with a connector 163 for inputting an optical signal to be confirmed is connected to the fiber block 161. An optical fiber with a connector (not illustrated) is separately used for alignment of the fiber block 161 and an input waveguide of the child optical waveguide chip 101. In addition, the child optical waveguide chip 101 is bonded and fixed with an adhesive to the parent optical waveguide chip 141 with a spacer (not illustrated) interposed therebetween. On the other hand, the child optical waveguide chip 121 is in a semi-fixed state and can be attached to and detached from the parent optical waveguide chip 141 to be replaceable.
Here, positioning of the child optical waveguide chip 101 and the child optical waveguide chip 121 on the parent optical waveguide chip 141 will be described with reference to
The first grooves 131 are formed in a cladding layer 143 of the parent optical waveguide chip 141. The first grooves 131 are formed to penetrate the cladding layer 143 and reach a substrate 142. Similarly, the second grooves 132 are formed in a cladding layer 124 including a core 123 of the child optical waveguide chip 121. The second grooves 132 are formed to penetrate the cladding layer 124 and reach a substrate 122.
The first grooves 131 and the second grooves 132 can be formed by a photolithography technique and an etching technique (such as reactive ion etching). The first grooves 131 are formed by etching the cladding layer 143 using a mask pattern formed by the photolithography technique as a mask and using the substrate 142 as an etching stop layer. Similarly, the second grooves 132 is formed by etching the cladding layer 124 using a mask pattern formed by the photolithography technique as a mask and using the substrate 122 as an etching stop layer.
The accuracy of a position (amount of displacement) in a surface direction with respect to the design of the first grooves 131 and the second grooves 132 formed in this manner is determined by the positional accuracy of the mask pattern and the amount of displacement of the position during etching. As is well known, the positional accuracy of the mask pattern is submicron or less, and the positional displacement in reactive ion etching is also submicron or less. Accordingly, the positions in the surface direction where the first grooves 131 and the second grooves 132 are formed are 1 μm or less with respect to the design.
The depth of each of the first grooves 131 is determined by the thickness of the cladding layer 143, and the depth of each of the second grooves 132 is determined by the thickness of the cladding layer 124. The accuracy of the thickness of the cladding layer 143 and the accuracy of the thickness of the cladding layer 124 are determined on the order of submicron, for example, by a well-known glass deposition technique. The same applies to the position in the thickness direction of the core 123 embedded in the cladding layer 124.
Here, the spacer members 171 can be formed by, for example, cutting an optical fiber to a predetermined length and the accuracy of a diameter of each of the spacer members 171 can be determined on the order of submicron. Accordingly, the positional accuracy in the thickness direction of the child optical waveguide chip 121 is also determined in a range of 1 μm or less.
As described above, between the child optical waveguide chip 101 and the child optical waveguide chip 121 mounted on the parent optical waveguide chip 141, positions of core centers of corresponding optical waveguides can be accurately matched with each other. Note that in general, alignment among a plurality of child chips mounted on a parent optical chip as described above is performed under conditions where warping does not occur in each of the chips. For more detailed description, see Reference 4, Reference 5, and Reference 6. This optical implementation is referred to as a pluggable photonic circuit platform (PPCP). The child optical waveguide chip 121 implemented by the PPCP is characterized by being detachable. As a result, child optical waveguide chips 121 having various functions can be replaced to be used, and it is possible to flexibly impart various functions to the wavelength checker. That is, it can be said that the PPCP has features such as an optical circuit (optical chip) version of an electronic block.
Furthermore, the positional accuracy between the child optical waveguide chip 101 and the child optical waveguide chip 121 is guaranteed as described above, and thus a transmission spectrum output from the child optical waveguide chip 121 is also represented by the spectrum in
Next, production of the child optical waveguide chip 121 will be described with reference to
First, as illustrated in
For example, the lower cladding layer 124a and the core forming layer 301 can be formed using a flame hydrolysis deposition (FHD) method. First, glass fine particles heated and hydrolyzed through raw material gas (mainly composed of silicon tetrachloride) in an oxyhydrogen flame are deposited on the substrate 122, thereby forming a first fine particle layer serving as the lower cladding layer 124a. Subsequently, a composition of the raw material gas is changed (a GeO2 dopant concentration is changed), and thus glass fine particles having different compositions are deposited on the first fine particle layer, thereby forming a second fine particle layer serving as the core forming layer 301. Thereafter, for example, the first fine particle layer and the second fine particle layer are heated using an electrical furnace or the like, so that the respective layers are formed as transparent glass composition films, thereby forming the lower cladding layer 124a and the core forming layer 301. These layers can also be formed using a chemical vapor deposition method.
Then, the core forming layer 301 is patterned using a known lithography technique and etching technique used for manufacture of a semiconductor device, thereby forming the core 123, as illustrated in
Next, an upper cladding layer 124b, is formed on the core 123, as illustrated in
Then, the upper cladding layer 124b and the lower cladding layer 124a are patterned using a known lithography technique and etching technique, so that the second groove 132 penetrating the upper cladding layer 124b and the lower cladding layer 124a and reaching the substrate 122 is formed as illustrated in
Next, formation of the light emitting-side end surface 108a of the child optical waveguide chip 121 will be described with reference to
A beam obtained by reflecting light having the MFD of 6 μm on the light emitting-side end surface 108a spreads out by diffraction. Hereinafter, an electric field distribution in the optical waveguide is approximated as a Gaussian distribution to calculate the above-described spread of the beam that propagates in the substrate 122 made of Si. When it is assumed that the spot size at the light emitting-side end surface 108a is ω0, a diameter of the beam that has propagated by a distance z from the light emitting-side end surface 108a is represented by Equation (6). This is described in detail in Reference 7. In Equation (6), λ represents a wavelength. Equation (6) may be approximated by Expression (7), under the condition that the squared term in √ of Equation (6) is sufficiently larger than 1 (in this case, about z>100 μm).
A plot of Expression (7) is shown in
As illustrated in
Incidentally, the light emitting-side end surface 108a has been described as a flat surface, but the present invention is not limited thereto, and may be a reflection surface (concave mirror) including a curved surface as in Reference 8. Note that when the curved surface (concave surface) is used, the light emitting-side end surface 108a cannot be made by the aforementioned polishing. For example, anisotropic etching is repeated to gradually change an angle of an end surface of a glass portion, and finally smoothing is performed by wet etching, so that a curved surface can be made. Note that in this case, the substrate 122 made of Si is not etched, and a portion to be etched is a portion of the lower cladding layer 124a, the core 123, and the upper cladding layer 124b, which are made of quartz-based glass.
As described above, when the light emitting-side end surface 108a is made a curved surface and a curvature radius of the curved surface and the like are properly designed, light reflected on the light emitting-side end surface 108a can be condensed at a point where the light reaches the optical conversion unit 102. When light is condensed in this manner, a power density of the light reaching the optical conversion unit 102 increases, and even if original signal light is weak, the light can be converted to visible light that can be recognized visually.
Incidentally, as illustrated in
The transmission spectrum in a case where the child optical waveguide chip 121 including linear optical waveguides is combined with the child optical waveguide chip 101 becomes a spectrum illustrated in
In addition, in a configuration in which the child optical waveguide chip 121 is combined with the child optical waveguide chip 101, as illustrated in
As described above, the child optical waveguide chip 121 and the child optical waveguide chip 121a are made interchangeable by PPCP implementation, so that the wavelength resolution and measurement range of the wavelength checker can be flexibly changed.
Note that while in the explanation described above, a wavelength is confirmed with higher definition by using an arrayed waveguide grating with a narrow wavelength interval in a wavelength range of wavelengths ranging from 1550 nm to 1600 nm, it can be seen that if an arrayed waveguide grating having 10 ports at 5 nm intervals is prepared and connected to a different output port of the arrayed waveguide grating of the child optical waveguide chip 101, the arrayed waveguide grating having 10 ports at 5 nm intervals corresponding to the range of wavelengths output from the different output port, a wavelength can be confirmed with a wavelength resolution of 5 nm even in other wavelength ranges.
Here, the description is added as to an arrayed waveguide grating having a narrow demultiplexed wavelength interval. An arrayed waveguide grating having a free spectral range (FSR) equal to channel spacing×the number of channels is referred to as a cyclic arrayed waveguide grating (circulating arrayed waveguide grating). When the above-described circulating arrayed waveguide grating is used for the arrayed waveguide grating with a narrow wavelength interval, an optical chip connected to the child optical waveguide chip 101 can be shared in the same circulating arrayed waveguide grating. However, in channels having excessively distant wavelengths such as a 1500 nm band and a 1300 nm band, a refractive index difference increases due to an effect of refractive index dispersion, and thus the arrayed waveguide grating cannot be shared.
In the above description, the device structure of the wavelength checker is explained, but here, the device structure will be supplemented slightly from the perspective of a wavelength inspection method. As a wavelength inspection method for an access-type PON system as well, an inspection method can be also proposed in which wavelengths are demultiplexed for each wavelength in an arrayed waveguide grating, and a material that converts near-infrared light to visible light (wavelength conversion material) is irradiated with demultiplexed light, and a wavelength is confirmed visually from a shiny port. Broad interpretation of the arrayed waveguide grating is a diffraction grating (grating), and thus an inspection method can be proposed in which wavelengths are demultiplexed for each wavelength in a diffraction grating (grating), a wavelength conversion material is irradiated with demultiplexed light, and a wavelength is confirmed visually from a shiny position. These inspection methods have a feature that wavelength inspection can be easily performed without using a power source or the like.
Next, a wavelength checker according to a third embodiment of the present invention will be described with reference to
Here, when a waveguide interval in a connection portion of the plurality of first output waveguides 107 with the first output-side slab waveguide 105 is Δxout, a waveguide interval between a connection portion of the main first input waveguide 106a with the first input-side slab waveguide 104 and a connection portion of the sub first input waveguide 106b with the first input-side slab waveguide 104 is Δxout/2. Further, in the child optical waveguide chip 101a, the first input-side slab waveguide 104, the first arrayed waveguide 103, and the first output-side slab waveguide 105 have a shape, in a plan view, line-symmetrical with respect to a straight line that passes through a midpoint of a line segment connecting a center of the first input-side slab waveguide 104 and a center of the first output-side slab waveguide 105 and perpendicular to the line segment. In the first input-side slab waveguide 104, an arc in contact with the input waveguide and an arc in contact with the arrayed waveguide have the same curvature. Thus, the center of the input-side slab waveguide is an intersection of straight lines diagonally connecting four points at which straight lines and arcs constituting an outer shape of the slab waveguide intersect with each other. The same applies to the first output-side slab waveguide 105.
Hereinafter, more details will be described.
The main first input waveguide 106a is connected to the center of the first input-side slab waveguide 104. Further, it is assumed that the respective first output waveguides 107 are connected to the center of the first output-side slab waveguide 105 at waveguide intervals of Δxout, and that light is branched into light beams having equally spaced central transmission wavelengths of λ1, λ2, λ3, . . . , and λ8 with respect to the respective first output waveguides 107. Further, the sub first input waveguide 106b is connected to the first input-side slab waveguide 104 at a waveguide interval of Δx, which is equal to Δxout, with respect to the main first input waveguide 106a (see
As described above, when the shape in a plan view of the first input-side slab waveguide 104, the first arrayed waveguide 103, and the first output-side slab waveguide 105 are line-symmetrical (see Reference 1), the following is satisfied.
When the sub first input waveguide 106b is connected, being shifted with respect to the main first input waveguide 106a, the wavelength-multiplexed light input to the sub first input waveguide 106b is branched into light beams having equally spaced central transmission wavelengths of λ2, λ3, λ4, . . . , and λ9 with respect to the respective first output waveguides 107. This is caused by the following reason: the sub first input waveguide 106b is shifted by one waveguide interval, and thus a wavefront when the light reaches the first arrayed waveguide 103 is inclined. As a result, a wavefront when the light reaches the first output waveguides 107 is inclined, and the light having the same wavelength is condensed on the first output waveguide 107 shifted by one waveguide interval. Note that in an arrayed waveguide (AWG), a connection position of a slab waveguide and an input waveguide and a central transmission wavelength are in a linear relationship. A detailed description is given in Reference 9.
When the waveguide interval Δx between the main first input waveguide 106a and the sub first input waveguide 106b is Δxout/2 and a central wavelength interval between adjacent channels is Δλ, the central transmission wavelengths become λ1+Δλ/2, λ2+Δλ/2, λ3+Δλ/2, . . . , and λ8+Δλ/2. The relationship of Δλ=λ2−λ1=λ3−λ2= . . . =λ9−λ8 is satisfied.
When the design of the arrayed waveguide grating in the child optical waveguide chip 101a is similar to that in the child optical waveguide chip 101, a spectrum (calculated value) of light input from the main first input waveguide 106a and transmitting through the arrayed waveguide grating becomes the same spectrum as the transmission spectrum of the child optical waveguide chip 101, as illustrated in
On the other hand, a spectrum (calculated value) of light input from the sub first input waveguide 106b and transmitting through the arrayed waveguide grating is shifted by half the wavelength interval as illustrated in
As compared with a case in which there is one input waveguide to the arrayed waveguide grating, effects of providing the main first input waveguide 106a and the sub first input waveguide 106b are as follows. When the number of input waveguides is one and light having a wavelength between transmission spectra of adjacent ones of the first output waveguides 107 is input, transmittance is low, and thus light converted from near-infrared light to visible light also becomes weak, so that the light emission in the optical conversion unit 102 cannot be recognized in some cases.
For example, the transmitted light intensities at ports 1 and 2 at a wavelength of 1300 nm in
On the other hand, when the main first input waveguide 106a and the sub first input waveguide 106b are used, signal light is also input to the sub first input waveguide 106b, so that the transmitted light intensity at port 1 at the wavelength of 1300 nm is the most transmissive wavelength. Consequently, as illustrated in
Accordingly, even in a case in which signal light is input to one input waveguide, but transmitted light intensity with respect to the signal light is weak, and thus a wavelength cannot be recognized, the main first input waveguide 106a and the sub first input waveguide 100 are used and signal light is input to both the waveguides, so that stronger light emission can be obtained in the optical conversion unit 102, thereby enabling more reliable wavelength recognition.
Next, a wavelength checker according to a fourth embodiment of the present invention will be described with reference to
First, as illustrated in
Next, considering that light is input to the arrayed waveguide grating of the child optical waveguide chip 101a from the sub first input waveguide 106b, a configuration is considered in which the second input waveguide 128 of the child optical waveguide chip 121a is connected to the port 7 of the first output waveguides 107 of the child optical waveguide chip 101a. A transmission spectrum of the port 7 of the child optical waveguide chip 101a becomes a spectrum as illustrated in
Next, consider that light is input to the arrayed waveguide grating of the child optical waveguide chip 101a from the sub first input waveguide 1o6b, and consider a configuration in which the second input waveguide 128 of the child optical waveguide chip 121a is connected to a port 6 in the first output waveguides 107 of the child optical waveguide chip 101a. A transmission spectrum of the port 6 of the child optical waveguide chip 101a is illustrated as in
As described above, the transmission spectrum using the main first input waveguide 106a and the sub first input waveguide 106b of the child optical waveguide chip 101a becomes a spectrum illustrated in
The transmission spectrum of the child optical waveguide chip 101 plus the child optical waveguide chip ma becomes a spectrum illustrated in
Note that, in the above description, the child optical waveguide chip 101a provided with two waveguides, that is, the main first input waveguide 106a and the sub first input waveguide 106b, is used to widen the wavelength range in which a transmittance is high, but when two input waveguides are also provided in the arrayed waveguide grating of the child optical waveguide chip 101a, it is possible to further widen a wavelength range in which a transmittance is high.
Next, a wavelength checker according to a fifth embodiment of the present invention will be described with reference to
An extra groove for fitting the child optical waveguide chip 121b is provided in a parent optical chip on which the child optical waveguide chip 101 and the child optical waveguide chip 121b are mounted to make the child optical waveguide chip 121b movable in a direction perpendicular to the light guided direction. With this configuration, the child optical waveguide chip 121b is slid over the parent optical chip to move the child optical waveguide chip 121b, so that connection between the child optical waveguide chip 101 and the optical waveguide portion 120a and connection between the child optical waveguide chip 101 and the arrayed waveguide grating 120b can be switched.
In the aforementioned implementation by PPCP, it is necessary to separately prepare the child optical waveguide chip 121 and the child optical waveguide chip 101a, but according to the fifth embodiment, only one child optical waveguide chip 121b need be provided, leading to the effect of reducing the number of parts. In general, for the arrayed waveguide grating of the child optical waveguide chip 121a, when a wavelength band is different, a separate arrayed waveguide grating needs to be prepared, but according to the fifth embodiment, for example, an arrayed waveguide grating required for a wavelength range in which an inspection resolution is to be increased only need be embedded in the child optical waveguide chip 121b to an extent permitted by the chip space.
As described above, the light emitting-side end surface of the optical waveguide chip on the side from which light is output to the external space is a reflection surface inclined so as to face the main substrate and the light emitting-side end surface is disposed in a location from which light reflected on the light emitting-side end surface is output to the external space, so that confirmation as to whether there is signal light in opening, failure isolation investigation, or the like of a PON system can be easily performed.
Meanwhile, the present invention is not limited to the embodiment described above, and it will be obvious to those skilled in the art that various modifications and combinations can be implemented within the technical idea of the present invention.
Filing Document | Filing Date | Country | Kind |
---|---|---|---|
PCT/JP2019/033063 | 8/23/2019 | WO |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2021/038630 | 3/4/2021 | WO | A |
Number | Name | Date | Kind |
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20080175284 | Konttinen | Jul 2008 | A1 |
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20210356665 | Tanaka | Nov 2021 | A1 |
20210373233 | Tanaka | Dec 2021 | A1 |
20220381982 | Tanaka | Dec 2022 | A1 |
20220404565 | Tanaka | Dec 2022 | A1 |
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2003-131071 | May 2003 | JP |
2003-218813 | Jul 2003 | JP |
2004-170488 | Jun 2004 | JP |
2008-96237 | Apr 2008 | JP |
2017-194565 | Oct 2017 | JP |
Entry |
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English translation of written opinion for PCT/JP2019/033063, dated Jan. 7, 2020. (Year: 2020). |
English translation of written opinion for PCT/JP2019/040415, dated Dec. 24, 2019. (Year: 2019). |
Koma et al. “Standardization trends for faster PON systems” NTT Technology Journal, vol. 29, No. 8, 2017, pp. 51-53. |
Number | Date | Country | |
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20220276435 A1 | Sep 2022 | US |