Abstract: A food/beverage article, comprising: one or more compounds represented by formula (I): wherein, R1 and R3 each independently represent a hydrogen atom or a C2-6 alkenyl group, R2 and R4 each independently represent a hydrogen atom or a C1-4 alkyl group, R5 and R7 each independently represent a hydrogen atom or a hydroxyl group, R6 represents a hydrogen atom or a C2-6 alkenyl group, X represents a direct bond, —CH2—, —CH?, or —C(?O)—, and Y represents —CH2—, —CH?, or —C(?O)—, wherein the total of the concentrations of the compounds is 1 ppm or more.

Abstract: Adding (a) transglutaminase, and a gluconic acid salt or lipase to a processed meat food product, or (b) transglutaminase, a gluconic acid salt, and lipase to a processed meat food product with a sodium chloride content of 0.1 wt % to 1 wt % or a processed meat food product with a binding agent content of not more than 0.2 wt % affords a processed meat food product with a reduced sodium chloride content or a reduced binding agent content, with a good elastic texture.

Abstract: A polarization dispersion compensation apparatus includes a polarization controller, a polarization beam splitter, an optical delay circuit, and a polarization beam combiner. The polarization controller controls polarization of an optical signal so that the polarization axis of the input optical signal substantially coincides with the optical axis of an optical transmission line, and the polarization beam splitter section splits the optical signal into two polarized components perpendicular to each other. The optical delay circuit section causes a difference in delay between the two polarized components, and the polarization beam combiner section combines the two polarized components output from the optical delay circuit section.

Abstract: A variable dispersion compensator includes an optical waveguide, a temperature controller. The optical waveguide has a chirped grating having a Bragg wavelength changing along the longitudinal direction of the grating. A temperature distribution T1(x) is applied to a central portion of the grating, defined as a region where a distance x from an end of the grating is a range of 20 % to 80 % of total length of the grating. Temperature distribution T2(x) and T3(x) are applied to end portions of the grating, defined as two regions extending from respective ends of the grating to the central region, respectively. At least one of T2(x) and T3(x) has a distance dependence different from that of the T1(x).

Abstract: In a polarization mode dispersion compensating apparatus for controlling polarization mode dispersion of an optical signal, a first optical monitor detects and outputs, based on an optical signal outputted from a first optical transmission line having a grating, a first detection signal indicating magnitude of waveform distortion of the first optical transmission line, and a second optical monitor detects and outputs, based on an optical signal output from a second optical transmission line having a grating, a second detection signal indicating magnitude of waveform distortion of the second optical transmission line. A calculator circuit calculates from the first and second detection signals an output signal. A controller controls a polarization controller based on the output signal from the calculator circuit.

Abstract: A polarization dispersion compensation apparatus of the present invention is provided with a polarization controller 4, a polarization beam splitter section 1, an optical delay circuit section 2 and a polarization beam combiner section 3. The polarization controller 4 controls polarization state of an optical signal so that the polarization axis of the inputted optical signal substantially coincides with the optical axis of an optical transmission line, and the polarization beam splitter section 1 splits, and outputs the optical signals of two polarized components perpendicular to each other from the optical signal outputted from the polarization controller 4. The optical delay circuit section 2 causes a difference in delay between the optical signals of the two polarized components outputted from the polarization beam splitter section 1, and the polarization beam combiner section 3 combines and outputs the optical signals of the two polarized components outputted from the optical delay circuit section 2.

Abstract: A method of manufacturing a grating in an optical waveguide that includes a core and a cladding covering the core. The method includes scanning a laser beam along an optical axis of the optical waveguide to modulate the refractive index of the core. The core is made of a material having a refractive index that is changeable upon irradiation by radiation. In addition, in scanning the core, the irradiation range of the laser beam is controlled and the core is scanned several times. Therefore, a predetermined distribution of irradiation is obtained in a direction of the optical axis of the grating.

Abstract: A variable dispersion compensator (1) includes an optical waveguide (8), a temperature controller (3, 5, 6, 7). The optical waveguide has a chirped grating (2) having Bragg wavelength changed along the longitudinal direction. Temperature distribution based on T1(x) is applied to a central portion defined as a region where a distance x from an end of the grating is a range of 20% to 80% of total length of the grating. Temperature distribution based on T2(x) and T3(x) are applied to both end portions defined as two regions extending from both ends of the grating to the central region, respectively. At least one of the T2(x) and T3(x) has distance dependence different from that of the T1(x).

Abstract: A temperature control device for controlling temperature variable devices disposed near a grating of a variable dispersion equalizer including an optical waveguide having the grating. The temperature variable devices control temperatures independently of each other. The temperature control device includes a controller for controlling the temperature variable units, and a storage device which stores temperature control patterns including combinations of control signals for the respective temperature variable units. The controller controls the temperature variable devices with a control signal of at least one of the temperature control patterns selected from the storage device.

Abstract: In a polarization mode dispersion compensating apparatus for controlling polarization mode dispersion of an optical signal, a first optical monitor detects and outputs, based on an optical signal outputted from a first optical transmission line having a grating, a first detection signal indicating magnitude of waveform distortion thereof, and a second optical monitor detects and outputs, based on an optical signal outputted from a second optical transmission line having a grating, a second detection signal indicating magnitude of waveform distortion thereof: A calculator circuit performs a predetermined calculation about the first and second detection signals, and outputs an output signal indicating a result of the calculation. A controller controls a polarization controller based on the output signal from the calculator circuit.

Abstract: A cathode for an electron tube provided with a base containing at least one kind of reducing agent, a metal layer whose main component is tungsten formed on the base, and an electron emission material layer whose main component is an alkaline-earth metal oxide including barium formed thereon, deformation of the base in operation is controlled by composing the metal layer with a porous metal layer and limiting the thickness and the porosity of the metal layer. As a result, it is possible to achieve a cathode for an electron tube applicable to a cathode-ray tube for a display in which the cutoff voltage is liable to change.

Abstract: This invention provides a temperature control device for controlling a plurality of temperature variable devices disposed near a grating of a variable dispersion equalizer including an optical waveguide having the grating. The temperature variable devices are able to control the temperatures independently of each other. The temperature control device includes a controller for controlling the temperature variable units, and a storage device which stores a plurality of temperature control patterns includes combinations of control signals of the respective temperature variable units. The controller controls the temperature variable devices by a control signal of at least one of the temperature control patterns selected from the storage device.

Abstract: A method of manufacturing a grating in an optical waveguide that includes a core and a cladding covering the core. The method includes the steps of providing the optical waveguide and scanning a laser beam along an optical axis of the optical waveguide to form modulation of refractive index of radiation in the core. The core is made of a material having the refractive index that is changeable by irradiation of radiation. In addition, on the step of scanning, in the core, the irradiation range of the laser beam is controlled and the laser beam is scanned a plurality of times. Therefore, predetermined distribution of irradiation amount is obtained in a direction of the optical axis of the grating.

Abstract: A light dispersion equalizer for compensating for variation in propagation rate among employed wavelengths. On a substrate having a groove for mounting an optical fiber provided thereon, heaters are formed side by side in parallel with the optical fiber mounting groove, and the optical fiber is accommodated in the groove. Because distance between the optical fiber and the heaters can be fixed, positioning of the optical fiber with the heaters can be performed with high accuracy.

Abstract: It is an object to obtain a cathode ray tube having a high resolution without decreasing electron emission property. Surface of a cathode was leveled by heating during forming a vacuum in order to oxidize a carbonate salt to an oxide as an electron emissive material, after applying a paste for printing on a metal substrate by screen printing, drying the same, and incorporating an oxide cathode in a cathode ray tube, the paste having a mixture of needle-like particles of the first group and bulk particles of the second group incorporated as an alkaline earth metal carbonate forming an electron emissive material layer.

Abstract: A cathode for an electron tube provided with a base containing at least one kind of reducing agent, a metal layer whose main component is tungsten formed on the base, and an electron emission material layer whose main component is an alkaline-earth metal oxide including barium formed thereon, deformation of the base in operation is controlled by composing the metal layer with a porous metal layer and limiting the thickness and the porosity of the metal layer. As a result, it is possible to achieve a cathode for an electron tube applicable to a cathode-ray tube for a display in which the cutoff voltage is liable to change.

Abstract: An electron tube cathode comprises a base (1) formed mainly of nickel, an alloy layer (4) disposed on the base (1) and including nickel and tungsten having a grain size smaller than that of the base, and an electron emissive material layer (5) deposited on the alloy layer, and including an oxide (6) of an alkaline-earth metal containing at least barium, and a rare earth metal oxide (7) of 0.01 to 25 weight percent and containing at least one of scandium oxide and yttrium oxide. The cathode has a life characteristics improved compared with the prior art, even if operated with a current density of 3 A/cm.sup.2 or more.

Abstract: A cathode for an electron tube including a base body having nickel as a major component and including at least one kind of reducing agents, a metal member in a layer-like shape, which has as a major component a metal provided with a reducing power equivalent to or smaller than a reducing power of the at least one kind of reducing agents included in the base body and larger than a reducing power of nickel and which is formed on faces of the base body, an electron emitting substance layer formed by depositing alkaline earth metal oxides including barium on the metal member, wherein the metal member is formed on the faces of the base body such that the base body is restrained from deforming by thermal stresses of intermetallic compounds formed at portions of the base body bounded with the metal member.

Abstract: Problems with a conventional cathode for electronic tubes arose because metals composing the substrate were subjected to heat deformation, resulting in a relatively lage drift of cutoff voltage. The present invention diminishes the heat deformation of the substrate to obtain a cathode with a small drift of cutoff voltage. Particularly, heat expansion coefficients can be made uniform while metals in the metal layer are prevented from diffusing into the substrate. This is done by incorporating the same metals present in the metal layer into the metals composing the substrate, thereby supressing deformation of the substrate.

Abstract: A control electrode portion for passing electrons through a given electron-passing hole selected from a plurality of electron-passing holes provided on an insulating substrate is formed by coating the insulating substrate with a conductive film and dividing the into a plurality of conductive films as control electrodes. This structure obviates the mesh structure of electrons which are necessary in the case of arranging control electrodes on the insulating substrate, thereby realizing high-definition display devices with improved luminance.