Abstract: The invention provides an apparatus for measuring the physical properties of a sample by optically monitoring the response of the sample to illumination by ultrashort optical pulses. The apparatus is a common path optical interferometer of a Sagnac type that can measure physical properties at normal incidence, i.e., a single-arm Sagnac interferometer featuring two beam splitters. Measurement is performed in such a manner that a sample is excited by a beam of ultrashort optical pulses, and variations in intensity and phase of another optical beam are detected. This enables a wide range of measurement of physical properties such as thickness, sound velocity, and thermal properties of substances.

Abstract: The invention provides an apparatus for measuring the physical properties of a sample by optically monitoring the response of the sample to illumination by ultrashort optical pulses. The apparatus is a common path optical interferometer of a Sagnac type that can measure physical properties at normal incidence. The interferometer is a two-arm Sagnac interferometer featuring two beam splitters. Measurement is performed in such a manner that a sample is excited by a beam of ultrashort optical pulses, and variations in intensity and phase of another optical beam are detected. This enables a wide range of measurement of physical properties such as thickness, sound velocity, and thermal properties of substances.

Abstract: An apparatus for measuring the physical properties of a sample by optically monitoring the response of the sample to illumination by ultrashort optical pulses utilizes a common path optical interferometer of a Sagnac type that can measure physical properties at normal incidence. The interferometer is a two-arm Sagnac interferometer featuring three beam splitters. A sample is excited by a beam of ultrashort optical pulses, and variations in intensity and phase of another optical beam are detected. This enables a wide range of measurement of physical properties such as thickness, sound velocity, and thermal properties of substances.

Abstract: A first magnetic film to constitute a first yoke part and a first pole part is formed in a given pattern on a substrate, and a write gap film is formed on the part corresponding to the first pole portion of the first magnetic film. Then, a second magnetic film having a second pole portion and a second yoke part is formed on the write gap film by a photolithography so that the second pole portion can have a width of 1.5-2.5 &mgr;m. Thereafter, the sides of the second pole portion are etched by an ion beam etching method to narrow its width, and the write gap film is removed by using, as a mask, the second pole portion to expose the first magnetic film. Subsequently, the exposed first magnetic film is partially removed to form the first pole portion and thereby a thin film magnetic head having a pole portion with a track width of not more than 1 &mgr;m beyond the limit of the photolithography is produced.

Abstract: In a semiconductor device manufacturing method capable of manufacturing semiconductor lasers, light emitting diodes or electron transport devices using nitride III-V compound semiconductors with a high productivity, a GaN semiconductor laser wafer is prepared in which a plurality of semiconductor lasers are formed on an AlGaInN semiconductor layer on a c-face sapphire substrate and separated from each other by grooves deep enough to reach the c-face sapphire substrate, and a p-side electrode and an n-side electrode are formed in each semiconductor laser. The GaN semiconductor laser wafer is bonded to a photo-diode built-in Si wafer having formed a photo diode for monitoring light outputs and solder electrodes in each pellet by positioning the p-side electrode and the n-side electrode in alignment with the solder electrodes, respectively.

Abstract: A confocal scanning microscope can process two-dimensional or third-dimensional optical information at high speed and can be simplified in arrangement. The confocal scanning microscope includes an optical coupling device array composed of a plurality of optical coupling devices arranged on a common substrate in a one-dimensional or two-dimensional fashion, and an objective lens, wherein each of the optical coupling devices has a light-emitting portion and a light-receiving portion closely disposed on the common substrate, and reflected-back light obtained from a target object after light emitted from the light-emitting portion has been reflected on the target object is received and detected near a confocal position by the light-receiving portion.

Abstract: A surface-emission semiconductor light-emitting device package can radiate heat from the front surface while emitting light to the front surface of the device. The package includes a semiconductor light-emitting device for emitting light to a semiconductor substrate in the upper direction and a package window portion formed of a transparent heat sink, wherein the semiconductor light-emitting device is bonded to the package window portion in accordance with an interconnection pattern. A method of manufacturing semiconductor light-emitting device package also is described.

Abstract: An audible sound of modulated wave where a very low-frequency wave of about 20 hertz or lower is superposed on an audio low-frequency wave effectively stimulates Fm theta in human brain waves to improve attention and concentration during mental tasks when auditorily administered. The audible sound is also effective in stimulation of human alpha wave when the very low-frequency wave lies within the range of about 2-10 hertz. Such audible sound is artificially obtainable by generating an electric signal which contains such a modulated wave, and transducing it into audible sound wave.

Abstract: A clock signal generating device of the present invention has an active and a spare clock selecting circuit. The two clock selecting circuits each includes a selector for selecting one of a plurality of outside timing signals and outputting it as an inside clock signal under the control of a controller. A PLL (Phase Locked Loop) circuit is commonly connected to the outputs of the active and spare selecting circuits. The PLL circuit reduces the influence of switching between the active and spare selecting circuits and switching between the outside timing signals. The PLL circuit includes a hold-over circuit for temporarily holding, in response to a control signal fed from the controller, a signal output from the selecting circuit.

Abstract: An optical device has an optical element 21 comprising a light-emitting region 1 and a light-detecting region 4 disposed closely to each other on a common substrate 9. Returning light L.sub.R from an irradiated medium which is irradiated with light L emitted by the light-emitting region 1 is detected by the light-detecting region 4. The returning light is applied to a light-detecting region 4 at an incident angle .alpha. in the range of 0.degree.<.alpha.<90.degree..

Abstract: A confocal scanning microscope can process two-dimensional or third-dimensional optical information at high speed and can be simplified in arrangement. The confocal scanning microscope includes an optical coupling device array composed of a plurality of optical coupling devices arranged on a common substrate in a one-dimensional or two-dimensional fashion, and an objective lens, wherein each of the optical coupling devices has light-emitting portion and a light-receiving portion closley disposed on the common substrate, and reflected-back light obtained from a target object after light emitted from the light-emitting portion has been reflected on the target object is received and detected near a confocal position by the light-receiving portion.

Abstract: A print head, printer and recording method wherein dye recording materials 22Y, 22M, 22C are irradiated by a laser beam L or the like so as to vaporize them, and transport them to a recording medium such as an imaging paper, and the path of a beam from a heating beam emitting means, for example a laser 18, is changed so as to selectively cause the beam to impinge on one of the plurality of recording materials. By using the same heating beam emitting means for the plurality of recording materials, the structure of the head comprising the heating beam emitting means is simplified and its assembly is easier. Moreover, as a common heating beam emitting means may be used, its manufacture is easy, and the electrode wiring in the heating beam emitting means is easily implemented.

Abstract: An optical device for detecting a magneto-optical signal can be simplified and miniaturized in arrangement. An optical device for detecting a magneto-optical signal includes an optical element in which a light-emitting portion and a light receiving portion are closely disposed on a common substrate and in which reflected-back light obtained from a magneto-optical medium after light from the light-emitting portion was reflected on the magneto-optical medium is detected at a position near confocal position by the light receiving portion and another light receiving element. The reflected-back light from the magneto-optical medium is divided. One reflected-back light is detected by the light receiving portion of the optical element and the other reflected-back light is detected by another light receiving element.

Abstract: Light is emitted from a light-emitting element toward an irradiated medium, and returning light reflected by the irradiated medium is diffracted by a hologram device. A polarizer polarizes the light diffracted by the hologram device to produce first polarized light that has passed through the polarizer and second polarized light that has been reflected by the polarizer. The first polarized light is detected by a first light-detecting element, and the second polarized light is detected by a second light-detecting element. A magnetooptical signal is generated as the difference between the intensities of the first and second polarized lights which are detected respectively by the first and second light-detecting elements.

Abstract: A recording unit structure comprising a recording material layer faced to a recording body with a space incorporated therebetween, so that said recording material is vaporized and transferred to said recording body through said space, provided that pores are provided to a vaporizing portion of the recording material in such a manner that the pores be present within the layer of the recording material. The recording unit structure of the present invention assures a recording of excellent quality, is made compact and light weight, yields a high thermal efficiency, and produces no used ink sheets and other wastes. The present invention also relates to a recording device comprising the same.

Abstract: An optical device structure can be simplified and miniaturized on the whole. A fabrication of optical device can be simplified and the optical device can be improved in reliability. The optical device can increase its output, operate a light emitting light source with a reduced power and reduce a power consumption by increasing a quantity of reflected-back light to a photosensor device, i.e., a quantity of photosensed light. An optical device includes a light emitting section (1), a radiated section (2), a converging means (3) and a photosensor section (4). Light emitted from the light emitting section (1) is converged and radiated on the radiated section (2) by the converging means (3). Reflected-back light (L.sub.R) reflected from the radiated section (2) is converged and the photosensor section (4) is disposed near a confocal of the converging means (3) concerning reflected-back light from the radiated section (2).

Abstract: An optical device for detecting a magneto-optical signal can be simplified and miniaturized in arrangement. An optical device for detecting a magneto-optical signal includes an optical element (101) in which a light-emitting portion (4) and a light-receiving portion (5) are closely disposed on a common substrate and in which reflected-back light obtained from a magneto-optical medium (34) after light emitted from the light-emitting portion (4) was reflected on the magneto-optical medium (34) is detected at a position near confocal position by the light-receiving portion (5). The light-receiving portion (5) on the optical element (1) has a light-receiving surface inclined relative to the optical axis of the reflected-back light formed thereon so that the light-receiving portion has a polarization selective transmittance function on its surface. Thus, the reflected-back light from the magneto-optical medium (34) can be received and detected by the light-receiving portion (5) on the optical element (101).

Abstract: An optical device for detecting a magneto-optical signal can be simplified and miniaturized in arrangement. An optical device for detecting a magneto-optical signal includes an optical element in which a light-emitting portion and a light receiving portion are closely disposed on a common substrate and in which reflected-back light obtained from a magneto-optical medium after light from the light-emitting portion was reflected on the magneto-optical medium is detected at a position near confocal position by the light receiving portion and another light receiving element. The reflected-back light from the magneto-optical medium is divided. One reflected-back light is detected by the light receiving portion of the optical element 1 and the other reflected-back light is detected by another light receiving element.

Abstract: An incandescent lamp which is operable at about 200-275 V is obtainable by enclosing a filling composition consisting of about 80-95% by volume of krypton gas and about 5-20% by volume of nitrogen gas in a glass envelope bearing a tungsten filament and an inner volume of about 0.2-1.2 ml/operating wattage in an amount of about 0.7-0.9 ml/ml of the inner volume. The incandescent lamp exhibits satisfactory luminous characteristics and an extended life expectancy without causing arc discharge even when operated at a voltage of about 200-275 V. Thus a lighting device which comprises such an incandescent lamp as the luminous source and a power source capable of energizing it at a voltage of about 200-275 V is very useful in general and special illumination.

Abstract: A recording unit structure comprising a recording material layer faced to a recording body with a space incorporated therebetween, so that said recording material is vaporized and transferred to said recording body through said space, provided that pores are provided to a vaporizing portion of the recording material in such a manner that the pores be present within the layer of the recording material. The recording unit structure of the present invention assures a recording of excellent quality, is made compact and light weight, yields a high thermal efficiency, and produces no used ink sheets and other wastes. The present invention also relates to a recording device comprising the same.