Abstract: For a plurality of combinations of a plurality of operating states included in an operating range of an engine and for a plurality of combinations of a plurality of objective variables, a system, which calculates design variables, includes a calculating device for obtaining global optimal solutions of the design variables that minimize or maximize a sum of the plurality of objective variables, which respectively correspond to the plurality of combinations of the plurality of operating states; a receiving device for receiving designation of an upper limit or a lower limit of the plurality of objective variables; and a searching device for searching for global optimal solutions that result in the smoothest change in the design variables when changing the operating states in a range of the received upper limit to the received lower limit of the objective variables, with one of the global optimal solutions as an initial value set.

Abstract: There is provided a current measuring apparatus that measures an electric current received by an electronic device from an input terminal, The current measuring apparatus includes a first voltage accumulator that accumulates a reference supply voltage that acts as a reference for a voltage being supplied to the electronic device during measuring electric currents, a first switch that connects a power supply to the first voltage accumulator to accumulate the reference supply voltage before measuring electric currents and disconnects the power supply from the first voltage accumulator during measuring electric currents, a current supplying section that supplies an electric current based on the reference supply voltage accumulated in the first voltage accumulator and a terminal voltage of the input terminal to the electronic device during measuring electric currents, and a first current measuring section that measures the supply current supplied to the electronic device.

Abstract: There is provided a test apparatus for testing a device under test, which includes a voltage supplying section which supplies a voltage to the device under test through a wire, a first capacitor which is arranged between the wire and a common potential in series, a current detecting section which detects a current flowing through the wire at a location closer to the device under test than the first capacitor is, an integrating section which outputs an integration value obtained by integrating a difference between the current detected by the current detecting section and a predetermined reference current, and a judging section which judges whether the device under test is a pass or a failure based on the integration value.

Abstract: There is provided a test apparatus for testing a device under test, which includes a voltage supplying section that supplies a voltage to the device under test through a wire, a first capacitor that is arranged between the wire and a common potential in series, a current detecting section that detects a current flowing through the wire at a location closer to the device under test than the first capacitor is, an integrating section that outputs an integration value obtained by integrating a difference between the current detected by the current detecting section and a predetermined reference current, and a judging section that judges whether the device under test is a pass or a failure based on the integration value.

Abstract: There is provided a current measuring apparatus that measures an electric current received by an electronic device from an input terminal, The current measuring apparatus includes a first voltage accumulator that accumulates a reference supply voltage that acts as a reference for a voltage being supplied to the electronic device during measuring electric currents, a first switch that connects a power supply to the first voltage accumulator to accumulate the reference supply voltage before measuring electric currents and disconnects the power supply from the first voltage accumulator during measuring electric currents, a current supplying section that supplies an electric current based on the reference supply voltage accumulated in the first voltage accumulator and a terminal voltage of the input terminal to the electronic device during measuring electric currents, and a first current measuring section that measures the supply current supplied to the electronic device.

Abstract: A method, computer, and recording medium storing a program are provided which, based on local optimal solutions, more efficiently calculate an optimal global optimal solution in a global operating area. System calculates the global optimal solution by solving, using a genetic algorithm based on the local optimal solutions and the initial values, an equation, which should be satisfied by the plurality of design variables, by obtaining the plurality of combinations of design variables composing local optimal solutions for each design variable respectively calculated for each of a plurality of combinations of a plurality of operating states, and by obtaining initial values for the plurality of combinations of design variables used for calculating the global optimal solution.

Abstract: A current measuring apparatus for measuring a power supply current received by an electronic device includes: a first current supplying unit for outputting a first current which is a part of the power supply current; a smoothing capacitor for smoothing the first current output by the first current supplying unit connected with one end thereof; a capacitor of device side for smoothing the power supply current, electrostatic capacity of the capacitor of device side being smaller than that of the smoothing capacitor and one end of the capacitor of device side being connected with the electronic device; a switch for making the first current flow from the smoothing capacitor to the capacitor of device side in case of being ON; a second current supplying unit for outputting a second current smaller than the first current to the capacitor of device side via a path parallel to the switch; and a power supply current acquiring unit for acquiring the power supply current on the basis of the second current output by the

Abstract: A power supply device for supplying source current to an electronic device comprises: a current output unit for outputting output current including at least the source current as a component of the current thereof; a connection resistor which electrically connects the current output unit and the electronic device for supplying the source current to the electronic device; a low-pass filter for allowing the output voltage of the current output unit to pass through; a differential detection unit for detecting the electric potential difference between the output voltage of the low-pass filter and the electric potential at the device-side terminal of the connection resistor; and a parallel load unit which is connected to the output terminal of the current output unit in parallel with the connection resistor, and which has a function of consuming a partial current which is a part of the output current of the current output unit in a case that the electric potential difference detected by the differential detection

Abstract: An optical component comprises an optical transmission element (e.g., an optical lens) whose circumferential wall partially joins a metal holder via a joining material (e.g., a low melting point glass), wherein stress is normally applied to the optical transmission element in a compression direction when joining the metal holder. The optical transmission element is inserted into a through hole of the metal holder, and the joining material is kept in a bank actualized by a tapered portion formed in proximity to one end of the through hole of the metal holder. This prevents tensile stress from being applied to the optical transmission element; thus, it is possible to avoid the occurrence of cracks and separations in the optical transmission element; and it is possible to avoid the occurrence of errors in optical characteristics, regardless of variations of the environmental temperature, so that, the optical component is improved in reliability.

Abstract: A method for generating a carrier residual signal and its device, in which a heterodyne optical signal used in a photometric field or an optical fiber radio communication field can be stably generated with a simplified structure. The device includes an optical modulating unit that includes a light source generating a light wave having a specific wavelength, and an SSB optical modulator. A light wave emitted from the light source enters into the optical modulating unit. A light wave emitted from the optical modulating unit includes a carrier component related to a zero-order Bessel function and a specific signal component related to a specific high-order Bessel function while suppressing signal components other than the specific signal component related to the specific high-order Bessel function, and a ratio of optical intensity between the carrier component and the specific signal component is set substantially to 1.

Abstract: Provided is a power supply apparatus including: a connection resistance that supplies a power supply current of an electronic device to the electronic device; a low pass filter that allows passage of an output voltage of a power current output section; a parallel load section that consumes a partial power current being a part of the output power current when receiving a power current decrease signal and stops receiving the partial power current when receiving a power current increase signal; an offset adder section that outputs a voltage obtained by adding an offset voltage to the output voltage of the low pass filter; and a difference detection section that supplies the power current increase signal to the parallel load section while a potential of a device side end of the connection resistance is smaller than a reference voltage obtained by subtracting a reference potential difference from the output voltage of the offset adder section, and supplies the power current decrease signal to the parallel load sec

Abstract: In a radio optical fusion communication system with the integration of an optical fiber transmission path and a radio propagation path, wherein by first and second light sources, an intermediate-frequency signal generating means for generating a modulating signal at an intermediate frequency band, a modulator for modulating an optical signal from the first light source into an SSB modulated optical signal using the intermediate-frequency signal, and an optical mixer for mixing the modulated optical signal with the optical signal from the second light source to obtain an optical transmission signal in a base station, the frequency of either of the optical signals is controlled such that the difference in frequency between the optical signals is a desired frequency of a modulated radio signal, thus switching the frequency channel of the modulated radio signal in the radio propagation path.

Abstract: An optical modulator is provided which includes: an optical splitting part that splits an input light wave into two light waves; two optical waveguides that propagate the two light waves into which the input light wave is split, respectively; a first SSB modulating part that is provided in one of the two optical waveguides and modulates a light wave, which propagates into the first SSB modulating part, with a carrier frequency so that the light wave is converted into a different light wave having a single side band; a second SSB modulating part that is provided in the other of the two optical waveguides and modulates a light wave, which propagates into the second SSB modulating part, with a data signal in order to generate a signal light wave having a different single side band; and an optical combining part that combines the light wave modulated by the first SSB modulating part with the signal light wave generated by the second SSB modulating part.

Abstract: Microorganism sensors used in environment assessment technologies and the like, instead of being used to detect environmental components and determine their concentrations, were used as tools to evaluate the ability of target soil microorganisms to adapt to various field soil environments, and comparative studies were performed. As a result, the present inventors found that by using the microorganism sensors to examine the growth potential of general soil microorganisms and pathogenic microorganisms in ecosystems, the balance in the soil ecosystems could be monitored, and further, the risk of disease occurrence and the bio-controlling effect of general soil microorganisms could also be determined.

Abstract: A particle monitoring device includes a light source for emitting a measurement light; and a light projecting/receiving unit, connected to a depressurized vessel of a processing apparatus, for projecting the emitted measurement light into the depressurized vessel and receiving a scattered light from a particle floating in the depressurized vessel. The light projecting/receiving unit is disposed such that the scattered light is received substantially parallel to the measurement light. The particle monitoring device further includes a received light intensity detection unit. The received light intensity detection unit has a received light intensity detection unit for determining whether or not the detected intensity is greater than a predetermined value and an instruction unit for instructing the processing apparatus to start, continue or stop a processing operation of the processing apparatus depending on the determined result.

Abstract: A method and device for adequately controlling the DC bias of each of the optical modulating sections of an optical modulator even while the optical modulator is operating in normal mode and even with a simple structure.

Abstract: There is provided a semiconductor testing apparatus comprising a current measuring portion which converts a load current quantity at the time of application of a relatively high test voltage to a DUT to fall within a low-voltage range, and then subjects the low-voltage range to quantization conversion with a predetermined measurement resolution even when the relatively high test voltage is applied to the DUT.

Abstract: A testing device that tests an electronic device includes a detection-voltage outputting unit operable to output a current detection voltage based on a power source current that the electronic device receives from a power source, a transmission line operable to transmit the current detection voltage, a detection amplifier operable to output an amplifier output voltage based on the current detection voltage received through the transmission line, a switching unit operable to select whether the current detection voltage is supplied to the detection amplifier, an integrator operable to output an integral value that is obtained by integrating values based on the amplifier output voltage, and a decision unit operable to decide whether the electronic device is good or bad based on the integral value.

Abstract: A first branched optical waveguide and a second branched optical waveguide, to constitute a Mach-Zehnder type optical waveguide, are formed at the surface of a substrate. A first ground electrode, a signal electrode and a second ground electrode are provided on a buffer layer formed on the substrate. The second ground electrode is partially cut away and divided, to form a ditch therein, so that the modulating electrode composed of the signal electrode, the first and the second ground electrodes are substantially symmetrized on the center line between the first and the second optical waveguides. Then, the ratio (d2/d1) of the distance d2 between the signal electrode and the second branched optical waveguide to the distance d1 between the signal electrode and the first electrode is set within 3.5–7.5.

Abstract: A power supply device for supplying source current to an electronic device comprises: a current output unit for outputting output current including at least the source current as a component of the current thereof; a connection resistor which electrically connects the current output unit and the electronic device for supplying the source current to the electronic device; a low-pass filter for allowing the output voltage of the current output unit to pass through; a differential detection unit for detecting the electric potential difference between the output voltage of the low-pass filter and the electric potential at the device-side terminal of the connection resistor; and a parallel load unit which is connected to the output terminal of the current output unit in parallel with the connection resistor, and which has a function of consuming a partial current which is a part of the output current of the current output unit in a case that the electric potential difference detected by the differential detection