Abstract: A blood flow index calculating method includes: obtaining, by a camera, an image capturing a first site of a living body and a second site of the living body; extracting an area of the first site of the living body and an area of the second site of the living body, by a processor; detecting a pulse wave pattern of the first site of the living body from the area of the first site of the living body and detecting a pulse wave pattern of the second site of the living body from the area of the second site of the living body, by the processor; first calculating a delay amount from the pulse wave pattern of the first site and the pulse wave pattern of the second site, by the processor; and second calculating an index related to blood flow by using the delay amount, by the processor.

Abstract: A pulse wave detection method includes obtaining an image obtained by photographing a subject with an imaging device, extracting intensities representative of signal components of a specific frequency band for respective wavelength components among signals of a plurality of wavelength components included in the image, calculating, using the intensities extracted for the respective wavelength components, a weight coefficient by which a signal is multiplied when the signals are calculated between the wavelength components to minimize an arithmetic value of the signal components in the specific frequency band after multiplication, multiplying at least one of the signals of the respective wavelength components by the weight coefficient, performing arithmetic operation on the signals between the wavelength components after multiplication by the weight coefficient, and detecting pulse waves of the subject using a signal after the arithmetic operation.

Abstract: A blood flow index calculating method includes: obtaining, by a camera, an image capturing a first site of a living body and a second site of the living body; extracting an area of the first site of the living body and an area of the second site of the living body, by a processor; detecting a pulse wave pattern of the first site of the living body from the area of the first site of the living body and detecting a pulse wave pattern of the second site of the living body from the area of the second site of the living body, by the processor; first calculating a delay amount from the pulse wave pattern of the first site and the pulse wave pattern of the second site, by the processor; and second calculating an index related to blood flow by using the delay amount, by the processor.

Abstract: A pulse wave detection method includes obtaining an image obtained by photographing a subject with an imaging device, extracting intensities representative of signal components of a specific frequency band for respective wavelength components among signals of a plurality of wavelength components included in the image, calculating, using the intensities extracted for the respective wavelength components, a weight coefficient by which a signal is multiplied when the signals are calculated between the wavelength components to minimize an arithmetic value of the signal components in the specific frequency band after multiplication, multiplying at least one of the signals of the respective wavelength components by the weight coefficient, performing arithmetic operation on the signals between the wavelength components after multiplication by the weight coefficient, and detecting pulse waves of the subject using a signal after the arithmetic operation.

Abstract: A positioning and ranging system includes a transmitter transmits a plurality of impulses; and a receiver receives the impulses; the receiver includes an initial detection unit records a sensing time of a first impulse among a plurality of impulses transmitted by the transmitter; a sensing margin detection unit for detecting a sensing margin being a difference between a field intensity of the first impulse and a reception limit field intensity of the receiver; a correction unit identifies a sensing error differential time based on a given relationship between the sensing margin and the sensing error differential time, and corrects the sensing time detected by the initial detection unit using the identified sensing error differential time; the system measures a distance between the transmitter and the receiver and a position of the transmitter based on a time the transmitter transmits the first impulse and a time the receiver receives the impulse.

Abstract: A positioning and ranging system includes a transmitter transmits a plurality of impulses; and a receiver receives the impulses; the receiver includes an initial detection unit records a sensing time of a first impulse among a plurality of impulses transmitted by the transmitter; a sensing margin detection unit for detecting a sensing margin being a difference between a field intensity of the first impulse and a reception limit field intensity of the receiver; a correction unit identifies a sensing error differential time based on a given relationship between the sensing margin and the sensing error differential time, and corrects the sensing time detected by the initial detection unit using the identified sensing error differential time; the system measures a distance between the transmitter and the receiver and a position of the transmitter based on a time the transmitter transmits the first impulse and a time the receiver receives the impulse.

Abstract: The present invention provides an electronic device and the like that can prevent the leakage of information related to a display image through an observation signal of an electromagnetic signal emitted from an electronic device or the like. The electronic device (10) includes a display control unit (11a) that causes a display unit (15) to display a display image that has been formed based on information, and a modification control unit (11b) that performs modification processing on a modification-target image element specified by a character code or vector information included in the information. The display control unit (11a) causes the display unit (15) to display the display image after the modification processing has been performed on the modification-target image element by the modification control unit (11b).

Abstract: To realize variable control of the output value of impulses with a simple construction, the present device includes an impulse generating unit which generates impulses; and a control unit which controls an output value of impulses output from the impulse generating unit by changing an input signal that is input to the impulse generating unit for generating impulses.

Abstract: An item display device displays numeric buttons on a screen using an ordinary format, but a numeric button that has been operated by a user is temporarily highlighted. When reverting to ordinary display after a fixed amount of time has elapsed, the device first displays all numeric buttons using an intermediate format, then highlights the operated numeric button, while displaying the other numeric buttons using the ordinary format. All numeric buttons are again displayed using the intermediate format, and then all numeric buttons are reverted to ordinary display. Moreover, a difference in the numeric button display colors between the ordinary display and the intermediate format is equal to a difference in the numeric button display colors between the highlighted display and the intermediate format. In so doing, snooping by detection of intensity differences in electromagnetic waves leaking from the screen display is prevented.

Abstract: A radio positioning system includes a plurality of base stations, each receiving a radio wave from a mobile terminal, and including a first base station whose position coordinates are known and a second base station whose position coordinates are unknown. The system also includes a distance measuring unit that measures a distance between the first and the second base stations based on the exchanging the radio waves; a position-coordinate calculating unit that calculates position coordinates of the second base station based on the measured distances; a determination control unit that determines a time reference station out of the base stations, and controls the time reference station to transmit a time reference pulse; and a distance-measurement control unit that calculates, using the time difference, a time difference between reception times of the wave signal at the base stations, and calculates position coordinates of the mobile terminal based on the time difference.

Abstract: The communication apparatus employing the non-coherent scheme is used in the UWB-impulse radio system. In order to make it possible to reliably realize long-distance communication, while observing the reference values of the average radiation power and the peak radiation power, and also to realize high-speed short-distance communication, the apparatus includes an impulse adjusting unit which adjusts, according to the distance between two communication apparatuses detected by the distance detecting unit, the amplitude and the repetition frequency of impulses used in radio communication between the two communication apparatuses.

Abstract: To realize variable control of the output value of impulses with a simple construction, the present device includes an impulse generating unit which generates impulses; and a control unit which controls an output value of impulses output from the impulse generating unit by changing an input signal that is input to the impulse generating unit for generating impulses.

Abstract: An ultrasonic length measuring apparatus measures the number of times a waveform of an ultrasonic wave signal crosses a threshold value, detects the crossing timing at, for example, a waveform having a maximal amplitude after a predetermined number of times counting from a first crossing point, measures the time period from the transmission start of the ultrasonic wave by the transmission unit to the detected crossing timing and calculates the length based on the time measured. A coordinate inputting apparatus includes a pen for transmitting an ultrasonic wave and a coordinate inputting apparatus for inputting coordinate positions of the pen based on a propagation time of the ultrasonic wave transmitted by the pen and received by a plurality of ultrasonic wave receivers. The receiver includes at least a pair of ultrasonic receivers for receiving the ultrasonic wave transmitted by the pen.

Abstract: An ultrasonic coordinate input apparatus identifies using ultrasonic waves whether an input pen contacts a handwriting surface or it is held in the air within a predetermined distance, and can input not only a contact input locus but also an aerial movement locus. A receiver of the ultrasonic coordinate input apparatus is fixed to any of the four corners of the handwriting surface in an appropriate method. Infrared and ultrasonic waves are transmitted respectively from an Infrared transmitting unit and an ultrasonic transmission unit of the input pen being used at predetermined intervals. A distance detection unit of the receiver computes and inputs the contact movement locus or the aerial movement locus of the point of the input pen to the handwriting surface using the ultrasonic waves detected by two ultrasonic sensors only when the infrared from the input pen is received at 90° in the horizontal direction and 10° in the vertical direction.

Abstract: In the present invention, two ultrasonic receivers are provided in common for plural input planes, and the plural input planes are restricted to a plane not perpendicular to a line connecting the two ultrasonic receivers, so that the sufficiently practicable coordinate input device can be provided. When the line connecting two ultrasonic receivers is perpendicular to the input plane, the distances from the input device to the two ultrasonic receivers exist in plural sets, so that the coordinates of an input device cannot be specified. Furthermore, in order to acquire the coordinates of the input device by the two ultrasonic receivers, a positional relations between the two ultrasonic receivers and the input planes are made initial setting in advance. When set in advance, it is possible to acquire the position of the input devices in the plural input planes from the distance from input device to two ultrasonic receivers.

Abstract: An ultrasonic length measuring apparatus measures the number of times of crossing of the waveform of an ultrasonic wave signal with the threshold value, detects the crossing timing at, for example, the waveform having the maximal amplitude after a predetermined number of times counting from a crossing point crossing first, measures the time period from the transmission start of the ultrasonic wave by the transmission unit to the detected crossing timing and calculates the length based on the time measured. A coordinate inputting apparatus comprises a pen for transmitting an ultrasonic wave and a coordinate inputting apparatus for inputting coordinate positions of the pen based on a propagation time of the ultrasonic wave transmitted by the pen and received by a plurality of ultrasonic wave receivers and the receiver comprises at least a pair of ultrasonic receivers for receiving the ultrasonic wave transmitted by the pen and a clip mechanism for pinching a corner of a sheet.

Abstract: A device for measuring an electric current of a target circuit includes a pair of contact pins, a resistor electrically connected between the contact pins, a voltage drop appearing across the resistor when the contact pins come into contact with the target circuit to direct the electric current to the resistor, and an electro-optical crystal electrically connected between the contact pins in parallel with the resistor, the electro-optical crystal having a voltage applied thereto responsive to the voltage drop appearing across the resistor, wherein the voltage applied to the electro-optical crystal changes polarization of a light beam passing therethrough, thereby allowing the electric current to be measured from the polarization.

Abstract: In the present invention, two ultrasonic receivers are provided in common for plural input planes, and the plural input planes are restricted to a plane not perpendicular to a line connecting the two ultrasonic receivers, so that the sufficiently practicable coordinate input device can be provided. When the line connecting two ultrasonic receivers is perpendicular to the input plane, the distances from the input device to the two ultrasonic receivers exist in plural sets, so that the coordinates of an input device cannot be specified. Furthermore, in order to acquire the coordinates of the input device by the two ultrasonic receivers, a positional relations between the two ultrasonic receivers and the input planes are made initial setting in advance. When set in advance, it is possible to acquire the position of the input devices in the plural input planes from the distance from input device to two ultrasonic receivers.

Abstract: It is an object of the present invention to provide a circuit board trimming apparatus and method used, in which apparatus and method a wiring pattern on a printed circuit board is trimmed, and to provide a circuit board trimming apparatus and method, in which apparatus and method a wiring pattern is trimmed efficiently while damage to the circuit board is minimized.A force exerted by a cutter against the circuit board is measured when the wiring pattern is cut by pressing an ultrasonic cutter against the wiring pattern on the circuit board and by moving the circuit board and the cutter relative to each other, a shape of the wiring pattern being determined on the basis of the force thus measured and a cutting process being controlled in accordance with the shape of the wiring pattern.

Abstract: A vertical stepper transfers a circuit pattern formed on a mask onto a wafer using synchrotron radiation instead of a light source. The vertical stepper includes a wafer stage for having the wafer mounted thereon in the vertical direction and a mask stage for having the mask mounted thereon in the vertical direction. The wafer stage includes a coarse X-Y stage, a transfer member, and a wafer mounting member. The wafer mounting member is provided with a fine X-Y stage. The wafer mounting member is moved in the horizontal direction between a first position mounted on the coarse X-Y stage and a second position mounted on the mask stage by the transfer member. When exposed to the synchrotron radiation, the wafer mounting member is integrated with the mask stage. After the wafer and the mask are strictly correctly positioned by the fine X-Y stage, the wafer mounting member, integrated with the mask stage, is stepped and repeat exposed by scanning in the vertical direction.