Abstract: A device that differentiates a living body includes at least one transmission antenna element that transmits a transmission signal to a predetermined range including the living body, N receivers that are arranged to surround a periphery of the predetermined range and each receive N reception signals using respective reception antenna elements of the receivers during a predetermined period, the N reception signals including a reflection signal resulting from the transmission signal reflected off the living body, memory that stores a teacher signal, a circuit that calculates a plurality of correlation coefficients according to the teacher signal and the N reception signals received by the N receivers and determines that the living body and the subject living body are identical to each other when a predetermined correlation coefficient included in the plurality of correlation coefficients is included in a predetermined value range.

Abstract: A positioning sensor includes a transmission antenna transmitting a transmission signal, a plurality of reception antennae, each receiving a reception signals, a receiver observing the each of the plurality of reception signals in a predetermined period, a processor, and a memory, in which the processor calculates a plurality of complex transfer functions based on the each of the plurality of reception signals, records each of the plurality of complex transfer functions in the memory as being associated with each time point, extracts, among the plurality of complex transfer functions, a plurality of pairs of two complex transfer functions respectively corresponding to two time points in a predetermined interval, calculates a plurality of pieces of differential information, and estimates to a location of a moving body based on each of the plurality of pieces of differential information.

Abstract: There is provided an estimation device that estimates a living body orientation.

Abstract: w An estimation method is provided which includes: calculating a plurality of complex transfer functions, based on reception signals respectively received by N reception antenna elements during a predetermined period, the complex transfer functions each representing propagation characteristics between a transmission antenna element and the N reception antenna elements; extracting a variation component corresponding to each of the N reception antenna elements, from the calculated complex transfer functions, the variation component being caused by a living body; calculating a correlation matrix based on the variation component corresponding to each of the N reception antenna elements: calculating eigenvalues of the correlation matrix calculated in the calculating of the correlation matrix; and estimating the number of living bodies in a predetermined method, using the eigenvalues calculated in the calculating of the eigenvalues.

Abstract: An identification device includes: M transmission antenna elements each of which transmits a first transmission signal to a predetermined area including a first living body; N receivers disposed surrounding the predetermined area, and each including a reception antenna element and receiving, using the reception antenna element, a first reception signal including a reflection signal obtained as a result of the first transmission signal being reflected by the first living body, during a predetermined period; a memory storing teacher signals which are M×N second reception signals obtained about a second living body; and a circuit which calculates a plurality of correlation coefficients from the teacher signals and M×N first reception signals obtained as a result of each of the N receivers receiving the first reception signal, performs biometric authentication of the first living body, and identifies the first living body and the second living body as identical.

Abstract: A sensor includes a reception antenna, a parasitic antenna terminating in a variable load, a controller, a transmitter transmitting a transmission signal, a receiver, a memory, and a processor. The controller sets an impedance value of the variable load. The receiver receives a first signal formed of signals received by the antennas and derived from the transmission signal, and the signal received by the parasitic antenna corresponding to the impedance value. The memory stores a first signal strength value of the first signal corresponding to the impedance value. The processor sets candidates of a complex propagation channel, calculates second signal strength values of a second signal respectively corresponding to the candidates, estimates a target complex propagation channel by selecting a candidate corresponding to a minimum difference among differences between the first signal strength value and the second signal strength values, and estimates a direction of arrival of the first signal.

Abstract: A positioning sensor includes m receiving antennas connected to a feeder circuit and n variable loads, and a receiver that receives a first signal via the m receiving antennas. The positioning sensor further includes a memory that stores a first signal strength value of a first signal that the receiver receives when a variable load varies in value, and a processor that calculates a second signal strength value from a complex propagation channel, searches for a complex propagation channel candidate that has a minimum difference between a first signal strength and a second signal strength, determines the complex propagation channel candidate to be a complex propagation channel when the receiver receives the first signal, and estimates an incoming direction of the first signal from the determined complex propagation channel.

Abstract: A sensor includes at least one transmitting station including a transmission antenna; a plurality of receiving stations each including a reception array antenna; a first circuit that extracts, from signals observed by the reception array antenna of each of the plurality of receiving stations, living-body components, which are signal components transmitted from the transmission antenna and reflected by at least one living body; a second circuit that calculates, from the extracted living-body components, a plurality of position spectral functions, which are evaluation functions for evaluating a position of the at least one living body when viewed from the plurality of respective receiving stations; and a third circuit that integrates the plurality of calculated position spectral functions into one position spectral function, and calculates at least one maximum value of the position spectral function obtained as a result of integration to estimate the position of the at least one living body.

Abstract: A sensor includes: a transmitting antenna with N transmitting antenna elements transmitting transmission signals; a receiving antenna with M receiving antenna elements, each receiving N received signals including a reflection signal generated by the living body reflecting part of the N transmission signals; a circuit; and a memory. The circuit extracts a second matrix corresponding to a specified frequency range from an N×M first matrix calculated from each received signal and indicating a propagation property between each transmitting antenna element and each receiving antenna element, estimates the position where the living body is present using the second matrix, calculates a radar cross-section (RCS) value of the living body based on the estimated position and the positions of the transmission and receiving antennas, and estimates the motion of the living body using the calculated RCS value and information indicating correspondence between RCS values and motions of the living body.

Abstract: A device that differentiates a living body includes at least one transmission antenna element that transmits a transmission signal to a predetermined range including the living body, N receivers that are arranged to surround a periphery of the predetermined range and each receive N reception signals using respective reception antenna elements of the receivers during a predetermined period, the N reception signals including a reflection signal resulting from the transmission signal reflected off the living body, memory that stores a teacher signal, a circuit that calculates a plurality of correlation coefficients according to the teacher signal and the N reception signals received by the N receivers and determines that the living body and the subject living body are identical to each other when a predetermined correlation coefficient included in the plurality of correlation coefficients is included in a predetermined value range.

Abstract: A sensor includes a transmit antenna, a receive antenna, circuitry, and a memory. The transmit antenna includes N transmit antenna elements each transmitting a transmit signal. The receive antenna includes M receive antenna elements each receiving N receive signals including reflection signals reflected by an organism. The circuitry extracts a second matrix corresponding to a predetermined frequency range from an N×M first matrix representing propagation characteristics between each transmit antenna element and each receive antenna element calculated from the receive signals. The circuitry estimates the position of the organism by using the second matrix, and calculates a radar cross-section value with respect to the organism, based on the estimated position and the positions of the transmit antenna and the receive antenna.

Abstract: A positioning sensor includes a transmission antenna transmitting a transmission signal, a plurality of reception antennae, each receiving a reception signals, a receiver observing the each of the plurality of reception signals in a predetermined period, a processor, and a memory, in which the processor calculates a plurality of complex transfer functions based on the each of the plurality of reception signals, records each of the plurality of complex transfer functions in the memory as being associated with each time point, extracts, among the plurality of complex transfer functions, a plurality of pairs of two complex transfer functions respectively corresponding to two time points in a predetermined interval, calculates a plurality of pieces of differential information, and estimates to a location of a moving body based on each of the plurality of pieces of differential information.

Abstract: A sensor includes a reception antenna, a parasitic antenna terminating in a variable load, a controller, a transmitter transmitting a transmission signal, a receiver, a memory, and a processor. The controller sets an impedance value of the variable load. The receiver receives a first signal formed of signals received by the antennas and derived from the transmission signal, and the signal received by the parasitic antenna corresponding to the impedance value. The memory stores a first signal strength value of the first signal corresponding to the impedance value. The processor sets candidates of a complex propagation channel, calculates second signal strength values of a second signal respectively corresponding to the candidates, estimates a target complex propagation channel by selecting a candidate corresponding to a minimum difference among differences between the first signal strength value and the second signal strength values, and estimates a direction of arrival of the first signal.

Abstract: A light-beam therapeutic apparatus for ensuring patient safety. The light-beam therapeutic apparatus includes an apparatus body portion having a light source; a light guide rod that guides light from the light source, a connecting socket, a cooling fan, an electronic component that performs control required for a therapy, and a control display panel that displays contents of the therapy; a therapeutic portion including a light guide portion including a plurality of bundled optical fibers, and a pad portion formed of the optical fibers spread out adjacently to one another into a flat-panel shape. The therapeutic portion is formed into a light-receiving plug that is insertable into a connecting socket of the apparatus body portion. The light-receiving plug is configured to be kept in a coupled state by an attracting action of a permanent magnet provided on a side of the connecting socket.

Abstract: A light-beam therapeutic apparatus used for a therapy for neonatal hyperbilirubinemia is disclosed, which includes an apparatus body portion having a light source; a light guide rod that guides light from the light source, a connecting socket, a cooling fan, an electronic component that performs control required for a therapy, and a control display panel that displays the contents of therapy; a therapeutic portion including a light guide portion including a plurality of bundled optical fibers, and a pad portion formed of the optical fibers spread out adjacently to one another into a flat-panel shape, and the therapeutic portion is formed into a light-receiving plug insertable into a connecting socket of the apparatus body portion, and the optical fibers positioned on the pad portion are subjected to exposing processing and have a protecting surface layer portion formed of a bag member filled with transparent and highly flexible high-molecular gel.

Abstract: A light-emitting diode (LED) therapeutic apparatus includes a body portion formed of a light-weight resin material into a rectangular housing; a printed circuit board including a plurality of LEDs having different emission colors mounted linearly in a plurality of rows at required intervals; a thermal radiating plate provided with a plurality of thermal radiating studs formed of a light-weight thermally conductive material; and a transparent plate mounted on an opening surface of the body portion. The thermal radiating plate is mounted in tight contact in the body portion, and the printed circuit board is mounted in tight contact with the heat radiating studs. The heat generated by the LEDs is radiated from the surface of the body portion via the thermal radiating plate from the thermal radiating studs. The LEDs may be maintained to a junction allowable temperature or lower so that a long life span without noise is achieved.

Abstract: A hand insertion door board is attached to the peripheral portion of each hand insertion window formed in an outside portion of a newborn infant container of an incubator. A holding portion is formed on one side portion of the hand insertion door board in the lateral direction. A bracket which pivotally supports a support shaft having a vertical axis is attached to the holding portion. A latch lever is pivotally supported by the support shaft of the bracket. A press lever which releases latching operation of the latch lever is pivotally attached by using the support shaft of the bracket. When the press lever is pressed against the biasing force of a compression coil spring, the press lever presses projecting pieces of the latch lever to make the latch lever pivot about the support shaft to the release position.

Abstract: A light-beam therapeutic apparatus ensured patient safety is disclosed, which includes an apparatus body portion having a light source; a light guide rod that guides light from the light source, a connecting socket, a cooling fan, an electronic component that performs control required for a therapy, and a control display panel that displays the contents of therapy; a therapeutic portion including a light guide portion including a plurality of bundled optical fibers, and a pad portion formed of the optical fibers spread out adjacently to one another into a flat-panel shape, wherein the therapeutic portion is formed into a light-receiving plug insertable into a connecting socket of the apparatus body portion, and the light-receiving plug is configured to be kept in a coupled state by an attracting action of a permanent magnet provided on the side of the connecting socket.

Abstract: A light-beam therapeutic apparatus used for a therapy for neonatal hyperbilirubinemia is disclosed, which includes an apparatus body portion having a light source; a light guide rod that guides light from the light source, a connecting socket, a cooling fan, an electronic component that performs control required for a therapy, and a control display panel that displays the contents of therapy; a therapeutic portion including a light guide portion including a plurality of bundled optical fibers, and a pad portion formed of the optical fibers spread out adjacently to one another into a flat-panel shape, and the therapeutic portion is formed into a light-receiving plug insertable into a connecting socket of the apparatus body portion, and the optical fibers positioned on the pad portion are subjected to exposing processing and have a protecting surface layer portion formed of a bag member filled with transparent and highly flexible high-molecular gel.

Abstract: An LED therapeutic apparatus is disclosed, which includes a body portion formed of a light-weight resin material into a rectangular housing; a printed circuit board including a plurality of LEDs having different emission colors mounted linearly in a plurality of rows at required intervals; a thermal radiating plate provided with a plurality of thermal radiating studs formed of a light-weight thermally conductive material; and a transparent plate mounted on an opening surface of the body portion. The thermal radiating plate is mounted in tight contact in the body portion, and the printed circuit board is mounted in tight contact with the heat radiating studs. The heat generated by the LEDs is radiated from the surface of the body portion via the thermal radiating plate from the thermal radiating studs. The LEDs may be maintained to a junction allowable temperature or lower, and the long life span without noise is achieved.