Abstract: A control output signal is supplied to a gate electrode of the transistor which is an insulated gate transistor from a control signal output terminal of a control device, however, with regard to the insulated gate transistor, a control output signal is also influenced when that transistor is short-circuited, and a signal waveform different from that in a normal operating state occurs. With employing this, the short-circuit is detected by monitoring the control output signal of the insulated gate transistor, and in case of the short-circuit, the short-circuit protection of the insulated gate transistor is performed by forcing the control device to stop that control output signal.

Abstract: An electrode 4 for detecting a biological signal and a loop antenna 3 are integrally mounted on a support 2 placed on the surface of a living body and a transmitter 5 is placed on the support 2. A biological signal detected on the electrode 4 is input through a connector 11 to electric circuitry 10 of the transmitter 5 and an electric signal processed by the electric circuitry 10 is output through connectors 12 and 13 to both ends of the loop antenna 3 from which the biological signal is emitted to a receiver. At this time, the opening face of the loop antenna 3 is in a direction almost perpendicular to the surface of a living body for improving sensitivity.

Abstract: A communication system has a Holter electrocardiograph having a biological signal detection apparatus having a transmitter 10 for processing and telemetering signals detected by a plurality of electrodes supported on supports for detecting biological signals, a receiver 14 for receiving the signal telemetered from the transmitter, demodulating the received signal, and outputting the demodulated signal to a biological signal input section of required record means, and a recorder 16 having record means for recording the demodulated signal by the receiver. The recorder of the Holter electrocardiograph has transmitting and receiving means 17 for telemetering the signal stored in the record means, receiving an external transmission signal, and telemetering some or all of the signals stored in the record means as instructed by the external transmission signal.

Abstract: An electrode 4 for detecting a biological signal and a loop antenna 3 are integrally mounted on a support 2 placed on the surface of a living body and a transmitter 5 is placed on the support 2. A biological signal detected on the electrode 4 is input through a connector 11 to electric circuitry 10 of the transmitter 5 and an electric signal processed by the electric circuitry 10 is output through connectors 12 and 13 to both ends of the loop antenna 3 from which the biological signal is emitted to a receiver. At this time, the opening face of the loop antenna 3 is in a direction almost perpendicular to the surface of a living body for improving sensitivity.

Abstract: A pulse generation part outputs a first ON pulse signal for turning a switching device on to a control part on based on the leading edge of a signal from the outside of a semiconductor device. The pulse generation part subsequently outputs a second ON pulse signal for turning the switching device on to the control part based on the same leading edge of the signal as the first ON pulse signal after a lapse of prescribed time after outputting the first ON pulse signal. Even if the control part cannot output an ON signal to the switching device based on the first ON pulse signal, the control part can output an ON signal based on the second ON pulse signal.

Abstract: As devices are often different in the characteristics from one another, semiconductor chips based on the devices have discrepancies in the performance. A semiconductor device having a semiconductor switching element and a drive controlling means (1) for generating from input signals (A) and (B) drive signals (a) and (b) to control the action of the semiconductor switching element is provided comprising a characteristic compensating means (2) for generating from a characteristic compensation input signal a compensation signal to eliminate variations in the transmission delay time of the drive controlling means (1).

Abstract: A comparator compares the voltage of a shunt resistor, detected by a current detection terminal, with a reference voltage and supplies a current abnormality signal to a fault circuit when the voltage of the shunt resistor is in excess of the reference voltage. A stop signal is then supplied to a power device driving circuit and an input circuit. In response to the received stop signal, the power device driving circuit and another power device driving circuit stop operation of transistors respectively. The fault circuit, which is capable of outputting the stop signal through a fault terminal, is also able to receive a stop signal output from another control circuit and supply the stop signal to the power device driving circuit and the input circuit. Thus, the circuitry of an inverter module having a protective function is simplified, and the module is able to be miniaturized.

Abstract: The module-type connector according to the present invention defines the connectable connectors with a rigid supporting plate which extends along the connecting direction in order to make it easy to properly fit a male connector to a female connector. In the module-type connector, the contacting portions of the contacts that are shifted in the separation direction of the corresponding terminal with which the contacting portions contact are almost uniformly distributed. Further, the male connector that receives a preliminary load from different levels in the direction so that opposing elastic contacting portions are widened by engaging between the first end portion of each contact within a housing and the different levels of the housing, has at least a protruding portion that protrudes from the contacting surface of the plurality of contacts toward the contacting surface thereof and that is provided between contacts.

Abstract: In an interface between a high-active driving circuit for driving a predetermined semiconductor power element and a microcomputer for controlling an output signal of the driving circuit, the microcomputer comprises a transistor, a collector terminal of which is an output side of the microcomputer; and the driving circuit comprises a first resistor, one end of which is directly connected with the output side of the microcomputer; a Schmidt circuit which is connected in series with the other end of the first resistor; a diode, an anode side of which is connected to a path between the first resistor and the Schmidt circuit; a power supply voltage connected with a cathode side of the diode; and a second resistor, one end of which is grounded and the other end of which is connected with a side of the first resistor being an input terminal of the driving circuit.

Abstract: As devices are often different in the characteristics from one another, semiconductor chips based on the devices have discrepancies in the performance.

Abstract: As devices are often different in the characteristics from one another, semiconductor chips based on the devices have discrepancies in the performance.

Abstract: As devices are often different in the characteristics from one another, semiconductor chips based on the devices have discrepancies in the performance.

Abstract: In an interface between a high-active driving circuit for driving a predetermined semiconductor power element and a microcomputer for controlling an output signal of the driving circuit, the microcomputer comprises a transistor, a collector terminal of which is an output side of the microcomputer; and the driving circuit comprises a first resistor, one end of which is directly connected with the output side of the microcomputer; a Schmidt circuit which is connected in series with the other end of the first resistor; a diode, an anode side of which is connected to a path between the first resistor and the Schmidt circuit; a power supply voltage connected with a cathode side of the diode; and a second resistor, one end of which is grounded and the other end of which is connected with a side of the first resistor being an input terminal of the driving circuit.

Abstract: The module-type connector according to the present invention defines the connectable connectors with a rigid supporting plate which extends along the connecting direction in order to make it easy to properly fit a male connector to a female connector. In the module-type connector, the contacting portions of the contacts that are shifted in the separation direction of the corresponding terminal with which the contacting portions contact are almost uniformly distributed. Further, the male connector that receives a preliminary load from different levels in the direction so that opposing elastic contacting portions are widened by engaging between the first end portion of each contact within a housing and the different levels of the housing, has at least a protruding portion that protrudes from the contacting surface of the plurality of contacts toward the contacting surface thereof and that is provided between contacts.

Abstract: A comparator compares the voltage of a shunt resistor detected by a current detection terminal with a reference voltage and supplies a current abnormality signal to a fault circuit when the voltage of the shunt resistor is in excess of the reference voltage, so that a stop signal is supplied to a power device driving circuit and an input circuit and the power device driving circuit and another power device driving circuit stop operation of transistors respectively. The fault circuit, outputting the stop signal created by the same through a fault terminal, can also receive a stop signal output from another control circuit and supply the same to the power device driving circuit and the input circuit. Thus, internal wires are simplified in an inverter module having a protective function for a power device for miniaturizing the module.

Abstract: An electrode 4 for detecting a biological signal and a loop antenna 3 are integrally mounted on a support 2 placed on the surface of a living body and a transmitter 5 is placed on the support 2. A biological signal detected on the electrode 4 is input through a connector 11 to electric circuitry 10 of the transmitter 5 and an electric signal processed by the electric circuitry 10 is output through connectors 12 and 13 to both ends of the loop antenna 3 from which the biological signal is emitted to a receiver. At this time, the opening face of the loop antenna 3 is in a direction almost perpendicular to the surface of a living body for improving sensitivity.

Abstract: An electrode 4 for detecting a biological signal and a loop antenna 3 are integrally mounted on a support 2 placed on the surface of a living body and a transmitter 5 is placed on the support 2. A biological signal detected on the electrode 4 is input through a connector 11 to electric circuitry 10 of the transmitter 5 and an electric signal processed by the electric circuitry 10 is output through connectors 12 and 13 to both ends of the loop antenna 3 from which the biological signal is emitted to a receiver. At this time, the opening face of the loop antenna 3 is in a direction almost perpendicular to the surface of a living body for improving sensitivity.

Abstract: A focusing position selecting mechanism for determining focusing positions of a taking lens is provided with a selector member for selecting among a plurality of focusing positions including a focusing position for close-up photographing. In the front portion of the photographing unit a mirror is provided fixedly beside a finder window, and the photographer can take a picture of an object from the front with himself included in the composition by watching the mirror. On the front portion of the apparatus is indicated a focusing state of normal photographing so that the photographer may not make a mistake in photographing from the front at the normal focusing position.

Abstract: An electrode 4 for detecting a biological signal and a loop antenna 3 are integrally mounted on a support 2 placed on the surface of a living body and a transmitter 5 is placed on the support 2. A biological signal detected on the electrode 4 is input through a connector 11 to electric circuitry 10 of the transmitter 5 and an electric signal processed by the electric circuitry 10 is output through connectors 12 and 13 to both ends of the loop antenna 3 from which the biological signal is emitted to a receiver. At this time, the opening face of the loop antenna 3 is in a direction almost perpendicular to the surface of a living body for improving sensitivity.

Abstract: A blood pressure monitoring system includes a blood pressure measurement device for measuring blood pressure using a cuff, a memory for storing an externally inputted pulse wave propagation time fluctuation threshold, a time interval detection reference point detection section for detecting a time interval detection reference point in a pulse wave on the side of aortae of a living organism, a pulse wave detection section for detecting a pulse wave on the side of peripheral blood vessels appearing with a time lag with respect to the pulse wave on the side of aortae, a pulse wave propagation time measurement section for measuring a pulse wave propagation time based on respective detected outputs from the time interval detection reference point detection section and the pulse wave detection section, an operation device for calculating a pulse wave propagation fluctuation from two measured pulse wave propagation times, a judgment device for judging whether or not the calculated pulse wave propagation time fluctua