Abstract: In a calculation system in which a neural network performing calculation using input data and a weight parameter is implemented in a calculation device including a calculation circuit and an internal memory and an external memory, the weight parameter is divided into two, i.e., a first weight parameter and a second weight parameter, and the first weight parameter is stored in the internal memory of the calculation device, and the second weight parameter is stored in the external memory.

Abstract: To achieve, in a load drive device including an H-bridge circuit, miniaturization of a capacitor or/and the constituent elements of the H-bridge circuit (e.g., reduction in volume) with circuit elements, for example, switching elements included in the H-bridge circuit, being inhibited from breaking down or destroying even in a case where a load is overloaded. The invention is disclosed in which, as a solution to the achievement, first and second modes are provided as a switching mode for the switching elements 11, 12, 13, and 14 and switching is appropriately performed between the first and second modes.

Abstract: Learning data of a usage environment can be efficiently collected. A recognition apparatus includes: a first neural network configured to receive input of data; a second neural network configured to receive input of the data, the second neural network having a different structure from a structure of the first neural network; a comparison unit configured to compare a first output result of the first neural network and a second output result of the second neural network; and a communication unit configured to wirelessly transmit the data to a host system configured to learn the data when a comparison result between the first output result and the second output result is different by a predetermined standard or more.

Abstract: Downsizing of an inductor is achieved while reducing radiation noise of an inductor current. A boosting power supply unit is, for example, provided in an ECU mounted in a vehicle or the like. The boosting power supply unit has a boosting coil, a switching element and a current control unit 16. The current control unit 16 controls the switching element 12 to turn on and off by using a clock signal CK1 with a higher frequency than a pulse signal SPL in a clamping period when the inductor current flowing in the boosting coil is clamped at a preset peak setting current, and controls the switching element to turn on and off by using the pulse signal SPL in periods other than the clamping period. By controlling the switching element to turn on and off in this manner, the inductor current flowing in the boosting coil is controlled.

Abstract: Downsizing of an inductor is achieved while reducing radiation noise of an inductor current. A boosting power supply unit is, for example, provided in an ECU mounted in a vehicle or the like. The boosting power supply unit has a boosting coil, a switching element and a current control unit 16. The current control unit 16 controls the switching element 12 to turn on and off by using a clock signal CK1 with a higher frequency than a pulse signal SPL in a clamping period when the inductor current flowing in the boosting coil is clamped at a preset peak setting current, and controls the switching element to turn on and off by using the pulse signal SPL in periods other than the clamping period. By controlling the switching element to turn on and off in this manner, the inductor current flowing in the boosting coil is controlled.

Abstract: A semiconductor device capable of easily and properly detecting a defective element unit(s) and a quality management method for the semiconductor device are suggested. A semiconducting device simulating interactions between nodes in an interaction model is equipped with a quality management unit for managing the quality of each element unit provided corresponding to each node, wherein the quality management unit executes a specified quality test of each element unit, compares test results of the quality test with pre-given results to be obtained from the quality test, and detects a defective memory cell(s) and a defective element unit(s) based on the comparison results.

Abstract: A semiconductor device capable of easily and properly detecting a defective element unit(s) and a quality management method for the semiconductor device are suggested. A semiconducting device simulating interactions between nodes in an interaction model is equipped with a quality management unit for managing the quality of each element unit provided corresponding to each node, wherein the quality management unit executes a specified quality test of each element unit, compares test results of the quality test with pre-given results to be obtained from the quality test, and detects a defective memory cell(s) and a defective element unit(s) based on the comparison results.

Abstract: A semiconductor integrated circuit device that detects an operation error of an SRAM caused by a device variation fluctuating with time is provided. In the SRAM, a memory cell has a transfer MOS transistor whose gate is connected to a word line. At the time of a write test of the memory cell, a control circuit including a test/normal operation selection circuit and a word line driver circuit applies a third voltage to the word line in a preparation period before writing test data, thereafter a first voltage to the word line, and a second voltage to the word line at the end of writing. Due to this, the threshold voltage of the transfer MOS transistor, which fluctuates with time, can be controlled. Therefore, it is possible to enhance detection efficiency for a malfunctioning cell of the SRAM due to a temporal variation.

Abstract: A transmitter circuit in which a driver circuit includes MOS transistors for bias voltage application, in which a driving current flows, cascode-connected to MOS transistors for differential signal input controlled by a voltage value of transmitted data signals, controlled by a voltage value of a bias voltage, and driver circuits include MOS transistors for bias voltage application, in which a driving current flows, cascode-connected to MOS transistors for differential signal input that is controlled by a voltage value of signals obtained by the transmitted data signals, connected to a load portion, and controlled by a voltage value of a bias voltage.

Abstract: A semiconductor integrated circuit device that detects an operation error of an SRAM caused by a device variation fluctuating with time is provided. In the SRAM, a memory cell has a transfer MOS transistor whose gate is connected to a word line. At the time of a write test of the memory cell, a control circuit including a test/normal operation selection circuit and a word line driver circuit applies a third voltage to the word line in a preparation period before writing test data, thereafter a first voltage to the word line, and a second voltage to the word line at the end of writing. Due to this, the threshold voltage of the transfer MOS transistor, which fluctuates with time, can be controlled. Therefore, it is possible to enhance detection efficiency for a malfunctioning cell of the SRAM due to a temporal variation.

Abstract: With the objective of enhancing receiving performance of a receiver with respect to pulse signals spread by spread codes, the receiver comprises an RF front-end section which performs amplification, an AD converter section which AD-converts signals outputted from the RF front-end section, a baseband section which inversely spreads the output of the AD converter section and performs signal detection and demodulation thereon, a reception environment measuring section which measures reception environment using the input signals of the baseband section, and a parameter setting section which sets parameters for respective parts on the basis of signals outputted from the reception environment measuring section. The parameter setting section sets the parameters for the respective parts to the optimum according to the environmental condition measured by the reception environment measuring section.

Abstract: A transmitter circuit in which a driver circuit includes MOS transistors for bias voltage application, in which a driving current flows, cascode-connected to MOS transistors for differential signal input controlled by a voltage value of transmitted data signals, controlled by a voltage value of a bias voltage, and driver circuits include MOS transistors for bias voltage application, in which a driving current flows, cascode-connected to MOS transistors for differential signal input that is controlled by a voltage value of signals obtained by the transmitted data signals, connected to a load portion, and controlled by a voltage value of a bias voltage.

Abstract: A pre-emphasis circuit which can improve a communication quality of a data transmission at low cost is provided. A current switch circuit, a current adder circuit, and transition detection circuits are provided in a transmitter of a data transmission system. The transition detection circuits detect transitions of transmission data signals which are a differential pair. The current switch circuit receives the transmission data signals, carries driving currents in accordance with the transmission data signals, and outputs output data signals which are a differential pair. The current adder circuit receives detection signals from the transition detection circuits, and adds driving currents in accordance with the detection signals to load resistors. By this means, output data signals in which the transitions are emphasized are inputted to a transmission line.

Abstract: With the objective of enhancing receiving performance of a receiver with respect to pulse signals spread by spread codes, the receiver comprises an RF front-end section which performs amplification, an AD converter section which AD-converts signals outputted from the RF front-end section, a baseband section which inversely spreads the output of the AD converter section and performs signal detection and demodulation thereon, a reception environment measuring section which measures reception environment using the input signals of the baseband section, and a parameter setting section which sets parameters for respective parts on the basis of signals outputted from the reception environment measuring section. The parameter setting section sets the parameters for the respective parts to the optimum according to the environmental condition measured by the reception environment measuring section.

Abstract: With the objective of enhancing receiving performance of a receiver with respect to pulse signals spread by spread codes, the receiver comprises an RF front-end section which performs amplification, an AD converter section which AD-converts signals outputted from the RF front-end section, a baseband section which inversely spreads the output of the AD converter section and performs signal detection and demodulation thereon, a reception environment measuring section which measures reception environment using the input signals of the baseband section, and a parameter setting section which sets parameters for respective parts on the basis of signals outputted from the reception environment measuring section. The parameter setting section sets the parameters for the respective parts to the optimum according to the environmental condition measured by the reception environment measuring section.

Abstract: A pre-emphasis circuit which can improve a communication quality of a data transmission at low cost is provided. A current switch circuit, a current adder circuit, and transition detection circuits are provided in a transmitter of a data transmission system. The transition detection circuits detect transitions of transmission data signals which are a differential pair. The current switch circuit receives the transmission data signals, carries driving currents in accordance with the transmission data signals, and outputs output data signals which are a differential pair. The current adder circuit receives detection signals from the transition detection circuits, and adds driving currents in accordance with the detection signals to load resistors. By this means, output data signals in which the transitions are emphasized are inputted to a transmission line.

Abstract: A body bias control system allows for independent design of a functional module, thereby reducing the burden of designing the module. The body bias control system provides a switch circuit having an area in which the body bias is controlled independently of its outside portion, for controlling the supply of body bias in the vicinity of the area. Preferably three types of switches are provided for switching the body bias to suitable levels for a standby mode, a mode of normal operation and a mode of high-speed operation.

Abstract: Power supply voltages delivered to processing units of a terminal device, respectively, and a delivery range of the power supply voltages are changed over. There is provided the terminal device comprising a connecter for connecting power supply boards for delivering respective power supply voltages thereto, a plurality of processing units to be operated by the respective power supply voltages delivered from the power supply boards, wherein by connecting the respective power supply boards differing in circuit structure from each other with the connecter, the processing units to which the respective power supply voltages are delivered and levels of the respective power supply voltages as delivered are changed over.

Abstract: An end device attachable to the body and containing a heartbeat detector capable of low-power operation. The end device includes a light receiver element and current-to-voltage converter and an amplifier to amplify the output voltage from the current-to-voltage converter and a microcomputer; and the electrical current flowing in the light receiver element from which a specified current is subtracted, is input to the current-to-voltage converter, and the microcomputer CPU detects the heartbeat based on the signal from the amplifier.

Abstract: With the objective of enhancing receiving performance of a receiver with respect to pulse signals spread by spread codes, the receiver comprises an RF front-end section which performs amplification, an AD converter section which AD-converts signals outputted from the RF front-end section, a baseband section which inversely spreads the output of the AD converter section and performs signal detection and demodulation thereon, a reception environment measuring section which measures reception environment using the input signals of the baseband section, and a parameter setting section which sets parameters for respective parts on the basis of signals outputted from the reception environment measuring section. The parameter setting section sets the parameters for the respective parts to the optimum according to the environmental condition measured by the reception environment measuring section.