Abstract: A monitoring device for monitoring an operation state of a device, the monitoring device includes a sound collecting device in which a plurality of microphones are arranged, the plurality of microphones being configured to convert a sound wave emitted from the device into a primary sound pressure signal, the sound wave including an audible sound and an ultrasonic wave, and an information processing device configured to perform a first processing of detecting presence or absence of an abnormality of the device, based on a signal, in an audible range, of the primary sound pressure signal, and a second processing of performing a beamforming processing on a signal, in an ultrasonic range, of the primary sound pressure signal to generate a secondary sound pressure signal, and detecting an abnormal portion of the device, based on the secondary sound pressure signal.

Abstract: A monitoring device that monitors a target area includes: a sound collecting device in which a plurality of microphones that converts sound waves emitted from the target area to a sound pressure signal is arranged; and an information processing device configured to detect an abnormality in the target area based on the sound pressure signal. The sound pressure signal is a signal of sound waves with a frequency of 20 kHz or higher.

Abstract: A monitoring apparatus includes a sound collecting device and an information processing device. The sound collecting device has a plurality of microphones arranged. The microphones convert sound waves emitted from the target regions into sound pressure signals respectively. The information processing device stores map information on positions of the target regions with respect to the sound collecting device, and extracts a specific sound pressure signal from the sound pressure signals for each of the target regions by subjecting the sound pressure signals to beam forming processing based on the map information.

Abstract: A mounting structure for a power conversion device includes: a vehicle body component extending in a front-rear direction of a vehicle; a mounting component provided on the vehicle body component; a drive unit held by the vehicle body component via the mounting component; and a power conversion device attached to the mounting component. A stiffness of the mounting component is greater than a stiffness of the vehicle body component. The power conversion device is arranged between a front end and a rear end of the drive unit in a side view of the vehicle.

Abstract: A mounting structure for a power conversion device includes: a vehicle body component extending in a front-rear direction of a vehicle; a mounting component provided on the vehicle body component; a drive unit held by the vehicle body component via the mounting component; and a power conversion device attached to the mounting component. A stiffness of the mounting component is greater than a stiffness of the vehicle body component. The power conversion device is arranged between a front end and a rear end of the drive unit in a side view of the vehicle.

Abstract: A bearing device includes a bearing portion that includes an inner ring, an outer ring, a plurality of rolling elements that are interposed between the inner ring and the outer ring, and a cage that holds the plurality of rolling elements, one of the inner ring and the outer ring being a rotational ring, and another of the inner ring and the outer ring being a fixed ring; and an oil supply unit that is provided adjacent to the bearing portion in an axial direction. The cage includes a guide portion that is configured to be in sliding contact with a part of the fixed ring via lubricating oil. The oil supply unit includes a vibration sensor configured to detect a vibration of the fixed ring, and a pump configured to supply the lubricating oil to the bearing portion.

Abstract: A bearing device includes a bearing portion that includes an inner ring, an outer ring, a plurality of rolling elements that are interposed between the inner ring and the outer ring, and a cage that holds the plurality of rolling elements, one of the inner ring and the outer ring being a rotational ring, and another of the inner ring and the outer ring being a fixed ring; and an oil supply unit that is provided adjacent to the bearing portion in an axial direction. The cage includes a guide portion that is configured to be in sliding contact with a part of the fixed ring via lubricating oil. The oil supply unit includes a vibration sensor configured to detect a vibration of the fixed ring, and a pump configured to supply the lubricating oil to the bearing portion.

Abstract: A hybrid vehicle has an internal combustion engine and a motor as a driving source, a transmission that changes a speed of rotation of the internal combustion engine or motor and transmits the rotation to driving wheels of the vehicle, a high-voltage battery that supplies power to the motor through an inverter, a cooling mechanism equipped with a pump to circulate a coolant and thereby cool the inverter, a coolant temperature measurement device that detects or estimates a temperature of the coolant, a low-voltage battery that supplies power to the pump, and a converter through which power is supplied from the high-voltage battery to the pump.

Abstract: A hybrid vehicle has an internal combustion engine and a motor as a driving source, a transmission that changes a speed of rotation of the internal combustion engine or motor and transmits the rotation to driving wheels of the vehicle, a high-voltage battery that supplies power to the motor through an inverter, a cooling mechanism equipped with a pump to circulate a coolant and thereby cool the inverter, a coolant temperature measurement device that detects or estimates a temperature of the coolant, a low-voltage battery that supplies power to the pump, and a converter through which power is supplied from the high-voltage battery to the pump.

Abstract: An engine stop control system for a hybrid electric vehicle including a powertrain having an engine, an electric motor/generator, and driving wheels, including a first clutch coupling the engine to the motor/generator, a second clutch coupling the motor/generator to the driving wheels, a controller configured to select between two driving modes of the vehicle by controlling engagement and disengagement of the first clutch and the second clutch so that the vehicle may be driven either solely by the motor/generator or a combination of the engine and the motor/generator, and to control the stop position of the engine to be a desired stop position by controlling the rotation speed of the motor/generator while the first clutch in complete engagement and the second clutch in a slip state.

Abstract: An engine stop control system for a hybrid electric vehicle including a powertrain having an engine, an electric motor/generator, and driving wheels, including a first clutch coupling the engine to the motor/generator, a second clutch coupling the motor/generator to the driving wheels, a controller configured to select between two driving modes of the vehicle by controlling engagement and disengagement of the first clutch and the second clutch so that the vehicle may be driven either solely by the motor/generator or a combination of the engine and the motor/generator, and to control the stop position of the engine to be a desired stop position by controlling the rotation speed of the motor/generator while the first clutch in complete engagement and the second clutch in a slip state.

Abstract: An inventive torque detection device includes: a magnetic circuit forming member having a tubular magnet provided at a first rotating body, and a magnetic ring that is located circumferentially of the tubular magnet and rotated together with a second rotating body connected to the first rotating body; a magnetic flux collecting ring part for collecting a generated magnetic flux; a detection part for detecting, based on a density of the collected magnetic flux, a torque applied to the first or second rotating body; and a molded body that is molded at an outer circumferential portion of the first rotating body, and is joined to longitudinal both sides of the tubular magnet so as to fix the tubular magnet to the first rotating body. A molding pressure, generated when the tubular magnet is molded, is applied in the longitudinal direction of the tubular magnet.

Abstract: An inventive torque detection device includes: a magnetic circuit forming member having a tubular magnet provided at a first rotating body, and a magnetic ring that is located circumferentially of the tubular magnet and rotated together with a second rotating body connected to the first rotating body; a magnetic flux collecting ring part for collecting a generated magnetic flux; a detection part for detecting, based on a density of the collected magnetic flux, a torque applied to the first or second rotating body; and a molded body that is molded at an outer circumferential portion of the first rotating body, and is joined to longitudinal both sides of the tubular magnet so as to fix the tubular magnet to the first rotating body. A molding pressure, generated when the tubular magnet is molded, is applied in the longitudinal direction of the tubular magnet.

Abstract: In apparatus and method for controlling a driving force for an automotive vehicle, a manipulated variable of an accelerator is detected, a vehicular velocity is detected, a vehicular velocity control purpose target driving force is calculated from an absolute value of the manipulated variable of the accelerator and the vehicular velocity, an acceleration control purpose target driving force is calculated from either at least one of an absolute value of the accelerator manipulated variable and a variation velocity of the manipulated variable of the accelerator or from at least one of an absolute value of a result of calculation of the vehicular velocity control purpose target driving force and a variation velocity of the result of calculation of the same, and both of the vehicular velocity control purpose target driving force and the acceleration control purpose target driving force are synthesized to achieve a target driving force of the vehicle.

Abstract: In a slippage prevention apparatus of a belt-drive continuously variable transmission for an automotive vehicle in which a transmission ratio is controlled by a speed-change hydraulic pressure brought closer to a desired speed-change hydraulic pressure, a quick-acceleration-frequency decision section is provided to determine whether a frequency of quick accelerating operations is low or high. Also provided is a desired hydraulic pressure decision section that sets the desired speed-change hydraulic pressure used during an operating mode that the frequency of quick accelerating operations is low to a relatively lower pressure level than the desired speed-change hydraulic pressure used during an operating mode that the frequency of quick accelerating operations is high.

Abstract: In a slippage prevention apparatus of a belt-drive continuously variable transmission for an automotive vehicle in which a transmission ratio is controlled by a speed-change hydraulic pressure brought closer to a desired speed-change hydraulic pressure, a quick-acceleration-frequency decision section is provided to determine whether a frequency of quick accelerating operations is low or high. Also provided is a desired hydraulic pressure decision section that sets the desired speed-change hydraulic pressure used during an operating mode that the frequency of quick accelerating operations is low to a relatively lower pressure level than the desired speed-change hydraulic pressure used during an operating mode that the frequency of quick accelerating operations is high.

Abstract: In apparatus and method for controlling a driving force for an automotive vehicle, a manipulated variable of an accelerator is detected, a vehicular velocity is detected, a vehicular velocity control purpose target driving force is calculated from an absolute value of the manipulated variable of the accelerator and the vehicular velocity, an acceleration control purpose target driving force is calculated from either at least one of an absolute value of the accelerator manipulated variable and a variation velocity of the manipulated variable of the accelerator or from at least one of an absolute value of a result of calculation of the vehicular velocity control purpose target driving force and a variation velocity of the result of calculation of the same, and both of the vehicular velocity control purpose target driving force and the acceleration control purpose target driving force are synthesized to achieve a target driving force of the vehicle.

Abstract: The apparatus comprises two accelerator position sensors and two throttle position sensors, and when one out of said two accelerator position sensors or said two throttle position sensors fails to operate, a limitation is added to the increase in accelerator position for the output characteristics of the accelerator position sensor. Thereby, the vehicle is enabled to travel at a minimum speed necessary without excessively increasing the engine output. When one of the two throttle position sensors fails to operate, the fuel injection quantity may be set based on the detection value of the accelerator position, which enables the vehicle to be driven by approximately the desired speed without excessively increasing the engine output.

Abstract: A driving force control system is provided for an automotive vehicle powertrain. In the driving force control system, an ordinary (or base) target driving force (tTd#n) is determined in response to operator depression of an accelerator (APO) and vehicle speed (VSP). A driving force correction (ADDFCE) is determined in response to a running resistance increment. The driving force correction is added to the ordinary target driving force to provide a first corrected target driving force (tTde) to an engine torque control The driving force correction is multiplied with a correction coefficient (&agr;) to provide a corrected driving force correction. The corrected driving force correction is add to the ordinary target driving force to provide a second corrected target driving force (tTdr) to a CVT ratio control.

Abstract: A driving force control system is provided for an automotive vehicle powertrain. The driving force control system has an accelerator pedal sensor to detect the vehicle's operator depression of an accelerator pedal of the vehicle, a vehicle speed sensor to detect a vehicle speed of the vehicle, and a powertrain control module. The powertrain control modules includes a microprocessor to determine an ordinary target driving force in response to the vehicle's operator depression of the accelerator pedal and the vehicle speed, to determine a running resistance increment, to determine a driving force correction in response to the vehicle's operator depression and the driving force correction, and to determine a corrected target driving force after correcting the ordinary target driving force with the driving force correction.