Abstract: A static magnetic field generator generates a non-magnetic field region. An AC magnetic field application instrument applies an AC magnetic field to the non-magnetic field region. A detection coil has an axis parallel to a direction of the AC magnetic field in order to detect a magnetization signal. A measuring instrument is connected to the detection coil. A resonance frequency variable device includes a capacitor connected in parallel to the detection coil in order to adjust a resonance frequency of the detection coil and the measuring instrument. A capacity of the capacitor is adjusted such that a resonance frequency of a closed circuit including the detection coil, the measuring instrument, and the resonance frequency variable device including the capacitor coincides with a frequency of a harmonic signal.

Abstract: This common mode choke coil (CC1) comprises: a choke coil including a magnetic core (1) and a covered conductive wire (2a, 2b) wound around the magnetic core (1); a conductor (5) extending along the surface of the magnetic core (1); and a ground conductive wire (6) for grounding the conductor (5). The conductor (5) is disposed at a position in contact with a winding start portion (3a, 3b) of the covered conductive wire (2a, 2b) with respect to the magnetic core (1) and not in contact with or close to a winding end portion (4a, 4b).

Abstract: A first path formed by a first capacitor connected in parallel with a noise generation source and a second path formed by a second capacitor connected in parallel with a load are arranged so as to be, at least partially, opposed to each other in a perpendicular direction, the first path and the second path are connected such that the first capacitor and the second capacitor are connected in parallel with each other, and the first path and the second path are arranged such that a direction of current flowing through the first path and a direction of induced current flowing when a magnetic flux generated by the current interlinks the second path are identical to each other at the first capacitor and the second capacitor.

Abstract: A static magnetic field generator generates a non-magnetic field region. An AC magnetic field application instrument applies an AC magnetic field to the non-magnetic field region. A detection coil has an axis parallel to a direction of the AC magnetic field in order to detect a magnetization signal. A measuring instrument is connected to the detection coil. A resonance frequency variable device includes a capacitor connected in parallel to the detection coil in order to adjust a resonance frequency of the detection coil and the measuring instrument. A capacity of the capacitor is adjusted such that a resonance frequency of a closed circuit including the detection coil, the measuring instrument, and the resonance frequency variable device including the capacitor coincides with a frequency of a harmonic signal.

Abstract: A drive device includes a first inverter and a second inverter configured to respectively drive two rotary electric machines. Carrier signals for controlling the first inverter and the second inverter are set to be in mutually opposite phases. For at least one connection line out of a connection line between the first inverter and one of the rotary electric machines and a connection line between the second inverter and another one of the rotary electric machines, a balance capacitor and a balance inductor are disposed between the at least one connection line and a ground potential such that an impedance to ground generated between the one of the rotary electric machines and the ground potential coincides with an impedance to ground generated between the other one of the rotary electric machines and the ground potential.

Abstract: A drive device includes a first inverter and a second inverter configured to respectively drive two rotary electric machines. Carrier signals for controlling the first inverter and the second inverter are set to be in mutually opposite phases. For at least one connection line out of a connection line between the first inverter and one of the rotary electric machines and a connection line between the second inverter and another one of the rotary electric machines, a balance capacitor and a balance inductor are disposed between the at least one connection line and a ground potential such that an impedance to ground generated between the one of the rotary electric machines and the ground potential coincides with an impedance to ground generated between the other one of the rotary electric machines and the ground potential.

Abstract: In a rotary machine control device for controlling a rotary machine having a multi-group multiphase configuration, a phase difference ?coil of 150° to 210° (excluding 180°) is electrically provided between a winding for an odd-number group and a winding for an even-number group in the rotary machine, wherein, when the effective value of a voltage command is smaller than a voltage threshold, the phase difference between the voltage commands for the respective groups is set to 180°, and when a torque command is greater than a torque threshold, the phase difference between the voltage commands for the respective groups is set to ?coil.

Abstract: In a rotary machine control device for controlling a rotary machine having a multi-group multiphase configuration, a phase difference ?coil of 150° to 210° (excluding 180°) is electrically provided between a winding for an odd-number group and a winding for an even-number group in the rotary machine, wherein, when the effective value of a voltage command is smaller than a voltage threshold, the phase difference between the voltage commands for the respective groups is set to 180°, and when a torque command is greater than a torque threshold, the phase difference between the voltage commands for the respective groups is set to ?coil.

Abstract: A semiconductor device includes a positive electrode-side semiconductor element, a negative electrode-side semiconductor element, a positive electrode plate, a negative electrode plate, an AC electrode plate, a positive electrode-side auxiliary electrode terminal, a negative electrode-side auxiliary electrode terminal, a positive electrode-side capacitor, and a negative electrode-side capacitor. The positive electrode plate is connected to a first positive electrode of the positive electrode-side semiconductor element. The negative electrode plate is connected to a second negative electrode of the negative electrode-side semiconductor element. The AC electrode plate is connected to a first negative electrode of the positive electrode-side semiconductor element and a second positive electrode of the negative electrode-side semiconductor element. The positive electrode-side capacitor is connected to the positive electrode plate and the positive electrode-side auxiliary electrode terminal.

Abstract: A semiconductor device includes a positive electrode-side semiconductor element, a negative electrode-side semiconductor element, a positive electrode plate, a negative electrode plate, an AC electrode plate, a positive electrode-side auxiliary electrode terminal, a negative electrode-side auxiliary electrode terminal, a positive electrode-side capacitor, and a negative electrode-side capacitor. The positive electrode plate is connected to a first positive electrode of the positive electrode-side semiconductor element. The negative electrode plate is connected to a second negative electrode of the negative electrode-side semiconductor element. The AC electrode plate is connected to a first negative electrode of the positive electrode-side semiconductor element and a second positive electrode of the negative electrode-side semiconductor element. The positive electrode-side capacitor is connected to the positive electrode plate and the positive electrode-side auxiliary electrode terminal.

Abstract: Even when a grounding capacitor is included at either end of a common mode coil, there is noise that flows from a load into a metal frame, and there is a need to restrict an amount of noise propagating to a system power supply. Because of this, a noise loop is formed of a rectifier circuit, an inverter, a first electrical wire that connects a positive polarity side of the rectifier circuit and the inverter, a second electrical wire that connects a negative polarity side of the rectifier circuit and the inverter, a ground wire terminal that can connect a load connected to an output terminal or the inverter, and a conductive plate that connects at least one or the first electrical wire and second electrical wire and the ground wire terminal.

Abstract: An isolation transformer wherein in a first coil group of a pair of coil groups provided in an isolation transformer, an inner peripheral side lead wire is drawn out in a positive direction of a z axis and then drawn out to an outer peripheral side of a primary side coil as a first inner peripheral side lead wire, and in a second coil group, the inner peripheral side lead wire is drawn out in a negative direction of the z axis and then drawn out to the outer peripheral side of the primary side coil as a second inner peripheral side lead wire. The first inner peripheral side lead wire and the second inner peripheral side lead wire are then connected to each other, such that respective inner peripheral side end portions are connected to each other in series.

Abstract: An isolation transformer wherein in a first coil group of a pair of coil groups provided in an isolation transformer, an inner peripheral side lead wire is drawn out in a positive direction of a z axis and then drawn out to an outer peripheral side of a primary side coil as a first inner peripheral side lead wire, and in a second coil group, the inner peripheral side lead wire is drawn out in a negative direction of the z axis and then drawn out to the outer peripheral side of the primary side coil as a second inner peripheral side lead wire. The first inner peripheral side lead wire and the second inner peripheral side lead wire are then connected to each other, such that respective inner peripheral side end portions are connected to each other in series.

Abstract: Even when a grounding capacitor is included at either end of a common mode coil, there is noise that flows from a load into a metal frame, and there is a need to restrict an amount of noise propagating to a system power supply. Because of this, a noise loop is formed of a rectifier circuit, an inverter, a first electrical wire that connects a positive polarity side of the rectifier circuit and the inverter, a second electrical wire that connects a negative polarity side of the rectifier circuit and the inverter, a ground wire terminal that can connect a load connected to an output terminal or the inverter, and a conductive plate that connects at least one or the first electrical wire and second electrical wire and the ground wire terminal.