A synchronous motor is driven by three phase alternate current. The rotor core includes a laminated body configured by laminating plate members made of electrical steel sheet. Each plate member is formed in a substantially circular shape in a plan view and formed with projections along an outer circumference thereof.

The number of slots of the stator is 3xy when variable x is a natural number and variable y is a positive odd number. The number of poles of the rotor is (3y+1)x or (3y1)x. The number of projections of each plate member is a common measure of (3y+1)x and (3y1)x. The laminated body has a structure in which the plate members are laminated so that the projections are shifted relative to one another.

A synchronous motor is driven by three phase alternate current. The rotor core includes a laminated body configured by laminating plate members made of electrical steel sheet. Each plate member is formed in a substantially circular shape in a plan view and formed with projections along an outer circumference thereof.

The number of slots of the stator is 3xy when variable x is a natural number and variable y is a positive odd number. The number of poles of the rotor is (3y+1)x or (3y1)x. The number of projections of each plate member is a common measure of (3y+1)x and (3y1)x. The laminated body has a structure in which the plate members are laminated so that the projections are shifted relative to one another.

A controller for a permanent magnet synchronous motor includes an estimating portion configured to determine an estimated value of a rotational speed of the rotor and an estimated value of a position of magnetic poles of the rotor based on a value of the current detected by the current detector and a parameter value indicating an interlinkage magnetic flux caused by the permanent magnet across the winding; a control unit configured to control the drive portion to cause the rotating magnetic field based on the estimated value of the rotational speed and the estimated value of the position of the magnetic poles; and a correction portion configured to correct the parameter value indicating the interlinkage magnetic flux based on correction information, the correction information being determined based on a temperature of the winding and a relationship between the temperature of the winding and a temperature of the permanent magnet.

A controller for a permanent magnet synchronous motor includes an estimating portion configured to determine an estimated value of a rotational speed of the rotor and an estimated value of a position of magnetic poles of the rotor based on a value of the current detected by the current detector and a parameter value indicating an interlinkage magnetic flux caused by the permanent magnet across the winding; a control unit configured to control the drive portion to cause the rotating magnetic field based on the estimated value of the rotational speed and the estimated value of the position of the magnetic poles; and a correction portion configured to correct the parameter value indicating the interlinkage magnetic flux based on correction information, the correction information being determined based on a temperature of the winding and a relationship between the temperature of the winding and a temperature of the permanent magnet.

A controller for a permanent magnet synchronous motor includes an estimating portion configured to determine an estimated value of a rotational speed of the rotor and an estimated value of a position of magnetic poles of the rotor based on a value of the current detected by the current detector and a parameter value indicating an interlinkage magnetic flux caused by the permanent magnet across the winding; a control unit configured to control the drive portion to cause the rotating magnetic field based on the estimated value of the rotational speed and the estimated value of the position of the magnetic poles; and a correction portion configured to correct the parameter value indicating the interlinkage magnetic flux based on correction information, the correction information being determined based on a temperature of the winding and a relationship between the temperature of the winding and a temperature of the permanent magnet.

An induction motor with on-rotor slip power recovery may have a rotor and a stator element. The rotor element has a rotor winding system with a number of winding units wound-distributed for inducing a rotor magnetic field. Each winding unit has an induction and an augmentation subwinding. The induction subwinding has two legs of each a number of induction conductor segments. The induction subwinding induces an emf that drives a rotor current in the rotor winding system to generate a basic induction component for the rotor magnetic field when the induction conductor segments move in the stator element. The augmentation subwinding has two legs of each a number of augmentation conductor segments aligned parallel to the induction conductor segments. The augmentation subwinding being wound that the two legs of augmentation conductor segments are immediately next to each other and positioned mid-way between the two legs of induction conductor segments.

An induction motor with on-rotor slip power recovery may have a rotor and a stator element. The rotor element has a rotor winding system with a number of winding units wound-distributed for inducing a rotor magnetic field. Each winding unit has an induction and an augmentation subwinding. The induction subwinding has two legs of each a number of induction conductor segments. The induction subwinding induces an emf that drives a rotor current in the rotor winding system to generate a basic induction component for the rotor magnetic field when the induction conductor segments move in the stator element. The augmentation subwinding has two legs of each a number of augmentation conductor segments aligned parallel to the induction conductor segments. The augmentation subwinding being wound that the two legs of augmentation conductor segments are immediately next to each other and positioned mid-way between the two legs of induction conductor segments.

Electric motors having variable poles are disclosed herein. In one aspect, an electric motor includes a stator including a plurality of magnetic conductive wires. The magnetic conductive wires are configured to form a plurality of poles. The electric motor further includes a rotor configured to rotate in response to a magnetic field generated by the poles of the stator and an electronic control module electrically coupled to the magnetic conductive wires. The electronic control module is configured to adjust a configuration of the poles of the stator.

Electric motors having variable poles are disclosed herein. In one aspect, an electric motor includes a stator including a plurality of magnetic conductive wires. The magnetic conductive wires are configured to form a plurality of poles. The electric motor further includes a rotor configured to rotate in response to a magnetic field generated by the poles of the stator and an electronic control module electrically coupled to the magnetic conductive wires. The electronic control module is configured to adjust a configuration of the poles of the stator.

A method for determining temperature of a chip, includes generating a first voltage and a second voltage using a pair of bipolar-junction transistors, and generating a third voltage using another bipolar-junction transistor. When a most recent bit of a bitstream is a logic-zero, the difference between the first and second voltages is sampled using a switched-capacitor input-sampling circuit, and a difference between the first and second voltages is integrated, to produce a proportional-to-absolute-temperature voltage. The proportional-to-absolute-temperature voltage is quantized to produce a next bit of the bitstream. When the most recent bit of the bitstream is a logic-one, the third voltage is sampled using the switched-capacitor input-sampling circuit, and the third voltage is integrated, to produce a complementary-to-absolute-temperature voltage. The complementary-to-absolute-temperature voltage is quantized to produce a next bit of the bitstream. The bitstream is filtered and decimated to produce an output code representative of the temperature of the chip.