Abstract: The drive control circuit (200) includes a driver circuit (250) for intermittently supplying the magnetic coils with a supply voltage VSUP; a switching signal generating circuit (240) that generates a switching signal supplied to the driver circuit (250); and a voltage setter (270) that supplies a supply voltage control value Ya to the switching signal generating circuit (240). By adjusting pulse width of the switching signals DRVA1, DRVA2 with reference to the supply voltage control value Ya, the switching signal generating circuit (240) adjusts the effective voltage which is applied to the magnetic coils.

Abstract: Provided is a small motor superior in weight/torque balance. A phase stator 10 and B phase stator 12 are disposed to face each other. A rotor is interpositioned between these stators. Electromagnetic coils @ are provided to the stators evenly in the circumferential direction. A permanent magnet is provided to the rotor evenly in the circumferential direction. The exciting polarity of the electromagnetic coil is alternately opposite, and this is the same for the permanent magnet. A signal having a prescribed frequency is input to the A phase electromagnetic coil and B phase electromagnetic coil. The rotor rotates between the stators as a result thereof.

Abstract: The brushless electric machine includes a first drive member (30U) having a plurality of permanent magnets (32U); a second drive member (10) having a plurality of electromagnetic coils and capable of movement relative to the first drive member (30U); and a third drive member (30L) disposed at the opposite side from the first drive member (30U) with the second drive member (10) therebetween, and having a fixed relative positional relationship with respect to the first drive member (30U). The second drive member (10) has magnetic sensors (40A, 40B) for detecting relative position of the first and second drive members; and a control circuit for carrying out control of the brushless electric machine utilizing the output signals of the magnetic sensors.

Abstract: An actuator mechanism having a different magnet polarity arrangement than the conventional mechanisms is provided. The actuator mechanism 100 has a magnet unit 210 that includes magnets 30 and an electromagnetic coil unit 110 that includes an electromagnetic coil. the relative positions of the magnet unit 210 and the magnetic coil unit 110 can change. The magnet unit 210 includes a yoke member 20 and two or more magnets 30. The two magnets 30 are pulled toward the yoke member 20 in the state where identical poles face each other across the yoke member 20.

Abstract: The rotation speed measuring device includes a position sensor (40A) for outputting position signals (SSA) indicating M (where M is an integer equal to or greater than 2) rotation positions of equal phase difference in each one rotation of the rotating equipment, a clock signal generator (510) for generating a basic clock signal; a counter (610) for counting the number of pulses of the basic clock signal; a measuring interval setting unit (800) for setting a duration coefficient that indicates the ratio of a measuring interval during which the number of pulses of the basic clock signal is to be counted within a time period between two successively occurring aforementioned position signals, to the entire time period between the two position signals; and for causing the counter to count the number of pulses of the basic clock signal during the measuring interval; and calculating unit (660, 670) for calculating the rotation speed of the rotating equipment as a function of the frequency of the basic clock signal,

Abstract: Provided is a drive regenerative control system of a drivee with a motor superior in torque and weight balance and suitable for miniaturization as the drive source. In a drive regenerative control system having a drive source with an electric motor, a drivee, a control circuit having a drive control circuit of the motor and a regenerative control circuit, and a detection unit for detecting the driving status of the drivee, the drive control circuit and regenerative control circuit have a control unit for controlling, linearly or in multiple stages, the duty ratio of the drive or regenerative signal to be supplied to the motor based on the phase difference of the phase of the detection signal from the detection unit and the command value signal to the motor.

Abstract: The brushless motor has a first and second drive member. The first drive member is equipped with M phase coil groups each having N electromagnetic coils where M is an integer of 1 or greater and N is an integer of 1 or greater. The second drive member has a plurality of permanent magnets, and is able to move relative to the first drive member. The first drive member has 2 (M×N) magnetic body cores. Each phase electromagnetic coil is coiled on a periodically selected magnetic body core at a ratio of 1 to 2M from among the arrangement of 2 (M×N) magnetic body cores.

Abstract: Provided is a drive regenerative control system of a drivee with a motor superior in torque and weight balance and suitable for miniaturization as the drive source. In a drive regenerative control system having a drive source with an electric motor, a drivee, a control circuit having a drive control circuit of the motor and a regenerative control circuit, and a detection unit for detecting the driving status of the drivee, the drive control circuit and regenerative control circuit have a control unit for controlling, linearly or in multiple stages, the duty ratio of the drive or regenerative signal to be supplied to the motor based on the phase difference of the phase of the detection signal from the detection unit and the command value signal to the motor.

Abstract: The planar heater includes an insulating substrate, an electric conductive film disposed on the substrate, a plurality of electrodes both attached to one side of the electric conductive film, and an insulating film covering the electric conductive film. The electric conductive film is preferably formed of material having a resistance temperature coefficient of 420 ppm/° C. or higher at normal temperature.

Abstract: An electric motor having an electromagnetic coil, wherein the electromagnetic coil has wiring formed by a vapor deposited insulating layer wound on the entire exterior circumference of a conductive substrate.

Abstract: The power generating device (1000) has a vane (1200) rotated by hydrodynamic force from a fluid; a generator motor (100); a flow velocity measuring unit (1130); a rotation speed measuring unit; and a control unit (200). In the event that at least one of the flow velocity and the rotation speed lies within a prescribed low range at startup of the generator motor, the control unit (200) operates the generator motor as a motor to increase the rotation speed of the vane, and then operates the generator motor as a generator.

Abstract: A serial communication system comprises: a master; a plurality of slaves; and a serial communication bus connecting the master and the plurality of slaves. The master is configured so as to perform peer-to-peer control, via the serial communication bus, of the plurality of slaves. Each of the plurality of slaves has: an I/O portion for controlling communication with the master; a control portion for controlling a driving portion of the slave; and a register portion. The register portion comprises a control program for the driving portion. The control program comprises a plurality of functions, and the register portion stores control information to which are allocated all or a portion of the plurality of functions corresponding to all or to a portion of the plurality of program steps.

Abstract: A clock signal generator including: a signal generation unit that outputs a first clock signal composed of a single frequency component; and a phase angle detection unit that detects phase angles of the first clock signal by comparing a plurality of threshold values set within the amplitude of the first clock signal with instantaneous values of the first clock signal by using window comparators, and generates a second clock signal by determining rising and/or falling edges of the signal according to the detected phase angles.

Abstract: A multilevel input interface device connected to a signal bus including one or more data lines that transmit an M-level signal and a clock line that transmits a transmission clock signal indicating the timings of reading level information for the M-level signal, includes: a threshold value generation unit that produces a plurality of voltage outputs as a plurality of variable comparison reference signals according to the level-varying supply voltage; a level detection unit that compares, in synchronization with the transmission clock signal, the M-value level signal with the variable comparison reference signals and generates a logic output corresponding to an instantaneous value of the M-level signal; and a logic circuit unit that converts the logic output to a data signal.

Abstract: A variable power supply voltage generator generates a variable power supply voltage Vvar and supplies it to other circuits. A transmitting circuit 130 (or 140), operative at the variable power supply voltage Vvar, generates multi-value analog signals Smulti and transmits them to other circuits. A receiving circuit 140 (or 130), operative at the variable power supply voltage Vvar, receives the multi-value analog signals Smulti and subjects them to A/D conversion to generate multi-value digital signals. The threshold voltage generator generates threshold voltages used for A/D conversion from the variable power supply voltage Vvar or from a signal having a voltage value proportional to that of the variable power supply voltage Vvar and supplies them to the receiving circuit. An analog clock generator 120 generates an analog clock signal having a cyclical analog waveform.

Abstract: A resonance control apparatus 100 includes a VCO 10 which generates a reference signal having a predetermined frequency, a divider 20 which divides the predetermined frequency of the reference signal, a phase reference forming section 50 which delays a phase of the divided signal for a predetermined interval, a voltage comparator 40 which compares a voltage of the output signal from a piezoelectric sensor 2 for detecting the driving state of a piezoelectric load 3 in synchronization with the driving of the piezoelectric load 3 with a predetermined voltage, a phase comparator 60 which compares the phase of the output signal from the voltage comparator 40 with the phase of the output signal from the phase reference forming section 50, and a duty control section 30 for controlling a duty ratio of the drive signal supplied to the piezoelectric load 3 based on the reference signal.

Abstract: The brushless motor includes a first permanent magnet magnetized in a direction perpendicular to the drive direction, and a electromagnetic coil wound around an axis parallel to the drive direction. The drive control circuit supplies a drive current in a given first electric current direction to the electromagnetic coil without changing the electric current direction to operate the brushless motor in the drive direction.

Abstract: The brushless motor includes a coil array, a magnet array, a magnetic sensor, a drive control circuit for driving the coil array, and a temperature sensor for detecting a detection target temperature associated with either the coil temperature or the driving element temperature. The drive control circuit reduces the effective value of driving voltage supplied to the coil array when coil temperature detected by the temperature sensor has exceeded a prescribed threshold value.

Abstract: The specific phase position detection circuit detects first and second temporal positions which have respective desired phase offsets from an upper peak position and an lower peak position of an analog signal having periodicity. The specific phase position detection circuit then outputs phase signals indicating the detected first and second temporal positions.

Abstract: In the m phase brushless generator, n (n<m) phase magnet coil groups are provided with magnetic sensors, while the remaining (m?n) phase magnet coil groups are not provided with magnetic sensors. The regeneration control circuit utilizes the sensor outputs of the n magnetic sensors to generates n sets of regeneration control signals for the n phase magnet coil groups. The regeneration control circuit further generates (m?n) sets of regeneration control signals for the (m?n) phase magnet coil groups not associated with the n magnetic sensors, using one or more of the sensor outputs of the n magnetic sensors in generation of each of the (m?n) sets of regeneration control signals.