Rotation angle detector and its temperature correcting method
First Claim
1. A rotational angle detection device having:
- a rotating rotor;
an exciting coil secured to the rotor and having one end thereof to which an alternating-current exciting current is applied and the other end thereof connected to an earth wire; and
a stator coil stationarily provided around the rotor and having one end thereof for taking out an output voltage and the other end thereof connected to the earth wire, the stator coil being for outputting the voltage which is made as a result that an alternating-current bias voltage, caused by an impedance of the earth wire and the exciting current, is superimposed on an alternating-current rotational angle voltage the amplitude of which fluctuates in dependence on the rotational angle of the rotor;
the improvement of the rotational angle detection device further comprising;
memory means for storing data necessary to calculate values of temperature-dependent components in connection with the passing time from a reference time;
rotational angle voltage detection means for calculating the alternating-current rotational angle voltage by subtraction means for subtracting the data stored in the memory means;
bias detection means for calculating the alternating-current bias voltage by addition means for adding the data stored in the memory means; and
means for calculating an amplitude value of the alternating-current rotational angle voltage, a phase difference of the alternating-current rotational angle voltage from the reference time, an amplitude value of the alternating-current bias voltage, and a phase difference of the alternating-current bias voltage from the reference time, based on values sampled by the rotational angle voltage detection means and the bias detection means at at least two different time points.
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Accused Products
Abstract
A first sin phase voltage representing the rotational angle of a resolver is derived from the sum of a rotational angle voltage involving a temperature component and a bias voltage. The rotational angle voltage and the bias voltage are calculated by calculating the values of the maximum peak point (θ=90 degrees) and the maximum bottom point (θ=270 degrees) of the rotor and then by subtracting them or adding them, respectively. Subsequently, a transformer efficiency K(T) and a phase difference α(T) which involve temperature components therein are calculated from the rotational angle voltage, while an impedance R(T) of a common earth wire and another phase difference β(T) which involve temperature components are calculated from the bias voltage. The rotational angle can be calculated by putting these parameters into equations for calculating the first sin phase voltage. As a consequence, it becomes possible to detect the rotational angle of the rotor accurately without suffering the influence of temperature.
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Citations
3 Claims
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1. A rotational angle detection device having:
- a rotating rotor;
an exciting coil secured to the rotor and having one end thereof to which an alternating-current exciting current is applied and the other end thereof connected to an earth wire; and
a stator coil stationarily provided around the rotor and having one end thereof for taking out an output voltage and the other end thereof connected to the earth wire, the stator coil being for outputting the voltage which is made as a result that an alternating-current bias voltage, caused by an impedance of the earth wire and the exciting current, is superimposed on an alternating-current rotational angle voltage the amplitude of which fluctuates in dependence on the rotational angle of the rotor;
the improvement of the rotational angle detection device further comprising;
memory means for storing data necessary to calculate values of temperature-dependent components in connection with the passing time from a reference time;
rotational angle voltage detection means for calculating the alternating-current rotational angle voltage by subtraction means for subtracting the data stored in the memory means;
bias detection means for calculating the alternating-current bias voltage by addition means for adding the data stored in the memory means; and
means for calculating an amplitude value of the alternating-current rotational angle voltage, a phase difference of the alternating-current rotational angle voltage from the reference time, an amplitude value of the alternating-current bias voltage, and a phase difference of the alternating-current bias voltage from the reference time, based on values sampled by the rotational angle voltage detection means and the bias detection means at at least two different time points. - View Dependent Claims (2)
- a rotating rotor;
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3. A temperature compensation method for the temperature which affects an output voltage of a rotational angle detection device for outputting the voltage which is made as a result that an alternating-current bias voltage caused by an impedance of an earth wire and an exciting current is superimposed on an alternating-current rotational angle voltage whose amplitude fluctuates in dependence on the rotational angle of a rotor, the temperature compensation method comprising:
- a first step of successively sampling the output voltages, with the rotor being rotated;
a second step of specifying first output voltages for at least one cycle in rotational angle including the maximum peak value, from the sampled output voltages, a third step of specifying second output voltages for at least one cycle in rotational angle including the maximum bottom value, from the sampled output voltages;
a fourth step of calculating the alternating-current rotational angle voltage by successively subtracting first and second output voltages which are the same in the passing time from a reference time, of the specified first output voltages and the specified second output voltages;
a fifth step of calculating the alternating-current bias voltage by successively adding first and second output voltages which are the same in the passing time from the reference time, of the specified first output voltages and the specified second output voltages; and
a sixth step of calculating an amplitude value of the alternating-current rotational angle voltage, a phase difference of the alternating-current rotational angle voltage from the reference time, an amplitude value of the alternating-current bias voltage, and a phase difference of the alternating-current bias voltage from the reference time, based on values which have been sampled at at least two different time points at the fourth step and the fifth step.
- a first step of successively sampling the output voltages, with the rotor being rotated;
Specification