Capacitive physical quantity sensor
First Claim
1. A capacitive physical quantity sensor comprising:
- a sensor element having a movable electrode and a fixed electrode opposite to the movable electrode, the movable electrode being displacable depending on change of a physical quantity;
a C-V converter configured to convert a variation in a capacitance between the movable electrode and the fixed electrode into a voltage to output the converted voltage in a first operating mode, the C-V converter being configured to output a constant voltage in a second operating mode;
an amplifier connected to the C-V converter and configured to amplify the converted voltage to output an amplified first voltage, the amplifier being configured to amplify the constant voltage to output an amplified second voltage;
a first sample and hold circuit connected to the amplifier and configured to operate in the first operating mode to sample and hold the first voltage outputted from the amplifier;
a second sample and hold circuit connected to the amplifier and configured to operate in the second operating mode to sample and hold the second voltage outputted from the amplifier; and
a first differential amplifier connected to the first and second sample and hold circuits and configured to obtain a difference voltage between the first voltage held by the first sample and hold circuit and the second voltage held by the second sample and hold circuit.
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Accused Products
Abstract
In a capacitive physical quantity sensor, a C-V converter converts a variation in a capacitance between a movable electrode and a fixed electrode into a voltage to output the converted voltage in a first operating mode. The C-V converter also outputs a constant voltage in a second operating mode. An amplifier amplifies the converted voltage to output a first voltage, and amplifies the constant voltage to output a second voltage. A first sample and hold circuit operates in the first operating mode to sample and hold the first voltage. A second sample and hold circuit operates in the second operating mode to sample and hold the second voltage. A first differential amplifier obtains a difference voltage between the first voltage held by the first sample and hold circuit and the second voltage held by the second sample and hold circuit.
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Citations
20 Claims
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1. A capacitive physical quantity sensor comprising:
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a sensor element having a movable electrode and a fixed electrode opposite to the movable electrode, the movable electrode being displacable depending on change of a physical quantity;
a C-V converter configured to convert a variation in a capacitance between the movable electrode and the fixed electrode into a voltage to output the converted voltage in a first operating mode, the C-V converter being configured to output a constant voltage in a second operating mode;
an amplifier connected to the C-V converter and configured to amplify the converted voltage to output an amplified first voltage, the amplifier being configured to amplify the constant voltage to output an amplified second voltage;
a first sample and hold circuit connected to the amplifier and configured to operate in the first operating mode to sample and hold the first voltage outputted from the amplifier;
a second sample and hold circuit connected to the amplifier and configured to operate in the second operating mode to sample and hold the second voltage outputted from the amplifier; and
a first differential amplifier connected to the first and second sample and hold circuits and configured to obtain a difference voltage between the first voltage held by the first sample and hold circuit and the second voltage held by the second sample and hold circuit. - View Dependent Claims (2, 3, 4)
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5. A capacitive physical quantity sensor comprising:
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a sensor element having a movable electrode and a fixed electrode opposite to the movable electrode, the movable electrode being displacable depending on change of a physical quantity;
a C-V converter configured to convert a variation in a capacitance between the movable electrode and the fixed electrode into a voltage to output the converted voltage in a first operating mode, the C-V converter being configured to output a constant voltage in a second operating mode;
a first sample and hold circuit connected to the C-V converter and configured to operate in the first operating mode to sample and hold the converted voltage outputted from the C-V converter;
a second sample and hold circuit connected to the C-V converter and configured to operate in the second operating mode to sample and hold the constant voltage outputted from the C-V converter;
a first differential amplifier connected to the first and second sample and hold circuits and configured to output the constant voltage outputted from the C-V converter in the second operating mode, the second differential amplifier being configured to obtain a difference voltage between the converted voltage held by the first sample and hold circuit and the constant voltage held by the second sample and hold circuit in the first operating mode;
an amplifier connected to the first differential amplifier and configured to amplify the difference voltage to output an amplified first voltage, the amplifier being configured to amplify the constant voltage to output an amplified second voltage;
a third sample and hold circuit connected to the amplifier and configured to sample and hold the first voltage outputted from the amplifier;
a fourth sample and hold circuit connected to the amplifier and configured to sample and hold the second voltage outputted from the amplifier; and
a second differential amplifier connected to the third and fourth sample and hold circuits and configured to obtain a difference between the first voltage held by the third sample and hold circuit and the second voltage held by the fourth sample and hold circuit. - View Dependent Claims (6, 7, 8)
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9. A capacitive physical quantity sensor comprising:
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a first sensor element having a first movable electrode and a first fixed electrode opposite to the first movable electrode, the first movable electrode being displacable depending on change of a first physical quantity;
a second sensor element having a second movable electrode and a second fixed electrode opposite to the second movable electrode, the second movable electrode being displacable depending on change of a second physical quantity;
a C-V converter configured to convert a variation in one of a capacitance between the first movable electrode and the first fixed electrode of the first sensor element and that between the second movable electrode and the second fixed electrode of the second sensor element into a voltage to output the converted voltage in a first operating mode, the C-V converter being configured to output a constant voltage in a second operating mode;
a first sample and hold circuit connected to the C-V converter and configured to operate in the first operating mode to sample and hold the converted voltage outputted from the C-V converter based on the capacitance of the first sensor element;
a second sample and hold circuit connected to the C-V converter and configured to operate in the first operating mode to sample and hold the converted voltage outputted from the C-V converter based on the capacitance of the second sensor element;
a third sample and hold circuit connected to the C-V converter and configured to operate in the second operating mode to sample and hold the constant voltage outputted from the C-V converter;
a first differential amplifier connected to the first and third sample and hold circuits and configured to obtain a first difference voltage between the converted voltage held by the first sample and hold circuit and the constant voltage held by the third sample and hold circuit in the first operating mode;
a second differential amplifier connected to the second and third sample and hold circuits and configured to obtain a second difference voltage between the converted voltage held by the second sample and hold circuit and the constant voltage held by the third sample and hold circuit in the first operating mode, one of the first and second differential amplifiers being configured to output the constant voltage outputted from the C-V converter in the second operating mode;
a first amplifier connected to the first differential amplifier and configured to amplify the first difference voltage to output an amplified first voltage;
a second amplifier connected to the second differential amplifier and configured to amplify the second difference voltage to output an amplified second voltage, one of the first and second amplifiers being configured to amplify the constant voltage to output an amplified third voltage;
a fourth sample and hold circuit connected to the first amplifier and configured to sample and hold the first voltage outputted from the first amplifier;
a fifth sample and hold circuit connected to the second amplifier and configured to sample and hold the second voltage outputted from the second amplifier;
a sixth sample and hold circuit connected to at least corresponding one of the first amplifier and the second amplifier and configured to sample and hold the third voltage outputted from one of the first and second amplifiers;
a third differential amplifier connected to the fourth and sixth sample and hold circuits and configured to obtain a difference between the first voltage held by the fourth sample and hold circuit and the third voltage held by the sixth sample and hold circuit; and
a fourth differential amplifier connected to the fifth and sixth sample and hold circuits and configured to obtain a difference between the second voltage held by the fifth sample and hold circuit and the third voltage held by the sixth sample and hold circuit. - View Dependent Claims (10, 11, 12)
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13. A capacitive physical quantity sensor comprising:
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a first sensor element having a first movable electrode and a first fixed electrode opposite to the first movable electrode, the first movable electrode being displacable depending on change of a first physical quantity;
a second sensor element having a second movable electrode and a second fixed electrode opposite to the second movable electrode, the second movable electrode being displacable depending on change of a second physical quantity;
a C-V converter configured to convert a variation in one of a capacitance between the first movable electrode and the first fixed electrode of the first sensor element and that between the second movable electrode and the second fixed electrode of the second sensor element into a voltage to output the converted voltage in a first operating mode, the C-V converter being configured to output a constant voltage in a second operating mode;
a first sample and hold circuit connected to the C-V converter and configured to operate in the first operating mode to sample and hold the converted voltage outputted from the C-V converter based on the capacitance of one of the first sensor element and the second sensor element;
a second sample and hold circuit connected to the C-V converter and configured to operate in the second operating mode to sample and hold the constant voltage outputted from the C-V converter;
a first differential amplifier connected to the first and second sample and hold circuits and configured to obtain a difference voltage between the converted voltage held by the first sample and hold circuit and the constant voltage held by the second sample and hold circuit in the first operating mode, the first differential amplifier being configured to output the constant voltage outputted from the C-V converter in the second operating mode;
an amplifier connected to the first differential amplifier and configured to amplify the first difference voltage to output an amplified first voltage, the amplifier being configured to amplify the constant voltage to output an amplified second voltage;
a fourth sample and hold circuit connected to the amplifier and configured to sample and hold the first voltage outputted from the amplifier based on the capacitance of the first sensor element;
a fifth sample and hold circuit connected to the amplifier and configured to sample and hold the first voltage outputted from the amplifier based on the second sensor element;
a sixth sample and hold circuit connected to the amplifier and configured to sample and hold the second voltage outputted from the amplifier;
a second differential amplifier connected to the fourth and sixth sample and hold circuits and configured to obtain a difference between the first voltage held by the fourth sample and hold circuit and the second voltage held by the sixth sample and hold circuit; and
a third differential amplifier connected to the fifth and sixth sample and hold circuits and configured to obtain a difference between the first voltage held by the fifth sample and hold circuit and the second voltage held by the sixth sample and hold circuit. - View Dependent Claims (14, 15, 16)
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17. A capacitive physical quantity sensor comprising:
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a first sensor element having a first movable electrode and a first fixed electrode opposite to the first movable electrode, the first movable electrode being displacable depending on change of a first physical quantity;
a second sensor element having a second movable electrode and a second fixed electrode opposite to the second movable electrode, the second movable electrode being displacable depending on change of a second physical quantity;
a C-V converter configured to convert a variation in one of a capacitance between the first movable electrode and the first fixed electrode of the first sensor element and that between the second movable electrode and the second fixed electrode of the second sensor element into a voltage to output the converted voltage in a first operating mode, the C-V converter being configured to output a constant voltage in a second operating mode;
a first sample and hold circuit connected to the C-V converter and configured to operate in the first operating mode to sample and hold the converted voltage outputted from the C-V converter based on the capacitance of one of the first sensor element and the second sensor element;
a second sample and hold circuit connected to the C-V converter and configured to operate in the second operating mode to sample and hold the constant voltage outputted from the C-V converter;
a first differential amplifier connected to the first and second sample and hold circuits and configured to obtain a difference voltage between the converted voltage held by the first sample and hold circuit and the constant voltage held by the second sample and hold circuit in the first operating mode, the first differential amplifier being configured to output the constant voltage outputted from the C-V converter in the second operating mode;
an amplifier connected to the first differential amplifier and configured to amplify the first difference voltage to output an amplified first voltage, the amplifier being configured to amplify the constant voltage to output an amplified second voltage;
a fourth sample and hold circuit connected to the amplifier and configured to sample and hold the first voltage outputted from the amplifier;
a fifth sample and hold circuit connected to the amplifier and configured to sample and hold the second voltage outputted from the amplifier; and
a second differential amplifier connected to the fourth and fifth sample and hold circuits and configured to obtain a difference between the first voltage held by the fourth sample and hold circuit and the second voltage held by the fifth sample and hold circuit. - View Dependent Claims (18, 19, 20)
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Specification