Control system
First Claim
1. A control system for a gas sensor element having a sensor resistance which varies with the concentration of a specific gas, comprising:
- a pulse input point into which a pulse signal is input, said pulse signal comprising a repetitive waveform having a first potential state and a second potential state;
a capacitor;
a charging circuit for charging said capacitor via a charge resistor during a period when the pulse signal in the first potential state is input to said pulse input point; and
a discharging circuit for discharging said capacitor via a discharge resistor during a period when the pulse signal in the second potential state is input to said pulse input point;
said gas sensor element comprising at least either the charge resistor of said charging circuit or the discharge resistor of said discharging circuit, and at least either a charging current of said charging circuit or discharging current of said discharging circuit varying with the sensor resistance of the gas sensor element; and
said control system further comprising;
a control circuit comprising;
a microcomputer; and
an A/D converter circuit for converting a potential at an operating point located at one end of said capacitor to a digital value, which potential varies with the sensor resistance of the gas sensor element;
said control circuit being connected to said pulse input point and outputting the pulse siggal.
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Accused Products
Abstract
A control system for a gas sensor element capable of lessening the effect of variations in sensor properties among gas sensor elements as well as the effect of environmental factors, such as temperature and humidity, to thereby accurately detect variation in the concentration of a specific gas. In a control system 10 for a gas sensor element 11 whose sensor resistance Rs varies with the concentration of NOx gas, a pulse signal Sc which alternates between 0 V and +5 V is input to a pulse input terminal 17. When a voltage of 5 V is applied to the pulse input terminal 17, a capacitor 14 is charged via a fixed resistor 15 having a resistance Rc and a diode 16. When a voltage of 0 V is applied, the capacitor 14 discharges via the gas sensor element 11. An output voltage Vout is A/D-converted and processed by means of a microcomputer 20, thereby controlling an electronic control assembly 21. The potential Vout at an operating point Pd varies with the sensor resistance Rs as well as with the duty ratio DT of the pulse signal Sc. Thus, the output voltage Vout can be maintained within a predetermined range by adjusting the duty ratio.
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Citations
13 Claims
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1. A control system for a gas sensor element having a sensor resistance which varies with the concentration of a specific gas, comprising:
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a pulse input point into which a pulse signal is input, said pulse signal comprising a repetitive waveform having a first potential state and a second potential state;
a capacitor;
a charging circuit for charging said capacitor via a charge resistor during a period when the pulse signal in the first potential state is input to said pulse input point; and
a discharging circuit for discharging said capacitor via a discharge resistor during a period when the pulse signal in the second potential state is input to said pulse input point;
said gas sensor element comprising at least either the charge resistor of said charging circuit or the discharge resistor of said discharging circuit, and at least either a charging current of said charging circuit or discharging current of said discharging circuit varying with the sensor resistance of the gas sensor element; and
said control system further comprising;
a control circuit comprising;
a microcomputer; and
an A/D converter circuit for converting a potential at an operating point located at one end of said capacitor to a digital value, which potential varies with the sensor resistance of the gas sensor element;
said control circuit being connected to said pulse input point and outputting the pulse siggal. - View Dependent Claims (2, 3, 4, 5, 6, 7)
wherein either the first potential state or the second potential state is a ground potential state, and the other state is a positive potential state, which is higher in potential than the ground potential. -
3. The control system as claimed in claim 1, wherein the control circuit further comprises:
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output range judgement means for judging whether or not an A/D-converted value produced in the A/D converter circuit falls outside a predetermined range; and
duty ratio modification means for modifying the duty ratio of the pulse signal such that the A/D-converted value falls within the predetermined range.
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4. The control system as claimed in claim 1, wherein:
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said charging circuit charging said capacitor at a first time constant via a charge resistor during a period when the pulse signal in the first potential state is input to said pulse input point, said gas sensor element comprising the charge resistor, said discharging circuit discharging said capacitor at a second time constant via a discharge resistor during a period when the pulse signal in the second potential state is input to said pulse input point, and said A/D converter circuit receiving a potential at an operating point located at one end of said capacitor, which potential varies with the sensor resistance of the gas sensor element.
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5. The control system as claimed in claim 1, wherein:
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said charging circuit charging said capacitor at a first time constant via the gas sensor element and a diode during a period when the pulse signal in the first potential state is input to said pulse input point, said discharging circuit discharging said capacitor at a second time constant via a resistor during a period when the pulse signal in the second potential state is input to said pulse input point, said A/D converter circuit receiving a potential at an operating point located at one end of said capacitor, which potential varies with the sensor resistance of the gas sensor element, and said control circuit being connected to said pulse input point of said charging circuit and outputting the pulse signal.
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6. The control system as claimed in claim 1, wherein:
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said charging circuit charging said capacitor at a first time constant via a RD series circuit comprising a resistor and a first diode, which is connected to the resistor in series, during a period when the pulse signal in the first potential state is input to said pulse input point, said discharging circuit discharging said capacitor at a second time constant via a SD series circuit comprising the gas sensor element and a second diode, which is connected to the gas sensor element in series, and connected to the RD series circuit in parallel, during a period when the pulse signal in the second potential state is input to said pulse input point, said A/D converter circuit receiving a potential at an operating point located at one end of said capacitor, which potential varies with the sensor resistance of the gas sensor element, and said control circuit being connected to said pulse input point of said charging circuit and outputting the pulse signal.
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7. The control system as claimed in claim 1, wherein:
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said charging circuit charging said capacitor at a first time constant via a SD series circuit comprising the gas sensor element and a first diode, which is connected to the gas sensor element in series, during a period when the pulse signal in the first potential state is input to said pulse input point, said discharging circuit discharging said capacitor at a second time constant via a RD series circuit comprising a resistor and a second diode, which is connected to the resistor in series, and connected to the SD series circuit in parallel, during a period when the pulse signal in the second potential state is input to said pulse input point, said A/D converter circuit receiving a potential at an operating point located at one end of said capacitor, which potential varies with the sensor resistance of the gas sensor element, and said control circuit being connected to said pulse input point of said charging circuit and outputting the pulse signal.
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8. A control system for a gas sensor element having a sensor resistance which varies with the concentration of a specific gas, comprising:
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a pulse input point into which a pulse signal is input, said pulse signal comprising a repetitive waveform having a first potential state and a second potential state;
a capacitor;
a charging circuit for charging said capacitor at a first time constant via a charge resistor during a period when the pulse signal in the first potential state is input to said pulse input point;
a discharging circuit for discharging said capacitor at a second time constant via a discharge resistor during a period when the pulse signal in the second potential state is input to said pulse input point, said gas sensor element comprising the discharge resistor, and the second time constant varying with the sensor resistance; and
a control circuit comprising;
a microcomputer; and
an A/D converter circuit receiving a potential at an operating point located at one end of said capacitor, which potential varies with the sensor resistance of the gas sensor element; and
said control circuit being connected to said pulse input point and outputting the pulse signal. - View Dependent Claims (9, 10)
wherein either the first potential state or the second potential state is a ground potential state, and the other state is a positive potential state, which is higher in potential than the ground potential. -
10. The control system as claimed in claim 8, wherein the control circuit further comprises:
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output range judgement means for judging whether or not an A/D-converted value produced in the A/D converter circuit falls outside a predetermined range; and
duty ratio modification means for modifying the duty ratio of the pulse signal such that the A/D-converted value falls within the predetermined range.
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11. A control system for a gas sensor element having a sensor resistance which varies with the concentration of a specific gas, comprising:
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a pulse input point into which a pulse signal is input, said pulse signal comprising a repetitive waveform having a first potential state and a second potential state;
a capacitor;
a charging circuit for charging said capacitor at a first time constant via a resistor and a diode during a period when the pulse signal in the first potential state is input to said pulse input point;
a discharging circuit for discharging said capacitor at a second time constant via the gas sensor element during a period when the pulse signal in the second potential state is input to said pulse input point; and
a control circuit comprising;
a microcomputer; and
an A/D converter circuit receiving a potential at an operating point located at one end of said capacitor, which potential varies with the sensor resistance of the gas sensor element; and
said control circuit being connected to said pulse input point of said charging circuit and outputting the pulse signal. - View Dependent Claims (12, 13)
wherein either the first potential state or the second potential state is a ground potential state, and the other state is a positive potential state, which is higher in potential than the ground potential. -
13. The control system as claimed in claim 11, wherein the control circuit further comprises:
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output range judgement means for judging whether or not an A/D-converted value produced in the A/D converter circuit falls outside a predetermined range; and
duty ratio modification means for modifying the duty ratio of the pulse signal such that the A/D-converted value falls within the predetermined range.
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Specification