WO2010119901A1 - 検出回路及び電気回路の異常検出装置、並びに、その異常検出装置を用いる検出システム及び電子システム - Google Patents
検出回路及び電気回路の異常検出装置、並びに、その異常検出装置を用いる検出システム及び電子システム Download PDFInfo
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- WO2010119901A1 WO2010119901A1 PCT/JP2010/056701 JP2010056701W WO2010119901A1 WO 2010119901 A1 WO2010119901 A1 WO 2010119901A1 JP 2010056701 W JP2010056701 W JP 2010056701W WO 2010119901 A1 WO2010119901 A1 WO 2010119901A1
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01R—MEASURING ELECTRIC VARIABLES; MEASURING MAGNETIC VARIABLES
- G01R31/00—Arrangements for testing electric properties; Arrangements for locating electric faults; Arrangements for electrical testing characterised by what is being tested not provided for elsewhere
- G01R31/28—Testing of electronic circuits, e.g. by signal tracer
- G01R31/30—Marginal testing, e.g. by varying supply voltage
- G01R31/3004—Current or voltage test
Definitions
- the present invention relates to an abnormality detection device for detecting an abnormality in an electric circuit, particularly a detection circuit, and a detection system and an electronic system using the abnormality detection device.
- a detection system that detects the pressure of a negative pressure booster that assists the braking force of a vehicle braking device (brake) is known.
- the detection system includes a pressure sensor that detects a negative pressure booster pressure, and a processing device (for example, ECU) that processes an output from the pressure sensor.
- a processing device for example, ECU
- the detection signal level may be within the normal range, and it may be difficult to detect the abnormality in the sensor circuit.
- a method for detecting an abnormality in a sensor circuit techniques using test pulses described in Patent Documents 1 and 2 have been proposed.
- Patent Document 1 detects a failure of an electric circuit including a vehicle speed sensor when the detected value of the vehicle speed sensor indicates a value less than a predetermined value in a brake system that performs an antilock operation of the vehicle using the detected value of the vehicle speed sensor.
- the vehicle speed sensor 18 is connected to the sensor signal conditional circuit 36 via the electric circuit 22, and the conditional circuit 36 determines that the value of the detection signal from the vehicle speed sensor 18 exceeds a predetermined value.
- a signal is output to the microprocessor 37.
- the electric circuit 22 is connected between two signal lines connecting the two terminals on the output side of the vehicle speed sensor 18 and the two terminals on the input side of the conditional circuit 36, and between these two signal lines. Input impedance 35.
- a direct current (test pulse) is provided between the two signal lines of the electrical circuit 22 from the continuity test circuit 38 to provide the sensor 18 or the electrical circuit. 22 continuity tests are performed. If the sensor 18 or the electrical circuit 22 is conductive (normal), there is a relatively small voltage drop between the input terminals of the conditional circuit 36, and no output is produced from the conditional circuit 36. On the other hand, if the sensor 18 or the electric circuit 22 is not conductive (abnormal), the impedance viewed from the continuity test circuit 38 is high, and a voltage drop of a predetermined value or more occurs between both terminals of the input of the conditional circuit 36. An output is generated from the auxiliary circuit 36.
- the test pulse is provided between the two signal lines of the electric circuit 22 and the output of the conditional circuit 36 is 0, the sensor 18 or the electric circuit 22 is normal and the conditional circuit 36 is normal. Is not 0, it is determined that the sensor 18 or the electric circuit 22 is abnormal.
- Patent Document 2 relates to a diagnostic apparatus for diagnosing a failure in an electric system of an automobile.
- a test pulse signal is output from a pulse generator (see FIG. 4) to a diagnosis target component, and a response to the test pulse of the target component is detected (see FIG. 1), thereby detecting an abnormality in the target component.
- a device for diagnosis is described.
- the pressure detection system of the negative pressure booster cannot detect abnormality of the sensor circuit using the test pulse as in Patent Documents 1 and 2.
- Patent Documents 1 and 2 require additional parts for a circuit for generating a test pulse, a circuit for evaluating the output of the test pulse, and the like, which may increase the cost.
- An object of the present invention is to make it possible to reliably detect abnormality of an electric circuit even in a situation where the value of the surrounding environment cannot be specified in an electric circuit whose behavior changes according to the surrounding environment.
- an object of the present invention is to make it possible to easily and reliably detect an abnormality in an electric circuit whose behavior changes according to the surrounding environment.
- One embodiment of the present invention relates to an abnormality detection device that detects an abnormality of a detection circuit (112) that detects a specific type of physical quantity.
- This abnormality detection device changes the magnitude of the power supply voltage (Vcc ′) supplied to the detection circuit (112), and based on the output signal (Vo2) from the detection circuit at the changed power supply voltage (Vc2).
- an abnormality detector (220a) for detecting an abnormality of the detection circuit.
- specific types of physical quantities include values of pressure, temperature, speed, acceleration, and humidity, but are not limited thereto.
- the magnitude of the power supply voltage supplied to the detection circuit is changed, and the output signal (Vo2) of the detection circuit with respect to the changed power supply voltage (Vc2) is a predetermined input voltage. It is possible to detect abnormality of the detection circuit by determining whether or not the output characteristic is complied with. That is, even if the current physical quantity is unknown, an abnormality in the detection circuit can be detected if the input / output characteristics of the detection circuit are known in advance.
- the input / output characteristics are the relationship between the input and output values of the detection circuit and indicate the relationship between the power supply voltage (input) and the output signal.
- the abnormality detection unit (220a) is configured such that the output signals (Vo1, Vo2) from the detection circuit (112) before and after the power supply voltage change are input / output characteristics with respect to the same physical quantity (P). An abnormality of the detection circuit (112) is detected based on whether or not it is on the curve.
- an input / output characteristic curve corresponding to each physical quantity is obtained and stored in advance, and the output signals (Vo1, Vo2) of the detection circuit (112) before and after the power supply voltage change within a short time that the physical quantity does not change. ) Are detected and the detection circuit is determined to be normal when they are on the input / output characteristic curve for the same physical quantity, and the detection circuit is determined to be abnormal when they are not on the input / output characteristic curve for the same physical quantity. .
- the input / output characteristic curve of the detection circuit can be calculated, the input / output characteristic curve corresponding to each physical quantity need not be stored in advance when calculating the input / output characteristic during the abnormality detection process.
- the input / output characteristics of the detection circuit are linear, there is no need to store the input / output characteristic curves corresponding to each physical quantity in advance, and the ratio of output signals before and after the change matches the ratio of inputs before and after the change.
- An abnormality of the detection circuit can also be detected based on whether or not to do so.
- the abnormality detection unit (220a) is configured such that the ratio of the output signals (Vo1, Vo2) from the detection circuit (112) before and after the power supply voltage change is the power supply voltage (Vc1, Vc2) before and after the change.
- An abnormality of the detection circuit (112) is detected on the basis of whether or not the ratio matches.
- the input / output characteristic of the detection circuit is a straight line
- an abnormality of the detection circuit can be detected based on whether the ratio of the output signals before and after the change matches the ratio of the inputs before and after the change.
- the abnormality detection unit (220a) changes the power supply voltage to a plurality of different voltages (Vc2, Vc3), and uses the changed power supply voltages (Vc2, Vc3).
- An abnormality of the detection circuit (112) is detected based on the output signals (Vo2, Vo3) from the detection circuit (112).
- output signals (Vo2, Vo3) at the plurality of changed power supply voltages (Vc2, Vc3) are in accordance with predetermined input / output characteristics, and an abnormality of the detection circuit is detected. Can do. Further, output signals (Vo1, Vo2, Vo3) for three or more types of power supply voltages (Vc1, Vc2, Vc3) including a power supply voltage (Vcc) before the change and a plurality of power supply voltages (Vc2, Vc3) after the change are predetermined. It may be determined whether or not the input / output characteristics are obeyed. In this case, when the input / output characteristic is a curve, it can be determined with high accuracy whether or not the output signal follows the predetermined input / output characteristic.
- the abnormality detection unit (220a) measures the output signal from the detection circuit (112) with respect to the power supply voltage value (Vc1) before the change at least twice at a predetermined time interval.
- the abnormality of the detection circuit is detected based on the output signal (Vo2) from the detection circuit at the changed power supply voltage (Vc2) To do.
- the physical quantity to be detected does not change in a short time, and the physical quantity is The abnormality detection process can be executed under a condition that does not change in a short time.
- a power supply voltage control unit (230) that changes the magnitude of the power supply voltage (Vcc ') supplied to the detection circuit (112) by the control of the abnormality detection unit (220a) is provided.
- Vcc ' the magnitude of the power supply voltage supplied to the detection circuit (112) by the control of the abnormality detection unit (220a)
- the detection circuit (112) is a pressure sensor that detects a pressure in a negative pressure booster that assists a vehicle braking device.
- the negative pressure booster residual pressure may remain even after the engine is stopped, and the pressure value cannot be determined. Therefore, the conventional method using the test pulse cannot detect abnormality of the pressure sensor.
- the present invention even if the pressure value at the time of diagnosis is unknown, an abnormality in the detection circuit can be detected if the input / output characteristics of the detection circuit are known in advance.
- An embodiment of the present invention relates to an abnormality detection device that detects an abnormality of an electric circuit (112) whose behavior changes according to the surrounding environment.
- This abnormality detection device changes the magnitude of the power supply voltage (Vcc ′) supplied to the electric circuit (112), and based on the behavior (Vo2) of the electric circuit at the changed power supply voltage (Vc2),
- An abnormality detection unit (220a) for detecting an abnormality in the electric circuit is provided.
- the ambient environment is a state such as pressure, temperature, speed, acceleration, temperature, and humidity around the electric circuit.
- the detection system includes a detection circuit (112) that detects a specific type of physical quantity, a processing device (200) that processes an output from the detection circuit (112), and an electrical connection between the detection circuit and the processing device.
- Conductive lines (L1, 101; L2, 102; L3, 103) connected to each other and monitoring conductive lines (L1a, 101a; L2a, electrically connected to the conductive lines on the detection circuit (112) side) 102a; L3a, 103a), and detecting a potential at a connection point between the conductive line and the monitoring conductive line by the monitoring conductive line, thereby detecting a resistance state of the conductive line.
- the detection system further changes the magnitude of the power supply voltage (Vcc ′) supplied to the detection circuit (112) and outputs the output signal (Vo2) from the detection circuit at the changed power supply voltage (Vc2).
- Vcc ′ the power supply voltage supplied to the detection circuit (112
- Vo2 the output signal from the detection circuit at the changed power supply voltage (Vc2).
- the electronic system includes a first electric circuit (112) whose behavior changes according to an ambient environment, a second electric circuit (200), and between the first electric circuit and the second electric circuit.
- Conductive lines (L1, 101; L2, 102; L3, 103) and monitoring signal lines (L1a, 101a; electrically connected to the conductive lines on the first electric circuit side).
- L2a, 102a; L3a, 103a) and detecting a potential at a connection point between the conductive line and the monitoring signal line by the monitoring signal line, thereby detecting a resistance state of the conductive line.
- the electronic system further changes the magnitude of the power supply voltage (Vcc ′) supplied to the first electric circuit (112), and changes the power supply voltage (Vc2) of the first electric circuit after the change.
- An abnormality detection unit (220a) that detects an abnormality of the first electric circuit (112) based on the behavior (Vo2) is provided.
- the power supply voltage (Vcc ′) supplied to the detection circuit (112) is large.
- 112 is provided with an abnormality detection unit (220b) for detecting the abnormality.
- the abnormality detection unit (220b) is further configured to electrically connect the detection circuit (112) to the outside based on the power supply voltage (Vx) at which the detection unit (151) stops. Detect the resistance state of the line.
- the power supply voltage (Vcc ′) supplied to the detection circuit (112) is large.
- the power supply voltage (Vx) at which the detection unit (151) stops is detected by changing the length, and the resistance state of the conductive wire connecting the detection circuit (112) to the outside is detected based on the detected value
- An abnormality detection unit (220b) is provided.
- the magnitude of the power supply voltage (Vcc ′) supplied to the electric circuit (112) is changed, and the electric circuit (112) is included in the one embodiment.
- An abnormality that detects an output signal (Vout) of the electric circuit (112) below the power supply voltage (Vx) at which the unit (151) stops and detects an abnormality of the electric circuit (112) based on the detected value A detection unit (220b) is provided.
- the magnitude of the power supply voltage (Vcc ′) supplied to the electric circuit (112) is changed, and a part of the electric circuit (112) ( 151) includes an abnormality detection unit (220b) that detects the power supply voltage (Vx) that stops and detects a resistance state of a conductive line that connects the electric circuit (112) to the outside based on the detected value.
- the first abnormality detection unit (220a) changes the magnitude of the power supply voltage (Vcc ′) supplied to the detection circuit (112) and is equal to or higher than the power supply voltage (Vx) at which the detection unit (151) stops. In this range, an output signal (Vo2) from the detection circuit with respect to the changed power supply voltage (Vc2) is detected, and an abnormality of the detection circuit is detected based on the detected value.
- the second abnormality detection unit (220b) detects the power supply voltage (Vx) at which the detection unit (151) stops, and based on this detection value, a conductive wire that connects the detection circuit (112) to the outside The resistance state of is detected.
- One embodiment of the present invention is an abnormality detection device that detects an abnormality of an electric circuit (112) including a circuit part (151) whose behavior changes according to the surrounding environment, and includes a first abnormality detection unit (220a). And a second abnormality detection unit (220b).
- the first abnormality detection unit (220a) changes the magnitude of the power supply voltage (Vcc ′) supplied to the electric circuit (112) so as to be equal to or higher than the power supply voltage (Vx) at which the circuit portion (151) stops. In this range, an output signal (Vo2) from the detection circuit with respect to the changed power supply voltage (Vc2) is detected, and an abnormality of the electric circuit is detected based on the detected value.
- the second abnormality detection unit (220b) detects the power supply voltage (Vx) at which the circuit portion (151) stops, and based on the detected value, a conductive wire that connects the electric circuit (112) to the outside The resistance state of is detected.
- the detection system includes a detection circuit (112) including a detection unit (151) that detects a specific type of physical quantity, a processing device (200) that processes an output from the detection circuit (112), the detection circuit, and the detection circuit.
- Conductive lines (L1, 101; L2, 102; L3, 103) that are electrically connected to the processing apparatus, and monitoring conductive lines that are electrically connected to the conductive lines on the detection circuit (112) side (L1a, 101a; L2a, 102a; L3a, 103a), and by detecting a potential at a connection point between the conductive line and the monitoring conductive line by the monitoring conductive line, the resistance state of the conductive line Is detected.
- the detection system further changes the magnitude of the power supply voltage (Vcc ′) supplied to the detection circuit (112), so that the detection unit (151) is less than the power supply voltage (Vx) at which it stops.
- An abnormality detection unit (220b) that detects an output signal (Vout) of the detection circuit (112) and detects an abnormality of the detection circuit (112) based on the detected value.
- the electronic system includes a first electric circuit (112), a second electric circuit (200), and a conductive wire (electrically connecting between the first electric circuit and the second electric circuit).
- the resistance state of the conductive line is detected by detecting the potential at the connection point between the conductive line and the monitoring signal line by the monitoring signal line.
- the electronic system further changes the magnitude of the power supply voltage (Vcc ′) supplied to the electric circuit (112), and stops the power supply voltage (Vx) at which a part (151) of the electric circuit stops.
- An abnormality detection unit (220b) that detects an output signal (Vout) of the electric circuit (112) at less than and detects an abnormality of the electric circuit (112) based on the detected value.
- the first abnormality detection unit (220a) changes the magnitude of the power supply voltage (Vcc ′) supplied to the detection circuit (112) and is equal to or higher than the power supply voltage (Vx) at which the detection unit (151) stops. In this range, an output signal (Vo2) from the detection circuit with respect to the changed power supply voltage (Vc2) is detected, and an abnormality of the detection circuit is detected based on the detected value.
- the second abnormality detection unit (220b) detects the output signal (Vout) of the detection circuit (112) below the power supply voltage (Vx) at which the detection unit (151) stops, and based on this detection value The abnormality of the detection circuit (112) is detected.
- One embodiment of the present invention is an abnormality detection device that detects an abnormality of an electric circuit (112) including a circuit part (151) whose behavior changes according to the surrounding environment, and includes a first abnormality detection unit (220a). And a second abnormality detection unit (220b).
- the first abnormality detection unit (220a) changes the magnitude of the power supply voltage (Vcc ′) supplied to the electric circuit (112) so as to be equal to or higher than the power supply voltage (Vx) at which the circuit portion (151) stops. In this range, an output signal (Vo2) from the detection circuit with respect to the changed power supply voltage (Vc2) is detected, and an abnormality of the electric circuit is detected based on the detected value.
- the second abnormality detector (220b) detects the output signal (Vout) of the electric circuit (112) below the stop power supply voltage (Vx) at which a part (151) of the electric circuit stops, and this detected value Based on the above, an abnormality of the electric circuit (112) is detected.
- One embodiment of the present invention is an electrical system, comprising: a first electrical circuit (112); a ground line (L3, 103) connected to a ground terminal of the first electrical circuit (112); And a monitoring conductive line (L3a, 103a) that is electrically connected to the ground line and detects a potential (V2 ′) at a connection point with the ground line, and detects a voltage (V2) detected by the monitoring conductive line. Based on this, the behavior (Vout) of the first electric circuit (112) is corrected.
- the monitoring conductive line (L3a, 103a) is connected to the power supply voltage (Vcc) via the first resistor (R5) and via the second resistor (R6). Are connected to the ground potential (GND), and the abnormality of the monitoring conductive line itself is detected by detecting the voltage of the second resistor as the detection voltage (V2).
- the detection voltage (V2) by the monitoring conductive line is smaller than a first threshold
- the detection voltage (V2) by the monitoring conductive line is used, and the first electric
- the behavior (Vout) of the circuit (112) is corrected and the detection voltage (V2) by the monitoring conductive line is equal to or higher than a first threshold, it is determined that the monitoring conductive line is disconnected.
- the detection voltage (V2) by the monitoring conductive line is smaller than a second threshold value smaller than the first threshold value, it is determined that the ground line is normal, and the first The correction is not performed when the behavior (Vout) of the electric circuit (112) of the first electric circuit (112) is executed, and the detection voltage (V 2) by the monitoring conductive line is equal to or higher than the second threshold and lower than the first threshold.
- the detected voltage (V2) of the first electric circuit (112) is corrected using the detected voltage (V2) of the conductive wire for detection, and the detected voltage (V2) of the conductive wire for monitoring is the first threshold value. When it is above, it is determined that the monitoring conductive wire is disconnected.
- the first electric circuit (112) is a detection circuit that detects a specific type of physical quantity, and the detection circuit (V2) is used to detect the detection circuit ( 112) is corrected.
- an output voltage (Vout) of the detection circuit (112) and an upper limit value (VDD) of the output voltage (Vout) are detected using the detection voltage (V2) by the monitoring conductive line.
- the physical quantity to be detected is corrected by correcting.
- the detection circuit (112) is a pressure sensor that detects a pressure in a negative pressure booster that assists a vehicle braking device, and the output voltage (Vout) is a pressure detection signal.
- the semiconductor device further includes a third resistor (R7) interposed in the monitoring conductive line (L3a, 103a), and one end of the third resistor (R7) is connected to the first resistor. (R5) and the other end of the third resistor (R7) is connected to the second resistor (R6).
- R7 interposed in the monitoring conductive line (L3a, 103a), and one end of the third resistor (R7) is connected to the first resistor. (R5) and the other end of the third resistor (R7) is connected to the second resistor (R6).
- the monitoring conductive line is further connected to a ground potential via a first capacitor (C1) connected in parallel to the second resistor (R6).
- FIG. 1 is a circuit diagram of a detection system according to a first embodiment of the present invention.
- the circuit diagram when the ground line is in a high resistance state In the circuit diagram of the detection system which concerns on 1st Embodiment, the circuit diagram in the case of connecting a monitoring line and a ground line outside a sensor chip.
- the circuit diagram of the detection system concerning a 2nd embodiment of the present invention.
- the circuit diagram when the grounding line will be in a high resistance state in the detection system which concerns on 2nd Embodiment of this invention.
- FIG. 1 is a circuit diagram in which an embodiment of the present invention is applied to a power supply line and a detection signal line.
- the circuit diagram of the detection system concerning a 3rd embodiment.
- An input / output characteristic curve representing the behavior of the circuit under diagnosis for each value of the surrounding environment.
- 9 is a flowchart for explaining abnormality detection processing of a detection circuit 112 according to a third embodiment.
- FIG. 11 is a diagram when the input / output characteristic is a straight line in FIG. 10.
- 10 is a flowchart for explaining an abnormality detection process of the detection circuit 112 according to the third embodiment when the input / output characteristic is a straight line.
- 2 is a configuration example of a power supply voltage control circuit.
- the circuit diagram of the detection system concerning a 4th embodiment of the present invention.
- the block diagram showing the structure of a detection circuit.
- An input / output characteristic curve representing the behavior of the circuit under diagnosis for each value of the surrounding environment.
- FIG. 1 shows a circuit diagram of a detection system according to the first embodiment of the present invention.
- the detection system used for detecting the pressure of the negative pressure booster for assisting the braking device of the vehicle will be described as an example.
- the present embodiment is not limited to the detection system. Any configuration can be applied to any electrical system as long as power supply or signal communication is performed between a plurality of circuits.
- a detection system 1 shown in FIG. 1 includes a detection device 100 and a processing device 200, and the detection device 100 and the processing device 200 are electrically connected by signal lines (conductive lines) L1 to L3 and L3a.
- the detection device 100 is a pressure detection device, and is a detection device that is mounted on a negative pressure booster (not shown) that assists the braking device of the vehicle and detects the pressure (negative pressure) in the negative pressure booster.
- the processing device 200 is, for example, an electronic control unit (ECU) mounted on a vehicle, and supplies a power supply voltage (input signal) to the detection device 100 and receives a pressure detection signal (output signal) from the detection device 100.
- the pressure detection signal is used for various vehicle controls.
- the signal line L1 is a detection signal line that outputs a pressure detection signal in the detection device 100 to the processing device 200, and is connected to the detection signal electrode P1 of the detection device 100 and the detection signal terminal T1 of the processing device 200.
- the signal line L2 is a power supply line that supplies a power supply voltage Vcc (for example, 5 V) from the processing device 200 to the detection device 100, and is connected to the power supply electrode P2 of the detection device 100 and the power supply terminal T2 of the processing device 200.
- the signal line L3 is a ground line that supplies a ground potential (GND) from the processing device 200 to the detection device 100, and is connected to the ground electrode P3 of the detection device 100 and the ground terminal T3 of the processing device 200.
- the signal line L3a is a monitoring line for monitoring and detecting an abnormality in the ground line L3, and supplies the processing device 200 with the potential V2 'on the detection device 100 side of the ground line L3.
- the detecting device 100 includes a resin-molded housing 110 and a sensor chip 111 installed in the housing 110.
- the sensor chip 111 includes a pressure detection circuit 112, and the pressure detection circuit 112 is provided with, for example, a pressure sensor including a diaphragm and a resistance bridge, an amplification circuit, and the like.
- the sensor chip 111 and the signal lines L1 to L3 are connected by the detection signal line 101, the power line 102, the ground line 103, and the wires 101 to 103 and 103a as the monitoring line 103a, and the wires 101 to 103 and 103a are connected.
- the pressure detection circuit 112 is connected to the signal lines L1 to L3 via.
- the pressure detection circuit 112 detects the pressure in the negative pressure booster, and outputs a pressure detection signal to the detection signal terminal T1 of the processing device 200 via the detection signal line 101, the detection signal electrode P1, and the detection signal line L1. Further, the pressure detection signal is input to the detection signal terminal 211 of the ADC 210 via the detection signal line 201.
- the pressure detection circuit 112 is supplied with the power supply voltage Vcc from the power supply Vcc of the processing apparatus 200 via the power supply line 202, the power supply terminal T 2, the power supply line L 2, the power supply electrode P 2, and the power supply line 102. Further, the ground potential GND is supplied to the pressure detection circuit 112 from the ground line 203 of the processing apparatus 200 through the ground terminal T3, the ground line L3, the ground electrode P3, and the ground line 103.
- the housing 110 is formed with a recess for receiving a connector (not shown) attached to one end of the signal lines L1 to L3 and L3a during resin molding, and the bottom surface of the recess penetrates into and out of the housing.
- Comb-like electrodes P1 to P3 and P3a corresponding to the signal lines L1 to L3 and L3a are provided.
- the recess and the electrodes P1 to P3 and P3a constitute a connector on the detection device 100 side.
- the electrodes P1 to P3 and P3a are formed inside the housing 110 to receive the tips of the wires 101 to 103 and 103a, and the tips of the wires 101 to 103 and 103a are fitted and connected to the electrodes P1 to P3.
- the wires 101 to 103 and 103a are electrically connected to the signal lines L1 to L3 and L3a via the electrodes P1 to P3, respectively.
- the ground lines L3 and 103 and the monitoring lines L3a and 103a are electrically connected in the sensor chip 111.
- an analog / digital converter (ADC) 210 is provided in the processing apparatus 200.
- the ADC 210 includes a detection signal terminal 211 to which a pressure detection signal is input, a reference terminal 212 to which a power supply voltage Vcc is supplied via a power supply line 202 in the processing apparatus 200, and the ground lines L3 and 103 on the processing apparatus 200 side.
- the detection signal terminal T1 of the processing device 200 is connected to the detection signal terminal 211 of the ADC 210 via the detection signal line 201 and is connected to the power source VA via the pull-up resistor R2.
- the voltage of the pressure detection signal input to the ADC 210 changes in the range of 0.25V to 4.75V, and the detection signal line L1 is disconnected (detection signal terminal)
- the detection signal line L1 is disconnected (detection signal terminal)
- the voltage input from the power source VA to the ADC 210 via the resistor R2 is 5 V or more.
- the disconnection of the detection signal line L1 can be detected based on the difference in input voltage to the ADC 210.
- the power supply voltage Vcc is supplied from the power supply Vcc of the processing apparatus 200 to the pressure detection circuit 112 in the sensor chip 111 via the power supply line 202 and the power supply lines L2 and 102.
- the pressure detection signal from the pressure detection circuit 112 is supplied to the detection signal terminal 211 of the ADC 210 via the detection signal lines 101, L 1, 201.
- the ground potential GND of the processing apparatus 200 is supplied from the ground line 203 to the pressure detection circuit 112 of the detection apparatus 100 via the ground lines L3 and L103.
- the ground potential GND of the processing device 200 is input from the ground line 203 to the signal terminal 213 of the ADC 210, and the potential V2 ′ at the connection point (monitoring point) between the ground lines L3, 103 and the monitoring lines L3a, 103a is set.
- the monitoring terminal 213a of the ADC 210 via the monitoring line 103a, the monitoring electrode P3a, and the monitoring lines L3a and 203a.
- the power supply voltage Vcc is a resistance value R0 of the sensor chip 111 (a resistance value between the input portion of the power supply line 102 of the sensor chip 111 and the connection point (V2 ′)).
- the resistor RX can be calculated by the following equation (1) based on the potential V2 ′ at the connection point.
- RX V2 ′ / (Vcc ⁇ V2 ′) * R0 (1)
- the resistance state of the ground line L3 can be evaluated by the resistance value RX. Further, since the potential V2 'at the connection point has a one-to-one correspondence with the resistance value RX, the resistance state of the ground line can be evaluated using the potential V2' at the connection point.
- Specific processing in the processing apparatus 200 is as follows.
- the signal is input to the monitoring terminal 213a of the ADC 210 via L3a and 203a.
- the ADC 210 converts the potential V1 (reference value) on the processing device 200 side of the ground lines L3 and 103 and the potential V2 at the connection point into digital signals and outputs them to the processing unit 220.
- the processing unit 220 may calculate the resistance value RX of the ground line using the detected value of V2 ′ and the equation (1). In this case, it is possible to monitor the resistance value RX and detect a change in the resistance value of the ground line and an abnormality that causes a high resistance state.
- the potential V2 ′ at the connection point between the ground lines L3, 103 and the monitoring lines L3a, 103a is monitored via the monitoring lines L3a, 103a, thereby reducing the resistance of the ground line.
- the state can be detected. Therefore, it is possible to reliably detect an abnormality in which the ground lines L3 and 103 are in a high resistance state.
- vibration due to the operation of the negative pressure booster is transmitted to the detection device 100, and the contact resistance between the ground lines L3, 103 and the electrode P3 is deteriorated.
- the resistance value RX of the ground line can be detected.
- the resistance state of the ground lines L3, 103 is monitored by monitoring the potential V2 ′ at the connection point between the ground lines L3, 103 and the monitoring lines L3a, 103a via the monitoring lines L3a, 103a. Therefore, it is possible to detect anomalies with a simple configuration.
- the monitoring lines L3a and 103a that are electrically connected to the ground lines L3 and 103 are provided on the detection device 100 side, and the resistance state of the ground lines L3 and 103 is detected.
- the present invention can also be applied to the lines L2, 102 and the detection signal lines L1, 101.
- the power supply potential Vcc input to the terminal 212 of the ADC 210 is used as a reference value, and the potential at the connection point between the power supply lines L2 and 102 and the monitoring lines L2a and 102a is monitored. Detect resistance state.
- the detection signal line for example, the detection signal voltage at the time of calibration for releasing the pressure in the negative pressure booster to the atmosphere (voltage input to the terminal 211 of the ADC 210) is used as the reference value, and the detection signal line L1, The potential of the connection point between 101 and the monitoring lines L1a and 101a is detected, and the resistance state of the detection signal line is detected by comparing this with the reference value.
- the processing unit 220 may be provided outside the processing apparatus 200, or both the ADC 210 and the processing unit may be provided in the processing apparatus. It may be provided outside the 200.
- a sensor in which a sensor detection circuit 112 is arranged on a printed wiring board may be used instead of the sensor chip 111.
- FIG. 4 shows a circuit diagram of a detection system according to the second embodiment of the present invention.
- the same components as those in the first embodiment are denoted by the same reference numerals, description thereof will be omitted, and portions different from those in the first embodiment will be described below.
- a potential correcting resistor R3 (10 ⁇ ) is interposed on the ground line 203 in the detection apparatus 100.
- the contact resistance increases at the connection portion between the electrode P3 and the ground line L3 of the detection device 100 (or the connection portion between the electrode P3 and the ground line 103), and the contact resistance increases on the ground lines L3 and 103.
- the resistor RX can be calculated by the following equation (2) based on the potential V2 ′ at the connection point.
- RX V2 ′ / (Vcc ⁇ V2 ′) * R0 ⁇ R3 (2)
- the determination of the resistance state of the ground line is performed as follows using the potential V2 'at the connection point or the input V2 of the ADC 210.
- V2 the potential of the ADC 210.
- 99 mV-10 mV ⁇ V2 ( ⁇ V) ⁇ 99 mV + 10 mV
- 99 mV + 10 mV ⁇ V2 ( ⁇ V) it is determined that the “ground line is in a high resistance state”
- ⁇ 10 mV ⁇ V2 ( ⁇ V ) If ⁇ 10 mV, it may be determined that “the monitoring line is disconnected”.
- V2 ( ⁇ V) when V2 ( ⁇ V) is within a predetermined value (0V, 99 mV) ⁇ 10 mV, it is determined that V2 ( ⁇ V) matches the predetermined value (0V, 99 mV). Is appropriately determined according to the resolution of the ADC 210.
- the ADC 210 outputs digital signals corresponding to the input analog signals V1 and V2.
- the processing unit 220 determines that “the ground line is normal” when ⁇ V is 99 mV ⁇ 10 mV ⁇ V ⁇ 99 mV + 10 mV, and determines that “the ground line is in a high resistance state” when 99 mV + 10 mV ⁇ ⁇ V, and ⁇ 10 mV ⁇ When ⁇ V ⁇ 10 mV, it is determined that “the monitoring line is disconnected”.
- the resistor R3 is provided on the ground line 203 in the processing apparatus 200, the resistor R3 may be provided on the ground line 103 side in the sensor chip 111 as shown in FIG.
- the potential correcting resistor R3 may be provided at any location on the ground line as long as it is electrically connected to the ground lines 103 and 203 in series.
- FIG. 9 shows a circuit diagram of a detection system according to the third embodiment of the present invention.
- This embodiment has the same configuration as that of the detection system of the first embodiment shown in FIG. 1 except that a power supply voltage control circuit 230 is added on the power supply line.
- a power supply voltage control circuit 230 is added on the power supply line.
- the detection system 1 shown in FIG. 9 includes a power supply voltage control circuit 230 on the power supply line 202 of the processing apparatus 200 in the detection system 1 of FIG.
- An abnormality detection unit 220 a that detects an abnormality of the detection circuit 112 is provided in the processing unit 220.
- the power supply voltage control circuit 230 may be disposed outside the processing apparatus 200.
- the power supply voltage control circuit 230 is interposed in series with the power supply line 202, and includes a voltage drop resistor RL and a switching circuit 231.
- a supply path of the power supply voltage Vcc ′ that does not pass through the resistor RL is referred to as a path I
- a supply path of the power supply voltage Vcc ′ that passes through the resistor RL is referred to as a path II.
- Vcc ′ Vcc ⁇ Vcc is output to the detection circuit 112.
- the switching circuit 231 is configured by, for example, a switch having a mechanical contact or a semiconductor switch.
- the switching circuit 231 may have any configuration as long as it is an element or a circuit that can switch the supply path of the power supply voltage Vcc to the paths I and II.
- the switching circuit 231 is connected to the abnormality detection unit 220a of the processing device 220 via the control line 232, and is switched between a conduction state and an open state by a control signal from the abnormality detection unit 220a.
- the switching circuit 231 becomes conductive.
- the processing device 220 includes, for example, a CPU and a microprocessor, and executes an abnormality detection process for detecting the high resistance state of the signal lines (L1, 101; L2, 102; L3, 103) described in the first embodiment.
- an abnormality detection unit 220a that detects an abnormality of the detection circuit 112 based on the detection signal (output signal) Vout after the power supply voltage is changed is further provided.
- the abnormality detection unit 220a controls the switching circuit 231 to change the power supply voltage Vcc ′ output to the detection circuit 112, and executes abnormality detection processing (described later with reference to the flowchart of FIG. 12).
- FIG. 10 shows an input / output characteristic curve representing the behavior of the diagnosis target circuit with respect to each value P of the surrounding environment.
- the diagnosis target circuit is the detection circuit 112 of the detection apparatus 100
- the value of the surrounding environment is a pressure value (a negative pressure value of the negative pressure booster) that is detected by the detection circuit 112.
- the behavior of the circuit to be diagnosed represents the relationship (Vcc ′, Vout) between the input (power supply voltage Vcc ′) and the output (detection signal Vout) of the detection circuit 112 with respect to each pressure value P.
- the input / output characteristic curve represents the behavior (Vcc ′, Vout) of the detection circuit 112 with respect to the value (pressure value) P of the same ambient environment as a curve (including a straight line).
- the present invention is not limited to the detection circuit, and can be applied to any electric circuit, electric element, and electronic element whose behavior changes according to the value of the surrounding environment.
- the value of the surrounding environment is not limited to the pressure value, and may be any physical quantity such as temperature, speed, acceleration, humidity, and the like.
- the behavior of the diagnosis target circuit with respect to each value of the surrounding environment is not limited to the input / output voltage, and at least one of the input and the output may be a current.
- the power supply voltage Vcc ′ is changed from Vc1 to Vc2 within a time during which the pressure value in the negative pressure booster (value of the surrounding environment) does not change, for example, within 100 msec (preferably 10 msec), and the output signal Vout is changed. If the detection circuit 112 is normal when detected, the value of the output signal Vout, that is, the behavior of the detection circuit 112 changes on the same input / output characteristic curve (CB) as shown by points s1 to s2 in FIG. .
- CB input / output characteristic curve
- the detection circuit 112 if the detection circuit 112 is abnormal, the value of the detection signal Vout, that is, the behavior of the detection circuit 112 deviates from the same input / output characteristic curve (CB), for example, from point s1 to point s21 or s22 in FIG. Change.
- CB input / output characteristic curve
- the detection circuit 112 of the detection circuit 112 is determined by determining “the detection circuit 112 is abnormal”. An abnormality detection process can be executed.
- the behaviors s1 and s2 before and after the change of the power supply voltage are the same as the input / output characteristics in order to enable detection even when the pressure (value of the surrounding environment) slightly fluctuates before and after the change of the power supply voltage (input).
- FIG. 12 is a flowchart for explaining abnormality detection processing of the detection circuit 112 according to the present embodiment.
- step S13 the values Vo1 and Vo1 ′ of the output signal Vout obtained in steps S10 and S12 are compared. If both are equal, that is, the pressure value (the value of the surrounding environment) changes between steps S10 to S12. If not, the process proceeds to step S14 to determine whether the detection circuit 112 is abnormal. On the other hand, if it is determined in step S13 that Vo1 and Vo1 'are different, the process returns to step S10 and the acquisition of the output signal Vout before and after the power supply voltage change is executed again.
- step S14 the output signal Vo1 (behavior s1 (Vc1, Vo1)) of the detection circuit 112 before the power supply voltage change and the output signal Vo2 (behavior s2 (Vc2, Vo2)) of the detection circuit 112 after the power supply voltage change are generated. It is determined whether or not they are on the input / output characteristic curve for the same pressure value. If both are on the same input / output characteristic curve, it is determined that the detection circuit 112 is normal (step S15). If they are not on the same input / output characteristic curve, it is determined that the detection circuit 112 is abnormal (step S16).
- the reason why the output signal Vo1 (behavior s1 (Vc1, Vo1)) for the power supply voltage value Vc1 before the change is measured twice in steps S10 and S12 is that the pressure value (the value of the surrounding environment) changes. This is because the behavior of the detection circuit 112 before and after the change of the power supply voltage is compared to determine whether or not there is an abnormality in a situation where the power supply voltage is not changed. Note that even if there is an error within a predetermined range (for example, about 1%) in the measurement value of the detection signal Vout twice with respect to the power supply voltage Vc1 before the change, it may be determined that the two measurement values match.
- a predetermined range for example, about 17%
- a predetermined error for example, 1%) in Vo2 (detection value
- the output signal Vo1 (behavior s1) of the detection circuit 112 with respect to the power supply voltage Vc1 before the change and the output signal Vo2 (behavior s2) of the detection circuit 112 with respect to the power supply voltage Vc2 after the change are the same input / output.
- the power supply voltage is changed from Vc1 to two or more different power supply voltages (for example, Vc2 and Vc3).
- the output signal Vo1 (behavior s1) for the power supply voltage Vc1 before the change the output signal Vo2 (behavior s2) for the power supply voltage Vc2 after the change, and the output signal for the power supply voltage Vc3 after the change. If all of Vo3 (behavior s3) are on the same input / output characteristic curve, it may be determined that “the detection circuit 112 is normal”. When the input / output characteristic for the pressure value is a curve, it is determined whether or not there is an abnormality in the detection circuit 112 by determining whether or not three or more points are on the same input / output characteristic curve. can do. In this case, the power supply voltage control circuit 231 is configured as shown in FIG.
- FIG. 13 is an input / output characteristic curve (input / output) when the relationship between the input (Vcc ′) and the output (Vout) of the detection circuit 112 is a straight line for each pressure value P in the input / output characteristic curve of FIG. Characteristic line).
- the output signal Vo1 (behavior s1 (Vc1, Vo1)) of the detection circuit 112 before the power supply voltage change and the output signal Vo2 of the detection circuit 112 after the power supply voltage change (Whether or not the behavior s2 (Vc2, Vo2)) is on the same characteristic line depends on whether the output signals Vo1, Vo2 (behavior s1, s2) of the detection circuit 112 before and after the power supply voltage change change at a predetermined ratio. This can be determined by examining the above.
- FIG. 14 is a flowchart illustrating an abnormality detection process of the detection circuit 112 according to the present embodiment when the input / output characteristic curve of the detection circuit 112 is a straight line. This flowchart is the same as the flowchart of FIG. 12 except for step S14a.
- step S14a it is determined whether or not the ratio Vo1 / Vo2 of the output signal Vout before and after the change of the power supply voltage matches the ratio Vc1 / Vc2 of the power supply voltage before and after the change. Is determined to be normal (step S15), and if they do not match, the detection circuit 112 is determined to be abnormal (step S16).
- step S14a when the ratio Vo1 / Vo2 of the output (Vout) before and after the power supply voltage change is within the range of Vc1 / Vc2 ⁇ predetermined error (for example, 1%), “Vo1 / Vo2 is Vc1 / Vc2. It may be determined that “matches”.
- step S14a the detection value Vo2 acquired in step S11 is compared with the theoretical value Vo2, and it is determined whether or not they match to detect an abnormality in the detection circuit 112. .
- a predetermined error range for example, 1%) of the theoretical value Vo2
- the resistance state of the signal line connected to the detection circuit 112 can be monitored by the monitoring line, and the output signal after the power supply voltage is changed.
- the abnormality of the detection circuit 112 itself can be reliably detected with a simple configuration. That is, according to the third embodiment, comprehensive abnormality detection for the detection apparatus 100 can be performed easily and reliably.
- the ambient environment value (pressure value, etc.) of the detection circuit 112 is known at the time of abnormality detection processing.
- the ambient environment value (pressure value, etc.) of the detection circuit 112 is known at the time of abnormality detection processing.
- residual pressure may remain in the negative pressure booster even when the engine is stopped, and it is not possible to determine whether the pressure value when the engine is stopped is atmospheric pressure or negative pressure remaining. I can't.
- the ambient environment values (pressure values, etc.) themselves are known, and the input / output characteristics of the detection circuit 112 for each pressure value are known.
- the abnormality of the detection circuit 112 is determined by determining whether the output of the detection circuit 112 before and after the power supply voltage change is in accordance with a known input / output characteristic (whether it is on the same input / output characteristic curve). Can be detected.
- the monitoring lines and the electrodes for connecting the monitoring lines described in the first and second embodiments are omitted, for example, the monitoring lines 103a, L3a, 203a, the electrode P3a, and the terminal T3a are omitted in FIG. good.
- the abnormality of the detection circuit 112 is detected without requiring an additional signal line for connecting the two, an additional electrode and a terminal for connecting the additional signal line. It can be reliably detected with a simple configuration.
- the component added in the processing device 200 is only the power supply voltage control circuit 231 including the resistor RL, the switch 231 and the like, and the abnormality of the detection circuit 112 is detected by software processing of the processing unit 220a with the minimum additional components. can do.
- the processing apparatus 200 when the processing apparatus 200 originally has a configuration in which the power supply voltage such as a regulator or a DC / DC converter is variable, it is not necessary to add the power supply voltage control circuit 231 and the processing unit 220a is software-like. An abnormality of the detection circuit 112 can be detected only by the processing.
- the power supply voltage control circuit 230 has been described as a configuration including the resistor RL and the switch 231, it may be a regulator or a DC / DC converter.
- the abnormality detection processing of the detection circuit 112 according to the present embodiment is not limited to the circuit shown in FIG. 1, but can be applied to the circuits of FIGS. 3, 4, 6, and 8 and modifications thereof. That is, the detection circuit 112 is obtained by combining the abnormality detection processing using the input / output characteristics of the detection circuit according to the third embodiment with the abnormality detection processing of the signal line using the monitoring line according to the first and second embodiments. It is possible to monitor the resistance state of the signal line connected to, and to reliably detect abnormality of the detection circuit 112 itself.
- FIG. 16 shows a circuit diagram of a detection system according to the fourth embodiment of the present invention.
- the present embodiment includes a power supply voltage control circuit 240 instead of the power supply voltage control circuit 230, an abnormality detection unit 220b instead of the abnormality detection unit 220a, and a monitoring line.
- the configuration is the same as that of the detection system of the third embodiment shown in FIG. 9 except that 103a, L3a, and 203a are omitted.
- the power supply voltage control circuit 240 receives an input of the power supply voltage Vcc, continuously changes the power supply voltage Vcc ′, and outputs it to the detection device 100.
- the power supply voltage control circuit 240 is a circuit that continuously changes the power supply voltage Vcc ′ by controlling switching elements such as transistors, and is a regulator circuit such as a DC / DC converter, for example.
- the power supply voltage control circuit 240 is connected to the processing unit 220 via the control line 241, and the value of the output power supply voltage Vcc ′ is controlled by the abnormality detection unit 220 b of the processing unit 220.
- FIG. 17 is a block diagram showing the configuration of the detection circuit 112.
- the detection circuit 112 is corrected by the detection unit (sensor) 151 that detects a physical quantity such as pressure, the correction circuit 152 that adds a predetermined correction ⁇ v to the detection signal vo output from the detection unit 151, and the correction circuit 152.
- the output signal Vout is input to the processing device 200 via the detection signal lines 101 and L1.
- the detection unit 151 is, for example, a pressure sensor including a diaphragm and a resistance bridge, and outputs an electric signal (detection signal) vo indicating a change in resistance due to deformation of the diaphragm.
- a predetermined correction value ⁇ v is added to the signal vo.
- the correction value ⁇ v is adjusted according to the value of the power supply voltage Vcc ′ supplied to the detection circuit 112 and is proportional to the power supply voltage Vcc ′.
- the correction value ⁇ v is adjusted in a decreasing direction so that the output signal Vout is output from the amplifier circuit 153 in the range of 0.3V to 2.7V.
- FIG. 19 shows an input / output characteristic curve (here, a straight line) of the detection circuit 112 for each pressure value.
- P PA, PB, PC (PA ⁇ PB ⁇ PC)
- Vcc ′ supplied to the detection circuit 112
- Vcc for example, 5 V
- the input / output characteristic of the detection circuit 112 is a straight line will be described as an example, but the input / output characteristic may be a curve as in the case of the third embodiment.
- the input / output characteristics of the detection circuit 112 change in accordance with the power supply voltage Vcc ′ regardless of the pressure value P and the region I that changes in response to the power supply voltage Vcc ′ for each pressure value P. Region II.
- an abnormality in a conductive line connecting the detection circuit 112 to an external circuit and an abnormality in the detection circuit 112 itself (abnormality in the detection circuit 112). Is detected.
- one of the conductive lines (L1, 101; L2, 102; L3, 103) is in a high resistance state based on the change (Vx0 ⁇ Vx1) of the minimum operating power supply voltage Vx. Detect that it is abnormal.
- any one of the conductive lines (L1, 101; L2, 102; L3, 103) is brought into a high resistance state due to the contact resistance or the like at the terminals P1 to P3, and for example, a resistance RX on the conductive line L3. (See FIG. 2 and the like), a part ⁇ Vcc of Vcc ′ supplied from the power supply voltage control circuit 240 is consumed by the resistor RX, and Vcc′ ⁇ Vcc is supplied to the detection circuit 112.
- Vcc ′ Vx0 + ⁇ Vcc
- Vx0 is supplied to the detection circuit 112
- the detection unit 151 (FIG. 17) does not operate and the input / output characteristics of the detection circuit 112 are determined regardless of the pressure value P. Abnormalities can be detected.
- FIG. 22 is a flowchart for explaining abnormality detection processing of the detection circuit 112 according to the fourth embodiment.
- the abnormality detection unit 220b controls the power supply voltage control circuit 240 to sweep the power supply voltage Vcc ′ from Vcc to 0 as shown in the horizontal axis of the graph of FIG. 19 (step S20), and from the change in the output signal Vout, the detection unit The minimum operating power supply voltage Vx at which 151 stops is detected (step S21), and the input / output characteristic curve C or the output signal Vout of the detection circuit 112 less than the minimum operating power supply voltage Vx is detected (step S22).
- the power supply voltage Vcc ′ is swept from Vcc to 0 V will be described.
- the power supply voltage Vcc ′ may be changed starting from a voltage lower than Vcc within a range in which the minimum operation power supply voltage Vx can be detected.
- the minimum operating power supply voltage Vx Vx0 (reference value) when the conductive line is normal and the value of the input / output characteristic curve C0 or the output signal Vout below Vx0 when the detection circuit 112 is normal are stored in advance. Keep it.
- step S23 the lowest operating power supply voltage Vx detected in step S21 is compared with Vx0 (reference value), and if the two match, it is determined that the conductive line is normal (step S24). On the other hand, if the minimum operating power supply voltage Vx and Vx0 (reference value) are different in step S23 (see FIG. 20), it is determined that the conductive line is abnormal (step S25).
- step S26 the input / output characteristic curve C detected in step S22 is compared with the reference curve C0, and when the two match, the detection circuit 112 determines that it is normal (step S27). On the other hand, if the input / output characteristic curve C is different from the reference curve C0 in step S26 (see FIG. 21), the detection circuit 112 determines that it is abnormal (step S28).
- step S22 When the input / output characteristic curve C0 below the minimum operating power supply voltage Vx0 is a straight line, one value of Vout below Vx is checked in step S22, and the detected value of Vout is compared with the reference value in step S26. May be.
- the detection circuit 112 based on the minimum operating power supply voltage Vx of the detection unit 151 determined regardless of the pressure value, the detection circuit 112 depends on the high resistance state of the conductive line connecting the external circuit. An abnormality can be detected, and an abnormality of the detection circuit 112 itself can be detected based on the input / output characteristics of the detection circuit 112 less than the minimum operating power supply voltage Vx.
- the abnormality detection processing since the region of the input / output characteristics not related to the pressure value is used, the abnormality detection of the detection circuit 112 is detected even when the ambient environment value (pressure value, etc.) itself is not known. Processing can be executed.
- the abnormality detection process for the detection circuit 112 and the conductive wire can be executed regardless of the pressure value even in a situation where the pressure value frequently fluctuates. Further, an abnormality caused by the high resistance state of the conductive wire can be detected without adding a monitoring line.
- the detection circuit that detects pressure is described as an example.
- the present embodiment can be applied to any detection circuit such as a detection circuit that detects temperature, speed, acceleration, humidity, and the like. is there.
- the abnormality detection method since the minimum operating power supply voltage Vx at which the detection unit 151 (FIG. 17) stops is used, actually, the correction circuit 152 excluding the detection unit 151 in the detection circuit 112 and An abnormality in the amplifier circuit 153 is detected.
- the abnormality detection process of the detection circuit 112 according to the third embodiment is equivalent to executing the abnormality detection process using the input / output characteristics of the region (I) above the minimum operating power supply voltage Vx in FIG. Therefore, it is possible to detect the presence or absence of abnormality in the entire detection circuit 112.
- the abnormality detection process of the detection circuit 112 itself is executed by the abnormality detection method according to the third embodiment, and the abnormality detection process of the conductive line connecting the detection circuit 112 to the external circuit is changed to the fourth embodiment. This is performed by the abnormality detection method.
- FIG. 23 is a flowchart for explaining the abnormality detection process of the detection circuit according to the fifth embodiment.
- the abnormality detection process of the detection circuit 112 itself is executed by the abnormality detection method according to the third embodiment, and the abnormality according to the fourth embodiment is performed. It is a flowchart which performs the abnormality detection process of a conductive wire with a detection method.
- the abnormality detection function of the processing unit 220 in this case is referred to as an abnormality detection unit 220c (not shown).
- the processing in step S31 corresponds to steps S10 and S11 in FIGS.
- the processing of steps S12 and S13 in FIGS. 12 and 14 may be added to confirm that the pressure value does not change, and then the diagnosis of the detection circuit 112 may be executed.
- step S33 the lowest operating power supply voltage Vx detected in step S32 is compared with Vx0 (reference value). If the two match, it is determined that the conductive line is normal (step S34), and the two do not match. Determines that the conductive wire is abnormal (step S35).
- step S38 the detection circuit 112 determines that there is an abnormality.
- the abnormality detection processing it is possible to detect an abnormality due to the high resistance state of the conductive wire without adding a monitoring line, and based on the input / output characteristics of the detection circuit 112 at Vx or higher. The presence or absence of abnormality in the entire detection circuit 112 including the detection unit 151 can be detected.
- the abnormality detection process of the detection circuit 112 itself may be executed using the method of the fourth embodiment, and the abnormality detection process of the conductive line may be executed using the method using the monitoring line of the first and second embodiments. In this case, it is possible to identify which conductive line has an abnormality by the method using the monitoring line, and it is possible to execute the abnormality detection process of the detection circuit 112 even in an ambient environment where the pressure is frequent.
- both the abnormality detection process of the detection circuit 112 itself according to the third embodiment and the abnormality detection process of the detection circuit 112 itself according to the fourth embodiment may be executed.
- the abnormality detection process of the third embodiment can detect an abnormality of the entire detection circuit including the detection unit in a situation where there is no pressure fluctuation, and the abnormality detection process of the fourth embodiment frequently causes a pressure fluctuation. Even underneath, it is possible to detect abnormality of the detection circuit excluding the detection unit. Therefore, the abnormality of the detection circuit 112 can be detected more reliably.
- the abnormality detection process of the conductive wire according to the fourth embodiment is combined to make the detection circuit 112 It is possible to easily and reliably perform the abnormality detection of the comprehensive detection circuit 112 including abnormality detection of the conductive wire connected to the external circuit.
- the abnormality detection process of the detection circuit 112 itself the abnormality detection process of the detection circuit 112 itself according to the fourth embodiment, the abnormality detection process of the conductive line according to the first and second embodiments, and the fourth embodiment.
- the abnormality detection of the comprehensive detection circuit 112 including the abnormality detection of the conductive line connecting the detection circuit 112 to the external circuit can be more reliably performed.
- the technical idea of the present invention is not limited to the detection of an abnormality in an electric circuit such as a detection circuit, but is also applicable to the detection of an abnormality in another electric device such as an electric motor or an electronic device.
- a predetermined power supply voltage Vcc ′ Vcc, that is, a sufficiently high power supply voltage is supplied and the motor is rotating at a high speed, even if the motor is in a high friction state due to a problem such as a bearing, the output rotation speed of the motor The change in is small and it is difficult to detect defects.
- the power supply voltage Vcc ′ when the supply power supply voltage Vcc ′ is decreased (when the rotational speed of the motor is decreased), the rotational speed of the motor is significantly reduced in the high friction state as compared with the normal state. Therefore, the power supply voltage Vcc is reduced to the power supply voltage Vy ( ⁇ Vcc) that causes a significant difference in the rotational speed of the motor between the normal state and the high friction state, and the detected value of the rotational speed is compared with the reference value.
- the abnormality detection process is performed as follows. During operation of the electric motor, the power supply voltage is decreased from Vcc to Vy, and the rotational speed R of the electric motor is detected. If the detected value R matches the reference value R0, it is determined that “the electric motor is normal”. Judge that “the motor is abnormal”.
- FIG. 24 is a circuit diagram of a detection system according to the sixth embodiment.
- the same components as those in the above embodiment are denoted by the same reference numerals, and detailed description thereof is omitted.
- parts different from the above embodiment will be described in detail.
- This detection system has a disconnection detection circuit 250 interposed in a monitoring line 203 a connected to the monitoring line 203 in the processing circuit 200.
- the detection circuit 250 includes a resistor R5 interposed between the monitoring line 203a and the power supply voltage Vcc, a resistor R6 interposed between the monitoring line 203a and the ground potential GND, and the monitoring line 203a and the ground potential GND.
- the monitoring line 203a is further connected to the ground potential GND via a capacitor C1 connected in parallel to the resistor R6.
- a resistor R7 is interposed in series with the monitoring line 203a. One end of the resistor R7 is connected to the first capacitor C1, and the other end of the resistor R7 is connected to the resistor R6.
- the power supply voltage Vcc is connected to the ground potential GND through the resistors R5, R7, and R6, and is connected to the ground potential GND through the resistor R5 and the capacitor C1.
- the capacitor C1 is provided to stabilize the potential of the monitoring line 203a.
- the resistor R7 is for limiting the current flowing into the ground terminal 213a of the ADC 210.
- RC1 and RC2 indicate the contact resistance and the resistance component of the conductive wire in the electrode or terminal.
- RC1 is connected to the contact resistance between the ground electrode P3 of the detection device 100 and the ground line 103, the contact resistance between the ground electrode P3 of the detection device 100 and the ground line L3, and the ground electrode P3 of the detection device 100.
- a resistance component between the point (V2 ′) and a resistance component on the ground line L3 are included.
- RC4 includes a contact resistance between the ground terminal T3 of the processing apparatus 200 and the ground line L3, a contact resistance between the ground terminal T3 of the processing apparatus 200 and the ground line 203, and a resistance component on the ground line 203. Including.
- the processing is performed.
- the current from the power supply voltage Vcc charges the capacitor C1 via the resistor R5, and after charging the capacitor C1, the current from the power supply voltage Vcc is changed to the monitoring lines 203a, L3a, It flows to the ground potential GND through 103a and the ground lines 103, L3, and 203.
- the current from the power supply voltage Vcc does not flow to the resistor R7 side, and the detection voltage V2 input from the monitoring line 203a to the monitoring terminal 213a of the ADC 210 is the same (0 V) as the ground potential GND.
- the contact resistances RC1 and RC2 are not 0 (when the resistance value of the path of the ground lines 203, L3 and 103 from the ground potential GND to the connection point (V2 ′) cannot be regarded as substantially 0), A potential difference is generated between the potential V2 ′ and the ground potential GND of the processing circuit 200. Accordingly, the potential of the ground terminal 112a of the detection circuit 112 (the same potential as the potential V2 'at the connection point) is also different from the ground potential GND of the processing circuit 200. In the present embodiment, the influence of the high resistance state of the ground line on the behavior (output voltage Vout) of the detection circuit 112 is corrected based on the detection voltage V2 indicating the resistance state of the ground line (103, L3, 203).
- the potential V2 ′ at the connection point is the current Ids flowing from the detection circuit 112 through the ground line (103, L3, 203) and the power supply voltage.
- the following expression (3)-(5) is expressed by the current Icc flowing from Vcc through the resistor R5, the monitoring lines (203a, L3a, 103a), and the ground lines (103, L3, 203).
- V2 (Ids + Icc) * (RC1 + RC2)
- Ids 10mA
- Icc Vcc / (R5 + RC1 + RC2) (5)
- Ids is assumed to be a value of 10 mA (a constant value) that typically flows in the detection circuit 112.
- the potential V2 'at the connection point is a value proportional to RC1 + RC2.
- the contact resistance RC1 + RC2 is compared with the resistance value of the resistor R7.
- the current I7 flowing through the resistor R7 is sufficiently smaller than the current Ids and can be ignored.
- the current Icc is several mA, and the current I7 flowing through the resistor R7 is about 1 ⁇ A.
- the voltage drop at the resistor R7 can be ignored, and the detection voltage V2 input to the monitoring terminal 213a of the ADC 210 can be regarded as the potential V2 'at the connection point.
- the detection voltage V2 input to the monitoring terminal 213a of the ADC 210 can be regarded as the potential V2 'at the connection point.
- the potential shift of the ground terminal of the detection circuit 112 can be corrected using the detection voltage V2.
- FIG. 26 is an explanatory diagram for explaining a process of correcting the output voltage Vout of the detection circuit 112 with the detection voltage V2.
- FIG. 26A is a characteristic curve showing the relationship between the output voltage Vout and the detected pressure (negative pressure) when the potential V2 'at the connection point matches the ground potential (0V).
- FIG. 26B shows a characteristic curve when the potential V2 'at the connection point rises due to the contact resistance RC1 + RC2 of the ground line.
- the characteristic curve of the pressure detection circuit 112 is a curve as shown in FIG.
- the section decreasing linearly in the characteristic curve of FIG. 26 (a) is expressed by equation (6).
- Vout (c1 * pe + c0) * VDD (6)
- Vout is the output voltage [V] of the pressure detection circuit 112
- pe is the detection pressure (negative pressure: [kPa]).
- c1 and c0 are constants determined by the specification of the pressure detection circuit 112.
- VDD is a reference voltage that determines the slope of the characteristic curve, and corresponds to the upper limit value [V] (3.3 [V] in this example) of the pressure detection range of the pressure detection circuit 112.
- the reference voltage VDD is set in advance according to the value of the power supply voltage Vcc according to the type of the pressure detection circuit 112.
- FIG. 26B is a characteristic curve when the potential V2 ′ (detection voltage V2) at the connection point increases due to the contact resistance Rc1 + RC2 of the ground line.
- V2 ′ detection voltage V2
- the output voltage Vout and the reference voltage VDD are corrected by the correction amount V2 as in Expression (7).
- the corrected output voltage Vout and the reference voltage VDD are set as an effective output voltage Vout_eff and an effective reference voltage VDD_eff, respectively.
- Vout_eff Vout ⁇ V2
- VDD_eff VDD ⁇ V2 (7)
- the detected pressure pe is calculated by the equation (8).
- the detected pressure pe compensated for the contact resistance of the ground line can be calculated. This process can compensate for the influence of the resistance value on the ground line on the detected pressure pe even when the resistance value is unexpectedly increased on the ground line.
- the detection voltage V2 input to the monitoring terminal 213a of the ADC 210 is a voltage applied to the resistor R6.
- the voltage of the resistor R6 is a voltage obtained by dividing the power supply voltage Vcc by the resistor R5 + R7 and the resistor R6, and is given by Expression (9).
- V2 Vcc * R6 / (R5 + R7 + R6) (9)
- V2 2.88 [V].
- the ADC 210 outputs digital signals corresponding to the input analog signals V1 and V2.
- the processing unit 220 determines that “the ground line is normal” when ⁇ V is ⁇ 10 mV ⁇ V ⁇ 10 mV, and determines that “the ground line is in a high resistance state” when 10 mV ⁇ ⁇ V ⁇ Vth, and Vth ⁇ In the case of ⁇ V, it is determined that “the monitoring line is disconnected”.
- V2 ′ V2 matches the predetermined value (0 V).
- this range is appropriately determined according to the resolution of the ADC 210. decide.
- the detected pressure pe may be calculated by the equation (6) without correcting the output voltage Vout and the reference voltage VDD.
- This process can compensate for the influence of the resistance value on the ground line on the detected pressure pe even when the resistance value is unexpectedly increased on the ground line.
- the detected pressure Pe can be corrected according to the resistance state of the ground line, and accurate pressure detection is continued while avoiding the stoppage of the system. be able to.
- the disconnection detection circuit 250 including the resistors R5 and R6 interposed between the monitoring line and the power supply voltage Vcc and the ground potential GND is arranged, so that the detection apparatus 110 has a special configuration. It is possible to detect the disconnection of the monitoring line itself for monitoring the resistance state of the ground line without adding.
- the correction processing of the output voltage Vout and the reference voltage VDD described above can also be applied to the first embodiment.
- the output voltage Vout and the reference voltage VDD may be corrected using ⁇ V calculated in the first embodiment as a correction amount.
- the detection system has been mainly described.
- the present invention is not limited to the detection system, and can be applied to any electric system as long as power supply or signal communication is performed between a plurality of circuits. is there.
- Detection System 100 Detection Device (Sensor Device) 200 Processing unit (ECU) 101, L1, 201 Detection signal line 102, L2, 202 Power supply line 103, L3, 203 Ground line 101a to 103a, L1a to L3a, 201a to 203a Monitoring lines P1 to P3, P1a to P3a Electrodes T1 to T3, T1a to T3a Terminal 110 Housing 111 Sensor chip 112 Detection circuit 112a Ground terminal 151 Detection unit 152 Correction circuit 153 Amplification circuit 210 Analog to digital converter (ADC) 220 processing unit 220a, 220b abnormality detection unit R2, R3 resistance Vcc power supply voltage source, power supply voltage 230, 240 power supply voltage control circuit 231 switching circuit 232, 241 control line 250 disconnection detection circuit RL resistance for voltage drop
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Abstract
Description
図1は、本発明の第1実施形態に係る検出システムの回路図を示す。ここでは、車両の制動装置を補助するための負圧ブースタの圧力を検出するために使用される検出システムを例に挙げて説明するが、本実施形態は、検出システムに限定されるものではなく、複数の回路間で電源供給又は信号通信を行う構成であれば、任意の電気システムに適用可能である。
図1に示す検出システム1は、検出装置100と処理装置200とを備え、検出装置100と処理装置200との間は信号線(導電線)L1~L3、L3aによって電気的に接続されている。検出装置100は、圧力検出装置であり、車両の制動装置の補助を行う負圧ブースタ(図示せず)に装着されて負圧ブースタ内の圧力(負圧)を検出する検出装置である。処理装置200は、例えば、車両に搭載される電子制御装置(ECU)であり、検出装置100に電源電圧(入力信号)を供給するとともに、検出装置100から圧力検出信号(出力信号)を受信し、この圧力検出信号を車両の各種制御に用いる。
以下、検出システム1における接地ラインの異常検出処理を説明する。この異常検出処理では、圧力検出回路112側における接地ラインと監視ラインとの接続点の電位V2’に基づいて、接地ラインの抵抗状態を検出する。以下では、接地ライン203の電位(V1=GND)を基準値とし、V1=0とする。
RX=V2’/(Vcc-V2’)*R0・・・(1)
なお、上記では、接地ラインL3,103と監視ラインL3a,103aとをセンサチップ111内で導通させる場合を例に挙げて説明したが、図3に示すように、監視電極P3aと接地電極103とを導通させて監視ラインL3aと接地ラインL3とを導通させても良い。
図4は、本発明の第2実施形態に係る検出システムの回路図を示す。第1実施形態と同様の構成には同一の符号を付し、それらの説明を省略し、第1実施形態と異なる部分を以下に説明する。
RX=V2’/(Vcc-V2’)*R0-R3・・・(2)
図9は、本発明の第3実施形態に係る検出システムの回路図を示す。本実施形態は、電源ライン上に電源電圧制御回路230が追加される点以外は、図1に示す第1実施形態の検出システムと同様の構成である。以下、同様の構成には第1実施形態と同一の符号を付し、異なる構成について詳細に説明する。
図9に示す検出システム1は、図1の検出システム1において、処理装置200の電源ライン202上に電源電圧制御回路230を設け、電源電圧変更後の圧力検出信号(出力信号)Voutに基づいて検出回路112の異常を検出する異常検出部220aを処理部220に設けたものである。なお、ここでは、電源電圧制御回路230が処理装置200内に設けられる場合を説明するが、電源電圧制御回路230は処理装置200外に配置されても良い。
本実施形態に係る異常検出処理について、図9及び図10を参照して説明する。
(異常検出処理例1)
図12は、本実施形態に係る検出回路112の異常検出処理を説明するフローチャートである。
図13は、図10の入出力特性曲線において、各圧力値Pに対して、検出回路112の入力(Vcc’)と出力(Vout)の関係が直線となる場合の入出力特性曲線(入出力特性直線)を示す。
なお、第1及び第2実施形態で述べた監視用ライン及びそれを接続するための電極を省略、例えば、図9において監視用ライン103a,L3a,203a、電極P3a及び端子T3aを省略しても良い。この場合には、検出装置100及び処理装置200において、両者を接続する追加の信号線、追加の信号線を接続するための追加の電極及び端子を必要とすることなく、検出回路112の異常を簡易な構成で確実に検出することができる。処理装置200で追加する部品は、抵抗RL及びスイッチ231等からなる電源電圧制御回路231のみであり、最小限の追加部品によって、処理部220aのソフトウェア的な処理によって、検出回路112の異常を検出することができる。
図16は、本発明の第4実施形態に係る検出システムの回路図を示す。本実施形態は、図9に示す第3実施形態の検出システムにおいて、電源電圧制御回路230の代りに電源電圧制御回路240を備え、異常検出部220aの代りに異常検出部220bを備え、監視ライン103a,L3a,203aを省略した点以外は、図9に示す第3実施形態の検出システムと同様の構成である。
電源電圧制御回路240は、電源電圧Vccの入力を受け、電源電圧Vcc’を連続的に変化させて検出装置100に出力するものである。電源電圧制御回路240は、例えば、トランジスタ等のスイッチング素子を制御することにより電源電圧Vcc’を連続的に変化させる回路であり、例えば、DC/DCコンバータのようなレギュレータ回路である。電源電圧制御回路240は、制御ライン241を介して処理部220に接続されており、処理部220の異常検出部220bによって出力電源電圧Vcc’の値が制御される。
本実施形態に係る異常検出処理について、図19~図21を参照して説明する。
図22は、第4実施形態に係る検出回路112の異常検出処理を説明するフローチャートである。
第4実施形態に係る異常検出方法では、検出部151(図17)が停止する最低動作電源電圧Vxを使用するため、実際には、検出回路112のうち検出部151を除いた補正回路152及び増幅回路153の異常を検出している。これに対して、第3実施形態に係る検出回路112の異常検出処理は、図19における最低動作電源電圧Vx以上の領域(I)の入出力特性を用いて異常検出処理を実行することに相当するので、検出回路112全体の異常の有無を検出することができる。そこで、本実施形態では、検出回路112自体の異常検出処理を第3実施形態に係る異常検出方法によって実行し、検出回路112を外部回路に接続する導電線の異常検出処理を第4実施形態に係る異常検出方法によって実行する。
第4実施形態の方法を用いて検出回路112自体の異常検出処理を実行し、第1及び第2実施形態の監視ラインによる方法を用いて導電線の異常検出処理を実行しても良い。この場合、監視ラインによる方法によって、何れの導電線に異常が生じたかを特定することができると共に、圧力が頻繁な周囲環境下においても検出回路112の異常検出処理を実行することができる。
図24は、第6実施形態に係る検出システムの回路図を示す。上記実施形態と同様の構成には同一の符号を付し、詳細な説明を省略する。以下、上記実施形態と異なる部分について、詳細に説明する。
V2=(Ids+Icc)*(RC1+RC2)・・・・・・・(3)
Ids=10mA・・・・・・・・・・・・・・・・・・・・・(4)
Icc=Vcc/(R5+RC1+RC2)・・・・・・・・・(5)
Vout=(c1*pe+c0)*VDD・・・・・・(6)
Vout_eff=Vout-V2
VDD_eff=VDD-V2・・・・・・・・・・・・・・・(7)
Vout_eff=(c1*pe+c0)*VDD_ef・・・・・・・(8)
V2=Vcc*R6/(R5+R7+R6)・・・・・(9)
100 検出装置(センサ装置)
200 処理装置(ECU)
101、L1、201 検出信号ライン
102、L2、202 電源ライン
103、L3、203 接地ライン
101a~103a、L1a~L3a、201a~203a 監視ライン
P1~P3、P1a~P3a 電極
T1~T3、T1a~T3a 端子
110 ハウジング
111 センサチップ
112 検出回路
112a 接地端子
151 検出部
152 補正回路
153 増幅回路
210 アナログデジタルコンバータ(ADC)
220 処理部
220a,220b 異常検出部
R2,R3 抵抗
Vcc 電源電圧源、電源電圧
230,240 電源電圧制御回路
231 切換回路
232,241 制御ライン
250 断線検出回路
RL 電圧降下用抵抗
Claims (29)
- 電気システムであって、
第1の電気回路(112)と、
前記第1の電気回路(112)の接地端子に接続される接地線(L3,103)と、
前記接地線に電気的に接続され、前記接地線との接続点における電位(V2’)を検出する監視用導電線(L3a,103a)とを備え、
前記監視用導電線による検出電圧(V2)に基づいて、前記第1の電気回路(112)の挙動(Vout)を補正する、電気システム。 - 請求項1に記載の電気システムにおいて、
前記監視用導電線(L3a,103a)は、第1の抵抗(R5)を介して電源電圧(Vcc)に接続されるとともに、第2の抵抗(R6)を介して接地電位(GND)に接続されており、
前記第2の抵抗の電圧を前記検出電圧(V2)として検出することにより、前記監視用導電線自体の異常を検出する、電気システム。 - 請求項2に記載の電気システムにおいて、
前記監視用導電線による検出電圧(V2)が第1の閾値(Vth)よりも小さい場合に、前記監視用導電線による検出電圧(V2)を用いて、前記第1の電気回路(112)の挙動(Vout)の補正を実行し、
前記監視用導電線による検出電圧(V2)が第1の閾値以上となった場合に、前記監視用導電線の断線と判断する、電気システム。 - 請求項2に記載の電気システムにおいて、
前記監視用導電線による検出電圧(V2)が前記第1の閾値より小さい第2の閾値よりも小さい場合には、前記接地線が正常であると判断し、前記第1の電気回路(112)の挙動(Vout)の補正を実行せず、
前記監視用導電線による検出電圧(V2)が前記第2の閾値以上かつ第1の閾値未満である場合に、前記監視用導電線による検出電圧(V2)を用いて、前記第1の電気回路(112)の挙動(Vout)の補正を実行し、
前記監視用導電線による検出電圧(V2)が前記第1の閾値以上となった場合に、前記監視用導電線の断線と判断する、電気システム。 - 請求項1乃至4の何れかに記載の電気システムにおいて、
前記第1の電気回路(112)は、特定種類の物理量を検出する検出回路であり、
前記監視用導電線による検出電圧(V2)を用いて、前記検出回路(112)の出力電圧(Vout)を補正する、電気システム。 - 請求項5に記載の電気システムにおいて、
前記監視用導電線による検出電圧(V2)を用いて、前記検出回路(112)の出力電圧(Vout)と、前記出力電圧(Vout)の上限値(VDD)とを補正することにより、検出する物理量の補正を実行する、電気システム。 - 請求項5に記載の電気システムにおいて、
前記検出回路(112)は、車両の制動装置を補助する負圧ブースタ内の圧力を検出する圧力センサであり、前記出力電圧(Vout)は圧力検出信号である、電気システム。 - 請求項2に記載の電気システムにおいて、
前記監視用導電線(L3a,103a)に介装される第3の抵抗(R7)を更に備え、
前記第3の抵抗(R7)の一端は前記第1の抵抗(R5)に接続され、前記第3の抵抗(R7)の他端は前記第2の抵抗(R6)に接続されている、電気システム。 - 特定種類の物理量を検出する検出回路(112)の異常を検出する異常検出装置であって、
前記検出回路(112)に供給する電源電圧(Vcc’)の大きさを変更し、変更後の電源電圧(Vc2)での前記検出回路からの出力信号(Vo2)に基づいて、前記検出回路の異常を検出する異常検出部(220a)を備える、検出回路の異常検出装置。 - 請求項9に記載の検出回路(112)の異常検出装置において、
前記異常検出部(220a)は、前記電源電圧変更前後の前記検出回路(112)からの出力信号(Vo1,Vo2)が、同一の物理量(P)に対する入出力特性曲線上にあるか否かに基づいて、前記検出回路(112)の異常を検出する、検出回路の異常検出装置。 - 請求項9に記載の検出回路(112)の異常検出装置において、
前記異常検出部(220a)は、前記電源電圧変更前後の前記検出回路(112)からの出力信号(Vo1,Vo2)比が変更前後の電源電圧(Vc1,Vc2)の比に一致するか否かに基づいて、前記検出回路(112)の異常を検出する、検出回路の異常検出装置。 - 請求項9に記載の検出回路(112)の異常検出装置において、
前記異常検出部(220a)は、前記電源電圧を、互いに異なる複数の電圧(Vc2,Vc3)に変更し、これら変更後の複数の電源電圧(Vc2,Vc3)での前記検出回路(112)からの出力信号(Vo2,Vo3)に基づいて、前記検出回路(112)の異常を検出する、検出回路の異常検出装置。 - 請求項9乃至12の何れかに記載の検出回路(112)の異常検出装置において、
前記異常検出部(220a)は、変更前における電源電圧値(Vc1)に対する前記検出回路(112)からの出力信号を所定の時間間隔をあけて少なくとも2回測定し、少なくとも2回の出力信号(Vo1,Vo1’)が一致する場合に、変更後の電源電圧(Vc2)での前記検出回路からの出力信号(Vo2)に基づいて、前記検出回路の異常を検出する検出回路の異常検出装置。 - 請求項9乃至13の何れかに記載の検出回路(112)の異常検出装置において、
前記異常検出部(220a)の制御によって、前記検出回路(112)に供給する電源電圧(Vcc’)の大きさを変更する電源電圧制御部(230)を備える、検出回路の異常検出装置。 - 請求項9乃至14の何れかに記載の検出回路(112)の異常検出装置において、
前記検出回路(112)は、車両の制動装置を補助する負圧ブースタ内の圧力を検出する圧力センサである、検出回路の異常検出装置。 - 周囲環境に応じて挙動が変化する電気回路(112)の異常を検出する異常検出装置であって、
前記電気回路(112)に供給する電源電圧(Vcc’)の大きさを変更し、変更後の電源電圧(Vc2)における前記電気回路の挙動(Vo2)に基づいて、前記電気回路の異常を検出する異常検出部(220a)を備える、電気回路の異常検出装置。 - 検出システムであって、
特定種類の物理量を検出する検出回路(112)と、
前記検出回路(112)からの出力を処理する処理装置(200)と、
前記検出回路と前記処理装置との間を電気的に接続する導電線(L1,101;L2,102;L3,103)と、
前記検出回路(112)側で前記導電線に電気的に接続される監視用導電線(L1a,101a;L2a,102a;L3a,103a)とを備え、
前記導電線と前記監視用導電線との接続点における電位を前記監視用導電線によって検出することによって、前記導電線の抵抗状態を検出し、
更に、前記検出回路(112)に供給する電源電圧(Vcc’)の大きさを変更し、変更後の電源電圧(Vc2)での前記検出回路からの出力信号(Vo2)に基づいて、前記検出回路(112)の異常を検出する異常検出部(220a)を備える、検出システム。 - 電子システムであって、
周囲環境に応じて挙動が変化する第1の電気回路(112)と、
第2の電気回路(200)と、
前記第1の電気回路と前記第2の電気回路との間を電気的に接続する導電線(L1,101;L2,102;L3,103)と、
前記第1の電気回路側で前記導電線に電気的に接続される監視用信号線(L1a,101a;L2a,102a;L3a,103a)とを備え、
前記導電線と前記監視用信号線との接続点における電位を前記監視用信号線によって検出することによって、前記導電線の抵抗状態を検出し、
更に、前記第1の電気回路(112)に供給する電源電圧(Vcc’)の大きさを変更し、変更後の電源電圧(Vc2)における前記第1の電気回路の挙動(Vo2)に基づいて、前記第1の電気回路(112)の異常を検出する異常検出部(220a)を備える、電子システム。 - 特定種類の物理量を検出する検出部(151)を含む検出回路(112)の異常検出装置において、
前記検出回路(112)に供給する電源電圧(Vcc’)の大きさを変化させて、前記検出部(151)が停止する前記電源電圧(Vx)未満における前記検出回路(112)の出力信号(Vout)を検出し、この検出値に基づいて、前記検出回路(112)の異常を検出する異常検出部(220b)を備える、検出回路の異常検出装置。 - 請求項19に記載の検出回路(112)の異常検出装置において、
前記異常検出部(220b)は、更に、前記検出部(151)が停止する前記電源電圧(Vx)に基づいて、前記検出回路(112)を外部と接続する導電線の抵抗状態を検出する、検出回路の異常検出装置。 - 特定種類の物理量を検出する検出部(151)を含む検出回路(112)の異常検出装置において、
前記検出回路(112)に供給する電源電圧(Vcc’)の大きさを変化させて、前記検出部(151)が停止する前記電源電圧(Vx)を検出し、この検出値に基づいて、前記検出回路(112)を外部と接続する導電線の抵抗状態を検出する異常検出部(220b)を備える、検出回路の異常検出装置。 - 電気回路(112)の異常検出装置において、
電気回路(112)に供給する電源電圧(Vcc’)の大きさを変化させ、前記電気回路(112)に含まれる一部(151)が停止する前記電源電圧(Vx)未満における前記電気回路(112)の出力信号(Vout)を検出し、この検出値に基づいて、前記電気回路(112)の異常を検出する異常検出部(220b)を備える、電気回路の異常検出装置。 - 電気回路(112)の異常検出装置において、
電気回路(112)に供給する電源電圧(Vcc’)の大きさを変化させ、前記電気回路(112)の一部(151)が停止する前記電源電圧(Vx)を検出し、この検出値に基づいて、前記電気回路(112)を外部と接続する導電線の抵抗状態を検出する異常検出部(220b)を備える、電気回路の異常検出装置。 - 特定種類の物理量を検出する検出部(151)を含む検出回路(112)の異常検出装置において、
前記検出回路(112)に供給する電源電圧(Vcc’)の大きさを変化させて、前記検出部(151)が停止する前記電源電圧(Vx)以上の範囲において、変化後の電源電圧(Vc2)に対する前記検出回路からの出力信号(Vo2)を検出し、この検出値に基づいて、前記検出回路の異常を検出する第1の異常検出部(220a)と、
前記検出部(151)が停止する前記電源電圧(Vx)を検出し、この検出値に基づいて、前記検出回路(112)を外部と接続する導電線の抵抗状態を検出する第2の異常検出部(220b)と、を備える検出回路の異常検出装置。 - 周囲環境に応じて挙動が変化する回路部分(151)を含む電気回路(112)の異常を検出する異常検出装置であって、
前記電気回路(112)に供給する電源電圧(Vcc’)の大きさを変化させて、前記回路部分(151)が停止する前記電源電圧(Vx)以上の範囲において、変化後の電源電圧(Vc2)に対する前記検出回路からの出力信号(Vo2)を検出し、この検出値に基づいて、前記電気回路の異常を検出する第1の異常検出部(220a)と、
前記回路部分(151)が停止する前記電源電圧(Vx)を検出し、この検出値に基づいて、前記電気回路(112)を外部と接続する導電線の抵抗状態を検出する第2の異常検出部(220b)と、
を備える電気回路の異常検出装置。 - 検出システムであって、
特定種類の物理量を検出する検出部(151)を含む検出回路(112)と、
前記検出回路(112)からの出力を処理する処理装置(200)と、
前記検出回路と前記処理装置との間を電気的に接続する導電線(L1,101;L2,102;L3,103)と、
前記検出回路(112)側で前記導電線に電気的に接続される監視用導電線(L1a,101a;L2a,102a;L3a,103a)とを備え、
前記導電線と前記監視用導電線との接続点における電位を前記監視用導電線によって検出することによって、前記導電線の抵抗状態を検出し、
更に、前記検出回路(112)に供給する電源電圧(Vcc’)の大きさを変化させて、前記検出部(151)が停止する前記電源電圧(Vx)未満における前記検出回路(112)の出力信号(Vout)を検出し、この検出値に基づいて、前記検出回路(112)の異常を検出する異常検出部(220b)を備える、検出システム。 - 電子システムであって、
第1の電気回路(112)と、
第2の電気回路(200)と、
前記第1の電気回路と前記第2の電気回路との間を電気的に接続する導電線(L1,101;L2,102;L3,103)と、
前記第1の電気回路側で前記導電線に電気的に接続される監視用信号線(L1a,101a;L2a,102a;L3a,103a)とを備え、
前記導電線と前記監視用信号線との接続点における電位を前記監視用信号線によって検出することによって、前記導電線の抵抗状態を検出し、
更に、前記電気回路(112)に供給する電源電圧(Vcc’)の大きさを変化させて、前記電気回路の一部(151)が停止する停止電源電圧(Vx)未満における前記電気回路(112)の出力信号(Vout)を検出し、この検出値に基づいて、前記電気回路(112)の異常を検出する異常検出部(220b)を備える、電子システム。 - 特定種類の物理量を検出する検出部(151)を含む検出回路(112)の異常検出装置において、
前記検出回路(112)に供給する電源電圧(Vcc’)の大きさを変化させて、前記検出部(151)が停止する前記電源電圧(Vx)以上の範囲において、変化後の電源電圧(Vc2)に対する前記検出回路からの出力信号(Vo2)を検出し、この検出値に基づいて、前記検出回路の異常を検出する第1の異常検出部(220a)と、
前記検出部(151)が停止する前記電源電圧(Vx)未満における前記検出回路(112)の出力信号(Vout)を検出し、この検出値に基づいて、前記検出回路(112)の異常を検出する第2の異常検出部(220b)と、
を備える検出回路の異常検出装置。 - 周囲環境に応じて挙動が変化する回路部分(151)を含む電気回路(112)の異常を検出する異常検出装置であって、
前記電気回路(112)に供給する電源電圧(Vcc’)の大きさを変化させて、前記回路部分(151)が停止する前記電源電圧(Vx)以上の範囲において、変化後の電源電圧(Vc2)に対する前記検出回路からの出力信号(Vo2)を検出し、この検出値に基づいて、前記電気回路の異常を検出する第1の異常検出部(220a)と、
前記電気回路の一部(151)が停止する停止電源電圧(Vx)未満における前記電気回路(112)の出力信号(Vout)を検出し、この検出値に基づいて、前記電気回路(112)の異常を検出する第2の異常検出部(220b)と、
を備える電気回路の異常検出装置。
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JPH06229778A (ja) * | 1992-10-07 | 1994-08-19 | Nec Corp | 故障検出回路付半導体センサ装置 |
JPH06273429A (ja) * | 1993-03-15 | 1994-09-30 | Sumitomo Electric Ind Ltd | 回転センサの故障検出装置および故障検出機能付回転センサ |
JP2005164435A (ja) * | 2003-12-03 | 2005-06-23 | Yamatake Corp | 個体情報提供システム |
US20080103705A1 (en) * | 2006-10-27 | 2008-05-01 | Dirk Hammerschmidt | Online Testing Of A Signal Path By Means Of At Least Two Test Signals |
JP2009057606A (ja) | 2007-08-31 | 2009-03-19 | Ntn Corp | 浸炭窒化方法、機械部品の製造方法、機械部品および熱処理炉 |
Cited By (3)
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JP2013212814A (ja) * | 2012-04-04 | 2013-10-17 | Ntn Corp | 電動ブレーキ装置 |
JP2014211382A (ja) * | 2013-04-19 | 2014-11-13 | 株式会社ハイレックスコーポレーション | センサ装置 |
JP2017125866A (ja) * | 2017-04-27 | 2017-07-20 | パナソニックIpマネジメント株式会社 | 光学式エンコーダ |
Also Published As
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JPWO2010119901A1 (ja) | 2012-10-22 |
WO2010119532A1 (ja) | 2010-10-21 |
US20120035824A1 (en) | 2012-02-09 |
CN102395892A (zh) | 2012-03-28 |
EP2420851A1 (en) | 2012-02-22 |
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