KR20200001980A - Electronic control device, semiconductor integrated circuit device for electronic control and gas cooking stove - Google Patents

Abstract

Provided are an electronic control apparatus having a watchdog function resistant to electronic noise, an IC for electronic control constituting the same, and a gas cooker. According to the present invention, the electronic control apparatus comprises a plurality of semiconductor integrated circuit devices, and generates and outputs a control signal for a device to be controlled. Each of the plurality of semiconductor integrated circuit devices has a function of outputting a clock signal with a predetermined frequency and a function of determining frequencies or periods of clock signals input from other semiconductor integrated circuit devices. The plurality of semiconductor integrated circuit devices are configured to mutually monitor clock signals input from other semiconductor integrated circuit devices.

Description

ELECTRONIC CONTROL DEVICE, SEMICONDUCTOR INTEGRATED CIRCUIT DEVICE FOR ELECTRONIC CONTROL AND GAS COOKING STOVE}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a technique for mutually monitoring a watchdog signal between a microcomputer and a plurality of semiconductor devices such as an analog front end. The present invention relates to an effective technology applied to an electronic control IC (semiconductor integrated circuit).

Conventionally, there is a gas passage control device as an example of an electronic control device having a watchdog function. The gas duct is equipped with an ignition circuit (igniter), and relatively large electromagnetic noise is generated during discharge by the igniter, which may cause the program of the microcomputer to runaway, thereby preventing the watchdog. The feature is being installed. In the electronic control device of such a gas path, an invention has been proposed in which the power supply to the solenoid valve is cut off even when the watchdog clock signal is lost, and the pulse period of the watchdog clock signal is shorter than the normal range. Document 1).

Patent Literature 2 also describes an invention in which two safety controllers monitor each other for abnormalities and, when an abnormality is detected, provide a safety circuit for interrupting power supply to the solenoid valve.

Japanese Patent Application Laid-Open No. 2017-133757 Japanese Patent Application Laid-Open No. 2016-011807 Japanese Patent Application Laid-Open No. 06-4353

The invention described in Patent Literature 2 is an invention in which the safety controllers monitor each other's abnormality after the safety control unit by the combustion temperature sensor is doubled, and the main control unit and the safety control unit do not monitor the abnormality.

The invention described in Patent Document 1 is effective in order to prevent a malfunction of the control device due to congestion of a microcomputer in an electronic control system. On the other hand, the electronic control apparatus of a gas path may be comprised by the microcomputer and the analog front-end IC which handles the signal of the sensor which detects a flame and temperature. In such a case, the controller may malfunction due to congestion of the analog front end IC. Therefore, it is necessary to monitor the operation of the analog front end IC to prevent congestion.

Conventionally, the technique which monitors mutual watchdog clock signal is known in the system provided with several IC (patent document 3). However, conventional microcomputers and other ICs having a function of outputting a watchdog clock signal generally include an oscillation circuit having an external oscillator such as a crystal oscillator for generating an operation clock signal, and oscillation of the oscillation circuit. A watchdog clock signal is generated based on the clock signal generated by dividing the signal.

An oscillator, such as a crystal oscillator, has a high impedance, and therefore, noise easily enters an external terminal to which the oscillator is connected, and the watchdog function may be impaired by noise jumping into the external terminal. In particular, in the electronic control apparatus of the gas path, since a relatively large electromagnetic noise is generated at the time of discharge by the igniter, the problem that the watchdog function may be impaired is caused by the electromagnetic noise jumping to the external terminal to which the oscillator is connected. I knew there was.

SUMMARY OF THE INVENTION The present invention has been made in view of the above problems, and an object thereof is to provide a gas-path electronic control device comprising a plurality of semiconductor devices such as a microcomputer and an analog front end. It is to be able to shut off solenoid valve.

Another object of the present invention is to provide an electronic control device having a watchdog function resistant to electromagnetic noise, an electronic control IC and a gas air passage constituting the electronic control device.

In order to achieve the above object, the present invention provides an electronic control apparatus including a plurality of semiconductor integrated circuit devices, and generating and outputting a control signal for a device to be controlled.

Each of the plurality of semiconductor integrated circuit devices has a function of outputting a clock signal of a predetermined frequency and a function of determining a frequency or period of the clock signal input from another semiconductor integrated circuit device,

The plurality of semiconductor integrated circuit devices are configured to monitor the clock signals input from other semiconductor integrated circuit devices.

According to the above configuration, since the clock signals are monitored with each other, it can be detected when any one semiconductor integrated circuit device is congested.

Here, preferably, one of the plurality of semiconductor integrated circuit devices is a microcomputer, and a clock signal of a predetermined frequency output from the microcomputer is generated by a watchdog function,

The semiconductor integrated circuit device except for the microcomputer has an oscillation circuit for generating a clock signal of a predetermined frequency, and is configured to output a clock signal based on the oscillation signal generated by the oscillation circuit as a clock signal for abnormal monitoring. .

According to such a structure, the electronic control apparatus can be designed efficiently by using the watchdog function with which a microcomputer is equipped.

Preferably, the semiconductor integrated circuit device except for the microcomputer includes an oscillation circuit for generating a clock signal of a predetermined frequency without using an oscillator, and a counter circuit capable of counting the number of clock signals input from another semiconductor integrated circuit device. And a comparison circuit for comparing the value counted by the counter circuit with a predetermined determination value,

The counter circuit is counted on the basis of the clock signal generated by the oscillation circuit, and configured to output an abnormal signal when the value counted by the counter circuit exceeds the predetermined determination value.

According to this configuration, since the counter circuit counts by the clock signal generated by the oscillator circuit which does not use the oscillator and determines the presence or absence of abnormality based on the count value, the clock signal causes abnormality by noise from the outside. In this case, the misjudgment can be prevented and the noise resistance of the semiconductor integrated circuit device can be improved.

According to another aspect of the present application, the gas passage is an electronic control device having the above configuration, a gas burner, ignition means arranged in the vicinity of the gas burner to ignite the gas, and a gas pipe connected to the gas burner. A gas regulating valve and a solenoid valve provided in the middle of the pump, and a switch circuit for turning on and off energization of the solenoid valve,

The switch circuit is controlled by the abnormal signal and the abnormal signal detected and generated by the watchdog function of the microcomputer to close the solenoid valve when any one of the abnormal signals is output.

According to such a structure, since the microcomputer and the semiconductor integrated circuit device constituting the electronic control device mutually monitor clock signals from each other, it is possible to detect when any one is congested and close the solenoid valve. Since the gas supply is cut off, the safety of the gas passage can be improved.

An electronic control semiconductor integrated circuit device according to still another aspect of the present application includes an output terminal for outputting a signal for controlling ignition means arranged in the vicinity of a gas burner;

An input terminal for receiving a clock signal supplied from another semiconductor integrated circuit device,

A communication circuit for transmitting and receiving data with another semiconductor integrated circuit device,

A first oscillator circuit for generating a clock signal for operation of the communication circuit using an oscillator;

A second oscillator circuit for generating a clock signal of a predetermined frequency without using an oscillator;

A counter circuit capable of counting the number of clock signals input to the input terminal from another semiconductor integrated circuit device;

A comparison circuit for comparing the value counted by the counter circuit with a predetermined determination value,

The counter circuit is configured to count based on a clock signal generated in the second oscillation circuit, so as to output a signal showing an abnormality when the value counted by the counter circuit exceeds the predetermined determination value.

According to this configuration, since the counter circuit counts by the clock signal generated by the oscillator circuit which does not use the oscillator and determines the presence or absence of abnormality based on the count value, the clock signal causes abnormality by noise from the outside. In this case, the misjudgment can be prevented and the noise resistance of the semiconductor integrated circuit device can be improved. In addition, since an oscillator is provided with an oscillator circuit for generating a clock signal for operation of a communication circuit, it is easy to make the oscillation frequency of the oscillator circuit higher than the oscillation frequency of an oscillator circuit without an oscillator. By using the clock signal of high frequency for a communication circuit, data transmission / reception with another semiconductor integrated circuit device can be performed at high speed.

According to the present invention, in the gas-path electronic control device comprising a plurality of semiconductor devices such as a microcomputer and an analog front end, mutual congestion can be monitored and a malfunction can be detected to shut off the solenoid valve. In addition, there is an effect that an electronic control device having a watchdog function resistant to electromagnetic noise, an electronic control IC constituting the same, and a gas air path can be realized.

BRIEF DESCRIPTION OF THE DRAWINGS It is a circuit block diagram which shows 1 Embodiment of the gas channel electronic control apparatus which concerns on this invention.
2 is a block diagram illustrating a specific configuration example of an analog front end IC (AFE-IC) in the embodiment.
3 is a circuit diagram showing a specific example of a watchdog circuit provided in the AFE-IC.
4 (a) and 4 (b) are flowcharts showing an example of the procedure of the ignition switch processing in the microcomputer (MCU) and the AFE-IC.
5 (a) and 5 (b) are flowcharts showing an example of a procedure of initial setting processing in the microcomputer (MCU) and the AFE-IC.
It is a circuit block diagram which shows the 1st modified example of the gas channel electronic control apparatus of embodiment.
It is a circuit block diagram which shows the 2nd modified example of the gas channel electronic control apparatus of embodiment.
8 (a) and 8 (b) are block diagrams illustrating another embodiment of the gas channel electronic control apparatus according to the present invention.

(Form to carry out invention)

EMBODIMENT OF THE INVENTION Hereinafter, preferred embodiment of this invention is described based on drawing.

BRIEF DESCRIPTION OF THE DRAWINGS The schematic structure of one Embodiment of the gas channel electronic control apparatus concerning this invention is shown. In FIG. 1, the part enclosed by the dashed-dotted line A is the gas-path electronic control apparatus 10. In FIG. In addition, the part enclosed by the dashed-dotted line B is the gas channel 20, The furnace path burner 21 which is a main component, the thermal control solenoid valve 23 and the solenoid valve provided in the middle of the gas pipe 22 are shown. A safety valve 24 for fail safe is shown.

In the vicinity of the air passage burner 21, the thermocouple 25 for detecting the flame and the temperature of the bottom of a cooking utensil such as a pan or a frying pan placed on the air passage above the air passage burner 21 are detected. Thermistors 26 and the igniters 27 for ignition are arranged in an array. Reference numeral 28 denotes an ignition switch for energizing the igniter 27. The thermal control solenoid valve 23 may have a motor and may be configured such that the gas flow rate can be adjusted by changing the angle of the valve by the motor. The solenoid valve that can be opened and closed may be driven by PWM (pulse width modulation) method. It may be configured to adjust the gas flow rate.

The gas path electronic control device 10 of the present embodiment includes an analog front end IC for detecting signals from a microcomputer (hereinafter referred to as MCU) 11 and a sensor such as a thermocouple 25 or thermistor 26. (Hereinafter referred to as AFE-IC) 12, a current switch transistor 13 which causes a current to flow to the igniter 27 as a peripheral device, a buzzer 14 which emits an alarm sound, and for thermal power adjustment A driver circuit 15 for driving the solenoid valve 23 and a transistor switch circuit 16 for operating the safety valve 24 are provided. In addition, a battery 17 for supplying a power supply voltage to the AFE-IC 12 is provided. The power supply voltage of the MCU 11 can also be supplied from the battery 17.

In addition, the oscillator 18 is connected to the AFE-IC 12 as an external device in order to generate a clock signal of a predetermined frequency in an internal oscillator circuit. Although not shown, the MCU 11 similarly generates a system lock signal for use inside the chip, and thus includes an internal oscillation circuit and an external terminal for connecting the oscillator. The MCU 11 may have an input terminal that receives an externally generated clock signal and may be of a type that operates with a clock signal supplied from the outside. Reference numeral 19 denotes an LED (light emitting diode) serving as a pilot lamp indicating supply or input of a power supply voltage (battery voltage) or abnormality of the air path.

The MCU 11 and the AFE-IC 12 are each provided with a function of generating a watchdog or an error monitoring clock signal inside the chip and a function of monitoring a watchdog clock input from the outside. The AFE-IC 12 is provided with a terminal CLKO for outputting a clock signal generated internally as an abnormal monitoring clock and a terminal WDI for inputting a watchdog clock WDP from the MCU 11. It is. The MCU 11 receives input of the abnormality monitoring clock WCK from the AFE-IC 12 at one general purpose IO port (input / output port) GPIO, and watches from another general purpose IO port GPIO. It is configured to output the read clock WDP.

As described above, when the watchdog for use, the watch for abnormality monitoring (WDP), and the WCK are mutually monitored, it can be detected when the other IC is congested. The AFE-IC 12 is provided with a terminal OUT for outputting a signal when an abnormality of the watchdog clock WDP is detected, and the MCU 11 detects an abnormality of the abnormality monitoring clock WCK. It is configured to output an abnormal signal from a general purpose IO port (GPIO). Which general purpose IO port GPIO is used by the MCU 11 to receive the clock WCK and output the clock WDP or the abnormal signal can be freely set by an internal user program.

In addition, the AFE-IC 12 includes an external terminal for inputting a chip select signal CS from the MCU 11, a synchronous clock signal SCK for serial communication, and serial data SDATA, and a microcomputer 11; ) Has an external terminal (SOUT) for outputting serial data. The temperature data detected by the AFE-IC 12 by signals from sensors such as the thermocouple 25 and thermistor 26 is configured to be sent from the external terminal SOUT to the MCU 11.

In addition, the AFE-IC 12 includes an input terminal SW for receiving a signal from the ignition switch 28, a terminal IG for outputting a signal for operating the igniter 27, and a buzzer 14. A terminal BZ for outputting a signal to be moved is provided.

On the other hand, the MCU 11 is provided with a function of generating and outputting a signal for operating the solenoid valve 23 from a general-purpose IO port GPIO.

The abnormal signal of the watchdog or fault monitoring clock output from the terminal OUT of the AFE-IC 12 and the general purpose IO port GPIO of the MCU 11 is supplied to the transistor / switch circuit 16 to supply a safety valve. To control (24). That is, the abnormal signal of the clock becomes a signal for operating the safety valve 24.

The transistor switch circuit 16 includes two PNP bipolar transistors TR1 and TR2 connected in series, resistors Rb1 and Rb2 connected to their respective bases, and resistors Re1 and Re2 connected between the emitter and base. ), The emitter terminal of the transistor TR1 is connected to the power supply voltage terminal VCC.

As a result, the transistors TR1 and TR2 normally flow a collector current, energize the solenoid of the safety valve 24, and excite it to control the valve in the open state. As a result, gas is supplied to the solenoid valve 23 via the safety valve 24. When a high level detection signal indicating an abnormality of the watchdog clock is output from either the terminal OUT of the AFE-IC 12 or the general purpose IO port GPIO of the MCU 11, the transistor TR1 or TR2 is output. ) Is turned off. As a result, the energization to the safety valve 24 is interrupted | blocked, and the valve is controlled to a closed state by demagnetizing a solenoid. For this reason, the safety function by which the safety valve 24 is cut off and gas is not supplied to the solenoid valve 23 is operated.

In addition, between the transistor switch circuit 16 and the safety valve 24, two resistors R1 and R2 connected in series with the transistors TR1 and TR2 are provided, and the potentials of the connection nodes of the resistors R1 and R2 are provided. Is input to the analog input terminal ANIN of the AFE-IC 12, and the AFE-IC 12 is able to detect the state of the safety valve 24 by the input potential of this terminal. Specifically, when the input potential of the terminal ANIN is high, the safety valve 24 is opened. When the input potential of the terminal ANIN is low, the safety valve 24 can be detected to be closed.

2 shows a specific circuit configuration example of the AFE-IC 12 of the above embodiment.

As shown in FIG. 2, the AFE-IC 12 includes a power supply voltage detection circuit 31 that detects a drop in battery voltage applied to the power supply voltage terminal VCC, and a signal from the ignition switch 28. An ignition switch input circuit 32 for receiving a voltage, a regulator circuit 33 for generating and outputting a bias voltage for activating the thermistor 26 and a power supply voltage for an internal circuit, and a power-on reset signal for resetting the internal power supply when the power is turned on. And a power-on reset circuit 34 for generating the power supply.

In addition, the AFE-IC 12 digitally codes the thermistor switch circuit 35 for changing the voltage-dividing resistance value connected in series with a plurality of thermistors 26 (5 in the figure) for detecting temperature, and the detected voltage of the thermistor. The AD conversion circuit 36 for converting the circuit to one of the plurality of thermistors 26 for detecting the temperature of the bottom of the cooking appliance, the power supply voltage detecting circuit 31, and the like. And a multiplexer 37a for selecting one detection signal from a plurality of thermocouples 25 (6 in the figure), and an amplifier 38 for amplifying the selected detection signal. The signal amplified by the amplifier 38 and the input signals to the general-purpose analog input terminals AIN1 to AIN4 are supplied to the AD conversion circuit 36 through the multiplexer 37a and converted into digital codes.

Further, the AFE-IC 12 includes a serial interface circuit 39 for serial data communication with the microcomputer 11 and an oscillator circuit 40 for generating a clock signal of the serial interface circuit 39. An external oscillator 18 is connected to the oscillation circuit 40. The AFE-IC 12 also supplies an internal control signal in accordance with the sequencer 41 for operating the internal circuit of the chip in a predetermined order, the command code of the sequencer 41 and the digital code from the AD conversion circuit 36. The control logic 42 to generate | generates, the timer circuit 43 which performs time measurement operation by the clock signal from the oscillation circuit 40, and the safety valve control circuit 44 which produces | generates the signal which operates the safety valve 24. ).

The AFE-IC 12 further includes an internal oscillator circuit (oscillator circuit not using an oscillator) 45, which is composed of a ring oscillator or the like for generating a clock signal of a predetermined frequency, and is generated by the internal oscillator circuit 45. A watchdog circuit 46 that operates by a clock signal is provided. In addition, the oscillation frequency of the oscillation circuit 40 is set to a high value, for example, several 100 kHz to several MHz, while the oscillation frequency of the internal oscillation circuit 45 is, for example, several kHz to It is set to a low value such as a few 10 kHz.

In the AFE-IC 12 according to the present embodiment, the internal oscillation circuit 45 generates a clock signal for the watchdog function by an internal oscillation circuit 45 that generates a signal having a predetermined frequency without using an external oscillator. Since the element constituting the 45 and the wiring for transmitting the clock signal are covered with a plastic package, even if relatively large electromagnetic noise occurs during discharge by the igniter 27, the internal oscillation circuit 45 may have electrons. The noise jumps in and the watchdog function is less likely to be damaged. That is, the gas path electronic control apparatus which has the clock monitoring circuit with high noise tolerance can be implement | achieved.

In addition, even when the discharge electrode of the igniter 27 is located at a position away from the AFE-IC 12, since the high-voltage cable is wired in the gas passage housing, when the external oscillator is used, the oscillator is connected. Although noise generated during ignition from a high voltage cable to an external terminal may adversely affect the internal circuit of the AFE-IC 12 and cause a malfunction, in the AFEIC 12 of the present embodiment, the internal oscillation circuit 45 Since the watchdog circuit 46 operates by the clock signal generated by the clock signal, malfunction due to noise at the time of discharge of the igniter 27 can be avoided.

3 shows a specific circuit configuration example of the watchdog circuit 46 in the present embodiment.

As shown in Fig. 3, the watchdog circuit 46 of the present embodiment includes an edge detection circuit 51 for detecting the rising or falling edge of the clock signal generated by the internal oscillation circuit 45, and the MCU ( 11) an edge detection circuit 52 for detecting the edge of the watchdog clock WDP input to the terminal WDI, and a W / D counter circuit 53 for counting the number of times of edge detection of the watchdog clock WDP. And comparison circuits 55A and 55B for comparing the value counted by the W / D counter circuit 53 with the determination value (maximum value) and the determination value (minimum value) set in the registers 54A and 54B, An OR gate 56 that takes a logical sum of the outputs of the comparison circuits 55A and 55B, and a test circuit 57 for testing the operation of the circuit are provided.

In the registers 54A and 54B, a counter value corresponding to the allowable maximum frequency of the watchdog clock WDP and a counter value corresponding to the allowable minimum frequency are set as determination values. The watchdog circuit 46 is operated by the control signal of the control logic 42, the output of the OR gate 56 is supplied to the control logic 42, and the control logic 42 is provided with a safety valve when an abnormality is detected. And outputs a signal to the control circuit 44 to shut off the safety valve 24. The W / D counter circuit 53 is configured to be able to write a value by the test circuit 57 in the test mode.

The abnormality determination of the watchdog clock WDP from the MCU 11 by the watchdog circuit 46 shows that the watchdog clock WDP input to the terminal WDI is internally oscillated, as shown in FIG. 3. The W / D counter circuit 53 operated by the clock signal from the circuit (internal OSC) 45 is counted for a predetermined time (for example, 1 second), converted into a pulse frequency, and the frequency is, for example, When it is determined that it is not in the range of 1 kHz to 10 Hz, it is determined that there is an error in the watchdog clock WDP.

When it is judged that there is an error, a signal (error signal) for shutting off the safety valve 24 is output by clearing all the bits of the safety valve control register, and, for example, to an error flag of the watchdog status register. Set 1 By transmitting the bit of the watchdog status register to the MCU 11, the MCU 11 can recognize the abnormality of the watchdog clock WDP.

In addition, the watchdog circuit 46 of the present embodiment includes a divider circuit 58 for dividing the clock signal? C generated by the oscillator circuit (OSC) 40, and a clock WCK for detecting the divided signal. ), A buffer 59 for outputting from the terminal CKLO to the outside of the chip. The abnormality detection clock WCK is inputted to the MCU 11 and monitored by a program so that the MCU 11 can detect an operation error of the AFE-IC 12. The clock signal generated by the internal oscillation circuit (internal OSC) 45 may be configured to be output to the outside of the chip as the abnormality detection clock WCK.

Next, in the gas channel electronic control apparatus shown in FIG. 1, the microcomputer (MCU) 11 as a master IC and the analog front end IC (AFE) as a slave IC when the ignition switch 28 is operated on. -The procedure of the ignition switch processing by the IC 12 is explained using the flowchart of FIG. In FIG. 4, (A) is a flowchart of the MCU 11, and (B) is a flowchart of the AFE-IC 12.

When the ignition switch 28 is turned on and the ON signal of the ignition switch 28 is input to the microcomputer (MCU) 11, the ignition switch process shown in FIG. 4 is started, and the AFE- The setting command (command code) for instructing the initial setting is sent to the IC 12, and the initial setting processing is executed by the AFE-IC 12 (steps S11 and S21). In addition, the specific content of this initial setting process is demonstrated in detail using FIG.

When the initial setting is completed, the MCU 11 transmits a start command for starting the sequencer to the AFE-IC 12, and the AFE-IC 12 receives a start command and performs start processing of the sequencer (step S12). , S22). As a result, abnormality monitoring for determining an abnormality of the watchdog clock WDP is started. Thereafter, the MCU 11 determines whether or not the ignition is successful by reading the status register in the AFE-IC 12 (step S13), and when it is determined that the ignition is successful (Yes), the sleep state is determined. Go to

On the other hand, the AFE-IC 12 turns on the current switch transistor 13 which causes a current to flow to the igniter 27 when the sequencer start command is received and the start process (step S22) is completed. After starting the discharge by () (step S23), the transistor TR1 of the switch circuit 16 is turned on to open the safety valve 24 to start the supply of gas (step S24).

Subsequently, it is determined whether the flame is detected by reading the electromotive force of the thermocouple 25 (step S25). Then, when the flame is detected, it is judged that the ignition is successful, and the discharge of the igniter 27 is stopped (step S26). When the flame is not detected, the abnormality processing for shutting off the safety valve 24 (step S30). ).

After the discharge of the igniter 27 is stopped in step S26, the flow proceeds to step S27, where it is determined whether the battery voltage is equal to or greater than the set value, and when the value is not equal to or greater than the set value, the safety valve 24 is shut off. The process (step S30) is executed. If the battery voltage is equal to or higher than the set value, the process proceeds to step S28, in which the detected voltage of the thermistor 26 is read and judged to be equal to or higher than the set value. Step S30) is executed. When the detection voltage of the thermistor 26 is read and is equal to or higher than the set value, the flow proceeds to step S29 to read the electromotive force of the thermocouple 25 to determine whether the flame is detected, that is, whether the air passage burner 21 is not turned off. If the flame is not detected, the abnormality processing (step S30) for shutting off the safety valve 24 is executed. When a flame is detected, it returns to step S27 and repeats the said process.

Next, the specific procedure of the initial setting process (step S11, S21) in each of master IC (MCU 11) and slave IC (AFE-IC 12) is demonstrated using the flowchart of FIG. .

As shown in FIG. 5, when the initial setting process is started, the MCU 11 first performs initial setting of the general-purpose port (input / output port), and also enables the AFE-IC 12 to activate the abnormality monitoring clock output. Sends a setting command (command code) that commands the initial setting of the general-purpose port of the AFE-IC, such as / disable, enable / disable interrupt output, enable / disable ignitor control output, enable / disable buzzer control output, Received by the AFE-IC 12, the port is set (steps S31 and S41).

Subsequently, generation and output of the watchdog clock WDP are started in the MCU 11 (step S32), and generation and output of the abnormality monitoring clock WCK are started in the AFE-IC 12 (step S42). ). Thereafter, a setting command for instructing the initial setting of the watchdog circuit 46 is transmitted from the MCU 11 to the AFE-IC 12, received by the AFE-IC 12, and the setting is performed (step S33). S43 and the MCU 11 start monitoring of the abnormality monitoring clock WCK from the AFE-IC 12 (step S34).

Next, a setting command for instructing the initial setting of the AD converter circuit 36 is transmitted from the MCU 11 to the AFE-IC 12, received by the AFE-IC 12, and the setting is performed (step S35). , S44).

Thereafter, a setting command for instructing initial setting of the thermistor switch circuit 35 is transmitted from the MCU 11 to the AFE-IC 12, received by the AFE-IC 12, and setting is performed (step). S36, S45). Further, a setting command for instructing the initial setting of the power supply voltage detection circuit 31 from the MCU 11 to the AFE-IC 12 and a command for setting the determination value to the registers 54A and 54B of the watchdog circuit 46. The setting command is transmitted (steps S37 and S38), received by the AFE-IC 12, and setting is performed (steps S46 and S47).

(Variation)

Next, a modification of the gas passage electronic control device according to the embodiment will be described with reference to FIGS. 6 and 7. 6 shows a 1st modification, FIG. 7 shows a 2nd modification, and attaches | subjects the same code | symbol to the same or equivalent component or circuit, and the overlapping description is abbreviate | omitted.

In the first modification, as shown in FIG. 6, instead of using the switch circuit 16 including the transistors TR1 and TR2 in series for operating the safety valve 24, the transistor TR1 and the OR gate are used. The switch circuit 16 is configured by (G1), and the signal from the MCU 11 and the AFE-IC 12 is input to the input terminal of the OR gate G1. The functions of the MCU 11 and the AFEIC 12 are the same as those in FIG.

In addition, the OR gate G1 in FIG. 6 can be comprised by the diode OR circuit which consists of two diodes which couple | combined cathode terminals, for example, and compared with the switch circuit 16 of FIG. Can reduce the cost.

As shown in Fig. 7, the second modification is such that the MCU 11 and the AFE-IC 12 are sealed in one package PK and constituted as one semiconductor device. In addition, the circuits of the MCU 11 and the AFE-IC 12 may be formed on one semiconductor chip and configured as one system LSI.

8 shows a second embodiment of the gas channel electronic control apparatus according to the present invention.

This embodiment applies to the case where the electronic control device is composed of three ICs. As a specific example of such a configuration, for example, the control having the MCU 11, the AFE-IC 12, and the power supply control IC 61 is used. You can think of a device.

In such a control device, as shown in Fig. 8A, watchdog clocks WDP1 and WDP2 are output from two general-purpose I / O ports of the MCU 11, and the AFE-IC 12 and power supply control are performed. Each of them is input to the IC 61 and monitored by a watchdog circuit (W / D) inside the chip, and the abnormal monitoring clock (WCK) is output from the AFE-IC 12 and the power supply control IC 61, respectively. Input to the MCU 11 and monitoring.

As shown in Fig. 8B, the watchdog clock WDP1 is output from the general-purpose I / O port of the MCU 11 to be input to the AFE-IC 12, and the AFE-IC 12 is inputted from the AFE-IC 12. The abnormality monitoring clock WCK1 may be output and input to the power supply control IC 61, and the abnormality monitoring clock WCK2 may be output from the power supply control IC 61 and input to the MCU 11 to monitor each other. . In the same concept, the present invention can also be applied to an electronic control device comprising four or more ICs.

As mentioned above, although the invention made by this inventor was demonstrated concretely based on the Example, this invention is not limited to the said Example. For example, in the above embodiment, two comparison circuits 55A for comparing the value counted by the W / D counter circuit 53 and the judgment values (maximum value and minimum value) set in the registers 54A and 54B. , 55B) is provided, but only one of these registers and the comparison circuit may be provided. In the above embodiment, an example is described in which the value counted by the W / D counter circuit 53 is compared with the judgment value (maximum value) and the judgment value (minimum value) set in the registers 54A and 54B. It may compare with the judgment value set previously as a fixed value instead of the value set in the register.

In the above embodiment, the watchdog circuit 46 determines whether there is an abnormality based on the frequency of the watchdog clock WDP from the MCU, but the period of the WDP is measured based on the length of the cycle. The presence or absence of the abnormality may be determined.

In addition, as described above, the AFE-IC 12 includes a serial interface circuit 39 for serial data communication with the microcomputer 11 and an oscillator circuit for generating a clock signal of the serial interface circuit 39. 40, the external oscillator 18 is connected to the oscillation circuit 40. The AFE-IC 12 also supplies an internal control signal in accordance with the sequencer 41 for operating the internal circuit of the chip in a predetermined order, the command code of the sequencer 41 and the digital code from the AD conversion circuit 36. The control logic 42 to generate | generates, the timer circuit 43 which performs time measurement operation by the clock signal from the oscillation circuit 40, and the safety valve control circuit 44 which produces | generates the signal which operates the safety valve 24. Although an independent abnormality monitoring operation is performed by the sequencer operation of the AFIC 12, the AFE-IC 12 of this configuration monitors the abnormality by the command from the microcomputer 11 by manual operation. It is also possible to perform the operation.

Moreover, although the said embodiment demonstrated the case where the invention made mainly by this inventor was applied to the electronic control apparatus of the gas furnace which is the background of the application which used as the background, this invention is not limited to it, The range etc. which cook food ingredients, etc. It can be used for an electronic control system of a device which is easy to generate noise, an engine control system for vehicle mounting, and the like.

11... Microcomputer (MCU)
12... Analog Front End IC (AFE-IC)
13... Current switch transistor
14... Buzzer
15... Driver circuit
16... Transistor Switch Circuit
20... gas ring
21... Cooker burner
23... Solenoid valve for thermal control
24... Safety valve
25... thermocouple
26... Thermistor
27... Igniter for ignition
28... Ignition switch
45... Internal oscillation circuit
46... Watchdog circuit

Claims (5)

An electronic control device comprising a plurality of semiconductor integrated circuit devices, and generates and outputs a control signal for a device to be controlled.
Each of the plurality of semiconductor integrated circuit devices has a function of outputting a clock signal of a predetermined frequency and a function of determining a frequency or period of the clock signal input from another semiconductor integrated circuit device,
And the plurality of semiconductor integrated circuit devices are configured to mutually monitor the clock signals input from other semiconductor integrated circuit devices. The method of claim 1,
One of the plurality of semiconductor integrated circuit devices is a microcomputer, and a clock signal of a predetermined frequency output from the microcomputer is generated by a watchdog function,
The semiconductor integrated circuit device except for the microcomputer includes an oscillation circuit for generating a clock signal of a predetermined frequency, and is configured to output a clock signal based on the oscillation signal generated by the oscillation circuit as a clock signal for abnormal monitoring. Electronic control device characterized in that. The method of claim 2,
The semiconductor integrated circuit device except the microcomputer
An oscillator circuit for generating a clock signal of a predetermined frequency without using an oscillator, a counter circuit capable of counting the number of clock signals input from another semiconductor integrated circuit device, a value counted by the counter circuit and a predetermined judgment value With a comparison circuit to compare,
The counter circuit is counted based on a clock signal generated in the oscillation circuit, and is configured to output an abnormal signal when a value counted by the counter circuit exceeds the predetermined determination value. Electronic control unit. An electronic control device according to claim 3, a gas burner, ignition means arranged in the vicinity of the gas burner to ignite the gas, a gas control valve and an electromagnetic valve provided in the middle of the gas pipe connected to the gas burner; A switch circuit for turning on and off electricity to the solenoid valve,
And the switch circuit is controlled by the abnormal signal and the abnormal signal detected and generated by the watchdog function of the microcomputer to close the solenoid valve when any one of the abnormal signals is output. Gas cooker. An output terminal for outputting a signal for controlling the ignition means arranged in the vicinity of the gas burner;
An input terminal for receiving a clock signal supplied from another semiconductor integrated circuit device,
A communication circuit for transmitting and receiving data with another semiconductor integrated circuit device,
A first oscillator circuit for generating a clock signal for operation of the communication circuit using an oscillator;
A second oscillator circuit for generating a clock signal of a predetermined frequency without using an oscillator;
A counter circuit capable of counting the number of clock signals input to the input terminal from another semiconductor integrated circuit device;
A comparison circuit for comparing the value counted by the counter circuit with a predetermined determination value,
The counter circuit is counted on the basis of the clock signal generated in the second oscillating circuit, and configured to output a signal indicating an abnormality when the value counted by the counter circuit exceeds the predetermined determination value. An electronic control semiconductor integrated circuit device, characterized in that.

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