KR20180018145A - Apparatus and method for monitoring Microcontroller Unit - Google Patents

Abstract

According to the present invention, an apparatus for monitoring a microcontroller comprises: a microcontroller unit; an application specific integrated circuit (ASIC); a sensor installed in a vehicle; a first communications interface installed between the sensor and the microcontroller unit, and simultaneously transmitting sensor data transmitted from the sensor to the ASIC and the microcontroller unit; and a second communications interface installed between the microcontroller unit and the ASIC. The microcontroller unit transmits an operation method to the ASIC, the microcontroller unit and the ASIC respectively derive first and second operation results for the sensor data using the operation method, and the ASIC compares the first operation result with the second operation result to transmit a reset signal to the microcontroller unit on the basis of a comparison result.

Description

[0001] Apparatus and method for monitoring microcontroller unit [

The present invention relates to an operation monitoring of a micro-controller unit (MCU), and more particularly, to an apparatus and a method for monitoring whether a micro-controller unit (MCU) operates normally.

Recently, automobiles use many electronic control devices with microcontroller unit, and their use is increasing. The in-vehicle microcontroller unit plays an important role in controlling the functions of each device of the vehicle.

However, there are cases in which the microcontroller unit occasionally malfunctions or malfunctions due to abnormal signal generation. A malfunction of the microcontroller unit can seriously affect the safety of the rider, so it must always operate normally. Therefore, it is necessary to periodically check whether the microcontroller unit is operating normally.

Generally, a watchdog is used to monitor the abnormality of the microcontroller unit. For example, there is a period watchdog to periodically check the trigger signal, a window watchdog with a time window of the trigger signal, and a Q & A watchdog to answer a given question.

On the other hand, various controllers implemented in a vehicle, such as an airbag controller, already include a number of functions such as proactive protection for safety, diagnosis and the like. However, in the technical field of automobile electronic control devices, there is a tendency to further emphasize the stability of the vehicle. Therefore, additional watchdog techniques for increasing the safety of vehicles other than the existing watchdog are continuously developed in the airbag controller.

Patent Publication No. 10-2013-0009086 {publication date: January 23, 2013}

SUMMARY OF THE INVENTION It is an object of the present invention to provide a novel watchdog apparatus and method capable of monitoring normal operation of a microcontroller unit in an airbag system.

According to an aspect of the present invention, there is provided a microcontroller unit monitoring apparatus comprising: a microcontroller unit; Application Specific Integrated Circuit (ASIC); A sensor installed in the vehicle; A first communication interface installed between the sensor and the microcontroller unit for simultaneously transmitting sensor data transmitted from the sensor to the ASIC and the microcontroller unit; And a second communication interface provided between the microcontroller unit and the ASIC, wherein the microcontroller unit transmits a calculation method to the ASIC, wherein the microcontroller unit and the ASIC are connected to the sensor The ASIC derives the first calculation result and the second calculation result for the data, and the ASIC compares the first calculation result and the second calculation result and transmits a reset signal to the microcontroller unit based on the comparison result Lt; / RTI >

In this case, the ASIC may be configured to transmit a reset signal to the microcontroller unit when the first calculation result and the second calculation result are not identical as a result of the comparison.

The method of operation may be transmitted from the microcontroller unit to the ASIC via the second communication interface.

The microcontroller unit also requests transfer of the sensor data to the sensor when the ASIC requests sensor data to the microcontroller unit, and the sensor transmits the sensor data to the microcontroller unit in response to the transfer request. Unit and the ASIC.

In addition, the microcontroller unit may transmit the calculation method to the ASIC when requesting transmission of the sensor data to the sensor.

The microcontroller unit may transmit the first calculation result to the ASIC, and the ASIC may receive the first calculation result and compare the first calculation result with the second calculation result.

In addition, the ASIC can check whether the time at which the first calculation result reaches the ASIC from the time when the ASIC requests the sensor data reaches the ASIC within a specific time.

Meanwhile, an ASIC according to the present invention includes a first communication interface; A computation method receiving a computation method from a microcontroller unit; A sensor data receiving module for receiving sensor data from the sensors via the first communication interface; A data operation module for deriving a second operation result for the sensor data using the operation method; A calculation result receiving module for receiving a first calculation result derived from the sensor data by the microcontroller unit using the calculation method; A comparison module for comparing the first calculation result and the second calculation result; And a reset module for generating a reset signal based on a result of comparison in the comparison module, and transmitting the reset signal to the microcontroller.

In this case, the reset module may be configured to transmit a reset signal to the microcontroller unit when the first calculation result and the second calculation result are not identical as a result of the comparison by the comparison module.

The method of claim 1, further comprising the second communication interface, wherein the computing method receiving module may receive the computing method from the microcontroller unit via the second communication interface.

In addition, the first and second communication interfaces may be SPI communication interfaces.

The calculation method receiving module requests the sensor data to the microcontroller unit, and the comparison module determines that the time when the first calculation result reaches the ASIC from the time when the sensor data is requested is within a predetermined time, Can be confirmed.

According to another aspect of the present invention, there is provided a microcontroller unit monitoring method, comprising: requesting sensor data from an ASIC to a microcontroller unit; The ASIC receiving an operation method from the microcontroller unit; Receiving the sensor data from a sensor installed in the vehicle via a first communication interface shared by the ASIC with the microcontroller unit; Deriving a second calculation result on the sensor data by the ASIC through the calculation method; Receiving, by the ASIC, a first calculation result derived from the sensor data by the microcontroller unit through the calculation method, and comparing the first calculation result with the second calculation result; And the ASIC generating a reset signal based on the comparison result and transmitting a reset signal to the microcontroller unit.

In this case, the ASIC may be configured to transmit a reset signal to the microcontroller unit when the first calculation result and the second calculation result are not the same.

In addition, the ASIC may receive the calculation method from the microcontroller unit via a second communication interface different from the first communication interface.

In addition, the ASIC may request the microcontroller unit to request the sensor data, and from the time when the sensor data is requested, it is possible to confirm whether the time at which the first calculation result reaches the ASIC reaches the ASIC within a predetermined time .

According to the present invention, it is possible to monitor whether the microcontroller unit operates normally or not by a novel method. Accordingly, the configuration according to the present invention can improve the coverage of the additional functional safety diagnosis in the existing watchdog.

1 is a block diagram showing a configuration of a microcontroller unit monitoring apparatus according to an embodiment of the present invention.
2 is a block diagram illustrating an operation of a microcontroller unit monitoring method according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. It should be understood, however, that the invention is not limited to the disclosed embodiments, but may be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, Is provided to fully inform the user. In addition, for convenience of explanation, components may be exaggerated or reduced in size.

The following embodiments are to be considered as illustrative and not restrictive, and the scope of the present invention is limited only by the following embodiments. It is not.

Hereinafter, a microcontroller unit monitoring apparatus and method according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings. 1 is a block diagram showing a configuration of a microcontroller unit monitoring apparatus according to an embodiment of the present invention.

A microcontroller unit monitoring apparatus according to an embodiment of the present invention includes a microcontroller unit 110 and an ASIC (Application Specific Integrated Circuit) 120. The microcontroller unit monitoring apparatus of the present invention can be utilized in a microcontroller unit installed in a vehicle, such as an airbag controller.

The microcontroller unit 110 may include a calculation method transmission module 112, a sensor data reception module 114, a data calculation module 116 and a calculation result transmission module 118. Modules herein may be implemented as hardware components, software components, and / or a combination of hardware components and software components, as desired by those skilled in the art.

 Operation Method The transmission module 112 sends a data request command to the controller internal sensor 130 through the second communication interface 140 to request sensor data and transmit the operation method. The above-described computation method is preferably a simple computation separate from the computation for utilizing the sensor data in the microcontroller unit 110. [ For example, the calculation method transmission can be performed by numbering a number of calculation methods in advance and transmitting only the numbers related to the calculation method.

In this case, the second communication interface 140 may be, for example, a Serial Peripheral Interface (SPI), and is responsible for communication between the microcontroller unit 110 and the ASIC 120. For example, if the second communication interface 140 is an SPI, the microcontroller unit 110 can supply the clock signal and the SPI communication enable signal as a master mode to the slave mode ASIC 120.

The sensor data receiving module 114 may receive sensor data from the plurality of sensors 130 through the first communication interface 150. [ The first communication interface 140 may be, for example, a serial peripheral interface (SPI). The first communication interface 140 is responsible for communicating with the microcontroller unit 110 and the plurality of sensors 130, e.g., the acceleration sensors within the airbag controller. Further, for example, when the first communication interface 150 is an SPI, the microcontroller unit 110 can supply the clock signal and the SPI communication enable signal as a master mode to the plurality of sensors 130 in the slave mode.

In this case, the first communication interface 150 is shared with the ASIC 120, and the ASCI 120 can monitor the communication signals transmitted and received through the first communication interface 150. That is, the ASIC 120 can directly receive the signals transmitted and received by the microcontroller unit 110 and the plurality of sensors 130 through the first communication interface 150. The first communication interface 150 and the second communication interface 140 are preferably separate interfaces.

The data operation module 116 transmits the operation result (operation value) to the ASIC 120 using the sensor data as a parameter in the same operation method as the operation method transmitted from the operation method transmission module 112.

The ASIC 120 includes a calculation method receiving module 122, a sensor data receiving module 123, a data calculating module 124, a calculation result receiving module 125, a receiving time checking and comparing module 126, and a reset module 127 ).

The computation method receiving module 122 may receive and store the computation method from the microcontroller unit 110 via the second communication interface 140. [

Meanwhile, the sensor data receiving module 123 simultaneously receives and monitors sensor data from the plurality of sensors 130 through the first communication interface 150 with the microcontroller unit.

The data computing module 124 computes the received sensor data as a parser using the computation method received by the computation method receiving module 122. The above-described computation method is preferably a simple computation separate from the computation for utilizing the sensor data in the microcontroller unit 110. [ The data operation module 124 may be performed based on, for example, a number of operation methods preliminarily implemented in hardware and associated with the operation method received by the operation method receiving module.

The calculation result receiving module 125 can receive the calculation result of the sensor data performed in the same manner from the microcontroller unit 110. [

On the other hand, the reception time confirmation and comparison module 126 performs the function of requesting the sensor data, confirming the reception time in the reception result module 125, and comparing the reception result and the operation result calculated by the data operation module 125 can do.

In order to perform the monitoring function for the first time, the reception time confirmation and comparison module 126 can request the sensor data. The reception module 125 confirms the reception time and outputs the calculation result to the microcontroller unit 110, it is possible to generate and send an error signal to the reset module. Alternatively, the microcontroller unit 110 may request sensor data again and repeat the same confirmation a predetermined number of times.

Also, it is possible to determine whether the sensor data operation result received from the microcontroller unit 110 is the same as the sensor data operation result performed by the data operation module 124. In this case, if the two operation results are not the same, an error signal can be generated and transmitted to the reset module 127.

If the two operation results are identical, the microcontroller unit 110 is in a normal state. Therefore, the sensor data is requested to the microcontroller unit 110 and the same process is repeated, You can monitor.

 The reset module 127 may generate a reset signal in response to the error signal received from the reception time confirmation and comparison module 126 and then transmit the reset signal to the microcontroller unit 110 via the second communication interface.

2 is a block diagram illustrating the operation of the microcontroller unit monitoring method of the airbag system according to the embodiment of the present invention.

The calculation module 112 of the microcontroller unit 110 can send a data request command to the controller internal sensor 130 through the second communication interface 140 in response to the request of the ASIC 120, (S202), and transmits the calculation method to the ASIC 120 through the second communication interface 140 (S202).

The calculation method of the ASIC 120 The reception module 122 receives and stores the calculation method from the microcontroller unit 110 (S204). The controller internal sensor 130 receives a data request command from the microcontroller unit 110 (S204).

The plurality of sensors 130 transmit sensor data to the microcontroller unit 110 through the first communication interface 150. [ In this case, the sensor data receiving module 123 of the ASIC 120 may receive and store the same sensor data (S208).

The microcontroller unit performs the calculation using the sensor data as a parameter in the same calculation method as the calculation method transmitted to the ASIC 120 in step S202 (S210), and transmits the sensor data calculation result to the calculation result receiving module (Step S212).

Meanwhile, the data operation module 124 of the ASIC 120 calculates the sensor data from the plurality of sensors 130 using the operation method received from the microcontroller unit 110 (S210).

The reception time confirmation and comparison module 126 of the ASIC 120 checks the reception time of the sensor data operation result received from the microcontroller unit 110 and determines whether the reception time is within a predetermined time range. In addition, it is determined whether the sensor data operation result performed by the data operation module 124 of the ASIC 120 is identical to the sensor data operation result performed by the microcontroller unit 110 (S214).

When the sensor data operation result performed by the data operation module 124 of the ASIC 120 is not the same as the sensor data operation result performed by the microcontroller unit 110, the reset module 127 of the ASIC 120 performs reset A signal is generated (S214) and transmitted to the microcontroller unit 110 to reset the microcontroller unit 110 (S218).

When the sensor data operation result performed by the data operation module 124 of the ASIC 120 is the same as the sensor data operation result performed by the microcontroller unit 110, the reception time confirmation and comparison module 126 of the ASIC 120, The microcontroller unit 110 can request the microcontroller unit 110 again for sensor data and continue to monitor whether the microcontroller unit 110 is in a normal state by repeating the process described above.

While the present invention has been described in connection with what is presently considered to be practical exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, It is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and similarities. Accordingly, the scope of the present invention should be construed as being limited to the embodiments described, and it is intended that the scope of the present invention encompasses not only the following claims, but also equivalents thereto.

110: Microcontroller unit
120: ASIC
130: Sensor inside the controller
140: Second communication interface
150: First communication interface

Claims (16)

A microcontroller unit;
Application Specific Integrated Circuit (ASIC);
A sensor installed in the vehicle;
A first communication interface installed between the sensor and the microcontroller unit for simultaneously transmitting sensor data transmitted from the sensor to the ASIC and the microcontroller unit; And
And a second communication interface installed between the microcontroller unit and the ASIC,
Wherein the microcontroller unit transmits a calculation method to the ASIC and the microcontroller unit and the ASIC derive a first calculation result and a second calculation result for the sensor data using the calculation method, And compare the first calculation result and the second calculation result to transmit a reset signal to the microcontroller unit based on the comparison result
Microcontroller unit monitoring device.
The method according to claim 1,
Wherein the ASIC is configured to transmit a reset signal to the microcontroller unit when the first operation result and the second operation result are not the same as a result of the comparison,
Microcontroller unit monitoring device.
The method according to claim 1,
Wherein the calculation method is transmitted from the microcontroller unit to the ASIC through the second communication interface,
Microcontroller unit monitoring device.
The method according to claim 1,
The microcontroller unit requests the sensor to transmit the sensor data when the ASIC requests the sensor data to the microcontroller unit,
The sensor transmitting the sensor data to the microcontroller unit and the ASIC in response to the transmission request,
Microcontroller unit monitoring device.
The method according to claim 1,
Wherein the microcontroller unit transmits the calculation method to the ASIC when requesting transmission of the sensor data to the sensor,
Microcontroller unit monitoring device.
6. The method of claim 5,
Wherein the microcontroller unit transmits the first calculation result to the ASIC, and the ASIC receives the first calculation result and compares the received first calculation result with the second calculation result,
Microcontroller unit monitoring device.
The method according to claim 6,
Wherein the ASIC confirms whether the time at which the first calculation result reaches the ASIC from the time when the ASIC requests the sensor data reaches the ASIC within a specified time,
Microcontroller unit monitoring device.
A first communication interface;
A computation method receiving a computation method from a microcontroller unit;
A sensor data receiving module for receiving sensor data from the sensors via the first communication interface;
A data operation module for deriving a second operation result for the sensor data using the operation method;
A calculation result receiving module for receiving a first calculation result derived from the sensor data by the microcontroller unit using the calculation method;
A comparison module for comparing the first calculation result and the second calculation result; And
And a reset module for generating a reset signal based on the comparison result in the comparison module and for transmitting the reset signal to the microcontroller,
Application Specific Integrated Circuit (ASIC).
9. The method of claim 8,
Wherein the reset module is configured to transmit a reset signal to the microcontroller unit when the first operation result and the second operation result are not the same as a result of comparison in the comparison module,
ASIC.
9. The method of claim 8,
Further comprising the second communication interface,
Wherein the calculation method receiving module receives the calculation method from the microcontroller unit via the second communication interface,
ASIC.
11. The method of claim 10,
Wherein the first and second communication interfaces are SPI communication interfaces,
ASIC.
9. The method of claim 8,
The calculation method receiving module requests the microcontroller unit for the sensor data,
Wherein the comparison module checks whether the time at which the first calculation result reaches the ASIC from the time when the sensor data is requested reaches the ASIC within a predetermined time,
ASIC.
The ASIC requesting sensor data to the microcontroller unit;
The ASIC receiving an operation method from the microcontroller unit;
Receiving the sensor data from a sensor installed in the vehicle via a first communication interface shared by the ASIC with the microcontroller unit;
Deriving a second calculation result on the sensor data by the ASIC through the calculation method;
Receiving, by the ASIC, a first calculation result derived from the sensor data by the microcontroller unit through the calculation method, and comparing the first calculation result with the second calculation result; And
The ASIC generating a reset signal based on the comparison result and sending a reset signal to the microcontroller unit.
Microcontroller unit monitoring method.
14. The method of claim 13,
Wherein the ASIC is configured to transmit a reset signal to the microcontroller unit when the first operation result and the second operation result are not identical,
Microcontroller unit monitoring method.
14. The method of claim 13,
Wherein the ASIC receives the calculation method from the microcontroller unit via a second communication interface different from the first communication interface,
Microcontroller unit monitoring method.
14. The method of claim 13,
Wherein the ASIC requests the sensor data to the microcontroller unit and confirms whether the time at which the first calculation result reaches the ASIC from the time when the sensor data is requested reaches the ASIC within a specified time,
Microcontroller unit monitoring method.

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