JPWO2020004092A1 - Vehicle display device - Google Patents

Abstract

Provided is a vehicle display device that makes it easy to identify the cause of an error. The vehicle display device (1) stores a display (30) that displays an image showing vehicle information, a GDC (20) that performs a process of displaying the image on the display (30), and a first error information (Er1). It includes a flash ROM (50) to be generated, and a meter microcomputer (10) that causes the GDC (20) to perform image processing by outputting a command signal (S2) to the GDC (20). The GDC (20) makes an error when the first error detection unit (21) that detects that an error related to the GDC (20) has occurred and the first error detection unit (21) detects that an error has occurred. The first error information writing unit (22) for writing the first error information (Er1) including the type, the ODO value indicating the error occurrence timing, and the status information indicating the situation at the time of the error to the flash ROM (50). ..

Description

The present invention relates to a vehicle display device.

Conventionally, a vehicle display device for displaying vehicle information has been known. For example, the display device described in Patent Document 1 includes a GDC (Graphic Display Controller) that performs processing for displaying an image on a liquid crystal panel, and a microcomputer that controls the entire display device.
Further, for example, as described in Patent Document 2, a storage means for storing the mileage of the vehicle and an error code indicating that an error has occurred while updating the mileage stored in the storage means are used as the storage means. It is provided with a control means for storing.

Japanese Unexamined Patent Publication No. 2014-25792 Japanese Unexamined Patent Publication No. 5-322594

In the vehicle display device of Patent Document 1, display control is performed by controlling the GDC and the microcomputer in cooperation with each other. Therefore, the configuration, control, and communication contents of the vehicle display device are complicated. Therefore, when the vehicle display device stops working due to an error, it is difficult to identify the cause of the error only by storing the error code indicating that the error described in Patent Document 2 has occurred. ..

The present invention has been made in view of the above circumstances, and an object of the present invention is to provide a vehicle display device that makes it easy to identify the cause of an error.

In order to achieve the above object, the vehicle display device according to the present invention includes a display element that displays an image indicating vehicle information, an image processing unit that performs image processing for displaying the image on the display element, and a first error. The image processing unit includes a first storage unit that stores information and a meter microcomputer that causes the image processing unit to perform the image processing by outputting a command signal to the image processing unit. When the first error detection unit that detects the occurrence of an error related to the unit and the first error detection unit detects that an error has occurred, the type of error, the timing information indicating the error occurrence timing, and the error It includes a first error information writing unit that writes the first error information including status information indicating the current situation to the first storage unit.

According to the present invention, it becomes easy to identify the cause of an error in a vehicle display device.

It is a block diagram of the display device for a vehicle which concerns on one Embodiment of this invention. It is a figure which shows the 2nd error information which concerns on one Embodiment of this invention. It is a figure which shows the 1st error information which concerns on one Embodiment of this invention. It is a flowchart which shows the procedure of the error information writing processing which concerns on one Embodiment of this invention. (A) to (d) according to one embodiment of the present invention are diagrams schematically showing a storage area of a flash ROM.

An embodiment of a vehicle display device according to the present invention will be described with reference to the drawings.
As shown in FIG. 1, the vehicle display device 1 includes a meter microcomputer 10, a GDC 20, RAMs (Random Access Memory) 15, 25, a display 30, EEPROM (Electrically Erasable Programmable Read-Only Memory) 40, and the like. It includes a flash ROM (Read-Only Memory) 50. The vehicle display device 1 is a vehicle instrument that displays vehicle information such as vehicle speed.

The display 30 corresponds to a display element, and is, for example, a TFT (Thin Film Transistor) type liquid crystal display. The display 30 receives a command signal S2 from the GDC 20 and displays an image showing vehicle information.

The RAM 15 is connected to the meter microcomputer 10 and is used as a work area of the meter microcomputer 10 when executing processing of the meter microcomputer 10. Further, the RAM 25 is connected to the GDC 20 and is used as a work area of the GDC 20 when executing the processing of the GDC 20.

The EEPROM 40 is connected to the meter microcomputer 10 and stores the second error information Er2 and the ODO value indicating the integrated mileage of the vehicle.

The flash ROM 50 is connected to the GDC 20 and stores the first error information Er1. The flash ROM 50 has a larger storage capacity than the EEPROM 40.

The meter microcomputer 10 is a CPU (Central Processing Unit) that controls the entire vehicle display device 1.
It is a microcomputer composed of Unit) and the like, and is connected to GDC20, EEPROM40, RAM15 and CAN (Controller Area Network). The meter microcomputer 10 receives vehicle information via the CAN and outputs a command signal S1 for instructing the GDC 20 to perform image processing. The meter microcomputer 10 includes a second error detection unit 11, a second error information writing unit 12, and an ODO value updating unit 13 as functions. The ODO value updating unit 13 acquires a pulse signal according to the mileage as vehicle information, and updates the ODO value stored in the EEPROM 40 according to the acquired pulse signal.

The second error detection unit 11 detects that an error related to the meter microcomputer 10 has occurred. When the second error detection unit 11 detects that an error has occurred, the second error information writing unit 12 writes the second error information Er2 to the EEPROM 40. As shown in FIG. 2, the second error information Er2 includes indexes Idx0 to Idxn (n is an arbitrary natural number) to which a number is added for each error, an error ID (Identification) Eid indicating the type of error, and an ODO at the time of an error. The value Iod and ancillary information Iad are included. The error related to the meter microcomputer 10 is, for example, a communication error between the meter microcomputer 10 and the GDC 20, the processing of the meter microcomputer 10 is stopped, and the like. The incidental information Iad is composed of data up to 4 bytes, for example, and is arbitrarily set to include more detailed error information than the error IDEid.

As shown in FIG. 1, the GDC 20 corresponds to an image processing unit, and performs image processing for drawing an image of the display 30 by outputting a command signal S2 to the display 30 based on the command signal S1 from the meter microcomputer 10. ..
When the GDC 20 receives the input data Di including the command signal S1 from the meter microcomputer 10, the GDC 20 temporarily writes the input data Di to the RAM 25. Further, when the GDC 20 outputs the output data Do including the command signal S2 to the display 30, the GDC 20 temporarily writes the output data Do to the RAM 25.
The GDC 20 includes a first error detection unit 21 and a first error information writing unit 22 as functions. The first error detection unit 21 detects that an error related to the GDC 20 has occurred. When the first error detection unit 21 detects that an error has occurred, the first error information writing unit 22 writes the first error information Er1 to the flash ROM 50. As shown in FIG. 3, the first error information Er1 is an index Idx0 to Idxn (n is an arbitrary natural number) to which a number is added for each error, an error IDEid, and an ODO value Iod which is timing information indicating an error occurrence timing. , Includes status information Ist indicating the status at the time of error. This status information Ist includes, for example, input data Di at the time of error, output data Do at the time of error, processing content Ipr of GDC 20 at the time of error, and memory usage rate Imu of the work area (RAM 25) at the time of error.

Next, as shown in FIGS. 5A to 5D, a method of storing the first error information Er1 in the flash ROM 50 by the GDC 20 will be described.
As shown in FIG. 5A, the GDC 20 stores the first error information Er1 in the first storage area 51 of the flash ROM 50 each time an error occurs. Then, as shown in FIG. 5B, the GDC 20 transfers the first error information Er1 to the second storage area 52 of the flash ROM 50 every time an error occurs after the free space of the first storage area 51 of the flash ROM 50 is exhausted. I will remember. As shown in FIG. 5C, the GDC 20 erases the data in the first storage area 51 when the free space in the second storage area 52 reaches a predetermined value, for example, 50%. Then, as shown in FIG. 5D, the GDC 20 stores the first error information Er1 in the first storage area 51 again when the free space of the second storage area 52 of the flash ROM 50 runs out. When the free space of the first storage area 51 reaches a predetermined value, for example, 50%, the data in the second storage area 52 is erased. After that, FIGS. 5 (a) to 5 (d) are repeated. Thereby, the first error information Er1 written in the flash ROM 50 can be protected.

Next, the error information writing process executed by the first error information writing unit 22 will be described with reference to FIG. This error information writing process is repeatedly executed when the power of the vehicle display device 1 is turned on.
First, the first error information writing unit 22 waits for the first error detecting unit 21 to detect that an error has occurred (step S101; NO). When the first error detection unit 21 detects that an error has occurred (step S101; YES), the first error information writing unit 22 recognizes the type of error related to the GDC 20, that is, the error IDEid (step S102). Errors related to the GDC 20 include, for example, a communication error between the meter microcomputer 10 and the GDC 20, processing of the GDC 20 is stopped, and a desired image cannot be written to the display 30.

The first error information writing unit 22 reads the ODO value Iod stored in the EEPROM 40 at the time of an error via the meter microcomputer 10 (step S103). Then, the first error information writing unit 22 reads the input data Di at the time of error input from the meter microcomputer 10 to the GDC 20 from the RAM 25 (step S104), and outputs the output data Do at the time of error output from the GDC 20 to the display 30. Read from RAM 25 (step S105).
Next, the first error information writing unit 22 recognizes the processing content Ipr of the GDC 20 at the time of an error (step S106). The processing content Ipr of the GDC 20 includes information such as a combination of processing and programs that were executed when an error occurred. Then, the first error information writing unit 22 recognizes the memory usage rate Imu of the work area (RAM 25) at the time of an error (step S107).

The first error information writing unit 22 includes the error IDEid, the ODO value Iod, the input data Di, the output data Do, the processing content Ipr of the GDC 20, and the memory of the work area corresponding to the types of errors acquired in steps S102 to S107 described above. The first error information Er1 including the usage rate Imu is generated, and the generated first error information Er1 is written to the flash ROM 50 (step S108). At this time, the first error information writing unit 22 attaches indexes Idx0 to Idxn that are not used in the first error information Er1 already stored in the flash ROM 50 to the new first error information Er1. For example, when all the indexes Idx0 to Idxn are used, the new first error information Er1 is overwritten with the first error information Er1 having the smallest ODO value Iod. This completes the error information writing process.

For example, when an error occurs in which a black image is displayed on the display 30, the first error information Er1 including the input data Di and the like at that time is written to the flash ROM 50. Therefore, the input data Di or the like that does not fit in the incidental information Iad of the second error information Er2 can be written to the flash ROM 50.

The first error information Er1 and the second error information Er2 are read by an external computer (not shown) when identifying the cause of the error. The cause of the error is identified by comparing various information included in the first error information Er1 and the second error information Er2.

(effect)
According to the above-described embodiment, the following effects are obtained.

(1) The vehicle display device 1 includes a display 30 which is an example of a display element that displays an image indicating vehicle information, a GDC 20 which is an example of an image processing unit that performs image processing for displaying an image on the display 30, and a third. 1 It includes a flash ROM 50 which is an example of a first storage unit in which error information Er1 is stored, and a meter microcomputer 10 which causes the GDC 20 to perform image processing by outputting a command signal S2 to the GDC 20. The GDC 20 has a first error detection unit 21 that detects that an error related to the GDC 20 has occurred, an error IDEid indicating the type of error when an error has been detected by the first error detection unit 21, and an error occurrence. It includes an ODO value Iod which is timing information indicating the timing, and a first error information writing unit 22 for writing the first error information Er1 including the status information Ist indicating the situation at the time of an error to the flash ROM 50.
According to this configuration, the first error information Er1 includes an error IDEid, an ODO value Iod, and a status information Ist. Therefore, by reading the first error information Er1, it becomes easy to identify the cause of the error.
In particular, the GDC 20 that performs image processing is provided separately from the meter microcomputer 10. In this case, since the GDC 20 and the meter microcomputer 10 perform control in cooperation with each other, the causes of errors are likely to be more diverse than in the configuration in which the meter microcomputer also performs image processing. Therefore, under such a configuration, it is particularly useful to facilitate the identification of the cause of the error by the first error information Er1 as described above.

(2) The first error information writing unit 22 uses the input data Di at the time of the error of the GDC 20, the output data Do at the time of the error of the GDC 20, the processing content Ipr at the time of the error of the GDC 20, and the memory of the work area of the GDC 20 at the time of the error. The rate Imu is included in the first error information Er1 as the status information Ist.
According to this configuration, the first error information Er1 includes the input data Di at the time of error, the output data Do, the processing content Ipr of the GDC 20, and the memory usage rate Imu of the work area as the status information Ist. Therefore, it becomes easy to identify the cause of the error by analyzing the input data Di or the like at the time of the error.

(3) The vehicle display device 1 includes an EEPROM 40 which is an example of a second storage unit in which the second error information Er2 is stored. The meter microcomputer 10 has an error IDEid and an error occurrence timing when the second error detection unit 11 that detects that an error related to the meter microcomputer 10 has occurred and the second error detection unit 11 detects that an error has occurred. A second error information writing unit 12 for writing the second error information Er2 including the ODO value Iod, which is the timing information indicating the above, to the EEPROM 40 is provided.
According to this configuration, an error related to the meter microcomputer 10 is written to the EEPROM 40 as the second error information Er2. Therefore, by analyzing the first error information Er1 and the second error information Er2, it becomes easy to identify the cause of the error.
For example, when a communication error occurs between the GDC 20 and the meter microcomputer 10, the status of the meter microcomputer 10 is written as the second error information Er2, and the status of the GDC 20 is written as the first error information Er1. Therefore, the cause of the communication error can be analyzed from both the GDC 20 and the meter microcomputer 10.

(Modification example)
In addition, the said embodiment can be carried out in the following embodiments which modified this as appropriate.

In the above embodiment, the meter microcomputer 10 includes the second error detection unit 11 and the second error information writing unit 12, but the second error detection unit 11 and the second error information writing unit 12 may be omitted. good.

In the above embodiment, the status information Ist included in the first error information Er1 includes the input data Di, the output data Do, the processing content Ipr of the GDC 20, and the memory usage rate Imu of the work area. However, the present invention is not limited to this, and at least one of the input data Di, the output data Do, the processing content Ipr of the GDC 20, and the memory usage rate Imu of the work area may be omitted in the status information Ist.
Further, the first error information writing unit 22 may include the temperature at the time of an error detected by a temperature sensor (not shown) built in the GDC 20 as the status information Ist in the first error information Er1.

In the above embodiment, the vehicle display device 1 includes a TFT liquid crystal type display 30 as a display element, but the present invention is not limited to this, and an organic EL (Electro-Luminescence) display may be provided as a display element. ..

In the above embodiment, the first error information Er1 includes the ODO value Iod as the timing information indicating the error occurrence timing, but the timing information indicating the error occurrence timing is not limited to the ODO value Iod and the clock. It may be the time to be measured.

In the above embodiment, the vehicle display device 1 is a vehicle instrument, but it may be a head-up display device. In this case, the display 30 is a display element that irradiates the display light, and the display light is projected onto the windshield or the combiner to display a virtual image.

1 Vehicle display device 10 Meter microcomputer 11 Second error detection unit 12 Second error information writing unit 13 ODO value update unit 15, 25 RAM
20 GDC (image processing unit)
21 First error detection unit 22 First error information writing unit 30 Display (display element)
40 EEPROM (second storage unit)
50 Flash ROM (1st storage unit)
Di Input data Do Output data Er1 1st error information Er2 2nd error information Eid Error ID
Idx0 to Idxn Index Iod ODO Value,
Ipr processing content Ist status information Imu memory usage rate

Claims (3)

A display element that displays an image showing vehicle information,
An image processing unit that performs image processing for displaying the image on the display element, and
The first storage unit that stores the first error information and
A meter microcomputer that causes the image processing unit to perform the image processing by outputting a command signal to the image processing unit is provided.
The image processing unit
A first error detection unit that detects that an error related to the image processing unit has occurred, and
When the first error detection unit detects that an error has occurred, the first error information including the type of error, timing information indicating the error occurrence timing, and status information indicating the situation at the time of the error is referred to as the first error information. A first error information writing unit for writing to 1 storage unit is provided.
Display device for vehicles. The first error information writing unit includes input data at the time of error of the image processing unit, output data at the time of error of the image processing unit, processing contents at the time of error of the image processing unit, and the image processing unit at the time of error. At least one of the usage rates of the work area is included in the first error information as the status information.
The vehicle display device according to claim 1. The vehicle display device includes a second storage unit that stores second error information.
The meter microcomputer is
A second error detection unit that detects that an error related to the meter microcomputer has occurred, and
When it is detected by the second error detection unit that an error has occurred, the second error information including the timing information indicating the type of error and the timing of occurrence of the error is written to the second storage unit. With a department,
The vehicle display device according to claim 1 or 2.

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