WO2017104218A1 - Display device and method for updating display device - Google Patents

Abstract

A display device relating to the present invention is provided with: a transmission unit 101 that transmits image data; and a display unit group, which has a plurality of display units 102 that receive the image data, said display units displaying an image on the basis of the image data, and in which the display units are connected in series, and a display unit in the upstream and the transmission unit are connected to each other. The transmission unit transmits, to the display unit in the upstream, updating data for updating functions of the display units, the display unit group transfers the updating data from the display unit in the upstream to the display unit in the downstream, and transmits, to the transmission unit, information relating to updating data storage states of the display unit group, and the transmission unit re-transmits predetermined updating data on the basis of the information relating to the updating data storage state.

Description

Display device and display device update method

The present invention relates to a method for updating activation data of a display device stored in a storage device, and relates to a display device that updates and displays the activation data without error and a method for updating the display device.

A large-screen display device installed on public facilities, stadiums, building walls, etc. that displays guidance, actual sports, advertisements, etc., has a transmission unit for transmitting video data and video data transmitted from the transmission unit. It is comprised including the 1 or several display unit which acquires and displays. In the display unit, a CPU (Central Processing Unit: hereinafter may be described only as CPU) that controls display by a program for displaying video data and a circuit configuration can be changed in a programmable manner. A PLD (Programmable Logic Device: hereinafter may be described only as PLD), or either a CPU or a PLD is mounted. In some cases, a PLD having a CPU is installed.

In such a display device, after installing the display device and starting operation, the program data of the CPU provided in the display unit or the PLD is provided for the purpose of improving the function, performance, and quality. It may be necessary to update the circuit data. In this case, if the display device is configured to include a plurality of display units, it is time consuming and labor-intensive to manually update program data and circuit data for each of the plurality of display units. Will also be enormous.

Therefore, the update data is transmitted from the transmission unit, received by each display unit, and remote update is performed to update the data stored in each display unit.

At this time, when the update data is transmitted from the transmission unit to the display unit, a transmission error due to the influence of noise or the like may occur. If a transmission error occurs, the CPU or PLD may not operate normally. Therefore, when updating, it is necessary to update the data without error.

As an error prevention technique at the time of such update, for example, an FPGA (field-programmable gate array: hereinafter may be described only as FPGA) having a communication function and circuit data for setting the operation of the FPGA are used. A non-volatile memory for storing, and a control unit for reading out circuit data from the non-volatile memory and writing it into the FPGA. The non-volatile memory stores a first area for storing circuit data including all functions and a first area. Invention having a second area for storing circuit data for receiving new circuit data from an external device and writing it to the first area when the FPGA operation by the circuit data thus made fails There is. (For example, refer to Patent Document 1).

With this configuration, when a transmission error occurs in the circuit data when receiving the circuit data from the external device, the FPGA does not operate normally. Therefore, the circuit data is transmitted again from the external device, and the nonvolatile memory Write to. By repeating this until the FPGA operates normally, circuit data without error is finally stored in the nonvolatile memory.

JP 2008-182327 A (page 6-10, FIG. 1)

In the invention according to Patent Document 1, when a transmission error occurs in the circuit data received from the external device, the FPGA fails to start once, and all the circuit data is retransmitted from the external device to the nonvolatile memory. Rewriting is required. At this time, before the re-transmission, it is necessary for the external device to poll each of the plurality of display units to check whether there is a transmission error, and since it takes time to check, the update time of the circuit data is long. Become.

The display device of the present invention has a transmission unit that transmits video data, and a plurality of display units that receive the video data and display video based on the video data, and the display units are connected in series. A display unit group in which the display unit on the upstream side and the transmission unit are connected to each other, and the transmission unit sends update data for updating the functions of the plurality of display units to the display unit on the upstream side. The display unit group transmits the update data from the upstream display unit to the downstream display unit, and transmits information on the storage status of the update data in the display unit group to the transmission unit. The transmission unit retransmits predetermined update data based on information related to the storage state of the update data. A.

According to the present invention, there is no need for the transmission unit to poll each of the plurality of display units for confirmation of status information indicating the error occurrence status of the received data and the write status of the received data in the nonvolatile memory. Since the display unit transmits information about the storage state of the update data to the transmission unit, the update time of the circuit data can be shortened, and the configuration of the display device can be simplified.

It is a block diagram which shows the structure of the display apparatus of Embodiment 1 of this invention. It is a block diagram which shows the structure of the display unit in the display apparatus of Embodiment 1 of this invention. It is a block diagram which shows an example of the display apparatus which concerns on Embodiment 1 of this invention. It is the figure which showed typically the video data output from the transmission unit in the display apparatus which concerns on Embodiment 1 of this invention. It is the figure which showed typically the update data transmitted from the transmission unit in the display apparatus which concerns on Embodiment 1 of this invention. It is a figure which shows an example of a structure of the update data which the display unit in the display apparatus of Embodiment 1 of this invention receives. It is a figure which shows the update data storage area in a non-volatile memory. It is a figure which shows an example of the reception condition of update data. It is a block diagram which shows the structure of the display unit in the display apparatus of Embodiment 1 of this invention. It is a block diagram which shows the structure of the display unit in the display apparatus of Embodiment 1 of this invention. It is a block diagram which shows the structure of the display apparatus of Embodiment 2 of this invention. It is a block diagram which shows the structure of the display unit in the display apparatus of Embodiment 3 of this invention. It is a block diagram which shows the structure of the display unit in the display apparatus of Embodiment 4 of this invention. It is a figure which shows the relationship between the frequency | count of transmission of Embodiment 4 of this invention, and an error correction code | symbol.

Embodiment 1 FIG.
Next, embodiments of the present invention will be described with reference to the drawings. In the following description of the drawings, the same or similar parts are denoted by the same or similar reference numerals. However, it should be noted that the drawings are schematic and ratios of dimensions and the like are different from actual ones. Therefore, specific dimensions and the like should be determined in consideration of the following description. Moreover, it is a matter of course that portions having different dimensional relationships and ratios are included between the drawings.

FIG. 1 is a block diagram schematically showing an example of the configuration of a display device according to Embodiment 1 of the present invention. In the figure, a display device 100 is a device that displays various guides, live video images of competitions, advertisement videos, and the like on, for example, public facilities, stadiums, and wall surfaces of buildings.

The display device 100 normally includes one transmission unit 101 and a plurality of display units 102. A plurality of display units 102 are connected to the transmission unit 101 in series. The transmission unit 101 and the display unit 102, and the display unit 102 and the display unit 102 are connected by a control data line having a relatively low communication speed and a video data line having a relatively high speed, respectively. Thus, the effect of simplifying the circuit and wiring of the apparatus can be obtained by connecting in series. Here, although one transmission unit is used, a display unit group is configured from a plurality of display units, a transmission unit is provided for each display unit group, and a configuration including a plurality of transmission units and a plurality of display unit groups. It does not matter. Moreover, although there are a plurality of normal display units, for example, a combination of one display unit associated with one transmission unit and one transmission unit associated with one display unit group Even in the case where a configuration in which one display unit corresponds to one transmission unit is included, a configuration that achieves the object of the present invention is also included.

FIG. 2 is a diagram showing an internal configuration of the display unit in the display device according to Embodiment 1 of the present invention. As shown in the figure, the display unit 102 includes a first reception unit 201, a volatile memory 202, an error detection unit 203, an address count unit 204, a status information generation unit 205, a write control unit 206, and a second reception unit 207. A non-volatile memory 208, an activation unit 209, a first transmission unit 210, a second transmission unit 211, a display control unit 212, and a display device 213.

The first reception unit 201 receives control data from the display unit 102 connected to the transmission unit 101 or the transmission unit 101 side (hereinafter sometimes referred to as upstream) via a control data line, and volatilizes the data. Stored in the memory 202.

The volatile memory 202 temporarily stores the received control data.

When the received control data is update data, the error detection unit 203 reads the received control data from the volatile memory 202, performs error detection, and outputs the detection result.

The address count unit 204 counts up the received update data until an error occurs.

The write control unit 206 writes the data from the beginning of the received update data to immediately before an error occurs in the nonvolatile memory 208.

Nonvolatile memory 208 stores update data. Here, the update data stored in the nonvolatile memory 208 is used to update the logic circuit data or program data in the PLD unit or the CPU unit shown in FIG. 9 or FIG.

For example, as shown in FIG. 9, the PLD unit 214 includes a first reception unit 201, a volatile memory 202, an error detection unit 203, an address count unit 204, a status information generation unit 205, a write control unit 206, a second control unit 206, The reception unit 207, the nonvolatile memory 208, the activation unit 209, the first transmission unit 210, the second transmission unit 211, and the display control unit 212 are included. The update data in this case is circuit data and is used to configure the logic circuit of the PLD unit 214.

The CPU unit 215 includes, for example, an error detection unit 203, an address count unit 204, a status information generation unit 205, and a write control unit 206, as shown in FIG. The data to be updated in this case is program data, and is used by the CPU unit 215 to perform each process.

The activation unit 209 reads the update data stored in the nonvolatile memory 208 and activates the display unit 102 when the display unit 102 is activated. For example, by setting the read update data in the PLD unit 214, the logic circuit of the PLD unit 214 becomes operable. Further, for example, each process is performed by the read update data being executed by the CPU unit 215.

The second receiving unit 207 receives adjacent status information from the adjacent display unit 102 connected to the opposite side (hereinafter sometimes referred to as downstream) of the transmitting unit 101.

The status information generation unit 205 generates status information based on the adjacent status information received by the second reception unit 207, the address value output by the address count unit 204, and the write status of the write control unit 206.

The first transmission unit 210 displays the status information generated by the status information generation unit 205 on the side different from the display unit connected to the second reception unit 207, that is, the display unit 102 adjacent to the upstream, or Transmit to the transmission unit 101.

The display control unit 212 receives the video data from the transmission unit 101 or the display unit 102 adjacent upstream, and outputs the video data to the display device 213 in the case of the video data displayed by the received display unit itself. If it is not the video data to be displayed by itself, the video data is transmitted to the display unit 102 adjacent to the side opposite to the receiving side.

The display device 213 displays the video data received from the display control unit 212.

The detailed operation of the transmission unit is described below. For example, the transmission unit may be a device having a video server function for supplying video and the like.

The transmission unit 101 outputs video data to be displayed on the display unit 102 via a video data line during normal operation. At this time, the transmission unit 101 multiplexes and outputs each video data to be displayed on each of the plurality of display units 102.

Hereinafter, a case where four display units 102 are connected in series to one transmission unit 101 will be described as an example so that it can be easily described. FIG. 3 is a block diagram showing an example of a display device according to Embodiment 1 of the present invention. As shown in the figure, a transmission unit 101 is connected to a display unit 102A, a display unit 102B, a display unit 102C, and a display unit 102D in order from the side closer to the transmission unit 101.

FIG. 4 is a diagram schematically showing video data output from the transmission unit in the display apparatus according to Embodiment 1 of the present invention.

For example, as shown in FIG. 4, the transmission unit 101 transmits the video data A to be displayed on the display unit 102A, then transmits the video data B to be displayed on the display unit 102B, and then the display unit 102C. The video data C to be displayed is transmitted, and then the video data D to be displayed on the display unit 102D is transmitted. Thereafter, video data D is repeatedly transmitted in the same manner from video data A. Note that the video data A to D may be partial data of the video displayed on the display units 102A to 102D, or may sequentially transmit video that changes with time.

The display unit 102 includes a PLD unit 214, and the logic circuit of the part can be changed. Thereby, it is possible to extend the display function and the control function of the display unit 102.

When updating the logic circuit of the display unit 102, the transmission unit 101 transmits the update data to each display unit 102 via the control data line. At this time, update data transmitted to each display unit 102 is assumed to be the same data.

FIG. 5 is a diagram schematically showing update data transmitted from the transmission unit in the display apparatus according to Embodiment 1 of the present invention. In the display unit 102, the received update data is temporarily stored in the volatile memory 202 and then written in the nonvolatile memory 208. Since the write time to the nonvolatile memory 208 may be longer than the update data transmission time, the present embodiment is configured to temporarily store the update data in the volatile memory 202.
For this reason, the transmission unit 101 divides the update data into a size smaller than the capacity of the volatile memory 202 of the display unit 102 and transmits the update data one by one. Update data 1 to update data N in FIG. 5 indicate each of the divided update data. If the writing time to the non-volatile memory 208 is short, it is not particularly necessary to temporarily store the data in the volatile memory 202.

The detailed operation will be described below.

During normal operation, the display unit 102 receives and displays the video data transmitted from the transmission unit 101.

The display control unit 212 of the display unit 102 receives video data transmitted from either the transmission unit 101 or the display unit 102 adjacent upstream. For example, in the case of the configuration illustrated in FIG. 3, the display control unit 212 of the display unit 102 </ b> A receives the video data transmitted from the transmission unit 101 via the video data line. The display control unit 212 of the display unit 102B receives the video data transmitted from the display unit 102A via the video data line. The display unit 102C receives the video data transmitted from the display unit 102B via the video data line. The display unit 102D receives the video data transmitted from the display unit 102C via the video data line.

Next, the display control unit 212 selects data to be displayed on its own display unit and data to be displayed on another display unit from the received video data, and displays the video data to be displayed on its own display unit as a display device. To 213. In addition, video data to be displayed on another display unit is output to an adjacent display unit. For example, in the case of the display unit 102 </ b> A, the video data A to be displayed on its own display unit among the video data shown in FIG. 4 is output to the display device 213. Also, among the video data shown in FIG. 4, video data B to D to be displayed on the other display units are not video data to be displayed on their own display units, and are transmitted to the adjacent display unit 120B. Thereafter, the same processing is performed in the display units B to D.

Next, the display device 213 displays the video data received from the display control unit 212. For example, the display device 213 includes a plurality of LED elements and a drive circuit for causing the LED elements to emit light, and displays video data by causing each of the plurality of LED elements to emit light.

Next, the operation when changing the circuit of the PLD section of the display unit will be described.

The first receiving unit 201 of the display unit 102 receives update data transmitted from either the transmission unit 101 or the display unit 102 adjacent upstream. For example, in the case of the configuration illustrated in FIG. 3, the first reception unit 201 of the display unit 102 </ b> A receives update data transmitted from the transmission unit 101 via the control data line. The first receiving unit 201 of the display unit 102B receives the update data transmitted from the display unit 102A via the control data line. The first receiving unit 201 of the display unit 102C receives the update data transmitted from the display unit 102B via the control data line. The first receiving unit 201 of the display unit 102D receives the update data transmitted from the display unit 102C via the control data line.

As shown in FIG. 5, the transmission unit 101 divides the update data into a size smaller than the capacity of the volatile memory 202 of the display unit 102 and transmits the update data one by one.

The first receiving unit 201 of the display unit 102 receives update data 1 to update data N in order. The first receiving unit 201 writes the received update data to the volatile memory 202.
At this time, the volatile memory 202 may not have a size sufficient to store all the update data. Therefore, after storing one of the update data 1 to update data N in the volatile memory 202, the update is performed. The next update data is not written until the data processing is completed.

The volatile memory 202 of the display unit 102 is a temporary storage buffer for temporarily storing received update data, and sequentially stores update data 1 to update data N. Therefore, the size of the volatile memory 202 does not need to have a size necessary for storing all the update data, and may have a capacity that can store the maximum size of the update data 1 to the update data N. .

The error detection unit 203 of the display unit 102 detects an error in the received update data. Examples of error detection methods include a checksum or CRC. FIG. 6 shows an example of the update data received. In the figure, the configuration of the update data 1 among the divided update data is illustrated. Here, an example in which a checksum is used for error detection is shown.

The update data 1 is divided into a predetermined size in the transmission unit 101, checksums are calculated for the divided update data 1-0 to update data 1-M, and checksum 1-0 to check Sum 1-M is generated and appended after each update data. The error detection unit 203 calculates a checksum for each of the update data 1-0 to update data 1-M, and confirms a match between the calculation result and the corresponding checksum 1-0 to checksum 1-M. The error detection unit 203 outputs an error detection result indicating that there is no error if the checksums match and that there is an error if the checksums do not match.

The address count unit 204 counts addresses based on the error detection result output from the error detection unit 203. For example, when the update data 1 shown in FIG. 6 is received, the address value is first initialized to 0, and if there is no error in the update data 1-0, the size DSZ1-0 of the update data 1-0 is set in the address value. to add. If there is an error in the update data 1-0, the address value count-up operation is stopped. Next, if the address value count-up operation is not stopped and there is no error in the update data 1-1, the size DSZ1-1 of the update data 1-1 is added to the address value. If there is an error in the update data 1-1, the address value count-up operation is stopped. Similarly, for update data 1-2 to update data 1-M, a count-up operation is performed by adding DSZ1-2 to DSZ1-M unless there is an error.

This operation provides the top address of the area where the first error occurred in update data 1. Hereinafter, this address may be referred to as an error start address. When the processing of the update data 1 is completed, the address count unit 204 outputs the address immediately before the error start address as the end address of normal data. Hereinafter, the end address of normal data may be described only as the end address.

The write control unit 206 writes data in the range from the beginning to the end address output from the address count unit 204 in the received update data in the nonvolatile memory 208. FIG. 7 is a diagram showing an update data storage area in the nonvolatile memory. The non-volatile memory 208 stores each of update data 1 to update data N to store each of update data 1 to update data N, an update data 1 storage area, an update data 2 storage area,. An update data N storage area is provided. If there is no error in the update data 1, the update data 1 is updated in the order of update data 1-0, update data 1-1,..., Update data 1-M from the start address of the update data 1 storage area. Data is written.

If there is an error in the update data, the write control unit 206 performs writing until the address at which the update data is written matches the end address output from the address count unit 204. FIG. 7 shows, as an example, a case where the update data 1-0 to the update data 1-7 have no error and the update data 1-8 includes an error. Update data 1-0 to update data 1-7 are written, and when the writing is completed, the address to which the update data is written matches the end address output from the address count unit 204, so the writing is stopped and the update data 1-8 to update data 1-M are not written.

The activation unit 209 reads the update data stored in the non-volatile memory 208 when the display unit 102 is activated, and sets the PLD unit 214 to make the display unit 102 operable. When the update data is stored in the update data 1 storage area to the update data N storage area of the nonvolatile memory 208, the activation unit 209 reads the update data stored in the update data 1 storage area to the update data N storage area By setting in the PLD unit 214, the PLD unit 214 can operate as a circuit having a configuration updated by the update data.

The second transmission unit 211 transmits the update data received by the first reception unit 201 to the display unit 102 adjacent to the opposite side of the connection destination of the first reception unit 201, that is, downstream.

The second receiving unit 207 receives status information from the display unit 102 adjacent to the downstream, and outputs the status information to the transmission unit or the display unit adjacent to the upstream side as adjacent status information. For example, in the case of the configuration shown in FIG. 3, the display unit 102A receives status information from the display unit B, and outputs the status information to the status information generation unit 205 of the display unit 102A as adjacent status information. The display unit 102B receives the status information from the display unit 102C and outputs the status information to the status information generation unit 205 of the display unit 102B as adjacent status information. The display unit 102C receives the status information from the display unit 102D and outputs the status information to the status information generation unit 205 of the display unit 102C as adjacent status information. The display unit 102D outputs the fact that there is no adjacent status information to the status information generating unit 205 of the display unit 102D because there is no display unit 102 adjacent downstream.

The status information generation unit 205 generates status information based on the tail address output from the address count unit 204, the adjacent status information output from the second reception unit 207, and the write status of the write control unit 206. . Here, a case will be described as an example where the address information at the end of the update data 1 that can be received without error is used as the status information.

At this time, the target display unit 102 is either the end address information output from the address count unit 204 or the end address information transmitted from the adjacent display unit 102 indicated as the adjacent status information, under a predetermined condition. Is output as its own status information. Hereinafter, the end address information transmitted from the adjacent display unit 102 indicated as the adjacent status information may be referred to as adjacent end address information.
Examples of the predetermined condition include a condition that the smaller one of the tail address and the adjacent tail address is output. If the same case, or is determined in advance whether to output either advance or may be a condition that may be output either.

The first transmission unit 210 outputs the status information selected and output by the status information generation unit 205 to the transmission unit 101 or a display unit adjacent upstream. In the case of the configuration shown in FIG. 3, the display unit 102 </ b> A outputs status information to the transmission unit 101.
The display unit 102B outputs status information to the display unit 102A. The display unit 102C outputs status information to the display unit 102B. The display unit 102D outputs status information to the display unit 102C.

When the transmission unit 101 finishes transmitting each of the update data 1 to the update data N, the transmission unit 101 transmits a response request command to each display unit 102 via the control data line. In the configuration shown in FIG. 3, the response request command is transmitted from the transmission unit 101 in the order of the display unit 102A, the display unit 102B, the display unit 102C, and the display unit 102D. When the response request command arrives at the display unit 102D located at the end, the second reception unit 207, status information generation unit 205, and first transmission unit 210 of the display unit 102D operate, and status information is displayed on the display unit 102C. Send to. In the display unit 102C, when the status information is input from the display unit 102D, the second reception unit 207, the status information generation unit 205, and the first transmission unit 210 of the display unit 102C operate, and the status information is displayed on the display unit 102B. Output to. In the display unit 102B, when the status information is input from the display unit 102C, the second reception unit 207, the status information generation unit 205, and the first transmission unit 210 of the display unit 102B operate, and the status information is displayed on the display unit 102A. Output to. In the display unit 102A, when the status information is input from the display unit 102B, the second reception unit 207, the status information generation unit 205, and the first transmission unit 210 of the display unit 102A operate to transmit the status information to the transmission unit 101. Output to.

In any display unit 102, the status information is transmitted after the update data 1 is written in the write control unit 206 until the write address matches the end address output from the address count unit 204. It will be done in.

Based on the operation described above, as shown in FIG. 8, the minimum address value, in this case, AB, is transmitted to the transmission unit 101 among the end addresses of the display units 102A to 102D. At this time, it is not necessary to issue a response request individually to each of the display units 102A to 102D from the transmission unit 101, and it is not necessary to sequentially obtain a response from each of them. There is. Further, the transmission unit 101 does not need to process each of the responses from the display unit 102A to the display unit 102D, and only needs to process the response from the display unit 102A. There is an effect that it can be processed in time.

When the transmission unit 101 receives the status information from the display unit 102A, it compares the status information (in this example, the end address) with the end address of the update data 1 transmitted earlier. If the received status information matches the address at the end of the update data 1, it is determined that the update data 1 has been transmitted to all the display units 102 without error, and the process proceeds to transmission of the update data 2. If the received address value does not match the end address of the update data 1, it is determined that an error has occurred during the transmission of the update data 1, and the update data after the received status information (the end address in this example) Send again. In the example shown in FIG. 7, since the received status information indicates the end of the update data 1-7 of the update data 1, the next update data 1-8 to update data 1-M are retransmitted. . The above operation is repeated until it is determined that all of the update data 1 has been transmitted to the display unit without error.

When the transmission unit 101 starts re-transmission of the update data 1, the display unit 102 performs the operation described above again. However, the error detection unit 203, the address count unit 204, and the write control unit 206 stop operating and receive the address count until the data at the end address output from the address count unit 204 of the display unit 102 is received. The error detection unit 203, the address count unit 204, and the write control unit 206 operate on data after the last address output from the unit 204. In the case of the example shown in FIG. 7, since the end address indicates the end of the update data 1-7, processing is performed from the update data 1-8 to the update data 1-M. By doing so, it is possible to receive without error, and it is possible to write update data after the occurrence of the error to the nonvolatile memory 208 without writing again the update data already written to the nonvolatile memory 208. Become.

Update data 2 to update data N are also transmitted from the transmission unit 101 and received by the display unit 102 and written to the nonvolatile memory 208 in the same manner as described above.

In the above description, the configuration of FIG. 3 has been described as an example. However, the number of display units 102 is not limited to four, and the present invention can be implemented for two or more display units 102.

Needless to say, even if there is only one display unit 102, an update data write operation can be performed by the method described above.

As described above, in the display device and the display method according to the first embodiment of the present invention, the update data after the error is retransmitted, so that the update data can be written without error.

Also, when there is an error in receiving the update data, the update time is shortened because the update data after the address where the error is found is sent instead of retransmitting all the data.

At this time, instead of retransmitting circuit data with a reception error in units of large blocks, it is possible to specify a range to be retransmitted in units of addresses, so it is only necessary to retransmit only the minimum necessary circuit data. Data transmission can be made more efficient.

In addition, instead of rewriting circuit data with a reception error into the nonvolatile memory in units of large blocks, only the circuit data after the error address is written into the nonvolatile memory, thereby reducing the writing time. Is obtained.

Also, it becomes possible to update the update data of many display units at the same time.

In addition, it is not necessary for the transmission unit to poll each display unit for the completion status of writing to a plurality of display units, and since the plurality of display units sequentially transmit the completion status of writing to the transmission unit, There is no need for complicated processing, and the update time can be shortened.

In addition, when there is an error in receiving the update data, the display unit writes the update data after the error in the previous update data transmission to the non-volatile memory. Thus, it is not necessary to rewrite the data, and the number of times of writing can be reduced, so that the physical burden on the nonvolatile memory can be reduced.
As a result, when the same memory is used, the operating life can be extended.

In the above, based on FIG. 2, the configuration in which the circuit data of the PLD unit is stored in the nonvolatile memory of the display unit as shown in FIG. 9 is explained. However, as shown in FIG. The program data to be executed by the CPU instead of the circuit data is stored in the volatile memory, and the program data is transmitted instead of the circuit data as the update data from the transmission unit. Similarly to the process when the update data is circuit data, it is also possible to process the program data as the update data. In this case, the program data stored in the nonvolatile memory of the display unit can be updated without error.

In the configuration in which the CPU part is included in the PLD part, when both the circuit data and the program data are stored in the nonvolatile memory, both the circuit data and the program data can be updated without error. . Furthermore, even when the circuit includes both the PLD and the CPU, both the circuit data and the program data are stored when both the circuit data and the program data are stored in a nonvolatile memory that can be accessed by the PLD and the CPU, respectively. Can be updated without error.

Embodiment 2. FIG.
In the first embodiment, the configuration in which all display units are connected in series to the transmission unit has been described. However, as shown in FIG. 11, a plurality of display unit groups connected in series to the transmission unit are arranged in parallel. It is good also as a structure to connect.

By adopting such a configuration, the number of display units connected in series is reduced as compared with the case where all display units are connected in series, so that the amount of video data transmitted through the video data line is reduced, which is shorter. In addition to being able to transmit video data in time, and considering transmission in the same time, the transmission speed of the video data line can be kept low, and the effect of reducing errors and the like can be obtained. It is also possible to use a data line with a low transmission rate.

In the above embodiment, the control data line for transmitting / receiving the control data and the video data line for transmitting the video data are described separately. However, it is not necessary to have two separate data lines. Control data and video data may be exchanged via a line, or the control data may be multiplexed with the video data and transmitted as a single data stream. If the control data and the video data can be exchanged, the transmission / reception mode is not particularly limited. For example, two-way communication using a twist cable may be used, or data exchange may be performed wirelessly instead of wired.

In the above embodiment, the end address information is compared from the downstream side and the smaller one is transmitted as the status information to the upstream side. However, the smaller end address information is compared from the upstream side as the status information. The same effect can be obtained by adopting a configuration in which the status information from the most downstream display unit is transmitted to the downstream display unit and each display unit transfers the status information to the transmission unit.

In the above embodiment, the address information is used as the status information. However, any information that indicates how much update data has been stored in each display unit, such as the recording capacity information of the update data, is particularly limited to the address information. However, there are many cases where the information specified by the address requires less information.

Embodiment 3 FIG.
FIG. 12 is a diagram illustrating an internal configuration of a display unit in the display device according to the third embodiment. The display unit 102 in this embodiment includes a first receiving unit 201, a volatile memory 202, an error detecting unit 203, an address counting unit 204, a status information generating unit 205, a writing control unit 206, a second receiving unit 207, A nonvolatile memory 208, an activation unit 209, a first transmission unit 210, a second transmission unit 211, a display control unit 212, a display device 213, and an error count unit 216 are provided. In other words, an error count unit 216 is further provided to the configuration of the display unit 102 shown in the first embodiment.

The error count unit 216 counts the number of occurrences of errors in the detection result of the error detection unit 203. For example, the error count unit 216 holds an error count number with an initial value of 0 in the initial stage, and when the detection result of the error detection unit 203 has an error, the error count number is incremented by one, thereby the error detection unit The number of errors generated in 203 is counted. The initial stage refers to, for example, a stage where the power source of the display device is activated or a stage returned when a reset instruction is acquired from the user.

Furthermore, the error count unit 216 notifies the status information generation unit 205 of frequent error information when the error count number becomes larger than a predetermined threshold. When the error information is received from the error count unit 216, the status information generation unit notifies the adjacent display unit 302 or the transmission unit 101 via the first transmission unit 210.

At this time, the identifier of the self-display unit is also notified as the frequent error display unit information together with the frequent error information. The identifier of the display unit is a unique identifier assigned to each display unit. For example, in the case of the configuration shown in FIG. 3, for each of the display units, 102A, 102B, 102C, and 102D, ID_A, Allocation is performed like ID_B, ID_C, and ID_D.

3) When errors frequently occur in the display unit 102C of FIG. 3, the error frequent occurrence information and the frequent error display unit information indicating ID_C are notified to the transmission unit 101 via the display unit 102B and the display unit 102A.

In the transmission unit 101, it can be seen from the error frequent occurrence information and the error frequent occurrence unit information that an error has occurred in the display unit 102C from a predetermined threshold, counting from the initial stage. Based on this information, the maintenance worker can find a display unit in which errors frequently occur. In the configuration shown in FIG. 3, there are only four display units. However, the display device targeted by the present invention assumes a configuration in which several hundred display units are connected, and error frequent occurrence information and error frequent occurrence units are assumed. When there is no information, it is difficult for the maintenance worker to know the display unit in which errors frequently occur. On the other hand, the error frequent occurrence information and the error frequent unit information make it easy for the maintenance operator to know the display unit that is out of order, and the maintenance work can be made more efficient.

Here, the identifier of the display unit may be a number. In other words, a unique number can be assigned if the number of display units is up to four, 2 bits, and up to 256, if 8 bits.

Embodiment 4 FIG.
FIG. 13 is a diagram illustrating an internal configuration of a display unit in the display device according to the fourth embodiment. The display unit 102 in this embodiment includes a first receiving unit 201, a volatile memory 202, an error detection / correction unit 403, an address count unit 204, a status information generation unit 205, a write control unit 206, and a second receiving unit. 207, a nonvolatile memory 208, an activation unit 209, a first transmission unit 210, a second transmission unit 211, a display control unit 212, and a display device 213. In other words, the error detection unit 203 is replaced with the error detection / correction unit 403 with respect to the configuration of the display unit 102 shown in the first embodiment.

FIG. 14 is a diagram illustrating the relationship between the number of times update data is transmitted and the error correction code in the present embodiment. In this embodiment, initially, update data is transmitted from the transmission unit 101 without using an error correction code as in the first embodiment. In the display unit 102, as in the first embodiment, the first receiving unit 201 receives the update data, stores it in the nonvolatile memory 202, and passes the update data to the error detection / correction unit 403.

The error detection / correction unit 403 performs error detection in the same manner as in the first embodiment, and when an error is detected, as in the first embodiment, the address count unit 204, the status information generation unit 205, and the first transmission unit. By 210, the status information is transmitted, and based on this information, the transmission unit 101 retransmits the update data.

At this time, in the present embodiment, at the first retransmission, the error correction code 1 is used to transmit the update data encoded by the error correction code. The display unit 102 receives the update data for the first retransmission as in the first embodiment, and performs error detection in the error detection / correction unit 403, but also performs error correction.

When all errors have been corrected by the error correction of the error detection / correction unit 403, the error detection / correction unit 403 notifies the address count unit 204 that there is no error. Further, the update data after error correction is transferred to the write control unit 206 and written into the nonvolatile memory 208. Thus, in the first embodiment, even when retransmission is necessary, retransmission is not necessary, and update data can be transmitted more efficiently.

On the other hand, if all the errors cannot be corrected by the error correction of the error detection / correction unit 403, the error detection / correction unit 403 notifies the address count unit 204 that there is an error. At this time, as in the first embodiment, the update data in which an error has occurred is not written in the nonvolatile memory 208. Further, similarly to the first embodiment, the status information is transmitted by the address count unit 204, the status information generation unit 205, and the first transmission unit 210, and the transmission unit 101 retransmits the update data based on this information. Send.

As shown in FIG. 14, in the second retransmission, the update data that has been subjected to error correction coding is retransmitted using error correction code 2. The error correction code 2 uses a higher error correction capability than the error correction code 1. The display unit 102 receives the update data for the second retransmission as in the first retransmission, and the error detection / correction unit 403 performs error detection / error correction.

In the second retransmission, an error correction code having a larger error correction capability is used than in the first retransmission, so that error correction can be performed more efficiently.

If an error occurs in the second retransmission and all errors cannot be corrected, similarly, retransmit until all errors can be corrected, as in the third and fourth retransmissions. At this time, as shown in FIG. 14, the error correction code is changed to one having higher error correction capability. Thereby, it becomes possible to perform error correction more efficiently.

As the error correction code, for example, a BCH code or a Reed-Solomon code can be used. At this time, it is possible to change the error correction capability according to the order of the generator polynomial. The error correction capability can be increased by increasing the order of the generator polynomial. However, increasing the order of the generator polynomial increases the size of the update data after error correction coding. For this reason, it is not preferable to use an error correction code having a high error correction capability from the first transmission. For this reason, every time retransmission is performed, the error correction capability is changed. Thereby, it becomes possible to send update data efficiently.

Although the method for not using an error correction code for transmission of the first update data has been described, an error correction code having a weaker error correction capability than the error correction code used for the first retransmission for transmission of the first update data is used. By using it, the number of retransmissions can be reduced as a result in the environment of a display device in which the error frequency of data received by the display unit is high, and the efficiency of update data can be improved.

100 display device, 101 transmission unit, 102 display unit, 201 first reception unit, 202 volatile memory, 203 error detection unit, 204 address count unit, 205 status information generation unit, 206 write control unit, 207 second reception Unit, 208 non-volatile memory, 209 activation unit, 210 first transmission unit, 211 second transmission unit, 212 display control unit, 213 display device, 214 PLD unit, 215 CPU unit, 216 error count unit, 403 error detection・ Correction department.

Claims (13)

1. A transmission unit for transmitting video data;
   A plurality of display units for receiving the video data and displaying video based on the video data, wherein each of the display units is connected in series, and the upstream display unit and the transmission unit are connected A display unit group;
   With
   The transmission unit transmits update data for updating the functions of the plurality of display units to the display unit on the upstream side,
   The display unit group transmits the update data from the display unit on the upstream side to the display unit on the downstream side, and transmits information on the storage status of the update data in the display unit group to the transmission unit,
   The display unit, wherein the transmission unit retransmits predetermined update data based on information related to a storage state of the update data.
2. Information on the storage status of the update data is
   The display device according to claim 1, wherein each of the plurality of display units is a minimum range among update data ranges that can be received without error.
3. The display unit compares the range of update data that the display unit can receive without error and the minimum range of the range of update data that the display unit downstream of the display unit can receive without error. The display device according to claim 2, wherein information relating to the storage state of the update data including the display unit is determined and transmitted to the display unit upstream of the display unit.
4. The information on the storage status of the update data is information indicating a tail address of the update data that each display unit of the display unit group has received without error. The display device according to any one of the above.
5. 5. The display device according to claim 4, wherein the information relating to the storage state of the update data is a minimum value of a tail address of the update data that each display unit of the display unit group has received without error.
6. The display unit includes a tail address of the update data that the display unit has received without error, and a minimum value of the tail address of the update data that the display unit downstream from the display unit can receive without error. 6. The display device according to claim 5, wherein comparison is performed, information relating to a storage state of the update data including the display unit is determined, and transmitted to the display unit upstream of the display unit.
7. The transmission unit is based on information related to the storage state of the update data, and after the data area in which the update data received by the display unit of any one of the display unit groups is out of the data area of the update data The display device according to claim 1, wherein the display device is retransmitted as the predetermined update data.
8. The display unit includes an error detection unit that detects whether there is an error in the received update data;
   An error count unit that counts the number of times the error detection unit detects that there is an error;
   The error frequent occurrence display unit information including the error frequent occurrence information indicating that errors frequently occur and the identifier of the display unit when the number of times the error is detected is larger than a predetermined threshold value set in advance. The display device according to claim 1, wherein the display device transmits the data to a transmission unit.
9. When the transmission unit transmits the update data, the transmission unit transmits the update data without using an error correction code for the first time,
   Each time the update data is retransmitted, the error correction code is transmitted using a high error correction code.
   2. The display unit according to claim 1, wherein the display unit performs error correction on the received update data corresponding to an error correction code used based on the number of times the update data is transmitted. Item 9. The display device according to any one of items 8.
10. The display device according to claim 1, comprising a plurality of the display unit groups.
11. The display device according to any one of claims 1 to 10, wherein the display unit includes a programmable logic device, and the update data updates circuit data of the programmable logic device. .
12. The display device according to any one of claims 1 to 11, wherein the display unit includes a CPU, and the update data is for updating program data of the CPU.
13. A transmission unit for transmitting video data;
    A plurality of display units for receiving the video data and displaying video based on the video data, wherein each of the display units is connected in series, and the upstream display unit and the transmission unit are connected A display device update method comprising a display unit group,
    Update data for updating the functions of the plurality of display units is transmitted from the transmission unit to the display unit on the upstream side,
    The display unit group transmits the update data from the display unit on the upstream side to the display unit on the downstream side, and transmits information on the storage status of the update data in the display unit group to the transmission unit,
    A method for updating a display device, comprising: retransmitting predetermined update data based on information relating to a storage state of the update data.

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