JP2020061030A - Display device, method of detecting breakage of cable in display device, information processing device, and program - Google Patents

Abstract

To provide a display device, a method of detecting breakage of a cable in the display device, an information processing device, and a program that allow disconnection of a signal line to be detected with a simple configuration without affecting the signal quality.SOLUTION: There is provided a display device 150 connected to an information processing device 100 via a cable 162, which, when image data for display is received from the information processing device, starts power supply to a drive unit 201 that drives a display 202, and upon reception of the image data, notifies the information processing device of an error in a case where power is not supplied to the drive unit within a prescribed time.SELECTED DRAWING: Figure 2

Description

  The present invention relates to a display device, a method for detecting disconnection of a cable in the display device, an information processing device, and a program.

  The high-resolution display device includes a display interface for inputting a high-resolution video signal from an image output device (source device). Display interface standards compatible with high-resolution video signals include, for example, DisplayPort (registered trademark: hereinafter DP) and HDMI (registered trademark). The DP standard (DP standard) defines, as signal lines, a main link (MainLink) of 0 lanes to 3 lanes in total of 4 lanes, an AUX (Auxiliary) channel, and an HPD (Hot Plug Detect). The main link is a unidirectional signal line that encodes a video signal (image signal) and a control signal from an image output device and transmits the encoded signal to a display device (sink device). Each lane of the main link is composed of two differential signals, and high speed transmission of 1.62 Gbps to 2.7 Gbps is performed per lane. The AUX channel is a bidirectional signal line used for passing EDID (Extended Display Identification Data) between the sink device and the source device, link training, and the like. The HPD is a unidirectional signal line that indicates whether or not the sink device can operate by transmitting from the sink device to the source device. The source device and the sink device can be connected by a DP cable conforming to the DP standard or an HDMI cable conforming to the HDMI standard. The sink device starts supplying power to the display unit when the receiving unit receives the video signal via the DP standard main link. Then, the sink device converts the received video signal into image data used in the display unit, and transmits the image data to the display unit for display.

  When the signal line is broken in such a cable, the AUX channel and HPD can be detected as a communication error because the signal from the sink device is not detected by the source device. On the other hand, for a unidirectional output signal from a source device to a sink device, such as a main link, the sink device only sends the signal received from the source device to the display unit as image data and displays it. Side cannot detect disconnection.

  When disconnection occurs in the differential signal of the main link, image data is not transmitted to the display unit, the screen of the display unit becomes black, or an abnormal image is displayed depending on the disconnection state. From the display of this screen, the service technician could not determine that the cable was broken, and it was difficult to identify the abnormal portion.

  As a method of detecting the disconnection in the output signal line in a single direction in such a cable, there is a method described in Patent Document 1, for example. According to this, the transmitting side synthesizes the determination signal with the signal line by the synthesizing circuit and then transmits the signal, and the determining circuit provided on the receiving side branches the received signal line and extracts the determination signal from the signal line. By detecting it, the disconnection of the cable is determined.

JP, 2008-72344, A

  However, with a high-speed differential signal such as the main link of the DP standard described above, when the determination signals are combined as in Patent Document 1, the signal is out of the standard, and the signal input from the cable is used in the display unit. It becomes impossible to convert to image data. In addition, a signal processing circuit for synthesizing the determination signal is required.

  An object of the present invention is to solve at least one of the problems of the above-mentioned conventional techniques.

  An object of the present invention is to provide a technique capable of detecting a disconnection of a signal line with a simple configuration without affecting the signal quality.

In order to achieve the above object, a display device according to an aspect of the present invention has the following configuration. That is,
A display device connected to an information processing device via a cable,
Receiving means for starting power supply to a drive unit that drives the display unit when receiving image data for display from the information processing device,
After receiving the image data, the control means for notifying the information processing device of an error when power is not supplied to the drive unit within a predetermined time.

  According to the present invention, it is possible to detect a disconnection of a signal line with a simple configuration without affecting the signal quality even for a high-speed signal used in high-resolution image data, for example.

  Other features and advantages of the present invention will be apparent from the following description with reference to the accompanying drawings. Note that, in the accompanying drawings, the same or similar configurations are denoted by the same reference numerals.

The accompanying drawings are included in and form a part of the specification, illustrate the embodiments of the invention, and together with the description, serve to explain the principles of the invention.
FIG. 3 is a block diagram illustrating a configuration of an information processing device and a display device according to the embodiment of the invention. FIG. 3 is a block diagram illustrating exchange of signals between the information processing device and the display device according to the embodiment. 3 is a timing chart of each signal described in FIG. 2. 6 is a flowchart illustrating a control process performed by the information processing device according to the embodiment. 6 is a flowchart illustrating a control method in the display device according to the embodiment.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. The following embodiments are not intended to limit the present invention according to the claims, and all combinations of features described in the present embodiments are essential to the solving means of the present invention. Not necessarily.

  FIG. 1 is a block diagram illustrating the configurations of the information processing device 100 and the display device 150 according to the embodiment of the present invention. In FIG. 1, the information processing device 100 is connected to the display device 150 via a cable 162, and these can communicate with each other via the cable 162.

  The information processing apparatus 100 is connected to a scanner 108 that reads an image of a document and a printer 107 that prints the image. Further, the information processing apparatus 100 is connected to the network 140 and the public line 141 to input / output image information and device information via these networks and lines. The information processing device 100 includes a CPU (Central Processing Unit) 101. The CPU 101 expands the program stored in the HDD 105 into the RAM 102, executes the expanded program, and totally controls the information processing apparatus 100. For example, the CPU 101 performs image processing of image data to be printed, communication control via the network 140, and also controls print processing by issuing a print instruction to the printer 107 described above. As control according to the embodiment, the CPU 101 executes control for transmitting image data to be displayed on the screen of the display device 150 to the display device 150 and displaying the image data on the screen.

  A RAM (Random Access Memory) 102 provides a system work memory for the CPU 101 to operate, and also functions as an image memory for temporarily storing image data. Further, the information processing apparatus 100 communicates with another PC or server connected to the network 140 via the network I / F 106 under the instruction of the CPU 101. For example, the information processing apparatus 100 receives print data from the client PC. The RAM 102 also stores setting information of the information processing apparatus 100, job logs and operation logs when each process is performed. A ROM (Read Only Memory) 103 is a boot ROM that stores a system boot program. A HDD (Hard Disk Drive) 105 stores system software, applications, image data, and the like. The operation unit I / F 104 mediates communication with the display device 150 described later. The operation unit I / F 104 also notifies the CPU 101 of the information input by the user via the display device 150.

  The network I / F 106 is connected to the network 140 and inputs / outputs information via the network 140. The modem 109 is connected to the public line 141 and inputs / outputs information via the public line 141. The SRAM 113 is a non-volatile storage medium that can operate at high speed. The timer 114 has a timer (timekeeping) function and measures time in the information processing device 100. The timer function can measure a plurality of times at the same time, and the start / end / readout of the measurement is performed by the CPU 101. The image bus I / F 116 is a bus bridge that connects the system bus 115 and the image bus 117 that transfers image data at high speed and converts the data structure. The image bus 117 is composed of a PCI bus or IEEE1394.

  The following devices are arranged on the image bus 117. The RIP unit 118 is a raster image processor and develops PDL data into a bitmap image. The device I / F 119 connects the scanner 108 and the printer 107 to the information processing apparatus 100, and performs synchronous / asynchronous conversion of image data. The scanner image processing unit 120 corrects, processes, and edits the image data input from the scanner 108. The printer image processing unit 121 performs correction, resolution conversion, etc. on the image data output to the printer 107 according to the characteristics of the printer 107. The encryption processing unit 122 performs an encryption process on input data including image data. The decryption processing unit 123 performs a decryption process on encrypted data.

  Next, the configuration of the display device 150 will be described.

  The display device 150 includes a microcomputer 151, a touch panel module 152, a display module (display panel) 154, and a data converter (DataConv) 153. The display device 150 receives the image data to be displayed from the information processing device 100 via the bus 161 in the cable 162. The display device 150 also communicates with the CPU 101 of the information processing device 100 via the serial bus 160 in the cable 162.

  The microcomputer 151 is a microcomputer that integrally controls the entire display device 150. A ROM 151a storing a program for operating the microcomputer 151 is installed in the microcomputer 151. The touch panel module 152 is arranged on the surface of the display module 154, detects the position information of the portion touched by the user, and notifies the microcomputer 151 via the touch panel communication bus 156. The touch panel module 152 has a touch panel device and a touch panel device controller. The detection method of the designated coordinate position in the touch panel device may be any of a resistance film method, a capacitance method, and an optical method such as infrared rays.

  The data converter 153 receives image data from the operation unit I / F 104 of the information processing apparatus 100 via the bus 161, and converts the image data into a data format that the display module 154 can receive. The data converter 153 receives standard data such as DisplayPort (hereinafter, DP) and HDMI from the information processing apparatus 100, for example. The data converter 153 converts the received data into an LVDS (Low Voltage Differential Signaling) or CMOS level signal format that the display module 154 can receive. The display module 154 has a display panel and a backlight module to display a screen. The display module 154 receives the data from the data converter 153 and displays the image data on the screen at a predetermined timing. The display module 154 displays a function icon, which is an icon associated with a predetermined function such as a fax function and a copy function, on the display screen. An icon is an operation screen of a computer and represents an object to be processed, contents, and the like with a small image of a certain size.

  FIG. 2 is a block diagram illustrating signal exchange between the information processing device 100 and the display device 150 according to the embodiment.

  The display module 154 includes a drive unit 201, a display unit 202, a backlight drive unit 203, a backlight unit 204, and a touch panel 152 (not shown in FIG. 2). The information processing device 100 and the display device 150 are connected via respective connectors 205 and 206 and a cable 162. The cable 162 is assumed to be a cable compliant with the DP standard or the HDMI standard, but it is sufficient if the differential signal of the DP standard can be transferred.

  The cable 162 has a serial bus 210 for communication between the CPU 101 and the microcomputer 151, a bus 161 for transmitting DP standard data for data transmission / reception between the CPU 101 and the data converter 153, and power supply lines 211, 212. The data of the DP standard has signal lines of a main link (MainLink) 207, an AUX (Auxiliary) channel 208, and an HPD (Hot Plug Detect) 209. It should be noted that the power supply lines 211 and 212 may be connected to the display device 150 via a route other than the cable 162 from the information processing device 100. The serial bus 210 transfers a serial signal capable of transmission and reception such as UART, and transmits and receives commands between the CPU 101 and the microcomputer 151. The CPU 101 can, for example, control the lighting of an LED (not shown) inside the backlight unit 204 from the microcomputer 151 or read the voltage level (high level or low level) of a predetermined terminal of the microcomputer 151 from a command.

  The main link 207 transmits a unidirectional output signal for transferring image data for display from the CPU 101 to the data converter 153. According to the DP standard, transmission is possible with four pairs of differential signals L1 + L1-, L2 + L2-, L3 + L3-, L4 + L4-, but here two pairs of differential signals L1 + L1- are used for image data. To transmit. The AUX channel 208 bidirectionally transmits device information and authentication information by the CPU 101 and the data converter 153. In the DP standard, a pair of two differential signals AUX + and AUX- are transmitted. The HPD 209 transmits an input signal indicating whether the data converter 153 is operable, and when the HPD 209 detects a high level state, the CPU 101 determines that communication with the data converter 153 is possible.

  The power supply line 211 supplies power from the information processing apparatus 100 to the microcomputer 151 of the display device 150, the data converter 153, and the power cutoff unit 217. The power supply of the power supply line 211 is a voltage at which the microcomputer 151, the data converter 153, and the driving unit 201 can operate, for example, a power supply of DC 3.3V. The power supply line 212 supplies power from the information processing device 100 to the backlight drive unit 203 of the display device 150. The power supply of the power supply line 212 is a voltage at which the backlight unit 204 can operate, and is, for example, a DC 12V power supply.

  The drive unit 201 receives the image data 214 from the data converter 153 and generates a drive signal for displaying the image data on the screen of the display unit 202. The power supply line 218 supplies power to the driving unit 201, and the voltage thereof is the same as that of the power supply line 211. The power cutoff unit 217 is, for example, a switching circuit using an FET or a transistor, and controls connection and cutoff between the power supply line 211 and the power supply line 218 according to a power supply enable signal 213 from the data converter 153. When the power supply enable signal 213 is at a high level in the state where power is supplied from the power supply line 211 to the power supply cutoff unit 217, the power supply cutoff unit 217 supplies power to the power supply line 218. On the other hand, when the power enable signal 213 is at the low level, the power cutoff unit 217 stops the power supply to the power line 218.

  When the data converter 153 detects the presence of valid image data on the main link 207 input from the CPU 101, it switches the power supply enable signal 213 from low level to high level. Then, the data converter 153 switches the power supply enable signal 213 from the high level to the low level when the presence of the valid image data on the main link 207 is no longer detected. Therefore, when the main link 207 is not normally input due to the disconnection of the cable 213, the power supply enable signal 213 remains at the low level.

  As the power supply sequence of the drive unit 201, the timing of power supply from the image data 214 and the power supply line 218 is defined. Power is supplied to the power supply line 218 before the image data 214 is input to the drive unit 201, for example, 30 milliseconds or more, and power is supplied to the power supply line 218, for example, 30 milliseconds or more after the image data 214 is stopped. The supply needs to be cut off. If this power supply sequence cannot be observed, there is a risk that the circuit inside the drive unit 201 will deteriorate, or that normal operation will not be possible and an abnormal screen will be displayed on the display unit 202. Therefore, the data converter 153 generates the power supply enable signal 213 and the image data 214 so that the above timing is satisfied. Since the power supply enable signal 213 is also connected to the terminal of the microcomputer 151, the microcomputer 151 can detect the signal level of the power supply enable signal 213.

  When the CPU 101 outputs the valid image data to the main link 207, it sends a command to the microcomputer 151 to start detecting the signal level of the power supply enable signal 213. The microcomputer 151 observes the signal level of the power supply enable signal 213 for a predetermined period (for example, 1 second). At this time, if the power supply enable signal 213 remains low level instead of high level, the microcomputer 151 notifies the CPU 101 of an error. The power supply enable signal 213 should maintain a high level while the CPU 101 outputs valid image data to the main link 207. The fact that the power supply enable signal 213 remains at the low level is because the data converter 153 cannot detect the existence of valid image data, and it is considered that the signal line of the main link 207 of the cable 162 is broken. Thus, the CPU 101 can detect the disconnection of the cable 162 by monitoring the change in the signal level of the power supply enable signal 213 after outputting the effective image data to the main link 207.

  The backlight drive unit 203 controls the lighting of the LED inside the backlight unit 204, and after the power supply of the power supply line 212 is supplied, the backlight drive signal 216 such as PWM is input from the microcomputer 151 to input the LED. You can adjust the light intensity of the LED when lights up. In addition to the backlight drive signal 216, the backlight enable signal 215 from the data converter 153 can drive or stop the control of the backlight drive unit 203.

  As the startup sequence of the display device 150, the timing of inputting the image data 214 and lighting of the backlight unit 204 is defined. The backlight drive unit 203 turns on the backlight unit 204 after the image data 214 is input, for example, 200 milliseconds or more, and turns on the backlight unit 204, for example, after the image data 214 is stopped, for example, 200 milliseconds or more. Need to turn off. If this startup sequence cannot be observed, an abnormal screen may be displayed on the display unit 202. The data converter 153 generates the backlight enable signal 215 and the image data 214 so that the above timing is satisfied. The backlight drive signal 216 may be output from the data converter 153. In that case, the backlight drive signal 216 is generated by setting a start flag in a predetermined register inside the data converter 153 from the microcomputer 151 via the serial signal 155.

  FIG. 3 is a timing chart of each signal described in FIG.

  First, a description will be given of the time when power is supplied from the information processing device 100 to the display device 150 via the power supply line 211. When the data converter 153 is supplied with power via the power supply line 211 and becomes operable, the data converter 153 switches the HPD 209 from the low level to the high level and notifies that the communication with the CPU 101 is possible.

  When the CPU 101 detects that the HPD 209 is switched to the high level, the CPU 101 determines that the data converter 153 becomes operable, transfers the AUX channel 208 between the CPU 101 and the data converter 153, and then outputs the output of the main link 207. Start.

  When the data converter 153 detects the presence of valid image data on the main link 207 input from the CPU 101, it switches the power supply enable signal 213 from low level to high level and supplies power to the power supply line 218.

  Then, the data converter 153 outputs the image data 214 about 50 milliseconds after switching the power supply enable signal 213. Here, it is assumed that the power supply by the power line 218 is started by the power cutoff unit 217 within 20 milliseconds after the power enable signal 213 is switched to the high level. This guarantees the power supply sequence defined by the drive unit 201 (the image data 214 is input 30 milliseconds or more after the power supply from the power supply line 218 is input to the drive unit 201).

  The data converter 153 switches the backlight enable signal 215 from low level to high level 200 milliseconds after the output of the image data 214. This guarantees the startup sequence of the display device 150 (the backlight unit 204 is turned on 200 milliseconds or more after the image data 214 is input to the drive unit 201).

  In FIG. 3, the power supply via the power supply line 212 is input at the same time as the power supply via the power supply line 211, and the backlight drive data 216 is generated at the same time as the main link 207. The power supply through the power line 212 and the backlight drive data 216 are input to the backlight drive unit 203 before the backlight enable signal 215 is switched to the high level, and it is sufficient that the backlight unit 204 can be driven. To do.

  Next, an example will be described with reference to FIG. 3 in which the power supply line 218 of the display device 150 is stopped when the information processing device 100 is powered off or when the information processing device 100 is in the power saving mode.

  When stopping the power supply from the power line 218, the CPU 101 stops the output of the valid image data of the main link 207. When the data converter 153 detects the stop of the effective image data on the main link 207 input from the CPU 101, it outputs a black image as the image data 214 and switches the backlight enable signal 215 from the high level to the low level. Here, the black image is output to the image data 214 because the image display on the display unit 202 continues until the backlight unit 204 is turned off after the backlight enable signal 215 is switched to the low level. At this time, by outputting a black image as the image data 214, it is possible to prevent an abnormal image that is not valid image data from being displayed on the display unit 202.

  The data converter 153 outputs a black image for a predetermined period (for example, 200 milliseconds) during which the backlight unit 204 can be turned off, and then stops outputting the image data 214. Subsequently, the data converter 153 switches the power supply enable signal 213 from the high level to the low level 50 milliseconds after stopping the image data 214, and stops the power supply to the power supply line 218.

  Here, for example, if the signal line of the main link 207 of the cable 162 is broken, the data converter 153 cannot detect the presence of valid image data on the main link 207 at power-on, so the power enable signal 213 is set to the low level. Do not switch as it is. At this time, since the microcomputer 151 cannot detect that the power supply enable signal 213 has changed from the low level to the high level, the microcomputer 151 can notify the CPU 101 of an error after a predetermined period has elapsed.

  FIG. 4 is a flowchart illustrating a control process performed by the information processing device 100 according to the embodiment. The process shown in this flowchart is achieved by the CPU 101 executing the program expanded in the RAM 102 described above.

  When power is input to the CPU 101 in step S401, the process proceeds to step S402, and the CPU 101 transmits a command to the microcomputer 151 via the serial bus 210. It suffices to use this command as long as it is possible to determine that communication with the microcomputer 151 can be normally performed, such as reading the version information of the firmware stored in the ROM 151a of the microcomputer 151. Next, the processing proceeds to step S403, and the CPU 101 determines whether or not a command has been received from the microcomputer 151. If no command has been received, the processing proceeds to step S404, and the timer 114 starts measurement for a predetermined time (for example, 5 seconds). If the predetermined time has not elapsed in S404, the process proceeds to S403, but if there is no response from the icon 151 even if the predetermined time elapses in S404, the process proceeds to S405. In step S405, the CPU 101 displays an error code on the display unit 202, notifies the user and the serviceman that a communication error with the microcomputer 151 has occurred, and ends this processing.

  On the other hand, when the command is received from the microcomputer 151 in S403, the process proceeds to S406, and the CPU 101 detects the signal level of the HPD 209 output by the data converter 153. If the signal level of the HPD 209 is low level, the process proceeds to step S407, and the CPU 101 causes the timer 114 to start measuring a predetermined time (for example, 5 seconds). If the predetermined time has not elapsed in S407, the process proceeds to S406, but if the signal level of the HPD 209 does not reach the high level even after the predetermined time has elapsed in S407, the process proceeds to S408. In step S408, the CPU 101 displays an error code on the display unit 202, notifies the user and the serviceman that a reception error from the data converter 153 has occurred, and ends this processing.

  On the other hand, in step S406, when the CPU 101 detects that the signal level of the HPD 209 has become high, the CPU 101 determines that the data converter 153 is operable, and proceeds to step S409. In step S409, the CPU 101 starts communication of the AUX channel 208 with the data converter 153. Next, the processing proceeds to step S410, and the CPU 101 determines whether or not the AUX channel 208 is received from the data converter 153. If there is no reception, the processing proceeds to step S411, and the CPU 101 causes the timer 114 to start measuring a predetermined time (for example, 5 seconds). If the predetermined time has not elapsed in S411, the process proceeds to S410, but if the AUX channel 208 cannot be received even if the predetermined time has elapsed in S411, the process proceeds to S412. In step S412, the CPU 101 causes the display unit 202 to display an error code, notifies the user and the serviceman that a communication error in the AUX channel 208 has occurred, and ends this processing.

  Thus, when the AUX channel 208 is received in S410, the process proceeds to S413, and the CPU 101 starts transmitting the main link 207 to the data converter 153. In S414, the CPU 101 determines whether or not there is an error notification from the microcomputer 151. The error notification determination here means that when the microcomputer 151 detects an error, it sends an UART interrupt command, for example, to the CPU 101 on the serial bus 210. When the CPU 101 receives the interrupt command, it reads the status register inside the microcomputer 151 and determines the content of the error information from the register. Here, when the CPU 101 detects the disconnection error of the cable 162, the process proceeds from step S414 to step S416. The CPU 101 instructs the microcomputer 151 to perform a process for the error with a command. Here, for example, in the case of a disconnection error of the cable 162, it cannot be displayed on the display unit 202 from the CPU 101. Therefore, for example, by controlling the display of the LED of the display device 150 (not shown) by a means different from the display of the error code, for example, the LED is blinked at a predetermined interval, and the disconnection error of the cable 162 is detected by the user. And notify the service person. On the other hand, if there is no error notification from the microcomputer 151 in S414, the process proceeds to S415, and the CPU 101 starts counting the predetermined time (for example, 5 seconds) by the timer 114, and the error notification from the microcomputer 151 does not elapse 5 seconds. At this time, the CPU 101 determines that the display on the display unit 202 has been normally performed, and ends this processing.

  In addition, in S404, S407, S411, and S415 of FIG. 4, the time measured by the timer 114 is set to 5 seconds, but if the CPU 101 can determine that the processes of S403, S406, S410, and S414 are normally completed, respectively. Good, but not limited to this. Further, these times may be different from each other.

  FIG. 5 is a flowchart illustrating a control method in the display device 150 according to the embodiment. The processing shown in this flowchart is achieved by the microcomputer 151 executing the program stored in the ROM 151a.

  This processing is started by supplying power from the information processing apparatus 100 to the power supply line 211 in S501. In S502, the microcomputer 151 determines whether or not a command indicating to transmit the image data for display is received from the CPU 101 via the serial bus 210. When the command is not received, S502 is executed, but when the command is received, the process proceeds to S503, the microcomputer 151 performs processing according to the command received from the CPU 101, and transmits the command according to the processing result to the CPU 101.

  Next, proceeding to S504, the microcomputer 151 monitors the terminal (port) of the microcomputer 151 to which the power supply enable signal 213 is connected for a predetermined period (for example, 1 second) and detects the signal level. Next, proceeding to step S505, the microcomputer 151 starts measuring a predetermined time (for example, 5 seconds) by a timer (not shown) inside the microcomputer 151. If the predetermined time has not elapsed in S505, the process proceeds to S506, but if the signal level of the power supply enable signal 213 does not become the high level even if the predetermined time elapses in S505, the process proceeds to S507. In S507, the microcomputer 151 sets a detection error flag of the power supply enable signal 213 in the status register inside the microcomputer 151. Then, the microcomputer 151 transmits, for example, a UART interrupt command to the CPU 101 via the serial bus 210, and ends this processing.

  On the other hand, when the microcomputer 151 detects that the power supply enable signal 213 has become high level in S506, it means that the data converter 153 can detect the presence of valid image data, and the image data can be transmitted normally. Then, this process ends.

  As described above, according to the embodiment, in order to determine the disconnection of the signal line in the single direction of the cable connecting the information processing device and the display device, the signal input through the cable is displayed by the display device. A signal generated when converting and outputting the image data to be used is used. As a result, it becomes possible to detect a disconnection of a signal line that transmits a signal at high speed for displaying high-resolution image data with a simple configuration without affecting the signal quality.

[Other Embodiments]
In the above-described embodiment, the CPU 151 detects the disconnection of the cable 213 by the microcomputer 151 determining the signal level of the power supply enable signal 213 generated by the data converter 153. However, the microcomputer 151 does not determine the signal level of the power supply enable signal 213, but detects the disconnection of the cable 213 according to the state of the power supply of the power supply line 218 from the power cutoff unit 217 under the control of the power supply enable signal 213. May be. In this case, the power supply line 218 may be connected to the terminal (port) of the microcomputer 151 instead of the power supply enable signal 213. In that case, the voltage of the power supply line 218 needs to be within the operating range (input 3.6 V (Max)) connectable to the terminal of the microcomputer 151.

  Further, in the above embodiment, the case where the cable 162 is provided with the main link 207, the AUX channel 208, the HPD 209, and the serial bus 210 has been shown. However, the cable 162 only needs to have the main link 207, the AUX channel 208, the HPD 209, and the serial bus 210 which are DP standards, and the serial bus 210 may be connected to the CPU 101 via a route different from the cable 162. Alternatively, the cable 162 only needs to have the main link 207, and the AUX channel 208, the HPD 209, the serial bus 210, and the cable 162 may be connected to the CPU 101 via a different route.

  Further, in the above-described embodiment, the disconnection of the cable 162 is detected by the microcomputer 151 observing the power supply enable signal 213 for a predetermined period. Instead of observing the power enable signal 213 for a predetermined period, the interrupt of the microcomputer 151 is performed. You may use the port. In that case, the interrupt circuit inside the microcomputer 151 notifies the microcomputer 151 of an interrupt when it detects an edge where the power supply enable signal 213 changes from the high level to the low level. Upon receiving the notification of the interrupt, the microcomputer 151 confirms the status of the interrupt, and when determining that the interrupt is generated by the power supply enable signal 213, transmits a UART interrupt command to the CPU 101 to notify the disconnection of the cable 162.

  Further, in the above-described embodiment, the case where the cable 162 is constantly disconnected from the time when the power source is started has been described. The disconnection state of the cable 162 includes an unstable state in which the cable 162 is not touched or not touched. Even if the cable 162 is touched when the power is turned on, the device cannot be operated or used while the information processing apparatus 100 is in use. It has been confirmed that there is no contact due to vibration at startup.

  Therefore, in S506 of FIG. 5, if the power supply enable signal 213 becomes high level at the time of power activation, it is determined that the cable 162 is normal thereafter. Even after detecting that the power enable signal 213 is at the high level at power-on, for example, the microcomputer 151 continuously monitors the signal level of the power enable signal 213 every one second, and when the low level is detected, the CPU 101 outputs an error. To notify. Alternatively, when it is detected that the power supply enable signal 213 has changed to the high level at the time of power-on, and then the interrupt port of the microcomputer 151 detects that the power supply enable signal 213 has changed from the high level to the low level, an error is output to the CPU 101. You may make it notify.

(Other embodiments)
The present invention supplies a program that implements one or more functions of the above-described embodiments to a system or apparatus via a network or a storage medium, and one or more processors in a computer of the system or apparatus read and execute the program. It can also be realized by the processing. It can also be realized by a circuit (for example, ASIC) that realizes one or more functions.

  The present invention is not limited to the above-described embodiments, and various changes and modifications can be made without departing from the spirit and scope of the present invention. Therefore, in order to make the scope of the present invention public, the following claims are attached.

  100 ... Information processing device, 101 ... CPU, 150 ... Display device, 151 ... Microcomputer, 153 ... Data converter, 154 ... Display module, 162 ... Cable, 201 ... Driving unit, 202 ... Display unit, 203 ... Backlight driving unit, 204 ... Backlight part, 217 ... Power cutoff part

Claims (14)

A display device connected to an information processing device via a cable,
Receiving means for starting power supply to a drive unit that drives the display unit when receiving image data for display from the information processing device,
After receiving the image data, control means for notifying the information processing device of an error when power is not supplied to the drive unit within a predetermined time,
A display device having: Further comprising a switching circuit for switching whether to supply a voltage of a power supply line to which power is supplied from the information processing device to the drive unit, according to a control signal from the receiving unit,
The display device according to claim 1, wherein the control unit determines whether power is supplied to the drive unit according to a signal level of the control signal. Further comprising a switching circuit for switching whether to supply a voltage of a power supply line to which power is supplied from the information processing device to the drive unit, according to a control signal from the receiving unit,
The display device according to claim 1, wherein the control unit determines whether power is supplied to the drive unit according to an output of the switching circuit.   4. The display according to claim 1, wherein the cable has a DP (DisplayPort) standard signal line, and the image data is received via a main link signal line. apparatus.   The display device according to claim 4, wherein the error includes disconnection of a signal line of the main link. The receiving unit further includes a converting unit that converts the image data into image data to be displayed on the display unit,
6. The receiving unit causes the converting unit to output image data to be displayed on the display unit within a predetermined time after starting power supply to the driving unit. The display device according to item 1.   The display device according to claim 6, wherein the image data displayed on the display unit has a signal format of LVDS (Low Voltage Differential Signaling) or a CMOS level. An information processing device connected to a display device via a cable,
Transmitting means for transmitting image data for display,
After transmitting the image data from the transmitting unit, a receiving unit that receives an error notification from the display device when power is not supplied to the display unit of the display device within a predetermined time,
An information processing device comprising:   The information processing apparatus according to claim 8, wherein the cable has a signal line of DP (Display Port) standard, and the image data is transmitted via a signal line of a main link.   The information processing apparatus according to claim 9, wherein the receiving unit receives the error notification via a signal line different from the signal line.   The information processing apparatus according to claim 10, wherein the error includes disconnection of a signal line of the main link. A method of detecting disconnection of the cable in a display device connected to an information processing device via a cable,
When receiving image data for display from the information processing device, starting the power supply to the drive unit that drives the display unit,
A step of notifying an error indicating that the cable is disconnected when power is not supplied to the drive unit within a predetermined time after receiving the image data,
A method comprising:   A program for causing a computer to function as each unit of the display device according to claim 1.   A program for causing a computer to function as each unit of the information processing apparatus according to claim 8.

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