JP2022000698A - Electronic apparatus - Google Patents

Abstract

To provide an electronic apparatus that, even when a plurality of different types of monitors are connected thereto, can achieve normal display.SOLUTION: An electronic apparatus (2) can be connected between a PC (1) and a plurality of monitors (5, 10), and comprises: a microcomputer (25) that acquires extended display identification data (EDID) from each of the plurality of monitors, compares between the acquired EDID, extracts common resolution information, and creates new EDID including the extracted information; and a memory (26) that stores the new EDID.SELECTED DRAWING: Figure 2

Description

The present invention relates to an electronic device.

Conventionally, an electronic device called an extender (extender) that extends a console such as a keyboard, a mouse, and a monitor, which is connected to a server or a PC (Personal Computer), has been known (see, for example, Patent Document 1). The extender includes a local unit to which the server or PC and the console are connected, and a remote unit to which the console is connected. The local unit and the remote unit are connected by a LAN cable, and are installed at locations separated from each other. The server or PC can be operated from the console connected to the local unit or from the console connected to the remote unit. Further, the video signal from the server or the PC is displayed on the monitor connected to the local unit and the monitor connected to the remote unit.

In the extender, the remote unit reads EDID (Extended Display Identification Data) from the monitor connected to the remote unit, transmits the read EDID to the local unit, and stores it in the memory of the local unit. At this time, the local unit has not read the EDID from the monitor connected to the local unit.

When the server or PC starts up, the local unit sends the EDID stored in the memory to the server or PC, and the server or PC connects the video signal corresponding to the received EDID to the monitor and remote unit connected to the local unit. Output to the monitor.

Japanese Unexamined Patent Publication No. 2011-81571

Since the server or PC outputs a video signal corresponding to the maximum resolution of the monitor connected to the remote unit, for example, when the resolution of the monitor connected to the local unit is smaller than the resolution of the monitor connected to the remote unit. , There is a problem that the monitor connected to the local unit cannot display the video signal normally. Therefore, it was necessary to connect the same type of monitor to the local unit and the remote unit.

An object of the present invention is to provide an electronic device capable of realizing a normal display even when a plurality of monitors of different types are connected.

In order to achieve the above object, the electronic device disclosed in the specification is an electronic device that can be connected between the information processing device and the plurality of display devices, and is a plurality of interfaces that are connected in parallel to the plurality of display devices. An acquisition means for acquiring EDID (Extended Display Identification Data) from each of the plurality of display devices via the unit and the plurality of interface units, and the plurality of display devices via one of the plurality of interface units. One of the first mode for acquiring EDID from one and the second mode for acquiring EDID from each of the plurality of display devices via the plurality of interface units is set as the acquisition means. When the setting means is set to the acquisition means by the setting means, the EDID acquired by the acquisition means is compared, and resolution information common to the plurality of display devices is extracted and extracted. When the setting means sets the first mode as the acquisition means, the acquisition means includes a creation means for creating a new EDID including the information and a storage means for storing the new EDID. It is characterized in that EDID is acquired from one of the plurality of display devices via one of the plurality of interface units.

According to the present invention, it is possible to realize a normal display even when a plurality of monitors of different types are connected.

It is a schematic block diagram of the system provided with the electronic device which concerns on this embodiment. It is a schematic block diagram of a local unit and a remote unit. It is a figure which shows the process executed by a local unit and a PC when a PC acquires the EDID of a monitor 5. It is a figure which shows the process which is executed in the local unit, the remote unit, and the PC when the PC acquires the EDID of the monitor 10. It is a figure which shows the process executed by a local unit and a PC when a PC acquires an EDID common to monitors 5 and 10. (A) is a figure which shows an example of the resolution information included in the EDID of a monitor 5. (B) is a diagram showing an example of resolution information included in the EDID of the monitor 10. (C) is a diagram showing an example of resolution information created by extracting information common to monitors 5 and 10. It is a schematic block diagram of a distributor as an electronic device. It is a schematic block diagram of a multi-KVM switch as an electronic device.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.

FIG. 1 is a schematic configuration diagram of a system including an electronic device according to the present embodiment. The electronic device according to the present embodiment is, for example, an extender.

The extender includes a local unit 2 as a first device and a remote unit 7 as a second device. A PC 1 is connected to the local unit 2, and power is obtained from the AC adapter 6. A keyboard 3, a mouse 4, and a monitor 5 are also connected to the local unit 2. The local unit 2 is connected to the remote unit 7 via the LAN cable 12. The maximum length of the LAN cable 12 is 300 m. The remote unit 7 acquires power from the AC adapter 11. A keyboard 8, a mouse 9, and a monitor 10 are connected to the remote unit 7. The PC 1 can be operated from the keyboard 3 or mouse 4 connected to the local unit 2 or from the keyboard 8 or mouse 9 connected to the remote unit 7. Further, the video signal from the PC 1 is displayed on the monitor 5 connected to the local unit 2 and the monitor 10 connected to the remote unit 7.

FIG. 2 is a schematic configuration diagram of the local unit 2 and the remote unit 7. Note that FIG. 2 omits the configurations related to the keyboards 3 and 8 and the mice 4 and 9.

The local unit 2 divides the interface 21 that connects to the PC 1, the selector 22 that selects either the memory 26 or the splitter 23 as the target to be connected to the PC 1, and the video signal from the PC 1, and divides the video signal from the PC 1 into the monitor 5 and the monitor 10. The splitter 23 that outputs to, the video interface 24 that connects to the monitor 5, the microcomputer 25 that controls the overall operation of the local unit 2, the memory 26 that stores EDID (Extended Display Identification Data), and various signals are remote. It includes a communication unit 27 for transmitting and receiving to and from the unit 7, and a communication interface 28 for connecting to the LAN cable 12. The microcomputer 25 functions as an acquisition means and a creation means, and the memory 26 functions as a storage means.

The microcomputer 25 is connected to the interface 21, the selector 22, the splitter 23, the memory 26, and the communication unit 27. The selector 22 is connected to the interface 21, the splitter 23, and the memory 26. The splitter 23 is connected to the video interface 24. The communication unit 27 is connected to the splitter 23 and the communication interface 28.

The remote unit 7 sets a communication interface 31 for connecting to the LAN cable 12, a communication unit 32 for transmitting and receiving various signals to and from the local unit 2, a microcomputer 33 for controlling the overall operation of the remote unit 7, and a mode described later. A switch 34 for the operation and a video interface 35 connected to the monitor 10 are provided.

The communication unit 32 is connected to the communication interface 31, the microcomputer 33, and the video interface 35. The microcomputer 33 is connected to the switch 34 and the video interface 35.

The local unit 2 and the remote unit 7 have three modes related to EDID. Specifically, the LOCAL_EDID mode in which the PC 1 acquires only the EDID of the monitor 5 connected to the local unit 2, the REMOTE_EDID mode in which the PC 1 acquires only the EDID of the monitor 10 connected to the remote unit 7, and the EDID of the monitor 5. And COMMON_EDID which creates a new EDID by acquiring the EDID of the monitor 10 and comparing both of them and extracting the resolution common to the two monitors.

The switch 34 is used to set the mode of the local unit 2 and the remote unit 7 to any one of the three modes. The set mode is notified to the microcomputer 33 and the microcomputer 25.

When the monitor 5 is connected to the local unit 2, the microcomputer 25 acquires an HPD (hot plug detection) signal indicating that the monitor 5 is connected to the local unit 2 from the monitor 5, and transmits the HPD signal to the PC1. Further, when the mode of the local unit 2 is set to the LOCAL_EDID mode by the switch 34, the microcomputer 25 transmits the HPD signal to the PC1. When the monitor 10 is connected to the remote unit 7, the microcomputer 33 acquires an HPD signal indicating that the monitor 10 is connected to the remote unit 7 from the monitor 10, and transmits the HPD signal to the PC 1 via the local unit 2. .. Further, when the mode of the remote unit 7 is set to the REMOTE_EDID mode by the switch 34, the microcomputer 33 transmits the HPD signal to the PC 1 via the local unit 2.

In this way, since the microcomputers 25 and 33 control the transmission of the HPD signal, the PC1 can be set at a mode other than the timing when the monitor 5 is connected to the local unit 2 or the timing when the monitor 10 is connected to the remote unit 7. Can get the EDID.

FIG. 3 is a diagram showing a process executed by the local unit 2 and the PC 1 when the PC 1 acquires the EDID of the monitor 5.

When the monitor 5 is connected to the local unit 2, the microcomputer 25 acquires an HPD signal indicating that the monitor 5 is connected to the local unit 2 from the monitor 5 (S1), and transmits the acquired HPD signal to the PC1 (S1). S2). On the other hand, when the mode of the local unit 2 is set to the LOCAL_EDID mode by the switch 34, the microcomputer 25 transmits the HPD signal to the PC1 (S2). Here, the microcomputer 25 controls the selector 22 so as to connect the PC 1 and the splitter 23. Upon receiving the HPD signal, the PC 1 requests the EDID from the monitor 5 via the local unit 2 and acquires the EDID from the monitor 5 (S3).

FIG. 4 is a diagram showing a process executed by the local unit 2, the remote unit 7, and the PC 1 when the PC 1 acquires the EDID of the monitor 10.

When the monitor 10 is connected to the remote unit 7, the microcomputer 33 acquires an HPD signal from the monitor 10 indicating that the monitor 10 is connected to the remote unit 7 (S11), and the HPD signal is transmitted to the PC1 via the local unit 2. (S12). On the other hand, when the mode of the remote unit 7 is set to the REMOTE_EDID mode by the switch 34, the microcomputer 33 transmits to the PC 1 via the local unit 2 (S12). Here, the microcomputer 25 controls the selector 22 so as to connect the PC 1 and the splitter 23. Upon receiving the HPD signal, the PC 1 requests the EDID from the monitor 10 via the local unit 2 and the remote unit 7, and acquires the EDID from the monitor 10 (S13).

FIG. 5 is a diagram showing a process executed by the local unit 2 and the PC 1 when the PC 1 acquires the EDID common to the monitors 5 and 10. FIG. 6A is a diagram showing an example of resolution information included in the EDID of the monitor 5. FIG. 6B is a diagram showing an example of resolution information included in the EDID of the monitor 10. FIG. 6C is a diagram showing an example of resolution information created by extracting information common to the monitor 5 and the monitor 10. In FIGS. 6A to 6C, the resolution information includes a resolution, a refresh rate, and a pixel clock, and may be collectively referred to as “resolution” below.

When the mode of the local unit 2 and the remote unit 7 is set to COMMON_EDID, the microcomputer 25 of the local unit 2 acquires the EDID from the monitor 10 via the remote unit 7 (S21). Next, the microcomputer 25 acquires the EDID from the monitor 5 (S22). The processing order of S21 and S22 may be reversed.

The microcomputer 25 compares the EDID of the monitor 10 with the EDID of the monitor 5, extracts only the resolution common to the two monitors, creates a new EDID including the extracted resolution information, and stores it in the memory 26 (S23). ).

For example, the information in the first line of FIG. 6 (A) (resolution: 640 × 480, refresh rate: 60, pixel clock: 25.175) is the same as the information in the first line of FIG. 6 (B), so 2 The resolution common to the two monitors is included in the newly created EDID as shown in FIG. 6 (C). On the other hand, the information in the third line of FIG. 6 (A) (resolution: 640 × 480, refresh rate: 85, pixel clock: 36) is not included in the information of FIG. 6 (B), so the resolution is monitored. It is not common among them and is not included in the new EDID. Similarly, the information in the fourth line of FIG. 6 (B) (resolution: 800 × 600, refresh rate: 60, pixel clock: 40) is not included in FIG. 6 (A), so that it is added to the new EDID. Is not included.

At the same time as S23, the microcomputer 25 controls the selector 22 so as to connect the PC 1 and the memory 26, and transmits the HPD signal to the PC 1 (S24). The PC 1 that has received the HPD signal acquires a new EDID stored in the memory 26 (S25). Since the new EDID stored in the memory 26 includes only the resolution common to the monitor 10 and the monitor 5, even if the PC 1 outputs the video signal corresponding to the maximum resolution of the new EDID, the monitor 10 and the monitor 5 have the same resolution. The video signal can be displayed normally on both sides.

In the above example, when the information in FIG. 6 (A) and the information in FIG. 6 (B) completely match, a new EDID including the information is created, but only a part of the resolution information is common. In the case of, a new EDID may be created. For example, if either the horizontal resolution or the vertical resolution in FIG. 6 (A) matches the resolution in the corresponding direction in FIG. 6 (B), the microcomputer 25 may create a new EDID according to the smaller resolution. good. Specifically, when the monitor 5 corresponds to the resolution of 1280 × 720 and the monitor 10 corresponds to the resolution of 1280 × 800, the horizontal resolutions of each other are common to 1280. In such a case, the microcomputer 25 may create a new EDID according to the resolution (1280 × 720) of the monitor 5 having the smaller vertical resolution among the resolutions of the two monitors, and store the EDID in the memory 26. In this case, since the horizontal resolutions of the monitor 5 and the monitor 10 match, it may be possible to display on both monitors.

In the above example, a method of creating a new EDID including a resolution common to a plurality of monitors by the local unit 2 has been described. This method of creating a new EDID can also be applied to distributors and multi-KVM (K: keyboard, V: video, M: mouse) switches, so the method of creating a new EDID can be applied to distributors and multi-KVM. An example applied to the switch will be described.

FIG. 7 is a schematic configuration diagram of a distributor as an electronic device. The same reference numbers are assigned to the same components as the local unit 2, and the description thereof will be omitted.

The distributor 40 of FIG. 7 distributes the video signal from the PC 1 and displays it on the monitors 5a and 5b. The distributor 40 includes an interface 21, a selector 22, a splitter 23, a video interface 24a connected to the monitor 5a, a video interface 24b connected to the monitor 5b, a microcomputer 25, and a memory 26.

In the distributor 40, the microcomputer 25 acquires the EDID from the monitor 5a (S31). Next, the microcomputer 25 switches the splitter 23 and acquires EDID from the monitor 5b (S32). The processing order of S31 and S32 may be reversed.

The microcomputer 25 compares the EDID of the monitor 5a and the EDID of the monitor 5b, extracts only the resolution information common to both, creates a new EDID including the extracted resolution, and stores it in the memory 26 (S33). At the same time as S33, the microcomputer 25 controls the selector 22 so as to connect the PC 1 and the memory 26.

The microcomputer 25 transmits the HPD signal to the PC 1 (S34). The PC 1 that has received the HPD signal acquires a new EDID stored in the memory 26 (S35). Since the new EDID stored in the memory 26 includes only the resolution common to the monitors 5a and 5b, even if the PC1 outputs a video signal having the maximum resolution of the new EDID, the monitors 5a and the monitor 5b still have the video. The signal can be displayed normally.

FIG. 8 is a schematic configuration diagram of a multi-KVM switch as an electronic device.

The multi-KVM switch 50 is a switch for switching between PC1a and PC1b operated by the consoles 61a and 61b, and can operate PC1a and PC1b at the same time by using the plurality of consoles 61a and 61b. For example, the console 61a can be used to operate the PC1a, and the console 61b can be used to operate the PC1b at the same time. However, when two consoles 61a and 61b are simultaneously connected to the PC1a, for example, the console 61a can operate the PC1a. At this time, the console 61b can receive the video signal from the PC1a, but cannot operate the PC1a.

The multi-KVM switch 50 stores a switch unit 51 that is connected to a plurality of PCs 1a and 1b and switches various signal paths, a microcomputer 52 that controls the overall operation of the multi-KVM switch 50, and an EDID created by the microcomputer 52. It is provided with a memory 53 to be used, and a switch unit 54 connected to a plurality of consoles 61a and 61b to switch various signal paths. The switch unit 51 is connected to the microcomputer 52 and the memory 53, and the switch unit 54 is connected to the microcomputer 52. Each of the consoles 61a and 61b includes a keyboard, mouse and monitor. The microcomputer 52 functions as an acquisition means and a creation means, and the memory 53 functions as a storage means.

In the multi-KVM switch 50, the microcomputer 52 controls the switch unit 54 so as to be connected to the monitor of the console 61a, and acquires EDID from the monitor of the console 61a (S41). Next, the microcomputer 52 controls the switch unit 54 so as to be connected to the monitor of the console 61b, and acquires EDID from the monitor of the console 61b (S42). The processing order of S41 and S42 may be reversed.

The microcomputer 52 compares the EDID of the monitor of the console 61a and the EDID of the monitor of the console 61b, extracts the resolution information common to both, creates a new EDID including the extracted resolution, and stores it in the memory 53 ( S43).

The microcomputer 52 controls the switch unit 51 so as to be connected to the PC 1a, and transmits an HPD signal to the PC 1 (S44). After that, the microcomputer 52 controls the switch unit 51 so that the PC 1a is connected to the memory 53.

The PC 1 that has received the HPD signal acquires a new EDID stored in the memory 53 (S45). Since the acquired EDID includes only the resolution common to the monitor of the console 61a and the monitor of the console 61b, even if the PC1 outputs a video signal having the maximum resolution of the new EDID, the monitor of the console 61a and the console 61b The monitor can display the video signal normally.

As described above, according to the present embodiment, EDIDs are acquired from each of a plurality of monitors, each of them is compared, resolution information common to each monitor is extracted, and a new resolution information including the extracted resolution information is included. Create and store EDID. Since the stored new EDID includes only the resolution common to multiple monitors, even if the PC outputs the video signal corresponding to the maximum resolution among the resolutions set in the new EDID, each monitor is concerned. The video signal can be displayed normally. Therefore, a normal display can be realized even when different types of monitors are connected.

The present invention is not limited to the above-described embodiment, and can be variously modified and implemented within a range that does not deviate from the gist thereof.

1,1a, 1b PC
2 Local unit 5,5a, 5b, 10 Monitor 7 Remote unit 22 Selector 25,33,52 Microcomputer 26,53 Memory 40 Distributor 50 Multi KVM switch

Claims (3)

An electronic device that can be connected between an information processing device and multiple display devices.
A plurality of interface units connected in parallel with the plurality of display devices, and
An acquisition means for acquiring EDID (Extended Display Identification Data) from each of the plurality of display devices via the plurality of interface units, and
A first mode for acquiring EDID from one of the plurality of display devices via one of the plurality of interface units, and a first mode for acquiring EDID from each of the plurality of display devices via the plurality of interface units. A setting means for setting any one of the two modes as the acquisition means, and a setting means for setting the acquisition means.
When the setting means sets the second mode to the acquisition means, the EDIDs acquired by the acquisition means are compared, resolution information common to the plurality of display devices is extracted, and the extracted information is included. How to create a new EDID and
A storage means for storing the new EDID and
Equipped with
When the setting means sets the first mode to the acquisition means, the acquisition means acquires EDID from one of the plurality of display devices via one of the plurality of interface units. Electronic device. When one of the horizontal resolution or the vertical resolution of one EDID of the EDIDs acquired by the acquisition means matches the resolution of the other EDID in the corresponding direction, the creating means has the resolutions of the plurality of display devices. The electronic device according to claim 1, wherein a new EDID is created according to the smaller resolution. The electronic device has a first device to which a first display device and the information processing device are connected, and a second device that communicates with the first device and is connected to a second display device. ,
The first device includes the acquisition means, the creation means, and the storage means.
The acquisition means according to claim 1 or 2, wherein the acquisition means acquires EDID from the first display device and acquires EDID from the second display device by communicating with the second display device. Electronic device.

Images