JP5226476B2 - Dual display computer - Google Patents

Description

  The present invention relates to a technique for switching displays in a dual display type computer capable of connecting an external display.

  Notebook-type personal computers (hereinafter referred to as notebook PCs) are lightweight and compact, so they are highly portable and can be connected to function expansion devices such as docking stations and port replicators. Functions equivalent to those of a computer can be realized. Since a notebook PC usually has only one display, in order to use two or more displays, it is necessary to connect to an external display through a function expansion device or connect an external display to the display terminal. .

  When there is only one display, when many windows are opened to work, the windows overlap each other, or it is inconvenient to work because they have to be reduced to be displayed at the same time. In recent years, so-called dual display type notebook PCs in which two displays are mounted on a housing have been developed. In addition, it is common practice to connect an external display directly to a notebook PC to work on a large screen, or connect a projector to give a presentation.

Patent Document 1 discloses a notebook PC that includes a main display and a retractable second display. In this document, it is described that a part of the window is moved to the second display by detecting that the second display has been pulled out by a switch. Patent Document 2 describes that, in a notebook PC having a plurality of folding displays, two LVDS signals or LVDS signals and an analog signal are output from each of two graphics controllers.
Japanese Patent Laid-Open No. 2005-182020 JP 2001-175360 A

  As described above, dual display type notebook PCs composed of a primary display and a secondary display have been developed. Currently, a graphic processing unit (GPU) that generates an image is 2 The so-called dual mode GPU of the data stream is mainstream. And since a normal notebook PC has a display terminal for connecting a primary display and an external display, in a notebook PC equipped with a dual-mode GPU that can output image data to only two displays at the same time, It is necessary to switch the primary display, secondary display and external display appropriately.

  In that case, since the user usually uses the primary display, and further uses the secondary display and the external display as necessary, there is a switching method that does not place a burden on the user according to the user's usage mode. desired. It is also desirable to have a switching method that minimizes changes to the dual mode GPU and the video driver or system BIOS responsible for its operation. Furthermore, a switching method that does not change peripheral software such as an operating system is desired.

  SUMMARY OF THE INVENTION An object of the present invention is to provide a dual display type computer having a display terminal and capable of easily switching between displays. Another object of the present invention is to provide a GPU switching method and a computer program in such a computer.

  The computer according to the present invention employs a dual display system including a primary display attached to a system casing so as to be openable and closable and a secondary display that can be housed and developed according to a use state. The computer further includes a display terminal for connecting an external display and a dual mode GPU. Since the GPU is in dual mode, image data can be output to only two displays at the same time. Therefore, if there is a possibility that at least three displays are connected, it is necessary to select any two displays that the user intends to use. It is desirable that the display is selected according to the user's intention to use and can be realized without placing an operational burden on the user.

  When the user opens the primary display, making it available matches the user's intention to use. Therefore, in the present invention, image data is always output from the first processing system to the primary display opened from the system casing. As a result, image data from the second processing system is output by selecting either the secondary display or the external display. The secondary display can only be used when unfolded from the housing and cannot be used when stored. Further, the state of development and storage of the secondary display can be detected relatively easily. Therefore, in the present invention, the secondary display developed by the user has priority over the external display, and the image data is output from the second processing system, and the external display outputs the image data when the secondary display is stored. By doing so, it is possible to provide a switching method that minimizes changes to existing software and hardware.

  Here, the secondary display is incorporated in the housing, and deployment means that the user can use the screen of the secondary display, and storage means that the user cannot use the screen of the secondary display. . Thus, deployment and storage includes various ways to slide and fold. A state table storing usable information of each display corresponding to the usage state of the primary display and the secondary display is provided to the computer. If the second output port of the GPU is selectively shared (connected) between the secondary display and the external display, the video driver will be able to share the output even if there is an enumeration request. Since it cannot recognize which display is connected to the port, it cannot respond correctly.

  On the other hand, in the state table, the usable information of the secondary display and the external display corresponding to the usage state of the secondary display is determined and stored in advance. In addition to the primary display open / closed status, the status table preliminarily stores the secondary display and external display availability information corresponding to the primary display open / closed status and secondary display usage status. Also good. The state table may be stored in a non-volatile memory that stores the system BIOS so that it can be referred to from the video driver. At this time, if the video driver uses the ACPI_DCS method, the change to the system BIOS can be minimized. The computer detects that the user has expanded or housed the secondary display and the usage state has changed.

  An open sensor attached to the housing may be used to change the usage state. When the usage state of the secondary display changes, the video driver obtains usable information corresponding to the changed usage state with reference to the state table and notifies the operating system (OS). Then, the OS sets each output port of the GPU to enable or disable based on the available information. Further, since the GPU can recognize the display connected to the second output port based on the available information and notify the OS, the display that can be used by the computer even when the output port is shared. Can be recognized.

  In the state table, usable information defined according to the open / close state of the primary display and the use state of the secondary display can be stored. Available information can be defined to indicate that the primary and secondary displays are available and the external display has detached when the primary display is opened and the secondary display is deployed. At this time, it does not matter whether the external display is connected to the display terminal. Even if the external display is connected to the display terminal when the secondary display is expanded, the external display is treated as being detached and the output port corresponding to the external display of the GPU is disabled so that image data is not output. be able to.

  Also, the availability information may be defined to indicate that the primary display and external display are available and the secondary display has detached when the primary display is opened and the secondary display is retracted. it can. In the present invention, when the primary display is opened, image data is always output there, and the secondary display and the external display are treated equally and are selected according to the usage state of the secondary display. Since the image data is output only on one side, the video driver compatible with the GPU corresponding to the primary display and the external display can be used with little change.

  Also, the available information can be defined to indicate that when the primary display is closed and the secondary display is retracted, the external display is connected and the primary display and the secondary display are disconnected. In this case, the present invention can be applied to a usage state in which the display housing is closed and only the external display is used. At this time, when there are a plurality of display terminals, image data can be output from the two display terminals. If the system BIOS holds the state table, it is convenient because it can communicate with the OS and the video driver using the BIOS function.

  The system BIOS notifies the OS of a display event using a Notify (VGA, 0x81) command specified in the ACPI standard, and the OS responds to the display event by enumerating the video driver corresponding to the GPU. In response to the enumeration request, the video driver queries the system BIOS for the available information in the state table using the _DCS method specified in the ACPI standard. Changes to the software used when it does not exist can be kept to a minimum.

  According to the present invention, it is possible to provide a dual display type computer having a display terminal and capable of easily switching between displays. Furthermore, according to the present invention, a display switching method and a computer program in such a computer can be provided.

[Configuration of notebook PC]
FIG. 1 is a diagram showing an outer shape of a notebook PC 10 according to the present embodiment. The notebook PC 10 employs a dual display system, and a primary display 15 and a secondary display 21 are incorporated in a casing. FIG. 1 (A) shows a state where only the primary display 15 is used, and FIG. 1 (B) expands the secondary display 21 and uses the primary display 15 and the secondary display 21 simultaneously. Indicates the state. In the notebook PC 10, a display housing 11 and a system housing 13 are coupled by a hinge so as to be opened and closed.

  The primary display 15 is incorporated so that the display surface faces the front when the display housing 11 is opened from the system housing 13. The secondary display 21 is incorporated in the back surface of the display housing 11 so that it can be pulled out (deployed) or pushed in (stored) depending on the state of use. When using the secondary display 21, the user pulls it out of the display housing 11 and sets the display surface in the same direction as the primary display 15. The system housing 13 accommodates various functional devices inside and has a keyboard 17 and a pointing device 19 mounted on the surface.

[Configuration of notebook PC]
FIG. 2 is a schematic block diagram showing the configuration of the notebook PC 10. The CPU 51 is an arithmetic processing unit having a central function of the notebook PC 10 and executes an OS, a BIOS, a device driver, an application program, or the like. The CPU 51 is connected to a memory controller hub (MCH) 53. The MCH 53 is a device that processes high-speed data transfer in the notebook PC 10, a memory controller function for controlling an access operation to the main memory 55, and a data transfer speed between the CPU 51 and other devices. Includes a data buffer function to absorb the difference. The MCH 53 also has a PCI Express x16 port for connecting the graphics card 57.

  The main memory 55 is a volatile RAM used as an area for reading a program executed by the CPU 51 and a work area for writing process data. The graphics card 57 is connected to the MCH 53 and includes a GPU, a video BIOS, and a video memory (VRAM). In response to a command from the CPU 51, the graphics card 57 generates an image of an image file to be drawn and writes the image file to the VRAM. Can be output to any one of the primary display 15, the secondary display 21, and an external display (not shown). The GPU is a dedicated processor that writes an image to the VRAM based on a drawing command received from the CPU 51, and is also called a graphics accelerator.

  The graphics card 57 corresponds to the dual mode, and can simultaneously output image data generated based on a drawing command from the CPU 51 from two systems. The graphics card 57 is connected to a primary display 15 of LVDS (Low voltage differential signaling) standard, a demultiplexer (DMUX) 65, a DP (DisplayPort) terminal 61, and a VGA (Video Graphics Array) terminal 59. . A protocol converter 67 is connected to one of the two output terminals of the DMUX 65, and a DVI (Digital Visual Interface) terminal 63 is connected to the other. The protocol converter 67 is a device that converts DVI format data into the LVDS format, and an LVDS standard secondary display 21 is connected to the output side. The connection of each device to the graphics card 57 will be described in detail with reference to FIG.

  When the secondary display 21 is housed in the display housing 11 as shown in FIG. 1 (A), a close signal is output to the display housing 11 and deployed as shown in FIG. 1 (B). An open sensor 73 that outputs an open signal is incorporated. The display housing 11 also incorporates a lid sensor 75 that outputs an open signal when the display housing 11 is opened from the system housing 13 and outputs a close signal when the display housing 11 is closed.

  An I / O controller hub (ICH) 69 is connected to the MCH 53 and handles data transfer related to peripheral input / output devices. ICH69 has ports such as USB (Universal Serial Bus), Serial ATA (AT Attachment), SPI (Serial Peripheral Interface) bus, PCI (Peripheral Component Interconnect) bus, PCI-Express bus, and LPC (Low Pin Count). , Devices corresponding to them are connected. In FIG. 2, only the HDD 71 connected to the serial ATA port of the ICH 69 is shown, and other devices are omitted. The HDD 71 stores an OS, device drivers, application programs, utility programs (see FIG. 3), and the like.

  Further, the ICH 69 is connected via the LPC bus 77 to a legacy device conventionally used for the notebook PC 10 or a device that does not require high-speed data transfer. FIG. 2 shows only an embedded controller (EC) 81 and a flash ROM 79 as devices connected to the LPC bus 77. The EC81 is a microcomputer composed of an 8- to 16-bit CPU, ROM, RAM and the like, and further includes a multi-channel A / D input terminal, D / A output terminal, timer, and digital input / output terminal. Yes. The EC 81 controls power supplied to a device mounted on the notebook PC 10. The EC 81 has a keyboard controller function, and is connected with a keyboard 17 and a pointing device 19. An open sensor 73 and a lid sensor 75 are connected to the A / D input terminal of the EC 81.

  The flash ROM 79 is a non-volatile memory that can be electrically rewritten. The flash ROM 79 is a device driver for controlling input / output devices, and conforms to the ACPI (Advanced Configuration and Power Interface) standard to supply power and system enclosures. The system BIOS that manages the temperature in the body 13 and the like, and POST (Power-On Self Test) that performs hardware testing and initialization when the notebook PC 10 is activated are stored. The system BIOS has a configuration of _DCS (Return the Status of Output Device) method defined in the ACPI standard. The system BIOS is configured to issue a Notify (VGA, 0x81) command defined in the ACPI standard to the OS when the connection state of the display connected to the notebook PC 10 is changed.

  Note that FIGS. 1 and 2 merely describe the main hardware configuration and connection relations related to the present embodiment in a simplified manner in order to describe the present embodiment. In addition to those mentioned in the above description, many devices are used to configure the notebook PC 10. However, they are well known to those skilled in the art and will not be described in detail here. A person skilled in the art arbitrarily selects a plurality of blocks shown in FIG. 2 as one integrated circuit or device, or conversely, a block is divided into a plurality of integrated circuits or devices. To the extent possible, it is included in the scope of the present invention.

[Function block for switching display]
FIG. 3 is a block diagram showing the configuration of software and hardware installed in the notebook PC 10 for switching the display. Note that description of the elements described in FIG. 2 is omitted or simplified. The utility program 101 is an application program for providing a user with a screen for configuring a display. Information for configuring the display includes hardware setting information regarding each display, information regarding selection of an external display to be used, and information regarding selection of a display mode when two displays are used. Such information is stored in the registry of the OS.

  The hardware setting information includes resolution, color gradation, refresh rate, set luminance, and the like. The information related to the selection of the external display is information for selecting an external display to be normally used from any one of the DVI display 143, the DP display 141, and the VGA display 139. The information regarding the selection of the display mode is information for selecting either the clone mode (duplication mode) or the extended mode (extended mode) when displaying on two screens.

  The system BIOS 105 is stored in the flash ROM 79. The system BIOS 105 holds _DCS information that can be selected based on an open signal or a close signal received from the lid sensor 75 or the open sensor 73. The _DCS information will be described later with reference to FIG. The video driver 107 is a device driver that relays data exchange between the OS 103 and the graphics card 57 and directly operates the graphics card 57 (FIG. 2). The video driver 107 can query the system BIOS 105 for _DCS information.

  The GPU 109 is a dual mode system having a first processing system 111 that generates a first data stream and a second processing system 113 that generates a second data stream. The GPU 109 includes four output ports: an LVDS port 115, a DVI port 117, a DP port 119, and a VGA port 121. From the LVDS port 115, the DVI port 117, the DP port 119, and the VGA port 121, digital image data or analog image data conforming to the respective standards is output. The GPU 109 processes the drawing command from the CPU 51 independently in the first processing system 111 and the second processing system, and outputs image data from any one of the output ports.

  A primary display 15 is connected to the LVDS port 115. The DVI port 117 is shared so that either the secondary display 21 or the DVI connector 63 is connected. In this embodiment, by adopting such a configuration, a graphics card that supports only the primary display 15 and the external display without mounting the secondary display 21 is used, and a dual display type notebook having a display terminal. Even when used in the PC 10, the display can be easily switched. The DVI port 117 is connected to the input terminal of the DMUX 65, and the two output terminals of the DMUX 65 are connected to the protocol converter 67 and the DVI terminal 63, respectively. The video driver 107 and the GPU 109 control the DMUX 65 to output DVI standard image data to the protocol converter 67 or the DVI terminal 63. The protocol converter 67 converts the DVI standard image data received from the GPU 109 into LVDS standard image data and outputs the image data to the secondary display 21.

  If the secondary display 21 is a DVI standard display, the protocol converter 67 need not be used. Further, the secondary display 21 may be shared with each display terminal at the DP port 119 or the VGA port 121. A DP connector 61 is connected to the DP port 119, and a VGA connector 59 is connected to the VGA port 121. A DVI display 143, a DP display 141, and a VGA display 139 can be connected to the DVI connector 63, the DP connector 61, and the VGA connector 59, respectively, as external displays.

  However, since the GPU 109 is a dual mode system, image data can be sent to only two displays at the same time among the five displays. In the present embodiment, in order to adapt to the user's usage and to simplify the switching of the display, when the display housing 11 is opened and the lid sensor 75 outputs an open signal, the first Image data from the processing system 111 is output to the primary display 15. The image data from the second processing system 113 is output to the secondary display 21 when the secondary display 21 is pulled out, and when the secondary display 21 is stored, the DVI display 143, the DP display 141, or the VGA. Output to one of the displays 139.

  The secondary display 21 shares the DVI terminal 63 and the DVI port 117, but may share the DP port 119 or the VGA port 121. Here, a dedicated output port may be assigned to the secondary display 21 and the remaining two output ports may be assigned to three external displays. In that case, a method for detecting that the external display is connected when the output port of the external display is disabled is required. In addition, as long as the secondary display is expanded as long as the external display is connected, if the image data is output to the external display, the user's intention to use the secondary display will be impaired. As shown in FIG. 3, it is desirable to share the output port between the secondary display and one of the display terminals.

[Status table]
FIG. 4 is a diagram showing the configuration of the status table 150 that stores _DCS information. The _DCS information is information indicating a display availability state for the GPU 109 and is stored in the flash ROM 79 as a part of the system BIOS 105. The video driver 107 can recognize whether a device connected to the LVDS port 115, the DVI port 117, the DP port 119, and the VGA port 121 of the GPU 109 is available, but the DVI port 117 is connected to the secondary display 21. And the DVI display 143 cannot be used to recognize which display is available. The _DCS information is information that defines which of the secondary display 21 and the DVI display 143 can be used in the DVI port 117. The state table 150 includes three types of _DCS information defined based on the open / close state of the primary display 15 determined by the output of the lid sensor 75 and the use state of the secondary display 21 determined by the output of the open sensor 73. Is stored.

  In the status table 150, _DCS = 1 indicates that the corresponding display can be used, and _DCS = 0 indicates that the display cannot be used. Type A and type B define that the primary display 15 can be used when the display housing 11 is open, and type C define that the primary display 15 cannot be used when the display housing 11 is closed. . Both type A and type B define available information when the primary display 15 is available. Type A defines the usable information of each display when the secondary display 21 is pulled out from the display housing 11 and type B is pushed into the display housing 11.

  In type A, it is defined that the primary display 15 and the secondary display 21 can be used, and the DVI display 143, the DP display 141, and the VGA display 139 cannot be used. In this case, it does not matter whether a display corresponding to the DVI connector 63, the DP connector 61, or the VGA connector 59 is connected. In type B, it is defined that the primary display 15, DVI display 143, DP display 141, and VGA display 139 can be used, and the secondary display 21 cannot be used. In this case, it does not matter whether displays corresponding to the DVI connector 63, the DP connector 61, and the VGA connector 59 are connected.

  In type C, only when the secondary display is housed, the primary display 15 and the secondary display 21 are defined as unavailable, and the DVI display 143, the DP display 141, and the VGA display 139 are available. Define. In this case, it does not matter whether displays corresponding to the DVI connector 63, the DP connector 61, and the VGA connector 59 are connected. Type C corresponds to the case where one of the external displays is used with the display housing 11 closed.

  In the present embodiment, since it is assumed that the secondary display 21 is always housed when the display housing 11 is closed, the definition in that case is not provided, but the system housing 11 is closed. If the secondary display 21 is sometimes used, such a definition may be added to the state table 150. In this case, the usable information can be defined as being able to use the secondary display 21, the DVI display 143, the DP display 141, and the VGA display 139.

  In the state table 150, when the display housing 11 is opened, the secondary display 21 and the three external display groups are exclusively defined so as to make the secondary display 21 the same as the external display. Since it can be handled, the display switching control according to the usage state of the secondary display 21 is simplified, and the video driver 107 almost changes the video driver used when the secondary display 21 does not exist. You can use what is not.

[Display switching procedure]
FIG. 5 is a flowchart showing a procedure for switching the display when the secondary display 21 is housed or pulled out. First, in block 501, the display housing 11 is opened as shown in FIG. 1A, the secondary display 21 is accommodated, and an image is displayed on the primary display 15. Further, it is assumed that the DVI display 143 is connected only to the DVI terminal 63 among the three display terminals. Further, the user uses the utility program 101 to set hardware, select an external display, and select a display mode. The DMUX 65 is switched to the DVI connector 63 side, and the OS 103 outputs image data from the first processing system 111 to the primary display 15 and outputs image data from the second processing system 113 to the DVI display 143. The GPU 109 is configured.

In block 503, the secondary display 15 is pulled out by the user as shown in FIG. Assuming that the secondary display 21 is stored as an initial state, the use state of the secondary display 21 changes from storage to expansion in the block 503, but the secondary display 21 is expanded in the block 501 . When the state is assumed, in block 503, the usage state of the secondary display 21 is changed from being expanded to being stored. The open sensor 73 generates an open signal or a close signal according to a change in use state and notifies the EC 81 of the signal. When the EC 81 that has received the open signal or the close signal interrupts the CPU 51 by SMI, the CPU 51 transfers control to the system BIOS 105.

  Receiving the open signal or the close signal, the system BIOS 105 issues an ACPI command Notify (VGA, 0x81) in block 505 to notify the OS 103 that the use state of the second display 21 has changed. The OS 103 temporarily stops the operation of the second processing system 113 and disables the DVI port 117, the DP port 119, and the VGA port 121 in order to safely switch the DMUX 65 performed in a later procedure. Since the Notify (VGA, 0x81) command is defined in the ACPI standard, it can be used by making a small change to the system BIOS. Even if the Notify (VGA, 0x81) command is received, the OS 103 cannot recognize how the display state has specifically changed, and thus cannot control the output port of the GPU 109. Therefore, the OS 103 issues an enumeration request to the video driver 107 in block 507 in order to recognize the changed usage state.

  Since the video driver 107 cannot directly recognize that the secondary display 21 is expanded or stored, the video driver 107 recognizes that the usage state of the secondary display 21 has changed through the OS 103 in this way. However, although the video driver 107 can recognize that a device is connected to each output port, either the secondary display 21 or the DVI display 143 is connected to the shared DVI port 117. It is not possible to recognize what is being done.

  Accordingly, in block 509, the video driver 107 inquires which of the secondary display 21 and the DVI display 143 is available to the system BIOS 105 using the ACPI_DCS method. The system BIOS 105 refers to the status table 150, acquires the usable information corresponding to the types A to C using the open signal or the close signal of each of the lid sensor 75 and the open sensor 73 as an index, and acquires the video driver 107. To tell. Specifically, when the system BIOS 105 determines in block 511 that the secondary display 21 has been stored, in block 513 the type B availability information is returned to the video driver 107, and the video driver returns it to the OS 103. When the system BIOS 105 determines in block 511 that the secondary display 21 has been expanded, the type A availability information is returned to the video driver 107 in block 515, and the video driver 107 returns it to the OS 103.

  When moving from the block 501 to the block 511, the type A availability information is returned to the OS 103, and when returning to the block 511 via the block 515 and the block 521, the type B availability information is returned to the OS 103. Type B availability information indicates that the currently available display is either the DVI display 143, the DP display 141, or the VGA display 139 and the primary display 15. The type A availability information indicates that the currently available displays are the primary display 15 and the secondary display 21.

  In block 517, the video driver 107 switches DMUX 65 through the GPU 109. The video driver 107 obtains usable information from the system BIOS 105 and recognizes whether the DMUX 65 should be connected to the secondary display 21 side or the DVI terminal 63 side, so that it can control correctly. The GPU 109 switches the DMUX 65 so that the DVI port 117 is connected to the DVI terminal 63 when moving from the block 513, and switches the DVI port 117 to the protocol converter 67 when moving from the block 515. At this time, since the DIV port 117 is set to be disabled in the block 505, it is possible to prevent an electrical failure associated with the switching of the DMUX 65 and image disturbance on the secondary display 21 or the DVI display 143.

  In block 519, the video driver 107 notifies the OS 103 that the DMUX 65 switching has been completed. When the OS 103 receives the type B availability information at block 513, the OS 103 sets the three output ports, DVI port 117, DP port 119, and VGA port 121, which have been disabled at block 505, to enable. . The OS 103 enables the DVI port 117 when the type A availability information is received in block 515.

  In block 519, the video driver 107 executes the rest of the processing for the enumeration request from the OS 103 in block 507. If the video driver 107 has received type B availability information at block 513, the video driver 107 identifies the external display connected to one of the three output ports DVI port 117, DP port 119, and VGA port 121. Information (EDID) is notified to the OS 103. Here, since it is assumed that the DVI display 143 is connected, the OS 103 is notified of the EDID. If the video driver 107 has received the type A availability information in block 515, the video driver 107 notifies the OS 103 of the EDID of the secondary display 21.

  In block 521, the OS 103 configures the GPU 109 so that appropriate image data can be output to the display connected to the output port. For the configuration of the display recognized by EDID, for example, a function called TMM (Transient Multimon Manager) included in Vista (registered trademark) of Windows (registered trademark) can be used. The TMM stores information related to the display configuration history in the registry, and can set information configured most recently for the same usable information in the GPU 109.

  For the type B available information, the OS 103 sets the configuration information previously set for the primary display 15 and the DVI display 143 in the GPU 109. Here, the GPU 109 is configured to output the image data from the first processing system 111 to the primary display 15 and from the second processing system 113 to the DVI display 143. When the video driver 107 recognizes that the DP display 141 is actually connected instead of the DVI display 143, the video driver 107 returns the EDID of the DP display 141 to the OS 103. Then, the TMM sets the configuration information previously set for the primary display 15 and the DP display 141 in the GPU 109.

  When the DVI display 143 is removed and the DP display 141 is connected to the DP connector 61 after the previously set configuration information is set for the primary display 15 and the DVI display 143, the GPU 109 is hot-detected (Hotdetect). This is detected by the function, and the OS 103 is notified by referring to the EDID of the DP display 141 and recognizing that a display different from the display set so far is connected. The OS 103 refers to the history information of the TMM for the combination of the DP display 141 and the primary display 15 that holds the received EDID, and if there is a recently set configuration, sets it in the GPU 109.

  If such a combination has not been set in the past, the OS 103 notifies the utility program 101. The utility program 101 displays a pop-up menu on the primary display 15 to prompt the user to set the configuration. Information regarding the configuration is stored in the registry, and in the next processing, the same configuration information for the primary display 15 and the DP display 141 is set in the GPU 109 by the TMM. If no external display is connected to any display terminal, the GPU 109 detects this and stops the operation of the second processing system.

  For the type A available information, the OS 103 sets the configuration information previously set for the primary display 15 and the secondary display 21 in the GPU 109. When the user pulls out the secondary display 21, there is usually an intention to use it with priority over the external display. Therefore, when the secondary display 21 is pulled out, even if any of the external displays is actually connected to the display terminal, the video driver 107 has only the primary display 15 and the secondary display 21 in the OS 103. By notifying that it can be used, the corresponding output port is set to enable, and a configuration suitable for the usage state of the user can be realized without requiring user operation.

  According to the procedure of FIG. 5, image data is always output from the first processing system 111 to the primary display 15. Image data is output from the second processing system 113 to a display selected according to the usage state of the secondary display 21. When the secondary display 21 is expanded, the GPU 109 is configured to output image data to the secondary display 21 in preference to the external display. When the secondary display 21 is stored, the image data is stored on the external display. Since the GPU 109 is configured so as to be output, even when the secondary display 21 is frequently stored or expanded, it is possible to cope with the user without setting the GPU 109 each time.

  Although the present invention has been described with the specific embodiments shown in the drawings, the present invention is not limited to the embodiments shown in the drawings, and is known so far as long as the effects of the present invention are achieved. It goes without saying that any configuration can be adopted.

It is a figure which shows the external shape of the notebook PC concerning this Embodiment. It is a schematic block diagram which shows the structure of the notebook PC concerning this Embodiment. It is a block diagram which shows the structure of the software and hardware mounted in notebook PC in order to switch a display. It is a figure which shows the structure of the state table which system BIOS holds. It is a flowchart which shows the procedure which performs the switching of the display accompanying accommodation or drawer | drawing-out of a secondary display.

Explanation of symbols

DESCRIPTION OF SYMBOLS 11 ... Display housing 13 ... System housing 15 ... Primary display 21 ... Secondary display 101 ... Utility program 109 ... GPU
150 ... Status table

Claims (15)

A primary display that can be opened and closed in the system chassis, a secondary display that can be stored and expanded according to usage conditions, a display terminal for connecting an external display, and dual-mode graphic processing In a dual display type computer comprising a unit, a method for switching a display,
The graphic processing unit includes a first output port to which the primary display is connected, a second output port capable of selectively connecting the secondary display and the external display,
Providing the computer with a status table storing usable information for each display corresponding to the usage status of the secondary display;
Detecting that the usage state of the secondary display has changed;
Referring to the state table in response to the detecting step, obtaining available information corresponding to the changed usage state;
And a step of selecting one of the secondary display and the display terminal based on the acquired usable information and connecting the selected display to the second output port. The availability information further corresponds to an open / closed state of the primary display, and when the primary display is opened and the secondary display is expanded, the primary display and the secondary display are available and the The switching method according to claim 1, comprising data indicating that the external display is unavailable . The availability information further corresponds to the open / closed state of the primary display, and when the primary display is opened and the secondary display is stored, the primary display and the external display are available and the secondary display is available. The switching method according to claim 1 or 2, comprising data indicating that the display is not usable . The availability information further corresponds to an open / closed state of the primary display, and when the primary display is closed and the secondary display is stored, the external display is available and the primary display and the secondary display are available. 4. The switching method according to claim 1 , further comprising data indicating that the display cannot be used .   5. The switching method according to claim 1, further comprising a step of stopping output of image data to the secondary display or the external display in response to the detecting step. 6. The step of configuring the graphic processing unit based on past history information for the selected secondary display or an external display connected to the selected display terminal. switching method according to any one. The system BIOS maintains the state table and obtains the availability information includes the system BIOS notifying the operating system of a display event, and the operating system in response to the display event. Making an enumeration request to a video driver that is compatible with the graphics processing unit; and in response to the enumeration request, the video driver sends availability information of the state table to the system BIOS. switching method according to any one of claims 1 to 6 and a step of querying. Switching method of claim 7 including the step of querying the availability information is queried _DCS method as defined in the ACPI specification. It said step of notifying a display event, switching method according to claim 7 or claim 8 comprising the step of notifying at Notify (VGA, 0x81) command defined in the ACPI specification. A primary display attached to the system casing so that it can be opened and closed, a secondary display that can be stored and deployed according to usage conditions, a display terminal for connecting an external display, and the primary display are connected. A dual display type computer having a dual mode graphic processing unit having a second output port capable of selectively connecting a first output port, the secondary display and the external display. In addition,
A function of holding a status table storing usable information of each display corresponding to the usage status of the secondary display;
A function of detecting that the usage state of the secondary display has changed;
A function of recognizing usable information corresponding to the changed usage state by referring to the state table in response to a change in the usage state of the secondary display;
A computer program for realizing a function of selecting one of the secondary display and the display terminal based on the recognized usable information and connecting to the second output port. A dual display computer,
A dual-mode graphics processing unit having a first output port and a second output port;
A primary display connected to the first output port;
A secondary display that can be stored or deployed according to usage conditions,
A display terminal for connecting an external display;
A changeover switch for connecting either the secondary display or the display terminal to the second output port;
A computer having control means for connecting the secondary display or the display terminal to the second output port by operating the changeover switch in response to the development or storage of the secondary display;   The control means is an open sensor that detects the usage state of the secondary display, a non-volatile memory that holds a state table storing availability information of each display corresponding to the usage state of the secondary display, The computer according to claim 11, further comprising: obtaining means for obtaining usable information corresponding to the changed usage state with reference to a state table.   The computer according to claim 11 or 12, wherein the control means connects the secondary display to the second output port when the secondary display is expanded.   The computer according to claim 11, wherein the second output port outputs DVI (Digital Visual Interface) standard data.   15. The computer according to claim 14, wherein the graphic processing unit includes a third port for outputting DP (DisplayPort) standard data and a fourth port for outputting VGA (Video Graphics Array) standard data. .

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