JP5289593B2 - Expansion unit - Google Patents

Description

  FIELD Embodiments described herein relate generally to an expansion device that expands the functions of an electronic device.

  Portable electronic devices such as notebook personal computers and PDAs (Personal Digital Assistants) have functions to be expanded in order to expand the functions available to users while ensuring the portability of electronic devices. Some devices (expansion devices) can be used. Each of the electronic device and the expansion device is provided with a connection terminal for electrically connecting each other.

  In general, the expansion device and the electronic device are electrically connected by a predetermined number of signal lines via the connection terminals. Signal transmission / reception between the expansion device and the electronic device is performed via the predetermined number of signal lines.

  One of signals transmitted and received between the expansion device and the electronic device is a video signal. Conventionally, in order to reduce the number of signal lines related to video signals, a technique that employs a unique signal transmission method has been proposed. According to this type of technology, the number of signal lines related to video signals can be reduced, and the connection terminal for connecting the expansion device and the electronic device can be reduced in size.

No. 2003-186667

  By the way, there are a plurality of video signal standards that can be used by the user, such as analog RGB, HDMI (High-Definition Multimedia Interface), and DisplayPort (hereinafter referred to as DP). Therefore, recently, electronic devices that can output video signals that comply with these multiple standards, and video that comply with each standard for outputting video signals that conform to each standard received from electronic devices via connection terminals. Expansion devices having multiple output terminals have been developed.

  On the other hand, when using a signal transmission method conforming to the standard, it is difficult to apply a conventional technique using an original signal transmission method. For this reason, when using a signal transmission method compliant with the standard, in order to provide the expansion device with video output terminals compliant with a plurality of standards, the expansion device and the electronic device are connected to the signals compliant with the respective standards via the connection terminals. All lines must be connected. As a result, the number of signal lines related to the video signal increases, resulting in an increase in the size of the connection terminal.

An expansion device according to an embodiment of the present invention is an expansion device that expands the functions of an electronic device in order to solve the above-described problem, and a connection terminal for electrically connecting to the electronic device, and a connection terminal And an input signal line for transmitting a video signal output from the electronic device via the connection terminal. The expansion device is a plurality of video output terminals provided corresponding to each of the first plurality of video signal standard groups , and each video output terminal has an output having a number compliant with the corresponding video signal standard It has a plurality of video output terminals provided with signal lines . Furthermore, when the video signal output from the electronic device is input via the input signal line, the expansion device conforms the video signal to each standard of the first plurality of video signal standard groups. There is provided a signal conversion unit for converting into a video signal and outputting the converted video signal to an output terminal corresponding to each standard of the plurality of video output terminals via output signal lines having a number corresponding to each corresponding standard . The video signal output from the electronic device is a signal that conforms to any one of the second plurality of video signal standard groups . In addition, the input signal line is shared in the transmission of a signal compliant with at least two standards among the second plurality of video signal standard groups output by the electronic device, and the number of input signal lines is a plurality of video signals. Less than the total number of output signal lines at the output terminals .

BRIEF DESCRIPTION OF THE DRAWINGS The whole perspective view which shows the structural example of the notebook PC as an expansion apparatus which concerns on 1st Embodiment of this invention, and an electronic device connected to this expansion apparatus. FIG. 2 is a block diagram schematically showing an internal configuration example of the expansion device and notebook PC shown in FIG. 1. An example of the operation of the signal converter when the RGB socket connection has the highest priority is shown. (A) is a case where the HDMI socket connection realized by the expansion device shown in FIG. 2 has priority over the DP socket connection. Explanatory drawing which shows an example of operation | movement of a signal conversion part, (b) is explanatory drawing which shows an example of operation | movement of a signal conversion part when the connection of DP socket gives priority to the connection of an HDMI socket. The figure which shows the modification of a signal conversion part in case the connection of an HDMI socket is given top priority. An example of the operation of the signal conversion unit when the HDMI socket connection has the highest priority is shown. (A) is a case where the RGB socket connection realized by the expansion device shown in FIG. 4 has priority over the DP socket connection. It is explanatory drawing which shows an example of operation | movement of a signal conversion part, (b) is explanatory drawing which shows an example of operation | movement of a signal conversion part in case the connection of DP socket gives priority to the connection of RGB socket. The block diagram which shows roughly the internal structural example of the expansion apparatus and notebook PC which concern on 2nd Embodiment. The block diagram which shows roughly the internal structural example of the expansion apparatus and notebook PC which concern on 3rd Embodiment. The block diagram which shows schematically the internal structural example of the expansion apparatus and notebook PC which concern on 4th Embodiment. The block diagram which shows roughly the internal structural example of the expansion apparatus and notebook PC which concern on 5th Embodiment. Explanatory drawing which shows an example of operation | movement of the signal conversion part in case the connection of the RGB socket implement | achieved by the expansion apparatus shown in FIG. 9 is given top priority. The block diagram which shows roughly the example of an internal structure of the expansion apparatus which concerns on 6th Embodiment, and the notebook PC which concerns on 6th Embodiment. Explanatory drawing which shows an example of operation | movement of the signal conversion part in case the connection of the RGB socket implement | achieved by the expansion apparatus shown in FIG. 11 is given top priority.

  Embodiments of an expansion device according to the present invention will be described with reference to the accompanying drawings.

  An expansion device according to an embodiment of the present invention is an expansion device that expands the function of an electronic device, has a video output terminal that conforms to a plurality of standards, and is electrically connected to the electronic device via a connection terminal This is to reduce the number of signal lines related to the video signal. The signal lines have a number that conforms to a predetermined video signal standard. In the following description, an example in which a notebook personal computer (hereinafter referred to as a notebook PC) is used as an electronic device connected to the expansion device according to the present invention will be described. The electronic device is not limited to a notebook PC as long as it has a video signal output function and is connected to an expansion device. For example, a PDA (Personal Digital Assistant), a portable game machine, a portable music player, a portable video player A machine may be used.

(1) First Embodiment (1-1) Configuration

  FIG. 1 is an overall perspective view showing an example of the configuration of an expansion device 10 according to the first embodiment of the present invention and a notebook PC 20 as an electronic device connected to the expansion device.

  The expansion device 10 is a device having a function to be expanded in order to expand the functions available to the user while ensuring the portability of the notebook PC 20, and includes a base unit 11 that includes various circuits, the notebook PC 20, and the like. The expansion side connection terminal 12 is provided for electrical connection. As shown in FIG. 1, in this embodiment, the expansion device 10 includes a video output terminal (RGB socket) 13 compliant with the analog RGB standard standardized by VESA (Video Electronics Standards Association), and an HDMI (High-Definition). An example in which the HDMI socket 14 conforming to the (Multimedia Interface) standard and the video output terminal (DP socket) 15 conforming to the DisplayPort standard (DP standard) are described.

  An RGB plug 101 is connected to the RGB socket 13. The RGB socket 13 outputs a video signal conforming to the analog RGB standard via the RGB plug 101 to an external display device 102 (monitor display) compatible with the analog RGB standard connected to the RGB plug 101.

  An HDMI plug 103 is connected to the HDMI socket 14. The HDMI socket 14 outputs a video signal that conforms to the HDMI standard via the HDMI plug 103 to an external display device 104 that supports the HDMI standard and is connected to the HDMI plug 103. A DP plug 105 is connected to the DP socket 15. The DP socket 15 outputs a video signal that conforms to the DP standard via the DP plug 105 to an external display device 106 that is connected to the DP plug 105 and conforms to the DP standard.

  The notebook PC 20 includes a computer main body 21 and a display unit 22 as a display device. The computer main body 21 has a thin box-shaped housing, and a PC side connection terminal 23 that can be electrically connected to the expansion side connection terminal 12 of the expansion device 10 is provided on the bottom surface of the case. For example, one of the expansion side connection terminal 12 and the PC side connection terminal 23 has a shape protruding from one housing of the expansion device 10 and the notebook PC 20 with a predetermined length, and the other is the expansion side connection terminal 12 and It has a concave shape that fits with one of the PC side connection terminals 23.

  A keyboard 24 as an operation unit is provided at the center of the upper surface of the housing of the computer main body 21. A palm rest is formed on the front side of the upper surface of the housing. Near the center of the palm rest, a touch pad 25 and a touch pad button 26 as an operation unit are provided. On the other hand, the display unit 22 has a display panel 27 and is connected to a computer main body 21 via a connecting portion (hinge) 28 that is supported so as to be opened and closed.

  The operation unit (keyboard 24, touch pad 25, touch pad button 26) gives an operation input signal corresponding to a user operation to the main control unit 32 of the notebook PC. The display panel 27 is configured by a general display output device such as a liquid crystal display, an OLED (Organic Light Emitting Diode) display, or a light emitting diode, and displays various types of information according to the control of the main control unit 32.

  FIG. 2 is a block diagram schematically showing an internal configuration example of the expansion device 10 and the notebook PC 20 shown in FIG.

  As shown in FIG. 2, the notebook PC 20 further includes a signal line 30 having a number that conforms to at least a predetermined video signal standard, a GPU 31 (Graphics Processing Unit) having an image processing function, and a main control unit 32. . The GPU 31 is controlled by the main control unit 32 to output a video signal conforming to a predetermined video signal standard to the expansion device 10 via the signal line 30 and the PC side connection terminal 23 to which the signal line 30 is connected. To do. The main control unit 32 is configured by a storage medium such as a CPU, a RAM, and a ROM, and controls the operation of the notebook PC 20 according to a program stored in the storage medium.

  On the other hand, the expansion device 10 further includes a signal line 40 that is connected to the expansion side connection terminal 12 and has a number of lines conforming to a predetermined video signal standard, a DP power control unit 45, and a signal conversion unit 50.

  The signal line 40 is electrically connected to the signal line 30 via the PC-side connection terminal 23 and supplies the video signal output of the GPU 31 to the signal conversion unit 50.

  The signal converter 50 receives a video signal that conforms to a predetermined video signal standard from the GPU 31 via the signal line 30, the PC side connection terminal 23, the expansion side connection terminal 12, and the signal line 40. The signal conversion unit 50 converts the video signal compliant with a predetermined video signal standard input from the GPU 31 via the signal line 40 into a video signal compliant with the video signal standard of each video output terminal of the expansion device 10. And output to each corresponding video output terminal.

  For example, when the expansion device 10 has a video output terminal that conforms to the first standard and the second standard, and the GPU 31 outputs a video signal that conforms to the third standard, the signal conversion unit 50 uses the third standard. When a video signal that conforms to the standard is input, the video signal that conforms to the third standard is converted into a video signal that conforms to the first standard, and is output to a video output terminal that conforms to the first standard. The signal conversion unit 50 converts the input video signal conforming to the third standard into a video signal conforming to the second standard, and outputs the video signal to a video output terminal conforming to the second standard.

  When the standard of the video output terminal and the standard of the video signal of the GPU 31 are the same, the signal conversion unit 50 outputs the input video signal with the same standard. This is equivalent to the signal conversion unit 50 outputting the input video signal as it is to the video output terminal without converting the video signal.

  In the following description, the expansion device 10 has the RGB socket 13, the HDMI socket 14, and the DP socket 15, and the GPU 31 conforms to the physical layer and logical layer standards of the DP standard via the signal lines 30 and 40 compliant with the DP standard. An example in the case of outputting a video signal compliant with the DP standard (video signal compliant with the DP standard) or a logical layer of the HDMI standard will be described.

  In this case, the signal lines 30 and 40 have at least the number according to the DP standard. Here, the number of signal lines 30 and 40 compliant with the DP standard is equivalent to 10 signal lines for differential signal transmission (two of which are for DVE (VESA Display Data Channel) signal transmission such as HDMI standard). 11 signal lines (sidebands)) and one signal line for hot plug signal transmission.

  In the present embodiment, an example in which the signal lines 30 and 40 further include two signal lines for power control for the GPU 31 to give an instruction to the DP power control unit 45 will be described. For this reason, the signal lines 30 and 40 are 13 in total.

  Note that the number of lines conforming to the analog RGB standard is a total of seven lines: three signal lines for transmission of RGB signals, two Sync signal lines, and two DDC signal lines. The number of lines conforming to the HDMI standard is a total of 11 lines: 8 signal lines for differential signal transmission, 2 signal lines for DDC, and 1 signal line for hot plug signal transmission.

  The DP power control unit 45 is controlled by the GPU 31 through two signal lines for power control, and controls power supply to the DP socket 15.

  The signal conversion unit 50 includes a DP to analog RGB conversion IC (Integrated Circuit) (hereinafter referred to as RGB conversion unit) 51, an HDMI bias circuit (hereinafter referred to as HDMI conversion unit) 52, and a DP conversion unit 53. A signal line conforming to the same video standard as the signal lines 30 and 40 is connected to the video signal input side (GPU 31 side) of each of the conversion units 51 to 53. In addition, signal lines compliant with the video signal standards of the sockets 13 to 15 are connected to the video signal output side (the sockets 13 to 15 side) of the conversion units 51 to 53.

  The RGB conversion unit (DP to analog RGB conversion IC) 51 converts the video signal conforming to the DP standard output from the GPU 31 into a video signal conforming to the analog RGB standard and outputs the video signal to the RGB socket 13.

  The RGB converter 51 monitors the potential output from the RGB socket 13. The RGB socket 13 outputs a high level potential and a low level potential when the RGB plug 101 is connected and when the RGB plug 101 is not connected. The RGB conversion unit 51 uses the potential output from the RGB socket 13 as a connection recognition signal, the hot plug signal (HPL_HDMI signal) output from the HDMI socket 14 and the hot plug signal (HPL_DP signal) output from the DP socket 15. An equivalent signal (HPL_RGB signal) is generated and output to the signal line on the GPU 31 side.

  In other words, the RGB socket 13 is configured to output a connection recognition signal to the signal conversion unit 50 when the RGB plug 101 is connected. Also, the HDMI socket 14 and the DP socket 15 output a hot plug signal (connection recognition signal) to the signal conversion unit 50 when the HDMI plug 103 and the DP plug 105 are connected thereto. In FIG. 2, signal lines for transmitting connection recognition signals are shown by dotted lines for the sake of explanation.

  The HDMI conversion unit (HDMI bias circuit) 52 adjusts the bias voltage (physical layer information) of the video signal compliant with the HDMI standard logical layer output from the GPU 31 to adjust to the physical layer standard of the HDMI standard. The signal is converted into a compliant signal and output to the HDMI socket 14. As a result, the signal output from the HDMI conversion unit 52 is a video signal compliant with the physical layer and logical layer standards of the HDMI standard.

  Further, the HDMI conversion unit 52 receives the hot plug signal (HPL_HDMI signal) output from the HDMI socket 14 and outputs it directly to the signal line on the GPU 31 side.

  The DP converter 53 is a member for outputting the video signal compliant with the DP standard output from the GPU 31 to the DP socket 15 as it is, and is configured by a simple wiring (signal line) compliant with the DP standard.

  Further, the DP converter 53 receives the hot plug signal (HPL_DP signal) output from the DP socket 15 and outputs it directly to the signal line on the GPU 31 side.

  Note that the connection recognition signal given to the signal converter 50 is given to the GPU 31 via the signal line 40, the expansion side connection terminal 12, the PC side connection terminal 23, and the signal line 30.

  In the present embodiment, an example in which the signal conversion unit 50 alternatively outputs a video signal to each of the sockets 13 to 15 will be described. In this case, the signal conversion unit 50 includes a switching unit 55.

  The switching unit 55 includes a first multiplexer (first MUX) 56 and a second multiplexer (second MUX) 57.

  The first MUX 56 gives the video signal received from the GPU 31 to one of the RGB conversion unit 51 and the second MUX 57. The first MUX 56 is supplied with the HPL_RGB signal converted and output by the RGB converter 51 based on the connection recognition signal output from the RGB socket 13 as a switching control signal.

  The HPL_RGB signal input as the switching control signal to the first MUX 56 is, for example, one signal line for hot plug signal transmission included in the signal line connecting the RGB converter 51 and the output terminal of the first MUX 56. Is provided as a switching control signal to the first MUX 56 via a new one that can be obtained by branching into two.

  In FIG. 2, if the HPL_RGB signal is at a high level (see “1” in the first MUX 56 in FIG. 2), the first MUX 56 connects the signal line 40 and the RGB converter 51, and the HPL_RGB signal In the case of the low level (see “0” in the first MUX 56 in FIG. 2), an example in which the signal line 40 and the second MUX 57 are connected is shown. In the following description, the case where the connection recognition signal is at the high level is “1”, and the case where the connection recognition signal is at the low level is “0”.

  The second MUX 57 gives the video signal received from the first MUX 56 to one of the HDMI conversion unit 52 and the DP conversion unit 53. A connection recognition signal (HPL_HDMI signal) output from the HDMI socket 14 is given to the second MUX 57 as a switching control signal via the HDMI conversion unit 52.

  The HPL_HDMI signal input to the second MUX 57 as a switching control signal is also one signal for hot plug signal transmission included in a signal line connecting the HDMI conversion unit 52 and the output terminal of the second MUX 57, for example. A switching control signal is given to the second MUX 57 through a new line that can be obtained by branching the line into two.

  In FIG. 2, the second MUX 57 connects the first MUX 56 and the HDMI conversion unit 52 if the HPL_HDMI signal is high level “1”, and the first MUX 56 if the HPL_RGB signal is “0”. An example in which the DP converter 53 is connected has been shown.

(1-2) Operation when the connection of the RGB socket 13 is given the highest priority FIG. 3 shows an example of the operation of the signal conversion unit 50 when the connection of the RGB socket 13 is given the highest priority. 2 is an explanatory diagram showing an example of the operation of the signal conversion unit 50 when the connection of the HDMI socket 14 realized by the expansion device 10 shown in FIG. 2 has priority over the connection of the DP socket 15, and FIG. FIG. 10 is an explanatory diagram illustrating an example of the operation of the signal conversion unit 50 when the connection has priority over the connection of the HDMI socket 14.

(1-2-1) When the connection of the HDMI socket 14 has priority over the connection of the DP socket 15 As shown in FIG. 2 and FIG. 3A, in the configuration shown in FIG. In addition, the connection of the HDMI socket 14 is prioritized over the connection of the DP socket 15. Specifically, when the RGB plug 101 is connected to the RGB socket 13 and the HPL_RGB signal is input to the first MUX 56 (the HPL_RGB signal is high level “1”), the video signal received from the GPU 31 Regardless of the connection status of the sockets 14 and 15, the RGB signal is supplied to the RGB conversion unit 51, converted into a video signal conforming to the analog RGB standard, and output to the RGB socket 13.

  Also, the RGB plug 101 is not connected to the RGB socket 13 and HPL_RGB is not input to the first MUX 56 (the HPL_RGB signal is low level “0”), and the HDMI plug 103 is connected to the HDMI socket 14 and the second MUX 57 When HPL_HDMI is input to (HPL_HDMI is at a high level “1”), the video signal received from the GPU 31 is supplied to the HDMI conversion unit 52 regardless of the connection status of the DP socket 15 and is compliant with the HDMI standard. It is converted into a signal and output to the HDMI socket 14.

  For example, consider the case where the RGB plug 101 is connected to the RGB socket 13. In this case, since the HPL_RGB signal is “1”, the first MUX 56 connects the signal line 40 and the RGB conversion unit 51 regardless of the connection status of the other sockets 14 and 15. As a result, the signal line 40 and the RGB socket 13 are electrically connected, while the connection between the signal line 40 and the other sockets 14 and 15 is released.

  For this reason, the RGB socket 13 is electrically connected to the GPU 31 of the notebook PC 20 via the RGB converter 51 and the first MUX 56. Therefore, the HPL_RGB signal generated by the RGB conversion unit 51 based on the connection recognition signal output from the RGB socket 13 is given to the GPU 31.

  When the GPU 31 receives the HPL_RGB signal, the external display device 102 connected to the RGB socket 13 corresponds to the RGB standard from the external display device 102 via the DDC signal line, for example, using data in the EDID (Extended Display Identification Data) format. The information indicating that the display device has been received is received. Then, the GPU 31 outputs a video signal conforming to the DP standard via the signal line 30 conforming to the DP standard. This video signal is given to the RGB converter 51 and converted into a video signal conforming to the analog RGB standard, and output to the RGB compatible external display device 102 via the RGB socket 13 and the RGB plug 101.

  Further, for example, consider a case where the HDMI plug 103 is connected only to the HDMI socket 14 of the sockets 13 to 15 and nothing is connected to the other sockets 13 and 15. In this case, the HPL_RGB signal is “0” and the HPL_HDMI signal is “1”. Therefore, the first MUX 56 connects the signal line 40 and the second MUX 57, and the second MUX 57 connects the first MUX 56 and the HDMI conversion unit 52.

  Therefore, the HDMI socket 14 is electrically connected to the GPU 31 of the notebook PC 20 via the HDMI conversion unit 52, the second MUX 57, and the first MUX 56. Therefore, the HPL_HDMI signal output from the HDMI socket 14 is given to the GPU 31. When the GPU 31 receives the HPL_HDMI signal, the external display device 104 connected to the HDMI socket 14 corresponds to the HDMI standard from the external display device 104 via the DDC signal line, for example, using data in the EDID (Extended Display Identification Data) format. The information indicating that the display device has been received is received.

  Then, the GPU 31 outputs a video signal compliant with the logical layer of the HDMI standard via the signal line 30 compliant with the DP standard. This video signal is applied to the HDMI conversion unit 52 to adjust the bias voltage (physical layer information) to be converted into a video signal conforming to the physical layer standard of the HDMI standard, and the HDMI socket 14 and the HDMI plug 103. To the HDMI compatible external display device 104.

  Further, for example, consider a case in which the DP plug 105 is connected only to the DP socket 15 among the sockets 13 to 15 and nothing is connected to the other sockets 13 and 14. In this case, the HPL_RGB signal is “0” and the HPL_HDMI signal is “0”. Therefore, the first MUX 56 connects the signal line 40 and the second MUX 57, and the second MUX 57 connects the first MUX 56 and the DP converter 53.

  For this reason, the DP socket 15 is electrically connected to the GPU 31 of the notebook PC 20 via the DP converter 53, the second MUX 57, and the first MUX 56. Therefore, the HPL_DP signal output from the DP socket 15 is given to the GPU 31. When the GPU 31 receives the HPL_DP signal, the external display device 106 connected to the DP socket 15 corresponds to the DP standard from the external display device 106 via the DDC signal line, for example, using data in the EDID (Extended Display Identification Data) format. The information indicating that the display device has been received is received.

  Then, the GPU 31 outputs a video signal conforming to the DP standard via the signal line 30 conforming to the DP standard. This video signal is supplied to the DP converter 53 and is supplied to the DP socket 15 as it is, and is output to the DP-compatible external display device 106 via the DP socket 15 and the DP plug 105.

(1-2-2) When the connection of the DP socket 15 has priority over the connection of the HDMI socket 14 As shown in FIG. 3B, the switching control signal is inputted to the second MUX 57 in the configuration shown in FIG. When the signal is replaced by the HPL_HDMI signal instead of the HPL_HDMI signal, the connection of the RGB socket 13 is given the highest priority, and the connection of the DP socket 15 is given priority over the connection of the HDMI socket 14.

  When the signal conversion unit 50 selectively outputs a video signal to each of the sockets 13 to 15, the connection priority of the sockets 13 to 15 is determined by the switching unit 55 and the conversion units 51 to 53. An arbitrary priority order can be set by a connection method and a switching control signal for the switching unit 55.

(1-3) Operation in the case where the connection of the HDMI socket 14 is given the highest priority Subsequently, in order to explain that the priority can be arbitrarily set, as another example of the priority, the connection of the HDMI socket 14 An example in which is given the highest priority will be briefly described.

  FIG. 4 is a diagram illustrating a modification of the signal conversion unit 50 when the connection of the HDMI socket 14 is given the highest priority. 5 shows an example of the operation of the signal conversion unit 50 when the connection of the HDMI socket 14 is given the highest priority. FIG. 5A shows the connection of the RGB socket 13 realized by the expansion device 10 shown in FIG. It is explanatory drawing which shows an example of operation | movement of the signal conversion part 50 when giving priority to the connection of DP socket 15, (b) of the signal conversion part 50 in case the connection of DP socket 15 has priority over the connection of RGB socket 13. It is explanatory drawing which shows an example of operation | movement.

(1-3-1) When the connection of the RGB socket 13 has priority over the connection of the DP socket 15 As shown in FIGS. 4 and 5A, in the configuration shown in FIG. 4, the connection of the HDMI socket 14 has the highest priority. In addition, the connection of the RGB socket 13 is prioritized over the connection of the DP socket 15. Specifically, when the HDMI plug 103 is connected to the HDMI socket 14 and the HPL_HDMI signal is input to the first MUX 56, the video signal received from the GPU 31 is not related to the connection status of the other sockets 13 and 15. The signal is supplied to the conversion unit 52 and converted into a video signal conforming to the HDMI standard and output to the HDMI socket 14.

(1-3-2) When the connection of the DP socket 15 has priority over the connection of the RGB socket 13 As shown in FIG. 5B, in the configuration shown in FIG. 4, the second MUX 57 is input as a switching control signal. When the signal is replaced with an HPL_RGB signal instead of an HPL_RGB signal, the connection of the HDMI socket 14 has the highest priority, and the connection of the DP socket 15 has priority over the connection of the RGB socket 13.

  In this way, any other priority order such as a setting in which the connection of the DP socket 15 is given the highest priority can be easily set.

  The expansion device 10 according to the present embodiment has three video output terminals (sockets) 13 to 15 compliant with different video standards (analog RGB standard, HDMI standard and DP standard). Alternatively, a video signal is output. At this time, the expansion device 10 receives a video signal from the notebook PC 20 via the signal lines 30 and 40 having the number in accordance with a predetermined video standard (DP standard).

  For this reason, according to the expansion device 10 according to the present embodiment, it is possible to output video signals compliant with a plurality of video standards while reducing the number of pins of the expansion side connection terminal 12. Therefore, since the expansion side connection terminal 12 can be reduced in size and the connection terminal 23 of the notebook PC 20 can also be reduced in size, according to the expansion device 10, the electronic device connected to the expansion device 10 can be reduced in size.

  Further, according to the expansion device 10 according to the present embodiment, the video output terminals are automatically and alternatively selected according to the connection status of the video output terminals based on the preset priority order. A video signal compliant with the video standard of each terminal can be output.

  Further, the expansion device 10 according to the present embodiment uses a DPto analog RGB conversion IC as the RGB conversion unit 51. Therefore, even if the electronic device connected to the expansion device 10 does not have a function of outputting a video signal compliant with the analog RGB standard, if the electronic device can output a video signal compliant with the DP standard, this DP A signal compliant with the standard can be converted into a signal compliant with the analog RGB standard. Therefore, for example, when the user has an electronic device that cannot output a video signal compliant with the analog RGB standard and the analog RGB compatible external display device 102, the expansion device 10 uses the electronic device and the analog RGB compatible external display device. Therefore, both can be used effectively without wasting them.

  When the GPU 31 outputs a video signal compliant with the analog RGB standard (or HDMI standard) and the signal line 30 and the signal line 40 are signal lines compliant with the analog RGB standard (or HDMI standard), the signal conversion unit 50 Each of the conversion units 51 to 53 may be configured to convert the input video signal into a video standard corresponding to the output destination sockets 13 to 15.

  Further, the switching unit 55 is not provided, and the video signal output from the GPU 31 may be equally applied to all the conversion units 51 to 53. In this case, the video signal output from the GPU 31 is converted by the converters 51 to 53 and output to the sockets 13 to 15, respectively. Since the video signal is a signal having a high frequency, the quality of the high-frequency signal is preferably ensured when the switching unit 55 is not provided. In order to ensure the quality of the high frequency signal, for example, it is preferable to take measures to minimize the total extension of the signal lines drawn inside the expansion device 10 and prevent interference with other signal lines.

(2) Second Embodiment FIG. 6 is a block diagram schematically illustrating an internal configuration example of the expansion device 10A and the notebook PC 20 according to the second embodiment.

  The expansion device 10A according to the second embodiment is different from the expansion device 10 according to the first embodiment in that the DP socket 15, the DP power control unit 45, the DP conversion unit 53, and the second MUX 57 are not provided. Since other configurations and operations are not substantially different from those of the expansion device 10 shown in FIG. 1, the same components are denoted by the same reference numerals and description thereof is omitted.

  As shown in FIG. 6, when the RGB conversion unit 51 is connected to the output terminal on the “1” side of the first MUX 56 and the HPL_RGB signal is input as the switching control signal of the first MUX 56, the RGB socket 13 is connected. Has priority over the connection of the HDMI socket 14. When the HDMI conversion unit 52 is connected to the “1” side output terminal of the first MUX 56 and the HPL_HDMI signal is input as the switching control signal of the first MUX 56, the connection of the HDMI socket 14 is connected to the RGB socket 13. Overrides connection.

  Note that the expansion device 10 </ b> A according to the present embodiment does not include the DP socket 15. For this reason, the DP power control unit 45 for controlling the power supply to the DP socket 15 becomes unnecessary. For this reason, two signal lines for power supply control are unnecessary among the 13 signal lines 30 and 40 of the expansion device 10 according to the first embodiment.

  According to the expansion device 10A according to the present embodiment, it is possible to output video signals conforming to a plurality of video standards while reducing the number of pins of the expansion side connection terminal 12. In addition, based on the priorities set in advance, video signals that comply with the video standards of each terminal are automatically output to each video output terminal automatically according to the connection status of multiple video output terminals. can do. For example, when the user owns an electronic device that cannot output a video signal compliant with the analog RGB standard and the analog RGB compatible external display device 102, the expansion device 10 </ b> A uses this electronic device and the analog RGB compatible external display device. Therefore, both can be used effectively without wasting them.

(3) Third Embodiment FIG. 7 is a block diagram schematically illustrating an internal configuration example of an expansion device 10B and a notebook PC 20 according to a third embodiment.

  The expansion device 10B according to the third embodiment is different from the expansion device 10 according to the first embodiment in that the HDMI socket 14, the HDMI conversion unit 52, and the second MUX 57 are not provided. Since other configurations and operations are not substantially different from those of the expansion device 10 shown in FIG. 1, the same components are denoted by the same reference numerals and description thereof is omitted.

  As shown in FIG. 7, when the RGB conversion unit 51 is connected to the output terminal on the “1” side of the first MUX 56 and the HPL_RGB signal is input as the switching control signal of the first MUX 56, the RGB socket 13 is connected. Has priority over the connection of the DP socket 15. When the DP converter 53 is connected to the “1” side output terminal of the first MUX 56 and the HPL_DP signal is input as the switching control signal of the first MUX 56, the connection of the DP socket 15 is connected to the RGB socket 13. Overrides connection.

  According to the expansion device 10B according to the present embodiment, it is possible to output video signals conforming to a plurality of video standards while reducing the number of pins of the expansion side connection terminal 12. In addition, based on the priorities set in advance, video signals that comply with the video standards of each terminal are automatically output to each video output terminal automatically according to the connection status of multiple video output terminals. can do. For example, when the user owns an electronic device that cannot output a video signal compliant with the analog RGB standard and the analog RGB compatible external display device 102, the expansion device 10 </ b> B uses this electronic device and the analog RGB compatible external display device. Therefore, both can be used effectively without wasting them.

(4) Fourth Embodiment FIG. 8 is a block diagram schematically showing an internal configuration example of an expansion device 10C and a notebook PC 20 according to a fourth embodiment.

  The expansion device 10C according to the fourth embodiment is different from the expansion device 10 according to the first embodiment in that the RGB socket 13, the RGB conversion unit 51, and the second MUX 57 are not provided. Since other configurations and operations are not substantially different from those of the expansion device 10 shown in FIG. 1, the same components are denoted by the same reference numerals and description thereof is omitted.

  As shown in FIG. 8, when the HDMI conversion unit 51 is connected to the “1” side output terminal of the first MUX 56 and the HPL_HDMI signal is input as the switching control signal of the first MUX 56, the connection of the HDMI socket 14 is performed. Has priority over the connection of the DP socket 15. When the DP converter 53 is connected to the “1” side output terminal of the first MUX 56 and the HPL_DP signal is input as the switching control signal of the first MUX 56, the connection of the DP socket 15 is connected to the HDMI socket 14. Overrides connection.

  According to the expansion device 10 </ b> C according to the present embodiment, it is possible to output video signals compliant with a plurality of video standards while reducing the number of pins of the expansion side connection terminal 12. In addition, based on the priorities set in advance, video signals that comply with the video standards of each terminal are automatically output to each video output terminal automatically according to the connection status of multiple video output terminals. can do.

  In addition, in the expansion devices 10A to 10C according to the second to fourth embodiments, similarly to the expansion device 10 according to the first embodiment, the conversion unit converts the video signal output from the GPU 31 without providing the switching unit 55. May be given equally to all of the above.

(5) Fifth Embodiment FIG. 9 is a block diagram schematically showing an internal configuration example of an expansion device 10D and a notebook PC 20 according to a fifth embodiment.

  The expansion device 10D according to the fifth embodiment has a second switch for outputting a switching control signal to the first switch 61 and the second MUX 57 for outputting a switching control signal to the first MUX 56. It differs from the expansion device 10 shown in the first embodiment in that a switch 62 is provided. Since other configurations and operations are not substantially different from those of the expansion device 10 shown in FIG. 1, the same components are denoted by the same reference numerals and description thereof is omitted.

  The first switch 61 is operated by the user and outputs a switching control signal to the first MUX 56. Further, the second switch 62 is operated by the user and outputs a switching control signal to the second MUX 57.

  FIG. 10 is an explanatory diagram illustrating an example of the operation of the signal conversion unit 50 when the connection of the RGB socket 13 realized by the expansion device 10D illustrated in FIG. 9 is given the highest priority.

  As shown in FIG. 9, when one of the output terminals of the first MUX 56 is connected to the RGB converter 51, if the output signal of the first switch 61 is at a high level, the output of the second switch 62 is output. Regardless, the video signal received from the GPU 31 is supplied to the RGB conversion unit 51, converted into a video signal conforming to the analog RGB standard, and output to the RGB socket 13.

  Therefore, in the configuration example shown in FIG. 9, the first switch 61 functions as a switch for accepting selection as to whether or not to output to the RGB socket 13 (see FIG. 10). Therefore, for example, the output signal of the first switch 61 may be a signal corresponding to the HPL_RGB signal.

  In the configuration example shown in FIG. 9, the second switch 62 selects which of the HDMI socket 14 and the DP socket 15 outputs when the first switch 61 outputs a low level. It functions as a switch for performing. When the first switch 61 outputs a low level, it can be said that both the HDMI socket 14 and the DP socket 15 are treated equally.

  Of course, the second switch 62 may be used as a switch for accepting selection of whether to output to the HDMI socket 14 when the first switch 61 outputs a low level. The output signal of the second switch 62 may be a signal corresponding to the HPL_HDMI signal.

  According to the expansion device 10D according to the present embodiment, it is possible to output video signals conforming to a plurality of video standards while reducing the number of pins of the expansion side connection terminal 12. In addition, based on the priority order set in advance, the user operates the switches 61 and 62 provided in the expansion device 10D, and the video that conforms to the video standard of each terminal alternatively to each video output terminal. A signal can be output. For example, when the user owns an electronic device that cannot output a video signal compliant with the analog RGB standard and the analog RGB compatible external display device 102, the expansion device 10 </ b> D uses this electronic device and the analog RGB compatible external display device. Therefore, both can be used effectively without wasting them.

  Similar to the expansion device 10 according to the first embodiment, the expansion device 10D according to the present embodiment can also easily set other arbitrary priorities such as a setting in which the connection of the HDMI socket 14 is given the highest priority. Yes (see, for example, FIG. 4). Similarly to the expansion devices 10A-10C according to the second to fourth embodiments, when there are two video output terminals, one multiplexer may be required, and therefore one switch may be required.

  Also in the expansion device 10D according to the present embodiment, the video signal output by the GPU 31 without providing the switching unit 55 is equivalent to all the conversion units 51 to 53, as in the expansion device 10 according to the first embodiment. You may give to.

(6) Sixth Embodiment FIG. 11 is a block diagram schematically illustrating an internal configuration example of an expansion device 10E according to a sixth embodiment and a notebook PC 20E according to the sixth embodiment.

  The expansion device 10E according to the sixth embodiment includes a first signal line 41, which is one signal line for giving a switching control signal from the notebook PC to the first MUX 56, and a second MUX 57 from the notebook PC. In the first embodiment, the second signal line 42, which is a single signal line for giving a switching control signal to the signal, and the switching control signal for the first MUX 56 and the second MUX 57 are given from the notebook PC 20E. Different from the expansion device 10 shown in FIG. Since other configurations and operations are not substantially different from those of the expansion device 10 shown in FIG. 1, the same components are denoted by the same reference numerals and description thereof is omitted.

  The notebook PC 20E further includes a PCH (Platform Controller Hub) 33, a first GPIO (General Purpose Input / Output) 34, and a second GPIO 35.

  The main control unit 32 causes the display panel 27 to display a selection request image for allowing the user to selectively select one of the output destination sockets 13 to 15. The main control unit 32 receives instruction information input by the user via the operation unit based on the selection request image.

  The PCH 33 is a chip in which I / O controller functions of various devices are integrated. The main control unit 32 outputs a switching control signal to the first MUX 56 via the first GPIO 34 via the PCH 33 in accordance with the instruction information input by the user, and the second GPIO 35 via the PCH 33. A switching control signal is output to the second MUX 57 via the.

  FIG. 12 is an explanatory diagram showing an example of the operation of the signal conversion unit 50 when the connection of the RGB socket 13 realized by the expansion device 10E shown in FIG.

  As shown in FIG. 11, when one of the output terminals of the first MUX 56 is connected to the RGB conversion unit 51, if the output signal of the first GPIO 34 is at a high level, it does not depend on the output of the second GPIO 35. The video signal received from the GPU 31 is supplied to the RGB conversion unit 51, converted into a video signal conforming to the analog RGB standard, and output to the RGB socket 13.

  Therefore, in the configuration example shown in FIG. 11, the first GPIO 34 outputs a signal for instructing whether or not to output to the RGB socket 13 (see FIG. 12). Therefore, for example, the output signal of the first GPIO may be a signal corresponding to the HPL_RGB signal.

  In the configuration example shown in FIG. 11, the second GPIO 35 instructs which of the HDMI socket 14 and the DP socket 15 to output when the first GPIO 34 outputs a low level. The signal is output. When the first GPIO 34 outputs a low level, it can be said that both the HDMI socket 14 and the DP socket 15 are treated equally.

  Of course, it can be considered that the second GPIO 35 outputs a signal for instructing whether or not to output to the HDMI socket 14 when the first GPIO 34 outputs a low level. The output signal may be a signal corresponding to the HPL_HDMI signal.

  According to the expansion device 10E according to the present embodiment, it is possible to output video signals conforming to a plurality of video standards while reducing the number of pins of the expansion side connection terminal 12. In addition, a video signal that conforms to the video standard of each terminal can be output to a video output terminal that is alternatively selected by the user via the operation unit of the notebook PC 20E. For example, when the user owns an electronic device that cannot output a video signal compliant with the analog RGB standard and the analog RGB-compatible external display device 102, the expansion device 10E enables the electronic device and the analog RGB-compatible external display device. Therefore, both can be used effectively without wasting them.

  Similar to the expansion device 10 according to the first embodiment, the expansion device 10E according to the present embodiment can also easily set other arbitrary priorities such as a setting in which the connection of the HDMI socket 14 is given the highest priority. Yes (see, for example, FIG. 4). Similarly to the expansion devices 10A to 10C according to the second to fourth embodiments, when there are two video output terminals, one multiplexer may be used, and therefore one GPIO may be used.

  Also in the expansion device 10E according to the present embodiment, the video signal output from the GPU 31 without providing the switching unit 55 is equivalent to all the conversion units 51 to 53, similarly to the expansion device 10 according to the first embodiment. You may give to.

  In addition, although some embodiment of this invention was described, these embodiment is shown as an example and is not intending limiting the range of invention. These novel embodiments can be implemented in various other forms, and various omissions, replacements, and changes can be made without departing from the scope of the invention. These embodiments and modifications thereof are included in the scope and gist of the invention, and are included in the invention described in the claims and the equivalents thereof.

  For example, when the expansion device 10 according to the first embodiment and the expansion device 10E according to the sixth embodiment are combined, the settings input by the user via the operation unit of the notebook PC 20E and the connection status of the sockets 13 to 15 In addition, the final output destination socket can be determined.

  In this case, for example, the first register in advance which signal in response to the output of the first GPIO34 output signal and HPL_RGB signal is determined whether the priority provided, the first MUX56 in response to the register value and it determines whether to whether the low level to the switching control signal to the high level, the second register in advance which signal in response to the output of the second GPIO35 output signal and HPL_HDMI signal is determined whether priority is given The switching control signal of the second MUX 57 may be determined to be high level or low level according to the register value.

10, 10A, 10B, 10C, 10D, 10E Expansion device 11 Base unit 12 Expansion side connection terminal 13 RGB socket 14 HDMI socket 15 DP socket 20 Notebook PC
21 Computer main body 22 Display unit 23 PC side connection terminal 24 Keyboard 25 Touch pad 26 Touch pad button 27 Display panel 28 Connection part 30, 40 Signal line 31 GPU
32 Main control unit 33 PCH
34 First GPIO
35 Second GPIO
41 First signal line 42 Second signal line 45 DP power control unit 50 Signal conversion unit 51 RGB conversion unit (DP to analog RGB conversion IC)
52 HDMI converter (HDMI bias circuit)
53 DP converter (signal line)
55 switching unit 56 first MUX
57 Second MUX
61 1st switch 62 2nd switch 101 RGB plug 102 Analog RGB compatible external display device 103 HDMI plug 104 HDMI compatible external display device 105 DP plug 106 DP compatible external display device

Claims (9)

An expansion device that expands the functions of an electronic device,
A connection terminal for electrically connecting to the electronic device;
An input signal line connected to the connection terminal and transmitting a video signal output from the electronic device via the connection terminal;
A plurality of video output terminals provided corresponding to each of the first plurality of video signal standard groups , each video output terminal having a plurality of output signal lines having a number in accordance with the corresponding video signal standard Video output terminal,
When the video signal output by the electronic device is input via the input signal line, the video signal is converted into a video signal conforming to the respective standards of the first plurality of video signal standard groups, A signal converter for outputting the converted video signal to an output terminal corresponding to each standard of the plurality of video output terminals via an output signal line having a number compliant with each corresponding standard ;
With
The video signal output by the electronic device is a signal that conforms to any one of the second plurality of video signal standard groups ,
The input signal line is shared in transmission of a signal conforming to at least two or more of the second plurality of video signal standard groups output by the electronic device;
The number of the input signal lines is smaller than the total number of output signal lines of the plurality of video output terminals . The first plurality of video signal standard groups include at least a first standard and a second standard,
The plurality of video output terminals include at least a first video output terminal compliant with the first standard and a second video output terminal compliant with a second standard,
The signal converter is
The video signal output from the electronic device is converted into a video signal conforming to the first standard, and the first video is transmitted via a first output signal line having a number conforming to the first standard. A first converter that outputs to an output terminal;
The video signal output from the electronic device is converted into a video signal that conforms to the second standard, and the second video is transmitted via a second output signal line having a number that conforms to the second standard. A second converter that outputs to the output terminal;
A switching unit that switches electrical connection between the input signal line and one of the first conversion unit and the second conversion unit;
Have,
Before Symbol switching unit,
When a first connection recognition signal compliant with the first standard is input from the first video output terminal, the input signal line and the first conversion unit are connected, and the first connection recognition signal If the input signal is not input, the input signal line and the second conversion unit are connected.
The expansion device according to claim 1. The first plurality of video signal standard groups further includes a third standard,
It said plurality of video output terminals further includes a third video output terminal that conforms to the third standard,
The signal converter is
The video signal output from the electronic device is converted into a video signal conforming to the third standard, and the third video is transmitted via a third output signal line having a number conforming to the third standard. A third converter that outputs to the output terminal;
Further comprising a,
Before Symbol switching unit,
When the first connection recognition signal is input, the input signal line and the first conversion unit are connected, and a second connection recognition signal that conforms to the second standard from the second video output terminal. Is connected, the input signal line and the second conversion unit are connected, otherwise the input signal line and the third conversion unit are connected,
The expansion device according to claim 2 . The second plurality of video signal standard groups include at least the second standard and the third standard,
The input signal line has a number which conforms to one of the standard prior Symbol second standard and the third standard,
The expansion device according to claim 3 . The first standard, the second standard, and the third standard are different from each other, and are selected from the group consisting of an analog RGB standard, an HDMI (High-Definition Multimedia Interface) standard, and a DisplayPort standard. Is,
The expansion device according to claim 4 . The first standard is an analog RGB standard;
The second standard is an HDMI (High-Definition Multimedia Interface) standard,
The third standard is the DisplayPort standard,
The input signal line is
Having a number that conforms to the DisplayPort standard;
The expansion device according to claim 5 . The first connection recognition signal and the second connection recognition signal are:
While being input to the switching unit of the signal conversion unit, it is given to the electronic device via the signal conversion unit and the connection terminal,
When the first connection recognition signal is given to the electronic device and when neither the first connection recognition signal nor the second connection recognition signal is given to the electronic device, the electronic device while outputting a video signal conforming to the DisplayPort standard logical layer standards as the second plurality of one the standard of the video standards group, if the previous SL second connection recognition signal is supplied to the electronic device The electronic device outputs a video signal that conforms to the logical layer standard of the HDMI (High-Definition Multimedia Interface) standard as one standard of the second plurality of video standard groups ,
The first conversion unit includes:
The video signal output by the electronic device is converted to the analog RGB standard and output to the first video output terminal,
The second converter is
The video signal output from the electronic device is converted into a signal conforming to the physical layer standard of the HDMI (High-Definition Multimedia Interface) standard by adjusting a bias voltage of the video signal output from the electronic device. And output to the second video output terminal,
The third converter is
The video signal output by the electronic device is directly output to the third video output terminal without being converted.
The expansion device according to claim 6 . The connection terminal is
One signal line for transmitting a first switching control signal from the electronic device to the switching unit and one for transmitting a second switching control signal from the electronic device to the switching unit The signal line is further connected,
The switching unit is
When the first switching control signal is input from the electronic device, the input signal line and the first conversion unit are connected, and when the second connection recognition signal is input from the electronic device, the input Connecting the signal line and the second converter,
The electronic device controls output of the first switching control signal and the second switching control signal through the connection terminal according to a user setting.
The expansion device according to any one of claims 3 to 7 . A first switch that is operated by a user to output the first connection recognition signal to the switching unit;
A second switch that is operated by a user to output the second connection recognition signal to the switching unit;
The expansion device according to any one of claims 3 to 8 , further comprising:

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