JP2017045097A - Connection apparatus, information system, and connection method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To make it possible to connect to a target connection destination by combining plural input/output devices in any form without going through a dedicated interface for each input/output device, and switching the combined input/output devices in a batch.SOLUTION: A connection apparatus comprises: a computer registration unit which searches for a connectable computer and registers the connectable computer as one of plural connection target computers; a device search unit which searches for a connectable input/output device and registers the connectable input/output device as one of plural connection target input/output devices; and a connection unit which, when a first condition is satisfied, selects a computer meeting the first condition from the plural connection target computers and then connects the plural connection target input/output devices to the selected computer in a batch.SELECTED DRAWING: Figure 7

Description

  The present invention relates to a connection device, an information system, and a connection method.

A switching device called a Keyboard, Video, Mouse (KVM) switch that switches between a set of keyboard, mouse, and display for multiple computers is used. FIG. 1 shows an example of a KVM switch. The KVM switch 501 in FIG. 1 connects the keyboard 531, the display 532, and the mouse 533 by switching to any one of the computers 521, 522, and 523. The KVM switch 501 is connected to the computers 521, 522, and 523 through dedicated wiring for each user interface (UI) device such as a keyboard 531, a display 532, and a mouse 533. That is, in the connection example of FIG. 1, three dedicated lines corresponding to the three UI devices are connected to the computers 521, 522, and 523, respectively. The KVM switch 501 uses a combination of dedicated wirings to switch signals of UI devices and connects each UI device to each computer.

FIG. 2 shows an example of a KVM switch that employs a technique called KVM over Internet Protocol (IP). In the connection of FIG. 2, for example, a remote console machine 534 is connected to the KVM switch 502 via the Internet or a local area network (LAN). The keyboard, display, mouse, and the like of the console machine 534 are connected to the KVM switch 502 by the console machine 534. The KVM switch 502 switches and connects the keyboard, display, mouse, etc. of the remote console machine 534 to one of the computers 521 and 522. Therefore, in the configuration of FIG. 2, a remote keyboard, display, mouse, and the like are switched to and connected to one of the computers 521 and 522 by the intervention of the remote console machine 534. Note that the keyboard, display, mouse, and the like of the local console machine 535 are connected to the KVM switch 502 through a wired interface such as a serial port. The keyboard, display, mouse, and the like of the local console machine 535 are switched to and connected to one of the computers 521 and 522 as in the case of FIG.

FIG. 3 is an example of a device that switches connection between a plurality of computers, host devices, and other host devices with a UI device by a button operation according to a wireless communication standard called Bluetooth. In Bluetooth, device registration called pairing is performed in advance. Pairing is set for each combination of the host side device and UI device. A function called multi-pairing allows a user to pair a host device with a UI device, specify the host device to connect with a button or dial on the UI device, and connect the UI device The host side device can be switched. However, the multi-pairing function is incorporated for each single UI device, and there is no function for switching UI devices collectively. That is, each UI device is connected to the host-side device on a one-to-one basis.

  Therefore, as illustrated in FIG. 4, for example, when the user switches the connection destination of input / output devices such as a keyboard and a mouse between different computers, the user individually disconnects and reconnects each input / output device. The operation of connecting to the connection destination is repeated.

JP 2000-010680 PR Japanese Laid-Open Patent Publication No. 2002-189542 JP 2013-156700 PR

  As described above, in the conventional technology, when an input / output device is connected to a computer by a switching device such as a KVM switch, a dedicated connection interface (or a dedicated connection line) is provided for each input / output device, or A device for performing individual connection operations for each input / output device has been proposed. However, if a dedicated connection interface (or a dedicated connection line) is provided for each input / output device, the number of components of the switching device increases. Further, in a switching device that performs individual connection operations for each input / output device, the burden on the switching operation of the user is large. In this embodiment, a plurality of input / output devices can be freely combined without using a dedicated interface for each input / output device, and the combined input / output devices can be switched together and connected to a target connection destination. The purpose is to.

  One aspect of the present invention is exemplified by a connection device that connects a plurality of input / output devices to be connected to a computer. That is, the connection device searches for a communication unit that communicates with a computer and input / output devices connected to the computer, and a computer that can be connected via the communication unit, and registers it as one of a plurality of computers to be connected. A computer registration unit that searches for input / output devices that can be connected via the communication unit and registers them as one of a plurality of input / output devices to be connected; and when the first condition is satisfied A connection unit that selects a computer that satisfies the first condition from the plurality of computers to be connected to and connects the plurality of input / output devices to be connected to the selected computer collectively via the communication unit. And comprising.

  According to this embodiment, a plurality of input / output devices can be freely combined without using a dedicated interface for each input / output device, and the combined input / output devices can be switched together and connected to a target connection destination. .

It is a figure which shows an example of a KVM switch. It is an example of a KVM switch that employs KVM over IP. It is an example of the apparatus which switches the connection of apparatuses, such as a some computer and a portable terminal, and UI apparatus with a button according to a wireless communication standard. It is an example of the procedure which switches connection with UI apparatuses with terminals, such as a some computer and a portable terminal, individually for UI apparatuses. 1 is a diagram illustrating a configuration of an information system according to Embodiment 1. FIG. 2 is a diagram illustrating a hardware configuration of a UI device switching apparatus according to Embodiment 1. FIG. 1 is a diagram illustrating a configuration of an information system according to a first embodiment. It is an example of data of a UI device list. It is an example of data of a host list. It is an example of the connection registration process of UI apparatus switching apparatus and UI apparatus. It is a figure which illustrates the connection registration process of the computer of a host side, and UI apparatus switching apparatus. It is a figure which illustrates the detail of a function list creation process. It is a figure which illustrates the procedure which switches the connection destination of UI apparatus. It is a figure which illustrates the detail of a connection process with the UI apparatus switching apparatus which a host computer performs. FIG. 10 is a diagram illustrating an example of UI device addition processing for a connected computer. It is a figure which illustrates UI apparatus deletion processing. It is a figure which illustrates the signal transmission process from UI apparatus to a computer. It is a figure which illustrates the transmission process of the signal from the computer of a host side to UI apparatus. It is a figure which illustrates the computer switching detection process of the operation target by radio wave intensity. It is a figure which illustrates the structure of the system which detects a user's eyes | visual_axis and switches the operation target computer. It is a figure which illustrates the process performed after the switching process of the computer by the host side is performed and the UI apparatus switching apparatus 1 connects a new computer. It is a figure which illustrates the procedure of the connection by the computer after pairing. It is a figure which illustrates the process of the reconnection request | requirement from UI apparatus switching apparatus.

Hereinafter, an information system according to an embodiment will be described. FIG. 5 illustrates the configuration of the information system according to the present embodiment. This information system includes a UI device switching device 1, computers 21, 22, and 23, UI devices 31 to 36, and the like. The UI device switching device 1 has a communication interface such as Bluetooth, is connected to the computers 21, 22, and 23, and is also connected to UI devices 31 to 36 and the like. The UI device switching device 1 is an example of a connection device. UI devices 31 to 36 are examples of input / output devices. The system including the computers 21 and 22, the UI device switching device 1, and the UI devices 31 to 36 in FIG. 5 is an example of an information system.

  The UI devices 34 and 35 are displays, and the UI device 36 is a projector. Video is transmitted and received between the computers 21, 22, and 23 and the UI devices 34, 35, and 36. The video has a larger amount of data than the operation signals from the operation units such as the UI devices 31, 32, and 33. Therefore, the computer 21 and the UI device 34, the computer 22 and the UI device 35, and the computer 23 and the UI device 36 may be connected by wire.

The UI device switching apparatus 1 stores a list called a UI device list. The UI device list is a list of connectable UI devices recognized by the UI device switching apparatus 1. The UI device switching apparatus 1 registers the recognized UI device in the UI device list by executing a process for searching for a UI device. For example, when the UI device switching device 1 and the UI device communicate with each other according to the Bluetooth standard, the UI device switching device 1 executes bluetooth pairing as a process for searching for a UI device.

  In the present embodiment, the UI device switching device 1 behaves as a UI device having the functions of all connected UI devices, and is connected to the computers 21 and 22 on the host side. When the host computers 21 and 22 are personal computers, portable information terminals, etc., the computers 21 and 22 are also called terminals. The computers 21 and 22 on the host side are not limited to devices called terminals, but are called servers when providing services to a plurality of users. The computers 21 and 22 can also be called information processing apparatuses.

The UI device switching device 1 connects all the connected UI devices 31 to 36 and the like together to the computer 21 and further switches the connection destination to another computer 22. For example, the UI device switching device 1 cuts off the connection with the currently connected computer 21 according to the user's instruction, and all the UI devices 3 to which the UI device switching device 1 is connected to the instructed unconnected computer 22.
1 to 36 etc. are connected. That is, the UI device switching device 1 is a device that simulates a UI device having one or more functions by collecting the connected UI devices.

The UI devices 31 to 36 are, for example, a keyboard, a mouse, headphones, a display, a projector, and the like. However, in the present embodiment, the type and number of UI devices are not limited. In other words, any device can be connected as long as the UI device switching device 1 is a UI device having a communication interface such as Bluetooth, that is, a communication interface of the same standard as the UI device switching device 1.

  The UI device switching apparatus 1 stores a list called a host list. The host list is a list of connectable host computers recognized by the UI device switching apparatus 1. In the present embodiment, the UI device switching apparatus 1 registers a recognized computer in the host list by executing a process of searching for a host computer. Furthermore, the UI device switching device 1 sets the state of whether or not currently connected to the record of each computer in the host list.

The UI device switching device 1 transfers a transmission signal from the connected computer to the switching device 1 to each UI device. In addition, the UI device switching device 1 transfers a transmission signal from the connected UI devices 31 to 36 to the switching device 1 to the connected computer.
[Embodiment 1]
Hereinafter, the UI device switching apparatus 1 according to the first embodiment will be specifically described with reference to the drawings.

<Configuration>
FIG. 6 illustrates a hardware configuration of the UI device switching apparatus 1 according to the first embodiment. The UI device switching apparatus 1 includes a Central Processing Unit (CPU) 11, a memory 12, a host side transmission / reception unit 13, a UI device side transmission / reception unit 14, a sensor 15, and a display panel 16. The CPU 11 controls the UI device switching device 1 by a computer program on the memory 12. The memory 12 stores computer programs executed by the CPU 11, data referred to by the CPU 11, data processed by the CPU 11, and the like. The memory 12 is a volatile Random Access Memory (RAM), a nonvolatile Read Only Memory (ROM), or the like. A computer program stored in the ROM that executes processing closely related to the hardware of the UI device switching apparatus 1 may be referred to as firmware.

The host-side transmitting / receiving unit 13 and the UI device-side transmitting / receiving unit 14 are communication interfaces, and are examples of a communication unit that communicates with a computer and input / output devices connected to the computer. The host-side transmitting / receiving unit 13 establishes a connection with the host-side computer. Further, the UI device side transmitting / receiving unit 14 establishes a connection with the UI device. In the present embodiment, Bluetooth is exemplified as the communication interface. However, the host side transceiver 13 and UI
As the device-side transmitting / receiving unit 14, a communication standard other than Bluetooth, for example, a wireless local area network (LAN), Zigbee, Miracast, or the like may be used. Further, the host-side transmitting / receiving unit 13 and the UI device-side transmitting / receiving unit 14 may have different communication standards or the same communication standard. Further, the host-side transmitting / receiving unit 13 and the UI device-side transmitting / receiving unit 14 may be the same communication interface and connected to both the host side and the UI device side. Further, a plurality of either or both of the host-side transceiver unit 13 and the UI device-side transceiver unit 14 may be provided.

The sensor 15 is a camera, for example, and is a component that detects a human face, line of sight, and the like. However, in this embodiment, the sensor 15 may not be provided. The display panel 16 is a liquid crystal display or the like, for example, and displays the connection status of the host computer and UI equipment. However, this information system may display the connection status of UI devices on a display connected to each computer on the host side, instead of the display panel 16 of the UI device switching apparatus 1. For example, the host computer may execute a dedicated application program for displaying the connection state on the display, acquire information from the UI device switching device 1 and display the connection state of the UI device.

  FIG. 7 specifically illustrates the configuration of the information system according to the first embodiment. In FIG. 7, as the information system, a UI device switching device 1, host-side computers 21 and 22, and UI devices 31 and 32 are illustrated.

  The CPU 11 of the UI device switching apparatus 1 executes a computer program on the memory 12 and operates as a host switching detection unit 111 and a UI device signal conversion / tunnel unit 112. For example, the host switching detection unit 111 detects the direction of the user's line of sight based on the image from the sensor 15 and switches the connection side on the host side. For example, the host switching detection unit 111 holds the positions of the computers 21 and 22 on the host side in the database with the position of the camera that is a part of the sensor 15 as the reference position. The host switching detection unit 111 detects the user's line of sight and selects a computer that exists in the direction of the line of sight as the connection destination computer.

However, such a computer switching function on the host side by detecting the user's line of sight may not be the present embodiment. For example, the host switching detection unit 111 may recognize the switching destination computer by a button operation or the like provided in the UI device switching device 1. Further, for example, by detecting a user operation on a menu, a graphical user interface, or the like displayed on a display which is one of UI devices, the host switching detection unit 111 can recognize the switching destination computer. Good. Once the host computer and the UI device switching device 1 are paired, they can communicate with each other. Therefore, for example, the UI device switching apparatus 1 may receive a switching instruction including a switching destination computer from a host computer by an application program and execute a process of switching the computer.

  Further, the host switching detection unit 111 may recognize the switching destination computer based on the radio wave intensity detected by the host-side transmission / reception unit 13. For example, the host switching detection unit 111 may determine, as a switching destination computer, a computer that can communicate with a wireless signal having the strongest radio wave intensity among a plurality of computers detected by the host-side transmitting / receiving unit 13.

  In addition, the UI device switching device 1 sends and receives transmission / reception signals to / from the computers 21 and 22 with the host side transmission / reception unit 13 by the driver 113. In addition, the UI device switching apparatus 1 exchanges transmission / reception signals with the UI devices 31 and 32 with the UI device side transmission / reception unit 14 by the driver 114.

The UI device signal conversion / tunnel unit 112 acquires signals from the host-side computers 21 and 22 via the driver 113, and the UI devices 31 and 32 from the UI device-side transmission / reception unit via the UI device-side driver 114. Etc. Such a function of connecting the driver 13 and the driver 14 is called a tunnel. The UI device signal conversion / tunnel unit 112 determines a UI device to which the signal is transmitted in the tunnel processing. Also, the UI device signal conversion / tunnel unit 112 decodes signals from the host-side computers 21, 22, etc., and encodes them in a code appropriate for the destination UI device. Then, the UI device signal conversion / tunnel unit 112 selects an appropriate driver 14 for the transmission destination UI device and delivers the encoded signal. Similarly, the UI device signal conversion / tunnel unit 112 acquires a signal from the UI device via the driver 14 and decodes it. Then, the UI device signal conversion / tunnel unit 112 encodes the decoded signal into an appropriate code for the transmission destination computer, and delivers it to the driver 13.

  The computer 21 has a CPU and a memory as in FIG. For example, an application program 211 and an OS 212 are stored on the memory. The CPU of the computer 21 executes an application program 211 and an OS 212 on the memory, and operates as a host computer. The computer 21 also includes a device signal transmission / reception unit 213 and a peripheral device 214. The device signal transmission / reception unit 213 communicates with the host-side transmission / reception unit 13 of the UI device switching device 1 according to a predetermined wireless communication standard. The peripheral device 214 is, for example, an external storage device. The configuration of the computer 22 is the same as that of the computer 21.

  The UI device 31 includes a ROM 312 and a transmission / reception unit 314. The UI device 31 holds firmware firmware on the ROM 312. The CPU included in the UI device 31 executes the firmware on the ROM 312 and provides the function of the UI device 31. In addition, the CPU included in the UI device 31 communicates with the UI device side transmission / reception unit 14 of the UI device switching device 1 via the transmission / reception unit 314 according to a predetermined wireless communication standard. The configuration of the UI device 31 is the same as that of the UI device 31.

<Data example>
FIG. 8 shows a data example of the UI device list. As described above, the UI device list is a list of connectable UI devices recognized by the UI device switching apparatus 1. In the example of FIG. 8, the UI device list has fields of a UI device name, a physical address, a profile, and a connection state in each record (each row of the table). In FIG. 8, two records are illustrated.

The UI device name field stores the name of the UI device. The physical address field stores the physical address of the network through which the UI device switching device 1 and the UI device communicate. The profile field stores a specification of a specific protocol set according to the type or characteristic of the UI device in the communication standard between the computer and the UI device. Alternatively, the profile field stores the type or characteristics of the UI machine on the communication protocol. For example, when the communication standard between a computer and a UI device is bluetooth, for example, Human Interface Device Profile (HID), Headset Profile (HSP), Hands-Free Profile (HFP), Advanced Audio Distribution Profile (A2DP), Audio / Video Remote Control Profile (AVRCP) and other profiles are stored. The computer and the UI device establish a communication procedure according to the type and characteristics of the UI device according to the profile. Also, the UI device switching apparatus 1 according to the present embodiment communicates with a host computer as a UI device that is registered in the UI device list and whose connection state is specified in the profiles of all connected UI devices. In the present embodiment, the profile is also referred to as a “function” of the UI device. Profiles and functions are examples of type information.

The connection status field indicates whether or not the UI device switching apparatus 1 and the UI device are connected. Normally, when the UI device switching device 1 performs pairing with a UI device, the UI device switching device 1 recognizes the UI device paired by an appropriate driver and determines that the UI device is being connected. Register in the UI device list. After that, when the UI device becomes unusable as when the power of the UI device is turned off, the UI device switching apparatus 1 cuts off the connection with the UI device, and Set the connection status in the device list to not connected. Furthermore, when the UI device is disconnected once after pairing and then turned on and becomes usable, the UI device switching device 1 connects the UI device to the UI device switching device 1. The connection status field in the UI device list is set to “connected”.

  FIG. 9 shows an example of data in the host list. As already described, the host list is a list of connectable host computers recognized by the UI device switching apparatus 1. In the example of FIG. 8, the host list has fields of a computer name, a physical address, a connection state, and a radio wave intensity in each record (each row of the table).

  The computer name field stores a name for identifying the computer. The computer name can also be called a node name on the network. The physical address is the same as that in the UI device list. The connection status field indicates whether the computer and the UI device switching device 1 are connected. The radio wave intensity is the intensity of the received radio wave when the host-side transmitting / receiving unit 13 of the UI device switching device 1 receives the radio wave from the computer.

<Operation example>
FIG. 10 is an example of a connection registration process between the UI device switching apparatus 1 and the UI device. The CPU 11 of the UI device switching apparatus 1 uses a computer program on the memory 12 to search for an input / output device that can be connected via the communication unit and register it as one of a plurality of input / output devices to be connected. As an example, the process of FIG. 10 is executed. FIG. 10 is an example of searching for connectable input / output devices and registering them as one of a plurality of input / output devices to be connected.

When a computer uses a UI device that connects wirelessly for the first time, connection registration called pairing is executed. The UI device switching apparatus 1 performs pairing with a UI device using an existing wireless communication standard (for example, Bluetooth) via the UI device side transmission / reception unit 14. The process of FIG.
For example, the process is started when an instruction to start pairing is given to the UI device switching device 1 by the user's operation (S11). The start of pairing is instructed in accordance with, for example, operation of an operation unit such as a push button provided in the UI device switching device 1.

  At the start of pairing, the user instructs each UI device to start pairing. In order to reduce battery consumption, the UI device normally does not monitor a pairing request from the host side (UI device switching apparatus 1). When the user operates an operation unit such as a start button provided on the UI device, the UI device starts monitoring a pairing request from the host side (UI device switching apparatus 1).

  Upon receiving a pairing request from the UI device switching device 1, the UI device performs pairing with the UI device switching device 1 (S12). Pairing refers to identifying and authenticating communication partners that exist in the vicinity, and can be said to be a preparation for connection. In pairing, authentication information is exchanged with each other, and if the authentication is successful, the partner device is registered as a device that can be connected to each other.

When pairing is completed, the UI device switching apparatus 1 requests a function list from the UI device (S13). Then, the UI device responds to the UI device switching device 1 with a list of functions that the UI device has. When acquiring the function list, the UI device switching apparatus 1 registers the UI device in the UI device list (S15). Further, the UI device switching apparatus 1 selects an appropriate driver based on the function list and recognizes each UI device corresponding to the function list (S16). Through the process of S16, the UI device switching apparatus 1 selects an appropriate driver that matches the function (profile) specified in the function list, and recognizes each UI device. By the process of S16, each UI device is connected to the UI device switching apparatus 1. Therefore, the connection state of the UI device list is set during connection.

The UI device switching apparatus 1 may collect UI device function (profile) information using, for example, a service discovery protocol (SDP) when using Bluetooth. In the pairing, the UI device switching device 1 can use Bluetooth Secure Simple Pairing Using NFC (BTSSP). In BTSSP, a function has been proposed in which pairing is automatically executed only by a user touching a UI device using Near field radio communication (NFC). There is no particular limitation on the specific procedure of pairing. Therefore, as a connection registration process with a UI device, the UI device switching apparatus 1 may adopt an existing pairing technology.

  FIG. 11 illustrates a connection registration process between the host computer and the UI device switching apparatus 1. The CPU 11 of the UI device switching device 1 executes the process of FIG. 11 by a computer program on the memory 12. The process of FIG. 11 by the CPU 11 is an example of a computer registration unit that searches for a connectable computer via a communication unit and registers it as one of a plurality of computers to be connected. The process of FIG. 11 is also an example of searching for a connectable computer and registering it as one of a plurality of computers to be connected. In the present embodiment, the UI device switching apparatus 1 performs connection registration when connecting to a host computer for the first time. In the connection registration of the computer on the host side, the UI device switching device 1 registers as the UI device side (peripheral side). In the process of FIG. 11 as well, the process starts when the user instructs the host computer to start pairing using the host-side operation unit (S21). Note that when the user instructs the UI device switching device 1 to perform pairing using the operation unit of the UI device switching device 1, the UI device switching device 1 serves as a device on the UI device side from a computer on the host side. Monitor pairing requests. Upon receiving the pairing request, the UI device switching apparatus 1 adds the host computer that has performed pairing to the host list (S22).

  When pairing is completed, the host computer requests the UI device switching apparatus 1 for a function list (S24). Upon receiving the function list request, the UI device switching apparatus 1 creates a function list (S25) and responds with the function list (S26). That is, the UI device switching device 1 returns a function list of all connected UI devices in response to a function list request from the host computer. Then, the host computer selects an appropriate driver based on the function list and recognizes each UI device corresponding to the function list (S27). Through the processing of S27, the host computer selects an appropriate driver that matches the function (profile) specified in the function list, and recognizes each UI device via the UI device switching apparatus 1.

  FIG. 12 illustrates details of the function list creation process (S25 in FIG. 11). In the process of FIG. 12, the UI device switching apparatus 1 first creates an empty list, and sets the created empty list as an initial function list (S251). Next, the UI device switching apparatus 1 determines whether or not there is an unprocessed row in the UI device list (S252). That is, the UI device switching apparatus 1 executes the following processing for all the rows in the UI device list.

  The UI device switching device 1 determines whether the connection state of the UI device in the row of the UI device list being processed is connected. When the connection is being made (YES in S253), the UI device switching device 1 adds the profile of the row to the function list (S254). Then, the UI device switching apparatus 1 returns the process to S252. Accordingly, if the connection is not being established in the determination of S553 (when the determination is NO), the corresponding line in the device list is ignored.

When all the rows in the device list are processed (YES in S252), the UI device switching device 1 makes the function list unique. Uniqueization refers to a process of consolidating them into one when the same profile is duplicated in the function list. For example, when the connected UI device includes a keyboard, a mouse, and the like, the HID is set in the multiple function list as the profile. However, the function list is information for defining the behavior as all UI devices to which the UI device switching apparatus 1 is connected, and only one profile needs to be defined. Therefore, the UI device switching apparatus 1 aggregates the profiles included in duplicate.

  FIG. 13 illustrates a procedure for switching the connection destination of the UI device. In FIG. 13, there are two registered computers 21 and 22. Now, for example, it is assumed that the UI device switching apparatus 1 is connected to the computer 21 together with the UI device. Here, the UI device switching apparatus 1 detects an operation from a user who switches the connection destination from the computer 21 to the computer 22, and starts the processing of FIG. The switching operation is detected by the UI device switching device 1 by an operation unit such as an operation button on the UI device, a function key, or a push button provided in the UI device switching device 1. However, the switching operation may be detected by the currently connected computer 21. For example, a menu, function keys, push buttons, and the like are displayed on a display to which the computer 21 to which the UI device switching apparatus 1 is currently connected is connected, and operation units such as menus, function keys, push buttons, etc. are selected. Thus, the currently connected computer 21 may accept a connection destination switching instruction. The computer 21 may transmit the received connection destination switching instruction to the connected UI device switching apparatus 1 via wireless communication. The CPU 11 of the UI device switching apparatus 1 executes an application program that receives an instruction to switch from the computer 21 or 21 on the host side via wireless communication, and executes a process according to the switching instruction including designation of the switching destination computer. That's fine.

  Upon receiving an instruction to switch the connection destination from the currently connected computer 21 to the unconnected computer 22, the UI device switching apparatus 1 cuts off the connection with the currently connected computer 21 (S31). More specifically, the UI device switching device 1 requests the computer 21 to cut off the connection with the computer 21 being connected, and the computer 21 cuts off the connection with the UI device switching device 1 (S32). . The CPU 11 of the UI device switching apparatus 1 operates as a connection unit, and collectively connects connections between the computer that satisfies the first condition and the plurality of input / output devices to be connected when the second condition is satisfied. Then, the process of S31 is executed as an example of blocking. Blocking collectively means that a plurality of UI devices connected to the UI device switching apparatus 1 are disconnected from the computer 21 by the one connection destination switching instruction received in S31.

  The UI device switching apparatus 1 issues a connection request to the computer 22 which is a new connection destination designated by the user (S33). The computer 22 receives a connection request from the UI device switching device 1 and executes a connection process with the UI device switching device 1 (S34). The CPU 11 of the UI device switching device 1 selects a computer corresponding to the first condition from the plurality of computers to be connected when the first condition is satisfied, and selects the plurality of input / output devices to be connected. As an example of a connection unit that collectively connects to the selected computers via the communication unit, the process of S33 is executed. The CPU 11 of the UI device switching device 1 selects a computer corresponding to the first condition from the plurality of computers to be connected when the first condition is satisfied, and selects the plurality of input / output devices to be connected. As an example of collectively connecting to the selected computer, the process of S33 is executed. To connect a plurality of input / output devices to a computer at a time is to connect a plurality of UI devices connected to the UI device switching apparatus 1 to a connection destination computer 22 in response to a single connection destination switching instruction received in S31. To do. In addition, it is an example of the first condition or the second condition to correspond to a new connection destination designated by the user. Further, the CPU 11 of the UI device switching apparatus 1 executes the process of S33 as an example of connecting the plurality of input / output devices to be connected to the computer meeting the second condition in a lump.

FIG. 14 illustrates details of the connection process (S34 in FIG. 13) with the UI device switching apparatus 1 executed by the host computer. In this process, for example, the computer 22 that is a new connection destination of the UI device switching device 1 requests the UI device switching device 1 for the current function list (S341). The UI device switching apparatus 1 accepts a request from the computer 22, creates a function list in the procedure illustrated in FIG. 12, and responds (S342). The CPU 11 of the UI device switching apparatus 1 operates as an example of a connection unit, and executes the process of S342 as an example of receiving an acquisition request for type information of a plurality of input / output devices to be connected from the computer at the time of connection. . Further, the CPU 11 of the UI device switching apparatus 1 operates as an example of a connection unit, creates a list of type information of a plurality of input / output devices to be connected, and executes the process of S342 as an example of providing to the computer. To do. The function (profile) is an example of input / output device type information.

  The computer 22 recognizes the UI device via an appropriate driver for each function in the obtained function list. That is, the computer 22 recognizes the UI device again for the function list received from the UI device switching apparatus 1. When there is an unprocessed function (profile) in the function list (YES in S343), the computer 22 activates the driver corresponding to the function (profile) and communicates with the UI device switching device 1 by the driver. The UI device is recognized (S344). When the computer 22 recognizes the UI device by the driver corresponding to all the functions (profiles) in the function list received from the UI device switching apparatus 1 (NO in S343), the computer 22 ends the process.

  FIG. 15 illustrates an example of UI device addition processing for a connected computer. When the UI device becomes usable because the power of the unconnected UI device is turned on (S41), the UI device in which the UI device switching device 1 is usable is detected (S42). The connected UI device is connected to the host computer. However, when the UI device switching device 1 detects an unpaired UI device that is not in the UI device list (NO in S43), the detected UI device is ignored without performing any particular process. The CPU 1 of the UI device switching apparatus 1 executes the processes of S42 and S43 as an example of a determination unit that determines whether or not a plurality of input / output devices to be connected are in a usable state.

  On the other hand, when the UI device switching device 1 detects that a UI device existing in the UI device list is usable (YES in S43), the UI device switching device 1 is connected to the UI device switching device 1 itself. Connection between UI devices is established (S44, S45). Establishing a connection means that the UI device switching apparatus 1 recognizes the UI device using a driver that matches the function (profile) of the UI device.

  Next, the UI device switching apparatus 1 creates a function list currently connected to the computer (S46), and in the process of S46, a function list is created according to the UI device list before update. Furthermore, the UI device switching apparatus 1 updates the UI device list so that the state of the added UI device becomes “connected” (S47). By updating the device list in S47, the connection state of the added UI device is reflected in the UI device list.

  Next, the UI device switching apparatus 1 determines whether or not all the functions of the added UI device are included in the function list before the UI device addition created in S46 (S48). If it is determined in S48 that all functions of the added UI device are included in the function list before adding the UI device created in S46, the UI device switching apparatus 1 ends the process. This is because, since the added function is already included in the device list, the computer has already recognized the added UI device and does not need to reconnect the computer.

On the other hand, if any of the functions of the added UI device is not included in the function list before adding the UI device created in S46 in the determination in S48, the UI device switching apparatus 1 is connected to the computer on the host side. A reconnection is requested (S49). The CPU 11 of the UI device switching apparatus 1 operates as an example of a connection unit, and when the at least one of a plurality of input / output devices to be connected is changed from an unusable state to an usable state, the CPU 11 uses the connected device. The process of S49 is executed as an example of the process of connecting the input / output device that has become possible. In order to prompt the host computer to connect again, the UI device switching device 1 disconnects the connected computer once and requests connection again.

  In response to the connection request from the UI device switching device 1, the host computer executes connection processing with the UI device switching device (S4A). The process of S4A is the same as that in FIG. 14 (connected to the UI device switching device).

  In the process of FIG. 15, it is determined whether or not a new function (profile) is added to the function list before the UI device addition by the process of S46, and the added function (profile) exists. In this case, the UI device switching device 1 reconnects to the host side. However, instead of the processing shown in FIG. 15, the UI device switching apparatus 1 determines whether or not the added function (profile) exists in the function list before the UI device addition when the UI device is added. The reconnection process to the computer on the host side may be performed without doing so.

  FIG. 16 illustrates UI device deletion processing. When the UI device becomes unusable due to power-off of the UI device (S51), the UI device switching device 1 detects a disconnection request due to the unavailability of the UI device (S52), and the UI device is sent from the computer. Disconnect. However, when it is detected that an unpaired UI device that is not in the UI device list is unusable, the UI device switching apparatus 1 performs no processing and ignores the unusable UI device (NO in S53).

  When a disconnection request due to the unusability of a UI device existing in the UI device list is detected (YES in S53), the UI device switching device 1 first disconnects the connection with the UI device (S54). For example, the UI device switching apparatus 1 deletes the driver of the UI device to be disconnected from the resident state of the memory, and sets the driver to an inactive state. Next, the UI device list is updated so that the state of the disconnected UI device becomes “not connected” (S55). Then, the UI device switching apparatus 1 creates a function list using the changed UI device list (S56).

  Then, the UI device switching apparatus 1 confirms whether or not the function of the deleted UI device is included in the function list created in S56 (S57). That is, it is determined whether or not there is a change in the function list due to deletion of the UI device. For example, when a UI device having the same function (profile) as a disabled UI device is connected to the UI device switching apparatus 1, the function list does not change even if one of the UI devices is deleted. That is, if the deleted function (profile) is included, the UI device switching apparatus 1 ends the process because there is no function to delete the computer on the host side. On the other hand, if the function (profile) of the deleted UI device is not included in the function list newly created in S56, the UI device switching apparatus 1 notifies the computer that the function (profile) has been deleted. . Therefore, the UI device switching apparatus 1 sends a reconnection request to the computer (S58). The computer that has received the reconnection request executes reconnection with the UI device switching apparatus 1 (S59). The process of S59 is the same as that in FIG. The UI device that is not included in the function list by the process of S59 is disconnected from the host computer. The CPU 11 of the UI device switching apparatus 1 operates as an example of a connection unit, and when at least one of a plurality of input / output devices to be connected is changed from being usable to being unusable, the connected computer and the use The process of S58 is executed as an example of the process of cutting off the connection with the input / output device that has become incapable.

In the process of FIG. 16, it is determined whether or not there is a deleted function (profile) in the function list before adding a UI device by the determination in S57, and there is a deleted function (profile). If not, the UI device switching device 1 reconnects to the host side. However, instead of the processing as shown in FIG. 15, the UI device switching device 1 does not determine whether the deleted function (profile) exists in the UI device list when the UI device is deleted. Reconnection processing to the host computer may be performed.

  Hereinafter, a flow of signal transmission / reception via the UI device switching apparatus 1 will be described. FIG. 17 illustrates a signal transmission process from the UI device to the computer. In this embodiment, since signals are encrypted with different keys between the UI device and the UI device switching apparatus 1 and between the UI device switching apparatus 1 and the computer, decryption and encoding are performed. In the process of FIG. 16, first, the UI device transmits a radio signal to the UI device switching apparatus 1 (S61). The UI device switching apparatus 1 receives the radio signal from the UI device (S62), once decrypts the signal received from the UI device, and returns it to plaintext (S63). When the UI device switching device 1 is connected to the host computer (YES in S64), the UI device switching device 1 encodes the decoded signal for the connection destination computer (S65) and transmits it (S66). The computer on the host side receives the encoded signal from the UI device via the UI device switching device 1 (S67). The CPU 11 of the UI device switching apparatus 1 executes the process of S63 as an example of a first decoding unit that decodes a signal from the input / output device. Further, the CPU 11 executes the process of S65 as an example of a first encoding unit that encodes the decoded signal and generates a transmission signal to the connected computer.

  FIG. 18 illustrates a signal transmission process from the host computer to the UI device. In this process, the computer wirelessly transmits a signal to the UI device to the UI device switching apparatus 1 (S71). Upon receiving a signal from the computer to the UI device (S72), the UI device switching apparatus 1 decodes the received signal (S73). Then, the UI device switching apparatus 1 specifies a connection destination UI device. More specifically, the UI device switching device 1 sequentially searches the UI device list (S74), selects one UI device (S75), and the UI device is connected and corresponds to the received signal. It is determined whether or not the UI device has (profile) (S76). If the corresponding UI device can be searched (YES in S76), the UI device switching apparatus 1 encodes the transmission signal (S77) and transmits the radio signal to the corresponding UI device (S78). The UI device receives the signal transmitted from the computer by the wireless signal encoded by the UI device switching apparatus 1 (S79). The CPU 11 of the UI device switching apparatus 1 executes the process of S73 as an example of a second decoding unit that decodes a signal from the connected computer. In addition, the CPU 11 executes the process of S75 as an example of a device selection unit that selects an input / output device according to a signal from the connected computer. In addition, the CPU 11 executes the process of S77 as an example of a second encoding unit that encodes the decoded signal and generates a transmission signal to the selected input / output device.

  FIG. 19 is a diagram illustrating a computer switching detection process to be operated. As processing for detecting switching of an operation target computer, for example, processing based on radio wave intensity, processing based on line-of-sight detection, processing based on button operation, and the like are assumed. Detecting switching of the operation target computer by any one of processing based on radio wave intensity, processing based on line-of-sight detection, processing based on button operation, and the like is an example of satisfying the first condition. FIG. 19 illustrates a process of switching the operation target computer according to the radio wave intensity. In this process, when the radio signal intensity of a radio signal transmitted from a computer is stronger than that of another computer, the computer is likely to be installed at a position close to the user. Based on the assumption that it is convenient to use.

The process of FIG. 19 is started by a timer interrupt. The UI device switching device 1 sequentially searches for computers registered in the host list. When there is an unsearched computer registered in the host list (NO in S81), the UI device switching apparatus 1 selects one unsearched computer (NO in S81). S82). Then, the UI device switching apparatus 1 investigates the radio wave intensity (the radio wave intensity between the computer and the switching apparatus) of the radio signal transmitted from the selected computer (S83). Then, the UI device switching device 1 updates the radio wave intensity of the host list (S84).

  On the other hand, if all the computers registered in the host list have been searched (YES in S81), the UI device switching apparatus 1 determines whether or not the computer having the highest radio field intensity has changed (S85). When the computer having the highest radio wave intensity changes (YES in S85), the UI device switching device 1 executes a computer switching process (S86). Details of the processing of S86 are the same as those in FIG. Here, the UI device switching apparatus 1 selects a computer with the highest radio field intensity and executes a process of switching the connection of the UI device to the selected computer. The CPU 11 of the UI device switching device 1 selects a computer corresponding to the first condition from the plurality of computers to be connected when the first condition is satisfied, and collectively selects the plurality of devices to be connected. As an example of a connection unit that connects to the selected computer via the communication unit, the process of S82 is executed. Further, the CPU 11 of the UI device switching device 1 selects a computer that satisfies the first condition from the plurality of computers to be connected when the first condition is satisfied, and selects the plurality of devices to be connected. As an example of collectively connecting to the selected computer, the process of S82 is executed. The maximum radio wave intensity is an example of the first condition or the second condition.

  FIG. 20 is a diagram illustrating a configuration of an information system that detects a user's line of sight and switches computers to be operated. In FIG. 20, computers 21, 22, and 23 are illustrated as computers to be operated. The computers 21, 22, and 23 each have a line-of-sight detection sensor. In addition, UI devices 31, 32, and 33 are connected to the UI device switching apparatus 1. The UI devices 31, 32, and 33 (or UI devices 34, 35, and 36) are, for example, a keyboard, a mouse, and headphones. Therefore, the configuration of the host computer and the configuration of the UI device in FIG. 20 are the same as those in FIG. Here, in the first embodiment, a process of switching the operation target computer according to the user's line of sight will be described.

  The line-of-sight detection sensor includes, for example, a camera that captures a user's eyes and a processor that analyzes an image of the eyes. For example, each of the line-of-sight detection sensors of the computers 21, 22, and 23 determines whether or not the user's line of sight is directed to the camera's visual axis from the white-eye portion and the black-eye portion, or how far the visual axis is deviated from the visual axis. It is determined whether or not. Then, the line-of-sight detection sensors of the computers 21, 22, and 23 report the analysis result to the UI device switching device 1. The UI device switching device 1 identifies a computer located in the direction of the user's line of sight according to a report from each of the line-of-sight detection sensors of the computers 21, 22, and 23, and sets it as the switching destination computer. Then, the UI device switching apparatus 1 connects the UI devices 31, 32, and 33 to the switching destination computer. Positioning in the direction of the user's line of sight according to the report from the line-of-sight detection sensor is an example of the first condition or the second condition.

  In the example of FIG. 20, each of the line-of-sight detection sensors of the computers 21, 22, and 23 individually determines the direction of the line of sight of the user, but the UI device switching apparatus 1 is, for example, a computer The camera images of the cameras 21, 22, and 23 may be transformed into a single coordinate system and combined into a single image to determine the user's line of sight.

In FIG. 20, the line-of-sight detection sensor is provided for each of the computers 21, 22, and 23 to be operated, but the line-of-sight detection sensor may be provided in the UI device switching device 1. When the gaze detection sensor is provided in the UI device switching device 1, the eyes of the user may be photographed using a plurality of cameras, the positional relationship between white eyes and black eyes may be analyzed, and the gaze direction may be determined. . For example, the UI device switching apparatus 1 may hold arrangement data indicating the installation positions of the computers 21, 22, and 23 in the database with reference to the position of the UI device switching apparatus 1 and the visual axis of the camera. Then, the UI device switching apparatus 1 may determine a computer installed in the direction of the detected user's line of sight and set it as a switching destination computer.

<Effect of embodiment>
As described above, the UI device switching apparatus 1 according to the present embodiment operates in a pseudo manner as a device having all the functions (profiles) of the UI device being connected to the host computer. For example, the UI device switching apparatus 1 provides a function (profile) of a UI device to a host computer. Then, a computer corresponding to a predetermined condition or user designation is selected, and a plurality of UI devices to be connected are collectively connected to the selected computer via the communication unit. The communication between the host computer and the plurality of UI devices is relayed. Therefore, the UI device switching apparatus 1 can be connected to a computer that selects a plurality of UI devices in a lump with a simple configuration and suppressing a user's operation burden. (Claim 1)
In addition, the UI device switching device 1 can collectively switch UI devices connected to the UI device switching device 1 from the first computer on the host side to the second computer. Become. Therefore, when a UI device connected to the UI device switching apparatus 1 is connected to the first computer by a user operation or the like, an operation for connecting each UI device to the first computer is not required. UI devices connected to the UI device switching device 1 can be collectively connected to the first computer as a single device. In addition, when the user switches the operation target from the first computer to the second computer using a plurality of UI devices, the connection destination of each UI device may not be switched.

Also, the UI device switching device 1 uses a communication procedure common to UI devices, for example, bluetooth, etc., to integrate a plurality of UI devices, and connect the connection destination of UI devices from the first computer on the host side to the second computer. You can switch to a computer. That is, in the connection using the UI device switching device 1, it is not necessary to provide a separate communication interface for each UI device between the host computer and the UI device. (Claim 2)
Also, the UI device switching device 1 can freely add and delete connected UI devices. Also, the UI device switching apparatus 1 can flexibly cope with addition and deletion of UI devices even once the connection between the UI devices and the computer is established. That is, when a UI device is added or deleted, the UI device switching apparatus 1 creates a function list again and operates as a device having the function (profile) of the currently connected UI device. Therefore, the user can freely combine the UI devices and switch the connection destination of the UI devices from the first computer on the host side to the second computer as a unit.

Also, the UI device switching device 1 creates a function list of usable UI devices according to a request from the switching destination computer when switching the computer to which the UI device is connected, and stores the function list in the switching destination computer. Send. Therefore, even when the connection with the UI device is switched, the switching destination computer can easily select the driver corresponding to the function list and recognize the UI device. (Claim 3)
Further, the UI device switching device 1 becomes usable when the UI device becomes usable because the power of the UI device described in the UI device list is turned on. Detect UI devices. Then, when there is a change in the function list corresponding to the UI device to which the UI device switching apparatus 1 is connected, a reconnection is requested to the computer on the host side. In addition, when the UI device described in the UI device list is turned off, for example, when the UI device becomes unusable, the UI device switching device 1 detects the unusable UI device. Then, when there is a change in the function list corresponding to the device to which the UI device switching apparatus 1 is connected, a reconnection is requested to the computer with the host side. As described above, the UI device switching device 1 requests reconnection to the host computer when there is a change in the function list of the UI device switching device 1 as viewed from the connected computer. Therefore, since the host computer performs reconnection when recognizing a new device, for example, by starting a device driver corresponding to a new function, the labor of reconnection is reduced. (Claims 5 and 6)
However, the UI device switching device 1 determines whether or not the function list of the connected UI device has changed when the unusable UI device becomes usable or when the usable UI device becomes unusable. Regardless, the host computer may request reconnection. Such processing simplifies the control of the UI device switching device 1.

  Further, the UI device switching device 1 switches the connection destination of the UI device from the first computer on the host side to the second computer in accordance with various conditions such as user operation, user's line of sight, and radio wave intensity. be able to.

  Also, the UI device switching apparatus 1 decodes communication data during communication with the host computer, selects an appropriate UI device corresponding to the communication data, and performs communication during communication with the selected UI device. Encrypt data. Also, the UI device switching apparatus 1 decodes communication data at the time of communication with the UI device, and encodes it into communication data at the time of communication with the host computer. That is, the UI device switching apparatus 1 can perform communication by encoding processing or encryption processing that is different from host-side communication and UI device-side communication. Accordingly, the UI device switching apparatus 1 can flexibly cope with various codes, encryptions, and the like on the host side and UI device side. (Claims 7 and 8)

[Embodiment 2]
In the first embodiment, as described with reference to FIG. 14, it is assumed that the computer at the switching destination requests a function list when switching computers. However, the existing wireless driver of the host computer does not always re-acquire the function list when reconnecting. The reason why the function list is not reacquired is that, conventionally, the configuration of the UI device is not assumed to be changed after pairing, and it is not considered that the driver reacquires the function list.

  However, the UI device switching apparatus 1 described in the first embodiment can add and delete UI devices, and can be used as a UI device that has all the functions (profiles) of the connected UI device in the computer on the host side. Behave against it. Therefore, even if the pairing is once performed between the host computer and the UI device switching device 1, when the computer and the UI device switching device 1 are next connected, the computer switches the UI device. It is desirable to obtain a function list from the device 1. This is because when the computer acquires the function list from the UI device switching apparatus 1, the computer can fully recognize the connected UI device.

Therefore, when a computer having a driver that does not acquire a function list after pairing is used on the host side, when the UI device switching device 1 switches the host computer, the host side computer and the UI device switching device Pairing with 1 (
It is desirable to perform device registration again. That is, the UI device switching device 1 of the present embodiment
When the host computer is switched, the host computer is forced to request a function list by performing pairing again between the host computer that is the connection destination and the UI device switching device 1. .

  FIG. 21 illustrates the process executed after the host computer switching process is executed and the UI device switching apparatus 1 connects a new computer (after S33 in FIG. 13) in FIG. 13 of the first embodiment. It is a figure to do.

In this process, the UI device switching apparatus 1 displays, for example, a message prompting the user to execute re-pairing on its connection display panel 16 (S91). By this display, the user performs operations such as selection of a predetermined push button and menu so as to re-pair the new connection destination computer. As a result, re-pairing is performed between the new connection destination computer and the UI device switching device 1 (S92), and the host computer transfers the UI device switching device 1 to the UI device switching device 1 in the same procedure as in FIG. A function list is requested (see S24 in FIG. 11). The CPU 11 of the UI device switching device 1 operates as an example of a connection unit, and when the plurality of input / output devices to be connected are collectively connected to a computer that satisfies the first condition or the second condition, The process of S92 is executed as an example of causing the corresponding computer to generate a type information acquisition request for the plurality of input / output devices to be connected.

  FIG. 22 illustrates a connection procedure by a computer after pairing. The computer newly connected by switching the computer selects an appropriate driver based on the function list received at the time of pairing, and recognizes the UI device. That is, the computer that has acquired the function list searches each function (profile) set in the function list until there is no unprocessed one (S101), and recognizes the UI device (S102). As described above, the host computer recognizes the UI device according to the function list returned from the UI device switching apparatus 1.

  As described above, the UI device switching apparatus 1 according to the present embodiment requests a function list at the time of computer switching even to a computer having a driver that does not request a function list of the UI device after pairing. The UI device can be recognized. Note that the computer having a driver that does not request a function list of the UI device by applying the processing of FIGS. 20 and 21 also in the case of addition and deletion of the UI device described in FIGS. 14 and 15 of the first embodiment. In addition, UI devices can be appropriately added and deleted. (Claim 4)

[Embodiment 3]
In the second embodiment, in order to cope with a driver that does not request a function list of the UI device when the computer is connected after the pairing is once performed, the process of prompting the user to pair again is exemplified. In the present embodiment, the existing wireless communication driver on the computer side is expanded to accept a connection / reconnection request including a function list from the UI device switching device 1.

In the present embodiment, when registering a computer (see FIG. 11 of the first embodiment), an existing wireless standard (ex. Bluetooth serial communication function) is used between the computer and the UI device switching device 1. A communication path for transmitting and receiving data is prepared. Here, the communication path is for the UI device switching device 1 to transmit data to the computer.

  In addition, when a UI device is added or deleted (see FIGS. 14 and 15), a request for reconnection including the function list of the connected UI device is transmitted from the UI device switching apparatus 1 to the computer via the prepared communication path. Send to. When receiving the reconnection request, the computer performs reconnection processing on the function list received together with the reconnection request. On the computer side, an application program for accepting and processing a reconnection request from the communication path as described above is prepared.

FIG. 22 illustrates processing for a reconnection request from the UI device switching apparatus 1 via the communication path. That is, in the reconnection of the computer in the UI device addition / deletion process (S49 in FIG. 14, S58 in FIG. 15), the UI device switching apparatus 1 transmits the function list together with the connection / reconnection request to the computer. (S111).

As described above, the computer executes an application program (hereinafter referred to as a connection / reconnection application) that accepts a connection / reconnection request from the UI device switching apparatus 1 and monitors the connection / reconnection request. The computer also saves a function list before receiving the reconnection request. When the computer receives the function list together with the reconnection request, the computer creates a function difference with respect to the function list before receiving the reconnection request based on the received function list (S112). Further, the computer determines whether or not all the differences have been processed (S113). If any difference is not processed, the computer extracts one unprocessed difference (S114).

  Then, the computer determines whether the difference is addition or deletion of the function of the UI device (S115). If the difference is the addition of the function of the UI device, the computer recognizes the UI device by the driver corresponding to the added function (profile) (S116). On the other hand, when the difference is the deletion of the function of the UI device, the computer deletes the corresponding UI device (S117). Specifically, for example, the driver corresponding to the deleted function (profile) is excluded from memory resident.

As described above, according to the present embodiment, for example, an application program that accepts a connection / reconnection request including a function list from the UI device switching apparatus 1 by extending an existing wireless communication driver on the computer side. Can be realized. Therefore, the host computer can add or delete UI devices triggered by a request from the UI device switching apparatus 1.

[recoding media]
A program for causing a computer or other machine or device (hereinafter, a computer or the like) to realize any of the above functions can be recorded on a recording medium that can be read by the computer or the like. The function can be provided by causing a computer or the like to read and execute the program of the recording medium. For example, firmware that causes the CPU 11 to execute the function of the UI device switching apparatus 1 is recorded on a recording medium readable by a computer or the like and distributed.

Here, a computer-readable recording medium is a recording medium that stores information such as data and programs by electrical, magnetic, optical, mechanical, or chemical action and can be read from a computer or the like. Say. Examples of such recording media that can be removed from a computer or the like include, for example, a flexible disk, a magneto-optical disk, a Compact Disc (CD) -Read Only Memory (ROM), a CD-Recordable (R), and a Digital Versatile Disk (DVD). ), Memory cards such as Blu-ray Disc, Digital Audio Tape (DAT), 8 mm tape, and flash memory. In addition, as a recording medium fixed to a computer or the like, there are a hard disk, a ROM (read only memory), and the like. Further, the solid state drive (SSD) can be used as a recording medium removable from a computer or the like, or as a recording medium fixed to the computer or the like.

1 UI equipment switching device 11 CPU
DESCRIPTION OF SYMBOLS 12 Memory 13 Host side transmission / reception part 14 UI apparatus side transmission / reception part 15 Sensor 16 Display panel 21, 22, 22 Computer 31, 32, 33, 34, 35 UI apparatus

Claims (10)

A communication unit that communicates with a computer and input / output devices connected to the computer;
A computer registration unit for searching for a computer connectable via the communication unit and registering it as one of a plurality of computers to be connected;
A device search unit for searching for an input / output device connectable via the communication unit and registering it as one of a plurality of input / output devices to be connected;
When a first condition is satisfied, a computer corresponding to the first condition is selected from the plurality of computers to be connected, and the plurality of input / output devices to be connected are collectively displayed on the selected computer. And a connection unit connected via a communication unit.   When the second condition is satisfied, the connection unit collectively disconnects the connection between the computer corresponding to the first condition and the plurality of input / output devices to be connected, and the second condition The connection device according to claim 1, wherein the plurality of input / output devices to be connected are collectively connected to a computer corresponding to the above.   The connection unit receives a request for obtaining type information of the plurality of input / output devices to be connected from the computer at the time of the connection, creates a list of type information of the plurality of input / output devices to be connected, and the computer The connection device according to claim 2, wherein the connection device is provided.   When the connection unit collectively connects the plurality of input / output devices to be connected to the computer corresponding to the first condition or the second condition, the connection unit includes a plurality of the connection target to the corresponding computer. The connection device according to claim 3, wherein an acquisition request for input / output device type information is generated. A determination unit that determines whether or not the plurality of input / output devices to be connected is in a usable state,
The connection unit connects the input / output device in the usable state to a connected computer when at least one of the plurality of input / output devices to be connected becomes unusable. The connection device according to any one of claims 1 to 4.   The connection unit connects a computer being connected to the input / output device that has become unusable when at least one of the plurality of input / output devices to be connected becomes unusable from the usable state. The connection device according to claim 5, wherein: A first decoding unit for decoding a signal from the input / output device;
The connection device according to claim 1, further comprising: a first encoding unit that encodes the decoded signal to generate a transmission signal to a connected computer. A second decoding unit for decoding a signal from the connected computer;
A device selection unit for selecting an input / output device according to a signal from the connected computer;
8. The connection device according to claim 1, further comprising: a second encoding unit that encodes the decoded signal to generate a transmission signal to the selected input / output device. 9. . A communication unit that communicates with a computer and input / output devices connected to the computer;
A computer registration unit for searching for a computer connectable via the communication unit and registering it as one of a plurality of computers to be connected;
A device search unit for searching for an input / output device connectable via the communication unit and registering it as one of a plurality of input / output devices to be connected;
When a first condition is satisfied, a computer corresponding to the first condition is selected from the plurality of computers to be connected, and the plurality of input / output devices to be connected are collectively displayed on the selected computer. A connection unit comprising: a connection unit connected via a communication unit;
A plurality of input / output devices to be searched by the device search unit;
An information system comprising: a plurality of computers to be registered by the computer registration unit. A connection method for connecting an input / output device of the computer to a computer,
Searching for a connectable computer and registering it as one of a plurality of computers to be connected;
Searching for connectable input / output devices and registering them as one of multiple input / output devices to be connected;
When a first condition is satisfied, a computer corresponding to the first condition is selected from the plurality of computers to be connected, and the plurality of input / output devices to be connected are collectively connected to the selected computer. And a connection method for executing processing including:

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