JP5197868B2 - Information processing apparatus, KVM switch, and control program - Google Patents

Description

  The present invention relates to an information processing apparatus, a KVM switch, and a control program that match the position of a mouse cursor of an information processing apparatus with the position of a mouse cursor of a server.

  Various techniques have been developed for remote control of computers. For remote operation, two computers are required: the operated side (server) and the operated side (remote PC).

  As a remote operation technique, for example, a system that displays both the screen information of a remote terminal and the information of the terminal at hand without impairing the operability and visibility of the screen displayed on the display of the terminal at hand ( For example, see Patent Document 1), a cursor control device (see, for example, Patent Document 2), a mobile phone in which the amount of cursor movement relative to the amount of movement of the remote control transmitter is constant even if the distance between the remote control transmitter and the imaging means is different. A system is known in which a terminal is connected to a remote personal computer and the computer is remotely operated from a mobile phone terminal (see, for example, Patent Document 2).

  Also, there is a technology in which a remote control software is not installed in the server, a converter is arranged between the connection path between the server and the remote PC, and the converter acts as a keyboard or mouse connected to the server. It is known (see, for example, Patent Document 4).

  In the technique of Patent Document 4, a signal output from a keyboard and a mouse connected to a remote PC is converted into digital data, the converted data is transferred onto a line, and the server receives the digital data and returns it to the signal. By inputting the signal, the server operates as if a keyboard and a mouse are directly connected. Furthermore, the video signal output from the server is converted into digital data, the converted data is transferred onto the line, the remote PC receives the digital data, returns it to the signal, and inputs the signal so that the remote PC side It operates as if the monitor installed in is a monitor connected to the server.

  As another technique that uses these techniques, for example, a system having a KVM switch of Patent Document 5 is known.

  The system of Patent Document 5 has the basic concept of Patent Document 4, and in the window system of a remote PC, one window is used as display means, and that window is used as a keyboard / mouse data input path. That is, keyboard and mouse operations executed in the remote PC window are reflected on the server.

JP 2007-65944 A JP-A-6-75695 JP 2006-197299 A Japanese Patent No. 2698855 Special table 2003-534585 gazette

  Next, the problem that occurs when the mouse cursor 205 of the remote PC once exits from the inside of the window 201 and enters the inside from the outside of the window 201 again will be described with reference to FIG.

  FIG. 19 is a diagram showing an example of a conventional remote PC screen.

  In the figure, reference numeral 201 denotes a window set to hide the mouse cursor, reference numeral 202 denotes another window set to display the mouse cursor, and reference numeral 203 denotes a remote PC screen. Reference numeral 204 denotes a server mouse cursor, and reference numeral 205 denotes a remote PC mouse cursor.

  In the initial state, it is assumed that the mouse cursor 204 of the server is at the position a and the mouse cursor 205 of the remote PC is at the position A and is at the same position. When the mouse cursor 205 of the remote PC is moved from position A to position B ', the server mouse cursor 204 is moved from position a to position b. The position B ′ and the position b are the same position.

  Next, when the mouse cursor 205 of the remote PC exceeds the frame of the window 201, the mouse cursor 204 of the server remains without moving from the position b.

  When the mouse cursor 205 of the remote PC moves from the position B to the position G along the path C, reaches the position H beyond the frame of the window 201, and moves to the position I, the mouse cursor 204 of the server moves from the position b to the position. Move to i '.

  Here, when the operator of the remote PC manually turns on the positional deviation correction function and forcibly moves the position i ′ of the server mouse cursor 204 to the position i, the remote PC mouse cursor 205 and the server mouse cursor 204 are moved. Can be operated correctly with no misalignment.

  As described above, when the mouse cursor 205 of the remote PC once exits from the inside of the window 201 and enters the inside from the outside of the window 201 again, unless the position shift correction function is executed, the mouse cursor 204 of the server Due to the displacement of the mouse cursor 205 of the remote PC, a comfortable mouse operating environment could not be provided for the remote PC mouse operator.

  The present invention has been made in view of the above problems, and an object thereof is to provide an information processing apparatus, a KVM switch, and a control program capable of providing a comfortable operating member operating environment to an operator of the information processing apparatus. There is to do.

  In order to achieve the above object, an information processing apparatus according to the present invention is connected to a server via a KVM switch to which a first operation member is connected, and a second operation member is connected to operate the second operation member. An information processing apparatus that displays a window including a cursor of an information processing apparatus that is moved by a cursor and a cursor of the server that is moved by an operation of one of the first operation member and the second operation member, wherein the second operation The coordinates on the window frame through which the cursor of the information processing apparatus moves when the cursor of the information processing apparatus moves outside the window by the operation of the member, and the position of the cursor of the server and the position of the cursor of the information processing apparatus match Storage means for storing coordinates to be performed, and when the cursor of the information processing apparatus reaches the window from outside the window, And calculating a difference between coordinates on the frame and the stored coordinates of the window, characterized in that it comprises a control means for outputting the difference to the server.

  According to this configuration, even when the cursor of the information processing apparatus moves to the outside of the window by the operation of the second operation member and reaches the window from the outside, the positional deviation between the cursor of the information processing apparatus and the cursor of the server can be corrected. A comfortable operating environment for the second operating member can be provided to the operator of the information processing apparatus. An example of the storage unit is the CPU 31 and the HDD 34 that execute the process of step S111 in FIG. 17, and an example of the control unit is the CPU 31 that executes the process of step S115 in FIG.

  Preferably, the control means moves the server cursor when the cursor of the information processing apparatus is moved outside the window and the cursor of the server is moved by the operation of the first operation member. The difference between the previous coordinate and the coordinate after the movement is calculated, the difference is stored in the storage unit, and when the cursor of the information processing apparatus reaches the window from the outside of the window, A difference between coordinates on the frame and the stored coordinates is calculated, and the difference is combined with the stored difference, and the combined value is output to the server.

  According to this configuration, even when the server cursor is moved by the operation of the first operation member while the cursor of the information processing apparatus is moving outside the window, the positional deviation between the cursor of the information processing apparatus and the cursor of the server is shifted. It can correct | amend and can provide the operation environment of the 2nd operation member comfortable with respect to the operator of information processing apparatus. The execution contents of the control means correspond to the processing in steps S113 and S114 in FIG.

  In order to achieve the above object, the KVM switch is a KVM switch to which the first operation member is connected, and the cursor of the information processing apparatus that is connected to the second operation member and moves by the operation of the second operation member, and the An information processing apparatus that displays a cursor of a server that moves by an operation of either the first operation member or the second operation member, and a KVM switch that can be connected to the server, the operation of the second operation member The coordinates on the frame of the window that pass when the cursor of the information processing apparatus moves outside the window, and the coordinates at which the cursor position of the server and the cursor position of the information processing apparatus match Storage means for acquiring and saving from the information processing apparatus, and a cursor of the information processing apparatus reaching the window from outside the window The coordinates of the arrived window frame are obtained from the information processing device, the difference between the obtained coordinates of the window frame and the stored coordinates is calculated, and the difference is calculated by the server. And a control means for outputting to the control unit.

  According to this configuration, even when the cursor of the information processing apparatus moves to the outside of the window by the operation of the second operation member and reaches the window from the outside, the positional deviation between the cursor of the information processing apparatus and the cursor of the server can be corrected. A comfortable operating environment for the second operating member can be provided to the operator of the information processing apparatus. An example of the storage unit is the controller 101 and the memory 105 that execute the process of step S121 in FIG. 18, and an example of the control unit is the controller 101 that executes the process of step S125 in FIG.

  Preferably, the control means moves the server cursor when the cursor of the information processing apparatus is moved outside the window and the cursor of the server is moved by the operation of the first operation member. The difference between the previous coordinate and the coordinate after the movement is calculated, the difference is stored in the storage unit, and when the cursor of the information processing apparatus reaches the window from the outside of the window, The coordinates on the frame are acquired from the information processing device, the difference between the acquired coordinates on the frame of the window and the stored coordinates is calculated, and the difference and the stored difference are combined and combined. A value is output to the server.

  According to this configuration, even when the server cursor is moved by the operation of the first operation member while the cursor of the information processing apparatus is moving outside the window, the positional deviation between the cursor of the information processing apparatus and the cursor of the server is shifted. It can correct | amend and can provide the operation environment of the 2nd operation member comfortable with respect to the operator of information processing apparatus. The execution contents of the control means correspond to the processing in steps S123 and S124 in FIG.

  In order to achieve the above object, a control program according to the present invention is connected to a server via a KVM switch to which a first operation member is connected, a second operation member is connected, and an operation of the second operation member is performed. An information processing apparatus that displays a window including a cursor of an information processing apparatus that moves and a cursor of the server that moves by an operation of any one of the first operation member and the second operation member. The coordinates on the frame of the window that passes when the cursor of the information processing apparatus moves outside the window, and the coordinates at which the cursor position of the server and the cursor position of the information processing apparatus match Save means for saving, and when the cursor of the information processing apparatus reaches the window from outside the window, It calculates a difference between coordinates on the frame of the window and the stored coordinates, characterized in that to function as a control means for outputting the difference to the server.

  According to this configuration, even when the cursor of the information processing apparatus moves to the outside of the window by the operation of the second operation member and reaches the window from the outside, the positional deviation between the cursor of the information processing apparatus and the cursor of the server can be corrected. A comfortable operating environment for the second operating member can be provided to the operator of the information processing apparatus.

  In order to achieve the above object, a control program according to the present invention is a KVM switch to which a first operation member is connected, and an information processing apparatus that is connected to the second operation member and moves by operation of the second operation member. An information processing apparatus that displays a cursor and a cursor of a server that is moved by an operation of one of the first operation member and the second operation member, and a KVM switch that can be connected to the server, the second operation member The position of the cursor of the server and the position of the cursor of the information processing device coincide with the coordinates on the frame of the window that pass when the cursor of the information processing device moves outside the window by the operation of Storage means for acquiring and storing coordinates from the information processing apparatus, and a cursor of the information processing apparatus from the outside of the window When reaching the dough, the coordinates on the frame of the reached window are acquired from the information processing apparatus, the difference between the acquired coordinates on the frame of the window and the stored coordinates is calculated, and the difference Is made to function as a control means for outputting to the server.

  According to this configuration, even when the cursor of the information processing apparatus moves to the outside of the window by the operation of the second operation member and reaches the window from the outside, the positional deviation between the cursor of the information processing apparatus and the cursor of the server can be corrected. A comfortable operating environment for the second operating member can be provided to the operator of the information processing apparatus.

  According to the present invention, it is possible to provide a comfortable operating environment for operating members for an operator of an information processing apparatus.

1 is a configuration diagram of a KVM system including a KVM (K: keyboard, V: video, M: mouse) switch, an information processing apparatus, and a server according to a first embodiment of the present invention. (A) is a block diagram showing a hardware configuration of the server 2a, and (B) is a block diagram showing a hardware configuration of the PC 11a. 2 is a block diagram showing a hardware configuration of a KVM switch 1. FIG. (A) is a figure which shows an example of the screen of the server 2a, (B) is the elements on larger scale of (A), (C) is a figure which shows an example of the screen of PC11a. (A) And (B) is a flowchart which shows a position shift correction function. It is a flowchart which shows the detection process of the acceleration coefficient of FIG.5 (A) step S3. (A) is a figure which shows an example of the table data created by step S16, (B) is a figure which shows an example of the table data which rounded off each value of (A), (C), It is a figure which shows an example of the table data for making the position of the mouse cursor 126 of PC11a and the position of the mouse cursor 122 of the server 2a correspond. (A) And (B) is a flowchart which shows the process performed with PC11a and KVM switch 1. FIG. (A) is the figure which modeled the data processing path | route in PC11a, KVM switch 1, and server 2a, (B) is a flowchart which shows the detection process of an acceleration coefficient. It is a figure which shows an example of the screen of PC11a. It is a flowchart which shows the case where the detection process of an acceleration coefficient is performed semiautomatically. (A) is a flowchart which shows the process performed by PC11a and KVM switch 1 concerning 2nd Embodiment, (B) is a flowchart which shows the modification of (A). (A) is a figure which shows the local (server 2a and KVM switch 1 side) screen which concerns on 3rd Embodiment, (B) is the remote (PC11a side) which concerns on 3rd Embodiment. It is a figure which shows a screen. (A) is a flowchart which shows the process performed with the KVM switch 1 and PC11a concerning 3rd Embodiment, (B) is a flowchart which shows the modification of a part of process of (A). 3 is a flowchart showing processing executed by a KVM switch 1; It is a figure which shows an example of the screen of PC11a which concerns on 4th Embodiment. It is a flowchart which shows the process which CPU31 of PC11a performs. 4 is a flowchart showing processing executed by a controller 101 of the KVM switch 1; It is a figure which shows an example of the screen of the conventional remote PC.

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

(First embodiment)
FIG. 1 is a configuration diagram of a KVM system including a KVM (K: keyboard, V: video, M: mouse) switch, an information processing apparatus, and a server according to the first embodiment of the present invention.

  As shown in the figure, the KVM system 1000 includes a KVM switch (K: keyboard, V: video, M: mouse) 1, servers 2a and 2b, a monitor 3, a keyboard 4, and a mouse 5. These constitute a local system. That is, the monitor 3 can display a video signal output from the server 2a or the server 2b, and the keyboard 4 and the mouse 5 can output data to the server 2a or the server 2b.

  Further, the multi-monitor switching system 1000 includes a PC 11a to which the monitor 12a, keyboard 13a, and mouse 14a are connected, and a PC 11b to which the monitors 12b to 12e, keyboard 13b, and mouse 14b are connected. The PC 11a and the PC 11b are remote terminals connected to the KVM switch 1 via the network 10 and constitute a so-called remote system. That is, the user can operate the server 2a or the server 2b via the network 10 and the KVM switch 1 from the remote operation application running on the PC 11a or the PC 11b.

  The server or remote terminal (PC) connected to the KVM switch 1 may be singular or plural.

  FIG. 2A is a block diagram illustrating a hardware configuration of the server 2a, and FIG. 2B is a block diagram illustrating a hardware configuration of the PC 11a. The hardware configuration of the server 2b is the same as the hardware configuration of the server 2a, and the hardware configuration of the PC 11b is the same as the hardware configuration of the PC 11a.

  The server 2a includes a CPU 21 for controlling the entire apparatus, a ROM 22 having a control program, a RAM 23 functioning as a working area, a hard disk drive (HDD) 24 having various information and programs, a video interface 26 for outputting video signals, a network An interface 27 and a USB (universal serial bus) interface 28 are provided. The CPU 21 is connected to a ROM 22, a RAM 23, a hard disk drive (HDD) 24, a video interface 26, a network interface 27, and a USB interface 28 via a system bus 29. The USB interface 28 is used to connect to the KVM switch 1 and is used when transmitting table data shown in FIGS. 7A to 7C described later to the KVM switch 1 or the PCs 11a and 11b. It is used when the table data (A) to (C) is received from the KVM switch 1 or the PCs 11a and 11b.

  The PC 11a includes a CPU 31 for controlling the entire apparatus, a ROM 32 having a control program, a RAM 33 functioning as a working area, a hard disk drive (HDD) 34 having various information and programs, a video interface 36 for outputting video signals, and a KVM switch. A network interface 37 for connecting to one or another computer and a USB (universal serial bus) interface 38 for connecting to a USB device (not shown) are provided. The CPU 31 is connected to a ROM 32, a RAM 33, a hard disk drive (HDD) 34, a video interface 36, a network interface 37, and a USB interface 38 via a system bus 39.

  The monitor 12 a is connected to the video interface 36, and the keyboard 13 a and the mouse 14 a are connected to the USB interface 38. The network interface 37 is used to connect to the KVM switch 1, and is used when transmitting table data shown in FIGS. 7A to 7C described later to the KVM switch 1 or the servers 2a and 2b. It is used when the table data (A) to (C) is received from the KVM switch 1 or the servers 2a and 2b.

  FIG. 3 is a block diagram showing a hardware configuration of the KVM switch 1.

  The KVM switch 1 includes a controller 101 that controls the operation of the entire switch, a switching circuit 102 that switches a video signal output destination and a mouse or keyboard data input destination, and interfaces (I / F) for connecting to the servers 2a and 2b, respectively. ) 103a and 103b, network interfaces (I / F) 104a and 104b for connecting to the PCs 11a and 11b via the network 10, a video interface (I / F) 106 for connecting to the monitor 3, and the keyboard 4 and the mouse 5 is provided with a keyboard / mouse interface (I / F) 107. The controller 101 includes a memory 105 that stores various control programs and data.

  The interfaces (I / F) 103a and 103b are used when transmitting table data shown in FIGS. 7A to 7C, which will be described later, to the servers 2a and 2b, respectively, as well as those shown in FIGS. 7A to 7C. It is used when receiving table data from the servers 2a and 2b, respectively. The network interfaces (I / F) 104a and 104b are used when transmitting table data shown in FIGS. 7A to 7C to be described later to the PCs 11a and 11b, respectively, and as shown in FIGS. 7A to 7C. It is used when receiving table data from the PCs 11a and 11b, respectively.

  In the following description, the server 2a is used as a representative example of the server and the PC 11a is used as a representative example of the remote terminal. However, the server and the remote terminal are not limited to these.

  In the present embodiment, table data for correcting the mouse data itself output from the mouse 14a by the PC 11a or the KVM switch 1 in order to realize a positional deviation correction function independent of the mouse cursor acceleration processing of the server 2a (FIG. 7). (See (A) to (C)). The positional deviation correction function executes a correction for matching the positions of the mouse cursors of the PC 11a displayed by the PC 11a and the mouse cursors of the server 2a displayed by the PC 11a when they do not match. It is a function.

  First, a first function for automatically creating table data for correcting mouse data will be described.

  4A is a diagram showing an example of the screen of the server 2a, FIG. 4B is a partially enlarged view of FIG. 4A, and FIG. 4C shows an example of the screen of the PC 11a. FIG. FIGS. 5A and 5B are flowcharts showing the positional deviation correction function.

  4A, reference numeral 121 indicates a screen of the server 2a, and reference numeral 122 indicates a mouse cursor of the server 2a. In FIG. 4C, reference numeral 123 indicates a screen of the PC 11a, and reference numeral 126 indicates a mouse cursor of the PC 11a. Reference numeral 124 denotes a window in which the mouse cursor 126 of the PC 11a is set not to be displayed, and reference numeral 125 denotes another window in which the mouse cursor is set to be displayed. In the window 124, the screen of the server 2a is displayed, and the mouse cursor 122 of the server 2a is displayed. The display / non-display of the mouse cursor in the window 124 and the window 125 can be set by the operating system of the PC 11a.

  In the initial state, as shown in FIG. 4A, the mouse cursor 122 of the server 2a may be at any position on the screen 121, but is assumed to be at the position a, for example. As shown in FIG. 4C, the mouse cursor 126 of the PC 11a may be at any position on the screen 123, but is assumed to be at the position A, for example. For example, even if the mouse cursor 126 of the PC 11a is located immediately above the window 125, the mouse cursor 126 of the PC 11a is moved immediately above the window 124 in this process. Good.

  5A, the CPU 31 of the PC 11a stores the current coordinates of the mouse cursor 126 of the PC 11a in the HDD 34 (step S1). As a result, the coordinates of the position A of the mouse cursor 126 in FIG.

  Next, the CPU 31 of the PC 11a outputs mouse data for moving the mouse cursor 126 of the PC 11a to the upper left corner of the window 124 to the PC 11a itself, and also displays data indicating the amount of movement of the mouse cursor 126 of the PC 11a according to the mouse data. 1 to the server 2a (step S2). As a result, the mouse cursor 122 of the server 2a in FIG. 4A moves from position a to position b, and the mouse cursor 126 in FIG. 4C moves from position A to position B.

The mouse data that can be output by the mouse 14a is 1 to 255. As shown in FIG. 4C, the size of movement of the mouse cursor 126 of the PC 11a is indicated by V _AB , and the size of movement of the mouse cursor 122 of the server 2a after reaching the server 2a is indicated by V _ab . Show. The relationship between the magnitudes of the two movements is V _AB << V _ab , and V _ab is much larger than V _AB and is not affected by the acceleration process of the server 2a, and the mouse cursor 122 and the PC 11a of the server 2a The mouse cursor 126 moves to a position B at the upper left corner of the screen 121 and a position b at the upper left corner of the window 124, respectively.

  Next, the CPU 31 of the PC 11a executes an acceleration coefficient detection process of the server 2a (step S3). This process is performed in order to examine how the data indicating the movement amount of the mouse cursor 126 of the PC 11a output from the PC 11a to the server 2a via the KVM switch 1 is accelerated by the server 2a. By this process, all the acceleration coefficients of the server 2a are grasped, and the PC 11a can output data optimized for the acceleration process executed by the server 2a via the KVM switch 1. Details of the acceleration coefficient detection processing of the server 2a will be described later.

  Finally, the CPU 31 of the PC 11a returns the mouse data for returning the mouse cursor 126 of the PC 11a from the coordinates of the upper left corner of the window 124 to the coordinates of the mouse cursor 126 of the PC 11a stored in the HDD 34 (that is, the coordinates of the position A). And data indicating the amount of movement of the mouse cursor 126 of the PC 11a according to the mouse data is output to the server 2a via the KVM switch 1 (step S4). The relationship between the mouse data in step S2 and the mouse data in step S4 is the same, but the sign is reversed. Thereby, the mouse cursor 126 of the PC 11a returns from the position B to the position A, and the mouse cursor 122 of the server 2a returns from the position b to the position a.

  In FIG. 5A, the CPU 31 position deviation correction function of the PC 11a is executed. In FIG. 5B, the controller 101 of the KVM switch 1 executes the position deviation correction function.

  5B, the controller 101 of the KVM switch 1 acquires the coordinates of the current mouse cursor 126 of the PC 11a from the PC 11a and stores them in the memory 105 (step S1-1). As a result, the coordinates of the position A of the mouse cursor 126 in FIG.

  Next, the controller 101 of the KVM switch 1 outputs mouse data for moving the mouse cursor 126 of the PC 11a to the upper left corner of the window 124 to the PC 11a, and data indicating the amount of movement of the mouse cursor 126 of the PC 11a according to the mouse data. The data is output to the server 2a (step S2-1). As a result, the mouse cursor 122 of the server 2a in FIG. 4A moves from position a to position b, and the mouse cursor 126 in FIG. 4C moves from position A to position B. The mouse data that can be output by the KVM switch 1 is 1 to 255.

  Next, the controller 101 of the KVM switch 1 executes the acceleration coefficient detection process of the server 2a (step S3-1). This process is performed in order to examine how the data indicating the movement amount of the mouse cursor 126 of the PC 11a output to the server 2a is accelerated by the server 2a. By this processing, all the acceleration coefficients of the server 2a are grasped, and the KVM switch 1 can output data optimized for the acceleration processing executed by the server 2a. Details of the acceleration coefficient detection processing of the server 2a will be described later.

  Finally, the controller 101 of the KVM switch 1 returns the mouse cursor 126 of the PC 11 a to the original position of the mouse cursor 126 of the PC 11 a stored in the memory 105 from the coordinates of the upper left corner of the window 124 (that is, the coordinates of the position A). Data is output to the PC 11a itself, and data indicating the amount of movement of the mouse cursor 126 of the PC 11a corresponding to the mouse data is output to the server 2a (step S4-1). The relationship between the mouse data in step S2-1 and the mouse data in step S4-1 is the same, but the sign is reversed. Thereby, the mouse cursor 126 of the PC 11a returns from the position B to the position A, and the mouse cursor 122 of the server 2a returns from the position b to the position a.

  FIG. 6 is a flowchart showing the acceleration coefficient detection process in step S3 of FIG.

  First, when the mouse cursor 122 of the server 2a is at the position b and the mouse cursor 126 of the PC 11a is at the position B, the CPU 31 of the PC 11a displays the closed region r surrounding the mouse cursor 122 of FIG. A bitmap corresponding to the mouse cursor 122 of the server 2a is extracted (step S11), and the movement of the mouse cursor 122 of the server 2a can be tracked inside the window 124.

  In the subsequent processing, the CPU 31 of the PC 11a outputs data indicating the amount of movement of the mouse cursor 126 of the PC 11a corresponding to each mouse data of the mouse 14a to 255 to the server 2a, and accordingly the mouse cursor 122 of the server 2a. Is detected, and the acceleration coefficient of the server 2a is detected.

  The CPU 31 of the PC 11a initializes mouse data (i), that is, sets 1 as mouse data (i = 1) (step S12). Next, the CPU 31 of the PC 11a calculates the amount of movement of the mouse cursor 126 of the PC 11a according to the set mouse data (i), and outputs data indicating the amount of movement of the mouse cursor 126 of the PC 11a to the server 2a (step S1). S13). As a result, the mouse cursor 122 of the server 2a in the window 124 moves.

  Next, the CPU 31 of the PC 11a detects the movement destination in the window 124 of the image of the mouse cursor 122 of the server 2a by pattern matching (step S14).

  The CPU 31 of the PC 11a calculates the difference between the position before the movement of the mouse cursor 122 of the server 2a and the position after the movement, and calculates the movement amount of the mouse cursor 122 of the server 2a with respect to the mouse data (i) (step S15). . This calculation of the movement amount is repeatedly executed by the loop from step S13 to step S18, the number of times corresponding to the mouse data (1 to 255) that can be output by the mouse 14a, that is, 255 times.

  The CPU 31 of the PC 11a creates table data based on the mouse data (i), the movement amount of the mouse cursor 126 of the PC 11a, and the movement amount of the mouse cursor 122 of the server 2a (step S16). The created table data is stored in the HDD 34. The table data will be described later.

  Subsequently, the CPU 31 of the PC 11a increments the mouse data (i) by 1 (step S17), and determines whether the mouse data (i) exceeds 255 (step S18).

  If the mouse data (i) does not exceed 255 in step S18 (NO), the process returns to step S13. On the other hand, if the mouse data (i) exceeds 255 in step S18 (YES), the CPU 31 of the PC 11a moves the mouse cursor 122 of the server 2a to the upper left corner of the window 124 (step S19), and this process Exit.

  The acceleration coefficient detection process in step S3-1 in FIG. 5B is executed in the same manner as in FIG. 6, but the execution subject is the controller 101 of the KVM switch 1. In this case, the controller 101 of the KVM switch 1 continuously receives the screen data of the PC 11a.

  FIG. 7A is a diagram illustrating an example of the table data created in step S16, and FIG. 7B is a diagram illustrating an example of the table data obtained by rounding each value of FIG. 7A. FIG. 7C is a diagram showing an example of table data for matching the position of the mouse cursor 126 of the PC 11a with the position of the mouse cursor 122 of the server 2a.

  In FIG. 7A, X represents mouse data corresponding to input to the PC 11a, Y represents the amount of movement of the mouse cursor 126 of the PC 11a, and Z represents the amount of movement of the mouse cursor 122 of the server 2a. At step S16, the CPU 31 of the PC 11a creates the table data of FIG. 7A. At this time, the table data of FIG. 7B obtained by rounding off the values of FIG. The table data in FIG. 7C is created by the CPU 31 of the PC 11a in step S19 and stored in the HDD 34, or is created in the controller 101 of the KVM switch 1 in step S19 and stored in the memory 105.

  In order to detect the acceleration coefficient of the server 2a, the mouse data X shown in FIGS. 7A and 7B is used. The server 2a includes the mouse data X shown in FIGS. 7A and 7B. The amount of movement Y of the mouse cursor 126 of the PC 11a shown is input. The reason why the mouse data X is different from the movement amount Y of the mouse cursor 126 of the PC 11a is that the acceleration processing of the mouse is also executed in the PC 11a.

  In order to prevent the position of the mouse cursor 122 of the server 2a from deviating from the position of the mouse cursor 126 of the PC 11a, the movement amount Y of the mouse cursor 126 of the PC 11a and the movement amount Z of the mouse cursor 122 of the server 2a match. There is a need. However, it is clear from FIG. 7B that the movement amount Y of the mouse cursor 126 of the PC 11a does not coincide with the movement amount Z of the mouse cursor 122 of the server 2a.

  Therefore, in the present embodiment, the CPU 31 of the PC 11a or the controller 101 of the KVM switch 1 causes the mouse of the PC 11a to match the movement amount Y of the mouse cursor 126 of the PC 11a and the movement amount Z of the mouse cursor 122 of the server 2a. An output conversion process for converting the output of the movement amount Y of the cursor 126 is executed. Specifically, in the output conversion process, the CPU 31 of the PC 11a or the controller 101 of the KVM switch 1 makes the movement amount Y of the mouse cursor 126 of the PC 11a and the movement amount Z of the mouse cursor 122 of the server 2a coincide with each other. Alternatively, two or more mouse data are output to the server 2a. This mouse data is data that has not been accelerated by the PC 11a and is directly input from the mouse to the PC 11a.

  The table data in FIG. 7C shows the relationship between the movement amount Y of the mouse cursor 126 of the PC 11a, the mouse data output to the server 2a, and the movement amount Z of the mouse cursor 122 of the server 2a.

  For example, if the movement amount Y = 5 of the mouse cursor 126 of the PC 11a is output from the PC 11a to the server 2a, the movement amount Z of the mouse cursor 122 of the server 2a is “7” from FIG. The mouse cursor 122 is accelerated by “2”. In this case, the movement amount Y of the mouse cursor 126 of the PC 11a does not coincide with the movement amount Z of the mouse cursor 122 of the server 2a.

  However, in FIG. 7C, when the movement amount Y of the mouse cursor 126 of the PC 11a is Y = 5, “3” as the mouse data X-1 and “1” as the mouse data X-2 are transferred from the PC 11a to the server 2a. In other words, mouse data is output in two steps. When the mouse data is “3”, the movement amount Z-1 of the mouse cursor 122 of the server 2a is “4” based on FIG. 7B, and when the mouse data is “1”, FIG. B), the movement amount Z-2 of the mouse cursor 122 of the server 2a is “1”, and the movement amount Z of the mouse cursor 122, which is the sum of the movement amount Z-1 and the movement amount Z-2, is “5”. It becomes. In this case, the movement amount Y of the mouse cursor 126 of the PC 11a matches the movement amount Z of the mouse cursor 122 of the server 2a.

  FIGS. 8A and 8B are flowcharts showing processing executed by the PC 11 a and the KVM switch 1.

  First, the process of FIG. 8A will be described.

  When the mouse 14a is operated on the PC 11a and the mouse cursor 126 of the PC 11a is moved (step S21), the CPU 31 of the PC 11a creates data on the amount of movement Y of the mouse cursor 126 of the PC 11a (step S22), and sends it to the KVM switch 1. Transmit (step S23). The controller 101 of the KVM switch 1 receives the data of the movement amount Y of the mouse cursor 126 of the PC 11a (step S24), executes the output conversion process using the table data of FIG. 7C (step S25), One or more mouse data are output to the server 2a (step S26). The server 2a receives one or more mouse data, moves the mouse cursor 122 of the server 2a (step S27), and ends this process. The movement of the mouse cursor 122 of the server 2a is displayed on the window 124 of the PC 11a.

  Next, the process in FIG. 8B will be described.

  When the mouse 14a is operated on the PC 11a and the mouse cursor 126 of the PC 11a is moved (step S31), the CPU 31 of the PC 11a executes output conversion processing using the table data of FIG. 7C (step S32). One or more mouse data are transmitted to the KVM switch 1 (step S33). The controller 101 of the KVM switch 1 receives one or more mouse data (step S34), and outputs it as it is to the server 2a (step S35). The server 2a receives one or more mouse data, moves the mouse cursor 122 of the server 2a (step S36), and ends this process. The movement of the mouse cursor 122 of the server 2a is displayed on the window 124 of the PC 11a.

  As described above, the PC 11a or the KVM switch 1 outputs the mouse data in which the positional deviation between the mouse cursor 126 of the PC 11a and the mouse cursor 122 of the server 2a does not occur to the server 2a, so that it is not affected by the mouse acceleration process of the server 2a. A positional deviation correction function can be provided, and it is not necessary to invalidate the acceleration processing of the server mouse as in the prior art. Further, as long as the mouse cursor 126 of the PC 11a is directly above the window 124, the mouse cursor 126 of the PC 11a and the mouse cursor 122 of the server 2a do not shift, and a comfortable mouse operating environment is provided to the operator of the mouse 14a. it can.

  Next, a second function for automatically creating table data for correcting mouse data will be described. Here, the server 2a automatically creates the table data of FIGS.

  In the first function, the PC 11a performs image capture and pattern matching processing of the mouse cursor 122 of the server 2a in the window 124 in order to create the table data of FIGS. 7A to 7C. .

  It is monitored on the server 2a how the movement of the mouse cursor 126 of the PC 11a is reflected on the server 2a, that is, how the mouse cursor 122 of the server 2a moves in accordance with the movement of the mouse cursor 126 of the PC 11a. It can be checked by operating the program and always detecting the position of the mouse cursor 122 of the server 2a.

  FIG. 9A is a diagram modeling data processing paths in the PC 11a, the KVM switch 1, and the server 2a.

  The HDD 24 of the server 2a includes a device driver 51, a window management system 52, and a program 53. These are read from the HDD 24 to the RAM 23 and executed by the CPU 21 as appropriate, thereby exhibiting their respective functions.

  In the figure, a path P1 indicates that an I / F (for example, Ethernet (registered trademark) or a telephone line) established between the KVM switch 1 and the PC 11a is used. The path P2 indicates that an I / F (for example, PS2 communication line or USB) established between the device driver 51 and the hardware KVM switch 1 is used. The path P3 indicates that an I / F (for example, Application Program Interface) established between the program 53 and the device driver 51 is used. The path P4 is a case where the server 2a and the KVM switch 1 are connected to a mutually connectable communication path, and an I / F established between the program 53 and the KVM switch 1 (for example, Ethernet (registered trademark) and TCP /) IP) is used. The path P5 is a case where the server 2a and the PC 11a are connected to a mutually connectable communication path, and uses an I / F (for example, Ethernet (registered trademark) and TCP / IP) established between the program 53 and the PC 11a. Indicates that

  The operations of the PC 11a, the KVM switch 1 and the server 2a will be described below.

  Data indicating the movement amount Y of the mouse cursor 126 of the PC 11a (see FIG. 7B) is notified from the PC 11a to the KVM switch 1 via the network 10. The KVM switch 1 serves as a mouse for the server 2 a, and inputs data notified from the PC 11 a to the server 2 a and passes it to the device driver 51.

  When the data indicating the movement amount Y of the mouse cursor 126 is passed to the device driver 51, the acceleration process of the server 2a is not performed, and the movement amount Y of the mouse cursor 126 is a value shown in FIG. .

  The device driver 51 passes data indicating the movement amount Y of the mouse cursor 126 to the window management system 52, and the window management system 52 performs acceleration processing and passes the data after acceleration processing to the program 53. Since the data that has passed to the program 53 has been subjected to acceleration processing, it is data indicating the amount of movement Z of the mouse cursor 122 of the server 2a in FIG. 7B. The CPU 21 moves the mouse cursor 122 of the server 2a according to the movement amount Z of the mouse cursor 122 of the server 2a on which the acceleration process has been performed.

  Thus, the data indicating the movement amount Y of the mouse cursor 126 of the PC 11a input to the server 2a is acquired by the device driver 51, and the data indicating the movement amount Z of the mouse cursor 122 of the server 2a is acquired by the program 53. . As will be described later, since the mouse data is incremented by one as described later, the device driver 51 receives “1” as the mouse data corresponding to the first received data indicating the movement amount Y of the mouse cursor 126 of the PC 11a. The mouse data corresponding to the data indicating the movement amount Y of the mouse cursor 126 of the PC 11a received next is “2”, and corresponds to the data indicating the movement amount Y of the mouse cursor 126 of the PC 11a received last. It can be determined that the mouse data is “255”. That is, the device driver 51 can acquire the value of the mouse data corresponding to the data indicating the movement amount Y of the mouse cursor 126 of the PC 11a.

  Therefore, the device driver 51 acquires data indicating the movement amount Y of the mouse cursor 126 of the PC 11a and mouse data acquired in advance by acquiring data indicating the movement amount Z of the mouse cursor 122 of the server 2a from the program 53. Based on the data indicating the movement amount Z of the mouse cursor 122 of the server 2a, the table data in FIG. 7B and the table data in FIG. 7C can be created.

  FIG. 9B is a flowchart showing acceleration coefficient detection processing.

  The device driver 51 initializes mouse data (i), that is, sets 1 as mouse data (i = 1) (step S41). Next, the device driver 51 acquires data indicating the movement amount Z of the mouse cursor 122 of the server 2a from the program 53, and data indicating the movement amount Y of the mouse cursor 126 of the PC 11a from the KVM switch 1 (step S42). The device driver 51 creates table data based on the mouse data, the movement amount Z of the mouse cursor 122 of the server 2a, and the movement amount Y of the mouse cursor 126 of the PC 11a (step S43). This table data is shown in FIG. 7A. The device driver 51 rounds off the mouse data, the movement amount Z of the mouse cursor 122 of the server 2a, and the movement amount Y of the mouse cursor 126 of the PC 11a. The table data in FIG. 7B is acquired.

  Next, the device driver 51 increments the mouse data by 1 (step S44), and determines whether the mouse data exceeds 255 (step S45).

  If the mouse data does not exceed 255 in step S45 (NO), the process returns to step S42. On the other hand, if the mouse data exceeds 255 in step S45 (YES), this process ends. After the completion of this process, the device driver 51 creates the table data in FIG. 7C based on the table data in FIG.

  In the above processing, the table data of FIGS. 7A to 7C is created by the device driver 51. However, the data indicating the movement amount Y of the mouse cursor 126 of the PC 11a and the mouse data are also obtained by the KVM switch 1 and the PC 11a. Since the data is acquired, the data indicating the movement amount Z of the mouse cursor 122 of the server 2a is transferred to the KVM switch 1 or the PC 11a using the path P1 or the path P2, and the KVM switch 1 or the PC 11a uses FIG. You may create the table data of FIG.7 (C).

  Further, the KVM switch 1 acquires data indicating the movement amount Z of the mouse cursor 122 of the server 2a from the program 53, creates the table data of FIGS. 7A to 7C, and self-holds it. The data may be transferred to the device driver 51 or the PC 11a. Further, the PC 11a acquires data indicating the movement amount Z of the mouse cursor 122 of the server 2a from the program 53, creates the table data shown in FIGS. 7A to 7C, holds the data itself, The data may be transferred to the driver 51 or the KVM switch 1.

  As described above, the table data shown in FIGS. 7A to 7C can be created by any of the PC 11a, the KVM switch 1, or the device driver 51. Further, the output conversion process executed based on the table data of FIG. 7C (that is, the amount of movement Y of the mouse cursor 126 of the PC 11a and the amount of movement Z of the mouse cursor 122 of the server 2a coincide with each other). Alternatively, the process of outputting two or more mouse data to the server 2a (more specifically, the program 53) may be executed up to the previous stage of the window management system 52. In the server 2a, the device driver 51 executes output conversion processing based on the table data of FIG.

  Next, a case where the acceleration coefficient detection process is executed semi-automatically will be described. Semi-automatic means that the operation of the operator of the PC 11a is necessary.

  FIG. 10 is a diagram illustrating an example of the screen of the PC 11a.

  In FIG. 10, reference numeral 123 indicates a screen of the PC 11a, and reference numeral 126 indicates a mouse cursor of the PC 11a. Reference numeral 124 indicates a window in which the screen of the server 2a is displayed, and reference numeral 125 indicates another window. In the window 124, the mouse cursor 122 of the server 2a is displayed, and the mouse cursor of the PC 11a is also displayed. However, the mouse cursor of the PC 11a is displayed only in the case of this processing, and normally, the mouse cursor of the PC 11a is set to non-display on the window 124.

  In FIG. 10, in the initial state, the position A of the mouse cursor 126 of the PC 11a and the position a of the mouse cursor 122 of the server 2a may be in any positions. However, the CPU 31 of the PC 11a stores the coordinates of the position A of the mouse cursor 126 of the PC 11a and the coordinates of the position a of the mouse cursor 122 of the server 2a in the HDD 34 in advance.

  The CPU 31 of the PC 11a first outputs data for moving the mouse cursor 122 of the server 2a to the server 2a, and moves the mouse cursor 122 of the server 2a from position a to position b. The operator of the PC 11a moves the mouse cursor 126 of the PC 11a and clicks the arrowhead of the mouse cursor 122 of the server 2a at the position b. By this click, the CPU 31 of the PC 11a can recognize that the position b of the mouse cursor 122 of the server 2a and the position of the mouse cursor 122 of the server 2a are the same position. At this time, the CPU 31 of the PC 11a does not output data indicating the amount of movement of the mouse cursor 126 of the PC 11a to the server 2a. This is because if the data indicating the amount of movement of the mouse cursor 126 of the PC 11a is output to the server 2a, the mouse cursor 122 of the server 2a is moved in conjunction with the movement of the mouse cursor 126 of the PC 11a and cannot be clicked. Because.

  Next, the CPU 31 of the PC 11a outputs data for moving the mouse cursor 122 of the server 2a to the server 2a. When the mouse cursor 122 of the server 2a moves from the position b to the position c, the operator of the PC 11a The mouse cursor 126 is moved, and the arrow tip of the mouse cursor 122 of the server 2a at the position c is clicked.

  As a result, it is understood how the data output from the CPU 31 of the PC 11a, which is obtained by moving the mouse cursor 122 of the server 2a from the position b to the position c, is accelerated by the server 2a. The CPU 31 of the PC 11a The relationship between the amount of movement of the cursor 126 from position b to position c and the amount of movement of the server 2a from the position b to position c of the mouse cursor 122 can be determined.

  In this way, the mouse cursor 122 of the server 2a is sequentially moved from position a to position h, and each time the operator of the PC 11a moves the mouse cursor 126 of the PC 11a and clicks the arrowhead of the mouse cursor 122 of the server 2a. Thus, the CPU 31 of the PC 11a determines the relationship between the amount of movement of the mouse cursor 126 of the PC 11a and the amount of movement of the mouse cursor 122 of the server 2a.

  FIG. 11 is a flowchart illustrating a case where the acceleration coefficient detection process is executed semi-automatically.

  First, the CPU 31 of the PC 11a initializes mouse data (i), that is, sets 1 as mouse data (i = 1) (step S61). Next, the CPU 31 of the PC 11a calculates the amount of movement of the mouse cursor 126 of the PC 11a according to the set mouse data (i), and outputs data indicating the amount of movement of the mouse cursor 126 of the PC 11a to the server 2a (step S1). S62). As a result, the mouse cursor 122 of the server 2a in the window 124 moves.

  Next, the CPU 31 of the PC 11a detects the coordinates clicked by the mouse cursor 126 of the PC 11a by the operator of the PC 11a (step S63).

  The CPU 31 of the PC 11a calculates the difference between the coordinates clicked last time and the coordinates clicked this time, and calculates the amount of movement of the mouse cursor 122 of the server 2a relative to the mouse data (i) (step S64). This calculation of the movement amount is repeatedly executed by the loop from step S13 to step S18, the number of times corresponding to the mouse data (1 to 255) that can be output by the mouse 14a, that is, 255 times. Note that the coordinates of the mouse cursor 122 of the server 2a in the initial state are those stored in the HDD 34.

  The CPU 31 of the PC 11a creates table data based on the mouse data (i), the movement amount of the mouse cursor 126 of the PC 11a, and the movement amount of the mouse cursor 122 of the server 2a (step S65). The created table data is stored in the HDD 34. The table data created here are shown in FIGS. 7A and 7B.

  Subsequently, the CPU 31 of the PC 11a increments the mouse data (i) by 1 (step S66), and determines whether or not the mouse data (i) exceeds 255 (step S67).

  If the mouse data (i) does not exceed 255 in step S67 (NO), the process returns to step S62. On the other hand, if the mouse data (i) exceeds 255 in step S67 (YES), the CPU 31 of the PC 11a moves the mouse cursor 122 of the server 2a to the upper left corner of the window 124 (step S68), and this process Exit. After this process is completed, the CPU 31 of the PC 11a creates the table data of FIG. 7C based on the table data of FIG. 7B.

  The function of executing the acceleration coefficient detection process semi-automatically is effective when the CPU 31 of the PC 11a cannot capture the closed area r surrounding the mouse cursor 122 of the server 2a on the area of the image displayed in the window 124. . This is because the shape of the cursor used by the operating system or the window system of the PC 11a is normally an arrow shape as shown in FIG. 10, but it is a finger shape or a point instead of an arrow. This is because the shape of the mouse cursor may not be determined depending on the preference of the operator of the server 2a. Even in such a situation, the operator of the PC 11a can specify the coordinates of the mouse cursor 122 of the server 2a by clicking the arrowhead of the mouse cursor 122 of the server 2a. As described above, the table data shown in FIG. 7C can be created even by using the function of executing the acceleration coefficient detection process semi-automatically.

  Note that the output conversion process using the table data in FIG. 7C is executed up to the preceding stage of the window management system 52 as described above.

(Second Embodiment)
As described in Problem 2 above, even if the mouse cursor 205 of the remote PC (corresponding to the PC 11) is hidden, if the mouse cursor 205 of the remote PC exceeds the frame of the window 201 in FIG. Cannot be remotely controlled.

  Therefore, in the present embodiment, a process of limiting the movement range of the mouse cursor 126 of the PC 11a before the process executed by the PC 11a and the KVM switch 1 of FIG. 8A or FIG. A process for enabling the selection of whether the process for limiting the movement range is valid or invalid is added.

  Note that the KVM system of the present embodiment has the same configuration as the KVM system 1000 of the first embodiment.

  FIG. 12A is a flowchart illustrating processing executed by the PC 11a and the KVM switch 1 according to the second embodiment.

  The CPU 31 of the PC 11a determines whether or not to enable the limitation on the movement range of the mouse cursor 126 of the PC 11a (step S71). Specifically, the CPU 31 of the PC 11a has a menu for restricting the movement range of the mouse cursor 126 of the PC 11a or a function key of the keyboard 13a to which an instruction to limit the movement range of the mouse cursor 126 of the PC 11a is assigned. Determine if it is selected. In this case, when the function key is pressed or when the menu is selected, the CPU 31 of the PC 11a determines that the restriction on the movement range of the mouse cursor 126 of the PC 11a is valid. When the function key is not pressed or the menu is not selected, the CPU 31 of the PC 11a determines that the restriction on the movement range of the mouse cursor 126 of the PC 11a is invalidated.

  If it is determined in step S71 that the restriction on the movement range of the mouse cursor 126 of the PC 11a is to be validated (YES), the CPU 31 of the PC 11a calls a function possessed by the operating system of the PC 11a and sets the mouse cursor 126 of the PC 11a. The movement range is limited to the window 124 (step S72). The function of the operating system of the PC 11a is, for example, an API (Application Program Interface) called ClipCursor of Microsoft Windows (registered trademark). This API generally limits the range of movement of the mouse cursor within a rectangular area on the window.

  After the process of step S72, the processes of steps S21 to S27 in FIG. 8A or steps S31 to S36 in FIG. 8B described above are executed (step S73), and this process ends.

  On the other hand, if it is determined in step S71 that the limitation on the movement range of the mouse cursor 126 of the PC 11a is invalidated (NO), this process is terminated.

  The execution subject of steps S71 and S72 in FIG. 12A is the CPU 31 of the PC 11a, but the controller 101 of the KVM switch 1 can also execute the processes of steps S71 and S72. Processing in this case is shown in FIG.

  In step S71a, the controller 101 of the KVM switch 1 indicates that a predetermined switch (not shown) on the KVM switch to which an instruction to limit the movement range of the mouse cursor 126 of the PC 11a is assigned or in the memory 105 It is determined whether or not the menu that limits the movement range of the mouse cursor 126 of the PC 11a is selected. If the controller 101 of the KVM switch 1 corresponds to any one (YES in step S71a), the function of the operating system of the PC 11a is called, and the movement range of the mouse cursor 126 of the PC 11a is displayed in the window 124. Limit (step S72a).

  As described above, in this embodiment, when the movement range of the mouse cursor 126 of the PC 11a is limited within the window 124, the output conversion process is executed. Therefore, when the movement range of the mouse cursor 126 of the PC 11a is limited within the window 124, a positional deviation between the mouse cursor 126 of the PC 11a and the mouse cursor 122 of the server 2a does not occur, and a comfortable mouse operating environment is provided. it can.

(Third embodiment)
In the present embodiment, a case will be described in which the mouse cursor 122 of the server 2a is alternately operated locally or remotely.

  Here, local refers to the server 2a and the KVM switch 1 side, and remote refers to the PC 11a side.

  In the present embodiment, it is assumed that the table data of FIGS. 7B and 7C are stored in the memory 105 of the KVM switch 1 and the HDD 34 of the PC 11a. Further, in the present embodiment, description will be made on the assumption that addition processing is performed when a mouse operation is performed in the server 2a and the PC 11a.

  The KVM system of the present embodiment has the same configuration as the KVM system 1000 of the first embodiment.

  Hereinafter, processing executed by the KVM switch 1 and the PC 11a will be described with reference to FIGS.

  FIG. 13A is a diagram showing a local (server 2a and KVM switch 1 side) screen, and FIG. 13B is a diagram showing a remote (PC 11a side) screen.

  In FIG. 13A, reference numeral 121 indicates a local screen, and reference numeral 122 indicates a mouse cursor of the server 2a. In FIG. 13B, reference numeral 123 indicates a remote screen, and reference numeral 126 indicates a mouse cursor of the PC 11a. Reference numeral 124 denotes a window in which the mouse cursor 126 of the PC 11a is set not to be displayed, and reference numeral 125 denotes another window in which the mouse cursor is set to be displayed. A local screen is displayed in the window 124. The display / non-display of the mouse cursor in the window 124 and the window 125 can be set by the operating system of the PC 11a.

Assuming that the position of the mouse cursor 126 of the PC 11a at the time of switching from the remote mouse operation to the local mouse operation is position A, the position of the mouse cursor 122 of the server 2a is at position a. When the mouse cursor 122 of the server 2a moves from the position a to the position b by the local mouse operation, the movement amount of the mouse cursor 122 of the server 2a, that is, the KVM switch 1 is finally transferred to the server 2a. accumulated value of the output data becomes V _ab.

Here, it is assumed that the position of the mouse cursor 122 of the server 2a when the local mouse operation is switched to the remote mouse operation is a position b, and the position of the mouse cursor 126 of the PC 11a is a position B. When the local mouse operation is switched to the remote mouse operation and the mouse cursor 126 of the PC 11a is moved in any direction by the remote mouse operation, the CPU 31 of the PC 11a uses the movement amount V _ab of the mouse cursor 122 of the server 2a as the server. 2b, the position b is calculated from the movement amount _Vab and the coordinates of the position a, and the difference ( _{Vb '} ) between the position b and the position B of the mouse cursor 122 of the server 2a is calculated. Then, the CPU 31 of the PC 11a adds the amount of movement of the mouse cursor 126 of the PC 11a and the difference (V _{b ′} ) between the calculated position b and position B, and adds up using the table data of FIG. One or more mouse data corresponding to the set value is output to the server 2a.

  FIG. 14A is a flowchart illustrating processing executed by the KVM switch 1 and the PC 11a according to the third embodiment.

  First, the CPU 31 of the PC 11a determines the position of the mouse cursor 126 of the PC 11a at the time of switching from the remote (PC 11a side) mouse operation to the local (server 2a and KVM switch 1 side) mouse operation, that is, the final of the remote mouse operation. The position is stored in the HDD 34 (step S81).

  Next, the controller 101 of the KVM switch 1 outputs the accumulated value of the data output to the server 2a to the PC 11a during local mouse operation (step S82). Here, the data output from the KVM switch 1 to the server 2a corresponds to the movement amount Y of the mouse cursor 126 of the PC 11a in the table data of FIG. 7B or FIG.

  The CPU 31 of the PC 11a acquires the cumulative value of the data output from the KVM switch 1 to the server 2a (step S83). Next, the CPU 31 of the PC 11a switches from the local mouse operation to the remote mouse operation, and when the mouse cursor 126 of the PC 11a is moved in any direction by the remote mouse operation (step S84), the remote stored in the HDD 34 is performed. The position of the mouse cursor 122 of the current server 2a is calculated based on the final position of the mouse operation and the accumulated value of the data output by the KVM switch 1 to the server 2a (step S85), and the mouse cursor 122 of the current server 2a is calculated. And the current position of the mouse cursor 126 of the PC 11a are calculated (step S86).

  Next, the CPU 31 of the PC 11a adds the amount of movement of the mouse cursor 126 of the PC 11a and the difference calculated in step S85, and 1 or 2 or more corresponding to the value added using the table data of FIG. Mouse data is output to the server 2a (step S87). Specifically, the CPU 31 of the PC 11a obtains the value of the movement amount Y of the mouse cursor 126 of the PC 11a that matches the summed value, and outputs one or more mouse data corresponding to this value to the server 2a. .

  With the above processing, when the local mouse operation is switched to the remote mouse operation, the position of the mouse cursor 122 of the server 2a matches the position of the mouse cursor 126 of the PC 11a.

  Instead of steps S82 and S83, the process of FIG. 14B may be executed. In this case, all the processes can be executed by the CPU 31 of the PC 11a.

  In FIG. 14B, after the process of step S81, the CPU 31 of the PC 11a captures the image of the mouse cursor 122 of the server 2a in the window 124 as described in the first embodiment (step S91). Then, the movement destination in the window 124 of the image of the mouse cursor 122 of the server 2a is detected by pattern matching (step S92), and the position before the movement of the mouse cursor 122 (that is, the remote mouse operation is switched to the local mouse operation). The difference between the position of the mouse cursor 122 at the time) and the position after the movement (that is, the position of the mouse cursor 122 when the local mouse operation is switched to the remote mouse operation) is calculated and moved by the local mouse operation. Calculate the amount of movement of the mouse cursor 122 of the server 2a Step S93).

  Then, the CPU 31 of the PC 11a uses the table data of FIG. 7B to indicate the movement amount of the mouse cursor 126 of the PC 11a corresponding to the calculated movement amount of the mouse cursor 122 of the server 2a, and the KVM switch 1 uses the server 2a. (Step S94), and the process proceeds to step S84.

  Next, an example in which the controller 101 of the KVM switch 1 executes the process of FIG.

  FIG. 15 is a flowchart showing processing executed by the KVM switch 1.

  First, the controller 101 of the KVM switch 1 determines the position of the mouse cursor 126 of the PC 11a at the time of switching from the remote (PC 11a side) mouse operation to the local (server 2a and KVM switch 1 side) mouse operation, that is, the remote mouse. The final position of the operation is acquired from the PC 11a and stored in the memory 105 (step S101).

  Next, the controller 101 of the KVM switch 1 stores the accumulated value of the data output to the server 2a during the local mouse operation in the memory 105 (step S102).

  Next, the controller 101 of the KVM switch 1 acquires from the PC 11a the position of the mouse cursor 126 of the PC 11a when the local mouse operation is switched to the remote mouse operation (step S103). The controller 101 of the KVM switch 1 calculates the current position of the mouse cursor 122 of the server 2a based on the final position of the remote mouse operation stored in the memory 105 and the accumulated value of the data output to the server 2a (step S1). In step S104, the difference between the current position of the mouse cursor 122 of the server 2a and the position of the mouse cursor 126 of the PC 11a acquired in step S103 is calculated (step S105).

  After that, when the controller 101 of the KVM switch 1 receives the data indicating the movement amount of the mouse cursor 126 of the PC 11a from the PC 11a, the movement amount of the mouse cursor 126 of the PC 11a and the difference calculated in step S105 are added together. One or two or more mouse data corresponding to the values added using the table data of 7 (C) are output to the server 2a (step S106). Specifically, the CPU 31 of the PC 11a obtains the value of the movement amount Y of the mouse cursor 126 of the PC 11a that matches the summed value, and outputs one or more mouse data corresponding to this value to the server 2a. .

  With the above processing, when the local mouse operation is switched to the remote mouse operation, the position of the mouse cursor 122 of the server 2a matches the position of the mouse cursor 126 of the PC 11a.

  14A, 14B, or 15, even when the mouse cursor 122 of the server 2a is alternately operated locally or remotely, the positional deviation between the mouse cursor of the PC 11a and the mouse cursor of the server 2a is not changed. It can be corrected, and a comfortable mouse operating environment can be provided to the operator of the mouse 14a.

  The present embodiment has been described on the assumption that the addition process is performed when the mouse operation is performed in the server 2a and the PC 11a. However, as in the conventional case, in the KVM system that invalidates the addition process of the server 2a and the PC 11a. The mouse data inputted and outputted by the server 2a, the KVM switch 1 and the PC 11a are all the same.

  For this reason, even in the KVM system that invalidates the addition processing of the server 2a and the PC 11a, the processing of FIGS. 14A, 14B, and 15 can be applied, but FIGS. 7B and 7C. There is no need to use the table data. In this case, in step S87, the CPU 31 of the PC 11a adds the movement amount of the mouse cursor 126 of the PC 11a and the difference calculated in step S85, and outputs the data of the added value to the server 2a. In step S94, the calculated movement amount of the mouse cursor 122 of the server 2a is the cumulative value of the data output from the KVM switch 1 to the server 2a. Further, in step S106, the amount of movement of the mouse cursor 126 of the PC 11a and the difference calculated in step S105 are summed, and data of the sum is output to the server 2a.

(Fourth embodiment)
In the present embodiment, a position correction process executed when the mouse cursor 126 of the PC 11a once exits from the inside of the window 124 and enters the inside from the outside of the window 124 again will be described.

  The KVM system of the present embodiment has the same configuration as the KVM system 1000 of the first embodiment.

  FIG. 16 is a diagram illustrating an example of a screen of the PC 11a.

  In FIG. 16, reference numeral 122 indicates the mouse cursor of the server 2a, reference numeral 123 indicates the screen of the PC 11a, and reference numeral 126 indicates the mouse cursor of the PC 11a. Reference numeral 124 denotes a window in which the mouse cursor 126 of the PC 11a is set not to be displayed, and reference numeral 125 denotes another window in which the mouse cursor is set to be displayed. In the window 124, a local (server 2a) screen is displayed. The display / non-display of the mouse cursor in the window 124 and the window 125 can be set by the operating system of the PC 11a.

  First, it is assumed that there is no positional deviation between the mouse cursor 126 of the PC 11a and the mouse cursor 122 of the server 2a. When the mouse cursor 126 of the PC 11a moves from the position A to the position B on the frame of the window 124, the CPU 31 of the PC 11a stores the coordinates of the position B in the HDD 34. At this time, the mouse cursor 122 of the server 2a is at the same position b as the position B.

Thereafter, the mouse cursor 126 of the PC 11 a follows an arbitrary path C outside the window 124 and reaches a position G on the frame of the window 124 by the mouse operation of the operator of the PC 11 a. At this time, the difference between the coordinates of the position B and the coordinates of the position G is _VBG .

The CPU 31 of the PC 11a calculates a difference V _BG between the coordinates of the position B and the coordinates of the position G stored in the HDD 34 at the moment when the position G on the frame of the window 124 is reached, and outputs the calculated difference to the server 2a. To do. Thereby, the mouse cursor 122 of the server 2a moves from the position b to the position g. Position g and position G are the same position.

In addition, while the mouse cursor 126 of the PC 11a is following an arbitrary path C outside the window 124, the mouse cursor 122 of the server 2a follows the locus x by the local mouse operation and moves from the position b to the position b ′. The CPU 31 of the PC 11 a calculates a difference V _b′b between the coordinates of the position b and the coordinates of the position b ′ in advance and stores it in the _{HDD 34} .

After that, the CPU 31 of the PC 11 a calculates the difference V _BG between the coordinates of the position B and the coordinates of the position G stored in the HDD 34 at the moment when the position G on the frame of the window 124 is reached, and the difference V _BG stored in the HDD 34. _b′b and the difference V _BG are combined, and the combined value V _b′G is output to the server 2a. Thereby, the mouse cursor 122 of the server 2a moves from the position b ′ to the position g.

  After the mouse cursor 126 of the PC 11a enters the inside of the window 124 from the position G, the processing described in the first to third embodiments is executed, so the mouse cursor 126 of the PC 11a and the server 2a are executed. No positional deviation of the mouse cursor 122 occurs.

  FIG. 17 is a flowchart showing processing executed by the CPU 31 of the PC 11a.

  First, the CPU 31 of the PC 11a stores the coordinates on the frame of the window 124 when the mouse cursor 126 of the PC 11a goes outside the window 124 in the HDD 34 (step S111). Next, the CPU 31 of the PC 11a determines whether or not the mouse cursor 122 of the server 2a has been moved by a local mouse operation (step S112).

  If YES in step S112, the CPU 31 of the PC 11a calculates a difference between the coordinates of the position of the mouse cursor 122 before the movement of the server 2a and the coordinates of the position after the movement, and stores the difference in the HDD 34 (step S112). S113).

  Next, when the mouse cursor 126 of the PC 11a reaches the frame of the window 124 again, the CPU 31 of the PC 11a calculates the difference between the coordinates on the window 124 when the mouse cursor 126 reaches the frame of the window 124 and the coordinates stored in the HDD 34 in step S111. Is calculated, and the difference is combined with the difference of the movement of the mouse cursor 122 of the server 2a stored in the HDD 34 in step S113, and the combined value is output to the server 2a (step S114), and this process ends.

  On the other hand, if NO in step S112, when the mouse cursor 126 of the PC 11a reaches the frame of the window 124 again, the CPU 31 of the PC 11a stores the coordinates on the frame of the window 124 and the HDD 34 when the mouse cursor 126 reaches the frame. The difference with the coordinate is calculated, the difference is output to the server 2a (step S115), and this process is terminated.

  FIG. 18 is a flowchart illustrating processing executed by the controller 101 of the KVM switch 1.

  First, the controller 101 of the KVM switch 1 acquires the coordinates on the frame of the window 124 when the mouse cursor 126 of the PC 11a goes outside the window 124, and stores it in the memory 105 (step S121). Next, the controller 101 of the KVM switch 1 determines whether or not the mouse cursor 122 of the server 2a has been moved by a local mouse operation (step S122).

  If YES in step S122, the controller 101 of the KVM switch 1 calculates the difference between the coordinates of the position of the server 2a before the mouse cursor 122 is moved and the coordinates of the position after the movement, and stores the difference in the memory 105. Save (step S123).

  Next, when the mouse cursor 126 of the PC 11a reaches the frame of the window 124 again, the controller 101 of the KVM switch 1 acquires the coordinates on the frame of the window 124 when the mouse cursor 126 arrives from the PC 11a. The difference between the coordinates and the coordinates stored in the memory 105 in step S121 is calculated, and the difference is combined with the movement difference of the mouse cursor 122 of the server 2a stored in the memory 105 in step S123. 2a (step S124), and this process is terminated.

  On the other hand, in the case of NO in step S122, when the mouse cursor 126 of the PC 11a arrives again on the frame of the window 124, the controller 101 of the KVM switch 1 sets the coordinates on the frame of the window 124 when the mouse cursor 126 arrives. The difference between the acquired coordinates and the coordinates stored in the memory 105 is calculated from the PC 11a, the difference is output to the server 2a (step S125), and the process is terminated.

  17 or 18, when the mouse cursor 126 of the PC 11 a once goes out of the frame of the window 124 and returns to the frame of the window 124 again, the mouse cursor 126 of the PC 11 a and the server 2 a are automatically set. Since the displacement of the mouse cursor 122 is corrected, a comfortable mouse operating environment can be provided to the operator of the mouse 14a.

  In the present embodiment, one window on which the server mouse cursor is displayed is displayed on the screen 123 of the PC 11a (see window 124). For example, the screen 123 of the PC 11a displays the server mouse cursor. When a plurality of windows are displayed (that is, when a plurality of windows for a plurality of servers are displayed), the processing of FIG. 17 or FIG. 18 is executed for each window.

  In the prior art, the remote PC operator manually activates the misalignment correction function every time the mouse cursor of the remote PC goes out of the window frame where the server mouse cursor is displayed and moves to another window. Since the positional deviation between the PC mouse cursor and the server mouse cursor was corrected, the remote PC operator felt troublesome.

  Even in such a case, by executing the processing of FIG. 17 or FIG. 18, the positional deviation between the mouse cursor of the remote PC and the mouse cursor of the server is automatically corrected. A comfortable mouse operation environment can be provided without feeling.

  In the first to fourth embodiments, the mouse 14a is used to operate the mouse cursor 126 of the PC 11a, and the mouse 14a or the mouse 5 is used to operate the mouse cursor 122 of the server 2a. The operation member for operating the mouse cursor 126 of the PC 11a or the mouse cursor 122 of the server 2a is not limited to the mouse, and may be an operation member having a function of moving the mouse cursor such as a tablet.

  The first medium is also provided by supplying a recording medium in which a software program for realizing the function of each server is recorded to the server, and the CPU of the server reads and executes the program stored in the storage medium. -There exists an effect similar to 4th Embodiment. In addition, a recording medium in which a software program for realizing the function of each remote terminal is recorded is supplied to the remote terminal, and the CPU of the remote terminal reads and executes the program stored in the storage medium. Has the same effect as the first to fourth embodiments. Further, a recording medium on which a software program for realizing the function of the KVM switch 1 is recorded is supplied to the KVM switch 1, and the controller 101 of the KVM switch 1 reads and executes the program stored in the storage medium. Even in this case, the same effects as those of the first to fourth embodiments can be obtained. In this case, the KVM switch 1 includes a device (such as a CD-ROM drive or a DVD-ROM drive) that reads a program from a storage medium. Note that the storage medium for supplying the program includes, for example, a CD-ROM, a DVD, or an SD card.

  Further, the same effects as those of the first to fourth embodiments can be obtained by the CPU of each server executing a software program for realizing the function of each server. Further, the same effects as those of the first to fourth embodiments can be obtained by the CPU of each remote terminal executing a software program for realizing the function of each remote terminal. Further, when the controller 101 of the KVM switch 1 executes a software program (for example, a driver) for realizing the function of the KVM switch 1, the same effects as in the first to fourth embodiments can be obtained. Play.

  Note that the present invention is not limited to the above-described embodiment, and can be implemented with various modifications without departing from the scope of the invention.

1 KVM switch 2a, 2b Server 3, 12a, 12b Monitor 4, 13a, 13b Keyboard 5, 14a, 14b Mouse 21, 31 CPU
22,32 ROM
23,33 RAM
24, 34 Hard Disk Drive (HDD)
26, 36 Video interface 27, 37 Network interface 28, 38 USB interface 101 Controller 102 Switching circuit 105 Memory

Claims (6)

The first operation member is connected to the server via the KVM switch to which the first operation member is connected, the second operation member is connected, and the cursor of the information processing apparatus that moves by the operation of the second operation member, the first operation member, An information processing apparatus for displaying a window including a cursor of the server that is moved by any operation of the second operation member,
The coordinates on the frame of the window that pass when the cursor of the information processing apparatus moves outside the window by the operation of the second operation member, and the position of the cursor of the server and the cursor of the information processing apparatus Storage means for storing coordinates that coincide with the position;
When the cursor of the information processing apparatus reaches the window from the outside of the window, the difference between the coordinates on the frame of the reached window and the stored coordinates is calculated, and the difference is output to the server An information processing apparatus comprising: a control unit. When the cursor of the information processing apparatus is moved outside the window and the cursor of the server is moved by the operation of the first operation member, the control means is configured to adjust the coordinates of the server before the cursor is moved. And the difference between the coordinates after movement and the difference is stored in the storage means,
When the cursor of the information processing apparatus reaches the window from the outside of the window, the difference between the coordinates on the frame of the reached window and the stored coordinates is calculated, and the difference and the stored difference The information processing apparatus according to claim 1, wherein the combined value is output to the server. A KVM switch to which the first operation member is connected, and a cursor of the information processing apparatus that is moved by the operation of the second operation member while the second operation member is connected, the first operation member, and the second operation member; An information processing device that displays a cursor of a server that is moved by any operation, and a KVM switch that can be connected to the server,
The coordinates on the frame of the window that pass when the cursor of the information processing apparatus moves outside the window by the operation of the second operation member, and the position of the cursor of the server and the cursor of the information processing apparatus Storage means for acquiring and storing coordinates corresponding to the position from the information processing apparatus;
When the cursor of the information processing apparatus reaches the window from the outside of the window, the coordinates on the frame of the reached window are acquired from the information processing apparatus, and the coordinates on the acquired frame of the window and the coordinates of the acquired window A KVM switch comprising: control means for calculating a difference from the stored coordinates and outputting the difference to the server. When the cursor of the information processing apparatus is moved outside the window and the cursor of the server is moved by the operation of the first operation member, the control means is configured to adjust the coordinates of the server before the cursor is moved. And the difference between the coordinates after movement and the difference is stored in the storage means,
When the cursor of the information processing apparatus reaches the window from the outside of the window, the coordinates on the frame of the reached window are acquired from the information processing apparatus, and the coordinates on the acquired frame of the window and the coordinates of the acquired window 4. The KVM switch according to claim 3, wherein the difference between the stored coordinates is calculated, the difference is combined with the stored difference, and the combined value is output to the server. The first operation member is connected to the server via the KVM switch to which the first operation member is connected, the second operation member is connected, and the cursor of the information processing apparatus that moves by the operation of the second operation member, the first operation member, An information processing apparatus for displaying a window including a cursor of the server that is moved by any operation of the second operation member;
The coordinates on the frame of the window that pass when the cursor of the information processing apparatus moves outside the window by the operation of the second operation member, and the position of the cursor of the server and the cursor of the information processing apparatus Storage means for storing coordinates that coincide with the position; and when the cursor of the information processing apparatus reaches the window from outside the window, the coordinates on the frame of the reached window and the stored coordinates A control program for calculating a difference and functioning as control means for outputting the difference to the server. A KVM switch to which the first operation member is connected, and a cursor of the information processing apparatus that is moved by the operation of the second operation member while the second operation member is connected, the first operation member, and the second operation member; An information processing device that displays a cursor of a server that is moved by any operation, and a KVM switch that can be connected to the server,
The coordinates on the frame of the window that pass when the cursor of the information processing apparatus moves outside the window by the operation of the second operation member, and the position of the cursor of the server and the cursor of the information processing apparatus A storage unit that acquires and stores coordinates that coincide with a position from the information processing apparatus; and when a cursor of the information processing apparatus reaches the window from outside the window, coordinates on the frame of the reached window are obtained. Control that is obtained from the information processing apparatus, calculates a difference between coordinates on the acquired window frame and the stored coordinates, and functions as a control unit that outputs the difference to the server program.

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