WO2007020408A1

WO2007020408A1 - A display system and method of operating a display system

Info

Publication number: WO2007020408A1
Application number: PCT/GB2006/003018
Authority: WO
Inventors: James Quentin Stafford-Fraser; Martin Towle King
Original assignee: Displaylink (Uk) Limited
Priority date: 2005-08-13
Filing date: 2006-08-11
Publication date: 2007-02-22
Also published as: GB0516713D0

Abstract

A display system comprises a plurality of display devices, each displaying respectively an image, a data processing device connected to each display device and controlling the image displayed by each display device, and a user interface device connected to the data processing device. The system is arranged, following a defined user input at the user interface, for at least two of the display devices, to move at least a portion of the image displayed to a different display device. When carrying out the moving of the at least a portion of the image displayed to a different display device, the system is arranged to scroll the at least a portion of the image between the two display devices.

Description

DESCRIPTION

A DISPLAY SYSTEM AND METHOD OF OPERATING A DISPLAY SYSTEM

This invention relates to a display system and to a method of operating a display system.

In most situations where a user is working with a computer with multiple displays, one of the displays will be more convenient to work with than the others, usually because it is directly in front of the user on their desk. This display device can be considered to be the 'primary display', though there may be more than one that is equally important to the user. The other displays will usually show more 'peripheral' information, which is not needed so regularly, or with which the user is not currently interacting. To transfer information from one display device to another display device, the user will "drag and drop" the required display element (usually an individual window) using the computer mouse. This method of transferring images between display device, can in many instances be overly complicated. A different system is disclosed in United States of America Patent

Application Publication US 2003/0227423, which discloses a multi-display control system that enables an operation screen to come up on an operator's front screen when an application performing a display operation changes, without the need for the operator to move the display image. When the conditions for image detection have been met, it is detected where the position of a mouse is on a hypothetical single-sheet page. Next, from the position detection result it is assessed if the mouse is on a second sub display apparatus. Then in the case where the assessed operating screen is not the main display apparatus, the screen contents of the second sub display apparatus and the screen contents of the main display apparatus are exchanged and displayed on the respective image display apparatuses. That is, the screen contents of the second sub display apparatus are transformed to the main display apparatus, and the screen contents of the main display apparatus are transformed to the second sub display apparatus.

The system of this publication detects the position of the user's pointer, and if this is located on a sub-display, then the sub-display and the main display are swapped over. This system has a number of weaknesses. For example, it does not give the user direct control over the swapping of the displayed images and does not support a user-friendly exchange of the images. It is also the case that the entire displayed images of the individual display devices are moved, when the image swapping takes place.

It is therefore an object of the invention to improve upon the known art. According to a first aspect of the present invention, there is provided a display system comprising a plurality of display devices, each displaying respectively an image, a data processing device connected to each display device and controlling the image displayed by each display device, and a user interface device connected to the data processing device, wherein the system is arranged, following a defined user input at the user interface, for at least two of the display devices, to move at least a portion of the image displayed to a different display device and, when carrying out the moving of the at least a portion of the image displayed to a different display device, to scroll the at least a portion of the image between the two display devices.

According to a second aspect of the present invention, there is provided a method of operating a display system comprising displaying respective images on a plurality of display devices, receiving a defined user input at a user interface, and, for at least two of the display devices, moving at least a portion of the image displayed to a different display device, the moving comprising scrolling the at least a portion of the image between the two display devices.

Owing to the invention, it is possible to provide a convenient way to move information from the peripheral displays onto the primary display so that, for example, the information can be more conveniently accessed by the user. In the simplest incarnation, the screens are simply cycled so that 'everything moves round one place' in response to a user instruction such as a keystroke. Thus the invention gives the user access to other parts of their workspace in a simple, fast and intuitive way. It provides the user with a simple way of screen cycling. The entire display space may be considered a single canvas, and the user can scroll to arbitrary points in this canvas. A simple example is when the displays are in a horizontal row, and the user may scroll the display space left and right so that the required part of the desktop is on the primary display.

The scrolling of the image off a first display device and onto a second device, gives the user a better impression of the transfer of an image from display to display. Animation may be used to give the user a clearer mental model of what transitions are taking place. For example, the screen images may slide smoothly from one location to the next.

In one embodiment of the system, the user interface device is a keyboard, and the defined user input comprises a single key press on the keyboard. Alternatively or additionally, the user interface device is a mouse, and the defined user input comprises a single press on a mouse button. The system can further comprising a data network, the data processing device connected to each display device via the data network. The cycling may be caused by a single action - for example, the user pressing a particular keystroke or combination of keystrokes, or a mouse button. In some embodiments, the keys are pressed once for each screen shift. In others, the user presses the keys and the screen images start moving, and he releases them when the desired arrangement is reached. The user may have control over the direction of the cycling.

Advantageously, the system is arranged to carry out the moving of at least a portion of the image displayed to a different display device, for each and all of the display devices, and when carrying out the moving of at least a portion of the image displayed to a different display device, to move all of the displayed image.

Preferably, the system is arranged, when carrying out the moving of at least a portion of the image displayed to a different display device, to move a portion of the image displayed to a virtual display device, and to move a portion of the image displayed from a virtual display device. This supports a user having control over a larger number of images than they have displays. For example, they may have three display devices, but have four active images. Only three of the four images are displayed, with the fourth image shown on a "virtual" display device. As they user cycles through the images or parts of images, then one image is moved to the virtual display device and the image held by the vitual display device is rendered on an actual display device. Ideally, the data processing means has access to a mapping table, the mapping table defining, when carrying out the moving of at least a portion of the image displayed to a different display device, the sending display device and receiving display device. The user specifies an ordering for the displays which form part of his workspace, or the system deduces one based on a geometric relationship of the displays which is defined elsewhere. The system maintains a table mapping the screen images which form part of the user's workspace onto the physical displays which make it up. This is used when drawing to the displays. When the user requests that the screens be cycled, the table is updated accordingly and all of the screen images refreshed. Preferably, the system is arranged, when carrying out the moving of at least a portion of the image displayed to a different display device, to change the resolution and/or scaling of the moved image portion. In some embodiments, the peripheral screens may be smaller, lower quality, or lower resolution than the primary display. The user may be aware of activity on the peripheral displays and cycle them onto the primary display for closer examination. In all of the above implementations, the image destined for each display may need to be modified before being displayed; most typically, this is because it needs to be scaled when not all of the displays are the same size or have the same resolution.

Embodiments of the present invention will now be described, by way of example only, with reference to the accompanying drawings, in which:- Figure 1 is a perspective view of a display system,

Figure 2 is a perspective view of a second version of the display system of Figure 1 ,

Figure 3 is a schematic diagram of the display system of Figure 1 , Figure 4 is a schematic diagram, similar to Figure 3, of the display system of Figure 1 ,

Figure 5 is a schematic diagram of another alternative version of the display system,

Figure 6 is a schematic diagram, similar to Figure 5, of the display system,

Figure 7 is a schematic diagram of another alternative version of the display system, and

Figure 8 is a schematic diagram, similar to Figure 7, of the display system.

Figure 1 shows a display system 10, which includes three display devices 12 and two user interface devices, a keyboard 14 and a mouse 16. A user 18 will interact with the system 10 via the user interface devices 14 and 16. The user 18 may be running several different applications simultaneously, with the primary display device 12a showing an image of the application on which the user is currently working, such as word processing application. The peripheral display device 12b may show an image of an application such as an email client, while the peripheral display device 12c may show an image of an application such as an Internet browser running an RSS newsfeed. The user 18 can, by making a defined input at the keyboard 14, cause the images displayed by each display device 12, to be displayed by a different display device 12. For example, the user 18 may realise (via an audible alarm) that a new email has been received by the email client displayed on the display device 12b. The user 18 can then press a defined key on the keyboard 14, and cycle the images shown by the display devices 12, with the email client now being displayed on the primary display device 12a. The other two images shown by the display devices 12 will correspondingly cycle to new T/GB2006/003018

display devices. The displayed images will scroll between the display devices 12, as they are moved.

In some situations, other orderings of the display devices 12 may be more appropriate. All of the displayed images remain 'live' and the user 18 can interact with them in situ if required. The images displayed by the other display devices 12 are always visible; therefore the user 18 can be constantly aware of what is happening on them. The effects of the transitions are visible, and the user 18 never gets confused about which image is where or which applications are running on which display device 12. Figure 2 shows an alternative to the arrangement of Figure 1. In this system, the user 18 has access to four display devices 12. When the user 18 wishes to cycle through the four images displayed by those display devices they can, as above, press a key on the keyboard 14 and cycle through the images shown by the display devices 12. A mapping table defines the order of cycling through the images, which will default to a simple clockwise or anticlockwise rotation, however the user can set the order in which the images are to pass through the principal display device 12a.

Figures 3 and 4 show schematically the display system 10, with the display devices 12, the keyboard 14 and the mouse 16 connected to a data processing device 20, which controls the image displayed by each display device 12. In Figure 3 the images "A", "B" and "C" are being shown by the respective display devices 12. Following the defined user input received at either the keyboard 14 or the mouse 16, the images displayed by each display device 12 are cycled, so that the system 10 now shows the images "C", "A" and "B", as shown in Figure 4.

In a further embodiment, shown in Figures 5 and 6, a peripheral display device 12b displays miniature but live versions of the images, in this example in a 2x2 grid, and the user cycles through these miniatures to be brought onto the primary display 12a. Figure 6 shows a change in the images displayed by the three display devices 12 when a user has instructed, via the keyboard or mouse, a cycle in the contents of the displayed images. In an alternative implementation, shown in Figures 7 and 8, the individual display elements 22 that are displayed on each display device 12, which may be individual windows, for example, are moved simultaneously to the next display device 12. Only a portion of the image displayed by each display device 12 is cycled according to the press of the key by the user. For example, as shown in Figures 7 and 8, only the display elements "A", "B", and "C" are cycled, while the window "D" remains on the principal device 12a, through out the cycling operation. This makes it easier for certain exceptions to be made in the case that there are certain items that should always remain on the primary screen such as a main menu.

Other practical implementations of the system are possible. A computer may be shared between several users, but only have a single keyboard and mouse. One user's session may move off to a peripheral display when another user logs in. In another implementation, where the transitions may be smooth, variable and do not need to occur in screen-sized chunks, the display devices 12 are considered to be views onto the users' workspace, which display the portion of that workspace which occurs at certain specified coordinates. The user's request to cycle through the displayed images results in the coordinates associated with each display device 12 being changed and the displays refreshed to show the appropriate content for their new coordinates. The system may be arranged such that the workspace 'wraps around'. For example, if the coordinates of the area shown in one display extend beyond the right-hand boundary of the user's workspace, the area beyond may be arranged so as to display the data from the extreme left of the workspace. This gives the impression of a continuously scrolling workspace similar to a conveyor-belt.

The user can have control over a larger number of images than they have displays. For example, they may have three display devices, but have four active images "A", "B", "C" and "D". Only three of the four images are displayed "A", ¹¹B" and "C", with the fourth image ¹¹D" shown on a "virtual" display device. As they user cycles through the images or parts of images, 8

then one image is moved to the virtual display device and the image held by the vitual display device is rendered on an actual display device. The user then sees images "B", "C" and "D" for example, with image "A" unseen (held by the virtual display device). The system 10 may further comprise a data network, the data processing device 20 connected to each display device 12 via the data network. The data network can be a general purpose data network. In the situation where all display devices 12 are connected in this way, there is a simple implementation, which just involves redirecting the network traffic to the appropriate display.

Claims

1. A display system comprising a plurality of display devices, each displaying respectively an image, a data processing device connected to each display device and controlling the image displayed by each display device, and a user interface device connected to the data processing device, wherein the system is arranged, following a defined user input at the user interface, for at least two of the display devices, to move at least a portion of the image displayed to a different display device and, when carrying out the moving of the at least a portion of the image displayed to a different display device, to scroll the at least a portion of the image between the two display devices.

2. A system according to claim 1 , wherein the user interface device is a keyboard, and the defined user input comprises a single key press on the keyboard.

3. A system according to claim 1 or 2, wherein the user interface device is a mouse, and the defined user input comprises a single press on a mouse button.

4. A system according to claim 1 , 2 or 3, and further comprising a data network, the data processing device connected to each display device via the data network.

5. A system according to any preceding claim, wherein the system is arranged to carry out the moving of at least a portion of the image displayed to a different display device, for each and all of the display devices.

6. A system according to any preceding claim, wherein the system is arranged, when carrying out the moving of at least a portion of the image displayed to a different display device, to move all of the displayed image.

7. A system according to any preceding claim, wherein the system is arranged, when carrying out the moving of at least a portion of the image displayed to a different display device, to move a portion of the image displayed to a virtual display device, and to move a portion of the image displayed from a virtual display device.

8. A system according to any preceding claim, wherein the system is arranged, when carrying out the moving of at least a portion of the image displayed to a different display device, to move one or more display elements of the displayed image.

9. A system according to any preceding claim, wherein the data processing means has access to a mapping table, the mapping table defining, when carrying out the moving of at least a portion of the image displayed to a different display device, the sending display device and receiving display device.

10. A system according to any preceding claim, wherein the system is arranged, when carrying out the moving of at least a portion of the image displayed to a different display device, to change the resolution and/or scaling of the moved image portion.

11. A method of operating a display system comprising displaying respective images on a plurality of display devices, receiving a defined user input at a user interface, and, for at least two of the display devices, moving at least a portion of the image displayed to a different display device, the moving comprising scrolling the at least a portion of the image between the two display devices.

12. A method according to claim 11 , wherein the step of moving of at least a portion of the image displayed to a different display device, is executed for each and all of the display devices.

13. A method according to claim 11 or 12, wherein the step of moving at least a portion of the image displayed to a different display device, moves all of the displayed image.

14. A method according to claim 11 , 12 or 13, wherein wherein the moving of at least a portion of the image displayed to a different display device comprises moving a portion of the image displayed to a virtual display device, and moving a portion of the image displayed from a virtual display device.

15. A method according to any one of claims 11 to 14, wherein the step of moving at least a portion of the image displayed to a different display device, moves one or more display elements of the displayed image.

16. A method according to any one of claims 11 to 15, and further comprising accessing a mapping table, the mapping table defining, when moving at least a portion of the image displayed to a different display device, the sending display device and receiving display device.

17. A method according to any one of claims 11 to 16, wherein the step of moving at least a portion of the image displayed to a different display device, changes the resolution and/or scaling of the moved image portion.