KR20000075806A - Graphical user interface for weighting input parameters - Google Patents

Abstract

The graphics device is used to control the system. The device takes the form of a pie diagram. The relative size of slices in the pie indicates the relative importance of system control parameters. The total size of the pie represents the overall system parameter.

Description

Graphical user interface for weighting input parameters

There are a number of user interfaces for specifying input data.

The present invention relates to the field of graphical user interfaces for receiving user input data for use in controlling a system having a data processing capacity.

1 illustrates a system based on a processor of a user interface in which the present invention is used;

2 shows a display screen according to a preferred embodiment of the present invention.

3 is a flow diagram of the operation of a user interface in accordance with the present invention;

4 illustrates an audio system with a user interface in accordance with the present invention.

5 shows a dance hall system controlled by an interface according to the invention.

6 illustrates an operating system controlled by an interface according to the present invention.

The present invention is from the recognition that the control of a system based on many processors can be at least conceptually described by a linear equation, i.e., a ₁ x ₁ + a ₂ x ₂ + ... + a _n x _n = A depart.

Here, the values x ₁ , x ₂ , B, x _n are components of the total value A, and the parameters a ₁ , a ₂ , B, a _n are the weights of the respective components. The equation may be a literal description of the system or a conceptual description of the system, or may explain what the user feels intuitively about the system rather than in a mathematical relationship. In controlling the system described by such an equation, the user wants to adjust the input parameter and the overall value.

It is an object of the present invention to provide a user-friendly interface for the input and adjustment of parameters, and optionally for the input and adjustment of overall values.

The object is achieved by a user interface with a geometric form. The geometry consists of sub-regions. The relative size of the sub-regions can be adjusted in response to the movement of the user pointer device. The relative size determines the relative value of the input parameter.

In an embodiment of the invention, the geometric shape is a circle and the sub-regions are pie shaped slices of circles.

EP 564 278 presents a graphical user interface with pie diagrams on screens that can detect touch. The input parameters are derived from the user contact position in the pie diagram. The user does not adjust the relative size of the pie slice or the absolute size of the pie.

US 5,627,951 shows a graphical user interface in a pie diagram. The pie diagram displays the result of the user color representing the input. Input comes from knobs located next to the screen.

The invention is illustrated by non-limiting examples with reference to the following figures.

1 illustrates a processor based system in which the present invention is usefully employed. The system includes a display 101, a user pointer device 102, and a component 103 having system functions. As described below, component 103 includes a processor 104 and typically some other component 105 to aid system functionality. In addition, component 105 may be an external system controlled by parameters a _i and A.

The display is shown in the figure as a CRT, but may be of another type, such as a liquid crystal display or a small display directly coupled to the component 103.

The pointer device is shown as a mouse on a mouse pad, but may be another kind of pointer device, such as a trackball, stylus, or a component capable of sensing a contact within the display 101.

Processor 104 is shown as a microprocessor mounted on board, but may also be a processor including a large standalone computer.

2 shows a screen displaying a user interface according to the invention. The interface includes a pie diagram 204. The pie diagram comprises sub-regions 201, 202 and 203 representing the relative sizes of the respective input parameters a ₁ , a _2, B, a _n . The sub-regions are displayed as slices of the pie. In the figure, although three slices, the number of slices is entirely arbitrary. There may be a number of pie slices suitable for the function of the system to be controlled.

The relative size of the sub-regions can be changed by dragging the sub-region boundaries with the pointer device. Arrow 206 shows the movement of the sub-region boundary in accordance with the present invention. As the boundary is adjusted, the remaining sub-regions can be adjusted by linear equations governing the particular system being controlled. Changes in the remaining sub-regions can be spread evenly across the remaining sub-regions. In addition, the change can be fully absorbed by sub-regions adjacent to the moving boundary. Another alternative is that the amount of adjustment of the remaining sub-area can function as the distance measured by the angle of the sub-area from the moving boundary. General techniques in this field may devise other functions to adjust the remaining sub-regions as the movement of 206.

The total size of the pie diagram represents the total value A. The overall size of the pie diagram can be changed by dragging the outer boundaries of the pie. Arrow 205 shows the direction of movement of the outer boundary of the pie diagram when the user input requires a change in the overall value A.

Although the invention is illustrated by a pie diagram, other geometric shapes may also be used and the sub-regions may have any convenient shape.

3 shows a flowchart of the operation of a user interface according to the invention. At 301, the system retrieves the values of a ₁ , a _2, B, a _n, and A stored during previous use of the system. Alternatively, the system may set such parameters to default levels. At 302, a graphics device, which is a user interface in accordance with the present invention, is displayed based on the parameters determined at box 301. At 303, the system output is calculated based on the parameter. At 304, the system contrasts with the graphics device for user interaction. At 305, if the boundary is not changed, then control returns to 304. If the boundary is changed, the graphics device and the parameters a ₁ , a _2, B, a _n and A are adjusted at 307 and stored according to the changed boundary.

Although the procedure is illustrated here as an infinite loop, one of the common techniques in the art can easily add several outlets to the loop. Alternatively, the loop may terminate by interrupting the system or interrupting the system.

4 shows an audio system with a user interface according to the invention. The audio system includes a CD player 401 having a CD slot 402 and a speaker 404. The audio system also includes a liquid crystal display 403 capable of sensing a contact having an interface according to the invention. The interface is a pie diagram with a pie slice representing the treble range (T) of the frequency, the bass range (B) of the frequency, and the midrange range (M) of the frequency. The total size of the pie represents the total audio volume. If the user wants to increase the overall audio volume, she or she must drag the outer boundary of the pie according to arrow 205. If the user wants to balance the various frequency ranges, the boundary between the pie slices must be moved by arrow 206. Thus, if the slice marked T is large compared to the other slices, the components of the high pitch will be relatively high compared to the low and mid range. If the whole pie is small, the volume will be lower. Although FIG. 4 illustrates a CD player, other types of audio systems may use the user interface described herein. If you want finer levels of frequency control, more pie slices can be added.

5a and 5b show a disco dancing room with a control interface according to the invention. 5A shows the room at an overall angle. The walls W and the ceiling C are covered with LEDs of various colors. The floor has a flashlight underneath and is transparent. 5B shows a DJ station. The station comprises, according to the present invention, an audio system 503, a microphone 502, and an interface 501 to control a large number of embols at any moment on the screen capable of sensing a contact. The interface contains a pie diagram of the full size of the pie representing the total number of lights. Each slice of pie represents a respective color of light. The relative size of the slices is a relative way of indicating how many lights of each color are on.

In the dance hall, with the embodiment used here, an error message can be displayed if the user specifies control parameters that cannot be physically executed by the system.

6 illustrates a workstation for a system operator of a large multitasking large computer. The workstation includes a user interface 601 in accordance with the present invention for controlling CPU usage. The system operator can use the mouse 602 to drag the boundaries of the user interface. The user interface is used to control CPU usage from various perspectives. One copy of the interface is used to control the current percentage of CPU allocated to another processor. Each slice of the pie represents one of the currently running processors. If a large number of processors are running, there will be many pie slices. The total size of the pie represents the total percentage of CPU usage. In addition, one of the slices of the pie may represent an unallocated portion. The system operator, who can then change the percentage of CPU utilization, drags the border of the slice representing the processor according to arrow 206 and assigns it to one processor.

If part of the processor looks too small in the pie diagram, it can be represented by a combination slice assigned to small processors. The system operator can then click on the combination slice to see a second pie diagram showing the small processor as a percentage of the combination slice.

Another copy of the interface is used to control the percentage of days a given user can take. In other words, each user spending significant time is represented by each slice. The system operator can then adjust the slice size of the user according to arrow 206 to control the percentage of dates the user can have.

In addition, the screen of FIG. 2 can be used to control a heating system having several zones, where the pie slice represents the allocation of the heating resources allocated to a particular zone, and the overall size of the pie represents the total heating resources allocated. . Since the heating control system looks the same as the screen of FIG. 2, it is not drawn again. The actual heating control then becomes part of the component 105 in FIG. 1.

In addition, the screen of FIG. 2 is used to control feature weights in a database search system. For example, take an image database. The database query includes sample brightness, color, and feel indicators to match objects in the database. The interface according to the invention is then used to add importance to the indicator in the query. For example, the parameter a ₁ indicates the relative importance of the brightness indicator, a ₂ indicates the relative importance of the color indicator, and a ₃ indicates the relative importance of the touch indicator. The parameter "A" represents the desired strength of the overall feature match for the retrieved object. The intensity is calculated using a distance threshold, in the n-dimensional feature space, and the candidate-target distance is the _ai weighted sum at the feature distance. The object retrieved from the database then has one or more features that best match the indicator in the query based on the weights represented by the user interface. Information about feature spaces in image retrieval can be found in Abdel-Mottaleb et al. "Aspects of Multimedia Retrieval" (Philips Journal of Research, Vol. 50, No. 1/2, 1996, pp.227-251).

In addition, the screen of FIG. 2 is used to control the photo retouching system in a sub-region representing color balance in the captured image. The output image is illustrated in FIG. 1 by the component 105 to a screen, or a suitable printer.

General techniques in the field of user interface design can be easily applied to control the large number of other systems, in addition to those revealed in the present application.

General techniques in the field of user interface design can be easily applied to control the large number of other systems, in addition to those revealed in the present application.

Claims (12)

In a graphical user interface for controlling a system wherein the overall output is a combination of component outputs, The total and component outputs are controlled with reference to input parameters, the interface has geometric shapes that make up the sub-area, the relative size of the sub-area can be adjusted in response to the movement of the user pointer device, The relative magnitude determines a relative value of the input parameter. The method of claim 1, The geometric shape is a circle, and the sub-region is a pie-shaped slice of a circle. The method of claim 1, The overall size of the geometry can be adjusted in response to the movement of the user pointer device, the overall size representing the overall output. In an audio control system, The interface of claim 3, wherein the sub-regions represent a frequency range of the output sound of the system, the overall magnitude of the geometry being a graphical user interface representing the overall volume of the system, The total volume of the system in response to said full size, Processing means for controlling the relative volume of the frequency range according to the relative size of the sub-regions; And control means for adjusting global and component outputs according to the output of the processor means. In a lighting control system, 4. The interface of claim 3, wherein the sub-area represents a wavelength range of an output light of a system, and wherein the overall size is a graphical user interface representing an overall output brightness of the system; The overall output brightness in response to the full size, Processing means for adjusting the relative brightness of the wavelength range according to the relative size of the sub-regions, And control means for controlling the overall and component outputs based on the output of said processing means. In the photo retouching system, The interface of claim 1, wherein the sub-regions comprise a graphical user interface representing color balance in the output photographic image; Processing means for adjusting the relative importance of the color components in the output image according to the relative size of the sub-regions; And photographic output means for displaying an output image in response to said processor means. In a computer operating system, The interface of claim 1, comprising: a graphical user interface in which the relative size represents a percentage of computer dates assigned to a particular user; And processing means for adjusting the relative allocation of the processing date according to the relative size. In the heating control system, The graphical user interface of claim 3, wherein the relative size represents each percentage of heating resources allocated to each heating zone, and wherein the total size represents the total heating resources allocated; And control means for heating in accordance with said interface. A database search system comprising the graphical user interface of claim 1. The method of claim 9, Said interface retrieves image data, said relative magnitude representing a weight given to a perspective of image data during a query. The method of claim 10, Perspective database search system including brightness, color and tactile. A database search system comprising the interface of claim 3, comprising: The interface retrieves image data, the relative size representing a weight given to the perspective of the image data during the query, and the overall size representing the desired intensity of the match according to the retrieved image.