WO2000036496A1

WO2000036496A1 - Method and arrangement for selecting a data set from a plurality of data sets

Info

Publication number: WO2000036496A1
Application number: PCT/DE1999/003848
Authority: WO
Inventors: Hubertus Hohl
Original assignee: Siemens Aktiengesellschaft
Priority date: 1998-12-16
Filing date: 1999-12-01
Publication date: 2000-06-22

Abstract

The invention relates to a method and an arrangement for selecting a data set from a plurality of data sets. According to the invention, a plurality of data sets is mapped on a set of values of a selection device. The output device is adjusted to a value of said set of values by way of an input means. A data set assigned to said value is selected from among the plurality of data sets.

Description

description

Method and arrangement for the selection of a data record from a set of several data records

The invention relates to a method and an arrangement for selecting a data record from a set of several data records.

Such a method and such an arrangement are known in a commercially available terminal device based on a processor unit. In particular, various embodiments of such end devices with an LCD display of small dimensions and a graphical user interface (GUI = Graphical User Interface) are known: smartphones, PDAs (Personal Digital Assistants), handheld PCs, web phones and online access -Times. Each of these devices enables, inter alia, interactive access to a large number of electronic data, which are present in particular in the form of data records and which can be represented by means of order features which can be specified by a user in different, almost any order sequences. A typical example is an orderly list of names in an electronic telephone or address book, a customer file or chronologically ordered data records in the form of appointment entries, incoming messages or project tasks.

Access by the user to the data sets requires mechanisms for targeted, optional selection

Representation and manipulation of the content of individual data records. In particular with each of the above (mobile) end devices, due to the display unit (display) encompassed by this, with a screen diagonal of only 5-8 inches, it is not possible to prepare all of the information to be displayed. For example, a common display unit has a format of 640 * 240 pixels (Pixels) with a resolution of 100 DPI. This results in 12 to 15 writing cells that can still be picked up by the human eye with little effort. Thus, for example, only a small section of the data records can be displayed for a line-by-line listing of the data records. A selection of certain data sets is associated with a context change (changing the view, calling up a different menu and displaying the newly selected data sets), which is time-consuming, cumbersome and less intuitive for the user.

A known type of display is the display of a viewing window with a view of a list of data records, which viewing window can be moved using so-called scroll bars (in horizontal and vertical direction) (see e.g. in [1] or [2]). This virtually results in a display window in multiple sizes of the viewing window, the ratio of the size of the viewing window to the size of the information to be actually displayed being decisive for clarity. With a small one

Viewing window and a tabular list with huge dimensions, the display for the user is so confusing that a lot of time m t searches and scrolls m the list. This leads to a waning acceptance by the user.

The object of the invention is to enable a selection of a data record from a set of several data records, the selection being carried out in a clear manner and in particular not necessarily a

Context change, i.e. a switch from a selection mode to a view or editing mode must be made.

The task is performed according to the characteristics of the independent

Claims resolved. Further developments also result from the dependent claims. To solve the problem, a method for selecting a data record from a set of several data records is specified, in which the multiple data records are mapped to a range of values of a selection means. The output means is set to a value of the value range using an input means. A data record from the multiple data records assigned to the value is selected.

A major advantage is that the

Activation of the selection means with the input means a clear and intuitive selection of a data record from the multiple data records can take place. In particular, the selection means can be provided on the display, the selection means taking up little space, so that the selection means can be displayed next to the currently selected data record. This is particularly advantageous since the user does not have to change the context (menu change) and the data record with the selection means presents itself as a unit for intuitive operation.

A further development consists in that the range of values of the selection means is predetermined by its representation size. The mapping of the data records to the range of values of the selection means (dynamic mapping) results in an effective and optimal utilization of the display size provided for the selection means. The area on the display that the selection means occupies is effectively used.

Another development consists in the fact that the range of values of the selection means is predetermined by a number of pixels comprising the representation size. The maximum number of representable data records that can be selected directly with the input means on the selection means is predetermined by the number of pixels that corresponds to the representation size of the selection means. If there are more data records than pixels, pixels become documented several times. In the other case, that is, if there are fewer data records than pixels, not every pixel in the representation of the selection means is used to select the data record.

In particular, it is a further development that the data records are mapped linearly onto the range of values of the selection means.

Another embodiment provides that the data records are not mapped linearly onto the range of values of the selection means. This mc tlinear mapping to the range of values of the selection means can take place using a distortion function. This is e.g. advantageous for a large amount of data records, each of which should not be selectable with the same priority. An example is a message list in which the newer messages are given a larger area on the selection means than the older messages. Here a distortion function can be an efficient and simple one

Ensure navigation in the mainly interesting data records (messages).

The distortion can also take place dynamically in an environment of the currently selected data record. Data records in this environment (the n processors and the k successors, if they exist) can be selected individually on the basis of the selection means, the data records available beyond this environment being able to be selected in a compressed manner in the range of values of the selection means.

It is also an embodiment that the selection means is provided with a scale. This scale can include graphical or textual representations, each graphical and textual representation respectively representing an ordering criterion for the data sets. This is particularly important if the records are lined up in a linear order are. The data records can also be sorted according to the order criterion, whereby the order criterion can be an alphabetical sorting, a chronological sorting or another sorting. In the example of alphabetical sorting, the scale can include the letters of the alphabet, with only those letters for which data records are available being shown, particularly with regard to the size of the selection means. Accordingly, letters can also be omitted if there are not enough values in the range of the

Selection means is available. The linear order of the letters of the alphabet intuitively shows, even if some letters are missing, that the entries between the missing letters refer to them. In particular, at least one data record stands for a graphic or textual representation as a label on the scale.

As part of an additional development, only those data records are mapped to the range of values of the selection means that are determined by a filter function.

It is also a further development that a search function is used to determine data sets which are particularly emphasized on the scale of the selection means. A special input means can be provided or an existing input means can be used to scroll through only those data records which represent the result of the search function. A cursor key arrangement is particularly suitable for this, on the basis of which an upward or downward scrolling through the found data records is possible.

In particular, the selection means is shown on a display unit (the display). With such a software-technical implementation, a dynamic

Adaptation of the display unit and if necessary the connected scale enables. Furthermore, different forms of representation of the selection means can be realized.

Another development consists in that the selection means and the respectively selected data record are displayed on the display unit. This unit of selection means and data record prevents a context change in which the user can first select and then view, change or delete the selected data record and must finally switch back to a selection mask. A new data record can also be added.

It is also an embodiment that the selection means is a representation of a slider, a scroll bar or another software-technical adjustment unit. The software-technical implementation of the selection means creates flexibility both with regard to a dynamic adaptation to the existing data records and to the type of display. In this way, a user can choose any display type that seems suitable for his purposes. A slider (horizontal or vertical) has proven to be particularly advantageous, with the aid of which a scale can be clearly represented and intuitively, by moving the regulator along the scale, access to the data records is possible.

Another development is that the input means is at least one of the following options: a) a pointer that is moved by means of a computer mouse, a touchpad or a unit that records analog movements and converts them into digital movements. Such analog input devices are widely known and commercially available. b) Cursor keys, by means of which a position on the selection means can be moved. Cursor keys are suitable preferred for (incremental) scrolling (up or down) through data records. Holding the cursor key enables repeated scrolling or fast scrolling, if necessary. c) An adjusting device, the position of which is implemented in a corresponding position of the selection means. Such an adjustment device can be a mechanical slide control or a rotary control. With a mechanical input device, it is possible to intuitively simulate the selection device and thus the

Allow users to input highly efficiently. The scale for the mechanical input means can be implemented using software. d) A touch screen in conjunction with a pointing device. If the display unit (the display) is a touch-sensitive screen, you can directly use a pointing device e.g. a plastic pen, an entry is made on the display unit itself. Such a mechanism is widely used in PDAs.

To achieve the object, an arrangement for selecting a data record from a set of several data records is also provided, in which a processor unit is provided which is set up in such a way that a) the multiple data records can be mapped to a range of values of a selection means; b) the selection means can be set to a value of the value range using an input means; c) a data record assigned to the value can be selected from the plurality of data records.

This arrangement is particularly suitable for carrying out the method according to the invention or one of its developments explained above. Exemplary embodiments of the invention are illustrated and explained below with reference to the drawing.

Show it

Fig.l a slider for selecting linearly ordered data sets;

2 shows a combined representation of the selection means (slider) together with the selected data set;

3 shows an extended selection process with an integrated search function;

4 several imaging characteristics for the slider;

5 shows a slider with the currently selected

Data record in the context of address management on a PDA;

6 shows a compact selection component for addresses;

7 shows a slider with the currently selected data record after entering a name change;

8 shows a slider with a newly inserted data record;

9 different implementation variants for an input means;

10 shows a processor unit. Fig.l shows as a selection means a slider for selecting a data record from a large number of linearly ordered data records. The slider comprises two direction symbols 101 and 102, a controllable area 103 and a slider 104. Furthermore, a Schieoerskale (scale) 105 is provided. There are n linearly ordered data records corresponding to their numerical index I (1 <I <n) linearly mapped to a numerical value range of the slider, so that the first data set d = 1) to the minimum value 1 of the slider and the last data set (i = n ) on the

Maximum value n of the slider can be mapped. If, as shown in FIG. 1, a numerical value range of a slider with a linear mapping characteristic is mapped to the representation length (m pixels) of the slider, the ordered data sets are evenly spaced over the area 103 of the slider and can be shifted of the slider 104 can be selected. The slide is preferred

104 operated in a latching mode, i.e. it is only the defined n discrete value positions of the present

Sequence of data records adjustable. If the scanner 104 is used with a freely positioning pointing device, e.g. moved to an intermediate position by a mouse pointer, the slide 104 automatically snaps to the next value position

A scale attached to the selection means (slider)

105 enables quick selection of a data record. For this purpose, markings in the form of lines or dots are provided at the n discrete value positions. In addition, textual or graphic representation symbols are placed on the scale 105 at excellent value positions, each of which reflects a specific ordering criterion of the data records. For this purpose, the linearly ordered sequence of all of the data records is broken down into successively ordered partial sequences such that each partial sequence contains exactly those data records that a Have order criteria in common. If the sequence of the data records is arranged alphabetically, then there is a partitioning (i.e. the subdivision into partial sequences) in such a way that each partial sequence contains exactly those alphabetically ordered data records whose ordering feature begins with a specific character of the alphabet. In the same way, with chronologically ordered data records, partial sequences can be determined in such a way that each partial sequence contains exactly those chronologically ordered data records that correspond to a certain time characteristic (eg day, month, year). The scale 105 can thus be provided with additional markings at the value position of the area 103 defined by the beginning of a partial sequence. In the case of alphabetically ordered data records, as Fig.l shows, these are the characters of the alphabet (A to Z).

The slide 104 is preferably operated with a freely positionable pointing device, for example a pen in the case of small input devices with a touch-sensitive display and / or with a cursor key control. With the pointing device, the slide 104 can be moved to a defined value position by pulling. In addition to this direct positioning, incremental positioning is also possible, which takes place by selecting one of the two direction symbols 101 or 102 and moves the slide 104 by one data record in each case in the direction associated with the direction symbols 101 and 102. Appropriate navigation can also be carried out by moving the above or below the control area (depending on the desired direction of movement; with vertical slider)

Slider 104 is clicked with the mouse pointer. The cursor 104 can be positioned mcrementally in both directions (here: up / down) using the cursor control. Continuous printing preferably results in repeated, automatic displacement of the slide 104 (auto-repeat function). In particular, both emit modalities, freely positionable pointing device and cursor key control, depending on the user's preference or depending on the application situation.

The scale 105 in FIG. 1 shows several letters of the alphabet, in the place of which (in alphabetical order) the first entry of the data record belonging to the letter is located (first data record of the partial sequence or partitioning). Since there is no data record in the example that begins with the letter "C", the letter "C" is missing as a label for the scale. Each (short or long) horizontal line on the scale 105 contains a data set.

2 shows a combined representation of the selection means (slider) together with the selected data set. The slider, whether horizontal (cf. 201) or vertical (cf. 202) form of representation, works in the manner described above (cf. Fig. 1). For the selection and manipulation of a data set, the selection means (slider) is combined in connection with the representation of the data set (or several data sets), the content preview of the currently selected data set being preferably synchronized with the selection means, in particular the scale of the slider. As a result, any movement of the slide 104 results in an update of the preview. According to representation 202, this preview can display all or specially selected data fields of the selected data record (e.g. attribute-value pairs in tabular form) or can be restricted to a single data field, in particular the data field that corresponds to the

Ordinal feature, here the name, corresponds (see illustration 201).

The preview can be used to manipulate the selected data record directly. For this, the

Data fields of the preview displayed via editable components in the form of text fields. The user changed over a Text field immediately the set data record. Accordingly, adding a new data record and deleting the currently selected data record are possible in this display. Additional buttons (see also Fig. 5) are provided for this. After adding a new one

As a rule, the data fields in the preview are empty or pre-assigned with application-specific default settings. After removing the selected data record, another data record is displayed, e.g. the previous or subsequent one (if any). In any case, the slider is updated automatically, i.e. the range of values, the selected value and the scale of the slider are recalculated and displayed.

If a variable number of data records is mapped onto the value range of the slider, which has a constant length determined by the display size, the problem arises of the graphic compression of value positions on the slider. If the number n of all data records exceeds the specified length of the slider (in pixels), it is no longer possible to set every discrete value position with a freely positionable pointing device, since several data records are to be mapped to certain pixels. This problem is solved by using the pointing device to roughly position on the scale. A further, data set-related positioning is carried out, as described above, with the pointing device or the cursor keys via the incremental control of the data sets. This selection process is sufficiently convenient on the end devices mentioned at the outset, since preferably less than 1000 data records are stored and, due to the size of the display unit (the display), a length of 200 to 300 pixels is available for the slider.

Due to the above-mentioned graphical compression of the value positions, the scale is adjusted accordingly by all Markings (classification features) are omitted, which would either lead to an overlap or to an immediate anemander border. Alternatively, the scale can be created in two or more stages, whereby those classification features that overlap are shown indented in a subsequent stage (see also the description below).

9 shows different implementation variants for an input means 901. As already described, possible input means are a pointer of an analog computer mouse or a touchpad (block 902) or cursor keys (block 903). A mechanical adjustment device 904, e.g. a mechanical slider can be provided, which is attached to the corresponding terminal. When the mechanical slider is moved, the analogue measurement values are sent to a computer in the end device via an analog-digital converter and a hardware interface. This computer controls the application, e.g. via an interrupt-controlled mechanism. For the incremental selection of data records, two mechanical pushbuttons are preferably additionally provided. The scale for the mechanical slider can be provided along the same, so that values of the scale can be dynamically adjusted. Instead of the mechanical slider, another mechanical regulator, for example a rotary regulator, can also be provided. Finally, it is a possibility for the emitting means 901 to design the display unit as a touch-sensitive screen 905, which is controlled by a plastic pen.

3 shows an extended selection process with an integrated search function. A search is started using an input field 301 with a term (here "Siemens"). All

Records that have this entry anywhere are highlighted on the scale 105. The highlights are in Fig.3 marked as horizontal lines with a small black dot 306. At the end of the search, the slide 104 is set to the first hit 307. The user can select the further hits by manually moving the slide 104 to the highlighted positions 306 or select the previous hit or the subsequent hit relative to the current slide position 305 using the two buttons 302 and 303 shown. In particular, as soon as the first hit 307 is selected, the button 302 becomes inactive or, if the last hit 304 is selected, the button 303 becomes inactive. It is particularly advantageous here that the user can navigate in the current set of hits as well as in the entire database without changing the context.

Fig. 4 schematically shows several mapping characteristics for the slider. If the slider receives a non-linear mapping characteristic, the problem of graphical compression can be clearly solved with a large number of data sets. The data records are distributed according to a predetermined distortion function m unequal distances on the slider so that a certain area around the currently set data set is shown in a higher resolution than the rest of the area. Here, the distance between the pixels between the data records is selected in the larger area. With this mapping characteristic, the value positions and the scale markings of the slider are dynamically recalculated and updated each time the setting is changed. The distortion function determines the value position of a data record on the slider depending on its geometric distance from the value position of the selected data record. In Fig. 4, the mapping characteristics are a linear undistorted mapping (see also Fig. 1, Fig. 2 and Fig. 3), a linear distortion with two discrete distortion factors, one Partial linear distortion and a non-linear distortion are shown.

5 shows a slider with the currently selected data record as part of an address management on a PDA. The scale marking corresponds to the first letter of the name. Each start of a new partition (partial sequence) on the scale is visualized by a scale line and the character describing the partition (A to Z). All other value positions on the

Scales are represented by scale points. The scale itself has two levels, with the markings that led to an overlap being shown indented to the right. The address management shown using the slider has the following functionalities: a) access to addresses by their names; b) adding addresses to the address book; c) deleting addresses from the address book and d) changing data fields of an address.

Fig. 6 shows a compact selection component for addresses. The compact selection component shown in Fig. 6 is suitable for the pure selection of an address by its name (e.g. in the context of an e-mail application in which a recipient address is to be specified). If necessary, this can be shown or hidden using the current screen content ("pop-up" dialog). The name of the currently set address (selected data record) is displayed above the controller. If the desired address is selected, the action is confirmed or canceled by printing the two buttons below the controller. In both cases, the selection component is hidden again and a corresponding feedback is sent to the application.

The buttons shown in Fig. 5 are offered for changing or manipulating individual addresses. A desired address is set with the slider on the right side, the selected address is synchronized at the same time. The data fields can be edited directly using the keyboard. After changing the "Name" data field, the slider with its scale may need to be recalculated and displayed. This is necessary because changing the order of the data record can potentially change the order in which the data is ordered. In this case, the position of the data record also changes its value position on the slider. In FIG. 5 the data record with the name "Hohl, Hubertus" is changed, which leads to the representation in FIG. 7 with the name "Kohl, Hubertus". 7 shows the newly calculated slider with the newly determined scale for the name "Kohl, Hubertus".

The currently selected address can be removed using the "Delete entry" button below the data fields. If the address has been deleted, the address preceding this address (if available, otherwise the following one, if available) is automatically set on the slider and visualized in the display unit. If there are no more addresses in the database, no entry can be deleted.

It is possible to add a new address using the "new entry" button below the data fields. A new data record is generated here, the fields of which are empty and which is initially classified in the database (see Fig. 8). The slider is recalculated accordingly and positioned at the beginning. The user can now fill in the individual data fields of the new address in the manner described above.

A processor unit PRZE is shown in FIG. The processor unit PRZE comprises a processor CPU, a memory SPE and an input / output interface IOS is used in different ways via an interface IFC: output is displayed on a monitor MON and / or output on a printer PRT via a graphic interface. An entry is made using a mouse MAS or a keyboard TAST. The processor unit PRZE also has a data bus BUS, which ensures the connection of a memory MEM, the processor CPU and the input / output interface IOS. Furthermore, additional components can be connected to the data bus BUS, for example additional memory, data storage (hard disk) or scanner.

Bibliography :

[1] The Windows Interface Guidelines for Software Design: An Application Design Guide; Microsoft Press, May 1995.

[2] OSF / Motif Style Guide, Revision 1.2, Prentice Hall, September 1992.

Claims

claims

1. Method for selecting a data record from a set of several data records, a) in which the multiple data records are mapped onto a range of values of a selection means; b) in which the selection means is set to a value of the value range on the basis of an input means; c) in which a data record assigned to the value is selected from the plurality of data records.

2. The method according to claim 1, wherein the range of values of the selection means is predetermined by its representation size.

3. The method as claimed in claim 2, in which the range of values of the selection means is predetermined by a set of pixels comprising the representation size.

4. The method as claimed in one of the preceding claims, in which the data records are mapped linearly onto the range of values of the selection means.

5. The method as claimed in one of claims 1 to 3, in which the data records are mapped nonlinearly to the range of values of the selection means.

6. The method according to claim 5, wherein the non-linear mapping to the range of values of the selection means is carried out using a distortion function.

7. The method according to any one of the preceding claims, wherein the selection means is provided with a scale.

8. The method of claim 7, wherein the scale comprises graphical or textual representations, each representing an ordering criterion for the records.

9. The method according to any one of the preceding claims, in which the data records are linearly ordered.

10. The method according to any one of the preceding claims, wherein the data records are ordered according to an ordering criterion.

11. The method of claim 10, wherein the ordering criterion is an alphabetical order or a chronological order.

12. The method according to any one of claims 7 to 11, in which a rough positioning according to the scale is carried out using the selection means.

13. The method according to any one of the preceding claims, in which only those data records are mapped onto the value range of the selection means that are determined by a filter function.

14. The method as claimed in one of claims 7 to 13, in which, on the basis of a search function, the data records which represent a result of the search function are highlighted on the scale of the selection means.

15. The method according to claim 14, in which the data records which represent the result of the search function can be browsed using a specific input means.

16. The method according to any one of the preceding claims, in which a display unit is provided on which the selection means is displayed.

17. The method according to claim 16, wherein the display unit displays the selection means and the selected data record.

18. The method according to claim 17, in which additional switches are provided, by means of which the data record can be changed, deleted or a new data record can be added.

19. The method according to any one of the preceding claims, wherein the selection means a representation of a

Slider, a scroll bar or another software adjustment unit.

20. Arrangement for the selection of a data record from a set of several data records, in which a processor unit is provided which is set up in such a way that a) the multiple data records can be mapped onto a range of values of a selection means; b) the selection means can be set to a value of the value range using an input means; c) a data record assigned to the value can be selected from the plurality of data records.

21. The arrangement as claimed in claim 20, in which the input means is at least one of the following options: a) a pointer which is moved by means of a computer mouse, a touchpad or a unit which records analog movements and converts them into digital movements; b) cursor keys by means of which a position on the selection means can be moved; c) an adjusting device, the position of which is converted into a corresponding position of the selection means; d) a touch-sensitive display unit.

22. The method of claim 21, wherein the adjusting device is a mechanical slider or a rotary controller.