RU2128361C1 - Keyboard for information input - Google Patents

Abstract

FIELD: computer engineering, in particular, information input. SUBSTANCE: device has board for alphanumeric keys, board for function keys, and pattern which is applied over board of function keys. Pattern has cuts for keys and its surface is covered with labels and icons of commands. Pattern may be turned over in same way as loose-leaf calendar sheets. In addition pattern has identification label which is designed as bar code. Keyboard also has reading unit for reading code from pattern sheets. EFFECT: increased efficiency of operator, due to increased typing speed and decreased number of errors. 2 cl, 9 dwg

Description

 The invention relates to the field of computer technology, in particular to the design of keyboards for entering information used, for example, as part of electronic computers (computers).

 The keyboard is one of the main means of entering information - data and commands into the computer, and the control commands entered by the operator during the dialogue with the computer have their own specifics. Commands are entered using the mouse and on-screen menus, either from the keyboard by typing the text of a command, by pressing a combination of control and alphabet keys, or by using the function keys. Entering commands from the keyboard is the fastest way, however, for the correct input, the user must remember either the syntax of the commands or the keyboard shortcuts corresponding to certain commands. If the number of teams is large, this is a difficult task.

 Known for the design of a keyboard type MF from IBM [1]. The keyboard contains a panel of alphanumeric keys, as well as 12 function keys for entering commands. When working with application programs, stencils are used that contain pictograms and command names placed along the outer edge of the function key line [2]. The disadvantage of this design is the small number of function keys, insufficient for a set of tens and hundreds of commands used in application programs.

 The known keyboard design, selected by the author as a prototype, containing a panel of alphanumeric keys and a panel containing several rows of function keys, controlled by a separate microprocessor [3]. The disadvantage of this design is the difficulty of reconfiguring when switching from one set of commands to another - if the keys are marked with the designation of the commands of a particular program. If the keyboard is universal and the keys contain designations, for example, only their serial number (such as F1, F2 ...), then the user is forced to learn the correspondence of the keys to certain application commands.

 The aim of the invention is to increase operator productivity and reduce the number of errors when typing commands through the use of a special keypad for entering commands, equipped with a stencil with pictograms and command names. This goal is achieved by the fact that the keyboard contains a panel of alphanumeric keys, a panel of command keys and also a stencil made in the form of one or more sheets with slots for keys, superimposed on the panel of command keys. Command keys are smaller than alphabetic; between them fields are left for placing pictograms and team names. The command keyboard is designed for use with stencils. The stencil, on which the names and pictograms of the teams are applied, represents one or more sheets attached to the spine with brackets similar to fastening sheets of the desk calendar. Thus, the user has the ability to flip through the sheets of the stencil in the same way as flipping through the calendar sheets. In order to increase the convenience of working with a stencil, according to the invention, the stencil root is placed near the middle of the keypad; with this arrangement, the spine pictograms are placed on both sides of the stencil.

 In order to exclude unauthorized issuance of a command due to an accidental keystroke when turning over sheets or when changing the entire stencil, the keyboard is locked (does not respond to keystrokes) until the process of turning over. According to the invention, for this purpose, for example, one or more optically coupled pairs of light source - photodetector, mounted on the edges of the keyboard in such a way that the light beam passes at a certain height above the sheets of the screen. When turning over, the beam is interrupted, which serves as a signal to lock the keyboard. The blocking is released, for example, if the following conditions are met: the beam path has been freed; no pressed command keys.

 Comparative analysis with the prototype allows us to conclude that, by the claimed device, which contains a panel of function keys and a stencil with pictograms and names of commands printed on both sides of the stencil sheets, which also have slots for the keys, the stencil sheets are attached to the spine using brackets, while the spine is located near the middle of the keypad. Thus, the claimed solution meets the criterion of "novelty."

 Comparison of the proposed solution not only with the prototype, but also with other technical solutions in this technical field did not allow us to identify signs that distinguish the claimed solution from the prototype, which allows us to conclude that the criterion of "significant differences".

 In FIG. 1 shows a general view of a keyboard; in FIG. 2 - a fragment of the panel with a command key with superimposed stencils, the roots of which are located horizontally; in FIG. 3 - panel command keys, stencil roots and stencils; in FIG. 4 - stencil sheet; in FIG. 5 - panel command keys with a vertical spine stencil; in FIG. 6 - stencil sheet for use with a vertical spine; in FIG. 7 - device blocking the keyboard; in FIG. 8 - a device for reading a code from a stencil; in FIG. 9 - keyboard with variable height keys.

 The keyboard contains a panel of alphanumeric keys 1, a panel of command keys 2, stencils 3 (see figure 1). The panel of command keys is connected to the panel of alphanumeric keys using the racks 4 movably, so that it is possible to change the relative position of the keyboard panels. This makes it possible to adjust the position of the command button panel to achieve the most convenient position. Stencils 3 are fastened to the nuts 5 with the help of brackets 6, passed through the holes 7 so that the user has the ability to flip through the sheets of the stencil as sheets of a flip calendar (see Fig. 3). The staples 6 are removable, which allows the user to add and replace stencil sheets 3. The stems of 5 stencils are located in the grooves 8 of the keypad 2. The stencil stems are located near the middle of the keyboard; Due to this, both sides of the stencil sheets are used. Keyboard options are possible both with a horizontal stencil root (see Figs. 1-4) and with a vertical spine (see Figs. 5,6). Stencils 3 are made in the form of sheets with slots 9 for keys (see figure 4). The surface of the sheets of stencils is divided into information fields 10, designed to accommodate pictograms and team names. The tongue 11 serves for convenient turning. Sheets can come to the user with the applied graphic information, or empty. In this case, the stencil comes in the form of a self-adhesive film, which the user sticks on an empty template. This approach makes sense for small sets of teams that occupy only part of the area of the stencil sheet. Thus, the user can combine different sets of commands on one sheet. It is also possible the formation of the original user set of commands. For this, the pictograms of the individual commands in the form of separate sheets of self-adhesive film are pasted onto an empty template, after which the decryption program is set accordingly.

 In many cases, it becomes necessary to identify not only the pressed key, but also the stencil in the working position. For this purpose, the stencil contains an element that carries the code. The code is a series of bands with different reflection coefficients. For reading the code is, for example, a line 12 of optically coupled pairs of LED 13 - photodiode 14 (see Fig. 8). A beam of light emitted by the LED 13 is sent to the front surface of the template on the platform 15, on which the code is applied. The magnitude of the signal from the photodetector 14 is determined by the reflection coefficient of the area on the surface of the template in the direction of the photodetector 14. There are options for using both simple diffuse reflection from the surface of the stencil and special surfaces that reflect light in the desired direction. This can be a coating containing glass balls, a notch on the surface of the template or hologram. In all cases, the page is encoded by a line of areas with different light transmission coefficients in the direction of the light source - photodetector. There are various options for reading the code - each time you press the command key, or only when you turn on the system and change the stencil sheets. In this case, the stencil code is stored either in the keyboard memory or in the computer memory. The keyboard may contain several rulers 12 for reading code 15. This allows you to use several independent sets of stencils 3. When you press a command key, the keyboard sends a message to the central device containing information about which key is pressed (scan code) plus an identification code read from the stencil. The program, analyzing the scan code and the stencil code, determines which team this combination matches and performs the necessary actions. The scan code is generated on the basis of information recorded in the read-only memory (ROM) of the keyboard. In some cases, it is necessary to transfer more complex commands to an external device, for example, in the form of text, usually typed using an alphanumeric keyboard. To provide this function, a more complex version of the keyboard design is possible, which provides for the installation of additional ROMs, for example, flash memory cards, and ROMs belonging to different programs can be installed at the same time. In this case, when you press the command key in accordance with the code 15 of the stencil 3, it is determined whether there is an additional ROM corresponding to this stencil. If there is such a ROM, a message is generated that is generated on the basis of the information recorded in this ROM. A message can be a code similar to the code generated by pressing ordinary function keys or keyboard shortcuts, as well as the texts of commands typed from a regular keyboard. This ensures full compatibility of the proposed keyboard with all existing programs.

 In order to exclude unauthorized issuance of a command due to accidental keystrokes when turning over sheets or when changing the entire stencil, the keyboard is locked until the end of the turning process. For this purpose, optically coupled pairs of LED-photodiode mounted on the edges of the keyboard are used. The light beam 16 emitted by the LED 17 passes at a certain height above the sheets of the stencil and is registered by the photodiode 18 (see Fig. 7). When turning the sheets of the stencil, the beam is interrupted, which serves as a signal to lock the keyboard (see Fig. 7b). If several keys were accidentally pressed during the search for the desired page, this does not matter, since the locked keyboard does not provide information to the computer. Locking the keyboard during the flipping process allows you to use the keys 19 with low pressure, which in turn allows you to reduce the area of the keys, and also facilitates and speeds up the keyboard. The lock also allows you to minimize the size of the slots 9 under the keys in the stencil, leaving maximum space for information fields with pictograms.

 For most users who use two or three programs on a computer, one spine with several stencils permanently installed on the command keyboard is enough. For some applications, it is necessary to have a large number of stencils on the keypad. In this case, it is necessary to provide for a large overhang of the keys 19 above the keypad 2 to accommodate a thick stack of stencils 3 (see Fig. 9). In order for the user to be able to maintain a constant level of the surface of the sheets of the stencils relative to the top edge of the keys, the top panel cover, through which the keys pass and on which the stencils lie, is divided into two halves 20, 21, each of which can be moved in the vertical direction relative to the keys . The movement is carried out, for example, by means of a flywheel 22, a worm pair 23 and a pair of a gear wheel and a gear rack 24. The ability to change the height of the keys provides convenient operation regardless of the number of sheets of the stencil on the keypad.

 To facilitate the movement of the stencil sheet when turning over, the staples 6 have a narrowing in the middle part (see Fig. 5), as a result, the gap between the bracket and the stencil sheet increases. Thickening of the ends of the staples is necessary for the exact fixation of the stencil sheets on the keypad.

 In a stencil with a vertical spine (see Fig. 6), when turning over the sheets of the stencil “hang” - the end removed from the spine is shifted down due to gravity. To align the stencil mounting holes 7 are located along a line located at an angle to the vertical edge of the stencil sheet. The same effect can be achieved by using staples of different diameters with a vertical arrangement of holes 7 in the stencil.

 Using a functional keyboard with interchangeable stencils provides parallel quick access to dozens and hundreds of commands of any program, eliminates the need for the user to memorize the command syntax or the meaning of various keyboard shortcuts. The presence of an icon next to each function key and the name of the corresponding team facilitates the learning process and the development of new programs. The images of the pictograms on the printed screen are of significantly higher quality than on a CRT or LCD screen. This is the main advantage of stencils. When working with high-quality images, the number of errors and operator fatigue are reduced, and labor productivity is increased. Changing the stencils takes a few seconds and in most cases is commensurate with the time required to load the serviced program. Turning over the sheets of the stencil takes generally a split second, which, given the speed of perception of information by the operator, is commensurate with the speed of perception of "drop-down" on-screen menus. The use of the proposed keyboard will increase the productivity of both a professional - due to parallel access to all commands, and a beginner - due to the visual representation of a list of commands.

Sources of information
1.1 Romanov F.I., Shakhnov V.A. Structural systems of micro- and personal computers. -M .: Higher school, 1991.

 2. The patent of Germany N 4014135 C1, G 06 F 3/033.

 3. US patent N 4766418, G 06 F 3/00, 1988.

Claims (2)

 1. Keyboard for entering information, comprising a keypad, a stencil with pictograms or other information explaining the purpose of the keys, designed to be placed on the keypad and made in the form of one or more sheets fastened together in the form of a booklet using arched staples characterized in that the slots for the keys are made in the stencil sheets, and the stencil root is mechanically fixed within the key field between the rows of keys so that when turning the stencil sheet into any The keys covered by the stencil are included in the corresponding slots of the stencil, while on both sides of the stencil sheets are pictograms and other information explaining the purpose of the keys, as well as a label used to identify the stencil sheets and made in the form of a barcode located along the edge a stencil sheet, and on the keyboard a device for reading the code from the stencil sheets is mechanically fixed, containing light sources and photodetectors optically connected to them, with the mark on the stencil sheet code reader body.  2. The keyboard according to claim 1, characterized in that the arcuate staples fastening the stencil sheets have a variable cross-section, and the cross-sectional area is minimal near the middle of the staples.

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