DE4026073A1 - Control point coupling mobile data terminal to fixed data processor - has two components forming transceiver for electromagnetic waves, and air path as transmission line - Google Patents

Abstract

The control point consists of stationary component coupled to the data processor by a fixed transmission line, and a second component in spatial, electric connection to the data terminal. A second transmission line porvides a releasable coupling between the two components. The two components form transceivers for electromagnetic waves. The transmission line consists of an air path. Pref. the transreceivers all for optical waves, typically in the IR range. Alternately the transreceivers can handle non-optical waves. The optical waves range is mm to cm extent. The transceivers may have directional diagrams. USE/ADVANTAGE- for large computers in air conditioned rooms, with low-cost design for reliable terminal installation.

Description

The invention relates to an interface according to the Oberbe handle of claim 1.

Data processing systems, especially mainframes, are generally stationary in air-conditioned rooms and with transmission lines in general several data terminals, e.g. B. several terminals (Ta stature and display device) and / or printers and / or multi plexer, detachably connected. The data terminals can in different rooms, e.g. B. offices be. It is currently common to have data about each room management, z. B. a twisted multi-wire line for serial data transmission, stationary  to lay. There is a fixed instal in the room the first component, preferably a data plug can, to the one leading to the data terminal flexible Transmission line, e.g. B. also a twisted Multi-wire line, can be connected, for. B. with the help of a plug into the data socket. On the date Terminal is a second component, for. B. also a Data socket available to which the flexible transfer supply line is releasably connectable, for. B. also with Help of a plug.

A disadvantage of the arrangement described is that it is often not possible to use the data terminal in immediate vicinity of the stationary first component (Da ten socket) so that a longer (e.g. up to to 15 m) flexible transmission line in general the floor must be laid. To avoid accidents len must this transmission line z. B. with the help specifically molded plastic strips are covered. Even at there is a risk of stumbling and also be these prevent the moving of rolling objects, e.g. B. a file trolley, and cleaning the floors.

In order to eliminate this disadvantage, it is obvious in the room or rooms retrospectively or immediately from to start installing multiple data sockets. This but is disadvantageously very expensive and therefore uneconomical, since there is a large scope for every data socket rich periphery, e.g. B. multiplexer and / or intermediate ver stronger and / or intermediate and / or distribution computer, ge hear. A simple ring line, such as. B. at the 220 V, 50 Hz network is not possible.

The invention is therefore based on the object of a gat to specify the appropriate interface, in particular in large rooms a location-independent and reliable Installation of the data terminals enables and the costs is inexpensive to manufacture.

The invention is in the characterizing part of Pa Claim 1 described.

Advantageous refinements and / or further developments are the dependent claims.

A first advantage of the invention is that the Data transmission between transceivers, these are broadcast and receiving arrangements, done wirelessly. That’s it e.g. B. possible in large office or factory premises To set up data terminals at almost any location len without the disadvantages mentioned above occur.

A second advantage is that there is no interference can occur due to induction influences and / or DC potential differences in the transmission line based. These disruptions can occur particularly in Factory halls occur in which electrical equipment has high lei are installed.

A third advantage is that a spatial one Directional data transmission is possible, so that an un Added data access and possible disruptions due to the same timely operated data terminals can be avoided.

The invention is based on an embodiment for example, based on a schematic drawing he clarifies.

The figure shows a room 1 , e.g. B. an open-plan office or a factory hall in which there is a table 2 with a data terminal 3 placed thereon. In this example, this is a so-called terminal, consisting of a keyboard and a data display device. The data terminal 3 is only connected to the mains, e.g. B. 220 V, 50 Hz, is connected, which is available in a simple manner almost everywhere ver. But it is also possible to use battery-powered data terminals independent of the network, e.g. B. so-called labtops. On the ceiling 4 of the room 1 there is the first component 5 , which is designed as a transceiver for electromagnetic waves and is installed in a stationary manner. This first component 5 is connected to a data processing system via a non-illustrated fixed data transmission line. Such a transceiver contains at least transmitting and receiving devices for the electromagnetic waves. On the data terminal 3 there is a second component 6 , which is also designed as a transceiver for electromagnetic Wel len and the device is electrically coupled to the data end. About the existing air gap between the components 5 , 6 then data transmission is possible, z. B. in the so-called duplex mode, which is indicated by the double arrow 7 . The transceivers mentioned can be adapted to the spatial conditions in a variety of ways. So these z. B work with light in the infrared range. Such optical transceivers, the z. B. contain as essential transmitting and receiving elements a semiconductor laser or a photodiode, may have the disadvantage that air pollution occurs through the surrounding space, the optical entry and exit surfaces, so that interference can occur. This disadvantage can be eliminated by the fact that Transcei ver for electromagnetic waves z. B. in the mm-wave or cm-wave range. In all cases, a spatially undirected transmission is possible, i.e. reflections on walls and / or objects are allowed. This type of transmission has the advantage that the data terminal 3 can be placed in almost any position. In the above-mentioned wave ranges, however, is also simple, for. B. with the help of small parabolic mirrors, a spatially directed data transfer possible. This type of transmission is e.g. B. necessary if unauthorized eavesdropping or interference from adjacent transmission lines should be avoided.

The data transmission between the transceivers can be done in a known manner, for. B. in a wavelength or time division multiplexing method. Furthermore, several transceivers can be attached to the ceiling and / or the walls of the room 1 , which are connected to a fixed data processing system. In this way, a multifaceted multiplexing method for data transmission with many mobile data terminals 3 is possible without the need for movable transmission cables. In currently usual data terminals z. B. a serial Da transmission z. B. with a data transfer speed of 9600 bit / s. This corresponds to a basic frequency of 9.6 kHz. For such frequencies, suitable modulators and demodulators can be produced at low cost in the specified wavelength ranges.

Such transceivers can also be used as communication Spotlights are referred to, for which the English Be drawing "Comspot" is suitable.

Claims (10)

1. Interface for coupling a mobile data terminal to a fixed data processing system, consisting of

• a stationary component that is connected to the data processing system via a stationary transmission line,
• - A second component, which is spatially and electrically connected to the data terminal, and
• a movable transmission line through which a releasable connection between the first and the second component can be established,

characterized,

• - That the first and the second component ( 5 , 6 ) are designed as Tran sceiver for electromagnetic waves and
• - That be the transmission line from an air gap stands.

2. Interface according to claim 1, characterized in that the transceivers for sending and receiving optical Waves are formed. 3. Interface according to claim 2, characterized in that the optical waves in the range of infrared waves lie. 4. Interface according to claim 1, characterized in that the transceivers for sending and receiving are not op table waves are formed. 5. Interface according to claim 4, characterized in that the non-optical waves in the millimeter range until there are centimeter waves. 6. Interface according to one of the preceding claims, characterized in that the transceivers have a directional slide possess a spatially undirected data about carrying allows. 7. Interface according to one of the preceding claims, characterized in that the transceivers have a directional slide have a gram, which is a spatially directed data transmission possible. 8. Interface according to one of the preceding claims, characterized in that the data terminal as termi nal, consisting of a keyboard and a display device,  is formed and that a transceiver on the display device is arranged. 9. Interface according to one of the preceding claims, characterized in that at least one transceiver is fixedly arranged on the ceiling of a room and that the transceiver via a permanently installed transmission Management line connected to the data processing system is.