DE4123008A1 - IR cordless telephone system - uses cooperating IR transceivers with duplicated transmission and reception elements for improving transmission quality - Google Patents

Abstract

The IR telephone system has at least one base station (Bn) and at least one associated sub-station (SuBnx). Each base station (Bn) or sub-station (SUBnx) has a stationary optical transceiver (OFSE) for transmission of IR signals to and from a cooperating transeciver (OUSE) within a portable telephone handset (4). The base station (Bn) and/or the sub-station (SUBnx) and each handset (H) has a number of transmisson elements (SS1,..SSM; HS1..HSM) and reception elements (SE1..SEM; HE1...HEM) covering the same space (Rn), exhibiting similar spatial transmission and reception characteristics. ADVANTAGE - Improved transmission quality of interface between adjacent reception zones.

Description

In telecommunications technology, the "cordless in infrared telephone "not only for the subscriber great interest because it is particularly practical, independent from the radius of action of the connecting cord of a conventional one Telecommunications facility to be and free in the Moving rooms in his home or at his work place, but especially because it's relatively short zen range of infrared connections no security measures required to make telephone connections before eavesdropping to protect unauthorized third parties and other misuse.

The invention relates to a cordless telephone system from at least one base station in one or more rooms men, whereby a base station assigns at least one substation is ordered and the base station or the substation in each case a stationary optical transmitter and receiver unit and one or several mobile telecommunication facilities, esp special handset for sending and receiving In has infrared signals.

From the US patent 44 56 793 and from a published by E.Braun and S.Schön: "A cordless infrared Telephone "in telecom report 3 (1980) Issue 1, pages 24 to 27, a cordless telephone system is known.

In practice, such telephone systems generally pose mean the problem that due to restrictive radiation and reception characteristics of the transmission and reception elements in the base or substation as well as mobile telecommunications onseinrichtung z. B. handset to considerable deterioration transmission quality.  

Another restriction or reduction in the transfer supply quality can e.g. B. also occur when during egg nes calls a telecommunications subscriber with his mobile telecommunications device its whereabouts from a reception area to an adjacent reception area range of the adjacent base or substation changes and switching from one to the next neighboring reception area of a base or substation becomes necessary.

The object underlying the invention is to show a way like a cordless phone system of the type mentioned optimizes the transmission quality as well as the transition from a reception area to a neighboring barten reception range of a base or substation without Ver reduction in transmission quality can be designed.

The solution to the problem results from patent claim 1.

The invention brings in connection with the advantage that emitting shadow, caused by objects in a transmitting lobe of a transmitting element can be avoided another advantage with that an uninterrupted change from a reception area to an adjacent reception area is richly feasible for a base or substation.

A further embodiment of the invention is that wäh an incoming one Radiation power in a decision unit per reception element in the base or substation and per receiving element in the mobile telecommunication facility in a short time Intervals measured and each with the incident beam performance of neighboring receiving elements is compared, to make an assignment between one after each measuring cycle To meet transmission and reception element, in which the one Sending element outgoing and the receiving element of the respective  Radiation power incident on the receiving unit is a Ma ximal value. This has the advantage that a selective assignment of send to receive element each because a high level of transmission quality is achieved, that is z. B. that a telephone connection during one Change from one reception area to an adjacent reception area rich seamlessly with high transmission quality, so for imperceptible to the telephone subscriber.

Another embodiment of the invention is that the over Carrying the infrared signals between the base or substation and mobile telecommunication device bidirectional and is done digitally, with at least that of mobile telecommunications Communication device to transfer base or substation digital infrared signals are data compressed with a Data rate <10 kbit / s can be transmitted in packets. this has in addition to the advantage of reducing the transmission power of the Transmission elements in the mobile telecommunication device, e.g. B. a handset, the advantages that a lower Dimensioning of a memory arranged in the handset lementes both weight and volume can be reduced. Furthermore, it is advantageous that because of the bidirection nalen data exchange no memory elements in the handset requirement.

One embodiment of the invention is that the bidi rectal transmission required both wavelengths, before preferably by using compound semiconductors such as Gallium aluminum arsenide (GaAl) As. This brings the advantages with that in addition to high radiation power a variety of emission wavelengths through simple varia tion of the Al content in the compound semiconductor during its Manufacturing can be generated.

Another embodiment of the invention is that each a bundling of the incident radiation power on the  Receiving elements of the base or substation or the emp trapping elements of the mobile telecommunications device wavelength-bundling elements, in particular by Fresnel lenses or concave mirror. This has the advantage with that due to the wavelength-bundling elements Increased antenna gain achieved and thereby a bes transmission quality is achieved.

A further embodiment of the invention is that the ver averaging processes in the basic and substatio microprocessor controlled and the base and substation are interconnected by at least one data bus, where, for example, at least one of a base station Connected to others at the base or substation closed telecommunications facilities, in particular private or public intermediaries is adjustable. This leads to the further advantage that it is ne ben a variety of connection options also several Gives access to the public switching network.

Further special features of the invention will become apparent from the ing closer explanation of an embodiment of the Cordless telephone system according to the invention using the Drawing can be seen.

The drawing schematically shows, to the extent necessary for understanding the invention, a cordless telephone system consisting of at least one base station Bn in one or more rooms Rn, wherein at least one substation SUBnx is assigned to a base station Bn and the base station Bn or SUBnx substation each Fixed optical transmission and reception unit OFSE and one or more mobile telecommunication device / s OUSE, in particular a handheld device H, for sending and receiving infrared signals IRS, the stationary base station Bn and / or sub station SUBnx and the mobile telecommunication device H each with a plurality of transmission SS 1 ,. . ., SSm; HS 1 ,. . . , HSm and receiving elements SE 1 ,. . . , SEm; HE 1 . . . , HEm illuminate the respective room Rn in such a way that an at least approximately uniform spatial transmission or reception characteristic results.

When a call is established, the input keys, those on the handset H or on the base Bn or substation SUBnx are arranged, a phone number is entered. over the microprocessor CP in the base Bn or SUBnx then all are then necessary for a connection maneuverable procedures initiated (e.g. dialing an office, creating Signaling tones, switching through switching networks).

As receiving elements SE 1 ,. . . , SEm; HE 1 . . . , HEm for the infrared signals IRS, commercially available silicon diodes with optical narrowband filters can be used in the base Bn or substation SUBnx.

The transmission elements SS 1 ,. . . , SSm; HS 1 ,. . . , HSm, which can be designed in particular as infrared luminescent diodes such as (GaAl) As diodes, convert the electrical signals, such as pulse signals or electrical voice signals, into infrared signals IRS.

To reduce the required infrared transmission power in the Handset H is a data compression <10 kbit / s of the di gital sampled voice signals (64 kbit / s) performed.

A further reduction in the power consumption of the shares ven components in the handset H can be by the user using a time separation method, such as that "Pong-Pong method" known from transmission technology, to reach. In this process, the stationary base Bn or Substation SUBx a fixed transmission data rate or data packet rate assigned, the transmission data rate from Handset H is held variable.  

In a transmission direction, for example from handset H to base station Bn, a plurality of transmission elements HS 1 , 1 operated in parallel are used. . . , HSm as in the drawing, but for reasons of clarity there with only 4 transmission elements HS 1 ,. . . , HSm, indicated, the infrared signal IRS emitted into the space Rn. The transmission elements HS 1 ,. . . , HSm are arranged in an advantageous manner in the upper region of the handset H so that the ceiling and wall can be used as primary reflection surfaces.

The receiving elements SE 1 ,. Directed in all directions of the space Rn, as indicated in the drawing. . . , SEm of a fixed base Bn or substation SUBnx receive the infrared signal IRS emitted in the space Rn.

Since it is possible that a further base station Bn + 1 or a substation SUBnx assigned to the base station Bn is arranged in the immediate vicinity, such as in the same room Rn or in an immediately adjacent room Rn - / + 1, this will be done by the Transmission elements HS 1 ,. . . , HSm in the handset H infrared signal IRS received by a plurality of receiving units.

A receiving unit in the base Bn or substation SUBnx consists of a plurality of receiving elements SE 1 ,. . . , SEm and connected amplifiers that receive and amplify the infrared signal IRS.

A comparator unit VS scans the received infrared gnal IRS and compares microprocesses in a first phase The CP receives the radiation energy received in each case neighboring receiving elements HEm.

In a second phase, the receiving element HEm in the base Bn or SUBnx substation where the strongest incident radiation power was measured.

The assignment of a specific transmission element HS 1 ,. . . , HSm of the handset H to a receiving element SE 1 ,. . . , SEm the BaSis-Bn or SUBnx substation not only enables an optimal infrared connection, but also a saving in transmission power. This is brought about by the fact that only that sensor element HEj is operated in the handset H which has been assigned a receiving element SEj in the base Bn or substation SUBnx.

All transmission elements of the handset H radiate in the cycle z. B. every 20 mS again the infrared signal IRS in the surrounding area Rn. A comparative measuring process carried out in the same time slot as described above for the receiving elements SE 1 . . . , SEm of the base Bn or substation SUBnx measures the incident radiation power and, after a new microprocessor-controlled decision process, causes, if necessary, the new assignment of a transmission element HSj in the handset H to a reception element SEj in the base Bn or substation SUBnx.

If an infrared signal IRS is emitted into the room by the base Bn or substation SUBnx, the best infrared connection between the plurality of transmission elements SS 1 ,. . . , SSm to the receiving elements HE 1 ,. . . , HE he averages.

A microprocessor-controlled measurement and assignment procedure averages the best connection for each measuring cycle and arranges it one receiving element for the duration of the next measuring cycle ment HEj in the handset H a transmitting element SSj in the ba sis- Bn or SUBnx too. To save electri shear energy in handset H becomes the other Receiving element HEj of handset H deactivated.

Claims (8)

1. Cordless telephone system, consisting of at least one base station (Bn) in one or more rooms (Rn), with a base station (Bn) being assigned at least one substation (SUBnx) and the base station (Bn) or the substation (SUBnx) in each case has a fixed optical transmitting and receiving unit (OFSE) and one or more mobile telecommunication devices (OUSE), in particular a handheld device (H), for transmitting and receiving infrared signals (IRS), characterized in that the fixed base station ( Bn) and / or Substation (SUBnx) and the mobile telecommunication device (H) each with a plurality of transmitting (SS 1 ,..., SSm; HS 1 ,..., HSm) and receiving elements (SE 1 ,. .., SEm; HE 1 ,..., HEm) illuminate the respective room (Rn) in such a way that there is an at least approximately uniform spatial transmission or reception characteristic. 2. Cordless telephone system according to claim 1, characterized in that during a telecommunications connection a falling radiation power in a decision unit (VS) per receiving element (SE 1 ,..., SEm) in the base (Bn) or sub station ( SUBnx) and each receiving element (HE 1 ,..., HEm) measured in the mobile telecommunication device (H) in short time intervals and each with the incident radiation power of adjacent receiving elements (SE 1 ,..., SEm; HE 1 ,. .., HEm) is compared (VS) in order to assign after a measurement cycle an assignment between a receiving element (HE 1 ,..., HEm) in the mobile telecommunication device (H) and a transmitting element (SS 1 ,..., SSm ) in the base (Bn) or substation (SUBnx), in which those originating from a transmitting element (SS 1 ,..., SSm; HS 1 ,..., HSm) and the receiving element (HE 1 ,..., HEn; SE 1 ,..., SEn) of the respective receiving unit ng has a maximum. 3. Cordless telephone system according to claim 1, characterized, that the transmission of infrared signals (IRS) between base (Bn) or Substation (SUBnx) and mobile telecommunications device (H) takes place bidirectionally and digitally, whereby to at least that of the mobile telecommunication device (H) to the base (Bn) or substation (SUBnx) digi to be transmitted tal infrared signals (IRS) data compressed with a data rate <10 kbit / s are transmitted in packets. 4. Cordless telephone system according to claim 1, characterized, that the transmission of infrared signals (IRS) between base (Bn) or Substation (SUBnx) and mobile telecommunications device (H) with a time separation process. 5. Cordless telephone system according to claim 1, characterized in that the transmitting elements (SS 1 ,..., SSm; HS 1 ,..., HSm) are light-emitting diodes or laser diodes. 6. Cordless telephone system according to claim 3, characterized, that both wel needed for the bidirectional transmission length of the digital infrared signal (IRS) preferably by using compound semiconductors such as gallium alumi nium arsenide ((GaAl) As) can be generated. 7. Cordless telephone system according to claim 1, characterized in that in each case a bundling of the incident Strahlungslei stung on the receiving elements (SE 1 ,..., SEm) of the base (Bn) or substation (SUBnx) or the receiving elements (HE 1 ,..., HEm) of the device in the mobile Telekommunikationseinrich (H) by wavelength-bundling elements, in particular by Fresnel lenses or concave mirrors. 8. Cordless telephone system according to claim 1, characterized, that the switching processes in the basic (Bn) or the substation (SUBnx) microprocessor controlled (CP) and the base (Bn) and substation (SUBnx) with each other at least one data bus system (D) are connected, with min at least from a base station (Bn) to a connection (Al) others to the base (Bn) or substation (SUBnx) closed telecommunications equipment (H) or pri vaten or public switching stations can be produced.