DE10336106A1 - Operation of a wireless LAN communication system has signal quality control for communication between different systems - Google Patents

Abstract

The first wireless LAN communication system has a station [S1] with the same frequency band as a station [S2] in a second system. The stations can be stationary or mobile. The signal quality of the first station is controlled to ensure good transmission to the second with a range boundary [C2]. A controller [CT] operates to control the first station within the first range [C1].

Description

The invention relates to a method for operating a first radio station of a first radio communication system in a frequency band that is simultaneously from a second radio station a second radio communication system is used, as well as a corresponding radio station, a control unit and a computer program.

For Radio communication systems, in which the communication via electromagnetic waves are usually carried out by the relevant authorities for the respective Communication system set one or more individual frequency bands. In these frequency bands generally no other radio communication system may work, mutual interference be avoided. Especially in the frequency range below 6GHz, the frequencies are highly fragmented and contiguous frequency bands for broadband Air interfaces (transmission rates for example greater than 100Mbit / s) are not available either or have to only released by the responsible authorities by means of lengthy approval processes become.

With the so-called Ultra Wideband (UWB) technology becomes a broadband spread band signal below the permissible limit the background noise level of existing radio communication systems used as a radio frequency transmission signal. That means the transmission power this signal is below the level that is the limit of noise signals within a second radio communication system is treated in the same frequency range as the UWB system and geographically overlapping with it is operated. In this way there is no impairment the signal quality in the second radio communication system by the UWB system.

The invention is based, the Operation of two radio communication systems in the same frequency band to allow being available standing radio resources can be used in an improved manner can.

This task is done with a procedure according to claim 1 and a radio station, a control unit and a computer program according to the siblings claims solved. Advantageous developments and further developments of the invention are the subject dependent Expectations.

In the method according to the invention for operating a first radio station of a first radio communication system in a frequency band that is simultaneously from a second radio station a second radio communication system is used, the first Radio station depending of a measure for the quality operated by signals transmitted by the second radio station.

That means by considering the signal quality the second radio station of the second radio communication system at Operation of the first radio station of the first radio communication system the latter use the common radio resource frequency band as far as possible can without the signal quality of the second radio communication system is impaired too much. In particular, therefore, according to a further development of the invention The transmission power of the first radio station is set as a function of the measure of the signal quality be that successful implementation of signal transmission guaranteed by the second radio station becomes.

It is cheap if for at least band spreading occurs in one of the two communication systems. Then lets the transmission power of the system in question compared to the case without using spreading codes, so that interference with the each other system can be reduced. Such a spread let yourself for example by using spreading codes.

While in the UWB technique mentioned above the transmission power is limited from the outset to values below of the background noise level of the geographically overlapping, the same Frequency range using second radio communication system, this is the method according to the invention unnecessary. By considering the signal quality of the second radio communication system when operating the first radio communication system for example, is it possible to increase the transmission power of the first radio station to such an extent that a trouble free Operation of the second radio communication system is just still possible. this makes possible compared to UWB technology, for example, increasing the signal quality in the first radio communication system by increasing the transmission power for existing connections and / or the operation of a larger number connections within the first radio communication system, since its total transmission power can be increased.

According to a development of the invention, the second radio station transmits its signals with a constant transmission power. This is typical for so-called broadcast systems, which are used, for example, in broadcasting. These systems eliminate the need for transmission power control. Therefore, the signal quality in such systems is not subject to the influence of changing transmission powers of the own system. Rather, the signal quality is solely due to the strength of interference signals. Thus, taking into account the signal quality according to the invention of the second communication system, in particular regarding the influence of the signal transmission in the first radio communication system on that in the second radio communication system, since the former results in the interference of the latter.

After a further development of the invention the first radio station has a first coverage area, the one smaller geographical extent than a second coverage area which is assigned to the second radio station, the first Coverage area is enclosed by the second coverage area. This means that the first coverage area is within the second Supply area is arranged. Because the path attenuation of a radio transmission proportional to the distance traveled is on the edge of the coverage area of a radio station maximum, so that the received power from there received signals is minimal. To be on the edge of the supply area for proper operation in the sense of a successful implementation of the signal transmission adequate signal quality to ensure, the transmission power of the radio station assigned to the coverage area chosen accordingly become. this leads to that the signal quality for one Broadcast operations starting at the edge of the coverage area in Direction of the transmitting radio station increases more and more. hereby is for the proper operation close to this system a larger degree of interference signals to the transmitting radio station permissible than at the edge of the supply area. By arranging the first supply area within the second coverage area can be achieved that the allowable interference power within the second coverage area by the first radio communication system is exploited.

The by the first radio station in the Interference generated second supply area of the second radio station can be without interference the operation of the latter may be particularly large if after further training the invention, the first coverage area near the second Radio station and spaced from the edge of the second coverage area is arranged.

It is convenient if the measure of the quality of the signals the second radio station by measurements at the edge of the first coverage area is determined. Here, for example, the position within of the first coverage area, their distance from the second radio station is maximum. This position is the one with the relatively poorest signal quality of the second coverage area within the first coverage area. This can be achieved that signal quality of the second system due to the interference of the first system in the entire first supply area is severely impaired.

According to one embodiment of the invention the measure of the quality of the signals a relationship to the second radio station from useful-to-interference services. In particular, the signal-to-noise ratio (signal to Noise Ratio (SNR). The first radio station can then be operated in this way are adjusted, in particular by adjusting their transmission power accordingly is that the measure of the quality of the signals is above a limit value for successful signal transmission must be observed by the second radio station. For example the transmission power of the first radio station can be increased as long as like a minimal signal-to-noise ratio for the reception powers of the signal transmitted by the second radio station is not undercut becomes.

According to another embodiment the invention can measure the quality of the signals of the second radio station also an error rate of transmitted with the signals Include data. As a measure comes in particular a bit error rate or block error rate.

Taking into account the signal quality of the broadcasts the second radio station through the first radio communication system is preferably repeated, for example periodically. So one can good, updated use of the available Radio resources are carried out by the first radio communication system, without affecting the second radio communication system, even if the strength from other sources of interference changes or if the transmission power of the second radio station changes.

The invention is applicable to any radio communication system applicable. The first radio communication system can, for example be a system with mobile subscribers, the first radio station a stationary station (for example a base station) for supply this participant is.

The radio station according to the invention for a first Radio communication system and the control unit for controlling the first Radio station assign the for the implementation of the method according to the invention as well as its further training and designs necessary components or funds. The same applies to the computer program according to the invention. The latter can, for example, be stored on a record carrier be the subject of a file collection in a configured computing unit such as a processor or computer loaded or stored in other storage devices or on a server his. When the program is run on an appropriate processor or computer, the method according to the invention with its further developments carried out.

The invention is explained below of an embodiment shown in the figures. It demonstrate:

1 an embodiment of the invention with two geographically superimposed radio communication systems in a plan view and

2 two measurement diagrams for the exemplary embodiment 1 ,

1 shows a first radio station S1 with a first coverage area C1, which belongs to a first radio communication system in the form of a WLAN (Wireless Local Area Network). Within the first coverage area C1, the first radio station S1 supplies several subscriber stations R1 of the first system, of which only one has been shown for the sake of clarity. While the first radio station S1 is stationary, the subscriber stations R1 can be either stationary or mobile. Furthermore shows 1 a second radio station S2 of a second radio communication system with a second coverage area C2, within which the second radio station S2 supplies further subscriber stations R3 of the second system, only one of which has been shown and which can be either stationary or mobile. The second radio station S2 is also stationary. The second radio communication system is a broadcast system (broadcasting operation) and the second radio station S2 is a transmitting station of this system, for example for transmitting radio signals SG. While in the second radio communication system there is a unidirectional transmission of the signals SG from the second radio station to the subscriber stations R3, the data transmission in the first radio communication system between the first radio station S1 and the corresponding subscriber stations R1 is bidirectional. The radio coverage areas C1, C2 are arranged approximately concentrically around the corresponding radio station S1, S2.

The second radio station S2 transmits their signals SG with constant transmission power, so this from any subscriber stations R3 within the second coverage area C2 can be received. In contrast, the transmission power of the first radio station is S1 for every individual connection to one of the associated subscriber stations R1 mutable. It is chosen that adequate signal quality for the corresponding connection is achieved.

The first coverage area is C1 significantly smaller than the second coverage area C2 and within from this nearby the second radio station S2 is arranged so that the second radio station S2 is in the first coverage area C1. In other embodiments the second radio station S2 preferably in the middle of the first coverage area C1 can be arranged. Because the first coverage area C1 is much smaller than the second service area is C2, the first service area is C1 also clearly spaced from the edge of the second coverage area C2.

The two radio communication systems or their radio stations S1, S2 are operated in frequency ranges, that at least partially overlap. Therefore, transmissions from the first radio station S1 are automatically interference signals for the second radio communication system and transmissions from the second radio station S2 interference signals for the first radio communication system. To the signals of the two radio communication systems to be able to separate at the receiving end anyway, are those transmitted in the first radio communication system Signals a CDMA component each with a connection-specific spreading code. hereby becomes a band spread of the transmitted Signals reached, with which a transmission is possible with a comparatively low transmission power.

At that position of the edge of the first coverage area C1, which is the furthest distance from the second radio station S2 is a control unit CT arranged to control the operation of the first radio communication system or its first radio station S1. The control unit CT has for this Tax required funds M on. These funds M include other a unit for determining the reception power of signals SG sent to the second station S2. This unit determined continue for the Signals SG a signal-to-noise ratio. The first radio communication system the first radio station S1 is now operated so that the determined one Value of the signal-to-noise ratio does not fall below a predetermined minimum limit. This Limit value must be observed to ensure proper operation to ensure the second radio communication system, so that a successful execution the signal transmission through the second radio station S2.

For this purpose, in a first embodiment of this exemplary embodiment, the comparison of the determined signal-to-noise ratio with the limit value is carried out in the control unit CT itself. The control unit CT then uses corresponding signals A to inform the first radio station S1 of the comparison result. If the result of the comparison is positive, that is to say the necessary signal-to-noise ratio of the second radio communication system is maintained, the first radio station S1 can further increase its total transmission power if necessary, for example to increase the quality of its own communication connections or to establish new connections to its own subscriber stations build. However, if the comparison result is negative, that is to say the necessary signal-to-noise ratio for the second The radio communication system is not reached, so that it is below the limit value for the signal-to-noise ratio, the first radio station S1 reacts to this by reducing the interference it causes. This is done by lowering its total transmission power, for example by accepting a deterioration in the quality of its own connections or by reducing the number of connections it operates.

In another embodiment transmitted the control unit CT the determined signal-to-noise ratio the first radio station S1, which now itself compares with the minimum limit of the signal-to-noise ratio performs and subsequently the measures described above to adjust their transmission power.

Determine the signal-to-noise ratio is carried out by the control unit CT in this exemplary embodiment periodically, as well as the subsequent communication of the results on the Signals A to the first radio station S1. The first radio station S1 has a corresponding unit E for processing by the control unit CT received signals A on and for performing the subsequent transmission power adjustment.

It's like in 1 shown, it is possible that the first radio station S1 transmits control signals B to the control unit CT, with which it requests the latter to determine the signal-to-noise ratio or to communicate the corresponding results to the first radio station S1.

For recording the signal-to-noise ratio by the control unit CT it is necessary that this with a corresponding recipient for the Signals SG of the second radio station S2 is equipped. Furthermore, the Control unit CT corresponding components to also work with the first radio station S1 to be able to communicate.

2 shows once again the mutual relative arrangement of the second radio station S2, the control unit CT and the subscriber station R3 of the second radio supply system 1 , The subscriber station R3 is further away from the second radio station S2 than the control unit CT. Above the control unit CT or the subscriber station R3 in 2 the respective current signal-to-noise ratio SNR is plotted against frequency f, specifically for the frequency range from a lower frequency limit f1 to an upper frequency limit f2, in which the two radio supply systems operate 1 operate. The limit value for the minimum permissible signal-to-noise ratio SNR _min , at which the execution of the signal transmission by the second radio station 52 is just still guaranteed, is entered in the two diagrams. The case is considered that the first radio communication system is not in operation, so that no signals are transmitted from the first radio station S1. Then, due to the shorter distance to the second radio station S2, a larger signal-to-noise ratio results at the control unit CT than at the subscriber station R3. The left diagram in 2 it can be seen that the distance between the current signal-to-noise ratio SNR and the limit value SNR _{min is} relatively large. It is therefore possible to put the first radio station S1 of the first radio communication system into operation and to select its transmission power in such a way that the current signal-to-noise ratio SNR for the signals SG of the second radio station S2 approaches the limit value SNR _min .

The fact that the first coverage area C1 the first radio station S1 is only in the vicinity of the second radio station S2 and does not extend to the edge of the second supply area C2, is the current value of the signal-to-noise ratio SNR at the subscriber station R3 practically unaffected by the emissions from the first radio station S1. It is convenient if the first coverage area C1 is as clearly defined as possible, so that transmissions from the first radio station S1 are actually not via its Exceed the limit and thus the interference signal portion outside of the first coverage area C1. For example happen that the first radio communication system within one is the transmissions of the first radio station S1 and the corresponding subscriber stations R1 outwards well damping building is arranged. One more way, the range of the first radio communication system in comparison to limit to the second radio communication system is to both with different vertical opening angles of the transmission characteristics to provide their radio stations S1, S2. For example by doing that for the transmitting antenna of the second radio station S2 has a higher position chosen is considered for that of the first radio stations on S1. The determination of the signal-to-noise ratio the control unit CT can be used to carry out conventional methods, that are known to the person skilled in the art.

The limit of the second coverage area C2 is defined, moreover, by the fact that the signal-to-noise ratio SNR actually achieved there corresponds to the limit value SNR _min . Further away from the second radio station S2, its signals SG can no longer be properly received.

2 it can be seen that without operation of the first radio communication system within the second radio communication system in the vicinity of the second radio station S2, a relatively high signal-to-noise ratio SNR is achieved for the broadcast signals SG transmitted by the second radio station S2, which is not necessary for correct reception is. With the first radio communication system, the transmission power of the first radio station S1 can now be increased until within the first coverage area C1 and in particular at the position of the control unit CT, the value of the signal-to-noise ratio SNR corresponds to the limit value SNR _min . In contrast to UWB technology, no signals below the permissible frequency range-specific limit of the background noise level of the second radio communication system are used, but rather transmit signals whose transmission power is adapted in accordance with the current values of the signal-to-noise ratio SNR continuously detected by the control unit CT.

Claims (11)

Method for operating a first radio station (S1) a first radio communication system in a frequency band, that from a second radio station (S2) of a second Radio communication system is used in which the first radio station (S1) depending of a measure for the quality of the second radio station (S2) transmitted signals (SG) operated becomes. The method of claim 1, wherein the transmission power the first radio station (S1) is set as a function of the measure for the signal quality, that a successful implementation the signal transmission is guaranteed by the second radio station (S2). Connection according to one of the preceding claims, which the second radio station (S2) their signals (SG) with constant Transmitting power sends. Method according to one of the preceding claims, a first coverage area (C1) of the first radio station (S1) a smaller geographic extent than a second coverage area (C2) of the second radio station (S2) and enclosed by this becomes. The method of claim 4, wherein the first coverage area nearby the second radio station (S2), spaced from the edge of the second coverage area (C2) is arranged. A method according to claim 4 or 5, wherein the measure of the quality of the signals (SG) of the second radio station (S2) by measurements on the edge of the first Coverage area (C1) is determined. Method according to one of the preceding claims, which is the measure of the quality of the signals (SG) a relationship from useful to disruptive services includes. Method according to one of the preceding claims, which is the measure of the quality of the signals (SG) includes an error rate of data transmitted with the signals. Radio station (S1) for a first radio communication system for operation in a frequency band that is simultaneously from a second Radio station (S2) of a second radio communication system is used, with a unit (E) to control its operation depending of a measure of the quality of the second radio station (S2) transmitted signals (SG). Control unit (CT) for controlling a first radio station (S1) of a first radio communication system operating in a frequency band is operated simultaneously by a second radio station (52) second radio communication system is used, with means (M) to control the operation of the first radio station (S1) depending of a measure of the quality of the second radio station (S2) transmitted signals (SG). Computer program for a first radio communication system, that operates in a frequency band that is simultaneously operated by one second radio communication system is used, which contains instructions for control the operation of a radio station (S1) of the first radio communication system dependent on of a measure of the quality of a second radio station (S2) of the second radio communication system sent signals (SG).