WO2015039926A1 - Method for automatic antenna orientation and transmission power regulation, and radio relay system - Google Patents

Abstract

The invention relates to a method for the automatic orientation of antennae of stations of a directional radio link, wherein one station is configured as master and at least one other station as slave. In a first phase, the master and the slave carry out a determination of a mutual coarse alignment for signal exchange. In a second phase, the master determines a control beam direction for each the master and the slave, and specifies the slave control beam direction of the slave. Subsequently, the master specifies, via a number of iterations, a new slave beam direction and a dwell time for the slave. Next, the master sends search signals in a predetermined number of the master beam directions without a waiting period. During the dwell time, the slave carries out a signal quality parameter determination for each signal received, and stores the results thereof. After the dwell time has expired, both stations align themselves in the respective control beam direction. The slave transmits signal quality parameter determination results, and an optimal orientation of the antennae of master and slave is determined and executed.

Description

 Method for automatic antenna alignment and transmission power regulation and radio relay system

The invention relates to a method for the automatic alignment of antennas of stations of a radio link, a master transceiver and an operating method for a master transceiver. Furthermore, the invention relates to a slave transceiver and an operating method for a slave transceiver and a directional radio arrangement.

Directional radio systems, in particular with wavelengths in the range of millimeter waves (60 GHz, 70-80 GHz, 90 GHz), use antennas with a very strong directivity, ie a very narrow radiation pattern, partly due to frequency-regulatory requirements. The typical opening angles of 60 GHz radio relay systems are, for example, between 0.5 ° and 3 °. However, some even more concentrated antennas are in use. The very small opening angle of the antennas and the consequent small beam diameters, especially in connection with non-fixed distances between two radio stations, lead to great difficulties in the alignment of the antennas. For the sake of brevity, microwave radio stations are also referred to simply as stations below. Manual alignment of the antennas is very time consuming and requires additional aids. Due to the small beam diameter, however, an automatic antenna adjustment is difficult. In particular, in the typical case of a point-to-point radio relay system in which the stations do not have an independent additional communication link, no data exchange parallel to the alignment and thus no synchronous and centrally controlled alignment of the antenna beam is possible. Instead, the stations involved must independently conduct a search for a communication partner by panning the antenna beam over all possible beam positions. US 2010/0302101 A1 describes a method used here which is based on two different pivoting speeds of the stations. One station swivels the beam rapidly and periodically over all of its beam positions, while the second station slowly swings its beam and remains the same time in a position that the first station requires to pan over all positions. This ensures that all combinations of beam positions are tested and the stations find each other.

The procedure described in US 2010/0302101 A1 results in a long search time, since many combination options have to be tested by the small beam diameters and the consequent large number of beam directions. In addition, in the method described there, information about the path attenuation (for example, based on the distance) is needed to narrow down the search space

Desirable is thus an accelerated automatic alignment of antennas of a radio link.

This object is achieved according to a first aspect by a method for the automatic alignment of antennas of stations of a radio link, wherein one station is configured as a master and at least one other station as a slave and in which in a first phase of the master and the slave Coarse scanning for determining a mutual coarse alignment in which master and slave can exchange signals with each other, and wherein in a second phase after the coarse alignment has been identified and set, the master determines a control beam direction of the master and a control beam direction of the slave, hereinafter referred to as master Control beam direction and slave control beam direction are designated, and the slave whose slave control beam direction specifies. At- Finally, over a number of iterations, the master respectively gives a new slave beam direction and a dwell time in which the slave is to receive in this new slave beam direction. The master then sends search signals in a predetermined number of its master beam directions without lingering in the master beam directions, the slave performs signal quality parameter determination for each received signal during the dwell time, and stores its results. After the dwell time has elapsed, both stations are directed into the respective predetermined control beam direction, the slave transmits the results of the signal quality parameter determination and, on the basis of the signal quality parameter determination, an optimal mutual alignment of the antennas of the master and slave is determined and these are aligned accordingly ,

The invention is based on the finding that a method for automatic alignment of antennas of a radio link can be accelerated by, after a coarse alignment was found in which the master and the slave can communicate with each other, the master increases its scanning speed. This happens in the present case by leaving no residence time in the respective master beam direction, but changes directly after sending a signal to the next master beam direction and the slave continuously receives signals and only after a search of the master over a predetermined number of its master beam directions of Slave transmitted to the master, in which beam direction he has received signals in which quality. The slave remains in this case for each pass on a slave beam direction predetermined by the master and changes only in the next pass on a turn determined by the master new slave beam direction. Using this method, accelerated searches can be performed over all combinations of beam directions of master and slave.

With beam position is meant in relation to antennas in the present application in different embodiments, for example, an orientation of an antenna by mechanical means, or for example, an orientation of the antenna, which alone or additionally by electronically influencing the radiation characteristics, such as beam steering can be adjusted.

The term beam direction is not always used in terms of antennas and stations of a radio link in the context of the present application in the sense of a transmission direction, but depending on the context (transmitter or receiver) in the sense of a receive direction. Hereinafter, embodiments of the method according to the invention will be described.

Preferably, the dwell time of the slave in the second phase corresponds to the amount of time the master requires to send seek signals in the predetermined number of master beam directions. The term dwell time is used here for periods of time in which a respective station dwells in a beam direction until the end of a predetermined time independently of signals arriving in this time. In contrast, the term waiting time is used for periods of time in which a respective station dwells in a beam direction until either a certain signal has arrived or a predetermined time has elapsed.

According to an exemplary embodiment of the method according to the invention, coarse sampling in the first phase comprises the following steps: the master sends a search signal in a first master beam direction and then waits for a defined waiting time for a response signal and changes to a second one if no response signal after the waiting time Master beam direction, upon receipt of a response signal, the master sends a start signal in the first master beam direction, with which a second phase is initiated; the slave waits in a first slave beam direction a defined waiting time which is greater than the waiting time of the master for receiving a search signal and changes in the absence of a search signal after the waiting time to a second slave beam direction, upon receipt of a search signal, it sends a response signal in the first slave beam direction. This method provides a way of coarse sampling. Other methods that can serve to find a combination of a master beam direction and a slave beam direction in which master and slave can communicate with each other are also suitable. In the method according to the invention, the master takes over the control functionality for the communication between master and slave and thus enables a controlled communication between both stations during the search. Therefore, the method according to the invention can be used particularly advantageously in TDD-based methods which have no possibility for continuous control. In one embodiment of the method according to the invention, the stations therefore work with a TDD-based method. In TDD-based methods, only one frequency channel is used so that the two stations can not simultaneously transmit a continuous signal during a scan of beam combinations. A sample of beam combination means here the search of master and slave for combinations of their respective beam directions, in which a communication between master and slave is possible.

Preferably, the method is used at stations operating in a frequency range above 50 GHz. In these frequency ranges, in some cases high antenna gains and thus very small beam widths are prescribed for frequency regulation in the outdoor area, so that a method for alignment is required. At lower frequencies very large antennas are necessary to realize high antenna gains. Above 50 GHz, even highly concentrated antennas are relatively small. However, the method can also be used in all other frequency ranges, provided that directional antennas are used with adjustable orientation.

In one embodiment of the method according to the invention, in order to find the best possible beam, in the second phase all remaining beam combinations are tested which have not yet been passed through in the first phase.

In one embodiment of the method, termination criteria for the iterations of the second phase may be defined. For example, such an abort criterion may be that an alignment has been found in which the signals of the desired quality can be transmitted or a certain number of slave beam directions have been traversed. With the aid of this embodiment, the alignment can be further accelerated. In this case, the search space no longer extends beyond all possible combinations and possibly the optimal combination is not found (for example, if several alignments lead to a contact due to reflections). But this is not a problem because the combination found meets all the requirements for data transmission.

As a rule, there is no knowledge of the distance between the antennas when aligning the antennas of a radio link. The missing distance indication requires that always the smallest beam diameter is used, ie the antenna gain, which is necessary for the maximum specified distance of the system. Moreover, in some cases, the use of a larger beam diameter that is a smaller antenna gain frequency regulatory not allowed. In addition, the maximum transmit power required for the largest possible specified distance is also used. However, if the distance of the stations is lower, this can lead to an overload of the input amplifiers on the receiver. In the prior art methods, this results in a communication link not being established can be, because the overdriven signal no response takes place and the transmitter has no knowledge of whether the response is missing due to a lack of agreement of the beam directions or due to an overload of the receiver. In one embodiment of the method, the master or the slave measures in the first phase when detecting an overdriven signal, the duration of this overdriven signal in the first phase. From the duration of the overdriven signal and a comparison with a desired duration of an expected search or response signal, the reception of the expected search or response signal is then concluded and a response provided in response to the receipt of this expected search or response signal is sent , This embodiment allows the communication between master and slave, even if it has come to an overdrive.

This embodiment makes use of the insight that communication can be established despite overriding, when the station receiving an overdriven signal measures the duration of the overdriven signal and concludes from this period of time and a comparison of this time duration with a desired duration of an expected signal can that the expected signal has arrived and then sends an appropriate response to the expected signal. It is particularly advantageous for the master in the context of this embodiment, when it receives an overdriven response signal in a first phase, to determine from a received power of the response signal a new transmission power of the search signal which is lower than that previously used and subsequently the master Search signal with the new transmission power sends. This process is then preferably carried out iteratively until either a non-overdriven exchange of search signal and response signal has occurred or a presence of an abort criterion is detected without receipt of a non-overdriven signal. By means of this method it is possible, in addition to optimizing the alignment of the antennas, to automatically optimize the transmission power and to avoid communication aborts in fundamentally suitable beam directions due to overloading. For example, the expiration of a predetermined maximum waiting time is a suitable stopping criterion or the passage of a predetermined number of iterations. Preferably, after the abort criterion has been met, the first phase is continued with a new master beam direction. After a non-overdriven exchange of response signal and search signal in a preferred embodiment, the master sends a start signal, with which it triggers the beginning of the second phase. The inventive method can be performed not only with a master and a slave, but also with multiple slaves, which are each addressed in different time slots. Thus, the operation of a radio link with more than two stations is possible. According to a second aspect, the invention relates to a master transceiver for operating a radio link, hereinafter master, with a transceiver configured to generate, transmit and receive signals in adjustable directions via at least one antenna and a control unit which is designed for automatic alignment of the antenna, the transceiver unit in a first phase to perform a coarse scan for determining a mutual coarse alignment with a slave transceiver, slave hereinafter to initiate after completion of coarse scanning a second phase and in the second phase of the send Receive unit to specify a master control beam direction and in the slave a slave control beam direction. Moreover, the control unit is designed to then specify a new slave beam direction for the slave over a number of iterations and a dwell time in which the slave is to receive in this new slave beam direction, the transceiver unit for the subsequent transmission of To drive search signals in a predetermined number of master beam directions, and to drive the transceiver unit to receive results of a signal quality parameter determination from the slave in the specified master control beam direction after expiration of the dwell time, and based on the signal quality parameter determination, optimizes mutual alignment of the antennas of transmission To determine receiving unit and slave and to control the antenna of the transceiver unit for the appropriate orientation. The master transceiver of the second aspect of the invention is adapted to be used in a method according to the first aspect of the invention or to perform parts of the method. He is also referred to here for a short time as Master. However, this does not mean that the transceiver within the meaning of the invention must be able to act exclusively as a master in the sense of the process control according to the invention. Such an exclusive function is only to be understood as an exemplary embodiment. Preferred embodiments of transceivers are designed to be operated both as a master and as a slave.

In a preferred embodiment, the master transceiver according to the second aspect of the invention is implemented in coarse sampling in the first phase Sending search signal in a first master beam direction and then waiting for a defined waiting time for a response signal and to switch to a second master beam direction in the absence of a response signal after the waiting time and to emit a start signal in the first master beam direction upon receipt of a response signal - send, with which a second phase is initiated.

In order to be able to establish a communication in spite of a possible override, the master is preferably designed to measure the duration of this overdriven signal in the first phase when detecting an overdriven signal, from the duration of the overdriven signal and a comparison with a setpoint duration of one expected response signal to close upon receipt of the expected response signal and to send a response provided in response to the receipt of this expected response signal response.

Preferably, in the first phase, when receiving an overdriven response signal, the master is adapted to determine from a received power of the response signal a new transmission power of the search signal which is lower than that previously used and subsequently to transmit the search signal at the new transmission power. For example, in a first variant of this embodiment, the master is designed to determine the power of the input signal at the output of the input amplifier. In this variant, it is not possible to deduce the absolute level of an overload, so that a suitable power must be determined via certain predefined gradations. In an alternative second variant, the master additionally has a module for power recognition with a greater dynamic range than the dynamic range of the input amplifier, which is connected in parallel with the input amplifier. This can be concluded directly on the received power and the corresponding adjustment can be calculated. This process is preferably carried out iteratively until either a non-overdriven exchange of search signal and response signal occurs or a presence of an abort criterion is detected without receipt of a non-overdriven signal. This embodiment of the master makes it possible to maintain communication despite an overdriven signal. In addition, it makes it possible to adapt the transmission power and thus not only to enable optimized alignment but also optimized transmission power.

Preferably, the master is designed to continue after the presence of the termination criterion, the first phase with a new master beam direction. Furthermore, the master preferably designed to emit a start signal to the beginning of the second phase after a non-overdriven exchange.

According to a third aspect, the invention relates to an operating method for a master transceiver of a radio link, hereinafter master, with a control unit and a transceiver with at least one antenna, in which the master in exchange with a slave transceiver, hereinafter slave, performs a coarse scan to determine a mutual coarse alignment, in which the master can exchange signals with the slave, after completion of coarse scanning of the master initiates a second phase in which the master of its transceiver unit specifies a master control beam direction and the slave a slave control beam direction and then over a number of iterations each of the master specifies a new slave beam direction for the slave and a dwell time in which the slave is to receive in this new slave beam direction. The master then sends search signals in a predetermined number of its master beam directions, upon expiration of the dwell time it receives results of a signal quality parameter determination from the slave on the designated master control beam direction. On the basis of the signal quality parameter determination, the master determines an optimal mutual alignment of the antennas of the transceiver unit and slave and aligns the antenna of the transceiver unit accordingly. According to a fourth aspect, the invention relates to a slave transceiver for operating a radio link, comprising a transceiver configured to generate, transmit and receive signals in adjustable directions via at least one antenna and a control unit adapted to automatic alignment of the antenna, the transceiver unit in a first phase for performing a coarse scan to determine a mutual coarse alignment with a master to control, and in a second phase over a number of iterations each time specified by the master, the transceiver for setting a new slave beam direction and a dwell time in which the transceiver unit is to receive this new slave beam direction, and to perform a signal quality parameter determination for each received signal and to store the results of the signal quality parameter determination To control the expiration of the dwell the transceiver unit to set a previously set by the master slave control beam direction and transmit the results of the signal quality parameter determination, the antenna of the transceiver unit for alignment according to a previously transmitted by the master optimum mutual alignment.

The slave transceiver of the fourth aspect of the invention is adapted to be used in a method according to the first aspect of the invention or to perform parts of the method. He is also referred to here for a short time as a slave. However, this does not mean that the transceiver within the meaning of the invention must be able to act exclusively as a slave in the sense of the process control according to the invention. Such an exclusive function is only to be understood as an exemplary embodiment. Preferred embodiments of transceivers according to the invention are designed, as mentioned, to be able to be operated both as a master and as a slave.

Preferably, in the coarse scan in the first phase in a first slave beam direction, the slave is designed to wait a defined waiting time which is greater than the waiting time of a master for receiving a search signal of the master and if there is no search signal after the waiting time to one to change the second slave beam direction and to send a response signal in the first slave beam direction upon receipt of a search signal.

In a further embodiment, the slave is configured to measure the duration of this overdriven signal in the first phase upon detection of an overdriven signal, the duration of the overdriven signal and a comparison with a desired duration of an expected search or response signal on the receive close the expected search or response signal and send a response in response to receiving this expected search or response signal.

According to a fifth aspect, the invention relates to an operating method for a slave having a control unit and a transceiver unit having at least one antenna, wherein the slave, in exchange with a master, performs a coarse scan for determining a mutual coarse alignment, in which the slave with a Master can exchange signals, the slave receives a signal to initiate a second phase in which the slave over a number of iterations each of the default of the master a new slave beam direction and a dwell time in which receive the slave in this new slave beam direction should set, perform a signal quality parameter determination for each received signal and store its results. After the dwell time has elapsed, the slave, in order to transmit the results of the signal quality parameter determination, sets the slave value previously set by the master. Control beam direction and aligns the antenna of the transceiver unit in accordance with a transmitted from the master optimal alignment.

According to a sixth aspect, the invention relates to a directional radio arrangement comprising a master according to the invention and at least one slave according to the invention.

The orientation of the antennas in the methods and devices according to the invention can be carried out both via a motor-assisted mechanical adjustment and via a so-called beamsteering method. In Beamsteering method, the alignment of the antenna is done via an amplitude and / or phase control. Antennas for beamsteering methods usually consist of several elements. For the purposes of this invention, beamsteering is understood to mean an electronic method for antenna alignment, in which a separate influencing of the signal amplitude or the signal phase or the signal amplitude and the signal phase takes place for each antenna element or for a group of antenna elements.

The above described apparatuses and operating methods according to the second to fifth aspects of the invention share the advantages of the method of the first aspect of the invention.

Hereinafter, with reference to figures, further embodiments will be explained, wherein

FIG. 1 shows schematically a flow chart of an embodiment of a method according to the first aspect of the invention,

Figure 2 shows schematically an embodiment of a directional radio arrangement according to the sixth aspect of the invention,

3 shows schematically an embodiment of an operating method for a

 Master transceiver according to the third aspect of the invention,

4 shows schematically an embodiment of an operating method for a

 Slave transceiver according to the fifth aspect of the invention shows.

Figure 1 shows schematically a method for automatic alignment of antennas of stations of a radio link according to the first aspect of the invention. The Method for automatically aligning antennas of stations of a radio link according to the first aspect of the invention is a two-stage process. In a first phase, a beam search is performed, in other words a coarse scan for determining a mutual coarse alignment of the antennas of the stations. The first station, the master M, scans in a first phase quickly over a predetermined number of its master beam directions. For this he selects a master beam direction and sends in this a Discover packet (S1 1 1). Subsequently, the master waits for a response signal in step S112. If the master does not receive a response signal during the waiting time, it continues its search with step S1 13, switching to the next master beam direction. The second station, the slave in turn scans in the first phase over a predetermined number of its slave beam directions. The scan speed of the slave is slower than the scan speed of the master. The slave waits for the reception of a DISCOVER packet sent by the master (S121). If the slave does not receive such a DISCOVER packet during its waiting time, it continues its scan in a next slave beam direction in step S122. If the slave receives a DISCOVER packet during the waiting time, it responds with a HEREIAM packet in step S123. This HEREIAM packet may include, among other things, an assessment of the receive signal quality of the DISCOVER packet (eg, RSSI) and the selected transmit direction. If the selected transmission direction is transmitted from the slave to the master M, then it is possible for him to determine the current position of the slave in the scan algorithm. It should be mentioned that the names of the packet types used are only examples. Of course, other names can also be used. Besides the use of DISCOVER and HEREIAM package types, the use of other types of packages is also within the scope of the invention. The packages may also have other functions or contain other parameters as well.

If the master has received a HEREIAM packet from the slave in step S1 12, he sends in step S1 14 a signal to initiate a second phase to the slave. This signal may contain a simple control packet for confirming the coarse alignment, but it may also be a more extensive handshake protocol between master and slave exchanged. Upon receipt of the second phase initiation signal in step S124, the slave also switches to the second phase. In the second phase, a fast iterative search of further connection possibilities controlled by the master M takes place in the remaining beam combination possibilities. For this purpose, the master M gives the slave at the beginning of an iteration in step S1 15 a slave control beam direction, as well as another, until now not tested slave beam direction and the time, in which the slave should receive in this direction. Furthermore, in step S1 15, the master determines a master control beam direction. In step S125, the slave receives the information of the master. In step S126, the slave then dwells in the specified slave beam direction until the dwell time has expired. Meanwhile, in step S116, the master sends DISCOVER packets in a predetermined number of its master beam directions without waiting for a response. This considerably speeds up the run for testing the beam combination possibilities. The slave also stores parameters of the received packets in step S126, e.g. B. the used beam direction of the master and parameters for signal quality assessment, such. B. an indicator for the reception power, such. For example, the RSSI value (Received Signal Strength Indicator). The master sets the master control beam direction after passing through the predetermined number of master beam directions in step S1 17. After the dwell time, the slave sets the slave control beam direction (S127) and now transmits to the master the parameters of the received packets as well as the parameters for signal quality evaluation. Subsequently, the master iteratively continues the evaluation at step S1 15 with the transmission of the previous or a new beam direction for the controller, as well as a new slave beam direction for the slave, until a predetermined number of beam combinations have been tested. After the predetermined number of beam combinations has been tested, the master evaluates the parameters received from the slave and thus determines an optimal alignment of slave and master. Optimal alignment means guaranteeing the best possible signal quality, whereby the signal quality is evaluated, for example, with the received signal strength. In one embodiment of the method, a measure of the accuracy of the received signal, for example the bit error rate, is additionally used. If an exchange between master and slave fails in the course of the procedure or a timeout occurs when returning to the predetermined control beam direction, ie no packet from the other station arrives within a specified waiting time, then in one embodiment the station can automatically return to the first phase , In this case, it advantageously selects a beam direction which corresponds to the last-used beam direction or one of the last-used adjacent and previously successfully tested beam directions. This procedure can be used to ensure that the connection search starts again with a beam direction in the vicinity of which a connection was already possible. This also leads to an acceleration of the method, for example compared to a restart with the coarse alignment. In one embodiment of the method shown, the master transmits at the beginning of the first phase with its maximum transmission power in order to also detect such stations. be able to reach those who are at a maximum distance to him. If an overload of the receiver's receive amplifier occurs due to the maximum transmission power of the master, then the incoming packet can generally not be decoded without error. In the prior art, no evaluation of the information contained and no handshake implementation is then possible. In one embodiment of the method according to the invention, despite the override, a connection can be established by both stations performing a time measurement of the incoming signal when receiving an overdriven signal. If an overdriven signal is received, the received power during the packet reception is at or near the maximum level. By measuring the duration of the overdrive and comparing the duration of the overdriven signal with a desired duration of an expected signal, the receiving station, e.g. B. the slave, determine that it is probably z. B. is a DISCOVER package. If the slave can conclude that it has received a DISCOVER packet, it will in turn send a HEREIAM packet. In a preferred embodiment of the method, this HEREIAM packet is also overridden at the master. For its part, the master can carry out a time measurement of the overdriven signal as well as a comparison with the desired duration of an expected signal and thus conclude that a HEREIAM packet has been received. In addition, the master can determine a new transmission power, which is reduced compared to the previous transmission power and send with this reduced transmission power another DISCOVER packet. In addition, when sending a packet in response to an overdriven packet, the respective station can adjust its latency in the current cycle accordingly, ie, the station extends its latency by the duration of the overdriven packet. This process is repeated iteratively until either a successive reduction in performance allows a faultless exchange of DISCOVER and HEREIAM packets or until a timeout expires, since no more packets arrive. In the latter case, the two stations continue with the first phase of the procedure. In the former, the master sends the signal to initiate the second phase. If the slave can decode this, the procedure continues in the second phase as described above. However, if the master has sent a signal to the slave after the faultless exchange of DISCOVER and HEREIAM packets that it can not decode, the slave resets its slave beam direction by one position and remains in the first phase, ie it does not save any Parameters of incoming signals and also does not send anything to the master. The master then notices after the first iteration of the second phase that it is not receiving any signal from the slave in the master control beam direction. Then he sets his transmission power back to the maximum and starts again with the first phase.

FIG. 2 schematically shows an embodiment of a radio relay arrangement 1000 according to a sixth aspect of the invention with a master transceiver 1100 according to the second aspect of the invention and a slave transceiver 1200 according to the third aspect of the invention. The master 1 100 has a control unit 1 1 10 and a transceiver unit 1 120 with an antenna 1 125. In this case, the transceiver unit 1 120 is designed to generate, transmit and receive signals in adjustable directions via the antenna 1 125. The control unit 1 1 10 is designed to control the automatic alignment of the antenna 1 125, the transceiver unit 1 120 for performing a coarse scan for determining a reciprocal coarse alignment with a slave transceiver 1200. In addition, the control unit is designed to initiate a second phase after coarse scanning and to specify in the second phase of the transceiver unit 1 120 and the slave 1200 a respective control beam direction, then over a number of iterations each have a new slave beam direction for the slave and a residence time in which the slave is to receive in this slave beam direction, pretending to control the transceiver unit 1 120 for the subsequent transmission of search signals in a predetermined number of master beam directions. In addition, the control unit 1 1 10 is configured to control the transceiver unit 1 120 after the expiration of the residence time for receiving results of a signal quality parameter determination from the slave in the fixed master control beam direction and based on the signal quality parameter determination an optimal mutual orientation of the antenna 1 125 , the transmitting-receiving unit 1 120 and the antenna 1225 of the slave 1200 to determine and to control the antenna 1 125 of the transceiver unit 1 120 for the corresponding alignment. The antenna 1 125 of the master 1 100 can be designed in the form of a mechanically adjustable antenna. The transceiver unit 1 120 can have a motor-assisted system which is controlled by the control unit 1 1 10 and mechanically adjusts the antenna 1 125. In a further embodiment, however, the antenna 125 can also consist of a plurality of elements and be set to a specific beam direction by an electronic phase and / or amplitude control of the signal for each element.

The slave 1200 has a controller 1210 and a transmitter-receiver unit 1220 with an antenna 1225. The transceiver unit 1220 of the slave 1200 is configured to generate signals in adjustable directions via the antenna 1225, to send and receive. The controller 1210 of the slave 1200 is configured to automatically align the antenna 1225 to drive the transceiver 1220 in a first phase to perform a coarse scan to determine mutual coarse alignment with the master 1100 and in a second phase over a number of iterations, respectively according to specification by the master 1 100, the transceiver unit 1220 for setting a new slave beam direction and a residence time in which the transceiver unit 1220 is to receive in this new slave beam direction and for performing a signal quality parameter determination for each received signal and the To save the results of the signal quality parameter determination. In addition, the control unit 1210 is configured to control the transceiver unit 1220 after the dwell time has elapsed, to set a slave control beam direction previously set by the master and to transmit the results of the signal quality parameter determination and the transceiver unit 1220 to align the antenna 1225 in accordance with one of Masters conveyed optimal reciprocal orientation. With the microwave radio arrangement 1000 shown so that a radio link can be established automatically and quickly.

Figure 3 shows schematically an embodiment of an operating method for a master transceiver according to the third aspect of the invention. The method of operation begins with the beginning of a first phase P1 in which the master is initialized in step MS101 in a first master beam direction. Thereafter, in step MS102, the master sends a DISCOVER packet and waits a predetermined waiting time for a response signal in step MS103. If the master has not received a signal during the wait, it continues phase 1 with step MS104, aligning in a new master beam direction and proceeding to step MS102. If the master has received a response (y) during the waiting time, it can optionally store its master beam direction and results of a signal quality parameter determination (eg RSSI) in step MS 105. In step MS106, the master sends to the slave, from which it has received the response signal, a start signal for starting a second phase P2. Optionally, in step MS106, with the second phase start signal to the slave, the master may input to the slave a slave control beam direction as well as a new slave beam direction for the slave and a dwell time in which the slave is to receive in phase in that slave beam direction Send slave. However, this can also be done in a separate exchange after the transmission of the start signal for the second phase. In phase P2, the master is again initialized to a first beam position in step MS201. In step MS202, it sends a DISCOVER packet in this master beam direction. After the sending that of the DISCOVER packet, the master does not dwell in the first master beam direction to await a response, but aligns with a next master beam direction in step MS203 unless it has already used a predetermined number of master beam directions (n ). If the master has passed through all the prescribed master beam directions (y), it orients itself to a previously determined master control beam direction (MS204). Optionally, in step MS205, the master sends a query packet to the slave for transmission of results of a signal quality parameter determination of the slave. The master can also simply wait for the receipt of a packet from the slave containing this information. If the master has not received the information from the slave, the master restarts phase 1 with step MS206. If the master has received the information from the slave (y), the master starts a query in step MS207 whether a predetermined number of beam combinations has been tested. If this is not the case, then in step MS208 the master sends a slave control beam direction as well as a new slave beam direction and a dwell time in which the slave is to stay in this slave beam direction to the slave and thus starts the iteration again at step MS201. If all predetermined beam combinations are tested (y), the master evaluates the results of the signal quality parameter determination transmitted by the slave in step MS209. For this purpose, in a step MS209a the master can first sort the tested beam combinations on the basis of the results of the signal quality parameter determination (eg RSSI) and send slave beam directions selected with the slave to the priority of the respective beam direction. In step MS209b, the master can then, in exchange with the slave, evaluate the selected beam combinations iteratively and with a bidirectional measurement of further signal quality parameters, eg the bit error rate or the packet error rate. The evaluation of the bit / packet error rate with approximately 1000 packets per beam direction advantageously takes place. In step MS209c, the master can then select the optimal beam combination from the evaluation and transmit it to the slave with a handshake protocol. If the handshake was successful (y), the antennas are aligned accordingly and the procedure is completed (MS210). If the handshake was not successful (n), then in step MS21 1 the master beam direction is discarded and if no further suitable beam combinations are available (y), phase 1 is restarted MS212. If further suitable beam combinations are available, then the next best beam combination is selected in step MS209c and transferred to the slave by means of a handshake. FIG. 4 schematically shows an operation method for a slave transceiver according to the fourth aspect of the invention. The operating procedure begins with a first Phase P1. In step SS101, the slave is initialized at a first beam position. In step S102, in this slave beam-beam direction, the slave waits a predetermined waiting time to receive a DISCOVER packet of a master. The waiting time of the slave is longer than a waiting time of the master. If the slave has not received a DISCOVER packet from a master within the waiting time, it sets a next slave beam direction in step SS103 and again waits for the reception of a DISCOVER packet in step SS102. If the slave has received a DISCOVER packet (y), it sends in step SS104 a response signal to the master from which it received the DISCOVER packet. With the response signal, the slave can optionally also send to the master information about the signal quality parameters of the receiving packet as well as about its current slave beam direction. If the slave has not received a first phase DISCOVER packet but a second phase DISCOVER packet, it proceeds to step SS203, in which case the DISCOVER packet additionally includes a slave control beam direction. In step SS105, after sending a response signal to the master in step SS104, the slave waits to receive a start signal for the second phase P2 or to exceed a predetermined time for a timeout. If the slave has not received a start signal for the second phase (n), it resets its slave beam direction by one position in step SS106 and restarts with step SS102. If the slave has received from the master a start signal for the second phase P2 (y), the slave starts the second phase by switching over to the slave beam direction transmitted by the master at the initiation of the second phase in step SS201. In step SS202, the slave stores all received packets as well as the results of signal quality parameter determinations of the received packets. If the dwell time which the master has transmitted to the slave with the initiation of the second phase has not yet expired, the slave proceeds to step SS202 until the time has elapsed (y). After the dwell time has elapsed, the slave switches to the slave control beam direction transmitted by the master in step SS203. There, in step SS204, the slave may optionally wait for the reception of a polling packet from the master, and after having received it (y), proceed to step SS206. If the slave does not receive a polling packet from the master in step SS204, the slave will reset its beam direction by one position in step SS205 and begin again with step SS102 of the first phase. In step SS206, the slave sends the results of the signal quality parameter determinations and optionally further information about the received packets to the master. Step SS206 may either be following a waiting time of the slave in step SS204 for a query packet of the master, or the transmission of the information in step SS206 is effected after the expiration of the dwell time. In step SS207, the slave may turn to a control signal of the master or the master Waiting for a timeout period to expire. If the slave does not receive a packet of the master (s) during the timeout period, the slave continues to step SS205. However, if the slave has received a packet from the master, it evaluates this in step SS208. If the master communicates with the packet requesting to assume a new slave beam direction, the slave continues phase 2 with the new slave beam direction in step SS201. If the master has declared with the packet that the iterative combination search is completed in phase 2 (n), then in step SS210 the slave can receive the optimal alignment from the master and secure it via a handshake protocol. Optionally, in step SS209, the slave may perform an iterative evaluation of beam combina- tions determined by the master together with the master. If the handshake has been successfully performed (y) in step SS210, the antennas are aligned accordingly and the process is completed (SS21 1). If the handshake is unsuccessful, the slave beam direction is rejected as inappropriate (SS212) and, if no further beam combinations have been identified as appropriate, phase P1 is restarted in step SS213. If further suitable beam combinations have been identified by the master, then a next beam combination is selected by the master and with a handshake to the slave the beam combination and the slave beam direction are passed in step SS210.

Claims

claims

A method for automatic alignment of antennas of stations of a radio link, wherein a station is configured as a master and at least one other station as a slave and wherein in a first phase - the master and the slave perform a coarse scan for determining a mutual coarse alignment, in the Master and slave signals can exchange with each other, and wherein in a second phase

after the rough alignment has been identified and set, the master determines a control beam direction of the master, hereinafter master control beam direction, and a control beam direction of the slave, hereinafter slave control beam direction, and gives the slave the slave control beam direction,

- Then over a number of iterations each - the master a new slave beam direction and a residence time in which the

Slave is to receive in this new slave beam direction, the slave pretends, the master then sends search signals in a predetermined number of its master beam directions to remain without waiting in the master beam directions, - the slave during the dwell a Signalqualitätsparameterfestim- mung for each receives the received signal and stores its results, after the lapse of the dwell time the master adjusts the master control beam direction and the slave sets the slave control beam direction and the slave transmits the results of the signal quality parameter determination to the master, - Based on the signal quality parameter determination, an optimal mutual alignment of the antennas of master and slave is determined and they are aligned accordingly.

2. The method of claim 1, wherein in the coarse scan in the first phase - the master sends a search signal in a first master beam direction and then waits for a defined waiting time for a response signal and

if there is no response signal after the waiting time, changes to a second master beam direction,

upon receipt of a response signal, emits a start signal in the first master beam direction, with which a second phase is initiated,

- The slave in a first slave beam direction a defined waiting time which is greater than the waiting time of the master waiting for the reception of a search signal and

in the absence of a search signal after the waiting time changes to a second slave beam direction, on receipt of a search signal a response signal in the first slave direction

Beam direction sends.

3. The method of claim 1, wherein the stations operate with a TDD-based method.

4. The method of claim 1, wherein in the first phase the master or the slave measures the time duration of this overdriven signal when detecting an overdriven signal, from the duration of the overdriven signal and a comparison with a desired duration of an expected search or response signal is closed upon receipt of the expected search or response signal and sends a response provided in response to receipt of this expected search or response signal.

5. The method of claim 4, wherein, when the master receives an overdriven response signal in the first phase, from a received power of the response signal a new transmission power of the search signal is determined, which is lower than that previously used, and then the master transmits the search signal with the new transmission power, and this process is iteratively performed until either a non-overdriven exchange of search signal and response signal occurs or a presence of a termination criterion without receipt of a non-overdriven signal is determined.

6. The method of claim 5, wherein after the presence of the termination criterion, the first phase is continued with a new master beam direction of the master.

7. The method of claim 5, wherein after a non-overdriven exchange, the master emits a start signal to start the second phase.

8. The method according to any one of the preceding claims, wherein a plurality of slaves are used, which are addressed in different time slots.

A master transceiver for operating a radio link, comprising a transceiver configured to generate, transmit and receive signals in adjustable directions via at least one antenna and a controller adapted to automatically align the at least one antenna antenna

to control the transceiver unit in a first phase for performing a coarse scan for determining a mutual coarse alignment with a slave transceiver, in the following slave,

- to start a second phase after completion of the coarse alignment and in the second phase

then prescribe a master control beam direction to the transceiver unit and a slave control beam direction to the slave subsequently over a number of iterations, respectively a new slave beam direction and a dwell time in which the slave is to receive in this new slave beam direction to specify to the slave

- To control the transceiver unit for subsequent transmission of search signals in a predetermined number of master beam directions, and - the transceiver unit after the expiration of the residence time for the reception of

To control the results of a signal quality parameter determination from the slave on the specified master control beam direction and

- Based on the signal quality parameter determination to determine an optimal mutual orientation of the antennas of the transceiver and slave and to control the at least one antenna of the transceiver unit to the appropriate orientation.

10. Master according to claim 9, which is formed in the coarse scan in the first phase

to send a search signal in a first master beam direction and then to wait for a defined waiting time for a response signal and

- In the absence of a response signal after the waiting time to switch to a second master beam direction and

- To send a start signal in the first master beam direction upon receipt of a response signal, with which a second phase is initiated.

A master according to one of claims 9 or 10, which is designed to measure in the first phase upon detection of an overdriven signal the duration of this overdriven signal, from the duration of the overdriven signal and a comparison with a desired duration of an expected one Response signal on the receipt of the expected response signal to close and to send a response in response to the reception of this expected response signal provided response.

12. Master according to claim 1 1, which is formed when it receives an overdriven response signal in the first phase, to determine from a received power of the response signal, a new transmission power of the search signal, which is lower than that before then used to transmit the search signal at the new transmit power and iteratively perform this process until either a non-overdriven exchange of the search signal and response signal occurs or a presence of an abort criterion is detected without receipt of a non-overdriven signal.

13. Master according to claim 12, which is designed to continue after the presence of the termination criterion, the first phase with a new master beam direction.

14. Master according to claim 1 1 or 12, which is designed to emit after a non-overdriven exchange a start signal to the beginning of the second phase.

15. Operating method for a master transceiver of a radio link, hereinafter master, with a control unit and a transceiver unit with at least one antenna, in which

the master, in exchange with a slave transceiver, hereinafter slave, performs a coarse scan to determine a mutual coarse alignment of the at least one antenna in which master can exchange signals with the slave,

- after completion of the coarse erection, the master initiates a second phase, in which

the master of its transceiver unit specifies a master control beam direction and the slave a slave control beam direction,

- then over a number of iterations each

- The master specifies a new slave beam direction and a residence time in which the slave is to receive in this new slave beam direction, the slave, the master then sends search signals in a predetermined number of its master beam directions, the master after the expiry of the residence time Receive results of a signal quality parameter determination from the slave in the specified master control beam direction and - The master based on the signal quality parameter determination determines an optimal mutual orientation of the antennas of the transceiver and slave and aligns the at least one antenna of the transceiver accordingly.

16. A slave transceiver, hereinafter slave, for operating a radio link with a transceiver configured to generate, transmit and receive signals in adjustable directions via at least one antenna and a control unit adapted for automatic alignment the at least one antenna

- To control the transceiver unit in a first phase for performing a coarse scan for determining a mutual coarse alignment with a master transceiver, hereinafter master, and in a second phase after completion of coarse alignment of the at least one antenna

- over a number of iterations each

as specified by the master, the transceiver unit for setting a new slave beam direction and a dwell time in which the transceiver unit is to receive in this new slave beam direction, and for performing signal quality parameter determination for each received signal and storing the signal To trigger the results of the signal quality parameter determination,

after the expiry of the dwell time, to control the transceiver unit, to set a slave control beam direction previously determined by the master, and to transmit the results of the signal quality parameter determination to the master, - To control the at least one antenna of the transceiver unit for alignment in accordance with a transmitted from the master optimum mutual alignment.

17. A slave according to claim 16, which is formed in the coarse scan in the first phase

- In a first slave beam direction, a defined waiting time which is greater than the waiting time of a master to wait for the receipt of a search signal of the master and

if there is no search signal after the waiting time, to change to a second slave beam direction, on receipt of a search signal, a response signal to the first slave direction;

Beam direction to send.

18. A slave according to claim 16 or 17, which is configured in the first phase in detecting an overdriven signal to measure the duration of this overdriven signal, from the duration of the overdriven signal and a comparison with a desired time duration of an expected search or response signal to conclude receipt of the expected search or response signal and to send a response in response to receipt of the expected search or response signal.

19. Operating method for a slave transceiver, hereinafter slave, with a control unit and a transceiver unit with at least one antenna, in which

- The slave in exchange with a master transceiver, hereinafter master performs a coarse scan for determining a mutual coarse alignment of the at least one antenna in which the slave can exchange signals with a master,

- After completion of the coarse alignment of the at least one antenna, the slave receives a signal for initiating a second phase, in which

- the slave over a number of iterations each - sets a new slave beam direction and a dwell time in which the slave is to receive in this new slave beam direction, as specified by the master,

performs a signal quality parameter determination for each received signal and stores its results,

after the expiry of the dwell time, sets a slave control beam direction previously defined by the master for transmission of the results of the signal quality parameter determination, transmits the results to the master and

- Aligns the at least one antenna of the transceiver unit according to a transmitted from the master optimal alignment.

20. Directional radio arrangement comprising a master according to at least one of claims 9 to 14 and at least one slave according to at least one of claims 16 to 18.

21. A transceiver comprising a master according to at least one of claims 9 to 15 and a slave according to at least one of claims 16 to 18.