DE102016123721A1 - A communication system for initiating a handover from a first base station to a second base station - Google Patents

Abstract

The invention relates to a communication system (100) for initiating a handover from a first base station (101) to a second base station (103). The communication system (100) comprises the first base station (101) comprising a leaky waveguide, the leaky waveguide having an attenuator with a predetermined insertion loss. The communication system (100) further comprises the second base station (103). The communication system (100) further comprises a communication device (105) configured to communicate with the first base station (101) via the leaky waveguide. The communication device (105) is configured to receive a reception signal from the first base station (101), to determine a reception field strength of the reception signal, and to compare the reception field strength with a reference field strength. The communication device (105) is designed to initiate the connection transfer from the first base station (101) to the second base station (103) when the reference field strength falls below the reference field strength.

Description

TECHNICAL AREA

The present invention relates to the field of communications technology.

TECHNICAL BACKGROUND

Handover or roaming is a process in which a communication device makes a change from one base station to another base station in a communication system. The change should take place without interrupting a data transfer or a call.

Typically, a handover is performed from the base station to the other base station if a quality of the data transmission or the conversation can no longer be guaranteed by a movement of the communication device.

Particularly in applications in the industrial environment, in which the communication device moves regularly between base stations, for example in tunnel radio systems, a high quality of data transmission is of particular importance.

DESCRIPTION OF THE INVENTION

It is therefore an object of the present invention to provide an efficient concept for initiating handoff between a first base station and a second base station.

This object is solved by the features of the independent claims. Advantageous embodiments of the invention are the subject of the description, the figures and the dependent claims.

The present invention is based on the finding that the above object can be achieved by a communication system having a first base station, a second base station and a communication device, wherein the first base station comprises a leaky waveguide with an attenuator. The attenuator has a predetermined insertion loss, whereby a reception field strength of a reception signal received from the first base station can be selectively reduced. The communication device compares the received field strength with a reference field strength and initiates the handover from the first base station to the second base station as soon as the received field strength falls below the reference field strength. The communication device may also use an expected data throughput to the first base station and the second base station as a criterion for a handover.

It is thereby achieved that the handover can be initiated at a position at which it is possible to set up or uninstall a respective communication connection without interrupting a data transmission or a conversation.

According to a first aspect, the invention relates to a communication system for initiating handover from a first base station to a second base station. The communication system comprises the first base station, which comprises a leaky waveguide, the leaky waveguide having an attenuator with a predetermined insertion loss. The communication system further comprises the second base station. The communication system further includes a communication device configured to communicate with the first base station via the leaky waveguide. The communication device is configured to receive a reception signal from the first base station, to determine a reception field strength of the reception signal, and to compare the reception field strength with a reference field strength. The communication device is designed to initiate the connection transfer from the first base station to the second base station when the reference field strength falls below the reference field strength. The reference field strength can therefore represent a threshold value or limit value which, if it is undershot, can lead to the initiation or triggering of a handover. The predetermined insertion loss may be, for example, 1 dB, 3 dB, 6 dB, 10 dB or 20 dB.

According to one embodiment, the second base station comprises a further leaky waveguide, wherein the communication device is configured to communicate with the second base station via the further leaky waveguide, and wherein the first base station and the second base station are interconnected via the leaky waveguide, the attenuator and the further leaky waveguide , As a result, the advantage is achieved that a further reception field strength of a further received signal can be selectively reduced by the second base station in order to initiate a corresponding handover from the second base station to the first base station. The handover from the second base station to the first base station may be realized based on the same concept as the described handover from the first base station to the second base station.

According to one embodiment, the leaky-waveguide and the further leaky-waveguide are arranged parallel to one another. This provides the advantage that the position of the handover can be easily determined.

According to one embodiment, the leaky waveguide and the further leaky waveguide are arranged in a line. This provides the advantage that the position of the handover can be easily determined.

According to one embodiment, the leaky waveguide comprises a slot cable or a slot antenna. As a result, the advantage is achieved that a uniform electromagnetic radiation can be realized by the leaky waveguide.

According to one embodiment, the further leaky waveguide comprises a further slot cable or a further slot antenna. As a result, the advantage is achieved that a uniform electromagnetic radiation can be realized by the other leaky waveguide.

According to one embodiment, the reference field strength is pre-stored in the communication device. Thereby, the advantage is achieved that a fixed pre-stored reference field strength can be provided efficiently. The reference field strength as a threshold or limit does not change in this case during operation, and can be defined, for example, at compile time or by a user.

According to one embodiment, the communication device is designed to receive a further received signal from the second base station, to determine a further received field strength of the further received signal, and to determine the reference field strength on the basis of the further received field strength. This provides the advantage that the reference field strength can be determined dynamically during operation. The reference field strength and the additional receive field strength can be identical. However, the reference field strength and the further reception field strength may also be in a predetermined relationship to each other or have a predetermined difference.

According to one embodiment, the communication device is configured to determine a first data throughput between the communication device and the first base station and a second data throughput between the communication device and the second base station, and to initiate the handover from the first base station to the second base station if the second data throughput is greater than the first data throughput is. As a result, the advantage is achieved that the handover is initiated only if the second base station allows communication with a larger data throughput. Consequently, when the reference field strength is undershot, the initiation of the handover by the communication device does not take place automatically. If the reference field strength is undershot, a decision process can therefore be started in which further parameters, in particular the first data throughput and the second data throughput, can be taken into account.

The first data throughput may be a first theoretically possible data throughput, and the second data throughput may be a second theoretically possible data throughput. The first data throughput and the second data throughput can be determined theoretically in each case on the basis of lookup tables.

According to one embodiment, the communication device is configured to determine a first modulation scheme of the first base station, and to determine the first data throughput based on the first modulation scheme, wherein the communication device is further configured to determine a second modulation scheme of the second base station and the second data throughput based on the second modulation scheme. This has the advantage that the first data throughput and the second data throughput can be determined efficiently. The modulation scheme may indicate, for example, the use of BPSK modulation, QPSK modulation, QAM modulation, DSSS modulation, or OFDM modulation by the respective base station.

According to one embodiment, the communication device is configured to determine a first encoding scheme of the first base station, and the first data throughput based on the first Determine coding schemes, wherein the communication device is further configured to determine a second coding scheme of the second base station, and to determine the second data throughput on the basis of the second coding scheme. This has the advantage that the first data throughput and the second data throughput can be determined efficiently. For example, the coding scheme may indicate the use of a particular source coding and / or channel coding by the respective base station.

According to one embodiment, the communication device is configured to determine a first modulation and coding scheme of the first base station, and to determine the first data throughput based on the first modulation and coding scheme, wherein the communication device is further configured to implement a second modulation and coding scheme second base station, and to determine the second data throughput based on the second modulation and coding scheme. This has the advantage that the first data throughput and the second data throughput can be determined efficiently. For example, the Modulation and Coding Scheme (MCS) may indicate a combined use of a modulation scheme and an encoding scheme by the respective base station.

According to one embodiment, the communication device is configured to determine a first communication standard of the first base station, and to determine the first data throughput based on the first communication standard, wherein the communication device is further configured to determine a second communication standard of the second base station and the second data throughput based on the second communication standard. This has the advantage that the first data throughput and the second data throughput can be determined efficiently. The first communication standard is used for communication by the first base station, and the second communication standard is used for communication by the second base station. The first communication standard and the second communication standard may be, for example, WLAN communication standards, for example IEEE 802.11a . IEEE 802.11b . IEEE 802.11g or IEEE 802.11n ,

According to one embodiment, the communication device is configured to determine a first utilization level of a first communication channel between the communication device and the first base station, and to determine the first data throughput based on the first utilization level, wherein the communication device is further configured to have a second utilization level of a second communication channel between the communication device and the second base station, and determine the second data throughput based on the second utilization level. This has the advantage that the first data throughput and the second data throughput can be determined efficiently.

According to one embodiment, the communication device is configured to receive a first utilization indicator from the first base station, the first utilization indicator indicating the first utilization level of the first communication channel, the communication device further configured to receive a second utilization indicator from the second base station, the second one Load indicator indicates the second utilization level of the second communication channel. As a result, the advantage is achieved that the respective degree of utilization can be determined by the respective base station and signaled to the communication device.

According to one embodiment, the first utilization level of the first communication channel is determined by a first number of free time slots of the first communication channel, wherein the second utilization rate of the second communication channel is determined by a second number of free time slots of the second communication channel. As a result, the advantage is achieved that the utilization rate of the respective communication channel can be easily characterized.

According to one embodiment, the communication device is configured to receive a network identifier associated with the second base station and to initiate the handover from the first base station to the second base station if the received network identifier corresponds to a pre-stored network identifier. As a result, the advantage is achieved that the connection transfer to the second base station only takes place when the second base station is known to the communication device. The network identifier may be pre-stored in the communication device. The network identifier can be a service set identifier (SSID).

According to one embodiment, the communication device is configured to release a first communication connection between the communication device and the first base station and establish a second communication connection between the communication device and the second base station to initiate the handover from the first base station to the second base station. This provides the advantage that the handover can be carried out efficiently.

According to one embodiment, the first base station is a first WLAN access point, wherein the second base station is a second WLAN access point, and wherein the communication device is a WLAN client. This provides the advantage that a handover can be realized in a wireless local area network (WLAN).

According to a second aspect, the invention relates to a method for initiating a handover from a first base station to a second base station in a communication system. The communication system comprises the first base station, the second base station and a communication device, wherein the first base station comprises a leaky waveguide, wherein the Leak waveguide has an attenuator with a predetermined insertion loss. The communication device is configured to communicate with the first base station via the leaky waveguide. The method comprises receiving by the communication device a reception signal from the first base station, determining a reception field strength of the reception signal by the communication device, comparing the reception field strength with a reference field strength by the communication device, and initiating the handover of the connection field when the reference field strength falls below the reference field strength first base station to the second base station by the communication device.

The method may be performed by the communication system. Further features of the method result directly from the features and / or the functionality of the communication system.

According to a third aspect, the invention relates to a computer program with a program code for carrying out the method according to the second aspect of the invention.

The communication system, in particular the first base station, the second base station and / or the communication device, may be set up by the program in order to execute the program code.

The invention can be implemented in hardware and / or in software.

list of figures

• 1 ein schematisches Diagramm eines Kommunikationssystems zum Einleiten einer Verbindungsübergabe von einer ersten Basisstation zu einer zweiten Basisstation;
• 2 ein schematisches Diagramm eines Kommunikationssystems zum Einleiten einer Verbindungsübergabe von einer ersten Basisstation zu einer zweiten Basisstation;
• 3 ein schematisches Diagramm eines Kommunikationssystems zum Einleiten einer Verbindungsübergabe von einer ersten Basisstation zu einer zweiten Basisstation;
• 4 ein schematisches Diagramm eines Kommunikationssystems zum Einleiten einer Verbindungsübergabe von einer ersten Basisstation zu einer zweiten Basisstation; und
• 5 ein schematisches Diagramm eines Verfahrens zum Einleiten einer Verbindungsübergabe von einer ersten Basisstation zu einer zweiten Basisstation in einem Kommunikationssystem.

Further embodiments will be explained with reference to the accompanying figures. Show it:

• 1 a schematic diagram of a communication system for initiating a handover from a first base station to a second base station;
• 2 a schematic diagram of a communication system for initiating a handover from a first base station to a second base station;
• 3 a schematic diagram of a communication system for initiating a handover from a first base station to a second base station;
• 4 a schematic diagram of a communication system for initiating a handover from a first base station to a second base station; and
• 5 a schematic diagram of a method for initiating a handover from a first base station to a second base station in a communication system.

DETAILED DESCRIPTION OF THE FIGURES

1 shows a schematic diagram of a communication system 100 for initiating a handover from a first base station 101 to a second base station 103. The communication system 100 includes the first base station 101 comprising a leaky waveguide, wherein the leaky waveguide comprises an attenuator having a predetermined insertion loss. The communication system 100 further comprises the second base station 103 ,

The communication system 100 also includes a communication device 105 , which is formed with the first base station 101 to communicate via the leaky waveguide. The communication device 105 is formed, a received signal from the first base station 101 to determine a received field strength of the received signal, and to compare the received field strength with a reference field strength. The communication device 105 is formed, when falling below the reference field strength by the reception field strength, the connection transfer from the first base station 101 to the second base station 103 initiate.

To initiate or trigger the handover for a roaming can be used as a criterion, the reception strength of the received signal, for example in the form of a Received Signal Strength Indicators (RSSI). Below that through the communication device 105 certain reception field strength of the received signal from the first base station 101 For example, a predetermined, for example adjustable in a driver, reference field strength, so a routine can be started, which can lead to a handover. In this case, the communication device 105 search for base stations whose network identification and access data are known, and use different parameters to create a ranking that is sorted, for example, according to the respective best possible data throughput. For example, is the currently connected first base station? 101 not at the top of the ranking, a handover may be triggered. The first base station 101 and the second base station 103 can be wireless access points (APs). The communication device 105 can be a wireless client.

• - Empfangsfeldstärke des Sendesignals der Basisstation, ermittelt an der Empfangsstation, beispielsweise bestimmt durch RSSI;
• - Verfügbares Modulationsschema der jeweiligen Basisstation;
• - Auslastungsgrad des Kommunikationskanals bzw. Übertragungsmediums; und/oder
• - Verwendeter Kommunikationsstandard der jeweiligen Basisstation, beispielsweise IEEE 802.11a, b, g, n, etc.

The parameters for creating the ranking may include, but are not limited to:

• - Receiving field strength of the transmission signal of the base station, determined at the receiving station, for example determined by RSSI;
• - Available modulation scheme of the respective base station;
• Degree of utilization of the communication channel or transmission medium; and or
• The communication standard used by the respective base station, for example IEEE 802.11a, b, g, n, etc.

While the transmit power may vary depending on the environment, the available modulation scheme and the utilization of the communication channel are parameters that may be defined within a communication standard used. These will be described in more detail below.

The criteria or mechanisms for initiating a handover are not specified in certain communication standards, for example the IEEE 802.11 communication standard in the case of WLAN. Each manufacturer of corresponding drivers can therefore implement their own functions and document and publish them at their own discretion.

Regarding the available modulation scheme of the respective base station, the following aspects can be considered. Depending on the communication standard used and the modulation and coding scheme (MCS), it is possible to use data packets with different data throughputs in terms of transmission rates between the base stations 101 . 103 and the communication device 105 to send. The IEEE 802.11g communication standard for WLAN, for example, allows data throughputs between 6 Mbps and 54 Mbps, depending on the MCS.

The modulation and coding scheme (MCS) can be used as a criterion for initiating a handover. For example, it can only be characterized according to different communication standards with its modulation schemes, for example DSSS modulation or OFDM modulation.

For example, if a usable communication standard determined, in a further step, the driver of the communication device 105 also include the transmission power of the respective base station and estimate a probable data throughput of the respective base station. With low RSSI, the likelihood of high data throughput is lower.

With regard to the degree of utilization, the following aspects can be taken into account. The respective base station 101 . 103 can provide various statistics during operation, including information on the utilization of the respective communication channel. For this purpose, for example, the number of free time slots are counted in which a communication device occupy the communication channel and may send to it. The respective number can be the respective base station 101 . 103 send in cyclically transmitted management telegrams or beacons as utilization indicators. If the respective communication channel is heavily assigned, for example, this can lead to a lower possible data throughput. The communication device 105 which is in front of a handover, may exploit this information and use it in the decision process for or against a handover to another base station.

To initiate a handover, therefore, an assessment of the various base stations 101 . 103 through the communication device 105 be performed. It can by the communication device 105 a ranking of the available base stations 101, 103 are created.

• - Signalleistung des jeweils ausgesendeten Signals von der Basisstation, beispielsweise in Form eines Signal-Rausch-Abstandes (Signal-to-Noise Ratio, SNR) des jeweiligen Empfangssignals;
• - Verwendeter Kommunikationsstandard der jeweiligen Basisstation, beispielsweise IEEE 802.11a, b, g, n, etc.; und/oder
• - Auslastung bzw. Medienbelegung des jeweiligen Kommunikationskanals.

As a criterion, for example, the maximum possible data throughput of the respective communication connection can be used. This can be determined, among other things, on the basis of the following parameters:

• - Signal power of each emitted signal from the base station, for example in the form of a signal-to-noise ratio (SNR) of the respective received signal;
• The communication standard used by the respective base station, for example IEEE 802.11a, b, g, n, etc .; and or
• - Utilization or media occupancy of the respective communication channel.

The respective data throughput can be determined on the basis of a prestored or stored table, for example as a lookup table. This can be stored for example by a manufacturer of a driver in a data array and display for each communication standard depending on the SNR value, a maximum possible gross data throughput. Consequently, a handover can take place on the base station which enables the best possible theoretical data throughput. The following are exemplary lookup tables for the communication standards IEEE 802.11a . IEEE 802.11b , and IEEE 802.11g shown: IEEE 802.11a: {105, 30600} {21, 30500}, (54 Mb / s) {20, 28500}, (48 Mb / s) {15, 23700} (36 Mb / s) {11, 17700}, (24 Mb / s) { 8th, 14105} (18 Mb / s) {6, 10105} (12 Mb / s) {4, 7800}, (9 Mb / s) {3, 5400}, (6 Mb / s) { 1, 0} (no connection) IEEE 802.11b: {105, 6500}, {7, 6400}, (11 Mb / s) {4, 4300}, (5 Mb / s) {3, 1800}, (2 Mb / s) {2, 105}, (1 Mb / s) {0, 1} (no connection) IEEE 802.11g: 10% discount {105, 28000} {21, 27450} (54 Mb / s) {20, 25650}, (48 Mb / s) {15, 21330} (36 Mb / s) {11, 15930}, (24 Mb / s) { 8th, 12690} (18 Mb / s) {7, 1030}, (12 Mb / s) {6, 6400}, (11 Mb / s) {4, 4300}, (5 Mb / s) {3, 1800}, (2 Mb / s) {2, 105}, (1 Mb / s) {0, 1} (no connection)

The left-hand column represents the signal-to-noise ratio SNR used by the communication device when searching for a base station 105 can be determined. The communication device 105 or the driver may later convert the SNR to an absolute RSSI value, for example, assuming that the noise level is -94 dBm, which may be typical for undisturbed environments. The right-hand column represents the expected gross data throughput for the respective signal-to-noise ratio SNR in kilobits / s. For example, the communication device goes 105 or the driver at an SNR of 21 (that is, RSSI = -94 + 21 = -73 dBm), or better, from a possible data throughput of 27.475 Mbps if the base station uses the IEEE 802.11g communication standard. If the base station only uses the communication standard IEEE 802.11b, then the data throughput would only be 6.4 MBit / s for the same SNR. If the base station only uses the communication standard IEEE 802.11a, then the data throughput would only be 30.5 Mbit / s for the same SNR.

Furthermore, the utilization of the communication channel can also be included. This can be determined on the basis of a number of free time slots on the respective communication channel and / or already provided by the driver. For example, if another communication user is on the same communication channel and occupies half of the possible access time, a factor of 50% may be multiplied by the previously determined gross data throughput. For example, if the communication channel is 50% occupied, and the theoretical gross data throughput is 27.475 Mbps based on the communication standard or modulation scheme and SNR, then actual data throughput may be 0.5 x 27.475 Mbps = 13 , 7375 Mbps are assumed.

Consequently, RSSI values and the communication standard of the respective base station can be used for the decision to transfer the connection 101 . 103 be considered and the base stations 101 . 103 sorted according to a ranking. The higher the estimated data throughput for the respective base station 101 . 103 For example, based on the RSSI value and the communication standard used, the higher the ranking or preference for this base station 101 . 103 ,

The influence of the communication standard can outweigh the influence of the RSSI value, especially if IEEE 802.11n and IEEE 802.11b be compared as communication standards, wherein a base station 101 . 103 With IEEE 802.11n usually sorted higher even with lower RSSI value. If the current base station 101 has the highest ranking, the communication device remains 105 at this base station 101 and re-starts the procedure if the RSSI value of the current base station 101 changed by more than an adjustable threshold and the received field strength or the RSSI value is still below the reference field strength. Furthermore, a restart of the procedure may be performed if the receive field strength is still below the reference field strength for a predetermined period of time, for example 10 seconds. If a base station 103 is present with higher ranking, the communication device 105 a handover to this base station 103 initiate.

2 shows a schematic diagram of a communication system 100 for initiating a handover from a first base station 101 to a second base station 103. The communication system 100 includes next to the first base station 101 and the second base station 103 a communication device 105 , The first base station 101 includes a leaky waveguide 201 , The second base station 103 includes another leaky waveguide 203 , The communication device 105 is trained with the first base station 101 over the leaky waveguide 201 to communicate and with the second base station 103 over the further leaky waveguide 203 to communicate.

For applications where along a long, defined distance, communication between multiple communication devices or base stations is desirable, leaky-wave conductors can be used. The leaky waveguide 201 . 203 may be formed, for example in the form of a coaxial cable, in which slots are provided in the jacket at cyclic intervals. From these slots can decouple a high-frequency electromagnetic wave and the leaky waveguide 201 . 203 thus make an antenna, which allows homogeneous illumination along its propagation direction. Such implementation provides an efficient way of communicating, for example in tunnels or extensive facilities, where many base stations and many antennas would otherwise have to be placed.

Relevant for a functioning communication link may be the attenuation. If this is too large, a received signal will be too weak and may no longer be evaluated. Causes of attenuation when using the leaky waveguide 201 , 203 are, for example, the longitudinal damping, so the attenuation by losses along the respective leaky waveguide 201 . 203 , as well as the coupling loss, ie the attenuation or the losses due to the decoupling of the high-frequency electromagnetic wave from the leaky waveguide 201 . 203 and the possible coupling into an adjacent antenna. In order not to let the total attenuation become too large, the leaky waveguides should 201 . 203 therefore not be dimensioned too long.

In large or extensive areas, for this reason, multiple leaky waveguides 201 . 203 are used by different base stations 101 , 103 can be fed. Does this move the communication device 105 Within a range and exceeds the transition of the two adjacent leaky waveguides 201, 203, it is advantageous in the previous first base station 101 and at the second base station 103 , which the other leaky waveguide 203 dines, login. This process is called handover or roaming.

The handover can be described by several protocol steps and includes, among other things, a logoff at the old first base station 101 and registering with the new second base station 103 , Thus, a time-critical application for communication without data loss can be realized. Loses the communication device 105 however, the connection to the first base station 101 abruptly, the renewed sign-on process usually takes longer and data packets can be lost at the same time. Moves the communication device in an application 105 along the leaky waveguide 201 and moves beyond its end, it may be due to the coupling loss, which is dependent on the distance from the leaky waveguide 201 increases, immediately the first communication link to the first base station 101 to lose. Especially in such applications, an optimized handover is desirable.

• - Ist eine zweite Basisstation 103 vorhanden?
• - Ist ein Aufbau einer zweiten Kommunikationsverbindung möglich bzw. sind die Zugangsdaten der zweiten Basisstation 103 bekannt?
• - Ist eine Empfangsfeldstärke von der zweiten Basisstation 103 besser als die Empfangsfeldstärke der ersten Basisstation 101, beispielsweise 15 dB besser?
• - Ist ein verwendetes Modulationsschema der zweiten Basisstation 103 so gut, dass trotz einer besseren Empfangsfeldstärke von der ersten Basisstation 101 eine schnellere Kommunikationsverbindung mit einem höheren Datendurchsatz zu der zweiten Basisstation 103 aufgebaut werden sollte?

A corresponding handover can, for example, be triggered autonomously if, after a cyclical query, it is recognized that the following criteria exist for this. The communication device 105 For example, you can evaluate the following criteria:

• - Is a second base station 103 available?
• - Is a structure of a second communication connection possible or are the access data of the second base station 103 known?
• - Is a receive field strength from the second base station 103 better than the reception field strength of the first base station 101 , for example 15 dB better?
• - Is a used modulation scheme of the second base station 103 so good that despite a better reception field strength from the first base station 101 a faster communication link with a higher data throughput to the second base station 103 should be built?

Are the two adjacent leaky waveguides 201 . 203 the same length, they also have the same longitudinal damping and the communication device 105 recognizes at the transition to each other two equally strong received signals. A criterion for the handover is usually not given directly at such a transition and arises only at a further spatial distance from the leaky waveguide 201 . 203 , However, it may happen that the described query of the criteria for a handover only takes place when the reception field strength at the communication device 105 already too low and the communication connection breaks off.

One possible approach is to use the transmit power of the first base station 101 so that there is a sufficiently large difference in the reception field strengths at the transition point of the two leaky waveguides 201 . 203 given is. When cascading several leaky waveguides 201 . 203 However, this may cause the first base station 101 is further limited in the transmission power, whereby the communication link to the communication device 105 may be worsened and the application may no longer be usefully operated.

Another possible approach is to connect the second base station 103 close to the end of the leaky waveguide 201 lead, whereby the difference or the delta of the reception field strengths or levels can be increased. However, this can eventually lead to a higher number of base stations in the application, which can increase costs.

3 shows a schematic diagram of a communication system 100 for initiating a handover from a first base station 101 to a second base station 103. The communication system 100 includes next to the first base station 101 and the second base station 103 a communication device 105 , The first base station 101 includes a leaky waveguide 201 , The second base station 103 includes another leaky waveguide 203 , The communication device 105 is trained with the first base station 101 over the leaky waveguide 201 to communicate and with the second base station 103 over the further leaky waveguide 203 to communicate. The leaky waveguide 201 has an attenuator 301 with a predetermined insertion loss.

For the reasons mentioned above, it is desirable to have a defined difference in reception field strengths at the junction of the two leaky waveguides 201 . 203 manufacture. This is the criterion, regardless of the length of the leaky waveguide 201 . 203 and the location of the base stations 101 . 103 and their transmission power, realize and perform an autonomous handover at a predefined position.

In order to ensure that the above-described interrogation of criteria for handover can take place, should depend on the speed of movement of the communication device 105 two adjacent leaky waveguides 201 . 203 be laid overlapping. At the transition of the leaky waveguide 201 . 203 Then, the attenuator 301 can be used in the form of a radio frequency (RF) attenuator.

This leads to the fact that at the predefined position a sufficiently large attenuation difference can be realized. Furthermore, the overlap of the leaky waveguide 201 . 203 achieved that the query takes place at a time when there is still a sufficiently large reception field strength to the first communication link to the first base station 101 to maintain.

4 shows a schematic diagram of a communication system 100 for initiating a handover from a first base station 101 to a second base station 103. The communication system 100 includes next to the first base station 101 and the second base station 103 a communication device 105 , The first base station 101 includes a leaky waveguide 201 , The second base station 103 includes another leaky waveguide 203 , The communication device 105 is trained with the first base station 101 over the leaky waveguide 201 to communicate and with the second base station 103 over the further leaky waveguide 203 to communicate. The leaky waveguide 201 has an attenuator 301 with a predetermined insertion loss. The first base station 101 and the second base station 103 are over the leaky waveguide 201 , the attenuator 301 and the other leaky waveguide 203 connected with each other.

The approach described above can be advantageous in a particular direction of travel of the communication device 105 be used. In this case, the difference of the reception field strengths for initiating an autonomous handover is achieved. Drives the communication device 105 however, in the opposite direction, this is typically not the case. Furthermore, the leaky waveguides 201 . 203 often used in narrow cable ducts or in cramped applications. There may be little room for an overlapping laying of the two leaky waveguides 201 . 203 , It is therefore desirable to have an approach in which a method of the communication device 105 along the transition of the two leaky waveguides 201 . 203 in both directions is possible, and which is space-saving.

Instead of two separate leaky waveguides 201 . 203 The leaky-wave conductors can be used 201 . 203 over the attenuator 301 be connected to each other. Alternatively, a common leaky waveguide with an attenuator 301 be used.

In the middle between the leaky waveguides 201 . 203 , ie at the point where else an overlap of the two leaky waveguide 201 . 203 would be present, the attenuator 301 set. Thus, in turn, a defined difference of the received field strengths for the received signals from the two, at the ends of the leaky waveguide 201 . 203 built, base stations 101 . 103 and meets the criteria for autonomous handover.

The use of the two leaky waveguides 201 . 203 without the integrated attenuator 301 is associated with challenges, as due to the usually low longitudinal damping over the two leaky waveguide 201 . 203 , the respective input of the connected two base stations 101 . 103 could be overridden.

• - Eine Verbindungsübergabe ist bei Verfahren des Kommunikationsgerätes 105 in beide Richtungen möglich;
• - Geringer Platzaufwand durch die Zusammenfügung beider Leckwellenleiter 201, 203, anstatt der Überlappung zweier Leckwellenleiter 201, 203;
• - Einsparung von Abschlusswiderständen von beispielsweise 50 Ohm an den Enden der Leckwellenleiter 201, 203;
• - Einsparung von Leckwellenleitermaterial durch die nicht durchgeführte Überlappung, ferner ist eine insgesamt größere Länge der Leckwellenleiter 201, 203 möglich;
• - Die Verbindungsübergabe kann an einer vordefinierten Position durchgeführt werden, beispielsweise an einer Position, an welcher keine Kommunikation stattfindet.

Through this approach, the following advantages can be realized:

• - A handover is in procedure of the communication device 105 possible in both directions;
• - Small space requirement by the joining of both leaky waveguide 201 . 203 instead of the overlap of two leaky waveguides 201 . 203 ;
• - Saving of terminating resistors of, for example, 50 ohms at the ends of the leaky waveguide 201 . 203 ;
• - Saving leaking waveguide material by the overlap not performed, also is an overall greater length of the leaky waveguide 201 . 203 possible;
• - The connection handover can be performed at a predefined position, for example at a position where no communication takes place.

5 shows a schematic diagram of a method 500 for initiating a handover from a first base station to a second base station in a communication system. The communication system comprises the first base station, the second base station and a communication device, wherein the first base station comprises a leaky waveguide, the leaky waveguide having an attenuator with a predetermined insertion loss. The communication device is configured to communicate with the first base station via the leaky waveguide.

The procedure 500 includes receiving 501 a receive signal from the first base station by the communication device, determining 503 a reception field strength of the reception signal by the communication device, a comparison 505 the receiving field strength with a reference field strength by the communication device, and in case of falling below the reference field strength by the reception field strength an initiation 507 the handover from the first base station to the second base station by the communication device.

All features shown or described in connection with individual embodiments of the invention may be provided in any combination in the subject matter of the invention to realize their beneficial effects simultaneously.

LIST OF REFERENCE NUMBERS

100

communication system

101

First base station

103

Second base station

105

communication device

201

Leaky Cable

203

Another leaky waveguide

301

attenuator

500

Method for initiating a handover

501

Receiving a received signal

503

Determine a receive field strength

505

Compare the receive field strength to a reference field strength

507

Initiate the handover

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited non-patent literature

• IEEE 802.11a [0022, 0047]
• IEEE 802.11b [0022, 0047, 0051]
• IEEE 802.11g [0022, 0047]
• IEEE 802.11n [0022, 0051]

Claims (14)

A communication system (100) for initiating a handover from a first base station (101) to a second base station (103), comprising: the first base station (101) comprising a leaky waveguide (201), the leaky waveguide (201) having an attenuator (301) with a predetermined insertion loss; the second base station (103); and a communication device (105) configured to communicate with the first base station (101) via the leaky waveguide (201), the communication device (105) configured to receive a reception signal from the first base station (101), a reception field strength of To determine the received signal strength, and to compare the received field strength with a reference field strength, wherein the communication device (105) is designed to initiate the handover from the first base station (101) to the second base station (103) when the reference field strength falls below the reference field strength. Communication system (100) after Claim 1 wherein the second base station (103) comprises another leaky waveguide (203), wherein the communication device (105) is adapted to communicate with the second base station (103) via the further leaky waveguide (203), and wherein the first base station (101) and the second base station (103) is interconnected via the leaky waveguide (201), the attenuator (301) and the further leaky waveguide (203). The communication system (100) of any one of the preceding claims, wherein the leaky waveguide (201) comprises a slot cable or a slot antenna. The communication system (100) of any one of the preceding claims, wherein the communication device (105) is configured to provide a first data throughput between the communication device (105) and the first base station (101) and a second data throughput between the communication device (105) and the second base station ( 103), and to initiate the handoff from the first base station (101) to the second base station (103) if the second data throughput is greater than the first data throughput. Communication system (100) after Claim 4 wherein the communication device (105) is adapted to determine a first modulation scheme of the first base station (101) and to determine the first data throughput based on the first modulation scheme, and wherein the communication device (105) is configured to use a second modulation scheme of the second Base station (103) to determine and the second data throughput on the basis of the second modulation scheme. Communication system (100) according to one of Claims 4 or 5 wherein the communication device (105) is adapted to determine a first encoding scheme of the first base station (101) and determine the first data throughput based on the first encoding scheme, and wherein the communication device (105) is adapted to a second encoding scheme of the second Base station (103) to determine and the second data throughput on the basis of the second coding scheme. Communication system (100) according to one of Claims 4 to 6 wherein the communication device (105) is configured to determine a first communication standard of the first base station (101) and to determine the first data throughput based on the first communication standard, and wherein the communication device (105) is configured to establish a second communication standard of the second Base station (103) to determine and the second data throughput based on the second communication standard. Communication system (100) according to one of Claims 4 to 7 wherein the communication device (105) is configured to determine a first utilization level of a first communication channel between the communication device (105) and the first base station (101) and to determine the first data throughput based on the first utilization level, and wherein the communication device ( 105) is adapted to determine a second utilization level of a second communication channel between the communication device (105) and the second base station (103), and to determine the second data throughput based on the second utilization rate. Communication system (100) after Claim 8 wherein the communication device (105) is configured to receive a first utilization indicator from the first base station (101), the first utilization indicator indicating the first utilization level of the first communication channel, and wherein the communication device (105) is configured to generate a second utilization indicator from the first utilization indicator second base station (103), wherein the second utilization indicator indicates the second utilization level of the second communication channel. Communication system (100) according to one of Claims 8 or 9 wherein the first utilization level of the first communication channel is determined by a first number of free time slots of the first communication channel, and wherein the second utilization rate of the second Communication channel is determined by a second number of free time slots of the second communication channel. The communication system (100) of any one of the preceding claims, wherein the communication device (105) is configured to terminate a first communication link between the communication device (105) and the first base station (101) and a second communication link between the communication device (105) and the second base station (103) to initiate the handover from the first base station (101) to the second base station (103). The communication system (100) of any one of the preceding claims, wherein the first base station (101) is a first WLAN access point, the second base station (103) being a second WLAN access point, and wherein the communication device (105) is a WLAN client , A method (500) for initiating handoff from a first base station (101) to a second base station (103) in a communication system (100), the communication system (100) including the first base station (101), the second base station (103), and a A communication device (105), wherein the first base station (101) comprises a leaky waveguide (201), the leaky waveguide (201) having an attenuator (301) with a predetermined insertion loss, the communication device (105) being formed with the first base station (101) via the leaky waveguide (201), with: Receiving (501) a received signal from the first base station (101) by the communication device (105); Determining (503) a received field strength of the received signal by the communication device (105); Comparing (505) the received field strength with a reference field strength by the communication device (105); and when the reference field strength is undershot by the reception field strength, initiating (507) the handover from the first base station (101) to the second base station (103) by the communication device (105). Computer program with a program code for carrying out the method (500) Claim 13 ,

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