EP2103162A2

EP2103162A2 - Method and apparatus for linking mobile communication devices to wireless networks in underground edifices

Info

Publication number: EP2103162A2
Application number: EP07845647A
Authority: EP
Inventors: Christoph Hunziker
Original assignee: Licania GmbH
Current assignee: Licania GmbH
Priority date: 2006-12-31
Filing date: 2007-12-28
Publication date: 2009-09-23
Also published as: US20100061300A1; WO2008080247A2; ZA200904143B; UA100235C2; EA200970649A1; WO2008080247A3; CA2671892A1; AU2007341926A1; AU2007341926B2; EA016000B1

Abstract

Disclosed is an apparatus for linking mobile communication devices to wireless networks in underground edifices. Said apparatus comprises a plurality of base stations which are arranged at a spatial distance from one another inside tunnel systems (11, 12), substantially in the direction of the tunnel axes, such that the reception areas (16) of two adjacent base stations (21, 22, 23) overlap (25) as little as possible, all base stations (21, 22, 23) operating on a single common channel. In a method used for said apparatus, the mobile station switches to an adjacent base station when a quality signal drops below a predetermined threshold value.

Description

Method and device for connecting mobile communication devices to wireless networks in underground structures

Description of the Prior Art

For the wireless communication in structures underground, so for example in tunnel systems, mines, etc. different systems are in use. Recently, home office and home office wireless networking technology has become increasingly popular in such applications. These are in particular networks according to the standard series of the IEEE 802.11 series of standards.

A disadvantage of these standards lies in the fact that mobile devices moving from one base station to the next sometimes require a very long time to switch the network connection to the next base station. In this way, the technology can not be used by machines or people who need to move quickly and continuously in the mine building while maintaining wireless communication.

This switching delay is due to the fact that the mobile device holds an existing connection until it finally breaks off. Thereafter, a search begins, at the end of the reestablishment of the connection to another base station. This process can take up to several seconds, which is unacceptable for remote machine control or wireless telephone conversations.

If a large area is to be provided with wireless coverage in a deployment of wireless LANs for days - ie in normal office environment, in industry or outdoors - then so Many base stations are used: Fig. 1 shows a schematic representation of omnidirectional antennas. In principle, very similar properties result if, for example, three directional antennas are used, which are used at 120 degrees from each other. Since the obstacle-free propagation in omnidirectional antennas is circular around the base station, here 101, 102 and 103, large overlap areas 110 result if it is to be ensured that reliable wireless coverage is to be achieved everywhere. With the reference numeral 105, the respective areas are marked, in which - without obstacles and without consideration of height profiles - can be assumed by a trouble-free reception. In order to prevent the base stations 101, 102 and 103 from interfering with one another in such large overlapping areas 110, these can be set to different channels (frequencies). If there are no ideal propagation conditions - such as inside buildings - the overlap area often has to be set even larger than under ideal propagation conditions, which can lead to functional limitations and bandwidth loss.

In addition, the number of channels that can be used without interference in many cases (for example, WLAN according to IEEE 802.11b / g) is limited in many cases, so that overlaps can often not be prevented for this reason alone.

Different channels are also used in order to be able to design optimally and robustly under different conditions (atmospheric changes, structural changes, etc.) under different propagation conditions of the high frequency, and to be able to offer uniform service quality to all parallel users throughout the coverage area. As wireless LAN is currently mainly used for mobile devices that do not require real-time critical behavior, and in particular no real-time critical base station switching, this is a solid process.

Summary of the invention

Based on this prior art, the present invention seeks to provide a suitable method for real-time critical change and a corresponding device for connecting mobile communication devices to networks in underground structures.

This object is achieved according to the invention with the features of claim 1.

The invention is based on the insight that a subsurface application differs from the regular application over days in a variety of ways: A mine building or tunnel structure consists of a network of tunnels that run straight over routes, ie the communication devices, be it on a machine or a human carrier, are moved within a more or less straight tubular cavity. This offers the radio, radio or radio frequency from one point only a more or less straight propagation possibility in two directions.

A device for connecting mobile communication devices to wireless networks in underground structures comprises a plurality of base stations, which are arranged in tunnel systems at a spatial distance substantially in the direction of the tunnel axes from each other, so that there is a least possible overlap of the common reception areas for every two adjacent base stations , All basic on a single common channel. In a method employed thereby, the mobile station switches to an adjacent base station when a quality signal falls below a predetermined threshold. The advantage lies in the simplification resulting from the presence of a directional "one-dimensional" tunnel system, which is aligned along the longitudinal axis, so that always a defined neighboring base station forms the next radio cell Advantageously, base stations are arranged at intersections, so that these have a one-dimensional structure for a moving mobile station.

Brief description of the drawings

The invention will be explained in more detail by way of example with reference to the drawings. 1 shows a schematic cover of a communication space according to the prior art,

Fig. 2 is a schematic cover of a communication space underground under an embodiment of the invention, and

3 shows a flowchart for a method according to an exemplary embodiment of the invention.

As already explained above, FIG. 1 shows a schematic covering of a communication space according to the prior art, in particular without representing obstacles and without that height profiles being considered or included. It serves to define reception areas 105 and overlapping areas 110.

Fig. 2 shows a schematic cover of a communication space underground according to the invention. The reference numerals 11 and 12 designate two perpendicularly intersecting sections. net. The term "route" is the usual technical term for a tunnel passage in underground mining. The center then forming the center of a 4-way intersection is replaced by the reference numeral 13. The reference numeral 15, the gears 11 and 12 surrounding rock is called. In other words, communication devices reside on machines or humans in areas 11, 12 and 13, respectively.

With an attachment of an omnidirectional antenna 21 in the middle of the 4-way intersection 13, so provide for the high frequency linear propagation options only along the four outgoing from the intersection tunnel axes, ie in the arms 11 and 12. A spread through the rock into The areas 15 can be excluded. In this respect, the reception areas 16 are actually limited to the inner route areas.

Thus, the propagation conditions of the high frequency underground are much more controlled than in the standard use of WLAN technology over days and especially within buildings, where a penetration of thin walls can not be ruled out and indeed takes place and is usually desirable.

2, two base stations 22 and 23 are shown in addition to the base station 21 for the route 11. It is clear that these are accordingly repeatable in further sections and corresponding base stations are also arranged in the route 12. A T-junction in which an arm 12 is absent and a kink in a stretch 11 or 12 is advantageously populated with a central base station, such as an intersection shown here in Figure 2, or the adjacent base stations are arranged such that the kink falls into an overlapping area 25. These controlled propagation conditions use the method according to the invention for the seamless switching between the base stations:

1. All base stations are deliberately set to a single, identical channel to use the method. All base stations receive a common network identification.

2. The transmission power and the placement of the base stations and design / selection of the antennas is so dimensioned that the mobile devices have only a relatively small coverage area 25 along the tunnel axis available, in which communication with both base stations can take place, so that a lowest possible Overlap area 25 is defined. Since the propagation of the high frequency can only take place along the tunnel axes, this overlap region 25 may be very small. This can be ensured quite easily in underground structures, since there are only minimal external factors influencing the propagation conditions. Furthermore, the overlapping area 25 can advantageously be defined by the fact that the receiving areas 16 of adjacent base stations which predetermine a threshold value for reception intersect at the tunnel walls, which is recorded by the reference numeral 17. However, it is advantageous if the signal threshold, which represents the safe receiving area 16, if appropriate, generous, so to measure larger than necessary. The predetermined setting of the threshold value, which is familiar to the person skilled in the art, leads here to a so-called least possible overlap 25 of the common reception areas 16. It is thereby possible to automatically adapt the transmission power in such a way that a measuring device can be calibrated in the said one common reception area 16 is brought and the sen- performance of the participating two base stations to a possible low transmission power to ensure reception. If it is assumed that a central base station 21, the other stations can be readjusted 22 or 23, etc. in the individual arms. Advantageously, the curves of the predetermined signal threshold values then intersect for reception of such two adjacent base stations in the region of the tunnel walls.

Another possibility for the automatic adaptation of the transmission power consists in the following procedure: If two neighboring base stations can still "see" themselves - ie they can still receive their beacons due to highly efficient antennas, they can also dynamically adapt their transmission power themselves. Visibility "has no influence on the communication with mobile devices, which can not achieve such good RF performance due to much poorer antennas and propagation conditions (polarization etc).

3. On the mobile device, a program control, which is explained in connection with FIG. 3, ensures that the connection (switching) to the next base station, for example 21 to 23 or 22, takes place at the right time, if the connection quality the current base station falls below a pre-set level if the connection quality of a station other than the current base station is better than that of the current base station, or if other link quality parameters make switching seem reasonable. It may also be parameters that result from the operation of the mobile device, so for example from its position in the tunnel. The individual method steps of switching in one embodiment will be described below. The setting of a single channel on a common network identification on all base stations 21, 22 and 23 results in the mobile device not having to actively seek other frequencies for a new base station. Thus, the very time-consuming process of "scanning" can be saved. Active scanning is disabled on the mobile device during normal operation. Instead, the mobile device initially looks only for alternative base stations on the already active channel. Only if no base stations can be found on this channel, it is possible that a configuration setting allows a subsequent full scan, which can then also be connected to a channel change.

Another positive effect is the possibility of using other channels for alternative tasks: Thus, completely separate networks for different purposes can be set up, which can cause no interference on the high-frequency side with each other.

The transmission power of the base stations and the selection of the antennas (in particular the Antennenabstrahlcharakteristik and the antenna gain) are chosen so that the smallest possible parts of the transmission power are wasted on reflections. The 0 overlap region 25 of two antennas, for example at 21 and 22, should be selected so that a secure and seamless switching can be ensured at the largest assumed movement speed of the mobile device.

On the mobile device, a program control ensures that the fastest possible switching to the next base station takes place as soon as the connection quality reaches a pre-set the dynamically determined threshold falls below. The measurement of the connection quality takes place permanently in the current data exchange and via the regularly sent by each base station calibration measurement signals (also called "beacons"), through which a mobile station (client) can determine the connection quality even without data exchange.

The measurement of the connection quality can take place in different ways:

1. On the mobile device: Measure the reception field strength of the currently connected base station

2. On the mobile device: Measuring the signal-to-noise ratio of the currently connected base station

3. On the base station: measurement of reception quality and signal-to-noise ratio of the connection to the mobile device and transmission of these values to the mobile device, which optionally then decides, when considering the self-determined quality parameters of 1) and 2), when switching to another base station is to take place. It is also possible to provide a measurement of the position of the mobile device, in particular by triangular or trilateral navigation or on the basis of field strength and signal-to-noise ratio, together with other base stations. If necessary, reference values can be "taught in" in a one-time measuring process ("teach-in").

In order to be able to include a measurement of the connection quality of both routes (both the HF route from the client to the base station and the connection quality from the base station to the client in the decision making, it is possible for the client to send a check telegram to the base station Base Station returns this telegram to the client, adding the link quality values it measures to the data, which allows the client to make its decision-making involve as he himself is received by the base station. This is particularly important when working with asymmetrical RF ratios, eg due to different antenna gains or output powers.

It is also possible for the mobile device to switch over to a new base station without an interim search for all available base stations (a so-called "scan") .Other possibility is the switching on the basis of the evaluation of position data in the mine, for example by reference on predetermined points and (on vehicles) measurement of the distance traveled (path and steering) This corresponds to a check of the position on a (virtual) map.This can also include position-determining goals, such as RFID gates or induction loops, etc.

Another way of adjusting the transmission power of the base stations can be pursued with the following procedure: All base stations advantageously operate on a single channel. This eliminates the need to switch channels in the (single) receiver on the mobile device if only one is present.

Each base station sends at predetermined intervals such as 100 milliseconds or even 5 seconds on the set frequency a sign of life, called beacone in hindsight. These signals, beacons, contain information of the base station in a data frame, such as the MAC address and / or a network identifier.

Each base station attempts to receive the beacons from the neighboring base stations. This will be the transmission power known. These marker pulses are often still over a very wide space receivable, which would not be sufficient for a regular connection of a mobile station.

Since advantageously all base stations (or access points) are set to a single frequency, the evaluation unit in each base station can permanently receive within the given intervals the beacons of all base stations in range.

Based on the received pulses, each base station can determine the reception field strength of the neighboring base stations. This is transmitted back to the transmitting base station via the stationary network. Thus, it receives information from all neighboring base stations as to whether and how they are received by them. If the field strength for all necessary neighbors is above a predetermined threshold value (which is individually dependent on the distance and antenna power of the individual base stations), the base station automatically reduces its transmission power. If this is below preset thresholds (which also depend on the distance and antenna power of the individual base stations) or if the beacons are not receivable by the neighbor, the base station increases its transmission power.

The information generated from this function can also be used to determine the quality of the system: For example, it is possible to warn of defective antennas if a base station can no longer recognize its neighbor over a longer period of time or increases in transmission power no longer result in "visibility""lead the station through its ^neighbors .

The said evaluation unit in the sense of the invention can Be implemented via the network card or even outside the driver in an application program.

Statistics about these network functions are relayed to central servers from which this reconciliation process can be remotely configured and controlled. But it can also, for-triggered In ^¬ game, be locally initiated by the individual base stations. In other words, the transmission power of each base station is adjusted so that the resulting coverage areas between mobile stations and base stations overlap as minimally as possible. For this purpose, a measurement of the reception field strength of the marking pulses emitted by each said base station is carried out by all adjacent base stations and the results are used for a subsequent control, in which the transmission power of said base station is set to achieve a reception field strength in a measuring interval.

On the basis of the received pulses, each mobile station can also determine the reception field strength of the neighboring base stations. The evaluation of the mobile station recognizes the field strengths of the beacons or other quality information associated with such as the signal to noise ratio, whether switching to another base station (access point) is necessary. This decision can be made about the highest or best value of field strength or signal-to-noise ratio, or the routine of comparing the individual values for a possible switch of the mobile device is not triggered until a corresponding threshold has been passed.

In particular, this switching process can take place as follows in order to avoid data loss during roaming. It must be ensured that no data frames with unclear Source-destination-route exist and get lost. This is done by dezidiertes Unsubscribe traffic with the old Ba ^¬ sisstation and logging in to the new base station.

The handset deauthentifies itself at the old base station. This triggers the connection. After dissolving the association is dissolved.

The handset authenticates with the new base station. In this case, keys can be exchanged according to a known pattern, which serve for data security. Alternatively, these keys can also been exchanged in advance and be ge ^¬ stores in the mobile device to speed up the authentication process. Thereafter, the mobile device is authorized to establish a data connection with the base station. In the next step, the handset associates itself with the new base station. The data exchange then flows through the new base station.

If both base stations (and the handset) are now on the same channel, this process takes a time of, for example, 2.5 milliseconds. This means that a safe switch to a new base station is possible very quickly when using a single channel and the standard-compliant procedure described above.

In this method according to the invention, certain steps defined in the standard are intentionally dispensed with in order to accelerate the overall process. These omitted process steps (e.g., channel scan) result from restricting channel selection as well as optimizations of the switching and authentication process.

Instead of the connection quality or as a supplement to this Parameter can serve as a decision criterion and the sequence of base stations: In this case, a "plan" is loaded on the mobile device, which contains the succession of base stations with their unique identifications (MAC addresses). In addition, if necessary, the reception field strengths belonging to the individual base stations can also be stored, from which the position of the mobile device in the tunnel 11 or 12 can then be derived. This makes it clear to the mobile device where it is located. It can then safely determine the next base station and connect to it by simply switching without search.

Another way of measuring the connection quality without own search is to use a second receiving unit, which is used exclusively for checking the connection quality to various base stations. The values of the receiver are evaluated by a program control which then proposes to the program control of the mobile device a connection to be newly selected.

If this receiving unit also contains a transmitter (it then constitutes a "transceiver" and thus a full-fledged network interface), then both network interfaces can also be used alternately by the mobile device by changing the network interface used at the application level.

If the optimized decision-making fails for whatever reason, then a full scan as defined in the WLAN procedure is used to search for a base station, in which case the channel binding may also be canceled. A full scan can also be done when the system is turned on. This process automatically sets the system to the selected channel. Alternatively, this one too be firmly configured in the mobile devices.

FIG. 3 shows a flow chart for a method according to an exemplary embodiment of the invention. A first program module 41 performs a measurement of the connection quality intermittently or continuously. This is done either by measuring the quality of the connection in the data stream or by measuring the field strength of Beacons received regularly by all base stations. With these beacons, each base station permanently (intermittently) tells the mobile stations how to reach them. The result of the measurement is compared with stored data in a step of comparing 42. As long as the connection quality remains good (stable network connection), the measurement 41 of the connection quality results in no action (arrow 43); except that the measurement is resumed according to the specifications.

On the other hand, if the comparison module 42 determines that the connection quality falls below a predetermined level (arrow 44), the mobile device will promptly poll the available base stations (module 45) at the set frequency. This request may be made internally in the memory of the mobile device or externally at the existing base station, or alternatively in a predetermined order on both devices. A measurement of the possible connection quality in the module 45 is then performed and delivered to another comparator module 46. If a base station with a better quality index (which can be, for example, field strength or signal-to-noise ratio) exists, the mobile station switches the active data connection to the new base station (arrow 47). The module 48 is then in principle the measurement module 41 already mentioned at the outset. If the connection to the new possible base station is not better, ie in particular even worse than the current one If there is no connection, then a return 49 of the control to the measuring module 45 takes place and this starts a new measurement and request at a short distance.

Since this process is very fast and can be partly parallel to the traffic, almost no interruption of the data traffic is detectable, as would be the case with a traditional scan. The method is therefore also suitable for machines that change their direction of movement very quickly and, for example, have to drive around curves. This advantage is very high when using a single channel in the participating devices, because the change time reaches the range of a few milliseconds.

If the process of changing the base station with the aid of this method is unsuccessful, this can only have the cause in a stable network that a base station has failed or antennas have been damaged. In this case, in addition, a complete, traditional scan is performed until a network connection can be established again.

A further advantageous embodiment lies in a procedure that is feasible in the presence of delimited areas, as they are given in underground mining. Here, the invention takes advantage of the fact that mobile devices, whether portable or attached to machines, are used cyclically in certain demarcated areas of the mine. This also limits the number of base stations needed during a deployment or drive cycle.

While the mobile device is being used, it either authenticates once (for example, the first time a machine has been driven) or as a precautionary measure at every base station during each trip. on, which comes within its reach, that is, be recognized by the beacons. In this case, this authentication takes place before the actual roaming sequence and, as it were, "on suspicion", that is to say with regard to a possibly later association to take place.

If the mobile device then determines which new access point is to be roamed, the sequence shown above is changed as follows: Instead of a de-authentication, only one disassociation is carried out when leaving the base station during roaming. In other words, the authentication is preserved. Instead of authenticating with the new base station, an association telegram is now sent to the new base station because the authentication (except for the first transit) already exists. This approach speeds up roaming and can work very reliably even with fast-moving machines and abrupt changes in WLAN coverage.

In addition to the single-channel embodiment, these methods can also be used with multiple channels, in particular if a scan can be carried out completely parallel to the data exchange, if, for example, a second receiver is present.

An additional use of the system is the exploitation of network information (which client devices are in the vicinity of a base station or other client), e.g. detect possible collisions with persons or other machines and make appropriate warnings and / or shutdowns.

Other features in the mobile device can be used to capture the quality of the wireless infrastructure and more or less as If this is done permanently or at regular intervals, for example, failed base stations or faulty or not (optimally) aligned antennas can be detected can affect negatively.

Claims

claims

Device for connecting mobile communication devices to wireless networks in underground structures, comprising a plurality of base stations, which are arranged in tunnel systems (11, 12) at a spatial distance substantially in the direction of the tunnel axes from each other, so that for every two adjacent base stations (21, 22, 23) results in a least possible overlap (25) of the common reception areas (16), and that all base stations (21, 22, 23) operate on a single common channel.

2. Device according to claim 1, characterized in that base stations (21) are arranged at crossing points (13) or at break points of tunnel passages of the tunnel system.

3. Apparatus according to claim 1 or 2, characterized in that each base station comprises one or more antennas which transmit and receive substantially in the direction of the tunnel longitudinal axes.

4. Device according to one of claims 1 to 3, characterized in that the distance from two adjacent base stations (21, 22, 23) is selected so that the curves of the predetermined signal thresholds for receiving such two adjacent base stations in the Cutting tunnel walls.

5. Device according to one of claims 1 to 4, characterized in that the communication devices are designed for communication according to the IEEE 802.11 - series of standards.

6. A method for the construction of underground networks with WLAN technologies with devices according to one of claims 1 to 5 and at least one mobile station, characterized in that all base stations in a tunnel system on a single, common channel and the design and configuration of the network so in that the smallest possible overlaps of the coverage areas arise and the mobile station selects the base station to be used on the basis of a connection quality signal.

7. A method according to claim 6 for operating the mobile station, characterized by the steps of intermittently or continuously consolidating (41) the communication quality with the connected base station by the mobile station or the connected base station, comparing (42) the determined communication quality (41). with a predetermined communication quality threshold, where below said communication quality threshold the mobile station determines (45) which other base station is in connection range and then a step of measuring (45) the possible communication quality with said other base station by the mobile station or said other base station followed by a step of comparing (46) the determined possible communication quality with a predetermined communication quality threshold, and switching (48) the communication to the n New base station with a better communication quality.

8. The method according to claim 7, characterized in that the communication quality is performed by measuring the reception field strength and / or by measuring the signal-to-noise ratio.

Method according to claim 6, characterized in that the coverage areas between microphone stations and base stations resulting from the transmission power of each base station are determined by a measurement of the reception field strength of the marker pulses emitted by each said base station by each of the adjacent base stations and a subsequent controlling adjustment of the transmission power of said base stations said base station to achieve a reception field strength in a measuring interval can be set.

An apparatus for interfacing mobile communication devices to wireless networks in underground structures, comprising a plurality of base stations arranged in tunneling systems (11, 12) at a spatial distance substantially in the direction of the tunnel axes from each other, the device being adapted to operate in their mobile stations are kept authenticated at the maximum number of base stations, and wherein said mobile stations are each associated with one of these base stations.

11. The device according to claim 10, characterized in that with all base stations marking pulses can be emitted, wherein the mobile stations are configured to authenticate at the base stations, of which they detect marker pulses.

Apparatus according to claim 10 or 11, characterized in that the mobile stations are arranged to disassociate only with the old base station upon a change from an old base station to another new base station in order to associate with the new base station without one Authentication step to perform.