DE102017001517B4 - Method for creating a status analysis of a wireless network infrastructure - Google Patents

Abstract

Method for creating a status analysis of a radio network infrastructure, which comprises at least one radio transmitter (36) and at least one mobile terminal (24), which is designed to receive at least one radio signal from the at least one radio transmitter (36). , in which - the at least one mobile terminal (24) records measurement data of the at least one radio signal, - position data is determined by means of a position determination device (25), which indicates the position of the at least one mobile terminal (24), - the measurement data and the Data comprising position data are transmitted to a higher-level detection device (15), - the data are stored in a database of the detection device (15), and in which - for the status analysis, the data are evaluated by means of a data processing device (13), characterized in that the Position data from a process control system is made available to the at least one mobile terminal (24), and that the data is filtered by the data processing device (13) using a mass data analysis tool with regard to at least one criterion, using the mass data analysis tool to determine a temporal development of the measurement data over a defined one Period is represented, and depending on the temporal development of the measurement data, limit values (44,46) of a strength of the radio signal are determined by the data processing device (13).

Description

The invention relates to a method for creating a status analysis of a radio network infrastructure according to the preamble of claim 1 and a system with a radio network infrastructure.

A method for analyzing data is already available US 9,532,180 B2 known. In the method, data recorded in a mobile radio network and assignable to respective mobile devices, which characterize network events in the mobile network, are assigned to position data of the respective mobile devices. Using a processor, the data is assigned to the position data and evaluated with regard to different measured variables.

A procedure for remote maintenance of an industrial truck is presented in the DE 10 2007 043 472 A1 disclosed. In this process, operational data is recorded using a recording device. The operational data are then stored in a data memory of the industrial truck and, after initiation of a wireless data transmission by an electronic control unit, are transferred from the data memory of the industrial truck to an external data memory using a wireless data transmission device.

In the EP 1 880 519 B1 A presence detection system integrated in a wireless local area network (WLAN) is disclosed. In this presence detection system, a presence signal is sent out using a transmitter to determine the presence of the transmitter in the wireless local area network (WLAN).

From the DE 10 2012 024 038 A1 a production system for the series production of motor vehicles is known, in which containers are transported using means of transport and the means of transport have at least one driverless transport vehicle, which can be or is controlled by a central device via radio, in particular via WLAN.

Furthermore, it reveals US 9,462,497 B2 a system and method for analyzing and rendering participant data.

Furthermore, from the US 2015/0326447 A1 a method for determining regions with particularly low user comfort is known. Here, diagnostic data from individual mobile devices are evaluated together with assigned positions.

To increase mobility and flexibility, more and more mobile and therefore radio-connected devices are being used in production companies. These mobile devices are, for example, participants in an extensive WLAN infrastructure, which is a radio network infrastructure and which is operated, for example, by an information technology department. At the moment there is at most status monitoring of the WLAN infrastructure, especially of active information technology components and access points, whereby their availability is checked. Since there is no collection of relevant measurement data to assess a WLAN signal as well as their evaluation and their experience-based limit operating values, comprehensive monitoring of the WLAN infrastructure is not possible. Due to the previous focus on the failure behavior of information technology components and not on the real operating values of the WLAN infrastructure, only reactive troubleshooting can take place in the event of disruptions. A maintenance department is notified by production employees based on manually recorded error symptoms. For example, a fault report can then be made by telephone to the information technology department. In the meantime, however, the problem may have disappeared and/or the at least one mobile device is again in an area in which reception of the WLAN signal works well.

This has the disadvantage that only reactive problem solving is possible and no forward-looking, predictive or proactive approaches can be pursued. Furthermore, it is difficult to determine the cause of the error. In addition, only very rough spatial and/or temporal monitoring of the WLAN infrastructure is possible, which is insufficient for production-critical components of the WLAN infrastructure. Since there is no long-term storage of operating data, no tendencies and/or trends and/or changes can be recognized. It is also not possible to provide an overview of the status of the WLAN infrastructure with a temporal and/or spatial focus. To date, spatial location of components, especially mobile devices, of the WLAN infrastructure has only been possible to a limited extent and imprecisely based on triangulation. In addition, a systematic analysis of operating parameters of the WLAN infrastructure is not possible because there are no reliable, data-based and transferable intervention and limit values.

The object of the present invention is to create a method and a system by means of which a state of a radio network infrastructure can be detected particularly advantageously.

This object is achieved according to the invention by a method with the features of patent claim 1 and by a system with the features of patent claim 10. Advantageous embodiments of the invention are the subject of the dependent claims.

A first aspect of the invention relates to a method for creating a status analysis of a radio network infrastructure, which comprises at least one radio transmitter and at least one mobile terminal, which is designed to receive at least one radio signal from the at least one radio transmitter. In the method, the at least one mobile terminal records measurement data from the at least one radio signal. Furthermore, position data is determined by means of a position determination device, which indicates the position of the at least one mobile terminal. In addition, the measurement data and data comprising the position data are transmitted to a higher-level recording device and the data is stored in a database of the recording device. For the condition analysis, the data is evaluated using a data processing device.

In other words, using the method according to the invention, for example, a WLAN infrastructure, which is an example of the radio network infrastructure, is analyzed with regard to its condition. Further examples of radio network infrastructure are a UMTS infrastructure and an LTE infrastructure. The method is explained in more detail below using the example of the WLAN infrastructure, whereby it is noted that the explanations and advantages explained in this context also apply to other radio network infrastructures.

For the condition analysis of the WLAN infrastructure, measurement data of the at least one WLAN signal is recorded using the mobile terminal, whereby the measurement data can be, for example, relevant measurement data for assessing the signal strength.

The relevant measurement data for assessing the signal strength includes, for example, current signal characteristics, such as the signal-to-noise ratio (noise) and at least one indicator for the received field strength (for example the Received Signal Strength Indicator (RSSI)). Furthermore, the hardware address (media access control address) of the mobile device, the respective name of all mobile devices (Service Set Identifier (SSID)), the active WLAN channel, etc. can be used as relevant measurement data for assessing the signal strength Data rate, the transmission power in milliwatts, the number of receiver packets (Rx), the number of transmitter packets (Tx), the number of retry packets, the number of error packets, switch settings between different WLAN networks (roaming settings ), in particular measurement data on the signal-noise ratio (SNR) as well as a number and time of changes, data on the communication protocol (Dynamic Host Configuration Protocol) and on Internet protocol addresses (IP addresses), included Validity period of an Internet protocol configuration (lease time) and name (host name), WLAN connection (WLAN IO/NIO), scanning of the surrounding access points (scan of the surrounding access points) as well as statistics on open connections (ports) and active ones Network protocols (transmission control protocol: Transmission Control Protocol (TCP), user datagram protocol: User Datagram Protocol (UDP)) can be used. The measurement data for WLAN IO/NIO can be determined by sending a packet from a diagnostic tool (ping) to fixed servers (servers), master computers or to protocol converters (gateways).

In the method, the position data, which indicates the position of the at least one mobile terminal, is determined by means of the position determination device. The position determination device is to be understood as a device which serves to determine the position of the at least one mobile terminal. The position determination device can, for example, determine the position of the at least one mobile terminal via received data, in particular using GPS, and/or via triangulation. Alternatively or additionally, the position determination device can determine the position of the at least one mobile terminal based on characteristic values for a process flow in which the mobile terminal is used, for example. For example, the mobile device is located in a vehicle, which in turn is located in a stationary test stand. For example, the position determination device determines position data for the position of the at least one mobile terminal based on the information that the mobile terminal in the vehicle is located in the stationary test stand.

The data comprising the measurement data and the position data are then transmitted to the higher-level detection device, whereby the transmission can take place, for example, via the WLAN infrastructure. In particular, the data comprising the measurement data and the position data are transmitted to the higher-level detection device in such a way that the position data corresponds to the measurement data or the measurement data corresponds to the posi tion data can be assigned. This means that the measurement data can be assigned to the position data or the position data can be assigned to the measurement data.

The higher-level recording device can be, for example, a server on which the data can be stored. For example, the server is equipped with software that enables data to be received. In addition, the recording device includes the database in which the data can be stored. Here, the database is to be understood in particular as a device in or on which the data can be stored. The database can include both software and hardware.

The data is stored in the database of the recording device and evaluated by the data processing device in order to create the status analysis of the WLAN infrastructure. In particular, the measurement data and the position data are stored in the database of the detection device so that they can be assigned to one another.

According to the invention, it is provided that the position data is made available to the at least one mobile terminal by a process control system. For example, the process control system stores at what point in time the at least one mobile terminal is in which position. For example, using programmable logic control of conveyor technology, the mobile device can be moved very precisely in accordance with the specifications of the process control system. For example, the conveyor technology ensures that the mobile device is at a position specified by the process control system at any given time. This time-dependent position data stored in the process control system can, for example, be transmitted to the position determination device. This makes a particularly precise determination of the position data of the mobile device possible. For example, the at least one mobile terminal is located in the vehicle, which in turn is located in the stationary test stand. Both the position of the test stand and the duration of a test process can be stored in the process control system and transferred to the position determination device. Consequently, the position data of the mobile terminal can be detected by the position determination device during the testing process and while the mobile terminal is in the stationary test stand.

If, for example, the mobile terminal is located in a vehicle that is continuously moved by means of the conveyor technology, the position data of the mobile terminal can also be detected by the position determination device, since the conveyor technology is controlled by means of the programmable logic controller and based on the data stored in the process control system and thus also the time-dependent position of the mobile terminal, which moves indirectly by means of the conveyor technology, is stored in the process control system and can be transferred to the position determination device.

The determination of the position data by means of the position determination device, in which the position data from the process control system is made available to the at least one mobile terminal, enables a particularly precise determination of the position of the at least one mobile terminal compared to the less precise triangulation methodology.

Furthermore, according to the invention, the data is filtered by the data processing device using a mass data analysis tool with regard to at least one criterion. This enables needs-oriented evaluation of the data and increases the comfort of a user of the data, especially when there is a large amount of recorded data. The mass data analysis tool used is advantageously designed in such a way that the desired data can be filtered out of the data to the user and presented in a particularly convenient manner.

Furthermore, a temporal development of the measurement data over a defined period of time is displayed using the mass data analysis tool. For example, the data is filtered with regard to the signal strength at a defined position of the mobile device over a defined period of time. This has the advantage that the temporal development of the state of the radio network infrastructure and in particular the WLAN infrastructure can be displayed particularly conveniently and clearly for the user using the mass data analysis tool. Furthermore, intervention and operating limits can be generated, secured and substantiated based on the temporal development of the measurement data. Based on these intervention and operating limits, it can advantageously be made clear to the user particularly quickly at which position the measurement data exceeds or falls below the intervention and operating limits. This enables proactive maintenance and error prevention. Furthermore, for example, structural changes can be recognized based on a change in the measurement data measured by the at least one mobile terminal. By detecting structural changes particularly quickly, for example, the WLAN infrastructure can can be adapted particularly quickly to new circumstances.

Furthermore, depending on the temporal development of the measurement data, limit values of the strength of the radio signal are determined by the data processing device. This means that the temporal development of the measurement data is analyzed over a longer period of time, for example, and depending on this, limit values for the strength of the radio signal are determined or set. For example, if the measurement data is above the specified limit, a warning can be issued to the user. Depending on the warning, proactive troubleshooting can then be carried out. The proactivity of troubleshooting is ensured by the fact that if the limit value is determined to be exceeded, the measurement data of the radio signal can be used to narrow down in which spatial area, or in which mobile device, if several mobile devices are used, the cause of the error is to be expected is. The user can now concentrate on this area or this mobile device when searching for the cause of the error. This enables particularly quick and efficient troubleshooting.

This is based on the idea that the status analysis of the WLAN infrastructure is carried out using the swarm intelligence of the at least one mobile terminal, in particular several mobile terminals that are used in a manufacturing company. Every mobile device can become a permanent WLAN sniffer in the manufacturing company. In particular, the data can be collected from the at least one mobile terminal, for example, at least essentially at any time and at any location.

Typically, the relevant measurement data for assessing the signal strength of the at least one WLAN signal is only measured when the WLAN infrastructure, in particular a WLAN network, is set up and handed over from a WLAN network supplier to a WLAN network customer. By means of the method described above, a permanent, area-spatial measurement of the WLAN infrastructure, in particular of the WLAN network, can be carried out based on a connection of the relevant measurement data for assessing the signal strength of the at least one WLAN signal with the position data on the position of the at least one mobile terminal . In particular, the data from the at least one mobile device is the basis for evaluations, which makes it visible and possible to analyze what the mobile device ultimately sees with regard to different parameters of the WLAN signal.

When evaluating the data for the status analysis using the data processing device, both individual evaluations for dedicated times, devices or locations are possible, as well as mass data analyses. In mass data analyses, for example, correlation and/or trend evaluations can be carried out. Using mass data analysis tools, the data can, for example, be evaluated, analyzed, correlated with one another, processed and/or visualized. For example, if the data is stored over a longer period of time, long-term observations can be carried out and trends can be identified, for example.

Using the method described above, a status analysis of the WLAN infrastructure can, for example, be carried out at any time. Real-time visualization and a time-space correlation of the relevant measurement data are therefore possible to assess the signal strength of the WLAN signal. For example, by recording a time course of the measurement data of the mobile terminal and the position data of the at least one mobile terminal, comprehensive monitoring options for the WLAN infrastructure arise. For example, by recording the measurement data of the at least one WLAN signal by the mobile terminal, the status analysis of the WLAN infrastructure can be created in, for example, a defined area, a hall or a processing location. For example, the state of the WLAN infrastructure can be recorded in relation to a bandwidth, with a temporal and spatial reference. Furthermore, for example, a spatial and temporal movement profile of the at least one mobile terminal can be created using the method. In addition, for example, roaming behavior of the at least one mobile terminal can be monitored with a temporal and spatial reference.

After the condition analysis has been created using the method according to the invention, data-based proactive intervention and operating limits can, for example, be developed and introduced based on long-term observation. Furthermore, for example, based on the status analysis, measures for optimizing and/or stabilizing the system behavior and/or the application operating behavior of the WLAN infrastructure can be defined. Advantageously, proactive maintenance of the WLAN infrastructure and error prevention can take place based on the condition analysis. For example, empirical values can be obtained using mass data analysis tools for safe operation, as well as intervention and operating limits are generated, secured and substantiated and, for example, then transferred to regular operation.

The use of the method results in the advantages that data-based and therefore reproducible transparency regarding the state of the WLAN infrastructure can be created using the at least one mobile terminal, which is used, for example, in a production hall. Since for the method the measurement data of the at least one WLAN signal are recorded by means of the at least one mobile terminal, which in particular includes a detection system intended for this purpose, no additional sensors associated with costs and no additional technology are necessary for the status analysis. In addition, the use of the method enables proactive error avoidance, in particular by detecting, for example, dead spots, deviating movement routes of the at least one mobile terminal, as well as detecting limit values being exceeded. By means of a graphic visualization of the data and, for example, through pre-processing of the data, an intuitive analysis option for the data is created. This enables, for example, particularly advantageous data accessibility and particularly quick analysis of the data. For example, using mass data analysis tools, large amounts of data can be processed particularly quickly. This leads, for example, to a particularly precise analysis of the state of the WLAN infrastructure, in particular error states and/or disruptions in the WLAN infrastructure. In addition, intervention and operating limit values defined on the basis of a condition analysis created by the method described above are particularly easy to reproduce, since these have been created, for example, based on data.

In an advantageous embodiment of the invention, the measurement data and/or the position data are first stored in a data memory of the at least one mobile terminal and then transmitted to the detection device.

In other words, the at least one mobile terminal comprises the data memory in which the measurement data and/or the position data can be stored. For example, the at least one mobile terminal is equipped with software by means of which the measurement data of the at least one WLAN signal is recorded and stored on the data memory of the at least one mobile terminal. The measurement data and/or the position data are then transmitted to the detection device. This results in the advantage that the measurement data and/or the position data can be collected and stored in the data memory of the at least one mobile terminal over a longer period of time in order to transmit them to the higher-level detection device if necessary. Thus, for example, the mobile terminal can record measurement data from the at least one WLAN signal and store it in the data memory, regardless of whether the signal strength of the WLAN signal is sufficient to transmit the measurement data and/or the position data to the higher-level detection device. If the at least one mobile terminal is, for example, in an area in which the signal strength of the WLAN signal is not sufficient to transmit the measurement data and / or the position data to the higher-level detection device, the mobile terminal can receive measurement data from the at least one WLAN signal record, store in its data memory and transmit the measurement data and / or the position data to the higher-level detection device at a time when it is again in an area in which the signal strength of the WLAN signal is sufficient.

Preferably, the measurement data and/or the position data are transmitted at the instigation of the at least one mobile terminal and/or the higher-level detection device. For example, the at least one mobile terminal can send the measurement data and/or the position data to the higher-level detection device. This sending of the measurement data and/or the position data from the at least one mobile terminal to the higher-level detection device can, for example, be initiated by the at least one mobile terminal. Alternatively or additionally, the transmission of the measurement data and/or the position data can be triggered by the higher-level detection device, for example by sending a signal. This allows a particularly high level of process reliability to be achieved when creating the condition analysis.

In a further advantageous embodiment, the measurement data and/or the position data are transmitted at regular time intervals. In other words, the measurement data and/or the position data are cyclically transmitted to the higher-level detection device. For example, the measurement data of the at least one WLAN signal is recorded once per minute, saved, stored in the data memory of the at least one mobile terminal and transmitted to the higher-level detection device every hour. This enables particularly secure operation of the wireless network infrastructure especially the WLAN infrastructure, as long-term observations are possible.

In an advantageous embodiment of the invention, a strength and/or a quality of the radio signal is recorded as measurement data. This has the advantage that a status analysis of the radio network infrastructure can be created with regard to the strength and/or quality of the radio signal.

The mobile terminal can, for example, record measurement data regarding the strength and/or quality of the WLAN signal and transmit it to the higher-level detection device. In the higher-level detection device, for example, it can be evaluated whether the strength and/or quality of the WLAN signal, in the form in which it can be detected by the mobile device, is sufficient or exceeds or falls below limit values. In this way, the performance of the radio network infrastructure and in particular the WLAN infrastructure can advantageously be adjusted in a targeted manner.

In an advantageous embodiment of the invention, the data is transmitted by means of a mobile terminal arranged in an industrial conveyor and/or in a motor vehicle and/or by means of a mobile telephone and/or a personal computer and/or a laptop and/or a tablet computer and/or a Hand-held terminals and/or a forklift terminal and/or a logistics terminal are recorded. In other words, mobile devices in particular that are equipped with a WLAN card can be used for the method according to the invention. The more mobile devices are used for the procedure, the more comprehensive the condition analysis can be carried out. Furthermore, the accuracy of the condition analysis can be optimized by using a plurality of mobile devices. For example, by using several mobile devices located in different positions, a status analysis of the WLAN infrastructure can be carried out in the area in which the mobile devices are located.

Areas of different quality of the radio signal are preferably detected using the method according to the invention. For example, the data comprising the measurement data and the position data are analyzed in relation to the quality of the WLAN signal at defined positions. In particular, the data is visualized in a diagram with different colors, in particular a heatmap. For example, a defined area in which the WLAN infrastructure is to be analyzed with regard to its condition can be shown in this diagram. The quality of the WLAN signal at different positions in this represented area can, for example, be marked with different colors, in particular a color coding, whereby a color can be assigned to a defined key figure range of the quality of the WLAN signal. This has the advantage that, thanks to the color coding, a user can quickly see how the quality of the WLAN signal behaves at different positions in the area being examined.

In an advantageous embodiment of the invention, standard values of the strength of the radio signal are determined by the data processing device depending on the development of the measurement data over time. This means that the temporal development of the measurement data is analyzed over a longer period of time, for example, and depending on this, standard values of the strength of the radio signal are determined or set.

In an advantageous embodiment of the invention, the data stored in the data memory is transferred depending on the occurrence of an error. For example, when the error occurs, a transmission of the measurement data and the position data to the higher-level detection device can be initiated. As a result of the occurrence of the error, the status analysis of the radio network infrastructure and in particular the WLAN infrastructure can be created. This ensures particularly quick and efficient troubleshooting, as the status analysis of the wireless network infrastructure is created as soon as the error occurs.

A second aspect of the invention relates to a system with a radio network infrastructure, which comprises a radio transmitter and at least one mobile terminal, wherein the at least one mobile terminal is designed to receive at least one radio signal from the at least one radio transmitter and To record measurement data of the at least one radio signal. Furthermore, the system includes a position determination device, which is designed to determine position data provided by a process control system, which indicates the position of the at least one mobile terminal. In addition, the system has a transmission device which is designed to transmit data comprising the measurement data and the position data to a higher-level detection device of the system, with a database of the detection device being designed to store the data. In addition, the system includes a data processing device which is designed to use the data to create a Evaluate the status analysis of the radio network infrastructure. The data processing device is further set up to filter the data using a mass data analysis tool with regard to at least one criterion, to display a temporal development of the measurement data over a defined period of time using the mass data analysis tool and to assign limit values for a strength of the radio signal depending on the temporal development of the measurement data determine.

The invention also includes further developments of the system according to the invention, which have features as have already been described in connection with the further developments of the method according to the invention. For this reason, the corresponding developments of the system according to the invention are not described again.

• 1 ein Verfahrensschema zur Auswertung von Daten mittels einer Datenverarbeitungseinrichtung;
• 2 eine schematische Draufsicht einer Fertigungsstätte;
• 3 eine schematische Darstellung einer örtlichen Zustandsanalyse eines Zugangspunktes mittels wenigstens eines mobilen Endgerätes;
• 4 eine schematische Darstellung eines Diagramms zur Visualisierung von Bereichen unterschiedlicher Qualität eines WLAN-Signals;
• 5 eine Darstellung von drei Diagrammen zur Visualisierung unterschiedlicher Messdaten in Abhängigkeit von der Zeit; und
• 6 eine Darstellung eines Diagramms zur Überwachung der Einhaltung von Eingriffs- und Betriebsgrenzen.

An exemplary embodiment of the invention is described below. This shows:

• 1 a process diagram for evaluating data using a data processing device;
• 2 a schematic top view of a manufacturing facility;
• 3 a schematic representation of a local status analysis of an access point using at least one mobile terminal;
• 4 a schematic representation of a diagram for visualizing areas of different quality of a WLAN signal;
• 5 a representation of three diagrams for visualizing different measurement data depending on time; and
• 6 a representation of a diagram for monitoring compliance with control and operating limits.

The exemplary embodiment explained below is a preferred embodiment of the invention. In the exemplary embodiment, the described components of the embodiment each represent individual features of the invention that can be viewed independently of one another, which also develop the invention independently of one another and are therefore also to be viewed as part of the invention individually or in a combination other than that shown. Furthermore, the described embodiment can also be supplemented by further features of the invention that have already been described.

In the figures, functionally identical elements are each provided with the same reference numerals.

The exemplary embodiment is an exemplary evaluation of data that was recorded to create a status analysis of a WLAN infrastructure. At this point it should be emphasized that this is only an exemplary embodiment and the status analysis is also valid for radio network infrastructures within which communication takes place via other radio connections such as UMTS or LTE.

The WLAN infrastructure analyzed with regard to its condition includes at least one WLAN transmitter 36 (which is shown schematically in the 3 and 4 is shown) and at least one mobile terminal 24, which is designed to receive at least one WLAN signal from the at least one WLAN transmitter 36. The data that is to be evaluated by means of a data processing device 13 includes measurement data of the at least one WLAN signal, which are recorded by the at least one mobile terminal 24, as well as position data, which are determined by means of a position determination device 25 and the position of the at least one mobile terminal Specify 24. To evaluate the data for the condition analysis using the data processing device 13, the data comprising the measurement data and the position data are transmitted to a higher-level recording device 15 and stored in a database of this recording device 15. The data can then be evaluated using the data processing device 13.

A process diagram for evaluating the data using the data processing device 13 is shown in 1 shown. By means of the mobile terminal 24 and by means of the position determination device 25 of the respective mobile terminal 24, the data comprising the measurement data and the position data are recorded in a recording process 10. An evaluation 12 of the data is carried out using the data processing device, in particular using a mass data analysis tool. A visualization 14 of the evaluated data then takes place.

For the visualization 14, for example, a schematic top view of a production facility 16, as shown in 2 is shown, with a following in connection with 3 measured value recording explained can be brought into line. For example, this creates an in 4 Diagram shown for visualizing areas of different signal strength of the WLAN signal of the WLAN transmitter 36 in the production facility 16. Different relevant measurement data of the signal strength of the WLAN signal can also be used over a period of time in under different diagrams, as in 5 shown, applied. In 6 An example diagram is shown in which a frequency distribution of average signal levels of the WLAN signal at a defined position in the production facility 16 is shown over a defined period of time.

In the in 2 In the schematic top view of the production facility 16 shown, test and production stands are identified with schematic circles and squares depending on their occupancy. Free test and production stands 18 are marked by squares. Occupied test or production stands 20 are shown by schematic circles. Incorrectly assigned test or production stands 22 are shown schematically with a crossed circle. In the 2 The schematic top view of the production facility shown can, for example, be stored in a process control system depending on the time. This makes it possible to determine the occupancy of the test or production stands at any time stored in the process control system based on the schematic top view of the production facility created at defined times.

In 3 an exemplary process of recording measured values by at least one mobile terminal 24 is shown. In this exemplary embodiment, the mobile terminal 24 is installed in a schematically shown motor vehicle 26. Furthermore, in 3 a first production system 28 with several production stations, and a second production system 33 are shown. The motor vehicle 26 can be moved in a first direction 30 through the first production system 28. The motor vehicle 26 is moved, for example, from a first production station 32 in the direction 30 into a second production station 34 of the production system 28. The mobile terminal 24 located in the motor vehicle 26 is also moved from the production station 32 to the production station 34 by means of the motor vehicle 26. Analogously to this, the motor vehicle 26 can be moved through the entire production system 28.

In 3 A WLAN transmitter 36 is also shown schematically. This WLAN transmitter 36 sends out at least one WLAN signal, for example.

Using the mobile terminal 24, measurement data from the at least one WLAN signal from the WLAN transmitter 36 can be recorded. For example, the mobile terminal 24 can record measurement data of the WLAN signal when it is located in a respective production station 32, 34, 38, 40, 42. If position data for the position of the mobile terminal 24 is determined by means of a position determination device at the same time at which the mobile terminal 24 records the measurement data for the WLAN signal, the measurement data of the WLAN signal can be assigned to the position of the mobile terminal 24. If the mobile terminal 24 measures, for example, a good strength of the WLAN signal in the production stations 38, a comparatively less good signal strength in the production stations 40 and a comparatively poor signal strength in the production stations 42, the measured signal strength in the data processing device can be compared with the Position data of the mobile terminal 24 are brought into context and, for example, a representation of the production system 28 is created, in which local differences in signal strength are identified, for example by means of color coding.

After passing through the production plant 28, the motor vehicle 26 can be moved, for example, into a further production plant 33, which is located, for example, in an area in which the signal strength of the WLAN signal of the WLAN transmitter 36 falls below a limit value.

The analogous to that in connection with 3 Location-related measurement data on the signal strength of the WLAN signal determined in the methods explained can be used, for example, with the in 2 shown view of the manufacturing facility 16 can be brought into line. The possibly resulting diagram is in 4 shown.

With the location-related measurement data on the signal strength of the WLAN signal of the WLAN transmitter 36 at different positions, a visualization of the data can be realized, for example, in which the production facility 16 is shown and areas of different quality of the WLAN signal, for example different signal strength, in the representation the manufacturing facility 16 are identified, as in 4 is shown. For example, areas 35, 37 of different signal strength can be represented with lines, in particular as contour lines, and/or by color coding. For example, a stronger signal can be received in a first area 35 than in a second area 37.

In 5 Three diagrams are shown for the temporal visualization of different measurement data of the WLAN signal. In a first diagram A, the change in a WLAN transmission rate is shown as a function of a period of time at a defined position in the production facility 16. In a second diagram B, a channel of the WLAN signal is shown at a defined position in the production facility 16 over the same period of time. A third diagram C in 5 describes a cumulative amount of transmitted data at a defined position in the manufacturing facility 16 over the same period of time.

In 6 the diagram is shown, which shows the frequency distribution of average signal levels of the WLAN signal of the WLAN transmitter 36 at a defined position in the production facility 16 in a defined period of time. The relative frequency is plotted on the ordinate and the signal level is plotted on the abscissa, descending to the right. Furthermore, in the diagram in 6 an intervention limit 44 and an operating limit 46 are marked. The intervention limit 44 marks the signal strength from which changes in the WLAN infrastructure should be made in order to shift the signal level into a safe operating range 48. If the signal level exceeds the operating limit 46, secure operation of the WLAN infrastructure can no longer be guaranteed. By means of this visualization of the intervention limit 44 and the operating limit 46, the need to make a change to the WLAN infrastructure in order to shift the signal level into the operating range 48 for safe operation can be identified.

Overall, the example shows how the invention can be used to achieve WLAN application monitoring in real operation through the swarm use of productive mobile WLAN devices.

Claims (10)

Method for creating a status analysis of a radio network infrastructure, which comprises at least one radio transmitter (36) and at least one mobile terminal (24), which is designed to receive at least one radio signal from the at least one radio transmitter (36). , in which - the at least one mobile terminal (24) records measurement data of the at least one radio signal, - position data is determined by means of a position determination device (25), which indicates the position of the at least one mobile terminal (24), - the measurement data and the Data comprising position data are transmitted to a higher-level detection device (15), - the data are stored in a database of the detection device (15), and in which - for the status analysis, the data are evaluated by means of a data processing device (13), characterized in that the Position data from a process control system is made available to the at least one mobile terminal (24), and that the data is filtered by the data processing device (13) using a mass data analysis tool with regard to at least one criterion, using the mass data analysis tool to determine a temporal development of the measurement data over a defined one Period is represented, and depending on the temporal development of the measurement data, limit values (44,46) of a strength of the radio signal are determined by the data processing device (13). Procedure according to Claim 1 , characterized in that the measurement data and/or the position data are first stored in a data memory of the at least one mobile terminal (24) and then transmitted to the detection device (15). Procedure according to Claim 2 , characterized in that the measurement data and/or the position data are transmitted at the instigation of the at least one mobile terminal (24) and/or the higher-level detection device (15). Method according to one of the preceding claims, characterized in that the measurement data and/or the position data are transmitted at regular time intervals. Method according to one of the preceding claims, characterized in that data indicating a strength and/or a quality of the radio signal are recorded as measurement data. Method according to one of the preceding claims, characterized in that the data is transmitted by means of a mobile terminal (24) arranged in an industrial conveyor and/or a motor vehicle and/or by means of a mobile telephone and/or a personal computer and/or a laptop and/or a Tablet computer and/or a handheld terminal and/or a forklift terminal and/or a logistics terminal can be recorded. Method according to one of the preceding claims, characterized in that areas of different quality of the radio signal are detected. Method according to one of the preceding claims, characterized in that standard values of a strength of the radio signal are determined by the data processing device (13) as a function of the temporal development of the measurement data. Method according to one of the preceding claims, characterized in that the data stored on the data memory is transferred depending on the occurrence of an error. System, with - a radio network infrastructure which comprises a radio transmitter (36) and at least one mobile terminal (24), the at least one mobile terminal (24) being designed to transmit at least one radio signal from the at least one radio to receive transmitter (36) and to record measurement data of the at least one radio signal, - a position determination device (25), which is designed to receive position data provided by a process control system, which indicate the position of the at least one mobile terminal (24), to determine, - a transmission device which is designed to transmit data comprising the measurement data and the position data to a higher-level detection device (15) of the system, - a database of the detection device (15) being designed to store the data, and - a data processing device (13), which is designed to evaluate the data to create a status analysis of the radio network infrastructure, to filter the data using a mass data analysis tool with regard to at least one criterion, and to use the mass data analysis tool to determine a temporal development of the measurement data over a defined period of time and to determine limit values (44,46) of a strength of the radio signal depending on the temporal development of the measurement data.

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