EP3158362A2 - Method for verifying the plausibility of gnss position signals - Google Patents

Abstract

The invention relates to different methods for verifying the plausibility of GNSS position signals, including a method for verifying the plausibility of position signals (112, 14f) of a global satellite navigation system (100) in a vehicle (1), said navigation system comprising at least one detection system (2) for detecting objects (64, 66, 70, 72, 67) in the surroundings of the vehicle (1) as well as a reception device (10) for receiving the position signals (112, 14f), said method involving the steps of: - having the reception device (10) receive the position signals (112, 14f), and determining the actual position of the vehicle (1) on the basis of the position signals (112, 14f); - having the detection system (2) detect at least one object (64, 66, 70, 72, 67) in the surroundings, and determining the position of the object (64, 66, 70, 72, 67); - verifying the plausibility of the position signals (112, 14f) by comparing at least one position of an object (64, 66, 70, 72, 67) with the actual position of the vehicle (1).

Description

Method for plausibilizing GNSS position signals

The invention relates to methods for plausibilizing position signals of a global navigation satellite system in a signal receiver, in particular vehicles or land vehicles.

In the prior art, the use of a global navigation satellite system (hereinafter GNSS for Global Navigation Satellite System), possibly supported by other vehicle sensors, where the vehicle sensors are possibly fused together, is a common method for determining the intrinsic position of the vehicle. As a rule, the receiver or sensor of the GNSS position signals is the only sensor which supplies an own position or absolute position of the signal receiver. He also provides a global time base that can be used to synchronize multiple sensors or systems or Car2X / vehicle-to-X (hereafter referred to as V2X for Vehicle-2-Χ) systems. In contrast to sensors installed in the vehicle such as IMU, Wheelspeed, etc., the GNSS sensor is influenced by the environment and can be disturbed from the outside (even without intervention in the vehicle hardware). In addition to principle-related disturbances such as shadowing and the so-called multipath, the GNSS sensor can deliberately be artificially disturbed (jammered) or manipulated (spoofer).

Jammers can be e.g. By means of artificial noise, the position or useful signals of the GNSS are superimposed, as a result of which the GNSS reception is effectively torn off and GNSS fix (position resolution) is no longer possible. This is equivalent to shading and is for a short time uncritical for the localization.

Spoofers, on the other hand, play the wrong position in the system by recording recorded or artificially calculated GNSS signals send out. It is not possible for the GNSS sensor to recognize that these are fake signals. The result is a wrong positioning and also a wrong time base. A system disturbed in this way can interfere with the V2X function through V2X communication and even transmit errors to other vehicles. This can be a security leak for the V2X system. If the spoofer data are not only fed directly into your own system but transmitted by radio, the forgery spreads throughout the entire environment and is present in all systems.

The reasons for the use of whining or spoofers are manifold and ranging from a private interest - for example, you do not want to be tracked or monitored - up to an economic interest, such. B. simulate speed limits, rest / break times, used road links and toll booths etc.

If the fake GNSS fed position signals not only directly in the system of spoofers, but, as with kos ^¬-effective GPS whining usual, transmitted by radio, then the manipulations affect not only one's own vehicle, but to all vehicles in the Environment, or the entire system can be manipulated within a certain range from the outside.

The civil-area Global Positioning System (GPS) does not provide a systemic way of detecting forged data, provided that it is meaningful, consistent, and not filtered out by the plausibility check.

The object of the invention is therefore to provide a method by which received position signals can be checked for plausibility. The object is achieved according to a first aspect of the invention by a method for checking the plausibility of position ^¬ signals of a global navigation satellite system in a vehicle, comprising at least one detection system for detecting objects in the surroundings of the vehicle and a receiving means for receiving the position signals, comprising the steps of :

 Receiving the position signals by means of the receiving device and determining the intrinsic position of the vehicle based on the position signals,

- Detecting at least one object in the environment by means of the detection system and determining the position of the object, plausibility of the position signals by comparing at least one position of an object with the own ^¬ position of the vehicle.

The first aspect of the invention is based on the basic idea that an estimate of the vehicle's own position is possible by means of the position of the objects from the environment, which is independent of the position signals of the GNSS and sufficiently plausible for the position signals. The detection system is thus a system which functions in principle independently of the determination of the intrinsic position via the position signals of the GNSS. To compare the position of an object with the intrinsic position of the vehicle based on the GNSS position signals, different criteria for plausibility can be used. In the simplest case, a radius around the eigenposition is used. If the objects lie within the radius, the position signals can be made plausible. In this case, the tolerance ranges for position determination via GNSS itself must also be taken into account. Assuming that spoilers want to simulate a fundamentally incorrect position specification, a plausibility check can then be denied if the deviation of the Own position of the position of the object in the range of several kilometers. Alternatively, it is also possible to create smaller comparison thresholds. These could advantageously be compared with other situational criteria, such. B. same direction, road, etc.

Particularly preferably, the step of detecting an object and determining the position of the object is carried out via a message sent by the object itself. This can be done, for example, via a V2X message in which the object describes itself and its position.

The detection system is in the most general form a system for capturing positional information from abstract or tangible objects such. As traffic lights, buildings or even digital data that are transmitted via electromagnetic waves.

According to an advantageous embodiment of the method according to the invention, the detection system comprises a camera device and is for the visual recognition of objects, in particular landmarks, such. As street signs, place signs, etc., trained. In this way, very different types of visually detectable objects can be detected by means of the vehicle, to which the position of the respective objects is known. Alternatively, the use of radar or lidar systems is conceivable, which can not visually, but because of their special signals objects can recognize. According to an advantageous embodiment of the method according to the invention, the respective position of objects is retrievable from a local map or from an external server.

According to an advantageous embodiment of the method according to the invention, the detection system comprises a vehicle-to-X or _n

 5

V2X Communication device for receiving objects in the form of V2X posts with a position specification of a sender of the V2X message. Particularly advantageous here is the exchange of position data with fixed objects whose position does not change and at best by a trusted body, eg. As a state or public institution is set.

According to an advantageous embodiment of the method according to the invention verified and / or signed V2X messages are used for plausibility. In this way, the authenticity of the V2X and the genuineness of the position indication can be ensured. According to an advantageous embodiment of the method according to the invention, the detection system comprises a motion sensor, in particular for detecting accelerations. In this way, road bumps that have a characteristic acceleration curve can be used to determine the vehicle's own position. Particularly advantageous is the detection of fixed road irregularities, such. B. speed bumps whose position is i. d. R. do not change. According to an advantageous embodiment of the method according to the invention, the detection system detects one of the objects from the following group:

 Infrastructure facilities, such as traffic signs, traffic lights,

Toll stations, tunnels, signposts, town signs,

- Point-of-Interest POIs, such as public institutions,

Shops, parking garages, and / or

 Road bumps.

The object is further achieved according to a second aspect of the invention by means of a method for plausibility of .

 b

Position signals of a global navigation satellite system for determining the intrinsic position of a signal receiver, in particular vehicle, having a receiving device for receiving a plurality of position signals, comprising the steps of: receiving the position signals by means of the receiving device,

 Analyzing the relative movements between the signal receiver and a plurality of signal transmitters of the position signals and / or analyzing the relative movements between a plurality of signal transmitters to each other based on the respective

Position signals

Checking the plausibility of the position signals when there is no Korre ^¬ lation between the relative movements is present. The second aspect of the invention is based on the recognition that real or regular position signals from GNSS satellites move relative to the signal receiver independently of each other. The relative movements of the satellites to the signal receiver are not dependent on each other and do not correlate with each other. Likewise, the likelihood that those satellites that are visible to a signal receiver will vary depending on each other. Although it is possible that several satellites are present in an orbit and thus dependencies may occur sporadically. In general, however, this case is very different from the case where a spoofer simulates multiple position signals from a single signal transmitter. Since this is only a single signal transmitter, the relative movements of the simulated transmitters or sources correlate with each other and also relative to the signal receiver. For plausibility of the position signals, therefore, different thresholds of correlations between the relative movements can be applied. ^

According to an advantageous embodiment of the method according to the invention, the relative movement between the signal receiver and each signal transmitter is performed on the basis of a Doppler effect and / or phase measurement and / or a measurement of the delta lengths of the respective received signals. Deltaranges is a route change or distance change or the relative speed between a satellite and a signal receiver, z. B. vehicle to understand.

According to an advantageous embodiment of the method according to the invention, the signal receiver performs a determination of the signal strength for each position signal. In addition or as an alternative to the aforementioned embodiment, a further possibility for the detection of spoofers can thereby be created. The signal strength of the position signals emitted by spoofers is usually equally strong and significantly stronger than true position signals from GNSS satellites. In particular, the uniform change, d. H. Increasing or decreasing the signal strength of the different position signals can be used to detect a spoofer.

According to an advantageous embodiment of the method according to the invention, the respective direction is determined based on the signal strengths, from which the respective signal, for. B. position signal of a satellite or another signal of a V2X communication tion ^¬ participant, is received, wherein the position signal is plausible if no other position signal is received from the substantially same directions. The term substantially the same direction encompasses a tolerance range which defines the expected reception direction. In three-dimensional space, it does not happen that two satellites from the same direction send their position signals. They differ in at least one of the spatial directions or vectors. The situation is different with falsified positions sition signals from a spoofer, which are usually all from one direction.

According to an advantageous embodiment of the method according to the invention, the receiver has an antenna device with at least one directional antenna and / or a plurality of antennas. In this way, different analyzes of the posi ^¬ onssignale can be performed. The object is further achieved according to a third aspect of the invention by means of a method for plausibility checking of position signals of a global navigation satellite system in a signal receiver, in particular a vehicle, which comprises a receiving device for receiving the position signals, comprising the steps:

 Receiving the position signals for determining the self-position of the signal receiver,

Comparing the position signals with previous position ^¬ signals of the signal receiver,

- Plausibilisieren the position signals, if there is no sudden change of properties of the received position signals to properties of previous position signals. The third aspect of the invention is based on the recognition that position signals distributed by spoofers, in contrast to true satellite signals of a GNSS, propagate over a limited range and thus can be recognized by a vehicle by comparison with preceding position signals. By using already received, in particular plausibilized position signals, sudden changes of characteristics of the position signals can be well recognized. By adapting the jump thresholds, plausible jumps in the position signals can then be detected. _

 y

According to an advantageous embodiment of the method according to the invention, the properties of the position signals comprise information about the time or clock used by the transmitter or the time stamp of the position signal. The problem with position signals is, in particular, the exact synchronization of the time information of the spoofer to the real time of the satellites. In this way, therefore, a Plausbilisierung the position signals are performed. According to an advantageous embodiment of the method according to the invention, the position signals are made plausible if there is no sudden change in the eigenposition determined on the basis of the position signals relative to the previous eigenpositions.

According to an advantageous embodiment of the method according to the invention, the method is carried out by means of an infrastructure device, in particular traffic lights. Here are two alternatives conceivable. According to a first alternative, the infrastructure device has a receiving device for receiving GNSS position signals. In this way, spoofers can be detected simply by matching the eigenposition derived via the position signals with the stored intrinsic position of the infrastructure device. Recognition of forged GNSS position signals is thus possible because it does not match the expectation and has jumps. An infrastructure, the position and time determined on GNSS, by comparison with a stored position and undisturbed network connection, which is equivalent with undisturbed or real time indication, he met a contradiction and thus fake GNSS ^¬. In the event that the spoofer brings the fake position data also in V2X messages, a V2X communication-capable infrastructure device can recognize the spoofer over the wrong position information in the V2X message and if necessary, warn subsequent cars. By comparing one's own position and time with the transmitted position and time of an infrastructure, which is preferably transmitted securely and encrypted, a contradiction and thus manipulation of one's own vehicle can be detected.

According to an advantageous embodiment of the method according to the invention, the method is carried out in a vehicle, wherein the position signals are additionally plausibilized by means of a method according to one of the preceding embodiments according to the first and / or second aspect of the invention. This embodiment allows the position signals also to be plausible if a vehicle is for a longer time in the range or coverage area of the spoofer position signals and thus a detection of non-plausible Posi ^¬ tion signals by means of a comparison with temporally older position signals is not possible.

According to an advantageous embodiment of the method according to the invention, in the event of a sudden change in the characteristics of the position signals and / or the eigenposition as a function of the direction of the change, an entry or exit from an area or transmission area is determined by a signal transmitter which transmits non-plausible position signals.

In the border area between "good" reception and "manipulation", V2X receives data from both areas that do not match, allowing manipulation to be detected, even if the own vehicle is consistently within the manipulated area and no jumps of its own received position signals can detect.

According to an advantageous embodiment of the method according to the invention, a signal transmitter, the non-plausible posi- tion signals sent, determined by means of a handshake or Verifi ^¬ ornamentation method. The handshake process includes a secure message transmission via V2X with about ^¬ mature content to the correct answer with respect to the random content takes place. Content of the random content should be the own position and time, as well as the position and time and confirmation information of the remote station, as well as a random number that must be identical in both messages. This can be used to rule out replay attacks that can not respond correctly to the random content, or to correctly counteract a tampering or plausibility check.

According to an advantageous embodiment of the method according to the invention, a signal transmitter that transmits not plausible Posi ^¬ tion data, determined by means of tracking or exclusion method.

According to an advantageous embodiment of the method according to the invention, the aforementioned method is carried out by means of an external system which receives movement information from vehicles which have a V2X communication device. The invention will be described in more detail below with reference to embodiments and figures. Show it:

Figure 1 is a schematic representation of a vehicle for carrying out the method according to the invention, and

Figure 2 is a schematic representation of a driving situation with a vehicle for carrying out the method according to the invention. In the figures, the same technical elements are provided with the same reference numerals and described only once.

Reference is made to Fig. 1, which shows a schematic diagram of a vehicle 1 with a chassis 4, which is carried on wheels 6 in a direction indicated in Fig. 2 driving direction 5 mobile.

To determine the intrinsic position or absolute position of the vehicle 1, the vehicle 1 receives a plurality of position signals 112 from a plurality of GNSS satellites 110 via a known GNSS antenna device 16, cf. FIG. 2 shows by way of example only one satellite 110 in FIG. A reception ^device 10 is connected to the antenna device 16 and evaluates the position signals 112 in such a way as to determine its own position. As a rule, the absolute position is derived in a manner known to the person skilled in the art on the basis of the position signals 112 emitted by GNSS satellites 110. In this example, the antenna device 16 and the receiving device 10 are shown separated from each other and be ^{¬ written} . However, it is also conceivable that both parts are integrated in a single receiving device.

In addition, the vehicle 1 has a detection system 2 for detecting objects and for plausibility of the intrinsic position. The detection system 2 includes represents only a configuration of a plurality of components 18, 24, 16, 10. The described in this embodiment recordable confi ^¬ guration of the detection system 2. According to requirements, the detection system 2 may be equipped with less or more components wasbspw. depending on the procedure to be carried out.

On the one hand, the detection system has a plurality of motion sensors in the form of an inertial sensor 18, the driving dynamics data 20 of the Vehicle 1 detected. These are known to include a longitudinal acceleration, a lateral acceleration and a vertical acceleration and a roll rate, a pitch rate and a yaw rate of the vehicle 1. This driving dynamics data 20 are used in the present embodiment to increase the information content data 12 on the intrinsic position of the vehicle 1 and, for example, the To specify position and the speed of the vehicle 1 on the roadway 13. The refined data may then be used by a navigation device even if the GNSS position signal 101 is not available under a tunnel, for example. To further increase the information content of the self-position, further motion sensor sensors in the form of wheel speed sensors 26 can optionally be used, which detect the wheel speeds 28 of the individual wheels 6 of the vehicle 2.

In addition, the detection system 3 comprises a further sensor cluster 24 for detecting objective objects. The sensor cluster 24 comprises a camera device, a radar device and a lidar device and makes it possible to detect the objects in the surroundings of the vehicle. The data 22 of the sensor cluster 24 can then be used to identify or identify the objects in the evaluation device 8 and to determine their position.

Further, the detection system comprises a V2X communication ^¬ device which is integrated in this embodiment, in the antenna device 16 and the receiving device 10th It should be noted that for the purposes of the invention V2X messages 30 are understood as objects. The antenna 16 is also used to receive and transmit V2X messages 30. The receiving device 10 has a partition for reading and processing the V2X messages 30. In this way, for example, the parameters contained in the V2X messages 30 are sition information readable. In addition, the receiving device 10 allows the verification of signatures of V2X messages and the implementation of handshake or verification procedures with other V2X communication participants.

The evaluation device 8 receives from the different components 18, 24, 16, 10 of the detection system 2 data and information about the intrinsic position and the environment of the vehicle 1 and compares them with each other. In order to plausibilize the self-position, several methods are provided which, depending on the configuration of the evaluation device 8, can be executed individually or in combination.

In the following, the plausibility method according to the invention and FIG. 2 will be discussed.

FIG. 2 illustrates the following driving situation. The vehicle 1 travels on the road 13 in the direction of the arrow 5. In the field of vision of the vehicle 1 there are four GNSS satellites 110, 120, 130, 140, which are each in their orbits 111, 121, 131 , 141 move. Each of the satellites 110, 120, 130, 140 sends Po ^¬ sitionssignale from 112, over which the vehicle 1 can determine its own position ^¬. For clarity, the position signals 112 are shown only for the satellite 110. In the same way, the satellites 120, 130, 140 Posi ^¬ tion signals send out.

In addition to the satellites 110, 120, 130, 140, another position signal transmitter is in the form of a spoofer 15f which transmits non-authentic or forged position signals 14f. The spoofer 15f sends its counterfeit Positi ^¬ onssignale 14f within a transmission area 17f, which is limited to the surroundings of the spoofers 15f and varies according to transmission power. However, if the vehicle 1 is within the Transmit range 17f, the position signals 112 of the satellites 110, 120, 130, 140 are dubbed. This can lead to an own position of the vehicle being determined, which is located entirely in a different location.

The spoofer 15f may be, for example, a stationary or a moving vehicle on the road 13. The direction of movement of the spoiler 15f is shown by the arrow 5f. Similar to the satellites 110, 120, 130, 140, the spoofer 15f transmits plausible position signals 14f which are sufficient to determine the intrinsic position of the vehicle 1. However, the position signals 15f are not from different signal transmitters, as is the case with the satellites 110, 120, 130, 140. Therefore, although the self-position of the vehicle 1 can be determined, but it does not match the actual own position of the vehicle 1. The wrong eigenposition could have a deviation of several kilometers compared to the actual eigenposition. According to a first embodiment, a check or plausibility of the position signals 14f may be performed by the following steps.

First, the position signals 14f of the spoofer 15f are received via the antenna device 16 of the receiving device 10. The receiving device 10 determines based on the position signals 14f spoofer the self position of the vehicle 1 in the same manner, such as regular position signals used to determine the egg ^¬ gene position.

In parallel, the detection system 2 detects several objects 66, 64 in the environment and determines the positions of the objects 66, 64. In the present example, the vehicle 1 detects by means of Ka ^¬ meraeinrichtung the sensor cluster 24, the traffic light 66. About the Inertial sensors 18, the cobblestone road 64 is detected. Although the latter allows only a localized localization of the respective object, but may be sufficient for plausibility. Other road bumps, such. As a Guilideckel 70 or road ramps 72 allow a more precise localization of the object and thus the environment of the vehicle via the motion sensors. The respective position of objects is, for example, retrievable from a local map or from an external server. It is also conceivable that the traffic light is equipped with a V2X communication device and sends V2X messages 67, in which the position of the traffic light is described. It is particularly advantageous if the messages 67 are signed. Additionally or alternatively, it is conceivable that certain obj ekte, such as place entrance signs or signposts are detected by the camera device and evaluated by the evaluation device content. In this way, solely due to the detection of the object, the position of the vehicle 1 can be determined in a location-accurate. By comparing the positions of the traffic light 66 and the paving stone road 64 with the intrinsic position of the vehicle 1, it can be found that there is a deviation between the intrinsic position of the vehicle and the position of the objects, for example, on the order of several kilometers. Since this deviation is well above the fault tolerance of GNSS, the position signals 14f are detected as implausible and not used for applications in the vehicle. In addition, a warning about V2X messages can be issued. Particularly advantageous objects for plausibility of the egg ^¬ genposition include

Infrastructure facilities such as traffic signs, traffic lights, toll stations, tunnels, signposts, city signs, Point-of-Interest POIs, such as public institutions,

Shops, parking garages, and / or

 Road bumps. A second embodiment for plausibility of the self-position will be described hereinafter.

In the first step, as already described above, the position signals 14 f are received and from this the intrinsic position of the vehicle 1 is determined.

The received position signals 15f are analyzed by means of a measurement of the Doppler effect or the phase or delta ranges (range changes), as already known from the distance measurement of GNSS position signals. By means of these measurements, on the one hand, the relative movement between the signal receiver or the vehicle 1 and the signal transmitter can be determined. As a rule, the relative movement of the satellites 110, 120, 130, 140 to the vehicle 1 can be determined from the position signal 112 of the satellites. Since each satellite 110, 120, 130, 140 moves in its own orbit 111, 121, 131, 141 independently of the other satellites 110, 120, 130, 140, there is no correlation in these relative movements. However, in the case of the spoofer 15f, it can indeed simulate several signal transmitters. However, these are all from the same source, so that the relative movement between the simulated signal transmitters and the vehicle 1 has a correlation, that is, the relative movements comprise a dependency on ^¬ today.

If such a correlation is detected, it is possible to infer fake position signals 14f and these should not be made plausible. Additionally or alternatively, the signal strength and / or direction of the signal may serve as a basis for determining plausibility of the position signal 14f. Based on the signal strengths and the respective direction can be determined, from which the respective position signal is received. The position signal 14f is made plausible only if no other position signal is received from the substantially same directions. For this purpose, it is advantageous to equip the on ^¬ antenna device 16 having at least one directional antenna and / or a plurality of antenna modules. If it is known from which direction the position signals of the actual satellites must come, in this way a position signal can be made plausible on the basis of the direction. A third exemplary embodiment for plausibilizing the egg ^¬ genposition will be described hereinafter.

In the first step, as in the previous embodiments, position signals 14f for detecting the self-position of the signal receiver or vehicle 1 are received.

In the second step, these position signals 14f are compared with previous or older position signals of the vehicle 1. This step can be carried out, for example, in the evaluation device 8. Previous or older position signals are understood to mean those which have been received in advance. The applicable period of the older position signals may be predefined or depending on movement activity, eg. B. speed of the vehicle to be selected. Alternatively can be reset spread to such a position signals to ^¬ that have already been checked for plausibility by means of other methods, for example. The two aforementioned embodiments. In this way, the following situation arises for the vehicle 1 in FIG. The vehicle 2 is entering the transmission range 17f of the spoiler 15f from the transmission range of the regular GNSS satellites 110, 120, 130, 140. The two different transmission ranges could also be defined in a regular and irregular or authentic and non-authentic transmission range. If the vehicle now comes from a regular transmission range in the irregular transmission range 17f so change the characteristics of the position signals, such. Phase, run time, timestamp, and other information contained in a GNSS position signal because spoofer 15f can not mimic the satellites exactly time synchronous to reality. Finally, the intrinsic position of the vehicle 1 also changes. These changes in the characteristics are erratic, so that due to such a change history, a transition from a regular transmission area to an irregular transmission area 17f is recognizable and the position signals 14f should not be made plausible.

If a vehicle is located within the irregular transmission range 17f for a relatively long time, the plausibility of the position signals 14f can not be checked with this method. Here, the above-mentioned embodiments may be useful to nevertheless plausibilize the position signals 14f. Therefore, a combination of the embodiments is particularly advantageous. In particular, the exchange of V2X messages with position information allows a vehicle to carry out a plausibility check in such a case.

The embodiment described here is not limited to an application in a vehicle. In a particularly advantageous manner, the method can also be implemented in an infrastructure facility. For example, a traffic light 66 could be equipped with a GNSS position signal receiver. This would with a passing Spoofer 15f whose position signals 14f with their own position signals, Compare position information or own position. Since the intrinsic position of the traffic light 66 does not change, this information base could be used as a fixed reference. A GNSS position signal 14f leading to another eigenposition could thus quickly be recognized as spoofer 15f.

In the event that the spoofer 15f is a vehicle with a V2X communication device, which also sends V2X messages with correspondingly incorrect position information in addition to the forged position signals 14f, it would be helpful to implement a handshake or verification method. The handshake procedure includes the following steps:

 Sending a request from a first vehicle to a second vehicle having a variable or random size, wherein the expected response to the request of the second vehicle to the first vehicle depends on the variable or random variable,

 - Receiving the answer of the second vehicle by the first

Vehicle, and

 - Check the response depending on the variable Random. Since a Spoofer 15f would provide its V2X messages routinely or by default with a corrupt position information, this fact could be exploited to detect the spoofer. A request with a variable or random variable regarding the position information could then not be correctly answered by a spoofer, which would not result in a valid handshake.

By means of the plausibility or the lack of plausibility a spoofer 15f can be reliably detected. Based on this In a V2X network, different solutions can be provided to track Spoofer 15f.

One possibility envisages that, in the event of a sudden change in the properties of the position signals and / or the intrinsic position, the direction of the change is examined in order to be able to determine whether an entry or exit into an irregular area has taken place. In a busy traffic flow, the limit of the irregular transmission range 17f can be quickly detected in this way. It makes sense to forward this information to an external evaluation system, which consolidates and evaluates the information. This could by contextual filtering of the information, for example. Direction of travel, speed of vehicles, etc. reduce the circle of suspicious vehicles so far, so ideally a vehicle is identified as Spoofer 15f. This could then be further tracked through the V2X by appropriately authorized sites. It should be noted that the architecture of the detection system 2 described here is only an example and the described functions and methods based on other architectures are feasible. The invention is therefore not limited to the example described here.

Claims

claims

A method for plausibilizing position signals (112, 14f) of a global navigation satellite system (100) in a vehicle (1), comprising at least one detection system (2) for detecting objects (64, 66, 70, 72, 67) in the vicinity of Vehicle (1) and a receiving device (10) for receiving the position signals (112, 14f), comprising the steps:

 Receiving the position signals (112, 14f) by means of

Receiving device (10) and determining the intrinsic position of the vehicle (1) on the basis of the position signals (112, 14f),

Detecting at least one object (64, 66, 70, 72, 67) in the environment by means of the detection system (2) and He ^¬ forward to the position of the object (64, 66, 70, 72, 67), plausibility check of the position signals (112, 14f by matching at least one position of an object (64, 66, 70, 72, 67) with the intrinsic position of the vehicle (1).

The method of claim 1, wherein the detection system comprises a camera device and is adapted for visual recognition of objects (66). 3. The method according to the preceding claim, wherein the respective position of objects (64, 66, 70, 72, 67) is retrievable from a local map or from an external server.

4. The method according to any one of the preceding claims, wherein the detection system (2) a vehicle-to-X (V2X) communication ^¬ tion device (16, 10) for receiving obj ekten (67) in the form of V2X messages with a position indication of a transmitter the V2X message includes. Method according to the preceding claim, wherein verifiable and / or signed V2X messages are used for plausibility.

Method according to one of the preceding claims, wherein the detection system (2) comprises a motion sensor (18), in particular for detecting accelerations.

Method according to one of the preceding claims, wherein the detection system detects one of the objects from the following group:

 Infrastructure facilities, such as traffic signs, traffic lights (66), toll stations, tunnels, signposts, city signs,

- Point-of-Interest POI, such as public facilities, shops, car parks, and / or

 - Road bumps (64, 70, 72).

A method for checking the plausibility of position signals of a global navigation satellite system to determine the self-position of a signal receiver, in particular driving ^¬ apparatus (1), the receiving means (16, 10) for receiving a plurality of position signals (112, 14f) has, comprising the steps of:

 Receiving the position signals (112, 14f) by means of

Receiving device (16, 10),

 Analyzing the relative movements between the signal receiver and a plurality of signal transmitters of the position signals (112, 14f) and / or analyzing the relative movements between a plurality of signal transmitters,

Plausibilisieren the position signals (112, 14f), if there is no correlation between the relative movements. Method according to the preceding claim, wherein the relative movement between the signal receiver and each signal transmitter by means of a Doppler-effect and / or Pha ^¬ senmessung and / or a measurement of a delta-rate of each received position signals (112, 14f) Runaway ^¬ leads is.

Method according to one of claims 8 to 9, wherein a determination of the signal strength for each position signal (112, 14f) is performed by the signal receiver.

Method according to the preceding claim, wherein the respective direction is determined on the basis of the signal strengths from which the respective position signal (112, 14f) is received, the position signal (112, 14f) being made plausible if no other position signal (112, 14f) is output which is received in substantially the same directions.

Method according to one of claims 8 to 11, wherein the receiver has an antenna device (16) with at least one directional antenna and / or a plurality of antennas.

Method for plausibilizing position signals (112, 14f) of a global navigation satellite system in a signal receiver, in particular vehicle (1), comprising receiving means (16, 10) for receiving the position signals (112, 14f), comprising the steps:

 Receiving the position signals (112, 14f) for determining the self-position of the signal receiver,

 Comparing the position signals (112, 14f) with previous ones

Position signals of the signal receiver,

Plausibilisieren the position signals (112, 14f), if no sudden change of properties of the received position signals to properties previous position signals is present.

14. The method of claim 13, wherein the characteristics of the position signals comprise information about the time or clock used by the transmitter.

15. The method according to any one of claims 13 to 14, wherein the position signals (112, 14f) are plausibility, if there is no sudden change in the position determined by means of the position signals (112, 14f) own position to the previous eigenpositions.

16. The method according to any one of claims 13 to 15, wherein the method by means of an infrastructure device, in particular traffic lights (66) is performed.

17. The method according to any one of claims 12 to 15, wherein the method in a vehicle (1) is performed, and wherein the position signals additionally by means of a method according to one of claims 1 to 7 and / or a method according to one of claims 8 to 12 be made plausible.

18. The method according to any one of claims 13 to 17, wherein in a sudden change in the properties of the position signals and / or the intrinsic position depending on the direction of change, an entry or exit from a range is determined with a signal transmitter, the non-plausible position signals.

19. The method according to any one of claims 13 to 18, wherein a signal transmitter (15f), the non plausible position signals sends, is determined by means of a handshake verification method. 2 B

Method according to one of claims 13 to 19, wherein a signal transmitter (15f), which sends implausible position data, is determined by means of tracking or an exclusion method.

The method of claim 20, wherein the method is performed by an external evaluation system, which receives Be ^¬ wegungsinformationen of vehicles which have a V2X communication device.