WO2019011570A1 - Method for determining a direction of travel and/or position, track-side device, and device for a vehicle - Google Patents

Abstract

The invention relates to a method for determining a direction of travel and/or position of a vehicle travelling on a route, in particular a rail vehicle, in which at least one information signal is emitted in the form of electromagnetic waves by a track-side device, in particular a balise, and is received by a device in the vehicle. In order to determine the direction of travel and/or position of the vehicle in a simple and nevertheless safe manner, the invention provides for the electromagnetic waves to be emitted in a first transmission direction with a first property and in a second transmission direction with a second property which can be distinguished from the first property, and for both the electromagnetic waves with the first property and the electromagnetic waves with the second property to be received and for the direction of travel and/or position to be determined therefrom, wherein the first transmission direction runs at least partially in a first direction of travel and the second transmission direction runs at least partially in a second direction of travel.

Description

description

Method for determining a direction of travel and / or position, trackside device and device for a vehicle

The invention relates to a method for determining a driving direction of a vehicle traveling on a traveling distance vehicle, in particular a rail vehicle, emitted at the track side by a device, in particular a beacon, at least one information signal in the form of electromagnetic ^¬ rule waves and received by an on-vehicle device becomes. Method of the type mentioned are used, for example, the direction of travel of a railway vehicle during limited ^¬ men which with an automatic train control (ATC - Automatic Train Control) or a European train control system (ETCS - European Train Control System) is equipped. Sol che modern train control systems serve a higher auto ^¬ mation and, thereby, the higher passenger capacity and route efficiency. To guarantee the safety of the train systems despite increased capacity Subsys ^¬ systems such as Automatic Train Protection (ATP) and Automatic Train Operation (ATO) are used. For example, an ATP system calculates minimum train distances between consecutive trains to guarantee safe operation. Of course, the calculated safe distance between two trains can only be guaranteed if the position of each train is known. Among other systems, example ^¬ the Eurobaiisen transmission as system in Europe is used by the trains can calculate their current position. The

Eurobalise Transmission System follows the ETCS standard and consists essentially of track-side facilities arranged along the route, the so-called

Balises, especially Eurobaiisen. The train side, a corresponding vehicle-mounted device is present, the first continuously delivers an energy-supplying magnetic field at 27 MHz, the so-called telepowering field. When a train passes or approaches a balise, the emitted magnetic field in the balise induces a voltage that activates the balise. As a result of the activation of the beacon starting a transmit In ^¬ information signal in form of electromagnetic waves, which is usually transmitted with a carrier frequency of 4 MHz. This information signal is received by the on-vehicle device as it passes the balise. By means of the information signal is a data message transmitted ^¬ program that includes, for example, an identification code of ^¬ Balise. Based on the identification code of the balise, the vehicle-mounted device can

Determine location from a database. Further, the timing at which the information signal was received from the balise is determined. Thus, the vehicle-side Einrich ^¬ tion determine the exact position of the train when passing the balise. Alternatively, the data telegram can also directly contain the position of the balise, so that no check in the database is necessary.

In addition to the position of the vehicle, the train control continues to require the direction of travel in which the train moves when passing over the balise. This may be, for example, west or east along a given route. A train with an automatic train control system (ATC) can only go into an automatic mode, if both the position and the direction of travel are determined. When one of these information is missing, the train must be manually, that is by a train operator, are controlled and are subject to ^¬ play certain conditions, such as a ge ^¬ rings speed. This leads to delays that are undesirable.

The direction of travel is often determined by the fact that a second balise overruns and their information signal ausge- is evaluated. From the two Baiisenpositionen and the times at which they were read, the direction of travel can be clearly determined. However, the beacons are arranged üb ^¬ SHORT- with a certain distance from each other, so that the train must move between them initially in manual mode. This is especially problematic if a train has lost its position for some reason and needs to re-qualify. An alternative system which determines the direction of travel without zuhilfe ^¬ acquisition of the beacons, is described for example in EP 066 72 75 AI. The method described uses a navigation system, such as GPS or a compass, to determine the direction of travel. However, this method is not applicable in the tunnel, for example, which is problematic. Another method for determining the direction of travel is described, for example, from EP 298 699 ^A1 , in which RFID transmitters are used. However, this process is quite complicated to implement.

The invention has for its object to provide a method of the type mentioned, with which the direction of travel and the position of a vehicle can be determined as quickly and easily as possible.

This object is achieved by the method mentioned above according to the invention in that the electromagnetic waves are emitted in a first transmission direction with a first property and in a second transmission direction with a distinguishable from the first property second property and both the electromagnetic waves with the first property as Also, the electromagnetic waves are received with the second property and from the direction of travel and / or position is determined, wherein the first transmission direction at least partially in a first

Direction of travel and the second transmission direction at least teilwei ^¬ se in a second direction of travel. The solution according to the invention has the advantage that the vehicle-side device immediately when driving over a single trackside device, such as a

Balise, or already before can determine the direction of travel.

In a vehicle running on a route the vehicle ^¬ ses travels in either a first direction or in a second direction which is opposite to the first direction of travel substantially. In the solution according to the invention, the electromagnetic waves of the information signal are emitted in a first transmission device with different properties than in a second transmission direction. In this case, the first transmission direction runs at least partially in the first direction of travel and the second transmission direction at least partially in the second direction of travel. Thus, there is a difference, detectable for the on-vehicle device, between the passing or approaching of the trackside device in the first direction of travel from passing or approaching the trackside device in the second direction of travel, there is some sort of encoding. Since both the electromagnetic waves having the first characteristic and the electromagnetic waves having the second characteristic are received by the vehicle-mounted device when passing or approaching the trackside device, this difference can be detected and the direction of travel can be determined therefrom.

Distinguishable properties of the electromagnetic waves of the information signal can be, for example, a carrier frequency, a modulation (eg CDMA modulaton) or a polarization. In any case, the electromagnetic waves emitted in the first transmission direction thereby differ from the electromagnetic waves radiated in the second transmission direction. It is known on the part of the vehicle soapy device with which property the electromagnetic waves are emitted in which transmission direction, eg. B. from a database or the route Atlas. Thus, when passing the trackside facility the Direction of travel can be determined from an analysis of the received electromagnetic waves.

Since the position of the antenna relative to the vehicle-side device can also be deduced from the waves received, the position of the vehicle can also be determined by means of the invention.

The solution according to the invention can be further developed by advantageous embodiments, which are described below.

Thus, different polarizations can be used as first and second characteristics of electromag ^¬ netic waves, so that the electromagnetic waves are emitted in the first transmission direction having a first polarization and in the second transmission direction with a distinguishable from the first polarization second polarization. This has the advantage that the different polarizations in the different transmission directions can be generated technically in a very simple manner, and thus this refinement can be implemented in a particularly simple and cost-effective manner. Ideally ^¬ the polarizations are aligned orthogonal to each other, z. Horizontal and vertical or RHCP (right hand circular polarization) and LHCP (left hand circular

polarization).

In order to determine the direction of travel and / or position with an even greater safety, the curves are in particular the amplitude curves determined for the received electro ^¬ magnetic waves having the first property and the received electromagnetic waves having the second property can and therefrom the direction of travel or Po ^¬ position to be determined. Based on the courses over time or over the route, maximum values for the received electromagnetic waves with the first or second property can be determined, from which the direction of travel is even more clearly readable. Furthermore, when passing the trackside device from the courses the relative position are determined very accurately and reliably.

In a further advantageous embodiment, the electromagnetic waves with the first property can be received optimally at least temporarily and the electromagnetic waves with the second property can be partially filtered out. This results in strongly different maximum values in the course of the electromagnetic waves with the first property in comparison to the course of the electromagnetic waves with the second property. As a result, the difference between passing or approaching in the first direction of travel from passing or approaching in the second direction of travel becomes even clearer. Of course, the association of the first and second properties with respect to optimized receive and filter out is interchangeable.

The invention further relates to a trackside ^¬ A direction, in particular Balise, for delivering at least one information signal in form of electromagnetic waves to a means which passierendes vehicle, in particular

Rail vehicle, wherein the device has at least one An ^¬ antenna, which is designed to emit the information signal in the form of electromagnetic waves. For the solu- tion of the above-mentioned task is inventively see ^¬ that the antenna impedance is designed to transmit the electromagnetic ^¬ tables waves in a first transmission direction to a first property, and in a second transmission direction with a distinguishable from the first properties second property.

The track-side device can advantageously be ^further developed in that the antenna is designed to emit the electromagnetic waves with at least two different polarizations as first and second properties, so that the electromagnetic waves in the first transmission direction with a first polarization and in the second transmission direction with one of the first polarization be emitted distinguishable second polarization. As already mentioned above, the polarization is an easily changeable property, which is therefore simple and inexpensive.

In order to easily provide these different polarizations of the electromagnetic waves, the device may comprise at least one dual polarized antenna or two single polarized antennas. Both dual polarized antennas and simply polarized antennas are well known and therefore available at low cost. A dual polarized antenna may e.g. B. generate two different polarizations via two outputs. Furthermore, the invention relates to a device for a

Vehicle for determining a direction of travel and / or position, the device having at least one antenna which is designed to receive at least one information signal in the form of electromagnetic waves from a trackside device, in particular a trackside device according to one of the aforementioned embodiments. To achieve the above object, it is OF INVENTION ^¬ dung provides that the antenna is designed for receiving the electromagnetic waves, said electromagnetic waves in a first transmission direction of a first property and a second transmission direction a distinguishable from the first property have second characteristic, and the device comprises at least one evaluation device which determines the direction of travel and / or position of the received electromagnetic waves, wherein the first transmission direction at least partially in the first direction of travel and the second transmission direction at least teilwei ^¬ se in the second direction of travel. In an advantageous embodiment of this device for a vehicle, these may be configured to receive the electromag netic ^¬ waves with different polarizations as first and second characteristics so that the Electromagnetic waves in the first transmission direction have a first polarization and in the second transmission direction distinguishable from the first polarization second polarization. This has the advantage already described above in the present process, various types of Polari ^¬ organizations of the electromagnetic waves can be generated easily.

In a further advantageous embodiment, the device can have at least one dual-polarized antenna or two single-polarized antennas. As mentioned above, this is advantageous because both dual-polarized antennas at ^¬ and simple polarized antennas are available at low cost. A single dual-polarized antenna can two outputs two different polarizations he witnesses ^¬ which respectively radiate in two directions.

Furthermore, the invention relates to a vehicle, in particular rail vehicle, with a device for determining a direction of travel and / or position, which is formed according to the invention according to one of the aforementioned embodiments of the device for a vehicle.

Finally, the invention also relates to an arrangement for determining a direction of travel and / or position of a moving on a route vehicle, in particular a rail vehicle, with at least one track side ^¬ direction, in particular a balise, for transmitting at least one information signal in the form of electromagnetic. Taken waves is formed, and with at least one vehicle-side device, which is adapted to receive the electromagnetic waves from the trackside device. In order to design the direction of travel detection or position determination particularly simple and reliable, it is inventively provided that the trackside device according to one of the aforementioned embodiment and the vehicle-mounted device is also designed according to one of the aforementioned embodiment. The invention will be explained in more detail below with reference to the embodiments shown in the accompanying drawings. By way of example:

Figure 1 is a schematic representation of an exemplary

 Embodiment of an inventive arrangement for determining a direction of travel and / or position on;

Figure 2 is a schematic representation of an inventive ^¬ SEN trackside equipment of the arrangement of Figure 1;

Figure 3 is a schematic representation of an inventive ^¬ SEN vehicle when approaching the trackside device according to Figure 2; Figure 4 is a schematic representation of a course of received electromagnetic waves by the vehicle-mounted device according to Figure 3;

FIG. 5 a schematic representation of a further course of received electromagnetic waves from the vehicle-side device according to FIG. 3;

FIG. 6 shows a schematic representation of a combined course, calculated from the courses of FIGS. 4 and 5.

First, the exemplary embodiment of an OF INVENTION ^¬ to the invention an arrangement is described in FIG. 1 FIG. 1 schematically shows an exemplary arrangement 1 according to the invention with which a direction of travel F, F ^{x of} a vehicle 2 can be determined. The arrangement 1 has a vehicle-side device 3 and a trackside device 4, 4 ^λ . The vehicle-side device 3 is arranged in or on the vehicle 2 and the track-side device 4, 4 ^λ is arranged in the region of a route 5, on which the vehicle 2 in the first direction F or the opposite second direction F ^x emotional. In the exemplary embodiment of the figures, the vehicle 2 is designed as a rail vehicle, the trackside device 4, 4 ^{λ is designed} as a balise, for example a Eurobalise, and the vehicle-side device 3 is designed as a balloon reading device. A plurality of track-side devices 4, 4 ^λ are arranged in a conventional manner along the route 5 and, for example, as shown in Figure 2, between see rails 6 of the route positioned.

The vehicle-mounted device 3 includes an antenna 7, ei ^¬ ne evaluation device 8, and a communication device. 9

The trackside device 4, 4 ^λ may be formed either as a fixed trackside device 4, such as a fixed data beacon, or alternatively as a switchable trackside device 4, such as a transparent data beacon. The switchable track side

In contrast to the fixed trackside device 4 ^λ , the device 4 has a connection to a trackside signal device 10, via which information can be transmitted, for example, to or from a signal box (not shown). For the invention, it is irrelevant whether the trackside device 4, 4 ^{λ is formed} fixed or switchable.

During operation of the arrangement 1 according to the invention, the track-side device 4, 4 is activated by the vehicle-mounted device 3 as is usual in the prior art. For this purpose, the antenna arrangement 7 of the vehicle-side device 3 continuously transmits a magnetic field 11, for example with a frequency of 27 MHz, which can also be called a tele-powering field. When the vehicle 2 passes the trackside device 4, 4 ^λ , it is energized by the magnetic field 11 and activated. Thereafter, the trackside device 4, 4 ^λ starts emitting an information signal 12. The information signal 12 contains a data telegram in which, as known from the prior art, an identification code or position data of the trackside device 4, 4 ^{λ are} included. With this information provided by the information signal 12 data, the vehicle device 3 can determine the position of stre ^¬ ckenseitigen device 4, 4 ^λ and thus also the position of the vehicle 2 at the time when the vehicle device 3 trackside device 4, 4 ^λ happens.

The properties and functions of the arrangement 1 according to the invention described so far essentially correspond to the prior art, as used, for example, in ETCS systems.

In the following, the further properties and functions according to the invention will now be described, in particular first with reference to FIGS. 2 and 3.

Figure 2 shows schematically one of the streckenseiti ^¬ gen devices 4 after activation. The trackside device 4 transmits the information signal 12 in the form of electromagnetic waves 13, 13 ^λ . The electromagnetic waves 13, 13 ^λ form an electromagnetic field, which is shown in FIGS. 2 and 3 as essentially conical.

To emit the electromagnetic waves 13, the trackside device 4, 4 ^λ an antenna 14. The

Antenna 14 in the exemplary embodiment of Figures 2 and 3 is a dual polarized antenna. Alternatively, two simple polarized antennas could be used become. As shown in FIG. 2, the antenna 14 transmits electromagnetic waves 13 in a first transmission direction + Y. In a second transmission direction -Y, electromagnetic waves 13 ^λ are likewise radiated from the antenna 14. The electromagnetic waves 13 in the first transmission direction + Y differ in at least one property from the electromagnetic waves 13 ^λ in the second transmission direction - Y. In the exemplary embodiment in the figures, this characteristic is the polarization. Namely, the electromagnetic waves 13 have a first polarization and the electromagnetic waves 13 ^{λ have} a second polarization different from the first one. The information signal 12 is thus transmitted according to the invention by means of the electromagnetic waves 13, 13 ^λ , which in each case transmit the data necessary for the location, but differ in their polarization. The first transmission direction + Y runs essentially in the first direction of travel F and the second transmission direction -Y essentially in the second direction of travel F ^x . The first transmission direction + Y is exactly opposite to the second transmission direction -Y.

Figure 3 shows in a very simplified manner, the vehicle 2 with the vehicle-mounted device 3, which moves in the first direction of travel F on the route 5 and the track-side device 4 approaches and then passes. In Figure 3 the trackside device is activated already be ^¬ 4 and sends out as described with reference to Figure 2 be ^¬ written, the information signal 12 in the form of electromag netic ^¬ shafts 13, 13 ^λ. The track-side device 4 in FIG. 3 is identical to that in FIG. 2.

The vehicle device 3 has two antennas 3 7, 7 ^λ in beispielhaf ^¬ th embodiment in FIG. Each antenna 7, 7 ^λ is designed as a dual polarized antenna. Alternatively, two simple polarized antennas would be possible, emitting in two directions. It would also be possible to use a single dual polarized antenna. The first antenna 7 ^λ is in the exemplary embodiment 3 forms for receiving the electromagnetic waves 13 with the first polarization, both in the first direction of travel F and in the second direction of travel F ^x . The second antenna 7 ^λ, however, is designed to receive electromagnetic waves 13 ^λ with the second polarization, and indeed in both directions. The reception ranges of the antennas 7, 7 ^λ are each shown in FIG. 3 as conical fields. ^¬ sliding surface colors denote identical polarizations, even in comparison to the trackside equipment. 4

The diagram in Figure 4 shows an amplitude response of the received signal of the first antenna 7 ^λ when approaching or passing the trackside equipment 4. In this case, 15 is the right Count the amplitude of the co-polar electromagnetic ^¬ rule shafts 13 and the left Graf 16, the amplitude the cross-polar electromagnetic waves 13 ^λ . Due to the same polarization, the antenna 7 ^{λ is} configured as optioned for the reception of the co-polar electromagnetic waves 13. The cross-polar shafts 13 ^λ are largely herausgefil ^¬ tert because the antenna is ^λ 7 not optimized for their reception. The polarization losses are thus high.

Figure 5 shows the amplitude response for the received signal of the second antenna 7 when approaching or passing the trackside device 4 in the direction of travel F. Here now 17 shows the left Count the amplitude of the co-polar electrostatic ^¬ magnetic waves 13 ^λ and the right Graf 18, the amplitude ^{¬ the} course of the cross-polar electromagnetic waves 13. This time, the antenna array 7 is optimized for the co-polar waves 13 ^λ . The cross-polar waves 13 are largely filtered out and give only a weaker signal.

In FIGS. 4-6, the abscissa represents the path in the direction Y (FIG. 2) and the ordinate the amplitude calculated from the received waves. FIG. 6 shows the combined accumulated amplitude profiles from FIGS. 4 and 5. The right-hand graph 19 shows the amplitude curve for the electromagnetic waves received by the antenna ^arrangement 7 ^λ and the graph 20 shows the amplitude profile of the electromagnetic waves received by the antenna arrangement 7. The maximum values of the courses are calculated and their positions a, b and their order in which they occurred are stored. In addition, a crossing point of the graphs 19, 20 and its position C is calculated and stored.

The invention determines from at least one of the curves shown in Figu ^¬ ren 4 to 6 the direction of travel F, F ^x and / or of 0.

The antenna arrangement 7 ^λ registers first a low amplitude and later a high and the antenna arrangement 7 first a high amplitude and later a low one. Further, it is known that the trackside device 4 emits electromagnetic waves 13 having the first polarity in the first transmission direction + Y and electromagnetic waves 13 ^λ having the second polarization in the second transmission direction -Y. This information can be recorded in a database. Consequently, the evaluation device 8 can determine that the vehicle 2 is moving in the first direction of travel F.

Furthermore, the relative position of the vehicle or the vehicle-mounted device 3 to the trackside device 4 ,, 4 ^λ from the counts 19, 20 determined. In Figures 4-6, the exact position of the trackside device 4, 4 ^λ at Y = 0. This can, for. Of the crossing point in Figure 6 or from among interim ^¬'s positions a and b (~~) are as determined from the posi tion c ^¬ · To increase the Genauig ^¬ ness all three points may be used.

A condition for the correct function when receiving the information signal 2 is a positioning of the antennas 7, 7 14 of the vehicle-side or the track-side input. directions in the far field. In the far field the polarization is stable. This can be supported through the use of higher frequencies, such as described in the as yet ver ^¬-published patent application DE 10 2016 215 696. Higher frequencies can reduce the near field area and increase the far field area accordingly.

Claims

claims

1. A method for determining a direction of travel (F, F ^x ) and / or a position of a vehicle (2) driving on a route (5), in particular a rail vehicle, in which a trackside device (4, 4 ^λ ), in particular a balise, at least one information signal (12) in the form of electromagnetic waves (13, 13 ^λ ) is emitted and received by a vehicle-side device (3),

d a d u r c h e c e n c i n e s that

the electromagnetic waves (13, 13 ^λ) in a first transmission direction (+ Y) having a first property, and (Y) in a second transmission direction with a lance from the first properties distinguishable second property emitted ^¬ and the

both the electromagnetic waves (13) having the first property and the electromagnetic waves (13 ^λ ) having the second characteristic are received, and from this the

Direction of travel (F, F ^x ) and / or position is determined, wherein the first transmission direction (+ Y) at least partially in ei ^¬ ner first direction (F) and the second transmission direction (-Y) at least partially in a second direction (F ^x ).

2. The method according to claim 1,

d a d u r c h e c e n c i n e s that

are used as the first and second properties of the electromagnetic waves (13, 13 ^λ ) different polarizations, so that the electromagnetic waves in the first transmission direction (+ Y) with a first polarization and in the second transmission direction (-Y) with one of the first Polarization distinguishable second polarization are emitted.

3. The method according to claim 1 or 2,

characterized in that the curves, especially the amplitude curves are determined for the emp ^¬ captured electromagnetic waves with the first and the second property and from this the drive ^¬ direction (F, F ^x) is determined.

4. The method according to any one of the above claims, d a d u r c h e c e n e c e s in that e

at least temporarily receive the electromagnetic waves (13, 13 ^λ ) optimized with the first property and the electromagnetic waves (13, 13 ^λ ) are partially filtered out with the second property.

5. path-side device (4, 4 ^λ ), in particular Balise, for emitting at least one information signal (12) to a vehicle (2), in particular rail vehicle,

wherein the device (4, 4 ^λ ) has at least one antenna (14) which is designed to emit the information signal (12) in the form of electromagnetic waves (13, 13 ^λ ),

d a d u r c h e c e n c i n e s that

the antenna (14) is designed to emit the electromagnetic waves (13, 13 ^λ ) in a first transmission direction (+ Y) with a first property and in a second transmission direction (-Y) with a second property distinguishable from the first property.

6. Device (4, 4 ^λ ) according to claim 5,

d a d u r c h e c e n c i n e s that

the antenna (14) is formed, the electromagnetic waves (13, 13 ^λ) emit at least two different Pola ^¬ risationen as first and second characteristics so that the electromagnetic waves (13, 13 ^λ) in the first transmission direction (+ Y) with a first polarization and in the second transmission direction (-Y) are emitted with a distinguishable from the first polarization second polarization.

7. Device (4, 4 ^λ ) according to claim 6, characterized in that

the device comprises at least one dual polarized antenna or two single polarized antennas.

8. Device (3) for a vehicle (2) for determining a direction of travel (F, F ^x ) and / or position, wherein the device has at least one antenna (7, 7 ^λ ), which for Emp ^¬ catch of at least one information signal (12) in the form of electromagnetic waves (13, 13 ^λ ) of a track-soapy device (4, 4 ^λ ), in particular a track-side device (4, 4 ^λ ) according to one of claims 5 to 7, is formed,

d a d u r c h e c e n c i n e s that

the antenna (7, 7 ^λ ) for receiving the electromagnetic waves (13, 13 ^λ ) is formed, wherein the electromagnetic ^¬ rule waves (13, 13 ^λ ) in a first transmission direction (+ Y) has a first property and in a second transmission direction (-Y) have a distinguishable feature from the first second natural ^¬ shaft, and

said means at least one evaluation device (8) which determines the direction of travel (F, F ^x) and / or position from the received electromagnetic waves, wherein the first transmission direction (+ Y) at least partially in the ers ^¬ th direction of travel (F) and the second transmission direction (-Y) run at least partially in the second direction of travel (F ^x ).

9. Device (3) according to claim 8,

d a d u r c h e c e n c i n e s that

the device (3) is designed to receive the electromagnetic waves (13, 13 ^λ ) with different polarizations as first and second properties, so that the electromagnetic waves (13, 13 ^λ ) in the first transmission direction (+ Y) have a first polarization and in the second transmission direction (-Y) have a re unterscheidba ^¬ from the first polarization second polarization.

10. Device (3) according to claim 9, characterized in that

the device comprises at least one dual polarized antenna or two single polarized antennas.

11. The device (3) according to claim 8, wherein:

the evaluation device (8) for determining the gradients, in particular the amplitude of waveforms of the received electromag netic ^¬ shafts (13, ^λ 13) is formed genschaft with the first and second egg.

12. The device (3) according to claim 8, wherein:

the means (3) for optimally receiving the electromagnetic waves (13, 13 ^λ ) having the first property and for partially filtering out the electromagnetic waves (13, 13 ^λ ) is formed with the second property.

13. vehicle (2), in particular rail vehicle, with a device (3) for determining a direction of travel and / or

Position,

d a d u r c h e c e n c i n e s that

the device (3) according to one of the above claims

8, 9, or 10 is formed.

14. Arrangement (1) for determining a direction of travel (F, F ^x ) and / or position of a vehicle (2) traveling on a travel route (6), in particular of a rail vehicle,

with at least one trackside device (4, 4 ^λ ), in particular a balise, for transmitting at least one information signal (12) in the form of electromagnetic signals

Shafts (13, 13 ^λ ) is formed,

and

with at least one vehicle-side device (3), which is designed to receive the electromagnetic waves (13, 13 ^λ ) from the trackside device (4, 4 ^λ ), characterized in that

the track-side device (4, 4 ^λ ) according to one of the Proverbs 5 to 7 and the vehicle-side device (3) is designed according to one of claims 8 to 10.