EP4067202A1 - Method and assembly for locating a track-bound vehicle in a route network following start-up of the vehicle - Google Patents

Abstract

The subject matter of the invention is a method for locating a track-bound vehicle (FZ) in a route network after the vehicle (FZ) has been put into operation. At least one camera (CM1...CM4) is used for localization, which takes a picture of the vehicle (FZ) and at least one stationary optical marker (OM1, OM2) whose absolute position in the route network is known. In addition, a relative vehicle position of the vehicle (FZ) to the fixed optical marker (OM1, OM2) in the image is determined and the absolute vehicle position of the vehicle (FZ) in the route network, taking into account the absolute position of the marker and the relative position of the vehicle (FZ) definitely. The invention also includes an arrangement for locating a track-bound vehicle (FZ) in a route network after the vehicle (FZ) has been put into operation, a computer program product and a provision device for the computer program product.

Description

The invention relates to a method for locating a track-bound vehicle in a route network after the vehicle has been put into operation. The invention also relates to an arrangement for locating a track-bound vehicle in a route network after the vehicle has been put into operation. Finally, the invention relates to a computer program product and a provision device for this computer program product, the computer program product being equipped with program instructions for carrying out this method.

The invention can be used in connection with a method for locating a rail vehicle that is automatically controlled by ATS (Automatic Train Supervision), in particular operated without a driver, for example a rail vehicle controlled by a CBTC train control and train protection system, with an on-board train control device and trackside train protection devices and with a localization unit for acquiring position values while the rail vehicle is in motion.

According to a known method DE 102015207223 A1 the on-board, automatic train control device of a rail-bound vehicle, which is integrated into a monitoring system of an Automatic Train Control (ATC), always knows the exact position of the vehicle on the route. In local rail transport, for example, the vehicles are also maintained and parked in depots. For safe operation, the vehicles are equipped with an on-board train protection device that secures the vehicles in regular operation and can trigger braking if the safety limits are exceeded. Modern, radio-based systems also include a trackside device of the train protection system, which Train movements securely tracked via position reports received from the vehicles. An example is CBTC (Communication-Based Train Control).

On the one hand, the vehicles (trains) and the train protection device should be switched off during decommissioning in order to save energy. On the other hand, the vehicles should be able to resume operation as quickly as possible in the most comfortable and therefore unrestricted operating mode (e.g. CTC, Continuous Train Control, without a fixed speed limit of 25 km/h). However, if the on-board train protection device is switched off, the safely measured and stored vehicle position is lost. This reliable location must be established by a cumbersome, driver-operated slow drive using location markers (balises) and driving in mode without a fixed speed limit is only possible again after a while, typically after 250 m or 1 to 2 minutes.

For the optimal processing of traffic in an ATC system such as a CBTC train control and train protection system, there is now a need to localize the rail vehicle again as quickly as possible in the event of delocalization. One could therefore think about arranging the trackside facilities, such as the balises, at shorter intervals in the depot in order to be able to locate them again as soon as possible after they have been put into operation. When a rail vehicle leaves a depot, localization can also be achieved more quickly if several balises are arranged on the depot access route before the train enters the main line. However, this increases the effort required to provide and maintain the infrastructure and thus also the operating costs.

According to the EP 3024713 B1 There is a way to monitor a parked and switched off vehicle during the standstill phase by using a camera for this purpose. This takes pictures at least after parking and before commissioning, the comparison of which can be used to determine a possible determine impermissible movement of the vehicle during the standstill phase (break in operation). The image comparison can be carried out, for example, by railway personnel. This manual procedure must be performed prior to commissioning to ensure reliable location of the vehicle upon commissioning.

The invention is based on the object of designing a method of the type specified at the outset in such a way that it can be used to quickly localize a rail vehicle with comparatively little effort. In addition, the object of the invention is to specify an arrangement, a computer program product and a device for providing such a product, with which the method can be carried out. Finally, it is the object of the invention to specify an automatic train control system with which the above-mentioned method can be carried out.

This object is achieved according to the invention with the subject matter of the claim (method) specified at the outset in that at least one camera is used for localization, which takes a picture of the vehicle and at least one stationary optical marker whose absolute position in the route network is known, a relative one Vehicle position of the vehicle is determined for the stationary optical marker in the image and the absolute vehicle position of the vehicle in the route network is determined taking into account the absolute position of the marker and the relative position of the vehicle.

With the method according to the invention, it is advantageously possible to immediately determine a position of a rail-bound vehicle, for example a local train such as a metro train in the depot, when it is started up. In this case, cameras are used according to the invention, which image stationary optical markers in the area surrounding the vehicle and the vehicle itself. The position of the vehicle relative to the stationary optical marker can thus be determined by image processing. Since the fixed optical marker (the fixed and mobile optical markers are also called markers for short below mentioned) cannot move in contrast to the vehicle, the absolute position of the vehicle in the route network, for example in the depot, can also be determined via the relative position of the vehicle to the marker.

The localization of the vehicle according to the invention is inherently subject to measurement errors. In order to obtain precise localization during ongoing normal operation of the vehicle, in addition to locating the vehicle using the method according to the invention when the vehicle is started up, a (per se known) locating normally provided for in the operating method of the vehicle must be carried out. This can be done, for example, by driving the vehicle over a balise installed in the track (more on this below).

The method according to the invention has the advantage that the vehicle can be temporarily located before it is put into operation. Therefore, cost-intensive locating devices, which would enable an immediate precise localization of the vehicle, can be saved at the place where the method according to the invention is used (for example in a vehicle depot). On the other hand, the vehicle can be put into operation without the need for exclusively manual operation by a driver who would have to board the train for this purpose. Particularly in the case of driverless rail operations, this results in a considerable saving in personnel costs.

On the other hand, there is no need to monitor the vehicle while it is stationary (cold movement detection, or CMD for short). This would also involve an outlay on components and an additional use of energy. The method according to the invention can also be used if a CMD is provided for the vehicle. If the CMD fails, there is then an alternative way of detecting a vehicle movement, so that manual driver operation can be dispensed with even if the CMD fails, because the method provides a second independent way of localization.

As stationary within the meaning of the invention are facilities understand that have constant coordinates in a global coordinate system (connected to the earth). In contrast, mobile means that the position of the mobile object (for example a vehicle or a vehicle-bound mobile optical marker) can change.

An absolute position is a position of an object (particularly vehicle, marker) in the global coordinate system. A relative position is to be understood as a position of an object in relation to another object (for example a vehicle in relation to a stationary optical marker).

In the context of the invention, “computer-aided” or “computer-implemented” can be understood to mean an implementation of the method in which at least one computer executes at least one method step of the method.

The term "computer" covers all electronic devices with data processing properties. Computers can be, for example, personal computers, servers, handheld computers, mobile radio devices and other communication devices, processors and other electronic devices for data processing, which can preferably also be combined to form a network.

In the context of the invention, a “processor” can be understood to mean, for example, a converter, a sensor for generating measurement signals, or an electronic circuit. A processor can in particular be a main processor (Central Processing Unit, CPU), a microprocessor, a microcontroller, or a digital signal processor, possibly in combination with a memory unit for storing program instructions, etc. A processor can also be understood to mean a virtualized processor or a soft CPU.

In the context of the invention, a “memory unit” can be, for example, a computer-readable memory in the form of a working memory (random-access memory, RAM) or data storage (hard disk or data carrier).

The “interfaces” can be realized in terms of hardware, for example by cable or as a radio connection, or in terms of software, for example as an interaction between individual program modules of one or more computer programs.

"Program modules" should be understood to mean individual functional sequences that enable a program sequence of computer-aided method steps according to the invention. These functional sequences can be implemented in a single computer program or in several computer programs that communicate with one another. The interfaces implemented here can be implemented in terms of software within a single processor or in terms of hardware if multiple processors are used.

According to one embodiment of the invention, the method uses an output device to display the image and an input device to input the absolute vehicle position.

The use of an output device and an input device advantageously makes it possible for the method to be partially carried out manually using operating personnel. The output device is preferably a screen that displays the recorded image. The input device is, for example, a keyboard or a control panel provided specifically for the purpose of input.

According to one embodiment of the invention, the method uses an output device to display the image and an input device to enter the relative vehicle position, and the absolute vehicle position in the route network is determined with computer assistance, taking into account the absolute position of the stationary marker and the relative vehicle position.

In the simplest case, an employee (operating personnel) can determine the position of the vehicle relative to one of several stationary markers. These markers can, for example, be numbered consecutively in order to be able to provisionally determine the position of the vehicle in a depot.

The input device can then be used by the employee to enter a specific position of the vehicle in the route network.

The output device and the input device can also be used when the position of the vehicle is determined with a higher degree of automation. In this case, the operating personnel can take on the role of a control authority since, as already mentioned, the position determination is less precise than would be the case in normal operation of the vehicle due to the ATC system that is used. This means that the operating personnel can intervene if obvious location errors occur.

According to one embodiment of the invention, the relative vehicle position to the stationary marker in the image is determined with computer assistance and the absolute vehicle position in the route network is determined with computer assistance, taking into account the absolute position of the stationary marker and the relative vehicle position.

By using a computer to determine the relative vehicle position and the absolute vehicle position in the route network, a greater degree of automation is advantageously achieved. Methods of image processing that are known per se, such as, for example, three-dimensional processing of the displayed image, can be carried out here. Stereo cameras can also be used here.

The automated image interpretation advantageously increases the reproducibility of the position determination. The measurement errors that occur can also be narrowed down more precisely than with a human evaluation of the recorded image case is. On the other hand, malfunctions can occur that are not noticeable in an automatic position calculation. Therefore, an additional control by the operating staff is advantageous, which is however supported by the automatic position determination.

According to one embodiment of the invention, it is provided that the absolute vehicle position is used as preliminary location information for starting up the vehicle in a restricted operating mode and the preliminary location information is replaced by secure location information as soon as the vehicle has been detected by a location device equipped with a security level, and the secure location information is used after a transition from the restricted mode of operation to a normal mode of operation.

If the determined absolute vehicle position is used as preliminary location information for starting up the vehicle, it can also be started up if no vehicle position is known, which is usually used for the ATC system in operation.

Since there is greater uncertainty with regard to the location information used than in the normal operation of the vehicle, the vehicle is commissioned in a restricted operating mode, with the restrictions being provided for the prevention of malfunctions and accidents.

According to one embodiment of the invention, it is provided that in the restricted operating mode, the at least one camera is used at least once more for localization, which takes a picture of the vehicle and at least one stationary optical marker whose absolute position in the route network is known, a vehicle position of the vehicle relative to the stationary optical marker is determined in the image, the absolute vehicle position of the vehicle in the route network is determined taking into account the absolute position of the marker and the relative position of the vehicle.

A repetition of the preliminary location procedure, i. H. a method of location using the cameras, can confirm or correct the preliminary location information that is already available. In particular, if the vehicle comes close to another stationary optical marker, it may be located with a smaller measurement error than was possible before it was put into operation. In the parking position, the optical and spatial conditions may not be optimal, so that the measurement uncertainties that have to be expected with a repeated position determination can be advantageously reduced. The localization step can be designed in the manner already described above (ie as in the first measurement).

According to one embodiment of the invention, it is provided that in the restricted operating mode the nearest accessible locating device is approached.

The closer to the locator used to confirm the vehicle's position, the less time the vehicle must operate in the degraded mode. This means that the uncertainties associated with the restricted operating mode are eliminated as quickly as possible.

After the provisional location information has been determined, the vehicle's ATC system can determine, for example, how it can reach the nearest locating device as quickly as possible. Of course, only locating devices that the vehicle can reach at all are taken into account. For example, the locating device that is actually the shortest distance from the vehicle but cannot be reached by the vehicle can be located on the adjacent track because the adjacent track is being traveled on in the opposite direction, for example.

According to one embodiment of the invention, it is provided that the restricted operating mode is limited to a maximum speed that may be driven in the restricted operating mode, and/or is limited to a maximum distance that may be covered in the restricted operating mode.

The permitted maximum speed, for example 25 km/h, which in the restricted operating mode is of course lower than that in the normal operating mode, and also the permitted maximum route, which is preferably in an area of the route network that is separated from regular traffic, offer restrictions for the operating mode that improve operational safety Use of still inaccurate provisional location information can advantageously increase. It is also easier for the train staff to intervene manually in this way.

According to one embodiment of the invention, it is provided that the at least one camera is also used to record an image of a mobile optical marker of the vehicle that is attached to the vehicle and whose position on the vehicle is known.

The use of a mobile optical marker on the vehicle advantageously makes it possible to be able to better determine its position relative to a stationary optical marker. The mobile optical marker is much smaller compared to the entire vehicle and its position relative to the stationary optical marker can therefore be determined more easily. As a result, the determination of the absolute position becomes more precise and the implementation of the method is therefore more reliable.

According to one embodiment of the invention, it is provided that the stationary and/or mobile optical markers have a code made up of alphanumeric characters and/or a machine-readable code.

The term "alphanumeric character" includes (at least) the letters of a given alphabet, as well as the ten digits from 0 to 9. In a broader sense, special characters (e.g. punctuation marks: period, comma, letters with diacritics, brackets, etc.) ) counted among the alphanumeric characters.

Alphanumeric characters advantageously facilitate a manual

Determination or a manual control of computer-aided determinations of the absolute and relative positions of the vehicle. Alphanumeric support can be given, for example, by numbering stationary optical markers in a depot or the like (and marking the markers with the numbers). Likewise, different vehicles can be provided with consecutive numbers on mobile optical markers. In the case of a manual evaluation, this makes it easier for the operating personnel to find their way around.

A machine-readable coding advantageously facilitates the computer-aided evaluation of the recorded images. The coding can contain train numbers and location information of the stationary or mobile marker in question.

According to one embodiment of the invention, it is provided that the stationary and/or mobile optical markers have a position mark.

Position markers enable a more precise determination of the location of the relevant fixed or mobile optical marker. This allows more accurate calculation or determination results to be obtained. Position markers can consist of crosses or circles, for example, and are smaller compared to the extent of the optical marker and can therefore be localized more precisely. These can also be contrasted in color so that they can be better recognized in poor lighting conditions.

As an alternative, the stated object is also achieved according to the invention with the subject matter of the claim (arrangement) specified at the outset in that the arrangement has: at least one stationary optical marker of the arrangement whose absolute position in the route network is known, at least one camera that is set up by the vehicle and take an image of the stationary optical marker, a computer that is set up to control an output device for displaying the image and an input device for inputting the absolute vehicle position, and/or that is set up to calculate a relative vehicle position of the vehicle with the computer aided to the stationary optical marker To determine markers in the image and to determine the absolute vehicle position of the vehicle in the route network, taking into account the absolute position of the stationary optical marker and the relative position of the vehicle.

The advantages that have already been explained in connection with the method described in more detail above can be achieved with the arrangement. What has been said about the method according to the invention also applies correspondingly to the arrangement according to the invention.

Furthermore, a computer program product with program instructions for carrying out the method according to the invention and/or its exemplary embodiments is claimed, with the method according to the invention and/or its exemplary embodiments being able to be carried out in each case by means of the computer program product.

In addition, a provision device for storing and/or providing the computer program product is claimed. The provision device is, for example, a storage unit that stores and/or provides the computer program product. Alternatively and/or additionally, the provision device is, for example, a network service, a computer system, a server system, in particular a distributed, for example cloud-based computer system and/or virtual computer system, which stores and/or provides the computer program product preferably in the form of a data stream.

The provision takes place in the form of a program data block as a file, in particular as a download file, or as a data stream, in particular as a download data stream, of the computer program product. However, this provision can also be made, for example, as a partial download consisting of several parts. Such a computer program product is read into a system, for example using the provision device, so that the method according to the invention is executed on a computer.

Further details of the invention are described below with reference to the drawing. Identical or corresponding drawing elements are each provided with the same reference symbols and are only explained several times insofar as there are differences between the individual figures.

The exemplary embodiments explained below are preferred embodiments of the invention. In the exemplary embodiments, the described components of the embodiments each represent individual features of the invention to be considered independently of one another, which also develop the invention independently of one another and are therefore also to be regarded as part of the invention individually or in a combination other than the one shown. Furthermore, the components described can also be combined with the features of the invention described above.

• Figur 1 ein Ausführungsbeispiel der erfindungsgemäßen Anordnung mit ihren Wirkzusammenhängen schematisch,
• Figur 2 ein Ausführungsbeispiel einer Computer-Infrastruktur der Anordnung gemäß Figur 1 mit einem Computer als Blockschaltbild aus Funktionseinheiten, wobei Programmmodule abgearbeitet werden, die jeweils in einem oder mehreren Prozessoren ablaufen können und wobei die Schnittstellen demgemäß softwaretechnisch oder hardwaretechnisch ausgeführt sein können,
• Figur 3 ein Ausführungsbeispiel des erfindungsgemäßen Verfahrens als Flussdiagramm, wobei die einzelnen Verfahrensschritte einzeln oder in Gruppen durch Programmmodule verwirklicht sein können und wobei die Funktionseinheiten und Schnittstellen gemäß Figur 2 beispielhaft angedeutet sind.

Show it:

• figure 1 an exemplary embodiment of the arrangement according to the invention with its functional relationships schematically,
• figure 2 an embodiment of a computer infrastructure according to the arrangement figure 1 with a computer as a block diagram of functional units, with program modules being processed, which can each run in one or more processors and with the interfaces being able to be implemented accordingly in terms of software or hardware,
• figure 3 an embodiment of the method according to the invention as a flow chart, wherein the individual method steps can be implemented individually or in groups by program modules and wherein the functional units and interfaces according to figure 2 are indicated as examples.

In figure 1 a vehicle FZ is shown in a depot DP. The vehicle FZ is on a track GL, in which a balise BL is installed outside the depot DP.

Next is in figure 1 to recognize a control center LZ, in which a computer CP is located. The control center LZ is radio-supported in a manner not shown in detail via a first interface S1 with a first camera CM1 in the depot DP, via a second interface S2 with a third camera CM3 and a fourth camera CM4 of the vehicle FZ and via a third interface S3 with a second camera CM2 connected outside the depot DP.

The angles of view BW of the first camera CM1, the second camera CM2 and the third camera CM3 are in figure 1 implied. Within the angle of view are a first stationary optical marker OM1 and a second stationary optical marker OM2, which are set up on track GL and whose respective absolute position in the route network (represented by track GL) is known. In addition, the vehicle FZ has a mobile optical marker OMM, which thus moves together with the vehicle.

The structure of the markings will be explained in more detail on the basis of the second stationary optical marker OM2, with the individual elements also being found in the other two optical markers. The second stationary optical marker OM2 has a position mark PSM in the form of a plus sign, which enables better localization of the second stationary optical marker OM2 on an image recorded by the second camera CM2. This marker is identified by a machine-readable code MLC (in figure 1 displayed as a barcode, but also executable as a QR code). This information can be evaluated on the image recorded by the second camera CM2. For better recognition of the second stationary optical marker OM2, an alphanumeric two is also provided as an alphanumeric character ANZ on the marker, which can be seen on the image recorded by the second camera CM2, for example by operating personnel.

The first stationary optical marker OM1 has the same structure. Of course, the barcode used there contains others Information, also an alphanumeric one is used. In figure 1 the first stationary optical marker OM1 can be recorded both by the camera CM3 located on the vehicle FZ and by the first camera CM1 permanently installed in the depot DP (cf. the indicated image angle BW).

The mobile optical marker OMM on the vehicle FZ has a Zett as an alphanumeric character so that the operating personnel can see it as a train-related mobile optical marker. A barcode is also used here, which contains corresponding information about the vehicle FZ. An Ix is used as a position mark

In the control center LZ, an employee BP of the operating staff can evaluate the images recorded by the cameras CM1, CM2, CM3 with the support of the computer CP in order to determine the position of the vehicle FZ in the depot DP before it is put into operation. The vehicle FZ can then be put into operation with the aid of this location information in order to drive in a restricted operating mode to the beacon BL and there to generate precise location information by crossing the beacon. Driving in the restricted operating mode and thus also the transition to the normal operating mode after crossing the balise can take place without a driver. The vehicle FZ is also preferably driving without a driver in the normal operating mode.

In figure 2 is the functional relationship of the individual components of the operating procedure figure 1 shown in more detail. In particular, it is shown how the computer CP supports the method. In accordance with figure 2 considered that the computer CP, as in figure 1 shown, may be present in the control center LZ. However, an alternative is the implementation of the method by the computer CP in the vehicle FZ figure 2 dash-dotted lines indicate both the system boundaries when using the computer CP in the control center LZ and when using the computer CP in the vehicle FZ. It should also be noted that the computing power of the computer CP is limited to several Processors can be distributed, which are distributed both in the control center LZ and in the vehicle FZ. Here too, in connection with this invention, a computer CP should be spoken of (in this case the dot-dash system boundaries LZ, FZ would not exist).

The computer CP is connected to a storage device SE via a fourth interface S4. The memory device SE can contain the software required for carrying out the method, which is activated to carry out the method after the computer CP in the vehicle FZ, for example, has been started up. The memory device SE can also be used to store localization information that is calculated by the method.

The computer CP is connected to the fourth camera CM4 via a fifth interface S5 and to the third camera CM3 via a sixth interface S6. This applies to accommodation of the computer CP in the vehicle. The reference symbols given in brackets apply to accommodation of the computer CP in the control center LZ figure 2 , i.e. that as in figure 1 shown, the first camera CM1 is connected to the computer CP via the first interface S1 and the second camera CM2 is connected to the computer CP via the third interface S3.

The computer CP is connected to an antenna arrangement AA via a seventh interface S7, which enables communication via radio interfaces, for example between the control center LZ and the vehicle FZ, but also, for example, between the vehicle FZ and the balise BL (the antenna arrangement can be different for this purpose have antennas).

The computer CP is connected to an input unit EE via the eighth interface S8 and to an output unit AE via a ninth interface S9. The input unit EE enables the operating personnel to make entries in the manner already described, while the output device AE enables the images recorded by one of the cameras CM1 . . . CM4 to be displayed in particular.

The procedure is carried out by figure 3 implied. The system limits of the computer CP, in which process steps are carried out automatically, and of the control center LZ or of the vehicle FZ, in which manual process steps can be carried out by operating personnel, is in figure 3 indicated by dotted lines. The in the figures 1 and 2 designated interfaces.

After the start of the method, an activation step AKTV of the vehicle takes place. In a subsequent image recording step PICT, an image recording is generated by one of the cameras used. This can alternatively be output to the operating personnel via the ninth interface S9 using the output device AE in an output step OUT. This can estimate the relative position ESTM RPOS in a manual step and then enter the determined relative position into the computer CP through an input step IN using the eighth interface S8. Alternatively, in a calculation step for the relative position CALC RPOS, the position of the vehicle relative to the marker imaged with the vehicle can be calculated.

Again alternatively, the absolute position ESTM APOS of the vehicle can be estimated manually by the operating personnel and in a subsequent input step IN the absolute position APOS can be entered into the computer CP using the input device EE via the eighth interface S8. Alternatively, the absolute position APOS can also be calculated by the computer CP in a calculation step CALC APOS.

In any case, the absolute position APOS that is now available can be used to set the location information SET LOC in a next step. This is then available in the computer CP to start operation in the restricted operating mode MOD LIM of the vehicle. In this case, it is possible for the operating personnel to monitor operation in the restricted operating mode in a control step CRTL (for example by evaluating other images which are recorded with the relevant cameras). With this it is possible that the operating personnel intervene if operational disruptions or accidents are imminent.

In a query step REP? a decision is made as to whether the localization procedure should be carried out again. This makes sense if operation in the restricted operating mode MOD LIM is aborted by the operating personnel's control step CRTL or there is a likelihood that repeating the localization (in the restricted operating mode) will improve the localization accuracy.

If the localization step is not repeated, the vehicle, while operating in the restricted operating mode MOD LIM, reaches a locating device for a more precise localization, which enables a detection step for the absolute position REC APOS, which, due to a higher localization accuracy, then sets the more precise location information SET again LOC enabled. Once this has been done, the next step is to start operation in the normal MOD NRM operating mode. The procedure is stopped.

Reference List

car

vehicle

BL

balise

GL

Track

DP

depot

LZ

control center

CP

computer

CM1...CM4

camera

BW

angle of view

OM1 ... OM2

stationary optical marker

OMM

mobile optical marker

PSM

position mark

MLC

machine-readable encoding

NO

alphanumeric character

bp

employees

SE

storage device

aa

antenna arrangement

EE

input device

AE

output device

S1...S9

interface

ACTIVE

activation step

PICT

image acquisition step

CALC RPOS

Relative position calculation step

CALC APOS

Calculation step for absolute position

SET LOC

Set for location information

REP?

Query step for repetition

REC APOS

Capture step for absolute position

MOD LIM

Operation in restricted operating mode

MOD NORM

Operation in normal operating mode

OUT

Computer output step

IN

Input step for the computer

ESTM RPOS

Estimate relative position

ESTM APOS

Estimate absolute position

CRTL

control step

Claims (14)

Method for locating a track-bound vehicle (FZ) in a route network after the vehicle (FZ) has been put into operation,
characterized,
that for localization • at least one camera (CM1 ... CM4) is used, which takes a picture of the vehicle (FZ) and at least one stationary optical marker (OM1, OM2) whose absolute position in the route network is known, • a relative vehicle position of the vehicle (FZ) to the stationary optical marker (OM1, OM2) is determined in the image, • the absolute vehicle position of the vehicle (FZ) in the route network is determined taking into account the absolute position of the marker and the relative position of the vehicle (FZ). Method according to claim 1
characterized,
that in the method an output device (AE) for displaying the image and an input device (EE) for inputting the absolute vehicle position are used. Method according to claim 1,
characterized,
that • an output device (AE) for displaying the image and an input device (EE) for inputting the relative vehicle position are used in the method, • the absolute vehicle position in the route network is determined by computer, taking into account the absolute position of the stationary optical marker (OM1, OM2) and the relative vehicle position. Method according to claim 1,
characterized,
that • the vehicle position relative to the fixed marker (OM1, OM2) in the image is determined with the aid of a computer, • the absolute vehicle position in the route network is determined with the aid of a computer, taking into account the absolute position of the fixed marker (OM1, OM2) and the relative vehicle position. Method according to one of the preceding claims,
characterized,
that • the absolute vehicle position is used as preliminary location information for starting up the vehicle (FZ) in a restricted operating mode (MOD LIM) and • the provisional location information is replaced by secure location information as soon as the vehicle (FZ) has been detected by a location device equipped with a security level, • the safe location information is used after a change from the restricted mode of operation (MOD LIM) to a normal mode of operation (MOD NRM). Method according to claim 5,
characterized,
that
in the restricted operating mode at least one more time for localization • the at least one camera (CM1 ... CM4) is used, which takes a picture of the vehicle (FZ) and at least one stationary optical marker (OM1, OM2) whose absolute position in the route network is known, • a vehicle position of the vehicle (FZ) relative to the stationary optical marker in the image is determined, • the absolute vehicle position of the vehicle (FZ) in the route network is determined taking into account the absolute position of the stationary optical marker and the relative position of the vehicle (FZ). Method according to claim 5 or 6,
characterized,
that in the restricted operating mode (MOD LIM) the nearest accessible locating device is approached. Method according to claim 5, 6 or 7,
characterized,
that the restricted mode of operation (MOD LIM) is limited to a maximum speed that may be driven in the restricted mode of operation (MOD LIM) and/or to a maximum distance that may be traveled in the restricted mode of operation (MOD LIM). Method according to one of the preceding claims,
characterized,
that the at least one camera (CM1 ... CM4) is also used to record an image of a mobile optical marker (OMM) attached to the vehicle (FZ) whose position on the vehicle (FZ) is known. Method according to one of the preceding claims,
characterized,
that the fixed (OM1, OM2) and/or mobile optical markers (OMM) have an alphanumeric character code (ANZ) and/or a machine-readable code (MLC). Method according to one of the preceding claims,
characterized,
that the stationary (OM1, OM2) and/or mobile optical markers (OMM) have a position mark (PSM). Arrangement for locating a track-bound vehicle (FZ) in a route network after the vehicle (FZ) has been put into operation,
characterized,
that the arrangement has: • at least one stationary optical marker (OM1, OM2) of the arrangement whose absolute position in the route network is known, • at least one camera (CM1 ... CM4), which is set up to record an image of the vehicle (FZ) and of the stationary optical marker (OM1, OM2), • a computer (CP) which is set up to control an output device (AE) for displaying the image and an input device (EE) for inputting the absolute vehicle position, and/or which is set up, computer-aided, to control a relative vehicle position of the vehicle (FZ) to the stationary to determine optical markers in the image and to determine the absolute vehicle position of the vehicle (FZ) in the route network, taking into account the absolute position of the fixed optical marker and the relative position of the vehicle (FZ). Computer program product with program instructions for carrying out the method according to one of Claims 1 - 11. Provision device for the computer program product according to the last preceding claim, wherein the provision device stores and/or provides the computer program product.

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