The invention relates to a method having the features as claimed in the preamble of claim 1.
Such a method is known from international patent application WO 2011/027166 A1. In this already known method, to locate a rail vehicle along a stretch of track a waveguide is provided which is laid along the stretch of track. Electromagnetic pulses are successively injected into said waveguide. For each pulse emitted, at least one backscatter pattern produced by vehicle-induced backscattering of the electromagnetic pulse is received and evaluated. The location of the vehicle on the stretch of track is determined by evaluating the backscatter pattern.
The object of the invention is to specify a method which provides reliable fault detection in the event of malfunction of the locating apparatus.
This object is achieved according to the invention by a method having the features as claimed in claim 1. Advantageous embodiments of the method according to the invention are set forth in sub-claims.
Accordingly, it is inventively provided that a vibration device installed at a known position in the region of the stretch of track is activated at a predefined activation time, thereby producing at the known position a vibration causing backscattering of the electromagnetic pulse, the time between the activation time and the arrival of the backscatter pattern indicating the vibration is measured, and the measured time is used to check the operation of the locating apparatus or to calibrate the locating apparatus.
A significant advantage of the method according to the invention is that it enables the operation of the locating apparatus to be regularly checked with little cost/complexity. To perform a check, it is merely necessary to selectively generate a vibration and evaluate the behavior of the locating apparatus.
Preferably a fault signal indicating a malfunction of the locating apparatus is generated if the measured time reaches or exceeds a predefined maximum duration or if the measured time reaches or falls below a minimum duration. That is to say, in both cases the evaluation device can assume that the locating apparatus is not operating correctly, either because it is defective or because it has been tampered with.
In order to enable the locating apparatus to be checked without additional equipment complexity and therefore at minimal cost, it is considered advantageous if a mechanically movable outdoor element of the track system present anyway is activated as the vibration device, and the vibration and therefore the backscattering of the electromagnetic pulses is produced when the outdoor element is moved.
Switches, derails, semaphore signals or barrier gates are particularly suitable for producing vibrations, so it is considered advantageous for a switch, derail, semaphore signal or barrier gate to be moved as the outdoor element of the track system, and the vibration and therefore the backscattering of the electromagnetic pulses to be produced by the movement of an outdoor element of this kind.
The measured time can also be used to obtain a correction value which can be taken into account for locating rail vehicles on the stretch of track.
To locate a rail vehicle on the stretch of track, it is considered advantageous, for example, if the time between injection of the electromagnetic pulse into the waveguide and detection of the associated vehicle-induced backscatter pattern is measured, the correction value is subtracted from this time to produce a corrected time, and a position signal indicating the location of the vehicle is generated on the basis of the corrected time.
The invention also relates to a locating apparatus for locating a rail vehicle along a stretch of track using a waveguide laid along the stretch of track, a pulse generating device for generating and injecting successive electromagnetic pulses into the waveguide, a detection device for detecting backscatter patterns produced by backscattering, and an evaluation device which can evaluate the backscatter patterns to locate the rail vehicle.
In respect of a locating apparatus of this kind it is inventively provided that the locating apparatus has a vibration device located in a known position in the region of the stretch of track and connected to the evaluation device, said vibration device being activatable at a predefined activation time, enabling it to produce, at the known location, a vibration causing backscattering of the electromagnetic pulses, wherein the evaluation device is designed such that it can activate the vibration device at a predefined activation time and can use the time lapse between the arrival of the backscatter pattern indicating the vibration and the activation time to check the operation of the locating apparatus or to calibrate the locating apparatus.
In respect of the advantages of the locating apparatus according to the invention, reference is made to the above statements relating to the method according to the invention, as the advantages of the method according to the invention essentially correspond to those of the locating apparatus according to the invention.
It is considered to be particularly advantageous if the evaluation device is designed such that it generates a fault signal indicating a malfunction of the locating apparatus if the measured time reaches or exceeds a maximum duration or if the measured time reaches or falls below a minimum duration.
The vibration device is preferably constituted by an outdoor element of the track system, with particular preference by a switch, a derail, a semaphore signal or a barrier gate.
The invention will now be explained in greater detail with reference to exemplary embodiments and the accompanying drawings in which
For the sake of clarity, identical or comparable components are denoted by the same reference characters throughout the drawings.
The pulse generating device 20 preferably has a laser (not shown) enabling short electromagnetic, in particular optical pulses to be regularly generated, e.g. at a fixed pulse rate, and to be injected into the waveguide 50 via the coupling device 40. The pulse generating device 20 is preferably controlled by the evaluation device 60 so that the pulse generation times are at least approximately known to the evaluation device 60.
The detection device 30 has, for example, a photodetector for detecting the electromagnetic radiation. The detection device 30 transmits its measurement signals to the evaluation device 60 which evaluates them.
As shown in
To locate the rail vehicle 110, the locating apparatus 10 according to
The evaluation device 60 triggers the pulse generating device 20 to inject a series of electromagnetic pulses Pin into the waveguide 50 via the coupling device 40. The generated electromagnetic pulses Pin travel from left to right in the direction of the arrow P in
The rail vehicle 110 running over the stretch of track 100 causes the waveguide 50 to be locally vibrated, or made to oscillate; this is indicated in
It can be seen from
As
dt=dr+dh+dv
It is self-evident that time interval dt will increase the farther the rail vehicle 110 is from the pulse generating device 20 or detection device 30, as the transit times dh and dr will increase. The system-related delay dv will remain approximately constant or vary stochastically within certain limits.
This situation is indicated by way of example in
The evaluation device 60 is therefore able, on the basis of the time interval dt or dt′ as the case may be, to determine the location of the rail vehicle 110 and generate a corresponding position signal So; it can disregard the system-related delay dv or take it into account if it is known by subtracting the system-related delay dv. The location of the rail vehicle 110 can be calculated e.g. according to:
Ls=½*(dt−dv)/V
where Ls denotes the length of the waveguide section between the pulse generating device 20 or rather the detection device 30 and the respective position of the rail vehicle 110, and V the velocity of the pulses in the waveguide 50. The factor ½ allows for the fact that the radiation has to pass through the respective waveguide section at least twice, namely once in the outward direction and once in the return direction.
The velocity V is given e.g. by:
V=c0/n
where c0 is the speed of light and n the refractive index in the waveguide 50.
If the vibration device 70 is activated by means of the activation signal ST, it produces vibrations which are denoted in
The backscatter pattern Rme of the vibration device 70 is produced at a known location in the waveguide 50, because the location of the vibration device 70 in the track system is known. The distance between the vibration device 70 and the coupling device 40 is denoted by the reference character Le in
The evaluation device 60 will measure the time Tv between generation of the activation signal ST and detection of the characteristic backscatter pattern Rme and produce a fault signal F if the time Tv is too long or too short or, in other words, reaches or exceeds a predefined maximum duration Tmax or reaches or falls below a predefined minimum duration Tmin:
Tv≧Tmaxfault signal F is produced
Tv≦Tminfault signal F is produced
In both cases the evaluation device 60 assumes that the locating apparatus 10 is not operating correctly, either because it is defective or has been tampered with.
As the time Tv approximately corresponds to the system-related delay dv or is at least approximately proportional thereto, the evaluation device 60 can use the time Tv to produce a correction value K which can be taken into account for locating the rail vehicle 110 on the stretch of track 100, e.g. according to:
K=p*Tv,
where p is a proportionality factor.
The evaluation device can take the correction value K into account, for example, by subtracting the correction value K from each future time measurement to produce a corrected time duration and generating a position signal So indicating the location of the rail vehicle on the basis of the corrected time duration.
Additionally or alternatively, the evaluation device 60 can determine the system-related delay dv during operation of the vibration device 70 by continuing to evaluate the time lapse dte between generation of the electromagnetic pulses Pin and detection of the respective backscatter pattern Rme in each case (cf.
As the distance Le from the vibration device 70 is known, the evaluation device 60 can determine the system-related delay dv required for pulse generation, detection and evaluation of the backscatter pattern by subtracting the transit times of the electromagnetic pulses in the waveguide 50 from the measured time dte, e.g. a follows:
dv=dte−Le/(2*V),
As explained above, the measured value for the measured system-related delay is preferably taken into account for determining the location.
Although the invention has been illustrated and described in detail using exemplary embodiments, the invention is not limited to the examples disclosed and other variations may be deduced therefrom by the average person skilled in the art without departing from the scope of protection sought for the invention.
Number | Date | Country | Kind |
---|---|---|---|
102012213495.6 | Jul 2012 | DE | national |
Filing Document | Filing Date | Country | Kind |
---|---|---|---|
PCT/EP2013/065469 | 7/23/2013 | WO | 00 |