WO2012117068A1 - Method for calculating a recommended speed using a driver assistance system built into a rail vehicle - Google Patents

Abstract

The invention relates to a method for calculating a recommended speed using a driver assistance system (3) which is built into a rail vehicle (1), in particular in a motorised train or a locomotive (3), and which comprises a control unit (2) and a data memory in which information about the timetable and routes of the journey which are to be driven, physical properties of the rail vehicle (1) and optionally, carriages attached to said rail vehicle, are stored. Said method consists of the following steps: the position of the rail vehicle (1) and the actual time is detected using a receiver (4) of a satellite navigation system (5), said receiver being installed on or in the rail vehicle (1); the actual speed of the rail vehicle (1) is determined from the data captured by the satellite navigation system (5); the actual speed of the rail vehicle (1) is compared to a previously calculated desired speed for the currently driven path section, whereby the desired speed is calculated for the individual path sections before the journey begins and is stored in the data memory as a desired speed profile; the desired speed profile is updated during the journey taking into account the actual position and speed of the rail vehicle (1) and the data stored in the data memory and the updated recommended speed is displayed.

Description

 Method for calculating a speed recommendation by a driver assistance system installed in a rail vehicle

The present invention relates to a method for calculating a speed recommendation by a driver assistance system installed in a rail vehicle, in particular in a railcar or a locomotive.

Driver assistance systems that are used in rail transport serve, inter alia, to move a rail vehicle, in particular a multiple unit or a locomotive with passenger or freight cars possibly attached to it, in the most energy-efficient manner possible over a route. The rail vehicles drive on closed railway lines on the basis of a predefined timetable, taking into account further railway-specific conditions such as safety devices with which a collision of rail vehicles is effectively prevented and on the basis of predetermined speed limits for sections.

The timetable and other railway-specific conditions generally define the operating mode of the rail vehicle. However, the driver (train driver or driver) has a certain freedom to choose the driving speed on certain sections suitable. The speeds selected by the driver on the respective sections have a lasting effect on the energy consumption and the energy costs of the rail vehicle. The object of the present invention is to provide a method for calculating a speed recommendation by a driver assistance system installed in a rail vehicle, which is to be integrated into the rail vehicle in a simple manner and with which the driver of the rail vehicle vehicle is offered a way that energy-efficient, safe and punctual to guide the rail vehicle to the next breakpoint of the route.

This object is achieved by a method for calculating a speed recommendation by a driver assistance system installed in a rail vehicle having the features of claim 1.

In the method according to the invention, the driver assistance system is equipped with a control unit and a data memory in which the timetable and route information of the route to be traveled are stored, as well as physical characteristics of the rail vehicle and, if appropriate, carriages attached to this rail vehicle. To control the speed recommendation display, the position of the rail vehicle and the current time is first recorded by a receiver of a global navigation satellite system installed on or in the rail vehicle. From this data, the current speed of the rail vehicle is determined. The current speed of the rail vehicle is compared in a further step with a predetermined target speed for the currently traveled section and then a speed recommendation for at least the next following section calculated taking into account the data stored in the data memory and displayed on the speed recommendation display. The setpoint speed for the individual sections is calculated dynamically. With the described method, a minimal connection of the driver assistance system to the electronics of the rail vehicle is possible. All that is necessary is the connection of the driver assistance system to the power supply and the antenna for satellite-supported position determination. An additional interface for connection to the train control of the rail vehicle is not necessary. The remaining data necessary for calculating a speed recommendation are stored in this variant in the data memory of the control unit of the driver assistance system or are derived from the dynamic driving behavior. These data include, in particular, the physical characteristics of the rail vehicle and the possibly attached wagons.

According to an advantageous embodiment variant of the method according to the invention, if the actual speed of the rail vehicle deviates from the speed setpoint when a predetermined speed is exceeded, th threshold value, a recalculation of the speed profile for the remaining distance traveled based on the current position of the rail vehicle and the current time made. With the aid of such a dynamic calculation of a speed profile, it is possible to make the laying of a predetermined route with the rail vehicle even more energy-efficient.

According to a further preferred embodiment variant, a speed recommendation deviating from the desired speed recommendation is calculated so that the actual speed of the rail vehicle, following this current speed recommendation, corresponds to the speed recommendation calculated before the start of the journey or dynamically recalculated in the subsequent speed recommendation change. This allows the output of a speed recommendation that directs the driver in setting the speed such that the speed for the next changes in the speed driving recommendation again corresponds to the calculated speed.

According to a further preferred embodiment variant, the speed recommendation display indicates a warning if the actual speed deviates from the currently calculated setpoint speed by more than a predefined threshold value. This is particularly important in dangerous situations when the train driver requires increased attention in order to master the critical situation in the best possible way. The speed recommendation can also be such that there is an indication that no speed recommendation can be given to make sure that the train driver focuses in a critical situation exclusively on the safe control of the vehicle. Hereinafter, preferred embodiments of the method according to the invention are explained in more detail with reference to Figures 1 to 5. Show it:

FIG. 1 shows a schematic illustration of a rail vehicle with a driver assistance system installed therein with a minimal interface between driver assistance system and rail vehicle, FIG. 2 shows a schematic representation of a rail vehicle with driver assistance system installed therein with additional data interface, FIG. 3 shows a schematic illustration of a rail vehicle with built-in driver assistance system with additional wireless communication interface,

FIG. 4 is a schematic flowchart showing an embodiment variant of the method according to the invention for controlling a speed recommendation display; and FIG

FIG. 5 is a further schematic flow diagram showing a variant of the method according to the invention for controlling a speed recommendation display.

FIGS. 1 to 3 show different variants of a driver assistance system 3 installed in a rail vehicle 1. The driver assistance system 3 essentially has a screen, which is preferably part of the cab of a trainset or a locomotive. The screen is connected to a control unit 2, which has a data memory. The data memory includes on the one hand the timetable and route information of the route to be traveled and on the other hand, the physical characteristics of the rail vehicle 1 and optionally attached to this car, wherein the physical properties u. a. the mass of the rail vehicle (s) and the characteristics of the drive and brake are included.

The control unit 2 is merely connected to a power supply of the rail vehicle and to an antenna for satellite-based position determination via a global navigation satellite system 5. A connection of the control unit 2 to the control of the rail vehicle itself, in particular to the control system of the rail vehicle, is not provided.

FIG. 2 shows a system architecture similar to the system architecture shown in FIG. 1, wherein the control unit 2 here has an additional data interface 6 which, for example, can be used to connect a memory array. te, a memory stick or other storage medium or a keyboard, via which the control unit 2 can be supplied with data. Via this data interface 6, data such as the vehicle characteristics, timetables or route information can be easily updated in a simple manner, whereby the calculations to be carried out by the control unit 2 can be optimized. Another purpose of this data interface is to be able to load data from the driver assistance system to a mobile storage medium and then make it accessible to an external evaluation. In this way, for example, logs of journeys, eg energy consumption and punctuality, can be evaluated.

The system architecture shown in FIG. 3 has, as an alternative to the data interface 6 of FIG. 2, a wireless communication interface 7, via which data can be exchanged with a central control station. Here, the communication can take place from the control center to the driver assistance system, for example, to update timetables or carried out by the driver assistance system to the control center, for example, to transmit the energy consumption of the train to the control center.

Since the driver assistance system has no interface to the control system of the rail vehicle, the information about used traction or braking force and other information such as the current mass of the train can not be determined directly. However, the connection to the global navigation satellite system makes it possible to deduce the speed and the currently acting forces. It is important that in the data memory exact data of the route profile including curve lines and height gradients and the physical properties of the train consisting of one or more rail vehicles are stored. Thus, based on the current time, which can also be queried via the global navigation satellite system 5 and the position on the route, the current timetable, the speed limits on the route, the exact knowledge of the route profile and the physical characteristics of the train an energy-efficient ride in Form of a desired speed profile from the current position to the next stop of the train are determined.

Is the train sufficiently late or are there no time reserves in the timetable, ie possibilities, with reduced speed at certain sections? No energy can be saved and the train travels at the maximum possible speed while maintaining the speed limits to the destination of the route.

To predict such an energy-efficient trip, the current position, current time, train composition, speed limits and other constraints must be defined a priori. With the driver assistance system, in contrast to static calculations of a desired speed profile known from the prior art, such a speed profile can be adapted dynamically to current conditions and thus the energy efficiency of a drive can be further improved. The driver assistance system is equipped with a powerful processor that allows the calculation of an energy-efficient ride based on the current situation.

In the method, as shown in the flowchart in FIG. 4, the position of the rail vehicle 1 is detected in a first step 101 and the current time in step 102 by a receiver 4 of a global navigation satellite system 5 installed on or in the rail vehicle. Then, in a further step 103, the current speed of the rail vehicle 1 is determined from the data received from the navigation satellite system 5, and then in step 104 the current speed is compared with a previously calculated setpoint speed for the currently traveled route section.

For calculating the target speed profile, the timetable, the train model and the route profile of the route to be traveled from the data memory of the control unit 2 are preferably detected in a first step. When using a system architecture shown in FIG. 2 or FIG. 3, the data can be entered into the data memory via the storage medium connected to the data interface 6 or via the wireless connection to the control center. In a further step, the current position of the rail vehicle 1 is detected by satellite navigation. The initial calculation of the driving recommendation and the output of the desired speed profile based thereon then ensue from these data.

Based on current values during the journey, this target speed profile is calculated taking into account the current position and speed. updated speed of the rail vehicle and the data stored in the data memory and the driver (train driver, train driver) displayed on a speed recommendation display. When calculating the current speed recommendation, a minimum for the energy consumption is preferably calculated by means of suitable optimization algorithms. If the initially stored boundary conditions change during the journey, for example due to a delay of the train, the dynamic calculation can again determine an energy-efficient speed profile, a new setpoint speed profile that is current as long as no deviation from the ideal course of the journey occurs.

Since the dynamic calculation of a completely new speed profile is very computationally intensive, an adaptive adaptation of the speed recommendation is preferably made for smaller deviations of the journey from the most energy efficient ride in a step 106, which leads to the driver as comfortable as possible to bring back to the correct speed. The target speed which is decisive for eliminating small deviations from the ideal speed is that at the position on the track at which the driving recommendation changes in the calculated speed profile. The vehicle speed recommendation is thus output so that the speed at the next change in the vehicle speed recommendation again corresponds to the pre-calculated speed.

If a return to the previously calculated speed profile is no longer possible due to a greater delay, for example, a dynamic recalculation of the vehicle speed profile in step 105 is necessary. It is important here to design the respectively adaptive adaptation of the vehicle speed recommendation so that the driver or locomotive driver does not keep contradictory or quickly changing driving recommendations from the driver assistance system. This means that once given driving speed recommendations for the train driver, even if the train driver slightly deviates from the calculated speed profile. The introduction to the recommended speed is carried out in such a way that the driver is not irritated or disturbed by speed recommendations in the short term and finds the correct target speed in the medium term by observing the driving speed recommendation. According to a further preferred embodiment variant, the speed recommendation display indicates a warning if the actual speed deviates from the currently reported setpoint speed by more than a predetermined threshold value. Such situations often require a quick response of both the driver assistance system and the driver or engine driver himself. Alternatively or in addition to the warning message, it may be provided to switch off the speed recommendation or to issue a message that a speed recommendation can not be given in order to allow the driver to concentrate exclusively on mastering the operating situation.

In addition, it is provided in an embodiment variant to log the essential driving data during the journey and then to store this data in the storage medium connected to the data interface 6 or to transmit the data directly via the wireless communication interface 7 to a control center for further evaluation.

In the flowchart shown in FIG. 5, the conditional recalculation of the setpoint speed profile during travel of the rail vehicle 1 is once again clarified. After a step 201, in which the timetable data, the data of the train model and the route profile are loaded from the data memory, the detection of the current position and time by satellite navigation follows in step 202. After the subsequent calculation of the current position and speed, it is checked in step 203 whether a possibly determined deviation from desired position to actual position or desired speed to actual speed exceeds a predetermined threshold value. If not, then step 202 is continued. If so, in step 204, a recalculation of the driving recommendation, as described in detail above. Subsequently, in step 205, the output of the new desired speed profile in the display of the driver assistance system 3 and it is continued with step 202 to check the course of the onward journey. LIST OF REFERENCE NUMBERS

1 rail vehicle

 2 control unit

3 driver assistance system

4 receivers

 5 navigation satellite system

6 data interface

 7 communication interface

Claims

Expectations

Method for calculating a speed recommendation by a driver assistance system (3) with a control unit installed in a rail vehicle (1), in particular in a multiple unit or a locomotive

(2) and a data memory in which timetable and route information of the route to be traveled, physical properties of the rail vehicle (1) and, if necessary, wagons attached to it are stored, comprising the method steps:

- Detecting the position of the rail vehicle (1) and the current time by a receiver (4) of a global navigation satellite system (5) installed on or in the rail vehicle (1),

- Determining the current speed of the rail vehicle (1) from the data received from the navigation satellite system (5),

- Comparison of the current speed of the rail vehicle (1) with a calculated target speed for the section of route currently being traveled, where

- the target speed for the individual route sections is calculated before starting the journey and saved in the data memory as a target speed profile,

- Updating the target speed profile while driving, taking into account the current position and speed of the rail vehicle (1) and the data stored in the data memory and

- View updated speed recommendation.

Method according to claim 1, wherein if the actual speed of the rail vehicle (1) deviates from the speed setpoint when a predetermined threshold value is exceeded, a recalculation of the speed profile for the remaining route is carried out based on the current position of the rail vehicle (1) and the current time.

3. The method according to claim 1 or 2, wherein when calculating the speed profile, a minimum for energy consumption is calculated using suitable optimization algorithms. Method according to one of the preceding claims, wherein the speed recommendation display is updated every second.

Method according to one of the preceding claims, wherein a speed recommendation that deviates from the target speed recommendation is calculated in such a way that the actual speed of the rail vehicle (1) when following this current speed recommendation corresponds to the speed recommendation calculated before the start of the journey when the speed recommendation changes.

Method according to one of the preceding claims, wherein the speed recommendation display displays a warning if the actual speed deviates from the currently calculated target speed by more than a predetermined threshold value.

Method according to one of the preceding claims, wherein the data stored in the data memory of the control unit (2) is updated via a data interface (6, 7) provided on the control unit (2).

Method according to claim 7, wherein the data interface (6, 7) is designed as a wireless communication interface (7), via which the data stored in the data memory of the control unit (2) is updated continuously or at predetermined time intervals.