EP2435998A1

EP2435998A1 - Method for the computer-supported control of a ship

Info

Publication number: EP2435998A1
Application number: EP10720432A
Authority: EP
Inventors: Marco Jaehnisch; Markus Radimirsch
Original assignee: Glaser Philipp
Priority date: 2009-05-26
Filing date: 2010-05-26
Publication date: 2012-04-04
Also published as: JP2012528417A; WO2010136490A1; US8442710B2; DE102009022652A1; US20120072059A1

Abstract

The positions and motions of a bow and a stern of the ship are detected using redundant means and evaluated to automatically perform difficult maneuvers in ports or to generate recommendations for controlling the ship.

Description

METHOD FOR COMPUTER-BASED CONTROL OF A SHIP

The invention relates to methods for the computer-aided control of a ship.

Assistance systems with which a ship can automatically be kept on a predefinable course are known in principle.

In this context, reference may be made to DE 198 13 005 A1.

From US 4,881,080 it is known to equip a vehicle with a GPS device having two antennas. In this way, the position of the vehicle or its longitudinal axis can be determined with high accuracy.

The publication P Andree et.al: Determination of ship movements and other high-frequency movements using GPS, DGON Symposium Location + Navigation 2000, (http // www.geop.de / download / dgon2000.pdf) deals with the possibility of more or less periodic Movements of a ship to capture the accuracy of readings, such as Echosounder data increase. In this context, a GPS system with three GPS antennas, which are arranged in triangular form, is preferably used.

US 2004/0064249 A1 relates to a method and a device for assisting in the control of a vehicle, in particular also of a ship, wherein the possibility is also raised of determining a course for a landing maneuver in order to assist the skipper.

Investment maneuvers are particularly difficult maneuvers of a ship. It is therefore an object of the invention to provide a reliable method for this purpose.

This object is achieved in that in plant maneuvers positions and movements of the vessel as well as moving or stationary obstacles or interference contours are detected automatically by redundant means and by means of a computer image display is controlled on the actual position of the ship relative to obstacles and Interference contours and introduced or recommended control measures are shown.

The invention is based on the general idea to constantly record the positions of the bow and stern of a ship relative to a fixed ground reference system and / or obstacles and Störkonturen and display on a display, so that the respective skipper the respective situation including the potential danger constantly Has eyes and in case of automatic maneuvers, if necessary, can intervene immediately.

According to a preferred embodiment of the invention, one of the redundant means for determining the positions and movements of the ship is a GPS system having a nose-end and a rear-end GPS receiver. Thus, on the one hand, the position of the ship (in a basically known manner) can be detected very accurately. On the other hand, from the position data of the GPS receiver whose distance from each other can be determined and compared with the actually measured value on the ship. The deviation between the distance determined from the GPS data and the actual distance can then be used as a criterion for the quality of the position data of the GPS system. Optionally, in the arrangement of three GPS antennas on the ship and very small quasi-periodic movements of the ship in a known per se can be accurately detected. Thus, ramming, rolling and / or rolling movements and the like of the ship can not lead to any errors in determining the position of the ship relative to the environment.

Preferably, in addition to or as an alternative to a GPS device on the ship, at least one further location system is provided, which allows the position of the bow and stern of the ship to be detected relative to stationary and / or movable obstacles. Such positioning systems may be sonar, ultrasound, laser and / or radar systems.

In particular, it may be provided that distance-measuring sensors, such as ultrasonic sensors, are arranged on the ship as sensor triples at three measured positions. Thus, the coordinates of obstacles can be detected with high accuracy in a ship-side coordinate system, so that at a start time of a plant maneuver a precise environment map of the ship can be generated.

A tracking of the reference system or a detection of the ship movements can be realized by an inertial navigation device, which determines the translational and rotational movements of the vessel from the start time. Due to the relatively short time duration of a docking maneuver, the position errors occurring during integration remain low and can be improved by redundant sensors, such as compass, GPS systems, etc., preferably when using a Kalman filter. Absolute position determination is of minor importance in landing maneuvers so that a relative frame of reference with respect to the ship is sufficient to automatically perform a landing maneuver. In this way, a map of the environment of the ship can be made and displayed on a monitor, so that the space of movement available to the ship is easily recognizable. The data acquired for the generation of the card can be processed by means of a Kalman filter in order to "hide" errors or measurement errors that occur during data acquisition.

As far as the aforementioned GPS facilities are present on the ship and a digital map of each port is already available, the map produced by the ship-side positioning systems of the environment as far as it relates to stationary contours of each port to be compared with the digital map , so that in this way criteria for the quality of the positions determined by the GPS receiver positions of the bow and stern of the ship are derivable.

As soon as the environment of the ship has been recorded with sufficient accuracy, it is possible in principle to automatically guide the ship to a desired location at the optimum course, with the assistance of a computer (with appropriate capacity). Again, it is advantageous again that in the invention, the position data of the bow and stern of the ship are detected, so that even complicated movements of the ship can be tracked and executed without delay. In this context, reference may be made to basically known control and drive systems with which a ship can be moved not only in the longitudinal but also in the transverse direction, by way of example reference is made to bow thrusters and Voith Schneider propellers. Such systems also allow traversing of the ship. As soon as the assistance system according to the invention has determined with its locating devices that there is sufficient freedom for a planned maneuver of the ship, a desired path of the ship is automatically determined and stored. Subsequently, then the control and propulsion systems of the ship are controlled so that the target-actual value deviation between the predetermined target path and the actually executed by the ship actual path is minimal or remains. Such a control of the propulsion and control systems of the ship is basically independent of any confounding factors, such. Eg flow or wind, possible. The only requirement is that the control and propulsion systems of the ship are sufficiently powerful to be able to move the ship against any disturbing forces relative to a fixed earth reference system.

However, it is expedient and provided according to a preferred embodiment of the invention to detect at least larger disturbance forces separately in order to make a corresponding presetting of the propulsion and control systems of the ship to compensate for the respective disturbance forces. In this way possible deviations between desired and actual way of the ship are kept low from the beginning. This reduces the need for regulation at the same time.

For measuring the wind speed, an anemometer communicating with the assistance system can be arranged on the ship. The thus determinable wind speed and direction relative to the ship can then be used by the assistance system for determining the wind speed and direction relative to a fixed ground reference system, as from the data of the GPS system or other ship-side positioning systems, the movement speed and direction of the ship relative can be determined to the earth-fixed reference system. Possible water flows can be determined with regard to direction and speed, if necessary, by the assistance system "knowing" a model of the respective ship and, based on the model parameters, being able to calculate the speed and direction of movement of the ship at the respective wind load in (ideally) still waters The flow velocity and direction can then be determined between the calculated course or calculated movement direction and speed with respect to the actual movement direction and speed Since, at least in ports, it can be assumed that the flow conditions of adjacent locations are practically indistinguishable, the flow data may be determined before the beginning of a critical maneuver and then taken into account in the subsequent critical maneuver.

Incidentally, with regard to preferred features of the invention, reference is made to the claims and the following explanation of the drawing, on the basis of a preferred embodiment of the assistance system according to the invention is explained in detail.

Protection is claimed not only for specified or illustrated feature combinations but also for any combinations of the specified or illustrated individual features.

In the drawing shows

1 is a schematic plan view of ships in a port section, Fig. 2 is a highly schematic block diagram of the assistance system according to the invention.

1 shows an "aerial view" of a section of a harbor with a quay wall 1 to which a ship 2 has put on. Another ship 3 occupies a berth, the longitudinal axis of the ship 3 being perpendicular to the quay wall 1. Both ships 2 and 3 are fixed by means of lines or ropes to polders 4. For a further ship 5 there is still a berth between the ships 2 and 3, parallel to the ship 3. The further ship 5 may now be equipped with an assistance system according to the invention It has a GPS device with a GPS receiver 6 at the bow and a GPS receiver 7 at the rear, and the ship 5 also has a plurality of locating devices 8 with which the environment of the ship 5 can be detected.

According to FIG. 2, a computer 9 of the assistance system is connected on the input side to the GPS receivers 6 and 7. On the output side, the computer 9 controls at least one image display 10 on which the position of the ship 5 can be determined on the basis of the data of the GPS receivers 6 and 7 relative to an earth-fixed reference system, e.g. UTM coordinates (UTM = universal transversal Mercator projection), can be represented. In addition, the computer 9 can communicate on the input side with a memory 11 or a transmitter or the like in order to obtain the data of a digital map of the respective port section.

Thus, the computer 9 can display the ship 5 in the correct position relative to the quay wall 1 on the image display 10.

If a digital map is not available, the computer 9 can also generate on the image display 10 by means of the data supplied by the locating devices 8 an image of the ship 5 with the surroundings of this ship. If the digital map of the port is available, the data of the locating devices 8 are essentially only used to "draw in" the ships 2 and 3 in the map or in the map image appearing on the image display 10. Otherwise the computer checks For example, from the data of the GPS receivers 6 and 7, their distance from one another can be determined and compared with the constructively specified value, the greater the deviation between the two values determined thereby The more uncertain are the position data for the bow and stern of the ship 5 ascertained by means of the GPS receivers 6 and 7. This can be reproduced on the image display 10, for example, by showing the most probable position of the ship 5 on the one hand and a corresponding uncertainty range on the other hand is reproduced figuratively, within which the ship are 5 could.

Now, with a keyboard 12 or a mouse or the like on the image display 10, a desired target position of the ship 5 can be given and "communicated" to the computer 9. The computer 9 then determines a suitable or optimum target path, so that the ship 5 can reach the target position In this case, the computer 9 takes into account the ship-side control and drive devices available to the ship 5. If these devices are not suitable or sufficient to carry out the necessary maneuvers, this is indicated If there are sufficient control and drive devices, on the one hand there is the possibility that the necessary maneuvers are carried out automatically by the computer 9 correspondingly actuating the drive and control devices 15 of the ship, that is to say depending on a setpoint. I stwert- comparison between the determined target path for the ship 5 and the actual From the ship 5 executed actual way. To determine this difference, both the signals provided by the GPS receivers 6 and 7 as well as the signals of the locating devices 8 can be used.

If the ship's crew prefers manual control of the ship, the control devices 15 are actuated by means of manual control elements 16, whereby the commands given by the computer 9 to the control devices become ineffective. However, the computer 9 can propose on the image display 10 appropriate operations of the control and drive means of the ship and simultaneously represent the actual position of the ship 5 and a recommended target position. As a result, the ship's crew, the control of the ship 5 is much easier.

Incidentally, the assistance system can also be helpful if the performance of the propulsion and control devices of the ship 5 alone is not sufficient to carry out the necessary maneuvers to achieve a desired berth. In this case, the computer may suggest appropriate maneuvers for tow tractors or the like, so that the ship's crew will be given substantial help in the necessary instructions to the crews of the tow tractors.

The computer 9 "knows" a model of the ship 5, so that it can predict the reactions of the ship to interventions on the control and propulsion devices of the ship in an ideal (in particular flow-free) waters From the data of the GPS receiver 6 and 7 compare actual reactions of the ship and thereby check whether the deviating reactions by acting on the ship 5 wind loads, the data from an input side connected to the computer 9 anemometer 13 determined are, can be explained. The reactions of the ship, which can not be explained in this way, are then returned by the computer 9 to water flows which can be determined in this way with regard to strength and direction. In principle, this determination of water flows can take place continuously, in particular in good time before a special maneuver of the ship 5, so that the flow influences can be taken into account in advance in the automatic or computer-assisted execution of a maneuver.

In this case, it is assumed that flow conditions usually differ only slightly from one another at adjacent positions, that is, they are largely constant regardless of location.

Incidentally, data on water currents and the like can in principle also be transmitted from a port-side data transmitter to a corresponding receiving device of the computer 9, for example together with a digital map of the respective port.

According to a particularly preferred embodiment of the invention, the computer 9 is additionally connected on the input side with a motion sensor system 14, with which rolling or pitching movements or the like of the ship can be detected. If the computer 9 due to a stored ship model possible rolling and tamping movements of the ship "knows" can be avoided in this way that the computer 9 undesirably reacts to the aforementioned ship movements in an automatically performed maneuver of the ship or in the determination of recommended maneuvers In particular, it is possible in this way to avoid that essentially periodic movements of the ship are stimulated by means of control measures. Rather, there is the advantageous possibility of damping periodic ship movements by push-pull control measures. The invention can be summarized by way of example as follows:

By means of the sensors of ship-side positioning systems, the environment of the ship is detected, with basically known methods (Kalman filtering) can be used to compensate for measurement errors. The GPS receivers of the ship are mainly used for course determination (compass) and to record the extent of the ship. The motion sensor detects movements of the ship in the direction of the degrees of freedom and thus allows conclusions about the strength of the sea state, also can be avoided so that unnecessary control measures of the ship are automatically performed or recommended to the ship's personnel. After measuring a mooring or berth a Sollweg the ship is calculated, the data used for the calculation are preferably improved by Kalman filtering or the like. On the basis of the desired path manipulated variables for the control and propulsion systems of the ship are determined and supplied to this via a CAN bus or the like. These manipulated variables are constantly updated by comparing the set and actual travel of the ship.

Claims

claims

1. A method for computer-aided control of a ship, characterized in that at Anlegemanövern positions and movements of the vessel and movable or stationary obstacles or interference contours are detected automatically by redundant means and by means of a computer image display is controlled on the actual position of Ship relative to obstacles and interference contours, as well as initiated or recommended control measures.

2. The method according to claim 1, characterized in that by means of an inertial and / or motion sensor substantially periodic movements of the ship (rolling, pounding, rolling) are detected.

3. The method of claim 1 or 2, characterized in that the computer also stored data of a model of the ship is accessed, and that its responses to control interventions and predetermined ideal conditions are determined and compared with actual reactions of the vessel for the quantitative detection of interference.

4. The method according to any one of claims 1 to 3, characterized in that by means of a GPS device with a bugseitigem and a rear-end GPS receiver each detected positions of the bow and stern Plausibility or accuracy can be checked by comparing the determined from the positions distance between the positions of the bow and stern with a constructively predetermined, stored value.

5. The method according to any one of claims 1 to 4, characterized in that reproduced on the image display a most probable position of the ship and an area of uncertainty.

6. The method according to any one of claims 1 to 5, characterized in that is displayed on the image display, if provided or necessary maneuvers with existing control or drive means of the ship are feasible.

7. The method according to claim 6, characterized in that the computer on the image display expedient maneuvers of Bugsierschleppern or the like are shown.

8. The method according to any one of claims 1 to 7, characterized in that proposed in manual control of the ship with the computer on the image display expedient operations of the control or drive means of the ship and at the same time the actual position and a desired position of the ship being represented.

9. The method according to any one of claims 1 to 8, characterized that obstacles are detected in a ship-side coordinate system with at least three distance-measuring sensors, which are arranged at measured positions of the ship.

10. The method according to claim 9, characterized in that ship movements are detected by an inertial navigation device from an initial time point, to which the obstacles have been detected on the ship-side coordinate system.

11. The method according to claim 9 or 10, characterized in that ship movements are detected by redundant sensors, such as compass or GPS system or inertial sensors.