DE102014219798A1 - Mobile terminal and orientation determination method on a mobile terminal - Google Patents

Abstract

The present invention comprises a method for orientation determination on a mobile terminal. In this case, a determination is made of a position (P) of the mobile terminal (MEG), detection of an environment of the mobile terminal, extraction of line-like patterns (M) from the detected environment and determination of a master pattern axis (MHA) from the linear patterns (M). A device offset (GEV) as the angular difference between a major axis (GHA) of the mobile terminal and the master pattern axis (MHA) at the determined position (P) is determined. Further, a pattern principal axis offset (MHV) is retrieved as an angle difference between the pattern main axis (MHA) and a reference orientation (RFO) at the designated position (P). Finally, an angle sum is determined from the pattern principal axis offset (MHV) and the device offset (GEV).

Description

The invention relates to a mobile terminal and to a method for orientation determination on a mobile terminal.

In the prior art, mobile terminals are known which allow a routing of an operator. A routing outside of buildings today is largely reliable in the application of a position determination based on satellite signals, in particular in the application of Global Positioning System signals, known in the art as GPS.

In contrast, routing systems within at least partially closed areas, such as buildings, still have a number of technical problems. These problems of such routing techniques, also referred to as indoor navigation systems, are mainly due to the fact that reception of GPS signals in buildings is technically almost impossible. In closed areas, therefore, alternative methods have been established which are intended to enable position and orientation determination of a mobile terminal in the absence of satellite signals.

For determining the position of a mobile terminal, methods are known, for example, which detect WLAN (Wireless Local Area Network) or Bluetooth signals and use their measured signal strength, for example using triangulation methods or lookup tables for position determination. These methods allow a determination of the position of a mobile terminal, but not the orientation of the mobile terminal.

Under the orientation of a mobile terminal, in the following, either an absolute directional indication measured at a current position with respect to a reference orientation, such as a compass direction, such as a compass direction, will be used. North, understood, or a relative directional indication into which the mobile terminal is moved in relation to a fixed reference point.

For orientation determination complementary methods are known, which provide for an application of an inertial navigation system with additional use of magnetic field sensors (compass sensors). An inertial navigation enables a measurement of movements in space in six kinematic degrees of freedom, of which three translational and three rotational degrees of freedom. With this inertial navigation system, changes in position, ie the orientation in space, can be determined. A determination of the orientation is in particular independent of any localization signals from the environment.

An inertial navigation system requires dual integration of accelerometer readings and easy integration of angular velocity readings. A usually strong sensor drift and a mathematically required cross-coupling of orthogonal sensor axes lead to considerable errors in the orientation determination whose effects cumulatively with increasing time.

It has therefore already been proposed to supplement inertial navigation systems with additional orientation determination methods. In order to determine integration constants, to improve the accuracy and to correct the sensor drift, supportive orientation determination methods using evaluation of magnetic field sensors or compass sensors are used. However, magnetic field sensors are influenced by magnetic interference caused by power lines, metal walls, etc. For the correction of deviations and disturbing influences a software-based signal processing, for example by means of Kalman filtering is known. Notwithstanding these additional orientation determination techniques, the in-building orientations deviate in practice from angular errors of up to 20 degrees from an actual orientation. The angle error, also known as deviation, corresponds to an angle between an actual orientation and the measured orientation.

The present invention has the object to provide means to ensure an alternative or additional orientation determination on a mobile terminal.

The object is achieved by a mobile terminal with the features of claim 1.

• – eine Positionsbestimmungseinheit zur Bestimmung einer Position des mobilen Endgeräts;
• – eine Bilderfassungseinheit zur Erfassung einer Umgebung des mobilen Endgeräts, zur Extraktion linienartiger Muster aus der erfassten Umgebung und zur Ermittlung einer Musterhauptachse aus den linienartigen Mustern;
• – eine Bestimmungseinheit zur Bestimmung eines Gerätversatzes als Winkeldifferenz zwischen einer Hauptachse des mobilen Endgeräts und der Musterhauptachse an der bestimmten Position;
• – eine Abrufeinheit zum Abruf eines Musterhauptachsenversatzes als Winkeldifferenz zwischen der Musterhauptachse und einer Referenzorientierung an der bestimmten Position;
• – eine Orientierungsbestimmungseinheit zur Bestimmung einer Winkelsumme aus dem Musterhauptachsenversatz und dem Gerätversatz.

The mobile terminal according to the invention comprises

• A position determination unit for determining a position of the mobile terminal;
• An image acquisition unit for detecting an environment of the mobile terminal, extracting line-like patterns from the detected environment and determining a master pattern from the line-like patterns;
• A determining unit for determining an apparatus offset as an angular difference between a major axis of the mobile terminal and the master pattern axis at the determined position;
• A fetching unit for fetching a master pattern axis offset as an angle difference between the master pattern axis and a reference orientation at the determined position;
• An orientation determination unit for determining an angle sum from the pattern principal axis offset and the device offset.

The object is further achieved by a method with the features of claim 5.

• – Bestimmung einer Position des mobilen Endgeräts;
• – Erfassung einer Umgebung des mobilen Endgeräts, Extraktion linienartiger Muster aus der erfassten Umgebung und Ermittlung einer Musterhauptachse aus den linienartigen Mustern;
• – Bestimmung eines Gerätversatzes als Winkeldifferenz zwischen einer Hauptachse des mobilen Endgeräts und der Musterhauptachse an der bestimmten Position;
• – Abruf eines Musterhauptachsenversatzes als Winkeldifferenz zwischen der Musterhauptachse und einer Referenzorientierung an der bestimmten Position; und;
• – Bestimmung einer Winkelsumme aus dem Musterhauptachsenversatz und dem Gerätversatz.

The inventive method for orientation determination on a mobile terminal comprises the following steps:

• - determining a position of the mobile terminal;
• Detecting an environment of the mobile terminal, extracting line-like patterns from the detected environment, and obtaining a master pattern from the line-like patterns;
• - determining a device offset as the angular difference between a major axis of the mobile terminal and the master pattern axis at the determined position;
• Retrieving a master pattern axis offset as the angular difference between the master pattern axis and a reference orientation at the determined position; and;
• - Determination of an angle sum from the pattern main axis offset and the device offset.

The object is further achieved by a computer program product having the features of patent claim 11. The computer program is processed in a processor of a mobile terminal, which executes the method with the processing.

With the use of the means according to the invention an orientation determination is advantageously provided, which achieves a high accuracy in comparison with other orientation determination methods while avoiding the drift or jitter problems known in the prior art.

Contrary to known complex optical position and orientation calculation from stored 3D models of a building, detection of an environment and extraction of line-like patterns from the detected environment is advantageously accomplished with less computational resources.

Further embodiments of the invention are the subject of the dependent claims.

In the following, further embodiments and advantages of the invention will be explained in more detail with reference to the drawing. Showing:

1 : a schematic representation of axes used for determining the orientation of a mobile terminal in a horizontal system; and;

2 : A schematic representation of selected functional components in a mobile terminal according to an embodiment of the invention.

In 1 is a Cartesian coordinate system - hereinafter also horizon system - consisting of an abscissa x and an ordinate y shown, whose origin P corresponds to a determined position of a mobile terminal MEG.

According to the invention, at least one image acquisition unit arranged in the mobile terminal detects an environment of the mobile terminal.

The detection of the environment takes place in an advantageous manner by an image acquisition unit directed at a floor. This direction on the floor advantageously corresponds to a natural orientation of an image capture unit or camera installed in commercially available mobile terminals on the rear side, when an operator holds the mobile terminal in his hand while looking at a display unit of the mobile terminal arranged on the opposite front side , The arranged on the back of image capture unit is directed in commercial mobile devices in the opposite direction to the display unit and usually serves an audiovisual recording of the environment with simultaneous possibility of viewing the recorded environment.

Alternatively or additionally, the detection of the environment is carried out by an image acquisition unit directed at a ceiling of the environment. This direction on the ceiling advantageously corresponds to a natural orientation of an image acquisition unit oriented in the direction of the display unit of the mobile terminal, when an operator holds the mobile terminal in the hand while looking at a display unit of the mobile terminal. The image acquisition unit oriented in the direction of the display unit of the mobile terminal corresponds to a camera, which is usually intended to detect the face of the operator for carrying out audio-visual communication.

From the detected environment line-like pattern M are extracted according to the invention, which are sketched by way of example in the drawing and are shown obliquely above the horizontal system for reasons of clarity. For example, regular patterns in tile joints, ceiling joints, parquet planks, strips in linoleum floors, weave patterns in carpets, overhead light tubes as well whose reflections on granite floors etc. are abstracted by means of pattern recognition methods and thus extract the line-shaped pattern M. The capture of wall patterns or baseboards is conceivable. In the example of the drawing, the line-like pattern M has been extracted from a tile joint pattern, wherein the tiles have an elongated rectangular base.

In a further step, a pattern main direction MHA is extracted. In the present example, the pattern main direction MHA corresponds to a detected tile joint pattern of the elongated joint direction.

On the other hand, if the line-like pattern M has been extracted from a tile joint pattern (not shown) in which tiles have a square base area, an unambiguous pattern main direction MHA can not be determined unambiguously. From the two possible directions orthogonal to one another, a pattern main direction MHA is determined by selection and an orientation determination based thereon is corrected, possibly by using orientations determined by other methods.

In the case of a hexagonal or more complex base area of a tile joint pattern or floor covering pattern (not shown), the pattern main direction MHA can be determined by a geometrical center of gravity determination of the individual lines whose individual center of gravity is extrapolated with a respective line. The geometric mean of the lines then also leads in this case to a unique pattern main direction MHA or, as in the abovementioned orthogonal case, at least only ambiguous pattern main direction MHA.

In the extraction of the line-like pattern M or even in the determination of the pattern main axis MHA, it should be noted that the mobile terminal in the already described attitude in which the operator holds the mobile terminal in the hand and viewing a display unit of the mobile terminal, Usually is not aligned parallel to the ground, so that the line-like pattern M is first detected with a distortion, which is caused by an opposite the horizontal plane of the Horizonsystems tilted and / or inclined image plane of the image acquisition unit. According to one embodiment of the invention is therefore intended to detect a detection of a tilt and / or inclination angle of a main axis of the mobile terminal extending ground plane of the mobile terminal relative to the horizontal plane and based on the tilt and / or inclination angle correction of the line-like pattern M or the pattern main axis MHA make.

In a following step, a device offset GEV is determined which corresponds to an angular difference between a main axis GHA of the mobile terminal MEG and the pattern main axis MHA at the determined position P. This angular difference can be taken directly from a geographical determination of the line-like pattern M in the image plane of the detection unit or the pattern main axis MHA in the image plane of the detection unit. An angular offset of the pattern main axis MHA around the main axis GHA of the mobile terminal MEG lying in the image plane corresponds to the device offset GEV.

In the drawing a wind rose consisting of the cardinal directions North N, South S, West W and East O is symbolized. This wind rose is merely an intuition of a direction of orientation. In the following, a reference orientation RFO is considered instead, which coincides with the north direction N in the present exemplary embodiment. Alternatively, any other cardinal directions S, W, O can be selected as the reference orientation RFO. Deviating from habits of a wind rose direction, a counterclockwise rotation corresponds to a positive angle, a clockwise rotation corresponds to a negative angle corresponding to the mathematical counting direction.

In a following step, a sample main axis offset MHV is retrieved as an angular difference between the master pattern axis MHA and a reference orientation RFO at the determined position P. The retrieval of corresponding data occurs either from a terminal-internal or an external data source, in the latter case by any wireless Interface of the mobile terminal MEG. Instead of a complex wireless data communication connection, this data may also be contained by received Bluetooth or WiFi beacons, which are sent by local transmitters for orientation in the building. The data includes an indication of which angular difference between the master pattern axis MHA of the linear pattern M and a reference orientation RFO, for example in the natural language: The joints in space at the given position P are located 10 degrees west of the north direction.

In the first case, ie an internal retrieval of data, it is provided according to an embodiment of the invention that the environment is detected with an initialization method. For example, a floor pattern is "surveyed" with the initialization process carried out on the mobile terminal MEG in order to create corresponding data in the terminal-internal data source. As part of the initialization process may be a request to the operator of the mobile device MEG be provided to align the mobile terminal MEG in a known orientation, for example, along a corridor. Even without measuring floor patterns, it can be assumed in many cases that the main lines of the floor pattern run parallel or at right angles to a wall of the room.

With existing internal or external existing map data of a building, the simple assumption "parallel or perpendicular to the wall" can be used for many rooms as a default assumption for floor lines, or more generally: linear patterns M, within a room.

Finally, in an orientation determination unit, an angle sum is derived from the pattern main axis offset MHV and the device offset GEV, which leads to the orientation ORT. Referring to the drawing, an orientation ORT of 35 degrees from the reference orientation RFO is determined from an angle sum of the pattern main axis offset MHV having a value of 15 degrees and the device offset GEV having a value of 20 degrees. The orientation of the mobile terminal MEG thus corresponds to a 35 degree direction in the northwest direction, according to one of the mathematical information given by reversed sign windrope information so - 35 degrees to the northwest.

For the main pattern axis MHA, the main axis GHA of the mobile terminal MEG and the reference orientation RFO only their respective direction in the horizon system of interest, while their respective length - in vector description: the amount - is irrelevant. Alternatively, the axes MHA, GHA, RFO referred to herein may be referred to as a unit vector.

Although the means according to the invention alone ensure an orientation determination of a mobile terminal, it is provided according to a preferred embodiment to combine the means for orientation determination known today with the agents according to the invention and in this way to refine and / or solidify the orientation determination. The currently known methods of orientation determination are performed using data provided by magnetic sensors and / or inertial sensors. The preferred embodiment is advantageously suitable for correcting the disadvantages of this known orientation determination, ie in particular the above-mentioned disadvantages such as sensor drift, complex calculation of cross-coupling of orthogonal sensor axes, cumulative deviations with increasing time, magnetic interference caused by power lines, metal walls, etc. to refine and - in view of the known effects of sensor drift - to ensure a reliable orientation determination even over long periods. The interaction with known orientation determination methods according to this preferred embodiment also has the advantage of making an initially indeterminate or ambiguous pattern main direction MHA unambiguously determinable by using the known "coarse" orientation determination methods, in conjunction with the preferred embodiment arrive at more precise and time-stable orientation data.

2 shows a schematic representation of selected functional components in a mobile terminal according to an embodiment of the invention.

The mobile terminal MEG comprises not only a position determination unit for determining a position of the mobile terminal MEG, the image acquisition unit BEF, a control unit STE, which the determination unit BSE for determining the device offset GEV, the retrieval unit ARE for retrieving the Musterhauptachsenversatzes MHA and the orientation determination unit OBE Position includes.

A mobile terminal MEG according to further embodiments also has further - not shown - functional units, such as a wireless interface, another provided on the opposite side image capture unit and internal terminal-internal memory.

The functional units mentioned are either implemented within the control unit STE as software routines or as separate and cooperative hardware components.

In summary, the present invention comprises a method for orientation determination on a mobile terminal. In this case, a determination is made of a position (P) of the mobile terminal (MEG), detection of an environment of the mobile terminal, extraction of line-like patterns (M) from the detected environment and determination of a master pattern axis (MHA) from the linear patterns (M). A device offset (GEV) as the angular difference between a major axis (GHA) of the mobile terminal and the master pattern axis (MHA) at the determined position (P) is determined. Further, a pattern principal axis offset (MHV) is retrieved as an angle difference between the pattern main axis (MHA) and a reference orientation (RFO) at the designated position (P). Finally, an angle sum is determined from the pattern principal axis offset (MHV) and the device offset (GEV).

Claims (11)

 Mobile terminal comprising - A position determining unit for determining a position (P) of the mobile terminal (MEG); - at least one image capture unit (BEF) for detecting an environment of the mobile terminal, for extracting line-like patterns (M) from the detected environment and for determining a master pattern axis (MHA) from the line-like patterns (M); - a determination unit (BSE) for determining a device offset (GEV) as an angular difference between a main axis (GHA) of the mobile terminal and the pattern main axis (MHA) at the determined position (P); - a polling unit (ARE) for retrieving a pattern main axis offset (MHV) as an angular difference between the pattern main axis (MHA) and a reference orientation (RFO) at the determined position (P); An orientation determination unit (OBE) for determining an angle sum from the pattern principal axis offset (MHV) and the device offset (GEV). Device according to Patent Claim 1, characterized in that the at least one image capture unit (BEF) is provided opposite a side of the mobile terminal comprising a display unit of the mobile terminal. Device according to one of the preceding claims, characterized in that the at least one image capture unit (BEF) is provided on a side of the mobile terminal comprising a display unit of the mobile terminal. Device according to one of the preceding claims, characterized in that the orientation determination unit (OBE) is set up for processing further orientation information, in particular orientation information supplied by magnetic sensors and / or inertial sensors. Method for determining orientation on a mobile terminal, comprising the following steps: - determining a position (P) of the mobile terminal (MEG); Detecting an environment of the mobile terminal, extracting line-like patterns (M) from the detected environment, and determining a master pattern axis (MHA) from the line-like patterns (M); - determining a device offset (GEV) as the angular difference between a major axis (GHA) of the mobile terminal and the master pattern axis (MHA) at the determined position (P); Retrieving a master pattern axis offset (MHV) as an angular difference between the master pattern axis (MHA) and a reference orientation (RFO) at the determined position (P); and; - Determination of an angle sum from the pattern main axis offset (MHV) and the device offset (GEV). A method according to claim 5, characterized in that the pattern main direction (MHA) is determined by a geometrical center of gravity determination of the line-like pattern (M). Method according to one of the preceding claims 5 to 6, characterized by the following method steps - Determining a tilt and / or inclination angle of a main axis of the mobile terminal (MEG) extending ground plane of the mobile terminal relative to a horizontal plane; and; - Making a correction to the line-like pattern M and / or on the pattern main axis MHA on the basis of the determined tilt and / or angle of inclination. Method according to one of the preceding claims 5 to 7, characterized in that the retrieval of the pattern main axis offset (MHV) takes place from a terminal-internal and / or external data source. Method according to claim 8, characterized in that terminal-internal and / or external map data of a building are processed to retrieve the master pattern axis offset (MHV). Method according to one of the preceding claims 5 to 9, characterized in that for orientation determination further orientation information, in particular provided by magnetic sensors and / or inertial sensors orientation information is used. Computer program product with means for carrying out the method according to one of the preceding claims 5 to 10 when the computer program product is executed on a mobile terminal (MEG).

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