EP2449345A1 - Analyzing the motion of objects - Google Patents

Abstract

The invention relates to a method for analyzing the motion of objects, in particular of objects, persons, or other living beings, wherein measured acceleration values relative to three orthogonal axes of a first coordinate system (x, y, z) are present and wherein: - the measured acceleration values (A1, A2, A3) are transformed into a second coordinate system (x', y', z') (devices 10, 12), - the direction of a gravitational field in which the motion takes place or has taken place is determined from the measured acceleration values (A1, A2, A3) for the transformation into the second coordinate system (x', y', z') (device 10), - the direction of the gravitational field is selected as the direction of a first axis (x') of the second coordinate system (x', y', z'), - the direction of a second axis of the second coordinate system (x', y', z') is determined from a comparison of the measured acceleration values (A1, A2, A3) or motion information derived therefrom, using existing information (memory 11) about another motion or about a motion type (device 12).

Description

 Our sign: FHIPT09011WO June 22, 2010

Analyze movements of objects

The invention relates to a method for analyzing movements of objects. The objects are, in particular, persons or other living beings. However, the objects of movement can also be objects.

The invention further relates to a corresponding apparatus for analyzing movements of objects, a computer program configured to execute the method for analyzing movements of objects when it is executed on a computer or computer system, and a data carrier on which the computer program is stored is so that it is loadable into the memory of the computer or computer system or is readable and executable directly on the disk of the computer or computer system.

DE 10 2005 004 086 A1 describes a device for detecting movements. The device detects the movements in the room by means of several motion sensors. The measured values of at least one motion dimension are offset with the measured values of at least one other motion dimension. A rotational speed measurement is combined with a linear acceleration measurement. Three linear

Acceleration measurements are combined to convert accelerations into three corrected spatial directions.

As mentioned in the document, such a conversion, i. a

Transformation of the acceleration measurements from the coordinate system of the measuring device into a corrected coordinate system useful to the

To be able to attach acceleration sensors as desired to the movement object. Also according to the present invention, such a transformation is made.

In particular, when the acceleration sensors are attached to a person, it is difficult to align the directions of the coordinate axes of the sensors with appropriate directions with respect to the person. The three directions that are mostly of interest to the person are the directions front and back, left and right, and top and bottom, respectively. The latter direction usually coincides with the direction of the gravitational force acting on the person in the gravitational field of the earth.

However, the same often applies not only to persons, but also to animals or objects whose movements are to be tracked and analyzed. Our sign: FHIPT09011WO June 22, 2010

The acceleration sensors according to the present invention may be implemented as described in DE 10 2005 004 086 A1. For example, Microsensors based on silicon structures can be used. Such sensors are small and lightweight. They can be according to the invention, e.g. integrate into electronic devices used by persons, e.g. Mobile phones, handheld computers or the like. However, due to their small size, the sensors can also be integrated into even smaller units. For example, Such a unit can only be the three

 Acceleration sensors for measuring the acceleration values in a Cartesian coordinate system and the facilities required to make the measured values available for evaluation. The transmission of the measurements from the unit may e.g. wirelessly via a radio interface.

A sensor unit that performs accelerations in a Cartesian coordinate system, i. can measure in three mutually orthogonal directions in space, hereinafter referred to as 3D acceleration sensor or 3D sensor.

The three individual acceleration sensors are preferably an integrated unit, e.g. in the form of an integrated circuit. However, they may also be composed of separate units, i. be mechanically interconnected, or alternatively be a locally distributed system. The individual can

Sensor units or the entire 3D sensor even from a single or

composite camera system and / or a combination with an SD acceleration sensor, which detects the environment in chronological order. By changing the optical image content and the knowledge about the

Camera parameters can thus be motion changes such as distance,

Determine speed and acceleration.

As mentioned above, in particular the movement of the object can be detected by a camera arranged on the object. It is not only possible to determine the acceleration values of the movement of the object by evaluating the images captured by the camera. Rather, alternatively, the speed of movement and / or the traveled distances of the movement can be determined. The later described method for analyzing movements of objects may therefore use speed values and / or instead of the 3D acceleration measurement values Our sign: FHIPT09011WO June 22, 2010

Distance values, each as three-dimensional values and transform in the manner described below in a second coordinate system.

The camera or the camera system with a plurality of differently oriented cameras can be used in various ways to determine the speed and / or acceleration of the object. In particular, at least one model of the movement of persons and / or objects can be used, wherein these persons and / or objects, as seen by the camera or the camera system, move past the object or move towards the object or move away from the object. In particular, the information that a certain object or a certain person is moving toward the object exactly (if this is considered in the coordinate system of the camera) gives the information about the main movement direction. It is understood by a movement exactly to the object that z. B. as when walking a person's hip performs a periodic overlaying movement. From the point of view of the camera or the camera system, the person or the object to be moved precisely to the object can therefore, for. B. reciprocate while other persons or objects move past the object. The same applies to persons or objects that move away from the object exactly. In addition, it can be determined from the camera images of persons or objects that move precisely toward or away from the object that the person or object appears to be enlarging (if he or she is moving closer to the object) or downsized (if he moves away from the object).

In the case of persons or objects moving past the object, optionally the information about the distance to the object can additionally be used in order to determine the speed and / or the acceleration of the object. The distance z. B. in a camera system by geometric considerations,

for example, in a triangulation calculation. However, additional information about known distances can be used, such as the distance from beacons to a sideline on a road for motor vehicles. It is also possible to determine this distance by additional sensors, for. B.

Ultrasonic sensors, which measure the time for reflection of sound waves and deduce the distance. Our sign: FHIPT09011 WHU June 22, 2010

If the main movement direction has been determined from the camera images, and it is additionally taken into account that the object is moving on the ground, the direction of the earth's gravitational force z. B. determined by the fact that they are perpendicular to

Main movement direction runs. In addition, the direction of gravity may be determined using the information that the persons and objects apparently passing by the object as seen by the camera or cameras are at least partially fixedly positioned on the ground. At least in the time average, this results in the horizontal. Another way to determine the gravitational direction that can be combined with the ones mentioned above is to use knowledge of the type of motion the object is performing. For example, when walking, the hip of a person moves in a certain way relative to

Main direction of movement (the direction of movement of the person's center of gravity in this case). The frequency of the superimposed movement of the hip or of another body part or object part in relation to the frequency of at least one other part of the object or of the person also provides information from which the direction of the gravitational field of the earth can be determined. On the mentioned

Frequency ratios will be discussed in more detail with reference to the accompanying figures.

For example, a camera to be used to analyze a person's walking motion may be attached to a belt (eg, around the waist or waist of the person

circumferential belt). Does the camera capture the

Main movement direction, as mentioned above, can be accurately detected on the person moving persons or objects with the camera images.

In particular, with a wide detection angle of the camera but also persons or objects are detected, which move past the person walking.

Motion analysis is of interest for a variety of applications. For articles, e.g. by tracing the accelerometer readings the movement of the object can be traced. This is conceivable, for example, for luggage. When evaluating the acceleration measured values, the speed and then the distance covered by the object can be calculated by integration over time. In order to provide the acceleration measurement values for a period of interest, the mentioned unit may be e.g. a suitable one

dimensioned data store in which the measured values are stored. Our sign: FHIPT09011WO June 22, 2010

For persons, e.g. the movement of the foot while running are analyzed (see also DE 10 2005 004 086 A1, which deals with the topic in more detail). Other uses in persons are the monitoring of physical activity, e.g. in persons suffering from diabetes or obese persons. In addition, by means of the 3D sensors in fall-prone persons a fall can be determined. The 3D sensor can be combined with a corresponding evaluation unit, e.g. to determine the calorie consumption or the fall. In animals, e.g. in nocturnal animals and / or pets can be determined by analyzing the movement, which is measured with the help of the 3D sensor, where the animal has been or whether the animal has behaved according to species.

Analysis methods for analyzing the motion for the respective purposes are known and will be described herein only with reference to application examples. For example, can be determined when attaching the 3D sensor on the shoe, whether the

Walking or running movement of a person to be corrected by special design of the shoe. Further details are described in DE 10 2005 004 086 A1. To determine the calorie consumption, the measured movement can be compared with known movement patterns. For example, a classification of a movement phase takes place and becomes dependent on the result of the classification

decided whether the person has moved or was moved himself and which calorie count or energy the person has consumed in their own movement. Not only can the calorie consumption be determined depending on the type of movement (e.g., walking, running, swimming, rowing, cycling, and the like), but also the actually measured movement information can be additionally used. In particular, the acceleration values can therefore not only for

Classification of the movement but also to evaluate the movement, e.g. be evaluated for determining the calorie consumption per time interval. From the acceleration readings, it is possible to determine whether the person was running fast or cycling slowly, cycling up or down a mountain, or swimming swiftly or slowly.

Regarding the transformation of the acceleration measurements from the

Coordinate system of the 3D sensor in a suitable other coordinate system can be deduced from DE 10 2005 004 086 A1, that a direction of the transformed, second Our sign: FHIPT09011WO June 22, 2010

Coordinate system is the direction of the weight of the object. If the object is at rest, the direction of the weight force can be directly measured from the measured

Determine acceleration values of the three sensors, since the direction of the weight corresponds to the direction of the acceleration vector of the gravitational field. But even as the object moves with the attached 3D sensor, the direction of the weight force can be determined. Preferably, time intervals of the acceleration measured values are evaluated and the direction of the gravitational force or of the acceleration vector of the gravitational field is determined by temporal averaging.

Embodiments will be described.

However, the transformed coordinate system is not yet uniquely determined by the direction of the weight. The two perpendicular coordinate axes can still be freely selected. At least one direction is still needed to define the second coordinate system. DE 10 2005 004 086 A1 proposes to carry out two so-called initial measurements. For this purpose, a movement of the object is carried out with the attached 3D sensor. By evaluating the motion, the second direction, i. the direction of another coordinate axis of the

transformed coordinate system determined.

After the initial measurements, the measuring operation can begin to detect movements of the moving object. The prerequisite is, however, that the orientation of the 3D sensor relative to the moving object does not change. Disadvantageous in the

DE 10 2005 004 086 A1 described method is therefore that for the

Transformation of the coordinate system Initial measurements are required. Such measurements take time and may therefore be forgotten. In particular, when the movement behavior of persons is to be measured continuously, the person will not be willing to perform initial measurements again and again. For example, For example, the 3D sensor can be integrated into an electronic device that carries the person on the body. When the person has used the electronic device and puts it back in a bag or holder worn on the person's body, the orientation of the 3D sensor with respect to the person changes. But even with animals or objects the repeated execution of initial measurements in many cases is not practical.

It is therefore an object of the present invention to provide a method and a device for analyzing movements of objects with which the previously Our sign: FHIPT09011 WHU June 22, 2010

mentioned disadvantages are overcome. In particular, it should be possible to get along without initial measurements that do not belong to the actual motion to be analyzed. Furthermore, the scope of the present invention is included

Computer program for performing the method on a computer or

Computer system and a disk on which the program is stored, in particular in the form of digital data.

The present invention is based, in particular, on the idea that in the evaluation of movements it is possible to resort to information about previous movements and / or information about types of movement. A comparison of the motion to be analyzed with such information is known in particular as pattern recognition per se. Depending on the comparison, as already mentioned above, the motion to be analyzed can be classified. For this purpose, a plurality of predefined classes may exist, one of which is determined for the classification of the movement. The information can be present in various ways and the comparison can accordingly be carried out in various ways. For example, can a

Frequency analysis of one or more components of the measured using the 3D sensor acceleration vector can be performed. When walking or walking a person it is e.g. characteristically that the frequency of going right-to-left accelerations is one-half the frequency of the fore-and-aft accelerations when the 3D sensor is worn around the person's hip. The area of the hip is a common place of wear. For example, For example, the 3D sensor may be worn on a belt or on the waistband, or it may be integrated with a device worn there. Also, the placement of the 3D sensor in a trouser pocket places him in the hip area.

It is now proposed to do the pattern recognition not or not only for the purpose of evaluating the movement, but to determine the direction of the second axis of the transformed coordinate system. The direction of the first axis of the second coordinate system runs in the direction of the gravitational field and is determined from the measured values of the 3D sensor. If this is the speech of the first and the second coordinate axis of the transformed coordinate system, this serves only to uniquely identify the axes. An order and thus a specific orientation of the transformed coordinate system is not defined. Our sign: FHIPT09011WO June 22, 2010

As mentioned, the pattern recognition can take place in very different ways.

Illustrated clearly is the direction of the second axis of the transformed

Coordinate system into which the acceleration measurements are transformed, the direction of a particular, excellent direction of motion. Excellent is the direction by features typical of the movement. For example, When walking a person, it makes sense to refer to the forward direction the person walks in as an excellent direction of movement. This excellent direction of movement is also referred to as the main movement direction or main movement axis. However, it is not absolutely necessary to select the forward direction as the direction of the second axis of the transformed coordinate system when walking. For example, The right-to-left direction running perpendicular thereto and likewise perpendicular to the direction of the gravitational field could also be selected as the direction of the second coordinate axis. It is only important to always choose the same direction for the second coordinate axis for similar movements. This makes it possible, in particular, to compare the movements with each other or to evaluate them at least in the same way.

If it is said that a pattern recognition is performed to determine this direction, then this need not be done in the context of a classification, i. E. done by determining a movement type. Rather, it is sufficient to determine the direction with the aid of information about a movement other than the movement to be analyzed. The direction, e.g. the main direction of movement, can be defined in relation to the other movement. For example, the other movement can also be one

Be walking. If it is known that the movements in terms of

Movement type can match or equal each other, using the

Information about the other movement the direction defined for it as second

Direction are transferred to the motion to be analyzed. Thus, the second direction is also fixed for the motion to be analyzed and can transform the motion measurements from the measurement coordinate system to the transformed one

Coordinate system are performed.

In particular, the following is proposed:

A method for analyzing movements of objects, in particular objects, persons or other living beings, wherein acceleration measurement values Our sign: FHIPT09011 WHU June 22, 2010

with respect to three orthogonal axes of a first one

Coordinate system and where:

 the acceleration measurement values are transformed into a second coordinate system,

 for the transformation into the second coordinate system from the

 Acceleration measurements the direction of a gravitational field is determined in which the movement takes place or took place,

 the direction of the gravitational field is chosen as the direction of a first axis of the second coordinate system,

 the direction of a second axis of the second coordinate system from a comparison of the acceleration measurements or derived therefrom

 Movement information on the one hand with existing information about another movement or a movement type on the other hand is determined.

In humans, the transformed coordinate system may in many cases be defined as the person or a characteristic area of the person (e.g., the hip) as a fixed coordinate system. However, depending on the type of movement, it may happen that the part of the body to which the 3D sensor is attached has a rotational component of motion, so that it moves in the body

Align gravitational field differently. In this case, it is preferred that the motion to be analyzed be subdivided into different time periods, in each of which a different transformed coordinate system is selected. The transitions between these periods are characterized by the moments of rotation

Movement component defined.

Since the orientation of the body part, relative to which the 3D sensor is positioned on the body, can vary continuously within certain limits, the direction of the first coordinate axis of the transformed coordinate system, i. the coordinate axis, which is to be aligned in the direction of the gravitational field, not exactly defined. Nevertheless, with the transformation of the acceleration measurement values into the transformed coordinate system, the result obtained is much better and more accurately evaluable if the direction of the first coordinate axis is determined by determining a gravitational acceleration vector averaged over a period of time.

More generally, therefore, motion measurements are continuously or continuously evaluated over the course of the motion to be analyzed to determine the direction of the motion Our sign: FHIPT09011 WHU June 22, 2010

Determine gravitational field and set the first axis of the second coordinate system. Preferably, for continuous evaluation

Movement measured values are evaluated in each case in a sliding manner over a period of time, in particular averaged, whereby the time period in each case at a current time of the

Motion measurement ends and goes back to the past. In particular, this slidingly shifting period, which in each case is based on the current time of the movement measurement, can always be the same length. For example, in the case of motion measured values with a constant sampling rate of the sensors, an equal number of consecutive measured values is always evaluated. During the averaging, the measured values distributed over the evaluation period can be weighted equally or differently. This depends in particular on the type of movement.

The averaging over the evaluation period to the direction of the first

Coordinate axis of the transformed coordinate system to determine, but not only has the above-mentioned advantage. In addition, information about the movement can be obtained from a rotation of this direction with respect to the measurement coordinate system. It can thus be easily recognized, for example, that movements were carried out before and after the rotation according to different types of movement.

The motion information for the second axis detection derived from the acceleration measurements may be e.g. to act at the speed of the movement, from the direction of which in a simple way results in an excellent direction of movement to a frequency of components of the measured

Acceleration vector or other information that allows for a particular type of movement to determine the direction of the second axis, or the

Determine type of movement.

In contrast to DE 10 2005 004 086 A1, the acceleration measured values used for the comparison are measured values of the motion to be analyzed. These are therefore not measured values of initial measurements. However, it is basically also possible to carry out such initial measurements and to use them for determining the direction of the second axis. However, it should be noted that the initial measurement may be subject to a different type of movement than the actual one

analyzing movement. In other words, the solution according to the invention does not Our sign: FHIPT09011 WHU June 22, 2010

assume that the orientation of the 3D sensor to the movement object does not change between the initial measurement and the actual measurement. Rather, even with such a change in the relative orientation, at least before and after the change, in each case a direction of a second axis of the second coordinate system can be determined directly from the measured data.

In particular, it is therefore possible to carry out the comparison and the transformation into the second coordinate system after completion of the movement to be analyzed. In the case of initial measurements, on the other hand, first, before the actual measurement begins, the second direction must be determined in order to determine the transformed coordinate system. In fact, if it later turns out that the initial measurement was unsuccessful, e.g. because certain requirements have not been met, the whole may be too

analyzing motion not in the manner described in DE 10 2005 004 086 A1 are evaluated.

Embodiments of the present invention will now be described with reference to the accompanying drawings. The individual figures of the drawing show:

Fig. 1: schematically a 3D acceleration sensor, the Cartesian

 Coordinate system of the sensor and a transformed coordinate system,

2 shows schematically a device for analyzing movements of objects, the figure also illustrating the method according to the invention in the manner of a flow chart,

 FIG. 3 is a diagram showing acceleration measurements with two components in an approximately horizontal plane when a person is walking, with the SD acceleration sensor carried in the right trouser pocket; FIG.

 4 shows measured values for a movement as in FIG. 3, but with the SD acceleration sensor in the left trouser pocket, FIG.

 5 shows movement measurements similar to those of FIG. 3 and FIG. 4, but with the sensor worn on the belt buckle in the hip region of the person, FIG.

 Fig. 6 is a diagram illustrating two components of measured acceleration values in an approximately horizontal plane, the movement taking place in that the person carrying the sensor in a

Road car drives. Our sign: FHIPT09011WO June 22, 2010

Fig. 1 shows a 3D sensor S, which is shown as a cube and three

Has acceleration sensors. These three sensors measure the components of the overall acceleration vector in the direction of the three coordinate axes x, y, z of a Cartesian coordinate system resting with respect to the sensor.

With g the gravitational acceleration vector of a gravitational field is designated, in which the sensor S is located. The direction of the acceleration vector g coincides with the direction of the coordinate axis x ', which is the first coordinate axis of a transformed coordinate system. The other coordinate axes of the

transformed coordinate system are denoted by y 'and z' and shown in Fig. 1 by dashed lines with an arrow at the end of the line. The measured values of the measurement coordinate system x, y, z are labeled A1 (x-axis), A2 (y-axis) and A3 (z-axis). These readings are sensor acceleration readings.

The sensor S may e.g. be integrated into an electronic device and / or be attached to the moving object.

2 shows a preferred embodiment of a device for analyzing the movement on the basis of 3D acceleration measured values of a 3D sensor. The sensor S may be e.g. to act the sensor of FIG. 1.

As shown schematically on the left in FIG. 2, the 3D sensor S has three individual acceleration sensors 15a, 15b, 15c which repeat, in particular cyclically at constant time intervals, measured values of the acceleration with respect to the three axes of a Cartesian coordinate system x, y, z (eg of the non-transformed

Coordinate system of FIG. 1) measure. The measured value A1 of the sensor 15a is e.g. the measured value of the x-axis, the measured value A2 of the sensor 15b, the measured value of the y-axis and the measured value A3 of the sensor 15c, the measured value with respect to the z-axis.

Via a signal connection between the sensor S and a determination device 10, the measured values A1, A2, A3 are transmitted to the device 10. The signal connection can be realized wirelessly and / or wired. Also, further devices or units may be arranged between the SD sensor S and the device 10, Our sign: FHIPT09011WO June 22, 2010

e.g. a processing device for processing the raw measured values of the sensors 15a, 15b, 15c (for example in order to correct systematic measuring errors and output corresponding corrected measured values to the device 10). Also, the 3D sensor S may be e.g. in a common assembly (e.g., an electronic device, e.g.

Mobile telephone) with a radio transmission device for transmitting the measured values A1, A2, A3 be installed. In the embodiment of FIG. 2, the device 10 would be in this case with a corresponding receiving device for receiving the

Radio signals combined. But it is also possible that the device 10 is installed in the same unit as the 3D sensor S. The same applies to the other devices shown in Fig. 2, will be discussed in more detail. Either all the devices shown in Fig. 2 may be installed in a common unit (e.g., the mentioned electronic device) or the boundary (e.g.

Radio interface) of the structural unit of the 3D sensor between the latter and the device 10, between the device 10 and the device 12 or between the device 12 and the device 14.

The determination device 10 determines from the acceleration measurement values A1, A2, A3 the direction of a gravitational field in which the movement of a movement object takes place on which the 3D sensor S is arranged. An embodiment of how the determination is made will be discussed in more detail. The thus determined direction of the gravitational field outputs the device 10 together with the measured values A1, A2, A3 as the direction of the first coordinate axis x ^{1 of} the transformed coordinate system to the device 12, which is a comparison device.

The comparison device 12 has access to a data memory 11, in which

Information about another movement or about a movement type are stored. The comparison device 12 determines the direction of a second axis y ^{1 of} the transformed coordinate system from a comparison of the acceleration measured values A1, A2, A3 or movement information derived therefrom on the one hand with the information stored in the data memory 11.

In the embodiment described here, the comparison device 12 also takes over the coordinate transformation. An embodiment of such

Coordinate transformation will be described in more detail. At an exit of the

Comparator 12 are therefore in the second, transformed Our sign: FHIPT09011 WHU June 22, 2010

Coordinate system x ', y ", z' transformed acceleration measurements R1, R2, R3 These transformed measured values are fed to an analysis device 14, which analyzes the movement on the basis of the transformed measured values

Analyzer 14, which energy has consumed a person for the movement, which was measured by taking the measured values A1, A2, A3.

In addition to the transformed measured values R, the comparison device 12 can also output further information to the analysis device 14, in particular the

Information about which type of movement or which movement types are involved in the measured movement. For example, can the comparison device 12 a

Perform motion pattern recognition, i. Identify patterns characteristic of a particular type of motion in the measured motion. From this, the comparison device determines, as mentioned, the direction of the second axis of the

transformed coordinate system. The information thus obtained about the

Movement type and optionally also the above-mentioned main axis of motion transmits them to the analysis device 14, which therefore no longer has to perform a pattern recognition. The analyzer 14 may use the motion type information immediately upon the actual analysis of the motion. For example, is the

Calorie consumption for movement 0, if it determines from the movement type that the person did not move himself, but was moved.

An embodiment for the coordinate transformation will now be described.

There is a transformation of the acceleration measured values from the Cartesian coordinate system x, y, z of the measuring sensor (output coordinate system) into the transformed coordinate system x ', y', z '. The transformed axis x 'corresponds to the direction of the acceleration vector of the earth's gravitational field.

The vector

points in the direction of the acceleration vector of the gravitational field and is already normalized, ie has the value 1. Its in the column notation one above the other Our sign: FHIPT09011WO June 22, 2010

standing components gl, g2, g3 are components in the output coordinate system. If there is no acceleration other than acceleration due to gravity, the components are the measured values of the three individual acceleration sensors of the 3D sensor. The vector

/ = y ₂ denotes the second coordinate axis of the transformed coordinate system. This vector is to be determined using information about another movement or type of movement, eg pattern recognition. Its components y1, y2, y3 are also related to the output coordinate system. If an arbitrary vector x is defined first, which is perpendicular to the vector x ', the following applies:

0

 In this case, the components of the vector 3c are chosen such that its magnitude is 1. For the vector z 'in the direction of the third coordinate axis of the transformed

Coordinate system applies:

The equation gives the cross product of the vectors x ', y'. For a measured vector

whose components m1, m2, m3 are acceleration measurements in the initial coordinate system, the following relationships hold: ml = <m-x, y> = (ml-xl) * yl + (m2-x2) * y2 + (ni3-x3) * y3

= (ml-xl) * x2 + (m2-x2) * (- xl) Our sign: FHIPT09011 WHU June 22, 2010

m2 = <mx, x> = (ml-xl) * xl + (m2-x2) * x2 + (m3-x3) * x3 m3 = <mx, z> = (ml-xl) * zl + (m2-x2 ) * z2 + (m3-x3) * z3

 = (ml-xl) * (- xl * x3) + (m2-x2) * (- x2 * x3) + (ni3-x3) * (x2 * x2 + xl * xl)

Here means <> the scalar product of vectors, which are separated in the brackets by a comma, "mx" is a difference of the vectors m and x. Using this normalization, a measurement vector is generated without the influence of gravity. The character ^* is the multiplication sign ,

The vector x 'is determined from the measured movement. These are the

Components of the vector averaged over time, whereby current measured values are weighted into the averaging calculation. The vector x 'with the components x1, x2 x3 can be calculated as an example as follows: x ^Λ ' new = a "* 'm" ^■ 2 * ^• + ^ h ^υ * ^Λ x' old '

ie the value x ' _{new of} the current processing cycle is equal to the sum of the summands weighted with the factors a and b, where the summands are the component m2 of the current measured value in the direction of x' and the value x \ _{lt of} the preceding processing cycle.

Here, a and b are to be chosen such that their sum a + b is equal to 1. The parameters a and b are preferably selected as a function of the sampling frequency of the 3D sensor (the so-called sampling rate). For example, a = 0.01 has been proven for the 20 Hz sampling rate.

An essential advantage of the present invention is that through the

Transformation taking into account information about another movement or a type of movement in the actual analysis of the movement, a higher accuracy can be achieved because an unexpected, incorrect or changed orientation of the 3D sensor is detected with respect to the moving object and taken into account in the transformation becomes.

The following is an example of movements. Our sign: FHIPT09011WO June 22, 2010

FIG. 3 shows the measured values of a running movement of a person in the plane which is perpendicular to the direction of the acceleration vector of the gravitational field. The horizontal axis of the coordinate system in Fig. 3 is oriented approximately in the left / right direction of the running motion, i. approximately perpendicular to the actual direction of travel. The vertical axis in FIG. 3 is therefore approximately in the forward / backward direction of FIG

Aligned running movement. It should be noted that the 3D sensor was in the pocket of the person while walking, i. E. was located in the hip area. Therefore, the 3D sensor did not directly measure the movement of the center of mass, but was located laterally from the center of mass. Characteristic of the running movement is in such a case that the 3D sensor certain

Performing movement cycles, from which one can see in which trouser pocket the sensor was located, right or left of the center of mass. Shown in FIG. 3 and the following figures are lines which each connect two temporally successive measured values of the 3D sensor. The measured values are therefore at the points where the line sharply kinks. In addition, in FIG. 3 and the following figures, in each case the main axis of movement is represented by a straight line, which corresponds to the direction of the second coordinate axis of the transformed coordinate system.

During the movement that underlies the measured values in FIG. 3, the 3D sensor was in the right trouser pocket of the person. Fig. 4 shows a running movement, in which the sensor was in the left trouser pocket. It can be seen in FIG. 3 that the connecting lines between the measuring points in their overall image are similar to FIG. Since the 3D sensor in the pocket on which the 3D sensor is based was located on the opposite side, the lines in FIG. 4 form a mirrored 9 about a vertical axis.

Fig. 5 shows acceleration measurements while walking the person, but in contrast to the movements of Figs. 3 and 4, the 3D sensor was carried in the center of the body in front of the center of mass on the belt buckle of a belt worn in the hip area.

The main axis of movement drawn in FIGS. 3 and 4 as well as in FIG. 5 was determined by means of a frequency analysis. The information about the

Movement type "running" is used, according to which the frequency of the right / left motion is half the frequency of the forward / backward movement. For example, for a Our sign: FHIPT09011 WHU June 22, 2010

assumed alignment of the coordinate system in the plane right / left and forward / back, as e.g. is shown in Figures 3 and 4, determined by Fourier transformation, how well this ratio of twice as large or half as large motion frequency is met. This degree of fulfillment is evaluated by a number. This procedure is repeated for other orientations of the right / left and forhead / back coordinate system and the agreement with the double frequency principle is again evaluated. The optimum found thereby, i. the alignment of the coordinate system with the best score is taken as the correct orientation. The direction forwards / backwards is the

Main movement direction and thus the direction of the second coordinate axis of the transformed coordinate system.

Fig. 6 shows measured values of a 3D sensor which was worn by a person while the person was driving in a road vehicle.

In the case of passive movement of an object in a road vehicle, the main axis of motion may be through the characteristic, with the aid of the 3D sensor

measured movement patterns are detected. When determining the type of motion, there is a high probability that acceleration operations will be from rest in the direction of the main axis of motion. Equally likely is that delays to a halt also in the direction of

Show main axis of movement. The main axis of motion is therefore preferably determined taking into account these high probabilities. Due to the resulting knowledge of the axial position is one example. able to better identify the road situation (highway, country road, driving in urban areas, etc.). In principle, the "driving" type of movement is recognized, for example, by evaluating the ratio of the horizontal acceleration to the vertical acceleration and comparing it with a typical value for this movement pattern, and identifying a vibration typical of driving, for example, by varying the vibration frequencies of the vehicle Moving objects are identified as frequencies typical for driving a car.

Claims

Our sign: FHIPT09011 WO 22 June 2010 Claims

1. A method for analyzing movements of objects, in particular of objects, persons or other living beings, wherein

 Acceleration measured values with respect to three orthogonal axes of a first coordinate system (x, y, z) are present and wherein:

 the acceleration measurement values (A1, A2, A3) are transformed into a second coordinate system (x \ y ', z'),

 for the transformation into the second coordinate system (x ', y', z ') from the

 Acceleration measurements (A1, A2, A3) the direction of a

 Gravitational field is determined in which the movement takes place or took place,

the direction of the gravitational field is chosen as the direction of a first axis (x ¹ ) of the second coordinate system (x ', y', z '),

- The direction of a second axis of the second coordinate system (x ¹ , y ', z') from a comparison of the acceleration measured values (A1, A2, A3) or derived motion information on the one hand with existing information about another movement or a movement type on the other hand is determined ,

2. Method according to the preceding claim, wherein for the comparison

 used acceleration measurements (A1, A2, A3) are measured values of the motion to be analyzed.

3. The method according to any one of the preceding claims, wherein the comparison and the. Transformation into the second coordinate system (x ¹ , y ', z') are carried out after completion of the motion to be analyzed.

4. The method according to any one of the preceding claims, wherein over the course of the motion to be analyzed repeatedly or continuously

Accelerometer readings (A1, A2, A3) are evaluated to determine the direction of the gravitational field and the first axis (x ¹ ) of the second

Coordinate system (x ¹ , y ', z') to choose. Our sign: FHIPT09011WO June 22, 2010

5. The method according to the preceding claim, wherein the continuous

 Evaluation motion measured values (A1, A2, A3) are each evaluated in a sliding manner over a period of time, in particular in each case an average of the

 Movement measured values (A1, A2, A3) is calculated, the period ends at a current time of the motion measurement and in the

 Past returns.

6. The method according to claim 1, wherein for measuring the acceleration measured values, the surroundings of the object are detected optically, wherein in the case of optical detection a camera arranged on the object acquires in each case an image of the surroundings in chronological sequence and from there the

 Accelerometer readings are determined.

7. Computer program that is configured, the method according to one of

 preceding claims, when the computer program is executed on a computer or computer system.

8. Disk on which the computer program after the previous one

 Claim is stored such that it is loadable into the main memory of the computer or computer system or is readable and executable directly on the disk by the computer or computer system.

9. Device for analyzing movements of objects, in particular of objects, persons or other living beings, wherein

 Acceleration measured values (A1, A2, A3) with respect to three orthogonal axes of a first coordinate system (x, y, z) are present and

 - The device comprises a transformation device (10, 12), the

 is configured to transform acceleration measurement values (A1, A2, A3) into a second coordinate system (x \ y ', z'),

 - The transformation means (10,12) comprises a detection means (10) which is designed for the transformation into the second

Coordinate system (x ¹ , y ', z') from the acceleration measurement values (A1, A2, A3) to determine the direction of a gravitational field in which the movement takes place or took place, Our sign: FHIPT09011WO June 22, 2010

- The transformation means (10,12) is configured, the direction of

Gravitational field as the direction of a first axis (x ¹ ) of the second coordinate system (x ', y', z '),

 the transformation device (10, 12) has a comparison device (12)

which is configured, the direction of a second axis of the second coordinate system (x ^ι , y ', z') from a comparison of

 Accelerometer readings (A1, A2, A3) or derived therefrom

 Determine motion information on the one hand with existing information about another movement or a type of movement on the other hand.

10. Device according to the preceding claim, wherein for the of the

 Comparison device (12) used comparison

 Accelerometer readings (A1, A2, A3) Measurements of the motion being analyzed.

11. Device according to one of the preceding claims, wherein the device is equipped, the comparison and the transformation into the second

Coordinate system (x ¹ , y ', z') to perform after completion of the motion to be analyzed.

12. Device according to one of the preceding claims, wherein the

 Detection device (10) has an evaluation device that is configured, repeated over the course of the motion to be analyzed or

continuously evaluate acceleration measurements (A1, A2, A3) to determine the direction of the gravitational field and to select the first axis (x ¹ ) of the second coordinate system (x ¹ , y ', z').

13. Device according to the preceding claim, wherein the

 Determining means (10) is configured for continuous evaluation to evaluate motion measured values (A1, A2, A3) each sliding over a period of time, in particular to calculate a mean value of the movement measured values (A1, A2, A3), wherein the period is in each case at a current

Time of the movement measurement ends and goes back to the past. Our sign: FHIPT09011 WHU June 22, 2010

14. Device according to one of the preceding claims, wherein the device has an analysis device (14) which is designed, at least one

 Movement of an object whose acceleration measurement values (A1, A2, A3) have been transformed by the transformation device (10, 12) into the transformed coordinate system, wherein the analysis device (14) is connected to an output of the transformation device (10, 12) ,

15. Device according to one of the preceding claims, wherein the device further comprises a 3D acceleration sensor for measuring the

 Acceleration measured values, wherein the 3D acceleration sensor is configured to measure the acceleration of the object by the optical detection of the environment, and wherein in the optical detection, an object-oriented camera of the 3D acceleration sensor detects images of the environment in a temporal sequence and an evaluation device from it the

 Acceleration measured values determined.