DE102017126981A1 - SYSTEM AND METHOD FOR DETERMINING A PASSAGE OF A MOBILE OBJECT THROUGH AN INTERESTING AREA OF A MONITORED LEVEL, AND MOVABLE OBJECTS - Google Patents

Abstract

A system is proposed for determining a passage of a moving object through a region of interest of a monitored plane. The system includes a first excitation loop configured to generate a first magnetic excitation field. The first magnetic excitation field is set up to excite the movable object for the expression of a first magnetic response field. Further, the system includes a second excitation loop configured to generate a second magnetic excitation field. The second magnetic excitation field is set up to excite the movable object for the expression of a second magnetic response field. The system further includes a first sensor arranged in a first detection plane parallel to the monitored plane and arranged to determine first measurements for the first magnetic response field. In addition, the system includes a second sensor which is arranged and arranged in a second detection plane, which runs parallel to the monitored plane, to determine second measured values for the second magnetic response field. The system further includes an evaluation circuit configured to display, based on the first measurement values, a first result indicating at least partial passage of the movable object through the first detection plane, and based on the second measurement values, a second result including at least partial passage of the second result indicates the moving object through the second detection plane.

Description

Technical area

The present disclosure is concerned with the localization of objects. In particular, embodiments relate to a system and method for determining a passage of a moving object through a region of interest of a monitored plane. Further embodiments also relate to movable objects.

background

In many fields of application, it is necessary to be able to know or to determine the position of a mobile object. The determination of a position of a movable object may be required, for example, in the sports sector in order to know or determine the position of a game device, for example. For example, it may be necessary to determine if a ball or puck has crossed a goal line.

According to regulations, a goal can only be scored in various sports if the game device has completely passed the goal line. For spherically symmetric sports equipment, such as footballs, the rotation or orientation of the sports equipment is not decisive for determining whether it has crossed a goal line. In non-ball-symmetric (i.e., ball-unbalanced) sports equipment, such as pucks, on the other hand, achieving a goal is both a matter of position and orientation and shape of the game machine.

Thus, there is a need to provide a way to accurately locate a non-spherical symmetric moving object.

Summary

Embodiments of a system for determining a passage of a moving object through a region of interest of a monitored plane make this possible. The system includes a first excitation loop configured to generate a first magnetic excitation field. The first magnetic excitation field is set up to excite the movable object for the expression of a first magnetic response field. Further, the system includes a second exciter loop configured to generate a second magnetic exciter field. The second magnetic excitation field is set up to excite the movable object for the expression of a second magnetic response field. The system further comprises a first sensor, which is arranged and arranged in a first detection plane, which runs parallel to the monitored plane, to determine first measured values for the first magnetic response field. In addition, the system comprises a second sensor, which is arranged and arranged in a second detection plane, which runs parallel to the monitored plane, to determine second measured values for the second magnetic response field. The system further comprises an evaluation circuit, which is set up, based on the first measurement values, a first result, which indicates an at least partial passage of the movable object through the first detection plane, and based on the second measurement values, a second result, which at least a partial passage of the indicates the moving object through the second detection plane.

Further embodiments further relate to a method for determining a passage of a mobile object through a region of interest of a monitored plane. The method includes generating a first magnetic excitation field. The first magnetic excitation field is set up to excite the movable object for the expression of a first magnetic response field. Furthermore, the method comprises generating a second magnetic exciter field. The second magnetic excitation field is set up to excite the movable object for the expression of a second magnetic response field. The method further comprises determining first measured values for the first magnetic response field by means of a first sensor, which is arranged in a first detection plane that runs parallel to the monitored plane. In addition, the method comprises determining second measured values for the second magnetic response field by means of a second sensor, which is arranged in a second detection plane which runs parallel to the monitored plane. Likewise, the method comprises determining a first result indicating an at least partial passage of the movable object through the first detection plane, based on the first measured values. The method further comprises determining a second result indicative of at least partial passage of the movable object through the second detection plane based on the second measurement values.

Also, embodiments relate to a moving object comprising three mutually orthogonal coils having a first resonant frequency and a fourth coil having a second resonant frequency. The three mutually orthogonal coils are arranged to impart a first component of a magnetic response field in response to a magnetic excitation field. The fourth coil is configured to impart a second component of the magnetic response field in response to the magnetic excitation field.

Embodiments further relate to yet another movable object comprising three mutually orthogonal first coils having the same first resonant frequency and three mutually orthogonal second coils having the same second resonant frequency. The first three coils are configured to impress a first component of a magnetic response field in response to a magnetic field. The three second coils are arranged to express a second component of the magnetic response field in response to the magnetic excitation field.

list of figures

• 1 zeigt ein Ausführungsbeispiel eines Systems zum Bestimmen eines Durchgangs eines beweglichen Objekts durch einen interessierenden Bereich einer überwachten Ebene;
• 2 zeigt ein Ausführungsbeispiel eines beweglichen Objekts aus dem Bereich des Sports;
• 3 zeigt ein weiteres Ausführungsbeispiel eines beweglichen Objekts aus dem Bereich des Sports;
• 4 zeigt ein Ausführungsbeispiel einer Reflexionscharakteristik einer Spule;
• 5 zeigt ein weiteres Ausführungsbeispiel eines Systems zum Bestimmen eines Durchgangs eines beweglichen Objekts durch einen interessierenden Bereich einer überwachten Ebene aus dem Bereich des Sports; und
• 6 zeigt ein Ablaufdiagramm eines Ausführungsbeispiels eines Verfahrens zum Bestimmen eines Durchgangs eines beweglichen Objekts durch einen interessierenden Bereich einer überwachten Ebene.

Some examples of devices and / or methods will now be explained in more detail by way of example only with reference to the attached figures. Show it:

• 1 shows an embodiment of a system for determining a passage of a moving object through a region of interest of a monitored plane;
• 2 shows an embodiment of a movable object in the field of sports;
• 3 shows a further embodiment of a movable object in the field of sports;
• 4 shows an embodiment of a reflection characteristic of a coil;
• 5 shows another embodiment of a system for determining a passage of a moving object through a region of interest of a monitored plane from the area of the sport; and
• 6 FIG. 13 is a flowchart of one embodiment of a method for determining a passage of a moving object through a region of interest of a monitored plane.

description

Various examples will now be described in more detail with reference to the accompanying figures, in which some examples are shown. In the figures, the strengths of lines, layers and / or regions may be exaggerated for clarity.

Accordingly, while other examples of various modifications and alternative forms are suitable, certain specific examples thereof are shown in the figures and will be described in detail below. However, this detailed description does not limit further examples to the specific forms described. Other examples may cover all modifications, equivalents, and alternatives that fall within the scope of the disclosure. Like reference numerals refer to like or similar elements throughout the description of the figures, which may be identical or modified in comparison with each other while providing the same or similar function.

It should be understood that when an element is referred to as being "connected" or "coupled" to another element, the elements may be connected or coupled directly, or via one or more intermediate elements. If two elements A and B are combined using a "or", it is to be understood that all possible combinations are disclosed, ie only A , just B such as A and B , An alternative formulation for the same combinations is "at least one of A and B ". The same applies to combinations of more than 2 elements.

The terminology used to describe certain examples is not intended to be limiting of other examples. If a singular form, e.g. For example, "one, one" and "the one that is used" and the use of only a single element is not explicitly or implicitly defined as mandatory, other examples may also use plural elements to implement the same function. If a function is described below as implemented using multiple elements, further examples may implement the same function using a single element or a single processing entity. It is further understood that the terms "comprising," "comprising," "having," and / or "having" in use, include the presence of the specified features, integers, steps, operations, processes, elements, components, and / or a group thereof but do not preclude the existence or addition of one or more other features, integers, steps, operations, processes, elements, components, and / or a group thereof.

Unless otherwise defined, all terms (including technical and scientific terms) are used herein in their ordinary meaning in the field to which examples belong.

1 shows a system for determining a passage of a moving object 190 through an area of interest 181 a monitored level 180 ,

With the moving object 190 it can be any object that is in space and can generate or generate a magnetic response field in response to a magnetic excitation field. For example, the moving object 190 be a coil or a coil system or include such. With the moving object 190 For example, it may be a sports device (eg, ball, puck, ball, football) that includes a component (element, device) that can generate or generate a magnetic response field in response to a magnetic field. For example, the moving object may be a ball, a puck, or a football that includes a spool. In particular, the object may be both spherically symmetric and globally asymmetric (ie, not spherically symmetric).

The monitored level 180 is an extended, substantially uncurved (ie non-curved) surface which is monitored. A subset of this is the area of interest 181 passing through the boundary lines 182 and 183 in 1 is indicated. The boundary lines 182 and 183 indicate two horizontal boundaries of the region of interest 181 within the monitored level 180 on. It goes without saying that the area of interest 181 also in the vertical direction within the monitored plane 180 is limited. Due to the representation of the system 100 as a lateral cut this is in 1 but not shown. In the area of interest 181 it is an area of interest within the monitored level 180 , The area of interest 181 can basically have any flat shape (eg rectangle, circle or freeform). In the area of interest 181 it may, for example, be the area enclosed by a goal line, the goal post and the goal crossbar of a goal (hereinafter also referred to as goal plane). Alternatively, it may be in the area of interest 181 For example, also act on the surface that extends vertically from a playing field. For example, the area at the position of an edge of a line mounted on the playing field may extend perpendicularly from the playing field (eg side line, goal line or other line on the playing field according to the regulations of the respective sport).

system 100 includes a first exciter loop 110 (and optionally further first exciter loops) arranged and arranged in a first exciter plane, a first magnetic exciter field 111 to create. The exciter loop 110 consists of a conductive material, which is traversed by an electric current. The first magnetic excitation field 111 is set up, the moving object 190 for expressing a first magnetic response field 191 to stimulate. The first magnetic excitation field 111 can be any magnetic field, which is the moving object 190 can stimulate the expression of a magnetic response field. For example, the first magnetic exciter field may be 111 to act a magnetic alternating field. The first magnetic excitation field 111 may include one or more frequency components. That is, the first exciter loop 110 can be set up, the first magnetic exciter field 111 to produce with field components at different frequencies. Also, a frequency of the magnetic exciter field may vary. The first exciter level, in which the first exciter loop 110 is arranged parallel to the monitored plane 180 and is spaced therefrom.

Furthermore, the system includes 100 a second exciter loop 120 (and optionally further second exciter loops) arranged and arranged in a second exciter plane, a second magnetic exciter field 121 to create. Also the second exciter loop 120 consists of a conductive material, which is traversed by an electric current. The second magnetic exciter field 121 is set up, the moving object 190 for expressing a second magnetic response field 192 to stimulate. Like the first magnetic excitation field 111 can also be the second magnetic excitation field 121 every magnetic field that is the moving object 190 can stimulate the expression of a magnetic response field. Furthermore, the second exciter loop can also be used 120 be furnished, the second magnetic excitation field 121 to produce with field components at different frequencies. The second exciter level, in which the second exciter loop 120 is arranged parallel to the monitored plane 180 and is spaced therefrom. The first and second exciter planes are also spaced apart.

The first exciter loop 110 and the second exciter loop 120 can be traversed by the same exciter current or by different exciter currents. This can be done by the system 100 For example, an exciter circuit (not shown) configured to apply the same excitation current to the first exciter loop 110 and the second exciter loop 120 apply or different exciter currents to the first exciter loop 110 and the second exciter loop 120 to apply. If the first exciter loop 110 and the second exciter loop 120 are traversed by the same excitation current, they can be connected, for example, in series. Alternatively, the excitation currents for the first exciter loop 110 and the second exciter loop 120 each have their own characteristic. The characteristic may be, for example, an individual (time-dependent) amplitude, phase position or frequency. Accordingly, the first and / or the second magnetic exciter field 111 or. 121 be modulated. The direction of the excitation currents through the individual excitation loops can be the same or also out of phase (eg by 180 °). Likewise, the first and / or the second magnetic excitation field 111 or. 121 A sequence can be impressed on the exciter currents. For example, the sequences may be orthogonal to each other so that they are distinguishable from each other.

The system 100 further comprises at least a first sensor 130 which is in a first detection level 101 parallel to the monitored plane 180 runs, is arranged. The first sensor 130 is set up, first measurements for the first magnetic response field 191 of the moving object 190 to determine. The first readings for the first magnetic response field 191 represent the state of the first magnetic response field 191 at the measuring position. For example, the first measured values may be the amplitude and / or the phase of the first magnetic response field 191 indicate at the measuring position. To the first magnetic response field 191 to measure, the sensor can 130 For example, include one or more receiving antennas. A voltage induced in the receiving antenna is proportional to the local amplitude and / or phase of the first magnetic response field 191 at the measuring position. For example, the first sensor 130 a first antenna and a second antenna. The longitudinal axis of the first antenna extends in the first detection plane 101 and the first antenna is perpendicular through the first detection plane. The longitudinal axis of the second antenna also extends in the first detection plane 101 , wherein and the second antenna is perpendicular to the first antenna (ie in the first detection plane 101 ) runs. Alternatively, for example, a Hall sensor or any other suitable magnetometer can be used to obtain the first measured values for the first magnetic response field 191 to determine.

In addition, the system includes 100 at least one second sensor 140 that is in a second detection plane 102 parallel to the monitored plane 180 runs, is arranged. The second sensor 140 is set up, second measured values for the second magnetic response field 192 to determine. The second measurements for the second magnetic response field 192 represent the state of the second magnetic response field 192 at the measuring position. The second sensor 140 can be as above for the first sensor 130 be executed described. The second detection level 102 is from the first detection level 101 spaced.

The system further comprises an evaluation circuit 150 that with the sensors 130 and 140 is coupled. evaluation 150 is established based on the first measurements of the first sensor 130 a first result, the at least partial passage of the movable object 190 through the first detection plane 101 indicating to determine. Furthermore, the evaluation circuit 150 established based on the second measured values of the second sensor 140 a second result, the at least partial passage of the movable object 190 through the second detection plane 102 indicating to determine.

The at least partial passage of the movable object 190 through the first detection plane 101 For example, it can be calculated from the phase of the first magnetic response field (measured by means of the first measured values) 191 in the first detection plane 101 be determined - for example, based on the phase in the first antenna of the first sensor 130 induced voltage due to the first magnetic response field 191 , The phase undergoes a phase change, ie the phase goes through the zero or the sign of the phase changes, if, for example, the center of the first magnetic response field 191 generating coil or such a coil system in the moving object 190 through the first detection plane 101 occurs. Regardless of which position the moving object 190 the first detection level 101 traverses, the phase change always takes place exactly at the position of the first detection plane 101 (ie in the first detection plane 101 ). In a phase change can therefore on the penetration of the first detection level 101 by a coil or a coil system in the moving object 190 and thus an at least partial penetration of the first detection plane 101 through the moving object 190 be closed (due to the knowledge of the positioning of the coil (s) within the mobile object 190 ). Accordingly, the at least partial passage of the movable object can also be used for the second detection plane 190 through the second detection plane 102 be determined.

Thus, for each detection level 101 . 102 individually determines whether the moving object 190 this has at least partially penetrated. The determination of the passage of the moving object 190 through the individual detection levels 101 . 102 which are from the monitored level 180 spaced apart, it is possible to determine with high accuracy whether the moving object is also the monitored plane 180 in the area of interest 181 completely crossed.

In other words: the evaluation circuit 150 is further set up, the complete passage of the movable object 190 by the interested party 181 the monitored level 180 based on the first result and the second result.

This can include the position and orientation of the moving object 190 (or the coil or the coil system in the moving object 190 ) at each passage through one of the detection planes 101 . 102 be taken into account. For determining the position of the moving object 190 when passing through the first detection plane 101 (ie the two-dimensional position in the first detection plane 101 ), for example, the waveforms in the antennas of the first sensor 130 induced voltages are considered. For example, from the maximum amplitude or its distance to the zero crossing of the signal to the distance of the moving object 190 (or the coil or the coil system in the moving object 190 ) to the first sensor 130 getting closed. The orientation of the moving object 190 (or the coil or the coil system in the moving object 190 ) can eg by means of a comparison of the first magnetic response field 191 (or a component thereof) with reference measured values (eg from a simulation). Accordingly, position and orientation of the moving object 190 when passing through the second detection plane 101 be determined.

In an at least partial passage of the movable object 190 through the first detection plane 101 Thus, the first result may be a first position and a first orientation of the moving object 190 when passing through the first detection plane 101 include. Likewise, in an at least partial passage of the movable object 190 through the second detection plane 102 the second result is a second position and a second orientation of the movable object 190 when passing through the second detection plane 102 include.

From the determined positions and orientations of the moving object 190 when passing through the detection levels 101 . 102 can now change the position and orientation of the moving object 190 relative to the area of interest 181 the monitored level 180 getting closed. The position or the distance of the detection planes 101 . 102 to the monitored level 180 is also known as the arrangement of the magnetic response field generating device in the moving object 190 (Eg one or more coils or one or more coil systems) and the shape of the moving object 190 , Accordingly, together with the first result and the second result by the evaluation circuit 150 the exact position and orientation of the moving object 190 relative to the area of interest 181 the monitored level 180 be determined. This allows the evaluation circuit 150 to decide if the moving object 190 the area of interest 181 the monitored level 180 completely crossed. In particular, this can also be the case for spherically unbalanced (ie non-spherically symmetric) moving objects 190 be determined whether this is the area of interest 181 the monitored level 180 completely crossed. This also makes it possible for ballunsymmetrical sports equipment such as pucks to determine whether this has eg completely exceeded a physical goal line.

Although previously only on the first detection level 101 and the second detection plane 102 Reference has been made to the system 100 optionally also include further detection levels as well as further exciter levels. This can be an accuracy of the decision as to whether the moving object 190 the area of interest 181 the monitored level 180 completely crossed, increase.

For example, the system can 100 and a third exciter loop disposed in a third exciter plane and configured to generate a third exciter magnetic field. The third magnetic excitation field is set up, the moving object 190 to stimulate the expression of a third magnetic response field. Furthermore, the system can 100 comprise at least a third sensor, in a third detection plane parallel to the monitored plane 180 is arranged and arranged to determine third measured values for the third magnetic response field. Accordingly, the evaluation circuit 150 Further, based on the third measurement values, a third result may be set up, which is an at least partial passage of the movable object 190 indicating by the third detection plane. Analogous to the first result and the second result can be at an at least partial passage of the movable object 190 the third result, by the third detection plane, comprises a third position and a third orientation of the movable object when passing through the third detection plane.

Likewise, the evaluation circuit 150 then further be set up, the complete passage of the movable object 190 by the interested party 181 the monitored level 180 based on the first result, the second result and the third result.

As already indicated above, the moving object can 190 have a plurality of coils or coil systems which the magnetic response fields of the mobile object 190 produce. In this context, some possible embodiments with respect to the coils are described in more detail below. It goes without saying, however, that the proposed Localization is not limited to the subsequent, specifically described coil configurations.

For example, the moving object 190 comprise at least two mutually orthogonal coils with different resonance frequencies. When the moving object 190 a sports device (game device), for example, three arbitrarily shaped coils can be arranged in the sports equipment. Each of the three coils is distinguishable by a respective resonant tuning to different frequencies. The excitement of the primary field (eg the first exciter field 111 and the second exciter field 121 ) now takes place in parallel on the three different resonance frequencies of the coils. That is, the exciter loops generate the magnetic exciter fields with field components at different frequencies.

Accordingly, each of the (at least two, eg three) distinguishable or differently tuned coils then physically characterizes a different secondary field amplitude. Relative to the first magnetic response field 191 A first coil of the at least two mutually orthogonal coils then correspondingly impresses a first component of the first magnetic response field 191 while a second coil of the at least two mutually orthogonal coils comprises a second component of the first magnetic response field 191 expresses. If a third coil with a third resonant frequency is used, this will impress a third component of the first magnetic response field 191 out. This also applies to the second magnetic response field 192 (and more magnetic response fields).

To compute (add) these (at least two, eg three) secondary fields, the fields are scaled or calibrated so that each of the coils is virtually attributed a similar behavior. So can the evaluation circuit 150 further be configured, a first measured value for the first component of the first magnetic response field 191 to scale, a first reading for the second component of the first magnetic response field 191 and optionally a first measurement for the third (or another) component of the first magnetic response field 191 to scale.

Thus, the (at least two, eg three) individual coil fields can be added as if identical coils were in the moving object 190 vorlägen. Correspondingly, the position determination can be carried out, for example, according to the approach for goal decision known from the GoalRef technique of the Fraunhofer Institute for Integrated Circuits. In the GoalRef magnetic field-based goal decision system, the center point of a passive orthogonal coil system is detected when passing through a virtual goal plane. In the spherically symmetric ball three identically constructed, mutually orthogonal introduced coils are installed. In these passive coils, a current is induced by the primary field (excitation field), which in turn expresses a secondary field (response field). The three coils are each resonantly tuned to the same frequency, with the aim that all coils behave electrically the same. It is thereby achieved that these current-carrying coils in total express a (secondary) independent of the rotation of the ball, secondary field, which always points geometrically at the location of the ball in the direction of the primary field. Thus, the secondary field is largely independent of the rotation of the ball. Antennas mounted around the gate detect the secondary fields of the ball, thereby closing the ball passing through the virtual plane of the goal. By scaling the components of the magnetic response fields of the magnetic object 190 can virtually also a substantially rotation independent secondary field of the moving object 190 be generated. From the summed (and scaled) fields of the (at least two, eg three) coils of the moving object 190 can thus be closed to the two-dimensional position in the passage through the respective detection plane.

Relative to the first detection level 101 can the evaluation circuit 150 thus be further configured, a first position of the movable object 190 when passing through the first detection plane 101 based on a combination of the scaled first measurement value for the first component of the first magnetic response field 191 and the scaled first measurement value for the second component of the first magnetic response field 191 to determine. Accordingly, a second position of the movable object 190 when passing through the second detection plane 102 and optionally also other positions of the movable object 190 be determined during the respective passage through further detection levels.

On the basis of the above position estimation, it is now also possible to determine the orientation of the coil or the moving object 190 be determined during each passage through one of the detection levels. By separately considering the (at least two, eg three) coil fields, their orientation can be determined for each coil. Since the position of the coils or the coil system is known, for example, with the help of (simulated) secondary field strengths for different orientations of a coil or the moving object 190 when passing through a detection plane at a certain position, the actual orientation of a coil or the moving object 190 be determined. These reference measurements can be in the form of a Fingerprint table be stored, on which the evaluation circuit 150 can access.

Relative to the first detection level 101 can the evaluation circuit 150 Thus, further configured, an orientation of the first coil based on the scaled first measurement value for the first component of the first magnetic response field 191 and the first position of the moving object 190 when passing through the first detection plane 101 to determine. Furthermore, the evaluation circuit 150 be configured, an orientation of the second coil based on the scaled first measurement value for the second component of the first magnetic response field 191 and the first position of the moving object 190 when passing through the first detection plane 101 to determine. Accordingly, the evaluation circuit 150 also the orientation of other coils of the moving object 190 when passing through the first detection plane 101 determine. The evaluation circuit 150 can then continue to be set up, an orientation of the moving object 190 when passing through the first detection plane 101 based on the orientation of the first coil and the orientation of the second coil. This also applies accordingly to the second detection level 102 and optional further detection levels of the system 100 ,

It can now with the calculation of the above-described (at least two, for example three) calibrated received signals to the passage of the moving object 190 (For example, a sports or game device) through the virtual detection levels (which can be spanned, for example, by an exciter wire, ie, a detection plane can be identical to an exciter plane) are closed. At the same time, the orientation can then be calculated if the moving object 190 crosses the plain.

The construction of multiple detection levels (which can also be understood as virtual goal levels when used for the goal decision) makes it possible to unambiguously and accurately determine whether, for example, an asymmetrical moving object 190 with its circumference has crossed the monitored plane representing a physical true plane. For example, it can be determined whether a game device has completely traversed the physically true goal plane with its circumference. As already indicated above, a detection plane can be constructed in each case from a current loop, for example, mounted around the gate, and antennas which are orthogonal to this plane. Each exciter loop receive antenna system on its own decides, in accordance with the principles set forth above, whether the center of the gaming device has crossed the respective virtual goal plane. During each passage of the game device, the two-dimensional position is first estimated on the basis of the calibrated sum reception signals of the (at least two, eg three) coils. Subsequently, the orientation of each of the (at least two, eg three) coils is estimated at a known position. Finally, a check is made as to whether the estimated position and the subsequently estimated orientation have achieved a regular goal or not.

Another possible embodiment of the movable object with respect to the coils is in 2 shown. 2 shows a moving object 200 in the form of a puck, ie a ballunsymmetric sports equipment. The representation of the moving object 200 in the form of a puck is for illustration only. In the 2 Spool configuration shown is not on this shape of the moving object 200 limited. Rather, the moving object 200 generally have any shape.

To clarify the arrangement of the coils, the moving object is in 2 shown four times. For reasons of clarity, only one of the coils is shown in each of the representations of the movable object.

The moving object 200 comprises three mutually orthogonal coils 210 . 220 and 230 with a first resonant frequency and a fourth coil 240 with a second resonant frequency.

The three mutually orthogonal coils 210 . 220 and 230 are configured to impart a first component of a magnetic response field in response to a magnetic excitation field. The fourth coil 240 is configured to impart a second component of the magnetic response field in response to the magnetic excitation field. Based on the first magnetic excitation field described above, the three mutually orthogonal coils thus form a first component of the first magnetic response field and the fourth coil embosses a second component of the first magnetic response field.

The fourth coil 240 and one of the three mutually orthogonal coils 210 . 220 and 230 extend in the same or in parallel planes. This is in 2 exemplary for the coil 210 shown, which are in the same plane as the fourth coil 240 located. In the example of 2 are the (geometric) centers of the first coil 210 and the fourth coil 240 not in the middle (ie the geometric center) of the moving object 200 , In alternative embodiments, the first coil 210 and the fourth coil 240 however, also be arranged so that their centers are in the middle of the moving object 200 are located.

2 thus shows an alternative to the above-described, tuned to different frequencies coils. In the 2 embodiment shown uses a "classic" coil system of three on the same frequency and otherwise equally matched, mutually orthogonal coils. This embodiment can also be incorporated into a ball-unbalanced game machine. With these coils, namely, the classic detection of the passage of the unbalanced game object can be implemented by a virtual plane spanned (ie detection level) according to the GoalRef technology. The fourth, on a different frequency tuned, coil 240 in the play object it allows, with the help of its secondary field, for the orientation of the object 200 close. The fourth coil 240 is in the plane of one of the remaining three coils 210 . 220 or 230 installed (alternatively, the coil 240 but also be installed in a parallel plane). These two coils have only a partial overlap with each other to allow tuning of these two coils to different frequencies.

For a play device in the form of a puck, this coil arrangement is in 2 shown. Here, only the fourth coil 240 tuned to its own resonant frequency, while the remaining three coils 210 . 220 and 230 oscillate at a common resonant frequency as in the classic GoalRef approach. The field characteristics of the three coils 210 . 220 and 230 (ie their components of the magnetic response field) are used for the determination of the rotationally independent passage through a detection plane and for the two-dimensional localization of the object in the detection plane, while the field of the remaining fourth coil 240 for orientation determination is taken.

When using the in 2 shown movable object 200 as a moving object 190 can the evaluation circuit 150 related to the first detection level 101 thus be further configured, a first position of the movable object 190 when passing through the first detection plane 101 based on a first measurement for the first component of the first magnetic response field 191 to determine. Furthermore, the evaluation circuit 150 be set up, an orientation of the moving object 190 when passing through the first detection plane 101 based on the first position of the moving object 190 and a first measured value for the second component of the first magnetic response field 191 to determine. This also applies accordingly to the second detection level 102 and optional further detection levels of the system 100 ,

Another possible embodiment of the movable object with respect to the coils is in 3 shown. 3 shows a moving object 300 again in the form of a puck, ie a ballunsymmetric sports equipment. The representation of the moving object 300 in the form of a puck is for illustration only. In the 3 Spool configuration shown is not on this shape of the moving object 300 limited. Rather, the moving object 300 generally have any shape.

The moving object 300 comprises three mutually orthogonal first coils 310 with the same first resonant frequency and three mutually orthogonal second coils 320 with the same second resonant frequency. Optionally, the moving object 300 comprise further coil systems at further resonance frequencies. For example, the moving object 300 three mutually orthogonal third coils 330 with the same third resonant frequency and three mutually orthogonal fourth coils 340 with the same fourth resonant frequency.

The first three coils 310 are configured to impart a first component of a magnetic response field in response to a magnetic excitation field. The three second coils 320 are configured to express a second component of the magnetic response field in response to the magnetic exciter field. Further coil systems are set up accordingly. Relative to the first magnetic exciter field described above 111 characterize the three first coils 310 thus a first component of the first magnetic response field 191 off and the three second coils 320 characterize a second component of the first magnetic response field 191 out.

In the example of 3 Thus, several (at least two) three-dimensional coil systems are introduced into an example game device. These coil systems each consist of three mutually orthogonal, electrically equal behaving individual coils. The three coils of each of these three-dimensional coil systems are tuned to the same resonant frequency. These different coil systems tuned to different frequencies 310 . 320 . 330 and 340 are at known positions in the moving object 300 brought in. The passage through a detection plane can only for each of these 3D coil systems 310 . 320 . 330 and 340 according to the principles described above, provided that the excitation loop expresses a magnetic field at that frequency (ie a field component of the magnetic exciter field at the respective resonance frequency). Similarly, the position of each coil systems 310 . 320 . 330 and 340 be determined during the passage through the respective detection level. from that can with the knowledge of the positions of the coil systems 310 . 320 . 330 and 340 in / on the moving object 300 the orientation of the moving object 300 be determined.

When using the in 3 shown movable object 300 as a moving object 190 can the evaluation circuit 150 related to the first detection level 101 thus further be set, a position of the first three coils 310 based on a first measurement for the first component of the first magnetic response field 191 to determine as well as a position of the three second coils 320 based on a first measurement value for the second component of the first magnetic response field 191 to determine. Furthermore, the evaluation circuit 150 be set, a first position and a first orientation of the movable object 300 when passing through the first detection plane 101 based on the position of the first three coils 310 and the position of the three second coils 320 to determine. As already described above, the evaluation circuit can be set up here, the first position and the first orientation of the movable object 300 when passing through the first detection plane 101 based on the arrangement of the three first coils 310 and the three second coils 320 in the moving object 320 to determine. This also applies accordingly to the second detection level 102 and optional further detection levels of the system 100 ,

It has been described above that coils arranged in the moving object can be tuned to the same or different resonance frequencies. When tuning the coils to a particular resonant frequency, it may be due to e.g. However, production-related tolerances happen that the desired resonance frequency can not be set exactly.

However, in order to allow the best possible localization of the coils, they should be operated as possible at their resonance frequency. Therefore, according to some embodiments of the present technology, the frequency of the primary field (i.e., the magnetic excitation field) can be matched to the coil resonance.

For this purpose, the respective coil resonance frequency is first determined (for example by means of a frequency sweep / frequency sweep of the primary field). The response signal of the coils measured in the sensors (e.g., receiving antennas or other magnetic field sensors) is then analyzed. At the resonant frequency of the coil, the response field of the resonant coil is strongest. This frequency is now chosen as one of the operating frequencies for the magnetic exciter field.

Related to the in 1 illustrated first exciter loop 110 For example, this can be set up, a frequency of the first magnetic exciter field 111 to change according to a frequency sweep. Accordingly, the evaluation circuit 150 further be set, a resonance frequency of a coil of the movable object 190 based on a first reading for the first magnetic response field 190 to determine. Furthermore, the evaluation circuit 150 be set up, the first exciter loop 110 to control, the first magnetic exciter field 111 with a field component at the resonant frequency of the coil of the moving object 190 to create.

As described above, the moving object 190 Coils at different resonant frequencies include. Accordingly, the evaluation circuit 150 further be set, a second resonant frequency of a second coil of the movable object 190 based on another first reading for the first magnetic response field 191 to determine. Accordingly, evaluation circuit 150 be further established, the first exciter loop 110 to control, the first magnetic exciter field 111 further comprising a field component at the resonant frequency of the second coil of the moving object 190 to create.

As noted above, the GoalRef technique can be used to talk about the passage of the moving object 190 decide by a detection level. The GoalRef technique, however, assumes a spherically symmetrical body with three orthogonal, electrically identical coils that form a predominantly rotation-independent field (if they are tuned to the same frequency). If the three coils are tuned to one frequency, they can no longer be individually separated in the software in the receiver and therefore can not be calibrated to compensate for their different physical effects.

The body to be detected, ie the moving object 190 , does not have to be spherically symmetric (eg puck). This has the effect that the quality of all (eg three) coils is unequal (when using coils with even number of turns). Accordingly, the sum secondary field of the (eg three) orthogonal coils would now no longer point in the direction of the primary field, which would have the effect that no precise goal decision, regardless of the orientation of the moving object 190 , could take place.

To compensate for this, for example, the number of turns of each of the (eg three) coils can be adjusted so that the quality of all 3 coil resonant circuits is electrically equal. For example, that can The product of the number of turns and the coil area of each individual coil should be the same. Also, for example, by means of additional series resistances on a coil, the quality can be damped so that all (eg three) coils behave electrically the same. The electrically same behavior can eg be tested on a network analyzer by checking the reflection factor of a coil. This reflects the course of the coil quality and should also show the same behavior in the same coils for the three coils. An exemplary course is in 4 shown. Both phasing (ie the sign of the phase) and amplitude at the operating frequency is the same for all coils.

Relative to the first magnetic excitation field 111 can thus any coil of the moving object 190 be arranged in the same position and orientation relative to the first magnetic exciter field 111 a component of the first magnetic response field 191 with a first amplitude and a first phase position when the frequency of the first magnetic excitation field 111 a first predetermined frequency is (eg, the resonant frequency of the respective coil).

In addition, it may be helpful for the purpose of filtering the interference object to observe the difference of the magnetic response field of the coils for two (or more) different frequencies of the magnetic exciter field. This is in the German patent application with the file number 10 2016 120 246.0, the contents of which are incorporated herein by reference, in detail. In order to be able to use this method, a further adaptation of the coil characteristic can take place. In this case, at two different frequencies, the coils would exhibit a certain behavior in terms of amplitude and phase position, so that the difference signal of the magnetic field responses at two defined different frequencies is the same for all coils.

Relative to the first magnetic excitation field 111 can thus any coil of the moving object 190 be arranged in the same position and orientation relative to the first magnetic exciter field 111 a component of the first magnetic response field 191 with a second amplitude and a second phase position when the frequency of the first magnetic excitation field 111 a second predetermined frequency

Transfer to the in 2 Spool configuration shown would be each of the three mutually orthogonal coils 210 . 220 and 230 arranged to generate, at the same position and orientation relative to the exciter magnetic field, a component of the first component of the magnetic response field having a first amplitude and a first phase position when the frequency of the first magnetic exciter field is a first predetermined frequency (eg, the resonant frequency of the respective coil) is. Optionally, each of the three orthogonal coils would be 210 . 220 and 230 further configured to generate, at the same position and orientation relative to the magnetic exciter field, a constituent of the first component of the magnetic response field having a second amplitude and a second phase position when the frequency of the first magnetic exciter field is a second predetermined frequency.

Transfer to the in 3 Spool configuration shown would be each of the first three coils 310 arranged to generate, at the same position and orientation relative to the exciter magnetic field, a component of the first component of the magnetic response field having a first amplitude and a first phase position when the frequency of the first magnetic exciter field is a first predetermined frequency (eg, the resonant frequency of the respective coil) is. Optionally, each of the first three coils would be 310 arranged to generate at the same position and orientation relative to the magnetic exciter field a component of the first component of the magnetic response field having a second amplitude and a second phase position when the frequency of the first magnetic exciter field is a second predetermined frequency. Accordingly, the three second coils would be 320 and set up further coil systems.

Referring to the principles of the proposed localization technology set forth above 5 an exemplary structure for goal decision.

On a playing surface (a floor) 570 is a gate arranged in which 5 through a goalpost 580 is indicated. To score, you must have a game machine 590 (eg a puck) completely pass the goal line, which extends between the goal posts of the gate.

To detect this, the proposed localization technology can be used. The supervised level corresponds to the plane spanned by the goal and goal posts of the goal and the goal line. The region of interest also corresponds to the goal plane, i. the area enclosed by the goal and goal posts of the goal and the goal line.

This in 5 shown system uses three exciter loops 510 . 520 and 530 behind the goal line or goalpost 580 are arranged and each adapted to generate a respective magnetic excitation field, wherein each of the three magnetic exciter fields is arranged, the play equipment 590 to stimulate the expression of an associated magnetic response field.

Furthermore, the system comprises at least three sensors 540 . 550 and 560 (eg antennas), each of which is in a respective detection plane 501 . 502 or. 503 , each parallel to the monitored plane (represented by the goal post 580 ), is arranged. The through the three exciter loops 510 . 520 and 530 defined exciter levels are identical to the detection levels 501 . 502 or. 503 , Accordingly, the at least three sensors 540 . 550 and 560 each set up, measured values for the associated magnetic response field of the game device 590 to determine.

An evaluation circuit (not shown) now determines based on the respective measured values of the at least three sensors 540 . 550 and 560 a respective result for each of the detection levels, the at least a partial passage of the game device 590 indicated by the respective detection level. According to the in 5 The situation thus presented would be the results for the first and second detection levels 501 or. 502 each indicate that the game device 590 has at least partially penetrated these levels. The results for the first and second detection levels 501 or. 502 in each case further the respective position and the respective orientation of the game device 590 when passing through the first and the second detection plane 501 or. 502 Show. The result for the third detection level 503 would indicate that the game device 590 this level has not at least partially penetrated.

Based on the first result and the second result, the evaluation circuit now determines whether a complete passage of the gaming device 590 through the goal plane (represented by the goalpost 580 ) or not. At the in 5 Thus, the evaluation circuit would determine that there is no complete passage of the non-spherically symmetric gaming machine 590 through the goal level.

According to 5 Thus, embodiments also include a gate (eg, an ice hockey goal) having a system for determining a passage of a moving object through a region of interest of a monitored plane according to the proposed technique. The area of interest then corresponds to the goal plane defined by the goal frames and the goal line. Accordingly, an automatic and reliable goal decision (especially for ballunsymmterische play equipment) are made possible.

It goes without saying that the described methods are not limited to an application in ice hockey. It can be determined according to the principles set out above, the passage of any sports equipment by a plane. Purely by way of example, reference is made here to the determination of a passage of the game ball in football, handball, American football, beach soccer, water polo, street hockey, hockey, lacrosse or any other ball sport.

To summarize the above described aspects of locating moving objects, see 6 a flowchart of a method 600 for determining a passage of a mobile object through a region of interest of a monitored plane.

method 600 includes generating 602 a first magnetic excitation field. The first magnetic excitation field is set up to excite the movable object for the expression of a first magnetic response field. Further includes method 600 a generate 604 a second magnetic excitation field. The second magnetic excitation field is set up to excite the movable object for the expression of a second magnetic response field. method 600 further comprises determining 606 of first measured values for the first magnetic response field by means of a first sensor, which is arranged in a first detection plane which runs parallel to the monitored plane. It also includes procedures 600 a determination 608 of second measured values for the second magnetic response field by means of a second sensor, which is arranged in a second detection plane which runs parallel to the monitored plane. Likewise, method includes 600 a determination 610 a first result indicating at least partial passage of the movable object through the first detection plane based on the first measurement values. method 600 further comprises determining 612 a second result indicating at least partial passage of the movable object through the second detection plane based on the second measurement values.

Further details and aspects of the method as well as the movable object are described above in connection with further embodiments (eg 1 and 5 ). The method as well as the moving object may include one or more optional features according to the further embodiments.

Thus, some embodiments of the present disclosure relate to matched coil systems that provide both high accuracy goal decision and orientation determination based on the principles GoalRef system, but with arbitrarily shaped play equipment.

According to some embodiments, e.g. three coils are resonantly tuned to different frequencies, the individual coil contributions (e.g., in software) calibrated and located in the usual way with calibrated signals, and the orientation estimated. In this case, a set-up of a plurality of virtual goal lines (i.e., detection levels) connected in series is used. In some embodiments, the resonance characteristic of the coil resonant circuit is adapted to the coil geometry. Other embodiments include detecting the resonant frequency of the coils and adjusting the operating frequencies to the coil characteristics. Alternatively, a fourth coil may also be used in parallel with one of the already existing three coils tuned to the same frequency. The shape of the fourth coil can be adapted to each other because of the coupling of the coils. Thus, three equal coils can be used for position determination while the fourth coil is used for orientation estimation. In a further alternative approach, distributed three-dimensional coils are used in the game device for orientation determination by determining the position of the individual three-dimensional coils.

1. 1) Ein System mit mehreren geometrisch hintereinander angebrachte Erregerschleifen und Empfangs-Antennen (Magnetfeldmesssensoren).
2. 2) Ein System mit einer zusätzliche vierte Spule, abgestimmt auf eine andere Frequenz, zur Orientierungsschätzung.
3. 3) Ein Konzept wie die elektrischen Eigenschaften von Spulen zu dimensionieren sind, damit eine optimierte Positions- und Orientierungsschätzung möglich ist.
4. 4) Ein Konzept wie aus der Positions- und Orientierungsschätzung eines nicht kugelrotationssymmetrischen Körpers auf die Torentscheidung geschlossen werden kann.
5. 5) Ein Konzept wie man einen nichtrotationssymmetrischen Körper mit speziell angepassten Spulen bestückt, um eine Torentscheidung durchführen zu können.
6. 6) Ein Konzept wie man Schätzungenauigkeiten durch die fertigungsbedingte Verschiebung der Resonanzfrequenz ausgleichen kann.
7. 7) Ein Konzept mit integrierten verteilten dreidimensionalen Spulen in/auf einem Objekt zur Lokalisierung und Orientierungsschätzung eines Objektes.

Embodiments of the present disclosure thus relate to, inter alia:

1. 1) A system with a plurality of excitation loops mounted geometrically one behind the other and receiving antennas (magnetic field measuring sensors).
2. 2) A system with an additional fourth coil tuned to a different frequency for orientation estimation.
3. 3) A concept of how to dimension the electrical properties of coils so that an optimized position and orientation estimation is possible.
4. 4) A concept that can be deduced from the position and orientation estimation of a non-spherical-rotationally symmetric body on the goal decision.
5. 5) A concept of how to equip a non-rotationally symmetric body with specially adapted coils in order to make a goal decision.
6. 6) A concept of how to compensate for estimation inaccuracies by the production-related shift of the resonance frequency.
7. 7) A concept with integrated distributed three-dimensional coils in / on an object for localization and orientation estimation of an object.

The aspects and features described in conjunction with one or more of the previously detailed examples and figures may also be combined with one or more of the other examples to substitute the same feature of the other example or in addition to the feature in the other example introduce.

The description and drawings depict only the principles of the disclosure. In addition, all examples provided herein are expressly intended to be instructive only to assist the reader in understanding the principles of the disclosure and the concepts for advancing the art contributed by the inventor (s). All statements herein about principles, aspects and examples of the disclosure as well as concrete examples thereof include their equivalents.

It should be understood that the disclosure of a plurality of steps, processes, operations, or functions disclosed in the specification or claims is not to be construed as being in any particular order unless explicitly or implicitly otherwise indicated, for example. B. for technical reasons. Therefore, the disclosure of multiple steps or functions does not limit them to any particular order unless such steps or functions are not interchangeable for technical reasons. Further, in some examples, a single step, function, process, or operation may include and / or break into multiple sub-steps, functions, processes, or operations. Such sub-steps may be included and part of the disclosure of this single step, unless explicitly excluded.

Furthermore, the following claims are hereby incorporated into the detailed description, where each claim may stand alone as a separate example. While each claim may stand on its own as a separate example, it should be understood that while a dependent claim may refer to a particular combination with one or more other claims in the claims, other examples also include a combination of the dependent claim with the subject matter of each other dependent or independent claim. Such combinations are explicitly suggested herein unless it is stated that a particular combination is not intended. Furthermore, features of a claim shall be included for each other independent claim, even if this claim is not made directly dependent on the independent claim.

Claims (34)

A system (100) for determining a passage of a moving object (190) through a region of interest (181) of a monitored plane (180), comprising: a first exciter loop (110) configured to generate a first magnetic exciter field (111), the first magnetic exciter field (111) being arranged to excite the movable object (190) to emit a first magnetic response field (191); a second exciter loop (120) configured to generate a second magnetic exciter field (121), the second magnetic exciter field (121) being arranged to excite the movable object (190) to emit a second magnetic response field (191); a first sensor (130) disposed in a first detection plane (101) parallel to the monitored plane (180) and arranged to determine first measurements for the first magnetic response field (191); a second sensor (140) arranged in a second detection plane (102) parallel to the monitored plane (180) and arranged to determine second measurements for the second magnetic response field (192); and an evaluation circuit (150), which is set up, based on the first measurement values, a first result, which indicates an at least partial passage of the movable object (190) through the first detection plane (101), and based on the second measurement values, a second result, indicates an at least partial passage of the movable object (190) through the second detection plane (102). System after Claim 1 wherein the evaluation circuit (150) is further configured to determine the complete passage of the movable object (190) through the area of interest (181) of the monitored plane (180) based on the first result and the second result. System after Claim 1 or Claim 2 wherein, in an at least partial passage of the movable object (190) through the first detection plane (101), the first result comprises a first position and a first orientation of the movable object (190) when passing through the first detection plane (101). System according to one of Claims 1 to 3 wherein, in an at least partial passage of the movable object (190) through the second detection plane (102), the second result comprises a second position and a second orientation of the movable object (190) when passing through the second detection plane (102). System according to one of Claims 1 to 4 wherein the system further comprises an exciter circuit configured to: apply the same excitation current to the first exciter loop (110) and the second exciter loop (120); or to apply different exciter currents to the first exciter loop (110) and the second exciter loop (120). System according to one of Claims 1 to 5 further comprising: a third exciter loop configured to generate a third magnetic exciter field, the third magnetic exciter field being configured to excite the movable object (190) to emit a third magnetic response field; and a third sensor disposed in a third detection plane parallel to the monitored plane (180) and arranged to determine third measurements for the third magnetic response field, the evaluation circuit (150) being further configured based on the third one Measured values to produce a third result indicating an at least partial passage of the movable object (190) through the third detection plane. System according to one of Claims 1 to 6 wherein the movable object (190) comprises at least two mutually orthogonal coils having different resonance frequencies, wherein a first coil of the at least two mutually orthogonal coils forms a first component of the first magnetic response field and a second coil of the at least two mutually orthogonal coils forms a second component of the first coil first magnetic response field, and wherein the evaluation circuit (150) is further configured to: scale a first measurement value for the first component of the first magnetic response field; to scale a first reading for the second component of the first magnetic response field; and a first position of the moving object (190) as it passes through the first detection plane (101) based on a combination of the scaled first measurement value for the first component of the first magnetic response field (191) and the scaled first measurement value for the second component of the first magnetic field Response field (191) to determine. System after Claim 7 wherein the evaluation circuit (150) is further arranged: an orientation of the first coil based on the scaled first measurement value for the first component of the first magnetic response field (191) and the first position of the movable object (190) when passing through the first detection plane ( 101); determine an orientation of the second coil based on the scaled first measurement for the second component of the first magnetic response field (191) and the first position of the mobile object (190) as it passes through the first detection plane (101); and determine an orientation of the moving object (190) as it passes through the first detection plane (101) based on the orientation of the first coil and the orientation of the second coil. System according to one of Claims 1 to 6 wherein the movable object (190) comprises three mutually orthogonal coils having a first resonant frequency and a fourth coil having a second resonant frequency, the three mutually orthogonal coils defining a first component of the first magnetic response field (191) and the fourth coil a second component of the first magnetic response field (191), and wherein the evaluation circuit (150) is further configured: a first position of the movable object (190) passing through the first detection plane (101) based on a first measurement value for the first component of the first magnetic field Determine response field (191); and determine an orientation of the moveable object (190) as it passes through the first detection plane (101) based on the first position of the moveable object (190) and a first measurement value for the second component of the first response magnetic field (191). System according to one of Claims 1 to 6 wherein the movable object (190) comprises three mutually orthogonal first coils having the same first resonant frequency and three orthogonal second coils having the same second resonant frequency, the first three coils defining a first component of the first magnetic response field (191) and the three second coils expressing a second component of the first magnetic response field (191), and wherein the evaluation circuit (150) is further configured to: determine a position of the three first coils based on a first measurement value for the first component of the first magnetic response field (191); determine a position of the three second coils based on a first measurement value for the second component of the first magnetic response field (191); and determine a first position and a first orientation of the movable object (190) as it passes through the first detection plane (101) based on the position of the three first coils and the position of the three second coils. System after Claim 10 wherein the evaluation circuit (150) is further adapted to the first position and the first orientation of the movable object (190) when passing through the first detection plane (101) based on the arrangement of the three first coils and the three second coils in the movable object determine. System according to one of Claims 1 to 11 wherein the first excitation loop (110) is arranged to change a frequency of the first magnetic excitation field according to a frequency sweep, and wherein the evaluation circuit (150) is further configured to: a resonance frequency of a coil of the moving object (190) based on a first measurement value for determine the first magnetic response field (191); and controlling the first excitation loop (110) to generate the first magnetic excitation field (111) with a field component at the resonant frequency of the coil of the moving object (190). System after Claim 12 wherein the evaluation circuit (150) is further configured to: determine a second resonant frequency of a second coil of the moving object (190) based on another first measurement value for the first magnetic response field (191); and controlling the first exciter loop (110) to further generate the first magnetic excitation field (111) with a field component at the resonant frequency of the second coil of the moving object (190). System according to one of Claims 1 to 13 wherein the first exciter loop (110) is arranged to generate the first magnetic excitation field (111) with field components at different frequencies. System according to one of Claims 1 to 14 wherein the first sensor comprises a first antenna and a second antenna, wherein a longitudinal axis of the first antenna extends in the first detection plane and the first antenna vertically through the first detection plane (101), wherein a longitudinal axis of the second antenna in the first Detection level runs and the second antenna is perpendicular to the first antenna. System according to one of Claims 1 to 15 wherein each coil of the moving object (190) is arranged to generate a component of the first magnetic response field (191) having a first amplitude and a first phase position at the same position and orientation relative to the first magnetic exciter field (111) when the frequency of the first magnetic exciter field (111) is a first predetermined one Frequency is. System after Claim 16 wherein the first predetermined frequency is the resonant frequency of the respective coil. System after Claim 16 or insert 17, wherein each coil of the movable object (190) is arranged, at the same position and orientation relative to the first magnetic excitation field (111), to a component of the first magnetic response field (191) having a second amplitude and a second phase position generate when the frequency of the first magnetic exciter field (111) is a second predetermined frequency. System according to one of Claims 1 to 18 wherein the movable object (190) is spherically asymmetric. A method (600) for determining a passage of a moving object through a region of interest of a monitored plane, comprising: Generating (602) a first magnetic excitation field, the first magnetic excitation field being arranged to excite the movable object to generate a first magnetic response field; Generating (604) a second magnetic excitation field, the second magnetic excitation field being arranged to excite the movable object to generate a second magnetic response field; Determining (606) first measurements for the first magnetic response field by means of a first sensor disposed in a first detection plane parallel to the monitored plane; Determining (608) second measurements for the second magnetic response field by means of a second sensor located in a second detection plane parallel to the monitored plane; Determining (610) a first result indicative of at least partial passage of the mobile object through the first detection plane based on the first measurements; and Determining (612) a second result indicative of at least partial passage of the mobile object through the second detection plane based on the second measurements. Method according to Claim 20 , further comprising: determining the complete passage of the mobile object through the region of interest of the monitored plane based on the first result and the second result. Mobile object (200) comprising: three mutually orthogonal coils (210, 220, 230) having a first resonant frequency; and a fourth coil (240) having a second resonant frequency, wherein the three mutually orthogonal coils (210, 220, 230) are arranged to impart a first component of a magnetic response field in response to a magnetic excitation field, and wherein the fourth coil (240) is arranged to impart a second component of the magnetic response field in response to the magnetic excitation field. Moving object after Claim 22 wherein the fourth coil (240) and one of the three mutually orthogonal coils (210, 220, 230) extend in the same or in parallel planes. Moving object after Claim 22 or Claim 23 , wherein the movable object is sphere-unbalanced. Moving object according to one of the Claims 22 to 24 , wherein the movable object is a sports device. Moving object according to one of the Claims 22 to 25 wherein each of the three mutually orthogonal coils (210, 220, 230) is arranged to generate at the same position and orientation relative to the magnetic excitation field a constituent of the first component of the magnetic response field having a first amplitude and a first phase position as the frequency of the first magnetic excitation field is a first predetermined frequency. Moving object after Claim 26 wherein the first predetermined frequency is the resonant frequency of the respective coil. Moving object after Claim 26 or Claim 27 wherein each of the three mutually orthogonal coils (210, 220, 230) is arranged to generate, at the same position and orientation relative to the magnetic excitation field, a constituent of the first component of the magnetic response field having a second amplitude and a second phase position as the frequency of the first magnetic excitation field is a second predetermined frequency. Mobile object (300), comprising: three mutually orthogonal first coils (310) having the same first resonant frequency; and three mutually orthogonal second coils (320) having the same second resonant frequency, the three first coils (310) being configured to impress a first component of a magnetic response field in response to a magnetic excitation field, and wherein the three second coils (320) are arranged , in response to the magnetic excitation field, express a second component of the magnetic response field. Moving object after Claim 29 , wherein the movable object is sphere-unbalanced. Moving object after Claim 29 or Claim 30 , wherein the movable object is a sports device. Moving object according to one of the Claims 29 to 31 wherein each of the first three coils (310) is arranged to generate at the same position and orientation relative to the magnetic excitation field a constituent of the first component of the magnetic response field having a first amplitude and a first phase position when the frequency of the first magnetic excitation field is the first predetermined frequency. Moving object after Claim 32 wherein the first predetermined frequency is the resonant frequency of the respective coil. Moving object after Claim 32 or Claim 33 wherein each of the three first coils (310) is arranged to generate, at the same position and orientation relative to the magnetic exciter field, a constituent of the first component of the magnetic response field having a second amplitude and a second phase position when the frequency of the first magnetic exciter field is one second predetermined frequency.

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