EP3292894A1 - Device for measuring the orientation of two skis or two ski boots - Google Patents

Abstract

The device for measuring the orientation of the two skis comprises
first and second sensors configured to provide first and second information relating to the orientation of first and second planes representative of the sole of the first and second skis,
first and second additional sensors configured to provide first and second information relating to the orientation of the longitudinal axes of the first and second skis,
a control circuit configured for
o comparing the orientation of the first plane with the second plane to determine if the first plane is parallel to the second plane,
recording the orientation of the longitudinal axis of the first ski and the orientation of the longitudinal axis of the second ski as corresponding to a configuration where the longitudinal axes are parallel when the first and second planes are parallel.

Description

Technical field of the invention

The invention relates to a device for measuring the orientation of two skis or two ski boots.

State of the art

In the practice of skiing, to identify risk situations, it is important to be able to detect, at each moment, the relative position of the first ski with respect to the second ski, while knowing how to distinguish the right ski from the left ski. In particular, it is important to be able to detect the orientation of the longitudinal axis of a first ski and the orientation of the longitudinal axis of a second ski.

In other words, the detection of risk situations for a skier requires knowing the orientation of the left ski relative to the orientation of the right ski to know for example whether the two skis are parallel or on the contrary if the skis are oriented in such a way as to cross each other or if they deviate from each other. Such teaching is described in the document WO 2014/122366 .

Different possibilities are offered to the skilled person to know the relative orientation of the two skis. First, both skis can be equipped with autonomous devices that is to say they are equipped with all the sensors to determine absolutely the position and orientation of each ski as well as sensors for distinguish ski right and ski left. Under these conditions, the two sets of sensors just have to exchange the information to a control circuit that will calculate which is the right ski and which is the left ski and the orientation of each ski in space. It is then easier to determine if the two orientations of the skis represent configurations at risk or not.

In this context, a simple way to obtain this information is to use a common repository, for example, magnetic north. The document WO 2014/122366 proposes to integrate a magnetometer on a ski in order to know at every moment the orientation of the ski with respect to the magnetic north. In this case, the positions and relative orientations of the first ski relative to the second ski are easier to determine.

However, tests have been conducted and have shown that the use of a magnetometer is not always compatible with the detection of magnetic north as a reference for the orientation of skis. It seems that in some environments, the measurement of the magnetometer is disturbed, for example if metal elements are near the sensor.

In addition, the practice of skiing is performed in difficult conditions, particularly because of vibrations, the wide temperature range encountered during skiing and temperature changes. Using a magnetometer can be difficult.

Object of the invention

• un premier capteur configuré pour être agencé sur un premier ski ou sur une première chaussure de ski, le premier capteur étant configuré pour fournir une première information relative à un premier angle existant entre un premier plan et la verticale, le premier plan étant représentatif de la semelle du premier ski ou de la semelle de la première chaussure de ski,
• un premier capteur additionnel configuré pour être agencé sur le premier ski ou sur la première chaussure de ski, le premier capteur additionnel étant configuré pour fournir une première information additionnelle relative à l'orientation de l'axe longitudinal du premier ski ou de la première chaussure de ski par rapport à un premier référentiel spatial fixe,
• un deuxième capteur configuré pour être agencé sur un deuxième ski ou sur une deuxième chaussure de ski, le deuxième capteur étant configuré pour fournir une deuxième information relative à un deuxième angle existant entre un deuxième plan et la verticale, le deuxième plan étant représentatif de la semelle du deuxième ski ou de la semelle de la deuxième chaussure de ski,
• un deuxième capteur additionnel configuré pour être agencé sur le deuxième ski ou sur la deuxième chaussure de ski, le deuxième capteur additionnel étant configuré pour fournir une deuxième information additionnelle relative à l'orientation de l'axe longitudinal du deuxième ski ou de la deuxième chaussure de ski par rapport au premier référentiel spatial fixe,
• un circuit de commande configuré pour
  • ∘ comparer la valeur du premier angle avec la valeur du deuxième angle,
  • ∘ enregistrer l'orientation de l'axe longitudinal du premier ski ou de la première chaussure de ski et l'orientation de l'axe longitudinal du deuxième ski ou de la deuxième chaussure de ski comme correspondant à une configuration où l'axe longitudinal du premier ski est parallèle à l'axe longitudinal du deuxième ski lorsque la valeur du premier angle est égale à la valeur du deuxième angle.

The object of the invention is to provide a device for measuring the relative orientation of first and second skis or of first and second ski boots which is more robust and / or makes it possible to dispense with magnetometers. The device for measuring the relative orientation of two skis and / or two ski boots is remarkable in that it comprises:

• a first sensor configured to be arranged on a first ski or on a first ski boot, the first sensor being configured to provide a first information relating to a first angle existing between a first plane and the vertical, the first plane being representative of the sole of the first ski or the sole of the first ski boot,
• a first additional sensor configured to be arranged on the first ski or on the first ski boot, the first additional sensor being configured to provide a first additional information relating to the orientation of the longitudinal axis of the first ski or boot ski with respect to a first fixed spatial reference,
• a second sensor configured to be arranged on a second ski or on a second ski boot, the second sensor being configured to provide second information relating to a second angle existing between a second plane and the vertical, the second plane being representative of the sole of the second ski or the sole of the second ski boot,
• a second additional sensor configured to be arranged on the second ski or on the second ski boot, the second additional sensor being configured to provide a second additional information relating to the orientation of the longitudinal axis of the second ski or the second shoe; ski with respect to the first fixed spatial reference,
• a control circuit configured for
  • ∘ compare the value of the first angle with the value of the second angle,
  • ∘ recording the orientation of the longitudinal axis of the first ski or the first ski boot and the orientation of the longitudinal axis of the second ski or the second ski boot as corresponding to a configuration where the longitudinal axis of the ski first ski is parallel to the longitudinal axis of the second ski when the value of the first angle is equal to the value of the second angle.

• ∘ initier un déchaussement de la première chaussure avec le premier ski et/ou le déchaussement de la deuxième chaussure avec le deuxième ski lorsque l'angle entre l'axe longitudinal du premier ski ou de la première chaussure de ski et l'axe longitudinal du deuxième ski ou de la deuxième chaussure de ski atteint une valeur seuil.

In an advantageous variant embodiment, the control circuit is further configured to

• ∘ initiating a loosening of the first shoe with the first ski and / or the loosening of the second boot with the second ski when the angle between the longitudinal axis of the first ski or the first ski boot and the longitudinal axis of the second ski or the second ski boot reaches a threshold value.

It is also interesting to choose that the first additional sensor and the second additional sensor are configured to respectively provide a third additional information relating to the orientation of a second axis of the first ski or the first ski boot with respect to a second fixed spatial reference and a fourth additional information relating to the orientation of a second axis of the second ski or the second ski boot relative to the second fixed spatial reference, the second axis being different from the longitudinal axis of the ski or the ski boot and preferably orthogonal to the longitudinal axis.

• ∘ calculer au moins un paramètre à partir de l'angle existant entre l'axe longitudinal du premier ski et l'axe longitudinal du deuxième ski, de la différence entre le premier angle et le deuxième angle et des troisième et quatrième informations additionnelles,
• ∘ comparer ledit au moins un paramètre à au moins un paramètre seuil,
• ∘ initier un déchaussement de la première chaussure avec le premier ski et/ou le déchaussement de la deuxième chaussure avec le deuxième ski en fonction de la comparaison.

In an advantageous embodiment, the control circuit is further configured to

• ∘ calculate at least one parameter from the angle between the longitudinal axis of the first ski and the longitudinal axis of the second ski, the difference between the first angle and the second angle and third and fourth additional information,
• Comparing said at least one parameter with at least one threshold parameter,
• ∘ initiate a loosening of the first shoe with the first ski and / or the loosening of the second shoe with the second ski according to the comparison.

Advantageously, the second axis of the first ski or the first ski boot is perpendicular to the longitudinal axis and is included in the first plane.

In order to gain compactness and cost, it is advantageous to provide that the control circuit is devoid of information coming from a magnetometer. It is also possible to provide in a particular embodiment that the control circuit is devoid of information from a geolocation system.

It is also advantageous to provide that the control circuit is coupled to an additional sensor measuring the acceleration or the linear speed of the first ski or the first ski boot along its longitudinal axis and that the control circuit is configured to record the the orientation of the longitudinal axis of the first ski or the first ski boot and the orientation of the longitudinal axis of the second ski or the second ski boot as corresponding to a configuration where the longitudinal axis of the first ski is parallel to the longitudinal axis of the second ski when the first angle is equal to second angle if the acceleration or linear speed of the first ski or the first ski boot along its longitudinal axis reaches a threshold value.

In an alternative embodiment, a pressure sensor is connected to the control circuit and is configured to detect the weight of the user on the first ski or on the first shoe, the control circuit being configured to record the orientation of the user. longitudinal axis of the first ski or first ski boot and the orientation of the longitudinal axis of the second ski or the second ski boot as corresponding to a configuration where the longitudinal axis of the first ski is parallel to the longitudinal axis of the second ski when the first plane is parallel to the second plane and when the pressure sensor detects a pressure greater than a threshold pressure.

In a preferred embodiment, the control circuit is further configured to calculate the angle existing between the longitudinal axis of the first ski or the first shoe and the longitudinal axis of the second ski or the second shoe and to define if the first ski is a right ski or a left ski or if the first shoe is a right shoe or a left shoe according to the sign of said angle.

It is advantageous to provide that the first additional sensor is part of the first sensor and the second additional sensor is part of the second sensor.

Brief description of the drawings

• la figure 1 représente, de manière schématique, en vue de dessus deux skis,
• la figure 2 représente, de manière schématique, en vue de coupe deux skis,
• la figure 3 illustre de manière schématique, un protocole de calibration de la position de deux skis.

Other advantages and features will emerge more clearly from the following description of particular embodiments of the invention given by way of non-limiting example and represented in the accompanying drawings, in which:

• the figure 1 represents, schematically, in top view two skis,
• the figure 2 represents, schematically, in view of cutting two skis,
• the figure 3 schematically illustrates a protocol for calibrating the position of two skis.

DESCRIPTION OF PREFERRED EMBODIMENTS OF THE INVENTION

The inventor has observed that the absolute determination of the position of one ski with respect to the other ski and / or the absolute determination of the orientation of one ski with respect to the other ski is not always possible. . Indeed, to be able to determine the relative position of the two skis, it is interesting to know the position of each ski with respect to a fixed spatial reference. This fixed spatial reference system comprises one or more fixed spatial directions which represent reference directions.

It is particularly advantageous to use the vertical as a fixed spatial direction because the measurement can be easily performed by means of gravity. Gravity can be measured using an accelerometer or a gyroscope.

Another interesting spatial direction may be the direction that points to magnetic north. Magnetic north can be determined by means of a magnetometer.

In addition, it is necessary to differentiate the right ski and the left ski to measure the orientation of the right ski relative to the left ski. The differentiation of the right ski with respect to the left ski can be carried out in different ways, for example by means of identification sensors which indicate whether the ski is a right or left ski or which recognize that the associated shoe is a right or left shoe. . However, it is advantageous not to use identification sensors.

It is therefore advantageous to use a device for determining the position of one ski relative to the other ski and / or the orientation of one ski relative to the other ski. It is also advantageous to provide that the device is also configured to discriminate the right ski of the left ski.

It has also been found that the use of a magnetometer determination system also has some disadvantages. The use of a magnetometer makes it possible to define in absolute terms the orientation of a ski. As noted above, if the magnetometer fails or is unable to provide relevant information, it becomes very difficult for the control circuit to distinguish an acceptable situation from a risky situation. The magnetometer may nevertheless be used to adjust an inertial unit, for example of the microelectromechanical system (MEMS) type, which drifts over time, that is to say to readjust the inertial unit.

A simple way of solving this problem may be to impose a calibration step on the user, also called an adjustment step. For example, the user may be encouraged to place his two skis in a predefined configuration at the beginning of each session or each time he puts on his skis, for example parallel and flat. During the calibration step, the control circuit retrieves relevant information from the different sensors and recalculates the criteria representative of risk situations or corrects the data from the sensors. The inertial unit can then operate with a certain autonomy for a limited period of time.

This calibration step can be particularly effective if it is carried out thoroughly by the skier. However, it has two important disadvantages. The calibration step requires a feedback to the user to indicate that the procedure is started and / or completed which is consuming specific resources, therefore costs and energy. It also imposes a formalism to respect over a period of time more or less long and in an environment that can not always be mastered. For example, a calibration step on a flat and substantially horizontal surface of a few seconds can be difficult to obtain at the exit of a gondola or chairlift. This step can therefore cause reliability concerns.

To avoid or reduce the use of the calibration step, the inventor has discovered that ski positions are found very regularly in skiers and they propose to use these specific positions to calibrate that is to say adjust the control circuit of a device for measuring the orientation of skis or ski boots. Indeed, according to the technologies, the measuring device can be set up on the two skis or on the two ski boots that are attached to the two skis. It is even possible to combine the use of devices on the ski and on the shoe.

To provide a device for measuring the relative orientation between the first and second skis or between the first and second shoes, it is advantageous to replace or supplement the magnetometer with another measurement. Indeed, if the magnetometer is kept, this other measure of the measuring device allows to support it in case of failure. This other measure can further compensate for a lack of relevant signal.

As illustrated in figures 1 and 2 , the measuring device comprises a plurality of sensors C ₁ and C ₂ configured to measure the orientation of axes and / or planes representative of the first and second ski S ₁ and S ₂ and / or first and second ski boots B ₁ and B ₂ . The sensors are in particular configured to measure the orientation of a representative plane of the ski or the ski boot relative to the vertical and follow the orientation of one or more axes that are not perpendicular to this plane.

In order to facilitate understanding, reference will no longer be made to ski boots B1 and B2 in the embodiments to be followed. However, those skilled in the art will keep in mind that what is being presented for a ski can also be presented for a ski boot because in ski action, these two elements are attached to one another. The embodiments of the skis and ski boots will be explained.

In an advantageous embodiment, the sensor C ₁ comprises a first sensor which is configured to be arranged on a first ski S ₁ . The first sensor is configured to provide first information relating to the orientation of a first plane representative of the sole of the first ski S ₁ . In other words, the first sensor is configured to measure the orientation of a first plane relative to the first ski S ₁ . The first plane may be the plane of the sole or any other fixed plane that is not perpendicular to the plane of the sole. In the case where the sole is not flat, the plane of the sole is represented by the surface directly under the user's foot. The first plane is for example the plane defined by the axes X ₁ and Y ₁ .

The sensor C ₂ also comprises a second sensor which is configured to be arranged on a second ski S ₂ . The second sensor is configured to provide a second information relating to the orientation of a second plane representative of the sole of the second ski S ₂ . In other words, the second sensor is configured to measure the orientation of a second plane relative to the second ski S ₂ . The second plane may be the plane of the sole or any other fixed plane that is not perpendicular to the plane of the sole. In the case where the sole is not flat, the plane of the sole is represented by the surface directly under the user's foot. The first plane is for example the plane defined by the axes X ₂ and Y ₂ .

The first sensor and the second sensor are configured to measure the angle that exists respectively between the first plane and the vertical direction and between the second plane and the vertical direction. The angle that exists between the vertical direction and the foreground is called the first angle. The angle that exists between the vertical direction and the second plane is called second angle. The vertical direction is represented by the gravitational acceleration vector g. The foreground is secant to the vertical direction and does not contain the vertical direction. The second plane is secant to the vertical direction and does not contain the vertical direction.

The first plan and the second plan each have at least two reference axes that are included in the plan to follow. The first reference axis is different from the second reference axis, preferably perpendicular to the second reference axis. The angle between the vertical direction and the first plane and between the vertical direction and the second plane can be broken down into at least two distinct components. The first component represents the angle that exists between the vertical direction and the first reference axis. The second component represents the angle that exists between the vertical direction and the first reference axis.

The sensor C ₁ comprises a first additional sensor which is configured to be arranged on the first ski S ₁ . The first additional sensor is configured to provide a first additional information relating to the orientation of the longitudinal axis of the first ski S ₁ . The information relating to the orientation of the longitudinal axis of the first ski S ₁ may be the orientation of the longitudinal axis or of any other axis which is fixed with respect to the longitudinal axis and which is not perpendicular. at the sole plane. The longitudinal axis is represented on the figures 1 and 2 , by the axis X ₁ . The orientation of the longitudinal axis of the first ski or the first shoe is also called the first orientation. The orientation of the first additional sensor with respect to the ski can be arbitrary. The first orientation is followed in time so as to follow the evolution of the orientation of the longitudinal axis of the ski in time. The first orientation can be followed by a 3-axis gyroscope possibly supplemented with a 3-axis accelerometer.

The sensor C ₂ comprises a second additional sensor which is configured to be arranged on the second ski S ₂ . The second additional sensor is configured to provide a second additional information relating to the orientation of the longitudinal axis of the second ski S ₂ . The information relating to the orientation of the longitudinal axis of the second ski S ₂ may be the orientation of the longitudinal axis or of any other axis which is fixed with respect to the longitudinal axis and which is not perpendicular. at the sole plane. The longitudinal axis is represented on the figures 1 and 2 , by the axis X ₂ . The orientation of the longitudinal axis of the second ski or the second shoe is also called the second orientation. The orientation of the second additional sensor with respect to the ski can be arbitrary. The second orientation is followed in time so as to follow the evolution of the orientation of the longitudinal axis of the ski in time. The second orientation can be followed by means of a 3-axis gyroscope optionally completed with a 3-axis accelerometer.

Each additional sensor is configured to measure the orientation of the longitudinal axis of the ski S ₁ or S ₂ or the shoe B ₁ or B ₂ . Each additional sensor may directly measure the longitudinal axis or any fixed axis relative to the longitudinal axis. Tracking the longitudinal axis of the ski or shoe is done by adding or removing a fixed angular value to the data provided by the additional sensor.

Advantageously, the first additional sensor is configured to provide, in addition, a third additional information relating to the orientation of a second axis of the first ski or the first ski boot relative to the fixed spatial reference system.

The second additional sensor is configured to provide, in addition, a fourth additional information relating to the orientation of a second axis of the second ski or the second ski boot relative to the fixed spatial reference.

For each ski or ski boot, the second axis is different from the axis used to follow the longitudinal axis, preferably orthogonal to the longitudinal axis.

The first additional sensor C ₁ may be part of the first sensor or be a dissociated element. The second additional sensor C ₂ may be part of the second sensor or be a dissociated element.

The measuring device further comprises a control circuit A which is connected to the first and second sensors and which is configured to compare the value of the angle existing between the first plane and the vertical with the value of the angle existing between the second and the second. plan and the vertical. The control circuit A receives information from the sensors C ₁ and C ₂ by any suitable technique, for example by a radio frequency signal.

The comparison of the first angle with the second angle can be done in different ways by means of the first information and the second information.

In a particular embodiment, when comparing the first angle with the second angle, one or more values representative of the two components of the first angle are compared to one or more values representative of the two components of the second angle.

In order to facilitate the comparison of the first angle with respect to the second angle, it appears particularly advantageous to configure the first angle sensor and the second sensor identically to follow the same planes and the same reference axes. The first components are compared with each other. It is the same for the second components.

For example, a reference axis is formed by the longitudinal axis of the ski. The other reference axis is formed by the transverse axis of the ski.

It is still possible to predict that the comparison of the first angle with the second angle is performed by comparing only the minimum angle that exists between the plane to be followed and the vertical and its sign with respect to the half plane of the first and second plane bounded by the longitudinal axis.

The modes of comparison between the two angles may vary for example as a function of the speed of the skier, its acceleration, its deceleration, its ski level.

In the illustrated example, the first sensor and the first additional sensor are part of the sensor C ₁ . Alternatively, the first sensor or the first additional sensor can be dissociated from the sensor C ₁ . It may be the same for the sensor C ₂ . The sensor C ₁ and / or the sensor C ₂ may be 3-axis sensors configured to measure linear and / or angular accelerations.

The control circuit A is connected to the first and second additional sensors and is configured to compare the orientation of the first longitudinal axis with the second longitudinal axis.

At each instant, the control circuit receives information for calculating the orientation of the first ski in space and information for calculating the orientation of the second ski in space. All this information is processed to find out if the skis' orientations represent at-risk orientations or not.

For example, the angular difference between the orientation of the first longitudinal axis and the orientation of the second longitudinal axis is compared with one or more threshold values. According to this comparison, the control circuit decides whether or not to release the heaving of at least one shoe with the associated ski.

In an advantageous embodiment, the relative position of the skis is defined by means of 3 angular deviations. A first angular difference corresponds to the angle formed between the longitudinal axes X1 and X2. A second angular gap is formed between the transverse axes Y1 and Y2. A third gap is formed between the axes Z1 and Z2.

Each angular difference value may be independently compared to a specific threshold to detect whether the position of the skis corresponds to a risk situation or to a normal situation. Moreover, the different angular difference values can be compared in combination with one or more thresholds so as to detect whether the position of the skis corresponds to a risk situation or to a normal situation.

In an advantageous embodiment, the different angular gaps that exist between the two skis are calculated by considering that each ski has a reference point and that these two reference points are merged. For example, the reference point of a ski is the intersection between the X, Y and Z axes. In the example of the figure 2 , the reference point is located in the plane of the sole under the heel of the ski boot. In this configuration, the angular deviations are easier to calculate.

Advantageously, the angular difference that exists between the axis X1 and the axis X2, between the axis Y1 and the axis Y2 or between the axis Z1 and the axis Z2 is signed, that is to say say that the control circuit takes into account the orientation of one ski relative to the other. Thus, depending on whether the value of the angle between X1 and X2 is positive or negative, the control circuit is able to determine that the longitudinal axes of the skis are moving towards or away from each other, more particularly the front or rear spatulas. It is the same for the angles between the axes Y1 and Y2 and between the axes Z1 and Z2.

• une première donnée qui est le premier angle ou une information relative au premier angle,
• une deuxième donnée qui est le deuxième angle ou une information relative au deuxième angle,
• une troisième donnée qui est la première direction ou une information relative à la première direction,
• une quatrième donnée qui est la deuxième direction ou une information relative à la deuxième direction.

For a given moment, the control circuit A receives:

• a first datum which is the first angle or information relating to the first angle,
• a second datum which is the second angle or information relating to the second angle,
• a third datum which is the first direction or information relating to the first direction,
• a fourth datum which is the second direction or information relative to the second direction.

The device is configured to operate in the absence of reliable information on a fixed geographical direction, for example magnetic north. For example, in the event of a magnetometer failure, the orientation provided may be false and / or random. Nevertheless, this does not prevent the device from following the relative evolution of the two skis reliably.

In order to compare the orientation of the first plane relative to the second plane, the control circuit is advantageously configured to compare the angle that exists between the orientation of the first plane and the vertical with the angle that exists between the orientation of the second plane. plan and the vertical. On the figure 2 the first angle is represented by the angle between the axis g and the axis Z ₁ . The second angle is represented by the angle that exists between the axis g and the axis Z ₂ .

The vertical, that is the gravitational acceleration vector g, is used as a common reference for the first and second planes. The measurement of the orientation of the plane can be easily performed using an accelerometer optionally supplemented with a gyroscope.

After measuring the orientation of the first plane relative to the vertical and the orientation of the second plane relative to the vertical from the first and second sensors, the control circuit can find if the first plane is parallel to the second plane. This search can be done simply by comparing the values of the first angle and the second angle to determine if they are equal or different. If the first angle is equal to the second angle, the two planes can be considered parallel.

The first angle is considered equal to the second angle, if the difference is less than or equal to 5 ° in absolute value.

The comparison of the orientation of the first and second planes can be performed by comparing the value of the first angle with the value of the second angle. It is also possible to compare the difference between the first angle and the second angle at one or more threshold values.

In an advantageous embodiment, the two sensors are installed identically on both skis so that the first plane relative to the first ski is the equivalent of the second plane relative to the second ski. In this particularly advantageous case. The comparison between the orientations of the first and second planes can be facilitated by simply comparing the value of the first and second angles or the value of the difference.

For example, the control circuit considers that the two planes are parallel if the value of the first angle is equal to the value of the second angle at plus or minus 5 °. For example, the control circuit considers that the two planes are parallel if the difference between the first angle and the second angle is less than or equal to 5 ° in absolute value.

Indeed, the inventor has discovered that during the practice of skiing, preferably when the skis are in motion, when the plane of the sole of the first ski S ₁ is parallel to the plane of the sole of the second ski S ₂ , the skis are mostly parallel. The inventor has discovered that when skiing, preferably when the skis are in motion, when the angle formed between the plane of the sole of the first ski S ₁ and the vertical is identical to the angle formed between the plane of the sole of the second ski S ₂ and the vertical, the skis are mostly parallel. The value of the angle takes into account its sign, that is to say, the orientation of the ski.

On the other hand, if the value of the first angle and the value of the second angle are different from 90 °, that is to say that the soles of the skis are not in a horizontal plane, it is advantageous to deduce that the skis are moving and so that skis are mostly parallel.

It has been observed that the period when the longitudinal axes of the skis are parallel increases as the angle deviates from 90 °, that is to say that the slope increases.

By mainly parallel, it is understood that in the majority of the study time the skis are parallel. The skis are considered parallel when the longitudinal axis of the first ski X ₁ is parallel to the longitudinal axis of the second ski X ₂ with a tolerance of a few degrees.

If the skier brakes by pressing on his heels and approaching the spatulas before his skis S ₁ and S ₂ , for example in the case commonly known as plow, it is observed that the plans of the two soles of the skis are not parallel . The first and second angles formed by these planes with the vertical may be identical in absolute value but they have opposite signs. It can be the same during a turn.

The measurement of the first angle and the second angle can be easily achieved by means of a 3-axis accelerometer optionally supplemented by a 3-axis gyroscope.

Based on this observation, the control circuit A is configured to compare the orientation of the first and second planes. If the first and second planes form the same angle with the vertical, the control circuit A considers that the longitudinal axes are also parallel and it records this information by recalibrating the orientation of the two longitudinal axes. This recording makes it possible to adjust the comparison between the first longitudinal axis and the second longitudinal axis to detect possible risk situations at a later date. Only the relative position of the skis is exploited. It is therefore sufficient to redefine the measurement of the position of the longitudinal axes of the skis with respect to each other and not to redefine the position of the longitudinal axes with respect to a reference geographical direction, for example magnetic north.

If the skis S ₁ and S ₂ are considered parallel, that is to say that the longitudinal axes are considered parallel, it is possible to readjust the additional sensors by sending information on the orientation of the first axis and / or the second axis. It is also possible to correct the information transmitted inside the measuring circuit for example by adding or removing a few degrees to the orientation of one of the skis or to the two skis S ₁ and S ₂ . It is still possible to recalculate the thresholds leading to the detection of a risk situation. These different options can be used independently or in any combination.

On the basis of this calibration, it is then possible to detect risk situations for the skier, for example a future ski cross.

This embodiment is particularly advantageous because it is performed when the skier is in ski action, that is to say in masked time. It can for example avoid fixed periods of calibration that should be performed regularly. The skier moves on the track and the control circuit A detects one or more situations where the two soles of the skis S ₁ and S ₂ form the same angle with the vertical and he deduces that these situations correspond to times when the skis S ₁ and S ₂ are parallel. The measuring circuit recalibrates itself on the basis of this information so that it can subsequently detect risk situations more safely.

If the measuring device comprises one or more inertial units in order to measure or follow the orientation of the longitudinal axis of the first ski S ₁ and / or the second ski S ₂ , the control circuit A can correct the drift of the inertial units. by redefining the values corresponding to the two parallel skis.

Similarly, if the measuring device comprises one or more gyroscopes to measure or follow the orientation of the longitudinal axis of the first ski and / or the second ski, the control circuit A can correct the drift of the gyroscope. It may be the same for accelerometers configured to measure linear and / or angular velocities.

Thus, by measuring the orientation of the first plane relative to the vertical and the orientation of the second plane relative to the vertical and comparing these two values, it is possible to define with a low error rate that the axis longitudinal X ₁ of the first ski S ₁ is parallel to the longitudinal axis X ₂ of the second ski S ₂ . The data relating to the first longitudinal axis or the second longitudinal axis remain relative data which are correlated by the measuring circuit.

This measurement can be used to replace a magnetometer or a calibration procedure. This measurement can also be used to supplement the measurement made by a magnetometer in the event of failure and / or absence of a signal.

The figure 3 schematically illustrates the different actions of the control circuit for the recalibration of the longitudinal axes.

In a step S1, the control circuit A receives information relating to the orientation of the first plane and the second plane.

In a step S2, the control circuit A calculates whether the first angle is equal to the second angle, that is to say if the first plane forms the same angle with the vertical as the angle formed between the vertical and the second plan based on the previous information.

If the first and second planes do not form the same angle with the vertical (output N), the control circuit leaves the recalibration protocol. If the first and second planes form a same angle with the vertical and are therefore parallel (output O), the control circuit A can go directly to a step S3 where the first and second longitudinal axes are considered parallel.

At a step S4, the control circuit 1 records this information by adjusting the information relating to the first longitudinal axis and the second longitudinal axis to secure the detection of a possible risk situation.

In an advantageous embodiment illustrated in figure 3 , taking into account the comparison of the orientation of the foreground with the second plane to know if they form a same angle with the vertical may be conditioned by the occurrence of another event.

According to the embodiments, the comparison is not performed or the result is not taken into account depending on the occurrence of another event.

In an advantageous embodiment, the information indicating that the first plane and the second plane form a same angle with the vertical is taken into account only if the first plane and / or the second plane are different from the horizontal plane, c that is, if the first and second planes intersect vertically without the vertical being perpendicular to these two planes. This additional condition is represented for example by step S5 placed after the output O of step S2.

In the case where the first plane and / or the second plane are parallel to the horizontal plane, the control circuit A can leave the recalibration protocol (output N) or condition the continuation of the protocol to the occurrence of another event ( not shown).

In a preferred embodiment, the control circuit A also measures the distance between the first ski S ₁ and the second ski S ₂ or the distance d between the first shoe B ₁ and the second shoe B ₂ . The distance d measured is compared with a first threshold distance d1. This embodiment allows a finer analysis of dangerous situations where it would be necessary to take off. This additional condition is represented by example by step S6 placed after the output O of step S5. In this particular case, the distance d is compared with two different threshold values.

In an advantageous configuration, the control circuit A comprises or is coupled to an additional sensor measuring the linear acceleration of the first ski or the first shoe along its longitudinal axis X. This additional sensor may be present in the sensor C1 and / or in the sensor C2. The control circuit A is configured to take into account the comparison between the first plane and the second plane if the linear speed of the first ski along its longitudinal axis reaches a threshold value, for example exceeds a threshold value (v> vseuil). This additional condition is represented for example by step S7 placed after the output O of step S6.

This precision makes it possible, for example, to eliminate configurations where the skier is at a standstill or possibly at a very low speed and he voluntarily places his skis in positions that are incompatible with the practice of skiing at a classic pace.

Compared speed can be an absolute measure, that is to say, it does not take into account the direction of progression of the skier or relative that is to say it differentiates a forward and a reverse.

It is further advantageous to provide that the control circuit can be configured to take into account the comparison between the first plane and the second plane when the acceleration measured by the sensor reaches a threshold value or is non-zero. This additional condition is represented for example by step S8 placed after the output O of step S7.

In an advantageous embodiment, the control circuit can be coupled to a pressure sensor. The pressure sensor is configured to detect if the weight of the skier is present on the skis for example to make a turn or braking or more generally if it is in action sliding on the snow. This additional condition is represented for example by step S9 placed after the output N of step S8.

In this way, it is possible to discriminate whether the skier is descending a track or on the contrary if he is on a chairlift or in a cabin.

If the skier is in a chairlift, he does not apply pressure on the shoe and / or the ski or a much lower pressure which warns the control circuit. The control circuit can be configured to take into account the comparison between the first plane and the second plane when the pressure sensor sends a signal that reaches a threshold value.

If the skier is standing in a cabin, he does not apply pressure on the ski but the pressure on the shoe can be identical to that of the practice of skiing. If the pressure sensor is placed in the ski, it is possible to discriminate the presence or absence of skier. On the other hand, if the sensor is placed in the boot, it is necessary to provide that the sensor or an additional sensor is configured to detect the connection between the ski and the boot. The control circuit can be configured to take into account the comparison between the first plane and the second plane when the sensor detects the connection between the ski and the associated shoe.

The use of a pressure sensor also makes it possible to detect if the skier performs a jump and is then in a position different from the ski position. It is therefore interesting not to take into account the position of his skis.

Alternatively, to discriminate whether the skier is skiing or is transported by a cabin or a seat, it is also possible to find out if the skier is descending the slope or if on the contrary it goes up the slope .

Alternatively, to know if the skier is skiing or if he is in another condition, it is also advantageous to provide that the control circuit is connected to means for analyzing the deformation of the ski or to vibration analysis means in the ski. This information can come for example from one or more strain gauges and / or from one or more blades of piezoelectric material.

It is then advantageous to provide that the control circuit can be configured to take into account the comparison between the first plane and the second plane when the information provided by the means for analyzing the deformation of the ski or the analysis means vibrations in the ski return a first value.

The different steps S2, S5, S6, S7, S8 and S9 can be performed in any order. It is even possible to provide that steps S5, S6, S7, S8 and S9 or part of these steps are performed between steps S3 and S4.

In the various configurations exposed, it is advantageous to provide that the control circuit is devoid of information from a magnetometer. This embodiment makes it possible to provide a measurement device devoid of a magnetometer to gain compactness and cost.

It is still possible to provide that the control circuit is devoid of information from a geolocation system to save energy. It is even more advantageous to plan a measuring device without geolocation system to increase compactness and cost.

In order to facilitate the use of the measuring circuit, it is advantageous not to provide a sensor relating to a straight ski and a sensor relating to a left ski. The dissociation of the sensors can be achieved easily when they are integrated into a shoe because there is a right shoe and a left shoe. On the other hand, it is more difficult to perform this type of operation for skis that are predominantly identical in a pair of skis.

A clever way of distinguishing the right sensor and the left sensor and therefore the right ski / right shoe combination of the left ski / left shoe unit is to measure the angle that exists between the longitudinal axis of the first ski S ₁ and the longitudinal axis of the second ski S ₂ during a ski descent.

As indicated above, the inventor has observed that, in ski action, a skier is very much in the direction of changing his skis between a first position where the skis are parallel and a second position where the front spatulas are directed towards each other. the other to brake or to turn.

By measuring the orientation of the longitudinal axes of the two skis, over a predefined period of time and by calculating the average value of the angle that exists between the two longitudinal axes, it is possible to deduce if the first ski is the right ski or the left ski and vice versa for the second ski. Indeed, the angle formed at the spatulas before skis is mostly an acute angle, especially when the skis are not horizontal or are not close to the horizontal. Alternatively, by controlling the sign of the difference between the first orientation and the second orientation over several instants, the control circuit is able to deduce whether the first ski is the right ski or the left ski and conversely for the second ski, that is to say if the acute angle is formed on the side of the spatulas before or on the contrary on the rear part of the skis.

This measurement can be associated with a second measurement intended to analyze the direction of progression of the skier. The acute angle formed by the skis is directed in the direction of progression of the skier which makes it possible to take into consideration a skier who chooses to ski in reverse.

This calibration phase can be performed on a first period of time following the fixing of the ski boots on the skis. This calibration phase can still be performed on a first period of time after a predetermined duration of use of the ski. The calibration phase can be initiated if the control circuit detects that the skis have been unused for a predetermined period, for example 5 minutes, and / or if the skis are in a particular position, for example the longitudinal axis of the ski is placed vertically. The calibration phase can be performed repetitively, for example after a predefined period, a predefined distance traveled and / or a predefined height difference. This calibration phase can also be performed permanently.

Claims (12)

Device for measuring the relative orientation of two skis comprising: a first sensor configured to be arranged on a first ski or on a first ski boot, the first sensor being configured to provide first information relating to a first angle existing between a first plane and the vertical, the first plane being representative of the sole of the first ski or the sole of the first ski boot, a first additional sensor configured to be arranged on the first ski or on the first ski boot, the first additional sensor being configured to provide a first additional information relating to the orientation of the longitudinal axis of the first ski or the first ski; ski boot with respect to a first fixed spatial reference, a second sensor configured to be arranged on a second ski or on a second ski boot, the second sensor being configured to provide second information relating to a second angle existing between a second plane and the vertical, the second plane being representative of the sole of the second ski or the sole of the second ski boot, a second additional sensor configured to be arranged on the second ski or on the second ski boot, the second additional sensor being configured to provide a second additional information relating to the orientation of the longitudinal axis of the second or second ski; ski boot with respect to the first fixed spatial reference, a control circuit configured for ∘ compare the value of the first angle with the value of the second angle, ∘ record the orientation of the longitudinal axis of the first ski or ski boot and the orientation of the longitudinal axis of the ski second ski or the second ski boot as corresponding to a configuration where the longitudinal axis of the first ski is parallel to the longitudinal axis of the second ski when the value of the first angle is equal to the value of the second angle. An apparatus according to claim 1, wherein the first information comprises a value of an angle existing between a first reference direction of the first plane and the vertical and a value of an angle existing between a second reference direction of the first plane and the vertical, the first reference direction being different from the second reference direction in the first plane and wherein the second information comprises a value of an angle existing between a first reference direction of the second plane and the vertical and a value of an angle existing between a second reference direction of the second plane and the vertical, the first reference direction being different from the second reference direction in the second plane. Device according to one of claims 1 and 2, wherein the control circuit is further configured to ∘ initiating a loosening of the first shoe with the first ski and / or the loosening of the second boot with the second ski when the angle between the longitudinal axis of the first ski or the first ski boot and the longitudinal axis of the second ski or the second ski boot reaches a threshold value. Device according to one of claims 1 to 3, wherein the first additional sensor and the second additional sensor are configured to respectively provide a third additional information relating to the orientation of a second axis of the first ski or the first shoe of ski in relation to the fixed spatial repository and fourth information additional to the orientation of a second axis of the second ski or the second ski boot relative to the fixed spatial reference, the second axis being different from the longitudinal axis of the ski or the ski boot and preferably orthogonal to the longitudinal axis. Apparatus according to claim 4, wherein the control circuit is further configured to ∘ calculate at least one parameter from the angle between the longitudinal axis of the first ski and the longitudinal axis of the second ski, the difference between the first angle and the second angle and third and fourth additional information, Comparing said at least one parameter with at least one threshold parameter, ∘ initiate a loosening of the first shoe with the first ski and / or the loosening of the second shoe with the second ski according to the comparison. Device according to one of claims 4 and 5, wherein the second axis of the first ski or the first ski boot is perpendicular to the longitudinal axis and is included in the first plane. Device according to one of claims 1 to 6, wherein the control circuit is devoid of information from a magnetometer. Device according to one of claims 1 to 7, wherein the control circuit is devoid of information from a geolocation system. Device according to one of claims 1 to 8, in the control circuit is coupled to an additional sensor measuring the acceleration or linear speed of the first ski or the first ski boot according to its longitudinal axis and in which the control circuit is configured to record the orientation of the longitudinal axis of the first ski or the first ski boot and the orientation of the longitudinal axis of the second ski or the second ski boot. ski corresponding to a configuration where the longitudinal axis of the first ski is parallel to the longitudinal axis of the second ski when the first angle is equal to the second angle if the acceleration or linear speed of the first ski or the first shoe of ski along its longitudinal axis reaches a threshold value. Device according to one of claims 1 to 9, comprising a pressure sensor connected to the control circuit and configured to detect the weight of the user on the first ski or on the first shoe, the control circuit being configured to record the the orientation of the longitudinal axis of the first ski or the first ski boot and the orientation of the longitudinal axis of the second ski or the second ski boot as corresponding to a configuration where the longitudinal axis of the first ski is parallel to the longitudinal axis of the second ski when the first angle is equal to the second angle and when the pressure sensor detects a pressure greater than a threshold pressure. Device according to one of claims 1 to 10, wherein the control circuit is further configured to calculate the angle between the longitudinal axis of the first ski or the first shoe and the longitudinal axis of the second ski or the second shoe and define whether the first ski is a right ski or a left ski or if the first shoe is a right shoe or a left shoe according to the sign of said angle. Device according to one of the preceding claims, wherein the first additional sensor is part of the first sensor and the second additional sensor is part of the second sensor.

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