EP2822462A1

EP2822462A1 - Method of identifying the geometric parameters of an articulated structure and of a set of reference frames of interest disposed on said structure

Info

Publication number: EP2822462A1
Application number: EP13707661.8A
Authority: EP
Inventors: Pierre Grenet; Christelle Godin
Original assignee: Movea SA; Commissariat a lEnergie Atomique et aux Energies Alternatives CEA
Current assignee: Movea SA; Commissariat a lEnergie Atomique et aux Energies Alternatives CEA
Priority date: 2012-03-08
Filing date: 2013-03-07
Publication date: 2015-01-14
Also published as: FR2987735A1; US20150057971A1; WO2013131990A1; FR2987735B1; US10386179B2

Abstract

The present invention relates to a method of identifying the geometric parameters of devices each comprising at least one accelerometer, each platform being disposed on a segment of an articulated body. Said method comprises steps of evaluating values of parameters characterizing the orientation and the position of each sensor in the reference frame of each segment and of the length of each segment, in a reference frame of said segment, by using predetermined configurations and movements of the structure. The method of the invention makes it possible to provide a device for capturing the movements of said body with measurements which allows greater reliability of said measurements.

Description

METHOD FOR IDENTIFYING GEOMETRIC PARAMETERS OF AN ARTICULATED STRUCTURE AND A SET OF INTEREST RECORDS

ARRANGED ON THIS STRUCTURE Technical area:

The present invention relates to a method for identifying the geometric parameters of an articulated structure and a set of reference marks arranged on said structure, using a suitable measurement system. The evaluated information is as follows:

- The positions and orientations of the landmarks of interest in relation to the structure;

The biomechanical parameters of the articulated structure (eg lengths of segments).

The invention is applicable, for example, without this list being limited to the following functions:

Characterize precisely a measurement system applied to the articulated structure. Benchmarks of interest are then those of measurement devices that instrument the structure.

Measure kinetic parameters of a solid structure (articulated or not). Benchmarks of interest are usually points where one is interested in kinetic parameters.

Capturing the movement of an articulated body (fields of medicine, animated cinema, sports or video games, research in biomechanical analysis, robotics, ...).

Prior art and technical problem:

The fields of application in which articulated structures are used are expanding. Examples include human or animal biomechanics and robotics. In these areas, two types of information are critical:

- The geometry of the articulated structure

The position and the orientation of a set of landmarks of interest (where one has for example temperature measurements, kinetic measurements, ...)

The present invention proposes to treat both these problems together without resorting to the methods of the prior art which consist mainly of directly measuring the lengths of the segments of the articulated structure (for example, using a tape measure or the using a complex optical system, ...), to take into account a morphological model making it possible to simulate the dynamics of said structure articulated and to locate the markers of interest on the segments also by direct measurement of their position and their orientation.

Summary of the invention

The method comprises associating a distributed measurement system on said structure, system comprising sensors fixed integrally to the segment of said structure instead of the points of the landmarks of interest to extract the desired information described above. In the remainder of the document, we will mainly illustrate the invention on an exemplary application in which:

The articulated structure is biomechanical and one wishes to evaluate the length of its segments;

A motion measurement system is disposed on the articulated structure and it is desired to identify their position and orientation, the previously defined reference points of interest are those of each measuring element of the system; this system serves both the measurement of the movement and the identification of the geometrical parameters making it possible to characterize the segments of the structure and the position of reference marks of interest with respect thereto;

- Said measurement system comprises at least one accelerometer.

Resumption of claims:

For this purpose, the invention discloses a method for determining the position of a set of sensors in a frame linked to a segment of an articulated chain, said set of sensors comprising at least one accelerometer and being integral with said articulated chain. , said method being characterized in that it comprises: a first step of determining the orientation of a marker linked to the set of sensors relative to the marker linked to said segment for at least one selected configuration of said articulated chain; a second step of estimating the movement of said marker linked to the set of sensors in the terrestrial frame during at least one movement of said segment; a third step of calculating said position of said set of sensors in the frame linked to said segment, said third stage receiving as input the estimation of the movement of said marker linked to the sensor at the output of the second stage and the measurements of said accelerometer during said less a movement. Advantageously, the first step comprises a first sub-step of calculating a first matrix of passage of said reference frame linked to the set of sensors to a grounded reference frame and a second substep of calculating a second matrix of passage of said land-bound mark to a mark related to said segment.

Advantageously, the first calculation sub-step uses at least one measurement of at least one second sensor of said set of sensors, said second sensor being able to provide measurements of at least one physical field that is substantially uniform in time and in time. space or speed of rotation.

Advantageously, the first calculation step further comprises a substep of computation prior to said first substep during which a third transition matrix is calculated between a moving marker and said marker linked to the earth, said third matrix The passageway is either selected or determined from measurements of at least one substantially uniform physical field in time and space or measurements of the rotational speed of said moving mark relative to said earth-bound mark.

Advantageously, the first step is performed for at least two configurations of said articulated chain.

Advantageously, prior to the first step, a first substep of determining a substantially invariant axis of rotation of said segment is carried out. Advantageously, the second step uses the outputs of at least one sensor selected from the group comprising the accelerometer and a second sensor of said set of sensors, said second sensor being able to provide measurements of at least one substantially uniform physical field in time and space or speed of rotation.

Advantageously, during the second step, said at least one movement of the segment is a rotation of substantially invariant axis.

Advantageously, during at least the second and third steps, a predictive model is used of the outputs of the accelerometer chosen as a function of the type of movement of said segment and the position of said set of sensors on said output segment is calculated. an algorithm that minimizes errors between measured values and predicted values. Advantageously, said articulated chain comprises at least N segments, N being greater than or equal to two.

Advantageously, the method of the invention further comprises a step during which the length of at least one segment of said articulated chain is calculated.

Advantageously, the calculation of a segment i inserted in an articulated chain comprising j segments, j being greater than 1 and i, is performed by solving the equation in which:

- is a matrix of dimension (i, j) whose coefficients are calculated by the formula

- PosLong is the vector

- The acceleration without base at time t is calculated by the formula

Advantageously, said articulated chain is a part of a human body or a humanoid structure.

Advantageously, the configurations of said articulated chain are determined by executing at least N predefined successive gestures, each gesture allowing only a rotation of all or part of the segments of said chain in a single plane around a single passing axis. by an articulation connecting two segments, the segments other than the two said segments remaining aligned during said rotation, so that rotations of segments are performed around at least N distinct axes.

Advantageously, N> = 3, a first segment corresponding to a shoulder, a second segment corresponding to an arm connected to the shoulder and a third segment corresponding to a forearm connected to the arm by an elbow, the execution of predefined gestures including, in order: a rotation of the entire body about a vertical axis (105) comparable to the axis of the body, the shoulder-arm-forearm assembly being held taut in a horizontal plane during the rotation of the body about said axis, and; a rotating the arm-forearm assembly about a horizontal axis (205) and passing through the joint connecting the shoulder to the arm, the arm-forearm assembly being held taut during said rotation, and; a rotation of the forearm about a horizontal axis (305) and passing through the elbow connecting the arm to the forearm, the shoulder-arm assembly being held taut during said rotation.

Advantageously, each rotation of segments is performed around an axis passing through an articulation. The invention also discloses a system for determining the position of a set of sensors in a frame linked to a segment of an articulated chain, said set of sensors comprising at least one accelerometer and being integral with said articulated chain, said system characterized in that it comprises a first module for determining the orientation of a marker linked to the set of sensors to said marker linked to said segment for at least one configuration of said articulated chain; a second module for estimating the movement of said marker linked to the set of sensors in the terrestrial frame during at least one movement of said segment; a third module for calculating said position of said set of sensors in the frame linked to said segment, said third module receiving as input the estimation of the movement of said reference frame linked to the sensor at the output of the second module and the measurements of said accelerometer during said at least a movement.

Advantages :

The present invention has the main advantage of accurately and automatically identifying, fast and practical critical geometric parameters of an articulated structure and a plurality of reference marks. In some of its embodiments, the invention is particularly advantageous because it expresses the estimation of said parameters in the form of a linear least squares problem, the calculation of the estimate is therefore explicit and optimal.

Summary of figures:

Other characteristics and advantages of the invention will become apparent with the aid of the following description made with reference to the following figures which illustrate examples of implementation of the method according to the present invention:

- Figure 1 specifies the pins used in the description of the present invention; FIG. 2 represents a general flowchart of the treatments in several embodiments of the invention;

FIGS. 3a to 3e represent different variants of the invention in several of its embodiments;

FIG. 4 illustrates the articulated structure (human being in the figure) equipped with a set of devices and the associated measurement system which will make it possible to identify the geometrical parameters of the structure and the devices whose markers are the reference marks of interest;

FIG. 5 illustrates a first movement of a human being carrying sensors of a measuring system whose markers are the reference marks of interest, in one embodiment of the invention;

FIG. 6 illustrates a second movement of a human being carrying sensors of a measuring system whose markers are the reference marks of interest, in one embodiment of the invention. ;

FIG. 7 illustrates a third movement of a human being carrying sensors of a measuring system whose markers are the reference marks of interest, in one embodiment of the invention.

Description of the invention from the figures:

The articulated structure is composed of at least one first segment that can be movable in space. The following segments are attached one after the other in the form of a tree that can have several branches.

The measurement system comprises sensors, arranged on the segments of the articulated structure, whose marks are the reference points of interest.

The present invention aims a method using:

Means for measuring the orientation of the marks of interest, the sensors of the measurement system or segments,

- The sensors of the fitted measurement system comprising at least one accelerometer,

Things to do

to extract:

The position and orientation of the landmarks of interest on each segment,

- Where appropriate, the length of each segment.

Figure 1 specifies the pins used in the description of the present invention. R _D is the index of interest, 101. The sensors used to perform the measurements will be placed on the reference of interest, at least for the time of the measurement. In the remainder of the description, the terms "reference of interest" or "reference linked to the set of sensors" will be alternately used to designate the reference 101.

Rs is the segment-related landmark, 02.

Rg is the landmark linked to the center of gravity of the body, 103.

R _T is the fixed marker, 104. The fixed marker is for example linked to the Earth.

Figure 2 shows a general flowchart of the treatments in several embodiments of the invention.

It is a question of determining the parameters which characterize the position and the orientation of the marks of interest with respect to the segments which constitute the branches of the articulated structure.

For that, it is necessary first of all to determine the orientation of the reference linked to the set of sensors (or reference of interest), 101 with respect to the marker of the segment 102. This orientation can be a directly accessible datum or it can be determined in one or more configurations of the articulated structure, as illustrated later in the description.

The articulated structure is also made to perform at least one more or less simple movement, in order to obtain measurements of the orientation and position parameters of the reference frame linked to the set of sensors that are available, so as to solve the equation of the movements that are made and to deduce the estimate of the parameters that characterize the position of the set of sensors in the frame of the segment.

Thus, according to the invention, during a first step 201, 202, either the orientation of the sensor assembly is directly fixed in the segment marker 103, or the orientation of the sensor assembly is determined. (For example the references 401, 401a, 402, 402a, 403, 403a of Figure 4) in the reference fixed reference, 104, making the articulated structure take one or more configurations, which determine said orientation, and thus a matrix of passage between the reference mark 101 and the mark 104, then a marker matrix 104 is determined at mark 102. Then, in one embodiment, during a step 203, the structure is made to articulated at least one movement for which it is possible to determine a predictive model of the measurements of the sensors belonging to the set of sensors 401, 401a, 402, 402a, 403, 403a.

Different variants for carrying out the steps 201 and 203 are illustrated in the remainder of the description. In Figure 3a is shown the flowchart of the treatments of Figure 2 in a first embodiment.

The set of sensors (references 401, 401a, 402, 402a, 403, 403a of FIG. 4) comprises a means for measuring the orientation Benchmarks of interest 101 relative to the fixed land-bound landmark (RT, 104). Different sensors are able to provide measurements with respect to substantially invariant fields in time and space (gravity, the earth's magnetic field) or with respect to a fixed reference in the reference numeral 104, such as magnetic sensors optical, acoustic or radiofrequency positioned in the set of sensors or on a fixed base in connection with a fixed base relative to the mark 104 or with sensors positioned in the set of sensors. For example, gyrometers are able to provide this information. Magnetometers are also capable of playing this role, as well as optical, acoustic or radiofrequency means.

In this case, the first step 201, 202 that identifies the target matrix consists of adopting predefined postures or poses and therefore, known as and therefore, by transitivity of the matrices of rotations the matrix

:

The second step 203 consists in taking gestures and analyzing the accelerometric measurement by exploiting the knowledge of in order to estimate the parameters of lengths and distances, by relying on the law of composition of the movements which links the accelerations of the various points concerned.

The third step 204 of estimating the position parameters of the set of sensors on the segment is explained later in the description.

Some special cases, illustrated by the flowchart of the treatments of figure 3b, oblige to add constraints on the type of movements. For example, the use of magnetometers as means for measuring orientations forces gestures to respect a substantially invariant axis of rotation. An algorithm called "constant U" is then used to solve the equations of the movements as explained later in the description. Such an algorithm is disclosed in the application EP1985233 belonging to the applicants of the present ^" application." The configurations and movements to be made by the articulated structure are illustrated in the embodiments described in comments to Figures 5, 6 and 7. Figure 3c represents the diagram of the processing of a ^2nd embodiment wherein it has means for measuring the orientation, wherein R 'is

any mark whose movement is known in the fixed reference R _T or which is capable of fixing. This allows us to take us back to the previous case for the steps 203 and 204. For example, a system of directional antennas carried on the one hand at the center of mass (R '), and on the other hand at the level of the reference points of interest makes it possible to follow the movements of the reference mark R' relative to the earth mark, 104. FIG. 3d represents the flowchart of the treatments of an embodiment in which the orientation of the reference mark 101 is already available in the reference mark 102, where a means is available. to measure said orientation. A matrix is then determined which makes it possible to go directly from the reference of interest to the mark of the segment,

which performs the first step 201, 202 of the method of the invention. For example, one can use the means mentioned in the patent application EP1985233 belonging to the applicants of the present application, already mentioned. These means may comprise only an accelerometer or, in fact, the same sensors as those of the measurement system of the invention. According to this invention, at least two substantially invariant axes of rotation of the instrumented segment are determined by the one or more sensors. The rotational movements are determined as substantially invariant with respect to one or more thresholds selected by the user of the system.

The second step 203 consists of performing protocol movements, for which the trajectory of all the segments equipped (Χ, Υ, Ζ) must be imposed independently of the time or the speed profile of execution. The accelerometric data measured over time during this gesture is then elastically approximated (elastic time deformation) of the expected measurement model linked to the predefined trajectory, for example by an error minimization or maximization of the likelihood ratio operation having as variables the desired parameters.

The third step 204 (which may optionally be simultaneous in step 203) for estimating the position parameters of the set of sensors on the segment is explained later in the description.

Figure 3e shows the flowchart of processing of a 4 ^th embodiment of the invention in which has a means to measure the orientation The same means as used in the embodiment of FIG. 3a may be suitable, for example, for optical systems, ultrasonic systems or any other system which has fixed base in the land reference.

The first step 201, 202 consists in making protocol movements, with a substantially invariant axis of rotation, so that using a measuring system comprising at least one accelerometer, the rotation matrix can be identified and thus reduced to in the first case above.

Figure 4 illustrates a particular case where the articulated structure (400) is a human being who is equipped on only part of his body: left shoulder and arms. The shoulder as well as the arm and forearm are respectively equipped with the devices (401a, 402b, 403b) and at the same locations the sensors of said measurement system (401, 402, 403). Figure 5 illustrates a first movement of a human carrying sensors (401, 402, 403) of a measurement system, in one embodiment of the invention. In this embodiment, all the devices shown in FIG. 4 and the measurement system are combined and consist of sensors associating accelerometers and magnetometers (Embodiment illustrated in FIG. 3b). In this exemplary implementation of the invention for calibrating a set of three sensors 401, 402 and 403 connected to three segments that are the shoulder of a person, to which is attached the sensor 401, the arm of the person, which is attached the sensor 402, and finally the forearm of the person, which is attached to the sensor 403. For the present embodiment of the invention, the applicants used sensors 401, 402 and 403 marketed by one of the applicants under the trade name MotionPod and which each combine a triax accelerometer with a triaxial magnetometer. Each of the sensors 401, 402 and 403 transmits its data via a radio link to a box commonly called Motion Controller, this box being connected to a computer via a USB link. The case and the computer are not shown in the figure. The data is usable on the computer through a programming interface that the applicants market under the trade name Smart Motion Development Kit (SMDK). The SMDK programming interface allows to obtain raw and calibrated measurements of a MotionPod, or to obtain an estimation of the orientation of a MotionPod.

In the remainder of the present application, the terms sensor, or MotionPod will be used indiscriminately to designate the elements 401, 402 and 403 shown in Figures 4, 5, 6 and 7.

Prior to using the system thus constituted by the sensors 401, 402 and 403, for example to capture the movements of the three-segment shoulder-arm-forearm of the person, it is necessary to evaluate the change of reference mark. between the mark of the solid that constitutes each segment and the mark of the sensor attached to said segment. Thus, it is necessary to evaluate the change of reference between the reference of the shoulder and the sensor 401, the change of reference between the mark of the arm and the sensor 402, and that the change of reference between the reference of the forearm and the sensor 403. It is also necessary to evaluate the changes of reference between the different segments. This is the object of the method for identifying geometric parameters according to the invention. In the present exemplary embodiment, it is firstly necessary to evaluate the orientation of each of the sensors 401, 402 and 403 with respect to the segment to which said sensor is attached by using the means for measuring the orientation and possibly protocol gestures (see the various embodiments described above in comments to Figures 3a to 3e). It is then necessary to evaluate the position of each of the sensors 401, 402 and 403 with respect to the segment to which said sensor is attached in the form of a position vector. It is also a question of evaluating the length of each of the three segments in the form of a vector length. It should be noted that the position of the sensors could be measured in the rule, but the estimate obtained would then prove too coarse, in addition only the component along the length of each of the segments, referenced X in FIGS. 5, 6 and 7 , can actually be evaluated by this manual method.

The method for identifying geometric parameters according to the invention comprises a step of evaluating the orientation of the sensors. In this exemplary embodiment (FIGS. 5, 6, 7), it is in particular to give the body a series of predefined static postures and to compare the real measurements with theoretical values, in order to determine the orientation parameters. The larger the series, the better the accuracy. Only one measurement is sufficient if the magnetic field is perfectly known and if the orientation of the segment is determined exactly, but this is not the case in human movements.

Thus, for example, the body is first placed in a posture called "posture 1" which corresponds to the reference posture, that is to say with all angles to 0. Then it is turned (for example) 90 ° clockwise to reach the posture called "posture 2". It is then known that the sensors 401, 402 and 403 measure (the equations being valid for all these sensors):

Or : refers to a measurement taken by the accelerometer when the body occupies the posture ;

means a measurement taken by the magnetometer when the

body occupies the posture;

designates the terrestrial gravitational field;

o denotes the Earth's magnetic field;

o is the angle between ; designate the values of the fields

in a given initial position and measured in the sensor mark; designates the rotation matrix to identify.

Indeed, by convention the Z axis is carried by the vertical and is oriented downwards. Several sizes are to be determined: the orientation matrix and the values of. For this, the following calculations are made:

He comes

It is noted that the first expression (sin (GH)) is an average of the vector products of the measurements of the sensors used and that the second expression (cos (GH)) is an average of the dot products. measurements of the sensors used. Finally, the rotation matrix is determined by:

This data is then included in the measurement model of the sensors in the form of angle triplet. To continue the identification of the geometrical parameters in this embodiment, a step is made to evaluate the lengths of the segments and the positions of the sensors on the segments by means of a gesture protocol. This step relies in particular on an algorithm aiming at reducing the number of degrees of freedom by allowing only plane rotations along constant axes, in order to exploit the a priori knowledge of the constant vector to solve the system.

In a first step, the method for detecting a substantially invariant axis of rotation described in the patent EP1985233 already cited makes it possible, using only the measurements of the magnetometers under the condition of plane motion to which the structure of the sensors is constrained, to find the movement, that is to say to deduce the axis of rotation in the magnetometer and the accelerometer, as well as to deduce the angle of rotation. This makes it possible to validate the evaluation of the orientation of the sensors carried out in the previous step and even to refine it. This also makes it possible to verify that the orientation of the different sensors is the same, that is to say that the axis of rotation calculated from the measurements of the accelerometer is identical to that calculated from the measurements of the magnetometer. undergoing the same movement plan. If this is not the case, it is necessary to carry out an identification of the box geometric parameters, that is to say an identification of the relative geometrical parameters of the relative orientation of the magnetometer and the accelerometer.

In a second step, the accelerometer measurements are used to determine the distance of each sensor to the axis of rotation. The measurements are transformed in the expected reference thanks to the orientation matrices evaluated during the previous step, in order to work with respect to the segments of the body and not with respect to the sensors. The identification of the geometrical parameters must be made in the order in which they are described in the present exemplary embodiment. The axes of rotation naturally pass through the joints of the body. It is therefore necessary to define a protocol to excite enough axes to determine the three components of the vectors lengths and positions.

FIG. 5 illustrates a rotation of the entire body about a vertical axis 505 assimilable to the axis of the body, the shoulder-arm-forearm assembly being held taut in a horizontal plane during the rotation of the body around the body. axis A1. We define:

Or :

o is the measurement taken by the sensor magnetometer ;

o denotes a function that returns the axis of rotation obtained by the method described in patent EP1985233 already cited;

o denotes a function that returns the arithmetic mean.

We then have, for :

Or :

FIG. 6 illustrates a rotation of the arm-forearm assembly about a horizontal axis 605, perpendicular to the plane of the figure and passing through the articulation connecting the shoulder to the arm, the arm-forearm assembly being held taut during rotation. We define:

We then have, for :

With: FIG. 7 illustrates a rotation of the forearm about a horizontal axis 705, perpendicular to the plane of the figure and passing through the articulation connecting the arm to the forearm, that is to say the elbow, the shoulder-arm assembly being held taut during rotation. We define: We then have:

With:

Using the relationships above, the following equations can be deduced

Finally, the lengths of the segments can be estimated according to the X component:

For the second length, it is best to evaluate the average of the two equations above to improve the quality of the estimate.

The same can be done on the other axes of the body, so as to define the other components of the vectors lengths and positions.

While remaining within the scope of the present invention, it is also possible to make the articulated structure perform less constrained movements than those used in the embodiments of FIGS. 5, 6 and 7. In these cases, it will not be possible to apply the predictive models of the simplified measures used in these embodiments. It will however be possible to apply the steps of the method of the invention, provided that the 3 ^rd step of the parameter estimation process will use a predictive model of more complex measures such as described in the application patent filed on the same day as the present application by the same applicants having the same inventor and entitled "METHOD OF IDENTIFYING THE GEOMETRIC PARAMETERS OF AN ARTICULATED STRUCTURE AND A SET OF INTEREST ROUNDS DISPOSED ON THE SAME STRUCTURE". According to this invention, the measurement model represented by the following equation is used:

Indeed, we have accelerometric measurements and the representation of motion through step 2 of the present invention. So we can build the vector through equality: We can also build the matrix through equality:

With if i is in the chain between the origin of the skeleton and the segment j

And otherwise

Once, it is matrix built, it remains only to solve the problem of least squares following:

With

Once PosLong estimated, it remains only to collect the parameters according to the arrangement given in the previous equation.

This method is advantageous because it expresses the estimate as a linear least squares problem, so calculating the estimate is explicit and optimal.

According to this invention (patent application filed on the same day as the present application by the same applicants having the same inventor and entitled "METHOD OF IDENTIFYING THE GEOMETRIC PARAMETERS OF AN ARTICULATED STRUCTURE AND A SET OF INTEREST RECORDS" ARRANGED ON THE SAID STRUCTURE "), the measurement model is advantageously solved, even if only a small number of gyrometers are available to complete the measurements of accelerometers and magnetometers, by calculating pseudo-static states which can to be substituted, each time the system is in a pseudo-static state, with the values calculated by a state observer of the Kalman type. These steps of the method of the invention are implemented in a software way, some parts of the software can be embedded in the sensors, others can be implanted on a micro-controller, a microprocessor, or a connected microcomputer. to the sensor system. These processing capabilities are ordinary circuits, connected and configured to perform the treatments described above.

The examples described above are given by way of illustration of embodiments of the invention. They in no way limit the scope of the invention which is defined by the following claims.

Claims

A method for determining the position of a set of sensors in a coordinate system (102) linked to a segment of an articulated chain, said set of sensors comprising at least one accelerometer and being integral with said articulated chain, said method being characterized in that it comprises:

^■ A first step (202) for determining the orientation of a mark (101) connected to the sensor array relative to the reference (102) connected to said segment for at least one selected of said articulated chain configuration,

^■ A second step (203) for estimating the movement of said reference linked to

the set of sensors in the terrestrial frame (104) during at least one movement of said segment,

^■ A third step (204) for calculating said position of said set of

sensors in the frame linked to said segment, said third stage receiving as input the estimation of the movement of said marker linked to the sensor at the output of the second stage and the measurements of said accelerometer during said at least one movement.

2. Method according to claim 1, characterized in that the first step comprises a first substep of calculating a first matrix of passage of said reference linked to the set of sensors to a grounded marker and a second subset. step of calculating a second matrix of passage of said land-related marker to a marker linked to said segment.

3. Method according to claim 2, characterized in that the first calculation sub-step uses at least one measurement of at least one second sensor of said set of sensors, said second sensor being able to provide measurements of at least one sensor. physical field substantially uniform in time and space or rotational speed.

4. Method according to claim 3, characterized in that the first calculation step further comprises a substep of calculation prior to said first substep during which a third transition matrix is calculated between a moving marker and said earth-bound landmark, said third land passing matrix being either selected or determined from measurements of at least one substantially uniform physical field in time and space or measurements of the rotational speed of said moving mark relative to said earth-bound mark.

5. Method according to one of claims 2 to 4, characterized in that the first step is performed for at least two configurations of said articulated chain.

6. Method according to claim 1, characterized in that, prior to the first step, a first substep of determining a substantially invariant axis of rotation of said segment is carried out.

7. Method according to one of claims 1 to 6, characterized in that the second step uses the outputs of at least one sensor selected from the group comprising the accelerometer and a second sensor of said set of sensors, said second sensor being capable of providing measurements of at least one substantially uniform physical field in time and space or rotational speed.

8. Method according to one of claims 1 to 7, characterized in that, during the second step, said at least one movement of the segment is a substantially invariant axis rotation.

9. Method according to one of claims 1 to 8, characterized in that, during at least the second and third steps, using a predictive model of the outputs of the accelerometer chosen according to the type of movement of said segment and calculating the position of said set of sensors on said output segment of an algorithm minimizing errors between measured values and predicted values.

10. Method according to one of claims 1 to 9, characterized in that said articulated chain comprises at least N segments, N being greater than or equal to two.

11. The method of claim 10, characterized in that it further comprises a step during which the length of at least one segment of said articulated chain is calculated.

12. Method according to claim 11, characterized in that the calculation of a segment i inserted into an articulated chain comprising j segments, j being greater than 1 and i, is performed by solving the equation

in which :

- PosLong is the vector

- The acceleration without base at time t is calculated by the formula

13. Method according to one of claims 11 to 12, characterized in that said articulated chain is a part of a human body or a humanoid structure.

14. The method of claim 13, characterized in that the configurations of said articulated chain are determined by executing at least N successive predefined gestures, each gesture allowing only a rotation of all or part of the segments of said chain in a single plane about a single axis passing through a hinge connecting two segments, the segments other than the two said segments remaining aligned during said rotation, so that segment rotations are performed around at least N distinct axes.

15. The method of claim 14, characterized in that N> = 3, a first segment corresponding to a shoulder, a second segment corresponding to an arm connected to the shoulder and a third segment corresponding to a forearm connected to the arm by an elbow, the execution of predefined gestures including, in order:

a rotation of the entire body about a vertical axis (105) assimilable to the axis of the body, the shoulder-arm-forearm assembly being kept taut in a horizontal plane during the rotation of the body about said axis, and;

a rotation of the arm-forearm assembly about a horizontal axis (205) and passing through the articulation connecting the shoulder to the arm, the arm-forearm assembly being kept taut during said rotation, and ; - A rotation of the forearm around a horizontal axis (305) and passing through the elbow connecting the arm to the forearm, the shoulder-arm assembly being held taut during said rotation.

16. The method of claim 15, characterized in that each segment rotation is performed around an axis passing through a joint.

17. A system for determining the position of a set of sensors in a frame linked to a segment of an articulated chain, said set of sensors comprising at least one accelerometer and being integral with said articulated chain, said system being characterized in that that he understands:

A first module (202) for determining the orientation of a marker linked to the set of sensors to said marker linked to said segment for at least one configuration of said articulated chain,

■ A second module (203) for estimating the movement of said reference linked to

the set of sensors in the terrestrial frame during at least one movement of said segment,

^■ A third module (204) for calculating said position of said set of

sensors in the coordinate system linked to said segment, said third module receiving as input the estimation of the movement of said reference linked to the sensor at the output of the second module and the measurements of said accelerometer during said at least one movement.