阅读说明：本技术 体育锻炼设备及用于在这种设备上进行训练的方法 (Physical exercise device and method for training on such a device ) 是由 A·贝当古 A·查涅 P·马洛塞 于 2019-11-20 设计创作，主要内容包括：公开的体育锻炼设备(2)包括配备有曲柄组和鞍座(26)的框架(2’),鞍座本身包括固定到框架的底架(262),两个鞍形部分(266)和用于使每个鞍形部分相对于底架围绕俯仰轴(A26)、围绕侧倾轴(B26)以及围绕横摆轴(L26)铰接的构件(267、268)。该设备(2)还包括传感器(30、50),用于检测每个鞍形部分分别围绕俯仰轴、侧倾轴和横摆轴的俯仰运动(T)、侧倾运动(R)和横摆运动(L),这些运动是由于用户踩踏板引起的。至少一个计算单元(40)被配置为从传感器的输出信号(S-(30),S-(50))中确定俯仰运动(T)、侧倾运动(R)和横摆运动(L)的角幅度(α,β,γ)。设置至少一个屏幕(29),以便根据由计算单元(40)确定的角幅度,显示每个鞍形部分上的在踩踏板过程中用户坐骨的支承点(P-(G),P-(D))的位置。(The disclosed gymnastic device (2) comprises a frame (2') equipped with a crank set and a saddle (26), which itself comprises an underframe (262) fixed to the frame, two saddle-shaped portions (266) and members (267, 268) for hinging each saddle-shaped portion with respect to the underframe about a pitch axis (a26), about a roll axis (B26) and about a yaw axis (L26). The device (2) further comprises sensors (30, 50) for detecting pitch (T), roll (R) and yaw (L) movements of each saddle-shaped portion about a pitch axis, a roll axis and a yaw axis, respectively, which movements are caused by the user pedaling. At least one calculation unit (40) is configured to derive an output signal (S) from the sensor 30 ，S 50 ) Determining the angular amplitudes (α, β, γ) of the pitch (T), roll (R) and yaw (L) movements. At least one screen (29) is provided to display, on each saddle-shaped portion, the points of support (P) of the user's ischial bones during pedaling, according to the angular amplitude determined by the calculation unit (40) G ，P D ) The position of (a).)

1. An exercise apparatus (2) comprising a frame (2') equipped with a crank set (24) and a saddle (26) itself comprising an underframe (262) fixed to the frame, two saddle-shaped portions (264, 266) and members (267, 268) for hinging each saddle-shaped portion with respect to the underframe about a pitch axis (a26), about a roll axis (B26) and about a yaw axis (L26), characterized in that it comprises:

-sensors (30, 50) for detecting pitch (T), roll (R) and yaw (L) movements of each saddle portion about a pitch, roll and yaw axis, respectively, which movements are due to a user pedaling;

-at least one calculation unit (40) configured to depend on an output signal (S) from the sensor₃₀，S₅₀) Determining the angular amplitude (alpha) of the pitch (T), roll (R) and yaw (L) movements_G，α_D，β，γ)；

-at least one screen (29, 200, 300) for displaying, on each saddle-shaped portion, the supporting point (P) of the user's ischial bones when pedalling, according to the angular amplitude determined by the calculation unit (40)_G，P_D) The position of (a).

2. The apparatus according to claim 1, characterized in that the detection sensor comprises at least one inertial unit (30), the inertial unit (30) being attached to each saddle-shaped portion (264, 266).

3. An arrangement according to claim 2, characterized in that the inertial unit (30) detects pitch (T) and roll (R) movements and at least one optical sensor (50) is used to detect yaw (L) movements of each saddle-shaped part (264, 266).

4. The apparatus according to any one of the preceding claims, characterized in that the calculation unit (40) is configured to determine each support point (P) on the saddle-shaped portion_G，P_D) Is compared with a reference position (S)_G，S_D) And the screen (29) is configured to display the deviation.

5. The device according to any one of the preceding claims, characterized in that the screen (29) is located in front of a user sitting on the saddle (26), preferably on the handlebar (28) of the device (2).

6. A method for training a user on a gymnastic device (2) according to any one of the preceding claims, characterized in that it comprises the steps of:

a) detecting (104, 106) a pitch motion (T), a roll motion (R) and a yaw motion (L) by means of sensors (30, 50);

b) determining (110, 112, 114) the angular amplitudes (a) of the pitch (T), roll (R) and yaw (L) movements_G，α_Dβ, γ); and

c) displaying (122) on the screen (29) ischial support points (P) according to the angular amplitude determined by the calculation unit_G，P_D) The position of (a).

7. Method according to claim 6, wherein the device is according to claim 3 and step b) comprises the sub-steps of:

b1) calculating (110) approximate pitch and roll amplitude values (α ', β') based on vector components (Ax, Ay, Az, Gx, Gy, Gz) of the pitch (T) and roll (R) movements determined by the inertial unit (30), preferably by a 6-axis Madgwick algorithm;

b2) calculating (112) an output signal (S) from the magnetometer on the basis of the output signal of the optical sensor (50) and the approximation calculated in sub-step b1)₅₀) The corresponding vector components (Mx, My, Mz);

b3) pitch, roll and yaw amplitude values (α, β, γ) are calculated (114), preferably by a 9-axis Madgwick algorithm.

8. According to claim 6 or 7The method of any of, characterized in that in step c), the screen also displays the angular amplitude (α) determined in step b)_G，α_D，β，γ)。

9. The method according to claim 8, characterized in that it comprises the additional step of:

d) determining a representative of said angular amplitude (a)_G，α_Dβ, γ) of each angular amplitude (α) of the symbol (588)_G，α_Dβ, γ) correspond to the respective sizes of the symbols;

e) displaying the symbol determined in step d) on said screen (29).

10. Method according to any one of claims 6 to 9, wherein the apparatus is according to claim 4, and wherein, in step c), the screen shows a representation (564, 566) of the saddle-shaped portion (264, 266), the ischial support position (P) relative to the representation of the saddle-shaped portion_G，P_D) And a representation (C) of a reference position relative to the representation of the saddle-shaped part_G，C_D)。

Technical Field

The present invention relates to a gymnastic apparatus, comprising in particular a saddle having two saddle-shaped portions capable of performing pitch, roll and yaw movements with respect to a frame. The invention also relates to a method for training a user on such a device.

Background

In the field of motor training, functional rehabilitation or fitness maintenance for elderly people, it is known, for example from WO-A-2013/135697, to use A proprioceptive saddle comprising two saddle-shaped portions capable of performing pitch T, roll R and yaw L movements with respect to the frame of the gymnastic apparatus. Before the user begins to step on the pedals, the health care professional or trainer may adjust the exercise machine in advance taking into account the user's body dimensions and possible pathological conditions. Depending on the user's body shape, it is not easy to check that the user is sitting correctly on the saddle, since the pelvis and thighs hide the saddle. Therefore, it is uncertain whether the user's posture on the exercise machine is correct. If the user's posture is incorrect, he or she may not be able to fully benefit from exercise and may even develop other pathological conditions due to abuse. Moreover, the possible progress of the user during the continuous exercise phase cannot be quantified.

Disclosure of Invention

The present invention aims to remedy these drawbacks, more particularly by proposing a new gymnastic device which can ensure that the user is correctly positioned on the saddle and which can detect any progress made by the user, in particular the progress of his/her pelvic mobility.

To this end, the invention relates to an exercise apparatus comprising a frame equipped with a crank set and a saddle, the saddle itself comprising an underframe fixed to the frame, two saddle-shaped portions and means for articulating each saddle with respect to the underframe about a pitch axis, about a roll axis and about a yaw axis. According to the invention, the device also comprises sensors for detecting pitch movements T, roll movements R and yaw movements L of each saddle-shaped portion about a pitch axis, a roll axis and a yaw axis, respectively, which movements are caused by the user pedaling. The device further comprises at least one calculation unit configured to determine the angular amplitudes of the pitch movement T, the roll movement R and the yaw movement L from the sensor output signals and the positions of the support points of the ischials on each saddle-shaped portion. Finally, the device comprises at least one screen for displaying the position of the support point of the user's ischial bones when pedalling on the saddle, according to the angular amplitude determined by the calculation unit.

Thanks to the invention, the user or the person assisting him/her, in particular a health professional or coach, is able to assess whether he or she is correctly positioned on the saddle of the gymnastic apparatus of the invention by positioning on the display screen the position of the support point of his or her ischial bones when pedaling. This allows the user or a person assisting him/her to adjust the posture of the user to correct the asymmetry or imbalance of his support. In addition, the device of the invention may allow to compare parameters from one exercise session to another or during the session by tracking these parameters determined by the computing unit in order to assess the possible progress of the user.

According to an advantageous but not compulsory aspect of the invention, such a gymnastic device may incorporate one or more of the following features, taken in any technically allowable combination:

the detection sensor comprises at least one inertial unit attached to each saddle-shaped portion.

The inertial unit detects pitch and roll movements and the at least one optical sensor is used to detect yaw movements of each saddle-shaped portion.

-the calculation unit is configured to determine a deviation between the position of each support point on the saddle-shaped portion and a reference position, and the screen is configured to show the deviation.

The screen is located in front of the user sitting on the saddle, preferably on the handlebar of the device.

According to another aspect, the invention relates to a method for training a user on a physical exercise device as described above, comprising the steps of:

a) detecting a pitch motion T, a roll motion R and a yaw motion L by means of sensors;

b) determining angular magnitudes of pitch, roll and yaw motions; and

c) the position of the ischial support points is displayed on the screen according to the angular amplitude determined by the calculation unit.

This method helps to verify the user's posture and its possible corrections, taking into account the data displayed on the screen.

According to an advantageous but not mandatory aspect of the invention, the method may incorporate one or more of the following features:

-the inertial unit detects pitch and roll movements, the at least one optical sensor is used to detect the yaw movement of each saddle, and step b) comprises the sub-steps of:

b1) calculating approximate pitch and roll magnitude values based on the vector components of pitch and roll motion determined by the inertial unit, preferably by a 6-axis Madgwick algorithm;

b2) calculating a vector component corresponding to the magnetometer output signal based on the output signal of said optical sensor and the approximation calculated in sub-step b 1);

b3) the pitch, roll and yaw amplitude values are preferably calculated by a 9-axis Madgwick algorithm.

In step c), the screen also displays the angular amplitude determined in step b).

-the method comprises the additional steps of:

d) determining a single symbol (588) representing angular magnitudes (α, β, γ), wherein each angular magnitude (α, β, γ) corresponds to a respective size of the symbol;

e) displaying the symbol determined in step d) on a screen (29).

The computing unit is configured to determine a deviation between the position of each bearing point on the saddle-shaped portion and a reference position, the screen being configured to display the deviation, and in step c) the screen displays a representation of the saddle-shaped portion, the ischial support position relative to the representation of the saddle, and a representation of the reference position relative to the representation of the saddle.

Drawings

The invention will be better understood and other advantages thereof will become clearer from the following description of an embodiment of a gymnastic device and of a method for training, according to the general description of the invention, given by way of example only and with reference to the accompanying drawings, in which:

FIG. 1 is a schematic diagram of the principles of a physical exercise device according to the present invention;

FIG. 2 is an enlarged side view of the saddle of FIG. 1 and a schematic view of certain other components of the apparatus;

FIG. 3 is a block diagram of a method according to the present invention;

FIG. 4 is a view of a display screen of the device of FIGS. 1 and 2 implementing the method of FIG. 3; and

fig. 5 is an enlarged view of detail V in fig. 4.

Detailed Description

The device 2 shown in fig. 1 is intended to allow a user to perform physical exercises by pedaling, thereby improving the activity of the pelvis and/or maintaining or even developing cardiovascular functions.

The apparatus 2 comprises a frame 22, which frame 22 is equipped with a crank set 24, and which frame 22 supports a saddle 26 and a handlebar 28, according to a known decomposition of the exercise bicycle. The device 2 is of the exercise bike type.

The crank set 24 includes two cranks and two pedals, only one of which is visible in fig. 1, indicated by the reference numerals 242 and 244, respectively.

Inside the cover 25 a braking system for the crank set 24 is provided, not shown and adjustable, so as to allow the force that the user has to exert on the pedals to be adjusted according to the exercise to be performed.

The saddle 26 is supported by a seat post 27 adjustably mounted on the frame 22, and the seat post 27 is secured by a fastening screw, not shown, controlled by a knob 272.

The screen 29 is mounted on the upper portion of the frame 22, between two branches 282 and 284 of the handlebar 28. This screen 29 is therefore visible to the user sitting on the saddle 26.

The saddle 26 includes an undercarriage 262 attached to the seat post 27 so as to be mounted to the frame 22 by the seat post. Saddle 26 also includes two saddle portions, a left saddle portion 264 and a right saddle portion 266. The saddle also includes a hinge member for each saddle relative to the undercarriage 262. These articulation members include a bracket 267 for articulating saddle portions about a pitch axis a26 defined by the bracket 267, each saddle portion being independent of the other saddle portion. The bracket 267 itself is supported by an elastically deformable element 268 which constitutes another articulated member of the saddle-shaped portion. The elastically deformable element 268 is arranged to elastically deform during a rolling movement R of the bracket 267 about an axis B26 parallel to the forward/rearward direction of the saddle 26. On the other hand, the elastically deformable element 268 is arranged to elastically deform during a yaw movement L of the carriage 267 about an axis C26, which axis C26 is generally vertical and parallel or coincident with the longitudinal axis of the seatpost 27. The pitch motions of saddle portions 264 and 266 are independent of each other, however, their roll and yaw motions R and L are identical because the roll and yaw motions R and L are caused by elastic deformation of an element 268 they share.

Preferably, the technical teaching of WO-A-2013/135697 is applied here.

In a variant, the saddle 26 may be provided with another structure, in particular a saddle-shaped portion with independent pitch, roll and yaw movements.

The saddle 26 is equipped with two inertial units. An inertial unit is located beneath each of the saddle portions 264 and 266, only the units disposed beneath the saddle portion 266 being visible in fig. 2 (reference numeral 30). The reference numeral is used to designate each of the two units.

Each inertial unit 30 is able to detect accelerations along three axes of an orthogonal reference frame X-Y-Z of the space in which the apparatus 2 is installed. Each inertial unit 30 is therefore able to provide three acceleration components Ax, Ay and Az parallel to the X, Y and Z axes, respectively, and three rotation components Gx, Gy and Gz around these axes. Each inertial unit 30 operates at a frequency of 100 Hz.

In practice, each inertial unit 30 may be formed by an electronic card sold by NXP company under the reference BRKT-STBC-AGM01, which integrates two types of inertial sensors, namely an FXOS8700 accelerometer-magnetometer and an FXPS21002 gyroscope. The magnetometer functionality of the FXOS8700 unit is not used here. In other words, the magnetometer is not activated.

In a variant, other types of inertial units may be used.

The components Ax, Ay, Az, Gx, Gy and Gz determined by one of the inertial units 30 represent the pitch movement T and the roll movement R of the saddle-shaped portion 264 or 266 under which the inertial unit 30 in question is mounted.

The output signals from the two inertial units 30 are provided to a computing unit 40 which comprises, among other things, a microprocessor 41 programmed to perform the computing operations detailed below, and a data storage memory 44.

The data link 32 connects each inertial unit 30 to the calculation unit 40 and allows the output signal S30 of the inertial unit 30 in question to be transmitted, which comprises the components Ax, Ay, Az, Gx, Gy and Gz.

The device 2 also comprises an optical sensor 50, the optical sensor 50 being located below the saddle 26 and having a viewing direction towards the saddle 30 in a direction substantially parallel to the axis C26, as indicated by the arrow F50 in fig. 2. The optical sensor 50 is used to determine the yaw movement L of the saddle 26 about the axis C26.

To this end, a target, not shown, may be attached beneath the saddle 26 to facilitate alignment of the optical sensor 50. The target comprises two marked points, namely a reflector or a light emitting diode or a LED.

The optical sensor 50 is mounted on the seat post 27 by means of a support 54 and is connected to the computing unit 40 by means of a data link 52, the output signal S of the optical sensor 50₅₀Flowing through the data link 52, the output signal S₅₀Including the angle corresponding to the instantaneous deviation of the saddle 26 about the axis C26 from the rest position, and/or the angular amplitude y of the yaw movement L of the saddle 26. Optical sensor output signal S₅₀The signal S₅₀Indicating the position 2D, i.e. the pixel coordinates of the target spot with reflector or with LED it detects.

The optical sensor 50 operates at a frequency of 50 Hz.

In practice, the optical sensor 50 may be of the SEN0158 type sold by DFRobot.

In one variation, other optical sensor types may be used.

Sensor assembly 60 is integrated into exercise device 2 in the vicinity of crank set 24 and is capable of detecting the speed of rotation V of crank set 24, the duration D of pedaling and the instantaneous power P of pedaling. This data is collected at a frequency of about 1Hz in order to verify that the speed V and the power D are not too high, in particular in the case of relaxation movements aimed at increasing the activity of the user's pelvis. The sensor assembly 60 further comprises a sensor, not shown and wearable by the user, for determining the heart rate F of the user when pedaling.

The sensor assembly 60 is connected to the calculation unit 40 by a data link 62, the data link 62 allowing to transmit an output signal S60 of the sensor assembly, the output signal comprising quantities V, D and P.

It is noted that even if an inertial unit comprising a magnetometer is known in the literature, including the magnetometers mentioned above as examples, the use of a magnetometer is not preferred in the embodiment of the invention shown in the drawings, since the magnetometer is subject to electromagnetic interference, which may distort the measurement results. Since such interference may occur in the area where the device 2 is installed, in particular because the user or a person assisting him/her, in particular a caregiver or a coach, may be carrying a mobile phone or other electronic device. In addition, some users may have metal hip prostheses installed that constitute a relatively large ferromagnetic mass located near the saddle 26, which may interfere with the operation of the magnetometer. In contrast, the angular amplitude γ of the yaw movement L is relatively small, typically less than 15 °, so that an absolute error of a few degrees will cause a large relative error when measuring this angle.

The use of the optical sensor 50 to supplement the measurement of the yaw movement L with respect to the measurement of the pitch movement T and the roll movement R obtained by the inertial unit 30 avoids the drawbacks caused by the electromagnetic interference of the magnetometer.

However, if the room in which the exercise device 2 is installed can be protected from electromagnetic interference, and if those in the room do not carry electromagnetic devices or large ferromagnetic masses, it is conceivable to use an inertial unit with an active magnetometer instead of the optical sensor 50.

The calculation unit 40 is connected to the screen 29 by a wired data link 42, the output signal S of the calculation unit 40₄₀Over which the data is propagated. The output signal includes information for the user to view on the screen 29 while sitting on the saddle 26.

Signal S₄₀Also included is information for assisting the user's person, which information may be displayed on the screen 29The information shown may be the same or different. In this regard, the signal S40 may be sent to the cellular telephone 200 or portable computer 300 via a wireless data link, such as a radio link, including by way of the wireless network 100, such as a Wi-Fi network or a bluetooth network. The cellular phone 200 or computer 300 may be a cell phone or computer that assists the user's person, or may even be the user's cell phone or computer. These two items may be used to display and store data received from the computing unit 40 for analysis after a session of exercise on the device 2. This data may also be stored in the memory 44.

To the extent that they are used with device 2, cellular telephone 200 and computer 300 are considered display screens of device 2, although unlike screen 29, this is not their only function.

In this example, the computing unit is composed of an electronic card. In a variant, the calculation unit 40 is constituted by several physical units distributed throughout the device 2. In practice, the unit 40 may be located under the cover 25 or on the back of the screen 29.

The distance between the unit 40 and the sensor should be as short as possible. It is preferred to locate the unit 40 close to the saddle 26 and the sensors 30 and 50 rather than locating the unit 40 remote from the saddle 26 and the sensors 30 and 50. Thus, the position under the cover 25 is merely an example.

During the exercise phase of the user on the device 2, the various electronic components described above are activated in a first step 100, and then in a subsequent step 102, the user starts to step on the pedal and remains on the pedal during the exercise.

In step 104 following the start of step 102, each inertial unit 30 is used to detect pitch and roll movements T and R of the saddle 264 or 266 under which the inertial unit 30 is mounted, about the axes a26 and B26, respectively, and to generate a signal S comprising the components Ax, Ay, Az, Gx, Gy and Gz₃₀To the calculation unit 40.

In parallel with step 104, step 106 is implemented by means of the optical sensor 50 to detect the yaw movement L and to include the signal S of the yaw angle detected by the optical sensor 50₅₀Is sent to the computing unit 40。

Still in parallel with step 104, a further step 108 is carried out to detect the parameters V, D and P by means of the sensor assembly 60, the sensor assembly 60 then outputting the signal S₆₀。

The calculation unit 40 is configured to receive the signal S₃₀、S₅₀And S₆₀And several calculation steps are performed by the microprocessor 41.

In a first calculation step 110, the Madgwick algorithm is implemented to determine quaternions representing approximations of the angular amplitudes of the pitch T and roll R motions.

The angular amplitude of the pitch movement T is denoted α and the angular amplitude of the roll movement R is denoted β. The approximate values of the angular magnitudes of pitch and roll determined in step 110 are denoted as α 'and β', respectively.

The "An orientation Filter for inertial and inertial/magnetic sensor arrays" paper published by Sebastian Magdwick at 30.4.2010 and the "Estimation of IMU and MARG orientation using a gradient descent algorithm" paper by Sebastian Magdwick et al (2011IEEE International Conference on robustness rotation, 2011IEEE 6.29-July 1,2011(2011IEEE International Conference on Rehabilitation robot International Conference-Zurich 6.2011 1) entitled "Estimation of IMU and MARG orientation" describe the Magwin algorithm used in this step.

In this case, the Madgwick algorithm is used with six input parameters.

After step 110, a step 112 is implemented in which the value of the angle detected by the optical sensor 50 is converted into three components Mx, My and Mz equivalent to the output signal of the magnetometer. Using the approximate values of pitch and roll as α 'and β' as detected by the optical sensor 50 and incorporated into the signal S₅₀The correction variable for yaw angle in (b) to perform the conversion step 112. In this step 112, the microprocessor 41 converts the data from the optical sensor 50 into Mx, My and Mz type data using the rotation matrix.

The conversion algorithm used in step 112 includes the implementation of the following types of rotation matrices:

the definition of this rotation matrix can be accessed by the following links:

http://doucets.free.fr/Matrice_de_Rotation/rotations_intro_doc.html。

this matrix has been simplified and adapted to the problems of 3D articulated saddles. And then expressed in the following form:

after step 112, a step 114 is implemented in which an algorithm of the Madgwick type is again used, this time using nine input parameters, namely the quantities Ax, Ay, Az, Gx, Gy and Gz, Mx, My and Mz. Thus, this version of the Madgwick algorithm is more complex than the algorithm used in step 110, where only six input parameters are used. In this step the algorithm can determine a quaternion and on this basis calculate the euler angle of the movement of the saddle.

At the end of step 114, the angular amplitudes α, β and γ of the pitching motion.

The calculation frequency of step 110 may be equal to the frequency of step 104 or 100 Hz. The frequency of steps 112 and 114 equals 100 Hz. In one variation, it may be equal to the frequency of step 106 or 50Hz, calculating roll and yaw. Hz.

Steps 110, 112 and 114 are repeatedly performed to restore the quantities representing the three movements, pitch R, roll R and yaw L, of each saddle portion 264 or 266. Thus, six angular values representing the angular amplitude of these movements are obtained, i.e.

Pitch angle α of left saddle portion 264_G；

Pitch angle α of right saddle portion 266_D；

The side inclination β of the left saddle portion 264_G；

The side inclination β of the right saddle-shaped portion 266_D；

Yaw angle γ of left saddle portion 264_G(ii) a And

yaw angle γ of right saddle shaped portion 266_D。

In this regard, it can be noted that steps 104 and 110 are carried out by a first inertial unit 30 for the left saddle portion 264 and a second inertial unit 30 for the right saddle portion 266.

After step 114, the calculation unit 40 carries out a selection step 116 at a frequency equal to that of step 114, to select four representative angles from the above six angles. Since the pitch motions T of saddle portions 264 and 266 are independent, angle α is chosen separately_GAnd alpha_D. Since the roll motions R of the saddle-shaped parts are linked, the angle β is_GAnd beta_DMay be identical or nearly identical and only one of them is selected, which is called β. Similarly, since the yaw movement L of the saddle-shaped part is linked, the angle γ is_GAnd gamma_DMay be considered to be identical or nearly identical and only one of them is selected, which is referred to as γ hereinafter.

After step 116, a step 118 is implemented, in which the signal S₄₀From the calculation unit 40 to the screen 29. The signal S₄₀Including a selected angle alpha_G、α_Dβ and γ, and the speed V, duration D, pedaling power P and heart rate F that have been provided by the sensor assembly 60.

The screen 29 receives the signal S in step 120₄₀And in step 122 the signal S is displayed from the display using the human machine interface visible in fig. 4₄₀Some of the data of (1).

On this human-machine interface, two icons 564 and 566 represent the saddle portions 264 and 266, respectively. Here, icons 564 and 566 form saddle portion symbols for saddle portions 264 and 266, respectively. Text box 580 is used to display user identifiers such as first and last names. Buttons 590, 592, and 594 are provided to start, pause, or stop, respectively, the operation of exercise device 2. The above step 100 is initiated by pressing the start button 590.

A horizontal bar 582 is located at the bottom of the screen 29 and is used to display tread time and/or power, particularly by color coding. In this example, the tread time is represented by a rectangle 584, the horizontal width of which increases according to the tread time. Within the bar 582, several areas 582a, 582b, 582c and 582d may be displayed, during which the user is to achieve different tread powers, in this example four tread powers P1, P2, P3 and P4 are marked with different colors or in other ways.

The graphical area 586 is used to display a symbol 588 whose geometry varies according to the angles of the pitch motion T, roll motion R and yaw motion L. Symbol 588 forms an angle α_G，α_DThe angular amplitude signs of beta and gamma, i.e. the angle alpha_G，α_D，β_G，β_D，γ_GAnd gamma_DBecause of the angle beta_GAnd beta_DSame, angle γ_GAnd gamma_DThe same is true.

The result of step 116 is selected to support point P of the user's left ischial bones on saddle 264_GAnd a point P on saddle 566 to support the user's right ischial bones_DIs displayed on the screen 29.

In particular, the graphical interface of the screen 29 is designed so that the x-axis, coinciding with the axis a26 in the embodiment of fig. 4, represents the value of the roll angle β, while the y-axis, coinciding with the axis B26 in the embodiment of fig. 4, represents the left pitch angle α_GAnd right pitch angle alpha_DThe value of (c).

Thus, can be based on the angle α_GAnd β in the A26 and B26 axis coordinate systems to show point P_GAnd according to the angle alpha_DAnd beta in the same coordinate system to display the point P_D。

In fact, the support of the user's ischials on the saddle-shaped portions 264 and 266 is not temporary, but is distributed over a relatively small area, less than a few cm². The supporting point of the ischial bones is defined as the center of the area.

Ideally, the support point P_GIs inscribed on curve C_GInner, the curve C_GAn area corresponding to the correct positioning of the left part of the user's pelvis on the saddle portion 264 is defined. Curve C_GAs embodied on the screen 29 by the dashed lines within the icon 564. Similarly, curve C_DA point P is defined within the icon 566_DThe area in which it should normally be located. On the screen 29 by curve C_GAnd C_DSurrounding region S_GAnd S_DDefine a point P_GAnd P_DIs determined by the acceptable reference position. Curve C_GAnd C_GAnd a surface S_GAnd S_DMay be stored in memory 44, thereby allowing unit 40 to determine each support point P_GOr P_DAnd the corresponding reference position (i.e., surface S)_GOr S_DThe upper point) of the data. The screen 29 is configured to display a point P_GAnd P_DWith the surface S_GAnd S_GThe relative position of the two elements is used to indicate the deviation.

In FIG. 4, on the surface S_GOuter point P_G1Corresponding to a situation where the user is too far forward on the saddle 26, which results in too large a pitch amplitude. This entails the risk of sliding forward, which requires adjustment of the rearward movement of the saddle.

Also on the surface S_GOuter point P_G2Indicating a situation where the user is too far back, which results in too little pitch. This results in under-exercise, or is not optimal for good physiological movement, and requires adjustment of the person's position on the bicycle by the rearward or height of the saddle.

The following can also be considered: support point P_GAnd P_DAre not symmetrically arranged with respect to the space defined between saddle portions 264 and 266, since these points P_GAnd P_DThe positioning on screen 29 lacks symmetry and can be seen on icons 564 and 566. This lack of symmetry in positioning must be corrected because it can lead to lack of movement or is not optimal for good physiological movement and requires the person to center himself/herself correctly in the seat.

Therefore, suppose a songLine C_GAnd C_DPermanently displayed on the screen 29, in particular as part of the icons 564 and 566, the user can identify his/her support point P by looking at the screen 29 in front of him/her_GAnd P_DCorrect his/her posture in an intuitive way, if necessary by being guided by a person assisting him/her, moving over the saddle-shaped part.

Point P_GAnd P_DThe position in the horizontal direction in fig. 4, i.e. parallel to the axis a26, has an influence on the angular amplitude β of the roll movement R. Point P_GAnd P_DThe closer to the space between the saddle portions, i.e. to the axis B26, the greater the roll movement R. Please note that point P_GAnd P_DThe spacing between them is a result of the anatomy of the user and cannot be altered.

The human-machine interface also comprises a representation of a yaw movement L, taking the arrow F oscillating around the axis B26_LHas an angular amplitude as a function of the value of the angle. To facilitate the arrow F_LThe point of articulation P of this arrow on the screen 29_LOffset from axis C26 along axis B26. This allows arrow F_LCurve C not located in icons 564 and 566_GAnd C_DIn the same section.

Instead, the symbol 588 is generated based on the parameters calculated by the unit 40 in step 116.

As shown in fig. 5, the symbol 588 is two-dimensional and extends in width parallel to the axis L588 and in height parallel to the axis H588. Conventionally, the width of the portion of the symbol 588 to the left of the axis H588 may be taken to represent the roll angle β observed for the left saddle portion 264_GQuasi-instantaneous values of. Similarly, the width of the portion of the symbol 588 to the right of the H588 axis represents the quasi-instantaneous side-tilt angle β of the right saddle-shaped portion 266_D. By "quasi-instantaneous" it is meant that the roll angle value is the average of the most recently taken values (e.g., the most recent 10 positions).

The median M588 of the symbols 588 is defined as a curve equidistant from its inner edge B588 and its outer edge B588.

Conventionally, the height between the endpoints of the median M588 in the left part of the symbol 588 may be taken as the average value a representing the pitch angle of the left saddle portion 264_GAnd the same distance in the right part of the symbol 588 represents the average value a of the pitch angle of the right saddle-shaped portion 266_D. L588. The average value for the pitch angle values is calculated from the last 10 values, from the values since the start of the phase, or according to any other suitable calculation rule.

Conventionally, the distance between median M588 and inner edge b588 may also be considered to represent the average value γ of the yaw angle of left saddle 264_GAnd the distance between the median value M288 and the outer edge B588 represents the average value γ of the yaw angle of the right saddle-shaped portion 266_D. The average value for the yaw angle is achieved in the same way as the pitch angle or in another suitable way.

The skilled person will then understand that the particular way of displaying the angular amplitudes α, β, γ is a second aspect of the invention, which differs from the first aspect of the invention, which corresponds to the detection of movements in the pitch movement T, roll movement R and yaw movement L, and the determination of the associated angular amplitudes α, β, γ.

In particular, the second aspect of the invention comprises determining a single symbol 588 representing a plurality of angular amplitudes α, β, γ, wherein each angular amplitude α, β, γ corresponds to a respective size of the symbol.

As an optional addition, the determined single symbol 588 represents a plurality of angular amplitudes α, β, γ of each of the two saddle portions 264, 266, wherein the single symbol is broken down into separate first and second portions, wherein the first portion corresponds to the left saddle portion 264 and the second portion corresponds to the right saddle portion 266. To facilitate user interpretation of the quantities displayed, the first and second portions are preferably disposed on opposite sides of a reference axis (e.g., the H588 axis), e.g., the first portion is to the left of the reference axis and the second portion is to the right of the reference axis.

As a further optional addition, at least two angular amplitudes α, β respectively correspond to the dimensions of the symbol in the respective directions, andone angular amplitude α, β is different from each other. In the example of fig. 5, the angular amplitude β of the roll motion R of each saddle-shaped portion 264, 266_G、β_DCorresponds to the dimension of the symbol 588 in the horizontal direction, i.e. parallel to the axis L588, and the angular amplitude a of the pitch movement T of each saddle-shaped portion 264, 266_G、α_DThe representation of (a) corresponds to the dimension of the symbol 588 in a direction (e.g., vertical) perpendicular to (i.e., parallel to the axis of H588) the direction associated with the roll motion R.

In the above example, considering that saddle portions 264 and 266 rotate integrally about the axis C26 and a single sensor 50 is used to measure the yaw angle γ, angle γ is therefore_GAnd gamma_DIs the same, which corresponds to curve M₅₈₈The fact of being the median of the symbols 588. However, according to the following variant, in particular, an optical sensor below each saddle-shaped portion 264, 266 is also possible.

To easily identify the location of the median value M588, the portions of the symbols 588 located on either side of the median value may be colored differently.

The display of a symbol 588 on the screen 29 allows the user to verify that the motion of each saddle portion 264 and 266 is regular and coordinated, i.e., apparently smooth. The symmetry of symbol 588 with respect to axes L588 and H588 also allows the user to ensure that the saddle motion is balanced. In practice, the geometry of the symbol 588 is comparable to the geometry of an "infinite" symbol. For a preset exercise program, the indication of smoothness and compliance of the pedaling motion may be the shape of the symbol 588 approaching the shape of an "infinite" symbol.

According to an embodiment of the invention, not shown, an optical sensor may be positioned below each saddle shaped section 264 and 266, which then allows determining the respective yaw motion of the two saddle shaped sections independently of each other. The calculation steps 110 to 118 and the display step 122 are then adjusted.

Instead of optical sensors, the calculations performed in the unit 40 are adjusted in the aforementioned case of an inertial unit with activated magnetometers. Steps 110 and 112 are omitted and step 114 is performed directly from the output signal of the inertial unit 30.

The values of the magnitudes α, β and γ of the pitch, roll and yaw angles calculated in step 114 may be stored in memory 44 and in the memories of devices 200 and 300, if necessary. Thus, the changes in these values may be observed during a session of physical exercise on the device 2, and these values may be compared during successive sessions of physical exercise on the device or even during the same session. Thus, the invention makes it possible to monitor the performance of the user.

It is also possible to store the values V, P, F and D of the exercise phase, or more precisely a table giving the values of speed V, power P and heart rate F as a function of the time D elapsed since the start of the phase, which makes it possible to evaluate the pace and energy changes of the user during the phase. Again, this allows the progress of the user to be tracked.

Preferably, the symbol 588 is obtained by combining the magnitudes of the pitch motion T, roll motion R and yaw motion L during use of the device (e.g., during an exercise phase).

Instead of the Madgwick algorithm mentioned above, other comparable types of algorithms, including the Mahony algorithm, may be used for steps 110 and 114. Likewise, for the algorithm used for the inversion step 112, another type of rotation matrix may alternatively be used, and may for example be based on the angle β on the one hand_GAnd beta_DOn the other hand on the basis of gamma_GAnd gamma_DA selection is made 116 or another selection may be made.

The data links 32, 42, 52 and 62 are, for example, wired links or, in a variant, wireless links, for example radio links.

According to an embodiment of the invention, not shown, the screen 29 may be omitted and used for displaying the support point P_G、P_DOnly on the screen of the auxiliary hardware, such as the screen of telephone 200 or computer 300, or any other screen of the user terminal considered to be part of the gymnastic device 2.

The embodiments and variations considered above may be combined to produce new embodiments of the invention.