2.1. Mechanical structure of robotic brace

Concerning the three-point pressure technique, the designed prototype of a robotic brace fits specially to a volunteer. The designed brace consists of three articulated rings that may be adjusted to fit the human body better. They are held on the trunk’s pelvic, mid-thoracic, and upper thoracic regions, Fig. 5(b). The pelvic ring is tightly fixed to the pelvis, so it is considered immobile regarding the pelvic reference frame. The mid-thoracic ring can move relative to the pelvic ring in a six-degrees-of-freedom (DOF) motion.

Figure 5. Outline of brace concept: (a) 3D scan of the body; (b) 3D-printed three rings; (c) Rings assembled with mounting parts; (d) Fully assembled robotics brace.

In the same way, the upper ring can move relative to the mid-thoracic ring in a 6 DOF motion. It provided each relative mobility by combining six linear actuators arranged between two consecutive rings like a Stewart–Gough platform. Therefore, it is twelve actuators integrated into the device. Rings are patient-specific, so we have implemented a particular procedure to design and manufacture them. The three rings exert forces on the patient’s body based on the three-point pressure bracing technique: Optical scanning got a 3D scan of the body, Fig. 5(a). Next, we make a 3D CAD model of the scan body shape using the 3D scan data. Then, this model superimposed the 3D CAD model of the spine to get the spine model’s approximate location of the spine vertebrae. Next, the areas and sizes of the three rings are determined. Finally, we designed a brace ring using rigid 3D-printed material, Fig. 5(b).

Before integrating the accurate actuators, we developed a complete model of the device (including printed actuators and sensors). Then, we have additive fabrication to have a precise understanding of the overall volume of this device and its mobilities, thus having a reasonable expectancy of patient comfort when fitted with our brace, Fig. 5(c).

2.2. The various components of the device

To drive the two Stewart–Gough platforms, this brace is equipped with twelve linear electric actuators. The joints between each actuator and each ring are universal joints (U) disposed at the base and the top of the actuators. The sliding link is the one that is actuated (P) So, each actuator constitutes a leg for the parallel mechanism, giving the robot a 6UPU structure.

Moreover, the actuators have an attached load cell at the base for measuring the actuated force/torque driven through a conditioning board to control the input and output voltage for each actuated parallel platform of the brace. A motor driver is used for the Pulse Width Modulation control (PWM) of each linear actuator which has a built-in potentiometer. All the control modules of the brace are driven through a real-time controller. The various elements of the brace are explained below.

2.2.1. The linear electric actuators

The linear actuators integrated with this robotic brace are from Actuonix Company with a gear ratio of 210:1 and operate at 12 V (a higher gear ratio leads to applying higher force by the robotic brace on the spine). They provide 5 cm of stroke length; see Fig. 6(a). They are capable of a peak force of 45 N and a peak speed of 5 mm/s allowing a peak power point of 62 N with a rate of 3.2 mm/s (allows consistent control of brace movement). They have high flexibility and make up a configurable and compact platform for the smooth mobility of the robotic brace. The linear actuators have a built-in potentiometer that provides a position feedback signal that can be input to the robotic brace controller to modulate brace mobility. Although they have an optional onboard microcontroller, we developed an external control device and drove the actuator at high frequency. We describe explicit expressions for the movement of the actuators in mechanical design parts. A similar approach and mathematical formulations are in [Reference Ray, Nouaille, Colobert and Poisson33–Reference Waldron and Hunt35].

Figure 6. (a) Robotic brace with actuator and load cell; (b) Mounting parts.

A series of holes have been built in the three rings to place the actuators in the best configuration on the brace and to respect the architecture of the Stewart–Gough platform. The actuator’s lower and upper parts are fitted with universal joints Fig. 6(a). The actuated legs are mounted on the rings with eighteen especially patient-dedicated 3D-printed mounting parts (six 3D mounting parts on each ring), Fig. 6(b). This technical choice makes it possible to fix the ends of the six legs on elliptical curves around the patient-adapted rings.

2.3. Hardware and software configurations of the brace

A first 6 DOF parallel-actuated module is attached between the lower and middle ring, and a second one is between the middle and upper ring. Each module contains six actuators and two universal joints disposed at the extremities of the actuators. The actuators are driven at 12 V and 2 A employing a PWM signal of 1000 Hz; a built-in potentiometer in the actuator provides the position feedback of each actuator. The position feedback of each actuator is sent to the external controller. Each actuator integrates with a load cell on the underside of a part and conditioning that amplifies the load cell signals and sends them to the external controller of the brace to control the whole mechanism of the robotic brace. The actuator’s position feedback and load cell voltage data are multiplexed and sent to the control board to drive the entire mechanism of the robotic brace. Position and force sensors can be used for control of every ring relative to the adjacent ring. With this architecture, the mid-thoracic ring can be controlled using the pelvic ring as a reference, either in force or position mode. Similarly, the thoracic ring can be controlled with respect to the thoracolumbar ring.

The system is portable and uses a controller programmed in Matlab and LabVIEW with custom-made electronic boards for real-time control of the motors and sensor communications.

A Lithium-polymer battery is the primary power source to run all the electronics. It can provide power to the system and continues to run all the mechanisms of the brace for up to 3–4 h with an output of 74 W of assistive force into the passive module.

3.1. Description of the mechanism of the platform

This section details the kinematic analysis of the Stewart–Gough platform, which is the fundamental principle of this designed robotic brace. Where Fig. 7 shows the architecture of the two parallel platforms. The kinematic structure of each leg is a UPU arrangement where linear electric actuators actuate prismatic links.

Figure 7. (a) Schematics of the robotic brace, (b) Brace on volunteer.

The actuators connect the fixed base to the moving platform at points $\textbf{A}_{{\boldsymbol{{i}}}}$ and $\textbf{B}_{{\boldsymbol{{i}}}}$ , i = 1, 2, …, 6. All the attachment points $\textbf{A}_{{\boldsymbol{{i}}}}$ ’s lie in the fixed base, and all the $\textbf{B}_{{\boldsymbol{{i}}}}$ ’s lie in the moving platform [Reference Tasi36]. $\textbf{O}_{\textbf{A}}$ and $\textbf{O}_{\textbf{B}}$ are the center of the rings.

3.2. Mechanism models

We attached the fixed frame F_A to the base with center the point $\textbf{O}_{\textbf{A}}$ . Vectors ${\boldsymbol{{a}}}_{{\boldsymbol{{i}}}}$ give the position of attachment points on the fixed base. Similarly, the moving frame F_B is attached to the moving platform with center the point $\textbf{O}_{\textbf{B}}$ , vectors give the position of moving attachment points ${\,\boldsymbol{{b}}}_{{\boldsymbol{{i}}}}$ ’s. Its length ${\,\boldsymbol{{l}}}_{{\boldsymbol{{i}}}}$ describes the geometrical parameter of each leg and unit vector ${\boldsymbol{{q}}}_{{\boldsymbol{{i}}}}$ denotes its direction.

The vector $${{\bf{P}}_{\bf{B}}} = {[{{\bf{P}}_{{\bf{B}}x}},{{\bf{P}}_{{\bf{B}}y}},{{\bf{P}}_{{\bf{B}}z}}]^{\bf{T}}}$$ describes the point $\textbf{O}_{\textbf{B}}$ of the moving platform. The rotation matrix $\textbf{R}_{\textbf{B}}$ describes the orientation of the moving platform [Reference Tasi36, Reference Taghirad37].

To analyze the inverse kinematic, we assume that the position P _B and orientation of the moving platform $\textbf{R}_{\textbf{B}}$ are to get the joint variable of the legs (actuator), $\textbf{L}=[{{\boldsymbol{{l}}}_{\textbf{1}}}{,{\boldsymbol{{l}}}_{\textbf{2}}}{,\ldots,{\boldsymbol{{l}}}_{\textbf{6}}}]^{\textbf{T}}$ .

From the geometry as illustrated in Fig. 7(a), the closed-loop equation for each leg, i = 1, 2, …, 6 is:

(1) \begin{equation}{{\boldsymbol{{l}}}_{{\boldsymbol{{i}}}}} {{\boldsymbol{{q}}}_{{\boldsymbol{{i}}}}}=-{{\boldsymbol{{a}}}_{{\boldsymbol{{i}}}}}+\textbf{P}_{\textbf{B}}+{\boldsymbol{{b}}}_{{\boldsymbol{{i}}}}\end{equation}

The position of the origin $\textbf{O}_{\textbf{B}}$ of frame B relative to frame A, where R _B is composed of three rotations from three angles ( ${\unicode[Arial]{x03C8}} _{\mathrm{B}},{\unicode[Arial]{x03B8}} _{\mathrm{B}},{\unicode[Arial]{x03D5}} _{\mathrm{B}}$ ).

${\boldsymbol{{q}}}=[{{\boldsymbol{{q}}}_{1}}{,{\boldsymbol{{q}}}_{2}}{,\ldots,{\boldsymbol{{q}}}_{6}}]^{\mathrm{T}}$ is the vector of the actuated joint variable of the leg (actuator) of the platform and ${\textbf{X}_{\textbf{B}}}=[{\mathrm{P}_{\mathrm{B{\boldsymbol{{x}}}}}},{\mathrm{P}_{\mathrm{B{\boldsymbol{{y}}}}}},{\mathrm{P}_{\mathrm{B{\boldsymbol{{z}}}}}},{{\unicode[Arial]{x03C8}} _{\mathrm{B}}},{\mathrm{\unicode[Arial]{x03B8}}_{\mathrm{B}}},{{\unicode[Arial]{x03D5}} _{\mathrm{B}}}]^{\mathrm{T}}$ the vector of moving platform (second ring) motion variables [Reference Tasi36, Reference Taghirad37].

A shorthand notation is used for the equation below where (c) denotes cos and (s) denotes sin.

(2) \begin{equation}\textbf{R}_{\textbf{B}}=\left[\begin{array}{c@{\quad}c@{\quad}c} \textbf{c}\boldsymbol{\theta }_{\textbf{B}}.\textbf{c}\boldsymbol{\phi }_{\textbf{B}} & \textbf{s}\boldsymbol{\psi }_{\textbf{B}}.\textbf{s}\boldsymbol{\theta }_{\textbf{B}}.\textbf{c}\boldsymbol{\phi }_{\textbf{B}}-\textbf{c}\boldsymbol{\psi }_{\textbf{B}}.\textbf{s}\boldsymbol{\phi }_{\textbf{B}} & \textbf{c}\boldsymbol{\psi }_{\textbf{B}}.\textbf{s}\boldsymbol{\theta }_{\textbf{B}}.\textbf{c}\boldsymbol{\phi }_{\textbf{B}}+\textbf{s}\boldsymbol{\psi }_{\textbf{B}}.\textbf{s}\boldsymbol{\phi }_{\textbf{B}}\\[5pt] \textbf{c}\boldsymbol{\theta }_{\textbf{B}}.\textbf{s}\boldsymbol{\phi }_{\textbf{B}} & \textbf{s}\boldsymbol{\psi }_{\textbf{B}}.\textbf{s}\boldsymbol{\theta }_{\textbf{B}}.\textbf{s}\boldsymbol{\phi }_{\textbf{B}}+\textbf{c}\boldsymbol{\psi }_{\textbf{B}}.\textbf{c}\boldsymbol{\phi }_{\textbf{B}} & \textbf{c}\boldsymbol{\psi }_{\textbf{B}}.\textbf{s}\boldsymbol{\theta }_{\textbf{B}}.\textbf{s}\boldsymbol{\phi }_{\textbf{B}}-\textbf{s}\boldsymbol{\psi }_{\textbf{B}}.\textbf{c}\boldsymbol{\phi }_{\textbf{B}}\\[5pt] -\textbf{s}\boldsymbol{\theta }_{\textbf{B}} & \textbf{s}\boldsymbol{\psi }_{\textbf{B}}.\textbf{c}\boldsymbol{\theta }_{\textbf{B}} & \textbf{c}\boldsymbol{\psi }_{\textbf{B}}.\textbf{c}\boldsymbol{\theta }_{\textbf{B}} \end{array}\right]\end{equation}

The legs ${\boldsymbol{{l}}}_{{\boldsymbol{{i}}}}\, {\boldsymbol{{q}}}_{{\boldsymbol{{i}}}}$ that connect the vertex points $\textbf{A}_{{\boldsymbol{{i}}}}$ and $\textbf{B}_{{\boldsymbol{{i}}}}$ , for i = 1, 2, …, 6 where these two Stewart platforms are similar, with the following constraints:

(3) \begin{equation}{\boldsymbol{{b}}}_{{\boldsymbol{{i}}}}=\boldsymbol{\mu } {\boldsymbol{{a}}}_{{\boldsymbol{{i}}}} \quad \textbf{for}\,\, {\boldsymbol{{i}}}=\textbf{1},\ldots,\textbf{6}\end{equation}

where $\boldsymbol{\mu }$ is the constant of the scaling factor, so we have

(4) \begin{equation}{\boldsymbol{{a}}}_{{\boldsymbol{{i}}}}={\boldsymbol{{a}}}_{{{\boldsymbol{{x}}}_{{\boldsymbol{{i}}}}}}{\boldsymbol{{x}}}+{\boldsymbol{{a}}}_{{{\boldsymbol{{y}}}_{{\boldsymbol{{i}}}}}}{\boldsymbol{{y}}}+{\boldsymbol{{a}}}_{{{\boldsymbol{{z}}}_{{\boldsymbol{{i}}}}}}{\boldsymbol{{z}}}\end{equation}

For Eq. (4) above its parameter, $a_{x}$ _i , $a_{y}$ _i , $a_{z}$ _i are the three components of ${\boldsymbol{{a}}}_{{\boldsymbol{{i}}}}$ . And x, y, and z are three-unit vectors of frame A. Now using Eq. (1) for the closed loop, we have

(5) \begin{align} {\boldsymbol{{l}}}_{{\boldsymbol{{i}}}}\, {\boldsymbol{{q}}}_{{\boldsymbol{{i}}}} &= \textbf{P}_{\textbf{B}}+\textbf{R}_{\textbf{B}}.\;{\boldsymbol{{b}}}_{{\boldsymbol{{i}}}}-{\boldsymbol{{a}}}_{{\boldsymbol{{i}}}} \nonumber\\[5pt] &\;\quad \textbf{P}_{\textbf{B}}+(\boldsymbol{\mu }\textbf{R}_{\textbf{B}}-{\boldsymbol{{I}}}){\boldsymbol{{a}}}_{{\boldsymbol{{i}}}}\end{align}

As written above for Eq. (5), in which I is an identity matrix, therefore, to calculate the lengths of the legs (actuators), we have here:

(6) \begin{equation}{\boldsymbol{{l}}}_{{\boldsymbol{{i}}}}^{\textbf{2}}={\boldsymbol{{q}}}_{{\boldsymbol{{i}}}}^{\textbf{T}} {\boldsymbol{{q}}}_{{\boldsymbol{{i}}}}+{\boldsymbol{{a}}}_{{\boldsymbol{{i}}}}^{\textbf{T}}[\boldsymbol{\mu }\textbf{R}_{\textbf{B}}^{\textbf{T}}-\textbf{I})(\boldsymbol{\mu }\textbf{R}-\textbf{I})]{\boldsymbol{{a}}}_{{\boldsymbol{{i}}}}+\textbf{2}{\boldsymbol{{a}}}_{{\boldsymbol{{i}}}}^{\textbf{T}}(\boldsymbol{\mu }\textbf{R}^{\textbf{T}}-\textbf{I}){\boldsymbol{{q}}}_{{\boldsymbol{{i}}}}\end{equation}

In forward kinematic analysis, we assumed that the leg lengths vector is given, and the problem is finding the position $\textbf{P}_{\textbf{B}}$ and orientation of the moving platform $\textbf{R}_{\textbf{B}}$ . The problem depends on the representation used for orientation, where X _B is the computed screw axis representation of the rigid body. An iterative numerical solver has been implemented in this study, and the “screw axis” method represents the rotation matrix. Detailed information about this method is available, particularly in [Reference Tasi36–Reference Park, Stegall and Agrawal38].

(7) $${{\bf{X}}_{\bf{B}}} = {[{{\bf{P}}_{{\bf{B}}x}},{{\bf{P}}_{{\bf{B}}y}},{{\bf{P}}_{{\bf{B}}z}},{{\boldsymbol{s}}_{\boldsymbol{x}}},{{\boldsymbol{s}}_{\boldsymbol{y}}},{{\boldsymbol{s}}_{\boldsymbol{z}}},{\bf{\Theta }}]^{\bf{T}}}$$

where s _x , s _y , s _z , and $\boldsymbol{\Theta }$ are obtained by taking the difference between each pair of two opposing off-diagonal elements, which are given below as [Reference Tasi36, Reference Taghirad37]:

(8) \begin{equation}{\boldsymbol{{s}}}_{{\boldsymbol{{x}}}}=\frac{{\boldsymbol{{r}}}_{\textbf{32}}-{\boldsymbol{{r}}}_{\textbf{23}}}{\textbf{2}.\,\boldsymbol{\sin } \!\left(\boldsymbol{\Theta }\right)}\quad{\boldsymbol{{s}}}_{{\boldsymbol{{y}}}}=\frac{{\boldsymbol{{r}}}_{\textbf{13}}-{\boldsymbol{{r}}}_{\textbf{31}}}{\textbf{2}.\,\boldsymbol{\sin }\! \left(\boldsymbol{\Theta }\right)}\quad{\boldsymbol{{s}}}_{{\boldsymbol{{z}}}}=\frac{{\boldsymbol{{r}}}_{\textbf{21}}-{\boldsymbol{{r}}}_{\textbf{12}}}{\textbf{2}.\,\boldsymbol{\sin } \!\left(\boldsymbol{\Theta }\right)}\end{equation}

And the angle of rotation is obtained by summing the diagonal elements of the rotation matrix, which is given by:

(9) \begin{equation}\boldsymbol{\Theta }=\boldsymbol{\cos }^{-\textbf{1}} \!\left(\frac{{\boldsymbol{{r}}}_{\textbf{11}}+{\boldsymbol{{r}}}_{\textbf{22}}+{\boldsymbol{{r}}}_{\textbf{33}}-\textbf{1}}{\textbf{2}}\right)\end{equation}

where r _ij represents the i ^th row and j ^th column component of R _B for the computed X _B . Pure rotation is through the screw axis of rotation $\hat{{\boldsymbol{{s}}}}$ ( $\hat{{\boldsymbol{{s}}}}$ denotes unit vector) and an equivalent angle $\boldsymbol{\Theta }$ [Reference Tasi36, Reference Taghirad37]. The solution that can be used for the numerical iterative method is to compute the following seven nonlinear equations:

(10) \begin{align}{\textbf{E}_{{\boldsymbol{{i}}}}}&=-{\boldsymbol{{l}}}_{{\boldsymbol{{i}}}}^{\textbf{2}}+\left[\textbf{P}_{\textbf{B}}+\textbf{R}_{\textbf{B}}.\,{\boldsymbol{{b}}}_{{\boldsymbol{{i}}}}-{\boldsymbol{{a}}}_{{\boldsymbol{{i}}}}\right]^\textbf{T}.\,[\textbf{P}_{\textbf{B}}+\textbf{R}_{\textbf{B}}.\,{\boldsymbol{{b}}}_{{\boldsymbol{{i}}}}-{\boldsymbol{{a}}}_{{\boldsymbol{{i}}}}]=\textbf{0}\quad\textbf{for} \,\,{\boldsymbol{{i}}}=\textbf{1},\ldots,\textbf{6}\nonumber \\[5pt] \textbf{E}_{\textbf{7}}&=\hat{{\boldsymbol{{s}}}}.\,\hat{{\boldsymbol{{s}}}}={\boldsymbol{{s}}}_{{\boldsymbol{{x}}}}^{\textbf{2}}+{\boldsymbol{{s}}}_{{\boldsymbol{{y}}}}^{\textbf{2}}+{\boldsymbol{{s}}}_{{\boldsymbol{{z}}}}^{\textbf{2}}-\textbf{1}\end{align}

The below equation is computed by numerical methods, which use nonlinear least-squares optimization routines [Reference Moré39], get a solution. In a least-squares problem, we minimize the function E(l_i ) [Reference Dennis and Schnabel40–Reference Marquardt42]. Finally, we consider the solution’s iteration value calculated for minor square optimization with the accuracy $\in$ << 1.

(11) \begin{equation}\textbf{E}\!\left({\boldsymbol{{l}}}_{{\boldsymbol{{i}}}}\right)=\frac{\textbf{1}}{\textbf{2}}\boldsymbol{\Sigma }_{{\boldsymbol{{i}}}}^{\textbf{7}}\textbf{E}_{{\boldsymbol{{i}}}}\end{equation}

The Jacobian of the Stewart–Gough platform is given by the matrices, which are computed from closed-loop closures Eq. (1) to obtain:

(12) \begin{equation}\dot{\textbf{P}}_{\textbf{B}}=\dot{{\boldsymbol{{q}}}}_{{\boldsymbol{{i}}}}-\boldsymbol{\omega }_{\textbf{B}}.\,\textbf{R}_{\textbf{B}}.\,{\boldsymbol{{b}}}_{{\boldsymbol{{i}}}}\quad \textbf{for}\,\, {\boldsymbol{{i}}}=\textbf{1},\ldots,\textbf{6}\end{equation}

in which angular velocity $\boldsymbol{\omega }_{\textbf{B}}$ of the second ring relative to the first ring is [Reference Waldron and Hunt35, Reference Taghirad37]:

(13) \begin{equation}\boldsymbol{\omega }_{\textbf{B}}=\left[\begin{array}{c} \boldsymbol{\omega }_{\textbf{1}}\\[5pt] \boldsymbol{\omega }_{\textbf{2}}\\[5pt] \boldsymbol{\omega }_{\textbf{3}} \end{array}\right]=\left[\begin{array}{c@{\quad}c@{\quad}c} \textbf{1} & \textbf{0} & -\textbf{s}\boldsymbol{\theta }_{\textbf{B}}\\[5pt] \textbf{0} & \textbf{c}\boldsymbol{\psi }_{\textbf{B}} & \textbf{s}\boldsymbol{\psi }_{\textbf{B}}.\,\textbf{c}\boldsymbol{\theta }_{\textbf{B}}\\[5pt] \textbf{0} & -\textbf{s}\boldsymbol{\psi }_{\textbf{B}} & \textbf{c}\boldsymbol{\psi }_{\textbf{B}}.\,\textbf{c}\boldsymbol{\theta }_{\textbf{B}} \end{array}\right]\left[\begin{array}{c} \dot{\boldsymbol{\psi }}_{\textbf{B}}\\[5pt] \dot{\boldsymbol{\theta }}_{\textbf{B}}\\[5pt] \dot{\boldsymbol{\phi }}_{\textbf{B}} \end{array}\right]\end{equation}

The twist of the ring as an input vector is defined as $\dot{\textbf{X}}_{\textbf{B}}=[\dot{\textbf{P}}_\textbf{Bx},\dot{\textbf{P}}_\textbf{By},\dot{\textbf{P}}_\textbf{Bz},{{\rm{\omega }}_1},{{\rm{\omega }}_2},{{\rm{\omega }}_3}]$ is mapped into the joint velocity vector of the moving platform by Jacobian as follows [Reference Tasi36–Reference Park, Stegall and Agrawal38, Reference Biagiotti and Melchiorri43].

Where ${\boldsymbol{{b}}}_{{\boldsymbol{{i}}}}$ and ${\boldsymbol{{q}}}_{{\boldsymbol{{i}}}}$ are the vector of the $\textbf{P}_{\textbf{B}}$ and unit vector of the $\textbf{A}_{{\boldsymbol{{i}}}}\textbf{B}_{{\boldsymbol{{i}}}}$ . To eliminate the $\boldsymbol{\omega }_{{\boldsymbol{{i}}}}$ with dot multiplication by ${\boldsymbol{{q}}}_{{\boldsymbol{{i}}}}$ where six equations can be arranged in general formulation of the parallel Stewart–Gough platform kinematics, ( $\textbf{J}_{{\boldsymbol{{x}}}}.\,\dot{\textbf{X}}=\textbf{J}_{{\boldsymbol{{q}}}}.\,\dot{\textbf{q}}$ ) can be rewritten as $\dot{{\boldsymbol{{q}}}}=\textbf{J}_{{\boldsymbol{{q}}}}^{-\textbf{1}}.\,\textbf{J}_{\textbf{X}}.\,\dot{\textbf{X}}_{\textbf{B}}=\textbf{J}.\,\dot{\textbf{X}}_{\textbf{B}}$ with:

(14) \begin{equation}\textbf{J}=\left[\begin{array}{c@{\quad}c} \hat{{\boldsymbol{{q}}}}_{\textbf{1}}^{\textbf{T}} & ({{\boldsymbol{{b}}}_{\textbf{1}}}\,.\, { \hat{{\boldsymbol{{q}}}}_{\textbf{1}}})^{\textbf{T}}\\[5pt] \hat{{\boldsymbol{{q}}}}_{\textbf{2}}^{\textbf{T}} & ({{\boldsymbol{{b}}}_{\textbf{2}}}\,.\, { \hat{{\boldsymbol{{q}}}}_{\textbf{2}}})^{\textbf{T}}\\[5pt] \hat{{\boldsymbol{{q}}}}_{\textbf{3}}^{\textbf{T}} & ({{\boldsymbol{{b}}}_{\textbf{3}}}\,.\, { \hat{{\boldsymbol{{q}}}}_{\textbf{3}}})^{\textbf{T}}\\[5pt] \hat{{\boldsymbol{{q}}}}_{\textbf{4}}^{\textbf{T}} & ({{\boldsymbol{{b}}}_{\textbf{4}}}\,.\, { \hat{{\boldsymbol{{q}}}}_{\textbf{4}}})^{\textbf{T}}\\[5pt] \hat{{\boldsymbol{{q}}}}_{\textbf{5}}^{\textbf{T}} & ({{\boldsymbol{{b}}}_{\textbf{5}}}\,.\, { \hat{{\boldsymbol{{q}}}}_{\textbf{5}}})^{\textbf{T}}\\[5pt] \hat{{\boldsymbol{{q}}}}_{\textbf{6}}^{\textbf{T}} & ({{\boldsymbol{{b}}}_{\textbf{6}}}\,.\, { \hat{{\boldsymbol{{q}}}}_{\textbf{6}}})^{\textbf{T}} \end{array}\right]\end{equation}

In our case, for the computed screw axis representation of the rotation matrix, ${\boldsymbol{{q}}}_{{\boldsymbol{{i}}}}$ represents the unit vector which is the direction of the moving length of the leg (actuator). The below equation provides the transformation between the end effector output forces and the linear actuator forces. The vector assumption with the principle of virtual work is made that the leg applies a force only along the leg axis

(15) \begin{eqnarray} \textbf{F}&=&\textbf{J}^{\textbf{T}} \mathbf{\tau} \nonumber \\[5pt] \left[\begin{array}{c} \mathrm{F}_{x}\\[5pt] \mathrm{F}_{y}\\[5pt] \mathrm{F}_{z}\\[5pt] \mathrm{M}_{x}\\[5pt] \mathrm{M}_{y}\\[5pt] \mathrm{M}_{z} \end{array}\right]&=&\left[\begin{array}{c@{\quad}c} \hat{{\boldsymbol{{q}}}}_{\textbf{1}} & \hat{{\boldsymbol{{q}}}}_{\textbf{2}}\ldots .\,. \;\hat{{\boldsymbol{{q}}}}_{\textbf{6}}\\[5pt] {\boldsymbol{{b}}}_{\textbf{1}}.\, \hat{{\boldsymbol{{q}}}}_{\textbf{1}} & {\boldsymbol{{b}}}_{\textbf{2}}.\, \hat{{\boldsymbol{{q}}}}_{\textbf{2}}\ldots .\,. \;{\boldsymbol{{b}}}_{\textbf{6}}.\, \hat{{\boldsymbol{{q}}}}_{\textbf{6}} \end{array}\right].\left[\begin{array}{c} \tau _{1}\\[5pt] \tau _{2}\\[5pt] \tau _{3}\\[5pt] \tau _{4}\\[5pt] \tau _{5}\\[5pt] \tau _{6} \end{array}\right] \end{eqnarray}

in which $\boldsymbol{\tau}=[{{\unicode[Arial]{x03C4}} _{1}}{,{\unicode[Arial]{x03C4}} _{2}}{,\ldots,{\unicode[Arial]{x03C4}} _{6}}]^{\mathrm{T}}$ is the vector of actuated joint torques or forces experienced by the legs (actuator force vector) and $\textbf{F}=[{\mathrm{F}_{x}},{\mathrm{F}_{y}},{\mathrm{F}_{z}}, {\mathrm{M}_{x}},{\mathrm{M}_{y}},{\mathrm{M}_{z}}]^{\mathrm{T}}$ represents vector of end effector output force and moment the end effector

3.3. The robotic brace trajectory

The trajectory of the brace is obtained with continuous acceleration, where different conditions are applied to position and velocity. The trajectory of the brace is assigned with necessary initial and desired and command values for the acceleration. Therefore, since there are six boundary conditions (position, velocity, and acceleration), a fifth-degree polynomial must be adopted, that is,

\begin{eqnarray*} \textbf{X}\!\left({\boldsymbol{{t}}}_{\textbf{0}}\right)&=\textbf{X}_{\textbf{0}}\quad\dot{\textbf{X}}\!\left({\boldsymbol{{t}}}_{\textbf{0}}\right)&=\dot{\textbf{X}}_{\textbf{0}}\quad\ddot{\textbf{X}}\!\left({\boldsymbol{{t}}}_{\textbf{0}}\right)=\ddot{\textbf{X}}_{\textbf{0}} \\[5pt] \textbf{X}\!\left({\boldsymbol{{t}}}_{{\boldsymbol{{f}}}}\right)&=\textbf{X}_{{\boldsymbol{{f}}}} \quad\dot{\textbf{X}}\!\left({\boldsymbol{{t}}}_{{\boldsymbol{{f}}}}\right)&=\dot{\textbf{X}}_{{\boldsymbol{{f}}}} \quad\ddot{\textbf{X}}\!\left({\boldsymbol{{t}}}_{{\boldsymbol{{f}}}}\right)=\ddot{\textbf{X}}_{{\boldsymbol{{f}}}}\end{eqnarray*}

Trajectory planning is implemented for every DOF independently in the following manner [Reference Gosselin44]:

(16) \begin{equation}\textbf{X}_{{\boldsymbol{{i}}}}\!\left({\boldsymbol{{t}}}\right)={{\boldsymbol{{a}}}_{\textbf{0}}}_{{\boldsymbol{{i}}}}+{{\boldsymbol{{a}}}_{\textbf{1}}}_{{\boldsymbol{{i}}}}{\boldsymbol{{t}}}+{{\boldsymbol{{a}}}_{\textbf{2}}}_{{\boldsymbol{{i}}}}{\boldsymbol{{t}}}^{\textbf{2}}+{{\boldsymbol{{a}}}_{\textbf{3}}}_{{\boldsymbol{{i}}}}{\boldsymbol{{t}}}^{\textbf{3}}+{{\boldsymbol{{a}}}_{\textbf{4}}}_{{\boldsymbol{{i}}}}{\boldsymbol{{t}}}^{\textbf{4}}+{{\boldsymbol{{a}}}_{\textbf{5}}}_{{\boldsymbol{{i}}}}{\boldsymbol{{t}}}^{\textbf{5}}\end{equation}

The trajectory path implemented for the X(t) is a position vector. It gives the positions and orientations of the ring with respect to the other. We can have six equations in a matrix from the derivation of the initial and final constraints and their values [Reference Gosselin44].

(17) \begin{equation}\left[\begin{array}{c@{\quad}c@{\quad}c@{\quad}c@{\quad}c@{\quad}c} 1 & {\boldsymbol{{t}}}_{\textbf{0}} & {\boldsymbol{{t}}}_{\textbf{0}}^{\textbf{2}} & {\boldsymbol{{t}}}_{\textbf{0}}^{\textbf{3}} & {\boldsymbol{{t}}}_{\textbf{0}}^{\textbf{4}} & {\boldsymbol{{t}}}_{\textbf{0}}^{\textbf{5}} \\[5pt] 1 & {\boldsymbol{{t}}}_{{\boldsymbol{{f}}}} & {\boldsymbol{{t}}}_{{\boldsymbol{{f}}}}^{\textbf{2}} & {\boldsymbol{{t}}}_{\textbf{0}}^{\textbf{3}} & {\boldsymbol{{t}}}_{\textbf{0}}^{\textbf{4}} & {\boldsymbol{{t}}}_{\textbf{0}}^{\textbf{5}} \\[5pt] 0 & 1 & 2{\boldsymbol{{t}}}_{\textbf{0}} & 3{\boldsymbol{{t}}}_{\textbf{0}}^{\textbf{2}} & 4{\boldsymbol{{t}}}_{\textbf{0}}^{\textbf{3}} & 5{\boldsymbol{{t}}}_{\textbf{0}}^{\textbf{4}}\\[5pt] 0 & 1 & 2{\boldsymbol{{t}}}_{{\boldsymbol{{f}}}} & 3{\boldsymbol{{t}}}_{\textbf{0}}^{\textbf{2}} & 4{\boldsymbol{{t}}}_{\textbf{0}}^{\textbf{3}} & 5{\boldsymbol{{t}}}_{\textbf{0}}^{\textbf{4}}\\[5pt] 0 & 0 & 2 & 6{\boldsymbol{{t}}}_{\textbf{0}} & 12{\boldsymbol{{t}}}_{\textbf{0}}^{\textbf{2}} & 20{\boldsymbol{{t}}}_{\textbf{0}}^{\textbf{3}} \\[5pt] 0 & 0 & 2 & 6{\boldsymbol{{t}}}_{\textbf{0}} & 12{\boldsymbol{{t}}}_{\textbf{0}}^{\textbf{2}} & 20{\boldsymbol{{t}}}_{\textbf{0}}^{\textbf{3}} \end{array}\right]\cdot \left[\begin{array}{c} \boldsymbol{{a}}_{\textbf{0}_{\boldsymbol{{i}}}}\\[5pt] \boldsymbol{{a}}_{\textbf{1}_\boldsymbol{{i}}}\\[5pt] \boldsymbol{{a}}_{\textbf{2}_{\boldsymbol{{i}}}}\\[5pt] \boldsymbol{{a}}_{\textbf{3}_{\boldsymbol{{i}}}}\\[5pt] \boldsymbol{{a}}_{\textbf{4}_{\boldsymbol{{i}}}}\\[5pt] \boldsymbol{{a}}_{\textbf{5}_{{\boldsymbol{{i}}}}} \end{array}\right] =\left[\begin{array}{c} \textbf{X}_{\textbf{0}_{\boldsymbol{{i}}}}\\[5pt] \textbf{X}_{\boldsymbol{{f}}_{{\boldsymbol{{i}}}}}\\[5pt] {\dot{\textbf{X}}_{\textbf{0}_{{\boldsymbol{{i}}}}}}\\[5pt] {\dot{\textbf{X}}_{{\boldsymbol{{f}}}_{{\boldsymbol{{i}}}}}}\\[5pt] {\ddot{\textbf{X}}_{\textbf{0}_{{\boldsymbol{{i}}}}}}\\[5pt] {\ddot{\textbf{X}}_{{\boldsymbol{{f}}}_{{\boldsymbol{{i}}}}}} \end{array}\right] \quad \textbf{for} \,\,\textbf{i}=\textbf{1},\ldots,\textbf{6}\end{equation}

The determinant of the left-most matrix is ${4(t_{0}}-{t_{f}})^{9}$ ; thus; this matrix is invertible provided $t_{0}\neq t_{f}$ ; therefore; the singular solution for the cubic polynomial coefficients can be determined [Reference Gosselin44]. Furthermore, the cubic polynomial parameters can be simplified if the initial and desired motion velocities are equal to zero (rest), that is: ${\dot{\textbf{X}}_{\textbf{0}_{{\boldsymbol{{i}}}}}}={\dot{\textbf{X}}_{\boldsymbol{{f}}_{{\boldsymbol{{i}}}}}}={\ddot{\textbf{X}}_{\textbf{0}_{{\boldsymbol{{i}}}}}}={\ddot{\textbf{X}}_{\boldsymbol{{f}}_{{\boldsymbol{{i}}}}}}=0$ for i = 1, …, 6 so that:

(18) \begin{align} \textbf{X}_{{\boldsymbol{{i}}}}\!\left({\boldsymbol{{t}}}\right)&={\textbf{X}_{{\boldsymbol{{i}}}}}_{\textbf{0}}-\textbf{10}\!\left({\textbf{X}_{{\boldsymbol{{i}}}}}_{\textbf{0}}-{\textbf{X}_{{\boldsymbol{{i}}}}}_{{\boldsymbol{{f}}}}\right){\boldsymbol{{t}}}^{\textbf{3}}-\textbf{15}\!\left({\textbf{X}_{{\boldsymbol{{i}}}}}_{\textbf{0}}-{\textbf{X}_{{\boldsymbol{{i}}}}}_{{\boldsymbol{{f}}}}\right){\boldsymbol{{t}}}^{\textbf{4}}-\textbf{6}\!\left({\textbf{X}_{{\boldsymbol{{i}}}}}_{\textbf{0}}-{\textbf{X}_{{\boldsymbol{{i}}}}}_{{\boldsymbol{{f}}}}\right){\boldsymbol{{t}}}^{\textbf{5}}\nonumber \\[5pt] \dot{\textbf{X}}_{{\boldsymbol{{i}}}}({\boldsymbol{{t}}})&=-\textbf{30}({\textbf{X}_{{\boldsymbol{{i}}}}}_{\textbf{0}}-{\textbf{X}_{{\boldsymbol{{i}}}}}_{{\boldsymbol{{f}}}}){\boldsymbol{{t}}}^{\textbf{2}}-\textbf{60}({\textbf{X}_{{\boldsymbol{{i}}}}}_{\textbf{0}}-{\textbf{X}_{{\boldsymbol{{i}}}}}_{{\boldsymbol{{f}}}}){\boldsymbol{{t}}}^{\textbf{3}}-\textbf{30}({\textbf{X}_{{\boldsymbol{{i}}}}}_{\textbf{0}}-{\textbf{X}_{{\boldsymbol{{i}}}}}_{{\boldsymbol{{f}}}}){\boldsymbol{{t}}}^{\textbf{4}}\nonumber \\[5pt] \ddot{\textbf{X}}_{{\boldsymbol{{i}}}}({\boldsymbol{{t}}})&=-\textbf{60}({\textbf{X}_{{\boldsymbol{{i}}}}}_{\textbf{0}}-{\textbf{X}_{{\boldsymbol{{i}}}}}_{{\boldsymbol{{f}}}}){\boldsymbol{{t}}}-\textbf{180}({\textbf{X}_{{\boldsymbol{{i}}}}}_{\textbf{0}}-{\textbf{X}_{{\boldsymbol{{i}}}}}_{{\boldsymbol{{f}}}}){\boldsymbol{{t}}}^{\textbf{2}}-\textbf{120}({\textbf{X}_{{\boldsymbol{{i}}}}}_{\textbf{0}}-{\textbf{X}_{{\boldsymbol{{i}}}}}_{{\boldsymbol{{f}}}}){\boldsymbol{{t}}}^{\textbf{3}}\end{align}

The above trajectory will keep the brace resting at the initial and final motion.

5.1. Position controller validation

We evaluated the position controllers to determine the robot’s performance regarding the actuator capabilities. In addition, we studied the system’s range of motion to analyze the performance of the position control of the brace on a human subject.

We combined the Lower Body Marker set (LBM) without the foot (we use where eighteen markers in static configuration and sixteen in dynamic); see Fig. 10(b). The Upper Body Marker set is only around the spine and shoulders (with ten markers in static and dynamic); see Fig. 10(a). We use static markers while the motion capture system records the position of the markers on the brace. We then tracked the marker in space during motion, and then, the data were post-processed to define the position and motion of the brace relative to the body motion. During the data acquisition with the brace, spine markers had to reposition on the brace relative to anatomical landmarks. The position controller moved the brace through a range of translations and rotations.

Figure 10. Motion analysis marker set: (a) position on the upper body; (b) position on the lower body.

Rotation around the z-axis and translation along the y-axis in the transverse plane was evaluated, denoted as three-point mode, as the traditional three-point correction in spine braces. In addition, we evaluated flexion and lateral bending to compare bending in the brace. We recorded the motion with the Qualisys® motion capture system. The translation and rotation of the middle and top rings are relative to the bottom base frame.

We used the markers highlighted in yellow in Fig. 10 for motion. The upper markers used for analysis are positioned on SJN-Sternum jugular notch, SXS-Sternum xiphisternal joint, CV7-7^th cervical vertebrae, TV2-2^nd thoracic vertebrae, MAI-the midpoint between inferior angles of most caudal points of the scapulae, LV1, LV3, LV5 (1^st, 3^rd and 5^th lumbar vertebrae), L_SAE- and R_SAE (scapula acromial edge) for the UBM sets. The LBM sets are used for static and dynamic data acquisition.

The lower markers used for analysis are positioned on the L_FCC-Aspect of the Achilles tendon insertion on the calcaneus, L_FM1-Dorsal margin of the first metatarsal head, L_FM2-Dorsal margin of the second metatarsal head, L_FM5-Dorsal margin of the fifth metatarsal head, R_FCC- Aspect of the Achilles tendon insertion on the calcaneus, R_FM1-Dorsal margin of the first metatarsal head, R_FM2-Dorsal margin of the second metatarsal head, R_FM5-Dorsal margin of the fifth metatarsal head. Once we do the data and information acquisition on the brace, we have markers for each ring. It is essential for 3D reconstruction on visual 3D and analysis of the motion imposed by the brace.

For each ring, we place four markers, see Fig. 11. Three are used to define the plane characterizing the ring position (markers BL1 to BL3 are associated with the lower ring, BM1-BM3 for the middle ring, and BU1-BU3 for the upper ring).

Figure 11. Motion analysis 3D construction with marker positions.

A theoretical brace center is defined, point O, represented in blue in Fig. 11, between BL1 and BL3. The line between point O and the center of BL1 and BL3 (in blue) gives the X-axis; the Z-axis is orthogonal to the plane.

5.2. Experimental evaluation of robot position

The linear actuator in each leg has an integrated potentiometer that feeds back the joint displacement from which we compute the Cartesian pose of every ring using forward kinematics. In addition, we placed infrared markers on the rings to measure their position and orientation with a motion capture system.

The robot position is evaluated by moving the brace through different modes of motion:

(1) Torso flexion, (2) lateral bending, (3) rotation following, (4) rotation mirroring, (5) translation following, and (6) translation mirroring.

We evaluated all the modes taking the three-point pressure principle into account.

Based on human biomechanics, the three-point pressure mode is the general principle used to correct abnormal spine curves in braces. This mode of spinal correction may involve rotation around the z-axis and translation along the y-axis through the transverse plane. In addition, sagittal trunk flexion and frontal bending modes evaluate the bending motion capability of the brace.

We applied the series of modes for isolated translations and rotations. In these modes, the robotic brace’s upper parallel module (middle ring articulated with upper ring) performed the identical task (following). The lower parallel module (lower ring articulated with middle ring) of the brace performs the alternative task (mirroring); see Fig. 7(b).

We recorded the motion using a motion capture system and a potentiometer providing position feedback of the actuator while being attached to the underside of this actuator. The translation’s interpretation and rotation of the middle and top ring are relative to the position and analyzed concerning the lower ring coordinate frame of the robotic brace. Figure 12 shows motion tracking results verified using a motion capture system for a three-point-pressure motion trial. The robot position controller could follow all paths for all tested trajectories. We calculate the position and rotation of the middle and upper ring relative to the lower ring coordinate frame see Fig. 12.

Figure 12. Graphical representation of the Qualisys motion capture results from the three-point mode test. Rotation and translation about x, y, and z are represented by blue, red, and black, respectively. (a) Position of the Middle ring origins; (b) Rotation angles of the middle ring; (c) Position of the upper ring (d) Rotation angles of the upper ring.

We can observe that the middle ring has more noteworthy rotations than the upper one. Therefore, for the prosthesis, it is necessary to have greater mobility of the middle ring than the upper, so the brace model correctly follows the patient’s movement. We conducted other tests with or without a brace to compare the amplitude of the patient’s movements [Reference Mac-Thiong, Petit, Aubin, Delorme, Dansereau and Labelle26, Reference Taghirad37]. We will perform future experiments with patients with scoliosis to confirm the performances of the brace in a real medical case.