2.1. Optimization-based kinematics of CCR: Theory

The backbone is the main element that determines the pose of the CCR after actuation and can be modeled as a slender beam. For straight cable routing and an undeformed straight beam, the deformed shape of the beam subjected to pure bending can be obtained by using minimization of strain energy. In the case of a general cable routing or a pre-bent shape of the backbone, the strain energy will be contributed by bending along $X$ and $Y$ directions (assuming $Z$ to be tangent to the backbone) and torsion applied on the backbone at the disk attachment points. The strain energy can then be represented mathematically as:

(1) \begin{equation} \displaystyle{\min _{\theta _x, \, \theta _y, \, \phi }\, \int _0^{L_0} \frac{1}{2}\left ( EI_{xx}\left (\frac{d \theta _x}{ds}\right )^2 + EI_{yy}\left (\frac{d \theta _y}{ds}\right )^2 + GJ\left (\frac{d \phi }{ds}\right )^2\right ) ds} \end{equation}

where, $L_0$ is the total length of the backbone, $s$ is the arc-length parameter, $\theta _x (=dx/ds)$ and $\theta _y (=dy/ds)$ are the slope angles of the beam with $x$ and $y$ the displacement in the transverse directions and $\phi$ is the change in angle due to torsion. For the two strain energies due to bending, we assume that the bending is along the plane formed by the local tangents and thus replace it with only one term. With this assumption, the strain energy minimization equation reduces to:

(2) \begin{equation} \min _{\theta, \, \phi }\, \int _0^{L_0}\frac{1}{2} \left ( EI\left (\frac{d \theta }{ds}\right )^2 + GJ\left (\frac{d \phi }{ds}\right )^2\right ) ds \end{equation}

where $\theta$ is the change in the angle made by the tangent vector locally and $I = I_{xx} = I_{yy}$ .

For an isotropic backbone material with constant cross-section, the material and geometrical properties, $E$ , $I$ , $G$ and $J$ , can be taken out of the integration. A further simplification can be done by discretizing the backbone into $n$ equal segments, with the disk numbered from $0$ (base) to $n$ (tip), to arrive at a finite difference form:

(3) \begin{equation} \begin{aligned} & \min _{\theta, \, \phi }\, \sum _{i=1}^{n} \frac{1}{2}\left (EI\left ( \frac{\Delta \theta _i}{\Delta s} \right )^2 + GJ\left ( \frac{\Delta \phi _i}{\Delta s} \right )^2 \right ) \delta s & = \min _{\theta,\, \phi }\, C \sum _{i=1}^{n} \left (\left ( \Delta \theta _i \right )^2 + D\left ( \Delta \phi _i \right )^2\right ) \end{aligned} \end{equation}

where $C$ and $D$ are constants related to $I$ , $J$ $E$ and $G$ . From the relation $E = 2G(1+\nu )$ , $D$ can be shown to be only dependent on the Poisson’s ratio, $\nu$ and the minimizing the strain energy of the backbone is equivalent to minimizing the weighted sum of squared changes in slope angles and torsion angles.

Figure 2 shows the $i^{\textrm{th}}$ section of CCR in between the disk labeled $\{i-1\}$ and, $\{i\}$ before and after an iteration with the backbone curve shown in dashed magenta line. The disks are always perpendicular to the backbone. The tangents to the backbone curve at the center of the disks $\{i\}$ is denoted by $\mathbf{t}_i$ and the normal vector from the center of the disk to the location of the hole (through which the cable passes) is denoted by $\mathbf{n}_i$ – in Fig. 2, $\mathbf{n}_i$ and $\mathbf{n}_{i-1}$ are not parallel due to the general cable routing. Hence, the minimization in Eq. (3) is equivalent to minimizing the weighted sum of squares of change in the angle made by the tangent and normal vectors.

Figure 2. Nomenclature used for the $i^{\textrm{th}}$ section of a CCR with a generally routed cable before and after an iteration. The backbone curve and the tangents and normals vectors at the disks are shown in magenta, blue and red, respectively.

The position vectors $\mathbf{X}_0^i$ and $\mathbf{X}_a^i$ denote the location (from the base) of the center of the disk and the cable on the $i^{\textrm{th}}$ disk and $\mathbf{X}_{(\cdot )}^i$ change to $\mathbf{x}_{(\cdot )}^i$ after an iteration. The tangent vector, $\mathbf{t}_i$ is approximated as the unit vector along $\left (\mathbf{(\cdot )}_0^{i} - \mathbf{(\cdot )}_0^{i-1}\right )$ where $(\cdot )$ can be $\mathbf{x}$ or $\mathbf{X}$ . The position vector for the cable at the $i^{\textrm{th}}$ disk, $\mathbf{X}_a^i$ and $\mathbf{x}_a^i$ are along the normal to the backbone curve at $\mathbf{X}_0^i$ and $\mathbf{x}_0^i$ , respectively. The change in bending and torsional angles, $\Delta \theta$ and $\Delta \phi$ , is found by comparing $\mathbf{x}_a$ (or $\mathbf{x}_0$ ) and its values in the previous iteration, making the change in angles more accurate and local in nature. The change in the bending angle, $\Delta \theta$ , is given by the angle between unit vectors along $\left ( \mathbf{x}_0^i - \mathbf{x}_0^{i-1} \right )$ and $\left ( \mathbf{X}_0^i - \mathbf{X}_0^{i-1} \right )$ , and likewise the change in the torsion angle $\Delta \phi$ can be obtained from the angle between the unit vectors along $\left ( \mathbf{x}_a^i - \mathbf{x}_0^{i} \right )$ and $\left ( \mathbf{X}_a^i - \mathbf{X}_0^{i} \right )$ (see Fig. 2).

The discretized minimization problem in Eq. (3) to find the pose of a CCR ( $\textbf{x}_0, \, \textbf{x}_a$ ) with general cable routing can thus be written as:

(4) \begin{equation} \begin{aligned} \displaystyle{ \mathop{\textrm{arg min}}\limits_{\textbf{x}_0, \, \textbf{x}_a} \, \sum _{i=1}^n \left [ \left ( \arccos \left ( \frac{\mathbf{x}_0^i - \mathbf{x}_0^{i-1}}{\Vert \mathbf{x}_0^i - \mathbf{x}_0^{i-1} \Vert } \cdot \frac{\mathbf{X}_0^i - \mathbf{X}_0^{i-1}}{\Vert \mathbf{X}_0^i - \mathbf{X}_0^{i-1} \Vert } \right ) \right )^2 \right . + }\\ \displaystyle{ \left . D \left ( \arccos \left ( \frac{\mathbf{x}_a^i - \mathbf{x}_0^i}{\Vert \mathbf{x}_a^i - \mathbf{x}_0^i \Vert } \cdot \frac{\mathbf{X}_a^i - \mathbf{X}_0^i}{\Vert \mathbf{X}_a^i - \mathbf{X}_0^i \Vert } \right ) \right )^2 \right ]} \end{aligned} \end{equation}

Subject to:

(5) \begin{equation} \begin{aligned} &\Vert \mathbf{x}_0^{i} - \mathbf{x}_0^{i-1} \Vert = l_0, \quad \Vert \mathbf{x}_a^{i} - \mathbf{x}_a^{i-1} \Vert = l_a^{i}, \quad &\Vert \mathbf{x}_0^{i} - \mathbf{x}_a^{i} \Vert = a\qquad (i = 1,2,\ldots,n) \end{aligned} \end{equation}

Given data: $l_0$ , $l_a^{i}$ , $a$ , $\mathbf{X}_0$ , $\mathbf{X}_a$ and $D$ .

The output of the optimization is the position vectors of the center of all $n$ disks $\mathbf{x}_0^i$ and cables $\mathbf{x}_a^i$ after deformation.

It may be noted that to preserve the length of the CCR and to maintain its geometry, the length between the center of two disks, $l_0$ ( $= L_0/n$ with $L_0$ being the total length of the CCR) and radial distance of the cable, $a$ , remains constant. The minimization is performed iteratively by decreasing $l_a^i$ (length of cable inside the $i^{\textrm{th}}$ section), each iteration using results of previous iteration as $\mathbf{X}_0$ and $\mathbf{X}_a$ values and iterating until the final value of $l_a^i$ is reached.

It may also be noted that the effect of gravity and friction is ignored in this formulation. These are reasonable assumptions since the CCR is lightweight, and we are only interested in kinematics and the friction force at the cable-disk interface is expected to be very small as the motion of the cable itself is small.

2.2. Kinematics of CCR with initially straight backbone

In this section, the kinematics for a CCR is presented, assuming the backbone is initially straight prior to actuation.

2.2.1. Straight cable routing

When the cable is routed straight from the bottom to the tip (parallel to the backbone), the CCR bends in a plane formed by the backbone and the cable. In this case, the length of the cable inside each of the sections is equal. Therefore, if $L$ is the total length of the cable inside the CCR, the length of cable inside each section $l_a^i = L/n = l_a$ . The second constraint in Eq. (5) can be modified to

\begin{equation*} \|{{{\mathbf{x}}_{a}^{i+1}} -{\mathbf{x}_a^{i}}}\| = l_a \end{equation*}

2.3. Kinematics of CCR with pre-bent backbone

For a backbone that is initially pre-bent (without any pre-tension), with a straight routing of the cable and the backbone curve assumed to be continuous and smooth, the optimization problem remains similar. The key difference is in the choice of $\mathbf{X}_0^i$ and $\mathbf{X}_a^i$ . In this case, initially, both $\mathbf{X}_0^i$ and $\mathbf{X}_a^i$ are chosen the same as the pre-bent shape, unlike straight for the previous cases.

2.4. Kinematics of CCR with obstacles

The kinematics of CCR in contact with obstacles can be easily incorporated by adding inequality constraints [Reference Ashwin, Mahapatra and Ghosal30]. The optimization problem is thus modified by adding the following to the constraints in (5)

(6) \begin{equation} \mathbf{f}(\mathbf{x}_0) \succeq 0, \quad \mathbf{f}(\mathbf{x}_a) \succeq 0, \quad \mathbf{f}(\mathbf{x}_b) \succeq 0 \end{equation}

where $\mathbf{f}(\mathbf{x})$ is a given data representing the boundary of the obstacle, and $\mathbf{x}_b=2 \mathbf{x}_0 - \mathbf{x}_a$ . The inequality constraints in Eq. (6) ensure that the CCR is never inside the obstacles. The non-zero Lagrange multipliers corresponding to the inequality constraints in Eq. (6) during the optimization procedure will indicate location of contact.