1.1. Problem statement and preliminaries

1.2. Moving RCM constraints

1.2.1. Kinematics analysis

To track the trajectory from the actual Cartesian position to the target position during the robot manipulation, as shown in Fig. 1, the end effector must go through the small incision $\boldsymbol{P}$ on the obstacle wall, representing the RCM constraint, where $\boldsymbol{r}_{0}$ is the RCM position, $\boldsymbol{r}_{1}$ is the actual Cartesian position, and $\boldsymbol{r}_{2}$ is the actual position of the position of joint $\theta _{n-1}$ . To respect the RCM constraint, $\boldsymbol{r}_{0}$ should always be on a straight line from the tooltip’s position, $\boldsymbol{r}_{1}$ , to the position of the joint holding the tool, $\boldsymbol{r}_{2}$ . In most previous works, no movement was applied to this point has been frequently assumed to simplify the complexity of the application. However, for an actual clinical operation, the patient’s abdominal wall may not be fixed due to breathing or heart beating, as it is shown in Fig. 2. The relation can be derived as

(1) \begin{equation} \!\left(\boldsymbol{r}_{0}-\boldsymbol{r}_{1}\right)\times \left(\boldsymbol{r}_{2}-\boldsymbol{r}_{1}\right)=0 \end{equation}

Figure 2. Moving remote center of motion due to breathing.

Assumption 2.1: The RCM constraint position $\boldsymbol{r}_{0}\in R^{3}$ is known or can be detected with optical tracking.

Consider an n-degrees-of-freedom manipulator, the projection from its joint space to the Cartesian coordinate $\boldsymbol{r}_{1}\in R^{m}$ of its end effector is characterised by the following nonlinear function:

(2) \begin{equation} \begin{array}{c} \boldsymbol{r}_{1}=f_{1}(\boldsymbol{\theta })\\ \boldsymbol{r}_{2}=f_{2}(\boldsymbol{\theta }) \end{array} \end{equation}

where $\theta \in R^{n}$ can be seen as the joint angle vector. The nonlinear function $f_{1}(.)$ and $f_{2}(.)$ for serial manipulators can be obtained through a systematic method known as the D-H convention. For excessive manipulators, $n\gt m$ . Straightforwardly, computing the time derivatives on both sides of (1) yields

(3) \begin{equation} \begin{array}{c} \dot{\boldsymbol{r}}_{1}=J_{1}\!\left({\theta }\right)\!\boldsymbol\omega \\ \dot{\boldsymbol{r}}_{2}=J_{2}\!\left({\theta }\right)\!\boldsymbol\omega \end{array} \end{equation}

where $\dot{\boldsymbol{r}}_{1}=\boldsymbol{d}\boldsymbol{r}_{1}/\boldsymbol{d}t, \dot{\boldsymbol{r}}_{2}=\boldsymbol{d}\boldsymbol{r}_{2}/\boldsymbol{d}t, J_{1}(\boldsymbol{\theta })=\partial f_{1}(\boldsymbol{\theta })/\partial \boldsymbol{\theta }, J_{2}(\boldsymbol{\theta })=\partial f_{2}(\boldsymbol{\theta })/\partial \boldsymbol{\theta }$ , and $\omega =\dot{\boldsymbol{\theta }}=\mathrm{d}\boldsymbol{\theta }/\mathrm{d}t$ .

1.2.2. Dynamic modelling

$\boldsymbol{F}_\boldsymbol{e}$ is the outside force created through the physical contact [Reference Chen, Chen, Wang, Yang, Ma, Leng and Fu17, Reference Chen, Zhang, Liu, Leng and Fu18] of the RCM constraint and the robot tool shaft, which maybe be modelled using a mass-damping-spring model:

(4) \begin{equation} \boldsymbol{M}_{\boldsymbol{P}}\ddot{\boldsymbol{P}}+\boldsymbol{H}_{\boldsymbol{P}}\!\left(\boldsymbol{P},\dot{\boldsymbol{P}}\right)\!\dot{\boldsymbol{P}}+\boldsymbol{G}_{\boldsymbol{P}}\!\left(\boldsymbol{P}\right) = \boldsymbol{F}_\boldsymbol{e} \end{equation}

where $\boldsymbol{M}_{\boldsymbol{P}},\boldsymbol{H}_{\boldsymbol{P}},\boldsymbol{G}_{\boldsymbol{P}}$ are the inertia, damping and stiffness matrices of the obstacle wall around the RCM constraint, $\boldsymbol{F}_\boldsymbol{e}\in R^{3}$ is the outside force from the physical contact, and $\boldsymbol{P}$ is the actual contact point between the surgical tool shaft and the obstacle. $\boldsymbol{F}_\boldsymbol{e}$ can be decomposed into two components $\boldsymbol{F}_\boldsymbol{eX}\in R^{3}$ and $\boldsymbol{F}_\boldsymbol{eN}\in R^{3}$ [Reference Ott19], where $\boldsymbol{F}_\boldsymbol{eX}$ is the projected outside force on the tooltip in the task space, and $\boldsymbol{F}_\boldsymbol{eN}$ is the external force acting on the corresponding null space of the tooltip.

Assumption 2.2: The time-varying external force $\boldsymbol{F}_\boldsymbol{e}\boldsymbol{(}\boldsymbol{t}\boldsymbol{)}\in R^{3}$ from physical interaction between the robot tool shaft and the obstacle wall is continuous in terms of time and constrained by a constant $\beta$ as follows:

(5) \begin{equation} \exists \beta \in R,\parallel \boldsymbol{F}_\boldsymbol{e}\mathbf{(}\boldsymbol{t}\mathbf{)}\parallel \leq \beta,\forall t\geq 0 \end{equation}

1.3. Robot modelling

The dynamic model of the $n$ degrees of freedom (DoFs) serial manipulator in the Lagrangian formulation can be expressed as [Reference Yang, Wang, Cheng and Ma20]

(6) \begin{equation} \boldsymbol{M}\!\left(\boldsymbol{\theta }\right)\ddot{\boldsymbol{\theta }}+\boldsymbol{C}\!\left(\boldsymbol{\theta }\mathbf{,}\dot{\boldsymbol{\theta }}\right)\dot{\boldsymbol{\theta }}+\boldsymbol{g}\!\left(\boldsymbol{\theta }\right)-{{\boldsymbol\tau}}_{\mathbf{e}} = \boldsymbol{\tau}_{\mathbf{C}} \end{equation}

where $\theta \in R^{n}$ is the joint vector, $\boldsymbol{M}\mathbf{(}\boldsymbol{\theta }\mathbf{)}\in R^{n\times n}$ is the positive definite, symmetric and bounded inertia matrix in the robot joint space, $\boldsymbol{C}\mathbf{(}\boldsymbol{\theta }\mathbf{,}\dot{\boldsymbol{\theta }}\mathbf{)}\in R^{n\times n}$ is a matrix which represents the effects for Coriolis and centrifugal and $\boldsymbol{g}\mathbf{(}\boldsymbol{\theta }\mathbf{)}\in R^{n}$ is the vector for gravity torques. The torque vectors ${\boldsymbol\tau} _\boldsymbol{C}\in R^{n}$ and ${\boldsymbol\tau} _{\mathbf{e}}\in R^{n}$ , respectively, symbol the control torques [Reference Li, Deng and Zhao21] and the outside disturbance torque vectors [Reference Li, Xu, Wei, Shi and Su22, Reference Li, Zhao, Zhang, Wu, Zhang, Li, Li and Su23]. For simplicity, it is presumed that the surgical robotic system is different from any pseudoinverse and singularity of the Jacobian matrix, $\boldsymbol{J}_{{\textbf{1}}}\mathbf{(}\boldsymbol{\theta }\mathbf{)}\in R^{m\times n}$ , in existence.

Since for Cartesian admittance control, the task space expresses the expected behaviour of the serial robot, and the generalised formulation can be written as [Reference Ott19, Reference Khatib24, Reference Albu-Schaffer, Ott, Frese and Hirzinger25]

(7)

where $\boldsymbol{r}=\boldsymbol{r}_{1}\in R^{m}$ is the vector of the task space coordinates,

(8) \begin{equation} \boldsymbol{M}_{\boldsymbol{r}}\mathbf{(}\boldsymbol{r}\mathbf{)} = \boldsymbol{J}_{\mathbf{1}}^{-{{\boldsymbol{T}}}}\boldsymbol{M}\mathbf{(}\boldsymbol{\theta }\mathbf{)}\boldsymbol{J}_{\mathbf{1}}^{-\mathbf{1}}, \end{equation}

(9)

(10) \begin{equation} \boldsymbol{F}_\boldsymbol{eT} = \boldsymbol{J}^{-\mathbf{T}}{\boldsymbol\tau} _{\mathbf{e}}. \end{equation}

The matrix $\boldsymbol{M}_{\boldsymbol{r}}\mathbf{(}\boldsymbol{r}\mathbf{)}\in R^{m\times m}$ is the Cartesian inertia matrix, $\boldsymbol{H}_{\boldsymbol{r}}\mathbf{(}\boldsymbol{r}\mathbf{,}\dot{\boldsymbol{r}}\mathbf{)}\in R^{m\times m}$ is the Coriolis and centrifugal force effects in the task space and $\boldsymbol{F}_\boldsymbol{eT}\in R^{m}$ is the external force in the task space, which is bounded by $\beta$ .

(11) \begin{equation} \exists \beta \in R,\parallel \boldsymbol{F}_\boldsymbol{eT}\parallel \leq \beta,\forall t\geq 0 \end{equation}

Property 2.1: The Cartesian inertia matrix, $\boldsymbol{M}_{\boldsymbol{r}}\boldsymbol{(}\boldsymbol{r}\boldsymbol{)}$ , as defined in (8), positive and symmetric, and it is also bounded as

(12) \begin{equation} \lambda _{1}\!\parallel \boldsymbol{A}\parallel \leq \boldsymbol{A}^\boldsymbol{T}\boldsymbol{M}_{\boldsymbol{r}}\boldsymbol{(}\boldsymbol{r}\boldsymbol{)}\boldsymbol{A}\leq \lambda _{2}\parallel \boldsymbol{A}\parallel,\forall \boldsymbol{A},\boldsymbol{r}\in R^{m} \end{equation}

where $\lambda _{1}$ and $\lambda _{2}$ are positive constants, and $\boldsymbol{A}$ is assumed as non-singular matrix.

Property 2.2: The Cartesian matrix, $\boldsymbol{H}_{\boldsymbol{r}}\boldsymbol{(}\boldsymbol{r},\dot{\boldsymbol{r}}\boldsymbol{)}$ , and the time derivative of the Cartesian inertia matrix, $\boldsymbol{M}_{\boldsymbol{r}}\boldsymbol{(}\boldsymbol{r}\boldsymbol{)}$ , fulfill the criterion:

(13) \begin{equation} \boldsymbol{A}^\boldsymbol{T}\left[\dot{\boldsymbol{M}}_{\boldsymbol{r}}\!\left(\boldsymbol{r}\right)-2\boldsymbol{H}_{\boldsymbol{r}}\!\left(\boldsymbol{r},\dot{\boldsymbol{r}}\right)\right]\boldsymbol{A}=0,\forall \boldsymbol{A},\boldsymbol\theta,\dot{\boldsymbol\theta }\in R^{n} \end{equation}

where $\boldsymbol{A}$ is assumed as a non-singular matrix.

1.4. Cartesian admittance control

In some applications in which the objective is to control the end effector to follow a path in free-space, position control methods are appropriate. Nevertheless, in some instances with a rigid interaction between the environment and the end effector, a large force will be generated and compromise the safety of the operation. This could be avoided by putting in place a compliant controller on the robot. Among the most commonly used compliant control approaches, Cartesian admittance control is an efficient mechanical admittance method [Reference Shuzhi, Hang and Woon26], featuring damping, stiffness and mass terms:

(14) \begin{equation} \boldsymbol{F}_{ext}=\boldsymbol{M}_{d}\ddot{\boldsymbol{r}}_{e}+\boldsymbol{D}_{d}\dot{\boldsymbol{r}}_{e}+\boldsymbol{K}_{d}\boldsymbol{r}_{e} \end{equation}

where $\boldsymbol{r}_{e}=\boldsymbol{r}_{1c}-\boldsymbol{r}_{1d}, \boldsymbol{M}_{d}, \boldsymbol{D}_{d}$ and $\boldsymbol{K}_{d}$ are the symmetric and positive definite matrices of the desired inertia, damping and stiffness, respectively. $\boldsymbol{r}_{1d}\in R^{m}$ is the desired trajectory, and $\boldsymbol{r}_{1c}\in R^{m}$ is the desired trajectory determined by the external force $\boldsymbol{F}_{ext}$ on the end effector. It can be seen that $\boldsymbol{r}_{1c}=\boldsymbol{r}_{1d}$ when there is no external interaction on the end effector, that is, $\boldsymbol{F}_{ext}=0$ . Meanwhile, when $\boldsymbol{F}_{ext}\neq 0$ indicates external interaction on the end effector, the desired trajectory will be modified as a new trajectory that can be seen as the adaptation relation between the external force and the target admittance model in [Reference Buerger and Hogan27]. As it is shown in Fig. 3, the proposed framework is constructed with a decoupled control and adaptive approximation layer.

Figure 3. The proposed control architecture.

1.5. Null-space projection and decoupling control

By specifying the joint angular velocity in the joint space and the end effector velocity in the workspace:

(15) \begin{equation} \dot{\boldsymbol{r}}_{\mathbf{1}}=\boldsymbol{J}_{\mathbf{1}}\!\left(\boldsymbol{\theta }\right)\dot{\boldsymbol{\theta }} \end{equation}

where $\dot{\boldsymbol{r}}_{\mathbf{1}}\in R^{3}$ is the real Cartesian velocity for the end effector, and $\boldsymbol{J}\mathbf{(}\boldsymbol{\theta }\mathbf{)}\in R^{3\times n}$ is the Jacobian matrix from the base to the end effector. To drive the end effector ( $\boldsymbol{r}_{\mathbf{1}}\in R^{3}$ ) to reach the desired position ( $\boldsymbol{r}_{{\textbf{1}}\boldsymbol{d}}\in R^{3}$ ), the task control torque, ${\boldsymbol\tau} _{\mathbf{T}}$ , can be defined as

(16) \begin{equation} \boldsymbol\tau _\boldsymbol{T} = \boldsymbol{J}_{\mathbf{1}}^\boldsymbol{T}\!\left(\boldsymbol{K}_{\boldsymbol{r}{\textbf{1}}}\tilde{\boldsymbol{r}}_{\mathbf{1}}-\boldsymbol{D}_{\boldsymbol{r}{\textbf{1}}}\dot{\boldsymbol{r}}_{{\textbf{1}}}\right) \end{equation}

where $\boldsymbol{J}\mathbf{(}\boldsymbol{\theta }\mathbf{)}\in R^{3\times n}$ is the Jacobian matrix from the base to the end effector, $\tilde{\boldsymbol{r}}_{\mathbf{1}} = \boldsymbol{r}_{{\textbf{1}}\boldsymbol{d}}-\boldsymbol{r}_{\mathbf{1}}\mathbf{(}\boldsymbol{\theta }\mathbf{)}\in R^{3\times n}, \boldsymbol{K}_{\boldsymbol{r}{\textbf{1}}}\in R^{3\times 3}$ is the diagonal stiffness matrix and $\boldsymbol{D}_{\boldsymbol{r}{\textbf{1}}}\in R^{3\times 3}$ is the diagonal damping matrix.

Because the number of the degrees of freedom is larger than three, the redundant serial robot can be employed to complete additional tasks by the null-space controller ( ${\boldsymbol\tau} _\boldsymbol{N}\in R^{n}$ ), which can be specified as

(17)

where ${\boldsymbol\tau} _{{\boldsymbol{T}}_{\mathbf{2}}}\in R^{n-3}$ serves as the torque to complete the additional assignment with redundant degrees, $\boldsymbol{J}\mathbf{(}\boldsymbol{\theta }{\mathbf{)}}_{\boldsymbol{M}}^{+}$ is the inertia-weighted pseudoinverse matrix [Reference Khatib24] defined as

(18) \begin{equation} \boldsymbol{J}\mathbf{(}\boldsymbol{\theta }{\mathbf{)}}_{\boldsymbol{M}}^{+} = \mathbf{(}\boldsymbol{J}_{\mathbf{1}}\mathbf{(}\boldsymbol{\theta }\mathbf{)}\boldsymbol{M}\mathbf{(}\boldsymbol{\theta }\mathbf{)}^{-\mathbf{1}}\boldsymbol{J}_{\mathbf{1}}\mathbf{(}\boldsymbol{\theta }\mathbf{)}^\boldsymbol{T}\mathbf{)}^{-\mathbf{1}}\boldsymbol{J}_{\mathbf{1}}\mathbf{(}\boldsymbol{\theta }\mathbf{)}\boldsymbol{M}\mathbf{(}\boldsymbol{\theta }\mathbf{)}^{-\mathbf{1}} \end{equation}

1.6. Adaptive neural approximation

The neural approximation has been well known to be adopted for the approximation of the uncertain disturbances [Reference Zhang, Li and Yang28], and here introduces a kind of feedforward neural web which is constructed with three general layers, that is, the hidden layer, the input layer and the output layer. Regarding the minimum MSE, it attains a globally optimised solution to the adjustable weights. The inputs variables ( $Z_{1},\ldots Z_{m}$ ) are distributed from the input layer to the hidden layer. The hidden layer consists of $N$ neurons, and each neuron computes the Euclidean distance between the inputs and the centres. Every neuron from the hidden layer employs a radial basis function ${\xi}$ as its nonlinear activation function. In this paper [Reference Yang, Wang, Cheng and Ma20], the Gaussian function is depicted as the most commonly used activation function in the RBFNN algorithm. The hidden layer conducts a nonlinear transform of the input, the output layer serves as a mixture of the weighted hidden layer outputs that calculates the approximated output variable ( $y_{1},\ldots,y_{j}$ ). The output of RBFNN ( $y_{1},\ldots,y_{j}$ ) is computed as

(19) \begin{equation} y_{i}=\sum\limits_{k=1}^{N}\omega _{ki}{\xi} _{i},\,\,\,\,\,\,i=1,2,\ldots,j \end{equation}

where $y_{i}$ is the $i$ th output, $\omega _{ki}$ is the connection weight from the $k$ th hidden unit to the $i$ th output unit and $j$ is the dimension of the outputs.

The approximation is employed in this study to correct for the Cartesian position mistake. As a result, the input $Z$ is picked with the Cartesian position $\boldsymbol{r}$ . The uncertain disturbance $\boldsymbol{\Xi }\mathbf{(}\boldsymbol{r}\mathbf{,}\dot{\boldsymbol{r}}\mathbf{)}$ is represented as

(20) \begin{equation} \boldsymbol{\Xi }\!\left(\boldsymbol{r}\mathbf{,}\dot{\boldsymbol{r}}\right) = \boldsymbol{\Omega }\cdot \boldsymbol{\xi} \!\left(\boldsymbol{r}\mathbf{,}\dot{\boldsymbol{r}}\right)+\varepsilon \end{equation}

where $\varepsilon$ is the smallest approximation error of RBFNN algorithm, $\boldsymbol{\Omega }=[\omega _{1},\omega _{2},\ldots,\omega _{l}]^{T}$ is the best constant weight matrix of neural web, $l$ is the number of nodes used in neural networks and $\boldsymbol\xi \mathbf{(}\boldsymbol{r}\mathbf{,}\dot{\boldsymbol{r}}\mathbf{)}=[{\xi} _{1},{\xi} _{2},\ldots,{\xi} _{l}]$ is Gaussian function matrix. According to the RBFNN approximation theory, the approximation error has an upper bound $\varepsilon ^{*}$ , i.e. $| \varepsilon | \leq \varepsilon ^{*}$ , with a positive constant $\varepsilon ^{*}\gt 0$ .

The Gaussian function matrix employed in the RBFNN algorithm is specified as below:

(21) \begin{equation} {\xi} _{i}\!\left(Z\right)=\exp \left[\frac{-(Z-c_{i})^{T}(Z-c_{i})}{{b}_{i}^{2}}\right] \end{equation}

Whereas $c_{i}$ is the central point of receptive field, $b_{i}$ appears as the width of the Gaussian function. In accordance with the rule of approximation, a positive constant $\delta$ such that $\parallel {\xi} (Z)\parallel \leq \delta$ with $\delta \gt 0$ exists.

The adaptive neural web update law [Reference Zhang, Li and Yang28] is presented to modify the weights of neural network as:

(22) \begin{equation} \dot{\boldsymbol{\Omega }} = \boldsymbol\gamma \!\left[\boldsymbol{E}\boldsymbol\xi ^\boldsymbol{T}\!\left(\boldsymbol{r}\mathbf{,}\dot{\boldsymbol{r}}\right)+\boldsymbol{\varsigma }\boldsymbol{\Omega }\right] \end{equation}

where $\boldsymbol\gamma$ is a diagonal positive definite constant matrix that determines the update pace, $\boldsymbol{E}$ is the error vector and $\boldsymbol\varsigma$ is a neural network momentum factor matrix that can boost both training speed and accuracy accuracy and training speed.