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Open now | Lancaster University | Sustainable disposal | TG0 Ltd

Shared Autonomy for Resilient Nuclear Decommissioning

Develop a shared-autonomy teleoperation framework built on tele-visual-tactile fusion for contact-rich nuclear decommissioning tasks.

Lead Supervisor
Dr Ziwei Wang
School of Engineering, Lancaster University

Industry Partner
TG0 Ltd
Confirmed (formal agreement in progress)

Project Start
TBC

Target Background
1st or 2:1 / Master's in Robotics, Control Engineering, Mechatronics or Human-Robot Interaction. C++/Python and ROS/ROS2 desirable.

Second Supervisor
To be confirmed

Industrial Funding
Indicative SME-level support
Sought

Advert Close Date
ASAP

Programme
4 year Engineering Doctorate (EngD)
with industry placement

Project summary

Aims and objectives

  1. Development of tactile-rich representations for contact-led nuclear tasks. Establish a high-fidelity tactile representation using the Linkerbot dexterous hands, identifying and modelling operationally significant regimes including free motion, exploratory contact, stable engagement and impending slip.

  2. Design of a tele-visuotactile shared control framework. Formulate a game-theory-based decision mechanism that modulates the balance of human and robot authority, with a force-guided attention fusion module that adaptively weights visual and tactile features without manual annotation.

  3. Experimental validation via laboratory mock-ups and industrial integration. Evaluate the system through experiments replicating the constraints of nuclear decommissioning, with metrics for peak contact forces, task completion efficiency and operator cognitive load (NASA-TLX).

Alignment to STAND-UP impact targets

>50% reduction in overall build or decommissioning process time

>40% reduction in maintenance time

>30% reduction in person hours on builds (not applicable)

Apply for this project

Contact the lead supervisor or programme team to discuss your interest. Full application instructions are on the How to Apply page.

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Tele-visual-tactile fusion for safety critical teleoperation.

The safe decommissioning of key nuclear assets depends on remote robotic systems capable of high-precision manipulation. While visual feedback remains a primary interface, its utility rapidly becomes degraded or wholly insufficient during contact-rich phases, such as valve interaction or seal engagement, where occlusion and limited focal range impede operator judgement.

Under these conditions, conventional teleoperation becomes acutely fragile, increasing cognitive workload and the risk of task failure.

This EngD project will develop a shared-autonomy teleoperation framework built on tele-visual-tactile fusion for contact-rich nuclear decommissioning tasks. The project is anchored by TG0's tactile sensing capabilities (the Linkerbot platform) and Lancaster University's expertise in robotic teleoperation and intelligent communications.

The expected outcome is a new class of operator-centred shared-autonomy methods that improve right-first-time task execution, reduce unsafe force application in visually ambiguous conditions and strengthen the resilience of remote nuclear intervention

Tele-visual-tactile fusion for safety critical teleoperation.

The safe decommissioning of key nuclear assets depends on remote robotic systems capable of high-precision manipulation. While visual feedback remains a primary interface, its utility rapidly becomes degraded or wholly insufficient during contact-rich phases, such as valve interaction or seal engagement, where occlusion and limited focal range impede operator judgement.

Under these conditions, conventional teleoperation becomes acutely fragile, increasing cognitive workload and the risk of task failure.

This EngD project will develop a shared-autonomy teleoperation framework built on tele-visual-tactile fusion for contact-rich nuclear decommissioning tasks. The project is anchored by TG0's tactile sensing capabilities (the Linkerbot platform) and Lancaster University's expertise in robotic teleoperation and intelligent communications.

The expected outcome is a new class of operator-centred shared-autonomy methods that improve right-first-time task execution, reduce unsafe force application in visually ambiguous conditions and strengthen the resilience of remote nuclear intervention.

Ready to apply?

Read the entry requirements, application process and FAQs on the How to Apply page.