Using a combination of mathematics, computer simulations, and laboratory experiments, the researchers have discovered how to design a robot with the optimum size, shape and the arrangement of its parts, allowing it to jump high enough to clear obstacles many times its own size.

The current highest-jumping robot can reach up to 33 metres, which is equivalent to 110 times its own size. Now, researchers have found out how to design a robot that could jump over 120 metres in the air – that’s more than the height of Big Ben’s tower.

The advancement, published in the journal , will revolutionise applications ranging from planetary exploration to disaster rescue to surveillance of hazardous or inaccessible spaces.

Co-author , Research Associate in Space Robotics at Swagֱ��, said: “Robots are traditionally designed to move by rolling on wheels or using legs to walk, but jumping provides an effective way of travelling around locations where the terrain is very uneven, or where there are a lot of obstacles, such as inside caves, through forests, over boulders, or even the surface of other planets in space.

“While jumping robots already exist, there are several big challenges in the design of these jumping machines, the main one being to jump high enough to overcome large and complicated obstacles. Our design would dramatically improve the energy efficiency and performance of spring-driven jumping robots.”

The researchers found that traditional jumping robots often take off before fully releasing their stored spring energy, resulting in inefficient jumps and limiting their maximum height. They also found that they wasted energy by moving side to side or rotating instead of moving straight up.

The new designs must focus on removing these undesirable movements while maintaining the necessary structural strength and stiffness.

Co-author, Senior Lecturer in Aerospace Engineering, said: “There were so many questions to answer and decisions to make about the shape of the robot, such as should it have legs to push off the ground like a kangaroo, or should it be more like an engineered piston with a giant spring? Should it be a simple symmetrical shape like a diamond, or should it be something more curved and organic? Then, after deciding this we need to think about the size of the robot – small robots are light and agile, but then large robots can carry bigger motors for more powerful jumps, so is the best option somewhere in the middle?

“Our structural redesigns redistribute the robot’s component mass towards the top and taper the structure towards the bottom. Lighter legs, in the shape of a prism and using springs that only stretch are all properties that we have shown to improve the performance and most importantly, the energy efficiency of the jumping robot.”

Although the researchers have found a practicable design option to significantly improve performance, their next goal is to control the direction of the jumps and find out how to harness the kinetic energy from its landing to improve the number of jumps the robot can do in a single charge. They will also explore more compact designs for space missions, making the robot easier to transport and deploy on the moon.

Backed by a £4.2 million funding award from UK Research and Innovation’s building a secure and resilient world strategic theme, the University team will drive a Research and Coordination Hub in confronting pressing risks and threats both online and in the world around us.  

Led by Dr Richard Kirkham, Deputy Director of the  at Swagֱ��, the project known as (Secure And ResiLIENT), will bring Swagֱ�� academics together with partners from the universities of Bath, Exeter and Sussex, to catalyse, convene and conduct research and innovation in support of the UK's national security and resilience. 

will drive interdisciplinary research to tackle some of the UK's most challenging security problems. Their focus will be on robust and secure supply chains, global order in a time of change, technologies used for security and defence, behavioural and cultural resilience, and strengthening resilience in our natural and built environments.  

This ambitious five-year investment, following a highly competitive selection process, will enable the SALIENT team to build strong connections across a broad group of stakeholders in central and local government, the devolved administrations and crucially, the public.

Dr Kirkham continued: “Our approach will promote a culture of genuine interdisciplinarity, co-production and citizen engagement, ensuring that the research we do is relevant, timely and represents value for money.” 

Duncan Shaw, Professor of Operational Research and Critical Systems at Swagֱ��, added: “Enhancing the resilience of systems and society is an epic ambition, one that has challenged the UK for years. SALIENT amasses an impressive multidisciplinary team that we will expand with policy and practice subject matter experts. Together we will pursue an exciting endeavour to make a real difference to resilience at home and create transferable lessons of global significance.” 

The collaboration will support the development of future engineering talent, as well as drive the development of innovative and sustainable power solutions.

As part of the collaboration, Swagֱ�� and Cummins will conduct cutting-edge research with the aim of accelerating product development of the latest generation of air handling technologies, such as e-turbos for fuel cells, together with fuel injection systems for hydrogen-based power solutions.

Academics and their students will explore the future use of hydrogen in power solutions as part of the collaboration, using world class engineering equipment, test cells and laboratories.

Students will also be given the opportunity to apply their learnings to a practical environment and gain valuable industry experience with Cummins. These placements will be open to all students, irrespective of academic discipline, aligning with the variety of roles available at Cummins.

Dr John Clark, Executive Director for Research & Development at Cummins, said: “It’s fantastic to announce our collaboration with Swagֱ��, with the partnership holding tremendous potential for both of us. It will provide students and researchers with the opportunity to work with an established, international manufacturer and actively contribute to the advancement of power solution technology. It will also help to drive the development of sustainable products, supporting our commitment to powering a more prosperous world.”

Dr Louise Bates, Head of Strategic Partnerships at Swagֱ��, added: “This partnership is a great opportunity for our research community to engage with an international company, developing widely-used technologies and groundbreaking solutions to real-world challenges. Swagֱ�� is committed to achieving the United Nations’ Sustainable Development Goals, and this partnership presents a very exciting platform for our two organisations to collaborate and address some of the most pressing challenges facing our planet. We look forward to growing our relationship with Cummins and witnessing what we can achieve together.”

The Cummins Engine Components (CEC) site in Huddersfield designs, develops, produces and refurbishes air handling solutions, which are used globally in vehicles and machinery across various markets.  CEC is part of the international engine, power generation and filtration product manufacturer, Cummins, which employs 73,600 worldwide and generated $28.1 billion in revenue last year. This collaboration between Cummins and Swagֱ��, and the development of future air handling solutions for sustainable technologies, will support the manufacturer’s Destination Zero commitment.

The drone, made from a cardboard-like material called foamboard, measures 6.4m (21 ft) corner to corner and weighs 24.5kg – 0.5kg less than the weight limit set by the Civil Aviation Authority.

The innovative design of the drone, dubbed the Giant Foamboard Quadcopter (GFQ), means it is unlike any other in existence. The four arms are formed of a series of hollow box structures and can be easily removed for transportation. There is no record of a purpose-built uncrewed quadcopter (four rotors) of any weight class which is larger than the Swagֱ�� vehicle as of the time of writing.

The project started as a curiosity-driven venture to inspire students’ creativity in design by utilising a suitable alternative low-cost material for lightweight aerospace structures that is more environmentally friendly than the usual carbon fibre.

Unlike carbon fibre, low-density sheet materials can be highly recyclable, or even compostable. The researchers hope this demonstration will inspire the next generation of designers to think about sustainability from a completely new perspective.

Dan Koning, a research engineer at Swagֱ��, who led the design and build of the vehicle, said: “Foamboard is an interesting material to work with, used in the right way we can create complex aerospace structures where every component is designed to be only as strong as it needs to be - there is no room for over-engineering here.

“Thanks to this design discipline and after extensive background research, we can say with confidence that we have built the largest quadcopter drone in the world.”

Whilst this drone was developed purely as a proof-of-concept exercise, future iterations of this vehicle type could be designed to carry large payloads over short distances or used as a drone ‘mothership’ in air-to-air docking experiments.

The quadcopter was built from sheets of 5mm thick foamboard, which has a foam core and paper skin. The sheets were laser cut to size and assembled into the 3D structure by hand using only hot melt glue.

Josh Bixler, world renowned YouTuber and innovator in remote-controlled aviation is the President of , the company that makes the foamboard used in the GFQ.

Commenting on the work, Josh said: “So many times aircraft with advanced features are made of costly materials and we truly believe they don’t have to be. Seeing engineers push the limits in such an approachable, yet extravagant way was inspirational and showed that they were truly thinking outside of the box.”

GFQ is powered by four electric motors running off a 50-volt battery pack. It also has an on-board flight control system and can fly autonomously.

The first flight took place on 5 July 2023 inside the main hangar at the Snowdonia Aerospace Centre during the CASCADE Collaboration Workshop Week where teams from various universities around the UK come together to demonstrate their latest research tech and brainstorm innovation.

Kieran Wood, a Lecturer of Aerospace Systems at Swagֱ��, who piloted the vehicle, said: “The first moments of flight are the make-or-break point for these types of multi-copter drones. There are many hundreds of things that you must get right. If everything has been designed and built well, we expect success, but any problems will become very apparent in a rapid unscheduled disassembly on the first take-off.”

The project builds on the previous success of an equally  Following this, a student society was created at the University specifically to focus on developing lightweight, large scale foamboard Unmanned Aerial Vehicles (UAVs).

Over the last year, a team of undergraduates helped build and test various critical sub-components of the structure.

Bill Crowther, a Professor of Aerospace Engineering at Swagֱ��, said: “Working with foamboard provides a unique learning opportunity for students to experiment with innovative structural designs. Although the material is strong for its weight, it requires significant engineering skill to exploit its structural potential. Ultimately, with this design you are holding up 25kg of aircraft with just a few strategically placed pieces of paper - that’s the art of the possible.”

The team are now looking to optimise the design of the Giant Foamboard Quadcopter further.

Dan Koning added: “The lessons we’ve learned from this pathfinder vehicle should help us add a few more metres to the next one. But to go 50% bigger, you’ve got to get 100% smarter.”

Three students from Swagֱ��'s have been named among the finalists of the . 

To be held on Friday, 29 April at a prestigious awards ceremony in London, the event – now in its 13th year – brings together prominent employers and talented undergraduates for 12 diverse awards. 

A total of 120 student finalists have been selected from almost 4,000 applicants, with all entrants required to complete an application, an online assessment with situational, numerical and inductive reasoning tests, and a range of interview stages. 

From Swagֱ��, Jacques Burgess (aerospace engineering) has been shortlisted for the Excellence through Adversity Undergraduate of the Year 2022; Jesy Luyengi (mathematics and related) is a finalist for the Black Heritage Undergraduate of the Year 2022; and Aneesa Riaz (electrical engineering) is up for the Undergraduate of the Year Celebrating Neurodiverse Talent 2022. 

Each of the 12 awards are partnered by a prominent graduate recruiter, which provides prizes for the winner – including a paid internship, trips abroad, and other exclusive opportunities. 

Among the partners are employers and professional bodies including the likes of AECOM, CIMA, Clifford Chance, Clyde and Co, Enterprise Rent-A-Car, HSBC, Rolls-Royce, Sky and Skyscanner. 

The students were required to complete the design and build within two weeks, and to perform a flight demonstration at the EPSRC CASCADE collaboration workshop, which was held between 17 and 21 June 2019 at Snowdonia Aerospace Centre in Llanbedr, North Wales.

Their aircraft uses foam board for the entirety of its structure and is powered by an electric ducted fan. It has a wingspan of two metres and all up weight of 6kg.

Currently, the whole of the UK aerospace sector is gearing up for Tempest - the future fighter jet - which is set to be released in 2035. Companies including BAE Systems and Rolls-Royce, as well as the Ministry of Defence, are restructuring to prepare for the years of research, development and manufacturing ahead.

The Tempest programme promises to be the pinnacle of British engineering - and Swagֱ�� is keen to be involved. The successful test flights of the students' model aircraft demonstrate some of the aerodynamic characteristics of an aircraft with a Tempest-like shape.

The MSc students involved have since been studying these characteristics in an effort to help with the research required for the next generation fighter jet.

A video of the students' successful flights can be seen below:

Contract represents one of the largest capital developments ever undertaken by a UK higher education institution.

Swagֱ�� has today announced that the £287 million contract to construct the Swagֱ�� Engineering Campus Development (MECD) has been formally awarded to Balfour Beatty, the international infrastructure group.

The four-year project forms an essential part of Swagֱ��’s ten-year to create a world-class estate benefitting staff, students and visitors.

This will support the University’s strategic goals of creating world-class research, providing an outstanding learning environment and student experience and social responsibility. will provide a state-of-the-art facility, housing the University’s schools, innovative teaching spaces and research institutes such as and the BP- International Centre for Advanced Materials ().

It will consolidate the majority of the University’s estate onto one main campus, creating a more compact and coherent infrastructure that reduces the institution’s carbon footprint and costs. MECD will also free up considerable land holdings in the north of the campus, contributing to the future economic success of the city with redevelopment opportunities in a prime city centre location.

Upon completion, the facility will benefit from ‘green’ construction techniques resulting in smart energy consumption and advanced water recycling and waste systems. The development will host a wide range of flexible hi-specification laboratories and lecture spaces to welcome up to 7,000 students and 1,300 staff. MECD will also incorporate blended learning facilities, workshops and a ‘maker space’ where students will see their engineering creations come to life.

At peak construction, the project will employ a workforce of 1,000, including multiple apprenticeships and graduate placements. The project will also create new job opportunities for unemployed local people through the University’s Construction Academy, which provides local residents with exposure to career opportunities in the construction sector. The project team will maximise the use of off-site manufacture and the latest in BIM technology to optimise construction efficiency and deliver a smart facility of the highest standard.

Dean Banks, Managing Director, UK Construction Services, said: “We are delighted to have been appointed to construct the MECD, one of the largest single developments ever undertaken by a higher education institution in the UK.

“We have extensive expertise in the higher education sector having delivered schemes such as the Holyrood postgraduate village at the University of Edinburgh, The Diamond building for the Engineering Faculty for the University of Sheffield, and the Foundry Courtyard Student Accommodation Complex in Glasgow. Our longstanding expertise enables us to provide Swagֱ��, its staff and students with an iconic campus, in addition to delivering multiple benefits to local communities including job generation and apprenticeship opportunities.”

Diana Hampson, Director of at Swagֱ��, said: “The Swagֱ�� Engineering Campus Development will be a world-leading centre for learning and research. This development is central to the University’s ten-year Campus Masterplan which is creating an exceptional environment for our exceptional people. We are providing state-of-the-art facilities that will rival those of our international competitors and help attract world-class academic talent to the institution."

Balfour Beatty was appointed to the University’s Construction Partnering Framework in May 2015 and has been working under a Pre-Construction Services Agreement (PCSA) since November 2015, enabling design development and early engagement with key supply chain partners.