The university is named after John Moores and was previously called Liverpool Mechanics’ School of Arts and later Liverpool Polytechnic before gaining university status in 1992, thus becoming Liverpool John Moores University.
The university is a member of the University Alliance, a mission group of British universities established in 2007. It is also a member of the European University Association and the North West Universities Association.
At present, LJMU serves more than 24,000 students comprising 20,410 undergraduate students and 4,270 postgraduate students, making it the largest university in Liverpool by student population – as well as the twentieth largest in the United Kingdom.
Liverpool John Moores University research articles from Innovation Toronto
The world’s first astrophysics-ecology drone project at Liverpool John Moores University could be the answer to many global conservation efforts.
Four hundred years ago Galileo created a revolution by pointing his telescope to the skies. Now an astrophysicist and an ecologist from Liverpool John Moores University (LJMU) are reversing this perspective to help endangered species including rhinos and orang-utans.
The authors of the study, published in the International Journal of Remote Sensing, have brought together their expertise using drones, thermal cameras and the techniques used to analyse objects in space to find a solution to this 21st Century challenge for Earth.
Professor Serge Wich, from LJMU’s School of Natural Sciences and Psychology and the University of Amsterdam’s Institute for Biodiversity and Ecosystem Dynamics, is a pioneer in using drones for conservation work and is the founder of conservationdrones.org, commented:
“As an ‘eye in the sky’, conservation drones are helping the fight against illegal deforesting, poaching and habitat destruction, all leading to many species being endangered, including rhinos, orang-utans, and elephants. Now, teamed with the same astrophysics analysis techniques used to find and identify objects in the far-distant Universe, we can try to do this more efficiently.”
“The World Bank estimates that ecosystems provide $33 trillion every year to the global economy and biodiversity loss and consequent ecosystem collapse is one of the ten foremost dangers facing humanity. We hope this research will help tackle these problems by allowing anyone in the world to upload their aerial data and in real time get back geo-locations of anything, whether that be survivors of natural disasters, or poachers approaching endangered species, or even the size, weight and health of livestock.”
Dr Steve Longmore, from the LJMU Astrophysics Research Institute, explains why this is possible:
“Astrophysicists have been using thermal cameras for many decades. Crucially, it turns out the techniques we’ve developed to find and characterise the faintest objects in the Universe are exactly those needed to find and identify objects in thermal images taken with drones. The key to success is building libraries of the thermal heat profiles that act like “thermal finger prints”, allowing us to uniquely identify any animals detected. Our goal is to build the definitive finger print libraries and automated pipeline that all future efforts will rely upon.”
The next stage of this research, which will be funded by the Science and Technology Facilities Council (STFC), is to start expanding these techniques to other equally significant applications, including disaster relief and search and rescue.
This new drone technology is part of the growing technological innovation within LJMU. The Astrophysics Research Institute is also developing the world’s largest fully robotic telescope, a scaled up version of the Liverpool Telescope, located at the Roque de Los Muchachos Observatory, on the island of La Palma, and operated by LJMU as a national facility.
The development of the smart power grid and the smart meter in our homes to accompany it brings several benefits, such as improved delivery and more efficient billing. Conversely, any digital, connected technology also represents a security risk. Writing in the International Journal of Smart Grid and Green Communications, UK researchers explain how a malicious third party that hacked into the metering system could manipulate en masse the data being sent back to the smart grid and perhaps trigger a power generation shortfall.
Carl Chalmers, Michael Mackay and Aine MacDermott of Liverpool John Moores University, explain how the implementation of the smart grid brings many improvements over the traditional energy grid by making use of the vast interconnected infrastructure that allows two-way communication and automation throughout the entire grid, from generator to consumer and back.
“A smart grid is a complex modern electricity system which utilises sensors, monitoring, communications, and automation, to improve the electricity system,” the team writes. “Smart grids fundamentally change the way in which we generate, distribute and monitor our electricity. They dramatically improve the efficiency, flexibility and reliability of the existing electricity infrastructure,” they add.
The researchers point out that a critical difference between the old “passive” electricity grid and the new smart grid, is the presence of the advanced metering infrastructure (AMI) which provides the two-way communication between consumer and generator. The flow of data between consumers and generators allows the power generation companies to match demand with generation, to spot patterns in changing demand on a day to day basis or through the changing seasons and more.
However, as the UK has shifted focus from coal- and oil-fired electricity generation to being more reliant on natural gas as the fuel of choice (irrespective of wind, solar, nuclear and other alternatives), this makes the electricity grid somewhat vulnerable to accidental and incidental problems with the flow of data and to malicious manipulation for the sake of sabotage, criminal or online military/terrorist action.
The team adds that, “Critical infrastructures in particular, present a tempting target for terrorists, military strikes and hackers wanting to cause disruption, steal information or incapacitate a country remotely.” The team suggests that now we are forewarned of the possible worst-case scenario with regard to the smart grid and smart meters, we must put in place security measures to protect the infrastructure and maintain that security as the hackers advance to stay at least one step ahead of the threat.
Learn more: When hackers turn out the lights