Northumbria Opens Research Labs

Facebook X LinkedIn Email
A new £600,000 ($1.2 million) facility for Northumbria and Newcastle universities to teach and conduct research into photonic and radio-frequency (RF) communications, microwave communications and microwave holography was officially opened this week at Northumbria's School of Computing, Engineering & Information Sciences (CEIS).

The facility, which includes several labs, was funded by the Higher Education Funding Council for England and has been equipped with electronic instruments -- including oscilloscopes, spectrum and network analyzers, optical test equipment and radio frequency and microwave imaging technology -- from test and measurement company Agilent Technologies. The labs will be used by faculty and students at Northumbria and Newcastle universities, which are both located in Newcastle upon Tyne.northumbria.jpg
British government official Alan Duncan with PhD student Shirt Fun Ooi in the photonics lab, part of $1.2 million in new lab facilities officially opened Wednesday at the School of Computing, Engineering & Information Sciences at Northumbria University in Newcastle upon Tyne, England. (Photo: Northumbria University)
The labs were officially opened May 2 by Shadow Secretary of State, Department of Trade and Industry and Shadow Minister for Tyneside Alan Duncan, MP.

The photonic and RF research laboratory is the first photonic lab of its kind in the North of England, officials said, and will showcase the latest design and measurement tools for communications research into new photonic networks, switching, free-space optics and RF technologies.

The new technology in the microwave communications and holography research labs puts them among the best-equipped labs in the United Kingdom for the design of microwave circuitry and research into the uses of microwave imaging, including for the detection of breast cancer tumors and concealed weapons, officials said.

Professor Alistair Sambell, CEIS dean, welcomed the opening of the new labs. He said in a statement, "There is currently tremendous growth in the fields of wired and wireless communications, especially the Internet and increasing demand for mobile handsets with functions such as cameras and MP3 players, which are smaller, cheaper, and with low power consumption. These facilities will help us develop our research in these areas.

“The microwave imaging technology we now have will position Northumbria as one of the leading universities in terms of facilities in this field. We are currently developing a microwave-based technique that can generate holographic high-quality images of hidden objects, such as breast cancer tumors, in our microwave imaging lab, and the new equipment may mean this method may reach the clinic trial stage sooner than we’d initially hoped," Sambell said.

The university's ultimate goal is the creation of a fast 3-D microwave imaging technique that would have medical, security and industrial applications, he said.

For more information, visit:

Published: May 2007
free-space optics
Free-space optics (FSO), also known as optical wireless communication or optical wireless networking, refers to the transmission of data using modulated beams of light through free space (air or a vacuum) rather than using physical cables or fiber optics. FSO systems leverage the principles of optical communication, similar to fiber optic communication, but they transmit signals through the atmosphere over relatively short distances. Key features and aspects of free-space optics include: ...
An electromagnetic wave lying within the region of the frequency spectrum that is between about 1000 MHz (1 GHz) and 100,000 MHz (100 GHz). This is equivalent to the wavelength spectrum that is between one millimeter and one meter, and is also referred to as the infrared and short wave spectrum.
Pertaining to optics and the phenomena of light.
The technology of generating and harnessing light and other forms of radiant energy whose quantum unit is the photon. The science includes light emission, transmission, deflection, amplification and detection by optical components and instruments, lasers and other light sources, fiber optics, electro-optical instrumentation, related hardware and electronics, and sophisticated systems. The range of applications of photonics extends from energy generation to detection to communications and...
Agilent TechnologiesAlan DuncanAlistair SambellcamerasCEISCommunicationsdefensefiber opticsfree-space opticsImagingindustrialInternetmicrowaveNewcastleNews & FeaturesNorthumbriaopticalphotonicphotonic networksphotonicsRFswitching

We use cookies to improve user experience and analyze our website traffic as stated in our Privacy Policy. By using this website, you agree to the use of cookies unless you have disabled them.