Putting solar panels onto houses and offices once seemed good for the environment but a nuisance for architects. Now buildings can easily be green and beautiful, says a Spanish and German EUREKA partnership, which found a way to make photovoltaic film virtually invisible.

Homeowners who wanted to produce energy by capturing the sun’s rays through solar panels on their roofs used to have to put up with ugly add-ons to their houses in order to help save the planet. But now there is no need for green buildings to be either expensive or an eyesore, says a Spanish-German partnership, which has developed a virtually invisible solar film for an accessible price in a EUREKA project.

“You don’t see the film at all – it’s marvellous,” says Francisco Ruiz Caballero, General Manager and Head of R&D projects at Intemper Espanola, the Spanish partner which led EUREKA project Fotointegral. “It’s integrated into the building rather than superimposed on it.”

Much solar energy technology uses rigid crystal silicon panels. Installing them on homes or offices usually involves placing a mechanical frame on the building – and that usually comes on top of rooftop waterproofing and insulation. Ruiz started to wonder if four or five separate products on a roof were really necessary and whether they couldn’t be combined into one multi-purpose product, made from flexible silicon cells.

One of Intemper’s suppliers was bought by a German company with an industry reputation for waterproofing flat roofs, which made it a clear candidate to partner with Ruiz’s Intemper in researching the new product. The company agreed to join the R&D with EUREKA backing.

Although some solar panelling did use amorphous silicon cells, they tended to be too expensive and had a reputation for being less effective than the crystal silicon panelling. Intemper and its partner had to make their flexible film thin enough to not jut out and spoil the sharp lines on stylishly designed roofs – and then they had to ensure the solar power it generated could compete with the power output from bulky panelling.

SOLAR SAMPLING

The German company created sophisticated performance tables to measure the quality of the test combinations of silicon cells the team developed. The researchers needed to know how thin the panelling could be, how the solar cells reacted to sunlight, how well they resisted the elements like wind and rain and how much energy they lost at different angles, if the cells were not all totally exposed to the sun. “One of the hard parts was testing the product on all kinds of inclinations,” says Ruiz.

Meticulous trials and analysis of the databases eventually paid off – the team found a film developed which was just 6mm thick could even be used on vertical surfaces and would lose only about 8 percent of the energy captured from the sun. The pair called this all-in-one roof insulation, waterproofing and solar-panelling Evalon Solar.

Intemper and the other company participating in the project are already selling it in their home markets and have their sights set on expansion as all countries seek to reduce their carbon dioxide emissions and increase the energy generated through renewables. Intemper has signed contracts in Portugal and is now looking at Latin America, starting with Chile and Colombia.

A DESIGNER’S DREAM

Evalon Solar is a hit, particularly with architects looking to include solar panelling on buildings without cluttering up simple roofs or spoiling unusual or effective shapes. “We’ve got another 46 architects coming to look round our site tomorrow,” says Ruiz.
“Architects tell us it looks even better when they see it for themselves on buildings than it does in our photographs.”

The new product happily increased the pair’s markets, giving them an edge as the industry battled the global downturn and a change in solar subsidies in Spain. “We would have done even better without the crisis and the regulation, but we’ve managed to get a bigger slice of a smaller cake,” says Ruiz. Intemper has sold Evalon Solar to customers, large and small, for residential and business premises. Although now the product is a clear winner, developing a technology which was marginal in the industry looked risky back at the start of the project in early 2006: the vast majority of photovoltaic generators sold all over the world were made from crystal silicon and only a tiny minority from amorphous silicon. “EUREKA helped us to make the decision to pursue this because the EUREKA seal gave us a certain financial peace of mind,” says Ruiz. Evalon Solar’s success is starting to change the industry. “Other similar products to ours have come. Unfortunately, yes, when you’re successful, people want to copy!”

A team of telecommunications engineers from the University of Jaen (UJA) has created a new method to automatically detect and identify the musical notes in an audio file and generate sheet music. The system identifies the notes even when the type of instrument, musician, type of music or recording studio conditions vary.

“We propose an automatic system to detect and transcribe musical notes for one-instrument musical signals which, unlike other methods, is capable of adapting to the music scene”, Julio José Carabias, co-author of the paper and a researcher from the Department of Telecommunications Engineering at the University of Jaen explained to SINC.

The details of the method were published recently in IEEE Transactions on audio, speech, and language processing. The fact that the new system can “adapt” means it will work even if elements such as the type of instrument, music, style, studio or microphone position vary.

“Automatic music transcription has many practical applications for musicological analysis and is of enormous assistance, for example, in recovering musical content, separating audio sources and codifying or converting audio files”, Carabias says.

The researchers start with a ‘wav’ file, a common format for audio recordings, and after applying the method they obtain a ‘midi’ file, a musical instrument communication protocol that makes it possible to visualise the sheet music and listen to the result.

Harmonic Dictionary

“Another advantage of this method is that it does not require prior training with a musical database,” the engineer highlights. What the technique does determine is the note or ‘spectral pattern’ of the musical notes of an instrument, which are used to compile a harmonic dictionary.

In music, people talk about ‘harmonicity’ when the energy produced by a note is distributed across the multiple positions of a fundamental frequency.. The distribution of the harmonic energy of a musical note is what defines its spectral pattern. The harmonic diction is a matrix in which the typical spectral patterns of all musical notes are represented.

With the help of this dictionary and a computer algorithm called ‘Matching Pursuit’, the musical notes with patterns that most resemble the harmonic dictionary are identified. While the method can only be applied to files with one sole instrument at present, the scientists are already investigating how it can be applied to several.

Canterbury Cathedral

A unique collaboration between the University of Kent, Canterbury Cathedral Archives and researchers in Rouen has laid the foundations for a new and exciting project through which Canterbury residents and visitors may in the future gain easy access to some of the older and/or more fragile documents held in the Cathedral Archives.

Known as DocExplore, the project aims to develop an interactive system which allows digitised versions of valuable historical documents to be explored via a touch-screen, simulating, as far as possible, the experience of accessing the physical object itself. But users can see much more than the document – they can access translations and transcriptions, read more about the period in which it was written, its contents and who would have used it at the time by using the additional text, image, sound and video resources that are a feature of the system.

DocExplore will also capture the knowledge and expertise of the Archives’ staff by allowing them to easily present any available digitised document.

If the second phase of this EU INTERREG IVA-funded project is agreed, DocExplore will ultimately offer manuscript readers an even wider variety of tools, invaluable for both for the casual visitor with an interest in researching these priceless documents, and for academic historians and literary scholars.

For example, there will be tools to help readers to clarify annotations and to recover sections of the text which are damaged. It will also enable researchers to identify and compare writing samples from different writers and to investigate the nature of the paper on which documents are written.

The system was developed by Dr Richard Guest, Professor Michael Fairhurst and Dr Yiqing Liang from the School of Engineering and Digital Arts (EDA) at the University of Kent; Dr Catherine Richardson from the University’s Centre for Medieval and Early Modern Studies; Dr Malcolm Mercer and Dr Mark Bateson from Canterbury Cathedral Archives; and a team of researchers from the University of Rouen and the Bibliothéque de Rouen Archives.

Dr Yiqing Liang, the EDA-based researcher developing the system software, said: ‘The scoping phase of DocExplore began in April 2009. However, on the 17th and 18th of March this year, local residents were given the opportunity to preview the ideas underpinning the proposed system at a two-day exhibition of the beautiful seventeenth century ‘Travel Diary of John Bargrave’ held in the Cathedral’s archives. This exhibition and the feedback we received helped us learn a great deal more about how to build on the basic concept and will be useful for when we move on to the implementation of the ultimate system in the next phase of the project.’

Dr Liang was also encouraged to see such a high level of interest in the project from those who visited the exhibition. ‘Canterbury Cathedral Archives continues a tradition of record-keeping that dates back at least 1300 years,’ she said. ‘We are proud and excited to be part of such an important tradition.’

Source: http://www.kent.ac.uk/news/stories/cathedral-archives/2010Source