WASHINGTON: At Vassar College in the United States, a university team gathered the week before the devastating fire at Notre-Dame cathedral in Paris to plan an ambitious project: inventorying about a terabyte of 3-D modeling data of the famed Gothic masterpiece.
The precious data — the most accurate in the world — is the work of Andrew Tallon, a Francophile American art professor who loved medieval architecture and was passionate about Gothic cathedral. He died in November.
His technique was nothing new, but his application of the tools was innovative. In 2011 and 2012, funded by a foundation, Tallon used a laser device to accurately measure the interior and exterior of the cathedral, which was ravaged by flames this week.
He placed the device in about 50 places to measure the distance between each wall and pillar, recess, statue or other form — and to record all the imperfections intrinsic to any centuries-old monument.
The result is over a billion points in the “point cloud.” The final computer-generated images reconstruct the cathedral down to the smallest detail, including its tiny defects, with a precision of about five millimeters (0.1 inches).
These images, for example, confirmed how the west side of the cathedral was a “total mess... a train wreck,” Tallon told National Geographic in 2015, pointing to the misalignment of the interior columns.
He wanted to get “into the mind of the builders,” said his former student Lindsay Cook, a Francophile like Tallon who is now a visiting assistant professor of art at Vassar.
“He was interested in using laserscan data to find moments like small ruptures in the construction, places where things were not exactly straight or in plumb, where you could see the hand of an individual architect at work, and in that case the hand of individual masons,” Cook told AFP.
From these measurements were born the images published in a book in 2013 and shown in an exhibition at Notre-Dame in 2014. But the bulk of the data remains untapped in the form of 1s and 0s on some hard drives.
Notre-Dame can probably be reconstructed without this data, but laser modeling brings precision to the photographs and drawings held by architects in France.
This is particularly useful for elements such as roofing and the spire, which were more difficult to measure physically. The 19th-century spire collapsed in the fire, and the roof is largely devastated.
The modeling will help restorers to identically recreate the part of the vault that has collapsed inside.
“If eventually the authorities wish to use this, then of course it would be shared with them,” said Cook.
The data is currently on external hard drives at Vassar, with copies at Columbia University, where academics collaborated with Tallon as part of the “Mapping Gothic” project.
If architects ask for the data, it would have to be delivered in person, as it is too large to be transmitted over the Internet.
If Tallon’s “scholarly work can somehow inform those who will be taking on the daunting task of restoring a cathedral to its former glory, it will be a fitting memorial for a very wonderful scholar who devoted so much to Notre-Dame,” said Vassar dean Jon Chenette.
On other hard drives, historians will also find, if they wish one day, another inheritance from Tallon: laser modeling of the cathedrals of Beauvais, Chartres, Canterbury and even the Basilica of Saint-Denis.