The researchers said that the new digital fibre can be sewn into fabrics and washed at least 10 times without breaking down. The fibre was created with the help of hundreds of square silicon microscale digital chips that were placed on a platform. It was then used to create polymer fibre, which is thin and flexible and can be passed through a needle.
Researchers said that the digital fibre can store a lot of memory as they were able to write, store, and read the information on it, including a 767Kb full-colour short movie file as well as a 0.48Mb music file. Such files can be stored for two months without power, they said.
A report in MIT News quoted Fink as saying, “This work presents the first realisation of a fabric with the ability to store and process data digitally.” Fink added that this was a “new information content dimension to textiles” and allowed “fabrics to be programmed literally.”
Gabriel Loke, a PhD student at MIT and a lead author on the study, said that when the fibre was put into a shirt, one can’t feel it at all. “You wouldn’t know if it was there,” Loke said.
Loke added that digital fibre opens up several areas of opportunities and solves some of the problems of functional fibres.
Since the digital fibre can store a lot of memory, among the “crazy ideas” that struck the researchers were using it for a wedding gown that would store digital music within the weave of its fabric.
Besides, the fibre, in its memory, also includes a neural network of 1,650 connections. Now, what does that do? To explain that, the researchers sewed the fibre around the armpit of a shirt and then collected 270 minutes of surface body temperature data from the person wearing the cloth. They then analysed how these data corresponded to the different physical activities. They found that the fibre was able to determine with 96 percent accuracy what activity the person wearing it was engaged in, they said.
And this analytic power, researchers say, may well one day reach a stage where it senses and alerts people in real-time to health changes like a respiratory decline or an irregular heartbeat. For now, the fibre is controlled externally by a device, but the next step, according to researchers, is to develop a microchip that can be connected within the fibre itself.