“This display is like a 3D printer for light. You’re actually printing an object in space with these little particles.” - Daniel Smalley, #BYU electrical engineering professor. BYU engineers have developed a technique for creating a full-color 3D graphic display that can float in free space and is visible from any angle. Inspired by the displays of science fiction--most notably the iconic Star Wars' Princess Leia projection--the new Optical Trap Display (OTD) technique, creates a 3D volumetric image by trapping and illuminating a particle with a laser, and then scanning the image in free space. Unlike a hologram, a volumetric image is created in free-space and is visible from any angle. BYU electrical engineering professor Daniel Smalley and co-authors publish their research ("A photophoretic-trap volumetric display') in the January 24, 2018, issue of the journal Nature.

Media inquires please contact Todd Hollingshead ([email protected])
Video produced by BYU University Communications: Julie Walker (producer); Brian Wilcox (DP), Hannah Hansen (editor)
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Special thanks to the films that inspired the research:
Star Wars (courtesy 20th Century Fox and LucasFilm)
Avatar (courtesy 20th Century Fox and Lightstorm Entertainment)
Iron Man (courtesy Marvel Studios, The Walt Disney Studios)
All rights retained by the copyright holders

News release from Todd Hollingshead, Brigham Young University:
See: http://bit.ly/2n7A9sh

Better than a hologram: BYU study produces 3D images that float in thin air
Photophoretic-trap volumetric display produces full-color graphics in free space

In the original Star Wars film, R2D2 projects an image of Princess Leia in distress. The iconic scene includes the line still famous 40 years later: “Help me Obi Wan Kenobi, you’re my only hope.”

BYU engineering professor and holography expert Daniel Smalley has long had a goal to create the same type of 3D image projection. In a paper published this week in Nature, Smalley details the method he has developed to do so.

“We refer to this colloquially as the Princess Leia project,” Smalley said. “Our group has a mission to take the 3D displays of science fiction and make them real. We have created a display that can do that.”

First things, first, Smalley says. The image of Princess Leia is not what people think it is: It’s not a hologram. A 3D image that floats in air, that you can walk all around and see from every angle, is actually called a volumetric image. Examples of volumetric images include the 3D displays Tony Stark interacts with in Ironman or the massive image-projecting table in Avatar.

A holographic display scatters light only at a 2D surface. If you aren’t looking at that surface you won’t see the 3D image because you must be looking at the scattering surface to see the image. A volumetric display has little scattering surfaces scattered throughout a 3D space — the same space occupied by the 3D image — so if you are looking at the image you’re are also looking at the scatters. For this reason, a volumetric image can be seen from any angle.

Smalley and his coauthors have devised a free -space volumetric display platform, based on photophoretic optical trapping, that produces full-color, aerial volumetric images with 10-micron image points by persistence of vision.

“We’re using a laser beam to trap a particle, and then we can steer the laser beam around to move the particle and create the image,” said undergrad coauthor Erich Nygaard.

Smalley said the easiest way to understand what they are doing is to think about the images they create like 3D-printed objects.

“This display is like a 3D printer for light,” Smalley said. “You’re actually printing an object in space with these little particles.”

So far Smalley and his student researchers have 3D light printed a butterfly, a prism, the stretch-Y BYU logo, rings that wrap around an arm and an individual in a lab coat crouched in a position similar to Princess Leia as she begins her projected message.

While previous researchers outside of BYU have done related work to create volumetric imagery, the Smalley team is the first to use optical trapping and color effectively. Their method of trapping particles and illuminating it with colorful lasers you can see is novel.

“We’re providing a method to make a volumetric image that can create the images we imagine we’ll have in the future,” Smalley said.