12 March 2018
Holography Approach Improves Heads up Displays for Planes and Cars
New heads-up display technology will make it easier for drivers and pilots to see information while viewing the outside world
WASHINGTON — Heads-up displays are transparent devices used in airplanes and cars to provide information such as critical flight data or driving directions on the windshield. An innovative holography-based approach could soon make these heads-up displays much easier to see with a large eye box.
Current heads-up displays have a small eye box, meaning that the displayed information partially or wholly disappears if users shift their gaze too much. “A heads-up display using our new technology installed in a car would allow a driver to see the displayed information even if he or she moved around or was shorter or taller than average,” said research team leader Pierre-Alexandre Blanche of the University of Arizona
In The Optical Society journal Applied Optics
, the researchers demonstrate a functional prototype heads-up display that uses holographic optical elements to achieve an eye box substantially larger than what is available without the holographic element. The researchers say that their approach could be turned into a commercial product in as little as a few years and might also be used to increase the size of the displayed area.
||The new heads-up display uses holographic optical elements to inject an image into the glass, or waveguide (left). The light enters the glass and bounces back and forth between its front and back edges until it reaches another holographic optical element that extracts a small portion of light that leaves the glass with each bounce (right). The extraction holographic creates a viewable image, with each bounce proportionally increasing the eye box size for the image. Image Credit: Pierre-Alexandre Blanche, University of Arizona.
“Increasing the size of either the eye box or the displayed image in a traditional heads-up display requires increasing the size of the projection optics, relay lenses and all the associated optics, which takes up too much space in the dashboard,” said first author Colton Bigler, a doctoral student in Blanche’s laboratory. “Instead of relying on conventional optics, we use holography to create a thin optical element that can be ultimately applied onto a windshield directly.”
Using holograms to make optics
The same laser light interactions used to create the holograms that protect credit cards from forgery can also be used to fabricate optical elements such as lenses and filters in light-sensitive materials. These holographic elements are not only smaller than traditional optical components but can be mass produced because they are easily fabricated.
For the new head-up display, holographic optical elements redirect light from a small image into a piece of glass, where it is confined until it reaches another holographic optical element that extracts the light. The extraction hologram presents a viewable image with a larger eye box size than the original image.
“We are working with Honeywell to develop these displays for aircraft, but they could just as easily be used in cars,” Blanche said. “Our approach requires no expensive equipment and no new materials need to be developed. Furthermore, the display can be completely integrated into a standard car windshield.”
After performing optical simulations, the researchers created a laboratory version of their head-up display that created an eye box seven times larger than the original image. They then made a working prototype that displayed flight information on a piece of glass that can be part of the transparent enclosure that covers cockpits. Using the prototype, they were able to almost double the eye box of the original image and showed that the image doesn't disappear until the user looks beyond the edge of the hologram. They also demonstrated that the presented image appears in the far field, meaning that observers don’t need to change their focus to see the displayed information.
“It’s possible to create a much larger eye box by increasing the size of the injection and extraction holographic elements, the only limitation is the size of the glass displaying the image,” Blanche continued. “Our work is a good example of how holography can be used to solve many types of optical problems for various applications. A similar approach might also be useful for augmented reality headsets, which also merge computer-generated images with views of the outside world but with a display that is close to the eye.”
Although the researchers demonstrated their approach using one color, they say that it could be expanded to create full-color heads-up displays. They are also working to use the same approach to create a much larger image that is extracted by the holographic element to increase the size, or field of view, of the display.
: C. M. Bigler, P.-A. Blanche, K. Sarma, “Holographic Waveguide Heads-Up Display for Longitudinal Image Magnification and Pupil Expansion
,” Applied Optics
, Volume 57, Issue 9, 2007-2013, (2018).
About Applied Optics
publishes in-depth peer-reviewed content about applications-centered research in optics. These articles cover research in optical technology, photonics, lasers, information processing, sensing and environmental optics. The editor-in-chief for Applied Optics is Ronald Driggers from the University of Central Florida. For more information, visit: OSA Publishing
About The Optical Society
Founded in 1916, The Optical Society (OSA) is the leading professional organization for scientists, engineers, students and business leaders who fuel discoveries, shape real-life applications and accelerate achievements in the science of light. Through world-renowned publications, meetings and membership initiatives, OSA provides quality research, inspired interactions and dedicated resources for its extensive global network of optics and photonics experts. For more information, visit osa.org