06 Nov 2019
French firm’s Chimera printer obviates costly lasers, slow printing, limited fov, and unsaturated color.
"Our 15-year research project aimed to build a hologram printer with all the advantages of previous technologies while eliminating known drawbacks such as expensive lasers, slow printing speed, limited field of view and unsaturated colors," commented research team leader Yves Gentet from Ultimate Holography in Bordeaux, France. "We achieved this by creating the Chimera printer, which uses low-cost commercial lasers and high-speed printing to produce holograms with high-quality color that spans a large dynamic range."
The work has been reported in Applied Optics. In the paper, the researchers describe the new printer, which creates holograms with wide fields of view and full parallax on a special photographic material they designed. Full parallax holograms reconstruct an object so that it is viewable in all directions, in this case with a field of view spanning 120 degrees.
The printer can create holograms from 3-D computer generated models or from scans acquired with a dedicated scanner developed by the researchers. The high-quality holograms can even be used as masters to produce holographic copies.
Design and construction
When developing the new hologram printer, the researchers carefully studied two types of previously-developed holographic printer technologies to understand their advantages and drawbacks.
"The companies involved in developing the first two generations of printers eventually faced technical limitations and closed," said Gentet. "Our small, self-funded group found that it was key to develop a highly sensitive photomaterial with a very fine grain rather than use a commercially available rigid material like previous systems."
The Chimera printer uses red, green and blue low-power commercially available continuous wave lasers with shutters that adjust the exposure for each laser in a matter of milliseconds. The researchers also created a special anti-vibrating mechanical system to keep the holographic plate from moving during the recording.
The hogel size can be toggled between 250 and 500µm and the printing rate adjusted from 1 to 50Hz. For example, if a hogel size of 250 µm is used, the maximum printing speed is 50 Hz. At this speed it would take 11 hours to print a hologram measuring 300 by 400mm, which is about half of the time it would take using conventional hologram printing systems, based on pulsed lasers.
High brightness and clarity
The researchers used the new technology to print holograms that measured up to 600 by 800mm showing various color objects including toys, a butterfly and a museum object.
"The new system also offers a much wider field of view, higher resolution and noticeably better color rendition and dynamic range than previous systems," said Gentet. "The full-color holographic material we developed provides improved brightness and clarity while the low-power, continuous wave lasers make the system easy to use."
The researchers say that as technology improves, especially 3-D software, it may be possible to expand their hologram printing approach to medical or other advanced applications.