Journal of Information Display

The Korean Infomation Display Society (한국정보디스플레이학회)
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Blazed $GxL^{TM}$ Device for Laser Dream Theatre at the Aichi Expo 2005

  • Ito, Yasuyuki (Semiconductor Technology Development Division, Semiconductor Business Group Sony Corporation) ;
  • Saruta, Kunihiko (Semiconductor Technology Development Division, Semiconductor Business Group Sony Corporation) ;
  • Kasai, Hiroto (Semiconductor Technology Development Division, Semiconductor Business Group Sony Corporation) ;
  • Nshida, Masato (Semiconductor Technology Development Division, Semiconductor Business Group Sony Corporation) ;
  • Yamaguchi, Masanari (Semiconductor Technology Development Division, Semiconductor Business Group Sony Corporation) ;
  • Yamashita, Keitaro (Semiconductor Technology Development Division, Semiconductor Business Group Sony Corporation) ;
  • Taguchi, Ayumu (Core Technology Development Group, Sony Corporation) ;
  • Oniki, Kazunao (Core Technology Development Group, Sony Corporation) ;
  • Tamada, Hitoshi (Core Technology Development Group, Sony Corporation)
  • Published : 2007.06.24
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Abstract

A blazed $GxL^{TM}$ device is described as having high optical efficiency (> 70% for RGB lasers), and high contrast ratio (> 10,000:1), and that is highly reliable when used in a large-area laser projection system. It has a robust design and precise stress control technology to maintain a uniform shape (bow and tilt) of more than 6,000 ribbons, a $0.25-{\mu}m$ CMOS compatible fabrication processing and planarization techniques to reduce fluctuation of the ribbons, and a reliable Al-Cu reflective film that provided protection against a high-power laser. No degradation in characteristics of the GxL device is observed after operating a 5,000- lumen projector for 2,000 hours and conducting 2,000 temperature cycling tests at $-20^{\circ}C$ and $+80^{\circ}C$. At the 2005 World Exposition in Aichi, Japan the world's largest laser projection screen with a size of 2005 inches (10 m ${\times}$ 50 m) and 6 million pixels (1,080 ${\times}$ 5,760) was demonstrated.

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References

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