One of the major power consuming components in a computer is its display unit. On average the screen consumes ten times more power than the DSP processor itself. Thus, reducing the power consumption should be one of the most important tasks in the development of low power consumption computing systems. In this paper we present one possible solution involving micro projection device based upon lasers and a digital light processing (DLP) matrix which is a matrix of electrically controllable mirrors capable of translating electrical signal to a time varying projected image. It can serve to substitute a screen and consume ten times less power than a conventional screen. The described device is a multifunctional highly efficient customized DLP light engine being capable of serving as an image projector and simultaneously to support range and topography estimation measurements.
Ha, Y.; Rolland, J. Optical assessment of head mounted displays in visual space. Appl. Opt. 2002, 41, 5282–5289, doi:10.1364/AO.41.005282.
[5]
Howlett, E.M. High resolution inserts in wide angle head mounted stereoscopic displays. SPIEProc. 1992, 1669, 193–203.
[6]
Hua, H.; Ha, Y.; Rolland, J.P. Design of an ultra light and compact projection lens. Appl. Opt. 2003, 42, 97–107, doi:10.1364/AO.42.000097.
[7]
Kelly, T.H.; Mucci, M.G.; Rector, B.; Sears, T. Initial performance data of portable scene projector. SPIE Proc. 2001, 4366, 140–146.
[8]
Slobodin, D.E.; Biber, C. Ultra portable projector progress and prospects. SPIE Proc. 2000, 3954, 19–26.
[9]
Urey, H. Diffractive exit pupil expander for display applications. Appl. Opt. 2001, 40, 5840–5851, doi:10.1364/AO.40.005840.
[10]
Karpman, M.S.; Wells, B.A. Virtual displays for entertainment applications: Hitting cost/performance with LED arrays. SPIE Proc. 1997, 3000, 161–198.
[11]
Zalevsky, Z.; Kapellner, Y.; Sabo, E.; Kapellner, S. Virtual display with low power consuming portable micro projector. SPIE Proc. 2003, 5002, 154–163.
[12]
Kapellner, Y.; Kapellner, S.; Pomerantz, I.; Zalevsky, Z.; Sabo, E. Image Projecting Device and Method. U.S. Patent 7128420, 31 October 2006.
[13]
Sharon, I.; Zalevsky, Z.; Manor, G.; Kapellner, Y. Image Projecting Device and Method. U.S. Patent 7746559, 29 June 2010.
[14]
Raskar, R.; Brown, M.S.; Ruigang, Y.; Wei-Chao, C.; Welch, G.; Towles, H.; Scales, B.; Fuchs, H. Multi-Projector Displays Using Camera-Based Registration. In Proceedings of the Visualization ’99, San Francisco, CA, USA, 29 October 1999; pp. 161–168.
[15]
Cotting, D.; Naef, M.; Gross, M.; Fuchs, H. Embedding Imperceptible Patterns into Projected Images for Simultaneous Acquisition and Display. In Proceedings of the 3rd IEEE and ACM International Symposium on Mixed and Augmented Reality (ISMAR 2004), Arlington, VA, USA, 2-5 November 2004; pp. 100–109.
[16]
Kley, E.B.; Cumme, M.; Wittiq, L.C.; Thieme, M. Beam shaping elements for holographic applications. SPIE Proc. 2000, 4179, 58–64.
[17]
Zhang, S.; Ren, Y.; Lupke, G. Beam shaping of ultra short laser pulses using diffractive optics: A theoretical study. SPIE Proc. 2002, 4770, 89–95.
[18]
Zalevsky, Z.; Mendlovic, D.; Dorsch, R.G. Gerchberg-Saxton algorithm applied in the fractional Fourier or the Fresnel domains. Opt. Lett. 1996, 21, 842–844, doi:10.1364/OL.21.000842. 19876177
[19]
Reidler, I.; Aviad, Y.; Rosenbluh, M.; Kanter, I. Ultra high speed random number generation based on a chaotic semiconductor laser. Phys. Rev. Let. 2009, 103, doi:10.1103/PhysRevLett. 103.024102.
[20]
Texas Instruments. DLP & MEMS. DLP design kits (including Pico). Available online: http://focus.ti.com/analog/docs/memsmidlevel.tsp?sectionId=622&tabId=2447 (accessed on 2 March 2012).
[21]
Texas Instruments. DLP Technology. Available online: http://focus.ti.com/analog/docs/memsmidlevel.tsp?sectionId=622&tabId=2442 (accessed on 2 March 2012).
[22]
Texas Instruments. Introduction to Digital Micro Mirror Device. Available online: http://focus.ti.com/lit/an/dlpa008/dlpa008.pdf (accessed on 2 March 2012).
[23]
Texas Instruments. Using DLP? Development Kits for 3D Optical Metrology Systems. Available online: http://focus.ti.com/lit/an/dlpa026/dlpa026.pdf (accessed on 2 March 2012).
[24]
Texas Instruments. Using PICO kit for structured light applications. Available online: http://www.ti.com/lit/an/dlpa021a/dlpa021a.pdf (accessed on 2 March 2012).
[25]
Texas Instruments. DLP? 0.17 HVGA DDR Series 210 DMD. Available online: http://www.ti.com/lit/ds/dlps018b/dlps018b.pdf (accessed on 2 March 2012).
[26]
Besl, P. Active optical range imaging sensors. Mach. Vis. Appl. 1998, 1, 127–152, doi:10.1007/BF01212277.
[27]
Horn, E.; Kiryati, N. Toward Optimal Structured Light Patterns. In Proceedings of the International Conference on Recent Advances in 3-D Digital Imaging and Modeling, Ottawa, Canada, 12-15 May 1997; pp. 28–37.
[28]
Sazbon, D.; Zalevsky, Z.; Rivlin, E. Qualitative real-time range extraction for preplanned scene partitioning using laser beam coding. Pat. Rec. Lett. 2005, 26, 1772–1781, doi:10.1016/j.patrec.2005.02.008.
[29]
Duadi, H.; Gordon, E.; Bittan, G.A.; Loven, A.; Zalevsky, Z. Correlation based interpolation technique for accurate 3-D estimation via projection of axially varied patterns. 3D Res. 2011, 2, 1–6.
