CX-0693
`
`Bibliography(cont.)
`
`
`127
`
`temperature for
`I. Ashdown, “Chromaticity and color
`achitectural lighting,” Proc. SPIE 4776, 51-60 (2002).
`
`L. Audin, D. Houghton, M. Shepard, and W. Hawthorne,
`Lighting Technology Atlas Series, Volume 1, E Source,
`Boulder, CO (1994).
`
`ASTM International, Standard Practice for Describing
`Retroreflection, ASTM E808-01 (2002).
`
`ASTM International, Standard Practice for Computing
`the Colors
`of Fluorescent Objects
`from Bispectral
`Photometric Data, ASTM E2152-01 (2001).
`
`ASTM International, Standard Practice for Obtaining
`Bispectral Photometric Data for Evaluation of Fluorescent
`Color, ASTM E2153-01 (2001).
`
`and_
`angle
`solid
`“Projected
`F. Bartell,
`simulators,” Appl. Opt. 28(6), 1055-1057 (1989).
`
`blackbody
`
`R. Berns, F. Billmeyer, and M. Saltzman, Principles of
`Color Technology, Wiley, New York (2000).
`
`B. R. Boylan, The Lighting Primer, lowa State University
`Press, Ames, IA (1987).
`
`in architecture,” Architectural Design
`J. Brogan “Light
`67(3/4), March-April 1997.
`
`F. Carlson and C. Clark, “Light sources for optical
`devices,” in Applied Optics and Optical Engineering, Vol.
`1, R. Kingslake, Ed., 60-61, Academic Press, New York
`(1965).
`
`W. Cassarly, Design of Efficient Ilumination Systems,
`unpublished notes for SPIE short course (2000).
`
`Commission internationale de l'éclairage (CIE), Method of
`Measuring and Specifying Colour Rendering Properties of
`Light Sources, CIE Publication 13.3-1995.
`
`Commission de_ l'éclairageinternationale (CIE),
`
`
`
`
`Colorimetry, 3rd Ed., CIE Publication 15:2004.
`
`
`
`MASITC_01080521 MASIMO 2054
`Apple v. Masimo
`IPR2022-01299
`
`PAGE 141 OF 154
`
`MASIMO 2054
`Apple v. Masimo
`IPR2022-01299
`
`
`
`Bibliography(cont.)
`
`
`127
`
`temperature for
`I. Ashdown, “Chromaticity and color
`achitectural lighting,” Proc. SPIE 4776, 51-60 (2002).
`
`L. Audin, D. Houghton, M. Shepard, and W. Hawthorne,
`Lighting Technology Atlas Series, Volume 1, E Source,
`Boulder, CO (1994).
`
`ASTM International, Standard Practice for Describing
`Retroreflection, ASTM E808-01 (2002).
`
`ASTM International, Standard Practice for Computing
`the Colors
`of Fluorescent Objects
`from Bispectral
`Photometric Data, ASTM E2152-01 (2001).
`
`ASTM International, Standard Practice for Obtaining
`Bispectral Photometric Data for Evaluation of Fluorescent
`Color, ASTM E2153-01 (2001).
`
`and_
`angle
`solid
`“Projected
`F. Bartell,
`simulators,” Appl. Opt. 28(6), 1055-1057 (1989).
`
`blackbody
`
`R. Berns, F. Billmeyer, and M. Saltzman, Principles of
`Color Technology, Wiley, New York (2000).
`
`B. R. Boylan, The Lighting Primer, lowa State University
`Press, Ames, IA (1987).
`
`in architecture,” Architectural Design
`J. Brogan “Light
`67(3/4), March-April 1997.
`
`F. Carlson and C. Clark, “Light sources for optical
`devices,” in Applied Optics and Optical Engineering, Vol.
`1, R. Kingslake, Ed., 60-61, Academic Press, New York
`(1965).
`
`W. Cassarly, Design of Efficient Ilumination Systems,
`unpublished notes for SPIE short course (2000).
`
`Commission internationale de l'éclairage (CIE), Method of
`Measuring and Specifying Colour Rendering Properties of
`Light Sources, CIE Publication 13.3-1995.
`
`Commission de_ l'éclairageinternationale (CIE),
`
`
`
`
`Colorimetry, 3rd Ed., CIE Publication 15:2004.
`
`
`
`MASITC_01080521 MASIMO 2054
`Apple v. Masimo
`IPR2022-01299
`
`PAGE 141 OF 154
`
`MASIMO 2054
`Apple v. Masimo
`IPR2022-01299
`
`
`
`CX-0693
`
`Bibliography (cont.)
`SSSSSSaaS
`
`128
`
`Commission de_ Il'éclairageinternationale (CIE),
`
`
`
`Recommended File Format
`for Electronic Transfer of
`Luminaire Photometric Data, CIE Publication 102-1993.
`
`(CIE), The
`l'éclairage
`Commission internationale de
`Photometry and Gontophotometry of Luminatres, CIE
`Publication 121-1996.
`
`Commission de_ Il'éclairageinternationale (CIE),
`
`
`
`Measurement
`of LEDs,
`2nd Ed., CIE Publication
`127:2007.
`
`C. De Cusatis, Ed., Handbook of Applied Photometry, AIP
`Press, Woodbury, NY (1997).
`
`C. Dimas, S. Read, and J. Kuta, “Integrating rod
`homogeneity as a function of cross-sectional shape,” Proc.
`SPIE 4768, 82—92 (2002).
`
`M. D. Egan, Concepts in Architectural Lighting, McGraw
`Hill Book Co., New York (1983).
`
`Electro-Optics Handbook, Burle Industries, Lancaster, PA,
`www.burle.com (1974).
`
`Eley Associates, Advanced Lighting Guidelines, 1993
`(Revision 1), Final Report Prepared for California Energy
`Commission (19938).
`
`J. Flynn and S. Mills, Architectural Lighting Graphics,
`Reinhold Publishing Corporation, New York (1962).
`
`J. Flynn, A. Segil, and G. Steffy, Architectural Interior
`Systems, Van Nostrand Reinhold Company,
`Inc., New
`York (1988).
`
`C. Gardner and B. Hannaford, Lighting Design, Design
`Council, London (1993).
`
`G. Gordon, Interior Lighting for Designers, 4 Edition,
`John Wiley & Sons, Inc., Hoboken, NJ (2008).
`
`J. Greivenkamp, Field Guide to Geometrical Optics, SPIE
`Press, Bellingham, WA (2004).
`
`
`
`PAGE 142 OF 154
`
`MASITC_01080522
`
`MASIMO 2054
`
`Apple v. Masimo
`IPR2022-01299
`
`MASIMO 2054
`Apple v. Masimo
`IPR2022-01299
`
`
`
`CX-0693
`
`Bibliography (cont.)
`
`
`129
`
`A. Gupta, J. Lee, and R. J. Koshel, “Design of efficient
`lightpipes for illumination by an analytical approach,”
`Appl. Opt. 40, 3640-3648 (2001).
`
`K. G. Holmes, Essays on Lighting, Crane, Russak &
`Company, Inc., New York (1975).
`
`R. G. Hopkinson, Architectural Physics: Lighting, Her
`Majesty's Stationary Office, London (1963).
`
`R. Hopkinson and J. B. Collins, Ergonomics of Lighting,
`MacDonald Technical & Scientific, London (1970).
`
`R. G. Hopkinson and J. D. Kay, The Lighting of Buildings,
`Faber and Faber, London (1972).
`
`D. Hunten, F. Roach, and J. Chamberlain, “A photometric
`unit for the airglow and aurora,” Journal of Atmospheric
`and Terrestrial Physics (GB) 8, 345-346 (1956).
`
`Illuminating Engineering Society of North America,
`IESNA Handbook, 9 Edition, New York (20038).
`
`Illuminating Engineering Society of North America,
`Goniophotometer Types and Photometric Coordinates, LM-
`75-01, New York (2001).
`
`Illuminating Engineering Society of North America,
`Lighting For Exterior Environments,
`IESNA RP-33-99
`(1999).
`
`Illuminating Engineering Society of North America,
`Recommended Practice of Daylighting,
`IESNA RP-5-99
`(1999).
`
`Illuminating Engineering Society of North America,
`Recommended Practice for Roadway Lighting, IESNA RP-
`8-00 (2000).
`
`Jankowski, The Best of Lighting Design, PBC
`W.
`International, Inc., New York (1987).
`
`Lighting
`Jankowski,
`W.
`International, New York (1988).
`
`the Workplace,
`
`PBC
`
`
`
`PAGE 143 OF 154
`
`MASITC_01080523
`
`MASIMO 2054
`
`Apple v. Masimo
`IPR2022-01299
`
`MASIMO 2054
`Apple v. Masimo
`IPR2022-01299
`
`
`
`Bibliography (cont.)
`SSSSSSaaS
`
`130
`
`CX-0693
`
`D. Jenkins and H. Monch, SID ‘00 Digest, Society for
`Information Display (2000).
`
`Jenkins and R. Winston, “Tailored reflectors
`D.
`illumination,” Appl. Opt. 35(10), 1669-1672 (1996).
`
`for
`
`M. E. Kaminski, K. J. Garcia, M. A. Stevenson, M. Frate,
`and R. J. Koshel, “Advanced topics in source modeling,”
`Proc. SPIE 4775, 46—57 (2002).
`
`N. Karlen and J. Benya, Lighting Design Basics, John
`Wiley & Sons, Inc., Hoboken, NJ (2004).
`
`H. Kaufman and J. Christensen, JES Lighting Handbook,
`1987 Application Volume,
`Illuminating Engineering
`Society of North America, New York (1987).
`
`R. Kingslake, “Illumination in optical images,” in Applied
`Optics and Optical Engineering, Vol. 2, R. Kingslake, Ed.,
`Academic Press, New York (1965).
`
`optimization method
`“Simplex
`J. Koshel,
`R.
`Ulumination design,” Opt. Lett. 30, 649-651 (2005).
`
`for
`
`R. J. Koshel, lecture notes from the Illumination Seminar,
`College of Optical Sciences, University of Arizona (2006).
`
`R. J. Koshel and I. A. Walmsley, “Modeling of the gain
`distribution for diode pumping of a solid-state laser rod
`with nonimaging optics,” Appl. Opt. 32, 1517-1527 (1998).
`
`R. J. Koshel and I. A. Walmsley, “Non-edge ray design:
`improved optical pumping of lasers,” Opt. Eng. 48, 1511-
`1521 (2004).
`
`L. Larson, Lighting and Its Design, Whitney Library of
`Design, New York (1964).
`
`Y. LeGrande, Light, Colour, and Vision, Chapman and
`Hall, London (1968).
`
`J. Lindsey, Applied Illuminating Engineering, Second
`Edition, The Fairmont Press, Inc, Lilburn, GA (1997).
`
`J. A. Lynes, Developments in Lighting-1, Applied Science
`Publishers LTD, London (1978).
`
`
`PAGE 144 OF 154
`
`MASITC_01080524
`
`MASIMO 2054
`
`Apple v. Masimo
`IPR2022-01299
`
`MASIMO 2054
`Apple v. Masimo
`IPR2022-01299
`
`
`
`CX-0693
`
`Bibliography (cont.)
`
`
`131
`
`M. J. J. J. B. Maes and A. J. E. M. Janssen, “A note on
`cylindrical reflector design,” Optik 88(4), 177-181 (1991).
`
`R. McCluney, Introduction to Radiometry and Photometry,
`Artech House, Boston (1994).
`
`M. Millet, Light Revealing Architecture, John Wiley &
`Sons, Inc., Hoboken, NJ (1996).
`
`P. Moon, Scientific Basis of Illuminating Engineering,
`McGraw-Hill Book Company, New York (1936).
`
`on Optical
`Self-Study Manual
`F. Nicodemus, Ed.,
`Radiation Measurements, National Institute of Standards
`and Technology:
`http://physics. nist. gov/Divisions/Div844/manual/studyman
`ual. html
`
`D. Phillips, Lighting tn Architectural Design, McGraw-
`Hill Book Company, New York (1964).
`
`D. Phillips, Lighting Modern Buildings, Architectural
`Press, an imprint of Butterworth-Heinemann, Boston
`(2000).
`
`M. D. W. Pritchard, Lighting, Environmental Physics
`Series, Elsevier Publishing Company, New York (1969).
`
`H. Ries and J. Muschaweck, “Tailored freeform optical
`surfaces,” J. Opt. Soc. Am. 19(8), 590-595 (2002).
`
`“How Many? A Dictionary of Units of
`R. Rowlett,
`Measurement,” The University of North Carolina at
`Chapel Hill http://www.unc.edu/~rowlett/units/index. html
`(2006).
`
`M. Ruda, Introduction to Illumination Design Techniques,
`unpublished notes for SPIE short course (1997).
`
`R. Rykowski and C. B. Wooley, “Source modeling for
`illumination design,” Proc. SPIE 3130, 204—208 (1997).
`
`R. Siegel and J. Howell, Thermal Radiation Heat
`Transfer, 4ed., Taylor and Francis, New York (2002).
`
`
`
`PAGE 145 OF 154
`
`MASITC_01080525
`
`MASIMO 2054
`
`Apple v. Masimo
`IPR2022-01299
`
`MASIMO 2054
`Apple v. Masimo
`IPR2022-01299
`
`
`
`Bibliography (cont.)
`————EESSSeeeEEE
`
`132
`
`CX-0693
`
`D. Sinclair, Phluometry, unpublished notes, Institute of
`Optics, University of Rochester (1970).
`
`F. K. Smith and F. J. Bertolone, Bringing Interiors to
`Light, Whitney Library of Design, New York (1986).
`
`W. Smith, Modern Optical Engineering, SPIE Press,
`Bellingham, WA, and McGraw Hill, New York (2000).
`
`G. Steffy, Architectural Lighting Design, Second Edition,
`John Wiley & Sons, Inc., New York (2002).
`
`G. Steffy, Architectural Lighting Design, Second Edition,
`Van Nostrand Reinhold Company, New York (1990).
`
`G. Steffy, Lighting the Electronic Office, Van Nostrand
`Reinhold, New York (1995).
`
`B. Stein and J. Reynolds, Mechanical and Electrical
`Equipment for Buildings, 10th Edition, Wiley & Sons,
`New York (2005).
`
`M. A. Stevenson, M. Frate, M. E. Kaminski, and R. J.
`Koshel, “Modeling filament-based sources
`for system
`tolerancing,” Proc. SPIE 4775, 67—77 (2002).
`
`W. Welford and R. Winston, High Collection Nonimaging
`Optics, Academic Press, San Diego (1989).
`
`R. Winston, J. C. Minano, and P. Benitez, Nonimaging
`Optics, Elsevier Academic Press, Burlington, MA (2005).
`
`R. Winston, and H. Ries, “Nonimaging reflectors as
`functionals of the desired irradiance,’ J. Opt. Soc. Am.
`10(9), 1902-1908 (1993).
`
`Introduction to Radiometry, SPIE Press,
`W. Wolfe,
`Bellingham, WA (1998).
`
`G. Wyszecki and W. Stiles, Color Science, Wiley, New
`York (1982).
`
`
`
`PAGE 146 OF 154
`
`MASITC_01080526
`
`MASIMO 2054
`
`Apple v. Masimo
`IPR2022-01299
`
`MASIMO 2054
`Apple v. Masimo
`IPR2022-01299
`
`
`
`CX-0693
`
`
`
`133
`
`Abbe illumination, 58
`Abel transform, 74
`ABg method, 29
`absorbance, 27
`absorbingfilter, 61
`absorptance, 27
`accent layer, 96
`accent lighting, 96
`acceptance angle, 51, 75
`apparent brightness, 95
`arc lamp, 74
`area-solid-angle-product, 49
`average projected solid
`angle, 37
`average projected solid
`angle, 36
`average reflectance, 67
`averaged LED intensity, 11
`
`back reflector:, 83
`backlight lightguides, 85
`backlighting, 82, 96, 104
`backlit displays, 82
`backlit LCD, 83
`backsidereflector, 85
`base type:, 73
`beam pattern distributions,
`106
`bendratio, 66
`bent lightpipes, 66
`bidirectional reflectance
`distribution function
`(BRDF), 28, 29
`bikeways, 104
`brightness enhancement
`film, 88
`brightness enhancement
`film (BEF), 82, 86
`building entries, 104
`bulb type, 73
`bumps, 85
`
`candela distribution curve
`(CDC), 97
`catadioptric, 81
`center wavelength, 26
`centroid wavelength, 26
`chromaticity, 12
`CIE 1924 luminous
`efficiency function, 5
`CIE 1931 chromaticity
`coordinates, 12
`CIE 1960 UCS coordinate
`system, 13
`CIE 1976 UCS coordinate
`system, 13
`CIE color matching
`function, 5
`CIE color matching
`functions, 12
`cobra head, 110
`coefficient of retroreflected
`luminance, 32
`coefficient of retroreflected
`luminousintensity, 32
`coefficient of retroreflection,
`a2
`coefficient of utilization
`(CU), 98
`cold mirrors, 61
`cold-cathode fluorescent
`lamps (CCFL), 82, 84
`color, 26
`color rendering index (CRI),
`18, 19
`color temperature, 14
`color-pixel patterns, 86
`compoundelliptical
`concentrator (CEC), 76,
`78
`compound hyperbolic
`concentrator (CHC), 76,
`78
`
`candela, 5
`
`
`PAGE 147 OF 154
`
`MASITC_01080527 MASIMO 2054
`Apple v. Masimo
`IPR2022-01299
`
`MASIMO 2054
`Apple v. Masimo
`IPR2022-01299
`
`
`
`CX-0693
`
`134
`
`
`
`compound parabolic
`concentrator (CPC), 76,
`77
`computer-aided design
`(CAD), 92
`concentration (C), 51
`concentration ratio, 51
`condition A, 11
`condition B, 11
`configuration factor, 37
`conservation of étendue, 50
`controls, 105
`correlated color
`temperature, 13
`correlated color
`temperature (CCT), 14
`cosine-fourth law, 41
`
`damplocation rated, 105
`daylight factor (DF), 99
`daylighting, 100
`delta, 86
`diagonal, 86
`diffusers, 83
`diffusion equation, 85
`digital light processing
`(DLP), 87
`dioptric, 81
`displays, 82
`dominant wavelength, 15,
`26
`donaldson matrix, 17
`downlighting, 104
`downlighting, 96
`dual brightness
`enhancementfilm
`(DBEF), 86
`
`electroluminescent (EL),
`83, 84
`ellipsoidal mirror, 60
`emergency egress doors,
`104
`
`entrance angle, 31
`étendue, 49
`exitance, 1
`eye adaptation, 94
`
`f-number, 48
`facade illumination, 102
`faceted reflectors, 80
`facets, 69
`features, 85
`features, 83
`filament type, 73
`flat-fielding, 88
`floodlighting, 103
`flow-line method, 78
`fluorescence, 17
`fluorescent lamps, 74
`flux, 1, 33, 35, 49
`focal layer, 96
`form factor, 36, 37
`frontlighting, 104
`front-projection displays, 82
`full cutoff, 110
`
`general color rendering
`index, 18
`general illumination
`approach, 96
`generalized étendue, 50
`geometrical model, 71
`glare, 101
`glazing, 96
`goniometer, 71
`goniophotometers, 89, 91
`
`hardscape lighting, 104
`Harvey method, 29
`high-pressure sodium, 111
`holes, 85
`horizontal ambientlayer,
`96
`horizontal field, 94
`hot mirrors, 61
`
`
`
`PAGE 148 OF 154
`
`MASITC_01080528 MASIMO 2054
`Apple v. Masimo
`IPR2022-01299
`
`MASIMO 2054
`Apple v. Masimo
`IPR2022-01299
`
`
`
`CX-0693
`
`135
`
`hybrid optics, 81
`
`uluminance, 6, 7, 108
`image irradiance, 49
`incandescent lamp, 73
`increase factor, 41, 47
`indium-tin oxide (TO), 86
`induction lamps, 111
`injection molding, 85
`injector, 84
`injector, 83
`integrating spheres, 67
`intensity, 1, 3, 38, 89, 91
`interference filters, 61
`inverse square, 3
`inverse square law
`calculations, 108
`involute, 78
`irradiance, 1, 33, 65, 67, 75
`isotropic source, 33
`
`knownintensity, 34
`Kohler illumination, 68
`
`Lambertian disk, 47
`Lambertian radiator, 36
`Lambertian source, 3, 33
`Lambertian surface, 27, 28,
`29
`LED, 72, 84
`lens design codes, 92
`lenslet array, 68, 69
`light center length (LCL),
`73
`lightbox, 84
`lightguide, 83
`lightguides, 53
`light-loss factor (LLF), 111
`lightpipes, 53
`linear polarizers, 86
`liquid crystal, 83
`
`liquid crystal on silicon,
`(LCoS), 87
`locating fixtures, 101
`long lateral distribution,
`107
`lumen, 5
`luminaire’s transverse
`reach, 106
`luminaires, 76
`luminance, 6, 7, 108
`luminances from a direct
`luminaire, 98
`luminousefficacy, 9
`luminousflux, 5, 6
`luminousintensity, 6
`
`maximum overall length
`(MOL), 73
`medium beam, 103
`medium fixtures, 107
`mesopic region, 8
`mesopic vision, 101
`metal halide, 111
`metal halide lamps, 111
`mixed bundle, 55
`mixing rod, 65
`
`narrow beam, 103
`nighttimevisibility, 101
`nonedge-ray design, 81
`nonimaging compound
`concentrators, 75, 76
`nonimaging Fresnel lens
`design, 81
`nonsequential ray tracing,
`92
`numerical aperture (NA),
`43, 48
`
`observation angle, 31
`OLED displays, 82
`optical density (OD), 27
`optical fibers, 53
`
`
`
`PAGE 149 OF 154
`
`MASITC_01080529 MASIMO 2054
`Apple v. Masimo
`IPR2022-01299
`
`MASIMO 2054
`Apple v. Masimo
`IPR2022-01299
`
`
`
`CX-0693
`
`136
`
`optics analysis codes, 92
`optimal concentration, 51
`organic LED (OLED), 82
`ornamentallayer, 96
`
`packing fraction (pf), 55
`paraboloidal mirror, 60
`peak wavelength, 26
`perfectly reflecting diffuser
`(PRD), 28
`photometric brightness, 95
`photometric report, 97
`photometry, 5
`photopic efficiency, 8
`photopic region, 8
`photopic vision, 101
`Planckian locus, 12
`plane angle, 2
`polarizers:, 83
`principal sections, 66
`projected area, 3
`projected solid angle, 3, 4,
`at, 43, 48
`projection, 82
`projection displays, 82, 87
`purity, 15
`
`radian, 2
`radiance, 1, 3, 33, 65, 67
`radiance model, 71
`ramps, 104
`rated current, 21
`rear-projection displays, 82
`rectilinear shoebox, 110
`reduction of light levels,
`101
`reference illuminant, 18
`reflectance, 27, 28
`reflectance coefficient, 108
`reflectance factor, 16, 28, 30
`retroreflectance factor, 32
`retroreflectors, 31
`
`scotopic efficiency, 8
`scotopic region, 8
`scotopic vision, 101
`searchlight, 63
`semicutoffs, 110
`setback, 103
`shape conversion, 55
`shielding the light source,
`101
`short fixtures, 107
`sidelighting, 104
`sidewalks, 104
`simultaneous multiple
`surfaces method (SMS),
`81
`skew invariant, 52
`small target visibility
`(STV), 108, 109
`softscape lighting, 104
`solid angle, 2, 3, 4, 35, 48,
`49, 54, 75
`solid-based geometry, 92
`source, 83
`source brightness, 101
`source model, 70
`source modeling methods,
`al
`spacing, 103
`spacingcriteria (SC), 98
`spatial light modulator
`(SLM), 87
`spatial light modulators
`(SLMs), 82
`spectral filter mask, 86
`spectral flux, 5
`spectral intensity, 5
`spectral irradiance, 5
`spectral radiance, 5
`spherical mirror, 57
`splitting the bundle, 55
`stairs, 104
`steradian, 2
`
`
`
`PAGE 150 OF 154
`
`MASITC_01080530 MASIMO 2054
`Apple v. Masimo
`IPR2022-01299
`
`MASIMO 2054
`Apple v. Masimo
`IPR2022-01299
`
`
`
`CX-0693
`
`
`
`137
`
`veiling luminanceratio
`(VLR), 108
`vertical ambient layer, 96
`vertical field, 94
`viewing angle, 26, 31
`vignetting, 47
`visibility level (VL), 109
`visual comfort probability
`(VCP), 97
`visual fields, 94
`
`walkways, 104
`wall washing, 96
`wet location rated, 105
`wide beam, 103
`working f-number, 48
`
`stippled illumination
`pattern, 80
`stripes, 86
`structure, 85
`surface-based geometry, 92
`system model, 71
`
`T-number, 48
`tailored-edge-ray, 80
`tailored-edge-ray reflectors,
`79
`task layer, 96
`test-color samples, 18
`throughput, 49
`total integrated scatter
`(TIS or TS), 29
`total irradiance, 5
`total radiance, 5
`total radiant flux, 5
`total radiant intensity, 5
`transient adaptation, 94
`transmittance, 27, 45
`triangular, 86
`tristimulus values, 12
`twisted-nematic LC
`module, 86
`type A spherical
`coordinates, 90
`type B spherical
`coordinates, 90
`type C spherical
`coordinates, 90
`type I, 106
`type IT, 106
`type III, 106
`type IV, 106
`
`uniform circular
`Lambertian disk, 40
`uniform light distribution,
`101
`uplighting, 104
`
`
`
`PAGE 151 OF 154
`
`MASITC_01080531 MASIMO 2054
`Apple v. Masimo
`IPR2022-01299
`
`MASIMO 2054
`Apple v. Masimo
`IPR2022-01299
`
`
`
`CX-0693
`
`
`
`is the Director of
`Angelo Arecchi
`Systems Engineering at Sphere-
`Optics, LLC. He also manages his
`own
`consulting
`firm,
`Sunrise
`Instruments, LLC. He was the Vice
`President
`of
`Engineering
`at
`Labsphere,
`Inc.
`for 14 years.
`In
`addition to his work in the optics industry, Angelo
`spent more than 20 years in the U.S. Coast Guard
`where, among other assignments, he workedin visual
`signaling,
`electronic communications and_aids-to-
`navigation. He was also on the faculty of the U.S.
`Coast Guard Academy for several years. Angelo holds
`an M.S. degree in Optics from the University of
`Rochester,
`an M.B.A.
`from Plymouth
`State
`University, and is a registered Professional Engineer.
`He is an adjunct faculty member at Plymouth State
`University and at Norwich University. Angelo is a
`member of SPIE, OSA, and the Council on Optical
`Radiation Measurements (CORM), where he serves on
`its Board of Directors.
`
`
`
`the
`is professor at
`Tahar Messadi
`the
`School
`of Architecture
`at
`University of Arkansas. He teaches
`environmental building systems and
`lighting courses,
`and manages
`a
`design studio focused on environ-
`mentally responsive architecture. His
`research interests include the lighting and thermal
`performance of buildings. Dr. Messadi has codirected
`the smart facade research program at the Georgia
`Institute of Technology. Other sponsored research
`includes the development of a toolkit
`to monitor
`lighting,
`IAQ, and comfort
`in high performance
`schools. He is also the recipient of a number of funds
`to support investigations conducted by students in
`environmental
`technology,
`specifically,
`lighting,
`thermal, and acoustics. Prof. Messadi has authored
`and coauthored numerous publications in national
`and international conferences and journals.
`
`PAGE 152 OF 154
`
`MASITC_01080532
`
`MASIMO 2054
`
`Apple v. Masimo
`IPR2022-01299
`
`MASIMO 2054
`Apple v. Masimo
`IPR2022-01299
`
`
`
`CX-0693
`
`
`
`R. John Koshelis the Senior Staff
`
`Engineer at Lambda_Research
`Corporation and Adjunct Assistant
`Professor at the College of Optical
`Sciences, University of Arizona. At
`Lambda he works on the TracePro
`nonsequential
`optical
`analysis
`code, especially in the field of illumination. At Arizona
`he
`has
`taught
`courses
`on Radiometry
`and
`Illumination Engineering, and he has worked on
`illumination research projects. His primary research
`areas are nonimaging optics,
`solid-state lighting,
`
`optimization and tolerancing, and_lit-appearance
`modeling. He is active in SPIE and OSA. He waschair
`of the International Optical Design Conference in
`2006 and serves as a chair or member for a numberof
`SPIE conferences. He obtained his B.S. and Ph.D.
`degrees from The Institute of Optics, University of
`Rochester.
`
`PAGE 153 OF 154
`
`MASITC_01080533
`
`MASIMO 2054
`
`Apple v. Masimo
`IPR2022-01299
`
`MASIMO 2054
`Apple v. Masimo
`IPR2022-01299
`
`
`
`CX-0693
`
`SPIE Field Guides
`
`John E. Greivenkamp
`Series Editor
`
`The aim of each SPIE Field Guide is to distill
`a major field of optical science or technology
`into a handy desk or briefcase reference that
`provides basic, essential information about
`optical principles, techniques, or phenomena.
`
`www.spie.org/press/fieldguides
`
`ISB
`
`N 978-0-8194-6768-
`
`3
`
`Ih
`| |
`"780819"467683 IK
`
`Written for you—thepracticing engineer or
`scientist—eachfield guide includes the key
`definitions, equations,illustrations, application
`examples, design considerations, methods, and
`tips that you needin the lab andin thefield.
`
`SPIE Vol. No.: FG11
`
`9
`
`GE sPic
`
`P.O. Box 10
`Bellingham, WA 98227-0010
`
`ISBN-13: 9780819467683
`
`MASITC_01080534 MASIMO 2054
`Apple v. Masimo
`IPR2022-01299
`
`PAGE 154 OF 154
`
`MASIMO 2054
`Apple v. Masimo
`IPR2022-01299
`
`
Accessing this document will incur an additional charge of $.
After purchase, you can access this document again without charge.
Accept $ Charge
Still Working On It
This document is taking longer than usual to download. This can happen if we need to contact the court directly to obtain the document and their servers are running slowly.
Give it another minute or two to complete, and then try the refresh button.
A few More Minutes ... Still Working
It can take up to 5 minutes for us to download a document if the court servers are running slowly.
Thank you for your continued patience.
This document could not be displayed.
We could not find this document within its docket. Please go back to the docket page and check the link. If that does not work, go back to the docket and refresh it to pull the newest information.
Your account does not support viewing this document.
You need a Paid Account to view this document. Click here to change your account type.
Your account does not support viewing this document.
Set your membership
status to view this document.
With a Docket Alarm membership, you'll
get a whole lot more, including:
- Up-to-date information for this case.
- Email alerts whenever there is an update.
- Full text search for other cases.
- Get email alerts whenever a new case matches your search.
One Moment Please
The filing “” is large (MB) and is being downloaded.
Please refresh this page in a few minutes to see if the filing has been downloaded. The filing will also be emailed to you when the download completes.
Your document is on its way!
If you do not receive the document in five minutes, contact support at support@docketalarm.com.
Sealed Document
We are unable to display this document, it may be under a court ordered seal.
If you have proper credentials to access the file, you may proceed directly to the court's system using your government issued username and password.
Access Government Site
