[1] WHITE L. The impact of historic lighting ［J］. Interior Finishes & Fittings for Historic Building Conservation, 2011, 143-162.

[2] WHEELER R M. A historical background of plant lighting: an introduction to the workshop ［J］. HortScience, 2008, 43(7):1942-1943.

[3] FURST J. Energy independence and security act of 2007 lighting mandate analysis ［D］. Worcester Polyte Chnic Institute, 2012.

[4] KARATSOREOS I N, BHAGAT S, BLOSS E B, et al. Disruption of circadian clocks has ramifications for metabolism, brain, and behavior ［J］. Proceedings of the National Academy of Sciences, 2011, 108(4):1657-1662.

[5] DAVIS S, MIRICK D K. Circadian disruption, shift work and the risk of cancer:a summary of the evidence and studies in Seattle ［J］. Cancer Causes & Control, 2006, 17(4):539-545.

[6] FONKEN L K, FINY M S, WALTON J C, et al. Influence of light at night on murine anxiety-and depressive-like responses ［J］. Behavioural Brain Research, 2009, 205(2):349-354.

[7] PARK S Y, WALKER J J, JOHNSON N W, et al. Constant light disrupts the circadian rhythm of steroidogenic proteins in the rat adrenal gland ［J］. Molecular and Cellular Endocrinology, 2012.

[8] ROYBAL K, THEOBOLD D, GRAHAM A, et al. Mania-like behavior induced by disruption of CLOCK ［J］. Proceedings of the National Academy of Sciences, 2007, 104(15):6406-6411.

[9] STEVENS R G, BRAINARD G C, DAVID E BLASK,et al. Breast cancer and circadian disruption from electric lighting in the modern world ［J］. CA:A Cancer Journal For Clinicians, 2014, 64(3):207-218.

[10] STEVENS R G, ZHU Y. Electric light, particularly at night, disrupts human circadian rhythmicity:is that a problem ［J］. Philosophical Transactions of the Royal Society of London B:Biological Sciences, 2015, 370(1667):20140120.

[11] DAUCHY R T, XIANG S, MAO L, et al. Circadian and melatonin disruption by exposure to light at night drives intrinsic resistance to tamoxifen therapy in breast cancer ［J］. Cancer Research, 2014, 74(15):4099-4110.

[12] GANGWISCH J E. Invited commentary:nighttime light exposure as a risk factor for obesity through disruption of circadian and circannual rhythms ［J］. American Journal of Epidemiology, 2014, 180(3):251-253.

[13] BELLIA L, PEDACE A, BARBATO G. Indoor artificial lighting:prediction of the circadian effects of different spectral power distributions ［J］. Lighting Research and Technology, 2014, 46(6):650-660.

[14] PARK B C, CHANG J H, KIM Y S, et al. A study on the subjective response for corrected colour temperature conditions in a specific space ［J］. Indoor and Built Environment, 2010, 19(6):623-637.

[15] SABER M, DARUS Z M. Impact of occupant density and day-lighting on the student academic achievement in primary school ［J］. European Journal of Social Sciences, 2012, 36(2):189-194.

[16] STROEBELE N, DE CASTRO J M. Effect of ambience on food intake and food choice ［J］. Nutrition (Burbank, Los Angeles County, Calif.), 2004, 20(9):821.

[17] CHO S. Blue lighting decreases the amount of food consumed in men, but not in women ［J］. Appetite, 2015, 85:111-117.

[18] HASENBECK A, CHO S, MEULLENET J F, et al. Color and illuminance level of lighting can modulate willingness to eat bell peppers ［J］. Journal of the Science of Food and Agriculture, 2014, 94(10):2049-2056.

[19] HUBALEK S, BRINK M, SCHIERZ C. Office workers’ daily exposure to light and its influence on sleep quality and mood ［J］. Lighting Research and Technology, 2010, 42(1):33-50.

[20] CHANG P C, CHOU S Y, SHEH K K. Reading performance and visual fatigue when using electronic paper displays in long-duration reading tasks under various lighting conditions ［J］. Displays, 2013.

[21] SHI X, LI H, MI W, et al. Visual fatigue diversity research of static and dynamic lighting environment ［C］. Industrial Engineering and Engineering Management (IE&EM), 2011 IEEE 18Th International Conference on. IEEE, 2011:291-294.

[22] SABER M, DARUS Z M. Impact of occupant density and day-lighting on the student academic achievement in primary school ［J］. European Journal of Social Sciences, 2012, 36(2):189-194.

[23] VANDEWALLE G, BALTEAU E, PHILLIPS C, et al. Daytime light exposure dynamically enhances brain responses ［J］. Current Biology, 2006, 16(16):1616-1621.

[24] BULLOUGH J D, SKINNER N P. Effect of dynamic lighting conditions on visual detection ［R］. SAE Technical Paper, 2009.

[25] VALLENDUUK V. The effect of variable lighting on mood and performance in an office environment ［J］. Graduation Report, Eindhoven University of Technology, 1999.

[26] VAN BOMMEL W. Dynamic Lighting at work-Both in level and colour ［C］. 2nd CIE Expert Symposium on “Lighting and Heath”. Ottawa. 2006.

[27] MOTT M S, ROBINSON D H, WALDEN A, et al. Illuminating the effects of dynamic lighting on student learning ［J］. Sage Open, 2012:2158244012445585.

[28] IZSL. Appropriate dynamic lighting as a possible basis for a smart ambient lighting ［M］. Universal Access in Human-Computer Interaction. Intelligent and Ubiquitous Interaction Environments. Springer Berlin Heidelberg, 2009:67-74.

[29] SPREEUWENBERG M D, et al. Dynamic lighting as a tool to influence the day-night rhythm of clients with psychogeriatric disorders:A pilot study in a Dutch nursing home ［J］. Gerontechnology, 2010, 9(2):250.

[30] IZSL, MAJOROS A. Dynamic lighting as a tool for finding better compromise between human performance and strain ［J］. Applied Psychology in Hungary, 2001, 3:83-95.

[31] MAJOROS A. Effects of dynamic lighting ［J］. LUX Europa, Reykjavik, Iceland, 2001, 74.

[32] IZSL. Developing evaluation methodologies for human-computer interaction ［M］. Delft University Press Satellite, 2001.

[33] DE KORT Y A W, SMOLDERS K. Effects of dynamic lighting on office workers:First results of a field study with monthly alternating settings ［J］. Lighting Research and Technology, 2010, 42(3):345-360.

[34] SLEEGERS P J C, MOOLENAAR N M, GALETZKA M, et al. Lighting affects students’ concentration positively:Findings from three Dutch studies ［J］. Lighting Research and Technology, 2013, 45(2):159-175.

[35] IZSL, LAUFER L, SUPLICZ S. Effects of dynamic lighting on the visual performance of older adults ［J］. Lighting Research and Technology, 2009, 41(4):361-370.

[36] IZSL. Appropriate dynamic lighting as a possible basis for a smart ambient lighting ［M］. Universal Access in Human-Computer Interaction. Intelligent and Ubiquitous Interaction Environments. Springer Berlin Heidelberg, 2009:67-74.

[37] CHARMAN W N. Age, lens transmittance, and the possible effects of light on melatonin suppression ［J］. Ophthalmic and Physiological Optics, 2003, 23(2):181-187.

[38] IZSL. Appropriate dynamic lighting as a possible basis for a smart ambient lighting ［M］. Universal Access in Human-Computer Interaction. Intelligent and Ubiquitous Interaction Environments. Springer Berlin Heidelberg, 2009:67-74.

[39] KOIKE M, SHIBATA N, KATO H, et al. Development of high efficiency GaN-based multiquantum-well light-emitting diodes and their applications ［J］. Selected Topics in Quantum Electronics, IEEE Journal of, 2002, 8(2):271-277.

[40] VURGAFTMAN I, MEYER J R. Band parameters for nitrogen-containing semiconductors ［J］. Journal of Applied Physics, 2003, 94(6):3675-3696.

[41] WU J, WALUKIEWICZ W, YU K M, et al. Unusual properties of the fundamental band gap of InN ［J］. Applied Physics Letters, 2002, 80:3967.

[42] GORCZYCA I, SUSKI T, CHRISTENSEN N E, et al. Limitations to band gap tuning in nitride semiconductor alloys ［J］. Applied Physics Letters, 2010, 96(10):101907-101907-3.

[43] MUELLER G G, DUCHARME A D, DOWLING K J, et al. Methods and apparatus for generating and modulating white light illumination conditions:U.S. Patent (2009-8-11), 7, 572, 028 ［P］.

[44] DUCHARME A D, MORGAN F M, LYS I A, et al. Methods and apparatus for generating white light:U.S. Patent Application (2007-7-20), 11/780, 602 ［P］.

[45] DUCHARME A D, MORGAN F M, LYS I A, et al. Methods and apparatus for generating prescribed spectrums of light:U.S. Patent (2008-6-17), 7, 387, 405 ［P］.

[46] MUELLER G G, DOWLING K J, MORGAN F M, et al. LED package methods and systems:U.S. Patent (2010-1-12), 7, 646, 029［P］.

[47] FOLTA K M, KOSS L L, MCMORROW R, et al. Design and fabrication of adjustable red-green-blue LED light arrays for plant research ［J］. BMC Plant Biology, 2005, 5(1):17.

[48] GAINES J M. Modelling of multichip LED packages for illumination ［J］. Lighting Research and Technology, 2006, 38(2):153-165.

[49] CHANG C. Color temperature correction for phosphor converted leds:European Patent EP (2008-4-9), 1579733 ［P］.

[50] HSIEH W, WANG C. Color temperature controller and color temperature control method of light emitting diode:European Patent EP (2010-3-3), 2160075 ［P］.

[51] KIM Y S. Light emitting package controlling color temperature, fabricating method thereof, color temperature controlling method of light emitting package:U.S. Patent (2012-7-3), 8, 212, 278 ［P］.

[52] OKUMURA, YUKIYASU. “Color temperature-regulable LED light.” European Patent No. EP (29 Sep. 2004), 1462711.

[53] LI Y Q, DONG Y, XU X. Color temperature tunable white light source:U.S. Patent Application (2011-5-6) 13/102, 448 ［P］.

[54] WAND K, LIU S, CHEN F, et al. Novel application-specific LED packaging with compact freeform lens［C］.Electronic Components and Technology Conference, 2009. ECTC 2009. 59th. IEEE, 2009:2125-2130.

[55] WANG K, CHEN F, LIU Z, et al. Design of compact freeform lens for application specific light-emitting diode packaging ［J］. Optics Express, 2010, 18(2):413-425.

[56] CHEN F, WANG K, QIN Z, et al. Design method of high-efficient LED headlamp lens ［J］. Optics Express, 2010, 18(20):20926-20938.

[57] HU R, LUO X, ZHENG H, et al. Design of a novel freeform lens for LED uniform illumination and conformal phosphor coating ［J］. Opt Express, 2012, 20(13):13727-13737.

[58] CHEN F, WANG K, LIU Z, et al. Freeform lens for application-specific LED packaging ［C］. Electronic Packaging Technology & High Density Packaging, 2009. ICEPT-HDP’09. International Conference on. IEEE, 2009:443-447.

[59] WANG K, LIU S, CHEN F, et al. Freeform LED lens for rectangularly prescribed illumination ［J］. Journal of Optics A:Pure and Applied Optics, 2009, 11(10):105501.

[60] WANG S, WANG K, CHEN F, et al. Design of primary optics for LED chip array in road lighting application ［J］. Optics express, 2011, 19(104):A716-A724.

[61] http://www.gizmag.com/glo-pillow-concept/9348/

[62] http://www.yankodesign.com/2011/09/20/an-easy-alarm/

[63] OPLNDER C, VOLKMAR C M, PAUNEL-GRGL A, et al. Whole body UVA irradiation lowers systemic blood pressure by release of nitric oxide from intracutaneousphotolabile nitric oxide derivates ［J］. Circulation Research, 2009, 105(10):1031-1040.

[64] JUZENIENE A, MOAN J. Beneficial effects of UV radiation other than via vitamin D production ［J］. Dermato-endocrinology, 2012, 4(2):109-117.

[65] FEELISCH M, Is sunlight good for our heart ［J］. European Heart Journal, 2010, 31(9):1041-1045.

[66] BIKLE D D. Protective actions of vitamin D in UVB induced skin cancer ［J］. Photochemical &Photobiological Sciences, 2012, 11(12):1808-1816.

[67] GRANT W B. Weighing the evidence linking UVB irradiance, vitamin D, and cancer risk ［C］. Mayo Clinic Proceedings. Mayo Foundation, 2011, 86(4):362.

[68] HOLICK M F, MACLAUGHLIN J A, CLARK M B, et al. Photosynthesis of previtamin D3 in human skin and the physiologic consequences ［J］. Science, 1980, 210(4466):203-205.

[69] SLEEGERS P J C, MOOLENAAR N M, GALETZKA M, et al. Lighting affects students’ concentration positively:findings from three dutch studies ［J］. Lighting Research and Technology, 2013, 45(2):159-175.

[70] http://www.clock3.com/index.php option=com_k2&view=item&id=234:the-glo-pillow-alarm-clock& Itemid=193

[71] NARAYANAN D L, SALADI R N, FOX J L. Review:ultraviolet radiation and skin cancer ［J］. International Journal of Dermatology, 2010, 49(9):978-986.

[72] SOEHNGE H, OUHTITI A, ANANTHASWAMY O N. Mechanisms of induction of skin cancer by UV radiation ［J］. Front Biosci, 1997, 2:D538-D551.

[73] OKUNO T. Thermal effect of infra-red radiation on the eye:a study based on a model ［J］. Annals of Occupational Hygiene, 1991, 35(1):1-12.

[74] SLINEY D, ARON-ROSA D, DELORI F, et al. Adjustment of guidelines for exposure of the eye to optical radiation from ocular instruments:statement from a task group of the International Commission on Non-Ionizing Radiation Protection (ICNIRP) ［J］. Applied optics, 2005, 44(11):2162-2176.

[75] IEC 62471.2006.

[76] HARRAR S, LIAO H W, TAKAO M, et al. Melanopsin-containing retinal ganglion cells:architecture, projections, and intrinsic photosensitivity ［J］. Science, 2002, 295(5557):1065-1070.

[77] GOOLEY J J, LU J, CHOU T C, et al. Melanopsin in cells of origin of the retinohypothalamic tract［J］. Nature Neuroscience, 2001, 4(12):1165-1165.

[78] HANNIBAL J, HINDERSSON P, KNUDSEN S M, et al. The photopigment melanopsin is exclusively present in pituitary adenylate cyclase-activating polypeptide-containing retinal ganglion cells of the retinohypothalamic tract［J］. Neurosci, 2002:22, RC191.

[79] MELYAN Z, TARTTELIN E E, BELLINGHAM J, et al. Addition of human melanopsin renders mammalian cells photoresponsive ［J］. Nature, 2005, 433(7027):741-745.

[80] LEWIS S. Circadian rhythms:Light hits mood head-on ［J］. Nature Reviews Neuroscience, 2012, 14(1):2-3.

[81] CHEN S K, BADEA T C, HATTAR S. Photoentrainment and pupillary light reflex are mediated by distinct populations of ipRGCs ［J］. Nature, 2011, 476(7358):92-95.

[82] KNOOP M. Dynamic lighting for well-being in work places:Addressing the visual, emotional and biological aspects of lighting design ［C］. Proc. of the 15th Symposium Lighting Engineering. 2006:63-74.

[83] WURTMAN R J, AXELROD J, FISCHER J E. Melatonin synthesis in the pineal gland:effect of light mediated by the sympathetic nervous system ［J］. Science, 1964, 143(3612):1328-1329.

[84] OLCESE J, BEESLEY S. Clinical significance of melatonin receptors in the human myometrium ［J］. Fertility and Sterility, 2014, 102(2):329-335.

[85] ACKERMANN K, STEHLE J H. Melatonin synthesis in the human pineal gland:advantages, implications, and difficulties ［J］. Chronobiology International, 2006, 23(1-2):369-379.

[86] BUIJS R M, WORTEL J, VAN HEERIKHUIZE J J, et al. Anatomical and functional demonstration of a multisynaptic suprachiasmatic nucleus adrenal (cortex) pathway ［J］. European Journal of Neuroscience, 1999, 11(5):1535-1544.

[87] LUO X, LI X, HU Z, et al. Evaluation of CYP3A activity in humans using three different parameters based on endogenous cortisol metabolism ［J］. Acta Pharmacologica Sinica, 2009, 30(9):1323-1329.

[88] DHILLON K S, SINGH J, LYALL J S. A new horizon into the pathobiology, etiology and treatment of migraine ［J］. Medical Hypotheses, 2011, 77(1):147-151.

[89] DIJK D J, DUFFY J F, SILVA E J, et al. Amplitude reduction and phase shifts of melatonin, cortisol and other circadian rhythms after a gradual advance of sleep and light exposure in humans ［J］. PloS One, 2012, 7(2):e30037.

[90] BOIVIN D B, CZEISLER C A, DIJK D J, et al. Complex interaction of the sleep-wake cycle and circadian phase modulates mood in healthy subjects ［J］. Archives of General Psychiatry, 1997, 54(2):145.

[91] BOIVIN D B. Influence of sleep-wake and circadian rhythm disturbances in psychiatric disorders ［J］. Journal of Psychiatry and Neuroscience, 2000, 25(5):446.

[92] ROSENTHAL N E, SACK D A, GILLIN J C, et al. Seasonal affective disorder:a description of the syndrome and preliminary findings with light therapy ［J］. Archives of General Psychiatry, 1984, 41(1):72.

[93] STEPHENSON K M, SCHRODER C M, BERTSCHY G, et al. Complex interaction of circadian and non-circadian effects of light on mood:Shedding new light on an old story ［J］. Sleep Medicine Reviews, 2012.

[94] TERMAN J S, TERMAN M, LO E S, et al. Circadian time of morning light administration and therapeutic response in winter depression ［J］. Archives of General Psychiatry, 2001, 58(1):69.

[95] OREN D A, BRAINARD G C, JOHNSTON S H, et al. Treatment of seasonal affective disorder with green light and red light ［J］. Am J Psychiatry, 1991, 148(4):509-511.

[96] ANDERSON J L, GLOD C A, DAI J, et al. Lux vs. wavelength in light treatment of seasonal affective disorder ［J］. Acta Psychiatrica Scandinavica, 2009, 120(3):203-212.

[97] GLICKMAN G, BYRNE B, PINEDA C, et al. Light therapy for seasonal affective disorder with blue narrow-band light-emitting diodes (LEDs) ［J］. Jefferson Myrna Brind Center of Integration Medicine Faculty Papers, 2006:3.

[98] GORDIJN M C M, T MANNETJE D, MEESTERS Y. The effects of blue-enriched light treatment compared to standard light treatment in seasonal affective disorder ［J］. Journal of Affective Disorders, 2012, 136(1):72-80.

[99] STEWART K T, GADDY J R, BYRNE B, et al. Effects of green or white light for treatment of seasonal depression ［J］. Psychiatry Research, 1991, 38(3):261-270.

[100] BRAINARD G C, SHERRY D, SKWERER R G, et al. Effects of different wavelengths in seasonal affective disorder ［J］. Journal of Affective Disorders, 1990, 20(4):209-216.

[101] PLITNICK B, FIGUEIRO M G, WOOD B, et al. The effects of red and blue light on alertness and mood at night ［J］. Lighting Research and Technology, 2010, 42(4):449-458.

[102] HOEKSTRA R, FEKKES D, VAN DE WETERING B J M, et al. Effect of light therapy on biopterin, neopterin and tryptophan in patients with seasonal affective disorder ［J］. Stemmingsstoornissen, 2003:63.

[103] BENKELFAT C, BOIVIN D B, YOUNG S N. Bright light exposure during acute tryptophan depletion prevents a lowering of mood in mildly seasonal women ［J］. European Neuropsychopharmacology, 2008, 18(1):14-23.

[104] YILDIRIM K, AKALIN-BASKAYA A, HIDAYETOGLU M L. Effects of indoor color on mood and cognitive performance ［J］. Building and Environment, 2007, 42(9):3233-3240.

[105] SINGH S. Impact of color on marketing ［J］. Management Decision, 2006, 44(6):783-789.

[106] CHELLAPPA S L, VIOLA A U, SCHMIDT C, et al. Human melatonin and alerting response to blue-enriched light depend on a polymorphism in the clock gene PER3 ［J］. Journal of Clinical Endocrinology & Metabolism, 2012, 97(3):E433-E437.

[107] BURES OV M, DVORKOV M, ZVOLSKY P, et al. Early morning bright light phase advances the human circadian pacemaker within one day ［J］. Neuroscience Letters, 1991, 121(1):47-50.

[108] APPLEMAN K, FIGUEIRO M G, REA M S. Controlling light-dark exposure patterns rather than sleep schedules determines circadian phase ［J］. Sleep Medicine, 2013.

[109] DEWAN K, BENLOUCIF S, REID K, et al. Light-induced changes of the circadian clock of humans:increasing duration is more effective than increasing light intensity ［J］. Sleep, 2011, 34(5):593.

[110] THAPAN K, ARENDT J, SKENE D J. An action spectrum for melatonin suppression:evidence for a novel non-rod, non-cone photoreceptor system in humans ［J］. The Journal of Physiology, 2001, 535(1):261-267.

[111] BRAINARD G C, HANIFIN J P, GREESON J M, et al. Action spectrum for melatonin regulation in humans:evidence for a novel circadian photoreceptor ［J］. The Journal of Neuroscience, 2001, 21(16):6405-6412.

[112] REA M S, BULLOUGH J D, FIGUEIRO M G. Phototransduction for human melatonin suppression ［J］. Journal of Pineal Research, 2002, 32(4):209-213.

[113] LEPROULT R, COLECCHIA E F, L’HERMITE-BALERIAUX M, et al. Transition from dim to bright light in the morning induces an immediate elevation of cortisol levels［J］. Journal of Clinical Endocrinology & Metabolism, 2001, 86(1):151-157.

[114] JUNG C M, KHALSA S B S, SCHEER F A J L, et al. Acute effects of bright light exposure on cortisol levels ［J］. Journal of Biological Rhythms, 2010, 25(3):208-216.

[115] CORBETT R W, MIDDLETON B, ARENDT J. An hour of bright white light in the early morning improves performance and advances sleep and circadian phase during the Antarctic winter ［J］. Neuroscience Letters, 2012.

[116] CHANG A M, SANTHI N, ST HILAIRE M, et al. Human responses to bright light of different durations ［J］. The Journal of Physiology, 2012, 590(13):3103-3112.

[117] CHELLAPPA S L, STEINER R, BLATTNER P, et al. Non-visual effects of light on melatonin, alertness and cognitive performance:can blue-enriched light keep us alert ［J］. PloS One, 2011, 6(1):e16429.

[118] SAHIN L, FIGUEIRO M G. Alerting effects of short-wavelength (blue) and long-wavelength (red) lights in the afternoon ［J］. Physiology & Behavior, 2013.

[119] TEIXEIRA L, LOWDEN A, LUZ A A, et al. Exposure to bright light during evening class hours increases alertness among working college students ［J］. Sleep Medicine, 2012.

[120] RAUTKYLE, PUOLAKKA M, HALONEN L. Alerting effects of daytime light exposure-a proposed link between light exposure and brain mechanisms ［J］. Lighting Research and Technology, 2012, 44(2):238-252.

[121] FIGUEIRO M G, BIERMAN A, PLITNICK B, et al. Preliminary evidence that both blue and red light can induce alertness at night ［J］. BMC Neuroscience, 2009, 10(1):105.

[122] SCHEER F, PIROVANO C, VAN SOMEREN E J W, et al. Environmental light and suprachiasmatic nucleus interact in the regulation of body temperature ［J］. Neuroscience, 2005, 132(2):465-478.

[123] VANDE WERKEN M, GIMNEZ M C, VRIES B, et al. Effects of artificial dawn on sleep inertia, skin temperature, and the awakening cortisol response ［J］. Journal of Sleep Research, 2010, 19(3):425-435.

[124] GIMNEZ M C, HESSELS M, VAN DE WERKEN M, et al. Effects of artificial dawn on subjective ratings of sleep inertia and dim light melatonin onset ［J］. Chronobiology International, 2010, 27(6):1219-1241.

[125] KLLER R, WETTERBERG L. Melatonin, CORTISOL, EEG, ECG and subjective comfort in healthy humans:impact of two fluorescent lamp types at two light intensities ［J］. Lighting Research and Technology, 1993, 25(2):71-80.

[126] DAURAT A, FORET J, BENOIT O, et al. Bright light during nighttime:effects on the circadian regulation of alertness and performance ［J］. Neurosignals, 2000, 9(6):309-318.

[127] LEWY A J, KEM H A, ROSENTHAL N E, et al. Bright artificial light treatment of a manic-depressive patient with a seasonal mood cycle ［J］. The American Journal of Psychiatry, 1982.

[128] VIOLA A U, JAMES L M, SCHLANGEN L J M, et al. Blue-enriched white light in the workplace improves self-reported alertness, performance and sleep quality ［J］. Scandinavian Journal of Work, Environment & Health, 2008:297-306.

[129] KATSUURA T, JIN X, BABA Y, et al. Effects of color temperature of illumination on physiological functions ［J］. Journal of Physiological Anthropology and Applied Human Science, 2005, 24(4):321-325.

[130] SHI L, KATSUURA T, SHIMOMURA Y, et al. Effects of different light source color temperatures during physical exercise on human EEG and subjective evaluation ［J］. Journal of the Human-Environment System, 2009, 12(1):27-34.

[131] YAN Y H, GGAN Y, TANG G L. Experimental research of visual performance with differenet optical spectrum light sources ［J］. Advanced Materials Research, 2012, 433:6375-6383.

[132] STEELE, ROBERT V. “The story of a new light source.” Nature photonics 1.1 (2007):25-26.