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Books on the topic 'Optimal energy efficiency'

Author: Grafiati
Published: 30 May 2022
Last updated: 31 May 2022

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1

Wang, Yan, Cheng-Lin Liu, and Zhi-Cheng Ji. Quantitative Analysis and Optimal Control of Energy Efficiency in Discrete Manufacturing System. Singapore: Springer Singapore, 2020. http://dx.doi.org/10.1007/978-981-15-4462-0.

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2

Jain, Raj K. Optimal design study of high efficiency indium phosphide space solar cells. [Cleveland, Ohio: Lewis Research Center, 1990.

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3

Jain, Raj K. Optimal design study of high efficiency indium phosphide space solar cells. [Cleveland, Ohio: Lewis Research Center, 1990.

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4

Moser, Philip. Energy-Efficient VCSELs for Optical Interconnects. Cham: Springer International Publishing, 2016. http://dx.doi.org/10.1007/978-3-319-24067-1.

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5

Nikkari, Jason James. An optical process sensor for steel furnace pollution control and energy efficiency. Ottawa: National Library of Canada, 2000.

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6

Optics, European Congress on. Optical materials technology for energy efficiency and solar energy conversion IX: ECO3, 12-13 March 1990, the Hague, the Netherlands. Edited by Granqvist Claes G, Lampert Carl M, European Physical Society, European Federation for Applied Optics., Society of Photo-optical Instrumentation Engineers., and Association nationale de la recherche technique. Bellingham, Wash., USA: SPIE, 1990.

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7

European Congress on Optics (1st 1988 Hamburg, Germany). Optical materials technology for energy efficiency and solar energy conversion VII: ECO1 19-21 September 1988, Hamburg, Federal Republic of Germany. Edited by Lampert Carl M, Granqvist Claes G, Society of Photo-optical Instrumentation Engineers., European Physical Society, European Federation for Applied Optics., and Association nationale de la recherche technique. Bellingham, Wash., USA: The Society, 1989.

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8

Shanks, Kirk B. P. The optimal deployment of energy efficient envelope technologies within the Northern Ireland Housing Executive existing stock. [s.l: The Author], 2001.

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9

Shinde, Kartik N. Phosphate Phosphors for Solid-State Lighting. Berlin, Heidelberg: Springer Berlin Heidelberg, 2012.

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10

Gordon, Jeffrey M., and Roland Winston. Nonimaging optics: Efficient design for illumination and solar concentration VIII : 21-22 August 2011, San Diego, California, United States. Edited by SPIE (Society). Bellingham, Wash: SPIE, 2011.

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11

Liu, Cheng-Lin, Yan Wang, and Zhi-Cheng Ji. Quantitative Analysis and Optimal Control of Energy Efficiency in Discrete Manufacturing System. Springer, 2020.

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12

Karlsson, Joakim. Windows - Optical Performance & Energy Efficiency. Uppsala Universitet, 2001.

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13

Wolf, E. L. Solar Cell Physics and Technologies. Oxford University Press, 2018. http://dx.doi.org/10.1093/oso/9780198769804.003.0010.

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Solar cells are based on semiconductor pn junctions. Absorption of sunlight is optimal at bandgap energies near one electron volt, and greatly increases the reverse current density. The efficiency of the cell is described by the “filling factor”, and is limited, for single junction cells, by the Quiesser–Shockley limit, near 30 percent. Tandem cells, series combinations of cells, absorb a larger portion of the solar spectrum with higher efficiency but with greater complexity and cost. Such cells are used with focusing optics that inherently raises the efficiency, but also the complexity and cost. This is a textbook for physics, chemistry and engineering students interested in the future of energy as impacted by depletion of fossil fuels, and in the effects of fossil fuel burning on climate.
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14

Lampert, Carl M. Optical Materials Technology for Energy Efficiency and Solar Energy Conversion XII. SPIE Society of Photo-Optical Instrumentation Engi, 1993.

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15

(Editor), Carl M. Lampert, and Satyen K. Deb (Editor), eds. Optical Materials Technology for Energy Efficiency and Solar Energy Conversion XIV. Society of Photo Optical, 1995.

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16

Granqvist, Claes G. Optical Materials Technology for Energy Efficiency and Solar Energy Conversion V. Society of Photo Optical, 1986.

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17

Granqvist, Claes G. Optical Materials Technology for Energy Efficiency and Solar Energy Conversion VII. Society of Photo Optical, 1989.

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18

Lampert, Carl M. Opticals Materials Technology for Energy Efficiency and Solar Energy Conversion. Society of Photo Optical, 1987.

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19

Lampert, Carl M. Optical Materials Technology for Energy Efficiency and Solar Energy Conversion IV (Spie, Vol 562). SPIE--the International Society for Optical Engineering, 1985.

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20

Wolf, E. L. Solar Thermal Energy. Oxford University Press, 2018. http://dx.doi.org/10.1093/oso/9780198769804.003.0009.

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The Sun’s spectrum on Earth is modified by the atmosphere, and is harvested either by generating heat for direct use or for running heat engines, or by quantum absorption in solar cells, to be discussed later. Focusing of sunlight requires tracking of the Sun and is defeated on cloudy days. Heat engines have efficiency limits similar to the Carnot cycle limit. The steam turbine follows the Rankine cycle and is well developed in technology, optimally using a re-heat cycle of higher efficiency. Having learned quite a bit about how the Sun’s energy is created, and how that process might be reproduced on Earth, we turn now to methods for harvesting the energy from the Sun as a sustainable replacement for fossil fuel energy.
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21

Granqvist, Claes G. Optical Materials Technology for Energy Efficiency and Solar Energy Conversion, Ix, March 1990, the Hague. Society of Photo Optical, 1990.

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22

(Editor), Volker Wittwer, and Claes G. Granqvist (Editor), eds. Optical Materials Technology for Energy Efficiency and Solar Energy Conversion Xiii: 18-22 April 1994 Freiburg, Frg. Society of Photo Optical, 1994.

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23

Krarti, Moncef. Optimal Design and Retrofit of Energy Efficient Buildings, Communities, and Urban Centers. Elsevier Science & Technology Books, 2018.

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24

Optimal Design and Retrofit of Energy Efficient Buildings, Communities, and Urban Centers. Elsevier, 2018. http://dx.doi.org/10.1016/c2016-0-02074-0.

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25

Optical materials technology for energy efficiency and solar energy conversion V: 15-18 April, 1986, Innsbruck, Austria. Bellingham, Wash: SPIE--the International Society for Optical Engineering, 1986.

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26

G, Granqvist Claes, Lampert Carl M, Society of Photo-optical Instrumentation Engineers., International Solar Energy Society, and United States. Dept. of Energy. Office of Solar Heat Technologies., eds. Optical materials technology for energy efficiency and solar energy conversion VIII: 10-11 August 1989, San Diego, California. Bellingham, Wash., USA: SPIE--the International Society for Optical Engineering, 1989.

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27

M, Lampert Carl, and Society of Photo-optical Instrumentation Engineers., eds. Optical materials technology for energy efficiency and solar energy conversion XIV: 12-13 July, 1995, San Diego, California. Bellingham, Wash., USA: SPIE, 1995.

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28

M, Lampert Carl, and Society of Photo-optical Instrumentation Engineers., eds. Optical materials technology for energy efficiency and solar energy conversion XV: 28-29 July 1997, San Diego, California. Bellingham, Wash., USA: SPIE, 1997.

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29

G, Granqvist Claes, Lampert Carl M, and Society of Photo-optical Instrumentation Engineers., eds. Optical materials technology for energy efficiency and solar energy conversion X: 25-26 July 1991, San Diego, California : proceedings. Bellingham, Wash., USA: SPIE, 1991.

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30

Optical materials technology for energy efficiency and solar energy conversion XI: Photovoltaics, photochemistry, and photoelectrochemistry : 19 and 21 May 1992, Toulouse-Labège, France. Bellingham, Wash., USA: SPIE, 1992.

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31

Optical materials technology for energy efficiency and solar energy conversion VI: 18-19 August 1987, San Diego, California. Bellingham, Wash., USA: SPIE--the International Society for Optical Engineering, 1987.

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32

M, Lampert Carl, and Society of Photo-optical Instrumentation Engineers., eds. Optical materials technology for energy efficiency and solar energy conversion XII: 13-14 July 1993, San Diego, California. Bellingham, Wash., USA: SPIE, 1993.

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33

M, Lampert Carl, Granqvist Claes G, Society of Photo-optical Instrumentation Engineers., International Solar Energy Society, and United States. Dept. of Energy. Office of Solar Heat Technologies., eds. Optical materials technology for energy efficiency and solar energy conversion VIII: 10-11 August 1989, San Diego, California. Bellingham, Wash., USA: The Society, 1989.

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34

M, Lampert Carl, University of Arizona. Optical Sciences Center., and Society of Photo-optical Instrumentation Engineers., eds. Optical materials technology for energy efficiency and solar energy conversion IV: August 20-22, 1985, San Diego, California. Bellingham, Wash., USA: SPIE--the International Society for Optical Engineering, 1985.

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35

M, Lampert Carl, and Society of Photo-optical Instrumentation Engineers., eds. Optical materials technology for energy efficiency and solar energy conversion XII: 13-14 July 1993, San Diego, California. Bellingham, Wash., USA: The Society, 1993.

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36

Advanced DSP Techniques for High-Capacity and Energy-Efficient Optical Fiber Communications. MDPI, 2019. http://dx.doi.org/10.3390/books978-3-03921-793-9.

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37

Gott, Anne Hugot-Le, and Claes G. Granqvist. Optical Materials Technology for Energy Efficiency and Solar Energy Conversion XI: Chromogenics for Smart Windows (Proceedings of S P I E). Society of Photo Optical, 1992.

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38

Optical materials technology for energy efficiency and solar energy conversion XI: Chromogenics for smart windows : 19 and 21 May 1992, Toulouse-Labège, France. Bellingham, Wash: SPIE, 1992.

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39

Granqvist, Claes G. Optical Materials Technology for Energy Efficiency and Solar Energy Conversion VIII: 10-11 August 1989 San Diego, California (Spie Proceedings, Vol). Society of Photo Optical, 1989.

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40

Lampert, Carl M. Optical Materials Technology for Energy Efficiency and Solar Energy Conversion X: 25-26 July 1991 San Diego, California (Spie Proceedings, Vol 1536). Society of Photo Optical, 1991.

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41

Shinde, Kartik N., S. J. Dhoble, and H. C. Swart. Phosphate Phosphors for Solid-State Lighting. Springer, 2012.

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42

Shinde, Kartik N., S. J. Dhoble, H. C. Swart, and Kyeongsoon Park. Phosphate Phosphors for Solid-State Lighting. Springer, 2015.

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43

Gordon, Jeffrey, and Roland Winston. Nonimaging Optics: Efficient Design for Illumination and Solar Concentration XI. SPIE, 2014.

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44

Gordon, Jeffrey, and Roland Winston. Nonimaging Optics: Efficient Design for Illumination and Solar Concentration XII. SPIE, 2015.

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45

Winston, Roland, and Sarah Kurtz. Nonimaging Optics: Efficient Design for Illumination and Solar Concentration XIV. SPIE, 2017.

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46

Gordon, Jeffrey, and Roland Winston. Nonimaging Optics: Efficient Design for Illumination and Solar Concentration X. SPIE, 2013.

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47

Optical materials technology for energy efficiency and solar energy conversion XI: Selective materials, concentrators and reflectors, transparent insulation, and superwindows : 18 May 1992, Toulouse-Labège, France. Bellingham, Wash., USA: SPIE, 1992.

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48

Wright, A. G. Photocathodes. Oxford University Press, 2017. http://dx.doi.org/10.1093/oso/9780199565092.003.0002.

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Optical properties of photocathodes and their characterization in terms of absorptance, transparency, and reflectance in mixed dielectric media are presented. Photometric units and international standards are based on a specified white light source. The electromagnetic spectrum covers about a decade in wavelength and there is a relationship between photon energy and wavelength. Spectral responsivity can be specified in milliamps per watt or as quantum efficiency, η‎(λ‎), in terms of photoelectrons per incident photon. Empirical specifications, based on filtered light from a standard white light source give a measure of the photocathode response to blue, red, and infrared light. Bialkali photocathodes laid on a conducting substrate can operate at ultra-low temperatures approaching absolute zero, while others can survive operation at 200 °C. End window and side window photomultipliers are available in a range of diameters and photocathode types.
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49

Eriksson, Olle, Anders Bergman, Lars Bergqvist, and Johan Hellsvik. Ultrafast Switching Dynamics. Oxford University Press, 2017. http://dx.doi.org/10.1093/oso/9780198788669.003.0011.

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The time-integrated amount of data and stored information, is doubled roughly every eighteen months, and since the majority of the worlds information is stored in magnetic media, the possibility to write and retrieve information in a magnetic material at ever greater speed and with lower energy consumption, has obvious benefits for our society. Hence the seemingly simple switching of a magnetic unit, a bit, is a crucial process which defines how efficiently information can be stored and retrieved from a magnetic memory. Of particular interest here are the concepts of ultrafast magnetism and all-optical control of magnetism which have in recent decades become the basis for an intense research field. The motivation is natural; the mechanisms behind these phenomena are far from trivial and the technological implications are huge.
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50

Guss-West, Clare. Attention and Focus in Dance. Human Kinetics, 2021. http://dx.doi.org/10.5040/9781718212718.

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The Western approach to dance is largely focused on control and mastery of technique, both of which are certainly necessary skills for improving performance. But mindful attention, despite its critical role in high performance, has gotten short shrift—until now. Attention and Focus in Dance, a how-to book rooted in the 20 years of attentional focus findings of researcher Gabriele Wulf, will help dancers unlock their power and stamina reserves, enabling efficient movement, heightening their sensory perception and releasing their dance potential. Author Clare Guss-West—a professional dancer, choreographer, teacher and holistic practitioner—presents a systematic, science-based approach to the mental work of dance. Her approach helps dancers hone the skills of attention, focus and self-cueing to replenish energy and enhance their physical and artistic performance. A Unique, Research-Based Approach Here is what Attention and Focus in Dance offers readers: • A unique approach, connecting the foundations of Eastern movement with Western movement forms • Research-based teaching practices in diverse contexts, including professional dance companies, private studios, and programmes for dancers with special needs or movement challenges • Testimonies and tips from international professional dancers and dance educators who use the book's approach in their training and teaching • A dance-centric focus that can be easily integrated into existing training and teaching practice, in rehearsal, or in rehabilitation contexts to provide immediate and long-term benefits Guss-West explores attentional focus techniques for dancers, teachers and dance health care practitioners, making practical connections between research, movement theory and day-to-day dance practice. “Many dancers are using excessive energy deployment and significant counterproductive effort, and that can lead to a global movement dysfunction, lack of stamina and an increased risk of injury,” says Guss-West. “Attentional focus training is the most relevant study that sport science and Eastern-movement practice can bring to dance.” Book Organisation The text is organised into two parts. Part I guides dancers in looking at the attentional challenges and information overload that many professional dancers suffer from. It outlines the need for a systematic attention and focus strategy, and it explains how scientific research on attentional focus relates to dance practice. This part also examines the ways in which Eastern-movement principles intersect with and complement scientific findings, and it examines how the Eastern and scientific concepts can breathe new life into basic dance elements such as posture, turnout and port de bras. Attention and focus techniques are included for replenishing energy and protecting against energy depletion and exhaustion. Part II presents attention and focus strategies for teaching, self-coaching and cueing. It addresses attentional focus cues for beginners and for more advanced dancers and professionals, and it places attentional focus in the broader context of holistic teaching strategies. Maximising Dance Potential “Whether cueing others or yourself, cueing for high performance is an art,” Guss-West says. “Readers will discover how to format cues and feedback to facilitate effective neuromuscular response and enhance dancer recall of information and accessibility while dancing.” Attention and Focus in Dance offers an abundance of research-backed concepts and inspirational ideas that can help dancers in their learning and performance. This book aids readers in filtering information and directing their focus for optimal physical effect. Ultimately, it guides dancers and teachers in being the best version of themselves and maximising their potential in dance.
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