Effects of LED lighting environments on lettuce (Lactuca sativa L.) in PFAL systems – A review

[1]  Zhongxiong Zhang,et al.  Multi-objective optimal regulation model and system based on whole plant photosynthesis and light use efficiency of lettuce , 2023, Comput. Electron. Agric..

[2]  J. A. Pascual,et al.  Role of Spectrum-Light on Productivity, and Plant Quality over Vertical Farming Systems: Bibliometric Analysis , 2023, Horticulturae.

[3]  Matthew J. Knowling,et al.  Space farming: Horticulture systems on spacecraft and outlook to planetary space exploration. , 2022, Plant physiology and biochemistry : PPB.

[4]  L. Csambalik,et al.  Characterizing the Spatial Uniformity of Light Intensity and Spectrum for Indoor Crop Production , 2022, Horticulturae.

[5]  M. A.,et al.  Effect of LED lighting on phytochemical content of lettuce plants (green coral and red coral) grown in plant factory condition , 2022, Supplementary 1.

[6]  Y. Kanayama,et al.  Effects of light quality on plant development and fruit metabolism and their regulation by plant growth regulators in tomato , 2022, Scientia Horticulturae.

[7]  Yeweon Kim,et al.  Analysis on the Economic Feasibility of a Plant Factory Combined with Architectural Technology for Energy Performance Improvement , 2022, Agriculture.

[8]  T. Tanabata,et al.  Effect of differences in light source environment on transcriptome of leaf lettuce (Lactuca sativa L.) to optimize cultivation conditions , 2022, PloS one.

[9]  Hao Zhou,et al.  Yield, resource use efficiency or flavour: Trade-offs of varying blue-to-red lighting ratio in urban plant factories , 2022, Scientia Horticulturae.

[10]  Qichang Yang,et al.  Lettuce growth, morphology and critical leaf trait responses to far-red light during cultivation are low fluence and obey the reciprocity law , 2021 .

[11]  B. Matysiak,et al.  The Impact of LED Light Spectrum on the Growth, Morphological Traits, and Nutritional Status of ‘Elizium’ Romaine Lettuce Grown in an Indoor Controlled Environment , 2021, Agriculture.

[12]  G. Xydis,et al.  Energy cost reduction by shifting electricity demand in indoor vertical farms with artificial lighting , 2021, Biosystems Engineering.

[13]  Lingyan Kong,et al.  Nutritional quality and health benefits of microgreens, a crop of modern agriculture , 2021, Journal of Future Foods.

[14]  Qichang Yang,et al.  Optimal control as a tool to investigate the profitability of a Chinese plant factory - lettuce production system , 2021, Biosystems Engineering.

[15]  Xiaoling Wu,et al.  Far-red light: A regulator of plant morphology and photosynthetic capacity , 2021, The Crop Journal.

[16]  M. V. van Iersel,et al.  Why Far-Red Photons Should Be Included in the Definition of Photosynthetic Photons and the Measurement of Horticultural Fixture Efficacy , 2021, Frontiers in Plant Science.

[17]  Tao Wu,et al.  Effect of LED Spectrum on the Quality and Nitrogen Metabolism of Lettuce Under Recycled Hydroponics , 2021, Frontiers in Plant Science.

[18]  G. Pennisi,et al.  Pulsed LED Light: Exploring the Balance between Energy Use and Nutraceutical Properties in Indoor-Grown Lettuce , 2021, Agronomy.

[19]  R. F. Karlicek,et al.  Effect of Multispectral Pulsed Light-Emitting Diodes on the Growth, Photosynthetic and Antioxidant Response of Baby Leaf Lettuce (Lactuca sativa L.) , 2021, Plants.

[20]  M. V. van Iersel,et al.  Only Extreme Fluctuations in Light Levels Reduce Lettuce Growth Under Sole Source Lighting , 2021, Frontiers in Plant Science.

[21]  E. Heuvelink,et al.  Adding Far-Red to Red-Blue Light-Emitting Diode Light Promotes Yield of Lettuce at Different Planting Densities , 2021, Frontiers in Plant Science.

[22]  Lisha Shen,et al.  Seeing the lights for leafy greens in indoor vertical farming , 2020 .

[23]  A. Jung,et al.  Horticultural lighting system optimalization: A review , 2020 .

[24]  Murat Kacira,et al.  Design and implementation of a low-cost sensor network to monitor environmental and agronomic variables in a plant factory , 2020, Comput. Electron. Agric..

[25]  L. Marcelis,et al.  Optimal photoperiod for indoor cultivation of leafy vegetables and herbs , 2020, European Journal of Horticultural Science.

[26]  L. Marcelis,et al.  Optimal light intensity for sustainable water and energy use in indoor cultivation of lettuce and basil under red and blue LEDs , 2020 .

[27]  E. Runkle,et al.  Promotion of lettuce growth under an increasing daily light integral depends on the combination of the photosynthetic photon flux density and photoperiod , 2020 .

[28]  Mamun Bin Ibne Reaz,et al.  Design, Construction and Testing of IoT Based Automated Indoor Vertical Hydroponics Farming Test-Bed in Qatar , 2020, Sensors.

[29]  Elmer P. Dadios,et al.  Vision-Based Lettuce Growth Stage Decision Support System Using Artificial Neural Networks , 2020 .

[30]  M. A. Morales,et al.  MODELLING PHOTOSYNTHETICALLY ACTIVE RADIATION: A REVIEW , 2020, Atmósfera.

[31]  Qichang Yang,et al.  Regulation of Ascorbate Accumulation and Metabolism in Lettuce by the Red:Blue Ratio of Continuous Light Using LEDs , 2020, Frontiers in Plant Science.

[32]  R. Paradiso,et al.  Air Distribution in a Fully-Closed Higher Plant Growth Chamber Impacts Crop Performance of Hydroponically-Grown Lettuce , 2020, Frontiers in Plant Science.

[33]  Chungui Lu,et al.  A review on the effects of light-emitting diode (LED) light on the nutrients of sprouts and microgreens , 2020, Trends in Food Science & Technology.

[34]  H. A. Ahmed,et al.  Optimal control of environmental conditions affecting lettuce plant growth in a controlled environment with artificial lighting: A review , 2020 .

[35]  P. Perkins-Veazie,et al.  Impact of sun-simulated white light and varied blue:red spectrums on the growth, morphology, development, and phytochemical content of green- and red-leaf lettuce at different growth stages , 2020 .

[36]  B. Bugbee,et al.  From physics to fixtures to food: current and potential LED efficacy , 2020, Horticulture Research.

[37]  G. Weaver,et al.  Longer Photoperiods with Adaptive Lighting Control Can Improve Growth of Greenhouse-grown ‘Little Gem’ Lettuce (Lactuca sativa) , 2020, HortScience.

[38]  Yadong Liu,et al.  Computer vision technology in agricultural automation —A review , 2020 .

[39]  E. Runkle,et al.  Blue Radiation Interacts with Green Radiation to Influence Growth and Predominantly Controls Quality Attributes of Lettuce , 2020 .

[40]  H. A. Ahmed,et al.  Lettuce plant growth and tipburn occurrence as affected by airflow using a multi-fan system in a plant factory with artificial light. , 2020, Journal of thermal biology.

[41]  B. Bugbee,et al.  Far-red photons have equivalent efficiency to traditional photosynthetic photons: implications for re-defining photosynthetically active radiation. , 2020, Plant, cell & environment.

[42]  M. Timmons,et al.  Quality, Yield, and Biomass Efficacy of Several Hydroponic Lettuce (Lactuca sativa L.) Cultivars in Response to High Pressure Sodium Lights or Light Emitting Diodes for Greenhouse Supplemental Lighting , 2020, Horticulturae.

[43]  Lihong Gao,et al.  Blue light alleviates ‘red light syndrome’ by regulating chloroplast ultrastructure, photosynthetic traits and nutrient accumulation in cucumber plants , 2019, Scientia Horticulturae.

[44]  C. Stanghellini,et al.  Resource use efficiency of indoor lettuce (Lactuca sativa L.) cultivation as affected by red:blue ratio provided by LED lighting , 2019, Scientific Reports.

[45]  V. Orsat,et al.  Re-interpreting the photosynthetically action radiation (PAR) curve in plants. , 2019, Plant science : an international journal of experimental plant biology.

[46]  A. Tukker,et al.  The second green revolution: Innovative urban agriculture's contribution to food security and sustainability – A review , 2019, Global Food Security.

[47]  Z. Hochman,et al.  Strategies to improve the productivity, product diversity and profitability of urban agriculture , 2019, Agricultural Systems.

[48]  Wenke Liu,et al.  Dynamic Responses of Ascorbate Pool and Metabolism in Lettuce to Long-term Continuous Light Provided by Red and Blue LEDs , 2019, Environmental and Experimental Botany.

[49]  K. Folta,et al.  Manipulation of Seedling Traits with Pulsed Light in Closed Controlled Environments , 2019, bioRxiv.

[50]  E. Runkle,et al.  Substituting green or far-red radiation for blue radiation induces shade avoidance and promotes growth in lettuce and kale , 2019, Environmental and Experimental Botany.

[51]  J. Lorenzo,et al.  Recent advances in the application of pulsed light processing for improving food safety and increasing shelf life , 2019, Trends in Food Science & Technology.

[52]  G. Niu,et al.  Evaluation of growth and quality of hydroponic lettuce at harvest as affected by the light intensity, photoperiod and light quality at seedling stage , 2019, Scientia Horticulturae.

[53]  Hiroshi Mineno,et al.  Leaf-Movement-Based Growth Prediction Model Using Optical Flow Analysis and Machine Learning in Plant Factory , 2019, Front. Plant Sci..

[54]  Giacomo Cocetta,et al.  Optimization of LED Lighting and Quality Evaluation of Romaine Lettuce Grown in An Innovative Indoor Cultivation System , 2019, Sustainability.

[55]  P. Fisher,et al.  Minimum Light Requirements for Indoor Gardening of Lettuce , 2019, Urban Agriculture & Regional Food Systems.

[56]  R. Wheeler,et al.  A strategic approach for investigating light recipes for 'Outredgeous' red romaine lettuce using white and monochromatic LEDs. , 2018, Life sciences in space research.

[57]  M. Takagaki,et al.  Supplemental upward LED lighting for growing romaine lettuce (Lactuca sativa) in a plant factory: cost performance by light intensity and different light spectra , 2018, Acta Horticulturae.

[58]  M. Kanechi Growth and Photosynthesis under Pulsed Lighting , 2018, Photosynthesis - From Its Evolution to Future Improvements in Photosynthetic Efficiency Using Nanomaterials.

[59]  J. Logan,et al.  Daily Light Integral: A Research Review and High-resolution Maps of the United States , 2018, HortScience.

[60]  Chungui Lu,et al.  Effect of green light on nitrate reduction and edible quality of hydroponically grown lettuce (Lactuca sativa L.) under short-term continuous light from red and blue light-emitting diodes , 2018, Environmental and Experimental Botany.

[61]  Chungui Lu,et al.  Study of the beneficial effects of green light on lettuce grown under short-term continuous red and blue light-emitting diodes. , 2018, Physiologia plantarum.

[62]  Yuming Fu,et al.  Effect of green, yellow and purple radiation on biomass, photosynthesis, morphology and soluble sugar content of leafy lettuce via spectral wavebands “knock out” , 2018, Scientia Horticulturae.

[63]  R. Matsuda,et al.  Effects of photosynthetic photon flux density, frequency, duty ratio, and their interactions on net photosynthetic rate of cos lettuce leaves under pulsed light: explanation based on photosynthetic-intermediate pool dynamics , 2018, Photosynthesis Research.

[64]  Tetsuya Mori,et al.  Metabolic Reprogramming in Leaf Lettuce Grown Under Different Light Quality and Intensity Conditions Using Narrow-Band LEDs , 2018, Scientific Reports.

[65]  Athanasios Koukounaras,et al.  Current status and recent achievements in the field of horticulture with the use of light-emitting diodes (LEDs) , 2018 .

[66]  L. Urban,et al.  UV-C light and pulsed light as alternatives to chemical and biological elicitors for stimulating plant natural defenses against fungal diseases , 2018 .

[67]  Lihong Xu,et al.  Dynamic control of supplemental lighting for greenhouse , 2018 .

[68]  Stefania De Pascale,et al.  Improving vegetable quality in controlled environments , 2018 .

[69]  G. Niu,et al.  Effects of environment lighting on the growth, photosynthesis, and quality of hydroponic lettuce in a plant factory , 2018 .

[70]  A. Lebeda,et al.  Description of morphological characters of lettuce (Lactuca sativa L.) genetic resources. A review , 2018 .

[71]  Imran Ali Lakhiar,et al.  Modern plant cultivation technologies in agriculture under controlled environment: a review on aeroponics , 2018 .

[72]  Rin-ichiro Taniguchi,et al.  Affordable field environmental monitoring and plant growth measurement system for smart agriculture , 2017, 2017 Eleventh International Conference on Sensing Technology (ICST).

[73]  Argel A. Bandala,et al.  Optimization of Photosynthetic Rate Parameters using Adaptive Neuro-Fuzzy Inference System (ANFIS) , 2017, 2017 International Conference on Computer and Applications (ICCA).

[74]  E. Gürel,et al.  Plant responses to extended photosynthetically active radiation (EPAR) , 2017 .

[75]  K. S. Shivaprakasha,et al.  IOT based greenhouse environment monitoring and controlling system using Arduino platform , 2017, 2017 International Conference on Intelligent Computing, Instrumentation and Control Technologies (ICICICT).

[76]  E. Fallik,et al.  Light quality manipulation improves vegetable quality at harvest and postharvest: A review , 2017 .

[77]  W. Yamori,et al.  A Combination of Downward Lighting and Supplemental Upward Lighting Improves Plant Growth in a Closed Plant Factory with Artificial Lighting , 2017 .

[78]  I. G. Tarakanov,et al.  LED crop illumination inside space greenhouses , 2017 .

[79]  K. Sonoike,et al.  Significance of structural variation in thylakoid membranes in maintaining functional photosystems during reproductive growth. , 2017, Physiologia plantarum.

[80]  Sung Jin Kim,et al.  Growth Characteristics of Lettuce under Different Frequency of Pulse Lighting and RGB Ratio of LEDs , 2017 .

[81]  Kurt K. Benke,et al.  Future food-production systems: vertical farming and controlled-environment agriculture , 2017 .

[82]  Kyung Sub Park,et al.  Leaf photosynthetic rate, growth, and morphology of lettuce under different fractions of red, blue, and green light from light-emitting diodes (LEDs) , 2016, Horticulture, Environment, and Biotechnology.

[83]  M. Oh,et al.  Application of supplementary white and pulsed light-emitting diodes to lettuce grown in a plant factory with artificial lighting , 2016, Horticulture, Environment, and Biotechnology.

[84]  Phillip A. Davis,et al.  Photobiology in protected horticulture , 2016 .

[85]  Y. Sago Effects of Light Intensity and Growth Rate on Tipburn Development and Leaf Calcium Concentration in Butterhead Lettuce , 2016 .

[86]  David Sinton,et al.  Photon management for augmented photosynthesis , 2016, Nature Communications.

[87]  Ying Zhang,et al.  A CFD study on improving air flow uniformity in indoor plant factory system , 2016 .

[88]  H. R. Gislerød,et al.  Acclimatisation of greenhouse crops to differing light quality , 2016 .

[89]  Y. Nishida,et al.  Effects of pulsed lighting based light-emitting diodes on the growth and photosynthesis of lettuce leaves , 2016 .

[90]  Céline Catherine Sarah Nicole,et al.  Lettuce growth and quality optimization in a plant factory , 2016 .

[91]  M. Oh,et al.  Increase in biomass and bioactive compounds in lettuce under various ratios of red to far-red LED light supplemented with blue LED light , 2016, Horticulture, Environment, and Biotechnology.

[92]  Hirokazu Fukuda,et al.  High-Throughput Growth Prediction for Lactuca sativa L. Seedlings Using Chlorophyll Fluorescence in a Plant Factory with Artificial Lighting , 2016, Front. Plant Sci..

[93]  C. Xiaoli,et al.  Growth and nutritional properties of lettuce affected by mixed irradiation of white and supplemental light provided by light-emitting diode , 2016 .

[94]  Michiko Takagaki,et al.  Supplemental Upward Lighting from Underneath to Obtain Higher Marketable Lettuce (Lactuca sativa) Leaf Fresh Weight by Retarding Senescence of Outer Leaves , 2015, Front. Plant Sci..

[95]  M. Oh,et al.  Growth, photosynthetic and antioxidant parameters of two lettuce cultivars as affected by red, green, and blue light-emitting diodes , 2015, Horticulture, Environment, and Biotechnology.

[96]  Eva Rosenqvist,et al.  Spectral Effects of Artificial Light on Plant Physiology and Secondary Metabolism: A Review , 2015 .

[97]  R. Halden,et al.  Comparison of Land, Water, and Energy Requirements of Lettuce Grown Using Hydroponic vs. Conventional Agricultural Methods , 2015, International journal of environmental research and public health.

[98]  So-Young Park,et al.  Growth and cell division of lettuce plants under various ratios of red to far-red light-emitting diodes , 2015, Horticulture, Environment, and Biotechnology.

[99]  Yonghua Zheng,et al.  Effect of light on quality and bioactive compounds in postharvest broccoli florets. , 2015, Food chemistry.

[100]  Ginés García-Mateos,et al.  Digital photography applied to irrigation management of Little Gem lettuce , 2015 .

[101]  R. Matsuda,et al.  A kinetic model for estimating net photosynthetic rates of cos lettuce leaves under pulsed light , 2015, Photosynthesis Research.

[102]  Chung-Liang Chang,et al.  The growth response of leaf lettuce at different stages to multiple wavelength-band light-emitting diode lighting , 2014 .

[103]  M. Sabzalian,et al.  Photosynthesis under artificial light: the shift in primary and secondary metabolism , 2014, Philosophical Transactions of the Royal Society B: Biological Sciences.

[104]  Min-Jeong Lee,et al.  Growth and phenolic compounds of Lactuca sativa L. grown in a closed-type plant production system with UV-A, -B, or -C lamp. , 2014, Journal of the science of food and agriculture.

[105]  Toyoki KOZAI,et al.  Resource use efficiency of closed plant production system with artificial light: Concept, estimation and application to plant factory , 2013, Proceedings of the Japan Academy. Series B, Physical and biological sciences.

[106]  Byoung Ryong Jeong,et al.  Light intensity and photoperiod influence the growth and development of hydroponically grown leaf lettuce in a closed-type plant factory system , 2013, Horticulture, Environment, and Biotechnology.

[107]  Jun Gu Lee,et al.  Effects of air temperature and air flow rate control on the tipburn occurrence of leaf lettuce in a closed-type plant factory system , 2013, Horticulture, Environment, and Biotechnology.

[108]  A. Brazaitytė,et al.  impact of supplementary short-term red led lighting on the antioxidant properties of microgreens , 2012 .

[109]  A. Brazaitytė,et al.  LED lighting and seasonality effects antioxidant properties of baby leaf lettuce. , 2012, Food chemistry.

[110]  A. Zukauskas,et al.  EFFECT OF SUPPLEMENTARY PRE-HARVEST LED LIGHTING ON THE ANTIOXIDANT PROPERTIES OF LETTUCE CULTIVARS , 2011 .

[111]  N. Paul,et al.  Increased exposure to UV-B radiation during early development leads to enhanced photoprotection and improved long-term performance in Lactuca sativa. , 2011, Plant, cell & environment.

[112]  P. Civello,et al.  Effect of visible light treatments on postharvest senescence of broccoli (Brassica oleracea L.). , 2011, Journal of the science of food and agriculture.

[113]  M. Johkan,et al.  Blue Light-emitting Diode Light Irradiation of Seedlings Improves Seedling Quality and Growth after Transplanting in Red Leaf Lettuce , 2010 .

[114]  Ali Akoglu,et al.  Original paper: Lettuce calcium deficiency detection with machine vision computed plant features in controlled environments , 2010 .

[115]  Pavelas Duchovskis,et al.  Decrease in Nitrate Concentration in Leafy Vegetables Under a Solid-state Illuminator , 2009 .

[116]  C. Kubota,et al.  Effects of supplemental light quality on growth and phytochemicals of baby leaf lettuce , 2009 .

[117]  Ilya Ioslovich,et al.  Optimal control strategy for greenhouse lettuce: Incorporating supplemental lighting , 2009 .

[118]  Gary W. Stutte,et al.  Photoregulation of Bioprotectant Content of Red Leaf Lettuce with Light-emitting Diodes , 2009 .

[119]  海老 澤聖宗,et al.  UV-B, UV-Aおよび青色光の夜間補光がサニーレタスの成長と着色に及ぼす影響 , 2008 .

[120]  P. Hadley,et al.  UV irradiance as a major influence on growth, development and secondary products of commercial importance in Lollo Rosso lettuce ‘Revolution’ grown under polyethylene films , 2008 .

[121]  K. Shoji,et al.  Supplementary Ultraviolet Radiation B Together with Blue Light at Night Increased Quercetin Content and Flavonol Synthase Gene Expression in Leaf Lettuce (Lactuca sativa L.) , 2008 .

[122]  J. Lovegrove,et al.  Changes in the flavonoid and phenolic acid contents and antioxidant activity of red leaf lettuce (Lollo Rosso) due to cultivation under plastic films varying in ultraviolet transparency. , 2007, Journal of agricultural and food chemistry.

[123]  S. Britz,et al.  Effect of supplemental ultraviolet radiation on the carotenoid and chlorophyll composition of green house-grown leaf lettuce (Lactuca sativa L.) cultivars , 2006 .

[124]  P. Santamaria Nitrate in vegetables: toxicity, content, intake and EC regulation , 2006 .

[125]  Hyeon-Hye Kim,et al.  Green-light supplementation for enhanced lettuce growth under red- and blue-light-emitting diodes. , 2004, HortScience : a publication of the American Society for Horticultural Science.

[126]  R. Wheeler,et al.  A COMPARISON OF GROWTH AND PHOTOSYNTHETIC CHARACTERISTICS OF LETTUCE GROWN UNDER RED AND BLUE LIGHT-EMITTING DIODES (LEDS) WITH AND WITHOUT SUPPLEMENTAL GREEN LEDS , 2004 .

[127]  R M Wheeler,et al.  Improving spinach, radish, and lettuce growth under red light-emitting diodes (LEDs) with blue light supplementation. , 2001, HortScience : a publication of the American Society for Horticultural Science.

[128]  T. Dougher,et al.  Evidence for Yellow Light Suppression of Lettuce Growth¶ , 2001 .

[129]  L. Gomes,et al.  Inheritance of bolting tendency in lettuce Lactuca sativa L. , 1999, Euphytica.

[130]  W. Lijinsky N-Nitroso compounds in the diet. , 1999, Mutation research.

[131]  S. Britz,et al.  Inhibitory effects of ambient levels of solar UV-A and UV-B radiation on growth of cv. New Red Fire lettuce , 1998 .

[132]  Louis D. Albright,et al.  Hydroponic lettuce production influenced by integrated supplemental light levels in a controlled environment agriculture facility: Experimental results , 1997 .

[133]  T. Yanagi,et al.  Effects of blue, red, and blue/red lights of two different PPF levels on growth and morphogenesis of lettuce plants. , 1996, Acta horticulturae.

[134]  L. V. Raamsdonk,et al.  Numerical morphological analysis of Lettuce cultivars and species (Lactuca sect.Lactuca, Asteraceae) , 1994, Plant Systematics and Evolution.

[135]  T. Górski Improvement of lettuce seedling vigour after far red irradiation of aged achenes , 1993 .

[136]  H. Wiebe,et al.  Relation between photosynthesis and nitrate content of lettuce cultivars , 1992 .

[137]  Photon efficacy in horticulture , 2022, Plant Factory Basics, Applications and Advances.

[138]  S. Navaratne,et al.  Impact of spectral composition of light from light-emitting diodes (LEDs) on postharvest quality of vegetables: A review , 2022, Postharvest Biology and Technology.

[139]  M. Kikuchi,et al.  Business model and cost performance of mini-plant factory in downtown , 2022, Plant Factory Basics, Applications and Advances.

[140]  N. Iqbal,et al.  Crop photosynthetic response to light quality and light intensity , 2021 .

[141]  Mulowayi Mutombo Arcel,et al.  The application of LED illumination and intelligent control in plant factory, a new direction for modern agriculture: A Review , 2021 .

[142]  L. Sutiarso,et al.  Plant growth prediction model for lettuce (Lactuca sativa.) in plant factories using artificial neural network , 2021, IOP Conference Series: Earth and Environmental Science.

[143]  C. Mitchell,et al.  LED advancements for plant-factory artificial lighting , 2020 .

[144]  C. Kubota Growth, development, transpiration, and translocation as affected by abiotic environmental factors , 2020, Plant Factory.

[145]  M. Krijn,et al.  Postharvest Quality of Leafy Greens Growing in a Plant Factory , 2019, Plant Factory Using Artificial Light.

[146]  Dongxian He,et al.  Light-Emitting Diodes for Horticulture , 2019, Light-Emitting Diodes.

[147]  A. Selmani,et al.  Towards autonomous greenhouses solar-powered , 2019, Procedia Computer Science.

[148]  Toyoki Kozai,et al.  Designing a Cultivation System Module (CSM) Considering the Cost Performance: A Step Toward Smart PFALs , 2018 .

[149]  Toyoki Kozai,et al.  Current Status of Plant Factories with Artificial Lighting (PFALs) and Smart PFALs , 2018 .

[150]  J. Jiang,et al.  On-the-go Image Processing System for Spatial Mapping of Lettuce Fresh Weight in Plant Factory , 2018 .

[151]  H. Nozue,et al.  Usefulness of Broad-Spectrum White LEDs to Envision Future Plant Factory , 2018 .

[152]  Ching-Lu Hsieh,et al.  Application of Integrated Control Strategy and Bluetooth for Irrigating Romaine Lettuce in Greenhouse , 2016 .

[153]  Wang Yushun,et al.  Monitoring lettuce growth using K-means color image segmentation and principal component analysis method , 2016 .

[154]  Murat Kacira,et al.  Automated machine vision guided plant monitoring system for greenhouse crop diagnostics , 2014 .

[155]  Yusuf Hendrawan,et al.  Applications of Intelligent Machine Vision in Plant Factory , 2014 .

[156]  Ta-Te Lin,et al.  An automated growth measurement system for leafy vegetables , 2014 .

[157]  Kazuhiro Shoji,et al.  Effect of green light wavelength and intensity on photomorphogenesis and photosynthesis in Lactuca sativa , 2012 .

[158]  Pavelas Duchovskis,et al.  Supplementary red-LED lighting and the changes in phytochemical content of two baby leaf lettuce varieties during three seasons , 2012 .

[159]  P. Duchovskis Supplementary red-LED lighting affects phytochemicals and nitrate of baby leaf lettuce , 2011 .

[160]  EFFECT OF ABNORMALLY LONG AND SHORT ALTER- NATIONS OF LIGHT AND DARKNESS ON GROWTH AND DEVELOPMENT OF PLANTS' , 2010 .

[161]  V. Rubatzky,et al.  Lettuce and Other Composite Vegetables , 1997 .

[162]  A. Lebeda,et al.  Genetic resources of vegetable crops from the genus Lactuca. , 1995 .