Considering the time-consuming and tedious work of the current methods to control plant layout, which is mostly based on expert experience or field trials, we propose an algorithm to optimize and simulate a planting layout based on a virtual plant model and an optimization algorithm. A functional-structural plant model, which combines the structure and physiological function of plants, is used to construct a planting scene. The planting and row spacing are set as the genetic factors and the chromosomes of the genetic algorithm are encoded with a binary method. The photosynthetic yield of the unit planting area is denoted as the fitness value. By using this method, the intercropping of maize and soybean plants and the sole cropping of rice plants are studied. Experimental results show that the proposed method can obtain a high yield planting plan.
Keywords: functional-structural plant models, genetic algorithm, spacing optimization, plant spatial distribution
DOI: 10.25165/j.ijabe.20201301.4877

Citation: Ding W L, Fan C C, Xu L F, Xie T, Liu Y, Wan Z X, et al. Optimization method to obtain appropriate spacing parameters for crop cultivation. Int J Agric & Biol Eng, 2020; 13(1): 146–152.

functional-structural plant models, genetic algorithm, spacing optimization, plant spatial distribution

Kurt C, Bakal H, Gulluoglu L, Arioglu H. The effect of twin row planting pattern and plant population on yield and yield components of peanut (Arachis hypogaea L.) at main crop planting in Cukurova region of Turkey. Turkish Journal of Field Crops, 2017; 22(1): 24–31.

Liu S Y, Baret F, Andrieu B, Abichou M, Allard D, de Solan B, et al. Modeling the spatial distribution of plants on the row for wheat crops. Computers & Electronics in Agriculture, 2017; 136: 147–156.

Wu D T, Wang C Z. Preliminary study on crop layout optimization model. Journal of Beijing Normal University: Natural Science, 1998; 4: 554–558. (in Chinese)

Yang L H, Ma R K. Definition and calculation of uniformity of plant distribution in crops field. Journal of Maize Sciences, 2006; 14(7): 92–94.

Huang M, Jiang P, Xie X B, Shi W J, Zeng Y, Ibrahim M. Optimization of plant-row spacing and establishment of plant height-hill density model in rice. Crop Research, 2011; 25(1): 1–3.

Cui H L, Zhai S S, Liu C L. Experiment in best way and density to plant rape by machine. Agriculture Machinery Technology Extension, 2015; 2: 36–37.

Wu X, Chen Y Q, Sui P, Gao W S, Yan P, Tao Z Q. Effect of planting geometries on canopy structure of spring maize under high-density condition in North China Plain. Chinese Journal of Ecology, 2015; 34(1): 18–24. (in Chinese)

Shao L W, Luo J M, Yin G C, Liu S X. Research on exploiting wheat-maize grain yield theory and technology in the eastern low plain of Hebei Province. Chinese Journal of Eco-Agriculture, 2016; 24(8): 1114–1122. (in Chinese)

Yang J X, Ji W X, Liu L, Wei S Y, Li C C, Zhang Y L. Effects of plant-row spacing on growth and yield components of oil tree peony Paeoniaostii ‘Feng Dan'. Journal of Arid Land Resources & Environment, 2017; 31(6): 202–208.

Ngullie R, Biswas P K. Effect of plant and row spacing on growth and yield of onion under Mokokchung district of Nagaland. International Journal of Plant Sciences, 2017; 12(1): 28–35.

Kumalasari N R, Wicaksono G P, Abdullah L. Plant growth pattern, forage yield, and quality of Indigofera zollingeriana influenced by row spacing. 2017; 40(1): 14–19.

Kang M, Wang F Y. From parallel plants to smart plants: intelligent control and management for plant growth. IEEE/CAA Journal of Automatica Sinica, 2017; 4(2): 161–166.

Qi R, Ma Y, Hu B, de Reffye P, Cournède P H. Optimization of source-sink dynamics in plant growth for ideotype breeding: A case study on maize. Computers and Electronics in Agriculture, 2010; 71(1): 96–105.

Quilot-Turion B, Ould-Sidi M-M, Kadrani A, Hilgert N, Génard M, Lescourret F. Optimization of parameters of the 'Virtual Fruit' model to design peach genotype for sustainable production systems. European Journal of Agronomy, 2012; 42: 34–48.

Drewry D, Kumar P, Long S P. Simultaneous improvement in productivity, water use, and albedo through crop structural modification. Global Change Biology, 2014; 20: 1955–1967.

Sievänen R, Perttunen J, Nikinmaa E, Posada J M. Functional structural plant models - case LIGNUM. In: Proceedings of Plant Growth Modeling, Simulation, Visualization and Applications (PMA), 2009; pp.3–9.

Kniemeyer O, Kurth W. The modeling platform GroIMP and the programming language XL. Lecture Notes in Computer Science, 2008; 5088: 570–572.

Kniemeyer O, Buck-Sorlin G, Kurth W. A graph-grammar approach to artificial life. Artificial Life, 2004; 10(4): 413–431.

Evers J B, Vos J, Yin X R, Romero P, van der Putten P E L, Struik P C. Simulation of wheat growth and development based on organ-level photosynthesis and assimilate allocation. Experimental Botany, 2010; 61(8): 2203–2216.

Buck-Sorlin G, de Visser P H B, Henke M, Sarlikioti V, van der Heijden G W A M, Marcelis L F M, et al. Towards a functional-structural plant model of cut-rose: Simulation of light environment, light absorption, photosynthesis and interference with the plant structure. Annals of Botany, 2011; 108(6): 1121–1134.

Hemmerling R, Kniemeyer O, Lanwert D, Kurth W, Buck-Sorlin G. The rule-based language XL and the modelling environment GroIMP illustrated with simulated tree competition. Functional Plant Biology, 2008; 35: 739–750.

Zhang L, Van der Werf W, Bastiaans L, Zhang S, Li B, Spiertz J H J. Light interception and utilization in relay intercrops of wheat and cotton. Field Crops Research, 2008; 1: 29–42.

Keating B A, Carberry P S. Resource capture and use in intercropping: Solar radiation. Field Crops Research, 1993; 34: 273–301.

Xu L F, Michael H, Zhu J, Kurth W, Buck-Sorlin G H. A rule-based functional-structural model of rice considering source and sink functions. Proceedings of the 2009 Plant Growth Modeling and Applications (PMA’09). IEEE Computer Society Washington DC, USA, 2009; pp.245–252.

Marcelis L F M, Heuvelink E, Goudriaan J. Modelling biomass production and yield of horticultural crops: a review. ScientiaHorticulturae, 1998; 74(1-2): 83–111.

Xu L, Henke M, Zhu J, Kurth W, Buck-Sorlin G. A functional–structural model of rice linking quantitative genetic information with morphological development and physiological processes. Annals of Botany, 2011; 107(5): 817–28.

Qiu C. Analysis on the differences of maize/soybean intercropping system. Master degree thesis, China Agricultural University, 2013. (in Chinese)

Ding W L, Xu L F, Wei Y, Wu F L, Zhu D F, Zhang Y P, et al. Genetic algorithm based approach to optimize phenotypical traits of virtual rice. Journal of Theoretical Biology, 2016; 403: 59–67.

Li M Q. The basic theory and application of genetic algorithm. Science Press, 2002. (in Chinese)

Zhu G. Realization of the genetic algorithm and roulette selection with C++. Journal of Dongguan University of Technology, 2007; 14(5): 70–74. (in Chinese)

Wei Y. A research for plant type quantitative design of high-yield crop based on light model. Master desertation, Zhejiang University of Technology, 2014. (in Chinese)

Wang X P, Cao L M, Shi H B. Design of artificial life demo system based on genetic algorithm. Journal of Tongji University: Natural Science, 2003; 31(2): 224–228. (in Chinese)

Gan Z B, Zhu C X, Ma Y, Lu H W. Concurrent negotiation of relative issues based on genetic algorithm. Journal of Software, 2012; 23(11): 2987–2999.

Zhang J B, Cao H F, Sun T, Shang W N, Jin X Y. Effect of 3-S wide space cultivation on growth and yield of rice. Journal of Agricultural Science and Technology, 2006; 8(2): 15–18.

Liu X W, Meng Y L, Zhou Z G, Cao W X. The primary study on floret and grain development simulation in rice. Chinese Journal of Rice Science, 2004; 18(3): 249–254. (in Chinese)

Wang J H, Shao L S, Cheng Y G, Li Y F, Yan J B, Wang R Q, et al. Influence of planting patterns on main agricultural characters and yield in ‘Dinuo278’. Chinese Agricultural Science Bulletin, 2013; 29(9): 117–122. (in Chinese)