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Analysis, modelling and forecasting of crop yields using artificial neural networks
- Authors: Bischokov R.M.1
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Affiliations:
- Kabardino-Balkarian State Agrarian University
- Issue: Vol 17, No 2 (2022)
- Pages: 146-157
- Section: Crop production
- URL: https://agrojournal.rudn.ru/agronomy/article/view/19761
- DOI: https://doi.org/10.22363/2312-797X-2022-17-2-146-157
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Abstract
The article gives information about the attempt made to select configurations, train and test artificial neural networks for predicting yields of grain crops considering of climate changes. Peculiarities of agricultural production require constant improvement of methods for analyzing crop yields, time series, and longterm climatic characteristics. Preliminary statistical evaluation of the considered time series made it possible to identify certain patterns. Time series were divided into four intervals: for building a network, its training, testing and control. During the construction of artificial neural networks, three models were used: MLP - multilayer perceptron, RBF - r adial basis functions and GRNN - g eneralized regression neural network. Based on the results of the construction, the best model was chosen. The sum of active air temperatures and the sum of precipitation for the growing season was used for artificial neural networks at the input, and the crop yield was used at the output. The use of sets of neural systems, generated automatically, contributed to the effective forecasting of crop yields based on the analysis of climate data. As a result, according to the selected model, a yield forecast was made for the coming years considering climatic characteristics.
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Table 1. Minimum air temperature for crop development
Crop | Growth stages | |||
Germination | Seadling emergence | Vegetative growth | Reproductive growth | |
Rice | 12…15 | 14…15 | 15 | — |
Millet | 8…10 | — | 10…12 | 16…19 |
Corn | 9…10 | 10…12 | — | 16 |
Flax | 3…4 | 6 | 8 | 15…17 |
Winter wheat | 1…4 | 4…6 | 5 | 5 |
Barley | 1…2 | 8…10 | 5 | — |
Oat | 1…2 | 4…5 | 5 | — |
Fig. 1. Dynamics of changes in active air temperature (a), °С, rainfall (b), mm, and winter wheat yield (c), c/ha
Fig. 2. Dynamics of changes in active air temperature (a), °С, rainfall (b), mm, and corn yield (c), c/ha
Table 2. List of selected networks after training
Index | Profile | Train Perf | Select Perf | Test Perf | Train Err | Select Err | Training/ Memebers | Inputs | Hidden | Hidden |
1 | MLP s5 2: | 0,482 | 1,359 | 0,114 | 0,432 | 0,368 | BP100, CG20, C | 2 | 7 | 0 |
2 | GRNN s5 2: 10—2 | 0,662 | 1,022 | 0,111 | 0,255 | 0,266 | SS | 2 | 21 | 2 |
3 | GRNN s6 2: 12—2 | 0,526 | 1,027 | 0,088 | 0,248 | 0,259 | SS | 2 | 21 | 2 |
4 | RBF s5 2: 10—2—1—1 | 0,979 | 1,004 | 0,164 | 0,243 | 0,281 | KM, KN, Pl | 2 | 2 | 0 |
5 | RBF s5 2: 10—1—1—1 | 0,965 | 1,004 | 0,162 | 0,239 | 0,289 | KM, KN, Pl | 2 | 1 | 0 |
Fig. 3. Actual and calculated winter wheat yield, c/ha
Fig. 4. The structure of building Artificial Neural Networks
Fig. 5. Productivity of winter wheat depending on climatic characteristics
About the authors
Ruslan M. Bischokov
Kabardino-Balkarian State Agrarian University
Author for correspondence.
Email: rusbis@mail.ru
ORCID iD: 0000-0001-6694-319X
Candidate of Physical and Mathematical Sciences, Associate Professor, Department of Higher Mathematics and Informatics
2v Lenin av., Nalchik, Kabardino-Balkarian Republic, 360012, Russian FederationReferences
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