ESTIMATION OF EUCALYPTUS TREE HEIGHT IN CLONAL AND PROGENY TESTS USING ARTIFICIAL NEURAL NETWORKS

Santos, Ana Carolina de Albuquerque; Almeida, Filipe Monteiro; Souza, Ramon Barreto; Chaves, Raul; Paiva, Haroldo Nogueira de; Binot, Daniel Henrique Breda; Leite, Helio Garcia; Farias, Aline Araújo

doi:10.1590/1806-90882017000600002

ABSTRACT

The goal of this study was to test the applicability of artificial neural networks for estimating tree heights in clonal tests and progenies. We used data from 8,329 clonal tests collected for six age groups, divided into six blocks and five repetitions. For the progeny tests, we used 36,793 data points, collected at age 5 and divided into ten blocks and five repetitions. The categorical input variables considered were age, treatment, and block. The diameter (dap) was used with continuous input variables. For training the networks, we used two samples. Sub-sample 1 was composed of the first tree of each block. In sub-sample 2, the tree was selected randomly within each block. This selection was made in both tests. The selected data were separated, with 70% used for training and 30% used for validation. The other unselected trees were used for generalization. For each age and treatment, we used the Kolmogorov-Smirnov (KS) test to verify the normality of the errors. The results show that ANNs can be used to estimate the heights of trees subjected to various experimental plot treatments, with no loss of accuracy or estimation precision.

Keywords:
Cost; Prediction; Experiment

RESUMO

O objetivo deste trabalho foi testar a aplicabilidade das redes neurais artificiais na estimação da altura em testes clonais e de progênies de eucalipto. Foram utilizados 8.329 dados de teste clonal, coletados em seis idades, divididos em 6 blocos e 5 repetições, e 36.793 dados para o teste de progênie, coletados em 5 idades e divididos em 10 blocos e 5 repetições. As variáveis categóricas de entrada foram a idade, o genótipo e o bloco. O diâmetro (dap) foi utilizado com variável de entrada contínua. Para definição dos dados para treinamento das redes foram utilizadas duas sub-amostras: a sub-amostra 1, composta pela primeira árvore de cada bloco e a sub-amostra 2, uma árvore foi selecionada aleatoriamente dentro de cada bloco. Essa seleção foi feita para os testes clonal e de progênies. Os dados selecionados foram separados em 70% para treinamento e 30% para a validação. As demais árvores, que não faziam parte das duas sub-amostras, foram utilizadas para a generalização. Para cada idade e tratamento foi calculado o teste kolmogorov - Smirnov (K-S) afim de verificar a normalidade dos resíduos. Os resultados demonstram que as redes podem ser usadas na estimação da altura das árvores dos diferentes genótipos presentes nos testes clonais e de progênies, sem perda da exatidão e significativa redução de custo de medição dos experimentos.

Palavras-Chave:
Custo; Predição; Experimento

1. INTRODUCTION

The evaluation of progenies and clones is the most time consuming and costly stage of forest improvement. Planning the experiments involves processes such as defining their design, location, number of families, number of blocks, data to be collected, and analysis methods (Ramalho et al., 2005Ramalho MAP, Ferreira DF, Oliveira AC. Experimentação em genética e melhoramento de plantas. 2. ed. Lavras: UFLA; 2005.). For plants with long productive cycles, such as eucalyptus, this evaluation should be done as efficiently as possible, because erroneous inferences could lead to the loss of years of work. According to Reis et al. (2011)Reis CAF, Gonçalves FMA, Rosse LN, Costa RRGF, Ramalho MAP. Correspondence between performance of Eucalyptus spp. trees selected from family and clonal tests. Genet Mol Res. 2011;10(2):1172-9. http://dx.doi.org/10.4238/vol10-2gmr1078. PMid:21732281.
http://dx.doi.org/10.4238/vol10-2gmr1078... , these tests help in the formation of more homogenous and more productive stands.

Clonal tests are conducted in the last stage of forest improvement, with the selected genotypes being planted on a commercial scale or in pilot tests (Araujo et al., 2015Araújo MJ, Dias DC, Scarpinati EA, Paula RC. Número de repetições, de plantas por parcela e de avaliações para testes clonais de eucalipto. Pesqui Agropecu Bras. 2015;50(10):923-31. http://dx.doi.org/10.1590/S0100-204X2015001000008.
http://dx.doi.org/10.1590/S0100-204X2015... ). In these tests, the heights of all trees that make up the useful area of the plots are measured (Santos et al., 2006Santos GA, Xavier A, Leite HG. Desempenho silvicultural de clones de Eucalyptus grandis em relação às matrizes. Rev Arvore. 2006;30(5):737-47. http://dx.doi.org/10.1590/S0100-67622006000500007.
http://dx.doi.org/10.1590/S0100-67622006... ). Likewise, in progeny tests, the heights of all trees are measured. When several measurements are taken, it results in a relatively large number of heights measured along a rotation. These heights are used both in early selection (Pinto et al., 2014Pinto DS, Resende RT, Mesquita AGG, Rosado AM, Cruz CD. Early selection in tests for growth traits of Eucalyptus urophylla clones test. Sci For. 2014;42(102):251-7.), and selections made at the end of the experiment (Santos et al., 2006Santos GA, Xavier A, Leite HG. Desempenho silvicultural de clones de Eucalyptus grandis em relação às matrizes. Rev Arvore. 2006;30(5):737-47. http://dx.doi.org/10.1590/S0100-67622006000500007.
http://dx.doi.org/10.1590/S0100-67622006... ), usually close to the regulatory rotation used by the company.

In a forest inventory, instead of measuring the heights of all trees in a plot, hypsometric relationships are used. The models are adjusted using data for the measured heights and diameters of some trees present in the plots. The resulting equations are applied to the other trees (Campos and Leite, 2013Campos JCC, Leite HG. Mensuração florestal: perguntas e respostas. 4. ed. Viçosa: Editora UFV; 2013.).

An alternative approach for modeling hypsometric relationships involves the application of artificial neural networks (ANNs). Binoti et al. (2012)Binoti D, Binoti MDS, Leite H, Silva A. Redução dos custos em inventário de povoamentos equiâneos utilizando redes neurais artificiais. Agraria. 2012;8(1):125-9. http://dx.doi.org/10.5039/agraria.v8i1a2209.
http://dx.doi.org/10.5039/agraria.v8i1a2... trained an ANN for different percentages of height measurement reductions in a plot, verifying the possibility of measuring the height of only 10% of the trees in the inventory plots without losing precision in the estimates. Other studies have demonstrated the efficiency of using ANN for predicting tree heights in forest inventory plots (Binoti et al., 2013Binoti DH, Binoti MLS, Leite HG, Silva A. Redução dos custos em inventário de povoamentos equiâneos. Agraria. 2013;8(1):125-129. http://dx.doi.org/10.5039/agraria.v8i1a2209.
http://dx.doi.org/10.5039/agraria.v8i1a2... ; Vendruscolo et al, 2015Vendruscolo DGS, Drescher R, Souza HS, Moura JPVM, Mamoré FMD, Siqueira TDS. Estimativa da altura de eucalipto por meio de regressão não linear e redes neurais artificiais. Revista Brasileira de Biometria. 2015;33(4):556-69., Ozçelik et al., 2013Özçelik R, Diamantopoulou MJ, Crecente-Campo F, Eler U. Estimating Crimean juniper tree height using nonlinear regression and artificial neural network models. For Ecol Manage. 2013;306:52-60. http://dx.doi.org/10.1016/j.foreco.2013.06.009.
http://dx.doi.org/10.1016/j.foreco.2013.... ), mapping natural forest biomass (Schoeninger et al., 2009Schoeninger ER, Koehler HS, Watzlawick LF, Oliveira PC Fo. Uso de redes neurais artificiais como uma alternativa para mapeamento de biomassa e carbono orgânico no componente arbóreo de florestas naturais. Ambiência. 2009;4(3):529-49.), classifying satellite images (Andrade, 2003Andrade FA. Integração de variáveis espectrais e forma na classificação de imagens de alta resolução utilizando redes neurais artificiais. Bol Ciênc Geod. 2003;9(1): 152-53.), estimating stem shapes (Schikowski et al, 2015Schikowski AB, Dalla Corte AP, Sanquetta CR. Estudo da forma do fuste utilizando redes neurais artificiais e funções de afilamento. Pesqui Florest Bras. 2015;35(82):119-27. http://dx.doi.org/10.4336/2015.pfb.35.82.867.
http://dx.doi.org/10.4336/2015.pfb.35.82... ), estimating the nutritional efficiency of eucalyptus leaves (Lafetá, 2012Lafetá BO. Eficiência nutricional, área foliar e produtividade de plantações de eucalipto em diferentes espaçamentos estimados com redes neurais artificiais [dissertação]. Diamantina: Universidade Federal dos Vales do Jequitinhonha e Mucuri; 2012.), and predicting growth and production (Alcântara, 2015Alcântara AEM. Redes neurais artificiais para prognose do crescimento e da produção de povoamentos de eucalipto em Minas Gerais [tese]. Viçosa: Universidade Federal de Viçosa; 2015.), among other applications.

Based on the results obtained for inventory height estimation, it is possible to understand the importance of evaluating ANN efficiency for research experiments in which the number of tree heights measured annually is relatively high. Therefore, this study aimed to evaluate the efficiency of an ANN used to estimate tree heights in clonal and progeny tests, and how this method reduced time and costs relative to a method of measuring the heights of 100% of trees in experimental plots.

2. MATERIALS AND METHODS

2.1. Data Description

The data used in this study were obtained from clonal and progeny tests with eucalyptus (conducted by forest companies), involving a complete rotation of approximately six years.

To train the networks to estimate heights in clonal tests, 114 treatments were used. Each treatment contained six blocks, for a total of 8,329 data points collected for six tree ages. For the progeny tests, 215 treatments were used as the basis for training the networks, each containing ten blocks, totaling 36,793 data distributed across five ages. Descriptive analyses for both tests are presented in Table 1.

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Table 1
Descriptive analysis of clonal and of progeny test data.
Tabela 1
Análise descritiva dos dados de teste de progênies e clonal.

2.2. Artificialneural networks:

To train and validate the ANN used for the clonal and progeny tests, a tree from each block was selected. In sub-sample 1, the first tree of the block was selected, while in sub-sample 2, a tree was selected randomly in each block. These sub-samples were separated, with 70% used for training and 30% used for network validation. The other unselected trees were used for ANN generalizations.

The trained networks were of the Multilayer Perceptrons (MLP) type, in which two layers (intermediate and output) process data, while only the input layer receives data (Haykin, 2001Haykin S. Redes neurais: princípios e prática. 2. ed. Porto Alegre: Bookman; 2001.). The categorical variables used in the input layer were age, treatment, and block. We used dap as a continuous input variable.

To train the networks, we used the application Neuroforet 3.3 and a resilient propagation (RPROP+) type algorithm, which adapts weight updates according to the behavior of the error function (Riedmiller; Braun, 1993Riedmiller M, Braun H. A direct adaptive method for faster backpropation learning: the RPROP algorithm. In: Proceedings of IEEE International Conference on Neural Networks; 1993 Mar-Apr 28-1; San Francisco. San Francisco: IEEE; 1993. p. 586-591. http://dx.doi.org/10.1109/ICNN.1993.298623.
http://dx.doi.org/10.1109/ICNN.1993.2986... ). As a criterion for stopping training, the following parameters were adopted: number of cycles equal to 3000, or average error equal to 0.0001. Numerical data were normalized on a 0 to 1 scale. These parameters were defined based on previous studies of the estimation of the height of eucalyptus trees in forest inventory plots (Silva, 2012Silva MLMS. Emprego de redes neurais artificiais em mensuração e manejo florestal [dissertação]. Viçosa: Universidade Federal de Viçosa; 2012.).

Five networks were trained, and the best network was selected based on the following statistics, calculated for each set (training, validation, and generalization): correlation between observed heights and estimated correspondents (r_ŷy), standard deviation of mean percentage error (S_ȳ), and histogram of residuals, calculated as follows:

r_{\hat{yy}} = \frac{n^{- 1} (\sum_{i = 1}^{n} ({\hat{y}}_{i} - {\hat{y}}_{m}) (y_{i} - \overset{─}{y}))}{\sqrt{(n^{- 1} \sum_{i = 1}^{n} {({\hat{y}}_{i} - {\hat{y}}_{m})}^{2}) (n^{- 1} \sum_{i = 1}^{n} {(y_{i} - \overset{─}{y})}^{2})}} S \overset{─}{y} = \pm \sqrt{\frac{S^{2}}{n}} Re sidue (%) = \frac{y_{i} - {\hat{y}}_{i}}{y_{i}} . 100

Where

y_i e ŷ_i = observed and estimated values of the variable under analysis;

ŷ_m e ȳ = estimated and observed mean value;

n = number of cases;

S² = sample variance.

The histogram graphs for the training, validation, and generalization of the networks were analyzed, considering a range of class of 5%.

The chosen ANN was evaluated for each combination of age and treatment, based on the Kolmogorov-Smirnov (K-S) test for the normality of residuals. Training, validation and generalization estimates were grouped so that the treatments were complete in relation to the number of trees sampled. Because of the large number of treatments in both tests, the p-values were grouped in intervals, and the percentage of treatments with values higher than 0.05 was defined. Thus, the greater the number of treatments with residual normality, the more accurate the network was at estimating the tree heights for different treatments.

3. RESULTS

Considering the two sub-samples, most of the training estimate errors in both tests varied by an average of 5%, with a trend of non-normality in the residuals, as observed in the histogram graphs in Figures 1 and 2.

Figure 1
Standard error, correlation between estimated and observed values, and histogram graphics generated with estimated data in the training, validation and generalization of the clonal test with sub-samples 1 and 2. X-axis shows the residue classes by percentage, y-axis shows the observed frequencies for each class.
Figura 1
Erro padrão, correlação entre os valores estimados e observados e gráficos de histograma das estimativas geradas pela RNA no treinamento, validação e generalização do teste clonal com as sub-amostras 1 e 2. No eixo x dos gráficos de histograma são apresentadas as classes de resíduo em %, no eixo y as frequências observadas em cada classe.

Figure 2
Standard error, correlation between estimated and observed values, and histogram graphics generated with estimated data in the training, validation, and generalization of the progeny test with sub-samples 1 and 2. X-axis shows the residue classes by percentage, y-axis shows the observed frequencies for each class.
Figura 2
Erro padrão, correlação entre os valores estimados e observados e gráficos de histograma das estimativas geradas pela RNA no treinamento, validação e generalização do teste de progênie com as sub-amostras 1 e 2. No eixo x dos gráficos de histograma são apresentadas as classes de resíduo em %, no eixo y as frequências observadas em cada classe.

The two methods of selecting trees within a block for training the network were compared, based on the generalization and normality statistics of the residuals for each treatment. Histogram plots for the ANN generalization estimates in the clonal test for sub-samples 1 and 2 showed 89% and 87% of residuals, ranging from an average of 10% (Figure 1) respectively. In the progeny test, 74% and 73% of the residuals obtained by estimates of the trained network generalization with sub-samples 1 and 2 varied by an average of 10%, respectively (Figure 2). The validation estimates were similar to the generalizations in both tests and subsamples (Figures 1 and 2).

Table 2 shows the p-values of the K-S test for verifying the normality of residuals for the combination of 1) age and treatment, and 2) sub-sample and test, grouped into intervals of 0.05. The normality of residuals was verified in 99% of clonal test treatments, when sub-sample 1 was used to train the networks. The random selection of data for network training was less precise, with 97% of the treatments presenting normality in the residuals. In the progeny test, the normality of residuals was observed in 99% of the treatments in both sub-samples.

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Table 2
K–S test for every age and treatment, sub-sample, and test. p-values greater than 0.05 indicates normal errors in the treatments.
Tabela 2
Teste Kolmogorov - Smirnov (K-S) para cada idade e tratamento, sub-amostra e teste. Os p-valores maiores que 0,05 indicam normalidade dos resíduos nos tratamentos.

Table 3 shows the time taken to measure the heights in the database, represented by days saved (based on an 8 h working day).

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Table 3
Time savings of measuring 40% of heights
Tabela 3
Economia de tempo mensurando 40% das alturas.

4. DISCUSSION

For both tests, the errors varied by an average of 10%, showing that the results generated by ANN were satisfactory. Both the relatively high correlation estimates between the data sets and the high percentage of treatments with normality in the residuals show that the networks were able to estimate tree heights in the experimental plots with sufficient accuracy for most of the treatments and all of the age ranges present in the database. The efficiency of neural networks for height estimation has already been demonstrated for forest inventories (where several categorical, edaphic, physiographic, and climatic variables are included) and forest inventory records (Binoti et al., 2012Binoti D, Binoti MDS, Leite H, Silva A. Redução dos custos em inventário de povoamentos equiâneos utilizando redes neurais artificiais. Agraria. 2012;8(1):125-9. http://dx.doi.org/10.5039/agraria.v8i1a2209.
http://dx.doi.org/10.5039/agraria.v8i1a2... ; Ozçelik et al., 2013Özçelik R, Diamantopoulou MJ, Crecente-Campo F, Eler U. Estimating Crimean juniper tree height using nonlinear regression and artificial neural network models. For Ecol Manage. 2013;306:52-60. http://dx.doi.org/10.1016/j.foreco.2013.06.009.
http://dx.doi.org/10.1016/j.foreco.2013.... ).

When analyzing the results of the normality tests, we verified that for a few treatments, the network did not accurately estimate heights. The highest errors were found for trees of lower heights, increasing the efficiency of the method, because these types of experiments aim to confirm superior characteristics, such as resistance to pests and diseases, density, natural pruning, volume diameter, etc. (Ferreira, 1992Ferreira M. Melhoramento e a silvicultura intensiva clonal. Scientia Florestalis. 1992;45:22-30.).

The highest treatment percentages in clonal tests with normality in the residuals were observed in the estimates obtained by networks trained with the first tree of the block (sub-sample 1). In the progeny test, there were no differences in terms of ANN training between selecting the first tree of the block or selecting a random tree. Therefore, we recommend that the first tree of each block be measured, so that the operating procedure is simpler for operators.

Given the efficiency estimating heights in experimental plots using ANNs, it is possible to analyze the time gains produced by measuring the height of only one replicate in each block for each genotype (20% of the data). This means that individual estimation would no longer be needed for 6,663 trees in clonal tests and 29,434 trees in progeny tests.

Considering that on average, a measurer spends 1 min measuring and recording the height of a tree (without considering worker displacement), this means a time savings of 6,663 min (or 111.05 h or 13.88 working days (8 h/day)) when measuring tree heights in clonal tests. In progeny tests the time savings are even greater, with savings of 29.434 min (or 490 h or 61.32 working days (8 h/day)) are saved. These time and labor savings represent a significant reduction in the time required to measure experimental plots, which would lead to a significant reduction in research costs.

When training and applying neural networks for a specific year, age could be eliminated in the input layer. Another potential application that could be tested by users, using the configuration proposed in this study, is to train networks with one year of data and apply the process to another year, generalizing the heights of all trees on the second occasion. This application might be necessary if in a given year, for economic reasons, it is necessary to significantly reduce research measurement costs. This alternative was not tested in the present study, because the aim was to construct, propose, apply, and demonstrate the efficiency of neural networks in estimating height in the case of experimental measurement. We found that by measuring only one height per replicate, it is possible to accurately generalize the heights of other trees with accuracy.

5. CONCLUSIONS

Artificial neural networks are efficient at estimating height in clonal and progeny tests. They allow a reduction in working time in the measurement of experimental plots, and consequently a reduction in research costs, without losing measurement accuracy.

By measuring the height of only the first tree of each treatment replicate (genotypes), in clonal and progeny tests, the heights of the other trees can be estimated with sufficient accuracy.

6. REFERENCES

Alcântara AEM. Redes neurais artificiais para prognose do crescimento e da produção de povoamentos de eucalipto em Minas Gerais [tese]. Viçosa: Universidade Federal de Viçosa; 2015.
Andrade FA. Integração de variáveis espectrais e forma na classificação de imagens de alta resolução utilizando redes neurais artificiais. Bol Ciênc Geod. 2003;9(1): 152-53.
Araújo MJ, Dias DC, Scarpinati EA, Paula RC. Número de repetições, de plantas por parcela e de avaliações para testes clonais de eucalipto. Pesqui Agropecu Bras. 2015;50(10):923-31. http://dx.doi.org/10.1590/S0100-204X2015001000008
» http://dx.doi.org/10.1590/S0100-204X2015001000008
Binoti D, Binoti MDS, Leite H, Silva A. Redução dos custos em inventário de povoamentos equiâneos utilizando redes neurais artificiais. Agraria. 2012;8(1):125-9. http://dx.doi.org/10.5039/agraria.v8i1a2209
» http://dx.doi.org/10.5039/agraria.v8i1a2209
Binoti DH, Binoti MLS, Leite HG, Silva A. Redução dos custos em inventário de povoamentos equiâneos. Agraria. 2013;8(1):125-129. http://dx.doi.org/10.5039/agraria.v8i1a2209
» http://dx.doi.org/10.5039/agraria.v8i1a2209
Campos JCC, Leite HG. Mensuração florestal: perguntas e respostas. 4. ed. Viçosa: Editora UFV; 2013.
Ferreira M. Melhoramento e a silvicultura intensiva clonal. Scientia Florestalis. 1992;45:22-30.
Haykin S. Redes neurais: princípios e prática. 2. ed. Porto Alegre: Bookman; 2001.
Lafetá BO. Eficiência nutricional, área foliar e produtividade de plantações de eucalipto em diferentes espaçamentos estimados com redes neurais artificiais [dissertação]. Diamantina: Universidade Federal dos Vales do Jequitinhonha e Mucuri; 2012.
Özçelik R, Diamantopoulou MJ, Crecente-Campo F, Eler U. Estimating Crimean juniper tree height using nonlinear regression and artificial neural network models. For Ecol Manage. 2013;306:52-60. http://dx.doi.org/10.1016/j.foreco.2013.06.009
» http://dx.doi.org/10.1016/j.foreco.2013.06.009
Pinto DS, Resende RT, Mesquita AGG, Rosado AM, Cruz CD. Early selection in tests for growth traits of Eucalyptus urophylla clones test. Sci For. 2014;42(102):251-7.
Ramalho MAP, Ferreira DF, Oliveira AC. Experimentação em genética e melhoramento de plantas. 2. ed. Lavras: UFLA; 2005.
Reis CAF, Gonçalves FMA, Rosse LN, Costa RRGF, Ramalho MAP. Correspondence between performance of Eucalyptus spp. trees selected from family and clonal tests. Genet Mol Res. 2011;10(2):1172-9. http://dx.doi.org/10.4238/vol10-2gmr1078 PMid:21732281.
» http://dx.doi.org/10.4238/vol10-2gmr1078
Riedmiller M, Braun H. A direct adaptive method for faster backpropation learning: the RPROP algorithm. In: Proceedings of IEEE International Conference on Neural Networks; 1993 Mar-Apr 28-1; San Francisco. San Francisco: IEEE; 1993. p. 586-591. http://dx.doi.org/10.1109/ICNN.1993.298623
» http://dx.doi.org/10.1109/ICNN.1993.298623
Santos GA, Xavier A, Leite HG. Desempenho silvicultural de clones de Eucalyptus grandis em relação às matrizes. Rev Arvore. 2006;30(5):737-47. http://dx.doi.org/10.1590/S0100-67622006000500007
» http://dx.doi.org/10.1590/S0100-67622006000500007
Schikowski AB, Dalla Corte AP, Sanquetta CR. Estudo da forma do fuste utilizando redes neurais artificiais e funções de afilamento. Pesqui Florest Bras. 2015;35(82):119-27. http://dx.doi.org/10.4336/2015.pfb.35.82.867
» http://dx.doi.org/10.4336/2015.pfb.35.82.867
Schoeninger ER, Koehler HS, Watzlawick LF, Oliveira PC Fo. Uso de redes neurais artificiais como uma alternativa para mapeamento de biomassa e carbono orgânico no componente arbóreo de florestas naturais. Ambiência. 2009;4(3):529-49.
Silva MLMS. Emprego de redes neurais artificiais em mensuração e manejo florestal [dissertação]. Viçosa: Universidade Federal de Viçosa; 2012.
Vendruscolo DGS, Drescher R, Souza HS, Moura JPVM, Mamoré FMD, Siqueira TDS. Estimativa da altura de eucalipto por meio de regressão não linear e redes neurais artificiais. Revista Brasileira de Biometria. 2015;33(4):556-69.

Publication Dates

Publication in this collection
14 June 2018
Date of issue
2017

History

Received
18 Apr 2016
Accepted
28 June 2017

This is an Open Access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

[1] Alcântara AEM. Redes neurais artificiais para prognose do crescimento e da produção de povoamentos de eucalipto em Minas Gerais [tese]. Viçosa: Universidade Federal de Viçosa; 2015.

[2] Andrade FA. Integração de variáveis espectrais e forma na classificação de imagens de alta resolução utilizando redes neurais artificiais. Bol Ciênc Geod. 2003;9(1): 152-53.

[3] Araújo MJ, Dias DC, Scarpinati EA, Paula RC. Número de repetições, de plantas por parcela e de avaliações para testes clonais de eucalipto. Pesqui Agropecu Bras. 2015;50(10):923-31. http://dx.doi.org/10.1590/S0100-204X2015001000008
» http://dx.doi.org/10.1590/S0100-204X2015001000008

[4] Binoti D, Binoti MDS, Leite H, Silva A. Redução dos custos em inventário de povoamentos equiâneos utilizando redes neurais artificiais. Agraria. 2012;8(1):125-9. http://dx.doi.org/10.5039/agraria.v8i1a2209
» http://dx.doi.org/10.5039/agraria.v8i1a2209

[5] Binoti DH, Binoti MLS, Leite HG, Silva A. Redução dos custos em inventário de povoamentos equiâneos. Agraria. 2013;8(1):125-129. http://dx.doi.org/10.5039/agraria.v8i1a2209
» http://dx.doi.org/10.5039/agraria.v8i1a2209

[6] Campos JCC, Leite HG. Mensuração florestal: perguntas e respostas. 4. ed. Viçosa: Editora UFV; 2013.

[7] Ferreira M. Melhoramento e a silvicultura intensiva clonal. Scientia Florestalis. 1992;45:22-30.

[8] Haykin S. Redes neurais: princípios e prática. 2. ed. Porto Alegre: Bookman; 2001.

[9] Lafetá BO. Eficiência nutricional, área foliar e produtividade de plantações de eucalipto em diferentes espaçamentos estimados com redes neurais artificiais [dissertação]. Diamantina: Universidade Federal dos Vales do Jequitinhonha e Mucuri; 2012.

[10] Özçelik R, Diamantopoulou MJ, Crecente-Campo F, Eler U. Estimating Crimean juniper tree height using nonlinear regression and artificial neural network models. For Ecol Manage. 2013;306:52-60. http://dx.doi.org/10.1016/j.foreco.2013.06.009
» http://dx.doi.org/10.1016/j.foreco.2013.06.009

[11] Pinto DS, Resende RT, Mesquita AGG, Rosado AM, Cruz CD. Early selection in tests for growth traits of Eucalyptus urophylla clones test. Sci For. 2014;42(102):251-7.

[12] Ramalho MAP, Ferreira DF, Oliveira AC. Experimentação em genética e melhoramento de plantas. 2. ed. Lavras: UFLA; 2005.

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Test	Block	Number of trees	Diameter (cm)			Height (m)
		Number of trees	Minimum	Mean	Maximum	Minimum	Mean	Minimum
Progeny	1	3709	4.5	12.5	25.6	4.5	18.6	31
	2	3774	3.5	12	24.5	3.5	17.8	32
	3	3755	2.5	12.2	25	2.5	18.3	31.5
	4	3762	2.5	12.3	24.8	2.5	18.2	31
	5	3655	3	12.5	25.4	3	18.7	31.5
	6	3580	2	12.4	26	2	18.5	31.5
	7	3676	4.5	12.1	25.5	4.5	18.6	31.5
	8	3687	4	12.1	26.8	4	18	32
	9	3662	4.5	12.1	27.7	4.5	18.8	32
	10	3533	4	12.4	26.6	4	18.5	33
Clonal	1	1446	4	11.8	21.1	4	18.6	31
	2	1317	4	11.8	23.1	4.5	17.7	30.5
	3	1456	4	11.7	24.1	7	18	29.5
	4	1409	4	11.9	24.4	6.5	17.7	30.5
	5	1381	4	11.8	22.8	6	18	28.5
	6	1320	4	12.1	25.5	8	17.9	30

Test	Data Selection	Age	K-S Test						Total treatments
Test	Data Selection	Age	p<0.01	p<0 .05	p<0.10	p<0 .15	p<0 .20	p>0.20	Total treatments
		2. 02		2			3	99	104
		3.35						4	4
	Random	3.96		4	2	3	4	91	104
	Random	5.06						3	3
		5.94		1		1		102	104
Clonal		5.95		2	1	2	1	98	104
Clonal		2. 02			1	4	3	96	104
		3.35						4	4
	Tree 1	3.96		2	7	5	2	88	104
	Tree 1	5.06						3	3
		5.94						104	104
		5.95		1	2	5	2	94	104
		2. 01		3	2	4	8	198	215
		3.1		2	3	6	4	200	215
	Random	3.13				2	3	210	215
		3.98	1	2	8	7	7	190	215
Progeny		5.33		5	6	7	6	191	215
Progeny		2. 01		2	6	4	3	200	215
		3.1		1	2	5	10	197	215
	Tree 1	3.13		1			2	212	215
		3.98	1	3	2	3	9	197	215
		5.33	2	3	4	5	7	194	215

Repetition	Time spent (h)			Workdayssaved (8 h/day)
	1	2, 3,4 and 5	Total
Clonal Test	54.8	84	138.7	10.5
Progeny Test	248.6	363.3	611.9	45.5

Brasil

Brasil

ESTIMATION OF EUCALYPTUS TREE HEIGHT IN CLONAL AND PROGENY TESTS USING ARTIFICIAL NEURAL NETWORKS

ESTIMAÇÃO DA ALTURA DE ÁRVORES DE EUCALIPTO EM TESTES CLONAIS E DE PROGÊNIES UTILIZANDO REDES NEURAIS ARTIFICIAIS

ABSTRACT

RESUMO

1. INTRODUCTION

2. MATERIALS AND METHODS

2.1. Data Description

2.2. Artificialneural networks:

3. RESULTS

4. DISCUSSION

5. CONCLUSIONS

6. REFERENCES

Publication Dates

History