Attempting to Estimate the Unseen—Correction for Occluded Fruit in Tree Fruit Load Estimation by Machine Vision with Deep Learning

Koirala, Anand; Walsh, Kerry B.; Wang, Zhenglin

doi:10.3390/agronomy11020347

Cited by 25 publications

(8 citation statements)

References 21 publications

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“…For example, Sarron et al [9] described the use of a human expert to categorize fruit load density to one of four classes as one input to a model for fruit load estimation. Koirala et al [12] described a machine vision-based classification of canopy images to three crop load densities using a 'Xception_classification' model and a Silhouette score as a first step in a pipeline for a machine vision-based estimation of tree fruit load (see later sections).…”

Section: Tree Evaluation and Historical Knowledgementioning

confidence: 99%

“…For the prediction of fruit load in a different season to that used for model training, the RMSE and R 2 between estimated and harvested apple yield were 2.6 kg/tree and 0.62 for early fruit growth (small, green fruit) and 2.5 kg/tree and 0.75 near harvest (red, large fruit), for trees with an average 18 kg of fruit. In a later attempt in the direct prediction of total tree fruit load, deep learning techniques were employed [12], and good predictions of current season tree fruit loads were achieved, but predictions of fruit load per tree for a subsequent season were poor. Further work should be undertaken to progress this concept.…”

Section: Implementation On Ground Vehiclesmentioning

confidence: 99%

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Technologies for Forecasting Tree Fruit Load and Harvest Timing—From Ground, Sky and Time

Anderson

Walsh

Wulfsohn³

2021

Agronomy

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The management and marketing of fruit requires data on expected numbers, size, quality and timing. Current practice estimates orchard fruit load based on the qualitative assessment of fruit number per tree and historical orchard yield, or manually counting a subsample of trees. This review considers technological aids assisting these estimates, in terms of: (i) improving sampling strategies by the number of units to be counted and their selection; (ii) machine vision for the direct measurement of fruit number and size on the canopy; (iii) aerial or satellite imagery for the acquisition of information on tree structural parameters and spectral indices, with the indirect assessment of fruit load; (iv) models extrapolating historical yield data with knowledge of tree management and climate parameters, and (v) technologies relevant to the estimation of harvest timing such as heat units and the proximal sensing of fruit maturity attributes. Machine vision is currently dominating research outputs on fruit load estimation, while the improvement of sampling strategies has potential for a widespread impact. Techniques based on tree parameters and modeling offer scalability, but tree crops are complicated (perennialism). The use of machine vision for flowering estimates, fruit sizing, external quality evaluation is also considered. The potential synergies between technologies are highlighted.

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Section: Tree Evaluation and Historical Knowledgementioning

confidence: 99%

Section: Implementation On Ground Vehiclesmentioning

confidence: 99%

Technologies for Forecasting Tree Fruit Load and Harvest Timing—From Ground, Sky and Time

Anderson

Walsh

Wulfsohn³

2021

Agronomy

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“…Use of the multi-view machine vision estimate There remains a need to develop better tools for estimation of an occlusion factor for a given orchard. Koirala et al [16] unsuccessfully attempted estimation of a per tree occlusion factor based on machine vision features such as the proportion of partly occluded to non-occluded fruit. A random forest model on the ratio of machine vision to packhouse count using inputs of various orchard attributes explained only 39% of the variance in the ratio, with 10, 8, 6, 4 and 3% attributed to tree age, SD of tree crown area, mean of tree crown area row spacing and tree spacing, respectively (Appendix B).…”

Section: Methods Comparisons 2019-2020mentioning

confidence: 99%

“…The sum of the manual fruit count for 18 trees in each orchard was regressed to the MangoYOLO pipeline count of fruit in the two images for these trees to estimate an 'occlusion factor' for each orchard. This correction factor was then applied to the machine vision count of all other trees, following the approach of Koirala et al [16].…”

Section: Machine Vision Systemmentioning

confidence: 99%

Estimation of Fruit Load in Australian Mango Orchards Using Machine Vision

et al. 2021

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The performance of a multi-view machine vision method was documented at an orchard level, relative to packhouse count. High repeatability was achieved in night-time imaging, with an absolute percentage error of 2% or less. Canopy architecture impacted performance, with reasonable estimates achieved on hedge, single leader and conventional systems (3.4, 5.0, and 8.2 average percentage error, respectively) while fruit load of trellised orchards was over-estimated (at 25.2 average percentage error). Yield estimations were made for multiple orchards via: (i) human count of fruit load on ~5% of trees (FARM), (ii) human count of 18 trees randomly selected within three NDVI stratifications (CAL), (iii) multi-view counts (MV-Raw) and (iv) multi-view corrected for occluded fruit using manual counts of CAL trees (MV-CAL). Across the nine orchards for which results for all methods were available, the FARM, CAL, MV-Raw and MV-CAL methods achieved an average percentage error on packhouse counts of 26, 13, 11 and 17%, with SD of 11, 8, 11 and 9%, respectively, in the 2019–2020 season. The absolute percentage error of the MV-Raw estimates was 10% or less in 15 of the 20 orchards assessed. Greater error in load estimation occurred in the 2020–2021 season due to the time-spread of flowering. Use cases for the tree level data on fruit load was explored in context of fruit load density maps to inform early harvesting and to interpret crop damage, and tree frequency distributions based on fruit load per tree.

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“…In cases where the number of samples is limited and a CNN-based machine learning algorithm is used, the success of the network is low. To increase the performance of the network, many samples are needed [35]. To increase the number of samples, synthetic images can be generated by using 3D models and game engines.…”

Section: Related Workmentioning

confidence: 99%

Real UAV-Bird Image Classification Using CNN with a Synthetic Dataset

Öztürk

Erçelebi

2021

Applied Sciences

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A large amount of training image data is required for solving image classification problems using deep learning (DL) networks. In this study, we aimed to train DL networks with synthetic images generated by using a game engine and determine the effects of the networks on performance when solving real-image classification problems. The study presents the results of using corner detection and nearest three-point selection (CDNTS) layers to classify bird and rotary-wing unmanned aerial vehicle (RW-UAV) images, provides a comprehensive comparison of two different experimental setups, and emphasizes the significant improvements in the performance in deep learning-based networks due to the inclusion of a CDNTS layer. Experiment 1 corresponds to training the commonly used deep learning-based networks with synthetic data and an image classification test on real data. Experiment 2 corresponds to training the CDNTS layer and commonly used deep learning-based networks with synthetic data and an image classification test on real data. In experiment 1, the best area under the curve (AUC) value for the image classification test accuracy was measured as 72%. In experiment 2, using the CDNTS layer, the AUC value for the image classification test accuracy was measured as 88.9%. A total of 432 different combinations of trainings were investigated in the experimental setups. The experiments were trained with various DL networks using four different optimizers by considering all combinations of batch size, learning rate, and dropout hyperparameters. The test accuracy AUC values for networks in experiment 1 ranged from 55% to 74%, whereas the test accuracy AUC values in experiment 2 networks with a CDNTS layer ranged from 76% to 89.9%. It was observed that the CDNTS layer has considerable effects on the image classification accuracy performance of deep learning-based networks. AUC, F-score, and test accuracy measures were used to validate the success of the networks.

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Attempting to Estimate the Unseen—Correction for Occluded Fruit in Tree Fruit Load Estimation by Machine Vision with Deep Learning

Cited by 25 publications

References 21 publications

Technologies for Forecasting Tree Fruit Load and Harvest Timing—From Ground, Sky and Time

Technologies for Forecasting Tree Fruit Load and Harvest Timing—From Ground, Sky and Time

Estimation of Fruit Load in Australian Mango Orchards Using Machine Vision

Real UAV-Bird Image Classification Using CNN with a Synthetic Dataset

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