Ganoderma boninense Disease Detection by Near-Infrared Spectroscopy Classification: A Review
Abstract
:1. Introduction
2. Spectroscopy Technique for Ganoderma boninense Detection
3. Near-Infrared Spectroscopy
3.1. Theory and Operating Principle
3.2. Advantages of Near-Infrared Spectroscopy
3.3. Disadvantages of Near-Infrared Spectroscopy
4. Application of NIRS for Plant Disease Detection
5. Machine Learning Techniques for Plant Disease Prediction
- k-nearest neighbour (kNN);
- Naïve Bayes (NB);
- Decision tree (DT)—random forest and decision forest;
- Artificial neural network (ANN);
- Support vector machine (SVM).
6. Challenges and Future Prospects
7. Conclusions
Funding
Institutional Review Board Statement
Informed Consent Statement
Data Availability Statement
Acknowledgments
Conflicts of Interest
References
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Disease Detection in Plants | ||||
---|---|---|---|---|
Physical Inspection | Serological Methods | Molecular Methods | Biomarker-Based Sensors | Remote Sensing |
Visually, based on external symptoms [24] | Flow cytometry [25] | Fluorescence in situ hybridisation (FISH) [26] | Gaseous metabolite profiling [27] | Imaging techniques [28] |
Enzyme-linked immunosorbent assay (ELISA) [29] | Polymerase chain reaction (PCR) [30] | Plant metabolite profiling [31] | Spectroscopy techniques [32] | |
Immunofluorescence [33] | DNA arrays [34] |
Spectroscopy Method | Instrument | Sample Grouping | Models/Algorithms | Significant Result | References |
---|---|---|---|---|---|
Dielectric spectroscopy | Solid dielectric test fixture + impedance analyser | Healthy Mild Moderate Severe | SVM, ANN | Overall classification accuracies of the impedance values are more than 80% | [54] |
Healthy Mild Moderate Severe | LDA, QDA, kNN and NB | Mean classification accuracy: LDA: 80.34% QDA: 80.79% kNN: 77.85% NB: 79.98% Impedance value overall accuracy: 95.45% | [55] | ||
Mass spectroscopy | GC-MS | Healthy Infected | PCA | The metabolite variation of healthy and infected oil palm root is identified | [52] |
NMR spectroscopy | NMR spectrometer | Healthy Infected | PCA | The metabolite variation of healthy and infected oil palm leaves is identified | [53] |
FTIR spectroscopy | FTIR spectrometer | Ganoderma basidiomata | - | CH3, CN and C-O-C functional groups are identified in the G. boninense basidiomata tissue. | [58] |
FTIR spectroscopy | FTIR spectrometer | Healthy Infected | - | Resemblance pattern of infected oil palm with pure G. boninense is observed at a particular wavelength which can be used as biomarker | [56] |
G. boninense contents as low as 5% were detected | [57] | ||||
N-H, C=N, C=H and C-O-C functional groups are identified in the G. boninense infected oil palm tissue | [64] | ||||
MIR spectroscopy | FTIR Spectrometer | Healthy Mild Moderate Severe | LDA, QDA, kNN and NB | The highest overall classification performance using LDA: 92% accuracy | [59] |
VIS-NIR spectroscopy | Spectroradiometer | Healthy Mild Severe | Maximum likelihood | 82% classification accuracy | [60] |
VIS-NIR spectroscopy | Spectroradiometer | Healthy Mild Moderate Severe | ANN | Up to 100% classification accuracy without any pre-processing methods | [61] |
VIS-NIR spectroscopy | Spectroradiometer | Healthy Mild Moderate Severe | LDA, QDA, kNN and NB | kNN has the highest classification performance: 97.3% accuracy Significant differences between each severity levels are observed in NIR region compared to VIS region | [46] |
VIS-NIR spectroscopy | Spectroradiometer | Healthy Mild Moderate Severe | PLS-DA | Almost 94% classification accuracy | [65] |
Functional Group | Found in |
---|---|
Hydroxyl (OH) | Water/Moisture, Carbohydrates, Sugars, Alcohols, Glycols |
Amino (NH2) | Proteins, Polymers, Dyes, Pharmaceuticals |
Alkyl/Aryl (C-H) Aliphatic and Aromatic Hydrocarbons | Fats/Lipids, Fuels, Plastics, Polymers |
IR Spectroscopy Region | Accuracy Range for Detection of Plant Disease |
---|---|
VIS-NIR | 66–90% |
NIR | 90–96% |
MIR | 79–92% |
Plant | Disease | Instrument | Wavelength (nm) | Models/Algorithms | Significant Result | Ref |
---|---|---|---|---|---|---|
Agaricus bisporus | Fungal contamination | FT-NIR spectrometer | 833–2500 | PLS-DA | Fungal species: 99% classification accuracy Storage period: 99.2% classification accuracy | [87] |
Papaya | Begomovirus infection | NIR spectrophotometer | 1000–2500 | PLS-DA | Calibration: R2 = 0.964 Validation: R2 = 0.957 | [79] |
Potato | Zebra chip disease | NIR spectrophotometer | 900–2600 | Canonical DA | Raw spectra: 98.35% classification accuracy 2nd derivative spectra: 97.25% classification accuracy | [88] |
Wheat | Stripe rust | FT-NIR spectrometer | 833–2500 | QPLS, SVR, QPLS+SVR | R2 > 0.5 for all models | [89] |
Honeycrisp apple | Bitter pit | Spectroradiometer | 800–2500 | QDA, SVM | QDA: 73–96% classification accuracy SVM: 69–89% classification accuracy | [90] |
Mango | Anthracnose disease | FT-NIR spectrometer | 900–2500 | PLS-DA | 89% classification accuracy | [91] |
Mango | Fruit fly eggs and larval infestation | NIRGun and the Bran + Luebbe InfraAlyzer 500 | 700–950 1100–2500 | PLS-DA | 700–950 Infested fruit: SD = 0.27 Control fruit: SD = 0.19 1100–2500 Infested fruit: SD = 0.26 Control fruit: SD = 0.28 | [92] |
Maize | Fungal infection | NIR spectrometer | 500–1700 | kNN | Healthy kernels: 98.1% classification accuracy Infected kernels: 96.6% classification accuracy | [93] |
Maize | Fusarium infection | NIR spectrophotometer | 400–2500 | SIMCA, PNN, k-means | PNN has the best performance Healthy grain: 99.3% classification accuracy Infected grain: 98.7% classification accuracy | [94] |
Maize | Fungal infection | NIR spectrometer | 904–1685 | LDA, MLP neural networks | Uninfected control kernels: 89% classification accuracy Infected kernels: 79% classification accuracy | [95] |
Chestnut | Fungal infection | NIR analyser | 1100–2300 | LDA, QDA, kNN | The highest overall classification using QDA: 97% accuracy | [96] |
Barley | Fusarium infection | NIR spectrometer | 1175–2170 | PLS-DA | Up to 100% classification accuracy | [80] |
Almond | Fungal infection | VIS-NIR spectrophotometer | 800–2500 | Canonical DA | Cross-validation error rate = 0.26% False negative error = 0 | [67] |
Tomato | Leaf miner infestation | FT-NIR spectrometer | 800–2500 | Regression analysis | R2 = 0.982 | [97] |
Sugarcane | Fiji leaf gall | NIR spectrometer | 909–2500 | PLS | SEV = 0.98 (R2 = 0.97) SEP =1.20 (R2 = 0.88) | [98] |
Rice | Aflatoxin B1 contamination | FT-NIR spectrometer | 1000–2500 | PLS | Correlation, R = 0.850, SEP = 3.211% | [99] |
Red paprika | Aflatoxin B1 and ochratoxin A contamination | NIR spectrophotometer | 1100–2000 | MPLS | AFB1: R2 = 0.95 OTA: R2 = 0.85 Total aflatoxins: R2 = 0.93 | [100] |
Classifier | Advantages | Disadvantages |
---|---|---|
kNN | Simple implementation Classes do not have to be linearly separable | Sensitive to noisy or irrelevant data Testing procedure is time-consuming because of calculation of distance to all known instances |
NB | Only a small amount of training data is required Has better speed | It cannot learn interactions between different features because dependency exists among variables |
Decision tree | Easy to interpret for small trees Accuracy is comparable to other classification techniques for many simple datasets | Decision tree has been observed to overfit for some datasets with noisy classification tasks Restricted to one output attribute Complex decision tree for numeric datasets |
ANN | Robust and user friendly and can handle noisy data Well suited to analysing complex problems | Scalability problem Requires large number of training samples Requires more processing time |
SVM | Effective and robust to noise Highly accurate Can handle many features | Not suitable for large datasets Speed is slow and requires more time to process |
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Mohd Hilmi Tan, M.I.S.; Jamlos, M.F.; Omar, A.F.; Dzaharudin, F.; Chalermwisutkul, S.; Akkaraekthalin, P. Ganoderma boninense Disease Detection by Near-Infrared Spectroscopy Classification: A Review. Sensors 2021, 21, 3052. https://doi.org/10.3390/s21093052
Mohd Hilmi Tan MIS, Jamlos MF, Omar AF, Dzaharudin F, Chalermwisutkul S, Akkaraekthalin P. Ganoderma boninense Disease Detection by Near-Infrared Spectroscopy Classification: A Review. Sensors. 2021; 21(9):3052. https://doi.org/10.3390/s21093052
Chicago/Turabian StyleMohd Hilmi Tan, Mas Ira Syafila, Mohd Faizal Jamlos, Ahmad Fairuz Omar, Fatimah Dzaharudin, Suramate Chalermwisutkul, and Prayoot Akkaraekthalin. 2021. "Ganoderma boninense Disease Detection by Near-Infrared Spectroscopy Classification: A Review" Sensors 21, no. 9: 3052. https://doi.org/10.3390/s21093052
APA StyleMohd Hilmi Tan, M. I. S., Jamlos, M. F., Omar, A. F., Dzaharudin, F., Chalermwisutkul, S., & Akkaraekthalin, P. (2021). Ganoderma boninense Disease Detection by Near-Infrared Spectroscopy Classification: A Review. Sensors, 21(9), 3052. https://doi.org/10.3390/s21093052