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YOLOv8n-SSND: An Improved Lightweight Model for Aerial Chenopodium Chenopodium quinoa Willd. Spike Target
Smart Agriculture 2026, 8(2): 59-71
Published: 01 March 2026
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Objective

The Chenopodium quinoa panicle is a critical phenotypic indicator for estimating crop yield and evaluating the growth condition of Chenopodium quinoa plants. Accurate and efficient recognition of Chenopodium quinoa panicles in complex field environments is therefore of great significance for intelligent agriculture, yield prediction, and automatic crop management. However, unmanned aerial vehicle (UAV)-acquired field imagery often exhibits complex characteristics such as diverse panicle morphology, uneven illumination, overlapping occlusion, and background interference, et al., posing substantial challenges for conventional target detection algorithms. To address these issues, a lightweight target detection model, named YOLOv8n-SSND (YOLOv8n with Switchable Atrous Convolution, Slim Neck, and Deformable Attention) is proposed, and specifically optimized for UAV-based Chenopodium quinoa panicle identification to improve the detection accuracy and inference efficiency for Chenopodium quinoa panicles while maintaining low computational cost and real-time performance suitable for embedded UAV deployment.

Methods

The proposed model was constructed based on the YOLOv8n and YOLOv11n frameworks, and incorporated several improvements tailored for small-object agricultural detection tasks. To enhance the ability to capture multi-scale and high-dimensional semantic features, the switchable atrous convolution (SAC) module was embedded into the backbone network. This module dynamically adjusted its receptive field according to spatial context, enabling more precise extraction of local and global texture details of Chenopodium quinoa panicles. In order to reduce redundant parameters and maintain high computational efficiency, a slim-neck lightweight feature fusion layer was designed, which effectively strengthened the integration of shallow spatial information and deep semantic features, allowing the network to maintain high accuracy without increasing model complexity. Additionally, a deformable attention (DA) mechanism was introduced to enable adaptive focus on regions with rich panicle-related features while suppressing irrelevant background noise. This attention mechanism assigned dynamic weights across both spatial and channel dimensions, improving the model's robustness against occlusions, illumination variations, and complex field textures commonly encountered in UAV images.

Results and Discussions

Comprehensive field experiments were conducted using UAV images of Chenopodium quinoa plots collected under different environmental conditions and growth stages. The results demonstrated that the proposed YOLOv8n-SSND model achieved a mean average precision (mAP50) of 94.3%, showing a remarkable improvement over multiple baseline and comparative models. Specifically, compared with YOLOv11n-SSND, YOLOv11n, YOLOv12n, YOLOv7, YOLOv5s, single shot multibox detector (SSD), fast region-based convolutional neural network (Fast R-CNN) and YOLOv8n, the proposed model achieved improvements of 0.7, 0.9, 2.1, 1.4, 2.0, 23.1, 19.6 and 1.8 percentage points respectively (SSD and Fast R-CNN). In terms of computational efficiency, the inference speed reached 166.7 f/s, representing a 26.7% increase over the YOLOv8n baseline, which ensured real-time detection capability for UAV-mounted onboard processors. Moreover, the total operation count was reduced to 6.8 GFLOPs, reflecting a 16.0% reduction compared with the baseline model, thus demonstrating the improved efficiency of the proposed architecture. The experimental comparison also indicated that the integration of SAC enhanced the model's sensitivity to complex spatial patterns, while the DA module effectively improved feature selectivity and prevented overfitting to background textures. The Slim-Neck design contributed significantly to reducing parameter redundancy and facilitated smooth feature propagation across layers.

Conclusions

The YOLOv8n-SSND model effectively achieves a balance among detection accuracy, inference speed, and computational cost, making it well-suited for real-time UAV-based agricultural monitoring. The experimental outcomes confirm that the model not only provides high-precision detection of Chenopodium quinoa panicles but also offers superior inference efficiency with minimal computational resources. These characteristics make it a promising solution for UAV-deployed intelligent agricultural systems, where power and processing capacity are limited. Furthermore, the proposed method provides a technical foundation for large-scale and automated monitoring of Chenopodium quinoa growth, enabling accurate yield estimation, phenotypic analysis, and precision crop management.

Open Access Research paper Issue
HTPRootSlides: A high-throughput phenotyping platform for crop root germination dynamic screening
The Crop Journal 2026, 14(2): 662-672
Published: 01 December 2025
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Root phenotyping is crucial for advancing our understanding of plant development and adaptation. However, existing platforms often face challenges in balancing high-throughput capacity with long-term, high-frequency monitoring. To overcome this limitation, we present HTPRootSlides, an integrated root phenotyping platform designed for dynamic and scalable trait analysis. Its design features a circulating zone that accommodates 141 specialized root boxes for high-throughput operation synchronously. Root boxes follow a continuous S-shaped trajectory step by step, facilitating repetitive imaging for high-throughput, time-series data acquisition. To address challenges such as water vapor condensation and fine root entanglement, we developed a dedicated segmentation algorithm, achieving 89.56% accuracy in root isolation. Combining morphological and skeleton-based feature extraction techniques, the platform ensures comprehensive and efficient phenotypic trait quantification. We validated HTPRootSlides by dynamically monitoring root development in four staple crops (soybean, maize, wheat, and rice) during early-stage germination (< 14 d). The results demonstrate the capability of HTPRootSlides for high-frequency, high-precision and large-scale root phenotyping (< 1 h with 141 root boxes per run), offering researchers a powerful tool to investigate root dynamics and optimize crop performance through trait selection.

Issue
LAI inversion and growth evaluation of winter wheat using semi-empirical and semi-mechanistic modeling
Transactions of the Chinese Society of Agricultural Engineering 2024, 40(1): 162-170
Published: 15 January 2023
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Leaf area index (LAI) is one of the key indicators in the structure and function of vegetation canopy, in order to estimate the biomass and crop growth. This study aims to improve the accuracy and generalization of the LAI inversion model for the winter wheat using unmanned aerial vehicle (UAV) remote sensing. An inversion model was established using semi-empirical and semi-mechanistic approaches. An UAV with a multispectral camera was utilized to obtain the measured data of winter wheat growth with different nitrogen treatments and replanting. PROSAIL radiative transfer model was used to generate the simulated data with mechanistic information. Five LAI inversion hybrid datasets were established using different combinations of measured and simulated data. Various machine learning methods were used to construct a high-precision LAI inversion model using empirical and mechanistic information. Seven kinds of vegetation indices related to NIR bands were screened to extract the winter wheat spectral features, in order to reduce the reflectance of NIR bands. The correlation coefficient matrix between the vegetation indices and the LAI of the mixed dataset was calculated to further explore the degree of influence of different spectral features on the LAI of winter wheat. The LAI inversion models of winter wheat were formed using Bayesian ridge regression, linear regression, elasticity network, and support vector regression model. The feasibility of LAI inversion was also evaluated using semi-empirical and semi-mechanistic data. The ability of the improved model was finally determined to assess the winter wheat growth for different nitrogen levels and replanting. The results showed that: 1) There was a strong correlation between the screened vegetation indices associated with NIR bands and winter wheat LAI. Normalized difference vegetation index (NDVI), enhanced vegetation index (EVI), normalized difference red edge index (NDRE), ratio vegetation index (SR), red edge chlorophyll vegetation index (RECI), and soil adjusted vegetation index (SAVI) were positively correlated with the LAI, whereas, the structurally insensitive pigment vegetation index (SIPI) was negatively correlated with the LAI. 2) The radiative transfer model was represented for the winter wheat LAI subjected to the propagation of solar rays. The strong robustness and generalization were achieved to mix with the measured data. The support vector regression (SVR) model achieved better LAI prediction performance under various data combinations, compared with the rest. In the training set of the four training-test combinations C1, C2, C3 and C4, R2 is 0.86, 0.87, 0.88, 0.91, RMSE is 0.47, 0.45, 0.45, 0.41; in the test set, R2 is 0.85, 0.19, 0.89, 0.87, RMSE is 0.45, 1.31, 0.49, 0.50. 3) A support vector machine model was used to generate the LAI inversion maps for the test area. The winter wheat growth was evaluated under four nitrogen levels and two replanting models. The results showed that 180 kg/hm2 fertilization was more effective than 135 kg/hm2 one, but 225 kg/hm2 fertilization was similar to 180 kg/hm2 one. An optimal application of nitrogen treatment can be expected to improve the LAI value of winter wheat. Among them, the LAI values under wheat-bean replanting were generally higher than those of wheat-yue replanting. This finding can provide an effective way for the inversion of winter wheat LAI in the efficient assessment of winter wheat growt

Open Access Research paper Issue
PlantGaussian: Exploring 3D Gaussian splatting for cross-time, cross-scene, and realistic 3D plant visualization and beyond
The Crop Journal 2025, 13(2): 607-618
Published: 15 February 2025
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Observing plants across time and diverse scenes is critical in uncovering plant growth patterns. Classic methods often struggle to observe or measure plants against complex backgrounds and at different growth stages. This highlights the need for a universal approach capable of providing realistic plant visualizations across time and scene. Here, we introduce PlantGaussian, an approach for generating realistic three-dimensional (3D) visualization for plants across time and scenes. It marks one of the first applications of 3D Gaussian splatting techniques in plant science, achieving high-quality visualization across species and growth stages. By integrating the Segment Anything Model (SAM) and tracking algorithms, PlantGaussian overcomes the limitations of classic Gaussian reconstruction techniques in complex planting environments. A new mesh partitioning technique is employed to convert Gaussian rendering results into measurable plant meshes, offering a methodology for accurate 3D plant morphology phenotyping. To support this approach, PlantGaussian dataset is developed, which includes images of four crop species captured under multiple conditions and growth stages. Using only plant image sequences as input, it computes high-fidelity plant visualization models and 3D meshes for 3D plant morphological phenotyping. Visualization results indicate that most plant models achieve a Peak Signal-to-Noise Ratio (PSNR) exceeding 25, outperforming all models including the original 3D Gaussian Splatting and enhanced NeRF. The mesh results indicate an average relative error of 4% between the calculated values and the true measurements. As a generic 3D digital plant model, PlantGaussian will support expansion of plant phenotype databases, ecological research, and remote expert consultations.

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