Prediction of Extensibility and Toughness of Wheat-Flour Dough Using Bubble Inflation-Structured Light Scanning 3D Imaging Technology and the Enhanced 3D Vgg11 Model
文献类型: 外文期刊
作者: Luo, Xiuzhi 1 ; Niu, Changhe 2 ; Zhu, Zhaoshuai 2 ; Hou, Yuxin 3 ; Jiang, Hong 1 ; Tang, Xiuying 3 ;
作者机构: 1.Xinjiang Univ, Coll Mech Engn, Urumqi 830046, Peoples R China
2.Xinjiang Acad Agr Sci, Inst Agr Mechanizat, 291 Nanchang South Rd, Urumqi 830046, Peoples R China
3.China Agr Univ, Coll Engn, 17 Qinghua East Rd, Beijing 100083, Peoples R China
关键词: 3D CNN; dough extensibility and toughness; bubble inflation; 3D scanning imaging technology; CBAM; point cloud images
期刊名称:FOODS ( 影响因子:5.1; 五年影响因子:5.6 )
ISSN:
年卷期: 2025 年 14 卷 8 期
页码:
收录情况: SCI
摘要: The extensibility of dough and its resistance to extension (toughness) are important indicators, since they are directly linked to dough quality. Therefore, this paper used an independently developed device to blow sheeted dough, and then a three-dimensional (3D) camera was used to continuously collect point cloud images of sheeted dough forming bubbles. After data collection, the rotation algorithm, region of interest (ROI) extraction algorithm, and statistical filtering algorithm were used to process the original point cloud images. Lastly, the oriented bounding box (OBB) algorithm was proposed to calculate the deformation height of each data point. And the point cloud image with the largest deformation depth was selected as the data to input into the 3D convolutional neural network (CNN) models. The Convolutional Block Attention Module (CBAM) was introduced into the 3D Visual Geometry Group 11 (Vgg11) model to build the enhanced Vgg11. And we compared it with the other classical 3D CNN models (MobileNet, ResNet18, and Vgg11) by inputting the voxel-point-based data and the voxel-based data separately into these models. The results showed that the enhanced 3D Vgg11 model using voxel-point-based data was superior to the other models. For prediction of dough extensibility and toughness, the Rp was 0.893 and 0.878, respectively.
- 相关文献
作者其他论文 更多>>
-
Development of a hydraulic variable-diameter threshing drum control system for combine harvester part I: Adaptive monitoring method
作者:Liu, Yanbin;Li, Yaoming;Ji, Kuizhou;Yu, Zhiwu;Ma, Zheng;Xu, Lizhang;Niu, Changhe
关键词:Threshing gap; Feeding rate; Central composite rotatable design (CCRD); Oil pressure
-
Development of a hydraulic variable-diameter threshing drum control system for combine harvester part II: Controller design and field performance
作者:Liu, Yanbin;Li, Yaoming;Ji, Kuizhou;Yu, Zhiwu;Ma, Zheng;Xu, Lizhang;Niu, Changhe
关键词:Adaptive contracting-expanding factor; Variable universe; Threshing gap; Feeding rate; Grain entrainment loss rate
-
Model and Parameter Adaptive MPC Path Tracking Control Study of Rear-Wheel-Steering Agricultural Machinery
作者:Wang, Meng;Wang, Zifan;Jian, Jianming;Tang, Xiuying;Wang, Meng;Niu, Changhe;Jiang, Yongxin
关键词:path tracking; rear-wheel steering model; MPC; preview; fuzzy control; PSO
-
Study on Path Planning in Cotton Fields Based on Prior Navigation Information
作者:Wang, Meng;Wang, Zifan;Jian, Jianming;Tang, Xiuying;Wang, Meng;Niu, Changhe;Jiang, Yongxin
关键词:agricultural machinery path planning; sowing navigation information; turnaround; obstacle avoidance; prior semantic map
-
Semi-supervised comparative learning compensation method for chemical gas sensor drift
作者:Xiong, Lijian;Wang, Meng;Zhu, Zhaoshuai;He, Meng;Hou, Yuxin;Tang, Xiuying;Wang, Meng;Zhu, Zhaoshuai
关键词:Machine olfaction; Sensor drift; Contrastive learning; Reference sample pairs; Multilayer perceptron
-
DESIGN AND TEST OF APRICOT KERNEL SHELL BREAKING MACHINE
作者:Zhu, Zhaoshuai;Mao, Wulan;Yang, Liling;Cui, Kuanbo;Zhu, Zhanjiang;Li, Jie
关键词:Agricultural machinery; Apricot; Breaking machine; Orthogonal test; Design; Optimization
-
Carbon and nitrogen metabolism under nitrogen variation affects flavonoid accumulation in the leaves of Coreopsis tinctoria
作者:Li, Zhiyuan;Jiang, Hong;Yan, Huizhuan;Jiang, Xiumei;Qin, Yong;Ma, Yan
关键词:Nitrogen; C. tinctoria; Carbon metabolism; Nitrogen metabolism; Flavonoid accumulation
