Smartphone-based food recognition system using multiple deep CNN models

Fakhrou, Abdulnaser A.; Kunhoth, Jayakanth

doi:10.1007/s11042-021-11329-6

Cited by 34 publications

(13 citation statements)

References 32 publications

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“…A dozen of works have concerned the deployment of food recognition systems on smartphone or on cloud for realworld dish image analysis [32][33][34][35][36][37][38][39][40][41][42][43][44][45][46][47][48][49]. As to multistage approaches, Kawano and Yanai implemented a food recognition system on smartphone with the purpose of recording calories, nutrition, and eating habits [32].…”

Section: Related Workmentioning

confidence: 99%

“…Moreover, it is evaluated on images taken by using hand-held cameras, and its top-five accuracy is also promising. Fakhrou also used smartphone for image acquisition of dishes and fruits as the input of an end-to-end recognition system [40]. e system utilizes ensemble learning to fuse two deep neural architectures, and its accuracy achieves 95.55% on twenty-nine categories of customized dataset that benefits children with visual impairments.…”

Section: Related Workmentioning

confidence: 99%

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Accurate Real-Life Chinese Dish Recognition

Lan

Wan

Pang

et al. 2022

International Transactions on Electrical Energy Systems

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Deep learning is a new research direction in the field of machine learning, which was introduced into machine learning to bring it closer to its original goal. Accurate dish recognition becomes increasingly important in the multimedia community since it can help cuisine recommendation, calorie management, service improvement, and other food computing tasks. Many novel approaches have been developed on web recipes and menu pictures, while few are concerned real-life dish image analysis. In this study, a deep learning-based prototype system is deployed in a Chinese canteen, and 28 dish types, 16,904 images, and 45,061 instances have been collected. Specifically, in the prototype system, three practical issues are explored, including the backbone network selection, the training strategy determination, and the minimum number of samples for model upgrading. Experimental results suggest that fine-tuned Faster-RCNN can serve as the backbone network of the prototype system since it outperforms the other four fine-tuned networks on dish recognition (accuracy, 98.10%; recall, 97.20%; MAP (mean average precession), 98.30%) and satisfies real-time requirement (0.15 second per image). Meanwhile, the transferred backbone network achieves superior results (MAP, 96.48%) over the same architecture trained from image scratches (MAP, 87.84%). On model upgrading, a good (MAP, 91.34%) to better (MAP, 96.48%) outcome is obtained when the training size is increased from 50 to 200 samples per dish type, and 150 and more instances should be annotated if a new dish type is added to the system's recognition list. Conclusively, the real-life deployment and evaluation of the prototype system indicate that deep learning is full of potential to enhance customer experience through accurate daily dish recognition.

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Section: Related Workmentioning

confidence: 99%

Section: Related Workmentioning

confidence: 99%

Accurate Real-Life Chinese Dish Recognition

Lan

Wan

Pang

et al. 2022

International Transactions on Electrical Energy Systems

View full text Add to dashboard Cite

show abstract

“…The sample size used for Aliyun Cloud food recognition model verification is not large enough, and the types of food involved are limited, containing only some common foods. Although the accuracy of food identification has reached 89.6%, a larger sample size is needed to further verify and improve the accuracy, and it is expected to achieve all-around and multi-type accurate identification of food ( 7 , 38 ). The area-weight calculation model needs to be further optimized, realizing AR automatic ranging when taking pictures, reducing the requirements for taking pictures, and image processing; further expanding the sample size for training, learning, and verification, and improving more accurate weight estimation.…”

Section: Discussionmentioning

confidence: 99%

Eliminate the hardware: Mobile terminals-oriented food recognition and weight estimation system

Zhang

He²,

Wen

et al. 2022

Front. Nutr.

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Food recognition and weight estimation based on image methods have always been hotspots in the field of computer vision and medical nutrition, and have good application prospects in digital nutrition therapy and health detection. With the development of deep learning technology, image-based recognition technology has also rapidly extended to various fields, such as agricultural pests, disease identification, tumor marker recognition, wound severity judgment, road wear recognition, and food safety detection. This article proposes a non-wearable food recognition and weight estimation system (nWFWS) to identify the food type and food weight in the target recognition area via smartphones, so to assist clinical patients and physicians in monitoring diet-related health conditions. In addition, the system is mainly designed for mobile terminals; it can be installed on a mobile phone with an Android system or an iOS system. This can lower the cost and burden of additional wearable health monitoring equipment while also greatly simplifying the automatic estimation of food intake via mobile phone photography and image collection. Based on the system’s ability to accurately identify 1,455 food pictures with an accuracy rate of 89.60%, we used a deep convolutional neural network and visual-inertial system to collect image pixels, and 612 high-resolution food images with different traits after systematic training, to obtain a preliminary relationship model between the area of food pixels and the measured weight was obtained, and the weight of untested food images was successfully determined. There was a high correlation between the predicted and actual values. In a word, this system is feasible and relatively accurate for one automated dietary monitoring and nutritional assessment.

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“…We developed four deep learning models: Inception-v3, plain convolutional neural network, Mobilenet-v2, and sequential feed-forward neural network. These models were selected based on their successes for western and eastern food recognition systems from related studies [ [19] , [20] , [21] , [22] ]. We evaluated these models based on six significant metrics: training accuracy, validation accuracy, testing accuracy, precision accuracy for individual classes, recall, and f1-score.…”

Section: Experimental Design Materials and Methodsmentioning

confidence: 99%

African foods for deep learning-based food recognition systems dataset

Ataguba,

Ezekiel,

Daniel

et al. 2024

Data in Brief

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Smartphone-based food recognition system using multiple deep CNN models

Cited by 34 publications

References 32 publications

Accurate Real-Life Chinese Dish Recognition

Accurate Real-Life Chinese Dish Recognition

Eliminate the hardware: Mobile terminals-oriented food recognition and weight estimation system

African foods for deep learning-based food recognition systems dataset

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