{"title":"嵌入式平面图合规控制系统","authors":"Mehmet Erkin Yücel, Serkan Topaloğlu, Cem Ünsalan","doi":"10.1007/s11554-024-01525-6","DOIUrl":null,"url":null,"abstract":"<p>The retail sector presents several open and challenging problems that could benefit from advanced pattern recognition and computer vision techniques. One such critical challenge is planogram compliance control. In this study, we propose a complete embedded system to tackle this issue. Our system consists of four key components as image acquisition and transfer via stand-alone embedded camera module, object detection via computer vision and deep learning methods working on single-board computers, planogram compliance control method again working on single-board computers, and energy harvesting and power management block to accompany the embedded camera modules. The image acquisition and transfer block is implemented on the ESP-EYE camera module. The object detection block is based on YOLOv5 as the deep learning method and local feature extraction. We implement these methods on Raspberry Pi 4, NVIDIA Jetson Orin Nano, and NVIDIA Jetson AGX Orin as single-board computers. The planogram compliance control block utilizes sequence alignment through a modified Needleman–Wunsch algorithm. This block is also working along with the object detection block on the same single-board computers. The energy harvesting and power management block consists of solar and RF energy-harvesting modules with suitable battery pack for operation. We tested the proposed embedded planogram compliance control system on two different datasets to provide valuable insights on its strengths and weaknesses. The results show that the proposed method achieves F1 scores of 0.997 and 1.0 in object detection and planogram compliance control blocks, respectively. Furthermore, we calculated that the complete embedded system can work in stand-alone form up to 2 years based on battery. This duration can be further extended with the integration of the proposed solar and RF energy-harvesting options.</p>","PeriodicalId":51224,"journal":{"name":"Journal of Real-Time Image Processing","volume":"58 1","pages":""},"PeriodicalIF":2.9000,"publicationDate":"2024-08-05","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Embedded planogram compliance control system\",\"authors\":\"Mehmet Erkin Yücel, Serkan Topaloğlu, Cem Ünsalan\",\"doi\":\"10.1007/s11554-024-01525-6\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<p>The retail sector presents several open and challenging problems that could benefit from advanced pattern recognition and computer vision techniques. One such critical challenge is planogram compliance control. In this study, we propose a complete embedded system to tackle this issue. Our system consists of four key components as image acquisition and transfer via stand-alone embedded camera module, object detection via computer vision and deep learning methods working on single-board computers, planogram compliance control method again working on single-board computers, and energy harvesting and power management block to accompany the embedded camera modules. The image acquisition and transfer block is implemented on the ESP-EYE camera module. The object detection block is based on YOLOv5 as the deep learning method and local feature extraction. We implement these methods on Raspberry Pi 4, NVIDIA Jetson Orin Nano, and NVIDIA Jetson AGX Orin as single-board computers. The planogram compliance control block utilizes sequence alignment through a modified Needleman–Wunsch algorithm. This block is also working along with the object detection block on the same single-board computers. The energy harvesting and power management block consists of solar and RF energy-harvesting modules with suitable battery pack for operation. We tested the proposed embedded planogram compliance control system on two different datasets to provide valuable insights on its strengths and weaknesses. The results show that the proposed method achieves F1 scores of 0.997 and 1.0 in object detection and planogram compliance control blocks, respectively. Furthermore, we calculated that the complete embedded system can work in stand-alone form up to 2 years based on battery. 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引用次数: 0
摘要
零售业面临着一些有待解决且极具挑战性的问题,先进的模式识别和计算机视觉技术可以帮助解决这些问题。其中一个关键挑战就是平面图合规性控制。在本研究中,我们提出了一个完整的嵌入式系统来解决这一问题。我们的系统由四个关键部分组成:通过独立的嵌入式摄像头模块进行图像采集和传输;通过单板计算机上的计算机视觉和深度学习方法进行物体检测;再次通过单板计算机进行平面图顺应性控制;以及与嵌入式摄像头模块配套的能量收集和电源管理模块。图像采集和传输模块在 ESP-EYE 摄像头模块上实现。物体检测模块基于 YOLOv5 作为深度学习方法和局部特征提取。我们在 Raspberry Pi 4、NVIDIA Jetson Orin Nano 和 NVIDIA Jetson AGX Orin 单板计算机上实现了这些方法。平面图顺应性控制模块通过改进的 Needleman-Wunsch 算法利用序列对齐。该程序块还与物体检测程序块一起在同一单板计算机上工作。能量收集和电源管理模块由太阳能和射频能量收集模块以及合适的电池组组成。我们在两个不同的数据集上测试了所提出的嵌入式平面图顺应性控制系统,以便对其优缺点提供有价值的见解。结果表明,在物体检测和平面图符合性控制模块中,建议的方法分别获得了 0.997 和 1.0 的 F1 分数。此外,我们还计算出,基于电池,整个嵌入式系统可独立工作长达 2 年。在集成了所建议的太阳能和射频能量收集方案后,这一持续时间还可进一步延长。
The retail sector presents several open and challenging problems that could benefit from advanced pattern recognition and computer vision techniques. One such critical challenge is planogram compliance control. In this study, we propose a complete embedded system to tackle this issue. Our system consists of four key components as image acquisition and transfer via stand-alone embedded camera module, object detection via computer vision and deep learning methods working on single-board computers, planogram compliance control method again working on single-board computers, and energy harvesting and power management block to accompany the embedded camera modules. The image acquisition and transfer block is implemented on the ESP-EYE camera module. The object detection block is based on YOLOv5 as the deep learning method and local feature extraction. We implement these methods on Raspberry Pi 4, NVIDIA Jetson Orin Nano, and NVIDIA Jetson AGX Orin as single-board computers. The planogram compliance control block utilizes sequence alignment through a modified Needleman–Wunsch algorithm. This block is also working along with the object detection block on the same single-board computers. The energy harvesting and power management block consists of solar and RF energy-harvesting modules with suitable battery pack for operation. We tested the proposed embedded planogram compliance control system on two different datasets to provide valuable insights on its strengths and weaknesses. The results show that the proposed method achieves F1 scores of 0.997 and 1.0 in object detection and planogram compliance control blocks, respectively. Furthermore, we calculated that the complete embedded system can work in stand-alone form up to 2 years based on battery. This duration can be further extended with the integration of the proposed solar and RF energy-harvesting options.
期刊介绍:
Due to rapid advancements in integrated circuit technology, the rich theoretical results that have been developed by the image and video processing research community are now being increasingly applied in practical systems to solve real-world image and video processing problems. Such systems involve constraints placed not only on their size, cost, and power consumption, but also on the timeliness of the image data processed.
Examples of such systems are mobile phones, digital still/video/cell-phone cameras, portable media players, personal digital assistants, high-definition television, video surveillance systems, industrial visual inspection systems, medical imaging devices, vision-guided autonomous robots, spectral imaging systems, and many other real-time embedded systems. In these real-time systems, strict timing requirements demand that results are available within a certain interval of time as imposed by the application.
It is often the case that an image processing algorithm is developed and proven theoretically sound, presumably with a specific application in mind, but its practical applications and the detailed steps, methodology, and trade-off analysis required to achieve its real-time performance are not fully explored, leaving these critical and usually non-trivial issues for those wishing to employ the algorithm in a real-time system.
The Journal of Real-Time Image Processing is intended to bridge the gap between the theory and practice of image processing, serving the greater community of researchers, practicing engineers, and industrial professionals who deal with designing, implementing or utilizing image processing systems which must satisfy real-time design constraints.