2022
DOI: 10.1109/tcpmt.2022.3225051
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Machine Vision System Utilizing Black Silicon CMOS Camera for Through-Silicon Alignment

Abstract: Current development trends concerning miniaturizing of electronics and photonics systems are aiming at assembly and 3D co-integration of a broad range of technologies including MEMS, microfluidics, wafer level optics, and silicon photonics. To this end, on-chip integration using silicon-photonics platform offers a wide range of possibilities addressing passive optics functionality, active optoelectronic devices, and compatibility with CMOS fabrication. On the other hand, the hybrid technology enabling volume m… Show more

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Cited by 7 publications
(7 citation statements)
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“…The experimental setup consists of a through-silicon machine vision system [12], optically combined with LAB 980 nm laser bottom irradiation beam delivery system (Fig. 2).…”
Section: Experimental Setup and Methodsmentioning
confidence: 99%
See 2 more Smart Citations
“…The experimental setup consists of a through-silicon machine vision system [12], optically combined with LAB 980 nm laser bottom irradiation beam delivery system (Fig. 2).…”
Section: Experimental Setup and Methodsmentioning
confidence: 99%
“…A machine visionbased sensor is employed for non-contact temperature control of the silicon substrate. The temperature data obtained using a through-silicon vision system [12] is compared with data obtained with a pyrometer. For the best temporal resolution, the measurements are taken using a power density of 40 W/cm 2 .…”
Section: Experimental Setup and Methodsmentioning
confidence: 99%
See 1 more Smart Citation
“…The utilization of computer vision (CV) technologies in manufacturing systems is widespread and serves various purposes, such as enhancing quality control, automating manufacturing tasks, and enabling closed-loop control systems, among others [20,21]. For instance, CV algorithms can be used to detect defects in products and components, such as surface cracks [22], weld defects [23], and misalignments [24]. Monitoring and analyzing sensor data from the production line can enhance quality control and defect prevention [25].…”
Section: Vision Systemsmentioning
confidence: 99%
“…IoT Real-time monitoring and control, optimization of production schedules [12] Integration challenges with existing manufacturing systems, compatibility issues with legacy equipment and software [15] Predictive maintenance, reducing downtime and saving costs [13] Limited computational resources [15], cybersecurity risks [16] Logistics management, improving productivity and delivery efficiency [14] CV Quality control, defect detection in products and components [22][23][24] Complex deployment, infrastructure requirements [20] Automation of manufacturing tasks, improving efficiency and accuracy [26] Calibration and accuracy validation requirements, limitations in handling complex variations or low-contrast features Human activity observation, facilitating human-machine interaction, ergonomics assessment [27,29] Camera positioning and angle requirements for accurate observation Integration with emerging technologies, enhancing functionality [31][32][33] Additional hardware and software integration requirements, limitations in real-time synchronization and data transfer Machine learning integration, improving accuracy and quality [34,35] Requirements for sufficient training data and computational resources…”
Section: Applications Challengesmentioning
confidence: 99%