16.1 An ultra-thin flexible CMOS stress sensor demonstrated on an adaptive robotic gripper

机译：16.1在自适应机器人夹具上展示的超薄柔性CMOS应力传感器

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Hybrid Systems-in-Foil (HySiF) are becoming important for wearable electronics, medical diagnostics and flexible displays, which require mechanical flexibility or adaptivity as well as large area [1]. Ultra-thin chips are an essential part of HySiF as they allow for analog signal processing or complex digital controllers using well established CMOS technology. However, the effect of mechanical stress on the signal processing circuitry (piezoresistivity) has to be considered during the top-to-bottom design in order to realize stress insensitive analog and digital operation. On the other hand, for sensing mechanical stress on the same substrate, the stress effect needs to be maximized [2], thus leading to conflicting design requirements.

机译：箔片混合系统（HySiF）对于可穿戴电子设备，医疗诊断和柔性显示器而言变得越来越重要，这些设备需要机械柔韧性或适应性以及大面积[1]。超薄芯片是HySiF的重要组成部分，因为它们允许使用成熟的CMOS技术进行模拟信号处理或复杂的数字控制器。但是，从上到下的设计必须考虑机械应力对信号处理电路的影响（压电电阻率），以实现对应力不敏感的模拟和数字操作。另一方面，为了感测同一基板上的机械应力，应力效应需要最大化[2]，从而导致设计要求冲突。

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《IEEE International Solid- State Circuits Conference》|2015年|1-3|共3页
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Mahsereci Yigit; Sailer Stefan; Richter Harald; Burghartz Joachim;
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1. An Ultra-Thin Flexible CMOS Stress Sensor Demonstrated on an Adaptive Robotic Gripper [J] . Mahsereci Yigit, Saller Stefan, Richter Harald, Solid-State Circuits, IEEE Journal of . 2016,第1期

机译：在自适应机器人夹具上展示的超薄柔性CMOS应力传感器
2. Adaptive gripper shows promise for jigless welding--Gripper designed to make the robotic welding cell more flexible [J] . Tim Heston The Fabricator . 2011,第10期

机译：自适应夹持器显示了无夹具焊接的希望-夹持器旨在使机器人焊接单元更加灵活
3. CMOS wireless stress sensor IC with 256-cell sensing array for ultra-thin applications [J] . Hanjun Jiang, Zheyao Wang, Shujie Yang, Electronics Letters . 2016,第20期

机译：具有256单元感测阵列的CMOS无线应力传感器IC，适用于超薄应用
4. 16.1 An ultra-thin flexible CMOS stress sensor demonstrated on an adaptive robotic gripper [C] . Mahsereci Yigit, Sailer Stefan, Richter Harald, IEEE International Solid- State Circuits Conference . 2015

机译：16.1在自适应机器人夹具上展示了超薄柔性CMOS应力传感器
5. Modeling, design, prototyping and performance evaluation of a sensor-based robotic gripper system for automated limp material handling. [D] . Kolluru, Ramesh. 1996

机译：基于传感器的机器人夹持器系统的建模，设计，原型制作和性能评估，可用于自动li行材料处理。
6. Fabrication of Ultra-Thin Printed Organic TFT CMOS Logic Circuits Optimized for Low-Voltage Wearable Sensor Applications [O] . Yasunori Takeda, Kazuma Hayasaka, Rei Shiwaku, -1

机译：为低压可穿戴传感器应用而优化的超薄印刷有机TFT CMOS逻辑电路的制造
7. 16.1 iVisual: An Intelligent Visual Sensor SoC with 2790fps CMOS Image Sensor and 205GOPS/W Vision Processor [O] . Chih-chi Cheng, Chia-hua Lin, Chung-te Li, 2013

机译：16.1 iVisual：具有2790fps CmOs图像传感器和205GOps / W视觉处理器的智能视觉传感器soC

16.1 An ultra-thin flexible CMOS stress sensor demonstrated on an adaptive robotic gripper

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