Download or read book Haptic Optical Tweezers with 3D High-speed Tracking written by Munan Yin and published by . This book was released on 2017 with total page 0 pages. Available in PDF, EPUB and Kindle. Book excerpt: Micromanipulation has a great potential to revolutionize the biological research and medical care. At small scales, microrobots can perform medical tasks with minimally invasive, and explore life at a fundamental level. Optical Tweezers are one of the most popular techniques for biological manipulation. The small-batch production which demands high flexibilities mainly relies on teleoperation process. However, the limited level of intuitiveness makes it more and more difficult to effectively conduct the manipulation and exploration tasks in the complex microworld. Under such circumstances, pioneer researchers have proposed to incorporate haptics into the control loop of OTs system, which aims to handle the micromanipulation tasks in a more flexible and effective way. However, the solution is not yet complete, and there are two main challenges to resolve in this thesis: 3D force detection, which should be accurate, fast, and robust in large enough working space; High-speed up to 1 kHz force feedback, which is indispensable to allow a faithful tactile sensation and to ensure system stability. In optical tweezers micromanipulation, vision is a sound candidate for force estimation since the position-force model is well established. However, the 1 kHz tracking is beyond the speed of the conventional processing methods. The emerging discipline of biomorphic engineering aiming to integrate the behaviors of livings into large-scale computer hardware or software breaks the bottleneck. The Asynchronous Time-Based Image Sensor (ATIS) is the latest generation of neuromorphic silicon retina prototype which records only scene contrast changes in the form of a stream of events. This property excludes the redundant background and allows high-speed motion detection and processing. The event-based vision has thus been applied to address the requirement of 3D high-speed force feedback. The result shows that the first 3D high-speed haptic optical tweezers for biological application have been achieved. The optical realization and event-based tracking algorithms for 3D high-speed force detection have been developed and validated. Reproducible exploration of the 3D biological surface has been demonstrated for the first time. As a powerful 3D high-speed force sensor, the developed optical tweezers system poses significant potential for various applications.