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Control System Design for High-Speed Atomic Force Microscopy

Control System Design for High-Speed Atomic Force Microscopy
Author: Nastaran Nikooienejad
Publisher:
Total Pages:
Release: 2021
Genre: Atomic force microscopy
ISBN:
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Video-rate atomic force microscopy is in high demand to visualize dynamic processes in realtime, whereas the functionality of a commercial atomic force microscope (AFM) is restricted to low-speed scans. In the past decades, extensive research efforts have aimed to reinforce the AFM structure toward high-speed atomic force microscopy. However, video-rate imaging of a relatively large scan area is still challenging due to the highly resonant nature of AFM and its conventional method of scanning. The AFM control system also needs to be significantly improved to harness the full potential of AFM mechanical structure at video rate and provide adequate robustness during scan. Therefore, besides the AFM configuration, scanning methods and control techniques contribute significantly to achieving the ultimate goal of sequential AFM imaging at video rate. This dissertation focuses on novel scanning methods and control design methodologies that facilitate sequential atomic force microscopy and improve positioning accuracy at high speed. First, we leverage a technique to smoothen the sequential cycloid trajectory and mitigate the sudden back and forth motions of a positioner in capturing successive frames of a scan. The resulting trajectory reduces the residual tracking error and enhances the AFM image quality. We also propose a systematic design methodology for a novel repetitive non-raster scan trajectory based on the rosette pattern. This pattern, generated by pure harmonic waveforms, can address the conventional issues with sequential non-raster imaging by enabling a smooth and continuous scan. We provide a thorvii ough mathematical analysis of the rosette pattern and a step-by-step design procedure for rosette scanning. We proceed by proposing high-precision model-based control design approaches for sequential AFM imaging using a microelectromechanical system (MEMS) nanopositioner. To precisely follow the reference setpoints in sequential cycloid and rosette scans, we design a tracking controller based on the internal model principle. The internal-model-based controller (IMBC) is intuitive and well-suited for tracking non-raster scan patterns. The controller incorporates the fundamental reference frequencies and their corresponding higher harmonics to reduce the deterministic error originated from uncompensated nonlinearities in the system. However, the resulting controller is of high order, and requires a priori knowledge of the dominant harmonics in the experimental tracking error. To resolve this, we develop a novel control scheme involving an internal-model-based control in feedback and an iterative learning control in feedforward. The internal-model-based controller only includes fundamental frequencies of the references while the iterative learning controller rejects the induced higher harmonics by learning from past experiences. The proposed control scheme is employed for tracking the rosette pattern at various scan rates. We investigate the performance of the proposed scanning methods and control techniques in closed-loop experiments. Finally, a series of high-quality images are obtained at high speed using a MEMS nanopositioner and a commercial AFM. A limiting factor toward high-speed atomic force microscopy is the lightly damped nature of the scanners. To increase the imaging bandwidth and scan speed, vibration control techniques have been practiced. Among them, fixed-structure strictly negative imaginary (SNI) controllers ensure robust stability of closed-loop system when the scanner incorporates collocated actuator and sensor pairs. In the third section of this dissertation, we present a convex synthesis of SNI controllers for a class of multi-input multi-output (MIMO) plants satisfying the negative imaginary property. The design procedure is based on the frequency response data of the plant, and the control objective is to minimize the distance between a desired and actual closed-loop frequency response. The controllers are experimentally implemented to augment damping to the fundamental resonant mode of a MEMS nanopositioner in a two-input two-output configuration.

Design and Control Optimization for High-speed Jumping Mode Atomic Force Microscope

Design and Control Optimization for High-speed Jumping Mode Atomic Force Microscope
Author: Fangzhou Xia
Publisher:
Total Pages: 111
Release: 2017
Genre:
ISBN:
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In this thesis, I improved the design of a high-speed Atomic Force Microscope (AFM) for jumping mode operation. The relations between important imaging parameters and physical limitations of the system were established first to identify the aspects of improvement. Two control algorithms to improve the imaging speed and probe sample interaction force for jumping mode atomic force microscopy operation have been proposed and investigated both in simulation and experiment. A new generation of multi-actuated sample scanner has been designed to address the dynamic coupling, thermal expansion and range issues in the previous design. Improvements to the optical beam deflection system, photodiode circuit, signal conditioning circuit and cantilever probe holder with actuators have been implemented. The combined optimization and design work improved the capability of the original custom made high-speed AFM setup in both subsystem performance and jumping mode operation.

Chaos Modeling and Control Systems Design

Chaos Modeling and Control Systems Design
Author: Ahmad Taher Azar
Publisher: Springer
Total Pages: 417
Release: 2014-12-03
Genre: Technology & Engineering
ISBN: 331913132X
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The development of computational intelligence (CI) systems was inspired by observable and imitable aspects of intelligent activity of human being and nature. The essence of the systems based on computational intelligence is to process and interpret data of various nature so that that CI is strictly connected with the increase of available data as well as capabilities of their processing, mutually supportive factors. Developed theories of computational intelligence were quickly applied in many fields of engineering, data analysis, forecasting, biomedicine and others. They are used in images and sounds processing and identifying, signals processing, multidimensional data visualization, steering of objects, analysis of lexicographic data, requesting systems in banking, diagnostic systems, expert systems and many other practical implementations. This book consists of 15 contributed chapters by subject experts who are specialized in the various topics addressed in this book. The special chapters have been brought out in the broad areas of Control Systems, Power Electronics, Computer Science, Information Technology, modeling and engineering applications. Special importance was given to chapters offering practical solutions and novel methods for the recent research problems in the main areas of this book, viz. Control Systems, Modeling, Computer Science, IT and engineering applications. This book will serve as a reference book for graduate students and researchers with a basic knowledge of control theory, computer science and soft-computing techniques. The resulting design procedures are emphasized using Matlab/Simulink software.

High-Speed Atomic Force Microscopy in Biology

High-Speed Atomic Force Microscopy in Biology
Author: Toshio Ando
Publisher: Springer Nature
Total Pages: 327
Release: 2022-03-23
Genre: Science
ISBN: 3662647850
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This first book on high-speed atomic force microscopy (HS-AFM) is intended for students and biologists who want to use HS-AFM in their research. It provides straightforward explanations of the principle and techniques of AFM and HS-AFM. Numerous examples of HS-AFM studies on proteins demonstrate how to apply this new form of microscopy to specific biological problems. Several precautions for successful imaging and the preparation of cantilever tips and substrate surfaces will greatly benefit first-time users of HS-AFM. In turn, the instrumentation techniques detailed in Chapter 4 can be skipped, but will be useful for engineers and scientists who want to develop the next generation of high-speed scanning probe microscopes for biology. The book is intended to facilitate the first-time use of this new technique, and to inspire students and researchers to tackle their own specific biological problems by directly observing dynamic events occurring in the nanoscopic world. Microscopy in biology has recently entered a new era with the advent of high-speed atomic force microscopy (HS-AFM). Unlike optical microscopy, electron microscopy, and conventional slow AFM, it allows us to directly observe biological molecules in physiological environments. Molecular “movies” created using HS-AFM can directly reveal how molecules behave and operate, without the need for subsequent complex analyses and roundabout interpretations. It also allows us to directly monitor morphological change in live cells, and dynamic molecular events occurring on the surfaces of living bacteria and intracellular organelles. As HS-AFM instruments were recently commercialized, in the near future HS-AFM is expected to become a common tool in biology, and will enhance and accelerate our understanding of biological phenomena.

Control Technologies for Emerging Micro and Nanoscale Systems

Control Technologies for Emerging Micro and Nanoscale Systems
Author: Evangelos Eleftheriou
Publisher: Springer
Total Pages: 300
Release: 2011-07-15
Genre: Technology & Engineering
ISBN: 3642221734
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This book comprises a selection of the presentations made at the “Workshop on Dynamics and Control of Micro and Nanoscale Systems” held at IBM Research – Zurich, Switzerland, on the 10th and 11th of December 2009. The aim of the workshop was to bring together some of the leading researchers in the field of dynamics and control of micro- and nanoscale systems. It proved an excellent forum for discussing new ideas and approaches.

Design and Control of High-speed and Large-range Atomic Force Microscope

Design and Control of High-speed and Large-range Atomic Force Microscope
Author: Iman Soltani Bozchalooi
Publisher:
Total Pages: 227
Release: 2015
Genre:
ISBN:
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This thesis presents the design, control and instrumentation of a novel atomic force microscope (AFM). This AFM is capable of high-speed imaging while maintaining large out-of-plane and lateral scan ranges. The primary contributions of this thesis include the design and implementation of a high-speed and large-range AFM; design, implementation and control of a multi-actuated nano-positioner; development of a general direct data-based control design scheme for redundantly actuated nano-positioners; design and implementation of a non-linear amplitude demodulation method for tapping mode imaging; and development of a parameter estimation methodology for piezo actuator hysteresis modeling and compensation. Atomic force microscopes can provide nano-scale resolution images of sample surface topography in air, vacuum or in liquid. This instrument operates by scanning a micro-mechanical probe on a sample. A measurement of the probe-sample interaction is used to control the AFM scanner and also form a 3D image of the sample surface topography. The mechanical nature and the serial-point-collection bases of operation of this instrument significantly limits its speed and constrains its application to the study of static samples. Unlocking the high-speed performance capability of AFM enables study of dynamic nano-scale processes and opens up the possibility of novel scientific discoveries. Improving the speed performance of AFM however, should not compromise imaging range so that the instrument can accommodate imaging experiments with diverse lateral and out-of-plane scan range requirements. In addition to high-speed and large-range performance, instrument flexibility and ease of use are very important. An AFM should allow samples of different sizes, and provide a simple platform for setting up the imaging experiment. In this work all the components of the AFM are designed to meet these specifications. A multi-actuated scanner is designed and built that is composed of five nano-positioners with different range and bandwidth characteristics. Through redundant actuation this nano-positioner is capable of operating at high speeds and over large lateral and out-of-plane scan ranges. A general data-based compensator design methodology for the control of redundantly actuated nano-positioners is developed. In the proposed approach the compensators are obtained directly from the measured scanner actuator response, without any intermediate modeling. This feature makes updating or tuning the associated parameters easier. The flexibility of AFM control is maintained by designing these compensators auxiliary to a PID control unit. It is shown that in this form, a PID controller suffices to meet the needs of high-speed atomic force microscopy. This approach to control design is also used in the thesis to retroactively enhance existing AFMs operating on both flexure-based scanners and piezo-tubes. To improve the positioning accuracy of the scanner we proposed a more accurate parameter estimation scheme for the Maxwell model of hysteresis extended to the full hysteresis loop. Finally, to enable operation of AFMs with probe arrays in tapping mode a non-linear demodulation method based on the Teager Energy Operator is designed and implemented in both analog and digital forms. The main advantage of this technique is simplicity, enabling implementation of hundreds of these operators in digital form on FPGAs (Field Programmable Gate Arrays) or in ASIC (Application-Specific Integrated Circuit) form on AFM probe arrays for parallel sensing. The developments of this thesis form the bases for the design and implementation of a novel AFM. The implemented instrument is capable of high-speed imaging and simultaneously achieves 6 [mu]m out-of-plane and 120 [mu]m lateral scan ranges making it the largest range high-speed AFM reported to this date. This instrument also features a modular design with a laser spot size of 3.5 [mu]m compatible with small cantilevers, an optical view of the sample and probe for site selection and laser adjustment, a conveniently large (15 mm) waterproof sample stage that accommodates samples with various sizes and a data logging and plotting system with 20 MHz throughput for high resolution image acquisition at high imaging speeds. The designed AFM is used to visualize etching of calcite in a solution of sulfuric acid. Layer-by-layer dissolution along the crystalline lines in a low pH environment is observed in real time and the corresponding dissolution rate is estimated. The designed AFM is also used to visualize in real time the nucleation, growth and striping of copper on gold for the first time.

Advances in High-Speed Atomic Force Microscopy

Advances in High-Speed Atomic Force Microscopy
Author: Pascal Nievergelt
Publisher:
Total Pages: 209
Release: 2018
Genre:
ISBN:
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Mots-clés de l'auteur: Atomic force microscopy (AFM) ; high--speed AFM ; photothermal excitation ; scanner design ; control system design ; off-resonance tapping AFM ; open hardware ; protein--protein dynamics ; live cell imaging.

The Design of High Performance Mechatronics - 3rd Revised Edition

The Design of High Performance Mechatronics - 3rd Revised Edition
Author: R. Munnig Schmidt
Publisher: IOS Press
Total Pages: 949
Release: 2020-02-05
Genre: Technology & Engineering
ISBN: 164368051X
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Since they entered our world around the middle of the 20th century, the application of mechatronics has enhanced our lives with functionality based on the integration of electronics, control systems and electric drives. This book deals with the special class of mechatronics that has enabled the exceptional levels of accuracy and speed of high-tech equipment applied in the semiconductor industry, realising the continuous shrink in detailing of micro-electronics and MEMS. As well as the more frequently presented standard subjects of dynamics, motion control, electronics and electromechanics, this book includes an overview of systems engineering, optics and precision measurement systems, in an attempt to establish a connection between these fields under one umbrella. Robert Munnig Schmidt is emeritus professor in Mechatronic System Design at Delft University of Technology with industrial experience at Philips and ASML in research and development of consumer and high-tech systems. He is also director of RMS Acoustics & Mechatronics, doing research and development on active controlled low frequency sound systems. Georg Schitter is professor at the Automation and Control Institute (ACIN) at Vienna University of Technology with a standing track record in research on the control and mechatronic design of extremely fast precision motion systems such as video rate AFM systems. Adrian Rankers is managing partner of Mechatronics Academy, developing and delivering high level courses to the industrial community, based on industrial experience at Philips in the research and development of consumer and high-tech systems. He also teaches Mechatronics at the Eindhoven University of Technology. Jan van Eijk is emeritus professor in Advanced Mechatronics at Delft University of Technology. He is also director of MICE BV and partner at Mechatronics Academy, acting as industrial R&D advisor and teacher with experience at Philips in the research and development of consumer and high-tech systems.

Design, Modeling and Control of Nanopositioning Systems

Design, Modeling and Control of Nanopositioning Systems
Author: Andrew J. Fleming
Publisher: Springer
Total Pages: 418
Release: 2014-05-15
Genre: Technology & Engineering
ISBN: 331906617X
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Covering the complete design cycle of nanopositioning systems, this is the first comprehensive text on the topic. The book first introduces concepts associated with nanopositioning stages and outlines their application in such tasks as scanning probe microscopy, nanofabrication, data storage, cell surgery and precision optics. Piezoelectric transducers, employed ubiquitously in nanopositioning applications are then discussed in detail including practical considerations and constraints on transducer response. The reader is then given an overview of the types of nanopositioner before the text turns to the in-depth coverage of mechanical design including flexures, materials, manufacturing techniques, and electronics. This process is illustrated by the example of a high-speed serial-kinematic nanopositioner. Position sensors are then catalogued and described and the text then focuses on control. Several forms of control are treated: shunt control, feedback control, force feedback control and feedforward control (including an appreciation of iterative learning control). Performance issues are given importance as are problems limiting that performance such as hysteresis and noise which arise in the treatment of control and are then given chapter-length attention in their own right. The reader also learns about cost functions and other issues involved in command shaping, charge drives and electrical considerations. All concepts are demonstrated experimentally including by direct application to atomic force microscope imaging. Design, Modeling and Control of Nanopositioning Systems will be of interest to researchers in mechatronics generally and in control applied to atomic force microscopy and other nanopositioning applications. Microscope developers and mechanical designers of nanopositioning devices will find the text essential reading.

High Speed Atomic Force Microscopy

High Speed Atomic Force Microscopy
Author: Younkoo Jeong
Publisher:
Total Pages:
Release: 2009
Genre:
ISBN:
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Abstract: Since its introduction more than twenty years ago, Atomic Force Microscopy (AFM) has extended its application areas from material science to biology or biophysics, based on its capability to image/manipulate objects in various environments with sub-nanometer spatial resolution in three dimensions. Among the two most commonly used modes, the dynamic (tapping) mode has a great advantage over contact mode when imaging soft materials, minimizing potentially destructive shear and adhesive forces on the sample. The amplitude modulation is the most commonly used control method in the dynamic mode of AFM, in which the oscillation amplitude of the cantilever is regulated. However, in typical implementations, due to tapping dynamics of the AFM cantilevers, the transient response of the cantilever induced by changes of the tip-sample interaction force leads to greater variations in tip-sample interaction via feedback, causing excessive tapping forces and/or possible loss of tapping during the scanning, and thus greater sample distortions and imaging errors. In addition, the low bandwidth of the actuators in conventional AFMs, such as the z-positioner and the raster scanner limits the scanning speed. Therefore, while dynamic mode AFM has many potential applications, the inability to achieve direct and precise control of the tip-sample interaction forces and the low bandwidth of actuators for the tip-sample separation control and the raster scanning have been key barriers which imaging rate and inhibit innovation leading to new applications. In this research, the design, actuation and control of a new generation AFM probing system which enables high-speed and high-resolution imaging of samples are investigated. In order to achieve direct tip-sample interaction control during the scanning, a novel dynamic sensing and control method are implemented, in which the tip-sample interaction force of each tapping cycle is estimated and subsequently controlled for dynamic force microscopy. By employing collocated magnetic actuation of the AFM cantilever and dual-actuator tip-motion control scheme, the high bandwidth tip-motion control, whose bandwidth is comparable to that of the cantilever, the dynamics over-damped, and the motion range comparable to that of conventional z-scanner is achieved. For the high bandwidth raster scanning as well as high bandwidth tip-sample separation control, active multi-axis probing system is implemented, in which multi-axis magnetic actuators along with a multi-axis probe with one magnetic moment, specially designed and fabricated for the multi-axis actuation, achieves high bandwidth multi-axis tip-motion control along the Z axis and the X axis. In order to achieve the high resolution imaging, a low noise laser measurement system is implemented and integrated to a commercial AFM (MFP3D, Asylum research). For the implementation of the direct tip-sample interaction control and high bandwidth active multi-axis probing system, high speed programmable digital controller is developed using field programmable gate array (FPGA) whose closed loop update rate is two orders of magnitude higher than commercially available ones. The results of scanning a standard grating whose pitch is 100nm and a biological grating (repeating protein structure on purple membranes) whose lateral pitch is about 6.2 nm using the high speed AFM are presented and discussed.