digital-brain/content/book/fleming14_desig_model_contr_nanop_system.md

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title = "Design, modeling and control of nanopositioning systems"
author = ["Thomas Dehaeze"]
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description = "Talks about various topics related to nano-positioning systems."
keywords = ["Control", "Metrology", "Flexible Joints"]
draft = false
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+++
Tags
: [Piezoelectric Actuators]({{<relref "piezoelectric_actuators.md#" >}}), [Flexible Joints]({{<relref "flexible_joints.md#" >}})
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Reference
: ([Fleming and Leang 2014](#orgd16fb21))
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Author(s)
: Fleming, A. J., & Leang, K. K.
Year
: 2014
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## Introduction to Nanotechnology {#introduction-to-nanotechnology}
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## Introduction to Nanopositioning {#introduction-to-nanopositioning}
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## Scanning Probe Microscopy {#scanning-probe-microscopy}
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## Challenges with Nanopositioning Systems {#challenges-with-nanopositioning-systems}
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### Hysteresis {#hysteresis}
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### Creep {#creep}
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### Thermal Drift {#thermal-drift}
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### Mechanical Resonance {#mechanical-resonance}
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## Control of Nanopositioning Systems {#control-of-nanopositioning-systems}
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### Feedback Control {#feedback-control}
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### Feedforward Control {#feedforward-control}
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## Book Summary {#book-summary}
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### Assumed Knowledge {#assumed-knowledge}
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### Content Summary {#content-summary}
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## References {#references}
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## The Piezoelectric Effect {#the-piezoelectric-effect}
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## Piezoelectric Compositions {#piezoelectric-compositions}
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## Manufacturing Piezoelectric Ceramics {#manufacturing-piezoelectric-ceramics}
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## Piezoelectric Transducers {#piezoelectric-transducers}
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## Application Considerations {#application-considerations}
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## Response of Piezoelectric Actuators {#response-of-piezoelectric-actuators}
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## Modeling Creep and Vibration in Piezoelectric Actuators {#modeling-creep-and-vibration-in-piezoelectric-actuators}
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## Chapter Summary {#chapter-summary}
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## References {#references}
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## Piezoelectric Tube Nanopositioners {#piezoelectric-tube-nanopositioners}
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### 63mm Piezoelectric Tube {#63mm-piezoelectric-tube}
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### 40mm Piezoelectric Tube Nanopositioner {#40mm-piezoelectric-tube-nanopositioner}
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## Piezoelectric Stack Nanopositioners {#piezoelectric-stack-nanopositioners}
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### Phyisk Instrumente P-734 Nanopositioner {#phyisk-instrumente-p-734-nanopositioner}
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### Phyisk Instrumente P-733.3DD Nanopositioner {#phyisk-instrumente-p-733-dot-3dd-nanopositioner}
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### Vertical Nanopositioners {#vertical-nanopositioners}
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### Rotational Nanopositioners {#rotational-nanopositioners}
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### Low Temperature and UHV Nanopositioners {#low-temperature-and-uhv-nanopositioners}
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### Tilting Nanopositioners {#tilting-nanopositioners}
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### Optical Objective Nanopositioners {#optical-objective-nanopositioners}
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## References {#references}
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## Introduction {#introduction}
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## Operating Environment {#operating-environment}
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## Methods for Actuation {#methods-for-actuation}
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## Flexure Hinges {#flexure-hinges}
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### Introduction {#introduction}
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### Types of Flexures {#types-of-flexures}
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### Flexure Hinge Compliance Equations {#flexure-hinge-compliance-equations}
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### Stiff Out-of-Plane Flexure Designs {#stiff-out-of-plane-flexure-designs}
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### Failure Considerations {#failure-considerations}
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### Finite Element Approach for Flexure Design {#finite-element-approach-for-flexure-design}
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## Material Considerations {#material-considerations}
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### Materials for Flexure and Platform Design {#materials-for-flexure-and-platform-design}
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### Thermal Stability of Materials {#thermal-stability-of-materials}
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## Manufacturing Techniques {#manufacturing-techniques}
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## Design Example: A High-Speed Serial-Kinematic Nanopositioner {#design-example-a-high-speed-serial-kinematic-nanopositioner}
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### State-of-the-Art Designs {#state-of-the-art-designs}
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### Tradeoffs and Limitations in Speed {#tradeoffs-and-limitations-in-speed}
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### Serial- Versus Parallel-Kinematic Configurations {#serial-versus-parallel-kinematic-configurations}
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### Piezoactuator Considerations {#piezoactuator-considerations}
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### Preloading Piezo-Stack Actuators {#preloading-piezo-stack-actuators}
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### Flexure Design for Lateral Positioning {#flexure-design-for-lateral-positioning}
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### Design of Vertical Stage {#design-of-vertical-stage}
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### Fabrication and Assembly {#fabrication-and-assembly}
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### Drive Electronics {#drive-electronics}
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\*\*\*\*0 Experimental Results
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## Chapter Summary {#chapter-summary}
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## References {#references}
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## Introduction {#introduction}
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## Sensor Characteristics {#sensor-characteristics}
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### Calibration and Nonlinearity {#calibration-and-nonlinearity}
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### Drift and Stability {#drift-and-stability}
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### Bandwidth {#bandwidth}
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### Noise {#noise}
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### Resolution {#resolution}
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### Combining Errors {#combining-errors}
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### Metrological Traceability {#metrological-traceability}
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## Nanometer Position Sensors {#nanometer-position-sensors}
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### Resistive Strain Sensors {#resistive-strain-sensors}
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### Piezoresistive Strain Sensors {#piezoresistive-strain-sensors}
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### Piezoelectric Strain Sensors {#piezoelectric-strain-sensors}
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### Capacitive Sensors {#capacitive-sensors}
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### MEMs Capacitive and Thermal Sensors {#mems-capacitive-and-thermal-sensors}
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### Eddy-Current Sensors {#eddy-current-sensors}
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### Linear Variable Displacement Transformers {#linear-variable-displacement-transformers}
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### Laser Interferometers {#laser-interferometers}
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### Linear Encoders {#linear-encoders}
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## Comparison and Summary {#comparison-and-summary}
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## Outlook and Future Requirements {#outlook-and-future-requirements}
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## References {#references}
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## Introduction {#introduction}
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## Shunt Circuit Modeling {#shunt-circuit-modeling}
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### Open-Loop {#open-loop}
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### Shunt Damping {#shunt-damping}
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## Implementation {#implementation}
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## Experimental Results {#experimental-results}
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### Tube Dynamics {#tube-dynamics}
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### Amplifier Performance {#amplifier-performance}
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### Shunt Damping Performance {#shunt-damping-performance}
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## Chapter Summary {#chapter-summary}
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## References {#references}
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## Introduction {#introduction}
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## Experimental Setup {#experimental-setup}
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## PI Control {#pi-control}
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## PI Control with Notch Filters {#pi-control-with-notch-filters}
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## PI Control with IRC Damping {#pi-control-with-irc-damping}
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## Performance Comparison {#performance-comparison}
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## Noise and Resolution {#noise-and-resolution}
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## Analog Implementation {#analog-implementation}
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## Application to AFM Imaging {#application-to-afm-imaging}
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## References {#references}
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## Introduction {#introduction}
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## Modeling {#modeling}
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### Actuator Dynamics {#actuator-dynamics}
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### Sensor Dynamics {#sensor-dynamics}
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### Sensor Noise {#sensor-noise}
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### Mechanical Dynamics {#mechanical-dynamics}
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### System Properties {#system-properties}
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### Example System {#example-system}
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## Damping Control {#damping-control}
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## Tracking Control {#tracking-control}
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### Relationship Between Force and Displacement {#relationship-between-force-and-displacement}
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### Integral Displacement Feedback {#integral-displacement-feedback}
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### Direct Tracking Control {#direct-tracking-control}
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### Dual Sensor Feedback {#dual-sensor-feedback}
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### Low Frequency Bypass {#low-frequency-bypass}
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### Feedforward Inputs {#feedforward-inputs}
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### Higher-Order Modes {#higher-order-modes}
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## Experimental Results {#experimental-results}
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### Experimental Nanopositioner {#experimental-nanopositioner}
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### Actuators and Force Sensors {#actuators-and-force-sensors}
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### Control Design {#control-design}
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### Noise Performance {#noise-performance}
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## Chapter Summary {#chapter-summary}
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## References {#references}
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## Why Feedforward? {#why-feedforward}
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## Modeling for Feedforward Control {#modeling-for-feedforward-control}
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## Feedforward Control of Dynamics and Hysteresis {#feedforward-control-of-dynamics-and-hysteresis}
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### Simple DC-Gain Feedforward Control {#simple-dc-gain-feedforward-control}
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### An Inversion-Based Feedforward Approach for Linear Dynamics {#an-inversion-based-feedforward-approach-for-linear-dynamics}
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### Frequency-Weighted Inversion: The Optimal Inverse {#frequency-weighted-inversion-the-optimal-inverse}
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### Application to AFM Imaging {#application-to-afm-imaging}
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## Feedforward and Feedback Control {#feedforward-and-feedback-control}
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### Application to AFM Imaging {#application-to-afm-imaging}
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## Iterative Feedforward Control {#iterative-feedforward-control}
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### The ILC Problem {#the-ilc-problem}
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### Model-Based ILC {#model-based-ilc}
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### Nonlinear ILC {#nonlinear-ilc}
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### Conclusions {#conclusions}
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## References {#references}
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## 10.1 Introduction {#10-dot-1-introduction}
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### 10.1.1 Background {#10-dot-1-dot-1-background}
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### 10.1.2 The Optimal Periodic Input {#10-dot-1-dot-2-the-optimal-periodic-input}
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## 10.2 Signal Optimization {#10-dot-2-signal-optimization}
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## 10.3 Frequency Domain Cost Functions {#10-dot-3-frequency-domain-cost-functions}
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### 10.3.1 Background: Discrete Fourier Series {#10-dot-3-dot-1-background-discrete-fourier-series}
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### 10.3.2 Minimizing Signal Power {#10-dot-3-dot-2-minimizing-signal-power}
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### 10.3.3 Minimizing Frequency Weighted Power {#10-dot-3-dot-3-minimizing-frequency-weighted-power}
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### 10.3.4 Minimizing Velocity and Acceleration {#10-dot-3-dot-4-minimizing-velocity-and-acceleration}
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### 10.3.5 Single-Sided Frequency Domain Calculations {#10-dot-3-dot-5-single-sided-frequency-domain-calculations}
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## 10.4 Time Domain Cost Function {#10-dot-4-time-domain-cost-function}
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### 10.4.1 Minimum Velocity {#10-dot-4-dot-1-minimum-velocity}
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### 10.4.2 Minimum Acceleration {#10-dot-4-dot-2-minimum-acceleration}
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### 10.4.3 Frequency Weighted Objectives {#10-dot-4-dot-3-frequency-weighted-objectives}
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## 10.5 Application to Scan Generation {#10-dot-5-application-to-scan-generation}
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### 10.5.1 Choosing β and K {#10-dot-5-dot-1-choosing-β-and-k}
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### 10.5.2 Improving Feedback and Feedforward Controllers {#10-dot-5-dot-2-improving-feedback-and-feedforward-controllers}
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## 10.6 Comparison to Other Techniques {#10-dot-6-comparison-to-other-techniques}
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## 10.7 Experimental Application {#10-dot-7-experimental-application}
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## 10.8 Chapter Summary {#10-dot-8-chapter-summary}
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## References {#references}
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## 11.1 Introduction {#11-dot-1-introduction}
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## 11.2 Modeling Hysteresis {#11-dot-2-modeling-hysteresis}
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### 11.2.1 Simple Polynomial Model {#11-dot-2-dot-1-simple-polynomial-model}
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### 11.2.2 Maxwell Slip Model {#11-dot-2-dot-2-maxwell-slip-model}
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### 11.2.3 Duhem Model {#11-dot-2-dot-3-duhem-model}
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### 11.2.4 Preisach Model {#11-dot-2-dot-4-preisach-model}
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### 11.2.5 Classical Prandlt-Ishlinksii Model {#11-dot-2-dot-5-classical-prandlt-ishlinksii-model}
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## 11.3 Feedforward Hysteresis Compensation {#11-dot-3-feedforward-hysteresis-compensation}
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### 11.3.1 Feedforward Control Using the Presiach Model {#11-dot-3-dot-1-feedforward-control-using-the-presiach-model}
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### 11.3.2 Feedforward Control Using the Prandlt-Ishlinksii Model {#11-dot-3-dot-2-feedforward-control-using-the-prandlt-ishlinksii-model}
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## 11.4 Chapter Summary {#11-dot-4-chapter-summary}
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## References {#references}
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## 12.1 Introduction {#12-dot-1-introduction}
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## 12.2 Charge Drives {#12-dot-2-charge-drives}
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## 12.3 Application to Piezoelectric Stack Nanopositioners {#12-dot-3-application-to-piezoelectric-stack-nanopositioners}
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## 12.4 Application to Piezoelectric Tube Nanopositioners {#12-dot-4-application-to-piezoelectric-tube-nanopositioners}
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## 12.5 Alternative Electrode Configurations {#12-dot-5-alternative-electrode-configurations}
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### 12.5.1 Grounded Internal Electrode {#12-dot-5-dot-1-grounded-internal-electrode}
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### 12.5.2 Quartered Internal Electrode {#12-dot-5-dot-2-quartered-internal-electrode}
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## 12.6 Charge Versus Voltage {#12-dot-6-charge-versus-voltage}
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### 12.6.1 Advantages {#12-dot-6-dot-1-advantages}
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### 12.6.2 Disadvantages {#12-dot-6-dot-2-disadvantages}
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## 12.7 Impact on Closed-Loop Control {#12-dot-7-impact-on-closed-loop-control}
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## 12.8 Chapter Summary {#12-dot-8-chapter-summary}
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## References {#references}
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## 13.1 Introduction {#13-dot-1-introduction}
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## 13.2 Review of Random Processes {#13-dot-2-review-of-random-processes}
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### 13.2.1 Probability Distributions {#13-dot-2-dot-1-probability-distributions}
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### 13.2.2 Expected Value, Moments, Variance, and RMS {#13-dot-2-dot-2-expected-value-moments-variance-and-rms}
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### 13.2.3 Gaussian Random Variables {#13-dot-2-dot-3-gaussian-random-variables}
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### 13.2.4 Continuous Random Processes {#13-dot-2-dot-4-continuous-random-processes}
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### 13.2.5 Joint Density Functions and Stationarity {#13-dot-2-dot-5-joint-density-functions-and-stationarity}
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### 13.2.6 Correlation Functions {#13-dot-2-dot-6-correlation-functions}
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### 13.2.7 Gaussian Random Processes {#13-dot-2-dot-7-gaussian-random-processes}
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### 13.2.8 Power Spectral Density {#13-dot-2-dot-8-power-spectral-density}
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### 13.2.9 Filtered Random Processes {#13-dot-2-dot-9-filtered-random-processes}
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### 13.2.10 White Noise {#13-dot-2-dot-10-white-noise}
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### 13.2.11 Spectral Density in V/sqrtHz {#13-dot-2-dot-11-spectral-density-in-v-sqrthz}
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### 13.2.12 Single- and Double-Sided Spectra {#13-dot-2-dot-12-single-and-double-sided-spectra}
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## 13.3 Resolution and Noise {#13-dot-3-resolution-and-noise}
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## 13.4 Sources of Nanopositioning Noise {#13-dot-4-sources-of-nanopositioning-noise}
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### 13.4.1 Sensor Noise {#13-dot-4-dot-1-sensor-noise}
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### 13.4.2 External Noise {#13-dot-4-dot-2-external-noise}
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### 13.4.3 Amplifier Noise {#13-dot-4-dot-3-amplifier-noise}
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## 13.5 Closed-Loop Position Noise {#13-dot-5-closed-loop-position-noise}
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### 13.5.1 Noise Sensitivity Functions {#13-dot-5-dot-1-noise-sensitivity-functions}
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### 13.5.2 Closed-Loop Position Noise Spectral Density {#13-dot-5-dot-2-closed-loop-position-noise-spectral-density}
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### 13.5.3 Closed-Loop Noise Approximations with Integral Control {#13-dot-5-dot-3-closed-loop-noise-approximations-with-integral-control}
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### 13.5.4 Closed-Loop Position Noise Variance {#13-dot-5-dot-4-closed-loop-position-noise-variance}
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### 13.5.5 A Note on Units {#13-dot-5-dot-5-a-note-on-units}
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## 13.6 Simulation Examples {#13-dot-6-simulation-examples}
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### 13.6.1 Integral Controller Noise Simulation {#13-dot-6-dot-1-integral-controller-noise-simulation}
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### 13.6.2 Noise Simulation with Inverse Model Controller {#13-dot-6-dot-2-noise-simulation-with-inverse-model-controller}
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### 13.6.3 Feedback Versus Feedforward Control {#13-dot-6-dot-3-feedback-versus-feedforward-control}
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## 13.7 Practical Frequency Domain Noise Measurements {#13-dot-7-practical-frequency-domain-noise-measurements}
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### 13.7.1 Preamplification {#13-dot-7-dot-1-preamplification}
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### 13.7.2 Spectrum Estimation {#13-dot-7-dot-2-spectrum-estimation}
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### 13.7.3 Direct Measurement of Position Noise {#13-dot-7-dot-3-direct-measurement-of-position-noise}
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### 13.7.4 Measurement of the External Disturbance {#13-dot-7-dot-4-measurement-of-the-external-disturbance}
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## 13.8 Experimental Demonstration {#13-dot-8-experimental-demonstration}
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## 13.9 Time-Domain Noise Measurements {#13-dot-9-time-domain-noise-measurements}
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### 13.9.1 Total Integrated Noise {#13-dot-9-dot-1-total-integrated-noise}
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### 13.9.2 Estimating the Position Noise {#13-dot-9-dot-2-estimating-the-position-noise}
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### 13.9.3 Practical Considerations {#13-dot-9-dot-3-practical-considerations}
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### 13.9.4 Experimental Demonstration {#13-dot-9-dot-4-experimental-demonstration}
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## 13.10 A Simple Method for Measuring the Resolution of Nanopositioning Systems {#13-dot-10-a-simple-method-for-measuring-the-resolution-of-nanopositioning-systems}
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## 13.11 Techniques for Improving Resolution {#13-dot-11-techniques-for-improving-resolution}
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## 13.12 Chapter Summary {#13-dot-12-chapter-summary}
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## References {#references}
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## Electrical Considerations {#electrical-considerations}
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### Amplifier and Piezo electrical models {#amplifier-and-piezo-electrical-models}
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<a id="orgb084203"></a>
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{{< figure src="/ox-hugo/fleming14_amplifier_model.png" caption="Figure 1: A voltage source \\(V\_s\\) driving a piezoelectric load. The actuator is modeled by a capacitance \\(C\_p\\) and strain-dependent voltage source \\(V\_p\\). The resistance \\(R\_s\\) is the output impedance and \\(L\\) the cable inductance." >}}
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Consider the electrical circuit shown in Figure [1](#orgb084203) where a voltage source is connected to a piezoelectric actuator.
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The actuator is modeled as a capacitance \\(C\_p\\) in series with a strain-dependent voltage source \\(V\_p\\).
The resistance \\(R\_s\\) and inductance \\(L\\) are the source impedance and the cable inductance respectively.
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<div class="exampl">
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<div></div>
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Typical inductance of standard RG-58 coaxial cable is \\(250 nH/m\\).
Typical value of \\(R\_s\\) is between \\(10\\) and \\(100 \Omega\\).
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</div>
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When considering the effects of both output impedance and cable inductance, the transfer function from source voltage \\(V\_s\\) to load voltage \\(V\_L\\) is second-order low pass filter:
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\begin{equation}
\frac{V\_L(s)}{V\_s(s)} = \frac{1}{\frac{s^2}{\omega\_r^2} + 2 \xi \frac{s}{\omega\_r} + 1}
\end{equation}
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with:
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- \\(\omega\_r = \frac{1}{\sqrt{L C\_p}}\\)
- \\(\xi = \frac{R\_s \sqrt{L C\_p}}{2 L}\\)
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### Amplifier small-signal Bandwidth {#amplifier-small-signal-bandwidth}
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The most obvious bandwidth limitation is the small-signal bandwidth of the amplifier.
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If the inductance \\(L\\) is neglected, the transfer function from source voltage \\(V\_s\\) to load voltage \\(V\_L\\) forms a first order filter with a cut-off frequency
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\begin{equation}
\omega\_c = \frac{1}{R\_s C\_p}
\end{equation}
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This is thus highly dependent of the load.
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The high capacitive impedance nature of piezoelectric loads introduces phase-lag into the feedback path.
A rule of thumb is that closed-loop bandwidth cannot exceed one-tenth the cut-off frequency of the pole formed by the amplifier output impedance \\(R\_s\\) and load capacitance \\(C\_p\\) (see Table [1](#table--tab:piezo-limitation-Rs) for values).
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<a id="table--tab:piezo-limitation-Rs"></a>
<div class="table-caption">
<span class="table-number"><a href="#table--tab:piezo-limitation-Rs">Table 1</a></span>:
Bandwidth limitation due to \(R_s\)
</div>
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| | Cp = 100 nF | Cp = 1 uF | Cp = 10 uF |
|--------------|-------------|-----------|------------|
| Rs = 1 Ohm | 1.6 MHz | 160 kHz | 16 kHz |
| Rs = 10 Ohm | 160 kHz | 16 kHz | 1.6 kHz |
| Rs = 100 Ohm | 16 kHz | 1.6 kHz | 160 Hz |
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The inductance \\(L\\) does also play a role in the amplifier bandwidth as it changes the resonance frequency.
Ideally, low inductance cables should be used.
It is however usually quite high compare to \\(\omega\_c\\) as shown in Table [2](#table--tab:piezo-limitation-L).
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<a id="table--tab:piezo-limitation-L"></a>
<div class="table-caption">
<span class="table-number"><a href="#table--tab:piezo-limitation-L">Table 2</a></span>:
Bandwidth limitation due to \(R_s\)
</div>
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| | Cp = 100 nF | Cp = 1 uF | Cp = 10 uF |
|-------------|-------------|-----------|------------|
| L = 25 nH | 3.2 MHz | 1 MHz | 320 kHz |
| L = 250 nH | 1 MHz | 320 kHz | 100 kHz |
| L = 2500 nH | 320 kHz | 100 kHz | 32 kHz |
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### Amplifier maximum slew rate {#amplifier-maximum-slew-rate}
Further bandwidth restrictions are imposed by the maximum **slew rate** of the amplifier.
This is the maximum rate at which the output voltage can change and is usually expressed in \\(V/\mu s\\).
For sinusoidal signals, the amplifiers slew rate must exceed:
\\[ SR\_{\text{sin}} > V\_{p-p} \pi f \\]
where \\(V\_{p-p}\\) is the peak to peak voltage and \\(f\\) is the frequency.
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<div class="exampl">
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<div></div>
If a 300kHz sine wave is to be reproduced with an amplitude of 10V, the required slew rate is \\(\approx 20 V/\mu s\\).
</div>
When dealing with capacitive loads, **the current limit is usually exceed well before the slew rate limit**.
### Current and Power Limitations {#current-and-power-limitations}
When driving the actuator off-resonance, the current delivered to a piezoelectric actuator is approximately:
\\[ I\_L(s) = V\_L(s) C\_p s \\]
For sinusoidal signals, the maximum positive and negative current is equal to:
\\[ I\_L^\text{max} = V\_{p-p} \pi f C\_p \\]
<a id="table--tab:piezo-required-current"></a>
<div class="table-caption">
<span class="table-number"><a href="#table--tab:piezo-required-current">Table 3</a></span>:
Minimum current requirements for a 10V sinusoid
</div>
| | Cp = 100 nF | Cp = 1 uF | Cp = 10 uF |
|-------------|-------------|-----------|------------|
| f = 30 Hz | 0.19 mA | 1.9 mA | 19 mA |
| f = 3 kHz | 19 mA | 190 mA | 1.9 A |
| f = 300 kHz | 1.9 A | 19 A | 190 A |
### Chapter Summary {#chapter-summary}
The bandwidth limitations of standard piezoelectric drives were identified as:
- High output impedance
- The presence of a ple in the voltage-feedback loop due to output impedance and load capacitance
- Insufficient current capacity due to power dissipation
- High cable and connector inductance
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### References {#references}
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## Bibliography {#bibliography}
<a id="orgd16fb21"></a>Fleming, Andrew J., and Kam K. Leang. 2014. _Design, Modeling and Control of Nanopositioning Systems_. Advances in Industrial Control. Springer International Publishing. <https://doi.org/10.1007/978-3-319-06617-2>.