Michaël Gauthier & Stéphane Régnier 
Robotic Microassembly 

Discover the latest models and methods for robotic microassembly
from around the world

This book presents and analyzes new and emerging models and
methods developed around the world for robotic microassembly, a new
and innovative way to produce better microsystems. By exploring
everything from the physics of micromanipulation to microassembly
to microhandling, it provides the first complete overview and
review of this rapidly growing field. Robotic Microassembly is
divided into three parts:

* Part One: Modeling of the Microworld

* Part Two: Handling Strategies

* Part Three: Robotic and Microassembly

Together, these three parts feature eight chapters contributed
by eight different authors. The authors, internationally recognized
experts in the field of robotic microassembly, represent research
laboratories in Asia, Europe, and North America. As a result,
readers get a remarkable perspective on different approaches to
robotic microassembly from around the world. Examples provided
throughout the chapters help readers better understand how these
different approaches work in practice. References at the end of
each chapter lead to the primary literature for further
investigation of individual topics.

Robotic microassembly offers a new, improved way to manufacture
high-performance microelectro-mechanical systems (MEMS). Therefore,
any professional or student involved in microrobotics,
micromechatronics, self-assembly or MEMS will find plenty of novel
ideas and methods in this book that set the stage for new
approaches to design and build the next generation of MEMS and
microproducts.

İçerik tablosu

Preface.

Introduction.

PART I MODELING OF THE MICROWORLD.

1 Microworld modeling in Vacuum and Gaseous
Environments.

1.1 Introduction.

1.2 Classical models.

1.3 Recent developments.

References.

2 Microworld Modelling: Impact of liquid and
roughness.

2.1 Introduction.

2.2 Liquid environments.

2.3 Microscopic analysis.

2.4 Surface Roughness.

References.

PART II HANDLING STRATEGIES.

3 Unified view of robotic microhandling and
selfassembly.

3.1 Background.

3.2 Robotic Microhandling.

3.3 Self Assembly.

3.4 Components of Microhandling.

3.5 Hybrid Microhandling.

3.6 Conclusion.

References.

4 Towards a precise micro manipulation.

4.1 Introduction.

4.2 Handling principles and strategies adapted to the
microworld.

4.3 Micromanipulation setup.

4.4 Experimentations.

4.5 Conclusion.

References.

5 Microhandling Strategies and Microassembly in
Submerged.

Medium.

5.1 Introduction.

5.2 Dielectrophoretic Gripper.

5.3 Submerged freeze gripper.

5.4 Chemical control of the release in submerged handling.

5.5 Release on adhesive substrate and microassembly.

5.6 Conclusion.

References.

PART III ROBOTIC AND MICROASSEMBLY.

6 Robotic microassembly of 3D MEMS Structures.

6.1 Introduction.

6.2 Methodology of the Microassembly System.

6.3 Robotic Micromanipulator.

6.4 Overview of Microassembly System.

6.5 Modular Design Features for Compatibility with the
Microassembly System.

6.6 Grasping Interface (Interface Feature).

6.7 PMKIL Microassembly Process.

6.8 Experimental Results and discussion.

6.9 Conclusion.

References.

7 High Yield Automated MEMS Assembly.

7.1 Introduction.

7.2 General Guidelines for 2 1 2D Microassembly.

7.3 Compliant Part Design.

7.4 3 Microassembly System.

7.5 High Yield Microassembly.

7.6 Conclusion and Future work.

References.

8 Design of a desktop microassembly machine and its
industrial.

application to micro solder ball manipulation.

8.1 Introduction.

8.2 Outline of the machine design to achieve fine accuracy.

8.3 Application to the joining process of electric
Components.

8.4 Pursuing higher accuracy.

8.5 Conclusion.

References.

Yazar hakkında

MICHAËL GAUTHIER, Ph D, is a researcher at the Centre
National de la Recherche Scientifique (CNRS), working with the
Automation and Micromechatronic Systems Department in the FEMTO-ST
Institute in France. His research interests focus on the modeling
and study of automatic micromanipulation strategies, with an
emphasis on artificial microobjects under 50 µm.

STÉPHANE RÉGNIER, Ph D, is Professor as well as
head of the micromanipulation team at the Institut des
Systèmes Intelligents et Robotique (ISIR) in France. His
research examines microscale phenomena such as micromechatronics
and biological cell micromanipulation.