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The investigation of the behavior of ferromagnetic particles in an
external magnetic field is important for use in a wide range of
applications in magnetostatics problems, from biomedicine to
engineering. To the best of the author's knowledge, the systematic
analysis for this kind of investigation is not available in the
current literature. Therefore, this book contributes a complete
solution for investigating the behavior of two ferromagnetic
spherical particles, immersed in a uniform magnetic field, by
obtaining exact mathematical models on a boundary value problem.
While there are a vast number of common numerical and analytical
methods for solving boundary value problems in the literature, the
rapidly growing complexity of these solutions causes increase usage
of the computer tools in practical cases. We analytically solve the
boundary value problem by using a special technique called a
bispherical coordinates system and the numerical computations were
obtained by a computer tool. In addition to these details, we will
present step-by-step instructions with simple explanations
throughout the book, in an effort to act as inspiration in the
reader's own modeling for relevant applications in science and
engineering. On the other hand, the resulting analytical
expressions will constitute benchmark solutions for specified
geometric arrangements, which are beneficial for determining the
validity of other relevant numerical techniques. The generated
results are analyzed quantitatively as well as qualitatively in
various approaches. Moreover, the methodology of this book can be
adopted for real-world applications in the fields of
ferrohydrodynamics, applied electromagnetics, fluid dynamics,
electrical engineering, and so forth. Higher-level university
students, academics, engineers, scientists, and researchers
involved in the aforementioned fields are the intended audience for
this book.
This book explains how depth measurements from the Time-of-Flight
(ToF) range imaging cameras are influenced by the electronic
timing-jitter. The author presents jitter extraction and
measurement techniques for any type of ToF range imaging cameras.
The author mainly focuses on ToF cameras that are based on the
amplitude modulated continuous wave (AMCW) lidar techniques that
measure the phase difference between the emitted and reflected
light signals. The book discusses timing-jitter in the emitted
light signal, which is sensible since the light signal of the
camera is relatively straightforward to access. The specific types
of jitter that present on the light source signal are investigated
throughout the book. The book is structured across three main
sections: a brief literature review, jitter measurement, and jitter
influence in AMCW ToF range imaging.
This book explains how depth measurements from the Time-of-Flight
(ToF) range imaging cameras are influenced by the electronic
timing-jitter. The author presents jitter extraction and
measurement techniques for any type of ToF range imaging cameras.
The author mainly focuses on ToF cameras that are based on the
amplitude modulated continuous wave (AMCW) lidar techniques that
measure the phase difference between the emitted and reflected
light signals. The book discusses timing-jitter in the emitted
light signal, which is sensible since the light signal of the
camera is relatively straightforward to access. The specific types
of jitter that present on the light source signal are investigated
throughout the book. The book is structured across three main
sections: a brief literature review, jitter measurement, and jitter
influence in AMCW ToF range imaging.
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