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Distributed-element model
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Related lectures (21)
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Introduction to LEM and Equivalent Circuits
Covers the Lumped Element Model, 'lumping' systems, equivalent circuits, and domain conversion.
Resonators: Eigenvalue Problem and Single Mode Solutions
Explores resonators' equation of motion, stress effect on frequency, and single mode solutions.
Force Detection: Basics and Structures
Covers force detection basics, structures, and mathematical models for detecting forces effectively.
Mechanical Scaling: Lumped Element Modelling
Covers Lumped Element Modelling in mechanical systems, simplifying complex systems into discrete elements that exchange energy.
Thermal FEM: Steady State and Transient Analysis
Explores steady-state and transient thermal analysis of silicon beams, including convection effects and practical exercises.
Localized vs Distributed Circuits: Criteria 1 and 2
Discusses criteria to distinguish between localized and distributed circuits based on time and frequency considerations.
Circuits: Localized or Distributed
Explores the theory of distributed circuits in electromagnetism and the importance of considering time delays in various engineering applications.
Transient Heat Diffusion: Lumped Capacitance Model
Introduces the lumped capacitance model for solving transient heat conduction under convective cooling, emphasizing the importance of the Biot number.
Direct Current Circuits: Kirchhoff's Laws and Resistors
Covers DC currents, resistors, capacitors, Kirchhoff's laws, and electromotive force in electric circuits.
Electrical Networks: Phasor Diagrams and Reactive Power
Explores active and reactive losses in electrical networks using phasor diagrams.
Finite Element Method: Basics and Applications
Covers the basics of the Finite Element Method for solid and structural modeling.
Delay Models: Resistance, Capacitance, and Inductance
Explores resistance, capacitance, and inductance calculations, MOS transistors, delay models, power dissipation, and PVT variations.
Transient Heat Transfer: Spatial Effects
Explores transient heat transfer with spatial effects, including Bi number and convective cooling.
Solid Surfaces in a Liquid: Surface Charge and Electrical Double Layer
Explores solid surfaces in a liquid, electrolyte presence, surface charge, and electrical double layer formation.
Homology of Riemann Surfaces
Explores the homology of Riemann surfaces, including singular homology and the standard n-simplex.
Groups & Rings: Morphisms, Kernels, and Injectivity
Explores group morphisms, kernels, and injectivity in group theory.
Concept of Proof in Mathematics
Delves into the concept of proof in mathematics, emphasizing the importance of evidence and logical reasoning.
Impedance and Kirchhoff Laws
Introduces impedance and Kirchhoff's laws for circuits, transfer functions, and filters.
Discrete Pressure Modes in Lecture 4
Explores discrete pressure modes and their impact on system analysis.
Fluid Dynamics: Navier-Stokes Equations
Covers the fundamentals of fluid dynamics and the Navier-Stokes equations for incompressible fluids.
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