s-domain Circuit Analysis

Similar documents

Basic Principle of Buck-Boost

The circuit shown on Figure 1 is called the common emitter amplifier circuit. The important subsystems of this circuit are:

Multiple stage amplifiers

(6)(2) (-6)(-4) (-4)(6) + (-2)(-3) + (4)(3) + (2)(-3) = = 0

Linear Circuits Analysis. Superposition, Thevenin /Norton Equivalent circuits

Faraday's Law of Induction

Chapter 12 Inductors and AC Circuits

TRANSFORM AND ITS APPLICATION

Chapter 6 Inductance, Capacitance, and Mutual Inductance

8.5 UNITARY AND HERMITIAN MATRICES. The conjugate transpose of a complex matrix A, denoted by A*, is given by

Module 2. AC to DC Converters. Version 2 EE IIT, Kharagpur 1

Correlated Noise Modeling - An Implementation into HICUM

Lecture #21. MOS Capacitor Structure

Lecture 3: Force of Interest, Real Interest Rate, Annuity

Solution: Let i = 10% and d = 5%. By definition, the respective forces of interest on funds A and B are. i 1 + it. S A (t) = d (1 dt) 2 1. = d 1 dt.

Ring structure of splines on triangulations

Lecture 2: Single Layer Perceptrons Kevin Swingler

Equivalent Electrical Simulation of High -Power Ultrasonic Piezoelectric Transducers by Using Finite Element Analysis

This circuit than can be reduced to a planar circuit

Imperial College London

Quantization Effects in Digital Filters

Chapter 14, Problem 1. Find the transfer function V o. /V i. of the RC circuit in Fig Express it using ω = 1/RC. Figure For Prob

Chapter 31B - Transient Currents and Inductance

Time Domain simulation of PD Propagation in XLPE Cables Considering Frequency Dependent Parameters

RELIABILITY, RISK AND AVAILABILITY ANLYSIS OF A CONTAINER GANTRY CRANE ABSTRACT

The Full-Wave Rectifier

Consider a 1-D stationary state diffusion-type equation, which we will call the generalized diffusion equation from now on:

Implementation of Deutsch's Algorithm Using Mathcad

Lecture 3: Annuity. Study annuities whose payments form a geometric progression or a arithmetic progression.

Computational Fluid Dynamics II

Laddered Multilevel DC/AC Inverters used in Solar Panel Energy Systems

7.5. Present Value of an Annuity. Investigate

The Bridge Rectifier

Peak Inverse Voltage

Canon NTSC Help Desk Documentation

Safety instructions VEGAVIB VB6*.GI*******

Recurrence. 1 Definitions and main statements

FINANCIAL MATHEMATICS. A Practical Guide for Actuaries. and other Business Professionals

Simple Interest Loans (Section 5.1) :

Addendum to: Importing Skill-Biased Technology

Chapter 4 ECONOMIC DISPATCH AND UNIT COMMITMENT

Analysis and Modeling of Magnetic Coupling

Introduction to Differential Algebraic Equations

VRT012 User s guide V0.1. Address: Žirmūnų g. 27, Vilnius LT-09105, Phone: (370-5) , Fax: (370-5) , info@teltonika.

In our example i = r/12 =.0825/12 At the end of the first month after your payment is received your amount in the account, the balance, is

An Isolated Feedback Circuit for a Flyback Charging Circuit

1. Introduction. 2. Derivation of a time-discrete algorithm for a PID controller

HALL EFFECT SENSORS AND COMMUTATION

0.02t if 0 t 3 δ t = if 3 < t

Small-Signal Analysis of BJT Differential Pairs

Active Compensation of Transducer Nonlinearities

Support Vector Machines

Extending Probabilistic Dynamic Epistemic Logic

Damage detection in composite laminates using coin-tap method

Time Value of Money. Types of Interest. Compounding and Discounting Single Sums. Page 1. Ch. 6 - The Time Value of Money. The Time Value of Money

Comparison of Control Strategies for Shunt Active Power Filter under Different Load Conditions

A frequency decomposition time domain model of broadband frequency-dependent absorption: Model II

RESEARCH ON DUAL-SHAKER SINE VIBRATION CONTROL. Yaoqi FENG 1, Hanping QIU 1. China Academy of Space Technology (CAST)

Course Notes: Linear circuit theory and differential equations

n + d + q = 24 and.05n +.1d +.25q = 2 { n + d + q = 24 (3) n + 2d + 5q = 40 (2)

Causal, Explanatory Forecasting. Analysis. Regression Analysis. Simple Linear Regression. Which is Independent? Forecasting

Level Annuities with Payments Less Frequent than Each Interest Period

10. (# 45, May 2001). At time t = 0, 1 is deposited into each of Fund X and Fund Y. Fund X accumulates at a force of interest

NOTE: The Flatpak version has the same pinouts (Connection Diagram) as the Dual In-Line Package. *MR for LS160A and LS161A *SR for LS162A and LS163A

Health Monitoring of DC link Capacitors

Chapter 35 Alternating Current Circuits

Topic 5. An Interleaved PFC Preregulator for High-Power Converters

substances (among other variables as well). ( ) Thus the change in volume of a mixture can be written as

Luby s Alg. for Maximal Independent Sets using Pairwise Independence

Using Series to Analyze Financial Situations: Present Value

The Mathematical Derivation of Least Squares

Switching Regulator IC Series Inductor Calculation for Buck Converter IC

Formulating & Solving Integer Problems Chapter

J. Parallel Distrib. Comput.

GRAVITY DATA VALIDATION AND OUTLIER DETECTION USING L 1 -NORM

A hybrid global optimization algorithm based on parallel chaos optimization and outlook algorithm

ITS-90 FORMULATIONS FOR VAPOR PRESSURE, FROSTPOINT TEMPERATURE, DEWPOINT TEMPERATURE, AND ENHANCEMENT FACTORS IN THE RANGE 100 TO +100 C.

Response Coordination of Distributed Generation and Tap Changers for Voltage Support

Automated information technology for ionosphere monitoring of low-orbit navigation satellite signals

Chapter 7: Answers to Questions and Problems

Abstract. 260 Business Intelligence Journal July IDENTIFICATION OF DEMAND THROUGH STATISTICAL DISTRIBUTION MODELING FOR IMPROVED DEMAND FORECASTING

Analysis and Modeling of Buck Converter in Discontinuous-Output-Inductor-Current Mode Operation *

ES250: Electrical Science. HW7: Energy Storage Elements

benefit is 2, paid if the policyholder dies within the year, and probability of death within the year is ).

Problem Set 3. a) We are asked how people will react, if the interest rate i on bonds is negative.

Rotation Kinematics, Moment of Inertia, and Torque

POLYSA: A Polynomial Algorithm for Non-binary Constraint Satisfaction Problems with and

Loudspeaker Voice-Coil Inductance Losses: Circuit Models, Parameter Estimation, and Effect on Frequency Response

What is Candidate Sampling

Risk-based Fatigue Estimate of Deep Water Risers -- Course Project for EM388F: Fracture Mechanics, Spring 2008

COMPUTER SUPPORT OF SEMANTIC TEXT ANALYSIS OF A TECHNICAL SPECIFICATION ON DESIGNING SOFTWARE. Alla Zaboleeva-Zotova, Yulia Orlova

Probabilistic Linear Classifier: Logistic Regression. CS534-Machine Learning

Derivation of Humidty and NOx Humidty Correction Factors

Transcription:

S-Doman naly

-Doman rcut naly Tme doman t doman near rcut aplace Tranform omplex frequency doman doman Tranformed rcut Dfferental equaton lacal technque epone waveform aplace Tranform nvere Tranform - lgebrac equaton lgebrac technque epone tranform

Krchhoff aw n -Doman t doman Krchhoff current law K doman t t 3 t 4 t t t t t 3 4 3 4 v t v t 4 Krchhoff voltage law K v t v 3 t v 5 t v t v t v t 3 3

Sgnal Source n Doman t doman oltage Source: v t vs t t depend on crcut t vt v S t S doman oltage Source: S depend on crcut urrent Source: t S t v t depend on crcut t v t t S S urrent Source: S depend on crcut

Tme Doman Tme and -Doman Element Model mpedance and oltage Source for ntal ondton t -Doman etor: v t t v t etor: nductor: v t d t dt v t t nductor: apactor: v t t d τ τ v v t t v apactor: v

mpedance and oltage Source for ntal ondton mpedance wth wth v voltage tranform current tranform wth all ntal condton et to zero mpedance of the three pave element

Tme and -Doman Element Model dmttance and urrent Source for ntal ondton Tme Doman t -Doman etor: t v t v t etor: nductor: t t v d τ τ apactor: dv t t dt v v t t t t nductor: v apactor: v

dmttance and urrent Source for ntal ondton dmttance wth all ntal condton et to zero current tranform voltage tranform wth wth v dmttance of the three pave element

Example: Solve for urrent Waveform t ut t y K: etor: nductor: t u e e t t t nvere Tranform: forced repone natural repone

Sere Equvalence and oltage Dvon et of rcut et of rcut EQ EQ K: EQ EQ EQ

Parallel Equvalence and urrent Dvon et of rcut et of rcut EQ EQ K: EQ EQ EQ

Example: Equvalence mpedance and dmttance v t EQ EQ EQ EQ v t nductor current at t capactor voltage Fnd equvalent mpedance at and Solve for v t EQ EQ EQ EQ EQ EQ

General Technque for -Doman rcut naly Node oltage naly n -doman Ue Krchhoff urrent aw K Get equaton of node voltage Ue current ource for ntal condton oltage ource current ource Meh urrent naly n -doman Ue Krchhoff oltage aw K Get equaton of current n the meh Ue voltage ource for ntal condton urrent ource voltage ource Work only for Planar crcut

Formulatng Node-oltage Equaton Step : Tranform the crcut nto the doman ung current ource to repreent capactor and nductor ntal condton Step : Select a reference node. dentfy a node voltage at each of the non-reference node and a current wth every element n the crcut Step : Wrte K connecton contrant n term of the element current at the non-reference node Step 3: Ue the element admttance and the fundamental property of node voltage to expre the element current n term of the node voltage Step 4: Subttute the devce contrant from Step 3 nto the K connecton contrant from Step and arrange the reultng equaton n a tandard form

Example: Formulatng Node-oltage Equaton S S t t doman doman 3 eference node Step : Tranform the crcut nto the doman ung current ource to repreent capactor and nductor ntal condton Step : dentfy N- node voltage and a current wth each element Step : pply K at node and : Node : S Node : v 3 Step 3: Expre element equaton n term of node voltage v G where G 3 [ ] [ ]

Formulatng Node-oltage Equaton ont d Step : pply K at node and : Node : Node : 3 S v Step 3: Expre element equaton n term of node voltage [ ] [ ] where 3 G G Step 4: Subttute eqn. n Step 3 nto eqn. n Step and collect common term to yeld node-voltage eqn. v G S Node : Node :

Solvng -Doman rcut Equaton G rcut Determnant: G G G Depend on crcut element parameter:,, G/, not on drvng force and ntal condton Solve for node ung ramer rule: S v G S G v G G ero State when ntal condton ource are turned off ero nput when nput ource are turned off

Solvng -Doman rcut Eqn. ont d Solve for node ung ramer rule: G S G G S G v G v G G ero State ero nput

Network functon Network Functon ero- tate epone Tranform nput Sgnal Tranform Drvng-pont functon relate the voltage and current at a gven par of termnal called a port Tranfer functon relate an nput and repone at dfferent port n the crcut T oltage Tranfer Functon T urrent Tranfer Functon n T Tranfer dmttance T Tranfer mpedance n T T nput rcut n the zero-tate rcut n the zero-tate Output or or Out Out n n T T Out Out

alculatng Network Functon EQ T Drvng-pont mpedance oltage tranfer functon: EQ T Drvng-pont admttance oltage tranfer functon:

mpule epone and Step epone nput-output relatonhp n -doman T X When nput gnal an mpule T T mpule repone equal network functon H mpule repone tranform ht mpule repone waveform When nput gnal a tep G tep repone tranform gt tep repone waveform T G g H h τ dτ, h t x t δ t x t u t dg t dt t nput T rcut Output X mean equal almot everywhere, exclude thoe pont at whch gt ha a dcontnuty