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MESB 374 System Modeling and Analysis Electrical Systems

MESB 374 System Modeling and Analysis Electrical Systems. Electrical Systems. Basic Modeling Elements Interconnection Relationships Derive Input/Output Models. d. =. q. i. dt. t. =. +. 1. q. (. t. ). q. (. t. ). i. (. t. ). dt. . 1. 0. t. 0. =. ×. p. e. i. t.

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MESB 374 System Modeling and Analysis Electrical Systems

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  1. MESB 374 System Modeling and AnalysisElectrical Systems

  2. Electrical Systems • Basic Modeling Elements • Interconnection Relationships • Derive Input/Output Models

  3. d = q i dt t = + 1 q ( t ) q ( t ) i ( t ) dt  1 0 t 0 = × p e i t  = + 1 w ( t ) w ( t ) p ( t ) dt 1 0 t 0 t = + × 1  w ( t ) ( e i ) dt 0 t 0 Variables • q : charge [C] (Coulomb) • i: current [A] • e: voltage [V] • R: resistance [W] • C: capacitance [Farad] • L: inductance [H] (Henry) • p : power [Watt] • w : work ( energy ) [J] 1 [J] (Joule) = 1 [V-A-sec]

  4. Resistor Ohms Law Voltage across is proportional to the through current. Dissipates energy through heat. Analogous to friction elements in mechanical systems, e.g. dampers + eR- + eC- R i i C Basic Modeling Elements • Capacitor • Charge collected is proportional to the voltage across. • Current is proportional to the rate of change of the voltage across. • Energy supplied is stored in its electric field and can affect future circuit response. • Steady-state response: i=0, Open Circuit 2 1 1 2 Static relation dynamic relation

  5. -e(t) + + eL- i L Basic Modeling Elements • Inductor • Voltage across is proportional to the rate of the change of the through current. • Energy supplied is stored in its magnetic field. • Steady-state response: e=0, Short Circuit • Voltage Source • Maintain specified voltage across two points, regardless of the required current. • Current Source • Maintain specified current, regardless of the required voltage. 1 2 dynamic relation 1 2 Static relation 2 1 i(t)

  6. Complex impedance Z(s) Ratio of E(s), the Laplace transform (LP) of voltage across the terminal, to I(s), the Laplace transform (LP) of current through the element, under the assumption of zero initial conditions Complex impedances of resistor, capacitor, inductor are

  7. Kirchhoff's Voltage Law (loop law) The total voltage drop along any closed loop in the circuit is zero. Kirchhoff’s Current Law (node law) The algebraic sum of the currents at any node in the circuit is zero. Interconnection Laws 2 1 3 - + 4

  8. I(s) Z1 Z2 Zn E(s) I(s) Zn Z2 Z1 E(s) Series and Parallel Elements • Parallel combinations • Series combinations • Equivalent Complex Impedance

  9. Modeling Steps • Understand System Function and Identify Input/Output Variables • Draw Simplified Schematics Using Basic Elements • Develop Mathematical Model • Label Each Element and the Corresponding Voltages. • Label Each Node and the Corresponding Currents. • Apply Interconnection Laws. • Check that the Number of Unknown Variables equals the Number of Equations • Eliminate Intermediate Variables to Obtain Standard Forms.

  10. Derive the I/O model for the following circuit. Let voltage ei(t) be the input and the voltage across the capacitor be the output. No. of Unknowns: + eL- + eR- R i L + eC - + ei(t) _ C In Class Exercise Simplify 3 1 2 I/O Model: How to get I/O model by concept of complex impedance ? 4 Element Laws: Mechanical translational system Mechanical rotational system Kirchhoff’s Loop Law:

  11. Obtain the I/O model for the following circuit. The input is the voltage ei(t) of the voltage source and the through current of the inductor is the output. Voltage Law Current Law Unknown Variables I/O Model + eL- + eR1- R1 i L + eC _ + ei(t) _ + eR2 _ R2 C Example Loop 1: Loop 2: 2 1 3 i1 2 Node 2: Loop 1 i3 Loop 2 4 Elemental Equations:

  12. Example (cont.)

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