Basic Electrical Circuits Analysis ECE 221
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K. A. Saaifan, Jacobs University, Bremen Basic Electrical Circuits Analysis ECE 221 PhD. Khodr Saaifan http://trsys.faculty.jacobs-university.de k.saaifan@jacobs-university.de 1 2 K. A. Saaifan, Jacobs University, Bremen Reference: Electric Circuits, 8th Edition James W. Nilsson, and Susan A. Riedel Lecturer: Khodr Saaifan (k.saaifan@jacobs-university.de) Research 1, Room 79 Office Phone 0421-200-3107 Office: M,W 1:30-3:30 pm Class Meets: Tue (11:15 am-12:30 pm) and Th (9:45-11:00 am) Grading: Two In-class Exams Laboratory/Practicum Final Exam Homework 50% 20% 20% 10% K. A. Saaifan, Jacobs University, Bremen 3 1. Introduction Electrical engineering is the field of engineering concerned with systems that produce, transmit, and measure electric signals Electrical circuits and systems are networks of electrical components used to supply, transmit and use electric power Circuit analysis is the process of studying and analyzing the various electrical quantities, such as currents, voltages, or powers, associated with each circuit's component Basic electrical circuits analysis covers the following topics: Linear circuit analysis Transient analysis Phasor domain circuit analysis 4 K. A. Saaifan, Jacobs University, Bremen 2. Basic Components and Electrical Circuits 2.1 Units and Scales The International System of Units (SI) defines 6 principal units from which the units of all other physical quantities can be derived Table 2.1 SI base units Basic Quantity Length Mass Time Electric current Thermodynamic temperature Luminous intensity Unit meter kilogram second ampere kelvin candela Symbol m kg s A K cd The SI unit of work or energy is the joule (J), which equals to a kg m2 s-2 in SI base units The SI unit of power is equivalent to one joule per second 5 K. A. Saaifan, Jacobs University, Bremen The SI unit uses prefixes based on the power of 10 to relate larger and smaller units to the basic unit Table 2.2 SI prefixes Basic Quantity 1012 109 106 103 10-2 10-3 10-6 10-9 10-12 Name Symbol tera giga mega kilo centi milli micro nano pico T G M k c m n p K. A. Saaifan, Jacobs University, Bremen 2.2 Circuit Variables 2.2.1 Charge Electric charge is an electrical property of the atomic particles of which matter consists, measured in coulombs (C) The charge of an electron is -1.602 X 10-19 C The coulomb is a large unit for charges such that in 1 C of charge, there are 1/(1.602 X 10-19)=6.24 X 1018 electrons The realistic or laboratory values of charges are on the order pC, nC, uC 2.2.2 Current Electric current is a flow of electric charge measured in ampere (A) note that 1 ampere (A) is equal to 1 coulombs per second (C/s) 6 K. A. Saaifan, Jacobs University, Bremen 7 The total charge transferred between time t0 and t can be expressed as There are several different types of current Direct current (dc) Sinusoidal current (ac) Exponential current Damped sinusoidal currents Representation of current in circuit analysis K. A. Saaifan, Jacobs University, Bremen Practice In the wire of shown figure, electrons are moving left to right to create a current of 1 mA. Determine and Ans: the current is in the opposite direction to flow of electrons 2.2.3 Voltage Voltage or potential difference measured in volts (V) is the energy required to move a unit of charge through an element note that 1 volt (V) is equal to 1 joule per coulombs (J/C) 8 K. A. Saaifan, Jacobs University, Bremen Representation of voltage in circuit analysis The plus (+) and minus (-) signs at the points a and b are used to define a reference direction (the voltage polarity) Similar to the electric current, a constant voltage is called a dc voltage, whereas a sinusoidal voltage (time-varying) is called an ac voltage For practical purposes, the power and energy are important measures in circuit analysis 9 K. A. Saaifan, Jacobs University, Bremen 10 2.2.4 Power Measured in watts (W) to indicate the average absorbing energy by a circuit element The sign of power + sign: the power is absorbed by the element (resistor) - sign: the power is supplied by the element (?) Since the energy can neither be created or dissipated (only transferred), the algebraic sum of powers in a circuit, at any instant of time, must be zero K. A. Saaifan, Jacobs University, Bremen 11 Determine p1 Ans: 2.2.5 Energy The energy absorbed or supplied by an element from time 0 to t is Electricity bills:: The electric power utility companies measure energy in kilowatt-hours (kWh), where 1 kWh = 3600 kJ 12 K. A. Saaifan, Jacobs University, Bremen 2.3 Voltage and Current Sources There are two types of circuit elements: Active elements (supplying energies), e.g., electric generator, batteries Passive elements (absorbing energy), e.g., resistors, capacitors, and inductors The passive elements can be classified according to the relationship of the current through it to the voltage Resistor, Capacitor, Inductor, Voltage and current sources: Voltage sources provides the circuit with a specified voltage Current source provides the circuit with a specified current 13 K. A. Saaifan, Jacobs University, Bremen Independent voltage source The source is characterized by a terminal voltage which is completely independent of the current through it dc voltage source ac voltage source Independent current source The current through the element is completely independent of the voltage across it dc current source ac current source 14 K. A. Saaifan, Jacobs University, Bremen Dependent sources The value of dependent sources depends on a voltage or currents of some other elements There are 4 different types of dependent sources current-controlled current source voltage-controlled current source Find vL Ans: voltage-controlled voltage source current-controlled voltage source 15 K. A. Saaifan, Jacobs University, Bremen Dependent sources The value of dependent sources depends on a voltage or currents of some other elements There are 4 different types of dependent sources current-controlled current source voltage-controlled current source voltage-controlled voltage source current-controlled voltage source Find the power absorbed by each element in the circuit Ans: 16 K. A. Saaifan, Jacobs University, Bremen 2.4 Ohm's Law Ohm's law states the voltage across conducting materials is directly proportional to the current flowing through the material, or where R is the resistance slope=R (V/A) The unit of the resistance is Ohm (Ω) The Resistor has a linear relation between the applied voltage and the current The current goes from a higher potential to a lower potential The power absorbed by the resistor can be expressed as The resistor is a passive element that cannot deliver or store energy Find i and R, if v=-10 V and R is absorbing 0.1 W Ans: 17 K. A. Saaifan, Jacobs University, Bremen The resistance of any cylindrical object is given as l Material with resistivity r A For a linear resistor, the ratio of the current to the voltage is called the conductance The SI unit of the electrical conductance G is siemens (S) Homework Assignments P2.11, P2.12, P2.15, P2.17, P2.20, P2.22, P2.23, P2.26, P2.31, P2.32, P2.33, and P2.35 18 K. A. Saaifan, Jacobs University, Bremen 3. Voltage and Current laws 3.1 Node, Branches, and loops A branch represents a single element such as a voltage source or a resistor A node is the point of the connection between two or more elements (branches) It is usually indicated by a dot in a circuit If a connecting wire (short circuit) connects two nodes, the two nodes constitute a single nodes A loop is any closed path in a circuit A closed path is formed by starting at a node, passing through a set of nodes and returning to the start node without passing through any node more than once branch loop K. A. Saaifan, Jacobs University, Bremen 3.2 Kirchhoff's Current Law Kirchhoff's Current Law (KCL) is based on the law of conservation of charge The algebraic sum of the currents entering any node is zero An alternative form of KCL is “the current entering any node = the current leaving that node” KCL can be applied to any closed boundary (closed path) 19 20 K. A. Saaifan, Jacobs University, Bremen 3.3 Kirchhoff's Voltage Law Kirchhoff's voltage Law (KVL) is based on the law of conservation of energy The algebraic sum of the voltages around any closed path is zero KVL When voltage sources are connected in series, KVL can be applied to obtain the total voltage a a = b b K. A. Saaifan, Jacobs University, Bremen Determine vx in the circuit Ans: 21 K. A. Saaifan, Jacobs University, Bremen Determine vx in the circuit Ans: 22 K. A. Saaifan, Jacobs University, Bremen 3.4 The Single-Loop Circuit Single-loop circuits Elements are connected in series All elements carry the same current We shall determine The current through each element The voltage across each element The power absorbed by each element 23 24 K. A. Saaifan, Jacobs University, Bremen 3.4 The Single-Loop Circuit Single-loop circuits Elements are connected in series All elements carry the same current We shall determine The current through each element The voltage across each element The power absorbed by each element We apply the following steps 1) Assign a reference direction for the unknown current 2) Assign voltage references to the elements 3) Apply KVL to the closed loop path 4) Use Ohms law where needed to get an equation in “i” 5) Solve for i KVL 25 K. A. Saaifan, Jacobs University, Bremen Find i and p for all elements in the circuit Ans: KVL
