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Transcript
EKT101 Electric Circuit Theory Chapter 1 Variable and Circuit Elements Overview of Chapter 1 1.1 1.2 1.3 1.4 1.5 1.6 1.7 1.8 Concepts of Circuit. Systems of Units. Electric Charge, Current. Voltage, Power and Energy. Circuit Elements. Ohm’s Law Circuit with Dependence Source Kirchhoff's Law 2 Objective of Chapter 1 Know the basic of electrical circuit Know the symbols for and definition of independent and dependent sources Know the definition of basic electrical quantities : voltage, current, and power Be able to calculate the power absorbed by a circuit element using the passive sign convention 3 1.1 Concept of Circuits An electric circuit is unbroken path along which an electric current exists or is intended or able to flow. A circuit consist of the power source, two conducting wires, and a small lamp. When the wires are connected properly, the circuit is said to be closed and the lamp will light. The current flows from the cell along one wire to the lamp, through the lamp, and along the other wire back to the cell. When the wires are disconnected, the circuit is said to be open. 4 1.2 System of Units (1) Six basic units Quantity Length Mass Time Electric current Thermodynamic temperature Luminous intensity Basic unit meter kilogram second ampere kelvin Symbol m Kg s A K candela cd 5 1.2 System of Units (2) The derived units commonly used in electric circuit theory Decimal multiples and submultiples of SI units 6 1.3 Electric Charges, Current (1) Charge is an electrical property of the atomic particles of which matter consists, measured in coulombs (C). The charge e on one electron is negative and equal in magnitude to 1.602 10-19 C which is called as electronic charge. The charges that occur in nature are integral multiples of the electronic charge. 7 1.3 Electric Charges, Current (2) Electric current i = dq/dt. The unit of ampere can be derived as 1 A = 1C/s. A direct current (dc) is a current that remains constant with time. An alternating current (ac) is a current that varies sinusoidally with time. (reverse direction) 8 1.3 Electric Charges, Current (3) The direction of current flow Positive ions Negative ions 9 1.3 Electric Charges, Current (4) Example A conductor has a constant current of A. 5 How many electrons pass a fixed point on the conductor in one minute? 10 1.3 Electric Charges, Current (5) Solution Total no. of charges pass in 1 min is given by 5 A = (5 C/s)(60 s/min) = 300 C/min Total no. of electron pass in 1 min is given 300 C/min 21 1 . 87 x 10 electrons/ min 19 1.602 x10 C/electron 11 1.4 Voltage, Power and Energy (1) Voltage (or potential difference) is the energy required to move a unit charge through an element, measured in volts (V). Mathematically, vab dw / dq (volt) ◦ w is energy in joules (J) and q is charge in coulomb (C). Electric voltage, vab, is always across the circuit element or between two points in a circuit. ◦ vab > 0 means the potential of a is higher than potential of b. ◦ vab < 0 means the potential of a is lower than potential of b. 12 1.4 Voltage, Power and Energy (2) Power is the time rate of expending or absorbing energy, measured in watts (W). Mathematical expression: dw dw dq p vi dt dq dt Passive sign convention absorbing power supplying power 13 1.4 Voltage, Power and Energy (3) The law of conservation of energy p0 • Energy is the capacity to do work, measured in joules (J). • Mathematical expression t t t0 t0 w pdt vidt 14 1.5 Circuit Elements (1) Active Elements Passive Elements • A dependent source is an active element in which the source quantity is controlled by another voltage or current. Independent Dependant sources sources • They have four different types: VCVS, CCVS, VCCS, CCCS. Keep in minds the signs of dependent sources. 15 1.5 Circuit Elements (2) Example Obtain the voltage v in the branch shown for i2 = 1A. 16 1.5 Circuit Elements (3) Solution Voltage v is the sum of the current-independent 10-V source and the current-dependent voltage source vx. Note that the factor 15 multiplying the control current carries the units Ω. Therefore, v = 10 + vx = 10 + 15(1) = 25 V 17 1.6 Ohm’s Law (1) Ohm’s law states that the voltage across a resistor is directly proportional to the current I flowing through the resistor. Mathematical expression for Ohm’s Law is as follows: v iR Two extreme possible values of R: 0 (zero) and (infinite) are related with two basic circuit concepts: short circuit and open circuit. 18 1.6 Ohm’s Law(2) Conductance is the ability of an element to conduct electric current; it is the reciprocal of resistance R and is measured in mhos or siemens. 1 i G R v The power dissipated by a resistor: 2 v p vi i R R 2 19 1.7 Nodes, Branches and Loops (1) A branch represents a single element such as a voltage source or a resistor. A node is the point of connection between two or more branches. A loop is any closed path in a circuit. A network with b branches, n nodes, and l independent loops will satisfy the fundamental theorem of network topology: b l n 1 20 1.7 Nodes, Branches and Loops (2) Example 1 Original circuit Equivalent circuit How many branches, nodes and loops are there? 21 1.7 Nodes, Branches and Loops (3) Example 2 Should we consider it as one branch or two branches? How many branches, nodes and loops are there? 22 1.8 Kirchhoff’s Laws (1) Kirchhoff’s current law (KCL) states that the algebraic sum of currents entering a node (or a closed boundary) is zero. N Mathematically, i n 1 n 0 23 1.8 Kirchhoff’s Laws (2) Example 3 Determine the current I for the circuit shown in the figure below. I + 4-(-3)-2 = 0 I = -5A This indicates that the actual current for I is flowing in the opposite direction. We can consider the whole enclosed area as one “node”. 24 1.8 Kirchhoff’s Laws (3) Kirchhoff’s voltage law (KVL) states that the algebraic sum of all voltages around a closed path (or loop) is zero. Mathematically, M v m 1 n 0 25 1.8 Kirchhoff’s Laws (4) Example 4 Applying the KVL equation for the circuit of the figure below. va-v1-vb-v2-v3 = 0 V1 = IR1 v2 = IR2 v3 = IR3 va-vb = I(R1 + R2 + R3) va vb I R1 R2 R3 26