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UNIVERSAL COLLEGE OF ENGG. & TECH.
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AKSHAY VERMA 130460111017 GUIDED BY: DHAVAL PATEL
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Circuit Variables
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Electric current is the time rate of change of charge, measured in amperes (A). dt dq i Where q is charge in coulombs(C) Sort A direct current (DC) is a current that remains constant with time. (I) An alternating current (AC) is a current that varies sinusoidally with time.
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Reference direction i i >0 means the real direction is same to the reference direction i <0 means the real direction is opposite to the reference direction
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Voltage (or potential difference) is the energy required to move a unit charge through an element, measured in volts(V). dq dw v Where w is energy in joules(J) And q is charge in coulombs(C) Reference direction or voltage polarity V+- V>0 means the real polarity is same to the reference polarity V<0 means the real polarity is opposite to the reference polarity
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passive sign convention Passive sign convention is satisfied when current enters through the positive polarity of the voltage. Unless stated, we will follow the passive sign convention throughout this course. i V+-
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Power is the time rate of expending or absorbing energy. Measured in watts(W) dt dw p vip using passive sign convention P=VI in a DC circuit The algebraic sum of power in a circuit, at any instant of time, must be zero. Power absorbed = - Power supplied
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Reference polarities for power using passive sign convention P > 0 absorbing power P < 0 releasing or supplying power Examples Law of conservation of energy must be obeyed in any electric circuit. 0p Power absorbed = - Power supplied
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Energy is the capacity to do work, measured in joules(J) The energy absorbed or supplied by an element from time t0 to time t is t t t t vidtpdtw 00
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Circuit Elements
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An electrical circuit is an interconnection of electrical circuit elements. A circuit element is basically just a component that makes up a complete electrical circuit. They are like building blocks that can be combined to create interesting circuits and model real world electronics. Some examples include conductors, voltage sources, current sources, and resistors.
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These elements can be categorized into two types: 1) Active elements and 2) Passive elements.
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Passive Circuit Elements The most basic of the passive circuit elements are 1) Resistance, 2) Inductance and 3) Capacitance. Passive elements do not generate (convert from non-electrical energy) any electricity. They may either consume energy (i.e. convert from electrical form to a non-electrical form such as heat or light), or store energy (in electrostatic and electromagnetic fields).
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Resistance Unit: ohm, Ω Letter symbol: R, r
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Symbols Figure (b) is the most general symbol for the resistor, especially when in printed form. R i(t) v(t) (a) The common circuit symbols for the Resistor are shown in figure. Figure (a) is the common symbol used for the general resistor, especially when hand-written. (b)
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Figure 1(c) is the symbol used for a non-inductive resistor, when it is necessary to clearly indicate that it has been specially made to have no or negligible inductance. A resistor made in coil form, must obviously have at least a small amount of inductance. (c)
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The basic equation governing the resistor is Ohm’s Law. v(t) = R. i(t) This may also be written as i(t) = G. v(t), G = 1/R where G is the conductance. (unit: siemen, S ) p(t) = v(t). i(t) = R. i^2(t) It is to be noted that p(t) is always positive indicating that power is always consumed and energy always increases with time.
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Inductance Unit: henry, H; Letter symbol: L, l
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Symbols i(t) v(t) (a) (b) Figure 2(a) shows a coil which is the simplest symbol (and most common when hand-written) for the inductor. A simpler representation of this is shown in figure 2(b) and is used to simplify the drawing of circuits.
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(c)(c) The symbol shown in figure 2(c) is sometimes used in printed form, especially on transformer nameplates, but is not a recommended form as it could lead to confusion with the common resistor.
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The energy stored in the magnetic field of an inductor can be expressed as. w(t) =∫ v(t). i(t). dt = ∫ L. i.di = ½ L. i^2 where, W = energy stored (Joules). L = inductance (henrys, H). It can be seen that w(t) is dependant only on i and not on time. Thus when the current i increases, the energy consumed increases and when i decreases, the energy consumed decreases. This actually means that there is no real consumption of energy but storage of energy.
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Capacitance Unit: farad, F Letter symbol: C, c
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Symbol i(t) v(t) (a)(a) The common circuit symbol for the Capacitor is shown in figure.
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When a voltage is applied across a capacitor, a positive charge is deposited on one plate and a negative charge on the other and the capacitor is said to store a charge. The charge stored is directly proportional to the applied voltage. q = C. v w(t) = v(t). i(t). dt = v. C d v dt C. v.dv = ½C. v 2 dt
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Summary: For a resistor, v = R i, i = G v For an inductor, v = Lp i, i=v/Lp Current through an inductor will never change suddenly. For a capacitor, v = i/Cp, i= Cpv Voltage across a capacitor will never change suddenly.
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Active Circuit Elements An Active Circuit Element is a component in a circuit which is capable of producing or generating energy. Active circuit elements are thus sources of energy (or simply sources) and can be categorized into i) Voltage sources and ii) Current sources.
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Sources can also be categorized as i) Independent sources, where the generated voltage (or current) does not depend on any other circuit voltage or current; ii) Dependent sources, where the generated voltage (or current) depends on another circuit voltage or current.
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Independent source For an independent voltage source (or current source), the terminal voltage (or current) would depend only on the loading and the internal source quantity, but not on any other circuit variable. Independent Voltage Sources Independent Current Sources
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(Independent) Voltage Sources An ideal voltage source keeps the voltage across it unchanged independent of load. However, practical voltage sources have a drop in voltage across their internal impedances. The voltage drop is generally small compared to the internal emf.
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(Independent) Current Sources An ideal current source keeps the current produced unchanged independent of load. Practical current sources have a drop in current across their internal admittances. The current drop is generally small compared to the internal source current
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Dependent Source A dependent voltage source (or current source) would have its terminal voltage (or current) depend on another circuit quantity such as a voltage or current. Thus four possibilities exist. These are o Voltage dependent (controlled) voltage source o Current dependent (controlled) voltage source o Voltage dependent (controlled) current source o Current dependent (controlled) current source
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Thank you. Thank you.
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