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Transcript
Electric Fields A charged object experiences a force inside an electric field Electric Fields • The field does work on charged objects • Charges accelerate •W=QxV Potential Difference • Work done to move 1 coulomb of charge • 1V = 1 J C-1 Internal Resistance Internal resistance, r E.m.f. (E) Current, I E = I.R + I.r Load, R Internal Resistance • Resistance of power supply itself • work is done to push charges through power supply hence ‘Lost Volts’ • E.M.F. Maximum energy to push unit charge around circuit • Terminal potential difference , work to push unit charge through external circuit ( load ) Internal Resistance • E = V t.p.d. + V lost • V t.p.d. = E - V lost V t.p.d = E - I x r V t.p.d E.M.F open circuit p.d. NO lost volts - slope = r I Short circuit current E = V lost Wheatstone Bridge R1 R2 R3 R3 R4 Wheatstone Bridge • At balance point R1 R3 For out of balance bridge V r = R2 R4 Alternating Current Voltage ( V ) Alternating Voltage Peak Voltage 2 1 0 -1 0 -2 Vpeak = 2 x Vr .m.s 5 10 Time ( ms ) 15 r.m.s. voltage Alternating Current I peak = 2 x I r .m.s Resistance is independent of frequency Capacitors • Dielectric 0V + 5V Charge builds up on plates ( does not flow through dielectric ) 1 F = 1 C V-1 Q C= V Capacitors • Work is done charging up Capacitor • Energy ( charge) is stored in Capacitor • Ee = 0.5.Q.V Q EE = 0.5 C.V 2 Q2 EE = 0.5 C V Area under graph = Energy Stored Slope = Capacitance Capacitors • • • • Capacitors block d.c. yet pass a.c Capacitors supply time delays Capacitors used to smooth a.c. Capacitors used as microphones Capacitors • I directly proportional to frequency I f Op Amps • Voltage Amplifier • Ideal Op Amp a) Input current = 0 A • b) p.d. across inverting and non inverting pin = 0V Op Amps : Inverting Mode Gain = Rf Vout = Rin Vin Rf Rin Vin Vout Op Aps : Inverting Mode • Saturation occurs at c.a. 85 % of p.supply voltage Vout Vin Op Amps : Summing Amp 2 inputs can be added together Op Amps :Differential Mode • Difference between two inputs is amplified Rf R4 Gain = (V2 V1 ) Rin Rf V1 V2 R3 Vout R i Rf Rin R3 R4 Op Amps :Differential Mode • Can be connected to a wheatstone bridge • Used in ECG to subtract the 50 Hz mains hum from the heart signal Rf R3 = Rin R4 Op Amps : Output • Output current is of micro amp order • To drive a speaker or motor a power amp must be used I.e. an NPN transistor or a MOSFET transistor • This increases the current Op Amps : Output NPN is switched on by output from op amp MOSFET is switched by output from op amp
