Survey
* Your assessment is very important for improving the workof artificial intelligence, which forms the content of this project
* Your assessment is very important for improving the workof artificial intelligence, which forms the content of this project
Stray voltage wikipedia , lookup
Skin effect wikipedia , lookup
History of electric power transmission wikipedia , lookup
Mains electricity wikipedia , lookup
Induction motor wikipedia , lookup
Electrification wikipedia , lookup
Wireless power transfer wikipedia , lookup
History of electromagnetic theory wikipedia , lookup
Alternating current wikipedia , lookup
Mathematics of radio engineering wikipedia , lookup
Calculating resistance A variable cross-section resistor treated as a serial combination of small straight-wire resistors: a b r ( x) b x; h h dx dr a b h dx R dR 2 r ( x) 0 h h 2 dr r a b ab b a Example: Equivalent resistances Series versus parallel connection What about power delivered to each bulb? P I 2 R or P I 2 R or Vab2 Vbc2 P R R Vde2 P R What if one bulb burns out? Symmetry considerations to calculate equivalent resistances No current through the resistor All resistors r Currents : I1 I / 3; I 2 I1 / 2 I2 I1 I1 I1 I2 I2 I2 I2 I1 I1 I1 I2 Total voltage drop between a and b : 1 1 1 5 V I ( )r I r 3 6 3 6 5 R r 6 Kirchhoff’s rules To analyze more complex (steady-state) circuits: 1. For any junction: Sum of incoming currents equals to sum of outgoing currents (conservation of charge) I 0 Valid for any junction 2. For any closed circuit loop: Sum of the voltages across all elements of the loop is zero (conservation of energy) V 0 - Valid for any close loop The number of independent equations will be equal to the number of unknown currents Loop rule – statement that the electrostatic force is conservative. Sign conventions for the loop rule A single-loop circuit IR1 2 IR2 1 0 I 1 2 R1 R2 With the numbers given, I is negative (Important is only consistenc y) Charging of a car battery Complex networks Find currents, potential differences and equivalent resistance I1 (1) ( I1 I 3 )(1) 0 (1) I 2 (1) ( I 2 I3 )(2) 0 (2) I 3 1 A I1 6 A I1 (1) I 3 (1) I 2 (1) 0 (3) I2 5 A Electrical Measuring Instruments Galvanometer Can be calibrated to measure current (or voltage) Example: Full-scale deflection Ifs =1 mA, internal coil resistance Rc =20 V I fs Rc 0.020V I fs Rc ( I a I fs ) Rsh For max current reading Ia of 50mA Rsh 0.408 Req 0.4 Vv I fs ( Rc Rsh ) For max voltage reading Vv =10V Rsh 9980 Req 10,000 Charging a Capacitor (instantaneous application of Kirchhoff’s rules to non-steady-state situation) Use lower case v, i, q to denote time-varying voltage, current and charge q iR 0 C t 0: q 0 dq q i dt R RC Initial current I 0 R Final conditions, i=0 Q f C dq q dt R RC dq dt q C RC i t q(t ) C (1 exp( )) RC dq t t i exp( ) I 0 exp( ) dt R RC RC Time-constant RC When time is small, capacitor charges quickly. For that either resistance or capacitance must be small (in either case current flows “easier”) Discharging a capacitor q IR 0 C t 0: q Q dq q I dt RC t ) RC Q t I (t ) exp( ) q (t ) Q exp( Power distribution systems Everything is connected in parallel V=120 V (US and Canada) V=220-240 V (Europe, Asia) Circuit Overloads and Short Circuits Fuse Circuit breaker Utility power (kW*h) 1 kW h (103W )(3600s) 3.6 106 J Magnetism First observation ~2500 years ago in fragments of magnetized iron ore Previously, interaction was thought in terms of magnetic poles The pole that points North on the magnetic field of the Earth is called north pole When points South – south pole By analogy with electric field bar magnet sets up a magnetic field in a space around it Earth itself is a magnet. Compass needle aligns itself along the earth’s magnetic field Earth as a magnet Magnetic Poles vs Electric Charge The interaction between magnetic poles is similar to the Coulomb interaction of electric charges BUT magnetic poles always come in pairs (N and S), nobody has observed yet a single pole (monopole). Despite numerous searches, no evidence of magnetic charges exist. In other words, there are no particles which create a radial magnetic field in the way an electric charge creates a radial field. Magnetic Field Electric charges produce electric fields E and, when move, magnetic fields B In turn, charged particles experience forces in those fields: Lorentz force acting on charge q moving with velocity v in electric field E and magnetic field B F q (E v B ) For now we will concentrate on how magnetic force affects moving charged particles and current-carrying conductors… Like electric field, magnetic field is a vector field, B