Question

all formulas of magnetic effects of electric current class 10​

Answer 1

Answer:

CHAPTER- Electricity

Formula 1:

Coulomb’s Law =(Q1*Q2)/(r*r)k ; where k= constant, Q1, Q2 are the charges on bodies 1 and 2.

Formula 2:

Conduction current ( I ) = dQ/dt ; where Q= charge and t = time, dQ=charge on the body for very short interval of time dt

Formula 3:

Constant current ( I ) = Q/t ; where Q= charge and t= time

Formula 4:

Current density ( J ) = I/ A ; where I= current and A= area in square meter

Formula 5:

Electric Power ( P ) = V/I ; where V= voltage and I= current

Formula 6:

Conductance ( G ) = 1/ R ; where R = resistance of the body

Formula 7:

Ohm’s Law = V= IR ; where V= voltage, I = current and R= resistance of the body

Formula 8:

Series connection of resistors, Req =( R1+ R2 + R3 +….+ Rn) ; where R1, R2, R3 — Rn are the respective resistances of “n” number of bodies.

Formula 9:

Parallel connection of resistors, Req = (1/R1 + 1/R2 + 1/R3 +…+ 1/Rn) ; where R1, R2, R3 — Rn are the respective resistances of “n” number of bodies.

Formula 10:

Electric work done = U I t = UQ ; where U= potential energy , Q= charge, I = curent and t=time

Formula 11:

Thermal emission = j = AT*T exp(-Wa/kT)

Formula 12:

Force in electric field ( F) = E .Q ; where E= Electric Field and Q= Charge on body

Formula 13:

Voltage in plate capacitor = V= Ed ; where E= Electric Field and d= distance vector

Formula 14:

Energy of particle accelerated in an electric field ( E ) = QU

Formula 15:

Effective current in AC circuit = I = Ieff/ ( 2 ) ^1/2

Formula 16:

Effective voltage in AC circuit = V = Veff / (2 )^ 1/2

Formula 17:

Ohm’s law in a.c. circuit , V= IZ ; where I = current, V= voltage and Z= impedance

Formula 18:

Thomsons equation, w = (1/LC )^ (1/2) ; where L=inductance, W=Work Done and C = Capacitance.

CHAPTER- Magnetic Effects of Current

Formula 1:

B (inversely proportional) (I/r) ; where B= Strength of Magnetic Field, I=current passed through conductor and r=distance from conductor

Formula 2:

B=(µI/2πr) where B= Strength of Magnetic Field, r= distance from conductor, I=current passed through conductor and µ= permeability of medium

Answer 2

Magnetic effect is one of the two effects that a flowing electric charge contributes to. The other being the heating effect. A flow of electricity creates a magnetic field around the current carrying conductor by the virtue of this property, This is in accordance to Faraday's Law. The formulae for the same have been mentioned below:

(1) Coulomb’s Law  = (Q1×Q2)/(r×r)k ;

where k= constant, Q1, Q2 are the charges on bodies 1 and 2.

(2) Conduction current ( I ) = dQ/dt ;

where Q= charge and t = time, dQ=charge on the body for very short interval of time dt

(3) Constant current ( I ) = Q/t ;

where Q= charge and t= time

(4)Current density ( J ) = I/ A ;

where I= current and A= area in square meter

(5)Electric Power ( P ) = V/I ;

where V= voltage and I= current

(6)Conductance ( G ) = 1/ R ;

where R = resistance of the body

(7) Ohm’s Law = V= IR ;

where V= voltage, I = current and R= resistance of the body

(8) Series connection of resistors, Req =( R1+ R2 + R3 +….+ Rn) ;

where R1, R2, R3 — Rn are the respective resistances of “n” number of bodies.

(9)Parallel connection of resistors, Req = (1/R1 + 1/R2 + 1/R3 +…+ 1/Rn) ;

where R1, R2, R3 — Rn are the respective resistances of “n” number of bodies.

(10) Electric work done = U I t = UQ ;

where U= potential energy , Q= charge, I = curent and t=time

(11)Thermal emission = j = AT*T exp(-Wa/kT)

(12) Force in electric field ( F) = E .Q ;

where E= Electric Field and Q= Charge on body

(13) Voltage in plate capacitor = V= Ed ;

where E= Electric Field and d= distance vector

(14) Energy of particle accelerated in an electric field ( E ) = QU

(15) Effective current in AC circuit = I = Ieff/ ( 2 ) ^1/2

(16) Effective voltage in AC circuit = V = Veff / (2 )^ 1/2

(17) Ohm’s law in a.c. circuit , V= IZ ;

where I = current, V= voltage and Z= impedance

(18)Thomsons equation, w = (1/LC )^ (1/2) ;

where L=inductance, W=Work Done and C = Capacitance.

(19) B α $\frac{i}{r}$ ;

where B= Strength of Magnetic Field, i=current passed through conductor and r=distance from conductor

(20) B = (µI/2πr);

where B= Strength of Magnetic Field, r= distance from conductor, I=current passed through conductor and µ= permeability of medium