LIST I | LIST II |
---|---|
A. Maxwell's First Equation | I. Modified Ampere's Law |
B. Maxwell's Second Equation | II. Faraday's Laws of Electromagnetic Induction |
C. Maxwell's Third Equation | III. Gauss Law in Electrostatics |
D. Maxwell's Fourth Equation | IV. Gauss Law in Magnetostatics |
A. Maxwell’s First Equation → Gauss’s Law in Electrostatics (III),
B. Maxwell’s Second Equation → Gauss’s Law in Magnetostatics (IV),
C. Maxwell’s Third Equation → Faraday’s Laws of Electromagnetic Induction (II),
D. Maxwell’s Fourth Equation → Modified Ampere’s Law (I).
1. Gauss’s Law in Electrostatics: Relates electric flux to enclosed charge.
2. Gauss’s Law in Magnetostatics: States there are no “magnetic charges.”
3. Faraday’s Law of Induction: An induced emf arises from changing magnetic flux.
4. Ampere-Maxwell Law: Relates magnetic fields to electric currents and changing electric fields.
LIST I | LIST II | ||
---|---|---|---|
A. | Intrinsic semiconductor | I. Used as a rectifier circuit | |
B. | N-Type Semiconductor | II. Pure form of Semiconductor | |
C. | P-Type Semiconductor | III. Doping of pentavalent impurity in semiconductor | |
D. | P-N Junction diode | IV. Doping of trivalent impurity in semiconductor |
LIST I | LIST II | ||
---|---|---|---|
A. | Bipolar npn transistor operate in the cut-off mode. | I. The base-emitter is reverse biased and | |
B. | Bipolar npn transistor operate in the saturation mode. | II. Both the base-emitter and base | |
C. | Bipolar npn transistor operate in the inverse active mode. | III. The base-emitter is forward biased | |
D. | Bipolar npn transistor operate in the forward active mode. | IV. Both the base-emitter and bas |
LIST I | LIST II | ||
---|---|---|---|
A. | ∇ ⋅ E = ρ/ε₀ | I. Gauss's Law in magnetostatics | |
B. | ∇ ⋅ B = 0 | II. Faraday's Law of electromagnetic Induction | |
C. | ∇ × E = - ∂B/∂t | III. Gauss's Law in electrostatics | |
D. | ∇ × B = μ₀J + μ₀ε₀ ∂E/∂t | IV. Modified Ampere's Law |