Understanding Electric Current and Resistance

watt

volt

ampere

ohm

ρ = R / (A × L)

ρ = A + (R / L)

ρ = L / (R × A)

ρ = R × (A / L)

Resistance increases with temperature.

Resistance remains constant regardless of temperature.

Resistance decreases with temperature.

Resistance is unaffected by changes in temperature.

P = R / V

P = V^2 / R or P = I^2 * R

P = V * R

P = V + I

Energy (J) = Voltage (V) × Current (A)

Energy (J) = Power (W) × Time (s)

Energy (J) = Power (W) ÷ Time (s)

Energy (J) = Power (W) + Time (s)

The total resistance in a circuit.

The current flowing through the circuit.

The voltage drop across a resistor.

The energy provided per unit charge by a source in a circuit.

The total resistance is greater than the individual resistances.

The total resistance is equal to the sum of individual resistances.

The total resistance is less than the smallest individual resistance.

The total resistance is the same as the largest individual resistance.

They assist in calculating power loss in transformers.

They are used to design circuit layouts for printed circuit boards.

They help analyze current and voltage in electrical circuits.

They help determine the resistance in electrical circuits.

The sum of currents entering a junction equals the sum of currents leaving the junction.

The power in a circuit is equal to the product of voltage and current.

The total voltage around a closed loop is equal to zero.

The current through a conductor is directly proportional to the voltage across it.

The sum of the voltages must equal zero.

The sum of the voltages must equal the total resistance.

The sum of the voltages must equal the total current.

The sum of the voltages must equal the power consumed.