4.2.2 Resistance

    Cards (52)

    • Resistance is the opposition to the flow of electric current
    • Match the variable with its symbol and units:
      Voltage ↔️ V, Volts
      Current ↔️ I, Amperes
      Resistance ↔️ R, Ohms
    • How does increasing the cross-sectional area of a conductor affect its resistance?
      Decreases resistance
    • What is the equation for the temperature coefficient of resistance?
      ΔRR0=\frac{\Delta R}{R_{0}} =αΔT \alpha \Delta T
    • The temperature coefficient of resistance describes how the resistance of a material changes with temperature
    • Order the following materials based on their temperature coefficient of resistance from most positive to most negative:
      1️⃣ Copper
      2️⃣ Rubber
    • Match the power dissipation equations with their formulas:
      Power = Voltage x Current ↔️ P=P =IV IV
      Power = Current^2 x Resistance ↔️ P=P =I2R I^{2}R
      Power = Voltage^2 / Resistance ↔️ P=P =V2R \frac{V^{2}}{R}
    • Ohm's Law states that voltage is directly proportional to current if temperature remains constant.
      True
    • What unit is used to measure resistance?
      Ohms
    • What does Ohm's Law state about the relationship between voltage, current, and resistance?
      V = IR
    • Match the material with its resistivity characteristic:
      Copper ↔️ Low resistivity
      Rubber ↔️ High resistivity
    • In series circuits, the total resistance is the sum of the individual resistances.
      True
    • Longer conductors have greater resistance.

      True
    • Resistance decreases with a larger cross-sectional area.

      True
    • What does the symbol α\alpha represent in the temperature coefficient formula?

      Temperature coefficient
    • What is the unit of power dissipation in resistors?
      Watts
    • In a parallel circuit, the reciprocal of the total resistance is equal to the sum of the reciprocals of the individual resistances
    • What is resistance measured in?
      Ohms
    • What is the equation for Ohm's Law?
      V=V =IR IR
    • How does increasing the length of a conductor affect its resistance?
      Increases resistance
    • The temperature coefficient of resistance describes how the resistance of a material changes with temperature
    • The resistivity of a material affects its resistance.

      True
    • Match the variables in the temperature coefficient of resistance formula with their descriptions:
      \Delta R</latex> ↔️ Change in resistance
      R0R_{0} ↔️ Initial resistance
      α\alpha ↔️ Temperature coefficient
      ΔT\Delta T ↔️ Change in temperature
    • Power dissipation in a resistor is calculated as the rate at which electrical energy is converted to thermal energy
    • In a parallel circuit, the current splits among resistors.

      True
    • Order the factors influencing resistance from most to least significant:
      1️⃣ Length
      2️⃣ Cross-sectional area
    • Resistance is the opposition to the flow of electric current
    • Resistance decreases with larger cross-sectional area
    • What is the power dissipated in a resistor if the voltage is 10V and the current is 2A?
      20W
    • What is the voltage across a conductor if the current is 3A and the resistance is 5 ohms?
      15V
    • How does the length of a conductor affect its resistance?
      Increases with length
    • The temperature coefficient of resistance is expressed as \frac{\Delta R}{R_{0}} = \alpha \Delta T
    • What happens to the resistance of a good conductor as temperature increases?
      Increases
    • How is the total resistance calculated in a series circuit?
      Sum of individual resistances
    • Ohm's Law states that voltage is directly proportional to current if temperature remains constant.

      True
    • The resistance of a conductor depends on its length, cross-sectional area, and material
    • Which material has higher resistivity: copper or rubber?
      Rubber
    • A wider path for electrons reduces resistance
    • The formula for the temperature coefficient of resistance is ΔRR0=\frac{\Delta R}{R_{0}} =αΔT \alpha \Delta T.

      True
    • Good conductors have a positive temperature coefficient of resistance.

      True
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