A hair dryer consumes \(1600 .\) W of power and operates at \(110 .\) V. (Assume that the current is \(D C .\) In fact, these are root-mean-square values of AC quantities, but the calculation is not affected. Chapter 30 covers AC circuits in detail.) a) Will the hair dryer trip a circuit breaker designed to interrupt the circuit if the current exceeds \(15.0 \mathrm{~A} ?\) b) What is the resistance of the hair dryer when it is operating?

Ohm's Law is a fundamental principle in the study of electric circuits, serving as a cornerstone for understanding how voltage, current, and resistance interact with each other. It is succinctly expressed by the formula:

\[ V = IR \]
where:

• \(V\) represents the voltage across the component in volts (V),
• \(I\) is the current flowing through the component in amperes (A), and
• \(R\) is the resistance of the component in ohms (\(\Omega\)).

By rearranging the formula, you can calculate any one of these three values if the other two are known. In the case of our hair dryer example, once the current is found using the electrical power formula, Ohm's Law is used to compute the resistance. Understanding this relationship helps troubleshoot and design electrical systems by predicting how they react to different currents and voltages.

Power in Electric Circuits

Electrical power is a measure of how much work can be done by an electric current over a certain period of time. It's typically measured in watts (W), and the formula linking power to current and voltage is:

\[ P = IV \]
where:

• \(P\) is the power in watts,
• \(I\) is the current in amperes, and
• \(V\) is the voltage in volts.

This equation indicates that for a constant voltage, as the current increases, the power consumption also grows. Taking our hair dryer, rated at \(1600\) W for its wattage, we found how much current it draws using this power relation, key to determining whether it would exceed the limit of a \(15\) A circuit breaker.

Alternating Current (AC) versus Direct Current (DC)

The difference between AC and DC current is in the direction of flow. DC current, which comes from sources like batteries, flows in a single constant direction. It's the simple, stable current that you'd calculate when using Ohm's Law in basic circuit analysis, as shown with our hair dryer's assumed DC current.

AC, on the other hand, is the type of current delivered to our homes and used by the majority of appliances. It periodically reverses direction. The root-mean-square (RMS) values for AC quantities such as voltage and current offer a 'DC equivalent' value—useful for calculations like the ones in our exercise. Understanding these differences is crucial when working with real-world electronics and when considering the safety, efficiency, and function of the devices we use every day.