# Watts to Volts Conversion Calculator > Convert power in watts to voltage in volts using current in amps with Ohm's Law **Category:** Conversion **Keywords:** watts, volts, voltage, power, amps, amperes, current, electrical, conversion, ohms law, electricity, wattage **URL:** https://complete.tools/watts-to-volts-converter ## How it calculates The calculation for converting watts to volts is based on the formula derived from Ohm's Law: V = P ÷ I. In this formula, V represents voltage in volts, P represents power in watts, and I represents current in amperes. To find the voltage, you divide the power (in watts) by the current (in amperes). This relationship shows that for a fixed amount of power, if the current increases, the voltage must decrease, and vice versa. This is an essential concept in electrical engineering, allowing for the design and analysis of electrical circuits. ## Who should use this Electrical engineers designing circuits requiring specific voltage levels. Technicians in renewable energy assessing solar panel output power. Electricians calculating voltage requirements for installing new electrical appliances. Students in physics conducting experiments related to electric circuits and power. ## Worked examples Example 1: A technician needs to find the voltage required for a device that consumes 150 watts of power and operates at 5 amps. Using the formula V = P ÷ I: V = 150 W ÷ 5 A = 30 V. Therefore, the voltage is 30 volts. Example 2: An engineer is designing a circuit for a motor that operates at 250 watts and draws 10 amps of current. Applying the formula: V = P ÷ I: V = 250 W ÷ 10 A = 25 V. Thus, the required voltage for the motor is 25 volts. Example 3: A researcher is testing a new LED system rated at 60 watts with a current of 2 amps. Using the formula: V = P ÷ I: V = 60 W ÷ 2 A = 30 V. The system will require 30 volts to operate efficiently. ## Limitations This tool assumes that the power factor is equal to 1, which may not be true for all devices, particularly inductive or capacitive loads. The results may be inaccurate if the current is zero, as division by zero is undefined. Additionally, this tool does not account for losses due to resistance in the wires or other components in the circuit. Precision may be limited by the accuracy of the user-entered values. The tool also assumes a constant power level; variations in power consumption will affect the accuracy of the voltage calculation. ## FAQs **Q:** How does this calculation apply to AC circuits? **A:** In AC circuits, the calculation requires consideration of the power factor, which accounts for phase differences between voltage and current. The formula becomes V = P ÷ (I × PF), where PF is the power factor. **Q:** Can this tool handle reactive power? **A:** This tool does not account for reactive power (measured in VARs), which can complicate voltage calculations in AC circuits. Only real power (watts) is used for calculations. **Q:** What happens if the current value is not steady? **A:** If the current fluctuates, the calculated voltage will also vary. For accurate results, ensure the current measurement reflects the average or RMS value for non-steady currents. **Q:** Is this tool applicable for three-phase systems? **A:** The tool is designed for single-phase calculations. For three-phase systems, additional factors and formulas are required to determine voltage accurately. --- *Generated from [complete.tools/watts-to-volts-converter](https://complete.tools/watts-to-volts-converter)*