# Electrical Resistance Conversion > Convert between ohms, kiloohms, megaohms, and milliohms for electrical resistance **Category:** Math **Keywords:** electrical, resistance, ohm, kiloohm, megaohm, milliohm, conversion **URL:** https://complete.tools/electrical-resistance-conversion ## How it calculates The conversion between units of resistance is based on the following relationships: 1 kΩ = 1,000 Ω, 1 MΩ = 1,000,000 Ω, and 1 mΩ = 0.001 Ω. The formulas for converting between these units are as follows: - To convert ohms to kiloohms: kΩ = Ω ÷ 1,000 - To convert ohms to megaohms: MΩ = Ω ÷ 1,000,000 - To convert ohms to milliohms: mΩ = Ω × 1,000 - To convert kiloohms to ohms: Ω = kΩ × 1,000 - To convert megaohms to ohms: Ω = MΩ × 1,000,000 - To convert milliohms to ohms: Ω = mΩ ÷ 1,000 Each variable represents the resistance value in the respective unit. The mathematical relationships are linear, meaning that each step follows a straightforward multiplication or division based on powers of ten. ## Who should use this Electrical engineers designing circuit components, electronics technicians troubleshooting devices, and researchers conducting experiments that involve precise resistance measurements may utilize this tool. Additionally, educators teaching principles of electricity can benefit from converting resistance units to enhance their instructional materials. ## Worked examples Example 1: A circuit design requires a resistance of 4.7 kΩ. To convert this to ohms, use the formula: Ω = kΩ × 1,000. Thus, 4.7 kΩ × 1,000 = 4,700 Ω. Example 2: A component specification states a resistance of 0.005 MΩ. To convert this to ohms, apply the formula: Ω = MΩ × 1,000,000. Therefore, 0.005 MΩ × 1,000,000 = 5,000 Ω. Example 3: A low-resistance measurement of 50 mΩ is needed in a power system analysis. To convert to ohms, use the formula: Ω = mΩ ÷ 1,000. Thus, 50 mΩ ÷ 1,000 = 0.050 Ω. ## Limitations This tool assumes ideal conditions without accounting for temperature effects on resistance, which can impact precision. It may also exhibit rounding errors when converting very large or very small values due to limited numerical precision. Additionally, users should be cautious when converting values close to zero, as rounding may lead to significant discrepancies in practical applications. The tool does not provide detailed information on the context of resistance (such as material properties) that may affect the actual resistance in a physical setup. ## FAQs **Q:** How does temperature affect electrical resistance in materials? **A:** Electrical resistance typically increases with temperature for conductive materials due to increased atomic vibrations, leading to more collisions between electrons and atoms. **Q:** Why might resistance values differ in practical applications compared to calculated values? **A:** Resistance in real-world conditions can vary due to factors such as material impurities, physical wear, and environmental influences, which are not accounted for in basic calculations. **Q:** What is the significance of using different units of resistance in electrical engineering? **A:** Different units of resistance are used to match the scale of the application, such as using ohms for small resistances and megaohms for high resistances to maintain clarity and precision in measurements. **Q:** Can this tool be used for inductance or capacitance conversions? **A:** No, this tool is specifically designed for resistance conversions only. Inductance and capacitance require different units and calculations. --- *Generated from [complete.tools/electrical-resistance-conversion](https://complete.tools/electrical-resistance-conversion)*