Enter any two values to complete the trio. Instantly see power dissipation and consistency warnings. Use multiple formulas, then download reports for records easily.
Provide any two of the three values. The calculator computes the missing value and power dissipation. Choose convenient units and an output unit for power.
Ohm’s law links voltage, current, and resistance:
V = I × RI = V ÷ RR = V ÷ IPower dissipation in a resistive load can be written in three equivalent forms:
P = V × IP = I² × RP = V² ÷ R| Voltage (V) | Current (A) | Resistance (Ω) | Power (W) | Typical note |
|---|---|---|---|---|
| 12 | 0.50 | 24 | 6 | Small DC load, modest heating. |
| 5 | 0.20 | 25 | 1 | Sensor or logic supply region. |
| 230 | 2.00 | 115 | 460 | High power; ensure proper rating and cooling. |
| 3.3 | 0.01 | 330 | 0.033 | LED resistor scale example. |
Electrical power dissipation is the rate at which a component converts electrical energy into heat. In resistors, wiring, and semiconductor paths, excessive dissipation raises temperature, shifts resistance, and can damage insulation or solder joints. This calculator helps quantify that heating risk in watts so you can choose safe parts and operating points.
For resistive behavior, voltage, current, and resistance follow V = I×R. Once two are known, the third is fixed. Power can then be computed by P = V×I, or expressed as P = I²×R and P = V²/R. All three forms are mathematically equivalent, but one may be numerically clearer depending on your known inputs.
If you measure voltage and current directly, P = V×I is most transparent. If you know current through a known resistor, P = I²×R highlights how doubling current quadruples heating. If you only know a supply voltage and a resistive load, P = V²/R shows how lower resistance sharply increases dissipation.
Small-signal electronics often use milliamps and kilohms, yielding milliwatt power levels. For example, 5 V across 1 kΩ produces 5 mA and 25 mW. Power supplies and heaters can reach hundreds of watts; 230 V across 115 Ω draws 2 A and dissipates 460 W. Use the unit selectors to avoid mental conversions and reduce mistakes.
Resistors are commonly rated at 0.125 W, 0.25 W, 0.5 W, 1 W, and higher. A practical design margin is to keep steady dissipation well below the nameplate rating, especially in warm enclosures. If your calculated power is near the rating, choose a higher wattage part or reduce current with a larger resistance.
Dissipated power also appears in conductors as I²R loss. Even small resistances in wires, connectors, and PCB traces can heat under high current. When you see high watts, evaluate conductor gauge, connector ratings, and ventilation. Lowering current or shortening runs can significantly reduce heating.
If you enter all three values, the calculator reports deviation from V = I×R. A small percent difference can be normal due to meter accuracy, lead resistance, or rounding. A large deviation suggests inconsistent measurements, a non‑ohmic device, or an incorrect unit selection.
Start with a target voltage and allowable current. Compute resistance, then compute power and compare against component ratings. Iterate: adjust resistance, add series limiting, or select a higher rated part. Finally, export a CSV or PDF record for documentation, reviews, or lab notebooks.
No. Power needs voltage plus current, or voltage plus resistance, or current plus resistance. Provide at least two values so the calculator can solve the missing parameter and then compute watts.
They are algebraic rearrangements using Ohm’s law. Substituting V = I×R into P = V×I yields P = I²×R, and substituting I = V/R yields P = V²/R.
It is heat generation rate. A resistor dissipating 1 W converts 1 joule of electrical energy into heat every second, raising its temperature unless heat is removed by air flow, conduction, or a heatsink.
Compare calculated power to the resistor’s rated wattage. For steady operation, use a safety margin and consider ambient temperature. If power is close to the rating, select a higher wattage resistor or reduce current.
Heating from resistive loss scales with I². Doubling current increases I²R power by four. This is why small increases in current can cause large temperature rises in resistors, wires, and connectors.
Ohm’s law may not hold for diodes, LEDs, motors, or switching regulators. The consistency check can flag this. Use measured V and I at the operating point, and treat R as an “effective” value only.
Physical resistors have positive resistance. Zero causes division errors in V²/R and can imply an unrealistic short circuit. Negative resistance requires specialized active devices and is outside this calculator’s intended use.
Important Note: All the Calculators listed in this site are for educational purpose only and we do not guarentee the accuracy of results. Please do consult with other sources as well.