Calculate voltage, current, resistance, and power with Ohm's Law. Includes energy cost estimation, AWG wire gauge recommendation, complete formula reference table, and collapsible wire sizing chart.
Ohm's Law is the cornerstone of electrical circuit analysis. It describes the relationship between voltage (V), current (I), and resistance (R) in a conductor: voltage equals current times resistance, or V = I × R. This deceptively simple equation underpins virtually all electrical and electronics engineering.
This calculator lets you solve for any one of the three variables when you know the other two. Select whether you want to find voltage, current, or resistance, enter the known values, and get your answer instantly. It also computes the power dissipated in the circuit using P = V × I.
Whether you are a physics student working through textbook problems, an electrician sizing wire for a residential circuit, or a hobbyist building an LED project, Ohm's Law is the first tool you reach for. Understanding it intuitively — how increasing resistance reduces current, or how higher voltage drives more current through the same resistance — is essential for anyone working with electricity.
While V = IR is simple to memorize, real-world problems often involve unit conversions, decimal values, and follow-up calculations like power dissipation that are tedious by hand. This calculator handles all three Ohm's Law rearrangements plus automatic power computation, eliminating arithmetic errors. It is especially useful for quickly sizing components, checking circuit behavior, or verifying measurements from a multimeter.
Ohm's Law: V = I × R I = V / R R = V / I Power: P = V × I = I²R = V²/R Where: V = voltage in volts (V) I = current in amperes (A) R = resistance in ohms (Ω) P = power in watts (W)
Result: 12 V
With a current of 2 amperes flowing through a 6-ohm resistor, the voltage across it is V = 2 × 6 = 12 volts. The power dissipated is P = 12 × 2 = 24 watts.
A popular mnemonic is the "Ohm's Law Triangle" — write V at the top, I on the bottom-left, and R on the bottom-right. Cover the variable you want to find: covering V reveals I × R, covering I reveals V / R, and covering R reveals V / I. This visual shortcut helps students quickly recall all three rearrangements.
Electricians use Ohm's Law to calculate wire gauge requirements: higher current demands thicker wire to keep resistance (and heat) low. Electronics designers use it to select resistor values for LED circuits: an LED needing 20 mA at 2V from a 5V supply requires a (5 − 2) / 0.02 = 150Ω resistor. Power supply designers use the power formula to ensure components stay within thermal limits.
While Ohm's Law is defined for linear resistors, the concept extends to other domains. In fluid dynamics, the analogous relationship is ΔP = Q × R (pressure drop = flow rate × hydraulic resistance). In thermal analysis, ΔT = Q × R_thermal. Recognizing these analogies deepens understanding of physical systems across disciplines.
Ohm's Law states that the voltage across a conductor is proportional to the current flowing through it, with resistance as the proportionality constant: V = I × R. It was formulated by Georg Ohm in 1827 and is fundamental to electrical engineering.
Divide voltage by resistance: I = V / R. For example, a 12V battery connected across a 4Ω resistor produces a current of 12 / 4 = 3 amperes.
Resistance is measured in ohms, symbolized by the Greek letter omega (Ω). Common multiples include kilohms (kΩ, thousands of ohms) and megohms (MΩ, millions of ohms).
For purely resistive AC loads, yes. For circuits with capacitors or inductors, you use impedance (Z) instead of resistance: V = I × Z. Impedance accounts for both resistance and reactance and is a complex number.
Power dissipation is the rate at which electrical energy is converted to heat in a resistor, measured in watts (W). It equals P = V × I, or equivalently P = I²R or P = V²/R. Exceeding a component's power rating causes overheating and potential failure.
They form a triangle: increasing voltage while keeping resistance constant increases current proportionally. Increasing resistance while keeping voltage constant decreases current. These three quantities are always linked by V = IR.
In passive components, no — resistance is always positive. However, some active devices (like tunnel diodes) exhibit negative differential resistance over certain operating ranges, where increasing voltage decreases current.