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How to Calculate Impedance

Impedance is the opposition of a circuit to alternating current. It's measured in ohms. To calculate impedance, you must know the value of all resistors and the impedance of all inductors and capacitors, which offer varying amounts of opposition to the current depending on how the current is changing in strength, speed, and direction. You can calculate impedance using a simple mathematical formula.

Formula Cheatsheet

Impedance Z = R or XL or XC (if only one is present)

Impedance in series only (if both R and one type of X are present)
Z= ( R 2 + X 2 )

Impedance in series only (if R, XL, and XC are all present)
Z= (R2 + (| XL - XC |) 2 )

Impedance in any circuit Z= R+ jX (j is the imaginary number -1 )

Resistance R=ΔV/I

Inductive reactance XL= 2πfL =ωL

Capacative reactance XC = 1 / (2πfC) = 1 / (ωC)

Calculating Resistance and Reactance

Define impedance.

Impedance is represented with the symbol Z and measured in Ohms (Ω). You can measure the impedance of any electrical circuit or component. The result will tell you how much the circuit resists the flow of electrons (the current). There are two different effects that slow the current, both of which contribute to the impedance:

Resistance (R) is the slowing of current due to effects of the material and shape of the component. This effect is largest in resistors, but all components have at least a little resistance.

Reactance (X) is the slowing of current due to electric and magnetic fields opposing changes in the current or voltage. This is most significant for capacitors and inductors.

Review resistance.

Resistance is a fundamental concept in the study of electricity. You'll see it most often in Ohm's law: ΔV = I * R. This equation lets you calculate any of these values if you know the other two. For instance, to calculate resistance, write the formula as: R = ΔV/I. You can also measure resistance easily, using a multimeter.

ΔV is the voltage, measured in Volts (V). It is also called the potential difference.

I is the current, measured in Amperes (A).

R is the resistance, measured in Ohms (Ω).

Know which type of reactance to calculate.

Reactance only occurs in AC circuits (alternating current). Like resistance, it is measured in Ohms (Ω). There are two types of reactance, which occur in different electrical components:

Inductive reactance XL is produced by inductors, also called coils or reactors. These components create a magnetic field that opposes the directional changes in an AC circuit. The faster the direction changes, the greater the inductive reactance.

Capacitive reactance XC is produced by capacitors, which store an electrical charge. As current flows in an AC circuit changes direction, the capacitor charge and discharges repeatedly. The more time the capacitor has to charge, the more it opposes the current. Because of this, the faster the direction changes, the lower the capacitive reactance.

Calculate inductive reactance.

As described above, inductive reactance increases with the rate of change in the current direction, or the frequency of the circuit. This frequency is represented by the symbol f, and is measured in Hertz (Hz). The full formula for calculating inductive reactance is XL = 2π fL , where L is the inductance measured in Henries (H).

The inductance L depends on the characteristics of the inductor, such as the number of its coils. It is possible to measure the inductance directly as well.

If you're familiar with the unit circle, picture an AC current represented with this circle, with one full rotation of 2π radians representing one cycle. If you multiply this by f measured in Hertz (units per second), you get a result in radians per second. This is the circuit's angular velocity, and can be written as a lower-case omega ω. You might see the formula for inductive reactance written as: XL=ω L

Calculate capacitive reactance.

This formula is similar to the formula for inductive reactance, except capacitive reactance is inversely proportional to the frequency. Capacitive reactance: Xc = 1 / (2πfc) where c is the capacitance of the capacitor, measured in Farads (F).

You can measure capacitance using a multimeter and some basic calculations.

As explained above, this can be written as 1 / ω C.

Calculating Total Impedance

Add resistances in the same circuit

Total impedance is simple if the circuit has several resistors, but no inductors or capacitors. First, measure the resistance across each resistor (or any component with resistance), or refer to the circuit diagram for the labeled resistance in ohms (Ω). Combine these according to how the components are connected:[9]

Resistors in series (connected end to end along one wire) can be added together. The total resistance R = R1 + R2 + R3...

Resistors in parallel (each on a different wire that connects to the same circuit) are added as their reciprocals. To find the total resistance R, solve the equation 1/R = 1 / R1 + 1 / R2 + 1 / R3 ...

Add similar reactance values in the same circuit

If there are only inductors in the circuit, or only capacitors, the total impedance is the same as the total reactance. Calculate it as follows:

Inductors in series: Xtotal = XL1 + XL2 + ...

Capacitors in series: Ctotal = XC1 + XC2 + ...

Inductors in parallel: Xtotal = 1 / (1/XL1 + 1/XL2 ...)

Capacitors in parallel: Ctotal = 1 / (1/XC1 + 1/XC2 ...)

Subtract inductive and capacitive reactance to get total reactance

Because one of these effects increases as the other decreases, these tend to cancel each other out. To find the total effect, subtract the smaller one from the larger.

You will get the same result from the formula Xtotal = |Xc - XL|

Calculate impedance from resistance and reactance in series

You can't just add the two together, because the two values are "out of phase." This means that both values change over time as part of the AC cycle, but reach their peaks at different times. Fortunately, if all of the components are in series (i.e. there is only one wire), we can use the simple formula Z= ( R2 + X2 )

The mathematics behind this formula involves "phasors," but it might seem familiar from geometry as well. It turns out we can represent the two components R and X as the legs of a right triangle, with the impedance Z as the hypotenuse.

Calculate impedance from resistance and reactance in parallel

This is actually a general way to express impedance, but it requires an understanding of complex numbers. This is the only way to calculate the total impedance of a circuit in parallel that includes both resistance and reactance.

Z = R + jX, where j is the imaginary component: -1 . Use j instead of i to avoid confusion with I for current.

You cannot combine the two numbers. For example, an impedance might be expressed as 60Ω + j120Ω.

If you have two circuits like this one in series, you can add the real and imaginary components together separately. For example, if Z1 = 60Ω + j120Ω and is in series with a resistor with Z2 = 20Ω, then Ztotal = 80Ω + j120Ω.

Community Q&A

How do I calculate the impedance of the coil connected in series with the capacitor?

If the coil has a resistance, then treat it as an LCR circuit. Z= [ (Xc - XL ) + R ] 0.5 , where Z is the impedence, Xc is reactance of the capacitor which is equal to 1/(ωC), ω being the angular frequency and C being capacitance. XL is reactance of the coil which is equal to ωL, L being the inductance of the coil, and R is resistance of the coil. Put R = 0 in case the coil has no resistance.

Why can't impedances in a series be added to find the total circuit impedance?

The reason behind this is how capacitors and inductors react to changing currents or voltages in an AC circuit. This is mentioned in part 1 step 3 just a little bit. Capacitors oppose changes in voltage so the current and voltage are 90 degrees out of phase with current leading the voltage. Inductors oppose changes in current so it is out of phase with the voltage and the voltage leads the current by 90 degrees. If you are interested in knowing more, please let me know and I will try to put together an article on this topic: Calculating AC phase angles.


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