How to Calculate Total Resistance in Circuits

There are two ways to hook together electrical components. Series circuits use components connected one after the other, while parallel circuits connect components along parallel branches. The way resistors are hooked up determines how they contribute to the total resistance of the circuit.

Method 1

Method 1 of 4:

Series Circuit

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Identify a series circuit. A series circuit is a single loop, with no branching paths. All the resistors or other components are arranged in a line.^{[1]XResearch source}
2
Add all resistances together. In a series circuit, the total resistance is equal to the sum of all resistances. The same current passes through each resistor, so each resistor does its job as you would expect.^{[2]XResearch source}
- For example, a series circuit has a 2 Ω (ohm) resistor, a 5 Ω resistor, and a 7 Ω resistor. The total resistance of the circuit is 2 + 5 + 7 = 14 Ω.
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3
Start with current and voltage instead. If you don't know the individual resistance values, you can rely on Ohm's Law instead: V = IR, or voltage = current x resistance. The first step is to find the circuit's current and total voltage:^{[3]XResearch source}
- The current of a series circuit is the same at all points on the circuit. If you know the current at any point, you can use that value in this equation.
- The total voltage is equal to the voltage of the supply (the battery). It is not equal to the voltage across one component.^{[4]XResearch source}
4
Insert these values into Ohm's Law. Rearrange V = IR to solve for resistance: R = V / I (resistance = voltage / current). Plug the values you found into this formula to solve for total resistance.^{[5]XResearch source}
- For example, a series circuit is powered by a 12 volt battery, and the current is measured at 8 amps. The total resistance across the circuit must be R_T = 12 volts / 8 amps = 1.5 ohms.

Method 2

Method 2 of 4:

Parallel Circuit

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1
Understand parallel circuits. A parallel circuit branches into multiple paths, which then join back together. Current flows through each branch of the circuit.^{[6]XResearch source}
- If your circuit has resistors on the main path (before or after the branched area), or if there are two or more resistors on a single branch, Skip down to the combination circuit instructions instead.
2
Calculate the total resistance from the resistance of each branch. Since each resistor only slows current passing through one branch, it only has a small effect on the total resistance of the circuit. The formula for total resistance R_T is ${\frac {1}{R_{T}}}={\frac {1}{R_{1}}}+{\frac {1}{R_{2}}}+{\frac {1}{R_{3}}}+...{\frac {1}{R_{n}}}$ $How.com.vn English: {\frac {1}{R_{T}}}={\frac {1}{R_{1}}}+{\frac {1}{R_{2}}}+{\frac {1}{R_{3}}}+...{\frac {1}{R_{n}}}$ , where R₁ is the resistance of the first branch, R₂ is the resistance of the second branch, and so on up to the last branch R_n.^{[7]XResearch source}
- For example, a parallel circuit has three branches, with resistances of 10 Ω, 2 Ω, and 1 Ω.
  Use the formula ${\frac {1}{R_{T}}}={\frac {1}{10}}+{\frac {1}{2}}+{\frac {1}{1}}$ and solve for R_T:
  Convert fractions to a common denominator: ${\frac {1}{R_{T}}}={\frac {1}{10}}+{\frac {5}{10}}+{\frac {10}{10}}$
  ${\frac {1}{R_{T}}}={\frac {1+5+10}{10}}={\frac {16}{10}}=1.6$
  Multiply both sides by R_T: 1 = 1.6R_T
  R_T = 1 / 1.6 = 0.625 Ω.
3
Begin with total current and voltage instead. If you don't know the individual resistances, you'll need the current and voltage instead:^{[8]XResearch source}
- In a parallel circuit, the voltage across one branch is the same as the total voltage across the circuit. As long as you know the voltage across one branch, you're good to go. The total voltage is also equal to the voltage of the circuit's power source, such as a battery.
- In a parallel circuit, the current may be different along each branch. You need to know the total current, or you won't be able to solve for total resistance.
4
Use these values in Ohm's Law. If you know the total current and the voltage across the whole circuit, you can find the total resistance using Ohm's Law: R = V / I.^{[9]XResearch source}
- For example, a parallel circuit has a voltage of 9 volts and total current of 3 amps. The total resistance R_T = 9 volts / 3 amps = 3 Ω.
5
Watch out for branches with zero resistance. If a branch on the parallel circuit has no resistance, all of the current will flow through that branch. The resistance of the circuit is zero ohms.
- In practical applications, this usually means a resistor has failed or been bypassed (short-circuited), and the high current could damage other parts of the circuit.^{[10]XResearch source}

Method 3

Method 3 of 4:

Combination Circuit

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1
Break down your circuit into series sections and parallel sections. A combination circuit has some components linked together in series (one after the other), and others in parallel (on different branches). Look for areas of your diagram that simplify to a single series or parallel section.^{[11]XExpert SourceMarvin Woo
Licensed ElectricianExpert Interview. 31 January 2022.} Circle each one to help you keep track of them.
- For example, a circuit has a 1 Ω resistor and a 1.5 Ω resistor connected in series. After the second resistor, the circuit splits into two parallel branches, one with a 5 Ω resistor and the other with a 3 Ω resistor.
  Circle the two parallel branches to separate them from the rest of the circuit.
2
Find the resistance of each parallel section. Use the parallel resistance formula ${\frac {1}{R_{T}}}={\frac {1}{R_{1}}}+{\frac {1}{R_{2}}}+{\frac {1}{R_{3}}}+...{\frac {1}{R_{n}}}$ $How.com.vn English: {\frac {1}{R_{T}}}={\frac {1}{R_{1}}}+{\frac {1}{R_{2}}}+{\frac {1}{R_{3}}}+...{\frac {1}{R_{n}}}$ to find the total resistance of a single parallel section of the circuit.^{[12]XExpert SourceMarvin Woo
Licensed ElectricianExpert Interview. 31 January 2022.}
- The example circuit has two branches with resistance R₁ = 5 Ω and R₂ = 3 Ω.
  ${\frac {1}{R_{parallel}}}={\frac {1}{5}}+{\frac {1}{3}}$
  ${\frac {1}{R_{parallel}}}={\frac {3}{15}}+{\frac {5}{15}}={\frac {3+5}{15}}={\frac {8}{15}}$
  $R_{parallel}={\frac {15}{8}}=1.875$ Ω
3
Simplify your diagram. Once you've found the total resistance of a parallel section, you can cross out that whole section on your diagram. Treat that area as a single wire with resistance equal to the value you found.^{[13]XResearch source}
- In the example above, you can ignore the two branches and treat them as one resistor with resistance 1.875Ω.
4
Add up resistances in series. Once you've replaced each parallel section with a single resistance, your diagram should be a single loop: a series circuit. The total resistance of a series circuit is equal to the sum of all individual resistances, so just add them up to get your answer.^{[14]XResearch source}
- The simplified diagram has a 1 Ω resistor, 1.5 Ω resistor, and the section with 1.875 Ω you just calculated. These are all connected in series, so $R_{T}=1+1.5+1.875=4.375$ Ω.
If you do not know the resistance in one component of your circuit, look for ways to calculate it. If you know the voltage V and current I across that component, find its resistance using Ohm's Law: R = V / I.^{[15]XResearch source}

Method 4

Method 4 of 4:

Formulas Using Power

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1
Learn the formula for power. Power is the rate that the circuit consumes energy, and the rate it delivers energy to whatever the circuit is powering (such as a light bulb).^{[16]XResearch source} The total power of a circuit is equal to the product of the total voltage and the total current. Or in equation form: P = VI.^{[17]XResearch source}
- Remember, when solving for total resistance, you need to know the total power of the circuit. It's not enough to know the power flowing through one component.
2
Solve for resistance using power and current. If you know these two values, you can combine two formulas to solve for resistance:^{[18]XResearch source}
- P = VI (power = voltage x current)
- Ohm's Law tells us that V = IR.
- Substitute IR for V in the first formula: P = (IR)I = I²R.
- Rearrange to solve for resistance: R = P / I².
- In a series circuit, the current across one component is the same as the total current. This is not true for a parallel circuit.
3
Find resistance from power and voltage. If you only know the power and voltage, you can use a similar approach to find resistance. Remember to use the total voltage across the circuit, or the voltage of the battery powering the circuit:^{[19]XResearch source}
- P = VI
- Rearrange Ohm's Law in terms of I: I = V / R.
- Substitute V / R for I in the power formula: P = V(V/R) = V²/R.
- Rearrange to solve for resistance: R = V²/P.
- In a parallel circuit, the voltage across one branch is the same as the total voltage. This is not true for a series circuit: the voltage across one component is not the same as the total voltage.
- Alternatively, you can isolate the circuit and physically test resistance using a multimeter. ^{[20]XExpert SourceMarvin Woo
  Licensed ElectricianExpert Interview. 31 January 2022.}

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Question
How do I calculate the resistance of 2 resistors when I know the sum of the resistors?
Community Answer
Assuming you mean total resistance, you first need to determine if they are in series or parallel. In series the total resistance simply equals the sum of the resistors. In parallel, the inverse of the total resistance equals the sum of the inverse of each individual resistor. Therefore, you will not be able to calculate total resistance in a parallel circuit if you only know the sum.
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If V = IR, how do I calculate if one cell = 2V and the resistor is 4 ohm?
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I = V/R . This is derived from the equation V =I R. In the question the value of potential difference (v) is mentioned as 2V, i.e, 2 volts. The value of resistance of the resistor is given as 4 ohms. Substitute these values in the first equation; i.e, l = V/R, so, I = 2/4. Therefore, I = 0.5 amps.
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Can I use frequency to calculate resistance?
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Resistance does not change with frequency. However, AC circuits do have a similar quality called reactance which does change with frequency. Learn more here.
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The power value P used in these formulas refers to instantaneous power, or power at a specific moment in time. If the circuit uses AC power, the power is changing constantly. Electricians calculate the average power for AC circuits using the formula P_average = VIcosθ, where cosθ is the power factor of the circuit.^{[21]XResearch sourcehyperphysics.phy-astr.gsu.edu/hbase/electric/powfac.html#c1}
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Power is measured in watts (W).
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Voltage is measured in volts (V).
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