AFR Calculator

Use this AFR Calculator to work through the same calculation as the main calculator page with clear steps, examples, and result context.

What This AFR Calculator Helps You Do

This page translates the basic air-fuel mass relationship into whichever number you are missing. That makes it useful for classroom combustion problems, calibration planning, and quick sanity checks on airflow or fueling assumptions.

It also reports lambda relative to a stoichiometric reference so the result is easier to interpret as rich, stoich, or lean instead of just reading a raw ratio.

How to Calculate AFR Calculator

Choose the AFR task: Solve for the ratio directly or for the fuel or air mass needed to hit a target ratio.
Use consistent mass units: Air and fuel can be grams, kilograms, or pounds as long as both use the same unit.
Set the target AFR: Stoichiometric gasoline is often referenced near 14.7:1, but tuning targets vary by fuel and engine state.
Review lambda: Lambda compares the calculated AFR with the stoichiometric reference and helps classify rich versus lean operation.

AFR Calculator Formula

AFR = air mass ÷ fuel mass; fuel mass = air mass ÷ AFR; air mass = fuel mass × AFR

Variable	Meaning	Unit
AFR	Air-fuel ratio by mass	ratio
Air mass	Mass of air entering combustion	g, kg, lb, or any consistent mass unit
Fuel mass	Mass of fuel used for combustion	same mass unit as air

Use the worked examples below to check how the formula behaves with real values. If the result looks unexpected, verify the unit assumptions and the meaning of each variable before interpreting the answer.

Worked Examples

Direct-ratio example - Calculate AFR from masses

Air mass: 147 g
Fuel mass: 10 g

Result: 147 / 10 = 14.7:1.

This is the classic stoichiometric gasoline reference ratio by mass.

Fuel-target example - Required fuel from air mass

Air mass: 294 g
Target AFR: 14.7

Result: Fuel mass = 294 / 14.7 = 20 g.

Target-ratio calculations help convert airflow information into a matching fuel requirement.

How to Interpret Your Results

Range	Meaning	Action
Lambda below 1	The mixture is richer than the stoichiometric reference.	Useful for power or cooling in some setups, but check emissions and washdown risk.
Lambda near 1	The mixture is close to the stoichiometric reference.	This is a common control target for catalytic-converter operation.
Lambda above 1	The mixture is leaner than the stoichiometric reference.	Check combustion stability and component temperatures.

Frequently Asked Questions

This calculator uses mass-based AFR, which is the standard chemical and engine-tuning definition.

A common reference value is about 14.7:1 by mass, though exact stoichiometry depends on the fuel blend.

Rich means less air per unit fuel than stoichiometric, while lean means more air per unit fuel than stoichiometric.

Yes. Any mass unit works as long as air and fuel use the same unit.

Note: This calculator is a mass-ratio planning tool. Real engine control also depends on fuel properties, sensor calibration, injector behavior, and operating conditions.

References

Omni Calculator - AFR Calculator

Last reviewed: March 2026

AFR Calculator

What This AFR Calculator Helps You Do

How to Calculate AFR Calculator

AFR Calculator Formula

Worked Examples

How to Interpret Your Results

Frequently Asked Questions

Does AFR use mass or volume?

What is stoichiometric AFR for gasoline?

What does rich versus lean mean?

Can I use kilograms or pounds?

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References

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