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🔧 Engine Compression Ratio Calculator

Enter a cylinder's swept (displacement) volume and combustion chamber volume to instantly calculate the static compression ratio. You can also derive swept volume directly from bore and stroke.

Static Compression Ratio
Swept Volume
cc
Chamber + Gasket + Deck Total
cc
GUIDE

Learn more

01

What Is Compression Ratio?

Compression ratio is the ratio of the total cylinder volume when the piston is at bottom dead center (BDC) to the remaining volume (combustion chamber volume) when the piston is at top dead center (TDC).

CR = (Vswept + Vchamber + Vgasket + Vdeck) ÷ (Vchamber + Vgasket + Vdeck)

Vswept is the per-cylinder displacement swept by the piston moving from BDC to TDC, Vchamber is the combustion chamber volume, Vgasket is the volume occupied by the head gasket, and Vdeck is the volume created by the deck clearance between the piston crown and the top of the cylinder. If there is no gasket or deck clearance, you can leave those at 0.
02

Worked Example

For example, with a swept volume of 500 cc and a chamber volume of 50 cc (no gasket or deck volume), the compression ratio is (500+50) ÷ 50 = 11.0 : 1.

Under the same conditions, adding 5 cc of head gasket volume increases the denominator (chamber + gasket + deck) to 55 cc, lowering the ratio to (500+55) ÷ 55 ≈ 10.09 : 1. This is why a thicker gasket or larger deck clearance lowers compression ratio.

Using the bore/stroke input mode, a cylinder with an 86 mm bore and 86 mm stroke gives a swept volume of (π/4) × 86² × 86 ÷ 1000 ≈ 499.56 cc, calculated automatically.
03

Caveat: Static vs Dynamic Compression Ratio

This calculator computes static compression ratio, based purely on the cylinder's geometric volumes. The value more closely tied to actual engine behavior and knock is the dynamic compression ratio, which also accounts for intake valve closing timing (cam timing) and is always lower than the static ratio.

A higher static compression ratio generally requires higher-octane fuel, and forced-induction (turbo/supercharged) engines often run a lower static compression ratio than naturally aspirated (NA) engines. Combustion chamber volume is most accurately measured by removing the head and cc-ing it — filling it with liquid to measure the exact volume. This tool computes static CR only.

Frequently asked questions

What compression ratio is typical?
Naturally aspirated gasoline engines typically run 9–13 : 1, while turbocharged or supercharged engines are often designed lower, around 8–10.5 : 1, to avoid knock. Diesel engines rely on compression ignition and run much higher, typically 14–23 : 1. These are general ranges — actual values vary widely with engine design, fuel, and forced induction.
Why do head gasket and deck clearance volume matter?
In a real engine, the head gasket's thickness and the deck clearance between the piston crown and cylinder top also count as part of the "remaining volume" at top dead center. Ignoring them overstates the compression ratio, so entering both gives a more accurate result. Leave them blank and they're treated as 0.
How is static compression ratio different from dynamic?
Static compression ratio is calculated purely from the cylinder's geometric volume ratio. Dynamic compression ratio also factors in when the intake valve actually closes (cam timing) — the later it closes, the shorter the effective compression stroke, making the dynamic ratio lower than the static one. This calculator only computes the static ratio.
How do I measure combustion chamber volume?
The most accurate method is to remove the cylinder head, lay it chamber-side up, and fill the chamber with liquid (such as oil) using a graduated burette to measure the exact volume — commonly called "cc-ing" the head. Manufacturer spec values can be a starting point, but a direct measurement is more accurate if the head has been machined or the valves replaced.