Convert between gauge pressure (PSIG) and absolute pressure (PSIA) with bar and kPa equivalents. Useful for compressors, vacuum systems, and pressure vessel specs.
PSIG and PSIA are not just different units. They measure pressure from different reference points. PSIG is gauge pressure relative to the surrounding atmosphere, while PSIA is absolute pressure relative to a perfect vacuum.
This converter is useful anywhere that pressure readings from a gauge need to be compared with engineering specs, thermodynamics formulas, vacuum-system numbers, or datasheets that use absolute pressure. The key relationship is simple: PSIA equals PSIG plus local atmospheric pressure.
Use it when a pressure value is correct numerically but uses the wrong reference basis for the equation, gauge, or spec you are working with. This matters in compressor work, vessel ratings, vacuum systems, and gas-law calculations because a pressure that looks reasonable can still be wrong if it is referenced to ambient air instead of vacuum. Making the reference basis explicit is often more important than the arithmetic itself. That is why this conversion shows up so often in troubleshooting and documentation reviews.
Gauge-versus-absolute confusion causes real engineering mistakes. This page keeps the reference point explicit and helps you move between shop-gauge readings and absolute-pressure requirements in compressors, vessels, gas systems, and vacuum work. It is a fast sanity check before you compare a field reading with a formula or datasheet that expects absolute pressure.
PSIA = PSIG + Atmospheric Pressure PSIG = PSIA - Atmospheric Pressure At sea level, Atmospheric Pressure ≈ 14.696 psi
Result: 46.70 psia
At sea level, 32 psig + 14.696 psi atmospheric pressure = 46.696 psia.
Gauge pressure treats the surrounding atmosphere as zero, which is convenient for tires, shop air, and many mechanical gauges. Absolute pressure treats a perfect vacuum as zero, which is what many equations and technical references require.
A number like 30 psi is incomplete until you know whether it is gauge or absolute. In a shop, 30 psi usually means 30 psig. In a thermodynamics calculation, the correct value may need to be 44.7 psia at sea level instead.
You will see this conversion in compressor performance data, vacuum systems, pressure-vessel specs, gas-law calculations, and instrumentation work. The arithmetic is simple, but the reference-pressure mistake is one of the easiest ways to get the wrong answer with otherwise correct numbers.
PSIG is measured relative to ambient atmospheric pressure. PSIA is measured relative to a perfect vacuum, so it includes the surrounding atmospheric pressure in the number.
Add atmospheric pressure. At sea level, that is about 14.696 psi, but the exact offset changes with location and weather.
Subtract atmospheric pressure. At sea level, subtract about 14.696 psi, then adjust that offset if you are working at a different elevation.
Atmospheric pressure drops with altitude, so the offset between psig and psia is smaller at higher elevations. A sea-level shortcut can therefore misstate the result if the site is much higher up.
They normally read gauge pressure, which is psig. That is why a tire marked 32 psi is almost always referring to pressure above ambient air, not absolute pressure.
Use absolute pressure for thermodynamics, vacuum calculations, compressor maps, and any formula or datasheet that references vacuum as the zero point. If the equation assumes perfect vacuum is zero, a gauge-pressure value will give the wrong result even when the unit looks correct.