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Density Altitude Calculator

Enter your field conditions. The readout updates as you type — pressure altitude, density altitude, and a color-coded status flag.

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Type an identifier or tap Nearby to fill the calculator from the latest official observation. U.S. stations (NWS).
ft MSL
From the airport diagram or sectional.
From ATIS / AWOS / METAR. Standard is 29.92 inHg = 1013.25 hPa.
Surface OAT, not the forecast high.
0%
Applied with the NWS virtual-temperature method. A small but real effect on hot, humid days.
Density Altitude
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Pressure Alt
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ISA Deviation
°C
Enter conditions above
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What Density Altitude Actually Tells You

Density altitude is the altitude your aircraft thinks it's at. Formally, it is pressure altitude corrected for non-standard temperature: the height in the standard atmosphere where the air density matches the density at your field right now. Your wings, propeller, and engine don't respond to the number on the airport sign — they respond to how many air molecules they can grab per second. When the air is hot, thin, or both, there are fewer molecules to work with, and the aircraft performs as if it were taking off from somewhere much higher.

Three drivers do almost all the work. Elevation sets the baseline: higher fields start with thinner air. Pressure shifts it: a low-pressure system effectively raises the field. Temperature is the one that catches pilots, because it changes hour by hour: every degree Celsius above standard adds roughly 120 ft of density altitude. A fourth factor, humidity, trims the margin further — water vapor is lighter than the nitrogen and oxygen it displaces, so humid air is less dense. It's the smallest effect of the four, worth roughly 700–800 ft at 95 °F and 100% relative humidity near sea level, which is why this calculator treats it as an optional refinement rather than a headline input.

The Formula, With Its Assumptions

This calculator uses the same two-step method taught in the FAA's Pilot's Handbook of Aeronautical Knowledge. First, convert what your altimeter is telling you into pressure altitude:

PA = field elevation + (29.92 − altimeter setting) × 1,000
Each inch of mercury below standard adds 1,000 ft; each inch above subtracts it. hPa settings are converted at 1013.25 hPa = 29.92 inHg.

Then correct for temperature against the ISA standard day, which starts at 15 °C at sea level and cools 1.98 °C per 1,000 ft:

DA = PA + 118.8 × (OAT − ISA temperature at PA)
The 118.8 ft-per-degree factor is the precise value behind the familiar "120 ft per °C" rule of thumb.

Two honest caveats. This is the standard linear approximation — excellent through the altitudes where piston aircraft operate, and the same relationship your POH charts assume. And the humidity correction uses virtual temperature (the National Weather Service method), which is a refinement on top of the classic dry-air formula, not part of it. If you compute DA by hand with the rule of thumb and get a slightly different number than this calculator, the gap is the difference between 120 and 118.8, plus any humidity you dialed in.

A Worked Example: Truckee on a Summer Afternoon

Truckee–Tahoe (KTRK) sits at 5,904 ft. Say the ATIS reports an altimeter of 30.12 and a temperature of 30 °C — an ordinary Sierra summer afternoon.

StepCalculationResult
Pressure altitude5,904 + (29.92 − 30.12) × 1,0005,704 ft
ISA temp at 5,704 ft15 − 1.98 × 5.704+3.7 °C
ISA deviation30 − 3.7+26.3 °C
Density altitude5,704 + 118.8 × 26.38,828 ft

The aircraft is parked at 5,904 ft but will take off, climb, and (if the engine is normally aspirated) make power as if it were at nearly 8,800 ft. That's roughly a quarter of its rated power gone before the throttle is even open, a takeoff roll stretched by more than half versus a standard day, and a climb rate that may be a few hundred feet per minute where the terrain ahead demands more. Punch the same numbers into the calculator above and you'll see the flag go red.

When the Number Should Change Your Plan

Density altitude is most dangerous when several margins shrink at once. Be deliberate when DA exceeds field elevation by 2,000–3,000 ft, when you're near max gross weight, when the runway is short or has obstacles off the departure end, or when terrain rises faster than your degraded climb rate. The classic accident profile is all four together: a loaded aircraft, a mountain strip, a hot afternoon. The fixes are equally classic — depart in the cool of early morning, leave fuel or baggage behind, use every foot of runway, and lean for best power at altitude the way your POH describes.

How to use the result: take the density altitude from the readout above and enter your POH takeoff and climb charts with it, exactly as you would a chart pressure altitude and temperature pair. If your aircraft's book numbers at that DA don't clear the runway and terrain you actually have — with margin — the calculator has done its job before you left the ground. For type-specific estimates (piston, turboprop, jet, helicopter), the all-aircraft performance calculator forecasts takeoff roll and hover ceiling from the same DA. For the hand-calculation method with worked examples, see how to calculate density altitude step by step, and for what the number does to your takeoff roll and climb, the takeoff performance guide. Just need the pressure-altitude step on its own? Use the pressure altitude calculator.

Frequently Asked Questions

What is density altitude?
Density altitude is pressure altitude corrected for non-standard temperature — the altitude in the standard atmosphere where air density equals the density at your field right now. High density altitude means thinner air: less engine power, less lift, longer takeoff rolls, and weaker climb.
What is the density altitude formula?
First find pressure altitude: PA = field elevation + (29.92 − altimeter setting) × 1,000. Then DA = PA + 118.8 × (OAT − ISA temperature), where ISA temperature is 15 °C minus 1.98 °C per 1,000 ft of pressure altitude. The 118.8 factor is the precise value behind the 120 ft-per-degree rule of thumb.
How do I find pressure altitude?
Set the altimeter to 29.92 inHg and read the indicated altitude, or compute it: field elevation plus 1,000 ft for every inch the setting is below 29.92 (subtract if above). Example: 5,904 ft elevation with a 30.12 setting gives 5,904 − 200 = 5,704 ft.
What is a dangerous density altitude?
There's no single cutoff — it depends on aircraft, weight, and runway. Caution rises sharply when DA exceeds field elevation by 2,000–3,000 ft, above roughly 6,000–8,000 ft DA for a normally aspirated piston near gross weight, and on short or obstructed runways. Always check your POH charts.
Does humidity affect density altitude?
Yes, but it's the smallest of the four factors. Water vapor is lighter than dry air, so humid air is less dense. At 95 °F and 100% relative humidity near sea level, humidity adds roughly 700–800 ft to DA. This calculator applies it using virtual temperature, the same method the National Weather Service uses.
How much performance do I lose at high density altitude?
Rules of thumb for a normally aspirated piston: about 3% power loss per 1,000 ft DA, takeoff roll growing roughly 10% per 1,000 ft, climb rate falling about 7% per 1,000 ft. At 8,000 ft DA you may have around 75% power available. These are planning approximations — verify against your POH.
Is this a substitute for my POH performance charts?
No. This tool gives you the density altitude to enter those charts with, plus context on what the number means. Takeoff, climb, and landing decisions must come from your aircraft's POH/AFM and an official weather briefing.
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