Temperature Lapse Rate Calculator

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Temperature Lapse Rate Calculator

Dry Adiabatic (DALR) Moist/Saturated (SALR) Standard Atmosphere (ISA) Custom Rate
Enter a positive number for cooling with height.

Calculation Results

Altitude Change:
Lapse Rate Used:
Temperature Change:
Final Temperature:

Understanding Temperature Lapse Rate

The Temperature Lapse Rate is a meteorological parameter that describes the rate at which atmospheric temperature decreases with an increase in altitude. Whether you are a pilot, a mountaineer, or a meteorology student, understanding how temperature changes as you ascend is critical for safety and planning.

Key Types of Lapse Rates

In atmospheric thermodynamics, there are three primary lapse rates used for calculations:

  • Dry Adiabatic Lapse Rate (DALR): This rate applies to unsaturated air parcels (air with less than 100% relative humidity). The standard value is approximately 9.8°C per 1,000 meters (or 5.4°F per 1,000 feet). Because dry air does not release latent heat through condensation, it cools rapidly as it rises and expands.
  • Moist (Saturated) Adiabatic Lapse Rate (SALR/MALR): Once air reaches saturation (dew point), water vapor condenses into clouds, releasing latent heat. This heat offsets some of the cooling caused by expansion. Consequently, the moist lapse rate is lower, typically averaging around 6.0°C per 1,000 meters (3.3°F per 1,000 feet), though it varies with temperature.
  • Environmental Lapse Rate (ELR): This is the actual observed decrease in temperature at a specific time and location, which can vary based on weather conditions. The International Standard Atmosphere (ISA) assumes a standard average lapse rate of 6.5°C per 1,000 meters (3.5°F per 1,000 feet).

How to Calculate Temperature at Altitude

To estimate the temperature at a specific altitude, you can use the following formula:

Tfinal = Tinitial – ( Lapse Rate × ( Altitudefinal – Altitudeinitial ) / 1000 )

Where:

  • Tfinal is the temperature at the target altitude.
  • Tinitial is the starting temperature (e.g., at sea level or ground station).
  • Altitude Difference is divided by 1,000 because lapse rates are typically expressed per 1,000 units (meters or feet).

Applications of Lapse Rate

Aviation: Pilots use lapse rates to determine the freezing level, which is crucial for avoiding structural icing on aircraft.

Hiking and Mountaineering: Hikers use this calculation to prepare for colder temperatures at summits. For example, if it is 20°C at the trailhead, the summit 2,000 meters higher could be near freezing depending on the lapse rate.

Weather Forecasting: The stability of the atmosphere is determined by comparing the Environmental Lapse Rate to the Dry and Moist Adiabatic rates. This comparison helps predict thunderstorm development and turbulence.

function updateLabels() { var unit = document.querySelector('input[name="unitSystem"]:checked').value; var startAltLabel = document.getElementById("startAltLabel"); var endAltLabel = document.getElementById("endAltLabel"); var tempLabel = document.getElementById("tempLabel"); var customRateLabel = document.getElementById("customRateLabel"); if (unit === "metric") { startAltLabel.innerText = "Starting Altitude (m)"; endAltLabel.innerText = "Target Altitude (m)"; tempLabel.innerText = "Starting Temperature (°C)"; customRateLabel.innerText = "Custom Lapse Rate (°C per 1000m)"; } else { startAltLabel.innerText = "Starting Altitude (ft)"; endAltLabel.innerText = "Target Altitude (ft)"; tempLabel.innerText = "Starting Temperature (°F)"; customRateLabel.innerText = "Custom Lapse Rate (°F per 1000ft)"; } // Reset results when unit changes to avoid confusion document.getElementById("resultsBox").style.display = "none"; } function toggleCustomRate() { var type = document.getElementById("lapseType").value; var customGroup = document.getElementById("customRateGroup"); if (type === "custom") { customGroup.style.display = "block"; } else { customGroup.style.display = "none"; } } function calculateTemperature() { // 1. Get Inputs var unit = document.querySelector('input[name="unitSystem"]:checked').value; var startAlt = parseFloat(document.getElementById("startAltitude").value); var endAlt = parseFloat(document.getElementById("endAltitude").value); var startTemp = parseFloat(document.getElementById("startTemp").value); var lapseType = document.getElementById("lapseType").value; var customRateInput = parseFloat(document.getElementById("customRateInput").value); // 2. Validation if (isNaN(startAlt) || isNaN(endAlt) || isNaN(startTemp)) { alert("Please enter valid numbers for altitude and temperature."); return; } // 3. Determine Lapse Rate var rate = 0; // Constants // Metric: °C per 1000m var DRY_METRIC = 9.8; var MOIST_METRIC = 6.0; var STD_METRIC = 6.5; // Imperial: °F per 1000ft var DRY_IMP = 5.4; // approx for 9.8 C/km var MOIST_IMP = 3.3; // approx for 6.0 C/km var STD_IMP = 3.56; // ISA standard if (lapseType === "custom") { if (isNaN(customRateInput)) { alert("Please enter a valid custom lapse rate."); return; } rate = customRateInput; } else { if (unit === "metric") { if (lapseType === "dry") rate = DRY_METRIC; else if (lapseType === "moist") rate = MOIST_METRIC; else if (lapseType === "standard") rate = STD_METRIC; } else { // Imperial if (lapseType === "dry") rate = DRY_IMP; else if (lapseType === "moist") rate = MOIST_IMP; else if (lapseType === "standard") rate = STD_IMP; } } // 4. Calculate var altDiff = endAlt – startAlt; // Formula: Temp Change = Rate * (AltDiff / 1000) // Note: Lapse rate is positive for cooling. So we subtract the change. var tempChange = rate * (altDiff / 1000); var finalTemp = startTemp – tempChange; // 5. Format Output var altUnit = (unit === "metric") ? "m" : "ft"; var tempUnit = (unit === "metric") ? "°C" : "°F"; var rateUnit = (unit === "metric") ? "°C/1000m" : "°F/1000ft"; // Display logic document.getElementById("resAltDiff").innerText = altDiff.toFixed(0) + " " + altUnit; document.getElementById("resRate").innerText = rate.toFixed(2) + " " + rateUnit; // Show change with sign var changeSign = (tempChange > 0) ? "-" : "+"; // If tempChange is positive, it means temp dropped (cooling) if (tempChange 0), tempChange is usually positive (cooling). Final = Start – Change. // We want to display the delta. // Let's just show (Final – Start) var delta = finalTemp – startTemp; var sign = (delta >= 0) ? "+" : ""; document.getElementById("resTempDiff").innerText = sign + delta.toFixed(1) + " " + tempUnit; document.getElementById("resFinalTemp").innerText = finalTemp.toFixed(1) + " " + tempUnit; // Show results document.getElementById("resultsBox").style.display = "block"; }

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