Altimeter setting is the value of local atmospheric pressure, typically expressed in inches of mercury (inHg) in the United States or hectopascals (hPa) elsewhere, to which an aircraft's barometric altimeter is adjusted to indicate the aircraft's altitude above mean sea level (MSL).[1] This adjustment compensates for variations in atmospheric pressure caused by weather systems and elevation, ensuring the altimeter provides reliable altitude readings essential for navigation, terrain avoidance, and air traffic separation.[1] In aviation, altimeter settings are provided by weather stations or air traffic control and must be updated frequently, as even small changes in pressure can lead to significant errors in indicated altitude.[1]In the United States, the primary purpose of altimeter setting is to standardize altitude measurements across different regions and flight phases, preventing discrepancies that could compromise safety.[2] For operations below 18,000 feet MSL, pilots set the altimeter to the current reported pressure from the nearest weather reporting station within 100 nautical miles; if no such setting is available or if pressure exceeds 31.00 inHg, a standard setting of 31.00 inHg is used under specific NOTAM guidance.[1] Above 18,000 feet MSL, in the transition to or within Class A airspace, the altimeter is set to the standard pressure of 29.92 inHg, allowing aircraft to fly at assigned flight levels based on pressure altitude rather than true altitude.[1] These procedures are mandated by regulations such as 14 CFR § 91.121 to maintain cruising altitudes and flight levels accurately.[2]Altimeter settings are subject to several sources of error that pilots must account for to ensure true altitude aligns closely with indicated altitude.[1]Instrument errors arise from mechanical inaccuracies in the altimeter itself, while position errors occur due to airflow disturbances around the aircraft's static ports.[1]Nonstandard pressure and temperature errors are particularly significant: in high-pressure areas above 29.92 inHg, the true altitude is higher than indicated, and conversely, in low-pressure areas below 28.00 inHg, true altitude is lower, potentially by hundreds of feet per inch of deviation.[1] Temperature variations further exacerbate this, with colder air causing the true altitude to be lower than indicated, a phenomenon known as "high to low, look out below."[1] In the United States, flight operations are not recommended in areas where the reported pressure is below 28.00 inHg, as this indicates extreme low-pressure conditions where true altitudes could be critically underestimated.[1]
Fundamentals
Definition and purpose
An altimeter setting is the value of atmospheric pressure, typically calibrated to sea level or another reference datum, that pilots enter into the subscale of a pressure altimeter to adjust for local variations in barometric pressure, thereby ensuring the instrument displays the aircraft's altitude above mean sea level (MSL) or the specified reference level.[3][4]The primary purpose of the altimeter setting is to provide consistent and accurate altitude readings for all aircraft in a given airspace, facilitating safe vertical separation between planes, adequate terrain clearance, and adherence to air traffic control (ATC) instructions.[5] By standardizing altitude references, it prevents discrepancies that could arise from non-uniform atmospheric conditions, enabling pilots and controllers to maintain situational awareness and operational safety.[3]The concept of altimeter setting emerged in the early 20th century alongside the development of pressure-based altitude measurement in aviation, with the invention of the first accurate barometric altimeter by Paul Kollsman in 1928 revolutionizing instrument flight by allowing adjustments for varying pressure levels.[6]At its core, altimeter calibration relies on the hydrostatic equation integrated over assumed atmospheric conditions, which relates pressure differences to altitude. A common approximation for constant temperature layers ish \approx \frac{R \bar{T}}{g} \ln \left( \frac{P_{\text{standard}}}{P_{\text{actual}}} \right)where h is the altitude, P_{\text{standard}} is the reference pressure, P_{\text{actual}} is the measured pressure, R is the specific gas constant for air, \bar{T} is the mean temperature of the layer, and g is gravitational acceleration.[7] This underpins the instrument's ability to convert static pressure to altitude indications using the International Standard Atmosphere model.[8]
Types of settings
Altimeter settings in aviation are categorized based on the reference pressure level they represent, enabling pilots to read altitude or height relative to specific datums for safe navigation and operations. The primary types include QNH, QFE, standard pressure setting, and QFF, each tailored to distinct phases of flight or meteorological applications.[3][9]QNH is the calculated barometric pressure at mean sea level (MSL) for a specific location, derived from station pressure using the International Standard Atmosphere (ISA) temperature lapse rate. When set on the altimeter subscale, it causes the instrument to indicate the aircraft's elevation above MSL when on the ground at the reporting station, providing a consistent reference for low-level operations.[3][9][10]QFE represents the atmospheric pressure at the elevation of an aerodrome or runway threshold. Setting the altimeter to QFE results in a reading of zero when the aircraft is on the ground at that location, displaying height above the airfield elevation during approach and landing procedures.[3][9][10]The standard pressure setting, also known as SPS or STD, is a fixed value of 1013.25 hectopascals (hPa), equivalent to the ISA sea-level pressure. It is used above the transition altitude to standardize altimeter readings as flight levels, such as FL050 indicating 5,000 feet above the 1013.25 hPa surface, ensuring vertical separation among aircraft in en route airspace.[3][9][10]QFF is the hypothetical MSL pressure computed from the station's QNH or QFE, but adjusted using the actual temperature and humidity at the location rather than the ISA model. Primarily employed in meteorological analysis rather than direct flight operations, it accounts for non-standard atmospheric conditions to derive more accurate sea-level pressure estimates.[10][3]Altimeter settings are expressed in inches of mercury (inHg) in the United States per FAA standards or in hectopascals (hPa) internationally under ICAO guidelines, with a conversion factor of approximately 1 inHg = 33.86 hPa. For example, the standard setting of 29.92 inHg corresponds to 1013.25 hPa.[11][12][3]These settings, particularly QNH, are disseminated through aviation weather reports such as METARs, where QNH appears as "Q" followed by a four-digit value rounded down to the nearest hPa, for instance, "Q1010" indicating a QNH of 1010 hPa. This integration ensures pilots receive timely local pressure data for accurate altimetercalibration.[13][14]
Atmospheric principles
Barometric altimeter basics
The barometric altimeter, also known as a pressure altimeter, operates as an aneroid barometer calibrated to indicate altitude rather than direct pressure readings.[15] It consists of one or more evacuated, corrugated metal diaphragms or capsules that expand or contract in response to changes in atmospheric pressure.[15] These diaphragms are linked mechanically through a series of levers, springs, and gears to pointers on a dial, converting the physical movement into a visual altitude display.[4]Atmospheric pressure decreases with increasing altitude due to the reduced density of the air column above, following a standard lapse rate assumed by the instrument.[15] As pressure drops, the diaphragms expand, causing the gears to rotate the pointers clockwise to indicate higher altitude.[16] This relationship is based on the principle that lower pressure corresponds to higher elevation in a standard atmosphere.[15]Key components include the static port, which senses ambient atmospheric pressure and transmits it to the instrument via tubing; the subscale adjustment knob, often associated with the Kollsman window for setting local pressure; and a three-pointer display showing altitude in thousands, hundreds, and tenths of feet.[15] The Kollsman window displays the reference pressure setting, typically in inches of mercury, allowing pilots to adjust the altimeter's reference datum.[15]The altimeter is factory-calibrated to the International Standard Atmosphere (ISA), where it reads zero at sea level under standard conditions of 29.92 inHg (1013.25 hPa) and 15°C.[15] Adjustments via the subscale knob effectively shift the instrument's zero point without altering the diaphragm's mechanical response, compensating for non-standard pressure to display indicated altitude accurately relative to a chosen reference.[15]The underlying pressure-altitude relationship in the ISA model for the troposphere (below approximately 36,000 ft) is given by the hypsometric formula for pressure altitude h_p (in feet):h_p = 145442 \left[1 - \left( \frac{P}{P_0} \right)^{0.190263} \right]where P_0 is standard sea-level pressure (1013.25 hPa) and P is the measured pressure.[17] This equation derives from hydrostatic equilibrium and the ideal gas law, incorporating the standard temperature lapse rate of -6.5 °C/km for accurate altimetercalibration.[17]
Standard atmosphere model
The International Standard Atmosphere (ISA) is a model of a hypothetical, idealized atmosphere established by the International Civil Aviation Organization (ICAO) to serve as a uniform reference for calibrating aviation instruments, including barometric altimeters.[18] It defines atmospheric conditions assuming dry air with no wind, providing standardized profiles of pressure, temperature, and density as functions of altitude.[19] The model is based on thermodynamic equations and empirical data, extending from sea level up to approximately 80 km, though the tropospheric and lower stratospheric layers up to 20 km (65,617 feet) are most relevant for altimeter calibration.[20]At sea level, the ISA specifies a pressure of 1013.25 hectopascals (hPa), a temperature of 15°C, and an air density of 1.225 kg/m³.[21] In the troposphere, from sea level to 11 km (approximately 36,089 feet), temperature decreases linearly at a lapse rate of -6.5°C per kilometer (equivalent to -1.98°C per 1,000 feet).[18] Above 11 km, in the lower stratosphere up to 20 km (65,617 feet), the temperature remains constant at -56.5°C, with pressure and density continuing to decrease exponentially.[19] These profiles are derived from the hydrostatic equation and the ideal gas law, ensuring consistent calibration scales for altimeters across global operations.[21]The ISA underpins altimeter settings by providing the baseline for pressure altitude calculations, where the instrument assumes the standard sea-level pressure.[1] Setting the altimeter to 29.92 inches of mercury (inHg), equivalent to 1013.25 hPa, aligns it with ISA conditions, causing the altimeter to read pressure altitude—the height above the standard datum plane in the ISA model—rather than true geometric altitude.[18] This standardization enables pilots to reference flight levels, expressed in hundreds of feet (e.g., FL180 for 18,000 feet), ensuring vertical separation in airspace.[1]While the ISA offers a reliable baseline for uniformity, the actual atmosphere frequently deviates from these parameters due to local weather patterns, seasonal variations, and geographical factors.[18] Nonetheless, its adoption by ICAO promotes consistent altimeter performance and safety in international aviation.[19]Key ISA values for pressure and temperature at representative altitudes up to the lower stratosphere are shown below. These data illustrate the model's profiles used in altimeter calibration.[22]
Altitude (ft)
Altitude (m)
Pressure (hPa)
Temperature (°C)
0
0
1013.25
15.0
5,000
1,524
843.0
5.1
10,000
3,048
697.0
-4.8
18,000
5,486
506.0
-20.7
36,000
10,973
227.0
-56.5
Operational procedures
Low-altitude operations
In low-altitude operations, pilots set the altimeter to the local QNH prior to departure, obtaining the value from the Automatic Terminal Information Service (ATIS), air traffic control (ATC) tower, or a nearby weather station to ensure the instrument reads the airfield elevation when the aircraft is on the ground.[1][3] This setting provides altitude above mean sea level (MSL), facilitating terrain clearance and obstacle avoidance during takeoff and initial climb.[3]During the climb phase, the QNH setting is maintained until the aircraft reaches the designated transition altitude, which varies by region but is commonly 3,000 to 5,000 feet MSL in many terminal areas outside the United States before switching to the standard pressure setting.[23][24] In the United States, operations below 18,000 feet MSL generally use local QNH throughout low-altitude flight unless otherwise instructed.[1]En route below 18,000 feet MSL in the U.S., pilots update the altimeter to the current local setting from a station along the route and within 100 nautical miles (NM) of the aircraft, as required by federal regulations, or use ATC-provided information via radio if no suitable station is available.[25] ATC issues these updates at least once during en route jurisdiction, identifying the source facility, and pilots adjust for significant pressure changes to maintain accurate MSL altitude reference for terrain and traffic separation.[5]Standard ATC phraseology for providing altimeter settings includes concise transmissions such as "Aircraft callsign, altimeter three zero one two," ensuring clear communication of the value in inches of mercury.[5] For high-pressure scenarios exceeding 31.00 inches Hg, controllers may direct "Set three one zero zero in your altimeter prior to reaching [altitude or 1,500 feet AGL]."[5]The transition layer serves as a buffer zone between the transition altitude (where local QNH is used below) and the transition level (the lowest flight level above using standard pressure of 29.92 inches Hg), typically providing at least 1,000 feet of vertical separation to prevent confusion from altimeter setting discrepancies during the changeover.[24] This layer ensures a common vertical reference datum, minimizing collision risks in controlled airspace.[3]
High-altitude operations
In high-altitude operations, pilots set the altimeter to the standard pressure of 1013.25 hPa (or 29.92 inHg) upon reaching the transition altitude during climb, at which point the altimeter begins displaying flight levels rather than altitudes.[3] This ensures uniform vertical separation among aircraft regardless of local pressure variations, with flight levels denoted by the hundreds of feet indicated on the altimeter (e.g., FL310 corresponds to 31,000 feet in the standard atmosphere). For example, an aircraft cruising at FL310 maintains this setting to align with air traffic control clearances based on pressure altitude.During en route high-altitude flight, the standard setting is retained without local adjustments above FL180 in the United States, to simplify separation and avoid confusion from fluctuating barometric pressures. This practice applies across most airspace above the transition altitude, promoting consistent flight level assignments and reducing the risk of altitude deviations. In regions like the continental U.S., the transition altitude is standardized at 18,000 feet, ensuring seamless operations in controlled airspace.[26]Upon descent through the transition level, pilots switch the altimeter back to the local QNH provided by air traffic control (ATC) to obtain accurate altitude readings relative to sea level for terrain clearance and approach procedures.[27]ATC advises the current QNH setting, often via radio or ATIS, and pilots must confirm the change to prevent errors such as level busts, which can result from a 1 hPa discrepancy equating to approximately 30 feet of altitude error.[27]In Reduced Vertical Separation Minima (RVSM) airspace, typically above FL290, the standard altimeter setting is critical due to the halved vertical separation of 1,000 feet between aircraft, necessitating high-precision altimetry systems with total vertical error limits not exceeding 200 feet.[28] Aircraft must be RVSM-approved, including pitot-static systems calibrated to maintain accuracy within these tolerances, to operate safely in this densely trafficked environment.[29]Transition altitudes vary globally to account for regional terrain and traffic demands; for instance, they are commonly set at 5,000 feet in much of Europe, while in the United States, they reach 18,000 feet over the continental interior.[30] These differences require pilots to consult aeronautical charts and ATC for the applicable values in each airspace.[23]
Regulatory framework
ICAO standards
The International Civil Aviation Organization (ICAO) provides standardized guidelines for altimeter settings to facilitate global aviation interoperability and safety. In ICAO Annex 3, Meteorological Service for International Air Navigation, QNH is defined as the atmospheric pressure reduced to mean sea level or aerodrome elevation using the International Standard Atmosphere model, which, when set on a pressure-type altimeter, indicates altitude above mean sea level; it is computed in tenths of hectopascals (hPa) and reported in whole hPa using four digits. QFE is the atmospheric pressure at aerodrome elevation or the runway threshold, set to indicate height above that reference datum. The standard setting of 1013.25 hPa is used above the transition altitude to indicate flight levels, ensuring uniform pressure reference in upper airspace.[31]Annex 3 further specifies that QNH must be included in METAR and SPECI reports for aerodromes, providing pilots with the necessary pressure data for low-level operations; QFE is reported only in local routine and special reports if required by regional agreements or users, but not routinely in METAR unless specified. These provisions ensure timely dissemination of pressure information through meteorological services.[31]ICAO recommends that each state define its transition altitude (TA)—the altitude at or below which vertical position is referenced to altitudes using local QNH—typically ranging from 3,000 to 10,000 feet above aerodrome elevation to accommodate varying terrain and traffic densities. The transition level (TL) is the lowest flight level available above the TA, calculated based on the prevailing QNH to avoid overlap with altitudes below. Above the TA, all instrument flight rules (IFR) and visual flight rules (VFR) operations above specified altitudes use the standard setting, promoting consistent vertical separation and collision avoidance in shared international airspace.[32]Detailed operational procedures for altimeter setting changes, including during climbs and descents through the transition layer, are outlined in ICAO Doc 8168, Procedures for Air Navigation Services—Aircraft Operations (PANS-OPS), which guides pilots and air traffic services on harmonized application worldwide.[33]These standards were initially adopted by ICAO in 1947 upon the organization's establishment to align post-World War II aviation practices, with significant updates in the 1970s—such as the shift to metric pressure units in hectopascals via amendments to Annex 5, Units of Measurement—to support the International System of Units (SI) for enhanced precision and global uniformity.[34]
National regulations
In the United States, the Federal Aviation Administration (FAA) mandates altimeter settings under 14 CFR § 91.121, requiring pilots operating below 18,000 feet mean sea level (MSL) to set the altimeter to the current reported altimeter setting (QNH) from the nearest weather reporting station along the route and within 100 nautical miles of the aircraft, or from an appropriate available station if none exists within that radius. Above 18,000 feet MSL, the standard setting of 29.92 inches of mercury must be used. The lowest usable flight level is calculated based on the local atmospheric pressure, adding specified feet to the minimum instrument flight rules (IFR) altitude in the operational area as per a regulatory table that accounts for pressure variations below 29.92 inches of mercury.[2]Pilots must update the altimeter setting when the aircraft exceeds 100 nautical miles from the source station or when the reported pressure differs by 0.01 inches of mercury or more, as such changes can introduce errors of approximately 10 feet per 0.01-inch deviation, ensuring vertical separation compliance.[1]In Europe, the European Union Aviation Safety Agency (EASA) oversees national implementations where transition altitudes— the level above which the standard pressure setting is used—vary by country and aerodrome, commonly ranging from 1,000 to 5,000 feet above aerodrome level to accommodate local topography and trafficdensity, providing flexibility beyond uniform international baselines.[32]Australia's Civil Aviation Safety Authority (CASA) requires a fixed transition altitude of 10,000 feet nationwide under Part 91 of the Civil Aviation Safety Regulations, closely mirroring ICAO guidelines but with occasional regional adjustments in remote or high-pressure areas to maintain safe vertical intervals.[35]Non-compliance with these national altimeter setting rules can lead to enforcement actions, such as FAA civil penalties of up to $40,000 per violation for individuals or higher for entities, along with potential pilot certificate suspensions or revocations in cases of resulting altitude deviations that compromise safety.[36][37]As of 2023, the FAA has intensified focus on digital altimeter verification and upgrades within its Next Generation Air Transportation System (NextGen) initiative, driven by requirements to address radio altimeter vulnerabilities from 5G spectrum interference, with mandatory modifications completed for most commercial aircraft by mid-year.[38]
Errors and limitations
Sources of inaccuracy
Barometric altimeters, calibrated to the International Standard Atmosphere (ISA), are susceptible to inaccuracies from environmental deviations and mechanical limitations.[1]Temperature effects arise primarily from deviations from ISA conditions, where cold air is denser than assumed, compressing the atmospheric column and causing the altimeter to overread altitude. In colder-than-ISA temperatures, the true altitude is lower than the indicated value, with an approximate error of 4% of the height above the altimeter setting source for every 10°C below standard temperature.[39] For instance, at an indicated altitude of 1,000 feet above terrain in temperatures 20°C below ISA, the actual height could be approximately 80 feet lower than shown, increasing risks near obstacles.[39]Non-standard atmospheric pressure introduces errors when the local pressure differs from the set altimeter value, often due to weather systems. In low-pressure environments, such as those associated with approaching fronts, the altimeter indicates a higher altitude than the true mean sea level (MSL) height because the instrument assumes a standard pressure gradient that does not match the actual thinner air column. An error of 1 inch of mercury (inHg) in the setting corresponds to roughly 1,000 feet of altitude discrepancy.[1]Instrument errors stem from the altimeter's mechanical and elastic properties, including hysteresis (lag in response to pressure changes), after-effects from pressure exposure, and inaccuracies in the barometric subscale. Hysteresis can cause readings to differ by up to ±75 feet between ascending and descending pressure tests, while subscale errors are limited to ±25 feet in calibration standards. Friction in the mechanism may also produce pointer deviations of up to ±70 feet at lower altitudes. These tolerances ensure operational reliability but highlight inherent limitations in precision.[40]Position errors occur due to aircraft-specific factors affecting the static pressure input, such as attitude changes (e.g., pitch or bank altering airflow to the static port) or icing blocking the port, leading to erroneous pressure readings. In clean configurations, these errors are typically small but can increase significantly during maneuvers or in icing conditions, sometimes exceeding 100 feet without mitigation.[1]
Correction methods
One primary method for correcting altimeter inaccuracies involves temperature adjustments, particularly in cold conditions where the true altitude is lower than indicated due to denser air. The Federal Aviation Administration (FAA) provides cold temperature altitude correction tables in the Aeronautical Information Manual (AIM) Table 7-3-1, which pilots use to add corrections to published altitudes during instrument approaches at affected airports. For instance, at an airport elevation with a temperature of -20°C and a segment altitude 3,000 feet above the airport, pilots add approximately 400 feet to the minimum descent altitude or decision altitude to ensure terrain clearance.[41][42]Since 2019, the FAA's Cold Temperature Airports (CTA) program has designated hundreds of airports where NOTAMs require mandatory application of these altitude corrections for instrument procedures when temperatures are at or below specified CTA thresholds (typically 0°C or colder, varying by airport). As of August 2025, the program includes over 300 airports across the United States, primarily in colder regions, to maintain required obstacle clearance. Pilots must report applying corrections to air traffic control at these locations.[41][43]An approximate equation for temperature correction is \Delta h = h \times \frac{\Delta T}{T_{ISA}} \times 0.00198 per foot, where \Delta h is the altitude correction, h is the height above the altimeter source, \Delta T is the deviation from the International Standard Atmosphere (ISA) temperature in degrees Celsius, and T_{ISA} is the ISA temperature at the altimeter source in Kelvin. This formula derives from the hydrostatic equation and lapse rate considerations, allowing pilots to estimate adjustments when tables are unavailable.[44][45]Modern aircraft employ radio altimeters (RA) for cross-checking barometric altimeter readings, especially during low-level operations like final approach and landing, where RA measures height above terrain using radar pulses for precise absolute altitude. The RA provides an independent reference, enabling pilots to validate barometric indications against ground proximity and detect discrepancies in real time.[46][47]Global Navigation Satellite Systems (GNSS) also support mean sea level (MSL) validation of barometric altimeters by providing geometric altitude data converted to MSL using geoid models, serving as a supplementary check in equipped aircraft. FAA Advisory Circular 20-138D emphasizes that while the barometric altimeter remains primary for operations, GNSS-derived altitudes enhance integrity monitoring without replacing it.[48][49]Air traffic control (ATC) may adjust minimum vectoring altitudes (MVA) upward in non-standard atmospheric conditions, such as extreme cold, to account for altimeter errors and maintain obstacle clearance. EUROCONTROL guidelines recommend including temperature corrections in MVA calculations when necessary, ensuring vectored aircraft remain at safe heights above terrain.[39]Digital enhancements in glass cockpits facilitate automatic altimeter setting inputs via datalink technologies, including Automatic Dependent Surveillance-Broadcast (ADS-B) In, which receives real-time meteorological data such as METARs containing current altimeter settings from ground stations. This integration reduces setting errors and improves situational awareness in advanced avionics suites.[4]