Fact-checked by Grok 2 weeks ago

National Weather Service

The National Weather Service (NWS) is a federal agency within the National Oceanic and Atmospheric Administration (NOAA), part of the U.S. Department of Commerce, responsible for observing and forecasting weather, water, and climate conditions to issue timely warnings and support services that protect life, property, and economic interests.^[1] It operates as the sole official U.S. government voice for life-threatening weather alerts, maintaining a nationwide network of over 120 forecast offices, Doppler radar sites, automated observation stations, and upper-air sounding facilities to collect and disseminate data.^[2] Established on February 9, 1870, via congressional legislation signed by President Ulysses S. Grant, the NWS traces its origins to the U.S. Army Signal Corps' meteorological division, which leveraged telegraph networks for coordinated storm warnings following devastating events like the 1869 Peshtigo fire and 1870 Great Gale.^[3] Renamed the Weather Bureau in 1891 and reorganized under civilian control, it adopted the NWS designation in 1967 amid broader federal restructuring, later integrating into NOAA in 1970 to incorporate satellite and computational advancements that dramatically improved forecast accuracy and lead times for severe events.^[4]^[5] Key achievements include pioneering national radar deployment in the mid-20th century, development of numerical weather prediction models, and contributions to disaster mitigation, such as enhanced hurricane tracking that has reduced fatalities through early evacuations and preparations.^[6] The agency has sustained public trust via empirical data-driven operations, though it faces defining challenges like chronic understaffing—exacerbated by hiring freezes and budget pressures—and occasional political influences on messaging, as seen in instances where administrative directives overrode field meteorologists' assessments during high-profile storms.^[7]^[8] These factors have prompted debates over resilience, with operational costs remaining low at roughly $4 per taxpayer annually while delivering 24/7 vigilance amid increasing extreme weather demands.^[9]^[10]

History

Founding and Early Expansion (1870–1900)

The National Weather Service originated from practical demands for weather predictions to mitigate losses in agriculture and maritime activities, particularly following devastating storms that destroyed crops, livestock, and vessels in the late 1860s. In 1869 alone, shipwrecks claimed 209 lives, prompting advocates like Increase A. Lapham to urge Congress for a systematic observation network using telegraph lines.^[5]^[11] On February 9, 1870, President Ulysses S. Grant signed a joint congressional resolution directing the Secretary of War to establish weather observations at military posts and select civilian sites, placing the service under the U.S. Army Signal Corps led by Brigadier General Albert J. Myer.^[5]^[3] This marked the birth of a centralized national weather effort focused on empirical data collection via simultaneous telegraphic reports to forecast storms and protect economic interests.^[12] Operations commenced with the first synchronized observations from 24 stations telegraphed to Washington at 7:35 a.m. on November 1, 1870, enabling initial 24-hour forecasts issued by the Signal Corps.^[13] Cleveland Abbe, hired as chief meteorologist in January 1871, organized the forecasting system, emphasizing verifiable pressure, temperature, and wind data from an expanding network of Army posts and volunteer observers.^[14] By 1873, the service issued its first hurricane warning on August 21, alerting coastal areas from Cape May, New Jersey, to New London, Connecticut, for an approaching tropical cyclone—a milestone in applying telegraphic data to maritime safety.^[15] The network grew rapidly, reaching over 100 stations by the mid-1870s, prioritizing storm tracks for farmers and shippers over speculative predictions.^[5] In response to criticisms of military oversight diverting Signal Corps resources from core duties, Congress passed an act on October 1, 1890, transferring meteorological functions to the Department of Agriculture, effective July 1, 1891, and renaming it the Weather Bureau.^[16]^[17] Under Chief Mark W. Harrington, the Bureau emphasized agricultural forecasting and commerce protection through standardized data collection, including crop weather reports and river gauges, aligning with empirical needs for verifiable observations to support national economic stability.^[18] By 1900, the service operated around 500 stations, issuing daily bulletins and probability forecasts based on accumulated telegraphic records, solidifying its role in causal prediction of weather impacts.^[5]

Institutional Growth and World Wars (1901–1950)

The U.S. Weather Bureau, predecessor to the National Weather Service, underwent significant institutional expansion in the early 20th century, driven by technological and military imperatives that enhanced observational capabilities and forecasting for civilian and aviation use. By the 1910s, the rise of powered flight introduced acute weather risks, prompting the Bureau to develop specialized aviation meteorology services. During World War I, the Bureau collaborated closely with the U.S. Army and Navy to provide tailored forecasts for aerial operations, addressing the hazards of fog, storms, and wind that plagued early military aviation.^[19] This wartime necessity laid the groundwork for post-war growth; on December 1, 1918, the Bureau formalized "flying forecasts" to support the burgeoning commercial aviation sector, expanding weather reporting at key airfields and integrating upper-air data for safer transcontinental flights.^[19]^[5] The 1930s presented fiscal challenges amid the Great Depression, with federal budgets strained and the Bureau operating under tight constraints from the Department of Agriculture. Nevertheless, technological innovations advanced upper-air observations, as the Bureau adopted radiosondes—instruments carried aloft by balloons to transmit temperature, humidity, and pressure data via radio. Initial testing occurred in 1936, followed by the establishment of a nationwide radiosonde network in 1937, which by decade's end included over 100 stations and revolutionized forecasting by providing vertical atmospheric profiles essential for predicting storm development and aviation turbulence.^[20]^[21] These expansions, supported by collaborations with the National Bureau of Standards, occurred despite limited funding, reflecting prioritized investments in data collection networks that causal links tied to improving economic resilience through better agricultural and transport predictions. Early experiments with radar-like precipitation detection also emerged in the late 1930s, though full weather radar deployment awaited postwar surplus equipment.^[22] World War II accelerated meteorological integration, with the Bureau engaging in joint operations alongside Army and Army Air Forces weather units to supply forecasts for combat missions, supply chains, and strategic bombing. Executive Order 8991 in 1942 centralized wartime meteorological efforts, establishing the Weather Bureau Analysis Center to coordinate data for Allied operations, including D-Day weather assessments that underscored the causal role of accurate predictions in military outcomes.^[23] The Reorganization Plan No. IV of 1940, effective June 30, 1940, transferred the Bureau from the Department of Agriculture to the Department of Commerce, positioning it to better align civilian forecasting with aviation commerce and military needs through streamlined interagency data sharing.^[18] This shift facilitated postwar consolidations, as surplus military radars—numbering at least 25 units—were donated to the Bureau in the late 1940s, bolstering national observational networks and embedding wartime meteorological expertise into civilian infrastructure for enhanced storm warnings and long-term climate records.^[24]

Modernization and Cold War Era (1951–1999)

In the early 1950s, the U.S. Weather Bureau, predecessor to the National Weather Service, pioneered numerical weather prediction through computational models grounded in atmospheric dynamics. Jule Charney led a team that, in 1950, produced the first electronic computer-generated forecast using the ENIAC, applying the barotropic vorticity equation to simplify geophysical fluid dynamics for practical computation.^[25] This effort, supported by collaborations with the U.S. Air Force and Navy amid Cold War demands for reliable aviation and defense forecasting, culminated in the 1955 establishment of the Joint Numerical Weather Prediction Unit, which integrated data assimilation techniques to initialize models with observed pressures and winds.^[26] These advancements shifted forecasting from subjective synoptic analysis to deterministic simulations, though limited by early computers' processing speeds of about 24 hours per 24-hour forecast.^[27] The 1960s introduced satellite-based remote sensing, transforming global data coverage previously constrained by surface stations. NASA's launch of TIROS-1 on April 1, 1960, marked the first successful meteorological satellite, delivering infrared and television imagery of cloud patterns that revealed previously unobserved weather systems over oceans and remote areas.^[28] Operational integration by the Weather Bureau enabled routine cloud-motion wind estimates and hurricane tracking, addressing gaps exposed in events like Typhoon Nina in 1959.^[29] By the 1970s, the Geostationary Operational Environmental Satellite (GOES) series, beginning with SMS-1 in 1974, provided continuous hemispheric views from fixed orbital positions, facilitating real-time monitoring of convective storms and supporting the bureau's transition to NOAA in 1970.^[30] Concurrently, planning for the Next Generation Weather Radar (NEXRAD) network addressed outdated World War II-era systems, with development authorized in 1979 to deploy Doppler radars for velocity and precipitation detection, motivated by needs for severe storm warnings amid increasing coastal populations vulnerable to hurricanes.^[31] Hurricane Andrew's landfall in south Florida on August 24, 1992, as a Category 5 storm with 165 mph winds, exposed deficiencies in forecast accuracy and warning dissemination, inflicting $27.5 billion in damages (1992 dollars) and prompting congressional scrutiny of the Weather Service's capabilities.^[32] Critiques highlighted underestimation of intensification and communication breakdowns with local officials, accelerating the Modernization and Associated Restructuring Act of 1992, which funded upgrades including the first WSR-88D radar deployment in Norman, Oklahoma, in 1990 and nationwide rollout by the mid-1990s.^[33] The Advanced Weather Interactive Processing System (AWIPS), implemented starting in fall 1996 at initial sites, integrated radar, satellite, and numerical model data into a unified workstation interface, enabling forecasters to assimilate diverse inputs for probabilistic outlooks and reducing manual processing errors.^[34] By 1999, these reforms had enhanced lead times for severe weather alerts, though challenges persisted in balancing computational demands with operational reliability.^[5] ![NWS Mosaic Radar Composite showing modernization-era radar advancements][float-right]

21st Century Transformations (2000–Present)

Following Hurricane Katrina in 2005, the National Weather Service (NWS) pursued reforms to enhance severe weather forecasting accuracy and lead times, incorporating advanced ensemble modeling techniques into operational systems. These efforts included the establishment of a dedicated hurricane modeling group in 2007 to refine intensity forecasts using high-resolution models like the Hurricane Weather Research and Forecasting (HWRF) system, which improved track and surge predictions through probabilistic ensemble approaches. By 2016, such advancements had elevated the reliability of three-day forecasts to match the accuracy of prior two-day predictions, contributing to extended warning periods for hurricanes and other hazards.^[36]^[37]^[38] In the 2010s, NWS integrated cloud computing to bolster data processing and model scalability, exemplified by early adoption for website operations and later expansions into high-performance forecasting. This shift enabled the development of cloud-based Warn-on-Forecast systems by 2022, leveraging platforms like Microsoft Azure for real-time severe weather prediction and ensemble data assimilation, reducing computational bottlenecks in numerical weather prediction.^[39]^[40] Recent operational changes emphasize clearer communication and specialized risk tools amid increasing disaster frequency, with NWS transitioning hazard messaging to plain-language headlines by 2024–2025, replacing terms like "Advisory" and "Special Weather Statement" to better convey specific threats such as flooding or excessive heat. In 2024, NWS updated its HeatRisk methodology in collaboration with the Centers for Disease Control and Prevention, introducing localized daily thresholds based on health impacts and temperature data for seven-day outlooks to aid alert decisions. The agency also launched the National Water Prediction Service in May 2024, superseding the Advanced Hydrologic Prediction Service with enhanced flood inundation mapping covering 60% of the U.S. population and integrated river forecasts. These align with ongoing Weather-Ready Nation initiatives, including annual billion-dollar disaster assessments by NOAA's National Centers for Environmental Information, which documented 27 such events in 2024 alone, informing adaptive forecasting methodologies.^[41]^[42]^[43]^[44]^[45]^[46]^[47]^[48]

Mandate and Core Functions

Legal Establishment and Statutory Responsibilities

The National Weather Service traces its legal origins to the Organic Act of 1890 (26 Stat. 65), which established the Weather Bureau within the United States Department of Agriculture to centralize meteorological observations and forecasting, initially emphasizing warnings for agricultural and maritime interests affected by weather variability.^[49] This foundational legislation vested the bureau with authority to collect data and issue storm signals, reflecting congressional recognition of weather's direct impact on national economic activities, including crop yields and river navigation.^[50] In 1940, the Weather Bureau transferred to the Department of Commerce under Public Law 76-610 (54 Stat. 396), aligning it more explicitly with the constitutional Commerce Clause (U.S. Const. art. I, § 8, cl. 3), as severe weather disrupts interstate trade, transportation, and supply chains.^[51] The service's modern framework solidified with the creation of the National Oceanic and Atmospheric Administration in 1970 (Public Law 91-196), integrating the renamed National Weather Service while preserving its core meteorological mandate under the Secretary of Commerce.^[52] Statutory responsibilities are codified primarily in 15 U.S.C. § 313, directing the Secretary of Commerce—through the NWS—to forecast weather conditions, issue storm warnings, display weather and flood signals benefiting commerce and agriculture, and distribute meteorological and climatological data. This provision mandates timely, accurate dissemination of observational data and short-term predictions to safeguard life, property, and economic productivity, without authorizing regulatory enforcement or proprietary restrictions on public access.^[53] Products such as forecasts and warnings must remain freely available to the public and non-federal entities, prohibiting commercialization of core government-generated data to ensure equitable access for aviation, agriculture, and emergency response sectors.^[54] The NWS's mandate delineates clear boundaries against expansion into non-meteorological domains, prioritizing empirical data collection and predictive modeling over interpretive advocacy or long-term policy influence.^[51] Responsibilities exclude prescriptive actions on climate policy or regulatory overreach, confining operations to verifiable, near-term hazard mitigation grounded in observed phenomena rather than speculative scenarios.^[52] This statutory focus underscores a non-partisan commitment to data-driven public goods, with accountability tied to forecast accuracy and warning efficacy rather than alignment with extraneous agendas.^[53]

Public Safety and Economic Objectives

The National Weather Service's public safety objectives center on issuing timely warnings and forecasts to reduce loss of life and injury from severe weather, as articulated in its core mission to provide weather, water, and climate data that protect life and property.^[55] This involves prioritizing empirical improvements in detection and communication, such as extended lead times for alerts, which enable proactive responses by individuals and emergency managers. For tornadoes, average warning lead times have risen to 10-14 minutes in recent years, allowing more time for sheltering and evacuation compared to pre-Doppler eras.^[56] Quantitative analyses demonstrate the causal benefits of these enhancements. The nationwide deployment of WSR-88D Doppler radars in the 1990s correlates with substantial casualty reductions, with one study estimating 1,900 lives saved and 26,000 injuries averted over the subsequent decades—translating to approximately 80-100 lives preserved annually on average.^[57] Such metrics reflect direct attribution to improved warning performance, including higher probabilities of detection, rather than confounding factors like population shifts, underscoring the value of technological investments in observation networks. Economically, NWS objectives focus on furnishing probabilistic forecasts that support decision-making in vulnerable sectors, thereby enhancing national productivity and mitigating losses. Weather-sensitive industries derive an estimated $13 billion in annual value from NWS data and predictions, with agriculture relying on short- and long-range outlooks for crop planning and irrigation, and aviation utilizing terminal forecasts to minimize disruptions and fuel inefficiencies.^[58]^[59] These tools reduce operational risks through uncertainty quantification, as evidenced by numerical weather prediction advancements that inform over $1 trillion in yearly GDP-influencing activities tied to weather variability.^[60]

Organizational Structure

Headquarters and Leadership

![National Weather Service headquarters building in Silver Spring, Maryland]float-right The National Weather Service (NWS) maintains its central headquarters at 1325 East-West Highway in Silver Spring, Maryland, serving as the administrative hub for operations under the National Oceanic and Atmospheric Administration (NOAA).^[61] This location coordinates national-scale policy, resource allocation, and strategic planning, with approximately 4,000 employees supporting core functions across the organization as of recent staffing assessments.^[62] The headquarters facilitates integration with NOAA's broader portfolio, including oceanic and climate initiatives, while preserving NWS's distinct emphasis on operational meteorology and public warnings grounded in real-time data.^[63] Leadership at the headquarters is headed by the NWS Director, who concurrently holds the position of NOAA Assistant Administrator for Weather Services, currently Ken Graham as of 2025.^[64] The Director provides oversight for budget distribution, prioritizing investments in empirical observation networks and predictive modeling systems to enhance forecast accuracy and reliability.^[65] This role ensures accountability in resource management, directing funds toward verifiable data acquisition and computational infrastructure rather than ancillary programs, thereby maintaining focus on causal mechanisms in weather prediction.^[66] Administrative efficiency is upheld through the Office of the Chief Operating Officer and supporting divisions, which manage day-to-day execution of weather services without overlap into regional field activities.^[67] NOAA's structure positions NWS as a dedicated line office, insulating weather-specific mandates from expansive environmental research agendas and promoting decisions based on measurable outcomes in public safety and economic protection.^[68]

Regional and Field Offices

The National Weather Service (NWS) employs a decentralized organizational framework featuring six regional headquarters that oversee field operations across the United States, facilitating localized weather forecasting and rapid dissemination of warnings tailored to specific geographic areas. This structure prioritizes proximity to affected regions, enabling meteorologists to integrate real-time local observations with national data for timely responses to severe weather events, in contrast to a fully centralized model that might delay decision-making.^[69] At the field level, the NWS operates 122 Weather Forecast Offices (WFOs), each assigned a defined area of responsibility covering states, counties, or portions thereof, staffed 24/7 to issue routine forecasts, severe weather watches, warnings, and advisories. These offices handle day-to-day meteorological services, including coordination with emergency managers for events like tornadoes, hurricanes, and winter storms, ensuring warnings reach the public within critical lead times—often 13-15 minutes for tornadoes.^[70]^[71] Complementing the WFOs, 13 River Forecast Centers (RFCs) specialize in hydrologic predictions, producing river stage forecasts, flood outlooks, and inundation mapping by integrating precipitation data with river basin models. These centers support flood risk management across multi-state basins, providing guidance to WFOs and federal agencies like the U.S. Army Corps of Engineers for dam operations and evacuations.^[72]^[73] Additionally, 21 Center Weather Service Units (CWSUs) are embedded within Federal Aviation Administration Air Route Traffic Control Centers to deliver continuous aviation weather support, issuing advisories on turbulence, icing, and thunderstorms that impact en-route flight safety. This co-location ensures seamless integration of weather information into air traffic control, minimizing disruptions and enhancing operational efficiency for the national airspace system.^[74]^[75]

Specialized National Centers

The National Centers for Environmental Prediction (NCEP), a component of the National Weather Service, coordinates a network of specialized centers focused on high-impact weather phenomena and extended-range guidance, producing centralized products that inform national decision-making across sectors like agriculture, energy, and transportation.^[76] These centers leverage ensemble modeling outputs and observational data to generate probabilistic forecasts, distinct from localized predictions handled by field offices.^[77] The Storm Prediction Center (SPC), located in Norman, Oklahoma, specializes in severe convective weather, issuing daily convective outlooks that delineate risks of tornadoes, large hail, and damaging winds up to eight days in advance, with categorical probabilities refined through forecaster expertise.^[78] These outlooks, updated multiple times daily during active severe weather periods, support emergency managers and media by highlighting areas of enhanced threat, such as slight, enhanced, moderate, or high risk levels.^[79] The National Hurricane Center (NHC) in Miami, Florida, delivers official track and intensity forecasts for tropical cyclones affecting the United States, issuing advisories every six hours during active storms, including probabilistic cone graphics that depict forecast uncertainty based on historical error statistics.^[80] Established under NCEP oversight, the NHC's products extend to wind probability fields and storm surge guidance, aiding coastal preparedness with lead times of 120 hours or more.^[80] The Climate Prediction Center (CPC) provides monthly and seasonal outlooks tying large-scale climate drivers like the El Niño-Southern Oscillation (ENSO) to U.S. temperature and precipitation patterns, with probabilistic tercile forecasts updated monthly and incorporating dynamical model consensus.^[81] For instance, as of October 2025, CPC assessments indicate La Niña conditions persisting through winter, influencing drought persistence in the southern U.S.^[81] The Aviation Weather Center (AWC) collaborates directly with the Federal Aviation Administration (FAA) to produce en-route and terminal forecasts, including graphical turbulence and icing products that integrate real-time pilot reports with model data for airspace flow optimization.^[82] AWC meteorologists embedded at FAA facilities contribute to traffic management decisions, issuing significant weather advisories that mitigate delays affecting over 50,000 daily flights.^[83] The Space Weather Prediction Center (SWPC) forecasts geomagnetic storms and solar radiation events stemming from coronal mass ejections, providing alerts on radio blackouts and satellite disruptions with 1-4 day lead times via physics-based models like WSA-ENLIL.^[84] These predictions safeguard power grids and GPS-dependent systems, with SWPC issuing scales for geomagnetic (G-scale) and solar radiation (S-scale) severity based on observed solar wind parameters.^[85] In 2025, NWS specialized centers advanced fire weather capabilities through the National Interagency Fire Weather Annual Operating Plan, standardizing products like spot weather forecasts for active wildfires across federal and state responders.^[86] An experimental hourly wildfire hazard prediction tool, leveraging updated model weather inputs, began operational testing in August 2025 to capture rapid fire spread dynamics.^[87] For ocean predictions, the Ocean Prediction Center implemented marine zone boundary adjustments in spring 2025, refining offshore wind and wave forecasts for improved maritime safety in regions like the Pacific and Atlantic.^[88]

Data Acquisition

Surface and Cooperative Networks

The National Weather Service (NWS) relies on surface observation networks to collect ground-level meteorological data essential for weather forecasting and climate monitoring. These networks include automated systems and volunteer-based programs that provide measurements of temperature, wind, precipitation, and other variables. Automated Surface Observing Systems (ASOS) form the primary real-time backbone, with over 900 stations across the United States operating continuously to record parameters such as air temperature, wind speed and direction, dew point, and visibility.^[89] Automated Weather Observing Systems (AWOS), often deployed at airports by the Federal Aviation Administration or private entities, supplement ASOS coverage, particularly in aviation-focused areas.^[90] Complementing automation, the Cooperative Observer Program (COOP) engages over 11,000 volunteers who submit daily observations, primarily maximum and minimum temperatures and precipitation totals, contributing to long-term climate baselines dating back over a century.^[91] These empirical records from diverse sites, including rural farms and national parks, enable detection of climatic trends with standardized protocols that minimize subjectivity. COOP data's reliability stems from its extensive spatial distribution and historical continuity, supporting verification of model outputs and historical comparisons.^[92] NWS integrates surface data from these networks under policies promoting open access, occasionally incorporating supplementary observations from state mesonets and private-sector contributors to enhance density in underserved regions. However, primary reliance remains on federal and volunteer sources to ensure data quality and uniformity. Challenges persist in raw observations, notably urban heat island effects, where stations in developed areas record elevated temperatures due to impervious surfaces and anthropogenic heat, potentially biasing local analyses by 1-3°C or more during calm conditions.^[93] Siting guidelines aim to mitigate such issues by preferring open, rural exposures, though urban encroachment and station relocations necessitate ongoing quality control adjustments.^[94]

Upper-Air and Remote Sensing Observations

The National Weather Service maintains a network of 92 radiosonde observation sites across North America and the Pacific Islands, conducting twice-daily launches synchronized to 00Z and 12Z UTC to capture vertical profiles of atmospheric pressure, temperature, humidity, and winds up to approximately 30 kilometers altitude.^[95]^[96] These measurements provide critical data on moisture distribution, stability indices like Convective Available Potential Energy (CAPE), and wind shear profiles essential for diagnosing conditions conducive to thunderstorm development and tornado genesis, where vertical gradients drive causal mechanisms such as updrafts and rotation.^[97] Radiosondes, carried aloft by helium-filled balloons ascending at 5-6 meters per second, transmit real-time telemetry via ground receivers, enabling rapid assimilation into numerical weather prediction models for initializing three-dimensional atmospheric states.^[98] To augment the geographically limited radiosonde coverage, the NWS incorporates Global Positioning System Radio Occultation (GPSRO) observations, which derive high-vertical-resolution profiles of bending angles convertible to temperature and humidity via inversion techniques, unaffected by clouds or aerosols.^[97] GPSRO data, sourced from satellite constellations like COSMIC-2 and commercial providers, offer near-global sampling with horizontal resolutions around 200 kilometers, proving particularly valuable over oceans and remote regions where direct soundings are infeasible, thereby improving model initial conditions for mid-tropospheric features influencing jet streams and storm tracks. Assimilation of these all-weather observations has demonstrated modest enhancements in forecast skill, such as anomaly correlations for upper-air temperatures by 0.01-0.03, by mitigating biases in data-sparse areas.^[99] For tropical cyclones, targeted upper-air data collection occurs via NOAA aircraft reconnaissance missions using WP-3D Orion "Hurricane Hunter" platforms equipped with GPS dropwindsondes—disposable probes that descend via parachute while measuring profiles similar to radiosondes but with finer temporal resolution during flight legs into storm cores.^[100] These missions, conducted when hurricanes threaten U.S. interests, yield vortex data messages detailing eyewall winds and thermodynamic structures at multiple altitudes, directly informing intensity forecasts where surface proxies alone fail to capture eyewall replacement cycles or rapid intensification driven by mid-level ventilation.^[101] Dropwindsondes provide data at intervals of 1-3 kilometers vertically, complementing flight-level observations at 700 hPa (about 10,000 feet).^[102] Despite these efforts, the sparsity of upper-air observations—limited to fixed sites and opportunistic flights—poses challenges for initializing high-resolution models, as horizontal gaps exceeding 200-400 kilometers can propagate errors in representing mesoscale features like dry lines or outflow boundaries, reducing predictability in convective-scale phenomena.^[103] Studies indicate that such initial condition uncertainties amplify forecast divergences, particularly in data-void regions, underscoring the need for denser sampling to resolve causal instabilities beyond surface-inferred approximations.^[104] Recent staffing constraints have occasionally reduced launches at select sites, further highlighting vulnerabilities in network reliability for consistent model inputs.^[105]

Marine and International Data Sources

The National Weather Service (NWS) acquires marine data through the National Data Buoy Center (NDBC), which operates moored buoys delivering real-time measurements of wind, waves, temperature, and pressure critical for assessing coastal hazards like storm surges and tsunamis.^[106] These observations supplement land-based networks by providing offshore baselines for model initialization and validation.^[106] A key component is the Deep-ocean Assessment and Reporting of Tsunamis (DART) array, comprising 39 U.S.-operated buoys positioned in the Pacific and Atlantic basins as of 2024, equipped with seafloor pressure sensors that transmit acoustic signals to surface units for rapid tsunami detection and alerting.^[107] Voluntary Observing Ships (VOS) further augment this by furnishing underway reports from merchant vessels, with the U.S. program equipping and training crews to cover about one-quarter of the global fleet, yielding thousands of daily surface observations on sea state and atmospheric conditions.^[108] International cooperation via World Meteorological Organization (WMO) frameworks enables reciprocal real-time data sharing, including satellite-derived marine products from entities like EUMETSAT, which bolsters U.S. forecasting through integrated global inputs without reliance on isolated national efforts.^[109]^[110] Nonetheless, deficiencies persist in Arctic marine coverage, where limited buoy and ship density constrains data density for initializing models and forecasting extended-range phenomena like polar low development.^[111]

Forecasting and Technology

Numerical Models and Prediction Systems

The National Weather Service (NWS), through the National Centers for Environmental Prediction (NCEP), employs numerical weather prediction (NWP) models that solve primitive equations representing atmospheric dynamics and physics, evolving from early barotropic models of the 1950s—which treated the atmosphere as a single layer conserving potential vorticity—to multi-layer primitive equation systems by the 1970s that incorporated baroclinic processes and improved verification scores for 24-48 hour forecasts by 20-30% in height anomaly correlations.^[112]^[113] This progression enabled better representation of vertical structure and frontal systems, with subsequent integrations of parameterized physics for convection, radiation, and land-surface interactions enhancing overall skill, as evidenced by global 500 hPa geopotential height anomaly correlations exceeding 0.90 for 5-day forecasts in modern iterations.^[114] Central to global predictions is the Global Forecast System (GFS), which utilizes the Finite-Volume Cubed-Sphere (FV3) dynamical core for semi-implicit, semi-Lagrangian advection of mass, momentum, and moisture, coupled with physics suites handling microphysics, boundary layer turbulence, and cumulus convection.^[115]^[116] The GFS runs at resolutions up to 13 km horizontally, producing forecasts out to 16 days, with deterministic and ensemble variants informing medium-range guidance. For short-range, high-impact events, the High-Resolution Rapid Refresh (HRRR) model operates as a convection-allowing system at 3 km grid spacing over the contiguous United States, explicitly resolving deep moist convection without reliance on parameterized schemes, and updates hourly using advanced data assimilation.^[117]^[118] As of 2025, HRRR version 4 incorporates refined physics for aerosols and fire weather, contributing to improved probabilistic severe weather forecasts with critical success indices for thunderstorms rising by 5-10% over prior versions in verification against radar observations.^[119] To quantify uncertainty inherent in chaotic atmospheric evolution, NWS employs ensemble prediction systems such as the Global Ensemble Forecast System (GEFS) and High-Resolution Ensemble Forecast (HREF), which generate 20-30 perturbed members via methods including breeding of growing modes and stochastic kinetic energy backscatter, effectively implementing Monte Carlo sampling of initial condition and model physics errors to produce probabilistic outputs like spread-error ratios near 1.0 for optimal reliability.^[120]^[121] These ensembles reduce overconfidence in deterministic runs, with verification showing ensemble-mean 5-day forecast skill matching or exceeding single-member performance from a decade prior, particularly for tropical cyclone tracks where spread captures 70-80% of observed variability.^[114] These models demand substantial computational resources, supported by NCEP's operational supercomputers achieving aggregate capacities of approximately 29 petaFLOPS across twin systems as of 2023 upgrades, enabling parallel integrations and ensemble suites within 1-2 hour cycles.^[122] By 2025, additional research capacity from systems like Rhea pushes total NOAA-wide performance toward 50 petaFLOPS, facilitating higher-resolution convection-allowing global extensions and real-time ensemble post-processing for enhanced prediction reliability.^[123]^[124]

Radar, Satellite, and Computational Infrastructure

The National Weather Service (NWS) relies on the Next Generation Weather Radar (NEXRAD) network, comprising 159 high-resolution S-band Doppler radars operated jointly with the Federal Aviation Administration and Department of Defense, to provide real-time precipitation and wind data essential for nowcasting severe weather events.^[125] These radars measure reflectivity to detect precipitation intensity and Doppler velocity to estimate wind speeds within storms, enabling forecasters to track storm motion and rotation indicative of tornadoes over ranges up to 250 nautical miles.^[125] Deployed since the 1990s, the network covers the contiguous United States, Alaska, Hawaii, and U.S. territories, with recent upgrades including a $150 million Service Life Extension Program completed in 2024 to extend operational lifespan amid rising maintenance demands.^[126] Geostationary Operational Environmental Satellites (GOES-R series), launched starting with GOES-16 in 2016, furnish continuous hemispheric imagery for monitoring convective development and tropical cyclones, supporting nowcasting through the Advanced Baseline Imager (ABI) that scans the full disk every 5 minutes in high resolution.^[127] This series enhances detection of rapid-onset hazards like lightning and wildfires via instruments such as the Geostationary Lightning Mapper, providing data latency under 20 minutes for forecaster integration.^[128] NOAA's four-satellite constellation ensures redundancy and overlap, though operational costs include ongoing ground system enhancements for data processing.^[129] Computational infrastructure centers on the Advanced Weather Interactive Processing System II (AWIPS-II), a modular software framework deployed at NWS offices since 2013 for visualizing and manipulating radar and satellite inputs alongside model outputs.^[130] AWIPS-II facilitates nowcasting by allowing interactive overlay of multi-sensor data, with open-source elements enabling customization, though legacy hardware strains have prompted migrations to cloud platforms post-2020 under NOAA's Cloud Strategy.^[131] These shifts leverage elastic computing for handling petabytes of incoming observations, reducing latency in data dissemination, but require substantial investment in cybersecurity and interoperability.^[132] Maintenance of this infrastructure incurs high costs, exemplified by NEXRAD's annual upkeep exceeding outage mitigation values estimated at $29 million from alternative datasets, yet yields quantifiable benefits in reducing tornado-related casualties through improved lead times.^[133] Funding shortfalls contributed to 2024 outages affecting radar data feeds and Automated Surface Observing Systems, prompting congressional scrutiny over reliability amid proposed budget reductions. While performance gains in nowcasting accuracy justify expenditures—evidenced by enhanced severe storm detection—these vulnerabilities underscore tensions between deferred maintenance and operational resilience, with critics noting that underinvestment risks eroding public safety margins despite empirical returns on radar enhancements.^[134]^[135]

Products and Services

Routine Weather Forecasts and Outlooks

The National Weather Service (NWS) issues routine short-term weather forecasts spanning 0 to 7 days, leveraging Model Output Statistics (MOS) to refine raw outputs from numerical weather prediction models like the Global Forecast System (GFS) and North American Mesoscale (NAM) into localized guidance for temperature, precipitation probability, sky cover, and wind speed.^[136] ^[137] MOS employs multiple linear regression equations derived from historical pairings of model predictors and observed surface data, enabling correction of systematic model biases such as overprediction of precipitation in certain terrains.^[138] These forecasts are disseminated via text products, graphical zone maps, and the National Digital Forecast Database, supporting daily public planning by providing deterministic point forecasts alongside probabilistic elements like 12-hour precipitation chances exceeding 0.01 inches.^[139] For longer-range guidance, the NWS Climate Prediction Center (CPC) produces extended outlooks up to 90 days, blending dynamical ensemble model outputs—such as from the Climate Forecast System (CFSv2)—with statistical regressions incorporating sea surface temperatures, soil moisture anomalies, and large-scale teleconnections like the El Niño-Southern Oscillation (ENSO).^[140] ^[141] CPC's 3-month precipitation outlooks specify tercile probabilities (e.g., 40-50% chance of above-median totals in the Pacific Northwest), issued monthly around mid-month and updated to reflect evolving predictive signals.^[140] ^[142] These probabilistic products aid agricultural and water resource planning by quantifying uncertainty beyond simple categorical statements. The effectiveness of NWS routine probabilistic forecasts, including precipitation probabilities, is quantified using the Brier score, defined as the mean squared error between forecasted probabilities and observed binary outcomes (e.g., precipitation occurrence), with values closer to zero indicating higher accuracy.^[143] ^[144] Brier skill scores, normalizing performance against climatological baselines, reveal positive skill in MOS-guided short-term precipitation forecasts (typically 0.1-0.3 for 24-hour events) and modest gains in extended outlooks through empirical tuning, where coefficients are recalibrated semiannually against recent verification data to mitigate persistent biases like underforecasting in convective regimes.^[143] ^[145] Such metrics underscore the forecasts' value for risk-informed decisions, though skill diminishes beyond 10 days due to chaotic atmospheric dynamics.^[145]

Warnings, Watches, and Advisories

The National Weather Service issues warnings for imminent or occurring hazardous weather events with high confidence of occurrence, typically providing lead times of minutes to hours for immediate threats like tornadoes or flash floods. Watches indicate conditions favorable for such events within 12 to 48 hours, while advisories alert to less severe but potentially hazardous conditions expected within hours to a day. These products aim to balance probability of detection (POD), false alarm ratios (FAR), and lead times, with ongoing verification showing average tornado warning lead times exceeding 10 minutes nationally, though FAR remains a focus for reduction to maintain public trust.^[146]^[147] Tornado warnings are issued upon radar-indicated rotation, spotter reports, or sightings confirming a tornado's path, emphasizing damage potential via the Enhanced Fujita (EF) scale, which estimates wind speeds from observed destruction to structures and vegetation. Criteria incorporate threat levels, such as considerable damage from hail of 1.75 inches (golf ball-sized) or winds of 70 mph, escalating to tornado emergencies for confirmed violent tornadoes (EF2 or stronger) in densely populated areas with radar-confirmed debris, signaling catastrophic impacts. In 2021, the NWS adopted impact-based messaging with plain-language headlines replacing generic "advisory" or "special statement" tags to enhance risk communication, a practice refined in 2024 events to include explicit phrases like "occasionally produce tornadoes with little advance warning" for clarity during rapid-onset storms.^[148]^[149]^[150]^[41]^[151] Flash flood warnings rely on inputs from River Forecast Centers (RFCs), which provide Flash Flood Guidance (FFG) estimating the rainfall volume over 1-, 3-, or 6-hour durations needed to inundate small streams, derived from multi-sensor precipitation data including radars, gauges, and hydrologic models. Warnings are triggered when observed or forecasted rainfall exceeds FFG thresholds, often combined with real-time stream gauges and Flash Flood Guidance tools in the Hazard Services application for rapid issuance, targeting lead times of 30 minutes to hours.^[152]^[153]^[154] Heat advisories are issued for heat index values of 100–104°F (38–40°C) persisting for at least two days or overnight lows not dropping below 75°F (24°C), focusing on apparent temperature risks rather than raw wet-bulb globe temperature (WBGT), an experimental metric accounting for sun exposure, wind, and humidity primarily for occupational heat stress rather than public alerts. Extreme cold warnings, renamed from wind chill warnings in October 2024, activate for temperatures or wind chills of -20°F (-29°C) or lower for at least three hours without a minimum wind threshold, varying locally (e.g., -25°F/-32°C in northern regions) to reflect hypothermia risks.^[155]^[156]^[157]^[158] Verification metrics for severe thunderstorm warnings, which encompass hail of 1 inch or winds of 58 mph, show a national POD of approximately 70%, indicating that about seven in ten verified events occur within warned areas, with efforts to minimize FAR through improved radar integration and forecaster training. These statistics, derived from contingency tables comparing warnings to storm reports, highlight persistent challenges in convective predictability, though POD has risen with dual-polarization radar upgrades since 2013.^[159]^[160]

Sector-Specific Services (Aviation, Fire, Marine)

The National Weather Service provides specialized aviation weather products through the Aviation Weather Center and local Weather Forecast Offices, including Terminal Aerodrome Forecasts (TAFs) that detail expected conditions such as wind speed and direction, visibility, present weather like thunderstorms or fog, cloud cover, and ceilings at over 1,200 U.S. airports, issued four times daily and valid for 24 or 30 hours.^[161] Additionally, Significant Meteorological Information (SIGMETs) serve as inflight advisories for widespread hazardous conditions, such as severe turbulence or thunderstorms, covering areas of at least 3,000 square miles and issued for durations up to 6 hours with extensions possible.^[162] These are complemented by AIRMETs for moderate hazards like icing or mountain obscuration, and Center Weather Service Units deliver real-time updates to air traffic controllers to enhance en route safety beyond standard public forecasts.^[163] For fire management, the NWS issues tailored Fire Weather Watches and Red Flag Warnings 24 to 96 hours in advance when criteria such as sustained winds over 20 mph combined with relative humidity below 15% and dry fuels indicate critical fire spread potential, drawing on the National Fire Danger Rating System (NFDRS) to forecast indices including ignition component, energy release component, and spread component based on inputs like temperature, humidity, wind, and precipitation duration valid from 1300 local time the following day.^[164]^[165] Spot forecasts provide customized point-specific predictions for active incidents or prescribed burns, integrating NFDRS outputs with local observations to support federal, state, and tribal fire agencies in operational decision-making, distinct from broader public outlooks by emphasizing fuel moisture and fire behavior metrics.^[166] Marine sector services include zone-specific offshore and coastal forecasts covering winds, waves, seas, and weather hazards up to 250 nautical miles from shore, subdivided into universal geographic identifiers for areas like the Mid-Atlantic or Gulf of Mexico, with updates incorporating synoptic overviews for shipping routes.^[167] These products are disseminated via U.S. Coast Guard VHF radio broadcasts providing near-continuous coastal coverage, where NWS forecasts form the core content relayed to mariners, enabling integration with search-and-rescue operations and vessel routing without relying solely on general coastal warnings.^[168] Private entities often augment NWS data feeds for enhanced marine decision support tools, such as route optimization software.^[169]

Dissemination and Accessibility

Distribution Channels and Partnerships

The National Weather Service (NWS) primarily disseminates weather products through the NOAA Weather Wire Service (NWWS), an emergency alert and warning system that delivers text-based meteorological, hydrologic, and geophysical information via satellite and internet connections. NWWS enables rapid distribution to public users, commercial entities, and local, state, and federal agencies, serving as the fastest method for receiving alerts and warnings over internet protocols or C-band satellite feeds.^[170] This infrastructure supports full product feeds alongside alternatives like the Family of Services (FOS) via SBN/NOAAPORT satellite channels for broader broadcast reception.^[171] For aviation-specific dissemination, the NWS employs the International Weather XML (IWXXM) standard, facilitating machine-to-machine exchanges of meteorological data such as METARs, TAFs, and warnings in XML format compliant with ICAO requirements. Implementation of IWXXM began with version 2.1 in 2017 and advanced to version 3.0 by 2019, with ongoing extensions for U.S.-specific needs like temperature extremes in reports. Public access to core data occurs through the weather.gov platform and its associated API, a RESTful JSON web service providing forecasts, alerts, and observations to developers for integration into third-party applications.^[172] NWS partnerships with broadcasters and emergency management entities enhance reach via the Integrated Public Alert and Warning System (IPAWS), where NWS data feeds Wireless Emergency Alerts (WEA) and the Emergency Alert System (EAS).^[173] FEMA, the FCC, and NWS collaborate to authenticate and transmit life-saving warnings through mobile carriers and broadcast stations, ensuring geo-targeted delivery without public subscription.^[174] The agency's open data practices, exemplified by the unrestricted API, allow private sector developers to leverage NWS datasets for custom weather apps, fostering innovation while maintaining free core access.^[175] These digital pathways, including internet-centric NWWS rollout since 2015, have streamlined dissemination by reducing reliance on legacy satellite hardware alone.

Public Communication and Education Efforts

The National Weather Service (NWS) emphasizes public education initiatives that prioritize practical training and community preparedness to foster resilience against severe weather, focusing on measurable outcomes such as participant training completion and program adoption rather than mere awareness dissemination.^[176] Central to these efforts is the SKYWARN program, a volunteer network that trains citizens to identify and report severe weather conditions, enabling ground-truth data to supplement radar and model forecasts.^[177] As of recent assessments, SKYWARN encompasses between 350,000 and 400,000 trained spotters across the United States, with local NWS offices conducting free, approximately two-hour sessions on storm structure, safety, and reporting protocols.^[177] These trainings, often held annually or seasonally in coordination with emergency management partners, aim to build a distributed observation network that enhances local response capabilities during high-risk events like tornadoes and thunderstorms.^[178] Complementing individual training, the StormReady program certifies communities, counties, and institutions that demonstrate sustained preparedness measures, including siren networks, emergency plans, and public outreach, to reduce vulnerability to severe weather.^[179] Launched in 2000, StormReady requires participants to meet criteria such as having multiple alert methods, conducting regular drills, and maintaining a cadre of trained spotters, with recertification every four years to ensure ongoing adoption.^[180] As of June 20, 2024, 3,371 sites nationwide held StormReady designation, representing a subset of the roughly 3,234 U.S. counties but illustrating targeted expansion toward comprehensive coverage.^[181]^[182] This program evaluates resilience through verifiable infrastructure and behavioral commitments, rather than self-reported awareness, aligning with NWS goals for proactive hazard mitigation.^[183] Following the May 22, 2011, Joplin, Missouri, EF5 tornado—which exposed gaps in warning dissemination—NWS refined risk messaging strategies, incorporating social media for real-time, impact-focused communication to better convey urgency and expected effects.^[184] The subsequent service assessment prompted a shift to impact-based warnings by 2013, emphasizing potential consequences over meteorological details, alongside increased use of platforms like Twitter and Facebook for targeted alerts, as local media in Joplin had demonstrated efficacy in text and social dissemination during the event.^[185]^[186] These adaptations sought to counteract message overload by prioritizing actionable resilience advice, such as sheltering protocols, over generalized alerts. NWS efforts also address risks of public desensitization from frequent warnings, monitoring false alarm ratios to avoid the "cry wolf" effect where repeated non-events erode trust and compliance.^[146] While theoretical models predict that excessive false alarms could diminish responsiveness—analogous to fatigue in emergency alerts—empirical surveys in tornado-prone regions indicate limited evidence of broad complacency, with residents often distinguishing verified threats via personal experience or supplementary sources.^[187]^[188] Nonetheless, NWS pursues false alarm reduction through refined verification criteria, balancing comprehensive coverage with messaging precision to sustain adoption of preparedness actions.^[146]

Performance and Accuracy

Metrics of Forecast Skill and Verification

The National Weather Service (NWS) evaluates forecast skill through quantitative metrics standardized in meteorology, including anomaly correlation (AC) for continuous predictions like temperature anomalies and geopotential heights, which measures pattern similarity relative to climatology, and the critical success index (CSI) for dichotomous events such as precipitation exceeding thresholds, defined as hits divided by hits plus misses plus false alarms.^[189] These indices quantify skill beyond persistence or climatology baselines, with AC values above 0.5 indicating useful forecasts and CSI values reflecting balanced detection of events without excessive false alarms. Since the 1970s, NWS forecast verification data document consistent skill gains across lead times, attributable to enhanced data assimilation, computational power, and model physics rather than random variability. For five-day 500 hPa geopotential height forecasts—a proxy for upper-air patterns influencing surface conditions—AC has improved markedly, with operational global models routinely exceeding 0.8 in recent years versus sub-0.7 levels in the 1990s, equating to multi-day forecasts now rivaling one-day accuracy from earlier eras.^[190] Surface temperature verifications, including gridded maximum temperature outlooks, show analogous AC trends, with experimental NWS products achieving higher correlations through bias-corrected ensemble methods.^[191] Precipitation skill, assessed via CSI for quantitative forecasts, has advanced similarly, with national and regional analyses indicating CSI values of 0.3–0.5 for 24-hour events at moderate thresholds, outperforming 1970s-era persistence baselines by factors of 2–3 in hit rates; frozen precipitation types exhibit particularly elevated CSI due to sharper synoptic signals.^[192]^[193] Post-event audits reinforce these trends; for Hurricane Ian in 2022, National Hurricane Center track forecasts—integral to NWS operations—yielded errors 20–30% below long-term averages at 48–72 hour leads, contributing to 2022's record-setting verification across multiple timesteps.^[194]^[195] Model resolution upgrades underpin much of this error reduction, as higher grid spacing (e.g., from 30 km to 3–13 km in convection-allowing models like HRRR) better resolves mesoscale features, lowering systematic biases and extending skillful lead times by 1–2 days in comparative tests.^[196]^[118] Verification protocols, including routine AC time series and CSI stratification by event prevalence, ensure ongoing refinement, though challenges persist in low-prevalence extremes where CSI sensitivity to base rates can mask subtle gains.^[197]

Comparisons to Private Sector Providers

Private sector weather providers, including AccuWeather and The Weather Company (operator of The Weather Channel), frequently outperform the National Weather Service (NWS) in short-term, consumer-oriented forecasts, particularly for temperature and precipitation in urban environments, according to independent verification analyses. For instance, a ForecastWatch evaluation of global and regional accuracy from 2021 to 2024 ranked providers like AccuWeather and The Weather Channel higher than NWS digital forecasts in metrics such as 1- to 3-day temperature predictions, with scores reflecting lower errors in densely populated areas where proprietary local data integration enhances resolution.^[198] Similarly, AccuWeather's ongoing 38-year study, which compares archived forecasts against observations, reported superior performance over NWS for June 2025 U.S. temperature outlooks, attributing gains to customized ensemble models layered atop public data.^[199] These edges stem from private investments in user-friendly visualizations and hyper-local adjustments, such as microclimate refinements for city-specific heat islands, which NWS grid-based products approximate less granularly.^[200] Despite these advantages, private providers remain fundamentally dependent on NWS and NOAA for foundational inputs, including radar composites, satellite imagery, radiosonde observations, and numerical weather prediction models like the Global Forecast System, which form the backbone of their operations. The NWS's 2017 Enterprise Analysis Report estimated that private weather firms derive up to $13 billion in annual economic value from publicly available government data, underscoring how commercialization amplifies rather than supplants public infrastructure.^[58] Without this free, comprehensive dataset—spanning over 3.5 billion daily observations—private replication would be cost-prohibitive, as affirmed by meteorological experts who note that no single company could sustain the NWS's nationwide observational network of radars, buoys, and cooperative stations.^[201]^[202] Comparisons highlight trade-offs in innovation versus accessibility: competition from private entities has spurred advancements in app-based graphics and niche short-term alerts, yet full privatization risks erecting paywalls that could exacerbate inequities in forecast access for underserved rural or low-income regions reliant on free NWS dissemination. In 2024–2025 discussions, proponents of hybrid models argue that private enhancements drive efficiency without compromising the public data mandate, while critics warn that restricting core observations behind commercial barriers—as floated in some policy proposals—would undermine equitable public safety, given NWS's role in deriving $31.5 billion in annual societal benefits from open forecasts.^[203]^[204] This dynamic positions NWS as the dominant provider of raw, verifiable data essential for both public warnings and private value-add services.

Notable Successes and Shortcomings

The National Weather Service demonstrated effective warning capabilities during the May 20, 2013, EF5 tornado in Moore, Oklahoma, issuing alerts with an average lead time of approximately 30 minutes—more than double the national average of 13 minutes at the time—which facilitated evacuations and limited fatalities to 24 amid $2 billion in damages and the destruction of over 1,000 homes.^[205]^[206] This outcome reflected empirical gains from prior lessons, including post-event refinements after the May 3, 1999, Oklahoma-Kansas outbreak of 74 tornadoes (including multiple F4/F5s) that killed 46 people; service assessments revealed technical glitches in radar data relay and alert dissemination via the Aging Fixed Telecommunication Switching System, spurring upgrades to more reliable NEXRAD Doppler networks and protocols like the inaugural "tornado emergency" issuance to prioritize life-saving communications.^[207]^[208] Despite such advances, shortcomings have arisen in underestimating event severity under data constraints. The May 18, 1980, Mount St. Helens eruption exemplified this, where initial forecasts anticipated steam explosions but failed to predict the magnitude of the lateral blast and ash column exceeding 80,000 feet, detected post-facto by NWS radar in Portland yet not preemptively detailed in advisories, contributing to 57 deaths and widespread aviation disruptions despite partial evacuations.^[209] Systemic vulnerabilities persist from excessive dependence on numerical weather prediction models in observation-poor environments, such as volcanic or remote terrains, where sparse inputs amplify initialization errors and degrade probabilistic outputs, as retrospective analyses of similar high-impact events have shown deviations exceeding 20-30% in plume trajectory and fallout predictions without real-time validation.^[207] These cases underscore causal trade-offs: timely, verified warnings in data-rich scenarios like Plains supercells have empirically reduced per-event mortality rates by enabling behavioral responses, whereas model-centric approaches in low-entropy regimes risk cascading inaccuracies, prompting ongoing NWS emphases on ensemble verification and augmented observations to mitigate false assurances.^[210]

Economic and Societal Impact

Contributions to Disaster Mitigation and Lives Saved

The issuance of timely warnings by the National Weather Service (NWS) has demonstrably reduced casualties from severe weather events, particularly tornadoes, through extended lead times that enable protective actions. Empirical analysis of tornado events shows that warnings with adequate lead times have reduced injuries by over 40% in affected areas, as longer preparation periods allow for sheltering and evacuation.^[211] Similarly, reductions in the national tornado false-alarm ratio, achieved via improved NWS verification processes, have lowered fatalities by 4% to 11% and injuries by 4% to 13% over the study period.^[212] Deployment of NWS-linked technologies, such as NOAA Weather Radio (NWR) transmitters, provides further evidence of causal impact on disaster mitigation. Cross-sectional studies comparing counties with and without NWR coverage found that transmitter introduction correlated with an almost 40% drop in tornado injuries and up to a 50% decrease in fatalities, controlling for factors like population density and storm intensity.^[213] These outcomes stem from real-time alert dissemination, which econometric models attribute to behavioral responses like seeking shelter, thereby averting deaths that would otherwise occur in unwarned events. Broader econometric evaluations quantify NWS alerts' role in limiting damages across hazards. Transition to probabilistic tornado warnings, informed by NWS data, has been modeled to decrease annual societal costs—including fatalities, injuries, and sheltering time—by $76 million to $139 million, by balancing warning coverage against false alarms.^[214] Such models, drawing on historical casualty data, underscore how NWS forecast improvements causally link to 20-40% reductions in event-specific damages through preemptive mitigation, though gains vary by hazard type and public response efficacy.^[213]^[211]

Cost-Benefit Evaluations and Resource Allocation

The National Weather Service (NWS) maintains an annual budget of approximately $1.25 billion for fiscal year 2025, drawn from federal appropriations within the National Oceanic and Atmospheric Administration (NOAA), representing a core investment in public weather infrastructure.^[215] Economic analyses, including the 2017 NWS Enterprise Analysis Report, estimate the total value of NWS-provided weather data and forecasts across industries at around $13 billion annually, implying a leveraged return where societal benefits from mitigated risks and enhanced productivity substantially exceed direct expenditures.^[216] Independent assessments of forecast utilization further suggest benefit-to-cost ratios exceeding 9:1 when attributing value to federal data contributions, underscoring undeniable public goods like reduced economic disruptions from severe weather.^[217] Critiques of resource efficiency focus on structural rigidities in government operations, where personnel expenses dominate budgeting—comprising up to 90% of costs in certain regional offices—and limit agility compared to private competitors with lower overhead and incentive-driven models.^[218] High staffing levels, including redundancies in administrative and field roles amid proposed consolidations, have drawn scrutiny for diverting funds from scalable technologies, with some analyses arguing that private-sector efficiencies could achieve similar outputs at reduced taxpayer cost without compromising core mandates.^[219] Allocation tensions persist between sustaining legacy observational networks—such as radars, buoys, and cooperative observer programs—and advancing research and development (R&D) for predictive modeling improvements.^[220] Budget proposals have intensified debates by targeting R&D reductions, including eliminations in weather laboratories, prompting warnings that underinvestment risks eroding forecast skill gains while maintenance demands consume a disproportionate share amid aging infrastructure.^[221] Proponents of rebalancing advocate prioritizing foundational data collection for immediate reliability, yet empirical reviews emphasize that integrated R&D yields compounding returns through refined algorithms and uncrewed observation alternatives.^[222]

Reform Debates and Controversies

Historical Privatization and Restructuring Proposals

In 1983, NOAA Administrator John V. Byrne proposed privatizing key elements of the National Weather Service, including auctioning off U.S. weather satellites to private industry and outsourcing operational weather forecasting, with the government repurchasing necessary data from commercial providers.^[223] The initiative, aligned with broader Reagan-era efforts to reduce federal involvement in commercializable activities, aimed to harness private sector efficiencies in satellite operations and data processing to lower costs and spur innovation.^[224] However, the plan drew opposition from agricultural groups, such as the National Farmers Union, which warned of higher data prices for essential users, and it was ultimately shelved without implementation due to concerns over equitable public access.^[225] Proponents of such restructuring argued that market competition would incentivize superior forecasting accuracy and responsiveness, contrasting the NWS's government monopoly with private firms' reliance on NWS raw data—effectively a public subsidy enabling value-added commercial products without reciprocal contributions to core data collection.^[226] This rationale drew parallels to the United Kingdom's Meteorological Office, which transitioned to a commercial trading fund model in 1990, allowing it to generate revenue from services while facing market pressures; post-reform, the agency invested in technologies yielding measurable forecast improvements, such as four-day predictions matching the one-day accuracy of 30 years earlier.^[227] Empirical verification studies post-commercialization affirmed sustained gains in public forecast quality under competitive dynamics, though direct causation remains debated amid concurrent technological advances.^[228] In 2005, Senator Rick Santorum introduced S. 786, the National Weather Service Duties Act, to codify restrictions preventing the NWS from issuing forecasts duplicative of private sector offerings, redirecting it toward exclusive data gathering, warnings for life-threatening events, and raw data provision.^[229] The legislation sought to eliminate perceived unfair competition, positing that private incentives would drive refined products tailored to users while curbing NWS expansion into commercial domains.^[230] Despite endorsements from some industry leaders favoring delineated roles, the bill stalled amid bipartisan pushback, including from smaller private meteorology firms reliant on free NWS data for viability, and apprehensions that curtailed services could undermine universal access during emergencies.^[226] These efforts underscored recurring tensions between efficiency gains from privatization and risks to the NWS's mandate for non-discriminatory public dissemination.

Recent Initiatives and Project 2025 Discussions (2024–2025)

In 2024, Project 2025, a policy blueprint prepared by the Heritage Foundation and aligned conservative groups, proposed restructuring the National Weather Service (NWS) to prioritize raw data collection and observation while shifting forecasting responsibilities to the private sector.^[231]^[232] The plan argued that private entities often deliver more accurate forecasts than government models, citing studies such as those evaluating commercial providers' performance in short-term predictions, and contended that commercialization would spur innovation by removing NWS from direct competition with firms like AccuWeather or The Weather Company.^[233]^[234] Proponents emphasized that open access to NWS data—already mandated under existing law—would mitigate risks to underserved areas, enabling private firms to extend services without taxpayer-funded duplication.^[235] Critics of the proposal, including climate policy experts and Democratic lawmakers, warned that full privatization could undermine equitable access in rural or low-profit regions where commercial incentives might lag, potentially increasing vulnerabilities during extreme events despite data availability.^[236]^[237] Fact-checks clarified that Project 2025 does not advocate eliminating the NWS or its core functions like the National Hurricane Center, but rather refocusing it on foundational data roles to leverage private sector efficiencies.^[231]^[233] Complementing these discussions, the Weather Act Reauthorization Act of 2025 (H.R. 3816), introduced in June 2025 and advanced by the House Science Committee in September, sought to expand NOAA's partnerships with commercial weather data providers.^[238]^[239] The legislation authorized increased procurement of private satellite and observational data, including radio occultation and geostationary imagery, to enhance forecasting models without fully privatizing NWS operations, allocating $160–170 million annually through 2030 for related research.^[240]^[241] Advocates highlighted its potential to integrate high-resolution commercial inputs, addressing gaps in public observations, though some equity concerns persisted regarding dependence on for-profit data streams.^[242] Early 2025 saw debates over proposed cuts under the Department of Government Efficiency (DOGE), an advisory body led by Elon Musk and Vivek Ramaswamy, which targeted federal redundancies and resulted in approximately 600–800 NOAA layoffs, including NWS meteorologists.^[236]^[243] These reductions, affecting about 40% of forecast offices' capacity, sparked empirical concerns over degraded severe weather predictions, with internal analyses linking staffing shortfalls to delayed warnings.^[244]^[245] By August 2025, NOAA secured approval to rehire up to 450 positions, restoring some operational resilience amid ongoing privatization talks.^[246]^[247] Private sector advocates cited these events as evidence for shifting to market-driven models, where firms demonstrated superior adaptability in resource-constrained scenarios.^[248]

Criticisms of Bureaucracy, Funding, and Political Influences

Critics have highlighted bureaucratic inefficiencies within the National Weather Service (NWS), part of the National Oceanic and Atmospheric Administration (NOAA), as impeding timely adoption of advanced technologies. Federal procurement regulations and multi-layered approval processes have delayed upgrades to critical systems, including weather radars and forecasting software, exacerbating vulnerabilities during severe events.^[249] ^[250] For example, outdated information technology infrastructure persists despite identified needs, with government-wide reports indicating slow modernization efforts that hinder operational agility.^[249] Funding constraints have compounded these issues, leading to operational gaps such as radar coverage deficiencies noted in 2024 assessments. NOAA's response to evaluations emphasized the need for sustained investment in the Radar Next program to address geographic and low-level detection shortfalls, yet budget limitations have stalled enhancements.^[251] In fiscal year 2025, proposed and enacted cuts reduced NOAA's overall budget by approximately 24 percent in initial plans, resulting in hundreds of staff layoffs at NWS offices and diminished research capacity for weather modeling.^[252] ^[253] These reductions, totaling less than $1.4 billion for NWS operations prior to further trims, have forced reliance on private sector supplements for data gaps during emergencies.^[219] ^[254] Political influences have drawn scrutiny for shaping NWS communications, with accusations that messaging sometimes prioritizes long-term climate attributions over immediate risk assessments. Conservative analysts, including contributors to policy blueprints like Project 2025, have argued that NOAA's emphasis on "climate alarmism" in research and warnings diverts resources from core forecasting duties, potentially eroding public trust in urgent alerts.^[255] ^[231] Conversely, Democratic lawmakers and former NWS directors have condemned budget cuts under Republican administrations as politically motivated reductions that compromise forecasting accuracy and public safety, citing instances like 2025 Texas floods where staffing shortfalls allegedly hindered responses.^[256] ^[257] These partisan divides underscore broader debates on whether bureaucratic streamlining or increased funding best addresses NWS vulnerabilities, with evidence suggesting overregulation and fiscal pressures mutually reinforce operational rigidities.^[258]

Leadership

Key Directors and Administrators

Francis W. Reichelderfer served as Chief of the U.S. Weather Bureau from June 1938 until December 1963, the longest tenure in its history, during which he professionalized forecasting by emphasizing empirical methods drawn from his naval aerology background and collaboration with international meteorologists.^[259] He prioritized data integration over organizational expansion, introducing radar for real-time precipitation detection in the 1940s, early computer-assisted numerical weather prediction in the 1950s, and foundational work on satellite meteorology by establishing the Weather Bureau's Meteorological Satellite Laboratory in 1958.^[260] These advancements enhanced causal realism in predictions, supporting military operations in World War II and civilian aviation safety without commensurate growth in administrative overhead.^[261] Robert H. Simpson, a pivotal administrator in hurricane research, directed the National Hurricane Center from 1967 to 1974 after the Weather Bureau's transition to the NWS in 1967, focusing on empirical standardization of tropical cyclone assessment.^[262] He co-developed the Saffir-Simpson Hurricane Wind Scale in 1971 with Herbert Saffir, categorizing storms from 1 to 5 based on sustained wind speeds (74 mph minimum for Category 1, exceeding 157 mph for Category 5) and correlating them to observed damage patterns from historical data.^[263] Simpson's earlier role as director of the National Hurricane Research Project from 1955 advanced field observations and aircraft reconnaissance, yielding verifiable insights into storm structure that prioritized scientific rigor over policy expansions.^[264] Ken Graham has directed the NWS since June 2022 as Assistant Administrator for Weather Services, appointed through NOAA's presidential nomination and Senate confirmation process, which shapes emphasis between core data missions and broader administrative mandates.^[64] Under his leadership, the agency pursued "Ken's 10" priorities, including upgraded numerical models for 0-2 day forecasts with 5 km resolution and enhanced observation networks adding over 1,000 automated sites since 2022, amid 2025 fiscal constraints and reform discussions.^[66] Graham's tenure has maintained empirical focus on high-impact events, such as issuing over 1,500 severe weather warnings in 2024 with lead times averaging 18 minutes, while navigating workforce adjustments to sustain operational integrity.

Influential Figures in NWS Development

Jule Charney pioneered numerical weather prediction (NWP) in the late 1940s and early 1950s by simplifying hydrodynamic equations into a filtered barotropic vorticity model suitable for early computers, addressing the computational limitations that had previously hindered Lewis Fry Richardson's 1922 manual forecasting attempts.^[25] In September 1950, Charney directed a team at the Institute for Advanced Study that produced the first viable 24-hour NWP forecasts using the ENIAC computer, validating mid-tropospheric predictability and establishing the causal framework for data assimilation and initialization techniques now central to NWS model suites.^[265] His emphasis on geophysical fluid dynamics over empirical correlations shifted forecasting from synoptic analysis to physics-based simulation, directly influencing the Joint Numerical Weather Prediction Unit formed in 1955 between the Weather Bureau (predecessor to NWS) and military services.^[266] Joanne Simpson advanced cloud physics and convective parameterization in the 1950s–1960s, developing the first explicit cumulus convection models that linked vertical motion in "hot towers" to hurricane intensification and large-scale tropical circulation. Her slide-rule and early computer simulations of cloud ensembles revealed buoyancy-driven release of conditional instability, providing mechanistic insights into radar-observable mesoscale structures like overshooting tops, which enhanced NWS interpretation of Doppler radar data for severe thunderstorm warnings.^[268] Simpson's parameterization schemes, tested in field programs like the 1960s Barbados Oceanographic and Meteorological Experiment, informed subgrid-scale representations in operational models, bridging microphysical processes to synoptic-scale predictability without relying on ad hoc adjustments.^[269] In recent decades, Stanley Benjamin spearheaded the development of the High-Resolution Rapid Refresh (HRRR) model at NOAA's Global Systems Laboratory, achieving operational status at the National Centers for Environmental Prediction in 2014 with 3-km grid spacing and hourly cycling incorporating radar reflectivities for explicit convection simulation.^[270] This convection-allowing architecture improved short-term (0–18 hour) forecasts of convective initiation and intensity by assimilating real-time observations via the Gridpoint Statistical Interpolation scheme, reducing errors in precipitation and severe weather nowcasting critical to NWS watch issuance.^[271] Benjamin's integration of ensemble Kalman filtering precursors and hybrid variational methods enhanced probabilistic guidance, demonstrating causal improvements in lead-time for hazards like tornadoes through physics-constrained data impact studies rather than empirical tuning alone.^[118]

References

[1]
About Our Office - National Weather Service
Our Mission · The mission of the National Weather Service is to provide weather, water and climate data, forecasts, warnings, and impact-based decision support ...
[2]
About the National Weather Service
The National Weather Service is the sole official voice of the US government for issuing warnings during life-threatening weather situations.
[3]
National Weather Service
Apr 10, 2023 · The National Weather Service we know today started on February 9, 1870, when President Ulysses S. Grant signed a joint resolution of Congress ...Missing: functions | Show results with:functions
[4]
[PDF] The United States Weather Service: The First 100 Years
The U.S. weather service started with the Signal Service in 1870, was given the name Weather Bureau in 1891, and the name National Weather Service in 1970 with.
[5]
History of the National Weather Service
The National Weather Service has its beginning in the early history of the United States. Weather always has been important to the citizenry of this country.
[6]
National Weather Service at 150: 7 tech inventions that improved ...
that's 15 decades of science and service ...Missing: functions | Show results with:functions
[7]
Here's what career meteorologists think of staffing issues - KUT News
Jul 10, 2025 · According to the three former career NWS meteorologists, staffing shortages at the National Weather Service are nothing new. ... “We've had hiring ...Missing: achievements controversies<|control11|><|separator|>
[8]
Trump Ignites Scientific Integrity Scandal at NOAA - AIP.ORG
Sep 11, 2019 · Multiple investigations are being opened into a NOAA statement criticizing a National Weather Service social media message that contradicted ...
[9]
State climatologist highlights concerns over NWS, NOAA cuts - WGLT
Mar 4, 2025 · Ford said the National Weather Service is already a model of efficiency, costing the average Illinois taxpayer only $4 per year. He said the ...
[10]
Evolving to Build a Weather-Ready Nation - National Weather Service
The National Weather Service is your first line of defense BEFORE extreme weather strikes -- operating 24x7 alongside emergency management officials in your ...<|separator|>
[11]
First official US weather forecast made on November 1, 1870
Nov 1, 2016 · Shipwrecks in such storms claimed 209 lives in 1869 alone. Prompted by newspaper clippings of shipwrecks Lapham sent to his congressional ...Missing: livestock | Show results with:livestock
[12]
The National Weather Service at 150: A Brief History - NOAA VLab
Feb 6, 2020 · ... law on February 9, 1870 by President Ulysses S. Grant, and the precursor to the Weather Bureau and National Weather Service was born. The ...
[13]
A Brief History of the National Weather Service | American Experience
... President Ulysses S. Grant ordered the army to systematically compile weather observations from stations across the nation. On November 1, 1870, weather ...
[14]
General Myer: Establishing a Legacy of Weather Service - NOAA
Sep 16, 2025 · The roots of NOAA's National Weather Service run deep in 19th century science and policy. The agency has moved from a national network of ...Missing: functions | Show results with:functions
[15]
140th anniversary of the first hurricane warning
Aug 20, 2013 · On Aug. 21, 1873 the weather service of the US Army Signal Corps issued its first warning for a hurricane. A long-tracking Cape Verde-type storm.
[16]
Office History - National Weather Service
In 1890, Congress voted to transfer the agency to the Department of Agriculture and renamed it the Weather Bureau. Although the parent agency was changed to ...Missing: transition | Show results with:transition
[17]
The Weather Bureau Begins - National Weather Service Heritage
Jun 30, 2021 · The effective date of the transfer was set at July 1, 1891 to allow the Agriculture Department to obtain separate and necessary appropriations ...Missing: transition | Show results with:transition
[18]
Records of the Weather Bureau - National Archives
The Weather Bureau's basic climatological records of surface, land, and air observations since 1872 and its principal records of marine observations since 1904Missing: growth | Show results with:growth
[19]
The Weather Bureau's "Flying Forecasts" - NOAA VLab
Nov 1, 2019 · During World War I, the Weather Bureau cooperated with the Army and Navy on the subject of aviation-specific forecasts.
[20]
A Brief History of Upper-air Observations - National Weather Service
In 1937 the Weather Bureau established a network of radiosonde stations that has continued to the present day. Click here to see maps of current radiosonde ...Missing: introduction Deal
[21]
Out of Thin Air: The History and Evolution of Upper-Air Observations
Jan 13, 2020 · In 1937, the Weather Bureau established a nationwide radiosonde network that is still operational today. As World War II proved the necessity ...Missing: introduction Deal
[22]
Tuning into Weather Forecasting | NIST
Jan 9, 2024 · Beginning in the 1930s the National Bureau of Standards (NBS) developed compact packages of radio equipment that could be sent aloft by balloon ...Missing: introduction Deal
[23]
Explore NWS History - National Weather Service Heritage - Virtual Lab
The history and legacy of the National Weather Service, from its beginnings as part of the U.S. Army Signal Service through today, is a story of science and ...Missing: functions | Show results with:functions
[24]
The National Weather Service and the Evolution of Meteorological ...
Dec 30, 2019 · At the end of the war, the military donated at least 25 radar systems to the Weather Bureau, marking the beginnings of the US weather radar ...Missing: 1930s | Show results with:1930s
[25]
The History of Numerical Weather Prediction - NOAA
Oct 31, 2023 · The group was headed by Jule Charney, who had done extensive work on developing a simplified, filtered system of equations for weather ...
[26]
[PDF] jule gregory charney - MIT PAOC
1954: Helped create the Joint. Numerical Weather Prediction. Unit, a collaboration between the U.S. Weather Bureau, Air. Force, and Navy. 1955: Helped establish ...
[27]
Jule Charney, Agnar Fjörtoff & John von Neumann Report the First ...
The paper reported the first weather forecast by electronic computer. It took twenty-four hours of processing time on the ENIAC Offsite Link to calculate a ...
[28]
Celebrating 65 Years of the World's First Weather Satellite | NESDIS
Apr 1, 2025 · On April 1, 1960, NASA launched the Television Infrared Observation Satellite (TIROS-1), the world's first successful weather satellite.
[29]
TIROS - NASA Science
TIROS-I was operational for only 78 days, but proved that satellites could be a useful tools for surveying global weather conditions from space. Participants: ...
[30]
GOES History GOES-R Series
In October 2015, NOAA celebrated the 40th anniversary of the launch of the first GOES satellite. In 2025, NOAA is celebrating 50 years of its heralded GOES ...
[31]
[PDF] NEXRAD/WSR-88D (ROC) History - Radar Operations Center - NOAA
Jun 30, 2025 · -. NEXRAD Training Unit established as part of WFSO (i.e., Weather Service. Forecast Office) Norman (July). -. IOT&E Part 2 conducted (March ...
[32]
On This Day: Hurricane Andrew Makes Landfall | News
Aug 24, 2017 · As Andrew approached the U.S. coast, massive evacuations were ordered in both Florida and Louisiana, where the storm made its second landfall.
[33]
[PDF] Hurricane Andrew: South Florida and Louisiana August 23-26, 1992
NOAA and the NWS are dedicated to a continuing improvement in warnings and forecasts, thereby allowing emergency management officials lead time to take ...
[34]
Introducing AWIPS - National Weather Service Heritage - Virtual Lab
Jan 27, 2020 · The initial installation of the system began in the fall of 1996, at 12 locations. With the modernized field network being implemented at the ...
[35]
Since Katrina, researchers studied the where and when of hurricanes
Aug 29, 2025 · With the formation of the hurricane modeling group in 2007, scientists decided to focus on using HWRF to forecast intensity changes.Missing: ensemble | Show results with:ensemble<|separator|>
[36]
11 Years After Katrina: Advancements in Weather Forecasting
Aug 29, 2016 · NOAA satellites are providing data that contribute to improved weather forecasts and models. The current three-day forecasts have become as accurate as two-day ...Missing: ensemble | Show results with:ensemble
[37]
Improve Forecasting Accuracy and Lead Times for Severe Weather
Under “Next Steps” below, NWS has proposed for the next reporting period a new APG which bases improvements on ensemble models as represented by the Global ...Missing: Katrina | Show results with:Katrina
[38]
Need precedes the deed of moving to the cloud - Nextgov/FCW
NOAA's use of cloud computing for the National Weather Service's Web site could be a model for other agencies.
[39]
Introducing Cloud-based Warn-on-Forecast - Inside NSSL - NOAA
May 16, 2022 · Azure DevOps was selected for its existing integration with Azure Active Directory, seamless integration with GitHub and many built-in project ...
[40]
Hazard Messaging Headlines - National Weather Service
NWS Advances Major Changes to Hazard Messaging Headlines This change will take effect no earlier than 2024 to allow the time needed for public outreach, ...Missing: 2023 2025
[41]
Soliciting Comments on the NWS Transition to Plain Language ...
The National Weather Service (NWS) will be implementing changes to its hazard messaging headlines no earlier than calendar year 2025 and is collecting public ...Missing: 2024 | Show results with:2024
[42]
New Heat and Health Initiative, developed in response to ... - CDC
Apr 22, 2024 · The methodology created by CDC and NWS identifies health and temperature data to deliver a seven-day outlook for hot weather. The tool uses a ...
[43]
[PDF] 2024 External HeatRisk - National Weather Service
Apr 22, 2024 · Methodology creates unique and localized daily thresholds for each station. How HeatRisk Works. Page 31. NATIONAL WEATHER SERVICE. // 31.
[44]
National Water Prediction Service - NOAA
Flood Inundation Mapping services are now available for 60% of the U.S. population. Additional NWPS resources are available here. NOAA Logo · NWS Logo ...River Forecast Centers · About National Water Center · National Water Model
[45]
Advanced Hydrologic Prediction Service (AHPS) has been replaced ...
On May 28, 2024 the NWS will replace AHPS with a new website, the National Water Prediction Service (NWPS). This new site can be viewed here: https:/water.noaa.
[46]
Evolving the National Weather Service to Build a Weather-Ready ...
A centerpiece of the MAR was the introduction of the Advanced Weather Interactive Processing System (AWIPS) and its NCEP counterpart, known as NAWIPS, which ...<|separator|>
[47]
2024: An active year of U.S. billion-dollar weather and climate ...
Jan 10, 2025 · In 2024, there were 27 individual weather and climate disasters with at least $1 billion in damages, trailing only the record-setting 28 events analyzed in ...
[48]
The National Weather Service Organic Act of 1890, currently ...
The authority is summarized as: The National Weather Service (NWS) provides weather, hydrologic, and climate forecasts and warnings for the United States, its ...Missing: 1963 | Show results with:1963
[49]
U.S.C. Title 15 - COMMERCE AND TRADE - GovInfo
15 U.S.C.. United States Code, 2020 Edition Title 15 - COMMERCE AND TRADE CHAPTER 9 - NATIONAL WEATHER SERVICE From the U.S. Government Publishing Office, www ...
[50]
15 U.S. Code Chapter 9 - NATIONAL WEATHER SERVICE
Duties of Secretary of Commerce · § 313a. Establishment of meteorological observation stations in the Arctic region · § 313b. Institute for Aviation Weather ...Missing: responsibilities | Show results with:responsibilities
[51]
[PDF] LEGAL AUTHORITIES FOR GCW Weather Service Organic Act 15 ...
National Climate Program Act. 15 U.S.C. § 2901 et seq. Authorizes a National Climate Program. Grants authority to enter into contracts, grants or cooperative.
[52]
Role of the National Weather Service and Selected Legislation in ...
Aug 8, 2016 · ... statutory authority for weather forecasting and for issuing storm warnings (15 U.S.C. §313). The NWS provides weather, water, and climate ...<|separator|>
[53]
U.S.C. Title 15 - COMMERCE AND TRADE - GovInfo
“(a) Report .—The Secretary shall prepare a report on the proposed modernization of the National Weather Service and transmit the report, not later than 6 ...
[54]
We are the National Weather Service
Building a Weather-Ready Nation and managing the nation's weather, water, and climate data, forecasts and warnings requires a diversified organization.Missing: statutory | Show results with:statutory
[55]
How Accurate Are Tornado Warnings? Here's What the Last Five ...
Apr 6, 2021 · A tornado warning accompanied an actual tornado roughly 60% of the time in that five-year period, with an average lead time between 8 and 10 minutes.
[56]
WSR-88D Radar, Tornado Warnings, and Tornado Casualties in
The date of WSR-88D radar installation in each National Weather Service Weather Forecast Office is used to divide the sample. ... lives saved per year.
[57]
None
### Summary of Economic Value of NWS Services
[58]
Industry and the Economy - Global Systems Laboratory - NOAA
Agriculture. Both short- and long-term forecasts are essential in agriculture production. HRRR predictions support better localized precipitation forecasts.Missing: objectives | Show results with:objectives
[59]
Evaluating the Economic Impacts of Improvements ... - AMS Journals
Aug 31, 2021 · ABSTRACT: Forecasts from numerical weather prediction (NWP) models play a critical role in many sectors of the U.S. economy.
[60]
Regional Headquarters - National Weather Service
National Weather Service Organization 1325 East West Highway Silver Spring, MD 20910 Comments? Questions? Please Contact Us.
[61]
About NOAA's National Weather Service
Explore various milestones in the history of the National Weather Service and our predecessor agencies, dating back to the 1800s, on our interactive timeline.
[62]
Organization | National Oceanic and Atmospheric Administration
Jul 22, 2025 · NOAA organization chart. See this chart of NOAA leadership and our organizational structure. Staff offices.NOAA organization chart · NOAA Communications · Office of General Counsel
[63]
Ken Graham - National Weather Service
Ken Graham is the Director of NOAA's National Weather Service and is the Assistant Administrator for Weather Services at NOAA.
[64]
NWS Leadership Biographies
Ken Graham is the Director of NWS, Michelle Mainelli is the Deputy Director, and Raymond Tanabe is the Chief Operating Officer. Ajay Mehta is Director of ...
[65]
Accelerating the NWS Transformation - NOAA
When Ken Graham began his tenure as the National Weather Service (NWS) Director in 2022, his conversations with employees led to "Ken's 10," a set of ten ...
[66]
Office of Chief Operating Officer - National Weather Service
The Office of the Chief Operating Officer (OCOO) manages the day-to-day mission execution units responsible for delivering NWS weather, water, climate and ...
[67]
National Weather Service Organization
Biographies for National Weather Service Senior Leadership can be found here. NWS Organizational Structure. ORGANIZATION RSS Feed.Regional Headquarters · Office of the NOAA Assistant... · Office of Planning and...
[68]
National & Regional Offices - NOAA
Sep 8, 2023 · The National Weather Service is comprised of a national headquarters and six regional offices. The National Headquarters is located in Silver Spring, Maryland.
[69]
Weather Forecast Office Information
The National Weather Service has 122 Weather Forecast Offices (WFOs) across the United States, Puerto Rico and Guam staffed 24/7 with meteorologists.
[70]
Weather | National Oceanic and Atmospheric Administration
Sep 18, 2025 · Go to NOAA's National Weather Service. 122 Weather Forecast Offices. With nearly 4,900 employees in 122 weather forecast offices, 13 river ...
[71]
River Forecast Centers - National Water Prediction Service - NOAA
River Forecast Centers · Alaska-Pacific RFC, Anchorage AK · Arkansas-Red Basin RFC, Tulsa OK · California-Nevada RFC, Sacramento CA · Colorado Basin RFC, Salt Lake ...
[72]
OHD/RFC: What is an RFC - National Weather Service
A River Forecast Center, or RFC, is one of 13 regional offices that forecasts whether rivers are going to flood or not. Information used to make these ...
[73]
Center Weather Service Unit Information
The Center Weather Service Units monitor and provide weather forecasts and advisories to the nation's 21 Air Route Traffic Control Centers (ARTCC).
[74]
Center Weather Service Units - NOAA
Apr 10, 2023 · The Center Weather Service Units monitor and provide weather forecasts and advisories to the nation's 21 Air Route Traffic Control Centers (ARTCC).
[75]
National Centers for Environmental Prediction
Aviation Weather Center · Climate Prediction Center · Environmental Modeling Center · NCEP Central Operations · National Hurricane Center.
[76]
National Centers for Environmental Prediction - NOAA
Oct 3, 2023 · The National Centers for Environmental Prediction (NCEP) is comprised of nine distinct Centers. These Centers are critical in national and global weather ...
[77]
SPC Convective Outlook - Storm Prediction Center - NOAA
No information is available for this page. · Learn why
[78]
Severe Weather 101: Tornado Forecasting
Meteorologists at the NOAA Storm Prediction Center (SPC) issue daily forecasts, or convective outlooks, for organized severe thunderstorms over the US.
[79]
National Hurricane Center - NOAA
There are no tropical cyclones in the Central Pacific at this time. Atlantic Marine Graphicast · Marine products from NHC's. Tropical Analysis and Forecast ...NHC, NOAATropical Weather OutlookActive Tropical CyclonesNorth Atlantic Marine ForecastsHurricane melissa
[80]
Climate Prediction Center: ENSO Diagnostic Discussion - NOAA
Oct 9, 2025 · A probabilistic strength forecast is available here. The next ENSO Diagnostics Discussion is scheduled for 13 November 2025.
[81]
Aviation Weather Center
Web site of the NWS Aviation Weather Center, delivering consistent, timely and accurate weather information for the world airspace system.Observations · Aviation Weather Testbed · Terminal Weather Dashboard · TAF Data
[82]
Aviation Weather Center Information
Additionally, there is a group of National Aviation Meteorologists (NAMs) located at the FAA Command Center. The NAMs are fully integrated with FAA staff.
[83]
WSA-ENLIL Solar Wind Prediction | NOAA / NWS Space Weather ...
WSA-Enlil is a large-scale, physics-based model of the inner heliosphere, used by the Space Weather Forecast Office to provide 1-4 day advance warning of solar ...
[84]
Space Weather Impacts
Oct 3, 2025 · Solar Energetic Particles (energetic protons) can penetrate satellite electronics and cause electrical failure. These energetic particles also ...
[85]
[PDF] NATIONAL FIRE WEATHER ANNUAL OPERATING PLAN 2025
Mar 12, 2025 · This document serves as the National Interagency Fire Weather Annual Operating Plan (AOP), detailing national-level services, products and ...
[86]
NOAA Announces an Experimental Tool That Predicts Hourly ...
Aug 29, 2025 · HWP provides an assessment of wildfire potential updated every hour based on model-predicted weather conditions. The frequent updates allow HWP ...<|separator|>
[87]
Marine Forecast and Warning Zone Changes for Spring 2025
In March of 2025, there will be changes in the marine zones for WFO San Diego, CA and WFO Tallahassee, FL. These changes will result in a more geographically ...
[88]
Automated Surface/Weather Observing Systems (ASOS/AWOS)
There are currently more than 900 ASOS sites in the United States. These automated systems collect observations on a continual basis, 24 hours a day. ASOS data ...
[89]
Observation Networks - National Weather Service
ASOS is the backbone of the U.S. surface weather observation system. There are 9 ASOS units in Kentucky and 12 in Indiana (over 900 nationwide). AWOS ...
[90]
Cooperative Observer Program - National Weather Service
Today, more than 11,000 Cooperative Weather Observers across the United States donate more than one million hours each year to collect daily hydrometeorological ...
[91]
Cooperative Observer Program (COOP) - National Weather Service
More than 8,700 volunteers take observations on farms, in urban and suburban areas, National Parks, seashores, and mountaintops. The data are truly ...
[92]
https://www.weather.gov/coop/overview
[93]
Urban Warming Challenges Verification of Frost Advisories and ...
These results suggest that urban warming presents forecast challenges to the issuance of frost advisories and freeze warnings, supporting the need for improved ...
[94]
Upper-air Observations Program - National Weather Service
Upper-air Program staff oversee the operation of 92 Radiosonde stations in North America and the Pacific Islands. While also supporting the operation of 10 ...
[95]
Radiosonde Network Information - National Weather Service
Upper-air Station Information, Network Maps - Maps showing station locations, Fact Sheet - Information on radiosondes, Publications
[96]
Radiosondes | National Oceanic and Atmospheric Administration
Sep 16, 2025 · NWS supports the operation of 10 other stations in the Caribbean. Through international agreements, data are exchanged between countries ...
[97]
Weather Balloon Instrument/Radiosonde Information
Around 76,000 radiosondes are flown every year within the NWS upper air network. This means that an opportunity to find one of these instruments does exist! NWS ...
[98]
Assimilation of Global Positioning System Radio Occultation ...
In the preliminary results presented in this study, the use of GPS RO observations slightly improves anomaly correlation scores for temperature (by ⬃0.01–0.03) ...
[99]
NOAA Hurricane Hunters | Office of Marine and Aviation Operations
The jet's mission covers thousands of square miles surrounding the hurricane, gathering vital high-altitude data with GPS dropwindsondes and tail Doppler radar ...
[100]
https://www.omao.noaa.gov/aircraft-operations/noaa-hurricane-hunters
[101]
Eyewall Wind Profiles in Hurricanes Determined By GPS ...
Even when aircraft reconnaissance data are available, these are typically obtained from the 700 mb (10,000 ft) level; from these flight-level observations, the ...Missing: upper | Show results with:upper
[102]
Upgrading the North American Upper-Air Observing Network
These two studies indicate that small changes in the model initial conditions can produce significant changes in the de- velopment and evolution of model ...
[103]
The role of model and initial condition error in numerical weather ...
The initial condition error is manipulated by varying the distribution and quality of the observing network and the magnitude of observation errors. The results ...Missing: air NWS
[104]
New tech fills forecast gap as weather balloon launches drop - WMTW
Apr 23, 2025 · The National Weather Service (NWS) usually launches weather balloons or upper-air soundings, twice a day from 92 locations across the U.S. ...
[105]
National Data Buoy Center - NOAA
The National Data Buoy Center's home page. The premier source of meteorological and oceanographic measurements for the marine environment.DART® Program Description · BuoyCAMs · NDBC - Station 42012 · Station List
[106]
Biden-Harris Administration invests $30M to improve tsunami ocean ...
May 17, 2024 · NOAA owns and operates an array of 39 DART buoys in the Pacific and Atlantic ocean basins, including the Gulf of Mexico and Caribbean basins.
[107]
Voluntary Observing Ship Program - NOAA
The United States VOS Program services about one quarter of the world's VOS fleet, providing ships' crews with weather observer training, handbooks and forms.The United States VOS Project ...VOS - The WMO Voluntary ...VOS Ship Resource PageTurboWin/AMVER SoftwareContact Us
[108]
Why Does NOAA Collaborate Internationally? - NESDIS
Nov 18, 2016 · NOAA works with the international community, sharing the Earth observation data required for weather and environmental prediction on a full, free, and open ...
[109]
WMO | EUMETSAT
Apr 24, 2023 · EUMETSAT's data policy is aligned with that of the WMO's Resolution 1 (2021), offering full and non-discriminatory access to as much as possible ...
[110]
[PDF] Predicting Arctic Weather and Climate and Related Impacts
Weather, water, ocean and wave, and sea ice forecasting gaps in the Arctic ... NOAA NWS Arctic Operational Forecasting Perspectives – Ming Ji (NWS/NCEP). 9 ...
[111]
Use of Numerical Guidance at the National Weather Service's ...
A review of verification statistics shows that the impact of use of operational prediction models from the Barotropic to the Primitive Equations has been most ...Missing: evolution | Show results with:evolution
[112]
[PDF] Models, Numerical Methods, and Data Assimilation
Charney made the first successful numerical weather forecast with barotropic potential vorticity equations (Charney et al. 1950). Specifically, between the ...
[113]
[PDF] Ensemble Methods for Meteorological Predictions
Mar 1, 2018 · In the early days, an EPS such as the Monte-Carlo approach proposed by Leith (1972) mainly addressed uncertainty in the IC, but this definition ...
[114]
NOAA upgrades flagship U.S. global weather model
Mar 22, 2021 · The GFS with the FV3 dynamical core brings together the superior physics of the global atmosphere with day-to-day reliability and speed of ...Missing: details | Show results with:details
[115]
Documentation - GFS - Virtual Lab - NOAA VLab
The current operational dynamical core of the GFS/GSM is based on a two time-level semi-implicit semi-Lagrangian discretization (Sela, 2010) with three ...
[116]
High-Resolution Rapid Refresh (HRRR)
The HRRR is a NOAA real-time 3-km resolution, hourly updated, cloud-resolving, convection-allowing atmospheric model, initialized by 3km grids with 3km radar ...HRRR · HRRR-Smoke · HRRR Sub-3km Regional Nests
[117]
The High-Resolution Rapid Refresh (HRRR): An Hourly Updating ...
NOAA's operational hourly updating, convection-allowing model, the High-Resolution Rapid Refresh (HRRR), is a key tool for short-range weather forecasting ...Introduction · Model initialization · High-impact weather...
[118]
[PDF] Evaluating the ability of the operational High Resolution ... - WES
Oct 6, 2025 · The HRRR is a regional, rapid- refresh, convective-allowing (3km horizontal grid) NWP model run operationally by the National Weather Service. ( ...
[119]
The Development of the NCEP Global Ensemble Forecast System ...
The new GEFS has cubed-sphere grids with a horizontal resolution of about 25 km and an increased ensemble size from 20 to 30. It extends the forecast length ...
[120]
[PDF] Uncertainty and Ensemble Forecast - National Weather Service
Dec 3, 2007 · Leith's Monte-Carlo approach is basically the traditional definition of ensemble forecasting although the content of this definition has been ...
[121]
NOAA upgrades weather forecasting supercomputers
Aug 14, 2023 · After the upgrade, the machines boast peak computing performance of 14.5 petaflops each, in addition to 31 petabytes of storage capacity.
[122]
GDIT awarded $100 million to support new NOAA high-performance ...
Sep 3, 2024 · Specifically, Rhea will mean the addition of eight petaflops of computing speed to that system's existing 35-petaflop capacity. A petaflop ...<|separator|>
[123]
NOAA upgrades supercomputers to enhance US weather forecasts
Aug 11, 2023 · ... capacity of 20 petaflops, the supercomputing capacity supporting NOAA's new operational prediction and research is now 49 petaflops. Ken ...
[124]
Next Generation Weather Radar (NEXRAD)
History. The National Weather Service (NWS) used World War II technology to develop and operate the Weather Surveillance Radars–1957 (WSR-57) network. This ...Missing: timeline | Show results with:timeline
[125]
National Weather Service completes major upgrades to weather ...
With the refurbishment of the radar pedestal in Missoula, Montana, earlier this month, all 122 National Weather Service NEXRAD systems have been fully upgraded.
[126]
Mission Overview GOES-R Series
The GOES-R Series (a collaboration of NOAA and NASA) is the Western Hemisphere's most advanced weather-monitoring satellite system.
[127]
Geostationary Operational Environmental Satellites (GOES)-R Series
It extends operational GOES satellite system through 2036. Visit the NOAA/OSPO GOES-R page for the current status of each spacecraft and its various subsystems.
[128]
Geostationary Operational Environmental Satellites - R Series ...
Search and Rescue Satellite Aided Tracking (SARSAT) The SARSAT system detects and locates mariners, aviators and other recreational users in distress. The GOES ...Mission Overview · GOES-16 Data and Imagery... · GOES History · GOES-17
[129]
Advanced Weather Interactive Processing System (AWIPS)
AWIPS is the NOAA/NWS cornerstone IT system used to ingest, analyze, forecast, & disseminate operational weather data.Missing: II | Show results with:II
[130]
AWIPS in the Cloud - National Weather Service
Data Integration: Cloud-based AWIPS systems can integrate with other cloud-based services and data sources, facilitating data sharing, analysis, and ...Missing: 2010s | Show results with:2010s<|separator|>
[131]
[PDF] NOAA Cloud Strategy
This document defines a strategy to guide NOAA's adoption and utilization of cloud services. The strategy assumes change and requires a new mindset.
[132]
Radar Outage Costs and the Value of Alternate Datasets in
$$29.1 million in annual radar outage costs may be attributable as value to alternative datasets for helping mitigate radar outage impacts.
[133]
[PDF] Monetized weather radar network benefits for tornado cost reduction
Aug 29, 2019 · Enhanced tornado warning performance, in turn, reduces casualty rates. In combination, then, it is clearly established that better and faster ...
[134]
The Challenges and Costs of Maintaining a Weather Radar Network
Jul 23, 2024 · Maintaining a weather radar network is a complex and costly endeavor, but the need for supplemental coverage for weather radar gaps in the US is vital.
[135]
Model Output Statistics - MDL - Virtual Lab - NOAA VLab
Model Output Statistics (MOS) is a type of statistical post-processing, a class of techniques used to improve numerical weather models' ability to forecast.
[136]
MOS - Model Output Statistics Page - NWS Raleigh, NC
Model Output Statistics (MOS) is a technique used to objectively interpret numerical model output and produce site-specific guidance.
[137]
Model Output Statistic - an overview | ScienceDirect Topics
Model Output Statistics (MOS) is defined as an objective weather forecasting technique that establishes a statistical relationship between measurement and ...<|separator|>
[138]
Model Data - National Weather Service
These links point to Model Output Statistics (MOS) data. These forecast data are generated by the numerical models based upon an extensive climatological ...
[139]
3-month seasonal outlook - Climate Prediction Center - NOAA
Official 90-day Outlooks are issued once each month near mid-month at 8:30am Eastern Time. Please consult the schedule of 30 & 90-day outlooks for exact release ...Missing: methodologies | Show results with:methodologies
[140]
Week 3-4 Outlook - Climate Prediction Center - NOAA
A blend of statistical and dynamical model 500-hPa height anomalies features a moderately strong trough over the western portion of the Gulf of Alaska, a ...Past Outlooks · HERE · Valid
[141]
Climate Prediction Center (CPC) Three Month Probabilistic ...
The Climate Prediction Center (CPC) issues a series of thirteen probabilistic three-month precipitation outlooks for the United States. CPC issues the ...
[142]
Score Definitions - MDL - Virtual Lab - NOAA VLab
Brier Score. brier score definition: the summation of ( each forecast minus observation )squared, divided. Heidke Skill Score (HSS). Heidke Skill Score ...
[143]
Verification of Public Weather Forecasts Available Via the Media
The Brier score (BS) is the mean-squared error of probability forecasts, fi , where xi = 0 if it doesn't rain and xi = 1 if it does. A perfect forecast has a ...
[144]
[DOC] Evaluation of Potential Forecast Accuracy Performance Measures
The overall Brier score of 0.048 can be interpreted as saying the forecasts are 95% accurate.
[145]
False Alarm Reduction Research - National Weather Service
Reduced Tornado Warning False Alarm Rate by 31% Since April 2011. The primary mission of the National Weather Service is to save lives and property through the ...
[146]
Watch/Warning/Advisory Definitions - National Weather Service
2) Hail 1 inch in diameter or larger. Tornado Watch. A Tornado Watch is issued when severe thunderstorms and tornadoes are possible in and near the watch area.
[147]
New Damage Threat Categories for Severe Thunderstorm Warnings
As of August 3, the National Weather Service will better convey the severity and potential impacts from thunderstorm winds and hail by adding a “damage threat” ...Missing: percentage | Show results with:percentage
[148]
The Enhanced Fujita Scale (EF Scale) - National Weather Service
Enhanced Fujita Scale Damage Indicators ; 1, Small barns, farm outbuildings, SBO ; 2, One- or two-family residences, FR12 ; 3, Single-wide mobile home (MHSW), MHSW.
[149]
Understand Tornado Alerts - National Weather Service
Be ready to act quickly if a warning is issued or you suspect a tornado is approaching. Acting early helps to save lives! Watches are issued by the Storm ...Missing: public objectives lead times
[150]
Weather Service uses updated warning language during ...
Apr 19, 2024 · "Occasionally, severe thunderstorms can and will produce tornadoes with little or no advance warning," the advisory said. Fast forward almost 40 ...
[151]
[PDF] National Weather Service Instruction 10-922
Aug 3, 2021 · Flash flood warnings will be created with the Hazard Services application. ... RFC guidance normally used as an input to this product and/or flood ...
[152]
Flash Flood Guidance - National Weather Service
Flash Flood Guidance is an estimate of the amount of rainfall required over a given area during a given duration to cause small streams to flood.Missing: inputs | Show results with:inputs
[153]
National Weather Service
Flash Flood Guidance (FFG) - The RFC model-estimated basin-averaged rainfall over either 1, 3, or 6 hours duration that would cause small streams to reach ...
[154]
Heat Forecast Tools - National Weather Service
How does WBGT differ from Heat Index? How can Wet Bulb Globe Temperature be used? Who can benefit from the use of Wet Bulb Globe Temperature? HeatRisk.
[155]
NWS La Crosse Heat Preparedness
Criteria for an Excessive Heat Warning is a heat index of 105° F or greater and a minimum heat index of 75°F or greater for at least 48 hours. Excessive Heat ...
[156]
Watch / Warning / Advisory Criteria - National Weather Service
Watches: 50% confidence of meeting Warning criteria (generally within 36-48+ hours). · Advisories and Warnings: 80% confidence in the event occurrence (generally ...Missing: percentage | Show results with:percentage
[157]
Cold Criteria & Frost/Freeze Changes in Effect October 1, 2024
Oct 1, 2024 · Starting October 1, 2024, these products will be issued based on the temperature or the wind chill, and there will be no wind threshold. In ...
[158]
[PDF] a comparison of severe thunderstorm warning verification
Verification of severe weather warnings is necessary in providing the probability of detection (POD) and false alarms rates. (FAR) of the issuance of weather.
[159]
[PDF] 1 Recent Improvements to the Verification of Convective Warnings at ...
Probability of detection (POD), critical success index (CSI), and false alarm ratio (FAR) for the months before and after the implementation date (black ...
[160]
[PDF] A Pilots Guide to Aviation Weather Services
Oct 1, 2020 · TAFs are valid for 24 or 30 hour time periods and are issued 4 times a day at. 6 hour intervals. 7. Page 8. A Pilot's Guide to Aviation Weather ...
[161]
ZSE SIGMETs - National Weather Service
SIGMETs are Inflight Weather Advisories for Significant Meteorological hazards. A SIGMET is "widespread" in that it covers an area of at least 3,000 square ...
[162]
Aviation - National Weather Service
NWS Aviation Weather Services · Directly forecasting aviation weather and hazards. · Providing real-time weather updates and forecasts to air traffic controllers.Aviation Weather Center (AWC) · Center Weather Service Units
[163]
Fire Weather Products Criteria - National Weather Service
Fire Weather Watches will be issued to indicate the potential for dangerous fire weather conditions 24 to 96 hours in advance of the expected onset of criteria.
[164]
Explaination of NFDRS Forecasts - National Weather Service
NFDRS forecasts include weather (0-9), temperature, humidity, lightning, wind, and precipitation duration. The forecast is valid for 1300 local the next day.
[165]
Fire Weather - National Weather Service
Severe thunderstorms and areas of heavy to excessive rainfall are forecast ... Updated: Sat Oct 25, 2025 5:00 PM PDT. Display: All Hazards & Warnings, Severe ...Wildfire Weather Safety · Fire Weather Forecasts · National AgreementsMissing: tools | Show results with:tools
[166]
U.S. Offshore Marine Text Forecasts by Zone
Maps of all NWS Marine Forecast and Warning Zones. Offshore waters forecasts are subdivided by zone, each identified by text description and a Universal ...Mid Atlantic · Gulf of America · New England · SW North Atlantic Including the...
[167]
Marine Weather Broadcasts from the USCG
These forecasts are produced by local National Weather Service Forecast Offices. The USCG VHF network provides near continuous coverage of coastal U.S., Great ...
[168]
NWS Enterprise Resources
[1] “Weather” is used in this context to mean all service areas which the NWS supports, including space weather, tsunamis, aviation, fire, marine, water ...Aviation · General Weather · Winter weather · Custom Weather Forecasts
[169]
National Weather Service Dissemination
NOAA Weather Wire Service (NWWS) - fastest method of receiving text weather information, alerts and warnings over either the Internet or a 1.8m C-Band ...
[170]
NWWS Description - National Weather Service
For a full distribution of NWS products use NWS FTP anonymous (over the Internet) or SBN/NOAAPORT Channels 101-108 (4m dish required). NWWS Description. NWWS is ...
[171]
API Web Service - National Weather Service
The National Weather Service (NWS) API allows developers access to critical forecasts, alerts, and observations, along with other weather data.
[172]
Integrated Public Alert & Warning System | FEMA.gov
IPAWS is FEMA's national system for local alerting that provides authenticated emergency and life-saving information to the public through WEA, EAS and NOAA ...
[173]
Wireless Emergency Alerts | Federal Communications Commission
FEMA, the FCC, and the National Oceanic and Atmospheric Administration's National Weather Service work collaboratively to maintain Wireless Emergency Alerts ...
[174]
api.weather.gov: General FAQs - GitHub Pages
It offers public access to a wide range of essential weather data, in a way that modern web developers expect: a REST-style, JSON-based web service.Missing: private | Show results with:private
[175]
Education - National Weather Service
A strong weather awareness within the community provides the building blocks for greater resilience against nature's worst. In addition, NWS Education assists ...Missing: training | Show results with:training
[176]
NWS SKYWARN Storm Spotter Program
SKYWARN® is a volunteer program with between 350,000 and 400,000 trained severe weather spotters. ... The collection of Skywarn information is authorized under ...Find a class in your area · Weather Forecast Office contact
[177]
SKYWARN Spotters - National Weather Service
... SKYWARN® with partner organizations. SKYWARN® is a citizen volunteer program with between 350,000 and 400,000 trained severe weather spotters. SKYWARN ...
[178]
StormReady - National Weather Service
The StormReady program helps arm America's communities with the communication and safety skills needed to save lives and property--before, during and after ...How to Become StormReady · StormReady Communities
[179]
Why Become StormReady® - National Weather Service
National Weather Service United States Department of Commerce. HOME. FORECAST ... lives saved in the impacted community.” These proactive actions include ...
[180]
NWS StormReady® and TsunamiReady® Sites
As of June 20, 2024, there were 3,474 StormReady and/or TsunamiReady ® Sites in 50 states, Puerto Rico and the U.S. Pacific Islands: 3,371 StormReady Sites.
[181]
NOAA - Number of StormReady Communities (cumulative)
... program is to make every county or county-equivalent in the United States StormReady. The 2010 U.S. Census identifies 3,234 county or county-equivalents in ...Missing: certified rates
[182]
[PDF] national weather service instruction 10-1802
Oct 25, 2023 · In addition, both the StormReady and TsunamiReady programs recognize communities that conduct community preparedness outreach and education ...
[183]
[PDF] NWS Central Region Service Assessment - Joplin, Missouri, Tornado
May 22, 2011 · One local media outlet in Joplin reported success using text messaging and social media (e.g.,. Facebook) as a method of disseminating ...
[184]
NWS changed warnings system after Joplin tornado - KSHB 41
May 20, 2021 · The National Weather Service now uses “impact based warnings” which basically place tornado and severe thunderstorm warnings in particular ...
[185]
[PDF] IMPACT BASED WARNINGS - National Weather Service
Following the historic Joplin tornado, the National Weather Service (NWS) conducted a service assessment for the purpose of evaluating NWS warnings and societal ...<|separator|>
[186]
[PDF] Cry Wolf Effect? Evaluating the Impact of False Alarms on Public ...
Through four surveys (N 5 4162), this study examines how residents in the southeastern United States understand, process, and respond to tornado false alarms.
[187]
Public alert and warning system literature review in the USA
The authors did not find empirical evidence suggesting that tornado false alarms create a complacent public. ... How individuals process NWS weather warning ...
[188]
The Critical Success Index as an Indicator of Warning Skill in
The Critical Success Index (CSI) is used by the National Weather Service to indicate the value of warnings, but it is not an unbiased indicator of forecast ...
[189]
Maturity of Operational Numerical Weather Prediction: Medium Range
In this paper we review some measures of opera- tional forecast skill that quantify improvements in. NWP at the National Centers for Environmental Pre- diction ...
[190]
Verification of Surface Temperature Forecasts from the National ...
Experimental gridded forecasts of surface temperature issued by National Weather Service ... Anomaly correlation coefficients between each 48-h NDFD temperature ...
[191]
[PDF] nws verification of precipitation type and snow amount forecasts ...
critical success index (CSI) and the Heidke skill score (skill). For national and regional data. CSI scores were much higher for frozen precipitation than ...
[192]
A Summary of U.S. Watershed Precipitation Forecast Skill and the ...
This study demonstrates that western U.S. water- sheds in California, Oregon, and Washington exhibit on average the highest QPF skill based on the critical ...
[193]
[PDF] HURRICANE IAN
Apr 3, 2023 · Hurricane Ian 64. Figure 24. Track forecast error (n mi) of the official forecasts and selected models for Hurricane Ian, 23‒30 September 2022.
[194]
[PDF] NATIONAL HURRICANE CENTER FORECAST VERIFICATION ...
May 8, 2023 · Records for track accuracy were set at 24, 36, 48, 60, 96, and 120 h in. 2022. Track forecast errors have decreased significantly over the long ...
[195]
The Effect of Increased Horizontal Resolution on the NCEP Global ...
ABSTRACT. The primary goal of this paper is to explore why the use of increased horizontal resolution enhances the performance of the National Centers for ...
[196]
On the Dependence of the Critical Success Index (CSI) on Prevalence
Mar 5, 2024 · The critical success index (CSI) is an established metric used in meteorology to verify the accuracy of weather forecasts.Missing: NWS | Show results with:NWS
[197]
[PDF] Global and Regional Weather Forecast Accuracy Overview 2021 ...
Jun 9, 2025 · Canada, the National Weather Service, and the NWS Digital Forecast each only had 62 accuracy ... AccuWeather, OpenWeather, The Weather Channel, ...
[198]
AccuWeather Proven Most Accurate in 38-Year Forecast Study ...
The results are now in for June of 2025 in the ongoing 38-year study comparing the accuracy of the AccuWeather and National Weather Service (NWS) forecasts and ...
[199]
How Does the National Weather Service Predictions Compare to the ...
Aug 15, 2024 · Who provides the most skillful forecast? Online providers such as the WeatherChannel (weather.com) or the National Weather Service?
[200]
NOAA's vast public weather data powers the local forecasts on your ...
Feb 11, 2025 · A lot of businesses rely on accuracy from NOAA's weather data and forecasts: aviation, energy companies, insurance, even modern tractors' ...
[201]
Why Private Forecasting Companies Can't Replace the National ...
Feb 11, 2025 · NOAA and the NWS provide public weather data that private companies cannot recreate.
[202]
The Plan to Privatize Weather Forecasts
Jul 15, 2024 · Project 2025 proposes replacing appointed roles at NOAA with Trump loyalists and privatizing NOAA's weather data and forecasts.Missing: equity | Show results with:equity<|control11|><|separator|>
[203]
United States' NOAA: Opening Up Global Weather Data in ...
NOAA has launched the Big Data Project (BDP), which provides an opportunity to combine NOAA's tremendous volume of high-quality environmental data and advanced ...
[204]
Average warning time for 2013 Moore tornado was about a half hour
May 20, 2014 · Even though the current average lead-time for tornado warnings is 13 minutes, the 2013 Moore tornado warning was near a half hour.
[205]
Oklahoma Tornado Shows Progress in Weather Warnings
May 23, 2013 · Moore residents, for example, had about 35 minutes of lead-time before the twister ripped their town apart. (The warning was issued 5 minutes ...
[206]
[PDF] Oklahoma/Southern Kansas Tornado Outbreak of May 3, 1999
May 3, 1999 · The third was fixed with a patch from. CommPower (a work-a-round was available on the NWS CRS Home. Page 2 days after the outbreak). The ...
[207]
The Great Plains Tornado Outbreak of May 3-4, 1999
A total of 40 people in Oklahoma were killed by the tornadoes on May 3-4, 1999 and another 675 persons were injured. Many homes and businesses were damaged or ...<|separator|>
[208]
[PDF] Atmospheric Effects and Potential Climatic Impact
The 18 May 1980 eruption of Mount St. Helens was observed on the. National Weather Service (NWS) radar system at Portland, Oregon. Additional radar coverage of ...
[209]
[PDF] May 20, 2013, Moore Tornado: Warnings and Products
May 20, 2013 · NORTHERN CLEVELAND COUNTY IN CENTRAL OKLAHOMA... * UNTIL 315 PM CDT. * AT 238 PM CDT...NATIONAL WEATHER SERVICE. METEOROLOGISTS DETECTED A ...
[210]
(PDF) Tornado Warnings, Lead Times, and Tornado Casualties
Aug 6, 2025 · It is found that warnings have had a significant and consistent effect on tornado injuries, with a reduction of over 40% at some lead time ...
[211]
False Alarms, Tornado Warnings, and Tornado Casualties
Oct 26, 2009 · The reduction in the national tornado false-alarm ratio over the period reduced fatalities by 4%–11% and injuries by 4%–13%. The casualty ...
[212]
The Not-So-Marginal Value of Weather Warning Systems
Identifying the number of lives saved by investments in weather warn- ... warning system of the National Weather Service. This research also serves as ...
[213]
[PDF] Direct Societal Benefits of Probabilistic Tornado Warnings
Lives Saved versus Time Lost: Direct Societal Benefits of Probabilistic ... National Weather Service tornado warnings. Wea. Forecast- ing, 33, 1501–1511 ...
[214]
[PDF] NOAA FY 2025 Congressional Budget Justification
There is increasing demand for NOAA to deliver continually improved products and services and to improve predictions of extreme weather events and climate- ...
[215]
[PDF] National Weather Service Enterprise Analysis Report
Jun 8, 2017 · The NWS provides the foundation to enable businesses to derive economic value from weather knowledge (estimated at roughly $13B across sectors ...Missing: objectives aviation
[216]
Forecasts increase productivity and mitigate extreme weather impacts
Assuming the majority of the underlying data comes from the federal government ($3.4B), the benefit increases to $9.3 for every $1 spent. Assuming all forecasts ...Missing: audit | Show results with:audit
[217]
Administrative Management Division - National Weather Service
Ninety percent of the regions costs are for labor. Getting the right costs charged to the right account is critical to managing the annual allotment.
[218]
How Trump's National Weather Service Cuts Could Cost Lives
May 13, 2025 · Now meteorology experts are urgently warning that the Trump administration's staff firings and funding cuts at the National Weather Service (and ...Missing: outages | Show results with:outages
[219]
[PDF] Budget Estimates - NOAA
Jun 30, 2025 · ... cost savings through the utilization of uncrewed systems within NOAA. ... National Weather Service (NWS). NOAA is modernizing the NWS by ...
[220]
Potential NOAA weather research cuts could have consequences
Jul 18, 2025 · The proposed budget released earlier this month “eliminates all funding for climate, weather, and ocean laboratories and cooperative institutes.
[221]
[PDF] A Report on Priorities for Weather Research (PWR)
The report recommends accelerated and increased investments in priority areas that build upon, and are balanced across, the entire weather information value ...
[222]
U.S. Considers Selling Parts of Weather Service To Private Side
Mar 7, 1983 · Byrne said that the White House has not made a decision on selling the satellites or parts of the weather service. But he said the proposed ...
[223]
ADMINISTRATION PROPOSES SELLING U.S. WEATHER ...
Mar 9, 1983 · The plan calls for industry to operate the satellites and three ground control stations but sell the data back to the Government for further ...
[224]
IDEAS & TRENDS; Cooking Up a Satellite Sale - The New York Times
Byrne said. Commercial groups, such as the National Farmers Union, said they suspect the cost of their weather information will eventually increase. (The ...
[225]
Santorum's weather crusade - POLITICO
Jan 5, 2012 · Even some private weather firms came out against the bill, saying the lack of free weather service data would cripple small companies trying to ...Missing: sales | Show results with:sales
[226]
How accurate are our public forecasts? - Met Office
Thanks to this commitment to accuracy, our four-day forecast is now as accurate as our one-day forecast was 30 years ago.Missing: commercialization | Show results with:commercialization
[227]
The quality and accuracy of a sample of public and commercial ...
Aug 7, 2025 · It is important that the quality of weather forecasts is closely monitored before and after commercialisation to ensure that the accuracy of ...Missing: commercialization impact
[228]
S.786 - National Weather Service Duties Act of 2005 109th ...
Apr 14, 2005 · A bill to clarify the duties and responsibilities of the National Oceanic and Atmospheric Administration and the National Weather Service, and for other ...Missing: sales | Show results with:sales
[229]
Storm Brewing Over Weather Service Access - ABC News
May 19, 2005 · In April, Santorum introduced the National Weather Services Duties Act of 2005, which states that with the exception of the "preparation and ...
[230]
Fact-checking what Project 2025 says about the National Weather ...
Sep 29, 2024 · Project 2025 would not outright end the National Weather Service. It says the agency “should focus on its data-gathering services,” and “should fully ...Missing: mandate | Show results with:mandate
[231]
Project 2025 calls for the 'break up' of NOAA, commercialized ...
Sep 30, 2024 · The plan, spearheaded by the Heritage Foundation, says that the weather service should “fully commercialize its forecasting operations” and ...
[232]
Posts Misrepresent Plan for National Hurricane Center in Project 2025
Oct 2, 2024 · A Heritage Foundation spokesperson said Project 2025 “does not call for eliminating the NHC,” though climate experts warned that the project's ...
[233]
Project 2025 and what it may mean for the National Weather Service ...
Jul 7, 2024 · NWS: Project 2025 states that according to a study, private companies provide more accurate forecasts than the NWS (pg 675). It states ...
[234]
Project 2025 — National Oceanic and Atmospheric Administration
The Environmental Historians Action Collaborative, an EDGI working group, annotated select chapters and sections of Project 2025 related to the environment.
[235]
The Lasting Threat of Trump's Cuts to NOAA and NWS on American ...
Jul 10, 2025 · The National Weather Service (NWS), in particular, has lost close to 600 staff at a time when 40 percent of national weather forecast offices ...
[236]
Project 2025 plan calls for demolition of NOAA and National ...
Jul 28, 2024 · Matthew Sanders, a lecturer at Stanford Law School and the acting deputy director of the Environmental Law Clinic.Missing: proposals | Show results with:proposals
[237]
H.R.3816 - Weather Act Reauthorization Act of 2025 - Congress.gov
Summary of H.R.3816 - 119th Congress (2025-2026): Weather Act Reauthorization Act of 2025. ... Commercial, Consular, Dispute Settlement and Arbitration, Drugs/ ...
[238]
H.R.5089, the Weather Act Reauthorization Act of 2025 - Bills
Sep 2, 2025 · Improves the National Oceanic and Atmospheric Administration's weather research, supports advancements in weather forecasting and prediction, ...
[239]
Lucas Reintroduces Weather Act Reauthorization
Jun 9, 2025 · Increases NOAA's access to critical forecasting data by expanding its authority to contract with the private sector to acquire commercial ...
[240]
House Science Committee Advances Weather Research Bill
Sep 11, 2025 · The bill recommends between $160 million and $170 million each year through 2030 for NOAA's research office to carry out specified weather ...
[241]
Weather Act Addresses Commercial Satellite Data and Hosted ...
The act requires NOAA to publish standards and specifications for space-based commercial weather data, including radio occultation data and geostationary ...
[242]
After deep DOGE cuts, National Weather Service gets OK to fill up to ...
Aug 6, 2025 · The National Oceanic and Atmospheric Administration will hire as many as 450 people to shore up the National Weather Service.
[243]
How Could the Weather Service Change Under Trump?
Feb 10, 2025 · The Weather Service provides its forecasts and warnings to the public free of charge. NOAA's observational data, from the agency's vast ...Missing: mandate | Show results with:mandate
[244]
Cuts to NOAA increase the risk of deadly weather tragedies
Jul 7, 2025 · ... National Weather Service, or NWS, contributed to the disaster. It's true that the weather service office at New Braunfels responsible for ...
[245]
National Weather Service Is Hiring Hundreds of New Staff
Aug 7, 2025 · The National Weather Service plans to hire hundreds of new employees, months after it lost more than 500 people to the Trump ...
[246]
Weather Service is now hiring back hundreds of positions that ... - CNN
Aug 5, 2025 · The National Weather Service has received permission to hire 450 meteorologists, hydrologists and radar technicians just months after being ...
[247]
Trump's pick to lead NOAA pledges to restaff weather service
Jul 9, 2025 · Asked whether he supports President Trump's proposal to cut NOAA's budget by 27% in fiscal 2026, Jacobs confirmed that he did and suggested ...Missing: percentage | Show results with:percentage
[248]
GAO: Agencies Slow to Replace Outdated Tech - FEDmanager
Jul 29, 2025 · The federal government needs to act more quickly in modernizing its information technology (IT) systems. That's according to a new report ...
[249]
The Weather Service Had a Plan to Reinvent Itself. Did DOGE Stop It?
May 15, 2025 · May 15, 2025. Ken Graham had a plan. When he became the director of the National Weather Service during the Biden administration, Mr. Graham ...
[250]
[PDF] NOAA Response to Report on Radar Gaps
Mar 19, 2024 · • SAB advocacy for Radar Next program funding at required levels to improve/enhance weather radar capabilities, geographic coverage, low ...Missing: shortfalls | Show results with:shortfalls
[251]
How NOAA funding cuts could make it harder to predict and ... - PBS
May 23, 2025 · The Trump federal spending overview, known as the skinny budget, released by the White House on May 2, calls for a 24 percent cut to NOAA's budget.Missing: outages | Show results with:outages
[252]
Cuts to National Weather Service Leave Forecasters Reeling
Mar 1, 2025 · Some critics of the cuts said they would lead to the loss of employees most likely to help the Weather Service navigate that future. Others ...Missing: bureaucracy | Show results with:bureaucracy
[253]
AI, drones, private radar fill gaps from National Weather Service cuts
May 30, 2025 · Private tech companies are stepping in to support local officials on the front lines of weather emergencies as federal offices struggle to stay staffed.Missing: reductions | Show results with:reductions
[254]
Trump will dismantle key US weather and science agency, climate ...
Apr 26, 2024 · Plan to break up Noaa claims its research is 'climate alarmism' and calls for commercializing forecasts, weakening forecasts.Missing: bias | Show results with:bias
[255]
'People will needlessly die': House Democrats warn about cuts to ...
Jul 9, 2025 · House Democrats on Wednesday raised alarms about President Donald Trump's proposed staff and budget cuts to weather monitoring and forecasting following deadly ...
[256]
Democrats call for probe into cuts at National Weather Service after ...
Jul 7, 2025 · Sen. Chuck Schumer is pressing the NWS's watchdog to probe whether Trump's cuts worsened the recent catastrophe.Missing: budget | Show results with:budget
[257]
How politics is weakening America's weather service | Brookings
Aug 21, 2025 · The story of the National Oceanic and Atmospheric Administration's (NOAA) in the first six months under the second Trump administration is a ...
[258]
Francis Reichelderfer: Sailor, Aviator, Meteorologist, and Director of ...
Oct 13, 2019 · Reichelderfer, head of the U.S. Weather Bureau from 1938 to 1963, laying the cornerstone of a new weather service building in 1940. A Naval ...
[259]
Reichelderfer, Francis Wilton | Encyclopedia.com
Reichelderfer led the U.S. Weather Bureau between 1938 and 1963. During this period he oversaw the introduction of radar, computer modeling, and satellites ...
[260]
15. Francis W. Reichelderfer | Biographical Memoirs: Volume 60
In 1922 Reichelderfer was appointed head of Navy Aerology, where he worked in a corner of the Map and Forecast Room of the U.S. Weather Bureau and was regarded ...
[261]
101st Birthday of Bob Simpson
Nov 19, 2013 · He wrote the plan establishing the National Hurricane Research Project in 1955 and became its first director. He was later the Weather Bureau's ...
[262]
The Saffir/Simpson Hurricane Scale - NovaLynx Corporation
Robert Simpson. He and his wife, Dr. Joanne Simpson, are both fellows of the American Meteorological Society. He is a former director of the National ...
[263]
Bob Simpson passes away at 102
Dec 19, 2014 · It is with a heavy heart that we note the death of HRD's founding director, Dr. Robert H. Simpson at the age of 102.
[264]
The Jule G. Charney Medal - American Meteorological Society
Jule Gregory Charney played a pivotal role in the development of modern meteorology. ... numerical weather prediction using early computers. Charney also ...
[265]
Jule Charney's Influence on Meteorology' - AMS Journals
It was this aspect of. Jule's thesis work that led him to early success in developing practical numerical weather prediction models. This simpli- fication ...
[266]
Joanne Simpson - NASA Earth Observatory
Apr 28, 2004 · Early in her career, Simpson developed the first cloud model, discovered what makes hurricanes run, and revealed what drives the atmospheric ...
[267]
The Research of Dr. Joanne Simpson: Fifty Years Investigating ...
Joanne Simpson's nine specific research contributions to the field of meteorology during her 50-year career—1) the hot tower hypothesis, 2) hurricanes, 3) ...Missing: physics radar
[268]
The Joanne Simpson Tropical Meteorology Research Award
Simpson also developed mathematical cloud models, at first using a slide rule, and then with early computers. In 1966, she became the director of Project ...Missing: radar | Show results with:radar
[269]
Distinguished career of Dr. Stan Benjamin| NOAA OAR GSL
Benjamin and his team delivered a 3-km hourly-updating High-Resolution Rapid Refresh (HRRR) model to the NCEP. The HRRR transformed weather prediction even in ...
[270]
Stanley Benjamin | CIRES
Development of Rapid Refresh (RAP) and High-Resolution Rapid Refresh (HRRR), two hourly updated models developed in the Global Systems Laboratory which are now ...