New NPP Satellite to Improve Land, Ocean, Ozone Observations

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Map showing the location of Peddavagu basin, a tributary of Krishna River basin

The NPP spacecraft is installed inside the Delta II rocket's protective payload fairing. Image Source: NASA/VAFBBy Ellen Gray

Goddard Space Flight Center

A new type of Earth-observing satellite has been launched into orbit. The National Polar-orbiting Operational Environmental Satellite System (NPOESS) Preparatory Project, or NPP, will fly at an altitude of 824 km in a polar orbit similar to that of its predecessors, the Earth Observing System satellites ‰ÛÒ Terra, Aqua and Aura. Built on the past decade’s work, NPP is a scientific powerhouse armed with five instruments that will improve observations of the land and ocean, the ozone hole, Earth’s energy balance and daily weather.

Begun in a partnership between NASA, the National Oceanic and Atmospheric Administration (NOAA) and the Air Force, NPP was reorganized from the National Polar-orbiting Operational Environmental Satellite System into the Joint Polar Satellite System (JPSS), which NASA is developing for NOAA.

Scientists who have been eagerly awaiting NPP’s launch and the promise of new data also are excited for another reason: The potential for unbroken data records. An unbroken data record is essential for finding small changes in a big system ‰ÛÒ Earth’s climate. NPP will bridge the gap between the record begun with Terra’s launch in 1999 and the next generation of Earth-observing satellites of JPSS in the coming decade.

“People often confuse weather and climate,” says NPP Project Scientist Jim Gleason. “Weather is what is going to happen tomorrow or this weekend. Climate is what happens over years and decades.”

To get a handle on how climate changes over those years and decades, scientists need a lot of data over a long period of time so that they can distinguish a true trend from the noise ‰ÛÒ the wiggles on a graph that represent the daily, weekly, seasonal and yearly fluctuations. The instruments on NPP will not only stretch the record longer, but more than 30 datasets also will help scientists answer the questions of how different parts of the climate system are changing, and more importantly how they interact as they change.


The Instruments of NPP

NPP has five instruments that observe the Earth’s surface twice every 24 hours, once in daylight and once at night. Circling the planet about 14 times a day, NPP flies 512 miles (824 kilometers) above the surface in a polar orbit, and sends its data one time per orbit to the ground station in Svalbard, Norway, and continuously to local direct broadcast users.

VIIRS ‰ÛÒ Visible Infrared Imaging Radiometer Suite

The largest instrument aboard NPP is the Visible Infrared Imaging Radiometer Suite (VIIRS). It collects radiometric imagery in visible and infrared wavelengths of the land, atmosphere, ice and ocean. Data from VIIRS, collected from 22 channels across the electromagnetic spectrum, are used to observe active fires, vegetation, ocean color, sea-surface temperature and other surface features. Atmospheric scientists use some of these channels to observe clouds and small airborne particles called aerosols. Oceanographers use VIIRS to monitor phytoplankton and sediment in the seas. Terrestrial ecologists use it to monitor forest cover and productivity, and ice experts use it to track changes in polar sea ice. VIIRS has similarities to the Moderate Resolution Imaging Spectroradiometers (MODIS) currently operating on two NASA satellites ‰ÛÒ Terra and Aqua.

CERES ‰ÛÒ Clouds and the Earth’s Radiant Energy System

The Clouds and the Earth’s Radiant Energy System (CERES) measures both solar energy reflected by the Earth and heat emitted by our planet. This solar and thermal energy are important parts of what’s called the Earth’s radiation budget. When sunlight hits Earth and its atmosphere, they warm up. Clouds and other light-colored surfaces like snow and ice reflect some of the sun’s heat and light, cooling Earth, while additional cooling comes from heat that the Earth radiates to space. The changing role of clouds in this system is one of the biggest unknowns in climate science. A total of four other CERES instruments fly on the Earth Observing System satellites Terra and Aqua.

CrIS ‰ÛÒ Cross-track Infrared Sounder

The Cross-track Infrared Sounder (CrIS) and the Advanced Technology Microwave Sounder (ATMS) work together to provide global high-resolution profiles of temperature and moisture. These advanced atmospheric sensors create cross-sections of storms and other weather conditions, helping with both short-term ‰Ûnowcasting‰Û and long-term forecasting. CrIS measures continuous channels in the infrared region and has the ability to measure temperature profiles with improved accuracy over its predecessor instruments on operational satellites, and comparable accuracy to the Atmospheric Infrared Sounder (AIRS) on Aqua. NOAA will be using CrIS for numerical weather prediction and, because it is a brand-new instrument, its use on NPP provides a real-world test of the equipment before NOAA’s upcoming Joint Polar Satellite System (JPSS) missions.

ATMS ‰ÛÒ Advanced Technology Microwave Sounder

The Advanced Technology Microwave Sounder (ATMS) works in both clear and cloudy conditions, providing high-spatial-resolution microwave measurements of temperature and moisture. ATMS has better sampling and two more channels than previous instruments like the Advanced Microwave Sounding Units (AMSU), and it combines all of their abilities into one instrument. Working in concert, CrIS and ATMS comprise the Cross-track Infrared Microwave Sounding Suite (CrIMSS).

OMPS ‰ÛÒ Ozone Mapping and Profiler Suite

The Ozone Mapping and Profiler Suite measures the ozone layer in our upper atmosphere ‰ÛÒ tracking the status of global ozone distributions, including the

‰Ûozone hole.‰Û It also monitors ozone levels in the troposphere, the lowest layer of our atmosphere, and extends the 40-year record of ozone layer measurements while also providing improved vertical resolution compared to previous instruments. Closer to the ground, OMPS’s measurements of harmful ozone improve air quality monitoring and when combined with cloud predictions, help to create the Ultraviolet Index, a guide to safe levels of sunlight exposure. The two new OMPS sensors have three advanced hyperspectral-imaging spectrometers.


According to Gleason, these questions range from the basic to the complex. If the data show droughts increasing, for example, he asks, “As it gets dryer, is the amount of dust coming off the Chinese desert increasing? And what does that dust do to other places?” Airborne dust, or aerosols, can rapidly travel thousands of miles and interact with clouds, which themselves influence the transport of water and energy through the climate system. The five NPP instruments, like a Swiss Army knife, are poised to answer different questions that ultimately build a bigger picture of the whole climate system.

The data the instruments provide also will improve and serve as a check on computer models that predict future climate. With the long-term data, scientists can compare model results with the actual observations of the past decades to see how well the model works. From there, scientists can take the NPP’s data and improve the models.

“NPP’s observations will help us make better long-term datasets which enable us to make better models, which lead to better predictions and better decisions,” says Gleason.

The decisions can be complex or as simple as whether to take an umbrella to work tomorrow. Among NPP’s many scientific missions is its use as an operational weather satellite by NOAA. Atmospheric data, including improved temperature and moisture profiles, will be added to NOAA’s weather prediction models.

Following 10 weather disasters in 2011 costing more than $1 billion each, the stakes for accurate and timely weather prediction are clear. Louis Uccellini, director of NOAA’s National Centers for Environmental Prediction, says that with NPP’s global data, “We expect to be advancing our forecast skills out to five to seven days in advance of extreme weather events, including hurricanes.”

Hurricanes aren’t the only disasters NPP will be keeping an eye on. And disaster monitoring is only the tip of the proverbial iceberg (which NPP will also be watching out for). NPP’s day-to-day observations will contribute to a number of scientific and societal applications.


Satellite images of big disasters make compelling news photos, but they also are tools. For instance, take the true-color Moderate-Resolution Imaging Spectroradiometer (MODIS) images of the 2011 Wallow fire that show smoke plumes billowing for miles across Arizona and New Mexico. First-responders and air quality experts used the images to track the fire and smoke, and scientists will use post-fire images to study forest recovery of burned areas. NPP’s Visible Infrared Imaging Radiometer Suite (VIIRS) is the successor to MODIS and will continue providing data on events such as fires, floods and volcanic eruptions, as well as on long-term vegetation changes that affect ecological and agricultural research.


In addition to atmospheric data for weather, NPP will monitor atmospheric ozone concentrations. In the upper atmosphere, ozone forms a shield that blocks dangerous ultraviolet radiation coming from the sun. In the lower atmosphere, ozone is a harmful air pollutant. The newly designed Ozone Mapping and Profiling Suite (OMPS) will detect concentrations of ozone in both regions, keeping an eye on the ozone hole over Antarctica.


For our watery planet, NPP will observe different aspects of the water cycle, oceans and ice. Among the datasets it will return are ocean color chlorophyll for evaluating phytoplankton, the base of the marine food chain; changes in ice cover over both land and sea; and temperature and moisture profiles in the atmosphere that contribute to weather forecasting and understanding of clouds, which are among the least predictable natural phenomena.


Energy in the form of heat is the major driver of atmospheric circulation ‰ÛÒ the pattern of air movements around the world. NPP will contribute to understanding the balance of heat coming in from the Sun, heat radiating out into space and heat moving in real time around the globe, contributing to weather systems, and ultimately to Earth’s complex climate system.