Data – New Data Acquisitions
This guide serves as a brief overview of the AVIRIS-NG instrument and its role in the field of imaging spectrometry. Mission planning and flight operations are discussed, and recommendations are given regarding the deployment of ground truth experiments.
Please note that when referring to/requesting AVIRIS-NG data, we are working to use the terms "imaging spectroscopy" and "imaging spectrometer data" rather than "hyperspectral." This allows us to communicate more clearly with our physics, chemistry, and biology science colleagues.
Objectives of Imaging Spectrometry with AVIRIS-NG
The AVIRIS-NG sensor collects data that can be used for characterization of the Earth's surface and atmosphere from geometrically coherent spectroradiometric measurements. This data can be applied to studies in the fields of oceanography, environmental science, snow hydrology, geology, volcanology, soil and land management, atmospheric and aerosol studies, agriculture, and limnology. Applications under development include the assessment and monitoring of environmental hazards such as toxic waste, oil spills, and land/air/water pollution. With proper calibration and correction for atmospheric effects, the measurements can be converted to ground reflectance data which can then be used for quantitative characterization of surface features.
Description of Sensor System
Scanner type: nadir-viewing, pushbroom
Image width (swath): 11 km (high altitude), 1.9 km (low altitude)
Typical image length: 10 - 100 km
Spatial sampling: 1.0 mrad
Spatial response: 1 to 1.5 x sampling
Sample distance: 0.3 m to 20 m
Spectral response: visible to near-infrared (380 to 2510 nm), with 481 contiguous channels, approximately 5 nm wide
Data quantization: 14 bits
Data rate: Up to 74 MB/s of throughput
Data capacity: Up to 1.0 TB of raw data before disk swap
Description of Airborne PlatformsTWIN OTTER - https://airbornescience.nasa.gov/aircraft/Twin_Otter_International
Nominal air speed: 80 - 160 knots
Altitude range: 6,000 ft to 17,500 ft
Maximum range: 560 nm
Maximum flight time: 5 hours
Flexible deployment sites
Operation of the AVIRIS-NG instrument and collection of AVIRIS-NG data aboard the Twin Otter is funded primarily through the Office of Earth Science at NASA Headquarters in Washington, D.C. This office also reviews experiment proposals and selects the experiments which it will fund. The Airborne Science Directorate of NASA-Armstrong Flight Research Center receives flight requests for experiments requiring AVIRIS-NG/Twin Otter data collection and, in collaboration with NASA headquarters, drafts aircraft deployment schedules. The AVIRIS-NG project operates under the Observational Systems Division of the Jet Propulsion Laboratory. In addition to operating and maintaining the sensor, the AVIRIS-NG project works to ensure that experiment requirements are met for each flight and that users are satisfied with data quality and the level of service provided.
Data Collection Process
All groups and agencies interested in acquiring AVIRIS-NG data must submit an experiment proposal to NASA headquarters and a flight request to Armstrong Flight Research Center. These items should be submitted by July 1st for the following fiscal year. Each experiment must designate a Principal Investigator who will serve as a single point of contact for headquarters, Armstrong Flight Research Center, and JPL.
NASA headquarters reviews experiment proposals, and selections are made based on merit and the program goals of the Office of Earth Science. Once the selection process is completed, the Airborne Sciences Directorate at Armstrong Flight Research Center iteratively designs an aircraft schedule that best accommodates the geographic and seasonal requirements for the suite of approved experiments. Reimbursable funding is also an option for the Twin Otter with the funds being sent through Armstrong Flight Research Center. Such arrangements must be approved individually by NASA headquarters. Help with the process can be sought through the Airborne Sciences Directorate at NASA Armstrong Flight Research Center.
After the aircraft schedule is drafted, it is distributed to all Principal Investigators. At least one month prior to the beginning of their experiments, investigators will be contacted by the AVIRIS-NG experiment coordinator. This contact is essential for verification of experiment requirements and to discuss schedules and arrangements for any calibration/validation activities that will accompany data collected during flight operations. The experiment coordinator will also assist investigators in fine-tuning experiment requirements and logistics to increase the likelihood of a successful mission. Investigators will be asked by to check their requirements on the AVIRIS-NG website and to e-mail an affirmation that the information is correct or a correction if it is not correct. It is critical for investigators to confirm that the data that the AVIRIS-NG team is using to plan the flights is correct. Latitude/Longitude target coordinates are especially critical to confirm.
Mission Planning and Execution
TWIN OTTER: Operations and Responsibilities
The personnel involved in the low altitude data acquisitions are two Twin Otter pilots, an AVIRIS-NG experiment coordinator, and an AVIRIS-NG engineer/technician. The primary contact for investigators will be the experiment coordinator. The primary mode of contact for the experiment coordinator should be e-mail sent to AVIRIS_Exp_Coord@jpl.nasa.gov . Urgent messages can be left at 818-398-7890. However, the experiment coordinator will not be able to listen to the voicemail in flight, so investigators may not receive a response for several hours and should leave an evening contact telephone number with these messages.
The duty of the experiment coordinator is to make sure that the pilots have the proper flight line coordinates for each day's experiment and that the investigator's requirements are met. The pilots enter the flightline coordinates into their GPS database several days before the lines are planned to be flown. For this reason, requests for new sites should be submitted one month in advance of the deployment. All changes in experiment requirements must be submitted by e-mail to the experiment coordinator one week prior to the first flight of a deployment. Late submission of requirement changes could result in missed flight opportunities for an experiment.
Because the weather determines when the twin otter will arrive at each site, the experiment coordinator is responsible for providing notice to the investigators as to when the acquisition might take place BUT the investigator is responsible for being ready at any time during the deployment. Our goal is to be able to give the investigators notice a night or two before the acquisition is planned. For this reason, providing both day and evening telephone numbers for ground team contacts is extremely important. If the investigator will not be available for the entire deployment period, including a secondary contact is also strongly recommended.
Depending upon weather and locality, the pilots and experiment coordinator will determine what targets are feasible for the next day and spend the night at a location which will allow them to acquire data at those targets the next day. The number of days spent waiting for a clear weather window at any given site is dependent upon the number of targets left, their locations, and the number of days left in the deployment.
On the day of the flight, the AVIRIS-NG experiment coordinator and the pilots will determine if the weather conditions are favorable for acquiring the sites that had been decided upon and the ground teams will be notified. If the ground team has information that is pertinent to the decision making process, then they should make contact with the experiment coordinator.
The investigator must provide the same information as for the ER-2 except for the flight line coordinate information. The flight line coordinate information should always take the form of start/stop end points for the center of each line (giving the latitude and longitude coordinates in degrees-minutes.decimal-minutes: ddd:mm.mm). The pilot can not check the accuracy of these coordinates; therefore, investigators need to check the AVIRIS-NG website and confirm that their lines have been accurately entered into the database. This confirmation should be in the form of e-mail to the experiment coordinator.
The PI will also need to specify the altitude at which data shall be flown. In order to achieve adequate sampling in the along-track direction at typical Twin Otter ground speeds, an altitude of at least 12,500' above ground level is recommended. However, investigators should also consider the following: FAA regulations require the pilots to use supplemental oxygen at 12500' (above sea level) - if they're there for more than 30 minutes, and at all times above 14000'. All passengers must be equipped with oxygen above 15,000' (above sea level). The higher the plane flies, the faster the oxygen gets used, and oxygen has been a limiting factor in data collection in the past (when we're out of oxygen, we're done for the day). For sites at high altitude, PI's may want to consider trading some undersampling (i.e., lower altitude) for more areal coverage.
Restricted and Military Operations Areas (MOAs)
Restricted Areas and Military Operations Areas (MOAs) are depicted on airspace charts, and investigators are encouraged to plan their lines outside of these areas, if at all possible. For flights requiring access to military areas or over foreign soil, investigators are responsible for making contact with the appropriate authorities and providing the experiment coordinator with the clearance number or code, and the controlling agency's radio frequency. On approach to the restricted area, the pilot will use this information to confirm entry into the area. When obtaining a clearance, investigators should inform the controlling authorities that the data might be collected at any time during the low altitude deployment window, and find out when the areas will be closed to non-military traffic. It is helpful to remember that many restricted areas will not allow access during the week, but might be accessible on weekends. In addition, flight lines that are near or adjacent to restricted areas may also require clearance to be flown. (This is less of an issue with the Twin Otter than it is with the ER-2 but it is still important to remember.) Finally, investigators should be aware that clearances could be revoked at any time. The Twin Otter pilots also have the authority to decide that military operations in the area make flight there too hazardous even with the clearance, thus canceling the collection. Therefore, lines within restricted airspace are much less likely to be flown given all of the other constraints of a mission.
Recommendations for Ground Truth Experiments
The chief purpose of ground truth data collection for AVIRIS-NG experiments is to provide input parameters to radiative transfer or other models that remove the effects of atmospheric absorption and scattering, ultimately converting the radiance data measured by AVIRIS-NG into reflectance data. The ground truth data can also be used to validate the results of AVIRIS-NG data analysis. This section discusses logistics and management issues of ground truth experimental it is not intended as a guide for designing such experiments.
Experiment teams are advised to establish reliable pathways of communications and to test these pathways prior to the start of operations. If the experiment site is in a remote location, it is well worth investing in a portable phone or a radio with phone-patch access. One person or one telephone number should be designated as the central point of contact for the group. A regular call-in schedule for key team members is also recommended, especially during initial deployment and during rotation of field personnel.
A time window of at least two weeks duration is recommended for each experiment to allow for uncertainties in weather patterns and possible equipment failures, air-traffic control problems and other factors. Accepting early data also helps ensure a successful experiment. A compromise in data quality that results from flying at a different time of the month or a different hour of the day is preferable to the possibility of no data at all. An investigator who insists on ideal conditions often ends up, out of desperation, accepting data with 50% cloud cover on the last day of the deployment.
Field team members should recognize that weather appearing to be clear from the ground may still be unacceptable to an airborne sensor, due either to cloud shadow, near-invisible cirrus, or haze. The ER-2 operations team has full access to satellite images and terminal forecast networks and is very experienced at making weather decisions. casual observations of the sky by field teams ("It's really clearing up - you people should fly!") are generally not useful due to the limited horizon of a ground-based observer. Field teams can, however, assist the weather decision process by providing information on local diurnal weather patterns.