sentinel-2

“Wheat Lodging Assessment Using Multispectral UAV Data” on ISPRS Archives

maia s2

 

Wheat Lodging Assessment Using Multispectral UAV Data

In 2018 we conducted a multispectral campaign using MAIA S2 on wheat fields that had lodging problems. We planned the photogrammetric paths, agreed with agronomists and technicians the geometric resolution and the products that we had to derive from the photogrammetric and multispectral survey, then we set the parameters of MAIA to obtain the correct radiometric information in each band, in such a way as to provide all the data useful for both radiometric and geometric analysis, thus developing a field of study that will have great applications in the future: 3D multispectral data analysis. In our processing lab, we then processed the data and obtained multispectral DSM, multispectral orthophotos and a large dataset of radiometric and geometric sample measurements. Thanks to the study of a team of Italian and Dutch experts, that data acquisition service resulted in a scientific publication.

For the first time, high-resolution multispectral data from a UAV with nine spectral bands (the same as Sentinel-2) covering the 390-950 nm wavelength region has been utilized for lodging assessment. This enabled a comparison of spectral variability across nine bands. Overall, we found that there was an increase in the magnitude of reflectance spectra as the lodging became more severe. The increase was more pronounced in the green, red-edge and NIR regions of the spectrum, thereby showing the sensitivity of these bands to changes in the crop canopy structure. Furthermore, the overall classification accuracy was very high (90%) where NL, ML, and SL classes were separated with reasonable accuracy while there was some mixing of VSL class with the other groups. To conclude, bands in the range of 700- 950nm can effectively detect lodging in wheat. These results underline how multispectral data can be an advancement with respect to conventional RGB camera traditionally mounted on the UAV platforms. Although we believe that these results are transferable to different crop varieties and growing conditions, further research is required to assess this.

Click here below to read and download the article:

Wheat Lodging Assessment Using Multispectral UAV Data 

S. Chauhan 1, R. Darvishzadeh 1, Y.Lu 1, D. Stroppiana 2, M. Boschetti 2, M. Pepe 2, A. Nelson 1
1 Faculty of Geo-information Science and Earth Observation (ITC), University of Twente, Enschede 7500AE, The Netherlands – (s.chauhan, a.nelson, r.darvish)@utwente.nl, y.lu-3@student.utwente.nl
2 CNR-IREA, Institute for Electromagnetic Sensing of the Environment, National Research Council, 20133 Milano, Italy – (stroppiana.d, boschetti.m, pepe.m)@irea.cnr.it

The International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Volume XLII-2/W13, 2019 ISPRS Geospatial Week 2019, 10–14 June 2019, Enschede, The Netherlands

“Quantifying Uncertainty and Bridging the Scaling Gap in the Retrieval of Leaf Area Index by Coupling Sentinel-2 and UAV Observations” on Remote Sensing journal

 

Quantifying Uncertainty and Bridging the Scaling Gap in the Retrieval of Leaf Area Index by Coupling Sentinel-2 and UAV Observations

Even within managed crop systems, there is considerable and important within-field variation in LAI at scales finer than the resolution of current satellite imagers.
In this scientific research it is demonstrated that UAV multispectral observations at the cm scale, acquired from a sensor designed to match Sentinel-2 spectral bands, improve interpretation of the satellite signal.
Furthermore, the fine-scale resolution of the UAV sensor provides a tool for accurately upscaling LAI ground measurements, which were collected in coordination with the UAV flights, to satellite resolution. The within-field variance in spectral data resolved from the UAV observations was linked to wheat growth stage. Consequently, the Sentinel-2 and UAV platform data were more comparable at the later growth stages, when the vegetation canopy appeared more homogeneous due to a reduced influence of bare soil.
Calibrating models used to retrieve LAI from Sentinel-2 observations directly from ground measurements performed poorly and were unable to explain the variance in LAI throughout the growing season. On the other hand, our novel two-stage model calibration, involving the use of upscaled UAV LAI estimates, demonstrated a clear improvement in the accuracy of LAI retrievals from Sentinel-2 data, reducing bias strongly.
This study has highlighted the value of UAV observations for eectively providing a link between point measurements on the ground and 20-m resolution multispectral observations made from the Sentinel-2 satellite.
Click here below to read the article:

“The Value of Sentinel-2 Spectral Bands for the Assessment of Winter Wheat Growth and Development” on Remote Sensing journal

 

The Value of Sentinel-2 Spectral Bands for the Assessment of Winter Wheat Growth and Development

We are proud to share the scientific publication of some researchers who have chosen our multispectral data acquisition system since the initial days when we were in the design and development phase. Below you will find the abstract and the link to access the scientific journal.

Leaf Area Index (LAI) and chlorophyll content are strongly related to plant development and productivity. Spatial and temporal estimates of these variables are essential for efficient and precise crop management. The availability of open-access data from the European Space Agency’s (ESA) Sentinel-2 satellite—delivering global coverage with an average 5-day revisit frequency at a spatial resolution of up to 10 metres—could provide estimates of these variables at unprecedented (i.e., sub-field) resolution. Using synthetic data, past research has demonstrated the potential of Sentinel-2 for estimating crop variables. Nonetheless, research involving a robust analysis of the Sentinel-2 bands for supporting agricultural applications is limited. In this scientific contribution, it is evaluated the potential of Sentinel-2 data for retrieving winter wheat LAI, leaf chlorophyll content (LCC) and canopy chlorophyll content (CCC). In coordination with destructive and non-destructive ground measurements, the team acquired multispectral data from an Unmanned Aerial Vehicle (UAV)-mounted sensor measuring key Sentinel-2 spectral bands (443 to 865 nm). They applied Gaussian processes regression (GPR) machine learning to determine the most informative Sentinel-2 bands for retrieving each of the variables. They further evaluated the GPR model performance when propagating observation uncertainty. When applying the best-performing GPR models without propagating uncertainty, the retrievals had a high agreement with ground measurements—the mean R2 and normalised root-mean-square error (NRMSE) were 0.89 and 8.8%, respectively. When propagating uncertainty, the mean R2 and NRMSE were 0.82 and 11.9%, respectively. When accounting for measurement uncertainty in the estimation of LAI and CCC, the number of most informative Sentinel-2 bands was reduced from four to only two—the red-edge (705 nm) and near-infrared (865 nm) bands.

This research demonstrates the value of the Sentinel-2 spectral characteristics for retrieving critical variables that can support more sustainable crop management practices.

Click here below to read and download the scientific article:

 

The Value of Sentinel-2 Spectral Bands for the Assessment of Winter Wheat Growth and Development

Andrew Revill 1 Anna Florence 2 Alasdair MacArthur 1Stephen P. Hoad 2  Robert M. Rees 2 and Mathew Williams 1
1
School of GeoSciences and National Centre for Earth Observation, University of Edinburgh
2
Crop & Soils Systems, Scotland’s Rural College, Edinburgh

MAIA S2 and Sentinel-2: remote to proximal sensing

 

MAIA S2 and Sentinel-2: remote to proximal sensing

Comparing multispectral data for environmental monitoring and precision agriculture

Following the development of MAIA WV, the most technologically advanced multispectral camera ever proposed in the market of sensors for surveying by plane or UAV, SAL Engineering has developed MAIA S2, in collaboration with the most important universities and research institutes in Europe, involved in studies of earth observation and remote sensing. MAIA WV has the same wavelenght intervals of WorldView-2 satellite mission by DigitalGlobe: this choice was made following evaluations regarding the most widespread applications of satellite remote sensing that could be useful also in the field of proximal sensing with airplanes or UAVs. In fact, WorldView-2 provides commercially available imagery of 0.46 m resolution, and eight-band multispectral imagery with 1.84 m resolution.

RGB false composition of a multispectral orthophoto obtained with MAIA S2 installed onboard an aircraft

Great interest in the use of satellite images for applications in agriculture and environmental monitoring was given by the Copernicus Programme of the European Space Agency, thanks to the Sentinel missions. The request of large agronomic companies and research institutes involved in sustainable agriculture projects was to have multispectral images at the same wavelength ranges available in the Sentinel missions data hubs, with the same radiometric reliability, but with a much higher geometric resolution and with the possibility to decide the moment of the multispectral survey according to the needs of the agronomic research.

Hence, MAIA S2 is designed to ensure multi-layer and multi-channel images at the same wavelength intervals as the multispectral sensor on board the Sentinel-2 satellite, with complete control on reflectance data and radiometric correction of RAW images, with the advantage of having a ground sample distance lower than 5 cm flying at 100 m AGL.

Sentinel-2 is an Earth observation mission from the Copernicus Programme that systematically acquires optical imagery at high spatial resolution (10m to 60m) over land and coastal waters. The mission is a constellation with two twin satellites (Sentinel-2A and Sentinel-2B). The mission supports a broad range of services and applications such as agricultural monitoring, emergencies management, land cover classification, water quality, disaster control, humanitarian relief operations, risk mapping and security concerns.

The Sentinel-2 mission has the following key characteristics:

  • Multi-spectral data with 13 bands in the visible, near infrared, and short wave infrared part of the spectrum
  • Systematic global coverage of land surfaces from 56° S to 84° N, coastal waters, and all of the Mediterranean Sea
  • Revisiting every 5 days under the same viewing angles. At high latitudes, Sentinel-2 swath overlap and some regions will be observed twice or more every 5 days, but with different viewing angles.
  • Spatial resolution of 10 m, 20 m and 60 m
  • 290 km field of view
  • Free and open data policy

To achieve frequent revisits and high mission availability, two identical Sentinel-2 satellites (Sentinel-2A and Sentinel-2B) operate together. The planned orbit is Sun synchronous at 786 km (488 mi) altitude, 14.3 revolutions per day, with a 10:30 a.m. descending node. This local time was selected as a compromise between minimizing cloud cover and ensuring suitable Sun illumination. It is close to the Landsat local time and matches SPOT‘s, allowing the combination of Sentinel-2 data with historical images to build long-term time series.

The Copernicus Land Monitoring service became operational in 2012. The object of the service is to provide land cover information to users working in the field of environmental and other terrestrial applications. The service is designed to provide geographical information on land cover and related variables such as the vegetation state or the water cycle, and also supports applications in other domains including spatial planning, forest management, water management, agriculture and food security.

The Copernicus Sentinel-2 mission comprises a constellation of two polar-orbiting satellites placed in the same sun-synchronous orbit, phased at 180° to each other. It aims at monitoring variability in land surface conditions, and its wide swath width (290 km) and high revisit time (10 days at the equator with one satellite, and 5 days with 2 satellites under cloud-free conditions which results in 2-3 days at mid-latitudes) will support monitoring of Earth’s surface changes. The coverage limits are from between latitudes 56° south and 84° north. For mission planning and updated coverage status information, see the Revisit and Coverage page.

Sentinel-2 is a European wide-swath, high-resolution, multi-spectral imaging mission. The full mission specification of the twin satellites flying in the same orbit but phased at 180°, is designed to give a high revisit frequency of 5 days at the Equator. Sentinel-2 carries an optical instrument payload that samples 13 spectral bands: four bands at 10 m, six bands at 20 m and three bands at 60 m spatial resolution.

With its frequent and systematic coverage, Sentinel-2 will make a significant contribution to land monitoring services by providing input data for both land cover and land cover change mapping, and support the assessment of biogeophysical parameters such as Leaf Area Index (LAI), Leaf Chlorophyll Content (LCC) and Leaf Cover (LC).

The high revisit frequency of the Sentinel-2 mission will support the attempts to mitigate deforestation by providing greater opportunities to acquire cloud-free image data. This will be of particular benefit in the tropical latitudes, where heavy cloud cover has previously delayed the potential acquisition of a complete catalogue of data. As well as the same parameters that are used in other GMES/Copernicus programmes (such as FAPAR, LAI, LC, LCC and NDVI) that contribute to the monitoring and modelling of climate-induced changes, high-resolution data from Sentinel-2 can support the change detection of flood events for affected countries. The Sentinel-2 satellites will each carry a single multi-spectral instrument (MSI) with 13 spectral channels in the visible/near infrared (VNIR) and short wave infrared spectral range (SWIR).

Spectral bands for the Sentinel-2 sensors
Sentinel-2 bands Sentinel-2A Sentinel-2B
Central wavelength (nm) Bandwidth (nm) Central wavelength (nm) Bandwidth (nm) Spatial resolution (m)
Band 1 – Coastal aerosol 442.7 21 442.2 21 60
Band 2 – Blue 492.4 66 492.1 66 10
Band 3 – Green 559.8 36 559.0 36 10
Band 4 – Red 664.6 31 664.9 31 10
Band 5 – Vegetation red edge 704.1 15 703.8 16 20
Band 6 – Vegetation red edge 740.5 15 739.1 15 20
Band 7 – Vegetation red edge 782.8 20 779.7 20 20
Band 8 – NIR 832.8 106 832.9 106 10
Band 8A – Narrow NIR 864.7 21 864.0 22 20
Band 9 – Water vapour 945.1 20 943.2 21 60
Band 10 – SWIR – Cirrus 1373.5 31 1376.9 30 60
Band 11 – SWIR 1613.7 91 1610.4 94 20
Band 12 – SWIR 2202.4 175 2185.7 185 20

Due to the layout of the focal plane, spectral bands within the MSI instrument observe the surface at different times and vary between band pairs. The mission will provide information for agricultural and forestry practices and for helping manage food security. Satellite images will be used to determine various plant indices such as leaf area chlorophyll and water content indexes. This is particularly important for effective yield prediction and applications related to Earth’s vegetation.

As well as monitoring plant growth, Sentinel-2 can be used to map changes in land cover and to monitor the world’s forests. It will also provide information on pollution in lakes and coastal waters. Images of floods, volcanic eruptions and landslides contribute to disaster mapping and help humanitarian relief efforts. Examples for applications include:

  • Monitoring land cover change for environmental monitoring
  • Agricultural applications, such as crop monitoring and management to help food security
  • Detailed vegetation and forest monitoring and parameter generation (e.g. leaf area index, chlorophyll concentration, carbon mass estimations)
  • Observation of coastal zones (marine environmental monitoring, coastal zone mapping)
  • Inland water monitoring
  • Glacier monitoring, ice extent mapping, snow cover monitoring
  • Flood mapping & management (risk analysis, loss assessment, disaster management during floods)

As seen in the diagram before, the spatial resolution of Sentinel-2 is dependent on the particular spectral band:

Sentinel-2 spectral bands and geometric resolution.
Multispectral survey with GNSS RTK master on field and rover onboard the drone, conducted in a glacier with MAIA multispectral camera

SAL Engineering is composed by operators experienced in acquisition, processing and analysis of remote sensing data from satellite missions, aerial surveys or UAVs, with proven experience over several years.

We provide remote sensing data analysis operations and multi-temporal monitoring by integrating georeferenced data from different acquisition systems and referring to different time intervals, to provide the right digital cartographic products, useful to agronomists and environmental protection operators.

MAIA is the multispectral camera that permits the simultaneous acquisition of high resolution images at various wavelenght intervals in VIS/NIR electromagnetic spectrum regions. It is designed to be employed on board the UAV systems or on board aircrafts, and it finds several applications on board terrestrial rovers too, for precision agriculture, classification of crops, classification of materials on soil, environmental monitoring, dumps monitoring. MAIA S2 is the only multispectral camera equipped with the same wavelenght intervals of the European Spatial Agency’s Sentinel-2™ satellite.

Diagram 2 MAIA S2 amplitude and distribution of wavelenght intervals.

Now, you can compare free satellite data with high-resolution maps obtained through a multispectral survey conducted with MAIA S2, the proper instrument for your multispectral survey.

In recent years, several agronomic research or remote sensing institutes have been evaluating the potential of the data provided by Sentinel missions through direct comparison in the field with high resolution optical sensors, and using UAVs for a closer flight. They evaluate the potential of Sentinel-2 data for retrieving winter wheat LAI, leaf chlorophyll content (LCC) and canopy chlorophyll content (CCC). In coordination with destructive and non-destructive ground measurements, they acquire multispectral data from MAIA, measuring key Sentinel-2 spectral bands (443 to 865 nm). Check for example this paper.

NDVI classified derived from a multispectral survey on a tomato field conducted with MAIA S2.

MAIA S2 is entirely developed in Italy by SAL EngineeringEoptis and Fondazione Bruno Kessler.

RGB false composition of a multiband orthophoto obtained with MAIA installed onboard an aircraft

If you participate in a research project that correlates multispectral satellite data with agronomic data acquired in the field, if you need a higher geometric resolution for your multispectral orthophotos, if you deal with water quality and want to monitor spills in waters, contact us and we will provide the multispectral survey service according to your needs.

MAIA M2: the modular multispectral camera

 

MAIA M2 is the new lightest modular multispectral camera

The potential offered by RPAS (Remotely Piloted Aircraft Systems) in environmental prevention and monitoring is related to the possibility for sensors to fly over areas of interest. In the last decade proximal sensing technology saw a great development both with regard to sensors (lightweight multispectral and iperspectral sensors) and platforms (aircraft, helicopters, RPAS). Research and development in photogrammetric and multispectral surveys is offering new innovative solutions in sensors and technologies to monitor our environmental resources with very high frequency, precision and reliability.

MAIA is the most advanced multispectral camera designed to be employed onboard UAV systems, airplanes and terrestrial rovers as well, jointly developed and made in Italy by SAL Engineering, that designs and manufactures systems for data acquisition in sea, air, land environments, EOPTIS, specialized in designing and manufacturing opto-electronic measurement instruments, and 3DOM Research Unit of Fondazione Bruno Kessler, that is actively involved in accurate measurements and reality-based 3D reconstruction issues. In this team the Italian excellence in the fields of physics, optics, geomatics, 3D modeling and remote sensing have been concentrated: a consolidated know-how was made available for the construction of a multispectral imagery acquisition instrument that could ensure scientific rigor and total control of geometrical and radiometric data for a correct multispectral survey.

Regarding the differentiation of wavelenght intervals along the electromagnetic spectrum, MAIA has been designed according to two main sets: MAIA WV and MAIA S2. Nevertheless, thanks to the profitable collaboration with agronomic consulting companies and environmental protection agencies, or with universities and research institutes, a fully customizable modular solution was subsequently developed.

MAIA M2, in fact, is the new modular multispectral camera that the user can customize with a large portfolio of VIS-NIR bandpass filters, according to his needs.

The MAIA M2 single module can be composed using a pair of available band-pass filters. The choice of the pre-selected filter pairs will be made according to the most widely used multispectral indexes with two single bands, or on the basis of the aim of the multispectral survey. In the following table you can see the selected filters that are available in stock:

Each module has stand-alone capability with external trigger and strobe or free run mode, and presents several inputs/outputs for external devices interfacing such as trigger, strobe, serial port, USB and two aux port. The module/camera is based on a double global shutter CMOS sensor with 8/12 bits resolution and automatic exposure with selectable target value.

Single module of MAIA M2 has the lowest values in the market of modular multispectral cameras in terms of size (48 mm X 33 mm X 23 mm), weight (70 g) and price (1990 € until July 15th), but it presents the highest values in terms of resolution and sensitivity of sensors.

Multi-module management, up to 8 modules, is possible using the external MAIA M2 Control Unit that manages the images synchronization and geo-referencing, the powering of modules, the reading of PWM inputs, the light sensor input, two outputs with customizable variable advance for delay compensation of any connected DSLR cameras. An RTK version of MAIA M2 Control Unit is supplied including the GNSS antenna, the UHF antenna, the Lux Sensor and the connection cables for batteries, PWM inputs and DSLR shutter input. Multispectral raw images and parameters are stored in a removable SD card, and they can be downloaded from USB in order to be pre-processed with MultiCam Stitcher Pro, the MAIA images pre-processing software.


The following table shows some combinations of 2 or more MAIA M2 modules, useful to allow the calculation of many of the main multispectral indexes:

MAIA is basically the proper instrument for your multispectral survey.

You can detect VIS-NIR informations through 9 global shutter sensors with high resolution and top sensitivity; next, you have the total control on creating your dataset of undistorted and geometrically corrected images for reflectance analysis, indexes calculation and photogrammetric processing. You can then make decisions on monitoring crops, wineyards, forests and coastal environments, in order to safeguard ecosystems and to make your agronomic system more efficient. Along with the camera, an image processing software will be provided for correction of geometric and radial distorsion, for coregistration (pixel-pixel convergence) of RAW multispectral images acquired with MAIA, with tools for indexes calculation and for band combinations.

Since its foundation, SAL Engineering has participated, contributing with the design and management of data acquisition, synchronization and processing systems, to several projects with agronomic and precision farming companies, or environmental protection agencies that deal with natural environments such as coastal dunes, forests, reclaimed sites, areas with high environmental risk.

SAL Engineering is a company specialized in photogrammetric surveys based in Italy: visit our website www.salengineering.it.

For any further information about services and products, send us an email at info@salengineering.it.

For any detailed information about products and technologies that deal with multispectral surveys, please contact usSAL Engineering is providing accurate multispectral data to companies specialized in agronomic consulting thanks to our integrated systems based on platform, control system and sensors.

MAIA WV is the multispectral camera equipped with the same wavelenght intervals of the WorldView-2™ satellite owned by DigitalGlobe. Now, you can compare satellite data with high-resolution maps obtained through a multispectral survey conducted with MAIA WV mounted on your UAV, getting centimeters-level precision and accuracy. WorldView-2™ is a commercial earth observation satellite that provides eight-band multispectral imagery with 1.84 m resolution, in support of services such as agriculture, forest monitoring, land cover changes and natural disaster management. MAIA WV multispectral camera is based on an array of 9 sensors (1 RGB and 8 monochrome with relative band-pass filters) to detect multispectral imagery in the VIS-NIR spectrum from 390 nm to 950 nm: MAIA WV is the most advanced broadband multispectral camera for RPAS, aircrafts, terrestrial rovers available today, with bands in Coastal and Blue spectrum region.

MAIA S2 is the multispectral camera equipped with the same wavelenght intervals of the European Spatial Agency‘s Sentinel-2™ satellite. Sentinel-2™ is an earth observation mission developed by ESA as part of the Copernicus Programme to perform observations in support of services such as precision agriculture, forest monitoring, land cover changes detection, and natural disaster management. Now, you can compare free satellite data with high-resolution maps obtained through a multispectral survey conducted with MAIA S2, the multispectral camera with two narrow spectral bands both in Red Edge and in NIR region.

The key features of the new-born MAIA M2, that presents the same quality of sensors, filters and optics of the standard versions WV and S2, are basically linked to the modular system and to the freedom to customize the set of bandpass filters, with excellent cost/benefit ratio and perfect physical adaptability onboard data acquisition platforms.

Applications of MAIA for environmental monitoring

 

Applications of MAIA the multispectral camera for environmental monitoring

The potential offered by RPAS in environmental awareness, prevention and monitoring is related to the possibility for sensors to fly over areas of interest. Remote Sensing in the environmental and territorial sector has undergone the first strong development with the NASA launch of the Landsat1 satellite in 1972, and since then numerous Earth Observation projects have been launched by numerous public and private space agencies.

In the last decade Proximity Remote Sensing technology saw its great development both with regard to sensors (lightweight multispectral and iperspectral sensors) and platforms (aircraft, balloons, helicopters, RPAS).

The platform is always equipped with a sensor, which can be active or passive. An active sensor emits electromagnetic radiation in the optical region, such as a LIDAR (Light Detection And Ranging) sensor, or SAR (Synthetic Aperture Radar): energy is reflected from the Earth’s surface and returns to the sensor where measurement is done. A passive sensor measures the physical and chemical data of the earth’s surface or the atmosphere on the basis of the reflected solar electromagnetic radiation or directly emitted by the objects in the investigated surface. A passive sensor can be optical or other type, such as those measuring meteorological parameters, air quality or ionizing or non-ionizing radiation. An optical sensor is characterized by the particular spectral region, within the entire electromagnetic spectrum, where the instrument works. The spectral region may include Visible (VIS), Near Infrared (NIR), Average Infrared (SWIR) and Thermal Infrared (TIR).

Figure 1 Electromagnetic spectrum in which the infrared regions are highlighted.

Figure 2 Electromagnetic spectrum in which the visible spectral region of the Visible is highlighted.

The number of its spectral bands characterizes an optical sensor: a panchromatic sensor operates in the visible region, a multispectral sensor provides images at different bandwidths and hence wavelengths, and a hyperspectral sensor is equipped with hundreds of very narrow bands.

The fundamental properties of the sensors are the geometric resolution, defined by the pixel size and therefore the ground information unit, the spectral resolution, i.e. the amplitude and variety of the bands, and the radiometric resolution, that is the sensitivity in the measurement that is able to return. The repetition rate of data acquisition finally defines the time resolution, which depends on the platform and not on the sensor.

MAIA WV is the multispectral camera with 9 sensors designed and developed with bands that have the same wavelength ranges as DigitalGlobe’s WorldView-2 satellite. It consists of an RGB sensor for real-life images, and 8 monochrome sensors with VIS-NIR spectrum sensitivity from 390 nm to 950 nm. Each sensor has a resolution of 1280×960 pixels (1.2 Megapixels) and the size of each sensor pixel is 3.75 μm x 3.75 μm. Monochrome sensors are coupled with band-pass filters that determine undesired wavelengths.

Figure 3 Electromagnetic Spectrum Detectable by MAIA WV-2 with relative wavelength intervals of the different spectral bands.

MAIA S2 is the 9-sensor multispectral chamber designed and developed to have 9 bands at the same wavelengths as ESA’s Sentinel-2 satellite. Each sensor has a resolution of 1280×960 pixels (1.2 Megapixels) and the size of each sensor pixel is 3.75 μm x 3.75 μm. Monochrome sensors are coupled with band-pass filters that determine undesired wavelengths.

Figure 4 Electromagnetic Spectrum Detectable by MAIA S2 with relative wavelength intervals of the different spectral bands.

Multispectral survey results are images unaffected by radial and geometric distortion, which present the pixel-pixel coregistration of information for all bands. Through the image processing software acquired with MAIA WV and MAIA S2, it is also possible to operate a radiometric correction of the multispectral data to obtain a repeatable and comparable data even under different light and environmental conditions.

For this reason, SAL Engineering and Eoptis have patented and developed ILS – Incident Light Sensor, an incident light sensor that records incident environmental radiation at every single shoot so that the multispectral data can be radiometrically corrected under the conditions of real and contingent lighting.

Different types of surface such as water, bare soil, or vegetation reflect radiation differently at the different wavelength ranges that define spectral bands: in this sense, the reflected radiation according to the wavelength is called spectral signature of the surface, which is proper and recognizable for certain elements and surfaces.

Figure 5 Spectral signature or spectral profile of vegetation, soil and water.

The vegetation has a very high reflection value in the near infrared and a low reflection value in the red channel of the visible: this allows for example to easily distinguish vegetation areas from those with bare soil through the RVI ( Ratio Vegetation Index), which is the ratio between quantified reflectance in NIR digital numbers and reflection in Red images.

Figure 6 Spectral sign of vegetation in the Visible and Near Infrared region.

It is possible to distinguish the dry vegetation from the wet vegetation, or to investigate the health of a crop by analyzing the curve of its spectral signature.

Dry vegetation does not absorb the red radiation typical of active photosynthesis, does not have the typical Red Edge reflection peak and does not exhibit the high reflection of NIR’s typical radiation incident.

The spectral signature of green plants is very characteristic: chlorophyll in a growing plant absorbs light in the visible, especially red, which it uses in photosynthesis. The near infrared light, on the contrary, is reflected very effectively because it does not serve the plant in any way: in this way the plants avoid excessive heating and evaporation of the lymph.

The vegetation reflection in the near infrared ranges and in the ranges of the visible varies considerably. The degree of difference reveals the extent of leafy vegetation in a portion of an area: in this sense a very important index is the Leaf Area Index (LAI), which is a very useful foliar index in agriculture and in management, for example, of a degraded area that has been regenerated or reclaimed.

Figure 7 Spectral differences, recognizable in their spectral signature, dry vegetation and active photosynthesis vegetation.

The vegetation can be classified according to the specific spectral signature of the different plant species: in fact, research on quantitative biomass estimation and on the classification and monitoring of the tree species has already been carried out for decades thanks to multispectral surveys based on different spectral signatures of the tree species.

Figure 8 Different tree species classified according to their characteristic spectral signature.

Figure 9 Distinction of spectral reflection characteristics of conifers and hardwoods in the specific region of the Red Edge.

Each plant species and each agrarian culture is characterized by a specific phenological schedule. Multitemporal Remote Sensing allows you to observe phenological evolution during the year, and by comparing and predicting, to implement a plan for the prevention and monitoring of crops and the protection of natural forest, shelter, marsh or mountain ecosystems.

Figure 10 Distinctions in spectral reflectance characteristics between different crops.

There are also significant differences between different types of soil, in fact the multispectral survey is a large scale survey also used for the classification of geological soil: different mineral and lithological elements for their physical and chemical composition present a definite spectral signature. You can read a summary of applications of multispectral survey here. In addition, as with vegetation, it is possible to distinguish in terms of reflection a soil with high humidity from an arid soil because a soil with higher water content has a higher absorption of the incident and diffused radiation.

Figure 11 Distinction in spectral reflection between arid soil and wet soil.

Another very important matrix to be analyzed from a spectrometric point of view is water, whose variations in terms of spectral signature may characterize turbidity, the presence of suspended materials, or even contamination or the unexpected or unusual presence of suspended materials, or excessive or reduced production of phytoplankton in suspension. Generally water has minimal reflection only in the spectrum of the visible, and more precisely in the band of Blue and Violet. The reflection at these specified wavelength intervals allows a certain depth of penetration in the survey below the surface of the water bodies. With MAIA S2, equipped with a bandpass filter set that allows you to capture images at the same wavelengths of the ESA satellite Sentinel-2, and with MAIA in its WV filter set, that allow to capture multispectral data at the same wavelengths of the WorldView-2 satellite, it is possible to evaluate some water quality parameters:

  • the concentration of suspended chlorophyll
  • the presence of harmful algal blooms
  • salinity and turbidity
  • state of pollution or contamination of a water body.

It is also possible to distinguish within the flora in a water body, different species based on different reflection in the wavelengths of Blue and Violet. This knowledge is conducive to the safety assessment in all the exploitation activities that man will be able to implement of that water resource.

Figure 12 Comparison of spectra reflecting the taxonomies of four different algae in a water body, with almost identical chlorophyll concentration (written in parenthesis and expressed in μg / l).

In this report we also present high-quality scientific applications that the Research Institutes, Universities and Environmental Agencies have successfully tested, adding multispectral survey to well-established survey techniques, and in particular correlating information from precious multispectral data to the information already sought and documented in different fields of investigation of environmental science and knowledge of the territory.

The main measurements that can be obtained through a multispectral survey carried out with MAIA, concern:

 

Vegetation –        Discrimination and classification of species
–        Estimation of biomass
–        Plant health status
–        Potential evapotranspiration
–        Real evapotranspiration
Soil –        Discrimination between different types of soil
–        Content of organic matter
water –        Content of turbidity
–        Concentration of chlorophyll
Anthropized –        Discrimination and classification of land use

 

With regard to the sensors that SAL Engineering can make fly over the areas of interest, the main applications useful to an Environmental Protection Agency can be:

 

MAIA and MAIA S2

The Multispectral Camera

 ·        Classification of vegetation and health monitoring based on biophysical parameters; vegetation indices.
·        Identification and classification of land use, soil types, vegetation and crops with their health status.

·        Analysis of the correlation between vegetation typologies and geomorphological aspects.

·        Issues on agricultural production.
·        Evaluation of the environmental impact of the burned and then repopulated regions; tools for VIA (Environmental Impact Assessment) and VAS (Strategic Environmental Assessment).
·        Identification of unauthorized waste areas; monitoring of RSU dumps; identification of biogas emissions, location of percolate leakage and assessment of the health status of the surrounding vegetation.
·        Spill analysis found in water bodies; thermal behavior of surface water, mapping of algal types and their diffusion, torpidity and color of water, identification of paleoalve.
·        Digital 3D model of surface and ground; topographic profiles, level curves; orthophoto RGB and multispectral area of the area of interest.
Thermal camera TIR ·        Thermal mapping of vegetation and crop anomalies.
·        Identification of areas with greatest fire risk; prediction areas of propagation; ongoing fire analysis.
·        Identification of spills of external material in water bodies; identification of floating or suspended material in water bodies.
·        Locating and mapping zones with thermal anomalies or differentials in landfill areas.
·        Creating georeferenced thermal video with database creation in GIS environment.
High-Res Video camera ·        Creating video insights of phenomena and objects in inaccessible, dangerous areas. Creating geo-referenced videos with database creation in GIS environment.
GAS Sensor ·        Measurement of the quantity of certain GASs for the determination of air quality.
·        Control the air quality during and after a fire in the areas adjacent to the event. Prediction of propagation areas during a fire.

In the table above, applications of an aerial thermographic survey for environmental monitoring were reported, and we have previously reported the utility of correlating the multispectral data to a surface temperature evaluation of some objects and surfaces of interest. In fact, in the field of environmental protection, the applications of the RPAS thermal relief are numerous and in continuous exploration:

  • It is possible to detect on the soil or in a forest any variation of temperature useful for the botanical or vegetative study of the species, and above all, to the prevention of fires and their propagation
  • Water infiltration can be detected in landslides, rainwater can be monitored and remediation operations can be monitored.
  • It is possible to detect thermal anomalies in free, woody or cultivated soils for the study of soil composition, to identify the coordinates of certain areas for possible geotechnical, geodynamic and geoelectric operations.

 

The RPAS thermographic survey has important application and development in the landfill areas, especially if the thermal orthophoto can be correlated with a multispectral orthophoto so as to associate to each pixel and thus to every small portion of the ground radiometric information thermal and multispectral.

The joint multispectral survey, as well as to identify and map the presence of hydrocarbons in the soil, serves to define and characterize the causes of the detected surface temperature differences.

 

In conclusion, by referring them to the reference environmental theme, below are the measurements and information that can be obtained by means of a survey conducted by SAL Engineering using MAIA optionally matched to a thermographic sensor:

Water quality Monitoring of eutrophic phenomena in water bodies such as mucilage, harmful algal blooms, chlorophyll content, suspended phytoplankton analysis or floating material analysis.
Identification and identification of drains in water bodies.
Soil quality Estimate organic content in the soil; identification and classification of minerals and metals in the soil.
Identification and mapping of underground or natural anthropic structures.
Hydrology, climate, agrometeorology Estimation of volumetric variations of glaciers; monitoring of frontal and periglacial areas.
Classification of phenological status of crops.
Mapping of nitrogen requirements in crops.
Estimating the water needs of crops.
Estimation of real and potential evapotranspiration.
Monitoring soil moisture.
Evaluation of damage from extreme atmospheric events, such as horns or air trumpets.
Dams, lamination basins Measurement of sediment volume.
Evaluation of the impact of the tax on water bodies downstream of the operations: assessment of torpidity, volumetric assessment of sediments.
Conservation of ecosystems Monitoring of vegetation remediation.
Monitoring of natural ecosystems.
Monitoring and prevention of peat fires.
Monitoring the phytosanitary and phenological status of natural vegetation.
Construction sites Estimated volumes of lands and rocks moved.
Monitor environmental impacts on natural vegetation and verify the correct restoration of the site at the end of the work.
Air quality Measurement of air quality parameters near industrial plants and landfills.
Geological instability Plano-altimetric survey of landslides, even on vertical walls.
Monitoring of infiltrations and water circulation within rocky bodies; identification of cracks, faults.
Avalanche Mapping areas of avalanche and estimating accumulation volumes.
Quarries Estimates volumes captured at predefined timeframes.
Verification of the correct restoration of the decommissioned quarries.
Landfills Inspection of preliminary excavations; Insulation control and waterproofing and anti-infiltration.
Checked volumes and volumetric estimates.
Locating and mapping the percolation and multispectral analysis of the percussion physico-chemical composition.
Identification and analysis of biogas emissions from RSU dumps.
Identification of abusive landfills by analysis of alterations in vegetation or in surface soil.