ENVI

ENVI® image analysis software is used by GIS professionals, remote sensing scientists, and image analysts to extract meaningful information from imagery to make better decisions. ENVI® can be deployed and accessed from the desktop, in the cloud, and on mobile devices, and can be customised through an API to meet specific project requirements. This includes lidar data.

ENVI

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ENVI Modules Available:

Feature Extraction (FX)

Find and extract specific objects of interest from all types of imagery with the ENVI® Feature Extraction Module (ENVI® FX).

DEM Extraction Module (DEM)

The ENVI® DEM Extraction Module (ENVI® DEM) is used to quickly and easily create spatially accurate DEM’s from geospatial imagery.

Atmosphere Correction Module (ACM)

Remove atmospheric interference from imagery with ENVI® Atmospheric Correction Module (ENVI® ACM).

Photogrammetry

Register imagery to ground coordinates and geometrically correct them to remove distortions that happen during image capture with the ENVI® Photogrammetry Module.

The National Imagery Transmission Format (NITF)

Read, edit, and deliver NITF files using the ENVI® NITF Module, certified by the Joint Interoperability Test Command (JITC).

Crop Science

ENVI® Crop Science analyses spectral and spatial data within imagery to provide extensive crop health information.

Interactive data language (IDL)

ENVI Analytics across the ArcGIS Platform

Harris is a platinum business partner with Esri and together we provide solutions for GIS users. ENVI analytics can be executed from within any ArcGIS environment and results can be accessed directly from ArcMap or via ArcGIS Online.

ENVI Opticalscape

ENVI Opticalscape generates Digital Surface Models (DSM’s) and orthorectified images from spaceborne and UAV data while giving users the industry leading tools for imagery preparation and data fusion. Modules available:

ENVI Opticalscape

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Modules Available:

UAV Module

Opticalscape UAV processes multiple stereo images to create orthorectified mosaic images while correcting for sensor orientation. The DSM generation is based on the most advanced algorithms and automated ortho image mosaicking. To facilitate the image orientation, images must include a coarse platform position, however, attitude data are not mandatory.

Spaceborne Module

Opticalscape Spaceborne processes optical stereo and tri-stereo images acquired from satellites for the generation of DSM’s and ortho images. The DSM generation is based on the most advanced algorithms and takes into account new sensor characteristics.

Fusion of Opticalscape and SARscape Products

High-resolution spaceborne or UAV DSM’s can be ingested into SARscape Interferometric Stacking module to derive precise land displacement maps. Opticalscape and SARscape fuse DEM data generated from SAR and optical sensors. This data fusion is unique to ENVI Opticalscape and greatly improves the accuracy of the DEM product. Futhermore, the fusion considers the sensor characteristics rather than simply averaging the different heights (top).

ENVI SARscape®:

ENVI SARscape® allows you to easily process and analyse SAR data acquired from all existing spaceborne and selected airborne platforms. Generate products, and integrate information with other geospatial products.

ENVI SARscape®:

ENVI SARscape® allows you to easily process and analyze SAR data acquired from all existing spaceborne and selected airborne platforms. Generate products, and integrate information with other geospatial products.

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Modules Available:

ENVI SARscape Basic

The ENVI SARscape Basic Module includes processing functionality for generating airborne and spaceborne SAR products based on intensity and coherence. This is complemented by a multi-purpose tool, which includes a wide range of functions – from image visualisation, to DEM’s import and interpolation, to cartographic and geodetic transforms.

The Basic Module provides automated pre-processing tools that allow you to quickly and easily prepare your imagery for analysis and visualisation. With the Basic Module, the following processing capabilities are supported:

Accessory modules

Focusing module

The Focusing Module generates complex images (SLC) based on a ‘ω – Ҡ’ frequency domain algorithm. Support for: RS-1/2 SAR, JERS-1 SAR, ENVISAT ASAR and ALOS PALSAR-1 data

Gamma and Gaussian filter module

The Gamma and Gaussian Filter Module includes a variety of SAR-specific filters, extending the range of filters of the Basic Module. Algorithms for this module are based on Gamma and Gaussian distributed scene models. They are particularly efficient in reducing speckle noise while preserving radar reflectivity, textural properties, and spatial resolution, especially in strongly textured SAR images.

Interferometry

This module enables the generation of DEM’s (insar technique) and surface deformation maps (dinsar technique). State-of-the-art methodology, applied to data acquired from SAR sensors, generate accurate (up to a vertical resolution of few meters) and detailed surface and terrain height products. The dinsar technique can detect centimeter-scale displacements over time spans of days to years. The interferometry module is applicable in geophysical monitoring of natural hazards like earthquakes, volcanoes and landslides. It is also useful in structural engineering, particularly for the monitoring of subsidence and structural stability.

Interferometric stacking module

The Interferometric Stacking Module integrates point-based (PS-like) and area-based (SBAS-like) techniques for the processing of interferometric stacks. This combined approach enables users to obtain accurate results on both point and distributed targets.

Accessory modules

Persistent Scatterers (PS)

Enables users to detect very small displacements (mm scale) and to infer the deformation velocity – and its variation over the time – in particular for very stable (man-made) reflectors that might have independent displacements in respect to the surrounding areas.

Small Baseline Subset (SBAS)

A complementary method that exploits Differential Synthetic Aperture Radar interferometry (difsar) techniques to analyse stacks of SAR acquisitions to extract small deformations over large areas, when no point targets are identified but large, correlated displacements occur over natural targets.

By combining these two approaches, it is possible to analyse deformation phenomena that affects both extended and localised structures related to natural or man-induced phenomena.