This project is currently seeking funding to improve and update the plugin. If you are a regular user please consider to contact us (https://github.com/tproduit ).

This plugin was initially developed during Gillian Milani's master thesis at EPFL in the LASIG laboratory. It is based on An open tool to register landscape oblique images and generate their synthetic models. T. Produit and D. Tuia. In Open Source Geospatial Research and Education Symposium (OGRS), 2012.

The development was supported by the EPFL, the Swiss National Park. The migration to QGIS3 was performed by Ministère des Forêts, de la Faune et des Parcs, Québec.

Contributors:

• https://github.com/gilliM
• https://github.com/tproduit
• https://github.com/frpin33
• https://github.com/jfbourdon

Comments and questions can be send to: timothee.produit[at]gmail.com

June 2019

The plugin was tested with QGIS 3.12.

OpenGL and piexif are required to use this extension. To install the libraries:

python -m pip install pyOpenGL
python -m pip install pyOpenGL_accelerate
python -m pip install piexif

OpenGL and piexif must be installed from the Python installed for QGIS. For instance C:\OSGeo4W64\apps\Python37

You can download the plugin directly from the QGIS plugin repository.

Plugins --> Manage ans install plugins... --> settings Tab --> Enable experimental plugins....

The goal of the plugin is to provide an interaction between a picture and the map. Hence, the plugin has two main functionalities.

1. The orientation of the picture is computed from 3D Ground Control Points (GCP).
2. The monoplotter provides the interaction between the picture and the map through a Digital Elevation Model.
   • Overlay of vecor layer on the picture
   • Vector layer digitization
   • Orthorectification

The steps to use Pic2Map are the following:

1. Load a landscape picture and the corresponding DEM.
2. Determine the orientation of the camera with GCP
3. Use the monoplotter to project vector data in the photograph or to project the picture on the map.

The original plugin folder contains a dataset for testing the plugin. Copy the data outside the original folder to use it.

A technical introduction video can be found here.

• A picture (png, jpeg, tiff etc.)
• A DEM in tiff format
• [Optional] An orthoimage to render the 3D image and detect GCPs
• [Optional] Vector layer to be overlaid on the picture

High resolution DEM and orthoimage can slow down (or crash) the plugin. Clip the DEM according to the image footprint and try to balance between performance and quality.

Ensure that the layers are in the same PROJECTED Coordinate Reference System

GCP are similar locations clicked in the picture (2D) and in the canvas (3D). A minimum of 6 GCP has to be provided if no information about the camera orientation is available. Each GCP helps to gain precision for the camera orientation.

The GCP can be clicked in the map or in the 3D view with ctrl + left click. The 3D view ease the recognition of similar location, but the map is better to digitize accurate GCP.

The digitization of GCP is an iterative process. Once that a camera orientation is obtained, the digitization of accurate GCP is facilated.

GCP can be loaded and saved as .csv with the and buttons. The headings of the columns are: line,column,X,Y,Z

The GCP digitalization interface is divided in five main areas:

1. The scene
2. The GCP table
3. The GCP toolbar
4. The scene toolbar
5. The 3D toolbar

It is a view of the picture.

You can select a GCP in the table and then click on the scene to provide the 2D coordinates.

• Zoom in the scene

• Zoom out the scene

• Toogle the Pan tool for the scene

• Zoom on the selected GCP in the scene and in the canvas

The two first columns record the 2D picture coordinates.

The three next columns are the world coordinates (East, Nord and altitude).

To fill the table, select a line and click on the scene to get image coordinates. Click on its correspondence in the QGIS canvas to record the world coordinates.

You can also get 3D coordinates from the 3D viewer with ctrl + Left Click.

The fifth column is used to enable or disable a GCP for the pose estimation.

In the last column, you have an indication of the error. It is a measure of the distance between the 3D world coordinate of the GCP and the projection of the 2D GCP on the DEM.

• Create a new line in the GCP table

• Delete the selected line in the GCP table

• Save the GCP table

• Load a GCP table

• Remove the reprojected GCPs after a pose estimation

• Change display setting of GCPs

• Open the pose estimation dialog box

• Open the 3D viewer.

• Close the GCP digitalization window and open the monoplotter

• Show information contain in EXIF

• Save current pose estimation in KML file

• Load a pose estimation from KML file

Information about the motion in 3D viewer:

• Left mouse button pressed: move left-right an up-down
• Right mouse button pressed; rotate on the tilt and azimuth
• Wheel: go front and back (Press wheel for a finer placement)

Information about the capabilites in 3D viewer:

• ctrl + Left Click: get 3D coordinates for selected GCP
• alt + Left Click: fix the position of the camera at the clicked position

The goal of the orientation is to compute the location, the orientation (azimuth, tilt, roll) and the focal of the camera (the field of view or zoom).

If the rough location of the camera is unknown, you can use the Add --> Photo tool of Google Earth. The picture orientation can be recorded as a KML file and loaded with pic2map.

The camera orientation window opens with a click on the button. A camera parameter can be:

• Free: The parameter is unknown and has to be computed. If all parameters are free at least 6 GCPs are required.

• Fixed: The parameter is known, the other parmeters will be optimized.

• A priori: An approximate parameter is provided, the optimization process searches for an optimum around the provided parameters. If an a priori value is provided for each parameter, a solution can be computed with 4 GCPs.

Check the pose estimation by opening the 3D viewer. It is initialized at the computed orientation.

The monplotting interface is reached with the button.

A point or line layer which is visible in the map will be overlaid on the picture if the Refresh Layers button is clicked. The symbology and labels used in the canvas are reproduced in the picture. You can overlay simple, categorized or graduated symbology. However, you cannot use complex symbology, like point represented by stars or double lines representations. You can press on label settings for controlling label appearance.

The monoplotter can be clicked with Click. You can choose to measure objects in the map plane (2D) or in 3D (on the DEM surface).

The measure tool doesn't measure directly in the picture but projects the click of the mouse in the canvas. This implies a strange behavior: if a precise measurement is required, you have to zoom in the canvas.

The layer to be filled has to be active and in edition mode in the canvas. The new feature button is toggled. New points or new line vertices can be directly clicked in the picture with Ctrl+click

If you want to do precise digitization in the picture, you have to zoom at the right place in the canvas.

Each pixel of the picture is linked to a 3D geographic coordinate. The orthorectification uses this information to interpolate the orthorectified picture. The accuracy depends on the DEM and GCP quality. Due to the oblique geometry large errors can be observed in some regions.

The 3D geographic coordinates of each pixel can be saved as tiff images.

This function computes three plots. The first plot shows the surface of a pixel which varies with the distance and the angle of incidence. The two other plots show the angle of incidence.

This function is usefull to choose a good camera location to sense a landscape.

This function generates a vector layer which contains the area sensed by the camera.