This driver provides a way to view MrSID/MG4 compressed LiDAR file as a raster DEM. The specifics of the conversion depend on the desired cellsize, filter criteria, aggregation methods and possibly several other parameters. For this reason, the best way to read a MrSID/MG4 compressed LiDAR file is by referencing it in a View (.view) file, which also parameterizes its raster-conversion. The driver will read an MG4 file directly, however it uses default rasterization parameters that may not produce a desirable output. The contents of the View file are described in the specification MrSID/MG4 LiDAR View Documents.
MrSID/MG4 is a wavelet-based point-cloud compression technology. You may think of it like a LAS file, only smaller and with a built in spatial index. It is developed and distributed by LizardTech. This driver supports reading of MG4 LiDAR files using LizardTech's decoding software development kit (DSDK). This DSDK is freely distributed; but, it is not open source software. You should contact LizardTech to obtain it (see link at end of this page).
The simplest way to view an MG4 file is to wrap it in a View (.view) file like this. Here, the relative reference to the MG4 file means that the file must exist in the same directory as the .view file. Since we're not mapping any bands explicitly, we get the default, which is elevation only. By default, we aggregate based on mean. That is, if two (or more) points land on a single cell, we will expose the average of the two. There's no filtering here so we'll get all the points regardless of classification code or return number. Since the native datatype of elevation is "Float64", that is the datatype of the band we will expose.
<PointCloudView> <InputFile>Tetons.sid</InputFile> </PointCloudView>
This is similar to the example above but we are using the optional ClipBox tag to select a 300 meter North-South swatch through the cloud. If we wanted to crop in the East-West directions, we could have specified that explicitly instead of using NOFITLER for those. Similarly, we could also have cropped in the Z direction as well.
<PointCloudView> <InputFile>Tetons.sid</InputFile> <ClipBox>505500 505800 NOFILTER NOFILTER</ClipBox> </PointCloudView>
Here, we expose a single band (elevation) but we want only those points that have been classified as "Ground". The ClassificationFilter specifies a value of 2 - the ASPRS Point Class code that stipulates "Ground" points. Additionally, instead of the default "Mean" aggregation method, we specify "Max". This means that if two (or more) points land on a single cell, we expose the larger of the two elevation values.
<PointCloudView> <InputFile>E:\ESRIDevSummit2010\Tetons.sid</InputFile> <Band> <!-- Max Bare Earth--> <Channel>Z</Channel> <AggregationMethod>Max</AggregationMethod> <ClassificationFilter>2</ClassificationFilter> </Band> </PointCloudView>
Here we expose an intensity image from the point cloud.
<PointCloudView> <InputFile>Tetons.sid</InputFile> <Band> <!-- All intensities --> <Channel>Intensity</Channel> </Band> </PointCloudView>
Some point cloud images include RGB data. If that's the case, you can use a .view file like this to expose that data.
<PointCloudView> <InputFile>Grass Lake Small.xyzRGB.sid</InputFile> <Band> <Channel>Red</Channel> </Band> <Band> <Channel>Green</Channel> </Band> <Band> <Channel>Blue</Channel> </Band> </PointCloudView>
This driver does not support writing MG4 files.
Only one <InputFile> tag is supported. It must reference an MG4 file.
The only <InterpolationMethod> that is supported is <None> (default). Use this to specify a NODATA value if the default (maximum value of the datatype) is not what you want. See View Specification for details.
There is insufficient error checking for format errors and invalid parameters. Many invalid entries will likely fail silently.