Extremely dense point clouds (10+ pts/m²)ĭo you want to have a more detailed of your buildings? In that case you will certainly need a higher point density to capture all the details. 5-10 pts/m² can be enough in order to capture the basic shapes of a building. High density point clouds (5-10 pts/m²)ģD city modelling is one of the examples where a high point density will be required in order to capture the details of buildings.
They might not be dense enough for 3D building modelling but can certainly be used to be post-processed and analyzed to derive new products.
Very often a compromise between point density and cost of acquisition, these data sets are suitable for satisfying most usages. This can be enough for flood modelling applications where even river and streams can be detected under forest canopies. Low density point clouds (1-2 pts/m²)Īt this point density the point spacing constitutes between 0.7 and 1m. Subsets of these point clouds (either based on return number or classification) are used to create surface layers like the digital terrain model (DTM), digital surface model (DSM), normalized height model or the canopy height model used in forestry applications. Point clouds with such low point densities are normally collected for large scale digital height models. Bear in mind that technologies are evolving fast and even today a trend towards denser point clouds can be observed in many of these applications. A higher point density will have a lower point spacing and therefore reveal more features in the point cloud than sparse data.īelow a few common point densities and how they are being used. While there might be various considerations for picking a certain point density, the level of detail that needs to be visible in the data set will be at least limiting the minimum point density. Knowing about the nominal definition of point density, the obvious next question is: where do I need which point density? The point density requirement of a project will be a major factor contributing to the overall cost of a LiDAR project. Such layers can come from multiple passes over the project area, flying with an overlap of over 50% as well as multiple channels or multiple sensors on a single collection platform. By combining multiple layers of points the point density within an area will increase accordingly. One major advantage of LiDAR data compared to aerial photographs is that different datasets can be merged into a unified point cloud.
The specifications mentioned within cover everything from definitions, data collection to data processing for the final deliverables.ĭownload the LiDAR Base Specifictions from the USGS website Aggregating Point Clouds This document published by the USGS is frequently referred to when talking about LiDAR. Looking at the three sample patterns below one can clearly see that especially the Triangle and Sine pattern will have higher point densities at the edges of the swath than in the center.Īs a result, the same USGS document specifies to only use what they call the usable part (typically the center 95 percent) of a swath for evaluating the point density of a LiDAR data set. Including all returns of an emitted beam obviously increases the observed point density in areas where multiple returns occur.Īnother factor that affects the distribution of points is the scanning pattern created by different sensors.
Using only one return per emitted signal allows to verify that the laser scanning system performed as required by the project specifications.
#Arcmap point density how to
Many projects refer to this document when specifying the point density requirements as it details exactly how to interpret the point density of a dataset.Īmong other things, the document defines that only last-returns shall be considered when evaluating the point density of a dataset. The United States Geological Survey has published their highly detailed standards regarding LiDAR surveys. When evaluating the NPD, it is always important to have a common understanding about which group of points to include in the assessment. When planning a survey mission it is therefore generally referred to the Nominal Point Density (NPD) or respectively to the Nominal Point Spacing (NPS). As always, there will be a lot of factor influencing the actual point density of the final LiDAR dataset.