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ArborCarbon is part of the ARC Training Centre for CubeSats, UAVs, and Their Applications

ArborCarbon is excited to be a partner in the new ARC Training Centre for CubeSats, Unmanned Aerial Vehicles, and their Applications. The recently announced Centre aims to develop a world-class Australian expertise in the research and development, manufacturing and commercial application of both CubeSats (small satellites weighing only a few kilograms), and cutting-edge drones equipped with a range of advanced sensors.

These technologies have a wide range of applications, including remote sensing for agricultural and forestry purposes. The Centre will provide exciting opportunities for PhD students to work with ArborCarbon in this area. For more information, please click here, or contact Paul Barber at ArborCarbon.

Cubert and VITO Remote Sensing introduced compact hyperspectral COSI-cam at EGU 2016

 

“Last week during the the European Geosciences Union – General Assembly 2016 (EGU 2016), Cubert, a German hyperspectral camera manufacturer, and VITO introduced the COSI Cam, a high ground resolution hyperspectral mapper.”

See article published on VITO  by Delaur’e Bavo

ArborCarbon in Perth, Western Australian are  distributors for Cubert in Australia and New Zealand.

 

 

 

 

Unmanned Airborne Systems (UAS) or ‘Drones’ – are they the answer for precision vegetation monitoring?

Unmanned Airborne Systems (UAS), Unmanned Airborne Vehicles (UAV), or Drones as commonly referred to, have captured the imagination of people. Their potential applications are almost endless, but are they the most appropriate platform for collection of airborne imagery on vegetation cover and condition.

Screen Shot 2016-04-03 at 3.10.26 pm

Change detection multispectral imagery at 1m pixel resolution acquired from fixed-wing plane. Inset: 1cm true colour imagery acquired using an UAS.

ArborCarbon scientists have been conducting research on the applications of satellite and airborne multi and hyperspectral imagery for more than 10 years. The variety of platforms carrying the sensing device (e.g. camera) include satellite, fixed-wing plane, helicopter and UAS. The range of sensors attached to these platforms include multispectral and hyperspectral imaging devices. ArborCarbon scientists first started using UAS in projects for capturing airborne imagery over vegetation monitoring sites in 2010 and were the first company in the world to do so for vegetation monitoring to determine the potential impacts of groundwater drawdown and alteration of sheet flow on mulga and riparian communities in Australia.

We are very selective about using UAS platforms for the capture of airborne imagery to measure and monitor vegetation cover and condition, including in precision agriculture and measurement of NDVI, as we have a close understanding of all the factors that affect these measurements. The arrival of many new ‘drone’ platforms and cheap multispectral cameras onto the market has certainly raised the profile of remote sensing and its potential application for precision vegetation management. However, there are many times when there are greater costs associated with acquiring data using these platforms due to mobilisation, limitations on battery life, and processing time.

We encourage anybody looking to use remote sensing for precision vegetation monitoring, whether that be for trees, horticulture, agriculture or turf, to carefully consider the range of platforms and sensors available, and discuss these with people who have an unbiased view.