• A soldier prepares to launch a PD-100 Black Hornet Nano unmanned aircraft.
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    A soldier prepares to launch a PD-100 Black Hornet Nano unmanned aircraft. Defence
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In conjunction with the Department of Defence, University of SA material scientists have developed a range of lightweight panels that can change colour on demand, allowing drones to match their appearance to the background colours of the sky.

The Australian Army has drones ranging from the tiny Black Hornet – which is about the size of a whiteboard marker – to larger models with wide ranging intelligence surveillance and reconnaissance (ISR) capabilities. 

Despite their ubiquity and utility, however, all military UAVs are currently hindered by the same simple problem – the sky changes colour, but they don’t. 

Given the huge importance of remaining undetected during ISR operations, the static colour of drones can be a significant problem, but now, thanks to researchers at the University of SA’s Future Industries Institute (FII), the solution is at hand.

In a collaboration with the Department of Defence, FII researchers, led by Dr Kamil Zuber, have developed a range of lightweight polymer panels that can change colour on demand.

The polymers are what are known as electrochromic materials, meaning they change colour in response to an electric field, and the exact colours can be tuned to specific voltages.

“Similar technology has been used in luxury cars, for diming mirrors, and on the windows of the Boeing 787 Dreamliner,” Dr Zuber said. “But those applications are slow, require high power consumption to switch, and the electric flow must be maintained to sustain the change state.

“Our panels, on the other hand, have switching speeds in the range of seconds and offer colour memory, which means they retain their switched colour without a continuously applied voltage.

“They also operate in the range from -1.5 to +1.5 volts, which means you only need to use an AA battery to activate the change.”

In addition to their chameleon-like characteristics, the panels are inexpensive, lightweight and durable, and can be either rigid or flexible, making them ideal for use on drones of all sizes and specifications.

“We have built a small-scale frame of a UAV and put our panels on it. We have demonstrated it against all sorts of different sky states and completed a range of validation testing showing how these materials can respond in actual use,” Dr Zuber said. “We have five or six different materials, and each of the materials can produce two to three distinct different colours.”

The technology is currently being refined to integrate self-awareness and autonomous adjustment into the system, so drones will be able to automatically change colour in response to changes in the surrounding environment.

“At this stage, we’ve been working mainly on the panels and the hardware, but during the latest stage of the project we’ve developed prototype electronics for the controller, which is something that could test the state of the sky and then automatically adjust the voltage to the panel to tune it to the right colour,” Dr Zuber said. “So, if the UAV passed in front of a cloud, it would turn pale, then when it moved back into blue sky, it would turn back to blue.”  

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