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Feature: What we learned from the Binar-1 mission

Feature: What we learned from the Binar-1 mission

In this crossposting from The Conversation, Curtin University PhD student Fergus Downey provides an overview of the Binar-1 satellite mission’s development and re-entry and explains the lessons the team has learned moving forward.

This weekend marked a milestone for Western Australia’s Binar Space Program as its first satellite, Binar-1, lived up to its name.

Binar is the word for “fireball” in the Noongar language spoken by the Aboriginal people of Perth. Binar-1 became a real “binar” as it re-entered Earth’s atmosphere over the weekend. Although the chance of it being seen over Australia was low, with the right amount of luck it would have appeared as a shooting star in the night sky.

Binar-1 was built by a team of PhD students and engineers at Curtin University’s Space Science and Technology Centre. Its mission: a technology demonstration to test whether the innovative design — all systems integrated on a single circuit board at its core — would survive in space.


Although some parts of the mission were not a complete success, owing to some last-minute design changes, that goal was still achieved.

A tiny sky cube

Binar-1 is a 1U size CubeSat, meaning it measured just 10 centimetres across, roughly the size of a lunch box. Don’t let the size fool you  the satellite was packed with microelectronics to optimise its volume for countless future science and education missions.

It was launched from the International Space Station on 29 August 2021 aboard a SpaceX resupply mission and deployed from the station’s Kibō module.


As a “technology demonstrator”, the spacecraft was flying its essential systems for the first time. The lessons learned from its fiery end will prepare the Binar Space Program for the next step: Binar-2, 3, and 4.

A team of scientists in dark crew shirts looking at a screen above their heads
Members of the Binar Space Program watch the live streamed deployment of Binar-1 in October last year. Curtin University

Five major takeaways from Binar-1

Lock down high-level mission objectives at the beginning

From the start of the mission, the team struggled to grasp what was achievable with the time and money available. This cost us valuable time, as redesigns were necessary every time we defined a new objective. Once we realised a technology demonstration was our true target, we could nail what we were trying to deliver.

Be prepared for delays

By having a plan for delays, we can be more agile when it comes to tight launch deadlines. With Binar-1, we assumed our test schedule would stick to the timeline, but this was never likely.

For our next launch, we’ve prioritised which tests we know are essential and which tests we can drop, so we can make better choices when it’s time to meet our deadlines.

A pair of hands in dark gloves working on computing chips
Installing the star tracker camera payload into Binar-1. The star tracker was designed and developed by undergraduates at Curtin University. An improved version will fly on Binar-2, 3 and 4. Curtin University

Test as you fly

One of the challenges we faced was testing our designs in a manner that replicated the satellite’s behaviour in space. It may seem like an obvious lesson — but using the antennas to test your satellite systems, instead of that convenient USB port you had designed it with, makes a big difference.

Prepare for operation throughout the design process

You can’t learn this lesson without actually flying the satellite but we certainly, we’re not as prepared as we could have been for operations.

The number of tweaks to the ground station and command and control processes once our satellite was already flying made it clear that involving the operation plan from an early stage will prepare you for mission success.

Remove as many assumptions as you can

A few too many assumptions were made during the design, which certainly affected the assembly and testing of Binar-1. For example, we assumed the radio module we tested on the ground worked the same as the one we sent to space — but that wasn’t the case, leading to some frantic last-minute changes that eventually meant we didn’t get the images or data we hoped for from orbit.

For our future missions, all assumptions need to be vetted by the entire team to minimise the impact they can have on a mission if the assumptions are inaccurate.

Onward with the mission

The Binar Space Program and the Space Science and Technology Centre are now preparing for their first real science mission. Onboard our three CubeSats will be a radiation material test performed in collaboration with the CSIRO, a software experiment letting the spacecraft make decisions on its own, and a few others designed by undergraduate students at the university.

But the mission’s final piece of science won’t come until it too meets its fiery end it’s our very own attempt to catch a falling star, a tracking system to identify exactly when each of the next spacecraft will become a binar.

Our current spacecraft burn up before they reach the ground, but eventually, we hope to return one of our satellites to Earth in one piece, and this tracking system is just one of many small steps towards this massive goal. If you want to follow along and catch these fireballs with your own eyes in the future, you can read more on the Binar Space Program website.The Conversation

Fergus Downey, PhD Student, Curtin University


Liam McAneny

Liam McAneny

Liam McAneny is a journalist who has written and edited for his University International Relations journal. He graduated with a Bachelor of Arts (International Relations) and Bachelor of Laws from the University of Wollongong in 2021. He joined Momentum Media in 2022 and currently writes for SpaceConnect and Australian Aviation. Liam has a keen interest in geopolitics and international relations as well as astronomy.

Send Liam an email at: [email protected]

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