The CubeSat is a small but mighty bit of tech. About the size of a shoebox, the tiny satellites were invented by Professor Bob Twiggs in 1999 as an educational tool for students.
“They couldn’t put very much in it, which was the real challenge. It forced them to quit adding things to their designs,” Bob says, laughing.
Quicker and cheaper to build and launch than conventional satellites, there are now hundreds of CubeSats orbiting Earth, made by universities, start-ups and governments.
Here we look at six exciting projects that are trying to change the world…
1: Stopping deforestation
The Norwegian government has partnered with the satellite company Planet, to tackle deforestation around the world.
Planet has a constellation of 180 CubeSats continually taking pictures of Earth. Their cameras have a resolution of 3m per pixel and can pick up evidence of logging from space.
“The Norwegian government has paid for data to track deforestation in 64 tropical countries,” Will Marshall, CEO of Planet says.
“We let the forestry ministries in those countries know where deforestation is happening and Norway then does or doesn’t provide funds to them depending on if they uphold an agreement to stop it.”
2: Tracking endangered animals
Earlier this year, a team of students from Italy and Kenya launched the WildtrackCube-Simba. This CubeSat will monitor birds and mammals in Kenya’s National Park.
“We have had conflicts between humans and wildlife, for example when elephants have invaded farmers crops, damaging the property, and sometimes even killing people,” says Daniel Kiarie, a student engineer in Nairobi.
“So we want to help them prevent that by giving them prior information about the movement of animals, so they can ward them off before they get to the villages.”
- To find out more about these small but mighty satellites, listen to People Fixing the World on the BBC World Service
They plan to fit animals with radio tags next year, which they hope will track more than just their location.
“There’s a common problem of poaching for elephant tusks and rhino horns in Kenya,” Daniel says.
“We think these tags could also look at the heart rate and detect if an animal is killed.”
The CubeSat is on a three-year mission. CubeSats typically last between two and five years before they burn up in the atmosphere, depending on how high they’re launched into orbit.
3: Exposing modern slavery
The Rights Lab at Nottingham University uses satellite imagery to help it delve into the secretive world of forced labour.
It most recently used CubeSat imagery to map the makeshift camps of Bangladeshi fruit pickers in Greece.
“We can see how these informal settlements are changing through time,” says Professor Doreen Boyd, who is leading the project.
“We know when there’s land clearance we’ll see new settlements forming when we look back later.”
The team worked with a local NGO who visited the camps they had found.
“They were able to talk to to the migrants there so they’ve got a lot more information about what’s going on in terms of living conditions… They were able to say: ‘Right we have got 50 informal settlements in this area, how do we prioritise our activity?'”
4: Clearing up space junk
Russia recently caused international outrage when it fired a missile at one of its old spy satellites, sending thousands of pieces of debris spinning out into low-Earth orbit.
Global networks track nearly 30,000 pieces of space junk as they journey around Earth, from defunct satellites to rocket stages. However, there’s far more debris that’s too small to be tracked but is big enough to threaten satellites or astronauts on board spacecraft.
There are lots of issues around clearing up space junk, not least working out which bit of engineering belongs to which nation. However, scientists are one step closer to solving the practical issue of how to catch an object speeding through space thanks to CubeSats. They are using them to replicate rubbish in experiments in space.
In 2018 the European RemoveDEBRIS satellite managed to release and catch two CubeSats using a harpoon and a net.
This year, Japanese company Astroscale launched the ELSA-d spacecraft, which successfully released and caught a CubeSat using a magnetic system. In future tests the CubeSat will be made to tumble like typical space junk, before a recapture is attempted.
5: Fixing wind turbines
There are several fleets of CubeSats working together above our heads to provide a low-cost ‘internet of things’. This network connects people to objects tagged with sensors in remote locations all around the world.
Some farmers use sensors to keep an eye on water levels in far flung animal troughs or storage towers, saving them having to check in person.
They can even be used to make renewable energy more efficient. Wind turbines are generally visited twice a year for maintenance, so if a blade is damaged, it can be months before it’s discovered and fixed.
A company called Ping Services has created a sensor that monitors the sound made by wind turbines as they rotate. It can pick up a change in this sound which indicates a damaged blade, and relay this back to the turbine operator via a CubeSat network. This means they can be fixed much quicker, and be more efficient.
6: Exploring deep space
While most CubeSats look inwards towards Earth, a handful are being pointed towards the stars.
In 2018, Nasa launched the first CubeSats into deep space. MarCO-A and B relayed vital information back from the Insight Lander as it descended on to Mars.
Next year, Nasa will launch 10 more CubeSats on its Artemis 1 rocket. Missions include testing the effects of deep space radiation on a living organism and studying water deposits at the lunar south pole.
They are all part of a programme that one day hopes to land humans back on the moon.
Listen to People Fixing the World from the BBC World Service https://www.msn.com/en-us/news/world/the-shoebox-sized-satellites-that-could-change-the-world/ar-AAR0T2L?fbclid=IwAR1uwEmpqhNDxNVVSy_9xQooPNxPf7O8W8t_3v2CLL62iaKrEkh8pnM2lqwhere.
A Shoebox-Sized Satellite Could be the Future for Space Tech
NASA Funds Shoebox-Size Space Satellite From Berkeley Students
This intrepid team at UC Berkeley hopes to launch a quantum CubeSat into space, and they already have NASA’s funding.
When a college senior approaches graduation, they traditionally write a final thesis, co-author a paper, or even give a talk at an academic conference, but when Paul Köttering graduates from the University of California, Berkeley, he hopes to launch a satellite, in 2021, according to UC Berkeley’s blog.
RELATED: TINY SATELLITES ARE THE FUTURE OF SPACE EXPLORATION
Berkeley students’ final test is satellite launch, courtesy of NASA
While shelter-in-place requires many throughout the world to stay home throughout the coronavirus epidemic — Köttering is riding out the rest of the semester from the comfort of his parents’ home in London — he and his team of UC Berkeley undergraduates are holding Zoom video conferences every week, to prepare for the forthcoming launch of a shoebox-sized experiment: to test novel navigation technology for satellites, based on research conducted on campus.
In February of this year, NASA declared it’d cover the launch costs — upwards of $300,000 — via the CubeSat Launch Initiative, which was developed to fly small experiments as auxiliary payloads on nominal rocket launches.
Building the shoe-sized CubeSat satellite
However, to build the satellite itself, the UC Berkeley team is trying to raise $15,000 via crowdfunding, and also campus’ Big Give campaign, and is looking for donated equipment from several manufacturers. The team has already received a $4,950 grant from the UC Berkeley Student Technology Fund.
“The NASA grant is just for the launch, so we have still got to supply and manufacture the satellite ourselves,” said Köttering, now a junior and majoring in applied mathematics and physics. “Luckily, the cost of CubeSats has dropped significantly over the past three to four years. The communications systems, power systems, control systems — a lot of those are just off-the-shelf, commercial parts, so they are quite cheap. The payload itself is the more expensive item, but again, a lot of that comes from in-kind donations from companies.”
Known as QubeSat (short for quantum CubeSat), the Berkeley team’s satellite will test a new kind of gyroscope based on the quantum mechanical interactions that happen in imperfect diamonds. The diamond gyroscope was first invented at Berkeley, in the laboratory of physicist Dmitry Budker, professor of the graduate school.
The undergraduate team behind the QubeSat is also part of an undergraduate aerospace club called Space Technologies at Cal (STAC), which has already flown experiments with help from balloons and the International Space Station — magnificent for a group that’s only four years old. Some of the intrepid team’s graduates have moved on to work at world-historical aerospace companies, like Boeing, SpaceX, and several others. https://interestingengineering.com/nasa-funds-shoebox-size-space-satellite-from-berkeley-students