Our CubeSat mode is designed to facilitate the creation of low-cost CubeSat-class satellites. Reducing the cost of spacecraft development in this form factor allows spacecraft development efforts to be funded from teaching funds, instead of requiring faculty to seek research funds to conduct this activity. Using teaching funds (instead of research funds) facilitates greater student leadership and involvement, as it reduces the risk of mission failure to the responsible faculty member.
GLOBAL CAPTURE
Our satellites have the capability to photograph any spot on the planet in a matter of hours, covering thousands of square miles in a single sweep.
UNRIVALED CLARITY
Boasting a remarkable 20 cm resolution, our sensors provide 10 times more detail than the closest alternative.
BUDGET FRIENDLY
Thanks to our innovative architecture, our imaging services are exceptionally efficient, offering visuals at a fraction of the cost - 50 times cheaper than traditional systems.
COLLABORATIVE RADAR IMAGING
Using collaborative radar cubesats, we capture multi-angle images for high-resolution 3D maps in a single, efficient pass with rapid large-area coverage.
UNRIVALED CLARITY
Our sensors offer 24/7 imaging globally, in any environment, resistant to jamming and external interference.
ABOUT THE CUBESAT:
Embark on a transformative learning experience with our Space and Satellite Workshop. This initiative is crafted to demystify the complexities of space science and satellite technology. Through hands-on activities, enlightening discussions, and practical modules, participants will traverse the vast universe of knowledge, gaining a deeper understanding of the celestial bodies above and the technologies that propel us toward them.
Once a design is ready, it must be tested in an environment similar to what the spacecraft will experience in space. This involves testing the spacecraft in a wind tunnel or an actual space environment. After this testing, engineers will have a much better idea of how their designs will hold up in space. In addition, this test allows for any necessary design changes before launching the spacecraft. Once testing is complete, it's time to put together a prototype of the spacecraft. This involves manufacturing several copies of parts needed for the spacecraft and testing them individually before assembling them into an actual spacecraft.
Assembling the actual spacecraft is only half of the process; now it's time to send it into space-or at least as far as possible without destroying it. It's important to aim cubesats towards specific areas of space so they can reach their intended destinations. Because these destinations are generally far away from Earth, launch trajectories must be carefully planned as well. After launch, there's no turning back; once in orbit, cubesats are out of everyone's hands and must face the unforgiving vacuum of space on their own.
Building a cubesat is an incredibly complicated process that requires years of research and development. Once finalized, cubesats are easy to build and can be used for many different purposes. Since everything has been done beforehand, all that's left is waiting for launch- and then hopefully understanding how to use your new pet project!
The cubesat kit by OCULLO SPACE was made to make the assembling and coding much easier than traditional way in building a cubesat, the cubesat kit is made and designed for beginners and schools or universities who are developing their 1st cubesat / nanosatellite mission, the module is ready to fly to sub-orbital flight and was tested in microgravity in many similar space missions.
Join us on this cosmic odyssey as we reach for the stars, foster collaboration, and promote a greater understanding of the vast and awe-inspiring universe.
“Together, we'll boldly go where no one has gone before!"