 The challenge that we've been faced with is that telescopes are extremely sensitive devices for resolving the finest detail and they're full of moving, vibrating equipment like cryocoolers and motors and pumps. Isolating that vibration is very difficult, both because it's extremely sensitive and because everything on the back of a telescope moves and tips with the telescope as it points to different parts in the sky. So what we've had to solve is the problem that we need. The best vibration isolation that you can possibly get and we need to make one that can be tipped in any orientation and still keep working. We've developed a anti-vibration mount that solves this problem of vibration on the telescope. What's special about it is that it offers orders of magnitude better vibration isolation than anything else that's out there for this application and it does this by using a new design of negative rate springs and those allow it to have an extremely low natural frequency way beyond what you could ever possibly do with a conventional sprung mount and it does this with a new design that allows it to be tipped to any orientation and still keep working. This has been a really interesting project for me because it's been a very difficult challenge that hasn't been solved before and I've been able to come up with a completely new solution that addresses it very, very well and what's exciting is that it is not just astronomy that can benefit from this technology, it's applicable to the wide range of applications, everything from aerospace to medical and everything in between. At this stage what we're looking for is industry partners to help bring this out into the world. That includes either groups interested in licensing the technology or people with applications that have the ability for AVM to help solve their problems or anyone that can help us with feedback on the technology or the implementation or how it might be used best.