PIC's in space

[mister_e]

But hey, with 4 years spent on it by Microchip engineers, I doubt they were using Arduino .

That make sense... Perhaps Z80 or 8051?

[rmteo]

Here's one you can actually buy if you have about $300,000 (excluding launch costs) to spare http://www.cubesatkit.com/#

Compared to traditional multi-million-dollar satellite missions, CubeSat projects have the potential to educate the participants and implement successful and useful missions in science and industry at much lower costs.

CubeSat payloads and experiments are often new and unique, and project timelines are typically 9-24 months from inception to launch. Since launch opportunties are scheduled well in advance, it's critically important that a CubeSat project adhere to its schedules and stay on time and under budget.

CubeSat missions still require considerable planning and many man-hours of work to maximize the chances for success. By employing as much standardization as possible you can concentrate on your project's mission-specific goals. By making use of as many off-the-shelf commercial and freely available tools and components in the construction of the nanosatellite, you'll save time and money.

[mister_e]

SuitSat-1 using PIC18F8722
http://www.microcontroller.com/news/...tSat1_NASA.asp

[Ioannis]

I wonder how are the electronics cooled in space. Even the slight temp rise has to be taken into account since there is no heat dissipation in space.

IR maybe?

Ioannis

[mister_e]

IcePaks and Vanilla Ice ... the dairy product... not the rapper

[Charles Linquis]

I can guarantee that some of my hardware designs - and code are orbiting the earth. There are many challenges. For example: Go to DigiKey and
buy a Panasonic lithium cell. Ask them if the cell will work in a vacuum. They will tell you they don't know. If you call Panasonic, they will also tell you
they don't know.
You will find the same thing with most capacitors. You may need a 450uF @ 50V. You can't use electrolytics because they generally can't take vacuum.
Tantalums generally have an MTBF (Mean Time Between Failures) that is too low (at least according to MIL-HDBK 217). The answer is 21 X 22uF ceramic caps
in parallel. Pricey!

And testing isn't always the answer. You can only test a few. What if there is a 10% failure rate of a part when subjected to 5 years of vacuum, and you
have 2 parts (because of price or availability) that you can test for 1 month at most (because of delivery schedules)? Now it isn't just electronics, it is statistics. And what if a part fails during testing? You start all over.

A full-blown military testing sequence (MIL-810, MIL-461, DO-160 etc.) generally costs $50K - $75K. This is the cost for unit #1. If the military wants 4 pieces
of something that doesn't already exist, then testing adds at least $13K to each one.

People are amazed when they find the military spends $500 for a hammer or some exorbitant amount for a part and they get outraged and want their congressman to take action.
I assure you, not all of that is graft and/or corruption.

[rsocor01]

People are amazed when they find the military spends $500 for a hammer or some exorbitant amount for a part and they get outraged and want their congressman to take action.
I assure you, not all of that is graft and/or corruption.

You can probably find that same hammer or a similar one at HomeDepot for $20. The contractors don't necessarily follow the specs all the time. I have seen over the years many overpriced products and projects been sold to the government.

Robert