Naperlou, bigger is better...but not always. The Nokia phone was probably not available when the project was put together. And the more photosites you cram onto a tiny imager the lower the light sensitivity. That's a big tradeoff. The available real estate for the imager in a cellular handset is rather small. If your chassis is a full size DSLR camera or shoulder mounted video camera you have the room for a much larger imager and much large optics. The photosites can be much larger affording far more photon energy collected per pixel.
Without resorting to a strobe or a puny LED camera light a DSLR can produce excellent photos in light way too dark for a cell phone camera.
While single chip video cameras are becoming more and more popular with some even appearing in professional equipment, the workhorse cameras still utilize three chips for best color rendition and uncompromized sensitivity.
BTW, cell phone imagers are typically CMOS. The older but still very popular imager technology for professional video is the CCD. But ironically they often develope hot stuck pixels due to cosmic radiation damage. How long do you suppose a CCD imager could survive in earth orbit before the imager would be pockmarked with hot pixels?
This is a project that could have been done by a University, not a serious government program. Considering we already know how to put cameras in space, this is a waste of effort and tax dollars. I am ashamed of our government for supporting and funding such a program. And to think they try to play it off like it only cost 3500 dollars. What a joke:
1. We paid people to do this (they could have been doing something useful)
2. We paid to have a rocket send it to space.
3. We paid to have a bunch of people involved in the launch and logistics
4. Does this device even have thrusters to keep it in position, or does it just spin around and take picutures randomly?
5. What happens when the battery runs out after a few hours, or days.
6. We all wasted time reading this article and commenting on it. LOL
I suspect that because the phones were manufactured such that they could be sold in the EU that they would be lead free. Lead free and vacuum don't mix. My guess is that tin whiskers would bring them down within a month. This is in addition to the radiation hardening needed.
I, too, echo the congratulations on the team from NASA sending a set of smart phones above the atmosphere. Yes, the phones seemed to work just fine for the short while they were in space on the sub-orbital hop. NASA loves to impress the public and why not? This kind of innovation does need to be fostered. It's the quirky things that sometimes shake things up to get something better on its way. Cheap space? Perhaps cheap...er
It's a very different story if you need to loiter on orbit for years at a time like most satellites do. Radiation harm is cumulative. You just can't simplisticly think "Oh, it worked this time. Why don't we just orbit our smart phones instead of paying big contractors (who know a lot about what works and what doesn't) to build something unnecessarily expensive." Radiation hardening is VERY necessary if you want months instead of hours of operation. Play the odds, sure, but the expensive ride up to orbit alone (or even just the human cannonball ride from Wallops) is justification enough to invest in making sure all systems work. One failure can turn profit and good science into another object for the space junk database. There's no one floating around on orbit to reboot the smart phone when Android decides to have one of its many "bad days" even while sitting on my desk at sea level. True, this story's smart phone(s) lasted just long enough.
Sounds like someone ought to research how to make radiation hardening cheaper? Not many commercial applications for radiation hardened chips today, but if as an old man I take that famed "Pan Am" Kubrick flight to orbit (2001: A Space Odyssey), I'd like to keep my cell phone apps going without interruption. :)
I wonder if they recovered the payload and how well the phones worked when they came back?
In a bid to boost the viability of lithium-based electric car batteries, a team at Lawrence Berkeley National Laboratory has developed a chemistry that could possibly double an EV’s driving range while cutting its battery cost in half.
Using Siemens NX software, a team of engineering students from the University of Michigan built an electric vehicle and raced in the 2013 Bridgestone World Solar Challenge. One of those students blogged for Design News throughout the race.
Robots that walk have come a long way from simple barebones walking machines or pairs of legs without an upper body and head. Much of the research these days focuses on making more humanoid robots. But they are not all created equal.
For industrial control applications, or even a simple assembly line, that machine can go almost 24/7 without a break. But what happens when the task is a little more complex? That’s where the “smart” machine would come in. The smart machine is one that has some simple (or complex in some cases) processing capability to be able to adapt to changing conditions. Such machines are suited for a host of applications, including automotive, aerospace, defense, medical, computers and electronics, telecommunications, consumer goods, and so on. This discussion will examine what’s possible with smart machines, and what tradeoffs need to be made to implement such a solution.