Tiny satellites ushering in a new space revolution
bloomberg.comThat is a pretty cool engineering feet. Never knew a shoe box sized telescope can give such detailed pictures.
They have sent about 200 satellites, cost "six figures" each, so an estimate of 200,000 a piece, they have spent about 40 million dollars, excluding the price of launches.
The data collected is definitely worth the price IMO. Imagine the ability to monitor storms and hurricanes, analyze their data and update our climate models.
They have about 80 million in funding alone, which is incredible.
I wonder what else is possible with so many eyes in the sky.
Another way to track animal and eventually bird migrations when resolution is high enough. Better coverage of large scale disasters, think earthquake and your mentioned hurricanes, but also fires in remote areas and possibly detection of avalanches. Perhaps even revealing ancient civilizations that haven't been identified yet? There is a lot of area on this planet not of interest and not extensively photographed to where its generally available.
Global surveillance networks.
"Google/Facebook: Please step outside and look up for 10 seconds to verify your identity"
This does seem reminiscent of some Bond movie: some young company/genius supposedly wants to save the world via a fleet of satellites tracking all sorts of environmental issues, a company called Planet (a logo written in greenery in their office). Then it turns out there's actually a nefarious reason for all this, like total surveillance of everybody etc.
I'm not sure if this includes the Skylabs-TerraBella launches?
Skylabs had seven high-res SkySat satellites that Planet got via acquiring Skylabs/TerraBella complementing its existing fleet of medium res satellites.
Planet’s existing network could only get three to five meter resolution, while Skybox’s satellites could manage “sub-meter" accuracy.
80 million in funding seems low. The price of the Skybox/TerraBella acquisition from Google alone had to be in the hundreds of millions.
There was substantial uncertainty about the cost of TerraBella's acquisition, see https://techcrunch.com/2017/01/25/google-satellite-planet/ which says "We’ve not heard a firm price. Aside from the $300 million figure we heard, another described Terra Bella as essentially being “donated” to Planet."
As of April 2015, Planet had raised $183M according to https://techcrunch.com/2015/04/13/planet-labs-rockets-to-118...
feet?
That sounds very scary to me. If they don't care whether a single satellite is working or not, they are basically asking Kessler syndrom to start within years. Multiple start-ups (etc.) and the article covers not even have a tiny bit about what happens at the end of life of the satellites, what could go wrong ...
The other comments that are replying to you have it fairly accurate. It's not widely known but it isn't a secret either: the point of the doves is to be deployed en masse and with more capability with every subsequent build. A quick refresh in the constellation means there is fresh hardware in space every so often.
This means the intention is indeed for re-entry into the atmosphere after the operational lifespan of the dove has lapsed. (They physically stay in space only a few years depending on altitude, orbit, exposed atmospheric drag and a couple of other things)
The last two flocks alone have put close to 130 sats in space so the debris issue is something that is taken quite seriously at the company.
Source: I work at planet. I generally lurk on HN but I created an account just now to reply to this :)
EDIT: Relevant blog post from a couple years ago - https://www.planet.com/pulse/keeping-space-clean-responsible...
It seems Planet currently only relies on passive de-orbiting, how long are sats expected to stay in orbit? And are active de-orbiting options being considered?
Between 6 months and 4 years ideally. 25 years max. If you can't prove reentry within 25 years in simulations you do not fly on the rocket at all in the first place.
Unrelated and probably a stupid question -- but I am curious. What would these satellites see if they looked the other way - i.e. Outwards towards space. Would they see just darkness? Some stars? Lots of stars? Would you know?
I'd hazard a guess at probably not a lot. The onboard telescopes and cameras are likely calibrated to look at and focus on specific sized patches (say 15km by 15km) of the earth between certain altitudes (say LEO distance + -450m to 9000m).
Turning them to look outwards might just capture something if it happened to be inside the size of patch and whatever the telescope/camera combo can focus on (which would be the LEO distance plus or minute a bit). But space is big, even at 500km above the earth, so the likelihood of finding something in your field of view such as another satellite is probably quite low. Stars and other astronomical objects might be too dim/out of focus.
[Disclaimer: not a rocket scientist]
I don't work for Planet but I know the doves have a space-looking camera that is used to help understand the satellite's orientation based on the location of stars in the image.
It sounds like you're relying on the satellites de-orbiting and burning up in the atmosphere.
Are there any steps taken to ensure the satellites de-orbit in a timely manner? Are there any estimates on how many of the satellites will de-orbit and when, absent such an intervention?
Anything in LEO will de-orbit unless you actively keep it there, due to atmospheric drag. This is like watching someone drop a ball and asking if they are taking any steps to ensure it will fall.
Obviously, but how long does that take, and is that long enough that collisions are negligibly probable?
It's possible that the problem will take care of itself, but the information provided is not adequate to model the problem and prove that the problem will take care of itself.
It's a Bloomberg article, not an intro to astrodynamics. If you know the orbit you can figure out when it will decay relatively accurately.
I'm not asking the Bloomberg article, I'm asking the person who works for the company who responded upthread.
This is simply ignorant of the plans. Firstly, there are levels of functionality, being able to provide service being the highest one. Out of service satellites are still most likely to be able to execute a controlled re-entry. Secondly, these satellites will be in low Earth orbit. If they become completely inoperable they have an orbital lifetime of only a few years before they re-enter. Only with routine station keeping maneuvers can they stay in orbit for even their sub-decade planned lifetimes. So there's very little risk of a Kessler syndrome type situation developing. At any given time the number of derelict satellites in orbit would be quite small if not zero.
> Out of service satellites are still most likely to be able to execute a controlled re-entry
How? By a burn? That's a lot of fuel reserve to use up.
It takes minimal energy to deorbit from LEO. By changing the shape of the orbit you spend some time in denser atmosphere which increases drag which quickly deorbits you. Controlled just means they start the processes at a specific time.
How much reserve fuel does an out of service satellite need to use after it burns up in Earth's atmosphere?
How much fuel do you imagine it takes a satellite to re-enter if it will happen automatically in a matter of a few years?
The answer to both is, of course, not much, not much at all.
You don't have to worry too much about the low Earth orbit (LEO) sateillites as they will deorbit soon enough. My understanding is that there is also ongoing research into methods to deorbit them at end of life.
In the case of a Kessler syndrom event it remains a concern. Collisions will push some debris higher while causing other pieces to enter early. The result would be a debris cloud that persists for decades even in LEO.
From first principles, I'm not seeing how a LEO collision pushes a significant amount of debris notably higher, but I'm certainly missing something:
Post collision, all debris orbits will still be passing through the point of collision. Any deflection with a vertical component (up or down towards the earth) will have a part of their orbit go through thicker atmosphere, which will make them deorbit faster. That leaves deflections which are in the plane spanned by the two orbits ("sideways" and "forwards/backwards"). If those deflections in any way slow down the piece of debris, that will also go through lower atmosphere and deorbit.
Disregarding debris under those effects, the remaining debris will have two more things going for it: They'll be out of the LEO orbit for a large part of their (now elliptic) orbits, and they'll be smaller so they'll slow down more from friction (due to the square-cube law).
Of course, cascading effects could still affect all satellites in LEO (and humanity's access to orbit for years), but it doesn't seem to me like it'd be a "permanent" issue in LEO? What am I not seeing?
When collisions are more frequent than once per orbit you get effects where more than one collision cause a bit of debris to have itself lifted. MOST debris is deorbited, but a small fraction is lifted into a higher orbit overall. As these collide with other objects the total mass of the system might go down (from reentry), but the number of objects and the frequency of collision goes up, continuing the process of some objects getting into higher energy orbits.
This is not too dissimilar to the process of evaporative cooling in a liquid, or gas escape from an atmosphere.
> more frequent than once per orbit
My gut feeling says that statistically, even just going from one impact to two impacts being likely would require an immense density of satellites, let alone having more collisions than that.
Then there's also the fact that every impact would have a loss of kinetic energy (because it gets converted to heat as the objects deform), which would also make a reduction in orbit likely.
If the debris keeps fragmenting, which maybe could increase odds of impact, the remaining kinetic energy would be divided over each object. The smaller the debris gets, the more drag it should feel too, because of the square-cube law[0]. So that too would only make it more likely to deorbit.
Not how orbits work. A collision can't cause, for example, an object with a circular orbit at 400km (passive reentry regime) to become fragments with a circular orbit at, say, 2000km (non-passive reentry regime.) Like snaily said, all fragments originating from a collision will still pass through the point of collision, which, if it is still in the upper atmosphere, will lead to reentry. Orbital debris is actually very dissimilar to gas escape.
Multiple collisions. Multiple.
The proportion of fragments that would have their orbits boosted, through multiple collisions, to an orbit higher than the upper atmosphere, is trivial. Nearly every angle of collision between two objects in orbit lowers their periapses. The risk of Kessler Syndrome doesn't come from objects in upper-atmosphere orbits somehow getting boosted out through collision chains, it comes from collisions between objects already in higher orbits not strongly affected by atmospheric drag (>600km).
It can me infinite collisions. It does not matter. Conservation of momentum still applies. The system of collisions only have a finite amount of energy. And it's chaotic rather than engineered. So it's not cumulative, much more likely to happen at numerous different angles cancelling previous collision trajectories out.
Maybe this is a good time to bring up the European Space Agency film about space debris [1].
[1]. http://www.esa.int/spaceinvideos/content/view/embedjw/484820
I took a tour of their SF office last year. It's a pretty impressive operation. The satellites are indeed quite small; I always compare them to a loaf of bread with some wings. The people that work there are pretty sharp and seem to be very excited about what they do.
I was one of the first people to consume their v0 and v1 APIs to get their analytic imagery dataset. It was more challenging than it should have been to transfer ~100TB into our compute cluster. I haven't touched their API in about 7 or 8 months, but from my last meeting with them they said they have eliminated my top pain point. Looking forward to seeing more great things from them.
There's a lot more to do in remote sensing, but I think your comment that there's an API for looking at the world is perhaps the more accurate way to describe the power of this moment in technology history. It is a great feat Planet has accomplished.
Agree a lot more is possible with remote sensing. I worked with it in ag in 80's and 90's, the biggest problems were:
1. Price was to high for the value we could offer
2. 40% chance we wouldn't get a usable image of the field due to cloud cover
3. Its one data point, you can see a problem but can't always figure out what's wrong.
I'm really hopeful for drones that can operate below the cloud cover and AI that can take bare soil images, tile maps, soil tests and provide a more intelligent answer for fixing the problems.
What the farmer wants is a prescription with a shot at a decent ROI.
This is a good Embedded.fm podcast episode interviewing one of the professors that was key in starting the trend of small satellites.
What's the best way for someone to get involved in space hardware?
Materials Science. Tinkering with off the shelf hardware (even start with RaspberryPis). Systems Integration (legit systems integration, not the shitty title Accenture/Deloitte/Generic Consulting Company gives you for working at an Enterprise client). FPGAs. Electrical Engineering. Thermal Engineering is huge. or the usual: Software Engineering. (because satellites need software too)
Any of the above to name a few
Engineering degree; willingness to work in Defense (to cut your teeth)
Kindly can someone tell me how these snall satellites are able to remain in orbit. Don't we need jet propulsion to have them stay in orbit and not fall into earth? I don't much about satellites.
Not really. Once something is in orbit, it's just going to naturally stay in orbit unless acted on by an outside force. That's just basic inertia.
There is some amount of atmospheric drag in low earth orbit which will eventually cause satellites at that altitude to lose speed and fall back to earth, but that drag is small enough that the satellites should be able to remain in orbit for years without needing any additional thrust.
The way it works is that the satellite has very high velocity tangent to the earth- so they are constantly falling to earth, but they are moving tangent at the same rate that they are falling- because the earth is a sphere, the ground "falls away" from underneath them. They're constantly "missing" the Earth.
The moon doesn’t need any propulsion to stay in orbit around the Earth. A satellite is just a very small and very close moon. The fact that it’s closer than the moon just means that it will orbit faster than the moon does.
This article is in desperate need of a r/spacex-style bullet point summary.
Yes, a tl;dr would be very much appreciated if anyone were to have the time and inclination.