[Cumulonimbus]

Before we can consider seeding terrestrial stations on Mars, we should consider seeding a communications net around Mars. Once we have a half dozen satellites circling Mars, we can start stable comms from the surface to orbit to Earth. It may take 10-20 minutes (for a signal to be received), but the communication is the essential piece here.

I'd also consider putting satellites in Earth and Mars lagrange L3, L4, and L5. It's the start of a solar system based internet, even if it is rudimentary. Think of this as a store-and-forward network where signals may be too weak for Earth to pick up, but can hit Jupiter L5 to Mars planet, to Earth L3.

And greetings, all, BTW.

[Robotbeat]

> Before we can consider seeding terrestrial stations on Mars, we should consider seeding a communications net around Mars.

We already do.

> Once we have a half dozen satellites circling Mars...

We already have half a dozen active satellites circling Mars:

https://en.wikipedia.org/wiki/2001_Mars_Odyssey

https://en.wikipedia.org/wiki/Mars_Express

https://en.wikipedia.org/wiki/Mars_Reconnaissance_Orbiter

https://en.wikipedia.org/wiki/Mars_Orbiter_Mission

https://en.wikipedia.org/wiki/MAVEN

https://en.wikipedia.org/wiki/ExoMars_Trace_Gas_Orbiter

All of these (including the European satellites) except the Indian MOM orbiter contain a communications relay radio (for relaying from Mars surface to Earth) provided by NASA: https://en.wikipedia.org/wiki/Electra_(radio)

We actually have quite a bit of infrastructure built up around Mars already. All these spacecraft are referred to as the "Mars fleet" (which is frakking awesome...).

[FLUX-YOU]

>https://en.wikipedia.org/wiki/Electra_(radio)

>Data rates up to 1 Mbit/s

That's a bit of a problem. It only seems to be a relay for other spacecraft and small surface craft. Much more data will need to be exchanged between Earth/Mars when humans are involved (weather, video, entertainment, collected data, software, etc.)

You'd probably want several brand new satellites dedicated to communications for an initial colonial undertaking.

[trey-jones]

If you think about the initial communications infrastructure around North America when Columbus set sail in the 15th century, we've got a leg up.

I realize it's not the same situation, not the same expectations, a different world than 500+ years ago, but real progress doesn't happen in a cleanroom.

[DougWebb]

1 Mbit/s is a problem? This communication network we're currently using started out at just 300 b/s, 3000x lower bandwidth. When speeds got up to 2.4 Kb/s, it really started to take off.

The bandwidth back than was more than adequate to handle a website like Hacker News, and the store-and-forward protocols that were developed back then to preserve bandwidth, like SMTP and NNTP, will probably come back into play for a Mars/Earth link. Any video would need to be highly compressed and low quality by today's standards, but in the 50s and 60s TV was far lower quality than it is today and served its purpose just fine. Audio recordings for voice messages likely would be just fine without any quality reduction.

You have to remember that the initial colonists are going to necessarily be a fairly independent bunch. They're not going to need, or care, to keep up with the latest shows, music, or social media. They'll be too busy with surviving, collecting and transmitting scientific data, and writing letters to their loved-ones back on Earth.

[mikeash]

Once humans get involved, putting up a better communications satellite fleet should be trivial by comparison. You could almost just toss some satellites out the airlock before you start aerobraking. Obviously it would take a little more thought than that, but it certainly wouldn't be the hard part of the whole deal.

[Robotbeat]

MRO does 6Mbit/s.

But indeed, NASA intends much higher bandwidth for future missions using laser communications.

SpaceX would likely use a variant of their constellation satellites which should be capable of multiple Gbit/s using laser communications.

[SEJeff]

Pretty sure this reason in specific is why SpaceX accepted the 1 billion USD investment from Google Ventures for their satellite internet constellation project in Seattle. If Musk's endgame plan is a serious Mars colony, there needs to be both location and communication over the entire planet (of mars). There also needs to be bidirectional communication with Earth. An orbiting constellation makes sense to do this.

https://www.nytimes.com/2015/01/21/technology/google-makes-1...

[Retric]

The important part of mars colonization is being able to produce 100% of all needed goods (from food to CPU's) on the surface of mars, not covering the planet with people. Really 2-3 redundant geosynchronous satellites on mars should be plenty for a very long time.

Musk wants satellite internet as it lets Space X lower cost per launch by launching a lot of satellites.

[monocasa]

> on the surface of mars

Why? Wouldn't it be easier to bootstrap by mining asteroids, and manufacturing in micro gravity, then dropping nearly finished goods onto the planet? That'd also allow you to use the same bootstrapping infrastructure for several surface sites.

[Retric]

Mining asteroids has a ton of issues even beyond the obvious cost and R&D problems. They are generally far from the sun so solar power is significantly less useful. You need to move a lot of bulk material which means heavy Delta V problems. Micro gravity means you can't have humans in the area for long without giant structures. Finally, economically resources are just not that scarce.

The delta V issues are more reasonable when you want stuff to end up in space. But, that's not an issue for a Mars colony. As to mining Mars's moon's they don't really have a lot of useful material that is not on Mars in the first place.

PS: Space X's slightly lower the cost to orbit actually makes Asteroid mining even less viable.

[gorkonsine]

>They are generally far from the sun so solar power is significantly less useful.

No, they aren't. There's tons of asteroids in Earth-crossing orbits. And Mars-crossing orbits too. It'll be a long time before we use those up.

>You need to move a lot of bulk material which means heavy Delta V problems.

No, you don't. You process the ores near the asteroids; you don't have to ship it all to the point-of-use.

>Micro gravity means you can't have humans in the area for long without giant structures.

So what? You don't need a lot of humans there; this stuff needs to be automated (or at least remote-controlled). And artificial gravity doesn't need a giant structure; you can do it with a small structure on a tether.

>Finally, economically resources are just not that scarce.

That depends on what resources, and where you want them. If you want a lot of platinum, it's very scarce here on Earth, but mining one Earth-crossing asteroid could provide a huge amount of it relatively cheaply.

>As to mining Mars's moon's they don't really have a lot of useful material that is not on Mars in the first place.

How do you know that? Mars's moons are really just captured asteroids and likely have no geological relation to Mars at all.

[Retric]

Basically, if you can mine it on earth you can do the same on mars excluding organic compounds.

Anyway, back to your argument. Processing ore is not light weight. Total mass of asteroids inside earths orbit is actually surprisingly low relative to planetary manufacturing needs. Sure the asteroid belt is ~4% of the moons mass, but inner planets have mostly cleared their orbits.

Yea, there are KM sized objects, which might be rich in stuff we want. But consider, Bingham Canyon Mine for example is 0.6 miles deep and 2.5 miles wide and that's just for copper. And even if you processed it all you still need Delta V on 19 million tonnes of copper.

Look at a periodic table. Mines can only really provide you with that stuff. Now exclude the useless elements and the stuff and what's abundant and there really is not a huge niche for asteroid mining. Futher ateriods regularly impacted mars after it had a solid surface so all the same elements are there much like they are on earth.

So, you really need asteroid mining to stand on it's own independent of colonizing Mars.

PS: Artificial gravity only gets you part of the way to dealing with micro gravity You need life support, food, water etc. Spin all that stuff and you need an even stronger tether with a larger counter weight.

[vkou]

Why would you want to manufacture in microgravity? What are the practical advantages of this? I can't think of any, but I can think of a lot of disadvantages of this.

Also, a Mars colony would require millions of tonnes of raw materials. You can only get that in-situ.

[logfromblammo]

I think the largest problem in orbital manufacturing is actually rejection of waste heat. Otherwise, being able to run robots in an oxygen-free environment and move around large masses without conveyors sounds pretty good.

[vkou]

It's also an environment full of cosmic rays, which requires hardening of all your electronics, an environment where fluids don't flow through pipes, an environment where dust and powders don't settle, an environment where conveyor belts don't work because things float off them...

Almost every single industrial process that we have relies on a constant, freely available, predictable, unidirectional acceleration of 9.8 m/s^2.

Imagine trying to build a twenty-tonne steel smelter that will function in orbit - I'm sure working with tonnes of molten steel that won't stay where you put it would be a breeze.

There's also the part where many of our industrial processes are extremely water-hungry. Any kind of space industries would require complete reclamation of all waste water, stream, etc - with a large cooling cycle, to boot. And heaven forbid if the process consumes nitrogen, oxygen, or hydrogen in any appreciable amounts - unlike on Earth, you can't synthesize them in space.

[valuearb]

It's far cheaper to send people to asteroids than Mars. Even those in the belt. And they have trillions of tons of easily accessible raw materials.

[tajen]

> I'd also consider satellutes in Earth/Mars lagrange L3, L4 and L5 (...) solar internet.

If there isn't already a patent on space strategies, it may be a good idea to create a patent agency. The first intergalactic agency.

[TomK32]

Bulding the Network is the best part about KSP, right?