Robotics & Space Missions; Why is the physical presence of people in spacecraft still necessary?

Question

Robotics is now well developed. Many programming languages allow you to work in real-time. Also, a new era of space missions and research is in full swing.

So here's the question: Why is the physical presence of people in spacecraft still necessary?

Answer 1

Between them, Spirit and Opportunity spent the equivalent of 22 years performing geology fieldwork on Mars. In that time, they managed a scientific output comparable to what a single geology grad student could do in two weeks.

Between them, Luna 16, Luna 20, Luna 24, and Chang'e 5 returned about 2.3 kg of material from four sampling sites. Neil Armstrong, in 20 minutes of work, collected over 20 kg of samples from a variety of sites.

Having a human on site greatly speeds the decision-making process and permits far more work to be done.

Answer 2

One of the most important reasons is that robots don't make great interview partners.

A significant part of space missions is outreach and inspiring people. Another important part is giving people a different view of our planet. Astronauts over and over again describe the awesome feeling of being able to see how small and fragile our planet is, and the feeling of seeing borders and differences disappear. You can only get first-hand accounts like this from humans, not from robots.

Another important part is: because we can. Humans are naturally curious, naturally adventurous, and natural born explorers.

There is also the political component, to prove that we can and "they" can't. (Insert various values for "we" and "they" to your liking.)

Especially for missions further out, where latency starts to become a problem, another important trait is that humans can improvise, be creative, make judgement calls, and make spontaneous decisions in unforeseen circumstances.

Lastly, the human body is an insanely engineered all-round machine. There are lots of robots that can do one specialized thing or a small number of very narrow specialized things better than a human. But there is no robot which can do everything a human can do even remotely as good.

Answer 3

Why is the physical presence of people in spacecraft still necessary?

Because robotics and AI aren't so developed as to totally replace humans (who are very versatile).

Having said that, there are lots of robotic space probes and landers, but not too many people in space.

Answer 4

Necessity

Why is anything "necessary"? Who gets to define that? The biological imperative, if you will, is to survive, reproduce, and exploit every niche. Look all over the planet, and you will see that living systems have done exactly that, to a degree well beyond human engineering. If space is a new niche for humans, especially other planets, then why shouldn't humans populate and exploit that environment? From this view, you could say it is as necessary as extremophiles living on undersea thermal vents or inside rocks hundreds of meters below the surface, at a metabolic rate so low it may take thousands of years for them to reproduce just a few times. Nobody has written up a TODO list that demands life fill these niches, and yet, here we are...

Redundancy

We take it for granted that planet Earth will be available as our home for as long as we care to think about the prospect. However, the way we are living right now makes it clear that this is an unreasonably optimistic presumption. Making space habitable seems like a pretty smart way to hedge any bets about our future as a species.

Also, if it turns out that we are not alone in the galaxy, and a hostile alien race visits our planet, the odds are that we will not be able to defend ourselves. At that point, our only hope will be that enough of us escape to the stars to rebuild elsewhere, or seek help.

AI

Suppose we develop a super-intelligent AI which decides for itself to expand beyond Earth and into the stars. Surely such a being will build robots and do things the smart way, right? Perhaps. But why doesn't such a being exist already, when we have petaflops of computing power available to us? One reason is that while our robotic (and computing) technology is incredibly advanced, our biological technology is even more advanced. Those petascale machines operate with electrical budgets measured in megawatts. And they offer roughly the same scale of raw computing power as your little 3 pound brain, which sips a mere 20 W of energy. The next time someone calls you a "dim bulb", you should say: "I sure am! But look at all this dim bulb can do!"

When Curiosity or Spirit or Opportunity suffer a malfunction or failure, scientists just try to make do with whatever systems are left working. The name of the game is as much redundancy as we can afford, and limited expectations for usable service life. The official mission duration for Curiosity was 2 earth years. If humans could only offer 2 years of useful working life, we would consider that an utter failure.

If a super-intelligent AI wants to travel the stars, why would it not use the best technology available? That technology is not offered by Boston Dynamics, as impressive as their offerings have become. The only truly adaptable, self-healing, energy-efficient, high strength-to-weight ratio nanotechnology exploration machines we have available today are humans. That super-AI will immediately recognize that DNA-based life is the pinnacle of nanotechnology and energy efficiency, and will build its endeavours around that technology. Humans may only be the starting point for what such an AI would send out into the stars, but I find it to be an infinitely more likely starting point than mere robots.

Answer 5

Even if robots were still used for most of the fieldwork (which I think is likely even with a human presence because spacesuits, and the humans inside them, are fragile and expensive), having a human in a habitat nearby would be a great advantage for scientific research. Due to communication delays and often the lack of a stable radio connection, near real-time teleoperation is difficult on the Moon, and impossible on Mars. Controllers usually have to send commands out and wait for a response, sometimes for a long time, and that limits the productivity of the rovers, and the ability to quickly just go back a bit and inspect that interesting rock they just passed. Materials can also be shipped back to the habitat for further analysis, meaning rovers can be cheaper and lighter by removing a lot of the onboard laboratory instruments. A damaged rover could also limp back to base for repairs, further extending their productive life and reducing the need for expensive overengineering and redundancy.

The future is not going to be humans doing all the fieldwork currently being done by robots, but a human presence allowing the robots to be a lot more productive, reliable and flexible.

Answer 6

Why is the physical presence of people in spacecraft still necessary?

The physical presence of people on most spacecraft is not necessary, not even those rated to carry passengers. Having humans doing the exploring in person is mostly aspirational rather than actual; most space exploration has been done remotely, using probes of varying complexity and autonomy. Most objectives would not have been possible to reach successfully had astronauts been included.

It was never really a matter of choice; there is enormous enthusiasm and commitment to using astronauts within space agencies as well the wider community. More than that, it can be an explicit Agency/Company objective. However, leaving out the astronauts greatly simplifies any mission and increases the available payload dedicated to instruments - and also allows probes to be used to destruction; return capability remains optional. Doing it without people having to come along extends the reach of our space exploration.

Probes and robots will remain the mainstay of space exploration - Landers, with and without sample return capability for Moon, Mars and (sort of landers) for asteroids, orbital mappers, flyby's. Missions that do include the physical presence of people will be missions that mandate that presence.

Answer 7

Speed of light

For Mars, at its closest point it takes 3m 22s to get a signal one way. We would need another 3m 22s to see what's happened. At its furthest we're looking at 24m each way. So good remote control is basically impossible.

We don't have good AI yet, so we only have three options for craft we send out into space. They can be pretty dumb and just send back data (e.g. Voyager); or they can carry out a single high-risk well-planned operation (e.g. Hayabusa); or they can be sent a series of very small operations, waiting for the round trip of getting the command there and seeing the results before moving to the next operation (Mars rovers). In the latter case they may only spend a few minutes a day actually doing anything, and the rest of the time is spent waiting for radio signals to go backwards and forwards.

If you have a human on site, all of this is avoided. Even if the human stayed in orbit, they could still accomplish orders of magnitude more work with the same rover.

Answer 8

There is a serious advantage to being able to make complex decisions, perhaps even moral decisions, on board the spacecraft without any lag due to the speed of light. For the sake of argument, imagine a robotic emissary encounters life on the nearby Jovian moon Europa, which immediately offers some kind of complex moral test to determine whether they will interact with us (or our emissary) and requires an answer within minutes. We would currently only be able to handle such a situation with any hope of success by sending humans to Europa, as the round trip time for radio comms is 1.5 hrs. While I'm not saying there is complex life on Europa, there might be similarly complicated situations that arise far from home.

Answer 9

While robotics has made huge strides, robots have not even approached surpassing many of the basic general-purpose abilities of humans equipped with suitable tools, and the potential for robots to actually do that does not belong to the field of mechatronic engineering or controls theory , but to the wild dreams and nightmares of "futurists".

(It is worth noting that, even as fairly "general purpose" robots have been invented, I do not believe that any "general purpose" robot has ever been launched on an uncrewed space mission).

(This is also the reason why, even though modern warfare is heavily dominated by armor, artillery, aircraft, and guided missiles, infantry are still very important and no modern military has seriously proposed an exclusively robotic force.)

Humans have a great deal of sensory ability (with heavy redundancy, so as to be able to maintain significant sensory ability even when impaired) and locomotion ability (once again, with heavy redundancy, such that a human with a disabling injury can still often be pretty effective in ways that robots rarely are). While the size and weight of a habitation module capable of supporting a crew for months are formidable, the ability to repair damaged equipment, maintain things that would otherwise need to be designed for ultra-reliability at high cost, set up and operate non-automated equipment which may even be commercial-grade, etc is simply not matched by robotics -- we don't have the ability to build robots that can do that for any size, weight, or cost.

A man, an EVA suit, and 50kg worth of tools are simply not something that robotics is anywhere near rivaling. This is then massively compounded by the intelligence / teleoperation issue mentioned by other answers.

Answer 10

Apart from everything else that's been mentioned: many times, one of the questions that the mission is trying to answer is "how well can humans do X in space" for some value of X. It should be reasonably obvious that you need some humans in space in order to answer such questions. NASA's website currently lists some 249 such experiments (plus 40 "title not found" ones), from "BP Reg (A Simple In-flight Method to Test the Risk of Fainting on Return to Earth After Long-Duration Spaceflights)" to "Wearable Monitoring (Wearable System for Sleep Monitoring in Microgravity)". None of these experiments could be done by any means other than putting humans in space.