Quote from: Coastal Ron on 05/28/2024 05:46 am..However VR is not really related to the topic of artificial gravity, since VR can also be used in zero gravity situations, and VR does not really mitigate the negative physical effects of reduced or zero gravity.I suspect I drowned my point in my enthusiasm. I edited my post down to make sure I was only responding to how an AR treadmill would be applied to the problem of this thread, which I understand to be primarily about answering human unknowns like gravity needed for bone mass, tolerance to small radii etc.I think Im on to something. The volume of a Dragon 2 is enough. You could do it in two F9R launches, and only a single launch for following missions.
..However VR is not really related to the topic of artificial gravity, since VR can also be used in zero gravity situations, and VR does not really mitigate the negative physical effects of reduced or zero gravity.
Not sure if we know how long an experiment needs to run before we find out the effects of artificial gravity..
...
Quote from: KelvinZero on 05/28/2024 08:24 amQuote from: Coastal Ron on 05/28/2024 05:46 am..However VR is not really related to the topic of artificial gravity, since VR can also be used in zero gravity situations, and VR does not really mitigate the negative physical effects of reduced or zero gravity.I suspect I drowned my point in my enthusiasm. I edited my post down to make sure I was only responding to how an AR treadmill would be applied to the problem of this thread, which I understand to be primarily about answering human unknowns like gravity needed for bone mass, tolerance to small radii etc.I think Im on to something. The volume of a Dragon 2 is enough. You could do it in two F9R launches, and only a single launch for following missions.Ah, OK, my bad. Not sure if we know how long an experiment needs to run before we find out the effects of artificial gravity, but this idea does have the appeal of using a great deal of existing hardware and capabilities.Perhaps the next step is to see if there are any estimates for how long artificial gravity experiments would need to run for humans, or how long they would need to run for smaller animals (supervised by humans)?
Quote from: Coastal Ron on 05/28/2024 05:50 pmNot sure if we know how long an experiment needs to run before we find out the effects of artificial gravity..Final point.. you could also plug larger hab modules into the exact same design. If the Dragon version could handle 1g you would not even need to make it redundantly large for a much larger dedicated hab to test mars gravity.
Just to be clear though, you wouldn't do this experiment to test for 1G, because we already know that humans can survive in 1G.
That said, I don't think Dragon would produce useful results for human health. The time-on-orbit (even assuming extra work is done by SpaceX to extend it) is just too short. You could expand the tiny sample size by including animals, but the time-on-orbit is still being to be limited to a few weeks at most.
Wikipedia claims https://en.wikipedia.org/wiki/Crew_Dragon_Endeavour stayed in orbit attached to ISS for 200 days.
For the two launch scheme the dragon would also be docked to something else, the counterweight module, which could supply the lifesupport somehow.[...]..or it could just be a preliminary mission before attaching a full hab.
I suspect that the necessary additions to allow Dragon to remain on-orbit for long periods without being docked to a station would effectively be a full hab (single module station). All Dragon is providing is the pressure vessel, which is not the difficult part. So the engineering might be easier if you just bite the bullet and add a dedicated hab.Essentially, you are adding parts until you reinvent VAST.
A lengthy trip to Mars, which exposes astronauts to a combination of cosmic radiation and weightlessness, could result in permanent kidney damage, according to a new study. It's the largest analysis to date on how spaceflight affects kidney health.
This webinar was kinda interesting:-Steve Hoeser (Moderator) - Senior Technical Advisor, Beyond Earth Institute-Donna Roberts, MD, MS - Deputy Chief Scientist, ISS National Lab-Dr. Dana Levin - Chief of Space Medicine, Vast Space-Gary Hudson - President, Space Studies Institute-Dr. Ted Hall - Extended Reality Software Developer, University of Michigan
But the big question continues to be, who would pay for such research?
adventure tourism/fun. Think finely-clothed celebrities and CEOs sitting down to a chef-cooked dinner <cue close-up shot of red wine swirling in a glass at Mars-G> before sitting down for a private Ed Sheeran concert for 30 people.
Quote from: mikelepage on 06/17/2024 02:09 amadventure tourism/fun. Think finely-clothed celebrities and CEOs sitting down to a chef-cooked dinner <cue close-up shot of red wine swirling in a glass at Mars-G> before sitting down for a private Ed Sheeran concert for 30 people.That's not "adventure tourism" as it's usually meant. It's usually intended to mimic the idea of being an "explorer" or "pioneer", not to just be yet-another-luxury-resort. Especially high-value adventure tourism; around-the-"world" yacht races, mountain-climbing, crossing the pole(s), etc etc.
Quote from: Paul451 on 06/17/2024 08:16 pmQuote from: mikelepage on 06/17/2024 02:09 amadventure tourism/fun. Think finely-clothed celebrities and CEOs sitting down to a chef-cooked dinner <cue close-up shot of red wine swirling in a glass at Mars-G> before sitting down for a private Ed Sheeran concert for 30 people.That's not "adventure tourism" as it's usually meant. It's usually intended to mimic the idea of being an "explorer" or "pioneer", not to just be yet-another-luxury-resort. Especially high-value adventure tourism; around-the-"world" yacht races, mountain-climbing, crossing the pole(s), etc etc.Agreed, but I’m not sure there’s a separate name for what I mean. One difference between ascending Everest, and James Cameron going to the bottom of the Marinara trench is that - I don’t think - Cameron had to do any physical endurance training to operate the sub. Presumably you don’t actually have to be near the limits of human capacity for it to count as an adventure.
I think the other confounding factor is that almost all the places that remain unexplored these days are so because they tend to be pretty inhospitable places. If there was a module containing a luxury restaurant at the top of Everest, or the bottom of the sea, it would still be adventure tourism if getting there was still an adventure. Is “luxury adventure tourism” a category? Retrace the great explorations of history, but with good food, hot showers and great entertainment to while away the boring parts Going to space would be the adventure part, and staying at the partial AG space station would be the luxury/exclusive/fun part.
Adventure travel is a type of tourism, involving exploration or travel with a certain degree of risk (real or perceived), and which may require special skills and physical exertion.
I think Tim Urban in wait but Wait but Why column said it well almost eight year ago: the intersection between those who want to go and those who can afford the cost.https://waitbutwhy.com/2015/08/how-and-why-spacex-will-colonize-mars.html/3This will be true for gravity testbeds as for Mars.
Quote from: mikelepage on 06/21/2024 03:13 amThe reason I don't like the punctuated gravity idea is that it presumes that biomedical problems are the only ones we're solving with spin G.Constant (or near-constant) spin G of some sort will save money by removing the necessity to redesign for microgravity, every machine or process which deals with any kind of fluid. The initial upfront investment is dwarfed by the ongoing development costs of not doing it. Plus, non-medical human factors issues are going to be the long pole in getting the general public to actually *want* to settle space.The caveat there is that the rotation or spin system then becomes a critical system element. If the structure has to be spun down or rotation stopped, then those acceleration-dependant systems either need a microgravity-operation fallback mode (that incurs the costs you are trying to avoid), or a redundant microgravity backup system to be carried anyway.
The reason I don't like the punctuated gravity idea is that it presumes that biomedical problems are the only ones we're solving with spin G.Constant (or near-constant) spin G of some sort will save money by removing the necessity to redesign for microgravity, every machine or process which deals with any kind of fluid. The initial upfront investment is dwarfed by the ongoing development costs of not doing it. Plus, non-medical human factors issues are going to be the long pole in getting the general public to actually *want* to settle space.