1) The neutrino detector is evidence that the Sun has exploded. It’s showing an observation which is 36^H^H 35 times more likely to appear if the Sun has exploded than if it hasn’t (likelihood ratio of 35:1). The Bayesian just doesn’t think that’s strong enough evidence to overcome the prior odds, i.e., after multiplying the prior odds by 35 they still aren’t very high.
2) If the Sun has exploded, the Bayesian doesn’t lose very much from paying off this bet.
Can you explain that more clearly? It seems that the sun exploding is so unlikely that the outcome doesn’t matter. Perhaps you are confusing odds and probability?
Because the stupider the prediction is that somebody is making, the harder it is to get them to put their money where their mouth is. The Bayesian is hoping that $50 is a price the other guy is willing to pay to signal his affiliation with the other non-Bayesians.
I’ll bet $50 that the sun hasn’t just gone nova even in the presence of a neutron detector that says it has.
If I lose, I lose what $50 is worth in a world where the sun just went nova. If I win, I win $50 worth in a world where it didn’t. That’s a sucker bet even as the odds of the sun just having gone nova approach 1-Epsilon.
Maybe the ship’s markets are built on Bitcoin and smart contracts with capability-based architectures & automation—they can’t not deliver. (Hey, it’s the future...)
If the Sun has exploded wouldn’t you also feel the heat wave when the neutrino detector has gone off since heat radiation moves at the speed of light? So if you are not feeling/seeing anything it means the Sun hasn’t exploded, right?
No. For example, in a supernova, the neutrinos leave the star a few hours before the light does (since they don’t get slowed down by all the mass in between). That’s why for example we were able to detect SN 1987A’s neutrinos before the light arrived. Similarly, the Supernova Early Warning System has been set up so that astronomers can point their telescopes in the right direction before any of the light gets to us (because we can detect and pinpoint a close supernova from the burst of neutrinos).
Two subtleties here:
1) The neutrino detector is evidence that the Sun has exploded. It’s showing an observation which is 36^H^H 35 times more likely to appear if the Sun has exploded than if it hasn’t (likelihood ratio of 35:1). The Bayesian just doesn’t think that’s strong enough evidence to overcome the prior odds, i.e., after multiplying the prior odds by 35 they still aren’t very high.
2) If the Sun has exploded, the Bayesian doesn’t lose very much from paying off this bet.
Nitpick, the detector lies on double-six regardless of the outcome, so the likelihood ratio is 35:1, not 36:1.
Can you explain that more clearly? It seems that the sun exploding is so unlikely that the outcome doesn’t matter. Perhaps you are confusing odds and probability?
I just want to know why he’s only betting $50.
Because the stupider the prediction is that somebody is making, the harder it is to get them to put their money where their mouth is. The Bayesian is hoping that $50 is a price the other guy is willing to pay to signal his affiliation with the other non-Bayesians.
Because its funnier that way.
I’ll bet $50 that the sun hasn’t just gone nova even in the presence of a neutron detector that says it has.
If I lose, I lose what $50 is worth in a world where the sun just went nova. If I win, I win $50 worth in a world where it didn’t. That’s a sucker bet even as the odds of the sun just having gone nova approach 1-Epsilon.
So, what’s the default clause on a contract for booze for immediate delivery? What makes you think a rational agent will fulfill the contract?
Maybe the ship’s markets are built on Bitcoin and smart contracts with capability-based architectures & automation—they can’t not deliver. (Hey, it’s the future...)
If the Sun has exploded wouldn’t you also feel the heat wave when the neutrino detector has gone off since heat radiation moves at the speed of light? So if you are not feeling/seeing anything it means the Sun hasn’t exploded, right?
No. For example, in a supernova, the neutrinos leave the star a few hours before the light does (since they don’t get slowed down by all the mass in between). That’s why for example we were able to detect SN 1987A’s neutrinos before the light arrived. Similarly, the Supernova Early Warning System has been set up so that astronomers can point their telescopes in the right direction before any of the light gets to us (because we can detect and pinpoint a close supernova from the burst of neutrinos).