For myself, I'm not at all assured that the shape of the universe can be compared in any way with the shape of the Earth. The Earth is spherical. If you go far enough in any direction on the Earth, you will eventually return to where you started. But for the same principle to be true about the universe, the universe has to be a "four-dimensional sphere". As far as I can understand, however, astronomers believe that the universe is "flat", so that it does not curve back on itself.flash wrote:Thanks for the assurance. But you can probably tell that I'm not all that assured.GBDB wrote:REST ASSURED: The universe is infinite.
Finite but unbounded is the generally accepted belief. Just as the 2-dimensional surface of a sphere is finite in area (but has no end or boundary), the 3-dimensional volume of the universe is finite (but it too has no end or boundary). I find this analogy most satisfying. Just as flatlanders living on a two-dimensional surface of a sphere, if you go far enough in any direction you will eventually return to where you started.
Having no boundary is not the same thing as infinite.
It can be tested by studying the geometry of space. It's technologically tricky, but perfectly feasible. If space is flat (for instance, the Universe is a hypersphere of infinite radius) then the internal angles of a triangle add up to 180°. If space is concave or convex, the sum of the angles will be slightly more or less than 180°. This is just like you can do on the surface of Earth. If you draw a triangle on the ground, its angles add up to more than 180°, demonstrating that the Earth isn't flat, but is convex. Of course, you need to draw a really big triangle for the difference to be detectible. To test the shape of the Universe, you send out three probes that connect to each other with lasers, and measure the angles between them. They might be millions of kilometers apart- a nice big triangle.BMAONE23 wrote:It would seem to me that Finite but unbounded would be untestable at least to the limits of current technology. Using the 2d model in a 3d reference frame would essentially say that we could in fact travel in any 1 of 3 spacial directions and eventually wind up back here. How could this hypothesis ever be tested?
Um, my tensor calculus is nowaday a little rusty but I think cosmological space curvature effects can't be measure around the solar neighborhood, you'd be swamp by local gravitational noise from the sun and planets.Chris Peterson wrote:It can be tested by studying the geometry of space. It's technologically tricky, but perfectly feasible. If space is flat (for instance, the Universe is a hypersphere of infinite radius) then the internal angles of a triangle add up to 180°. If space is concave or convex, the sum of the angles will be slightly more or less than 180°. This is just like you can do on the surface of Earth. If you draw a triangle on the ground, its angles add up to more than 180°, demonstrating that the Earth isn't flat, but is convex. Of course, you need to draw a really big triangle for the difference to be detectible. To test the shape of the Universe, you send out three probes that connect to each other with lasers, and measure the angles between them. They might be millions of kilometers apart- a nice big triangle.BMAONE23 wrote:It would seem to me that Finite but unbounded would be untestable at least to the limits of current technology. Using the 2d model in a 3d reference frame would essentially say that we could in fact travel in any 1 of 3 spacial directions and eventually wind up back here. How could this hypothesis ever be tested?
I guess we could wait for V'Ger to return.BMAONE23 wrote:It would seem to me that Finite but unbounded would be untestable at least to the limits of current technology. Using the 2d model in a 3d reference frame would essentially say that we could in fact travel in any 1 of 3 spacial directions and eventually wind up back here. How could this hypothesis ever be tested?
It seems to me that If it is not infinite, then either it is has a boundary, or it curves back on itself. (Is there any other alternative?) I can't understand the boundary at all. It's similar to the flat earth concept that if you get too close to the edge you'll fall off. (Or, "What's beyond the edge?") Therefore it must curve back on itself.Ann wrote:For myself, I'm not at all assured that the shape of the universe can be compared in any way with the shape of the Earth. The Earth is spherical. If you go far enough in any direction on the Earth, you will eventually return to where you started. But for the same principle to be true about the universe, the universe has to be a "four-dimensional sphere". As far as I can understand, however, astronomers believe that the universe is "flat", so that it does not curve back on itself.flash wrote:Thanks for the assurance. But you can probably tell that I'm not all that assured.GBDB wrote:REST ASSURED: The universe is infinite.
Finite but unbounded is the generally accepted belief. Just as the 2-dimensional surface of a sphere is finite in area (but has no end or boundary), the 3-dimensional volume of the universe is finite (but it too has no end or boundary). I find this analogy most satisfying. Just as flatlanders living on a two-dimensional surface of a sphere, if you go far enough in any direction you will eventually return to where you started.
Having no boundary is not the same thing as infinite.
That said, I agree with you that the universe may not be infinite.
Ann
The local gravitational field is a source of signal that has to be compensated for, not of noise (which is another word for uncertainty). The mission I referred to is real, although currently suspended for funding reasons.scr33d wrote:Um, my tensor calculus is nowaday a little rusty but I think cosmological space curvature effects can't be measure around the solar neighborhood, you'd be swamp by local gravitational noise from the sun and planets.
It only suggests Ω = 1 with a 0.5% margin of error, which isn't good enough to rule out other geometries. It's a tricky problem, because if the Universe is flat, we may never know that for sure. That's because no matter how good your measurement, all you can tell is that you are very close to zero flatness- there will always be both a positive and negative sign within your error bars.WMAP measurement has good evidence that Ω = 1, i.e. we are in a flat universe.
A flat universe can still curve back on itself. Topology is often rather nonintuitive. While a sphere is not topologically flat, a torus is. Both are compact and finite. Using a sphere to describe the Universe is still useful, because the concept is the same as for flat, bounded manifolds as well... and a lot easier to visualize.Ann wrote:For myself, I'm not at all assured that the shape of the universe can be compared in any way with the shape of the Earth. The Earth is spherical. If you go far enough in any direction on the Earth, you will eventually return to where you started. But for the same principle to be true about the universe, the universe has to be a "four-dimensional sphere". As far as I can understand, however, astronomers believe that the universe is "flat", so that it does not curve back on itself.
Chris Peterson wrote:The local gravitational field is a source of signal that has to be compensated for, not of noise (which is another word for uncertainty). The mission I referred to is real, although currently suspended for funding reasons.scr33d wrote:Um, my tensor calculus is nowaday a little rusty but I think cosmological space curvature effects can't be measure around the solar neighborhood, you'd be swamp by local gravitational noise from the sun and planets.
It only suggests Ω = 1 with a 0.5% margin of error, which isn't good enough to rule out other geometries. It's a tricky problem, because if the Universe is flat, we may never know that for sure. That's because no matter how good your measurement, all you can tell is that you are very close to zero flatness- there will always be both a positive and negative sign within your error bars.WMAP measurement has good evidence that Ω = 1, i.e. we are in a flat universe.
No, not LISA, or any of the space-based gravity wave missions. The mission (I don't recall the name off-hand, or how far it got into the proposal process) was specifically for looking at the geometry of spacetime.scr33d wrote:If you are thinking of LISA, that is a mission for gravity wave detection (unless there is a component of the mission I am not aware of).
I don't think this is true. The local spacetime geometry can be compensated for, because it represents a fixed bias, not noise. For instance, simply by observing the changes with orientation it is possible to separate local and global components of the signal. The real problem is establishing a long enough baseline, not dealing with local effects.Cosmological flatness/curvature is too small a signal to measure directly given that you are around massive objects: I mean WMAP has to use CMB variation distribution to deduces omega--and even then it still (as you pointed out) can't rule out other geometries.
Agh, Chris. Let me dust off and check with my copy of MTW's Gravitation!Chris Peterson wrote:No, not LISA, or any of the space-based gravity wave missions. The mission (I don't recall the name off-hand, or how far it got into the proposal process) was specifically for looking at the geometry of spacetime.scr33d wrote:If you are thinking of LISA, that is a mission for gravity wave detection (unless there is a component of the mission I am not aware of).
I don't think this is true. The local spacetime geometry can be compensated for, because it represents a fixed bias, not noise. For instance, simply by observing the changes with orientation it is possible to separate local and global components of the signal. The real problem is establishing a long enough baseline, not dealing with local effects.Cosmological flatness/curvature is too small a signal to measure directly given that you are around massive objects: I mean WMAP has to use CMB variation distribution to deduces omega--and even then it still (as you pointed out) can't rule out other geometries.
The problem is an engineering one, not a purely scientific one, and I think you are underestimating the engineering capabilities available. What in your references contradicts the assertion that cosmological curvature can't be measured if you can compensate for the fixed bias of local geometry? As I recall, the mission was vetted as scientifically sound, which suggests that there was at least reasonable confidence as to the methodology.scr33d wrote:See chapter 27 of Gravitation, or a short exercise here:
http://www.astro.ufl.edu/~guzman/ast793 ... ect01.html
Cosmological curvature almost by definition can't be measured locally--it is dependent on the energy density of the universe and the cosmological constant. In principal you could do it with lasers and mirrors locally (imagine measuring the curvature of the earth with subatomic scale rulers), but not in practice.
The canceled NASA probe might have been a local spacetime geometry, supernova/distance, or CMB mission?
The Riemann curvature tensor gives, for a homogeneous closed universe and a triangle base of 10^7 Km, an angle deviation of (10^-53)º from 180º. You'd need a millions-lightyear size triangle to have any chance (and you need to be far away from galactic masses too), so triangle-sum measurement of universe geometry belongs to thought-experiment/concept-explanation.Chris Peterson wrote:The problem is an engineering one, not a purely scientific one, and I think you are underestimating the engineering capabilities available. What in your references contradicts the assertion that cosmological curvature can't be measured if you can compensate for the fixed bias of local geometry? As I recall, the mission was vetted as scientifically sound, which suggests that there was at least reasonable confidence as to the methodology.scr33d wrote:See chapter 27 of Gravitation, or a short exercise here:
http://www.astro.ufl.edu/~guzman/ast793 ... ect01.html
Cosmological curvature almost by definition can't be measured locally--it is dependent on the energy density of the universe and the cosmological constant. In principal you could do it with lasers and mirrors locally (imagine measuring the curvature of the earth with subatomic scale rulers), but not in practice.
The canceled NASA probe might have been a local spacetime geometry, supernova/distance, or CMB mission?
I'm motivated now to track down the project details. It wasn't that long ago... I think in the last 10 or 15 years at most.
Ron
