George Jones said:We don't know how to calculate a sensible value for the cosmological constant (that would be a major breakthrough), we can only measure the value of the cosmological constant. Maybe a more accurate statement would be something like "A so-and-so cosmological model with cosmological constant having value such-and-such is consistent with observations."
This is usually what is meant by "measure" in science. For example, "A model for an electron with electric charge such-and-such is consistent with observations."
George Jones said:As with any theoretical conjecture, we need a model that makes predictions that can be compared with observation. In this case, cosmological models which predict, e.g., observed absolute magnitudes, apparent magnitudes, and redshifts of cosmological objects. Different values for the cosmological constant give different relationships between the these things.
from Geroch said:It seems to me that "theories of physics" have, in the main, gotten a terrible press. The view has somehow come to be rampant that such theories are precise, highly logical, ultimately "proved". In my opinion, at least, this is simply not the case - not the case for general relativity and not the case for any other theory in physics. First, theories, in my view, consist of an enormous number of ideas, arguments, hunches, vague feelings, value judgements, and so on, all arranged in a maze. These various ingredients are connected in a complicated way. It is this entire body of material that is "the theory". One's mental picture of the theory is this nebulous mass taken as a whole. In presenting the theory, however, one can hardly attempt to present a "nebulous mass taken as a whole". One is thus forced to rearrange it so that it is linear, consisting of one point after another, each connected in some more or less direct way with its predecessor. What is supposed to happen is that one who learns the theory, presented in this linear way, then proceeds to form his own "nebulous mass taken as a whole". The points are all rearranged, numerous new connections between these points are introduced, hunches and vague feelings come into play, and so on. In one's own approach to the theory, one normally makes no attempt to isolate a few of these points to be called "postulates". One makes no attempt to derive the rest of the theory from postulates. (What, indeed, could it mean to "derive" something about the physical world?) One makes no attempt to "prove" the theory, or any part of it. (I don't even know what a "proof" could mean in this context. I wouldn't recognize a "proof" of a physical theory if I saw one.)
The cosmological constant is a term in Einstein's field equations of general relativity that describes the energy density of the vacuum of space. It is often denoted by the symbol Λ (lambda) and is a measure of the expansion or contraction of the universe.
The cosmological constant plays a crucial role in explaining the accelerated expansion of the universe. It also has implications for the shape and fate of the universe, as well as the distribution of matter and energy within it.
The value of the cosmological constant can be calculated using a combination of observational data and theoretical models. This involves measuring the expansion rate of the universe, the distribution of matter and energy, and other cosmological parameters.
The cosmological constant has been a subject of intense study in modern physics, as it has implications for our understanding of gravity, quantum mechanics, and the nature of the universe. It also has connections to other areas of research, such as dark energy and the multiverse theory.
One of the main challenges in calculating the cosmological constant is the fact that its value is very small and difficult to measure accurately. There are also discrepancies between different methods of calculation, which highlight the need for further research and refinement of theories.