okay thanksWWGD said:I have never heard of anything remotely Mathematically reasonable that reads like that statement; specifically , the expression " Non-contradictory Abelian group" has no meaning I am aware of.
tylerfarzam said:in the tv show "The Big Bang Theory", Sheldon wrote a book called "A proof the algebraic topology can never have a non self-contradictory set of abelian groups". Is this just a random set of words that is meant to sound smart but in reality means nothing or is it accurate? If it is, what does it mean. I looked it up and someone said it was the first option but they didn't explain why.
I can see where your coming from but the question is not wether he was right or not, but if that is just a collection of words meant to sound "smart" or not. So I was asking if that collection of words make sense and if there is even such a thing as "self- contradictory abelian groups in algebraic topology".PeroK said:All the maths and physics in that show is authentic, so I was surprised by this. I haven't seen that episode.
From what I found on line, he wrote that paper when he was 5 years old. And, the joke is that as an adult he cannot accept that even as a five-year-old he could have been wrong about anything.
Yes.tylerfarzam said:if that is just a collection of words meant to sound "smart" or not
Okay thank you. That is all I was asking.fresh_42 said:Yes.
As already mentioned: "non self-contradictory set of abelian groups" is rubbish. A set cannot be "contradictory" and "algebraic topology" is just a branch of mathematics which probably sounds sophisticated in the ears of common people. Well, it actually can be sophisticated and Abelian groups play a role in there, but not as a subject of investigation, only as a quality of some groups there.
Yes, where this binary operation obeys certain rules.Rohan said:Quite likely:
"A proof that algebraic topology can never have a non self-contradictory set of Abelian groups".
is rubbish; but shouldn't we start from the term , " set of Abelian groups". ?
(I have recently got up to here in my attempt to understand modern mathematics
so as a beginner please correct me if I am not understanding !)
- A group is just a set, for which an operation eg * is defined
Those do not obey these rules in general. Better think of the multiplication of non zero numbers, or invertible square matrices.(I like to think of the multiplication of square matrices !)
Yes, that is one way to define it.-ordinary groups have the properties of (a)closure (b) associativity (c)identity (d)inversion and
Again, not in general. Matrix multiplication is "far more often" not commutative, as it is commutative.-an "Abelian group" is just a group with the additional property of (e) commutation ( eg A x B = B x A for square matrices)
Almost all.Thus " a set of Abelian groups", could mean a set of these, now sets can famously contain all kinds of things.
This certain set is excluded for a set if properly defined. Thus, and even for pure linguistic reasons, the term "contradictory set" doesn't make sense. It simply does not say in what the contradiction lies. E.g. we can talk about self-contradiction of a system, i.e. a set of rules which when applied create a contradiction. This demonstrates the next reason why "contradictory set" is nonsense: A contradiction means a conclusion leads to ##true = false##, and a set per se cannot do this. Only its elements, so they are conclusion laws can do this. Abelian groups are no rules, and I've never heard of a binary operation on rules, let alone a commutative. One might be able to construct such a thing, but even then, the specification "Abelian groups" is far too general. And on top: neither of these things has anything to do with algebraic topology.I seem to recall one as part of a famous paradox which " was the set of all sets , which do not contain themselves";
which was described as a "contradictory set" ?
No, as contradictory to what is still missing. An abelian group cannot be "contradictory" regardless how many you sample in a set.Thus couldn't the statement "that algebraic topology can never have a non self-contradictory set of Abelian groups";
be interpreted as stating ' all sets of Abellian groups in algebaic topology are contradictory ?'
Of course what this means and whether it is true are well beyond my ability !
That is Russell's Paradox. As understood now, it is not a contradictory set, but a contradictory description of a set. ZF set theory avoids the problem by not allowing "unrestricted comprehension". Unrestricted comprehension is the practice of defining a set by specifying a property without specifying what containing set elements with that property are to be drawn from.Rohan said:I seem to recall one as part of a famous paradox which " was the set of all sets , which do not contain themselves";
which was described as a "contradictory set" ?
Rohan said:Quite likely:
"A proof that algebraic topology can never have a non self-contradictory set of Abelian groups".
is rubbish; but shouldn't we start from the term , " set of Abelian groups". ?
(I have recently got up to here in my attempt to understand modern mathematics
so as a beginner please correct me if I am not understanding !)
- A group is just a set, for which an operation eg * is defined (I like to think of the multiplication of square matrices !)
-ordinary groups have the properties of (a)closure (b) associativity (c)identity (d)inversion and
-an "Abelian group" is just a group with the additional property of (e) commutation ( eg A x B = B x A for square matrices)
Thus " a set of Abelian groups", could mean a set of these, now sets can famously contain all kinds of things.
I seem to recall one as part of a famous paradox which " was the set of all sets , which do not contain themselves";
which was described as a "contradictory set" ?
Thus couldn't the statement "that algebraic topology can never have a non self-contradictory set of Abelian groups";
be interpreted as stating ' all sets of Abellian groups in algebaic topology are contradictory ?'
Of course what this means and whether it is true are well beyond my ability !
Expandingjbriggs444 said:That is Russell's Paradox. As understood now, it is not a contradictory set, but a contradictory description of a set. ZF set theory avoids the problem by not allowing "unrestricted comprehension". Unrestricted comprehension is the practice of defining a set by specifying a property without specifying what containing set elements with that property are to be drawn from.
Rohan said:Quite likely:
"A proof that algebraic topology can never have a non self-contradictory set of Abelian groups".
is rubbish; but shouldn't we start from the term , " set of Abelian groups". ?
(I have recently got up to here in my attempt to understand modern mathematics
so as a beginner please correct me if I am not understanding !)
- A group is just a set, for which an operation eg * is defined (I like to think of the multiplication of square matrices !)
-ordinary groups have the properties of (a)closure (b) associativity (c)identity (d)inversion and
-an "Abelian group" is just a group with the additional property of (e) commutation ( eg A x B = B x A for square matrices)
Thus " a set of Abelian groups", could mean a set of these, now sets can famously contain all kinds of things.
I seem to recall one as part of a famous paradox which " was the set of all sets , which do not contain themselves";
which was described as a "contradictory set" ?
Thus couldn't the statement "that algebraic topology can never have a non self-contradictory set of Abelian groups";
be interpreted as stating ' all sets of Abellian groups in algebaic topology are contradictory ?'
Of course what this means and whether it is true are well beyond my ability !
Algebraic Topology is a branch of mathematics that studies the properties of topological spaces using algebraic tools. It combines concepts from abstract algebra and topology to understand the shape and structure of spaces.
In the show, the character Sheldon Cooper uses Algebraic Topology to solve complex mathematical problems and to understand the universe. He applies its principles to topics such as string theory and quantum mechanics.
Yes, Algebraic Topology is a legitimate branch of mathematics that has been studied and developed by mathematicians for centuries. It has real-world applications in fields such as physics, computer science, and engineering.
While Algebraic Topology is a complex and advanced field of study, it is possible for anyone to learn it with dedication and hard work. A strong foundation in mathematics and abstract thinking is necessary to understand its concepts and applications.
Algebraic Topology has many practical applications, such as in the study of data analysis, robotics, and computer graphics. It is also used in fields such as biology, chemistry, and economics to model and understand complex systems.