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Have I got these properties of matrices correct?

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    Maybe retry C. Just multiply your result by AB.2012-03-04
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    five of your six answers (counting unchecked entries as answers) are correct. One is wrong.2012-03-04
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    $(AB)^{-1}=B^{-1}A^{-1}$2012-03-04

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Your answers are correct, except that C is false. The right side is the inverse of $BA$, because $$(A^{-1}B^{-1})(BA)=A^{-1}(B^{-1}B)A=A^{-1}IA=A^{-1}A=I.$$ But must the inverse of $AB$ be the inverse of $BA$? See if you can find an explicit counterexample.

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    Actually, if the entries of A,B are in a ring, we may only have 1-sided inverses, I think.2012-03-04
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    Sorry, what I meant is that if the entries of A,B are in some ring R, and AB=I , I think we cannot conclude that BA=I.2012-03-04
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    I think you're right if $R$ is non-commutative, but for any commutative ring $R$, the collection of invertible matrices, i.e. $$\operatorname{GL}_n(R)=\{A\in M_n(R)\mid \det(A)\in R^\times\},$$ is a group, so there are always two-sided inverses.2012-03-04
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    @Zev Chonoles: So I cant distribute the $^{-1}$ across A & B....because that is what I did for A..I thought that was a valid operation. Why is my answer for A correct?2012-03-04
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    @John: Your answer for A is correct because $$(ABA^{-1})^3=(ABA^{-1})(ABA^{-1})(ABA^{-1})=$$ $$AB(A^{-1}A)B(A^{-1}A)BA^{-1}=ABIBIBA^{-1}=AB^3A^{-1}$$ You can't distribute a ${}^{-1}$ in general for matrices, unlike the case for numbers (this is ultimately because matrix multiplication is not always commutative). I'm not sure how distributing a ${}^{-1}$ would have come up in problem A though.2012-03-04
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    Downvoter care to explain themselves?2012-03-04
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    sorry i meant distributing the 32012-03-04