Both proofs are using the same basic idea: if the product of two (square) matrices is I, then the two matrices are inverses of each other.Kuma said:Homework Statement
The proofs:
show (A')^-1 = (A^-1)'
and
(AB)^-1 = B^-1A^-1
Homework Equations
The Attempt at a Solution
for the first one:
(A^-1*A) = I
(A^-1*A)' = I' = I
A'(A^-1)' = I
Kuma said:but I am not sure how this proves that a transpose inverse = a inverse transpose...
the second i have the same problem. Not sure how this really proves what it's asking.
http://tutorial.math.lamar.edu/Classes/LinAlg/InverseMatrices_files/eq0041M.gif
Linear algebra is a branch of mathematics that deals with the study of linear equations and their representations in vector spaces. It involves the use of matrices and vectors to solve various problems in geometry, physics, engineering, and economics.
Proofs in linear algebra are logical arguments that are used to demonstrate the validity of a mathematical statement or theorem. They involve using axioms, definitions, and previously proven statements to arrive at a conclusion.
Proofs are essential in linear algebra because they provide a rigorous and systematic way to verify the accuracy of mathematical statements and theorems. They also help in understanding the underlying concepts and principles of linear algebra.
A simple linear algebra proof involves showing that the sum of two matrices is commutative. This means that the order in which the matrices are added does not affect the result. The proof involves using the properties of matrix addition and the distributive property of multiplication over addition.
To improve your understanding of linear algebra proofs, it is important to have a strong foundation in the basic concepts of linear algebra, such as matrices, vectors, and operations. It is also helpful to practice solving problems and proofs, and to seek guidance from a tutor or instructor if needed.