Can the 'Determinant' be Reversed for 2-by-2 Matrices?

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In summary, there are 4 equations that can be formed from the given matrices A and B, and these equations can be solved for the variables a, b, c, and d. This allows for w, x, y, and z to be represented solely in terms of a, b, c, and d. Furthermore, the determinant of A can also be used to determine the solutions for a, b, c, and d.
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scikidus
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Let there be a 2-by-2 matrix A with the elements:

[a b]
[c d]

Now, let there be a 2-by-2 matrix B with the elements:

[w x]
[y z]

Let A*A = B.

This means that w, x, y, and z can all be independantly represented solely in terms of a, b, c, and d.

My question: is there any way for a, b, c, and d to be represented solely in terms of w, x, y, and z?
 
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  • #2
Well, multiplying A*A out, you have a2+ bc= w, ab+ bd= x, ac+ cd= y, and bc+ d2= z. Now it is a matter of solving those 4 equations for a, b, c, and d.
Those are quadratic equations so there will be more than one solution - as you might expect from the fact that A*A= B is really "quadratic" itself.

Now, my question is, What does this have to do with the "determinant"?
 

What is the "determinant" in scientific terms?

The determinant is a mathematical concept used to describe the properties of a matrix. It is a numerical value that represents the scaling factor of the matrix and determines whether the matrix is invertible or not.

What does it mean to "reverse" the determinant?

Reversing the determinant means finding the inverse of a matrix. This is done by using mathematical operations to transform the original matrix into its inverse, which when multiplied together, will result in the identity matrix.

Why is reversing the determinant important?

Reversing the determinant is important because it allows us to solve systems of equations, find the area of a parallelogram or triangle, and perform other mathematical operations that require the use of matrices. It is also used in fields such as physics, engineering, and economics.

What are some common methods for reversing the determinant?

There are several methods for reversing the determinant, including the Gauss-Jordan elimination method, the cofactor method, and the adjugate matrix method. These methods involve different mathematical operations and can be used depending on the type and size of the matrix.

Are there any limitations to reversing the determinant?

Yes, there are some limitations to reversing the determinant. For example, not all matrices have an inverse. A matrix must be square and have a non-zero determinant in order for it to be invertible. Additionally, the process of reversing the determinant can be computationally intensive for larger matrices.

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