Understanding Upper Triangular, Lower, and Diagonal Matrices

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Discussion Overview

The discussion focuses on the definitions and characteristics of upper triangular, lower triangular, and diagonal matrices, exploring their properties and potential applications in linear algebra.

Discussion Character

  • Technical explanation
  • Conceptual clarification
  • Exploratory

Main Points Raised

  • One participant seeks clarification on the definitions of upper triangular, lower triangular, and diagonal matrices.
  • Another participant defines a diagonal matrix as one with nonzero entries only on the diagonal and provides an example.
  • The same participant defines an upper triangular matrix as having nonzero entries on or above the diagonal, also providing an example.
  • A later reply expresses confusion about the utility of flipping matrices around, suggesting it seems unnecessary.
  • Another participant introduces concepts related to the geometry of these matrices, mentioning terms like "Cartan subgroup" and "parabolic subgroup," and notes that strictly upper triangular matrices are nilpotent and serve as counterexamples to diagonalizability.

Areas of Agreement / Disagreement

Participants have not reached a consensus on the utility of manipulating these matrices, and there are varying perspectives on the significance of certain properties and terms related to them.

Contextual Notes

The discussion does not resolve the implications of nilpotency or diagonalizability in relation to strictly upper triangular matrices, nor does it clarify the definitions of lower triangular matrices.

JasonRox
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I know what an Augmented Matrix is, but what is Upper Triangular Matrix(or Lower) and a Diagonal Matrix?

This would help.
 
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A diagonal matrix is a matrix whose nonzero entries lie on the diagonal.

[tex] \left(<br /> \begin{array}{ccc}<br /> 1&0&0 \\<br /> 0&5&0 \\<br /> 0&0&0<br /> \end{array}<br /> \right)[/tex]

An upper triangular matrix is one whose nonzero entries all lie on or above the diagonal.

[tex] \left(<br /> \begin{array}{ccc}<br /> 1&14&0 \\<br /> 0&5&-3 \\<br /> 0&0&0<br /> \end{array}<br /> \right)[/tex]
 
Thanks.

Now, I understand why they keep flipping them around. Seems useless to do that, but I guess that's how its done.
 
matt grime might tell us the geometry, or other special interest of these classes of matrices. i.e. words like "cartan subgroup" or "parabolic subgroup" and so on come to mind...

strictly upper triangular matrices are also interesting because they are "nilpotent" hence counterexamples to diagonalizability.
 

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