Page:Linear Algebra (1882) Tevfik.djvu/20

LINEAR ALGEBRA

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CHAPTER I.

Straight Lines in Algebraic Expressions.

1. The author here desires to say to the reader, that though the present chapter contains nothing new it is yet of unquestioned importance for a clear understanding of the chapters following.

2. If the lines ${\displaystyle AB,NO}$, for example, of a geometric figure are in different directions, and if not only their absolute lengths are considered, but their respective directions as well, it is evident that, though the lengths of these lines are equal, it cannot be said ${\displaystyle AB=NO}$.

3. By the expression ${\displaystyle AB=NO}$, in Linear Algebra and in the science of Quaternions also, it is understood that the length of ${\displaystyle AB}$ is equal to that of ${\displaystyle NO}$, and also that the direction of the line ${\displaystyle AB}$ is the same as that of ${\displaystyle NO}$, that is to say they are either on the same straight line or are parallel to each other in the same direction. But in Numerical Algebra it is the absolute equality of the lengths only of these lines which is understood.

4. In describing a line ${\displaystyle AB}$ for example, if we say the line ${\displaystyle AB}$ or simply ${\displaystyle AB}$ we mean the special line AB which has a determined direction and length. If we write the line ${\displaystyle {\underline {AB}}}$, or simply ${\displaystyle {\underline {AB}}}$, we mean that the lenght alone is considered.

Sometimes I shall write ${\displaystyle N(AB)}$ for ${\displaystyle {\underline {AB}}}$ and ${\displaystyle N(\alpha )}$, for ${\displaystyle {\underline {\alpha }}}$. I shall also write ${\displaystyle N^{2}(AB),N^{2}(\alpha )}$ for ${\displaystyle N(AB)\times N(AB),N(\alpha )\times N(\alpha )}$, or for ${\displaystyle {\underline {AB}}\times {\underline {AB}},{\underline {\alpha }}\times {\underline {\alpha }}}$. In these cases by the letter ${\displaystyle N}$ prefixed to a line will be meant the number of the abstract length of that line.

5. To represent the different lines of a figure with regard to their directions as well as lengths, Greek letters are often employed. For example, if ${\displaystyle \rho }$ is put for the line ${\displaystyle AB}$, so long as the problem is not changed, by this ${\displaystyle \rho }$ is understood the line ${\displaystyle AB}$ which by supposition has a determined length and direction.

6. It is obvious that the lines ${\displaystyle AB,BD}$, having a determined direction and length, the line ${\displaystyle AD}$ will also, necessarily have a determined direction and length; and if in departing from the point ${\displaystyle A}$ after having traced the line ${\displaystyle AB}$ in giving to it its direction and length, we trace ${\displaystyle BD}$ commencing at ${\displaystyle B}$, giving to it also its length and direction, the distance from ${\displaystyle A}$ to ${\displaystyle D}$ will represent the line ${\displaystyle AD}$ with its special length and direction.