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nydus/An Introduction to MathematicsPublic
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VII

Here the effect is more complicated, and is best comprehended in the geometrical interpretation to which we proceed after noting three yet more special cases.

Thirdly, we multiply the "real" couple (a,0) by the imaginary (0,b) and obtain (a,0)×(0,b)=(0,ab).

Fourthly, we multiply the two "real" couples (a,0) and (a,0) and obtain (a,0)×(a,0)=(aa,0).

Fifthly, we multiply the two "imaginary couples" (0,b) and (0,b) and obtain (0,b)×(0,b)=(bb,0).

We now turn to the geometrical interpretation, beginning first with some special cases.

Take the couples (1,3) and (2,0) and consider the equation (2,0)×(1,3)=(2,6). 11

In the diagram ([fig.]11) the vector OP represents (1,3), and the vector ON represents (2,0), and the vector OQ represents (2,6). Thus the product (2,0)×(1,3) is found geometrically by taking the length of the vector OQ to be the product of the lengths of the vectors OP and ON, and (in this case) by producing OP to Q to be of the required length. Again, consider the product (0,2)×(1,3), we have (0,2)×(1,3)=(6,2).

The vector ON1, corresponds to (0,2) and the vector OR to (6,2). Thus OR which

represents the new product is at right angles to OQ and of the same length. Notice that we have the same law regulating the length of OQ as in the previous case, namely, that its length is the product of the lengths of the two vectors which are multiplied together; but now that we have ON1 along the "ordinate" axis OY, instead of ON along the "abscissa" axis OX, the direction of OP has been turned through a right-angle.

Hitherto in these examples of multiplication we have looked on the vector OP as modified by the vectors ON and ON1. We shall get a clue to the general law for the direction by inverting the way of thought, and by thinking of the vectors ON and ON1 as modified by the vector OP. The law for the length remains unaffected; the resultant length is the length of the product of the two vectors. The new direction for the enlarged ON (i.e. OQ) is found by rotating it in the (anti-clockwise) direction of rotation from OX towards OY through an angle equal to the angle XOP: it is an accident of this particular case that this rotation makes OQ lie along the line OP. Again consider the product of ON1 and OP; the new direction for the enlarged ON1 (i.e. OR) is found by rotating ON in the anti-clockwise direction of rotation through an angle equal to the angle XOP, namely, the angle N1OR is equal to the angle XOP.

The general rule for the geometrical representation of multiplication can now be enunciated thus: 12

The product of the two vectors OP and OQ is a vector OR, whose length is the product of the lengths of OP and OQ and whose direction OR is such that the angle XOR is equal to the sum of the angles XOP and XOQ.

Hence we can conceive the vector OP as making the vector OQ rotate through an angle XOP (i.e. the angle QOR=the angle XOP), or the vector OQ as making the vector OP rotate through the angle XOQ (i.e. the angle POR=the angle XOQ).

We do not prove this general law, as we

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