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1. A straight line can be drawn joining any two points. 2. A straight line may be prolonged to any length.
3. If two straight lines are unequal, the length of the less may be laid off on the greater. 4. A straight line may be bisected ; that is, divided into
, two equal parts.
5. An angle may be bisected.
6. A perpendicular may be drawn to a given straight line, either from a point without, or from a point on the line.
7. A straight line may be drawn, making with a given straight line an angle equal to a given angle.
8. A straight line may be drawn through a given point, parallel to a given line.
Ν Ο Τ Ε.
In making references, the following abbreviations are employed, viz.: A. for Axiom; B. for Book; C. for Corollary; D. for Definition; I. for Introduction; P. for Proposition ; Prob. for Problem; Post. for Postulate; and S. for Scholium. In referring to the same Book, the number of the Book is not given; in referring to any other Book, the number of the Book is given.
If a straight line meets another straight line, the sum of the
adjacent angles is equal to two right angles.
DC meet AB at C: then is the
E sum of the angles DCA and DCB equal to two right angles. At C, let CE be drawn perpen
B dicular to AB (Post. 6); then, by definition (D. 12), the angles ECA and ECB are both right angles, and consequently, their sum is equal to tuo right angles.
The angle DCA is equal to the sum of the angles ECA and ECD (A. 9); hence,
DCA + DCB = ECA – ECD + DCB;
ECD + DCB is equal to ECB (A. 9); hence,
DCA + DCB = ECA + ECB.
The sum of the angles ECA and ECB, is equal to two right angles; consequently, its equal, that is, the sum of the angles DCA and DCB, must also be equal to two right angles; which was to be proved.
Cor. 1. If one of the angles DCA, DCB, is a right angle, the other must also be a right angle.
angles EAB and EAF; which, from the proposition just demonstrated, is equal to two right angles.
If two straight lines intersect each other, they form four angles about the point of intersection, which have received different names, with respect to each other.
1° ADJACENT ANGLES are those which lie on the same side of one line, and on opposite sides of the other; thus, ACE and ECB,
ACE and ACD, adjacent angles.
2° OPPOSITE, or VERTICAL ANGLES, are those which lie
. on opposite sides of both lines; thus, ACE and DCB, or ACD and ECB, are opposite angles. From the proposition just demonstrated, the sum of any two adjacent angles is equal to two right angles.
If two straight lines intersect each other, the opposite or
vertical angles are equal.
Let AB and DE intersect at C: then are the opposite or
E vertical angles equal.
The sum of the adjacent angles ACE and ACD, is equal to two right angles (P. I.): the sum of the adjacent angles ACE and ECB, is also equal to two right angles. But things which are equal to the same thing, are equal to each other (A. 1); hence,
and, taking away the common angle ACD, we have,
Cor. 1. If one of the angles about C is a right angle, all of the others are right angles also. For, (P. I., C. 1), each of its adjacent angles is
right angle; and from the proposition just demonstrated, its opposite angle is also right
Cor. 2. If one line DE, is perpendicular to another AB, then is the second line AB perpendicular to the first DE. For, the angles DCA and DCB are right angles, by definition (D. 12); and from what has just been proved, the angles ACE and BCE are also right angles. Hence, the two lines are mutually perpendicular to each other.
For, if two lines are drawn through the point, mutually perpendicular to each other, the sum of the angles which they form is equal to four right angles, and it is also equal to the sum of the given angles (A. 9). Hence, the sum of the given angles is equal to four right angles.
If two straight lines have two points in common, they
coincide throughout their whole extent, and form one and the same line.
Let A and B B be two points common to two lines: then the lines coincide throughout.
Between A and B they must coincide (A. 11). Suppose, now, that they begin to separate at some point C, beyond AB, the one becoming ACE, and the other ACD. If the lines do separate at C, one or the other must change direction at this point; but this is contradictory to the definition of a straight line (D. 4): hence, the supposition that they separate at any point is absurd. They must, therefore, coincide throughout; which was to be proved.
Cor. Two straight lines can intersect in only one point.
NOTE.—The method of demonstration employed above, is called the reductio ad absurdum. It consists in assuming an hypothesis which is the contradictory of the proposition to be proved, and then continuing the reasoning until the assumed hypothesis is shown to be false. Its contradictory is thus proved to be true. This method of demonstration is often used in Geometry.