Geometrical Drawing.
Geometry is the science of measurement; it has been known for more than three thousand years; many lives have been devoted to its development, and it exists to-day as the foundation of all mathematics.
Geometrical drawing is the art of representing, to the eye, the problems “worked out” by geometricians, and the importance of a knowledge of geometrical drawing is paramount. The student will find that the figures delineated and explained in the next few pages constantly occur in mechanical drawing. Says Walter Smith, State Director of Art Education in Massachusetts, “I have never known a case where a student did not progress more satisfactorily in his studies after a course of practical geometry.”
The elementary conceptions of geometry are few:
1.—A point.2.—A line.3.—A surface.4.—A solid, and5.—An angle.
1.—A point.2.—A line.3.—A surface.4.—A solid, and5.—An angle.
All of which elements are used in mechanical drawings.
From these, as data, a vast number of mathematical problems have been deduced; of which a few of the most elementary will be illustrated in this work; but these few will repay the attention of the student.
In “freehand” drawing the crayon and pencil are used; in geometrical drawings the dividers, asshown in illustration,fig. 97, together with a rule, are all that is necessary to accomplish the work.
A problem is something to be done, and geometry has been defined as the science of measurement; the relation between geometry and mechanical drawing is very close, hence the term “geometrical problem.”
CompassesFig. 97.
Fig. 97.
RulerFig. 98.
Fig. 98.
Before proceeding with the examples, a few elementary statements belonging to the science of geometry are presented; these will be useful to the student, not only while “doing” the problems, but in many cases of every-day—future—experience.
Geometry is one of the oldest and simplest of sciences; it may be defined asthe science of measurement; geometry isthe rootfrom which all regular mathematical calculations issue. It has claimed the best thought of practical men from the times of the Greeks and Romans two thousand years ago; they derived their knowledge of the science from the Egyptians, who in turn were indebted to the Chaldeans and Hindoos in times beyond any authentic history; hence it was under the operations of the laws explained in geometry, that the pyramids of Egypt and the temples of Greece were constructed, as well as the engines of war and appliances of peace of ancient times.
A pointis mere position, and has no magnitude.
A lineis that which has extension in length only. The extremities of lines are points.
A surfaceis that which has extension in length and breadth only.
Angle
A solidis that which has extension in length, breadth and thickness.
An angleis the difference in the direction of two lines proceeding from the same point.
Lines, Surfaces, Angles and Solids constitute the different kinds of quantity calledgeometricalmagnitudes.
Lines
Parallel linesare lines which have the same direction; hence parallel lines can never meet, however far they may be produced; for two lines taking the same direction cannot approach or recede from each other.
AnAxiomis a self-evident truth, not only too simple to require,but too simple to admit of demonstration.
APropositionis something which is either proposed to be done, or to be demonstrated, and is either a problem or a theorem.
AProblemis something proposed to be done.
ATheoremis something proposed to be demonstrated.
AHypothesisis a supposition made with a view to draw from it some consequence which establishes the truth or falsehood of a proposition, or solves a problem.
ALemmais something which is premised, or demonstrated, in order to render what follows more easy.
ACorollaryis a consequent truth derived immediately from some preceding truth or demonstration.
AScholiumis a remark or observation made upon something going before it.
APostulateis a problem, the solution of which is self-evident.
Let it begranted—
III. That a straight line can be drawn from any one point to any other point;
III. That a straight line can be produced to any distance, or terminated at any point;
III. That the circumference of a circle can be described about any center, at any distance from that center.
The common algebraic signs are used in Geometry, and it is necessary that the student in geometry should understand some of the more simple operations of algebra. As the terms circle, angle, triangle, hypothesis, axiom, theorem, corollary and definition are constantly occurring in a course of geometry, they are abbreviated as shown in the following list:
1.Things which are equal to the same thing are equal to each other.
2.When equals are added to equals the wholes are equal.
3.When equals are taken from equals the remainders are equal.
4.When equals are added to unequals the wholes are unequal.
5.When equals are taken from unequals the remainders are unequal.
6.Things which are double of the same thing, or equal things, are equal to each other.
7.Things which are halves of the same thing, or of equal things, are equal to each other.
8.The whole is greater than any of its parts.
9.Every whole is equal to all its parts taken together.
10.Things which coincide, or fill the same space, are identical, or mutually equal in all their parts.
11.All right angles are equal to one another.
12.A straight line is the shortest distance between two points.
13.Two straight lines cannot enclose a space.