COORDINATE GEOMETRY - NCERT

1 CHAPTER3 COORDINATE GEOMETRYWhat s the good of Mercator s North Poles and Equators, Tropics, Zones andMeridian Lines? So the Bellman would cry; and crew would reply They aremerely conventional signs! LEWIS CARROLL, The Hunting of the IntroductionYou have already studied how to locate a point on a number line. You also know howto describe the position of a point on the line. There are many other situations, in whichto find a point we are required to describe its position with reference to more than oneline. For example, consider the following situations:I. In Fig. , there is a main road runningin the East-West direction and streets withnumbering from West to East. Also, on eachstreet, house numbers are marked. To look fora friend s house here, is it enough to know onlyone reference point? For instance, if we onlyknow that she lives on Street 2, will we be ableto find her house easily?

2 Not as easily as whenwe know two pieces of information about it,namely, the number of the street on which it issituated, and the house number. If we want toreach the house which is situated in the 2ndstreet and has the number 5, first of all wewould identify the 2nd street and then the housenumbered 5 on it. In Fig. , H shows thelocation of the house. Similarly, P shows thelocation of the house corresponding to Streetnumber 7 and House number 2252 MATHEMATICSII. Suppose you put a dot on a sheet of paper [ (a)]. If we ask you to tell usthe position of the dot on the paper, how will you do this? Perhaps you will try in somesuch manner: The dot is in the upper half of the paper , or It is near the left edge ofthe paper , or It is very near the left hand upper corner of the sheet . Do any ofthese statements fix the position of the dot precisely?

3 No! But, if you say The dot isnearly 5 cm away from the left edge of the paper , it helps to give some idea but stilldoes not fix the position of the dot. A little thought might enable you to say that the dotis also at a distance of 9 cm above the bottom line. We now know exactly where the dot is!Fig. this purpose, we fixed the position of the dot by specifying its distances from twofixed lines, the left edge of the paper and the bottom line of the paper [ (b)]. Inother words, we need two independent informations for finding the position of the , perform the following classroom activity known as Seating Plan .Activity 1 (Seating Plan) : Draw a plan of the seating in your classroom, pushing allthe desks together. Represent each desk by a square. In each square, write the nameof the student occupying the desk, which the square represents. Position of eachstudent in the classroom is described precisely by using two independent informations:(i)the column in which she or he sits,(ii)the row in which she or he you are sitting on the desk lying in the 5th column and 3rd row (represented bythe shaded square in Fig.)

4 , your position could be written as (5, 3), first writing thecolumn number, and then the row number. Is this the same as (3, 5)? Write down thenames and positions of other students in your class. For example, if Sonia is sitting inthe 4th column and 1st row, write S(4,1). The teacher s desk is not part of your seatingplan. We are treating the teacher just as an 22 COORDINATE GEOMETRY53 Fig. the discussion above, you observe that position of any object lying in a planecan be represented with the help of two perpendicular lines. In case of dot , werequire distance of the dot from bottom line as well as from left edge of the paper. Incase of seating plan, we require the number of the column and that of the row. Thissimple idea has far reaching consequences, and has given rise to a very importantbranch of Mathematics known as COORDINATE GEOMETRY .

5 In this chapter, we aim tointroduce some basic concepts of COORDINATE GEOMETRY . You will study more aboutthese in your higher classes. This study was initially developed by the French philosopherand mathematician Ren D D scartes, the great French mathematician of theseventeenth century, liked to lie in bed and think! Oneday, when resting in bed, he solved the problem ofdescribing the position of a point in a plane. His methodwas a development of the older idea of latitude andlongitude. In honour of D scartes, the system used fordescribing the position of a point in a plane is alsoknown as the Cartesian will you describe the position of a table lamp on your study table to anotherperson?2.(Street Plan) : A city has two main roads which cross each other at the centre of thecity. These two roads are along the North-South direction and East-West D scartes (1596 -1650)Fig.

6 2254 MATHEMATICSAll the other streets of the city run parallel to these roads and are 200 m apart. Thereare 5 streets in each direction. Using 1cm = 200 m, draw a model of the city on yournotebook. Represent the roads/streets by single are many cross- streets in your model. A particular cross-street is made bytwo streets, one running in the North - South direction and another in the East - Westdirection. Each cross street is referred to in the following manner : If the 2nd streetrunning in the North - South direction and 5th in the East - West direction meet at somecrossing, then we will call this cross-street (2, 5). Using this convention, find:(i)how many cross - streets can be referred to as (4, 3).(ii)how many cross - streets can be referred to as (3, 4). Cartesian SystemYou have studied the number line in the chapter on Number System . On the numberline, distances from a fixed point are marked in equal units positively in one directionand negatively in the other.

7 The point from which the distances are marked is calledthe origin. We use the number line to represent the numbers by marking points on aline at equal distances. If one unit distance represents the number 1 , then 3 unitsdistance represents the number 3 , 0 being at the origin. The point in the positivedirection at a distance r from the origin represents the number r. The point in thenegative direction at a distance r from the origin represents the number r. Locationsof different numbers on the number line are shown in Fig. invented the idea of placing two such lines perpendicular to each otheron a plane, and locating points on the plane by referring them to these lines. Theperpendicular lines may be in any direction such as in But, when we chooseFig. 22 COORDINATE GEOMETRY55these two lines to locate a point in a plane in this chapter, one linewill be horizontal and the other will be vertical, as in Fig.

8 (c).These lines are actually obtained as follows : Take two numberlines, calling them X X and Y Y. Place X X horizontal [as in Fig. (a)]and write the numbers on it just as written on the number line. We dothe same thing with Y Y except that Y Y is vertical, not horizontal[Fig. (b)].Fig. both the lines in sucha way that the two lines cross eachother at their zeroes, or origins(Fig. ). The horizontal line X Xis called the x - axis and the verticalline YY is called the y - axis. Thepoint where X X and Y Y cross iscalled the origin, and is denotedby O. Since the positive numberslie on the directions OX and OY,OX and OY are called the positivedirections of the x - axis and they - axis, respectively. Similarly, OX and OY are called the negativedirections of the x - axis and they - axis, 2256 MATHEMATICSYou observe that the axes (plural of the word axis ) divide the plane into four parts.

9 These fourparts are called the quadrants (one fourth part),numbered I, II, III and IV anticlockwise from OX(see ). So, the plane consists of the axes andthese quadrants. We call the plane, the Cartesianplane, or the COORDINATE plane, or the axes are called the COORDINATE , let us see why this system is so basic to mathematics, and how it is the following diagram where the axes are drawn on graph paper. Let us seethe distances of the points P and Q from the axes. For this, we draw perpendicularsPM on the x - axis and PN on the y - axis. Similarly, we draw perpendiculars QR andQS as shown in Fig. find that(i)The perpendicular distance of the point P from the y - axis measured along thepositive direction of the x - axis is PN = OM = 4 units.(ii)The perpendicular distance of the point P from the x - axis measured along thepositive direction of the y - axis is PM = ON = 3 22 COORDINATE GEOMETRY57(iii)The perpendicular distance of the point Q from the y - axis measured alongthe negative direction of the x - axis is OR = SQ = 6 units.

10 (iv)The perpendicular distance of the point Q from the x - axis measured alongthe negative direction of the y - axis is OS = RQ = 2 , using these distances, how can we describe the points so that there is noconfusion?We write the coordinates of a point, using the following conventions:(i)The x - COORDINATE of a point is its perpendicular distance from the y - axismeasured along the x -axis (positive along the positive direction of the x - axisand negative along the negative direction of the x - axis). For the point P, it is+ 4 and for Q, it is 6. The x - COORDINATE is also called the abscissa.(ii)The y - COORDINATE of a point is its perpendicular distance from the x - axismeasured along the y - axis (positive along the positive direction of the y - axisand negative along the negative direction of the y - axis). For the point P, it is+ 3 and for Q, it is 2.