CBSE Board Paper Solution 2020 Mathematics Standard PDF
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2020
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This is a mathematics past paper for class 10 from CBSE board, 2020. The paper consists of multiple choice and other types of questions. The areas of testing include various mathematical concepts.
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CBSE Board Paper Solution-2020 Class : X Subject : Mathematics (Standard) - Theory Set : 1 Code No : 30/5/1 Time allowed : 3 Hours Maximum Marks :...
CBSE Board Paper Solution-2020 Class : X Subject : Mathematics (Standard) - Theory Set : 1 Code No : 30/5/1 Time allowed : 3 Hours Maximum Marks : 80 Marks General instructions: Read the following instructions very carefully and strictly follow them: (i) This question paper comprises four sections – A, B, C and D. This question paper carries 40 question All questions are compulsory (ii) Section A: Question Numbers 1 to 20 comprises of 20 question of one mark each. (iii) Section B: Question Numbers 21 to 26 comprises of 6 question of two marks each. (iv) Section C: Question Numbers 27 to 34 comprises of 8 question of three marks each. (v) Section D: Question Numbers 35 to 40 comprises of 6 question of four marks each. (vi) There is no overall choice in the question paper. However, an internal choice has been provided in 2 question of the mark, 2 question of one mark, 2 questions of two marks. 3 question of three marks and 3 question of four marks. You have to attempt only one of the choices in such questions. (vii) In addition to this. Separate instructions are given with each section and question, wherever necessary. (viii) Use of calculations is not permitted. Section A Question numbers 1 to 20 carry 1 mark each. Question numbers 1 to 10 are multiple choice questions. Choose the correct option. 1. On dividing a polynomial p(x) by x2 – 4, quotient and remainder are found to be x and 3 respectively. The polynomial p(x) is (A) 3x2 + x - 12 (B) x3 -4x + 3 (C) x2 + 3x - 4 (D) x2 - 4x - 3 Answer: Correct Answer: (B) x3 –4x+3 Explanation: P(x) = (divisor)×(quotient) + Remainder =(x2 – 4)x+3 = x3 – 4x+3 2) In Figure-1, ABC is an isosceles triangle, right- angled at C. Therefore (A) AB2 = 2AC2 (B) BC2 = 2AB2 (C) AC2 = 2AB2 (D) AB2 = 4AC2 Answer: Correct Answer: (A) AB2 = 2AC2 Explanation: Given that ACB is an isosceles triangle right angled at C. Therefore, AC = BC Using Pythagoras theorem in the given triangle, we have AB2 = AC2 + BC2 = AC2 + AC2 = 2AC2 3) The point on the x-axis which is equidistant from (─ 4, 0) and 10, 0) is (A) (7, 0) (B) (5, 0) (C) (0, 0) (D) (3, 0) OR The centre of a circle whose end points of a diameter are (─ 6, 3) and 6, 4) is (A) (8, ─ 1) (B) (4, 7) 7 (C) 0, 2 7 (D) 4, 2 Answer: Correct Answer: (D) (3, 0) Explanation: The required point and the given points as well lie on the x-axis. The required point (x, 0) is the mid-point of the line joining points (–4, 0) and (10, 0). So, x = (– 4+10)/2 = 6/2 =3 Required point = (x, 0) = (3, 0) OR Correct Answer: (C) (0, 7/2) Explanation: The centre of a circle is the mid-point of its diameter. End points of the diameter are: (–6, 3) and (6, 4) Coordinates of the centre = ((– 6+6)/2, (3+4)/2) = (0, 7/2) 4) The value(s) of k for which the quadratic equation 2x2 + kx + 2 = 0 has equal roots, is (A) 4 (B) 4 (C) ─ 4 (D) 0 Answer: Correct Answer: (B) ±4 Explanation: The given equation is: 2x2 + kx + 2 =0 Discriminant = b2–4ac Here, b =k, a =2, and c =2 So, Discriminant = k2–4×2×2 = k2–16 A quadratic equation has equal roots if its discriminant is zero. k2–16 = 0 k2 =16 k = ±4 5) Which of the following is not an A.P.? (A) ─ 1.2, 0.8, 2.8 …. (B) 3, 3 + 2, 3 + 2 2, 3 + 3 2,.... 4 7 9 12 (C) , , , ,... 3 3 3 3 -1 -2 -3 (D) , , ,... 5 5 5 Answer: 4 7 9 12 Correct Answer: (C) , , , ,... 3 3 3 3 Explanation: 4 7 9 12 , , , ,... 3 3 3 3 7 4 7 4 3 3 3 3 3 1 9 7 9 7 3 3 3 2 3 3 2 3 3 Difference between consecutive terms is not same. So, this is not an A.P. 6) The pair of linear equations 3x 5y + = 7 and 9x + 10y = 14 is 2 3 (A) consistent (B) inconsistent (C) consistent with one solution (D) consistent with many solutions Answer: Correct Answer: (B) Inconsistent Explanation: 3x 5y 7 2 3 9x 10y 7 6 9x 10y 42...(1) 9x 10y 14...(2) Ratios of coefficients of x and that of y are 9 10 1 9 10 1 42 3 1 Ratio of constants= = 14 1 1 Ratios of coefficients of x and y are equal but they are not equal to the ratio of constants. So, the given equations represent a pair of parallel lines and so they do not have a common solution. 7) In Figure-2 PQ is tangent to the circle with centre at O, at the point B. If AOB = 100°, then ABP is equal to (A) 50° (B) 40° (C) 60° (D) 80° Answer: Correct Answer: (A) 50° Explanation: OA = OB (radii) So, ∠OAB = ∠OBA = (180° –100°)/2 = 40° Now, a radius of a circle meets a tangent at 90°. So, ∠ABP = ∠OBP – ∠OBA = 90° –40° = 50° 8) The radius of a sphere (in cm) whose volume is 12 cm3, is (A) 3 (B) 3 3 (C) 32/3 (D) 31/3 Answer: Correct Answer: (C)32/3 Explanation: 4 3 Volume of sphere = r 3 4 3 12 r 3 r3 32 r 32 /3 9) The distance between the points (m,–n) and (–m, n) is (A) m2 + n2 (B) m+n (C) 2 m2 + n2 (D) 2m2 + 2n2 Answer: Correct Answer: (C) 2 m2 n2 Explanation: 2 Distance = m ( m) (–n – n)2 (m m)2 (–2n)2 2 m2 n2 10) In Figure-3. From an external point P, two tangents PQ and PR are drawn to a circle of radius 4 cm with centre O. If QPR = 90°, then length of PQ is (A) 3cm (B) 4cm (C) 2cm (D) 2 2 cm Answer: Correct Answer: (B) 4 cm Explanation: Tangents are drawn from an external point P. So, line joining centre O and point P bisects ∠PQR. OP bisects ∠QPR = 90°. In ∆ OQP, ∠Q = 90° (radius meets tangent at 90°) ∠QPO = 45° = ∠QOP Thus, OQ = PQ = 4 cm Fill in the blanks in question number 11 to 15 11) The probability of an event that is sure to happen is __. Answer: 1 1 tan2 A 12) Simplest form of 2 is ______. 1 cot A Answer: cot2A 1 tan2 A sec2 A sin2 A cot2 A 1 cot A cos ec A cos A 2 2 2 13) AOBC is a rectangle whose three vertices are A(0, –3), O(0, 0) and B (4, 0). The length of its diagonal is ____. Answer: In right-angled triangle AOB, AB OA2 OB2 32 42 25 5 fu i i 14) In the formula x a h, ui = _____. fi Answer: xi a h 15) All concentric circles are ______ to each other. Answer: similar Answer the following question numbers 16 to 20. 16) Find the sum of the first 100 natural numbers. Answer: 1 2 3 ....100 is an A. P. Here first term a 1 Common difference d =1 n Sum of n terms of an A.P. = 2a + n 1 d 2 The sum of first 100 natural numbers 100 = 2×1 + 100 1 1 2 100 (101) = 2 50 101 5050 17) In Figure-4 the angle of elevation of the top of a tower from a point C on the ground, which is 30 m away from the foot of the tower, is 30°. Find the height of the tower. Answer: AB tan30 30 1 AB 3 30 30 AB 10 3 3 So, the height of the tower is 10 3 m. 18) The LCM of two numbers is 182 and their HCF is 13. If one of the numbers is 26, Find the other. Answer: LCM HCF Pr oduct of the two numbers 182 × 13 = 26 × x 182 × 13 x= 91 26 So, the other number is 91. 19) Form a quadratic polynomial, the sum and product of whose zeroes are (-3) and 2 respectively. OR Can (x2 – 1) be a remainder while dividing x4 – 3x2 + 5x – 9 by (x2 +3)? Justify your answer with reasons. Answer: x2 – (sum of zeroes)x + product of zeroes = x2 – (–3)x+2 = x2 + 3x+2 So, the required polynomial is x2 +3x+2. OR When a polynomial p(x) is divided by another polynomial g(x), then the degree of remainder r(x) < degree of g(x) Therefore, for the given question x2 – 1 cannot be a remainder while dividing x4 – 3x2 + 5x – 9 by x2 + 3 because deg (x2 – 1) = deg (x2 + 3). 20) Evaluate: 2 tan 450 cos 600 sin 300 Answer: 2 tan45° ×cos60° sin30 1 2 1 2 1 2 2 SECTION B Question number 21 to 26 carry 2 marks each. 21) In the given Figure-5, DE ||AC and DF||AE. BF BE Prove that =. FE EC Answer: In ABC, DE AC So, using basic proportionality theorem, we get BD BE ...(1) DA EC In BAE, DF AE So, using basic proportionality theorem, we get BD BF ...(2) DA FE From (1) and (2), we get BE BF EC FE 22) Show that 5 +2 7 is an irrational number, where 7 is given to be an irrational number. OR Check whether 12n can end with the digit 0 for any natural number n. Answer: Let us assume, to the contrary, that 5 2 7 is rational. That is, we can find coprime a and b (b 0) such that a 52 7 b a 2 7 5 b 1a a – 5b Rearranging this equation, we get 7 5 2b 2b a – 5b Since, a and b are integers, we get is rational, and 2b so 7 is a rational. But this contradicts the fact that 7 is irrational. This contradiction has arisen because of our incorrect assumption that 5 2 7 is rational. So, we conclude that 5 2 7 is irrational. OR If the number 12n , for any n, were to end with the digit zero, then it would be divisible by 5. That is, the prime factorisation of 12n would contain the prime 5. This is not possible 12n = (2 × 2 × 3)n So, the prime numbers in the factorisation of 12n are 2 and 3. So, the uniqueness of the Fundamental Theorem of Arithmetic guarantees that there are no other primes in the factorisation of 12n. So, there is no natural number n for which 12 n ends with the digit zero. 23) If A, B and C are interior angles of a ABC, then show that cos B + C = sin A. 2 2 Answer: Given that A, B and C are interior angles of a triangle ABC. A B C 180 or A 180 B C Now, B C B C cos sin 90 2 2 180 B C sin 2 A sin 2 24) In Figure 6, a quadrilateral ABCD is drawn to circumscribe a circle. Prove that AB + CD = BC +AD. OR In Figure-7, find the perimeter of ABC, if AP = 12 cm. Answer: We have to prove that AB CD BC AD We know that lengths of tangents drawn from a point to a circle are equal. Therefore, from figure, we have DR DS, CR CQ, AS AP, BP BQ Now, LHS AB CD (AP BP) (CR DR) (AS BQ) (CQ DS) BQ CQ AS DS BC AD RHS OR From the given figure, we have AP = 12 cm Since AQ and AB are the tangent to the circle from a common point A, hence AP = AQ = 12 Similarly, PB = BD and CD =CQ Also, AP =AB + PB and AQ = AC + CQ Perimeter of ABC = AB + BD + CD + AC = AB + PB + CQ + AC (since PB = BM and CM = CQ) = (AB + PB) + (CQ + AC) = AP + AQ = 12 +12 = 24 cm Therefore, the perimeter of triangle ABC =24 cm 25) Find the mode of the following distribution: Marks 0 – 10 10 – 20 20 – 30 30 – 40 40 – 50 50 – 60 Number 4 6 7 12 5 6 of Students Answer: Marks 0-10 10-20 20-30 30-40 40-50 50-60 Number of 4 6 7 12 5 6 Students From the given data, we have l 30, f1 12, f0 7, f2 5, h 10 f1 f0 Mode l h 2f1 f0 f2 12 7 30 10 2 12 7 5 34.1667 Mode of the given data is 34.1667. 26) 2 cubes, each of volume 125 cm3, are joined end to end. Find the surface area of the resulting cuboid. Answer: Let the side of the old cube = a The volume of the old cube = 125 cm3 (Given) The volume of the cube = a3 a3 =125 cm3 a3 =53 a = 5 cm The dimensions of the resulting cuboid are: Length, l = 10 cm Breadth, b = 5 cm Height, h = 5 cm Total surface area of the resulting cuboid: = 2(lb+bh+hl) = 2[10(5)+5(5)+5(10)] = 2[50+25+50] = 2 = 250 cm2 Section C 1 27) A fraction becomes when 1 is subtracted from 3 1 the numerator and it becomes when 8 is 4 added to its denominator. Find the fraction. OR The present age of a father is three years more than three times the age of his son. Three years hence the father's age will be 10 years more than twice the age of the son. Determine their present ages. Answer: Let the numerator of the fraction be x and denominator be y. x Therefore, the fraction is. y According to question, x 1 1 y 3 3 x 1 y 3x 3 y...(1) x 1 and y 8 4 4x y 8 4x 8 y...(2) From equations 1 and 2 , we get 3x 3 4x 8 4x 3x 8 3 x 5 Putting x 5 in equation (1), 3 5 3 y y 12 5 So, the required fraction =. 12 OR Let the son's present age be x. So, father's present age = 3x 3 3 years later: Son's age = x 3 Father's age = 3x 3 3 3x 6 But, according to the given condition, 3 years later father's age= 2 x 3 10 2x 6 10 2x 16 So, we can write 3x 6 2x 16 3x 2 x 16 6 x 10 So, son's present age 10 years and father's present age 10 3 3 33 years 28) Use Euclid Division Lemma to show that the square of any positive integer is either of the form 3q or 3q + 1 for some integer q. Answer: Let a be a positive integer and b 3. By Euclid's Algorithm, a 3m r for some integer m 0 and 0 r 3. The possible remainders are 0, 1 and 2. Therefore, a can be 3m or 3m 1 or 3m 2. Thus, a2 9m2 or (3m+1)2 or (3m 2)2 9m2 or (9m2 6m 1) or (9m2 12m 4) 3 (3m2 ) or 3(3m2 2m) 1 or 3(3m2 4m 1) 1 3k1 or 3k2 1 or 3k3 1 where k1, k2 and k3 are some positive integers. Hence, square of any positive integer is either of the form 3q or 3q + 1 for some integer q. 29) Find the ratio in which y-axis divides the line segment joining the points (6, - 4) and (-2, -7). Also find the point of intersection. OR Show that the points (7, 100, (-2, 5) and (3, -4) are vertices of an isosceles right triangle. Answer: Let the ratio in which the line segment joining A 6, 4 and B 2, 7 is divided by the y-axis be k : 1. Let the coordinate of point on y-axis be 0, y . Therefore, 2k 6 7k 4 0 and y k 1 k 1 Now, 2k 6 0 k 1 or 0 2k 6 or k 3 Therefore, the required ratio is 3:1. Also, 7k 4 y k 1 7 3 4 31 25 4 Therefore, the given line segment is divided by the point 25 0, in the ratio 3:1. 4 OR Let the given points are P(7, 10), Q(-2, 5) and R(3, 4). Now, using distance formula we find distance between these points i.e., PQ, QR and PR. Distance between points P(7, 10) and Q(-2, 5), 2 7 5 10 2 2 PQ 81 25 106 Distance between points Q(-2, 5) and R(3, 4), 3 2 4 5 2 2 QR 25 81 106 Distance between points P(7, 10) and R(3, 4), 3 7 4 10 2 2 PR 16 196 212 Now, PQ2 QR 2 106 106 212 PR 2 i.e., PQ2 QR 2 PR 2 Therefore, points P(5, 2), Q(6, 4) and R(7, 2) form an isosceles right triangle because sides PQ and QR are equal. 30) Prove that: 1 sin A sec A + tan A 1 sin A Answer: 1 sin A LHS 1 sin A 1 sin A 1 sin A 1 sin A 1 sin A 1 1 sin A 1 sin2 A 1 sin A cos2 A 1 sin A cos A sin A 1 cos A cos A tan A sec A RHS 31) For an A.P., it is given that the first term (a) = 5, common difference (d) = 3, and the nth term (an) = 50. Find n and sum of first n terms (Sn) of the A.P. Answer: Here, a 5, d 3, an 50 We need to find Sn. Firstly, we will find the value of n. We know that an a (n 1)d So, 50 5 (n 1)3 or 50 5 (n 1)3 45 or 1 n 3 or n 16 We know that sum of first n terms of an AP is given by n Sn a an 2 16 So, S16 5 50 2 8 55 or S16 440 32) Construct a ΔABC with sides BC = 6 cm, AB = 5 cm and ABC = 60°. Then construct a triangle 3 whose sides are of the corresponding sides of 4 ΔABC. OR Draw a circle of radius 3.5 cm. Take a point P outside the circle at a distance of 7 cm from the centre of the circle and construct a pair of tangents to the circle from that point. Answer: Steps of Construction : Step 1: Draw a ABC with sides AB 5 cm, BC 6 cm and ABC 60. Step 2: Draw a ray BX making an acute angle with line BC on the opposite side of vertex A. Step 3: Locate 4 points B1, B2 , B3 , B 4 on BX such that BB1 B1B2 B2B3 B3B4. Step 4: Join the points C and B 4. Step 5: Through the point B3 , draw a line parallel to CB4 intersecting line segment BC at point C. Step 6: Draw a line through C parallel to the line AC to intersect line segment AB at A. The required triangle is A BC. OR Steps of Construction : Step 1: Draw a circle of radius 3.5 cm with centre at point O. Locate a point P, at a distance of 7 cm from O, and join O and P. Step 2: Bi sec t OP. Let M be the mid-point of OP. Step 3: Draw a circle with centre at M and MO as radius. Q and R are points of intersections of this circle with the circle having centre at O. Step 4: Join PQ and PR. PQ and PR are the required tangents. 33) Read the following passage and answer the question given at the end: Diwali Fair. A game in a booth at a Diwali Fair involves using a spinner first. Then, if the spinner stops on an even number, the player is allowed to pick a marble from a bag. The spinner and the marbles in the bag are represented in Figure – 8. Prizes are given when a black marble is picked. Shweta plays the game once. (i) What is the probability that she will be allowed to pick a marble from the bag? (ii) (ii) Suppose she is allowed to pick a marble from the bag, what is the probability of getting a prize, when it is given that the bag contains 20 balls out of which 6 are black? Answer: Numbers on spinner 1, 2, 4, 6, 8, 10 Even numbers on spinner 2, 4, 6, 8, 10 Shweta will pick black marble, if spinner stops on even number. Therefore, n Even number 5 n Possible number 6 i P Shweta allowed to pick a marble P Even number n Even number n Possible number 5 6 Therefore, the probability of allowing Shweta 5 to pick a marble is. 6 ii Since, prizes are given, when a black marble is picked. Number of black marbles 6 Total number of marbles 20 Therefore, P getting a prize P a black marble n Black marbles n Total marbles 6 20 3 10 3 Therefore, the probabiltiy of geting prize is. 10 34. In figure – 9, a square OPQR is inscribed in a quadrant OAQB of a circle. If the radius of circle is 6 2 cm , find the area of the shaded region. Answer: Given that, OQ 6 2 cm OPQR is a square. Let the side of square a The diagonal of square a 2 Here, OQ is a diagonal of square. a 2 6 2 a 6 cm Area of square OPQR 62 36 cm2 Radius of the quadrant OAQB Diagonal of the square OPQR 6 2 cm 90 22 2 Area of the quadrant OAQB 6 2 360 7 396 cm2 7 Area of shaded region Area of the quadrant OAQB Area of square OPQR 396 36 7 144 7 20.6 cm2 SECTION D Obtain other zeroes of the polynomial 35) p(x) = 2x 4 - x3 - 11x2 + 5x + 5 if two of its zeroes are 5 and - 5. OR What minimum must be added to 2x3 - 3x2 + 6x + 7 so that resulting polynomial will be divisible by x2 - 4x + 8 ? Answer: The given polynomial is p x = 2x 4 x3 11x2 + 5x + 5. The two zeroes of p(x) are 5 and 5. Therefore, x 5 and x + 5 are factors of p(x). Also, x 5 x + 5 = x2 5 and so x2 5 is a factor of p(x). Now, 2x2 x 1 x2 5 2x 4 x3 11x2 + 5x + 5 2x 4 10x2 + x3 x2 + 5x + 5 x3 + 5x x2 +5 x2 +5 0 2x 4 x3 11x2 + 5x + 5 x2 5 2x2 x 1 = x 2 52x 2x + x 1 2 = x 2 5 2x + 1 x 1 Equating x2 5 2x + 1 x 1 to zero, we get the zeroes of the given polynomial. Hence, the zeroes of the given polynomial are : 1 5, 5, and 1. 2 OR The given polynomial is 2x3 3x2 6x 7. Here, divisor is x2 4x 8. Divide 2x3 3x2 6x 7 by x2 4x 8 and find the remainder. 2x 5 x2 4x 8 2x3 3x2 6x 7 2x3 8x2 16x 5x2 10x 7 5x2 20x 40 10x 33 Re mainder 10x 33 Therefore, we should add 10x 33 to make it exactly divisible by x2 4x 8. Thus, we should add 10x 33 to 2x3 3x2 6x 7. 36) Prove that the ratio of the areas of two similar triangles is equal to the square of the ratio of their corresponding sides. Answer: Given : ABC DEF 2 2 2 Area ΔABC AB BC AC To prove : Area ΔDEF DE EF DE Construction: Draw AL BC and DM EF 1 Area ΔABC BC AL BC AL Proof: Here 2 1 Area ΔDEF 1 EF DM EF DM 2 In ΔALB and ΔDME ALB DME Each 90° and B E Since ΔABC ΔDEF So, ΔALB ΔDME AA similarity criterion AL AB DM DE AB BC AC But Since ΔABC ΔDEF DE EF DF AL BC Therefore, 2 DM EF From 1 and 2 , we have 2 Area ΔABC BC AL BC BC BC Area ΔDEF EF DM EF EF EF AB BC AC But Since ΔABC ΔDEF DE EF DF This implies that, 2 2 2 Area ΔABC AB BC AC Area ΔDEF DE EF DE 37) Sum of the areas of two squares is 544m2. If the difference of their perimeters is 32 m, find the sides of the two squares. OR A motorboat whose speed is 18km/h in still water takes 1 hour more to go 24 km upstream than to return downstream to the same spot. Find the speed of the stream. Answer: Let the sides of first and second square be x any y. Then, Area of first square = x2 And, Area of second square = y2 According to the question, x2 y2 544... 1 Now, Perimeter of first square = 4x And, Perimeter of second square = 4y According to the question, 4x – 4y = 32... 2 From equation 2 , we get 4 x – y 32 32 or, x – y = 4 or, x – y = 8 or, x=8+y... 3 Subsituting this value of x in equation 1 , we get x2 + y2 = 544 8 y 2 or, + y2 = 544 or, 64 + y2 + 16y + y2 = 544 or, 2y2 16y 64 544 or, 2y2 16y 64 – 544 0 or, 2y2 16y – 480 0 or, 2 y2 8y – 240 0 or, y2 8y – 240 0 or, y2 20y – 12y – 240 0 or, y y 20 – 12 y 20 0 or, y 20 y – 12 0 y + 20 = 0 or y – 12 = 0 y = –20 or y = 12 Since side of a square cannot be negative, therefore y = 12. Substituting y = 12 in equation 3 , we get x = 8 + y = 8 + 12 =20 Therefore, Side of first square = x = 20 cm And, Side of second square = y = 12 cm OR Let the speed of the stream be x km/h. Therefore, speed of the boat upstream = (18 – x) km/h and the speed of the boat downstream = (18 + x) km/h. distance The time taken to go upstream = speed 24 = hours 18 – x 24 Similarly, the time taken to go downstream = hours 18 x According to the question, 24 24 – 1 18 – x 18 x 24 18 x – 24 18 – x or, 1 18 x 18 – x or, 24 18 x – 24 18 – x 18 x 18 – x or, 432 + 24x – 432 + 24x = 324 – x2 or, x 2 48x –324 = 0 Using the quadratic formula, we get –48 482 – 4 1 –324 x= 2 –48 2304 1296 = 2 –48 3600 = 2 –48 60 = 2 –48 60 –48 – 60 Therefore, x = or x = 2 2 12 –108 x= or x = 2 2 x = 6 or x = –54 Since x is the speed of the stream, it cannot be negative. So, we ignore the root x = –54. Therefore, x = 6 gives the speed of the stream as 6 km/h. 38. A solid toy is in the form of a hemisphere surmounted by a right circular cone of same radius. The height of the cone is 10 cm and the radius of the base is 7 cm. Determine the volume of the toy. Also find the area of the coloured sheet required to cover the toy. 22 (Use = and 149 12.2) 7 Answer: Let ABC be the hemisphere and ADC be the cone standing on the base of the hemisphere. Height of the cone (h1) = 10 cm (Given) Radius of the cone (r1) = 7 cm (Given) Since the hemisphere is surmounted by the right circular cone of same radius, therefore Radius of the hemisphere (r2) = 7 cm So, Volume of the toy = Volume of the cone + Volume of the hemisphere 1 2 = r12h1 r23 3 3 1 22 2 22 7 7 10 7 7 7 cm3 3 7 3 7 1540 2156 cm3 3 3 3696 cm3 3 1232 cm3 Area of the coloured sheet required to cover the toy = CSA of hemisphere + CSA of cone 2r22 r Where is the slant height of the cone r12 h12 = 72 102 = 49 100 = 149 = 12.2 cm So, Area of the coloured sheet required to cover the toy 22 22 2 7 7 7 12.2 cm2 7 7 308 268.4 cm2 576.4 cm2 39. A statue 1.6 m tall, stands on the top of a pedestal. From a point on the ground, the angle of elevation of the top of the statue is 600 and from the same point the angle of elevation of the top of the pedestal is 450. Find the height of the pedestal. (Use 3 = 1.73) Answer: A Statue 1.6 m D Pedestal x 60° 45° B C Let BD be a pedestal of height x m and AD be a statue of height 1.6 m. The angle of elevation of the top of pedestal from a point C is 45° and that of point statue from C is 60°. In the triangle ABC: AB tan60 BC 1.6 x 3 BC 1.6 x Or, BC... 1 3 In the triangle DBC: DB tan 45 BC x Or, 1 BC Or, x BC... 2 By equations 1 and 2 , we get 1.6 x x 3 Or, 3x 1.6 x 3 1 x 1.6 1.6 3 1 Or, x 3 1 3 1 1.6 1.73 1 3 1 1.6 2.73 2 2.184m Therefore, the height of the pedestal is 2.184m. 40) For the following data, draw a 'less than' ogive and hence find the median of the distribution. Age(in 0-10 10-20 20-30 30-40 40-50 50-60 60-70 years): Number 5 15 20 25 15 11 9 of persons: OR The distribution given below show the number of wickets taken by bowlers in one-day cricket matches. Find the mean and the median of the number of wickets taken. Number 20-60 60-100 100-140 140-180 180-220 220-260 of wickets Number 7 5 16 12 2 3 of bowlers: Answer: Age Number of Persons (Cumulative frequency) Less than 10 5 Less than 20 5 + 15 = 20 Less than 30 20 + 20 = 40 Less than 40 40 + 25 = 65 Less than 50 65 + 15 = 80 Less than 60 80 + 11 = 91 Less than 70 91 + 9 = 100 Age No. of Persons Cumulative frequency (f) (cf) 0 – 10 5 5 10 – 20 15 20 20 – 30 20 40 30 – 40 25 65 40 – 50 15 80 50 – 60 11 91 60 – 70 9 100 Plot the points (10, 5), (20, 20), …, (70, 100) on a graph paper. 110 100 Cumulative Frequency 90 80 70 60 50 40 Median (34) 30 20 10 0 0 10 20 30 40 50 60 70 80 Upper Limits OR Class interval No. of bowlers fi Class mark xi fx i i 20 60 7 40 280 60 100 5 80 400 100 140 16 120 1920 140 180 12 160 1920 180 220 2 200 400 220 260 3 240 720 Total fi 45 fx i i 5640 fx i i 5640 x 125.33 fi 45 Number of Number of bowlers Cumulative wickets Frequency 20 – 60 7 7 60 – 100 5 12 100 – 140 16 28 140 – 180 12 40 180 – 220 2 42 220 – 260 3 45 n 45 n 45 22.5 2 2 Median class 100 140 n cf 2 Median l h f n l 100, 22.5, cf 12, f 16, h 40 2 22.5 12 Median 100 40 16 100 26.25 126.25