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practice problems pending

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  Q1) Let (ABCD) be a rectangle such that (BC = 3AB). (P) and (Q) are points on the side (BC) such that BP = PQ = QC. Show that \angle DBC + \angle DPC = \angle DQC. S1. Q2. In a quadrilateral ABCD, given that angle A + angle D = 90. Pr. th. AC^2 + BD^2 = AD^2 + BC^2. S2. BC^2 = OB^2 + OC^2 AD^2 = OA^2 + OD^2 BC^2 + AD^2 = OB^2 + OC^2 + OA^2 + OD^2 Look at RHS: OA^2 + OC^2 = AC^2 OB^2 + OD^2 = BD^2 H.P. Q3.  In ( \triangle ABC ), (BM) and (CN) are perpendiculars from (B) and (C) respectively on a line passing through (A). If (L) is the midpoint of (BC), prove that [ ML = NL. ] S3. Method 1: Let LP be perpendicular to the same line passing through A. LP || BM || CN According to Intercept theorem, if 3 parallel lines cut 2 equal segments from a traversal, they will do the same with any other traversal. So MP = PN Now we will show triangle LMP congruent to LNP. LP is common side. Angle P is 90 in both. MP = PN. => LM = LN. Method 2: co-ordinate geometry Let the line thro...

practice problems pending

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Q1. The side AB of a parallelogram ABCD is produced both ways to F and G, so that AF = AD and BG = BC. Prove that FD and GC produced intersect at right angle. S1. There are 2 ways to draw the diagram here. Both give us the desired proof. Q2. In triangle AQB, points P and D lie on sides AB and AQ, respectively, such that [APQ]=[ABD]. Through D, draw the line DR∥AB, meeting BQ at R. Through B draw a line || to AQ which meets DR at C. Pr. th. RC=AP. S2. ABCD is a ||gram. AB = CD____[1] AD = BC Given [APQ] = [ABD] => Sin(A).AP.AQ = Sin(A).AB.AD => AP/AB = AD/AQ => Triangles APD and ABQ are similar by SAS. => PD || BR => BPDR is a ||gram => PD = BR and BP = DR___[2] From [1]: AP + PB = DR + RC Using [2]: AP = RC H.P. Q3. ABCD is a parallelogram. Through C, a straight line RQ is drawn outside the parallelogram, and AP, BQ, DR are drawn perpendicular to RQ. Show that DR + BQ = AP. S3.  

practice problems pending CRT homework - pending q1,2,3,7

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Q1. Let n be the least positive integer greater than 1000 for which gcd(63,n+120) = 21 and gcd(n+63,120) = 60. What is the sum of digits of n? S1. First wrong attempt: n = 21p - 120 = 60q - 63 => q = (7p - 19)/20 p = 17 works between p = 1 to 20. So p = 17 mod 20. p = 17,37,57,77,97... 21p - 120 >= 1000 => p>=880/21 => p = 57 => q = 19 n = 21*57-120 = 1077 sum_digits(n) = 15 Why is this wrong? gcd(63, 1077 + 120) = 63 not 21. gcd(63, n + 120) = 21 means that gcd(63/21,(n+120)/21) = 1 gcd(3,p) = 1 => p can't be a multiple of 3 but we chose 57. Similarly: gcd(n+63,120) = 60 => gcd((n+63)/60,2) = 1 => gcd(q,2) = 1 => q is odd. So coming back to: q = (7p - 19)/20 for p = 77, q = (77*7 - 19)/20 = 26 but q has to be odd. for p = 97, q = (97*7 - 19)/20 = (630 + 49 - 19)/20 = 660/20 = 33. It works. So, n = 60*33 - 63 = 1980 - 63 = 1917 sum_digits(n) = 18 Q2. Prove that 10^(3n+1) cannot be represented as a sum of 2 cubes(integers). S2. Typically when dealing wi...

practice problems

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Q1. S1. First do angle chasing and get all angles. Now apply Sine rule in AMC. AC/sin(150) = MC/sin(7) sin(150) = sin(180-150) = sin(30) = 1/2 => AC = MC/2sin(7)___[1] In BMC: BC/sin(M) = MC/sin(97-M) BC = AC and sin(97-M) = sin(90 + 7 - M) = cos(7-M) = cos(M-7) => AC = MC.sin(M)/cos(M-7)  ____[2] Using [1] and [2]: 1/2sin(7) = sin(M)/cos(M-7) => 2sin(7)sin(M) = cos(M-7) = cosMcos7 + sinMsin7 sin7sinM = cos7cosM tan7 = cotM = tan(90-M) => M = 83 = answer Q2. S2. Isosceles triangle, altitude bisects the base. x^2 = h^2 + 225 y^2 = h^2 + 36 (x+y)(x-y) = 189 = 3^3*7 189 = 189 * 1 = 63 * 3 = 21 * 9 = 7 * 27 case 1: x+y = 189, x-y=1 => 2x = 190 => x = 95, y=94 => AD = CD = 95, perimeter = 190 + 30 = 220 case 2: x+y = 63, x-y=3 => 2x = 66 => x = 33, y=30 => AD = CD = 33, perimeter = 66 + 30 = 96 case 3: x+y = 21, x-y=9 => 2x = 30 => x = 15, y=6 => AD = CD = 15, invalid since AC = 30 case 4: x+y = 27, x-y=7 => 2x = 34 => x = 17, y=10 => AD =...

practice problems pending concept class

Q1. Is there a solution to 5x = 3 mod 11? Yes. Why? Since 5,11 are co-prime we can always find 'x' s.t. 5.x = r mod 11 for all 'r' from 0 to 10. Q2. Simple way to solve x = 1 mod 3 x = 2 mod 5 x = 3k + 1 3k + 1 = 2 mod 5 3k = 1 mod 5 => k = 2 mod 5 => k = 5t + 2 => x = 3(5t + 2) + 1 = 15t + 7 = 7 mod 15 Similarly x = 0 mod 8 x = 59 mod 125 125p + 59 = 0 mod 8 5p + 3 = 0 mod 8 5p = 5 mod 8 p = 1 mod 8 So x = 125*1 + 59 = 184

Euler's totient theorem(Euler-Fermat theorem)

Let phi(n) = totient function, i.e. number of integers upto 'n' which are co-prime to it. Then: a^(phi(n)) = 1 mod 'n' if 'a' and 'n' are co-prime. You can see the similarity with Fermat's little theorem: a^(p-1) = 1 mod 'p' where 'p' is a prime and 'a','p' are co-prime. As we know all integers upto 'p' are co-prime to it.

calculus pending Newton's method

 newton's method