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5.4.2a The nth Term of Geometric Progression (Examples)


Example 1:
The sixth term of a geometric progression is 32 and the third term is 4. Find the first term and the common ratio.
Smart TIPSSolving the simultaneous equation of a and rUsing the formula T n = a r n−1

Solution:
T 6 =32 a r 5 =32 —– (1) T 3 =4 a r 2 =4 —– (2) (1) (2) = a r 5 a r 2 = 32 4 r 3 =8 r=2 Substitute r=2 into (2), a ( 2 ) 2 =4 a=1


Example 2:
In a geometric progression, the sum of the second term and the third term is 12 and the sum of the third term and the fourth term is 4, find the first term and the common ratio.
[Smart TIPS: Solving simultaneous equation to find a and r]

Solution:
T2 + T3 = 12
ar + ar2  = 12
ar (1 + r) = 12 —– (1) ← (Factorisation)
T3 + T4 = 4
ar2 + ar3  = 4
  ar2 (1 + r) = 4 —– (2)

(2) (1) = a r 2 ( 1+r ) ar( 1+r ) = 4 12 r= 1 3 Substitute r= 1 3  into (1), a( 1 3 )( 1+ 1 3 )=12 a=27



Example 3
Find which term in the progression 3, 12, 48, , … is the first to exceed 1 000 000.
[Smart TIPS: Using Tn formula for solving n]

Solution:
3 , 12 , 48 , ….. G P , a = 3 , r = T 2 T 1 = 12 3 = 4 T n > 1000000 ( 3 ) ( 4 ) n 1 > 1000000 ( 4 ) n 1 > 1000000 3 [ ( 3 ) ( 4 ) n 1 12 n 1 ] log 4 n 1 > log 1000000 3 ( Put log for both sides) ( n 1 ) lg 4 > lg 1000000 3 ( log a m n = n log a m ) ( n 1 ) ( 0.6021 ) > 5.523 n 1 > 9.17 n > 10.17 n = 11 ( n is an integer) C h e c k : T 11 = ( 3 ) ( 4 ) 10 T 11 = 3145728 > 1000000

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