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You can put this solution on YOUR website!
the formula for the sum of the first n terms of a geometric series is equal to:\r
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\n" ); document.write( "\n" ); document.write( "S[n] = (a[1] * (1-r^n)) / (1-r) where a[1] is the first term in the series.\r
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\n" ); document.write( "\n" ); document.write( "an example:\r
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\n" ); document.write( "\n" ); document.write( "n = 3 and r = .7 and a[1] = 500\r
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\n" ); document.write( "\n" ); document.write( "S[3] = (500 * (1-.7^3)) / (1-.7)\r
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\n" ); document.write( "\n" ); document.write( "this becomes equal to 1095.\r
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\n" ); document.write( "\n" ); document.write( "We can verify this by adding the elements together.\r
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\n" ); document.write( "\n" ); document.write( "the nth element in a geometric series is given by the equation a[n] = a[1]*r^(n-1).\r
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\n" ); document.write( "\n" ); document.write( "a[1] = 500 * .7^0 = 500
\n" ); document.write( "a[2] = 500 * .7^1 = 350
\n" ); document.write( "a[3] = 500 * .7^2 = 245\r
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\n" ); document.write( "\n" ); document.write( "sum is 500 + 350 + 245 = 1095\r
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\n" ); document.write( "\n" ); document.write( "as n approaches infinity, the formula of:\r
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\n" ); document.write( "\n" ); document.write( "S[n] = (a[1] * (1-r^n)) / (1-r) where a[1] is the first term in the series.\r
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\n" ); document.write( "\n" ); document.write( "becomes:\r
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\n" ); document.write( "\n" ); document.write( "S[infinity] = a[1] / (1-r) where a[1] is the first term in the series.\r
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\n" ); document.write( "\n" ); document.write( "r^n approaches 0 as n approaches infinity because r has to be smaller than 1.\r
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\n" ); document.write( "\n" ); document.write( "this makes the expression (1-r^n) approach 1 as n approaches infinity.\r
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\n" ); document.write( "\n" ); document.write( "an example:\r
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\n" ); document.write( "\n" ); document.write( "let r = .9\r
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\n" ); document.write( "\n" ); document.write( ".9^10 = .35
\n" ); document.write( ".9^100 = .000027
\n" ); document.write( ".9^1000 = 1.75 * 10^-46
\n" ); document.write( ".9^10000 = 0 on my calculator. it's not really 0 but it's so small that the calculator is not able to show it so it rounds the answer to 0.\r
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\n" ); document.write( "\n" ); document.write( "at any rate, the formula for the sum of a geometric series as n approaches infinity is equal to:\r
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\n" ); document.write( "\n" ); document.write( "S[infinity] = a[1] / (1-r) where a[1] is the first term in the series.\r
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\n" ); document.write( "\n" ); document.write( "your problem states:\r
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\n" ); document.write( "The sum of an infinite geometric series is twice its first term. Find the common ratio of the series.
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\n" ); document.write( "\n" ); document.write( "if the sum of the infinite geometric series is twice its first term, then we get:\r
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\n" ); document.write( "\n" ); document.write( "S[infinity] = 2*a[1]\r
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\n" ); document.write( "\n" ); document.write( "we can replace S[infinity] in the equation of:\r
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\n" ); document.write( "\n" ); document.write( "S[infinity] = a[1] / (1-r) where a[1] is the first term in the series.\r
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\n" ); document.write( "\n" ); document.write( "by 2*a[1] to get:\r
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\n" ); document.write( "\n" ); document.write( "2 * a[1] = a[1] / (1-r)\r
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\n" ); document.write( "\n" ); document.write( "if we multiply both sides of this equation by (1-r) and we divide both sides of this equation by 2 * a[1] then we get:\r
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\n" ); document.write( "\n" ); document.write( "(1-r) = a[1] / (2 * a[1])\r
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\n" ); document.write( "\n" ); document.write( "we simplify this to get:\r
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\n" ); document.write( "\n" ); document.write( "(1-r) = 1/2\r
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\n" ); document.write( "\n" ); document.write( "we add r to both sides of this equation and we subtract 1/2 from both sides of this equation to get:\r
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\n" ); document.write( "\n" ); document.write( "r = 1/2\r
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\n" ); document.write( "\n" ); document.write( "let's see if this can be confirmed.\r
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\n" ); document.write( "\n" ); document.write( "we assume r = 1/2 as we just calculated.\r
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\n" ); document.write( "\n" ); document.write( "we let a[1] be any number chosen at random.\r
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\n" ); document.write( "\n" ); document.write( "let's try 1469\r
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\n" ); document.write( "\n" ); document.write( "S[infinity] = a[1] / (1-r) = 1469 / (1-(1/2) = 1469 / (1/2) = 2938\r
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\n" ); document.write( "\n" ); document.write( "2938 is twice as large as 1469 so the equation is good.\r
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\n" ); document.write( "\n" ); document.write( "it will work in all equations, since the general form would be:\r
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\n" ); document.write( "\n" ); document.write( "S[infinity] = a[1] / (1 - (1/2) which always winds up being:\r
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\n" ); document.write( "\n" ); document.write( "S[infinity] = a[1] / (1/2).\r
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\n" ); document.write( "\n" ); document.write( "reference for formulas used is in the following link:\r
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\n" ); document.write( "\n" ); document.write( "http://people.richland.edu/james/lecture/m116/sequences/geometric.html\r
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\n" ); document.write( "\n" ); document.write( "Remember that r has to be smaller than 1 if we want to get the sum of the geometric series as n approaches infinity.\r
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