Answer:
[tex]S_{n} = \frac{2(4^{n}-1) }3} if r>1[/tex]
Step-by-step explanation:
Explanation:-
Geometric sequence:-
The geometric sequence is of the form
[tex]a,ar,ar^{2},ar^{3}[/tex] ……… be an infinite sequence
here first term is 'a' and ratio is 'r '
In this geometric sequence 'n' t h term is [tex]t_{n} = a r^{n-1}[/tex]....(1)
Given data a1 term is '8 ' and ratio is '4'
substitute n=1 in equation(1)
[tex]t_{1} = a r^{1-1}[/tex] = 8
[tex]ar=8[/tex]...........(2)
substitute r= 4 in equation(2)
now we get a(4)=8
dividing "4" on both sides , we get a = 2
Geometric series:-
[tex]a+ar+ar^{2}+ar^{3}+[/tex].....is an infinite geometric series.
sum of this infinite series will be the upper limit of the fungal spores
that is we have to find sum of infinite series
[tex]S_{n} = \frac{a(r^{n}-1) }{r-1} if r>1[/tex]
[tex]S_{n} = \frac{2(4^{n}-1) }{4-1} if r>1[/tex]
[tex]S_{n} = \frac{2(4^{n}-1) }3} if r>1[/tex]
Final answer:-
sum of this infinite series will be the upper limit of the fungal spores
[tex]S_{n} = \frac{2(4^{n}-1) }3} if r>1[/tex]
