a^4 + b^3 = c^2 --> c^2-a^4 = b^3 --> we can put it as (c-a^2)*(c+a^2)=b*b^2 --> c-a^2=b--> a^2=c-b-----> (1) c+a^2=b^2 -----> (2) Considering (1) in (2) we have c+c-b=b^2 --> b^2+b-2c=0, to solve it as quadratic equation, b=(-1+sqrt(1+8c))/2, it has infinite number of solutions concerning b&c lets see what can a get, obviously it has much less solutions: b=1--> c=1--> a=0 b=2--> c=3--> a=1 b=3--> c=6--> a^2=3, no integer solution ... b=9--> c=45--> a=6 ... b=50--> c=1275--> a=35 ... b=289--> c=41905--> a=204 .. b=1682--> c=1415403--> a=1189 I got these numbers with the help of excel within first 3000 values of b. So based on above there are infinite number of solutions
Give positive numbers a, b and c are such that ab + bc + ca + abc = 4, What is the value of 1/a+2 + 1/b+2 + 1/c+2 = ?
Calculate the number of ordered triples (A1, A2, A3) such that:
A1 ∪ A2 ∪ A3 = {1, 2, 3, 4, 5, 6, 7, 8, 9, 10} A1 ∩ A2 ∩ A3 = ∅
Write your answer as 2a3b5c7d where a, b, c, d are non-negative integers.
If a, b, c and d are distinct pairwise co-prime positive integers such that a^2 + b^2 = c^2 + d^2, find the lowest possible value of a + b + c + d?
