The answer depends on whether or not a is a factor of c.
The GCF is b.
The GCF is a2b.
The GCF of 35 a^2 and 85ab is 5a. The GCF of 35 and 85 is 5, and the GCF of a squared and ab is a.
a and b are factors of ab
It depends on whether or not a and c are coprime (have no factors in common). Suppose x is the greatest common factor of a and c, where x = 1 if a and c are coprime. ie GCF(a, c) = x then let a = x*m and c = x*n where m and n are coprime then LCM(ab, bc) = LCM(x*m*b, x*n*b) = x*m*n*b
The GCF is b.
The GCF is a.
The GCF is a2b.
The GCF is 7ab^2.
You want: abc + ab Factor out the common terms which are "a" and "b" ab ( c + 1 )
The GCF of 35 a^2 and 85ab is 5a. The GCF of 35 and 85 is 5, and the GCF of a squared and ab is a.
The GCF is 2.
a and b are factors of ab
The GCF of 7, 21 and 35 is 7. This leaves you with 1, 3 and 5 respectively, You can go no further as the only common factor remaining is 1.The factors of 7 are: 1, 7The factors of 21 are: 1, 3, 7, 21The factors of 35 are: 1, 5, 7, 35The common factors are: 1, 7The Greatest Common Factor (GCF) is: 7
It depends on whether or not a and c are coprime (have no factors in common). Suppose x is the greatest common factor of a and c, where x = 1 if a and c are coprime. ie GCF(a, c) = x then let a = x*m and c = x*n where m and n are coprime then LCM(ab, bc) = LCM(x*m*b, x*n*b) = x*m*n*b
Yes,type O is the universal donor,type O blood can be transfused to any blood type.Also,type AB is the universal receipiant , a person with type AB blood can be transfused with blood or blood products from any blood type.
Plus ab is an algebraic expression. As given you cannot solve it. However, If you have x +ab = c Then 'ab' can be solved. We do this by subtracting 'x' from both sides. (Preserve equality) x - x + ab = c - x x-x = 0 , just like 2 - 2 = 0 Hence ab = c -x