The relation R is defined on the set of natural numbers as {(a, b) : a = 2b}. Then, `R^(-1)` is given by

The relation R defined on the set of natural numbers as {(a,b) : a differs from b by 3} is given by

Prove that the relation R defined on the set of real numbers R as R = {(a,b) : a le b^(2) AA a, b in R} is neither reflexive nor symmetric nor transitive.

Let us define a relation R on the set R of real numbers as a R b if a ge b . Then R is

The given relation is defined on the set of real numbers. a R b iff |a| = |b| . Find whether these relations are reflexive, symmetric or transitive.

Prove that the relation R defined on the set N of natural numbers by xRy iff 2x^(2) - 3xy + y^(2) = 0 is not symmetric but it is reflexive.

Let R be a relation defined on the set of natural numbers N as follow : R= {(x,y):x in N, y in N and 2x+y=24} Find the domain and range of the relation R. Also, find R is an equivalence relation or not.

R is a relation over the set of real numbers and it is given by mn ge 0 . Then R is :

Show that the relation S in the set R of real numbers defined as S={(a,b): a, b in R and a le b^(3) } is neither reflexive, nor symmetric, nor transitive.

Show that the relation R in the set of all natural number, N defined by is an R = {(a , b) : |a - b| "is even"} in an equivalence relation.