Check the relation is a factor of on the set of natural numbers N for reflexivity symmetry and transitivity.

The relation 'less than' in the set of natural numbers is

Show that the relation is a subset of on the set of all sets is reflexive and transitive but not symmetric on S.

The relation R is defined on the set of natural numbers N as x is a factor of y where x, y in N. Then R is -

Show that the relation is greater than on the set of real numbers RR is transitive but neither reflexive nor symmetric on RR .

Define a relation R on the set A ={a,b,c} which is neither reflexive nor symmetric and transitive.

Check whether the relation R in R defined by R = {(a,b): a le b ^(3)} is reflexive, symmetric or transitive.

Prove that the relation is perpendicular to on the set L of all straight lines in a plane is symmetric but neither reflexive nor transitive on L.

The relation R defined on the set N N of natural numbers by xRy iff 2x^(2) -3xy +y^(2) =0 is

A relation S is defined on the set of real numbers R R a follows : S{(x,y) : x^(2) +y^(2)=1 for all x,y in R R } Check the relation S for (i) reflexivity (ii) symmetry an (iii) transitivity.

A relation R is defined on the set of natural numbers NN as follows : (x,y)in R rArr y is divisible by x, for all x, y in NN . Show that, R is reflexive and transitive but not symmetric on NN .