Let `x, y in R`. Then `x + i y` is a non real complex number if

For real numbers x and y, define xRY if and only if x - y + sqrt(2) is an irrational number. Then the relation R is

Let R be the set of real numbers. Statement 1: A={(x,y) in R xx R : y-x is an integer} is an equivalence relation on R. Statement 2: B= {x,y} in Rxx R : x=alpha y for some rational number alpha } is an equivalence relation on R.

Let f: R->R whre R^+ is the set of all positive real numbers, be such that f(x)=(log)_e xdot Determine: whether f(x y)=f(x)+f(y) holds.

If R is a relation on R (set of all real numbers) defined by x R y iff x-y+sqrt2 is an irrational number, then R is

For real numbers x and y, we write x* y, if x - y +sqrt2 is an irrational number. Then, the relation * is an equivalence relation.

Let R_(1)= {(x,y)in RxxR :x = lambda y implies lambda in Q} is a relation, R is set of real numbers then R_(1) is

Check whether the following pair of statements are negation of each other. Give reasons for your answer.(i) x + y = y + x is true for every real numbers x and y.(ii) There exists real numbers x and y for which x + y = y + x

Let z=x+i y be a complex number, where xa n dy are real numbers. Let Aa n dB be the sets defined by A={z :|z|lt=2}a n dB={z :(1-i)z+(1+i)bar z geq4} . Find the area of region AnnB

Let a, x, y, z be real numbers satisfying the equations ax+ay=z x+ay=z x+ay=az, where x, y, z are not all zero, then the number of the possible values of a is

Let R be a relation on the set of all real numbers defined by xRy iff |x-y|leq1/2 Then R is