If `f:R rarr [(pi)/(3), pi)` defined by `f(x)=cos^(-1)((lambda-x^(2))/(x^(2)+3))` is a surjective function, then `lambda` is equal to

If f:R rarr [(pi)/(3),pi) defined by f(x)=cos^(-1)((lambda-x^(2))/(x^(2)+2)) is a surjective function, then the value of lambda is equal to

If f:R rarr [(pi)/(3),pi) defined by f(x)=cos^(-1)((lambda-x^(2))/(x^(2)+2)) is a surjective function, then the value of lambda is equal to

If the function f:R rarr A defined as f(x)=sin^(-1)((x)/(1+x^(2))) is a surjective function, then the set A is

If the function f:R rarr A defined as f(x)=sin^(-1)((x)/(1+x^(2))) is a surjective function, then the set A is

If f:R rarr (0, pi//2], f(x)=sin^(-1)((40)/(x^(2)+x+lambda)) is a surjective function, then the value of lambda is equal to

If f:R rarr (0, pi//2], f(x)=sin^(-1)((40)/(x^(2)+x+lambda)) is a surjective function, then the value of lambda is equal to

If the function f:R rarrA defined as f(x)=tan^(-1)((2x^(3))/(1+x^(6))) is a surjective function, then the set A is equal to

If the function f:R rarrA defined as f(x)=tan^(-1)((2x^(3))/(1+x^(6))) is a surjective function, then the set A is equal to

Show that f: R->R defined by f(x)=(x-1)(x-2)(x-3) is surjective but not injective.

Show that f: R->R defined by f(x)=(x-1)(x-2)(x-3) is surjective but not injective.