vertical asymptote at x = 3. There is no horizontal asymptote, but notice that the degree of thenumerator of the function is 1 greater than the denominator. This means that there is an oblique(slant) asymptote. We find this by dividing the denominator into the numerator and looking atthe quotient. We getThis means that as x → ±∞, the function will behave like the function y = x + 3. This means that
there is an oblique asymptote of y = x + 3. Next, we take the derivative:= = . Next, we set thederivative equal to zero to find the critical points. There are two solutions: x = 3 + and x =3 − . We plug these values into the original equation to find the y-coordinates of the criticalpoints: When x = 3 + , = 6 + 2 . When x = 3 − , y = = 6 −2 . Thus, we have critical points at (3 + , 6 + 2 ) and (3 − ,6 − 2 ). Next, we take the second derivative: . If we set this equal to zero,there is no solution. Therefore, there is no point of inflection. But, notice that the secondderivative changes sign from negative to positive at x = 3. This means that the curve is concavedown for values of x less than x = 3 and concave up for values of x greater than x = 3. Next, weneed to determine if each critical point is maximum, minimum, or something else. If we plug x= 3 + into the second derivative, the value is positive, so (3 + , 6 + 2 ) is aminimum. If we plug x = 3 − into the second derivative, the value is positive, so (3 − ,6 − 2 ) is a maximum.