The asymptotes and intercepts, describe the behaviour of vertical asymptotes using limits, analyse and graph the function.
The vertical asymptotes,
Given:
The function is
Concept Used:
If a polynomial function in the form
And,
The end behaviour asymptote given by
The condition can be concluded as,
1) If
2) If
3) If
And,
The x -intercept is given by zeros of numerator that are not zero of denominator. And y -intercept is given by
From using asymptotes and intercepts the graph can be drawn.
Calculation:
Consider the function,
To find vertical asymptotes, find the zeros of denominator, so factorize the denominator
Thus, the zeros of denominator of
To find the behaviour of vertical asymptotes, compute the limit when x approaches to
To find end behaviour asymptotes, find
Since,
Now find the intercept, the x -intercept is given by zeros of numerator that are not zero of denominator.
Hence, to solve
That gives,
And y -intercept is given by
Thus y -intercept is
Hence, using vertical asymptotes,
Interpretations form graph:
1) Domain of
2) Range is
3) Continuous everywhere except
4) Increasing in
5) Local minima at
6) Not symmetric.
7) Unbounded.
Conclusion:
The vertical asymptotes,
Chapter 2 Solutions
Precalculus: Graphical, Numerical, Algebraic Common Core 10th Edition
- (4) (8 points) (a) (2 points) Write down a normal vector n for the plane P given by the equation x+2y+z+4=0. (b) (4 points) Find two vectors v, w in the plane P that are not parallel. (c) (2 points) Using your answers to part (b), write down a parametrization r: R² — R3 of the plane P.arrow_forward(2) (8 points) Determine normal vectors for the planes given by the equations x-y+2z = 3 and 2x + z = 3. Then determine a parametrization of the intersection line of the two planes.arrow_forward(3) (6 points) (a) (4 points) Find all vectors u in the yz-plane that have magnitude [u also are at a 45° angle with the vector j = (0, 1,0). = 1 and (b) (2 points) Using the vector u from part (a) that is counterclockwise to j, find an equation of the plane through (0,0,0) that has u as its normal.arrow_forward
- (1) (4 points) Give a parametrization c: R R³ of the line through the points P = (1,0,-1) and Q = (-2, 0, 1).arrow_forward4. Consider the initial value problem y' = 3x(y-1) 1/3, y(xo) = yo. (a) For what points (co, yo) does the IVP have a solution? (b) For what points (xo, yo) does the IVP have a unique solution on some open interval that contains 20? (c) Solve the IVP y' = 3x(y-1) 1/3, y(0) = 9 and determine the largest open interval on which this solution is unique.arrow_forwardFind the limit. (If the limit is infinite, enter 'oo' or '-o', as appropriate. If the limit does not otherwise exist, enter DNE.) lim X→ ∞ (✓ 81x2 - 81x + x 9x)arrow_forward
- 2) Compute the following anti-derivative. √1x4 dxarrow_forwardQuestion 3 (5pt): A chemical reaction. In an elementary chemical reaction, single molecules of two reactants A and B form a molecule of the product C : ABC. The law of mass action states that the rate of reaction is proportional to the product of the concentrations of A and B: d[C] dt = k[A][B] (where k is a constant positive number). Thus, if the initial concentrations are [A] = = a moles/L and [B] = b moles/L we write x = [C], then we have (E): dx dt = k(ax)(b-x) 1 (a) Write the differential equation (E) with separate variables, i.e. of the form f(x)dx = g(t)dt. (b) Assume first that a b. Show that 1 1 1 1 = (a - x) (b - x) - a) a - x b - x b) (c) Find an antiderivative for the function f(x) = (a-x) (b-x) using the previous question. (d) Solve the differentiel equation (E), i.e. find x as a function of t. Use the fact that the initial concentration of C is 0. (e) Now assume that a = b. Find x(t) assuming that a = b. How does this expression for x(t) simplify if it is known that [C] =…arrow_forward3) Find the volume of the solid that lies inside both the sphere x² + y² + z² cylinder x²+y² = 1. = 4 and thearrow_forward
- 1) Compute the following limit. lim x-0 2 cos(x) 2x² - x4arrow_forwardy = f(x) b C The graph of y = f(x) is shown in the figure above. On which of the following intervals are dy > 0 and dx d²y dx2 <0? I. aarrow_forward3 2 1 y O a The graph of the function f is shown in the figure above. Which of the following statements about f is true? о limb f(x) = 2 Olima f(x) = 2 о lima f (x) = lim x →b f(x) → f (x) = 1 limb. lima f(x) does not existarrow_forwardarrow_back_iosSEE MORE QUESTIONSarrow_forward_ios
- Calculus: Early TranscendentalsCalculusISBN:9781285741550Author:James StewartPublisher:Cengage LearningThomas' Calculus (14th Edition)CalculusISBN:9780134438986Author:Joel R. Hass, Christopher E. Heil, Maurice D. WeirPublisher:PEARSONCalculus: Early Transcendentals (3rd Edition)CalculusISBN:9780134763644Author:William L. Briggs, Lyle Cochran, Bernard Gillett, Eric SchulzPublisher:PEARSON
- Calculus: Early TranscendentalsCalculusISBN:9781319050740Author:Jon Rogawski, Colin Adams, Robert FranzosaPublisher:W. H. FreemanCalculus: Early Transcendental FunctionsCalculusISBN:9781337552516Author:Ron Larson, Bruce H. EdwardsPublisher:Cengage Learning