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Chapter 12: Problem 22

Sketch the surfaces in Exercises \(13-44.\) PARABOLOIDS AND CONES $$z=8-x^{2}-y^{2}$$

Short Answer

Expert verified
The surface is an elliptic paraboloid opening downward with a vertex at (0, 0, 8).

Step by step solution

01

Recognize the Type of Surface

The given equation is \( z = 8 - x^2 - y^2 \). This is in the standard form of an elliptic paraboloid given by \( z = c - ax^2 - by^2 \), where \( a, b > 0 \). This indicates a paraboloid that opens downwards.
02

Identify Vertex and Axis

The vertex of the paraboloid is at the point where \( x = 0 \) and \( y = 0 \), which gives \( z = 8 \). So, the vertex is at \((0, 0, 8)\). The axis of symmetry is along the negative \( z \)-axis, as the paraboloid opens downward.
03

Determine Intercepts

For the \( z \)-intercept, set \( x = 0 \) and \( y = 0 \) in the equation: \( z = 8 \). For \( x \)- and \( y \)-intercepts, set \( z = 0 \): \( 0 = 8 - x^2 - y^2 \) simplifying to \( x^2 + y^2 = 8 \). This is the equation of a circle in the \( xy \)-plane.
04

Draw Level Curves

Level curves are obtained by setting \( z = k\), with \( 0 \leq k \leq 8 \). Substitute \( z = k \) into the equation to get \( k = 8 - x^2 - y^2 \), rearranging gives \( x^2 + y^2 = 8 - k \). These are circles with radii \( \sqrt{8-k} \) in the \( xy \)-plane.
05

Sketch the Surface

Start by plotting the vertex at \( (0, 0, 8) \). Sketch circles of decreasing radius as \( z \) decreases from 8 to 0. Connect the circles smoothly to form the downward-opening paraboloid, ensuring the surfaces taper into a single point at each level curve.

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Key Concepts

These are the key concepts you need to understand to accurately answer the question.

Vertex of a Paraboloid
In mathematics, the vertex of a paraboloid is a critical point that acts as the pinnacle or base of the shape, depending on its orientation. For an elliptic paraboloid given by the equation \( z = c - ax^2 - by^2 \), the vertex is located where the expressions for \( x \) and \( y \) are both zero. This simplifies the equation to \( z = c \), offering the vertex coordinates as \((0, 0, c)\). In this case, for the paraboloid described by \( z = 8 - x^2 - y^2 \), the vertex is at \((0, 0, 8)\).
  • The vertex is crucial because it provides a reference point from which we determine other aspects of the paraboloid, such as its spread and direction.
  • Understanding the vertex can help in graphing and analyzing how the surface behaves as \( x \) and \( y \) change.
Axis of Symmetry
The axis of symmetry for a paraboloid is the line around which the surface is symmetrical. For elliptic paraboloids of the form \( z = c - ax^2 - by^2 \), the axis of symmetry aligns with the \( z \)-axis. This particular paraboloid opens downward along the negative \( z \)-axis since the coefficients of \( x^2 \) and \( y^2 \) are both positive, indicating that it curves away from the vertex.
  • The axis of symmetry helps in visualizing the shape since the paraboloid is uniform around this axis.
  • By knowing the axis, students can better understand the slope and spread of the paraboloid.
The axis of symmetry is vital for creating a clear and precise graph of the paraboloid surface.
Level Curves
Level curves are two-dimensional slices of a three-dimensional surface that help us understand the structure of a paraboloid. By setting \( z = k \) for various values of \( k \), we can find sets of \( (x, y) \) that satisfy \( x^2 + y^2 = 8 - k \). These equations describe circles in the \( xy \)-plane with radii \( \sqrt{8-k} \).
  • As \( k \) decreases from 8 to 0, the radii of these level curves shrink, showing how the paraboloid narrows as it gets closer to the vertex.
  • Level curves are instrumental in three-dimensional graphing, offering a step-by-step path to constructing the full surface from its slices.
By examining level curves, we can grasp both the height and variation of the surface, making it a powerful tool for visualization.
Three-Dimensional Graphing
Three-dimensional graphing involves visualizing surfaces like paraboloids in a coordinate system made of three axes: \( x \)-axis, \( y \)-axis, and \( z \)-axis. For the paraboloid \( z = 8 - x^2 - y^2 \), the graphing process starts with plotting the vertex at \( (0, 0, 8) \). Each level curve, which you obtain by setting different \( z \) values, can be plotted as circles in the \( xy \)-plane. These circles connect to form a downward-opening surface.
  • Visualizing through three-dimensional graphing offers insights into the symmetry and shape of the paraboloid.
  • Using this approach, you can accurately depict both the shape's curvature and its diminishing size as it moves toward the vertex.
Three-dimensional graphing not only aids in understanding the mathematics behind the paraboloid but also enhances intuitive comprehension by providing a tangible view of the surface.

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Most popular questions from this chapter

In Exercises \(1-8,\) find \begin{equation} \begin{array}{l}{\text { a. } \mathbf{v} \cdot \mathbf{u},|\mathbf{v}|,|\mathbf{u}|} \\ {\text { b. the cosine of the angle between } \mathbf{v} \text { and } \mathbf{u}} \\ {\text { c. the scalar component of } \mathbf{u} \text { in the direction of } \mathbf{v}} \\ {\text { d. the vector proj, u. }}\end{array} \end{equation} \begin{equation} \mathbf{v}=2 \mathbf{i}+10 \mathbf{j}-11 \mathbf{k}, \quad \mathbf{u}=2 \mathbf{i}+2 \mathbf{j}+\mathbf{k} \end{equation}

Find the areas of the triangles whose vertices are given in Exercises \(41-47 .\) $$ A(-5,3), \quad B(1,-2), \quad C(6,-2) $$

Perpendicular diagonals Show that squares are the only rectangles with perpendicular diagonals.

Triangle area Find a \(2 \times 2\) determinant formula for the area of the triangle in the \(x y\) -plane with vertices at \((0,0),\left(a_{1}, a_{2}\right),\) and \(\left(b_{1}, b_{2}\right) .\) Explain your work.

Use a calculator to find the acute angles between the planes in Exercises \(49-52\) to the nearest hundredth of a radian. $$ 2 x+2 y+2 z=3, \quad 2 x-2 y-z=5 $$
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