Problem 16
Question
Describe the interval(s) on which the function is continuous. Explain why the function is continuous on the interval(s). If the function has a discontinuity, identify the conditions of continuity that are not satisfied. \(f(x)=3-2 x-x^{2}\)
Step-by-Step Solution
Verified Answer
The function \(f(x)=3-2x-x^{2}\) is continuous for all real numbers, \(-\infty
1Step 1: Identify the function type
The given function \(f(x)=3-2x-x^{2}\) is a quadratic function. A polynomial function of degree n (in this case n=2, a quadratic function), is continuous everywhere in its domain, because all of the operations in the function (addition, subtraction, multiplication, and powers) are also continuous.
2Step 2: Determine the continuity
For a polynomial function, such as \(f(x) = 3-2x-x^{2}\), it is continuous for all values of real number x. The domain of \(f(x)\) is the set of all real numbers, \(-\infty
3Step 3: Identify the conditions not satisfied
Since \(f(x)=3-2x-x^{2}\) is continuous for all real numbers, no conditions of continuity are violated. Hence, this step does not apply because there's no discontinuity.
Key Concepts
Quadratic FunctionsDomain of a FunctionConditions of Continuity
Quadratic Functions
When we talk about quadratic functions, we're discussing a very particular kind of polynomial. They're shaped like a U or an upside-down U and have a formula that can be written as \(f(x) = ax^2 + bx + c\), where \(a\), \(b\), and \(c\) are constants and \(a\) is not zero. The graph of such a function is called a parabola.
One remarkable property of quadratic functions is their symmetry; they are symmetric about a vertical line that goes through their vertex, the highest or lowest point on the graph. The importance of this symmetry becomes clear when we discuss the function's continuity and domain. Owing to the unbroken and smooth nature of the parabola, quadratic functions are inherently continuous throughout their domain.
One remarkable property of quadratic functions is their symmetry; they are symmetric about a vertical line that goes through their vertex, the highest or lowest point on the graph. The importance of this symmetry becomes clear when we discuss the function's continuity and domain. Owing to the unbroken and smooth nature of the parabola, quadratic functions are inherently continuous throughout their domain.
Domain of a Function
The domain of a function is the set of all the inputs over which the function is defined. In simpler terms, it's an answer to the question, 'For which values of \(x\) does this function give a valid output?' For quadratic functions, like the one we're examining \(f(x) = 3-2x-x^2\), the domain is all real numbers because you can plug any real number into that function and get a real number out.
Understanding the domain is vital when studying the function's behavior because it tells us where to look for continuity and possible discontinuities. However, since quadratic functions are polynomial functions of degree 2, their continuous nature means we expect no interruptions in the graph — so the function is continuous over its entire domain.
Understanding the domain is vital when studying the function's behavior because it tells us where to look for continuity and possible discontinuities. However, since quadratic functions are polynomial functions of degree 2, their continuous nature means we expect no interruptions in the graph — so the function is continuous over its entire domain.
Conditions of Continuity
For a function to be continuous at a point, it must satisfy three conditions: the function must be defined at that point, the limit of the function as it approaches the point from both sides must exist, and the value of the limit must equal the function's value at that point. These conditions ensure there are no breaks, jumps, or holes at that point in the graph.
For our quadratic function \(f(x) = 3-2x-x^2\), it meets all these conditions for continuity for every value in its domain, which is the set of all real numbers. This means the graph of \(f(x)\) is a single unbroken curve with no gaps or jumps — illustrating a perfect example of a continuous function. Because all these continuity conditions are satisfied for all real numbers, the function does not have any discontinuities.
For our quadratic function \(f(x) = 3-2x-x^2\), it meets all these conditions for continuity for every value in its domain, which is the set of all real numbers. This means the graph of \(f(x)\) is a single unbroken curve with no gaps or jumps — illustrating a perfect example of a continuous function. Because all these continuity conditions are satisfied for all real numbers, the function does not have any discontinuities.
Other exercises in this chapter
Problem 16
At \(0^{\circ}\) Celsius, the heat loss \(H\) (in kilocalories per square meter per hour) from a person's body can be modeled by \(H=33(10 \sqrt{v}-v+10.45)\) w
View solution Problem 16
Find the derivative of the function. $$ y=2 x^{3}-x^{2}+3 x-1 $$
View solution Problem 16
Use the limit definition to find the slope of the tangent line to the graph of \(f\) at the given point. $$ f(x)=2 x+4 ;(1,6) $$
View solution Problem 16
Find the limit of (a) \(\sqrt{f(x)}\), (b) \([3 f(x)]\), and (c) \([f(x)]^{2}\), as \(x\) approaches \(c\). $$ \lim _{x \rightarrow c} f(x)=9 $$
View solution