Calculus I · Limits and Continuity · practice
Continuity and IVT Practice Problems
Practice Continuity and IVT Practice Problems with warm-up, homework-level, reasoning, and exam-style problems plus answer support.
Chapter 5 Exercises
A. Three-part continuity test
Is continuous at ? Verify all three conditions.
Is continuous at ? Identify the first failed condition.
A function has and . Is it continuous at ?
A function has and . Which condition fails?
A function is undefined at , but its limit there is . Which conditions fail?
A function has unequal one-sided limits at . Can it be continuous there?
Explain why existence of alone says nothing about continuity.
Explain why existence of a finite limit alone does not guarantee continuity.
B. Intervals of continuity
Find intervals of continuity of .
Find intervals of continuity of .
Find intervals of continuity of .
Find intervals of continuity of .
Find intervals of continuity of on .
Find intervals of continuity of .
Find the domain and intervals of continuity of .
Explain endpoint continuity for on .
C. Classifying discontinuities
Classify the discontinuity of at .
Classify the discontinuity of at .
Classify the discontinuity of at .
Classify the discontinuity of at .
Find and classify every discontinuity of .
Find and classify every discontinuity of .
Can changing one function value repair a jump? Explain.
Can changing one function value repair a vertical asymptote? Explain.
D. Repairing holes
Find so makes continuous.
Find so makes continuous.
Find so makes continuous.
Find so makes continuous.
Explain why no value at makes continuous there.
Explain why no value at makes continuous there.
E. Piecewise parameters
Find so \(
\) is continuous at .
Find so \(
\) is continuous at .
Find so \(
\) is continuous at .
Find so \(
\) is continuous at .
Determine whether any makes \(
\) continuous at .
Find so \(
\) is continuous at both joins.
Design a piecewise function with one parameter that becomes continuous when the parameter is .
Explain why setting left and right formulas equal is necessary but not always sufficient when the actual function value is defined by a third rule.
F. Intermediate Value Theorem and bisection
Show that has a root in .
Show that has a root in .
Show that has a solution in .
Explain why a sign change is sufficient but not necessary for a root to exist.
Give a continuous function with a root in whose endpoint values have the same sign.
Explain why IVT cannot be applied to on , despite opposite endpoint signs.
Use two bisection steps to narrow a root of from .
Use three bisection steps to narrow a root of from .
Does IVT prove uniqueness? Give an example supporting your answer.
State every hypothesis and conclusion in a complete IVT solution.
Answers begin in the referenced section.
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