6:[["$","$L12",null,{"dangerouslySetInnerHTML":{"__html":"\n if (typeof window !== 'undefined') {\n if ('scrollRestoration' in history) {\n history.scrollRestoration = 'manual';\n }\n }\n "},"id":"disable-scroll-restoration","strategy":"beforeInteractive"}],["$","$L1e",null,{"label":"subjects-ap-calculus-ab-quiz-sketching-graphs-of-functions-and-derivatives","children":[["$","$L1f",null,{"ancestors":[{"slug":"advanced-placement","name":"Advanced Placement","description":"College-level courses and examinations designed for motivated high school students.","tier":"Flagship Academic","icon":"BadgeCheck","color":"amber","parent_slug":null,"hidden":false,"canonical_slug":null}],"initialQuestionIndex":0,"pathString":"sketching-graphs-of-functions-and-derivatives","questions":[{"answers":[{"id":"c13dae34-30f1-4ee8-91df-56b674f2eb20-3","isCorrect":false,"text":"$$f$ must be increasing for all $x$."},{"id":"c13dae34-30f1-4ee8-91df-56b674f2eb20-2","isCorrect":false,"text":"$$f$ must be decreasing for all $x$."},{"id":"c13dae34-30f1-4ee8-91df-56b674f2eb20-0","isCorrect":false,"text":"$$f$ has a local minimum at $x=-1$."},{"id":"c13dae34-30f1-4ee8-91df-56b674f2eb20-1","isCorrect":true,"text":"$$f$ has an inflection point at $x=-1$ because $f''$ changes sign there."},{"id":"c13dae34-30f1-4ee8-91df-56b674f2eb20-4","isCorrect":false,"text":"$$f$ has a local maximum at $x=-1$."}],"explanation":"This question tests graph-derivative reasoning by inferring the function's concavity from the derivative's extrema. f' having a local maximum at x=-1, increasing for x<-1 and decreasing for x>-1, means f'' > 0 left (f' increasing) and f'' < 0 right (f' decreasing), so f'' changes sign at -1. This sign change indicates an inflection point for f at x=-1, where concavity shifts from up to down. The description doesn't specify f'(-1)=0 or its sign, so no guaranteed critical point or extremum for f. A tempting distractor is E, suggesting a local max for f, but if f'(-1) > 0 and doesn't change sign, f would be increasing through -1 without a max. A reliable sketch-checking strategy is to use f'' sign changes to locate inflections on f, independent of f' values.","graphic_url":"$undefined","id":"c13dae34-30f1-4ee8-91df-56b674f2eb20","name":"Question 1","passage":"$undefined","question":"$$f'$ has a local maximum at $x=-1$ and is increasing for $x<-1$ and decreasing for $x>-1$. What can be concluded about $f$?","slug":"sketching-graphs-of-functions-and-derivatives-question-1"},{"answers":[{"id":"471a3b6c-42e4-4807-af59-c2571f2ca772-1","isCorrect":false,"text":"$$f''(x)<0$ on $(-2,1)$ and $f''(x)>0$ on $(1,4)$."},{"id":"471a3b6c-42e4-4807-af59-c2571f2ca772-2","isCorrect":false,"text":"$$f''(x)=0$ for all $x$ in $(-2,4)$."},{"id":"471a3b6c-42e4-4807-af59-c2571f2ca772-4","isCorrect":false,"text":"$$f''(x)<0$ for all $x$ in $(-2,4)$."},{"id":"471a3b6c-42e4-4807-af59-c2571f2ca772-0","isCorrect":true,"text":"$$f''(x)>0$ on $(-2,1)$ and $f''(x)<0$ on $(1,4)$."},{"id":"471a3b6c-42e4-4807-af59-c2571f2ca772-3","isCorrect":false,"text":"$$f''(x)>0$ for all $x$ in $(-2,4)$."}],"explanation":"This question tests graph-derivative reasoning by relating concavity of the function to the sign of its second derivative. Concave up on (-2, 1) means f'' > 0 there, as the second derivative positive indicates the graph curves upward. Concave down on (1, 4) means f'' < 0 there, curving downward. This direct correspondence matches choice A, with the change at x = 1 potentially indicating an inflection point. A tempting distractor is B, which swaps the signs, but that would reverse the concavity intervals, making it up on (1, 4) and down on (-2, 1). A useful strategy for checking sketches is to remember that f'' > 0 where f' is increasing and f'' < 0 where f' is decreasing, linking concavity to the derivative's monotonicity.","graphic_url":"$undefined","id":"471a3b6c-42e4-4807-af59-c2571f2ca772","name":"Question 2","passage":"$undefined","question":"$$f$ is concave up on $(-2,1)$ and concave down on $(1,4)$. Which statement could describe the sign of $f''$?","slug":"sketching-graphs-of-functions-and-derivatives-question-2"},{"answers":[{"id":"853f6be2-f53f-4a7e-a360-010f7ec59456-0","isCorrect":false,"text":"$$f'(x)>0$ and $f''(x)>0$."},{"id":"853f6be2-f53f-4a7e-a360-010f7ec59456-1","isCorrect":true,"text":"$$f'(x)<0$ and $f''(x)>0$."},{"id":"853f6be2-f53f-4a7e-a360-010f7ec59456-3","isCorrect":false,"text":"$$f'(x)<0$ and $f''(x)<0$."},{"id":"853f6be2-f53f-4a7e-a360-010f7ec59456-2","isCorrect":false,"text":"$$f'(x)>0$ and $f''(x)<0$."},{"id":"853f6be2-f53f-4a7e-a360-010f7ec59456-4","isCorrect":false,"text":"$$f'(x)=0$ and $f''(x)>0$ for all $x$."}],"explanation":"This question tests graph-derivative reasoning, connecting the signs of f' and f'' to the monotonicity and concavity of f. For f decreasing on (0,4), f' < 0 there, indicating a negative slope. For concave up, f'' > 0, meaning the graph curves upward like a U-shape while overall descending. This combination shows f decreasing but with slopes becoming less negative over the interval. A tempting distractor is choice D, which has f'' < 0, but that would make f concave down, not up. A transferable sketch-checking strategy is to combine sign charts for f' and f'' to predict both direction and curvature on f's graph.","graphic_url":"$undefined","id":"853f6be2-f53f-4a7e-a360-010f7ec59456","name":"Question 3","passage":"$undefined","question":"If $f$ is decreasing and concave up on $(0,4)$, which sign pattern must occur on $(0,4)$?","slug":"sketching-graphs-of-functions-and-derivatives-question-3"},{"answers":[{"id":"bf167047-9e8a-4880-898c-375eeea66f63-0","isCorrect":true,"text":"$$f''(x)>0$ for $x<1$, $f''(1)=0$, and $f''(x)<0$ for $x>1$."},{"id":"bf167047-9e8a-4880-898c-375eeea66f63-4","isCorrect":false,"text":"$$f''$ is undefined at $x=1$ and negative on both sides."},{"id":"bf167047-9e8a-4880-898c-375eeea66f63-1","isCorrect":false,"text":"$$f''(x)<0$ for $x<1$, $f''(1)=0$, and $f''(x)>0$ for $x>1$."},{"id":"bf167047-9e8a-4880-898c-375eeea66f63-3","isCorrect":false,"text":"$$f''(x)>0$ for all $x$ and never equals $0$."},{"id":"bf167047-9e8a-4880-898c-375eeea66f63-2","isCorrect":false,"text":"$$f''(x)=0$ for all $x$."}],"explanation":"This question tests graph-derivative reasoning, linking the concavity of f to the signs and zeros of f''. Concave up intervals correspond to f'' > 0, and concave down to f'' < 0. An inflection point at x=1 means f'' changes sign there, from positive to negative for a shift from concave up to down. Thus, f'' > 0 for x<1, =0 at x=1, and <0 for x>1. A tempting distractor is choice B, which flips the signs and would reverse the concavity change. A transferable sketch-checking strategy is to plot the sign changes in f'' and verify they match the desired concavity shifts on f's graph.","graphic_url":"$undefined","id":"bf167047-9e8a-4880-898c-375eeea66f63","name":"Question 4","passage":"$undefined","question":"A function $f$ is concave up on $(-\\infty,1)$ and concave down on $(1,\\infty)$; which could be $f''$?","slug":"sketching-graphs-of-functions-and-derivatives-question-4"},{"answers":[{"id":"8548f4e4-dba8-4194-b4a9-97b0c29ae39e-1","isCorrect":false,"text":"$$f$ has local minima at both $x=-2$ and $x=3$."},{"id":"8548f4e4-dba8-4194-b4a9-97b0c29ae39e-3","isCorrect":false,"text":"$$f$ is decreasing on $(-2,3)$ and increasing elsewhere."},{"id":"8548f4e4-dba8-4194-b4a9-97b0c29ae39e-0","isCorrect":false,"text":"$$f$ has a local maximum at $x=-2$ and a local minimum at $x=3$."},{"id":"8548f4e4-dba8-4194-b4a9-97b0c29ae39e-2","isCorrect":true,"text":"$$f$ is increasing everywhere and has no local extrema at $x=-2$ or $x=3$."},{"id":"8548f4e4-dba8-4194-b4a9-97b0c29ae39e-4","isCorrect":false,"text":"$$f$ has local maxima at both $x=-2$ and $x=3$."}],"explanation":"This question tests graph-derivative reasoning, examining how zeros of f' without sign changes affect f's monotonicity. With f' = 0 at x=-2 and x=3 but > 0 elsewhere, f' never changes sign and remains non-negative. This means f is increasing everywhere, and the zeros do not create local extrema since there's no shift from increasing to decreasing or vice versa. Such points might be horizontal inflections but do not halt the overall increasing trend. A tempting distractor is choice A, which assumes sign changes for extrema, but here f' stays positive around the zeros. A transferable sketch-checking strategy is to check for sign changes around f''s zeros; no change means no extremum, even if f'=0.","graphic_url":"$undefined","id":"8548f4e4-dba8-4194-b4a9-97b0c29ae39e","name":"Question 5","passage":"$undefined","question":"A differentiable function $f$ has $f'(x)=0$ at $x=-2$ and $x=3$ and $f'(x)>0$ elsewhere; which best describes $f$?","slug":"sketching-graphs-of-functions-and-derivatives-question-5"},{"answers":[{"id":"237d3a04-70d5-4665-96ee-7ffbe055d81e-4","isCorrect":false,"text":"$$f'$ is zero only at $x=-3$ and changes sign there."},{"id":"237d3a04-70d5-4665-96ee-7ffbe055d81e-0","isCorrect":false,"text":"$$f'$ crosses from negative to positive at $x=-3$ and from positive to negative at $x=1$."},{"id":"237d3a04-70d5-4665-96ee-7ffbe055d81e-3","isCorrect":false,"text":"$$f'$ has no zeros and stays negative for all $x$."},{"id":"237d3a04-70d5-4665-96ee-7ffbe055d81e-1","isCorrect":false,"text":"$$f'$ is zero at $x=-3,1$ and positive everywhere else."},{"id":"237d3a04-70d5-4665-96ee-7ffbe055d81e-2","isCorrect":true,"text":"$$f'$ crosses from positive to negative at $x=-3$ and from negative to positive at $x=1$."}],"explanation":"This question tests graph-derivative reasoning, specifically identifying sign changes in f' at local extrema of f. A local maximum occurs where f' changes from positive to negative, as the function shifts from increasing to decreasing. A local minimum occurs where f' changes from negative to positive, marking a shift from decreasing to increasing. Here, f' should cross from positive to negative at x=-3 (for the maximum) and from negative to positive at x=1 (for the minimum). A tempting distractor is choice A, which reverses the sign changes and would swap the maximum and minimum locations. A transferable sketch-checking strategy is to use the first derivative test by checking sign changes around critical points to confirm the type of extremum.","graphic_url":"$undefined","id":"237d3a04-70d5-4665-96ee-7ffbe055d81e","name":"Question 6","passage":"$undefined","question":"A differentiable function $f$ has a local maximum at $x=-3$ and a local minimum at $x=1$; which could be $f'$?","slug":"sketching-graphs-of-functions-and-derivatives-question-6"},{"answers":[{"id":"ad3c2780-58c0-44e5-9cbc-eb9684940fbc-3","isCorrect":false,"text":"$$f$ decreases on both intervals and has no extremum at $x=0$."},{"id":"ad3c2780-58c0-44e5-9cbc-eb9684940fbc-1","isCorrect":true,"text":"$$f$ decreases on $(-2,0)$, increases on $(0,4)$, with a local minimum at $x=0$."},{"id":"ad3c2780-58c0-44e5-9cbc-eb9684940fbc-2","isCorrect":false,"text":"$$f$ increases on both intervals and has no extremum at $x=0$."},{"id":"ad3c2780-58c0-44e5-9cbc-eb9684940fbc-0","isCorrect":false,"text":"$$f$ increases on $(-2,0)$, decreases on $(0,4)$, with a local maximum at $x=0$."},{"id":"ad3c2780-58c0-44e5-9cbc-eb9684940fbc-4","isCorrect":false,"text":"$$f$ has a horizontal tangent at $x=0$ but continues decreasing for $x>0$."}],"explanation":"This question tests graph-derivative reasoning, relating the signs and zeros of f' to the monotonicity and extrema of f. Where f' is negative on (-2,0), f is decreasing, and where positive on (0,4), f is increasing. The zero of f' at x=0 indicates a critical point, with the sign change from negative to positive signaling a local minimum. Thus, f decreases to a minimum at x=0 and then increases. A tempting distractor is choice A, which reverses the intervals and would imply a local maximum instead of a minimum. A transferable sketch-checking strategy is to trace the sign chart of f' and ensure it produces the correct increasing/decreasing patterns on f's graph.","graphic_url":"$undefined","id":"ad3c2780-58c0-44e5-9cbc-eb9684940fbc","name":"Question 7","passage":"$undefined","question":"The derivative $f'$ is negative on $( -2,0)$ and positive on $(0,4)$ with a zero at $x=0$; which could be $f$?","slug":"sketching-graphs-of-functions-and-derivatives-question-7"},{"answers":[{"id":"9075ff68-f7e3-4b67-8522-806664d9e4b6-3","isCorrect":false,"text":"A cubic with three real zeros at $x=-1,0,3$."},{"id":"9075ff68-f7e3-4b67-8522-806664d9e4b6-4","isCorrect":false,"text":"A constant positive function."},{"id":"9075ff68-f7e3-4b67-8522-806664d9e4b6-2","isCorrect":false,"text":"A line that is negative for all $x$."},{"id":"9075ff68-f7e3-4b67-8522-806664d9e4b6-0","isCorrect":false,"text":"A parabola opening down crossing the $x$-axis at $x=-1$ and $x=3$."},{"id":"9075ff68-f7e3-4b67-8522-806664d9e4b6-1","isCorrect":true,"text":"A parabola opening up crossing the $x$-axis at $x=-1$ and $x=3$."}],"explanation":"This question asks you to identify which derivative graph matches the given increasing/decreasing behavior of f. When f is increasing, f'(x) > 0, and when f is decreasing, f'(x) < 0. Since f changes from increasing to decreasing at x = -1, we have a local maximum there, so f'(-1) = 0. Similarly, f changes from decreasing to increasing at x = 3, giving a local minimum, so f'(3) = 0. The derivative must be positive on (-∞,-1), negative on (-1,3), and positive on (3,∞). Option A (parabola opening down) would be positive between its roots but negative outside, which is backwards. The correct answer is a parabola opening up, which is negative between its roots -1 and 3 and positive outside, matching our required sign pattern.","graphic_url":"$undefined","id":"9075ff68-f7e3-4b67-8522-806664d9e4b6","name":"Question 8","passage":"$undefined","question":"A function $f$ is increasing on $(-\\infty,-1)$, decreasing on $(-1,3)$, then increasing on $(3,\\infty)$. Which could be $f'(x)$?","slug":"sketching-graphs-of-functions-and-derivatives-question-8"},{"answers":[{"id":"64ccfaae-95c7-436a-bb93-dd07a1b9a671-1","isCorrect":false,"text":"A decreasing function for $x<0$ and increasing function for $x>0$ (a valley at $x=0$)."},{"id":"64ccfaae-95c7-436a-bb93-dd07a1b9a671-4","isCorrect":false,"text":"A decreasing function for all $x$."},{"id":"64ccfaae-95c7-436a-bb93-dd07a1b9a671-0","isCorrect":true,"text":"An increasing function for $x<0$ and decreasing function for $x>0$ (a peak at $x=0$)."},{"id":"64ccfaae-95c7-436a-bb93-dd07a1b9a671-2","isCorrect":false,"text":"A constant function."},{"id":"64ccfaae-95c7-436a-bb93-dd07a1b9a671-3","isCorrect":false,"text":"An increasing function for all $x$."}],"explanation":"This question asks you to determine what the derivative looks like given concavity information about the original function. When f is concave up, f'' > 0, which means f' is increasing. When f is concave down, f'' < 0, which means f' is decreasing. Since concavity changes at x = 0, this is an inflection point where f'' = 0, so f' has a local extremum at x = 0. The derivative f' must be increasing for x < 0 and decreasing for x > 0, which means f' has a local maximum at x = 0. Option B (valley at x = 0) would represent a local minimum of f', not a maximum. The correct answer shows f' increasing then decreasing with a peak at x = 0, matching our requirement.","graphic_url":"$undefined","id":"64ccfaae-95c7-436a-bb93-dd07a1b9a671","name":"Question 9","passage":"$undefined","question":"A function $f$ is concave up on $(-\\infty,0)$ and concave down on $(0,\\infty)$. Which could be $f'(x)$?","slug":"sketching-graphs-of-functions-and-derivatives-question-9"},{"answers":[{"id":"626e7eba-680f-415f-bdc2-ab7217e12f88-3","isCorrect":false,"text":"A constant negative function."},{"id":"626e7eba-680f-415f-bdc2-ab7217e12f88-1","isCorrect":false,"text":"A parabola opening downward crossing the $x$-axis at $x=0$ and $x=2$."},{"id":"626e7eba-680f-415f-bdc2-ab7217e12f88-4","isCorrect":false,"text":"A sinusoid crossing the $x$-axis infinitely many times."},{"id":"626e7eba-680f-415f-bdc2-ab7217e12f88-0","isCorrect":false,"text":"A line with positive slope crossing the $x$-axis at $x=0$."},{"id":"626e7eba-680f-415f-bdc2-ab7217e12f88-2","isCorrect":true,"text":"A line with negative slope crossing the $x$-axis at $x=0$."}],"explanation":"This question requires you to determine what derivative graph produces exactly one critical point with consistent concavity. Since f has exactly one critical point at x = 0, the derivative f'(0) = 0 and this is the only place where f' equals zero. Since f is concave down for all x, we have f''(x) < 0 everywhere, which means f' is always decreasing. A decreasing function that crosses the x-axis exactly once must go from positive to negative. Option A (positive slope line) would represent an increasing f', contradicting that f'' < 0. The correct answer is a line with negative slope crossing at x = 0, which is always decreasing (matching f'' < 0) and gives exactly one critical point.","graphic_url":"$undefined","id":"626e7eba-680f-415f-bdc2-ab7217e12f88","name":"Question 10","passage":"$undefined","question":"A differentiable $f$ has exactly one critical point at $x=0$, and $f$ is concave down for all $x$. Which could be $f'(x)$?","slug":"sketching-graphs-of-functions-and-derivatives-question-10"},{"answers":[{"id":"42f17bfc-4baf-4e51-9cdc-a1a69941f6f4-3","isCorrect":false,"text":"Always positive and strictly increasing (no turning point)."},{"id":"42f17bfc-4baf-4e51-9cdc-a1a69941f6f4-2","isCorrect":false,"text":"Always negative with a local extremum at $x=0$."},{"id":"42f17bfc-4baf-4e51-9cdc-a1a69941f6f4-0","isCorrect":true,"text":"Always positive with a local extremum at $x=0$."},{"id":"42f17bfc-4baf-4e51-9cdc-a1a69941f6f4-4","isCorrect":false,"text":"Always positive and constant."},{"id":"42f17bfc-4baf-4e51-9cdc-a1a69941f6f4-1","isCorrect":false,"text":"Crosses the $x$-axis at $x=0$."}],"explanation":"This question asks what the derivative looks like when a function is always increasing but has an inflection point. Since f is increasing for all x, we know $f'(x) > 0$ everywhere. At the inflection point $x = 0$, the concavity changes, so $f''(0) = 0$ and f' has a local extremum at $x = 0$. Since f' must stay positive (to keep f increasing), it cannot cross the x-axis but can have a local minimum or maximum while remaining above the x-axis. Option B (crosses the x-axis) would create a critical point of f, contradicting that f is always increasing. The correct answer shows f' always positive with a local extremum at $x = 0$, which keeps f increasing while allowing the concavity to change at the inflection point.","graphic_url":"$undefined","id":"42f17bfc-4baf-4e51-9cdc-a1a69941f6f4","name":"Question 11","passage":"$undefined","question":"A function $f$ is increasing for all $x$ and has exactly one inflection point at $x=0$. Which could be $f'(x)$?","slug":"sketching-graphs-of-functions-and-derivatives-question-11"},{"answers":[{"id":"cf33aa10-f67c-4598-bb0e-9b6232f66028-4","isCorrect":false,"text":"$$f'$ is decreasing on all real numbers."},{"id":"cf33aa10-f67c-4598-bb0e-9b6232f66028-0","isCorrect":true,"text":"$$f'$ is increasing for $x<0$ and decreasing for $x>0$."},{"id":"cf33aa10-f67c-4598-bb0e-9b6232f66028-3","isCorrect":false,"text":"$$f'$ is increasing on all real numbers."},{"id":"cf33aa10-f67c-4598-bb0e-9b6232f66028-1","isCorrect":false,"text":"$$f'$ is decreasing for $x<0$ and increasing for $x>0$."},{"id":"cf33aa10-f67c-4598-bb0e-9b6232f66028-2","isCorrect":false,"text":"$$f'$ is constant on both sides of $0$ with a removable discontinuity at $0$."}],"explanation":"This question tests the relationship between f'' and the monotonicity of f'. When f'' > 0, the derivative f' is increasing; when f'' < 0, the derivative f' is decreasing. Since f'' > 0 for x < 0, we know f' increases on (-∞,0). Since f'' < 0 for x > 0, we know f' decreases on (0,∞). This means f' has a maximum at x = 0. Choice B incorrectly reverses this, showing f' with a minimum at x = 0. To determine f' behavior from f'': positive second derivative means f' increases; negative second derivative means f' decreases.","graphic_url":"$undefined","id":"cf33aa10-f67c-4598-bb0e-9b6232f66028","name":"Question 12","passage":"$undefined","question":"A function $f$ has $f''(x)>0$ for $x<0$ and $f''(x)<0$ for $x>0$; which could be $f'$?","slug":"sketching-graphs-of-functions-and-derivatives-question-12"},{"answers":[{"id":"cb7ebcc0-d600-4862-a725-1aad11c76800-0","isCorrect":false,"text":"$$f'$ is negative for $x<-2$, positive for $-21$."},{"id":"cb7ebcc0-d600-4862-a725-1aad11c76800-1","isCorrect":true,"text":"$$f'$ crosses the $x$-axis at $x=-2$ and $x=1$, positive for $x<-2$, negative for $-21$."},{"id":"cb7ebcc0-d600-4862-a725-1aad11c76800-2","isCorrect":false,"text":"$$f'$ is zero only at $x=0$ and is positive everywhere else."},{"id":"cb7ebcc0-d600-4862-a725-1aad11c76800-4","isCorrect":false,"text":"$$f'$ is negative for all $x$ and has holes at $x=-2$ and $x=1$."},{"id":"cb7ebcc0-d600-4862-a725-1aad11c76800-3","isCorrect":false,"text":"$$f'$ is positive for $x<-2$, negative for $x>-2$, and never zero again."}],"explanation":"This problem requires translating local extrema of f into sign changes of f'. At a local maximum, f' changes from positive to negative; at a local minimum, f' changes from negative to positive. Since f has a local max at x = -2, f' must go from positive to negative there, crossing zero. Since f has a local min at x = 1, f' must go from negative to positive there, also crossing zero. Between these points (-2 < x < 1), f' must be negative for f to decrease from the max to the min. Choice A incorrectly omits the zero crossings at the extrema. Remember: local extrema of f correspond to sign-changing zeros of f'.","graphic_url":"$undefined","id":"cb7ebcc0-d600-4862-a725-1aad11c76800","name":"Question 13","passage":"$undefined","question":"A function $f$ has a local maximum at $x=-2$ and a local minimum at $x=1$; which could be $f'$?","slug":"sketching-graphs-of-functions-and-derivatives-question-13"},{"answers":[{"id":"9e166160-c282-404d-b69c-d55e61a3594e-3","isCorrect":false,"text":"A graph with a jump discontinuity at $x=1$ but increasing on both sides."},{"id":"9e166160-c282-404d-b69c-d55e61a3594e-1","isCorrect":true,"text":"A graph that is decreasing on $(-4,1)$ and increasing on $(1,5)$."},{"id":"9e166160-c282-404d-b69c-d55e61a3594e-2","isCorrect":false,"text":"A constant positive horizontal line."},{"id":"9e166160-c282-404d-b69c-d55e61a3594e-0","isCorrect":false,"text":"A graph that is increasing on $(-4,1)$ and decreasing on $(1,5)$."},{"id":"9e166160-c282-404d-b69c-d55e61a3594e-4","isCorrect":false,"text":"A graph that is increasing on all real numbers with a sharp corner at $x=1$."}],"explanation":"This problem tests understanding how concavity of f relates to monotonicity of f'. When f is concave down, f' must be decreasing; when f is concave up, f' must be increasing. Since f is concave down on (-4,1), we need f' to decrease on this interval. Since f is concave up on (1,5), we need f' to increase on this interval. This describes a function f' that has a minimum at x = 1. Choice A incorrectly shows f' increasing then decreasing, which would make f concave up then down. Remember: concave down means f' decreases; concave up means f' increases.","graphic_url":"$undefined","id":"9e166160-c282-404d-b69c-d55e61a3594e","name":"Question 14","passage":"$undefined","question":"A function $f$ is concave down on $(-4,1)$ and concave up on $(1,5)$; which could be $f'$?","slug":"sketching-graphs-of-functions-and-derivatives-question-14"},{"answers":[{"id":"872f483f-0c6c-42f7-bf8c-f85c2a936994-3","isCorrect":false,"text":"A function with local minima at both $x=-1$ and $x=2$."},{"id":"872f483f-0c6c-42f7-bf8c-f85c2a936994-0","isCorrect":false,"text":"An increasing function with a horizontal tangent at $x=-1$ and $x=2$, increasing everywhere else."},{"id":"872f483f-0c6c-42f7-bf8c-f85c2a936994-2","isCorrect":true,"text":"An increasing function with a local maximum at $x=-1$ and a local minimum at $x=2$."},{"id":"872f483f-0c6c-42f7-bf8c-f85c2a936994-1","isCorrect":false,"text":"A decreasing function with a local minimum at $x=-1$ and local maximum at $x=2$."},{"id":"872f483f-0c6c-42f7-bf8c-f85c2a936994-4","isCorrect":false,"text":"A function with local maxima at both $x=-1$ and $x=2$."}],"explanation":"This question requires translating derivative sign information into the behavior of the original function. When f' is positive on (-∞, -1) ∪ (2, ∞), the function f is increasing on these intervals. When f' is negative on (-1, 2), the function f is decreasing there. At x = -1, f transitions from increasing to decreasing, creating a local maximum. At x = 2, f transitions from decreasing to increasing, creating a local minimum. Choice A incorrectly claims f has horizontal tangents without extrema at these points. The key insight is that sign changes in f' create extrema in f, with positive-to-negative producing maxima and negative-to-positive producing minima.","graphic_url":"$undefined","id":"872f483f-0c6c-42f7-bf8c-f85c2a936994","name":"Question 15","passage":"$undefined","question":"A function $f'$ is positive on $(-\\infty,-1)\\cup(2,\\infty)$ and negative on $(-1,2)$; which could be $f$?","slug":"sketching-graphs-of-functions-and-derivatives-question-15"}],"subject":{"slug":"ap-calculus-ab","name":"AP Calculus AB","description":"Advanced Placement Calculus AB covering limits, derivatives, and integrals.","tier":"Flagship Academic","icon":"TrendingUp","color":"amber","parent_slug":"advanced-placement","hidden":false,"canonical_slug":null},"topicId":"ap-calculus-ab.sketching-graphs-of-functions-and-derivatives","topicName":"Sketching Graphs of Functions and Derivatives"}],"$L20"]}]]

Sketching Graphs of Functions and Derivatives Practice Test

$f'$ has a local maximum at $x=-1$ and is increasing for $x<-1$ and decreasing for $x>-1$. What can be concluded about $f$?

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