Deck 4: The Derivative in Graphing and Applications

Answer true or false. A graphing utility can be used to show that Rolle's Theorem can be applied to show that f(x) = (x - 8)² has a point where f '(x) = 0.

Answer true or false. According to Rolle's Theorem if a function's derivative is 0, the graph of the function must cross the y-axis.

Answer true or false. The hypotheses of the Mean-Value Theorem are satisfied for on [-2, 2].

Answer true or false. on [-3, 3] satisfies the hypotheses of Rolle's Theorem.

Verify that f(x) = x³ -5x + 4 satisfies the hypothesis of the Mean-Value Theorem over the interval [-2, 3] and find all values of C that satisfy the conclusion of the theorem.

Answer true or false. The hypotheses of the Mean-Value Theorem are satisfied for on [0, 4 $\pi$ ].

Verify that f(x) = x² + 7x - 3 satisfies the hypothesis of the Mean-Value Theorem over the interval [0, 1] and find all values of C that satisfy the conclusion of the theorem.

Answer true or false. Rolle's Theorem is used to find the zeros of a function.

Verify that f(x) = x³ - x satisfies the hypothesis of Rolle's Theorem on the interval [-1, 1] and find all values of C in (-1, 1) such that f '(C) = 0

Answer true or false. The hypotheses of the Mean-Value Theorem are satisfied for f(x) = cos 2x on [0, 4 $\pi$ ].

Answer true or false. The Mean-Value Theorem can be used on f(x) = |x - 3| on [-5, 5].

Answer true or false. The Mean-Value Theorem guarantees there is at least one c on [0, 1] such that f '(x) = 0.8 when f(x) = x.

Find the value c that satisfies Rolle's Theorem for f(x) = cos 4x on .

Does satisfy the hypothesis of the Mean-Value Theorem over the interval [-3, 3]? If so, find all values of C that satisfy the conclusion of the theorem.

Does satisfy the hypothesis of the Mean-Value Theorem over the interval [0, 1]? If so, find all values of C that satisfy the conclusion.

A cyclist starts from rest and travels 6.25 miles along a straight road in 15 minutes. Use the Mean-Value Theorem to show that at some instant during the trip his velocity was exactly 25 miles per hour.

Use Rolle's Theorem to prove that the equation 6x⁵ - 28x³ + 6 = 0 has at least one solution in the interval (0, 1).

Does satisfy the hypothesis of the Mean-Value Theorem over the interval [0, 6]? If so, find all values of C that satisfy the conclusion of the theorem.

Verify that f(x) = x² + 8 satisfies the hypothesis of the Mean-Value Theorem on the interval [0, 4] and find all values of C that satisfy the conclusion of the theorem.

Use Rolle's Theorem to show that f(x) = 4x³ + 5x - 1 does not have more than one real root.

Find the value of c in the interval [0, 2 $\pi$ ] that satisfies the Mean Value Theorem. f(x) = 6 cos x

Use Rolle's Theorem to show that f(x) = x³ + ax + b, where a > 0, cannot have more than one real root.

Does satisfy the hypothesis of the Mean-Value Theorem over the interval [-5, 5]? If so, find all values of C that satisfy the conclusion.

Find the value of c in the interval [0, 1] that satisfies the Mean Value Theorem. f(x) = x⁷

Verify that f(x) = x³ -3x²- 3x + 1 satisfies the hypothesis of the Mean-Value Theorem over the interval [0, 2] and find all values of C that satisfy the conclusion of the theorem.

Find the value of c in the interval [0, 4] that satisfies the Mean Value Theorem. f(x) = 5x² + 20

An automobile starts from rest and travels 4.5 miles along a straight road in 6 minutes. Use the Mean-Value Theorem to show that at some instant during the trip its velocity was exactly 45 miles per hour.

Find the value of c in the interval [-1, 1] that satisfies the Mean Value Theorem. f(x) = x² - 4x + 3

Verify that satisfies the hypothesis of the Mean-Value Theorem over the interval [6, 8] and find all values of C that satisfy the conclusion of the theorem.

Does satisfy the hypothesis of the Mean-Value Theorem over the interval [0, 16]? If so, find all values of C that satisfy the conclusion of the theorem.

Find the value of c in the interval [0, $\pi$ ] that satisfies the Mean Value Theorem. f(x) = sin(6x)

Find the value of c in the interval [0, 1] that satisfies the Mean Value Theorem. f(x) = x⁴ + 8

Approximate by applying Newton's Method to the equation x⁵ - 83 = 0. Use -2 for your initial value and calculate nine iterations.

Approximate by applying Newton's Method to the equation x³ - 73 = 0. Use 4 for your initial value and calculate five iterations.

Approximate by applying Newton's Method to the equation x³ -29 = 0. Use 3 for your initial value and calculate five iterations.

Approximate by applying Newton's Method to the equation x² -44 = 0. Use 6 for your initial value and calculate five iterations.

The equation, x³ - 2x - 19 = 0 has one real solution for 1 < x < 19. Approximate it by Newton's Method. Use 4.75 for your initial value and calculate eight iterations.

Approximate by applying Newton's Method to the equation x³ - 88 = 0. Use 4 for your initial value and calculate nine iterations.

Answer true or false. For the position function graphed, the acceleration at t = 1 is positive.

The equation, x³ + x² - 5x - 6 = 0 has one real solution for 1 < x < 6. Approximate it by Newton's Method. Use 3 for your initial value and calculate eight iterations.

Answer true or false. If a particle is dropped a distance of 624 m. It has a speed of 110.58 m/s (rounded to the nearest hundredth of a m/s) when it hits the ground.

The graph represents a position function. Determine what is happening to the velocity at t = 0.

The graph represents a position function. Determine what is happening to the velocity at t = 1.

s(t) = 4t - 3t², t $\ge$ 0. The velocity function is

The graph represents a velocity function. The acceleration at t = 2 is

Answer true or false. This can be the graph of a particle's position if the particle is moving to the right at t = 3.3.

The equation, has one real solution for . Approximate it by Newton's Method. Use 2 for your initial value and calculate eight iterations.

s(t) = 5t-4t³, t $\ge$ 0. The acceleration function is

Answer true or false. If the graph on the left is a position function, the graph on the right represents the corresponding velocity function.
y = x²

The equation, x³ - x² - 4x - 4 = 0 has one real solution for 1 < x < 4. Approximate it by Newton's Method. Use 3 for your initial value and calculate eight iterations.