5.2 Extreme Value Theorem, Global Versus Local Extrema

Cards (100)

  • Global extrema are the absolute maximum and minimum values of a function over its entire domain.

    True
  • The Extreme Value Theorem states that if a function f(x) is continuous on a closed interval [a, b], then f(x) must attain both a global maximum and a global minimum
  • What does the Extreme Value Theorem ensure about continuous functions on closed intervals?
    Absolute extreme values exist
  • How are global extrema defined in the context of the Extreme Value Theorem?
    Absolute max/min on interval
  • What is the key difference between global and local extrema?
    Absolute vs relative values
  • If the second derivative at a critical point is negative, the critical point is a local maximum
  • Steps to identify local extrema:
    1️⃣ Find the critical points
    2️⃣ Evaluate the function at critical points
    3️⃣ Determine the type using the second derivative test
  • What is the first condition for the Extreme Value Theorem?
    Function continuity
  • Global extrema are absolute maximum and minimum values within a closed interval.

    True
  • If the second derivative is positive at a critical point, it indicates a local minimum
  • What is the purpose of the second derivative test in identifying local extrema?
    Determine the type of critical points
  • The critical points of f(x) are the x-values where f'(x) = 0 or is undefined.

    True
  • What does the Extreme Value Theorem state for a continuous function on a closed interval?
    Global max and min exist
  • Match the type of extrema with its definition:
    Global Extrema ↔️ Absolute max/min over entire domain
    Local Extrema ↔️ Relative max/min in a local region
  • The interval required for the Extreme Value Theorem must be closed.

    True
  • The Extreme Value Theorem requires the function to be differentiable on the closed interval.
    False
  • To find local extrema, first find the critical points by setting the first derivative equal to zero
  • Steps to identify local extrema using differentiation:
    1️⃣ Find critical points
    2️⃣ Evaluate the function at critical points
    3️⃣ Apply the second derivative test
    4️⃣ Classify each critical point
  • A positive second derivative at a critical point indicates a local minimum.

    True
  • The Extreme Value Theorem guarantees the existence of both a global maximum and a global minimum
  • The interval for the Extreme Value Theorem must be closed
  • Match the type of extrema with its description:
    Global Extrema ↔️ Absolute max/min on a closed interval
    Local Extrema ↔️ Relative max/min in a specific region
  • If the second derivative is zero at a critical point, the second derivative test is inconclusive.

    True
  • Steps to find local extrema using differentiation
    1️⃣ Calculate the first derivative f'(x)
    2️⃣ Set f'(x) = 0 and solve for x
    3️⃣ Determine where f'(x) is undefined
    4️⃣ Calculate the second derivative f''(x)
    5️⃣ Evaluate f''(x) at critical points
    6️⃣ Find the y-values of the extrema
  • What type of extrema is x = 4 for f(x) = x³ - 6x² + 5?
    Local minimum
  • If f''(0) = -6 for f(x) = x³ - 3x² + 2, then x = 0 is a local maximum
  • The Extreme Value Theorem requires the function to be continuous on a closed interval.

    True
  • The Extreme Value Theorem states that if a function f(x) is continuous on a closed interval [a, b], then f(x) must attain both a global maximum and a global minimum
  • Why is the Extreme Value Theorem important in AP Calculus AB?
    Analyzes continuous function behavior
  • Match the condition with its requirement for the Extreme Value Theorem:
    Function ↔️ Must be continuous on the closed interval
    Interval ↔️ Must be closed [a, b]
  • Steps to identify global extrema using the Extreme Value Theorem:
    1️⃣ Find critical points
    2️⃣ Evaluate the function at critical points
    3️⃣ Evaluate the function at endpoints
    4️⃣ Identify the highest and lowest values
  • If the second derivative at a critical point is positive, the point is a local minimum.

    True
  • How do you find the critical points of a function?
    Set first derivative to zero
  • What is the difference between local and global extrema?
    Relative vs absolute values
  • The Extreme Value Theorem requires the function to be continuous on a closed interval.

    True
  • How do you find global extrema on a closed interval?
    Critical points and endpoints
  • What is the first step to identify local extrema of a function?
    Find critical points
  • Steps to complete the identification of local extrema:
    1️⃣ Find critical points
    2️⃣ Evaluate the second derivative
    3️⃣ Find the y-values
  • If f''(x) > 0 at a critical point, it is a local minimum
  • If f''(x) < 0 at a critical point, it is a local maximum