Differentiation (DP IB Applications & Interpretation (AI))

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Cards in this collection (30)

  • What is a limit?

    A limit is a value that a function approaches as x approaches a particular value from either side.

  • What is a derivative?

    A derivative (also known as a gradient function) is a function that relates the gradient of another function to the value of x.

  • What does fraction numerator straight d y over denominator straight d x end fraction mean?

    fraction numerator straight d y over denominator straight d x end fraction means the derivative of y with respect to x.

  • What does f to the power of apostrophe stretchy left parenthesis x stretchy right parenthesis mean?

    f to the power of apostrophe open parentheses x close parentheses means the derivative of the function f open parentheses x close parentheses with respect to x.

  • True or False?

    The derivative of a constant function is always zero.

    True.

    The derivative of a constant function is always zero.

  • State the formula for differentiating x to the power of n.

    If f open parentheses x close parentheses equals x to the power of n, then f to the power of apostrophe open parentheses x close parentheses equals n x to the power of n minus 1 end exponent.

    I.e. the original power comes in front as a multiplier, then the original power is reduced by 1.

    This formula is in the exam formula booklet.

  • What is the derivative of a x, where a is a constant?

    The derivative of a x, where a is a constant, is a.

  • What is a tangent?

    A tangent is a straight line that touches a curve at a point without crossing through it.

  • True or False?

    The gradient of a curve at a point is equal to the gradient of the tangent to the curve at that point.

    True.

    The gradient of a curve at a point is equal to the gradient of the tangent to the curve at that point.

  • What is an alternative notation for f to the power of apostrophe open parentheses x close parentheses?

    If y equals f open parentheses x close parentheses, then an alternative notation for f to the power of apostrophe open parentheses x close parentheses is fraction numerator straight d y over denominator straight d x end fraction.

  • True or False?

    The derivative of 4 over x is 4 x to the power of negative 2 end exponent.

    False.

    The derivative of 4 over x is negative 4 x to the power of negative 2 end exponent, which is the same as negative 4 over x squared.

    To differentiate a reciprocal, first rewrite it as a negative power: 4 over x equals 4 x to the power of negative 1 end exponent.

    Then use "If f open parentheses x close parentheses equals x to the power of n, then f to the power of apostrophe open parentheses x close parentheses equals n x to the power of n minus 1 end exponent".

  • What is the derivative of a sum (or difference) of functions equal to?

    The derivative of a sum (or difference) of functions is equal to the sum (or difference) of their individual derivatives.

  • What does it mean if f to the power of apostrophe open parentheses x close parentheses greater than 0?

    If f to the power of apostrophe open parentheses x close parentheses greater than 0, it means the function f open parentheses x close parentheses is increasing.

  • True or False?

    A function is decreasing if f to the power of apostrophe open parentheses x close parentheses less than 0.

    True.

    A function is decreasing if f to the power of apostrophe open parentheses x close parentheses less than 0.

  • What is a stationary point?

    A stationary point is a point on a function where f to the power of apostrophe open parentheses x close parentheses equals 0.

    I.e., it is a point on a function where the tangent is horizontal.

  • What is a normal (or normal line) with regard to a function?

    A normal (or normal line) is a straight line that passes through a point on a curve and is perpendicular to the tangent at that point.

  • What is the relationship between the gradients of a tangent and a normal at the same point on a curve?

    At the same point on a curve, the product of the gradients of a tangent and its normal is equal to -1.

  • True or False?

    Local minimum and maximum points are types of stationary points.

    True.

    Local minimum and maximum points are types of stationary points.

  • What is a local minimum point?

    A local minimum point is a point where the function value is the lowest in the immediate vicinity.

  • True or False.

    The equation of the tangent to y equals f open parentheses x close parentheses at the point open parentheses x subscript 1 comma space y subscript 1 close parentheses can be found by using y minus y subscript 1 equals f open parentheses x subscript 1 close parentheses open parentheses x minus x subscript 1 close parentheses.

    False.

    To find the equation of the tangent you need to use the value of the derivative (gradient function) of the curve at the point open parentheses x subscript 1 comma space y subscript 1 close parentheses.

    The equation of the tangent to y equals f open parentheses x close parentheses at the point open parentheses x subscript 1 comma space y subscript 1 close parentheses can be found by using y minus y subscript 1 equals f to the power of apostrophe open parentheses x subscript 1 close parentheses open parentheses x minus x subscript 1 close parentheses.

  • True or False.

    A local maximum point is the point at which a function takes on its maximum value.

    False.

    A local maximum point is not necessarily the point at which a function takes on its maximum value.

    A local maximum point is a point at which the function value is the highest in the immediate vicinity. There may however be other points (not in the immediate vicinity) at which the function takes on a higher value.

  • How can you use gradients to determine if a stationary point is a local minimum or local maximum?

    To determine if a stationary point is a local minimum or local maximum, look at the gradient of the function on either side of the stationary point.

    • If the gradient is positive to the left of the point and negative to the right, then the stationary point is a local maximum.

    • If the gradient is negative to the left of the point and positive to the right, then the stationary point is a local minimum.

  • What is an equation for the normal to a curve y equals f open parentheses x close parentheses at the point open parentheses x subscript 1 comma space y subscript 1 close parentheses?

    An equation for the normal to a curve y equals f open parentheses x close parentheses at the point open parentheses x subscript 1 comma space y subscript 1 close parentheses is y minus y subscript 1 equals negative fraction numerator 1 over denominator f to the power of apostrophe open parentheses x subscript 1 close parentheses end fraction open parentheses x minus x subscript 1 close parentheses.

  • What are optimisation problems?

    Optimisation problems are problems that involve maximizing or minimising a quantity.

  • What is a constraint?

    A constraint is a condition that limits the possible values of variables in a problem.

  • True or False?

    A useful first step in solving an optimisation problem is rewriting the quantity to be optimised as a function of a single variable.

    True.

    A useful first step in solving an optimisation problem is rewriting the quantity to be optimised as a function of a single variable.

  • True or False?

    A GDC can be used to find local maximum or minimum points in optimisation problems.

    True.

    A GDC can be used to find local maximum or minimum points in optimisation problems.

    One way to do this is to use the GDC's graphing features to draw a graph of the function.

  • True or False?

    The context of a question is not important when writing down the final solution of an optimisation problem.

    False.

    The final step in solving an optimisation problem is interpreting the answer in the context of the question.

  • True or False?

    Optimisation problems always have a unique solution.

    False.

    Optimisation problems may have multiple solutions or no solution.

  • Why is it important to interpret the solution to an optimisation problem in the context of the problem?

    Interpreting the solution to an optimisation problem in the context of the problem is important to ensure the answer makes sense in the real-world situation being modelled.