Further Differentiation (DP IB Analysis & Approaches (AA))

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  • What does it mean to differentiate from first principles?

    Differentiating from first principles means using the definition of the derivative to show what the derivative of a function is.

    The definition is space f apostrophe left parenthesis x right parenthesis equals limit as h rightwards arrow 0 of space fraction numerator f left parenthesis x plus h right parenthesis minus f left parenthesis x right parenthesis over denominator h end fraction.

  • What is the definition of the derivative of a function f open parentheses x close parentheses?

    The definition of the derivative of a function f open parentheses x close parentheses is f apostrophe open parentheses x close parentheses equals limit as h rightwards arrow 0 of fraction numerator f open parentheses x plus h close parentheses minus f open parentheses x close parentheses over denominator h end fraction.

    This formula is in the exam formula booklet.

  • True or False?

    When h equals 0, fraction numerator f open parentheses x plus h close parentheses minus f open parentheses x close parentheses over denominator h end fraction is always defined.

    False.

    When h equals 0, fraction numerator f open parentheses x plus h close parentheses minus f open parentheses x close parentheses over denominator h end fraction is always undefined as it is equal to 0 over 0.

  • True or False?

    First principles is the quickest way to find derivatives.

    False.

    First principles is not the quickest way to find derivatives; there are much quicker methods.

    Only differentiate by first principles if an exam question tells you to.

  • What are the four steps in differentiating from first principles?

    The four steps in differentiating from first principles are:

    1. Identify the function f open parentheses x close parentheses and substitute this into the first principles formula.

    2. Expand f open parentheses x plus h close parentheses in the numerator.

    3. Simplify the numerator, factorise and cancel h with the denominator.

    4. Evaluate the remaining expression as h tends to zero.

  • Define the term rate of change.

    A rate of change is a measure of how a quantity is changing with respect to another quantity.

  • What is meant by related rates of change?

    Related rates of change are rates of change connected by a linking variable or parameter, often time.

    For example, if a container is being filled with water the rates of change for the volume and height of the water in the container are related rates of change connected by time.

  • True or False?

    A positive rate of change always indicates a decrease.

    False.

    A positive rate of change indicates an increase.

  • How is the chain rule used in solving related rates of change problems?

    In solving related rates of change problems, the chain rule is used to set up an equation linking rates of change.

    E.g. fraction numerator straight d V over denominator straight d t end fraction and fraction numerator straight d r over denominator straight d t end fraction can be linked using the chain rule equation fraction numerator straight d V over denominator straight d t end fraction equals fraction numerator straight d V over denominator straight d r end fraction cross times fraction numerator straight d r over denominator straight d t end fraction.

  • State the chain rule equation for related rates of change, connecting fraction numerator straight d y over denominator straight d x end fraction, fraction numerator straight d y over denominator straight d t end fraction and fraction numerator straight d x over denominator straight d t end fraction.

    The chain rule equation for related rates of change, connecting fraction numerator straight d y over denominator straight d x end fraction, fraction numerator straight d y over denominator straight d t end fraction and fraction numerator straight d x over denominator straight d t end fraction is fraction numerator straight d y over denominator straight d t end fraction equals fraction numerator straight d y over denominator straight d x end fraction cross times fraction numerator straight d x over denominator straight d t end fraction.

    This is not in the exam formula booklet (but it is a variant of the general chain rule formula which is in the booklet).

  • What is a useful mathematical relationship between fraction numerator straight d y over denominator straight d x end fraction and fraction numerator straight d x over denominator straight d y end fraction?

    A useful mathematical relationship between fraction numerator straight d y over denominator straight d x end fraction and fraction numerator straight d x over denominator straight d y end fraction is fraction numerator straight d y over denominator straight d x end fraction equals fraction numerator 1 over denominator open parentheses fraction numerator straight d x over denominator straight d y end fraction close parentheses end fraction.

    This allows fraction numerator straight d y over denominator straight d x end fraction to be found by finding fraction numerator straight d x over denominator straight d y end fraction instead and then inverting it.

  • True or False?

    If you know y equals f open parentheses x close parentheses and want to find the derivative of the inverse function y equals f to the power of negative 1 end exponent open parentheses x close parentheses, it might be easiest to start with x equals f open parentheses y close parentheses and find fraction numerator straight d x over denominator straight d y end fraction.

    True.

    If you know y equals f open parentheses x close parentheses and want to find the derivative of the inverse function y equals f to the power of negative 1 end exponent open parentheses x close parentheses, it might be easiest to start with x equals f open parentheses y close parentheses and find fraction numerator straight d x over denominator straight d y end fraction.

    E.g. for y equals square root of left parenthesis 5 x plus 1 right parenthesis cubed end root, you can start with x equals square root of left parenthesis 5 y plus 1 right parenthesis cubed end root, find fraction numerator straight d x over denominator straight d y end fraction, and then use fraction numerator straight d y over denominator straight d x end fraction equals fraction numerator 1 over denominator open parentheses fraction numerator straight d x over denominator straight d y end fraction close parentheses end fraction to find the derivative of the inverse of y equals square root of left parenthesis 5 x plus 1 right parenthesis cubed end root.

  • True or False?

    When using y equals f to the power of negative 1 end exponent open parentheses x close parentheses space left right double arrow space x equals f open parentheses y close parentheses to find the derivatives of inverse functions, the final result will always be in terms of x.

    False.

    When using y equals f to the power of negative 1 end exponent open parentheses x close parentheses space left right double arrow space x equals f open parentheses y close parentheses to find the derivatives of inverse functions, the final result will not always be in terms of x.

    The final result will usually be in terms of y, but it may be possible to use a substitution to get the answer in terms of x if required.

  • The equation for the volume, V, of a right cone is V equals 1 third pi r squared h.

    How can you find an expression for the rate of change fraction numerator straight d V over denominator straight d t end fraction expressed in terms of the rates of change fraction numerator straight d r over denominator straight d t end fraction and fraction numerator straight d h over denominator straight d t end fraction?

    The equation for the volume, V, of a right cone is V equals 1 third pi r squared h.

    To find an expression for the rate of change fraction numerator straight d V over denominator straight d t end fraction expressed in terms of the rates of change fraction numerator straight d r over denominator straight d t end fraction and fraction numerator straight d h over denominator straight d t end fraction, differentiate the formula for V implicitly with respect to t:

    fraction numerator straight d V over denominator straight d t end fraction equals fraction numerator straight d over denominator straight d t end fraction open parentheses 1 third pi r squared h close parentheses equals 2 over 3 pi r h fraction numerator straight d r over denominator straight d t end fraction plus 1 third pi r squared fraction numerator straight d h over denominator straight d t end fraction

    (Note that this involves using the product rule along with implicit differentiation.)

  • What is implicit differentiation?

    Implicit differentiation is a method of differentiating equations where y is not given explicitly as a function of x.

  • True or False?

    Implicit differentiation always uses the chain rule.

    True.

    Implicit differentiation always uses the chain rule.

  • What is fraction numerator straight d over denominator straight d x end fraction open parentheses f open parentheses y close parentheses close parentheses equal to using implicit differentiation?

    In implicit differentiation, fraction numerator straight d over denominator straight d x end fraction open parentheses f open parentheses y close parentheses close parentheses equals f apostrophe open parentheses y close parentheses fraction numerator straight d y over denominator straight d x end fraction.

    E.g. fraction numerator straight d over denominator straight d x end fraction open parentheses y squared close parentheses equals 2 y fraction numerator straight d y over denominator straight d x end fraction

  • True or False?

    When using implicit differentiation, fraction numerator straight d y over denominator straight d x end fraction will always be found in terms of bold italic x only.

    False.

    When using implicit differentiation, fraction numerator straight d y over denominator straight d x end fraction will not always be found in terms of bold italic x only.

    It will usually be found in terms of both x and y.

  • True or False?

    The product rule is never used in implicit differentiation.

    False.

    The product rule is often used (along with the chain rule) in implicit differentiation.

    E.g. fraction numerator straight d over denominator straight d x end fraction open parentheses x squared y squared close parentheses equals x squared fraction numerator straight d over denominator straight d x end fraction open parentheses y squared close parentheses plus y squared fraction numerator straight d over denominator straight d x end fraction open parentheses x squared close parentheses equals 2 x squared y fraction numerator straight d y over denominator straight d x end fraction plus 2 x y squared

  • True or False?

    At points on a curve where the tangent is horizontal fraction numerator straight d x over denominator straight d y end fraction equals 0, and at points where the tangent is vertical fraction numerator straight d y over denominator straight d x end fraction equals 0

    False.

    At points on a curve where the tangent is horizontal fraction numerator straight d y over denominator straight d x end fraction equals 0, and at points where the tangent is vertical fraction numerator straight d x over denominator straight d y end fraction equals 0

  • True or False?

    In optimisation questions using implicit differentiation, the locations of minimums and maximums will always occur at turning points.

    False.

    In optimisation questions using implicit differentiation, the locations of minimums and maximums will not always occur at turning points.

    It is possible that there may not be a turning point. Also the minimum or maximum could be at the start or end of a given or appropriate interval.

  • What is the derivative of f open parentheses x close parentheses equals sec x?

    The derivative of f open parentheses x close parentheses equals sec x is f to the power of apostrophe open parentheses x close parentheses equals sec x tan x.

    This is in the exam formula booklet.

  • True or False?

    The derivative of f open parentheses x close parentheses equals cosec x is f to the power of apostrophe open parentheses x close parentheses equals cosec x cot x.

    False.

    The derivative of f open parentheses x close parentheses equals cosec x is f to the power of apostrophe open parentheses x close parentheses equals negative cosec x cot x.

    This is in the exam formula booklet.

  • True or False?

    The derivatives for sec x and cosec x can be derived using the quotient rule.

    True.

    The derivatives for sec x and cosec x can be derived using the quotient rule.

    First write sec x equals fraction numerator 1 over denominator cos x end fraction and cosec x equals fraction numerator 1 over denominator sin x end fraction, then the quotient rule can be used to work out the derivatives of the reciprocal fraction forms.

  • What is the derivative of f open parentheses x close parentheses equals cot x?

    The derivative of f open parentheses x close parentheses equals cot x is f to the power of apostrophe open parentheses x close parentheses equals negative cosec squared x.

    This is in the exam formula booklet.

  • What is the derivative of f open parentheses x close parentheses equals arcsin x?

    The derivative of f open parentheses x close parentheses equals arcsin x is f to the power of apostrophe open parentheses x close parentheses equals fraction numerator 1 over denominator square root of 1 minus x squared end root end fraction.

    This is in the exam formula booklet.

  • True or False?

    The derivative of arccos x is positive for all values in its domain.

    False.

    The derivative of arccos x is negative for all values in its domain.

    The derivative of f open parentheses x close parentheses equals arccos x is f to the power of apostrophe open parentheses x close parentheses equals negative fraction numerator 1 over denominator square root of 1 minus x squared end root end fraction.

    This is in the exam formula booklet.

  • What is the derivative of f open parentheses x close parentheses equals arctan x?

    The derivative of f open parentheses x close parentheses equals arctan x is f to the power of apostrophe open parentheses x close parentheses equals fraction numerator 1 over denominator 1 plus x squared end fraction.

    This is in the exam formula booklet.

  • What is the derivative of f open parentheses x close parentheses equals a to the power of x?

    The derivative of f open parentheses x close parentheses equals a to the power of x is f to the power of apostrophe open parentheses x close parentheses equals a to the power of x open parentheses ln a close parentheses.

    This is in the exam formula booklet.

  • What is the derivative of f open parentheses x close parentheses equals log subscript a x?

    The derivative of f open parentheses x close parentheses equals log subscript a x is f to the power of apostrophe open parentheses x close parentheses equals fraction numerator 1 over denominator x ln a end fraction.

    This is in the exam formula booklet.

  • True or False?

    To derive the form of the derivative for arcsin x, start by rewriting y equals arcsin x as sin y equals x.

    True.

    To derive the form of the derivative for arcsin x, start by rewriting y equals arcsin x as sin y equals x.

    From there, the derivative of arcsin x can be found by using implicit differentiation and then rearranging.