Number & Algebra Toolkit (DP IB Analysis & Approaches (AA))

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  • What is the advantage of using standard form for very large or small numbers?

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Cards in this collection (23)

  • What is the advantage of using standard form for very large or small numbers?

    Standard form lets us represent very large or very small numbers in a concise and manageable way using powers of 10. This means we can write them more neatly, compare them more easily, and carry out calculations more efficiently.

  • True or False?

    In standard form, numbers are always written in the form a cross times 10 to the power of k, where 1 less or equal than a less or equal than 10 and k is an integer.

    False.

    In standard form, numbers are always written in the form a cross times 10 to the power of k, where 1 less or equal than a less than 10 (not 1 less or equal than a less or equal than 10) and k is an integer.

    In standard form, the value of a must be greater than or equal to 1 and less than 10 .

  • True or False?

    There is always one non – zero digit before the decimal point in a standard form number.

    True.

    There is always one (and only one) non – zero digit before the decimal point in a standard form number.

  • What does a straight E n mean on a calculator display?

    On a calculator display, a straight E n means a cross times 10 to the power of n in standard form.

    (Some calculators use that form of notation instead of the usual standard form notation.)

  • True or False?

    Scientific notation is another term for standard form.

    True.

    Scientific notation is another term for standard form.

  • True or False?

    The exponent k in standard form must always be positive.

    False.

    The exponent k in standard form can be positive, negative, or zero.

  • Define the term exponent.

    An exponent is a power that a number (called the base) is raised to.

  • What number do you get when you raise any non-zero number to the power of zero, e.g. 20?

    Any non-zero number raised to the power of 0 is equal to 1.

    E.g. 20 = 1.

  • True or False?

    If you raise a non-zero number to the power of 1, you get 1.

    False.

    Any number raised to the power 1 is just itself.

    E.g. 6 to the power of 1 equals 6.

  • What do you get if you raise a non-zero number to the power of -1,
    e.g. 3-1 ?

    If you raise a non-zero number to the power of -1 you get the reciprocal of the number.

    E.g. 3 to the power of negative 1 end exponent equals 1 third.

  • What do you get if you raise a positive number to the power of ½,
    e.g. 51/2 ?

    If you raise a non-zero number to the power of ½ you get its positive square root.

    E.g. 5 to the power of 1 half end exponent equals square root of 5.

  • What is the index law for x to the power of m cross times x to the power of n?

    x to the power of m cross times x to the power of n equals x to the power of m plus n end exponent

    If you multiply two powers with the same base number, you add the indices together.

    This formula is not given in the exam formula booklet.

  • What is the index law for x to the power of m divided by x to the power of n?

    x to the power of m divided by x to the power of n equals x to the power of m minus n end exponent

    If you divide two powers with the same base number, you subtract one index from the other.

    This formula is not given in the exam formula booklet.

  • What is the index law for open parentheses x to the power of m close parentheses to the power of n?

    open parentheses x to the power of m close parentheses to the power of n equals x to the power of m cross times n end exponent

    If you raise a power to another power, you multiply the indices.

    This formula is not given in the exam formula booklet.

  • What is the index law for open parentheses x y close parentheses to the power of m?

    open parentheses x y close parentheses to the power of m equals x to the power of m y to the power of m

    A power outside brackets is applied to each factor inside the brackets individually.

    This formula is not given in the exam formula booklet.

    But note that open parentheses x plus y close parentheses to the power of m not equal to x to the power of m plus y to the power of m, i.e. you can only use this index law when the things inside the bracket are multiplied together.

  • Define the term reciprocal in relation to exponents.

    In relation to exponents, the reciprocal of x to the power of m is x to the power of negative m end exponent, which equals 1 over x to the power of m.

  • True or False?

    Index laws only work with terms that have the same base.

    True.

    Index laws only work with terms that have the same base.

  • If a rational function has a linear numerator and denominator, how can it be rewritten as partial fractions?

    If a rational function has a linear numerator and denominator, it can be rewritten as the sum of a constant and a fraction with a linear denominator, e.g. fraction numerator a x plus b over denominator c x plus d end fraction equals A plus fraction numerator B over denominator c x plus d end fraction

  • How can a rational function with a quadratic denominator be rewritten using partial fractions?

    A rational function with a quadratic denominator can be rewritten as the sum of two rational functions with linear denominators (if the quadratic denominator can be factorised into two distinct factors).

    E.g. fraction numerator a x plus b over denominator left parenthesis c x plus d right parenthesis left parenthesis e x plus f right parenthesis end fraction equals fraction numerator A over denominator c x plus d end fraction plus fraction numerator B over denominator e x plus f end fraction

  • What is the first step in finding partial fractions if the denominator is a quadratic?

    The first step in finding partial fractions if the denominator is a quadratic is to factorise the denominator.

    It is a good idea at this point, to also check to see if there are any common factors that can be cancelled.

  • What form does a rational expression p over open parentheses a x plus b close parentheses squared take in partial fractions?

    A rational expression p over open parentheses a x plus b close parentheses squared takes the form fraction numerator A over denominator open parentheses a x plus b close parentheses end fraction plus B over open parentheses a x plus b close parentheses squared in partial fractions.

  • After eliminating fractions, e.g. blank fraction numerator 5 x blank plus blank 5 over denominator left parenthesis x blank plus blank 3 right parenthesis left parenthesis x blank minus blank 2 right parenthesis end fraction blank identical to blank fraction numerator A over denominator x blank plus blank 3 end fraction plus fraction numerator B over denominator x blank minus blank 2 end fraction becomes 5 x plus 5 blank identical to A open parentheses x minus 2 close parentheses plus B left parenthesis x plus 3 right parenthesis

    What two methods can be used to find the numerators A and B?

    After eliminating fractions, the two methods that can be used to find the numerators A and B are:

    (a) Substitute the root of each linear factor into the identity and solve.
    5 open parentheses 2 close parentheses plus 5 identical to A open parentheses open parentheses 2 close parentheses minus 2 close parentheses plus B left parenthesis open parentheses 2 close parentheses plus 3 right parenthesis and 5 open parentheses negative 3 close parentheses plus 5 identical to A open parentheses open parentheses negative 3 close parentheses minus 2 close parentheses plus B left parenthesis open parentheses negative 3 close parentheses plus 3 right parenthesis

    (b) Expand brackets and compare coefficients.
    5 x plus 5 identical to open parentheses A plus B close parentheses x plus open parentheses negative 2 A plus 3 B close parentheses

  • True or False?

    Partial fractions can only be used with rational functions that have linear or quadratic denominators.

    False.

    Partial fractions can be used with rational functions that have linear or quadratic denominators but also for higher degree polynomials that can be factorised.