Further Complex Numbers (DP IB Analysis & Approaches (AA))

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  • What happens geometrically to a complex number, z, when the complex number a plus b straight iis added to it?

    When the complex number a plus b straight iis added to z, z is translated on the Argand diagram by the vector open parentheses table row a row b end table close parentheses.

  • What happens geometrically to a complex number, z, when the complex number a plus b straight iis subtracted from it?

    When the complex number a plus b straight iis subtracted from z, z is translated on the Argand diagram by the vector open parentheses table row cell negative a end cell row cell negative b end cell end table close parentheses.

  • Describe the geometric relationship between the origin of an Argand diagram and the complex numbers z, w and z plus w.

    The origin of an Argand diagram and the complex numbers z, w and z plus w form a parallelogram. z plus w is the vertex opposite the origin.

  • Describe the geometric relationship between the origin of an Argand diagram and the complex numbers z, w and z minus w.

    The origin of an Argand diagram and the complex numbers z, w and z minus w form a parallelogram. z minus w is the vertex opposite the origin.

  • What two geometrical transformations happen to a complex number, z, when it is multiplied by the complex number w?

    When z is multiplied by the complex number w:

    • it is rotated counter-clockwise by arg open parentheses w close parentheses,

    • it is stretched from the origin by scale factor open vertical bar w close vertical bar.

  • What two geometrical transformations happen to a complex number, z, when it is divided by the complex number w?

    When z is divided by the complex number w:

    • it is rotated clockwise by arg open parentheses w close parentheses,

    • it is stretched from the origin by scale factor fraction numerator 1 over denominator open vertical bar w close vertical bar end fraction.

  • Describe the geometrical relationship between z and z asterisk times.

    On an Argand diagram, z and z asterisk times are reflections in the real axis.

  • What does a complex number look like when written in modulus-argument (polar) form?

    A complex number that is written in modulus-argument (polar) form looks like z equals r open parentheses cos theta plus isin theta close parentheses where r is the modulus and theta is the argument.

  • What is denoted by r cis open parentheses theta close parentheses?

    r cis theta equals r open parentheses cos theta plus isin theta close parentheses.

  • What is the complex conjugate of r cis open parentheses theta close parentheses?

    The complex conjugate of r cis open parentheses theta close parentheses is r cis open parentheses negative theta close parentheses.

  • True or False?

    2 open parentheses cos open parentheses straight pi over 3 close parentheses minus isin open parentheses straight pi over 3 close parentheses close parentheses is written in modulus-argument (polar) form.

    False.

    2 open parentheses cos open parentheses straight pi over 3 close parentheses minus isin open parentheses straight pi over 3 close parentheses close parentheses is not written in modulus-argument (polar) form. There should be a "+" in front of straight i.

  • Write the complex number r open parentheses cos theta minus isin theta close parentheses in modulus-argument (polar) form.

    The complex number r open parentheses cos theta minus isin theta close parentheses in modulus-argument (polar) form is r open parentheses cos open parentheses negative theta close parentheses plus isin open parentheses negative theta close parentheses close parentheses.

  • If you know the modulus (r) and argument (theta) of a complex number, how can you find the real part?

    If you know the modulus (r) and argument (theta) of a complex number, the real part is equal to r cos theta.

  • If you know the modulus (r) and argument (theta) of a complex number, how can you find the imaginary part?

    If you know the modulus (r) and argument (theta) of a complex number, the imaginary part is equal to r sin theta.

  • What does a complex number look like when written in exponential (Euler) form?

    A complex number that is written in exponential (Euler) form looks like z equals r straight e to the power of straight i theta end exponent where r is the modulus and theta is the argument.

  • What is the complex conjugate of r straight e to the power of straight i theta end exponent?

    The complex conjugate of r straight e to the power of straight i theta end exponent is r straight e to the power of negative straight i theta end exponent.

  • How can you write z equals r straight e to the power of straight i theta end exponent in Cartesian form?

    You can write z equals r straight e to the power of straight i theta end exponent in Cartesian form as z equals r cos theta plus straight i r sin theta.

  • True or False?

    straight e to the power of straight i straight pi end exponent equals negative 1.

    True.

    straight e to the power of straight i straight pi end exponent equals negative 1.

  • True or False?

    You can multiply and divide complex numbers written in exponential (Euler) form by using the laws of indices.

    For example, 2 e to the power of straight pi over 4 i end exponent cross times 3 straight e to the power of straight pi over 2 straight i end exponent equals 6 straight e to the power of open parentheses straight pi over 4 plus straight pi over 2 close parentheses straight i end exponent.

    True.

    You can multiply and divide complex numbers written in exponential (Euler) form by using the laws of indices.

    For example, 2 e to the power of straight pi over 4 i end exponent cross times 3 straight e to the power of straight pi over 2 straight i end exponent equals 6 straight e to the power of open parentheses straight pi over 4 plus straight pi over 2 close parentheses straight i end exponent.

  • How do you divide complex numbers written in modulus-argument (polar) form?

    To divide complex numbers written in modulus-argument (polar) form, you divide the moduli and subtract the arguments.

    fraction numerator r subscript 1 open parentheses cos open parentheses theta subscript 1 close parentheses plus isin open parentheses theta subscript 1 close parentheses close parentheses over denominator r subscript 2 open parentheses cos open parentheses theta subscript 2 close parentheses plus isin open parentheses theta subscript 2 close parentheses close parentheses end fraction equals r subscript 1 over r subscript 2 open parentheses cos open parentheses theta subscript 1 minus theta subscript 2 close parentheses plus isin open parentheses theta subscript 1 minus theta subscript 2 close parentheses close parentheses.

  • If z equals p plus q straight i is a complex root to a polynomial with real coefficients, then what is another root of the polynomial?

    If z equals p plus q straight i is a complex root to a polynomial with real coefficients, then its complex conjugate, z asterisk times equals p minus q straight i, is also a root.

  • True or False?

    If a quadratic function has no real roots, then the real parts of the complex roots are equal to the x-coordinate of the turning point of the graph.

    True.

    If a quadratic function has no real roots, then the real parts of the complex roots are equal to the x-coordinate of the turning point of the graph.

  • If you are given a complex root (p plus q straight i) of a quadratic, how can you find the equation of the quadratic?

    If you are given a complex root (p plus q straight i) of a quadratic, then you can find the equation of the quadratic by:

    • writing as a product of two brackets and set it equal to zero open parentheses x minus open parentheses p plus q straight i close parentheses close parentheses open parentheses x minus open parentheses p minus q straight i close parentheses close parentheses equals 0,

    • rewriting the expressions to form a difference of two squares open parentheses open parentheses x minus p close parentheses minus q straight i close parentheses open parentheses open parentheses x minus p close parentheses plus q straight i close parentheses equals 0,

    • expand and simplify open parentheses x minus p close parentheses squared plus q squared equals 0.

  • True or False?

    A polynomial of degree n has exactly n distinct complex roots.

    False.

    A polynomial of degree n has exactly n complex roots, they are not necessarily distinct.

  • What is the smallest number of real roots that a cubic, with real coefficients, can have?

    The smallest number of real roots that a cubic, with real coefficients, can have is one. It is not possible for a cubic to have zero real roots.

  • True or False?

    A quartic, with real coefficients, can have at most two distinct non-real roots.

    False.

    A quartic, with real coefficients, can have at most four distinct non-real roots.

  • If you are given a complex root of a cubic with real coefficients, how do you find the real root?

    If you are given a complex root of a cubic with real coefficients, you can find the real root by:

    • find a quadratic which has the same complex root open parentheses x minus open parentheses p plus q straight i close parentheses close parentheses open parentheses x minus open parentheses p minus q straight i close parentheses close parentheses,

    • write the cubic as a product of the quadratic and a linear factor by comparing coefficients or using polynomial division,

    • use the linear factor to find the real root.

  • What is de Moivre's Theorem?

    De Moivre's Theorem tells us how to raise a complex number to a power.

    If z equals r open parentheses cos theta plus isin theta close parentheses then z to the power of n equals r to the power of n open parentheses cos open parentheses n theta close parentheses plus isin open parentheses n theta close parentheses close parentheses

    This can also be written as z to the power of n equals r to the power of n cis open parentheses n theta close parentheses or z to the power of n equals r to the power of n straight e to the power of straight i n theta end exponent.

    This is given in the formula booklet.

  • True or False?

    The reciprocal of z equals cos theta plus isin theta is equal to its conjugate z asterisk times equals cos theta minus isin theta.

    True.

    The reciprocal of z equals cos theta plus isin theta is equal to its conjugate z asterisk times equals cos theta minus isin theta.

    This is a result of de Moivre's Theorem: open parentheses cos theta plus isin theta close parentheses to the power of negative 1 end exponent equals cos open parentheses negative theta close parentheses plus isin open parentheses negative theta close parentheses.

  • Proof by induction is used to prove de Moivre's Theorem, open parentheses cos theta plus isin theta close parentheses to the power of n equals cos open parentheses n theta close parentheses plus isin open parentheses n theta close parentheses.

    Part of the inductive step is open parentheses cos open parentheses k theta close parentheses plus isin open parentheses k theta close parentheses close parentheses open parentheses cos theta plus isin theta close parentheses. How do you finish the inductive step?

    Proof by induction is used to prove de Moivre's Theorem, open parentheses cos theta plus isin theta close parentheses to the power of n equals cos open parentheses n theta close parentheses plus isin open parentheses n theta close parentheses.

    Part of the inductive step is open parentheses cos open parentheses k theta close parentheses plus isin open parentheses k theta close parentheses close parentheses open parentheses cos theta plus isin theta close parentheses. To finish the proof by induction, expand the brackets and use the compound angle identities to writecos open parentheses k theta close parentheses cos theta minus sin open parentheses k theta close parentheses sin theta equals cos open parentheses open parentheses k plus 1 close parentheses theta close parentheses and sin open parentheses k theta close parentheses cos theta plus cos open parentheses k theta close parentheses sin theta equals sin open parentheses open parentheses k plus 1 close parentheses theta close parentheses.

  • How can you find the square roots of a complex number without using de Moivre's Theorem?

    For example, how could you find the square roots of 1 plus 2 straight i?

    You can find the square roots of a complex number without using de Moivre's Theorem, by

    • setting a square root equal to c plus d straight i,

    • squaring the expression and setting it equal to the original complex number open parentheses c plus d straight i close parentheses squared equals a plus b straight i,

    • form two equations using the real and imaginary parts and solve them.

    For example, to find the square roots of 1 plus 2 straight i, solve the equal open parentheses c plus d straight i close parentheses squared equals 1 plus 2 straight i.

  • How many cube roots does a complex number have?

    A complex number has three cube roots.

  • What is an expression for the nth roots of the complex number r straight e to the power of straight i theta end exponent?

    The nth roots of the complex number r straight e to the power of straight i theta end exponent have the form n-th root of r straight e to the power of fraction numerator theta plus 2 straight pi k over denominator n end fraction straight i end exponent, where k equals 0 comma space 1 comma space 2 comma space... comma space n minus 1.

  • True or False?

    If omega is an nth root of a complex number then omega e to the power of fraction numerator 2 straight pi over denominator n end fraction straight i end exponent is also an nth root.

    True.

    If omega is an nth root of a complex number then omega e to the power of fraction numerator 2 straight pi over denominator n end fraction straight i end exponent is also an nth root.

    If you know one root you can find another by multiplying it by e to the power of fraction numerator 2 straight pi over denominator n end fraction straight i end exponent.

  • True or False?

    The nth roots of a complex number form a regular polygon when plotted on an Argand diagram.

    True.

    The nth roots of a complex number form a regular polygon when plotted on an Argand diagram.

  • True or False?

    There is only one solution to the equation z cubed equals 1 plus 2 straight i.

    False.

    There are three solutions to the equation z cubed equals 1 plus 2 straight i. The solutions are the three cube roots of 1 plus 2 straight i.