Plane Trigonometry

De Moivre's Theorem

756 (~~cos~~𝛼+𝑖~~sin~~𝛼)(~~cos~~𝛽+𝑖~~cos~~𝛽)⋯=~~cos~~(𝛼+𝛽+𝛾+⋯)+𝑖~~sin~~(𝛼+𝛽+𝛾+⋯), where 𝑖=−1 Proved by Induction 757 (~~cos~~𝜃+𝑖~~sin~~𝜃)^𝑛=~~cos~~𝑛𝜃+𝑖~~sin~~𝑛𝜃 Proof: By Induction, or by putting 𝛼, 𝛽, ⋯ each = 𝜃 in (756).

Expansion of cos𝑛𝜃, ⋯ in powers sin𝜃 and cos𝜃

758 ~~cos~~𝑛𝜃=~~cos~~^𝑛𝜃−𝐶(𝑛,2)~~cos~~^𝑛−2𝜃~~sin~~²𝜃+𝐶(𝑛,4)~~cos~~^𝑛−4𝜃~~sin~~⁴𝜃−⋯ 759 ~~sin~~𝑛𝜃=𝑛~~cos~~^𝑛−1𝜃~~sin~~𝜃−𝐶(𝑛,3)~~cos~~^𝑛−3𝜃~~sin~~³𝜃+⋯ Proof: Expand (757) by Bin. Th., and equate real and imaginary parts. 760 ~~tan~~𝑛𝜃=𝑛~~tan~~𝜃−𝐶(𝑛,3)~~tan~~³𝜃+⋯1−𝐶(𝑛,2)~~tan~~²𝜃+𝐶(𝑛,4)~~tan~~⁴𝜃−⋯ In series (758, 759), stop at, and exclude, all terms with indices greater than 𝑛. Note, 𝑛 is here an integer. 761 Let 𝑠_𝑟=sum of the 𝐶(𝑛,𝑟) products of ~~tan~~𝛼, ~~tan~~𝛽, ~~tan~~𝛾, ⋯ to 𝑛 terms. ~~sin~~(𝛼+𝛽+𝛾+⋯)=~~cos~~𝛼~~cos~~𝛽⋯(𝑠₁−𝑠₃+𝑠₅−⋯) 762 ~~cos~~(𝛼+𝛽+𝛾+⋯)=~~cos~~𝛼~~cos~~𝛽⋯(1−𝑠₂+𝑠₄−⋯) Proof: By equating real and imaginary parts in (756). 763 ~~tan~~(𝛼+𝛽+𝛾+⋯)=(𝑠₁−𝑠₃+𝑠₅−𝑠₇+⋯)1−𝑠₂+𝑠₄−𝑠₆+⋯

Expansion of sine and cosine in powers the angle

764 ~~sin~~𝜃=𝜃−𝜃³3!+𝜃⁵5!−⋯, ~~cos~~𝜃=1−𝜃²2!+𝜃⁴4!−⋯ Proof: Put 𝜃𝑛 for 𝜃 in (757) and 𝑛=∞, employing (754) and (755). 766 𝑒^𝑖𝜃=~~cos~~𝜃+𝑖~~sin~~𝜃, 𝑒^−𝑖𝜃=~~cos~~𝜃−𝑖~~sin~~𝜃By 150 768 𝑒^𝑖𝜃+𝑒^−𝑖𝜃=2~~cos~~𝜃, 𝑒^𝑖𝜃−𝑒^−𝑖𝜃=2𝑖~~sin~~𝜃 770 𝑖~~tan~~𝜃=𝑒^𝑖𝜃−𝑒^−𝑖𝜃𝑒^𝑖𝜃+𝑒^−𝑖𝜃, 1+𝑖~~tan~~𝜃1−𝑖~~tan~~𝜃=𝑒^2𝑖𝜃

Expansion of cos^𝑛𝜃 and sin^𝑛𝜃 in cosines or sines of multiples of 𝜃

772 2^𝑛−1~~cos~~^𝑛𝜃=~~cos~~𝑛𝜃+𝑛~~cos~~(𝑛−2)𝜃+𝐶(𝑛,2)~~cos~~(𝑛−1)𝜃+𝐶(𝑛,3)~~cos~~(𝑛−6)𝜃+⋯ 773 When 𝑛 is even, 2^𝑛−1(−1)^12𝑛~~sin~~^𝑛𝜃=~~cos~~𝑛𝜃−𝑛~~cos~~(𝑛−2)𝜃+𝐶(𝑛,2)~~cos~~(𝑛−4)𝜃−𝐶(𝑛,3)~~cos~~(𝑛−6)𝜃+⋯ 774 And when 𝑛 is odd, 2^𝑛−1(−1)^𝑛−12~~sin~~^𝑛𝜃=~~sin~~𝑛𝜃−𝑛~~sin~~(𝑛−2)𝜃+𝐶(𝑛,2)~~sin~~(𝑛−4)𝜃−𝐶(𝑛,3)~~sin~~(𝑛−6)𝜃+⋯ Observe that in these series the coefficients are those of the Binomial Theorem, with this exception: If 𝑛 be even, the last term must be divided by 2.
The series are obtained by expanding (𝑒^𝑖𝜃±𝑒^−𝑖𝜃)^𝑛 by the Binomial Theorem, collecting the equidistant terms in pairs, and employing (768) and (769).

Expansion of cos𝑛𝜃 and sin𝑛𝜃 in powers of sin𝜃

775 When 𝑛 is even, ~~cos~~𝑛𝜃=1−𝑛²2!~~sin~~²𝜃+𝑛²(𝑛²−2²)4!~~sin~~⁴𝜃−𝑛²(𝑛²−2²)(𝑛²−4²)6!~~sin~~⁶𝜃+⋯ 776 When 𝑛 is odd, ~~cos~~𝑛𝜃=~~cos~~𝜃1−𝑛²−12!~~sin~~²𝜃+(𝑛²−1)(𝑛²−3²)4!~~sin~~⁴𝜃−(𝑛²−1)(𝑛²−3²)(𝑛²−5²)6!~~sin~~⁶𝜃+⋯ 777 When 𝑛 is even, ~~sin~~𝑛𝜃=~~cos~~𝜃~~sin~~𝜃−𝑛²−2²3!~~sin~~³𝜃+(𝑛²−2²)(𝑛²−4²)5!~~sin~~⁵𝜃−(𝑛²−2²)(𝑛²−4²)(𝑛²−6²)7!~~sin~~⁷𝜃+⋯ 778 When 𝑛 is odd, ~~sin~~𝑛𝜃=𝑛~~sin~~𝜃−𝑛(𝑛²−1)3!~~sin~~³𝜃+𝑛(𝑛²−1)(𝑛²−3²)5!~~sin~~⁵𝜃−𝑛(𝑛²−1)(𝑛²−3²)(𝑛²−5²)7!~~sin~~⁷𝜃+⋯ Proof: By (758), we may assume, when 𝑛 is an even integer ~~cos~~𝑛𝜃=1+𝐴₂~~sin~~²𝜃+𝐴₄~~sin~~⁴𝜃+⋯+𝐴_2𝑟~~sin~~^2𝑟𝜃+⋯ Put 𝜃+𝑥 for 𝜃, and in ~~cos~~𝑛𝜃~~cos~~𝑛𝑥−~~sin~~𝑛𝜃~~sin~~𝑛𝑥 substitute for ~~cos~~𝑛𝑥 and ~~sin~~𝑛𝑥 their values in powers of 𝑛𝑥 from (764). Each term on the right is of the type 𝐴_2𝑟(~~sin~~𝜃~~cos~~𝑥+~~cos~~𝜃~~sin~~𝑥)^2𝑟. Make similar substitutions for ~~cos~~𝑥 and ~~sin~~𝑥 in powers of 𝑥. Collect the two coefficients of 𝑥² in each term by the multinomial theorem (137) and equate them all to the coefficient of 𝑥² on the left. In this equation write ~~cos~~²𝜃 for 1−~~sin~~²𝜃 everywhere, and then equate the coefficients of ~~sin~~^2𝑟𝜃 to obtain the relation between the successive equatities 𝐴_2𝑟 and 𝐴_2𝑟+2 for the series (775).
When 𝑛 is an odd integer, begin by assuming, by (759) ~~sin~~𝑛𝜃=𝐴₁~~sin~~𝜃+𝐴₃~~sin~~³𝜃+⋯ 779 The expansions of ~~cos~~𝑛𝜃 and ~~sin~~𝑛𝜃 in powers of ~~cos~~𝜃 are obtained by changing 𝜃 into 12𝜋−𝜃 in (775) to (778).

Expansion of cos𝑛𝜃 in descending powers of cos𝜃

780 2~~cos~~𝑛𝜃=(2~~cos~~𝜃)^𝑛−𝑛(2~~cos~~𝜃)^𝑛−2+𝑛(𝑛−3)2!(2~~cos~~𝜃)^𝑛−4−⋯+(−1)^𝑟𝑛(𝑛−r−1)(𝑛−r−2)⋯(𝑛−2r+1)r!(2~~cos~~𝜃)^𝑛−2r+⋯ up to the last positive power of 2~~cos~~𝜃.
Proof: By expanding each term of the identity ~~log~~(1−𝑥𝑧)+~~log~~1−𝑧𝑥=~~log~~1−𝑧~~𝑥+1𝑥−𝑧~~ By (156), equating coefficients of 𝑧^𝑛, and substituting from (768). 783 ~~sin~~𝛼+𝑐~~sin~~(𝛼+𝛽)+𝑐²~~sin~~(𝛼+2𝛽)+⋯ to 𝑛 terms =~~sin~~𝛼−𝑐~~sin~~(𝛼−𝛽)−𝑐^𝑛~~sin~~(𝛼+𝑛𝛽)+𝑐^𝑛+1~~sin~~{𝛼+(𝑛−1)𝛽}1−2𝑐~~cos~~𝛽+𝑐² 784 If 𝑐 be < 1 and 𝑛 infinite, this becomes =~~sin~~𝛼−𝑐~~sin~~(𝛼−𝛽)1−2𝑐~~cos~~𝛽+𝑐² 785 ~~cos~~𝛼+𝑐~~cos~~(𝛼+𝛽)+𝑐²~~cos~~(𝛼+2𝛽)+⋯ to 𝑛 terms = a similar result, changing ~~sin~~ into ~~cos~~ in the numerator. 786 similarly when 𝑐 is < 1 and 𝑛 infinite. 787 Method of summation: Substitute for the sines or cosines their exponential values (768). Sum the two resulting geometrical series, and substitute the sines or cosines again for the exponential values by (766). 788 𝑐~~sin~~(𝛼+𝛽)+𝑐²2!~~sin~~(𝛼+2𝛽)+𝑐³3!~~sin~~(𝛼+3𝛽)+⋯ to infinity =𝑒^𝑐cos𝛽~~sin~~(𝛼+𝑐~~sin~~𝛽)−~~sin~~𝛼 789 𝑐~~cos~~(𝛼+𝛽)+𝑐²2!~~cos~~(𝛼+2𝛽)+𝑐³3!~~cos~~(𝛼+3𝛽)+⋯ to infinity =𝑒^𝑐cos𝛽~~cos~~(𝛼+𝑐~~sin~~𝛽)−~~cos~~𝛼 Obtained by the rule in (787) 790 If, in the series (783) to (789), 𝛽 be changed into 𝛽+𝜋, the signs of the alternate terms will thereby be changed.

Expansion of 𝜃 in powers of tan𝜃 (Gregory's series)

791 𝜃=~~tan~~𝜃−~~tan~~³𝜃3+~~tan~~⁵𝜃5−⋯ The series converges if ~~tan~~𝜃 be not >1. Proof: By expanding the logarithm of the value of 𝑒^2𝑖𝜃 in (771) by (158).

formula for the calculation of the value of 𝜋 by Gregor's series

792 𝜋4=~~tan~~⁻¹12+~~tan~~⁻¹13=~~tan~~⁻¹15−~~tan~~⁻¹1239791 794 𝜋4=4~~tan~~⁻¹15−~~tan~~⁻¹170+~~tan~~⁻¹199 Proof: By employing the formula for ~~tan~~(𝐴±𝐵), (631)

To Prove that 𝜋 is Incommensurable

795 Convert the value of ~~tan~~𝜃 in terms of 𝜃 from (764) and (765) into a continued fraction, thus ~~tan~~𝜃=𝜃1₋𝜃²3₋𝜃²5₋𝜃²7₋⋯; or this result may be obtained by putting 𝑖𝜃 for 𝑦 in (294), and by (770). Hence 1−𝜃~~tan~~𝜃=𝜃²3₋𝜃²5₋𝜃²7₋⋯ Put 𝜋2 for , and assume that 𝜋, and therefore 𝜋²4, is commensurable. Let 𝜋²4=𝑚𝑛, 𝑚 and 𝑛 being integers. Then we shall have 1=𝑚2𝑛₋𝑚𝑛5𝑛₋𝑚𝑛7𝑛₋⋯
The continued fraction is incommensurable, by (177). But unity cannot be equal to an incommensurable quantity. Therefore 𝜋 is not commensurable. 796 If ~~sin~~𝑥=𝑛~~sin~~(𝑥+𝛼), 𝑥=𝑛~~sin~~𝛼+𝑛²2~~sin~~2𝛼+𝑛³3~~sin~~3𝛼+⋯ 797 If ~~tan~~𝑥=𝑛~~tan~~𝑦, 𝑥=𝑦−𝑚~~sin~~2𝑦+𝑚²2~~sin~~4𝑦−𝑚³3~~sin~~6𝑦+⋯, where 𝑚=1−𝑛1+𝑛
Proof:By substiuting the exponential values of the sine or tangent (769) and (770), and then eliminating 𝑥. 798 Coefficient of 𝑥^𝑛 in the expansion of 𝑒^𝑎𝑥~~cos~~𝑏𝑥=(𝑎²+𝑏²)^𝑛2𝑛!~~cos~~𝑛𝜃, where 𝑎=𝑟~~cos~~𝜃 and 𝑏=𝑟~~sin~~𝜃.
For proof, substitute for ~~cos~~𝑏𝑥 from (768); expand by (150); put 𝑎=𝑟~~cos~~𝜃 and 𝑏=𝑟~~sin~~𝜃 in the coefficient of 𝑒^𝑥, employ (757). 799 When 𝑒<1, ~~1−𝑒²~~1−𝑒~~cos~~𝜃=1+2𝑏~~cos~~𝜃+2𝑏²~~cos~~2𝜃+2𝑏³~~cos~~3𝜃+⋯, where 𝑏=𝑒1+~~1−𝑒²~~
For proof, put 𝑒=2𝑏1+𝑏² and 2~~cos~~𝜃=𝑥+1𝑥, expand the fraction in two series of powers of 𝑥 by the method of (257), and substitute from (768). 800 ~~sin~~𝛼+~~sin~~(𝛼+𝛽)+~~sin~~(𝛼+2𝛽)+⋯+~~sin~~{𝛼+(𝑛−1)𝛽}=~~sin𝛼+𝑛−12𝛽sin~~𝑛2𝛽~~sin~~𝛽2 801 ~~cos~~𝛼+~~cos~~(𝛼+𝛽)+~~sin~~(𝛼+2𝛽)+⋯+~~cos~~{𝛼+(𝑛−1)𝛽}=~~cos𝛼+𝑛−12𝛽sin~~𝑛2𝛽~~sin~~𝛽2 802 If the terms in these series have the signs + and − alternately, change 𝛽 into 𝛽+𝜋 in the results.
Proof: Multiply the series by 2~~sin~~𝛽2, and apply (669) and (666). 803 If 𝛽=2𝜋𝑛 in (800) and (801), each series vanishes. 804 Generally, if 𝛽=2𝜋𝑛, and if 𝑟 be an integer not a multiple of 𝑛, the sum of the 𝑟^th powers of the sines or cosines in (800) or (801) is zero if 𝑟 be odd; and if 𝑟 be even it is =𝑛2^𝑟; by (772) to (774) 805 General Theorem: Denoting the sum of the series 𝑐+𝑐₁𝑥+𝑐₂𝑥²+⋯+𝑐_𝑛𝑥^𝑛 by 𝐹(𝑥); then 𝑐~~cos~~𝛼+𝑐₁~~cos~~(𝛼+𝛽)+⋯+𝑐_𝑛~~cos~~(𝛼+𝑛𝛽)=12{𝑒^𝑖𝛼𝐹(𝑒^𝑖𝛽)+𝑒^−𝑖𝛼𝐹(𝑒^−𝑖𝛽)} and 806 𝑐~~sin~~𝛼+𝑐₁~~sin~~(𝛼+𝛽)+⋯+𝑐_𝑛~~sin~~(𝛼+𝑛𝛽)=12𝑖{𝑒^𝑖𝛼𝐹(𝑒^𝑖𝛽)−𝑒^−𝑖𝛼𝐹(𝑒^−𝑖𝛽)} Provd by substituting for the sines and cosines their exponential values (766), ⋯.

Expansion of the sine and cosine in factors

807 𝑥^2𝑛−2𝑥^𝑛𝑦^𝑛~~cos~~𝑛𝜃+𝑦^2𝑛=𝑥²−2𝑥𝑦~~cos~~𝜃+𝑦²𝑥²−2𝑥𝑦~~cos𝜃+~~2𝜋𝑛~~~~+𝑦²⋯ to 𝑛 factors, adding 2𝜋𝑛 to the angle successively.
Proof: By solving the quadratic on the left, we get 𝑥=𝑦(~~cos~~𝑛𝜃+𝑖~~sin~~𝑛𝜃)^1𝑛. The 𝑛 values of 𝑥 are found by (757) and (626), and thence tha factors. For the factors 𝑥^𝑛±𝑦^𝑛 see (480). 808 ~~sin~~𝑛𝜙=2^𝑛−1~~sin~~𝜙~~sin~~𝜙+𝜋𝑛~~sin~~𝜙+~~2𝜋𝑛~~⋯ as far as 𝑛 factors of sines.
Proof: By putting 𝑥=𝑦=1 and 𝜃=2𝜙 in the last. 809 If 𝑛 be even, ~~sin~~𝑛𝜙=2^𝑛−1~~sin~~𝜙~~cos~~𝜙~~sin~~²𝜋𝑛−~~sin~~²𝜙~~sin~~²~~2𝜋𝑛~~−~~sin~~²𝜙⋯ 810 If 𝑛 be odd, omit ~~cos~~𝜙 and make up 𝑛 factors, reckoning two factors for each pair of terms in brackets.
Proof: From (808), by collecting equidistant factors in pairs, and applying (659). 811 ~~cos~~𝑛𝜙=2^𝑛−1~~sin~~𝜙+~~𝜋2𝑛sin~~𝜙+~~3𝜋2𝑛~~⋯ to 𝑛 factors. Proof: Put 𝜙+~~𝜋2𝑛~~ for 𝜙 in (808). 812 Also, if 𝑛 be odd, ~~cos~~𝑛𝜙=2^𝑛−1~~cos~~𝜙~~sin~~²~~𝜋2𝑛~~−~~sin~~²𝜙~~sin~~²~~3𝜋2𝑛~~−~~sin~~²𝜙⋯ 813 If 𝑛 be even, omit ~~cos~~𝜙,
Proof: as in (809) 814 𝑛=2^𝑛−1~~sin~~𝜋𝑛~~sin2𝜋𝑛sin3𝜋𝑛~~⋯~~sin~~(𝑛−1)𝜋𝑛 Proof: divide (809) by ~~sin~~𝜙, and make 𝜙 vanish; then apply (754). 815 ~~sin~~𝜃=𝜃1−𝜃𝜋²1−~~𝜃2𝜋~~²1−~~𝜃3𝜋~~²⋯ 816 ~~cos~~𝜃=1−~~2𝜃𝜋~~²1−~~2𝜃3𝜋~~²1−~~2𝜃5𝜋~~²⋯ Proof: Put 𝜙=𝜃𝑛 in (809) and (842); divide by (814) and make 𝑛 infinite. 817 𝑒^𝑥−2~~cos~~𝜃+𝑒^−𝑥=4~~sin~~²𝜃21+~~𝑥²𝜃²~~1+~~𝑥²(2𝜋±𝜃)²~~1+~~𝑥²(4𝜋±𝜃)²~~⋯ Proved by substituting 𝑥=1+𝑧2𝑛, 𝑦=1−𝑧2𝑛, and 𝜃𝑛 for 𝜃 in (807) Making 𝑛 infinite, and reducing one series of factors to 4~~sin~~²𝜃2 by putting 𝑧=0.

De Moivre's Property of the Circle

Circle: Take 𝑃 any point, and 𝑃𝑂𝐵=𝜃 any angle, 𝐵𝑂𝐶=𝐶𝑂𝐷=⋯=2𝜋𝑛; 𝑂𝑃=𝑥; 𝑂𝐵=𝑟

819 𝑥^2𝑛−2𝑥^𝑛𝑟^𝑛~~cos~~𝑛𝜃+𝑟^2𝑛=𝑃𝐵²𝑃𝐶²𝑃𝐷²⋯ to 𝑛 factors By (807) and (702), since 𝑃𝐵²=𝑥²−2𝑥𝑟~~cos~~𝜃+𝑟², ⋯ 820 If 𝑥=𝑟, 2𝑟^𝑛~~sin~~𝑛𝜃2=𝑃𝐵⋅𝑃𝐶⋅𝑃𝐷⋯ 821