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This assumes ARG to be an Add. The multiple of $\pi$ returned in the second position is always a Rational. Examples ======== >>> from sympy.functions.elementary.trigonometric import _peeloff_pi >>> from sympy import pi >>> from sympy.abc import x, y >>> _peeloff_pi(x + pi/2) (x, 1/2) >>> _peeloff_pi(x + 2*pi/3 + pi*y) (x + pi*y + pi/6, 1/2) F) rrMr make_argscoeffrr9appendHalf is_integeris_even)rrB rest_termsr]Km1m2r2r2r3 _peeloff_pis        rrrcyclesintreturn Expr | Nonec Cs |turtjS|s tjS|jr}|t}|r{|\}}|jrZt|d}|dkrPt t t |d  }d|}||}t |} t | |rOt| |}||}n tt |}||}|jry|d} | dkrg|S| su|jdurqtjStdS| |S|SdS|jrtjSdS)a6 When arg is a Number times $\pi$ (e.g. $3\pi/2$) then return the Number normalized to be in the range $[0, 2]$, else `None`. When an even multiple of $\pi$ is encountered, if it is multiplying something with known parity then the multiple is returned as 0 otherwise as 2. Examples ======== >>> from sympy.functions.elementary.trigonometric import _pi_coeff >>> from sympy import pi, Dummy >>> from sympy.abc import x >>> _pi_coeff(3*x*pi) 3*x >>> _pi_coeff(11*pi/7) 11/7 >>> _pi_coeff(-11*pi/7) 3/7 >>> _pi_coeff(4*pi) 0 >>> _pi_coeff(5*pi) 1 >>> _pi_coeff(5.0*pi) 1 >>> _pi_coeff(5.5*pi) 3/2 >>> _pi_coeff(2 + pi) >>> _pi_coeff(2*Dummy(integer=True)*pi) 2 >>> _pi_coeff(2*Dummy(even=True)*pi) 0 rrrwN)rrOnerMrSry as_coeff_Mulis_FloatrUrroundr!evalfrrr|r}rr:) rrcxcxrZpmcmic2r2r2r3rAsF%       rAcseZdZdZd8ddZd9ddZedd Zee d d Z d:fd d Z ddZ ddZ ddZddZddZddZddZddZdd Zd!d"Zd#d$Zd%d&Zd'd(Zd;d*d+Zd,d-Zd.d/Zd0d1Zd2d3Zd4d5Zd6d7ZZ S)<sina The sine function. Returns the sine of x (measured in radians). Explanation =========== This function will evaluate automatically in the case $x/\pi$ is some rational number [4]_. For example, if $x$ is a multiple of $\pi$, $\pi/2$, $\pi/3$, $\pi/4$, and $\pi/6$. Examples ======== >>> from sympy import sin, pi >>> from sympy.abc import x >>> sin(x**2).diff(x) 2*x*cos(x**2) >>> sin(1).diff(x) 0 >>> sin(pi) 0 >>> sin(pi/2) 1 >>> sin(pi/6) 1/2 >>> sin(pi/12) -sqrt(2)/4 + sqrt(6)/4 See Also ======== csc, cos, sec, tan, cot asin, acsc, acos, asec, atan, acot, atan2 References ========== .. [1] https://en.wikipedia.org/wiki/Trigonometric_functions .. [2] https://dlmf.nist.gov/4.14 .. [3] https://functions.wolfram.com/ElementaryFunctions/Sin .. 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[1] https://en.wikipedia.org/wiki/Trigonometric_functions .. [2] https://dlmf.nist.gov/4.14 .. 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Returns the tangent of x (measured in radians). Explanation =========== See :class:`sin` for notes about automatic evaluation. Examples ======== >>> from sympy import tan, pi >>> from sympy.abc import x >>> tan(x**2).diff(x) 2*x*(tan(x**2)**2 + 1) >>> tan(1).diff(x) 0 >>> tan(pi/8).expand() -1 + sqrt(2) See Also ======== sin, csc, cos, sec, cot asin, acsc, acos, asec, atan, acot, atan2 References ========== .. [1] https://en.wikipedia.org/wiki/Trigonometric_functions .. [2] https://dlmf.nist.gov/4.14 .. [3] https://functions.wolfram.com/ElementaryFunctions/Tan NcC |t|Sr`rrr2r2r3rr z tan.periodrcCs |dkr tj|dSt||Nrrw)rrrrr2r2r3rrz tan.fdiffcCtSz7 Returns the inverse of this function. rrr2r2r3inversez tan.inversecCsddlm}|jr&|tjurtjS|jrtjS|tjtjfvr&|tjtjS|tj ur.tjSt ||r~|j |j }}t |t}|tjurK||t}|tjurV||t}ddlm}||||tdttddru|tjtjS|t|t|S|r||  St|}|durddlm}tj||St|d} | dur| jrtjS| js| t} | |kr|| SdS| jr| j} | j| } tddtddtddtdtddtddtddtdd } | d vrd | | }|dkrd |}| | S| |S| jdsG| td} t| t| td}}t |tsGt |tsG|dkr?tj Sd|||St }| |vry|| \}}|| t||| t|}}d||fvrodS||d||S| tj!dtj!t} t| t| td}}t |tst |ts|dkrtj S||S| |kr|| S|j"rt#|\}}|rt|t}|tj urt$| St|S|jrtjSt |t%r|j&dSt |t'r|j&\}}||St |t(r |j&d}|td|dSt |t)r |j&d}td|d|St |t*r/|j&d}d|St |t+rH|j&d}dtdd|d|St |t,r_|j&d}tdd|d|SdS) Nrrrrwrh)tanhrrj)rrwrhrirjrlrl)-rrrrrr:rMrrrfr/rrr#rrrrrrrr4rrr1rAr|rrSrr$rrvr{rVrrrr8rrrrrr)rrrrrrrrrrBrrSrtable10rcresultsresultrTr]rUrVrWrrtanmrr2r2r3rs          $               "                     ztan.evalcGsz|dks |ddkr tjSt|}|ddd|d}}t|d}t|d}tj|||d||||SNrrwr)rrMrrrr)rrrr]rUBFr2r2r3rJs  &ztan.taylor_termrcsL|jd|ddt}|r|jr|tj|||dStj|||dS)Nrrwrr)r8r2rr&rrrrr<rrrrrrr2r3rYs ztan._eval_nseriescKsFt|tr!tj}|jd}||| |||| ||SdSrrrr2r2r3r_s  (ztan._eval_rewrite_as_PowcCrrrrr2r2r3rerztan._eval_conjugateTcKst|jdd|i|\}}|r2ddlm}m}td||d|}td|||d||fS||tjfSNrDrrrwr2 rNrrrrrr7rrMr<rDrFr rrrdenomr2r2r3rEhs  ztan.as_real_imagc s@|jd}d}|jrgt|j}g}|jD]}t|dd}||qtdfddt|D}ddg}t|dD]} |d| dt| |d | d d7<q=|d|d t t ||S|j r|j d d \} } | jr| dkrtj} td d d} d| | | }t|t| | t| fgSt|S)NrFrYcg|]}tqSr2nextr^rYgr2r3r`|z)tan._eval_expand_trig..rrwrriTr!dummyreal)r8rVrrr%rzr.ranger-rlistrfrSrr&rr1rrLrr )r<rFrrrTXtxrrrryrurrdPr2rr3r%qs,    0   ztan._eval_expand_trigcKsftj}ddlm}t|t|fr||jdt }t | |t ||}}|||||SNrrr\)r<rrrrneg_exppos_expr2r2r3rs  ztan._eval_rewrite_as_expcKsdt|dtd|Srrr<rrr2r2r3r]ztan._eval_rewrite_as_sincKst|tdddt|Srrrr2r2r3rrztan._eval_rewrite_as_coscKt|t|Sr`rrr2r2r3rrztan._eval_rewrite_as_sincoscKrrrrr2r2r3rr ztan._eval_rewrite_as_cotcK4t|jtfi|}t|jtfi|}||Sr`)rrr r)r<rrsin_in_sec_formcos_in_sec_formr2r2r3r ztan._eval_rewrite_as_seccKrr`)rrrr)r<rrsin_in_csc_formcos_in_csc_formr2r2r3rrztan._eval_rewrite_as_csccK2|jtfi|jtfi|}|trdS|Sr`rrrrRr<rrrr2r2r3r  ztan._eval_rewrite_as_powcKrr`rrr$rRrr2r2r3rrztan._eval_rewrite_as_sqrtcKs&ddlm}|tj||tj |SNrrrrrr{rr2r2r3r ztan._eval_rewrite_as_besseljc Csddlm}ddlm}|jd}||d}d|t}|jr6||td |} |j r2| Sd| S|t j urJ|j |d||jrFdndd}|t jt jfvrY|t jt jS|jra||S|S) Nrrr rwrr+r,r-rr$sympy.functions.elementary.complexesr r8rr0rr|r1r}rrfr2r3rrr4r7 r<rrrrr rr6rr7r2r2r3r8s     ztan._eval_as_leading_termcC |jdjSrr;rr2r2r3r<s ztan._eval_is_extended_realcC0|jd}|jr|ttjjdurdSdSdSr?r8is_realrrr{r|r?r2r2r3 _eval_is_reals ztan._eval_is_realcCs6|jd}|jr|ttjjdurdS|jrdSdSr?)r8rrrr{r| is_imaginaryr?r2r2r3r@s ztan._eval_is_finitecCrArrBrCr2r2r3rFrGztan._eval_is_zerocCrr?rr?r2r2r3rK ztan._eval_is_complexr`rMrNr_)"rarbrcrdrrr}rOrrPrrrrrrEr%rr]rrrr rrrrr8r<rr@rFrKrQr2r2rr3rs@ %        rc@seZdZdZdddZ ddZ d?ddZddZddZddZddZddZd d!Zd"d#Zd$d%Zd&d'Zd(d)Zd*d+Zd,d-Zd.d/Zd0d1Zd2d3Zd4d5Zd6d7Zd8d9Z d:d;Z!dS)@ra The cotangent function. Returns the cotangent of x (measured in radians). Explanation =========== See :class:`sin` for notes about automatic evaluation. Examples ======== >>> from sympy import cot, pi >>> from sympy.abc import x >>> cot(x**2).diff(x) 2*x*(-cot(x**2)**2 - 1) >>> cot(1).diff(x) 0 >>> cot(pi/12) sqrt(3) + 2 See Also ======== sin, csc, cos, sec, tan asin, acsc, acos, asec, atan, acot, atan2 References ========== .. [1] https://en.wikipedia.org/wiki/Trigonometric_functions .. [2] https://dlmf.nist.gov/4.14 .. [3] https://functions.wolfram.com/ElementaryFunctions/Cot NcCrxr`rrr2r2r3r r z cot.periodrcCs |dkr tj|dSt||ry)rrrrr2r2r3rrz cot.fdiffcCrzr{rrr2r2r3r}r~z cot.inversecCsddlm}|jr&|tjurtjS|jrtjS|tjtjfvr&|tjtjS|tjur.tjSt ||r.rrwrirTr!rr)r8rVrrr%rzr.rr-rrrfrSrr&rr1rrLr r)r<rFrrrCXrrrrryrurrdrr2rr3r%s,    4   zcot._eval_expand_trigcCs0|jd}|jr|tjdurdS|jrdSdSr?)r8rrr|rr?r2r2r3r@s zcot._eval_is_finitecC*|jd}|jr|tjdurdSdSdSr?r8rrr|r?r2r2r3r  zcot._eval_is_realcCrr?rr?r2r2r3rKrzcot._eval_is_complexcCs0t|jd\}}|r|jr|tjjSdSdSrrv)r<rDpimultr2r2r3rFrwzcot._eval_is_zerocCs6|jd}|||}||kr|tjrtjSt|Sr)r8rrr|rrfr)r<oldnewrargnewr2r2r3 _eval_subss  zcot._eval_subsr`rMrNr_)"rarbrcrdrrr}rOrrPrrrrrErrr]rrrr rrrrr8r<r%r@rrKrFrr2r2r2r3rs@ %   h     rc@seZdZUdZdZejfZdZde d<dZ de d<e ddZ dd Z d d Zd d ZddZd1ddZddZddZddZddZddZddZdd Zd!d"Zd2d$d%Zd&d'Zd(d)Zd*d+Zd,d-Zd3d/d0ZdS)4ReciprocalTrigonometricFunctionz@Base class for reciprocal functions of trigonometric functions. Nr _is_even_is_oddcCs>|r|jr || S|jr||  St|}|durYd|jsY|jrY|j}|jd|}||kr>|dt}|| Sd||krYd|t}|jrQ||S|jrY|| St |dri| |kri|j dS|j |}|duru|Stdd|| fDrd|tStdd|| fDrd|tSd|S)Nrwrr}rcs|]}t|tVqdSr`)r/rrr2r2r3rbPz7ReciprocalTrigonometricFunction.eval..csrr`)r/rrr2r2r3rbRr)rrrrAr|rrSrrhasattrr}r8_reciprocal_ofranyrr r)rrrBrSrrtr2r2r3r2s@         z$ReciprocalTrigonometricFunction.evalcOs$||jd}t|||i|Sr)rr8getattr)r< method_namer8ror2r2r3_call_reciprocalWsz0ReciprocalTrigonometricFunction._call_reciprocalcOs,|j|g|Ri|}|durd|S|Sr)r)r<rr8rrr2r2r3_calculate_reciprocal\sz5ReciprocalTrigonometricFunction._calculate_reciprocalcCs2|||}|dur|||krd|SdSdSr)rr)r<rrrr2r2r3_rewrite_reciprocalbs z3ReciprocalTrigonometricFunction._rewrite_reciprocalcCst|jd}|||Sr)r r8rr)r<rYrZr2r2r3r^isz'ReciprocalTrigonometricFunction._periodrcCs|d| |dS)Nrrwrrr2r2r3rmz%ReciprocalTrigonometricFunction.fdiffcK |d|S)Nrrrr2r2r3rpr z4ReciprocalTrigonometricFunction._eval_rewrite_as_expcKr)Nrrrr2r2r3rsr z4ReciprocalTrigonometricFunction._eval_rewrite_as_PowcKr)Nr]rrr2r2r3r]vr z4ReciprocalTrigonometricFunction._eval_rewrite_as_sincKr)Nrrrr2r2r3ryr z4ReciprocalTrigonometricFunction._eval_rewrite_as_coscKr)Nrrrr2r2r3r|r z4ReciprocalTrigonometricFunction._eval_rewrite_as_tancKr)Nrrrr2r2r3rr z4ReciprocalTrigonometricFunction._eval_rewrite_as_powcKr)Nrrrr2r2r3rr z5ReciprocalTrigonometricFunction._eval_rewrite_as_sqrtcCrrrrr2r2r3rrz/ReciprocalTrigonometricFunction._eval_conjugateTcKs"d||jdj|fi|Sr)rr8rE)r<rDrFr2r2r3rEsz,ReciprocalTrigonometricFunction.as_real_imagcKs|jdi|S)Nr%)r%r)r<rFr2r2r3r%rz1ReciprocalTrigonometricFunction._eval_expand_trigcCs||jdSr)rr8r<rr2r2r3r<rz6ReciprocalTrigonometricFunction._eval_is_extended_realcCs d||jdj|||dS)Nrrrr)rr8r8)r<rrrr2r2r3r8rz5ReciprocalTrigonometricFunction._eval_as_leading_termcCsd||jdjSr)rr8r4rr2r2r3r@rz/ReciprocalTrigonometricFunction._eval_is_finitercCsd||jd|||Sr)rr8rr<rrrrr2r2r3rsz-ReciprocalTrigonometricFunction._eval_nseriesrMr_rN) rarbrcrdrrrfrgr__annotations__rrOrrrrr^rrrr]rrrrrrEr%r<r8r@rr2r2r2r3r$s6    $  rc@seZdZdZeZdZdddZddZdd Z d d Z d d Z ddZ ddZ dddZddZddZeeddZddZdS)r a The secant function. Returns the secant of x (measured in radians). Explanation =========== See :class:`sin` for notes about automatic evaluation. Examples ======== >>> from sympy import sec >>> from sympy.abc import x >>> sec(x**2).diff(x) 2*x*tan(x**2)*sec(x**2) >>> sec(1).diff(x) 0 See Also ======== sin, csc, cos, tan, cot asin, acsc, acos, asec, atan, acot, atan2 References ========== .. [1] https://en.wikipedia.org/wiki/Trigonometric_functions .. [2] https://dlmf.nist.gov/4.14 .. [3] https://functions.wolfram.com/ElementaryFunctions/Sec TNcC ||Sr`r^rr2r2r3r z sec.periodcKs t|dd}|d|dSrr)r<rr cot_half_sqr2r2r3rszsec._eval_rewrite_as_cotcKrrrrr2r2r3rr zsec._eval_rewrite_as_coscKt|t|t|Sr`rrr2r2r3rrzsec._eval_rewrite_as_sincoscKrqr)rrrrr2r2r3r]rrzsec._eval_rewrite_as_sincKrqr)rrrrr2r2r3rrrzsec._eval_rewrite_as_tancKttd|ddSr)rrrr2r2r3rrzsec._eval_rewrite_as_cscrcCs.|dkrt|jdt|jdSt||r)rr8r rrr2r2r3rs z sec.fdiffcKsBddlm}tdtt|td|tj |t|dfdS)Nrrrrwrsrtrr2r2r3rs .zsec._eval_rewrite_as_besseljcCrr?)r8rJrrr{r|r?r2r2r3rKrzsec._eval_is_complexcGsX|dks |ddkr tjSt|}|d}tj|td|td||d|Sr)rrMrrrrrrrkr2r2r3rs .zsec.taylor_termc Csddlm}ddlm}|jd}||d}|tdt}|jr8||ttd |} t j || S|t j urL|j |d||jrHdndd}|t jt jfvr[|t jt jS|jrc||S|S)Nrrrrwr+r,r-rrrr r8rr0rr|r1rrrfr2r3rrr4r7rr2r2r3r8s    zsec._eval_as_leading_termr`rM)rarbrcrdrrrrrrrr]rrrrrKrPrrr8r2r2r2r3r s$#    r c@seZdZdZeZdZdddZddZdd Z d d Z d d Z ddZ ddZ ddZdddZddZeeddZddZdS)ra The cosecant function. Returns the cosecant of x (measured in radians). Explanation =========== See :func:`sin` for notes about automatic evaluation. Examples ======== >>> from sympy import csc >>> from sympy.abc import x >>> csc(x**2).diff(x) -2*x*cot(x**2)*csc(x**2) >>> csc(1).diff(x) 0 See Also ======== sin, cos, sec, tan, cot asin, acsc, acos, asec, atan, acot, atan2 References ========== .. [1] https://en.wikipedia.org/wiki/Trigonometric_functions .. [2] https://dlmf.nist.gov/4.14 .. [3] https://functions.wolfram.com/ElementaryFunctions/Csc TNcCrr`rrr2r2r3r/rz csc.periodcKrrrrr2r2r3r]2r zcsc._eval_rewrite_as_sincKrr`rrr2r2r3r5rzcsc._eval_rewrite_as_sincoscKs t|d}d|dd|Srrrr2r2r3r8s zcsc._eval_rewrite_as_cotcKrqr)rrrrr2r2r3r<rrzcsc._eval_rewrite_as_coscKrrr rr2r2r3r ?rzcsc._eval_rewrite_as_seccKrqr)rrrrr2r2r3rBrrzcsc._eval_rewrite_as_tancKs0ddlm}tdtdt||tj|S)Nrrrwrrrr2r2r3rEs $zcsc._eval_rewrite_as_besseljrcCs0|dkrt|jd t|jdSt||r)rr8rrrr2r2r3rIs z csc.fdiffcCrr?rr?r2r2r3rKOrzcsc._eval_is_complexcGs|dkr dt|S|dks|ddkrtjSt|}|dd}tj|dddd|ddtd||d|dtd|Sr)rrrMrrrrr2r2r3rTs  $  zcsc.taylor_termc Csddlm}ddlm}|jd}||d}|t}|jr0||t |} t j || S|t j urD|j |d||jr@dndd}|t jt jfvrS|t jt jS|jr[||S|S)Nrrrr+r,r-rrr2r2r3r8as    zcsc._eval_as_leading_termr`rM)rarbrcrdrrrrr]rrrr rrrrKrPrrr8r2r2r2r3rs$#    rc@s\eZdZdZejfZdddZeddZ ddd Z d d Z d d Z ddZ ddZeZdS)r a Represents an unnormalized sinc function: .. math:: \operatorname{sinc}(x) = \begin{cases} \frac{\sin x}{x} & \qquad x \neq 0 \\ 1 & \qquad x = 0 \end{cases} Examples ======== >>> from sympy import sinc, oo, jn >>> from sympy.abc import x >>> sinc(x) sinc(x) * Automated Evaluation >>> sinc(0) 1 >>> sinc(oo) 0 * Differentiation >>> sinc(x).diff() cos(x)/x - sin(x)/x**2 * Series Expansion >>> sinc(x).series() 1 - x**2/6 + x**4/120 + O(x**6) * As zero'th order spherical Bessel Function >>> sinc(x).rewrite(jn) jn(0, x) See also ======== sin References ========== .. [1] https://en.wikipedia.org/wiki/Sinc_function rcCs8|jd}|dkrt||t||dSt||r)r8rrr)r<rrr2r2r3rs  z sinc.fdiffcCs|jrtjS|jr|tjtjfvrtjS|tjurtjS|tjur$tjS| r-|| St |}|durQ|j rBt |jr@tjSdSd|j rStj |tj|SdSdSr)r:rrrrrrMrrfrrAr|r rr{)rrrBr2r2r3rs*     z sinc.evalrcCs |jd}t|||||Sr)r8rrrr2r2r3rs zsinc._eval_nseriescKsddlm}|d|S)Nr)jn)rr)r<rrrr2r2r3_eval_rewrite_as_jns  zsinc._eval_rewrite_as_jncKs&tt||t|tjftjtjfSr`)r'rrrrMrtruerr2r2r3r]&zsinc._eval_rewrite_as_sincCsP|jdjrdSt|jd\}}|jrt|j|jgS|jr$|jr&dSdSdS)NrTF)r8 is_infiniterr:r r| is_nonzerorrCr2r2r3rFs  zsinc._eval_is_zerocCrHr:)r8rKrrr2r2r3rszsinc._eval_is_realNrMrN)rarbrcrdrrfrgrrOrrrr]rFrr@r2r2r2r3r qs4    r c@s^eZdZUdZejejejejfZ de d<e e ddZ e e ddZe e dd Zd S) InverseTrigonometricFunctionz/Base class for inverse trigonometric functions.ztuple[Expr, ...]rgc CsBitddtdtddtddtdtdtdtddtdtdtdtddtdtdtddttddtdtdtddttddtjtdtdtddtdttjtddtdtdtddttddttjtddttddtdddtddtddt dtdddttddtddtddtd td dtddt d tddtdtd dtdtdt d tddtddttdd dtdtdttdd iS) Nrhrwrirrjrmrkrlrr)r$rrrr{r2r2r2r3 _asin_tablesP &       "z(InverseTrigonometricFunction._asin_tablecCstddtddtdtdtdtdtddtddtdt ddtdttddtddtdtdtddtdttddtddtddtdtddtddttdddtdtdd tdt ddtdttddi S) Nrhrkrrwrmrjrlrrrr$rrr2r2r2r3 _atan_tables "z(InverseTrigonometricFunction._atan_tablecCsidtddtdtdtdtddtddtddttddtddtdtddtddttdddttddtddttdddtdtddtdtddtdtdtdtddtdttdddtdtdttdddtdtdtddttddtdd ttd dtdtdtd tdtdttdd tdtd ttd d S) Nrwrhrirjrrmrkrlrrrr2r2r2r3 _acsc_table$sF ""(     z(InverseTrigonometricFunction._acsc_tableN)rarbrcrdrrrrMrfrgrrPrrrrr2r2r2r3rs   rcseZdZdZd$ddZddZddZd d Zed d Z e e d dZ ddZ d%fdd ZddZddZddZeZddZddZddZd d!Zd$d"d#ZZS)&rad The inverse sine function. Returns the arcsine of x in radians. Explanation =========== ``asin(x)`` will evaluate automatically in the cases $x \in \{\infty, -\infty, 0, 1, -1\}$ and for some instances when the result is a rational multiple of $\pi$ (see the ``eval`` class method). A purely imaginary argument will lead to an asinh expression. Examples ======== >>> from sympy import asin, oo >>> asin(1) pi/2 >>> asin(-1) -pi/2 >>> asin(-oo) oo*I >>> asin(oo) -oo*I See Also ======== sin, csc, cos, sec, tan, cot acsc, acos, asec, atan, acot, atan2 References ========== .. [1] https://en.wikipedia.org/wiki/Inverse_trigonometric_functions .. [2] https://dlmf.nist.gov/4.23 .. [3] https://functions.wolfram.com/ElementaryFunctions/ArcSin rcCs,|dkrdtd|jddSt||Nrrrwr$r8rrr2r2r3ri z asin.fdiffcC2|j|j}|j|jkr|jdjrdSdS|jSr6r7r8r9r;r2r2r3r>o   zasin._eval_is_rationalcC|o |jdjSr)r<r8 is_positiverr2r2r3_eval_is_positivewrzasin._eval_is_positivecCrr)r<r8r3rr2r2r3_eval_is_negativezrzasin._eval_is_negativecCs|jr:|tjur tjS|tjurtjtjS|tjur!tjtjS|jr'tjS|tjur0t dS|tj ur:t dS|tj urBtj S| rL||  S|j r[|}||vr[||St|}|durpddlm}tj||S|jrvtjSt|tr|jd}|jr|dt ;}|t krt |}|t dkrt |}|t dkrt |}|St|tr|jd}|jrt dt|SdSdS)Nrwr)asinh)rrrrrr1r:rMrrrrfr is_numberrr4rrr/rr8 is_comparablerr)rr asin_tablerrangr2r2r3r}sX                  z asin.evalcGs|dks |ddkr tjSt|}t|dkr1|dkr1|d}||dd||d|dS|dd}ttj|}t|}|||||Sr)rrMrrrr{rrrrrrRrr2r2r3rs$  zasin.taylor_termcCs|jd}||d}|tjur|||S|jr"||S|tj tjtj fvr:| t j |||d Sd|djry|||rH|nd}t|jr\|jr[t ||Snt|jrl|jrkt||Sn | t j |||d S||SNrrrrw)r8rr0rrr7r1r:rrfrr!r8rLr3r.rrrr<rrrrr6ndirr2r2r3r8s(      zasin._eval_as_leading_termrcsddlm}|jd|d}|tjurtddd}ttj|dt  |dd|}tj|jd} | |} | | | } | |dsX|dkrN|dSt d|t|Sttj| j|||d} | t| } ||| ||||S|tjurtddd}ttj|dt  |dd|}tj|jd} | |} | | | } | |ds|dkr|dSt d|t|Sttj| j|||d} | t| } ||| ||||Stj|||d} |tjur| Sd|djrJ|jd||r|nd}t|jr.|jr,t | S| St|jr>|jrrrrOrrPrrr8rr!r"r$_eval_rewrite_as_tractabler%r(r*r<r}rQr2r2rr3r>s, * 6 ,rcseZdZdZd$ddZddZeddZee d d Z d d Z d dZ ddZ d%fdd ZddZeZddZddZd$ddZddZddZd d!Zd"d#ZZS)&ra The inverse cosine function. Explanation =========== Returns the arc cosine of x (measured in radians). ``acos(x)`` will evaluate automatically in the cases $x \in \{\infty, -\infty, 0, 1, -1\}$ and for some instances when the result is a rational multiple of $\pi$ (see the eval class method). ``acos(zoo)`` evaluates to ``zoo`` (see note in :class:`sympy.functions.elementary.trigonometric.asec`) A purely imaginary argument will be rewritten to asinh. Examples ======== >>> from sympy import acos, oo >>> acos(1) 0 >>> acos(0) pi/2 >>> acos(oo) oo*I See Also ======== sin, csc, cos, sec, tan, cot asin, acsc, asec, atan, acot, atan2 References ========== .. [1] https://en.wikipedia.org/wiki/Inverse_trigonometric_functions .. [2] https://dlmf.nist.gov/4.23 .. [3] https://functions.wolfram.com/ElementaryFunctions/ArcCos rcCs,|dkrdtd|jddSt||Nrrrrwrrr2r2r3rS rz acos.fdiffcCrr6rr;r2r2r3r>Y rzacos._eval_is_rationalcCs|jr7|tjur tjS|tjurtjtjS|tjur!tjtjS|jr(tdS|tjur0tj S|tj ur7tS|tj ur?tj S|j r`| }||vrRtd||S| |vr`td|| St|}|durptdt|S|jrt|jdkr|jddkr|jd}d}n|}d}t|tr|jd}|jr|rt|}|dt;}|tkrdt|}|St|tr|jd}|jr|rtdt|Stdt|SdSdSNrwrrrTF)rrrrr1rr:rrrMrrfrrr4rrSrr8r/rrr)rrrrrminusr r2r2r3ra s\         "       z acos.evalcGs|dkrtdS|dks|ddkrtjSt|}t|dkr9|dkr9|d}||dd||d|dS|dd}ttj|}t|}| ||||Sr)rrrMrrrr{rr r2r2r3r s$  zacos.taylor_termcCs|jd}||d}|tjur|||S|dkr,tdttj||S|tj tj fvr@| t j |||dSd|dj r|||rN|nd}t|j rc|j rbdt||Snt|jrr|jrq|| Sn | t j |||dS||SNrrrwr)r8rr0rrr7r1r$rrfrr!r8r3r.rrrrLr r2r2r3r8 s(      zacos._eval_as_leading_termcCr+r,r-r/r2r2r3r< r0zacos._eval_is_extended_realcCs|Sr`)r<rr2r2r3_eval_is_nonnegative szacos._eval_is_nonnegativercsddlm}|jd|d}|tjur~tddd}ttj|dt  |dd|}tj|jd} | |} | | | } | |dsT|dkrN|dS|t |St tj| j|||d} | t | } ||| ||||S|tjurtddd}ttj|dt  |dd|}tj|jd} | |} | | | } | |ds|dkr|dSt|t |St tj| j|||d} | t | } ||| ||||Stj|||d} |tjur| Sd|djrB|jd||r|nd}t|jr'|jr%dt| S| St|jr6|jr4| S| S|t j||||d S| Sr)rrr8rrrrrrr!rr1rr$rrrLrrrrrfr3r.rrrrr2r3r sN   &   &  &    &    zacos._eval_nseriescKs,tdtjttj|td|dSrrrr1r!r$rr2r2r3r$ s zacos._eval_rewrite_as_logcKrrrrrr2r2r3_eval_rewrite_as_asin rzacos._eval_rewrite_as_asincKs8ttd|d|tdd|td|dSry)rr$rrr2r2r3r" 8zacos._eval_rewrite_as_atancCrzr{rrr2r2r3r} r~z acos.inversecKs(tddtdtd|d|Sr)rrr$rr2r2r3r% (zacos._eval_rewrite_as_acotcKr)r)rrr2r2r3r( r zacos._eval_rewrite_as_aseccKr&rrrrr2r2r3r* rzacos._eval_rewrite_as_acsccCsV|jd}||jd}|jdur|S|jr%|djr'|djr)|SdSdSdSNrFr)r8r7rrKr.is_nonpositive)r<rdrr2r2r3r s   zacos._eval_conjugaterMrN)rarbrcrdrr>rOrrPrrr8r<r6rr$r1r9r"r}r%r(r*rrQr2r2rr3r' s, + 6 , rcseZdZUdZded<ejej fZd*ddZddZ d d Z d d Z d dZ ddZ eddZeeddZddZd+fdd ZddZeZfddZd*ddZd d!Zd"d#Zd$d%Zd&d'Zd(d)ZZS),ra The inverse tangent function. Returns the arc tangent of x (measured in radians). Explanation =========== ``atan(x)`` will evaluate automatically in the cases $x \in \{\infty, -\infty, 0, 1, -1\}$ and for some instances when the result is a rational multiple of $\pi$ (see the eval class method). Examples ======== >>> from sympy import atan, oo >>> atan(0) 0 >>> atan(1) pi/4 >>> atan(oo) pi/2 See Also ======== sin, csc, cos, sec, tan, cot asin, acsc, acos, asec, acot, atan2 References ========== .. [1] https://en.wikipedia.org/wiki/Inverse_trigonometric_functions .. [2] https://dlmf.nist.gov/4.23 .. [3] https://functions.wolfram.com/ElementaryFunctions/ArcTan z tuple[Expr]r8rcCs(|dkrdd|jddSt||rr8rrr2r2r3rC  z atan.fdiffcCrr6rr;r2r2r3r>I rzatan._eval_is_rationalcCrr)r8is_extended_positiverr2r2r3rQ r zatan._eval_is_positivecCrr)r8is_extended_nonnegativerr2r2r3r6T r zatan._eval_is_nonnegativecCrr)r8r:rr2r2r3rFW r zatan._eval_is_zerocCrrr;rr2r2r3rZ r zatan._eval_is_realcCs|jr7|tjur tjS|tjurtdS|tjurt dS|jr$tjS|tjur-tdS|tj ur7t dS|tj urLddl m }|t dtdS| rV||  S|jre|}||vre||St|}|durzddlm}tj||S|jrtjSt|tr|jd}|jr|t;}|tdkr|t8}|St|tr|jd}|jrtdt|}|tdkr|t8}|SdSdS)Nrwrirr)atanh)rrrrrrr:rMrrrfrrrrrr4rrDr1r/rr8rrr)rrr atan_tablerrDr r2r2r3r] sX                 z atan.evalcGs@|dks |ddkr tjSt|}tj|dd|||Sr)rrMrrrrrr2r2r3r szatan.taylor_termcCs|jd}||d}|tjur|||S|jr"||S|tj tjtj fvr:| t j |||d Sd|djr||||rH|nd}t|jr]t|jr\||tSnt|jrot|jrn||tSn | t j |||d S||Sr )r8rr0rrr7r1r:r1rfrr!r8rLr3r.r rrrr r2r2r3r8 s(        zatan._eval_as_leading_termrcs|jd|d}|tjtjtjfvr |tj||||dStj|||d}|jd ||r3|nd}|tj urGt |dkrE|t S|Sd|dj rzt |j r^t|jr\|t S|St |jrnt|j rl|t S|S|tj||||dS|SNrrrrrw)r8rrr1rrr!rrr.rfr rr3rrr<rrrrrrrrr2r3r s(     zatan._eval_nseriescKs2tjdttjtj|ttjtj|Sr)rr1r!rrr2r2r3r$ szatan._eval_rewrite_as_logcsJ|dtjtjfvrtdtd|jd|||St||||Sr) rrrrrr8rr _eval_aseriesr<rargs0rrrr2r3rI s$zatan._eval_aseriescCrzr{rrr2r2r3r} r~z atan.inversecKs0t|d|tdtdtd|dSrr$rrrr2r2r3r9 0zatan._eval_rewrite_as_asincKs(t|d|tdtd|dSrr$rrr2r2r3r! r;zatan._eval_rewrite_as_acoscKr)rrrr2r2r3r% r zatan._eval_rewrite_as_acotcKs$t|d|ttd|dSrr$rrr2r2r3r( s$zatan._eval_rewrite_as_aseccKs,t|d|tdttd|dSrr$rrrr2r2r3r* ,zatan._eval_rewrite_as_acscrMrN)rarbrcrdrrr1rgrr>rr6rFrrOrrPrrr8rr$r1rIr}r9r!r%r(r*rQr2r2rr3r s4 &  4   rcseZdZdZejej fZd&ddZddZddZ d d Z d d Z e d dZ eeddZddZd'fdd ZfddZddZeZd&ddZddZddZd d!Zd"d#Zd$d%ZZS)(ra The inverse cotangent function. Returns the arc cotangent of x (measured in radians). Explanation =========== ``acot(x)`` will evaluate automatically in the cases $x \in \{\infty, -\infty, \tilde{\infty}, 0, 1, -1\}$ and for some instances when the result is a rational multiple of $\pi$ (see the eval class method). A purely imaginary argument will lead to an ``acoth`` expression. ``acot(x)`` has a branch cut along $(-i, i)$, hence it is discontinuous at 0. Its range for real $x$ is $(-\frac{\pi}{2}, \frac{\pi}{2}]$. Examples ======== >>> from sympy import acot, sqrt >>> acot(0) pi/2 >>> acot(1) pi/4 >>> acot(sqrt(3) - 2) -5*pi/12 See Also ======== sin, csc, cos, sec, tan, cot asin, acsc, acos, asec, atan, atan2 References ========== .. [1] https://dlmf.nist.gov/4.23 .. [2] https://functions.wolfram.com/ElementaryFunctions/ArcCot rcCs(|dkrdd|jddSt||r2r@rr2r2r3r rAz acot.fdiffcCrr6rr;r2r2r3r> rzacot._eval_is_rationalcCrr)r8r.rr2r2r3r( r zacot._eval_is_positivecCrr)r8r3rr2r2r3r+ r zacot._eval_is_negativecCrrr;rr2r2r3r<. r zacot._eval_is_extended_realcCs|jr5|tjur tjS|tjurtjS|tjurtjS|jr"tdS|tjur+tdS|tj ur5t dS|tj ur=tjS| rG||  S|j rf| }||vrftd||}|tdkrd|t8}|St|}|dur|ddlm}tj ||S|jrttjSt|tr|jd}|jr|t;}|tdkr|t8}|St|tr|jd}|jrtdt|}|tdkr|t8}|SdSdS)Nrwrir)acoth)rrrrrMrr:rrrrfrrrr4rrRr1r{r/rr8rrr)rrrEr rrRr2r2r3r1 s\                 z acot.evalcGsP|dkrtdS|dks|ddkrtjSt|}tj|dd|||Sr)rrrMrrrFr2r2r3rg s zacot.taylor_termcCs|jd}||d}|tjur|||S|tjur&d||S|tj tjtj fvr>| t j |||d S|jrd|djr|||rO|nd}t|jrdt|jrc||tSnt|jrvt|jru||tSn | t j |||d S||S)Nrrrrw)r8rr0rrr7r1rfr1rMrr!r8rLrrr.r rrr3r r2r2r3r8r s(        zacot._eval_as_leading_termrcs|jd|d}|tjtjtjfvr |tj||||dStj|||d}|tj ur0|S|jd ||r:|nd}|j rLt |dkrJ|t S|S|jrd|djrt |jrft|jrd|t S|St |jrvt|jrt|t S|S|tj||||dS|SrG)r8rrr1rrr!rrrfr.r:r rrrrr3rHrr2r3r s,     zacot._eval_nseriescsB|dtjtjfvrtd|jd|||St||||Sr,)rrrrr8rrrIrJrr2r3rI szacot._eval_aseriescKs.tjdtdtj|tdtj|Sr)rr1r!rr2r2r3r$ szacot._eval_rewrite_as_logcCrzr{rrr2r2r3r} r~z acot.inversecKs@|td|dtdtt|d t|d dSryrLrr2r2r3r9 s*zacot._eval_rewrite_as_asincKs8|td|dtt|d t|d dSryrNrr2r2r3r! r:zacot._eval_rewrite_as_acoscKr)rr|rr2r2r3r" r zacot._eval_rewrite_as_atancKs0|td|dttd|d|dSryrOrr2r2r3r( rMzacot._eval_rewrite_as_aseccKs8|td|dtdttd|d|dSryrPrr2r2r3r* r:zacot._eval_rewrite_as_acscrMrN)rarbrcrdrr1rgrr>rrr<rOrrPrrr8rrIr$r1r}r9r!r"r(r*rQr2r2rr3r s0*  5    rcseZdZdZeddZdddZdddZee d d Z d d Z dfdd Z ddZ ddZeZddZddZddZddZddZZS) ra The inverse secant function. Returns the arc secant of x (measured in radians). Explanation =========== ``asec(x)`` will evaluate automatically in the cases $x \in \{\infty, -\infty, 0, 1, -1\}$ and for some instances when the result is a rational multiple of $\pi$ (see the eval class method). ``asec(x)`` has branch cut in the interval $[-1, 1]$. For complex arguments, it can be defined [4]_ as .. math:: \operatorname{sec^{-1}}(z) = -i\frac{\log\left(\sqrt{1 - z^2} + 1\right)}{z} At ``x = 0``, for positive branch cut, the limit evaluates to ``zoo``. For negative branch cut, the limit .. math:: \lim_{z \to 0}-i\frac{\log\left(-\sqrt{1 - z^2} + 1\right)}{z} simplifies to :math:`-i\log\left(z/2 + O\left(z^3\right)\right)` which ultimately evaluates to ``zoo``. As ``acos(x) = asec(1/x)``, a similar argument can be given for ``acos(x)``. Examples ======== >>> from sympy import asec, oo >>> asec(1) 0 >>> asec(-1) pi >>> asec(0) zoo >>> asec(-oo) pi/2 See Also ======== sin, csc, cos, sec, tan, cot asin, acsc, acos, atan, acot, atan2 References ========== .. [1] https://en.wikipedia.org/wiki/Inverse_trigonometric_functions .. [2] https://dlmf.nist.gov/4.23 .. [3] https://functions.wolfram.com/ElementaryFunctions/ArcSec .. 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Returns the arc cosecant of x (measured in radians). Explanation =========== ``acsc(x)`` will evaluate automatically in the cases $x \in \{\infty, -\infty, 0, 1, -1\}$` and for some instances when the result is a rational multiple of $\pi$ (see the ``eval`` class method). Examples ======== >>> from sympy import acsc, oo >>> acsc(1) pi/2 >>> acsc(-1) -pi/2 >>> acsc(oo) 0 >>> acsc(-oo) == acsc(oo) True >>> acsc(0) zoo See Also ======== sin, csc, cos, sec, tan, cot asin, acos, asec, atan, acot, atan2 References ========== .. [1] https://en.wikipedia.org/wiki/Inverse_trigonometric_functions .. [2] https://dlmf.nist.gov/4.23 .. 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Signs of both `y` and `x` are considered to determine the appropriate quadrant of `\operatorname{atan}(y/x)`. The range is `(-\pi, \pi]`. The complete definition reads as follows: .. math:: \operatorname{atan2}(y, x) = \begin{cases} \arctan\left(\frac y x\right) & \qquad x > 0 \\ \arctan\left(\frac y x\right) + \pi& \qquad y \ge 0, x < 0 \\ \arctan\left(\frac y x\right) - \pi& \qquad y < 0, x < 0 \\ +\frac{\pi}{2} & \qquad y > 0, x = 0 \\ -\frac{\pi}{2} & \qquad y < 0, x = 0 \\ \text{undefined} & \qquad y = 0, x = 0 \end{cases} Attention: Note the role reversal of both arguments. The `y`-coordinate is the first argument and the `x`-coordinate the second. If either `x` or `y` is complex: .. math:: \operatorname{atan2}(y, x) = -i\log\left(\frac{x + iy}{\sqrt{x^2 + y^2}}\right) Examples ======== Going counter-clock wise around the origin we find the following angles: >>> from sympy import atan2 >>> atan2(0, 1) 0 >>> atan2(1, 1) pi/4 >>> atan2(1, 0) pi/2 >>> atan2(1, -1) 3*pi/4 >>> atan2(0, -1) pi >>> atan2(-1, -1) -3*pi/4 >>> atan2(-1, 0) -pi/2 >>> atan2(-1, 1) -pi/4 which are all correct. Compare this to the results of the ordinary `\operatorname{atan}` function for the point `(x, y) = (-1, 1)` >>> from sympy import atan, S >>> atan(S(1)/-1) -pi/4 >>> atan2(1, -1) 3*pi/4 where only the `\operatorname{atan2}` function returns what we expect. We can differentiate the function with respect to both arguments: >>> from sympy import diff >>> from sympy.abc import x, y >>> diff(atan2(y, x), x) -y/(x**2 + y**2) >>> diff(atan2(y, x), y) x/(x**2 + y**2) We can express the `\operatorname{atan2}` function in terms of complex logarithms: >>> from sympy import log >>> atan2(y, x).rewrite(log) -I*log((x + I*y)/sqrt(x**2 + y**2)) and in terms of `\operatorname(atan)`: >>> from sympy import atan >>> atan2(y, x).rewrite(atan) Piecewise((2*atan(y/(x + sqrt(x**2 + y**2))), Ne(y, 0)), (pi, re(x) < 0), (0, Ne(x, 0)), (nan, True)) but note that this form is undefined on the negative real axis. See Also ======== sin, csc, cos, sec, tan, cot asin, acsc, acos, asec, atan, acot References ========== .. [1] https://en.wikipedia.org/wiki/Inverse_trigonometric_functions .. [2] https://en.wikipedia.org/wiki/Atan2 .. 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