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\(\int \cot ^{-1}(c+(1+i c) \tan (a+b x)) \, dx\) [16]

Optimal result
Mathematica [B] (warning: unable to verify)
Rubi [A] (verified)
Maple [B] (verified)
Fricas [B] (verification not implemented)
Sympy [F(-2)]
Maxima [B] (verification not implemented)
Giac [F]
Mupad [F(-1)]
Reduce [F]

Optimal result

Integrand size = 17, antiderivative size = 85 \[ \int \cot ^{-1}(c+(1+i c) \tan (a+b x)) \, dx=\frac {b x^2}{2}+x \cot ^{-1}(c+(1+i c) \tan (a+b x))+\frac {1}{2} i x \log \left (1-i c e^{2 i a+2 i b x}\right )+\frac {\operatorname {PolyLog}\left (2,i c e^{2 i a+2 i b x}\right )}{4 b} \] Output: 

1/2*b*x^2+x*arccot(c+(1+I*c)*tan(b*x+a))+1/2*I*x*ln(1-I*c*exp(2*I*a+2*I*b* 
x))+1/4*polylog(2,I*c*exp(2*I*a+2*I*b*x))/b

Mathematica [B] (warning: unable to verify)

Both result and optimal contain complex but leaf count is larger than twice the leaf count of optimal. \(967\) vs. \(2(85)=170\).

Time = 3.68 (sec) , antiderivative size = 967, normalized size of antiderivative = 11.38 \[ \int \cot ^{-1}(c+(1+i c) \tan (a+b x)) \, dx=x \cot ^{-1}(c+(1+i c) \tan (a+b x))-\frac {i x \left (2 i b x \log (2 \cos (b x) (\cos (b x)-i \sin (b x)))-\log \left (\frac {\sec (b x) (\cos (a)-i \sin (a)) ((i+c) \cos (a+b x)+(1+i c) \sin (a+b x))}{2 c}\right ) \log (1-i \tan (b x))+\log \left (\frac {\sec (b x) ((1-i c) \cos (a+b x)+(-i+c) \sin (a+b x))}{2 \cos (a)-2 i \sin (a)}\right ) \log (1+i \tan (b x))-\operatorname {PolyLog}(2,-\cos (2 b x)+i \sin (2 b x))-\operatorname {PolyLog}\left (2,\frac {\sec (b x) ((-i+c) \cos (a)+i (i+c) \sin (a)) (\cos (a+b x)-i \sin (a+b x))}{2 c}\right )+\operatorname {PolyLog}\left (2,\frac {1}{2} \sec (b x) ((1+i c) \cos (a)-(i+c) \sin (a)) (\cos (a+b x)+i \sin (a+b x))\right )\right ) \sec ^2(a+b x) (\cos (b x)+i \sin (b x)) (i \cos (b x)+\sin (b x)) ((1-i c) \cos (a+b x)+(-i+c) \sin (a+b x))}{((i+c) \cos (a+b x)+(1+i c) \sin (a+b x)) \left (2 b x-i \log \left (1-\frac {\sec (b x) ((-i+c) \cos (a)+i (i+c) \sin (a)) (\cos (a+b x)-i \sin (a+b x))}{2 c}\right )-i \log \left (1+\frac {1}{2} \sec (b x) ((-1-i c) \cos (a)+(i+c) \sin (a)) (\cos (a+b x)+i \sin (a+b x))\right )-\frac {i (-i+c) \cos (a+b x) (\log (1-i \tan (b x))-\log (1+i \tan (b x)))}{(i+c) \cos (a+b x)+(1+i c) \sin (a+b x)}+\frac {(i+c) (\log (1-i \tan (b x))-\log (1+i \tan (b x))) \sin (a+b x)}{(i+c) \cos (a+b x)+(1+i c) \sin (a+b x)}-2 i b x \tan (b x)+\log \left (1-\frac {\sec (b x) ((-i+c) \cos (a)+i (i+c) \sin (a)) (\cos (a+b x)-i \sin (a+b x))}{2 c}\right ) \tan (b x)-\log \left (1+\frac {1}{2} \sec (b x) ((-1-i c) \cos (a)+(i+c) \sin (a)) (\cos (a+b x)+i \sin (a+b x))\right ) \tan (b x)-\log (1-i \tan (b x)) \tan (b x)+\cos ^2(a) \log (1+i \tan (b x)) \tan (b x)+\log (1+i \tan (b x)) \sin ^2(a) \tan (b x)+\frac {\log \left (\frac {\sec (b x) ((1-i c) \cos (a+b x)+(-i+c) \sin (a+b x))}{2 \cos (a)-2 i \sin (a)}\right ) \sec ^2(b x)}{-i+\tan (b x)}-\frac {\log \left (\frac {\sec (b x) (\cos (a)-i \sin (a)) ((i+c) \cos (a+b x)+(1+i c) \sin (a+b x))}{2 c}\right ) \sec ^2(b x)}{i+\tan (b x)}\right ) (-i+\tan (a+b x)) (1-i c+(-i+c) \tan (a+b x))} \] Input: 

Integrate[ArcCot[c + (1 + I*c)*Tan[a + b*x]],x]

Output: 

x*ArcCot[c + (1 + I*c)*Tan[a + b*x]] - (I*x*((2*I)*b*x*Log[2*Cos[b*x]*(Cos 
[b*x] - I*Sin[b*x])] - Log[(Sec[b*x]*(Cos[a] - I*Sin[a])*((I + c)*Cos[a + 
b*x] + (1 + I*c)*Sin[a + b*x]))/(2*c)]*Log[1 - I*Tan[b*x]] + Log[(Sec[b*x] 
*((1 - I*c)*Cos[a + b*x] + (-I + c)*Sin[a + b*x]))/(2*Cos[a] - (2*I)*Sin[a 
])]*Log[1 + I*Tan[b*x]] - PolyLog[2, -Cos[2*b*x] + I*Sin[2*b*x]] - PolyLog 
[2, (Sec[b*x]*((-I + c)*Cos[a] + I*(I + c)*Sin[a])*(Cos[a + b*x] - I*Sin[a 
 + b*x]))/(2*c)] + PolyLog[2, (Sec[b*x]*((1 + I*c)*Cos[a] - (I + c)*Sin[a] 
)*(Cos[a + b*x] + I*Sin[a + b*x]))/2])*Sec[a + b*x]^2*(Cos[b*x] + I*Sin[b* 
x])*(I*Cos[b*x] + Sin[b*x])*((1 - I*c)*Cos[a + b*x] + (-I + c)*Sin[a + b*x 
]))/(((I + c)*Cos[a + b*x] + (1 + I*c)*Sin[a + b*x])*(2*b*x - I*Log[1 - (S 
ec[b*x]*((-I + c)*Cos[a] + I*(I + c)*Sin[a])*(Cos[a + b*x] - I*Sin[a + b*x 
]))/(2*c)] - I*Log[1 + (Sec[b*x]*((-1 - I*c)*Cos[a] + (I + c)*Sin[a])*(Cos 
[a + b*x] + I*Sin[a + b*x]))/2] - (I*(-I + c)*Cos[a + b*x]*(Log[1 - I*Tan[ 
b*x]] - Log[1 + I*Tan[b*x]]))/((I + c)*Cos[a + b*x] + (1 + I*c)*Sin[a + b* 
x]) + ((I + c)*(Log[1 - I*Tan[b*x]] - Log[1 + I*Tan[b*x]])*Sin[a + b*x])/( 
(I + c)*Cos[a + b*x] + (1 + I*c)*Sin[a + b*x]) - (2*I)*b*x*Tan[b*x] + Log[ 
1 - (Sec[b*x]*((-I + c)*Cos[a] + I*(I + c)*Sin[a])*(Cos[a + b*x] - I*Sin[a 
 + b*x]))/(2*c)]*Tan[b*x] - Log[1 + (Sec[b*x]*((-1 - I*c)*Cos[a] + (I + c) 
*Sin[a])*(Cos[a + b*x] + I*Sin[a + b*x]))/2]*Tan[b*x] - Log[1 - I*Tan[b*x] 
]*Tan[b*x] + Cos[a]^2*Log[1 + I*Tan[b*x]]*Tan[b*x] + Log[1 + I*Tan[b*x]...

Rubi [A] (verified)

Time = 0.44 (sec) , antiderivative size = 107, normalized size of antiderivative = 1.26, number of steps used = 6, number of rules used = 5, \(\frac {\text {number of rules}}{\text {integrand size}}\) = 0.294, Rules used = {5687, 2615, 2620, 2715, 2838}

Below are the steps used by Rubi to obtain the solution. The rule number used for the transformation is given above next to the arrow. The rules definitions used are listed below.

\(\displaystyle \int \cot ^{-1}(c+(1+i c) \tan (a+b x)) \, dx\)

\(\Big \downarrow \) 5687

\(\displaystyle i b \int \frac {x}{e^{2 i a+2 i b x} c+i}dx+x \cot ^{-1}(c+(1+i c) \tan (a+b x))\)

\(\Big \downarrow \) 2615

\(\displaystyle i b \left (i c \int \frac {e^{2 i a+2 i b x} x}{e^{2 i a+2 i b x} c+i}dx-\frac {i x^2}{2}\right )+x \cot ^{-1}(c+(1+i c) \tan (a+b x))\)

\(\Big \downarrow \) 2620

\(\displaystyle i b \left (i c \left (\frac {i \int \log \left (1-i c e^{2 i a+2 i b x}\right )dx}{2 b c}-\frac {i x \log \left (1-i c e^{2 i a+2 i b x}\right )}{2 b c}\right )-\frac {i x^2}{2}\right )+x \cot ^{-1}(c+(1+i c) \tan (a+b x))\)

\(\Big \downarrow \) 2715

\(\displaystyle i b \left (i c \left (\frac {\int e^{-2 i a-2 i b x} \log \left (1-i c e^{2 i a+2 i b x}\right )de^{2 i a+2 i b x}}{4 b^2 c}-\frac {i x \log \left (1-i c e^{2 i a+2 i b x}\right )}{2 b c}\right )-\frac {i x^2}{2}\right )+x \cot ^{-1}(c+(1+i c) \tan (a+b x))\)

\(\Big \downarrow \) 2838

\(\displaystyle i b \left (i c \left (-\frac {\operatorname {PolyLog}\left (2,i c e^{2 i a+2 i b x}\right )}{4 b^2 c}-\frac {i x \log \left (1-i c e^{2 i a+2 i b x}\right )}{2 b c}\right )-\frac {i x^2}{2}\right )+x \cot ^{-1}(c+(1+i c) \tan (a+b x))\)

Input: 

Int[ArcCot[c + (1 + I*c)*Tan[a + b*x]],x]

Output: 

x*ArcCot[c + (1 + I*c)*Tan[a + b*x]] + I*b*((-1/2*I)*x^2 + I*c*(((-1/2*I)* 
x*Log[1 - I*c*E^((2*I)*a + (2*I)*b*x)])/(b*c) - PolyLog[2, I*c*E^((2*I)*a 
+ (2*I)*b*x)]/(4*b^2*c)))

Defintions of rubi rules used

rule 2615 
Int[((c_.) + (d_.)*(x_))^(m_.)/((a_) + (b_.)*((F_)^((g_.)*((e_.) + (f_.)*(x 
_))))^(n_.)), x_Symbol] :> Simp[(c + d*x)^(m + 1)/(a*d*(m + 1)), x] - Simp[ 
b/a   Int[(c + d*x)^m*((F^(g*(e + f*x)))^n/(a + b*(F^(g*(e + f*x)))^n)), x] 
, x] /; FreeQ[{F, a, b, c, d, e, f, g, n}, x] && IGtQ[m, 0]

rule 2620 
Int[(((F_)^((g_.)*((e_.) + (f_.)*(x_))))^(n_.)*((c_.) + (d_.)*(x_))^(m_.))/ 
((a_) + (b_.)*((F_)^((g_.)*((e_.) + (f_.)*(x_))))^(n_.)), x_Symbol] :> Simp 
[((c + d*x)^m/(b*f*g*n*Log[F]))*Log[1 + b*((F^(g*(e + f*x)))^n/a)], x] - Si 
mp[d*(m/(b*f*g*n*Log[F]))   Int[(c + d*x)^(m - 1)*Log[1 + b*((F^(g*(e + f*x 
)))^n/a)], x], x] /; FreeQ[{F, a, b, c, d, e, f, g, n}, x] && IGtQ[m, 0]

rule 2715 
Int[Log[(a_) + (b_.)*((F_)^((e_.)*((c_.) + (d_.)*(x_))))^(n_.)], x_Symbol] 
:> Simp[1/(d*e*n*Log[F])   Subst[Int[Log[a + b*x]/x, x], x, (F^(e*(c + d*x) 
))^n], x] /; FreeQ[{F, a, b, c, d, e, n}, x] && GtQ[a, 0]

rule 2838 
Int[Log[(c_.)*((d_) + (e_.)*(x_)^(n_.))]/(x_), x_Symbol] :> Simp[-PolyLog[2 
, (-c)*e*x^n]/n, x] /; FreeQ[{c, d, e, n}, x] && EqQ[c*d, 1]

rule 5687 
Int[ArcCot[(c_.) + (d_.)*Tan[(a_.) + (b_.)*(x_)]], x_Symbol] :> Simp[x*ArcC 
ot[c + d*Tan[a + b*x]], x] + Simp[I*b   Int[x/(c + I*d + c*E^(2*I*a + 2*I*b 
*x)), x], x] /; FreeQ[{a, b, c, d}, x] && EqQ[(c + I*d)^2, -1]
Maple [B] (verified)

Both result and optimal contain complex but leaf count of result is larger than twice the leaf count of optimal. 561 vs. \(2 (69 ) = 138\).

Time = 2.14 (sec) , antiderivative size = 562, normalized size of antiderivative = 6.61

method result size
derivativedivides \(\frac {-\frac {\operatorname {arccot}\left (c +\left (i c +1\right ) \tan \left (b x +a \right )\right ) \ln \left (-i+c +\left (i c +1\right ) \tan \left (b x +a \right )\right ) c^{2}}{2 i-2 c}+\frac {2 i \operatorname {arccot}\left (c +\left (i c +1\right ) \tan \left (b x +a \right )\right ) \ln \left (-i+c +\left (i c +1\right ) \tan \left (b x +a \right )\right ) c}{2 i-2 c}+\frac {\operatorname {arccot}\left (c +\left (i c +1\right ) \tan \left (b x +a \right )\right ) \ln \left (-i+c +\left (i c +1\right ) \tan \left (b x +a \right )\right )}{2 i-2 c}+\frac {\operatorname {arccot}\left (c +\left (i c +1\right ) \tan \left (b x +a \right )\right ) \ln \left (-c +\left (i c +1\right ) \tan \left (b x +a \right )+i\right ) c^{2}}{2 i-2 c}-\frac {2 i \operatorname {arccot}\left (c +\left (i c +1\right ) \tan \left (b x +a \right )\right ) \ln \left (-c +\left (i c +1\right ) \tan \left (b x +a \right )+i\right ) c}{2 i-2 c}-\frac {\operatorname {arccot}\left (c +\left (i c +1\right ) \tan \left (b x +a \right )\right ) \ln \left (-c +\left (i c +1\right ) \tan \left (b x +a \right )+i\right )}{2 i-2 c}+\left (i c +1\right )^{2} \left (\frac {\frac {i \left (\operatorname {dilog}\left (-\frac {i \left (c +\left (i c +1\right ) \tan \left (b x +a \right )+i\right )}{2}\right )+\ln \left (-i+c +\left (i c +1\right ) \tan \left (b x +a \right )\right ) \ln \left (-\frac {i \left (c +\left (i c +1\right ) \tan \left (b x +a \right )+i\right )}{2}\right )\right )}{2}-\frac {i \ln \left (-i+c +\left (i c +1\right ) \tan \left (b x +a \right )\right )^{2}}{4}}{2 i-2 c}-\frac {-\frac {i \left (\operatorname {dilog}\left (\frac {-i+c +\left (i c +1\right ) \tan \left (b x +a \right )}{-2 i+2 c}\right )+\ln \left (-c +\left (i c +1\right ) \tan \left (b x +a \right )+i\right ) \ln \left (\frac {-i+c +\left (i c +1\right ) \tan \left (b x +a \right )}{-2 i+2 c}\right )\right )}{2}+\frac {i \left (\operatorname {dilog}\left (\frac {c +\left (i c +1\right ) \tan \left (b x +a \right )+i}{2 c}\right )+\ln \left (-c +\left (i c +1\right ) \tan \left (b x +a \right )+i\right ) \ln \left (\frac {c +\left (i c +1\right ) \tan \left (b x +a \right )+i}{2 c}\right )\right )}{2}}{2 \left (i-c \right )}\right )}{b \left (i c +1\right )}\) \(562\)
default \(\frac {-\frac {\operatorname {arccot}\left (c +\left (i c +1\right ) \tan \left (b x +a \right )\right ) \ln \left (-i+c +\left (i c +1\right ) \tan \left (b x +a \right )\right ) c^{2}}{2 i-2 c}+\frac {2 i \operatorname {arccot}\left (c +\left (i c +1\right ) \tan \left (b x +a \right )\right ) \ln \left (-i+c +\left (i c +1\right ) \tan \left (b x +a \right )\right ) c}{2 i-2 c}+\frac {\operatorname {arccot}\left (c +\left (i c +1\right ) \tan \left (b x +a \right )\right ) \ln \left (-i+c +\left (i c +1\right ) \tan \left (b x +a \right )\right )}{2 i-2 c}+\frac {\operatorname {arccot}\left (c +\left (i c +1\right ) \tan \left (b x +a \right )\right ) \ln \left (-c +\left (i c +1\right ) \tan \left (b x +a \right )+i\right ) c^{2}}{2 i-2 c}-\frac {2 i \operatorname {arccot}\left (c +\left (i c +1\right ) \tan \left (b x +a \right )\right ) \ln \left (-c +\left (i c +1\right ) \tan \left (b x +a \right )+i\right ) c}{2 i-2 c}-\frac {\operatorname {arccot}\left (c +\left (i c +1\right ) \tan \left (b x +a \right )\right ) \ln \left (-c +\left (i c +1\right ) \tan \left (b x +a \right )+i\right )}{2 i-2 c}+\left (i c +1\right )^{2} \left (\frac {\frac {i \left (\operatorname {dilog}\left (-\frac {i \left (c +\left (i c +1\right ) \tan \left (b x +a \right )+i\right )}{2}\right )+\ln \left (-i+c +\left (i c +1\right ) \tan \left (b x +a \right )\right ) \ln \left (-\frac {i \left (c +\left (i c +1\right ) \tan \left (b x +a \right )+i\right )}{2}\right )\right )}{2}-\frac {i \ln \left (-i+c +\left (i c +1\right ) \tan \left (b x +a \right )\right )^{2}}{4}}{2 i-2 c}-\frac {-\frac {i \left (\operatorname {dilog}\left (\frac {-i+c +\left (i c +1\right ) \tan \left (b x +a \right )}{-2 i+2 c}\right )+\ln \left (-c +\left (i c +1\right ) \tan \left (b x +a \right )+i\right ) \ln \left (\frac {-i+c +\left (i c +1\right ) \tan \left (b x +a \right )}{-2 i+2 c}\right )\right )}{2}+\frac {i \left (\operatorname {dilog}\left (\frac {c +\left (i c +1\right ) \tan \left (b x +a \right )+i}{2 c}\right )+\ln \left (-c +\left (i c +1\right ) \tan \left (b x +a \right )+i\right ) \ln \left (\frac {c +\left (i c +1\right ) \tan \left (b x +a \right )+i}{2 c}\right )\right )}{2}}{2 \left (i-c \right )}\right )}{b \left (i c +1\right )}\) \(562\)
risch \(\text {Expression too large to display}\) \(1244\)

Input: 

int(arccot(c+(I*c+1)*tan(b*x+a)),x,method=_RETURNVERBOSE)

Output: 

1/b/(I*c+1)*(-arccot(c+(I*c+1)*tan(b*x+a))/(2*I-2*c)*ln(-I+c+(I*c+1)*tan(b 
*x+a))*c^2+2*I*arccot(c+(I*c+1)*tan(b*x+a))/(2*I-2*c)*ln(-I+c+(I*c+1)*tan( 
b*x+a))*c+arccot(c+(I*c+1)*tan(b*x+a))/(2*I-2*c)*ln(-I+c+(I*c+1)*tan(b*x+a 
))+arccot(c+(I*c+1)*tan(b*x+a))/(2*I-2*c)*ln(-c+(I*c+1)*tan(b*x+a)+I)*c^2- 
2*I*arccot(c+(I*c+1)*tan(b*x+a))/(2*I-2*c)*ln(-c+(I*c+1)*tan(b*x+a)+I)*c-a 
rccot(c+(I*c+1)*tan(b*x+a))/(2*I-2*c)*ln(-c+(I*c+1)*tan(b*x+a)+I)+(I*c+1)^ 
2*(1/2/(I-c)*(1/2*I*(dilog(-1/2*I*(c+(I*c+1)*tan(b*x+a)+I))+ln(-I+c+(I*c+1 
)*tan(b*x+a))*ln(-1/2*I*(c+(I*c+1)*tan(b*x+a)+I)))-1/4*I*ln(-I+c+(I*c+1)*t 
an(b*x+a))^2)-1/2/(I-c)*(-1/2*I*(dilog((-I+c+(I*c+1)*tan(b*x+a))/(-2*I+2*c 
))+ln(-c+(I*c+1)*tan(b*x+a)+I)*ln((-I+c+(I*c+1)*tan(b*x+a))/(-2*I+2*c)))+1 
/2*I*(dilog(1/2*(c+(I*c+1)*tan(b*x+a)+I)/c)+ln(-c+(I*c+1)*tan(b*x+a)+I)*ln 
(1/2*(c+(I*c+1)*tan(b*x+a)+I)/c)))))

Fricas [B] (verification not implemented)

Both result and optimal contain complex but leaf count of result is larger than twice the leaf count of optimal. 199 vs. \(2 (60) = 120\).

Time = 0.12 (sec) , antiderivative size = 199, normalized size of antiderivative = 2.34 \[ \int \cot ^{-1}(c+(1+i c) \tan (a+b x)) \, dx=\frac {b^{2} x^{2} - i \, b x \log \left (\frac {{\left (c e^{\left (2 i \, b x + 2 i \, a\right )} + i\right )} e^{\left (-2 i \, b x - 2 i \, a\right )}}{c - i}\right ) - a^{2} + {\left (i \, b x + i \, a\right )} \log \left (\frac {1}{2} \, \sqrt {4 i \, c} e^{\left (i \, b x + i \, a\right )} + 1\right ) + {\left (i \, b x + i \, a\right )} \log \left (-\frac {1}{2} \, \sqrt {4 i \, c} e^{\left (i \, b x + i \, a\right )} + 1\right ) - i \, a \log \left (\frac {2 \, c e^{\left (i \, b x + i \, a\right )} + i \, \sqrt {4 i \, c}}{2 \, c}\right ) - i \, a \log \left (\frac {2 \, c e^{\left (i \, b x + i \, a\right )} - i \, \sqrt {4 i \, c}}{2 \, c}\right ) + {\rm Li}_2\left (\frac {1}{2} \, \sqrt {4 i \, c} e^{\left (i \, b x + i \, a\right )}\right ) + {\rm Li}_2\left (-\frac {1}{2} \, \sqrt {4 i \, c} e^{\left (i \, b x + i \, a\right )}\right )}{2 \, b} \] Input: 

integrate(arccot(c+(1+I*c)*tan(b*x+a)),x, algorithm="fricas")

Output: 

1/2*(b^2*x^2 - I*b*x*log((c*e^(2*I*b*x + 2*I*a) + I)*e^(-2*I*b*x - 2*I*a)/ 
(c - I)) - a^2 + (I*b*x + I*a)*log(1/2*sqrt(4*I*c)*e^(I*b*x + I*a) + 1) + 
(I*b*x + I*a)*log(-1/2*sqrt(4*I*c)*e^(I*b*x + I*a) + 1) - I*a*log(1/2*(2*c 
*e^(I*b*x + I*a) + I*sqrt(4*I*c))/c) - I*a*log(1/2*(2*c*e^(I*b*x + I*a) - 
I*sqrt(4*I*c))/c) + dilog(1/2*sqrt(4*I*c)*e^(I*b*x + I*a)) + dilog(-1/2*sq 
rt(4*I*c)*e^(I*b*x + I*a)))/b

Sympy [F(-2)]

Exception generated. \[ \int \cot ^{-1}(c+(1+i c) \tan (a+b x)) \, dx=\text {Exception raised: CoercionFailed} \] Input: 

integrate(acot(c+(1+I*c)*tan(b*x+a)),x)

Output: 

Exception raised: CoercionFailed >> Cannot convert 2*_t0**2*c*exp(2*I*a) - 
 _t0**2*I*exp(2*I*a) + I of type <class 'sympy.core.add.Add'> to QQ_I[b,c, 
_t0,exp(I*a)]

Maxima [B] (verification not implemented)

Both result and optimal contain complex but leaf count of result is larger than twice the leaf count of optimal. 455 vs. \(2 (60) = 120\).

Time = 0.15 (sec) , antiderivative size = 455, normalized size of antiderivative = 5.35 \[ \int \cot ^{-1}(c+(1+i c) \tan (a+b x)) \, dx =\text {Too large to display} \] Input: 

integrate(arccot(c+(1+I*c)*tan(b*x+a)),x, algorithm="maxima")

Output: 

-1/8*((-I*c - 1)*(4*I*(b*x + a)*log(-2*(-I*c^2 + (c^2 - 2*I*c - 1)*tan(b*x 
 + a) - 2*c + I)/(2*I*c^2 - 2*(c^2 - 2*I*c - 1)*tan(b*x + a) + 2*I))/(I*c 
+ 1) - I*(4*(b*x + a)*(log(-I*c^2 + (c^2 - 2*I*c - 1)*tan(b*x + a) - 2*c + 
 I) - log(-I*c^2 + (c^2 - 2*I*c - 1)*tan(b*x + a) - I)) + I*log(-I*c^2 + ( 
c^2 - 2*I*c - 1)*tan(b*x + a) - 2*c + I)^2 - 2*I*log(-I*c^2 + (c^2 - 2*I*c 
 - 1)*tan(b*x + a) - I)*log(-1/2*(c - I)*tan(b*x + a) + 1/2*I*c + 1/2) + 2 
*I*log(-I*c^2 + (c^2 - 2*I*c - 1)*tan(b*x + a) - I)*log(-1/2*((I*c + 1)*ta 
n(b*x + a) + c + I)/c + 1) - 2*I*log(-I*c^2 + (c^2 - 2*I*c - 1)*tan(b*x + 
a) - 2*c + I)*log(-1/2*I*tan(b*x + a) + 1/2) - 2*I*dilog(1/2*(c - I)*tan(b 
*x + a) - 1/2*I*c + 1/2) + 2*I*dilog(1/2*((I*c + 1)*tan(b*x + a) + c + I)/ 
c) - 2*I*dilog(1/2*I*tan(b*x + a) + 1/2))/(I*c + 1)) - 8*(b*x + a)*arccot( 
(I*c + 1)*tan(b*x + a) + c) - 4*(b*x + a)*(c - I)*log(-2*(-I*c^2 + (c^2 - 
2*I*c - 1)*tan(b*x + a) - 2*c + I)/(2*I*c^2 - 2*(c^2 - 2*I*c - 1)*tan(b*x 
+ a) + 2*I))/(I*c + 1))/b

Giac [F]

\[ \int \cot ^{-1}(c+(1+i c) \tan (a+b x)) \, dx=\int { \operatorname {arccot}\left ({\left (i \, c + 1\right )} \tan \left (b x + a\right ) + c\right ) \,d x } \] Input: 

integrate(arccot(c+(1+I*c)*tan(b*x+a)),x, algorithm="giac")

Output: 

integrate(arccot((I*c + 1)*tan(b*x + a) + c), x)

Mupad [F(-1)]

Timed out. \[ \int \cot ^{-1}(c+(1+i c) \tan (a+b x)) \, dx=\int \mathrm {acot}\left (c+\mathrm {tan}\left (a+b\,x\right )\,\left (1+c\,1{}\mathrm {i}\right )\right ) \,d x \] Input: 

int(acot(c + tan(a + b*x)*(c*1i + 1)),x)

Output: 

int(acot(c + tan(a + b*x)*(c*1i + 1)), x)

Reduce [F]

\[ \int \cot ^{-1}(c+(1+i c) \tan (a+b x)) \, dx=\int \mathit {acot} \left (\tan \left (b x +a \right ) c i +\tan \left (b x +a \right )+c \right )d x \] Input: 

int(acot(c+(1+I*c)*tan(b*x+a)),x)

Output: 

int(acot(tan(a + b*x)*c*i + tan(a + b*x) + c),x)

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