3.138 \(\int d^x x^2 \sin (x) \, dx\)
Optimal. Leaf size=162 \[ \frac{x^2 d^x \log (d) \sin (x)}{\log ^2(d)+1}-\frac{x^2 d^x \cos (x)}{\log ^2(d)+1}-\frac{2 x d^x \log ^2(d) \sin (x)}{\left (\log ^2(d)+1\right )^2}+\frac{2 x d^x \sin (x)}{\left (\log ^2(d)+1\right )^2}+\frac{2 d^x \log ^3(d) \sin (x)}{\left (\log ^2(d)+1\right )^3}-\frac{6 d^x \log (d) \sin (x)}{\left (\log ^2(d)+1\right )^3}+\frac{4 x d^x \log (d) \cos (x)}{\left (\log ^2(d)+1\right )^2}-\frac{6 d^x \log ^2(d) \cos (x)}{\left (\log ^2(d)+1\right )^3}+\frac{2 d^x \cos (x)}{\left (\log ^2(d)+1\right )^3} \]
[Out]
(2*d^x*Cos[x])/(1 + Log[d]^2)^3 - (6*d^x*Cos[x]*Log[d]^2)/(1 + Log[d]^2)^3 + (4*d^x*x*Cos[x]*Log[d])/(1 + Log[
d]^2)^2 - (d^x*x^2*Cos[x])/(1 + Log[d]^2) - (6*d^x*Log[d]*Sin[x])/(1 + Log[d]^2)^3 + (2*d^x*Log[d]^3*Sin[x])/(
1 + Log[d]^2)^3 + (2*d^x*x*Sin[x])/(1 + Log[d]^2)^2 - (2*d^x*x*Log[d]^2*Sin[x])/(1 + Log[d]^2)^2 + (d^x*x^2*Lo
g[d]*Sin[x])/(1 + Log[d]^2)
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Rubi [A] time = 0.175857, antiderivative size = 162, normalized size of antiderivative = 1.,
number of steps used = 11, number of rules used = 5, integrand size = 9, \(\frac{\text{number of rules}}{\text{integrand size}}\) = 0.556, Rules used =
{4432, 4465, 14, 4433, 4466} \[ \frac{x^2 d^x \log (d) \sin (x)}{\log ^2(d)+1}-\frac{x^2 d^x \cos (x)}{\log ^2(d)+1}-\frac{2 x d^x \log ^2(d) \sin (x)}{\left (\log ^2(d)+1\right )^2}+\frac{2 x d^x \sin (x)}{\left (\log ^2(d)+1\right )^2}+\frac{2 d^x \log ^3(d) \sin (x)}{\left (\log ^2(d)+1\right )^3}-\frac{6 d^x \log (d) \sin (x)}{\left (\log ^2(d)+1\right )^3}+\frac{4 x d^x \log (d) \cos (x)}{\left (\log ^2(d)+1\right )^2}-\frac{6 d^x \log ^2(d) \cos (x)}{\left (\log ^2(d)+1\right )^3}+\frac{2 d^x \cos (x)}{\left (\log ^2(d)+1\right )^3} \]
Antiderivative was successfully verified.
[In]
Int[d^x*x^2*Sin[x],x]
[Out]
(2*d^x*Cos[x])/(1 + Log[d]^2)^3 - (6*d^x*Cos[x]*Log[d]^2)/(1 + Log[d]^2)^3 + (4*d^x*x*Cos[x]*Log[d])/(1 + Log[
d]^2)^2 - (d^x*x^2*Cos[x])/(1 + Log[d]^2) - (6*d^x*Log[d]*Sin[x])/(1 + Log[d]^2)^3 + (2*d^x*Log[d]^3*Sin[x])/(
1 + Log[d]^2)^3 + (2*d^x*x*Sin[x])/(1 + Log[d]^2)^2 - (2*d^x*x*Log[d]^2*Sin[x])/(1 + Log[d]^2)^2 + (d^x*x^2*Lo
g[d]*Sin[x])/(1 + Log[d]^2)
Rule 4432
Int[(F_)^((c_.)*((a_.) + (b_.)*(x_)))*Sin[(d_.) + (e_.)*(x_)], x_Symbol] :> Simp[(b*c*Log[F]*F^(c*(a + b*x))*S
in[d + e*x])/(e^2 + b^2*c^2*Log[F]^2), x] - Simp[(e*F^(c*(a + b*x))*Cos[d + e*x])/(e^2 + b^2*c^2*Log[F]^2), x]
/; FreeQ[{F, a, b, c, d, e}, x] && NeQ[e^2 + b^2*c^2*Log[F]^2, 0]
Rule 4465
Int[(F_)^((c_.)*((a_.) + (b_.)*(x_)))*((f_.)*(x_))^(m_.)*Sin[(d_.) + (e_.)*(x_)]^(n_.), x_Symbol] :> Module[{u
= IntHide[F^(c*(a + b*x))*Sin[d + e*x]^n, x]}, Dist[(f*x)^m, u, x] - Dist[f*m, Int[(f*x)^(m - 1)*u, x], x]] /
; FreeQ[{F, a, b, c, d, e, f}, x] && IGtQ[n, 0] && GtQ[m, 0]
Rule 14
Int[(u_)*((c_.)*(x_))^(m_.), x_Symbol] :> Int[ExpandIntegrand[(c*x)^m*u, x], x] /; FreeQ[{c, m}, x] && SumQ[u]
&& !LinearQ[u, x] && !MatchQ[u, (a_) + (b_.)*(v_) /; FreeQ[{a, b}, x] && InverseFunctionQ[v]]
Rule 4433
Int[Cos[(d_.) + (e_.)*(x_)]*(F_)^((c_.)*((a_.) + (b_.)*(x_))), x_Symbol] :> Simp[(b*c*Log[F]*F^(c*(a + b*x))*C
os[d + e*x])/(e^2 + b^2*c^2*Log[F]^2), x] + Simp[(e*F^(c*(a + b*x))*Sin[d + e*x])/(e^2 + b^2*c^2*Log[F]^2), x]
/; FreeQ[{F, a, b, c, d, e}, x] && NeQ[e^2 + b^2*c^2*Log[F]^2, 0]
Rule 4466
Int[Cos[(d_.) + (e_.)*(x_)]^(n_.)*(F_)^((c_.)*((a_.) + (b_.)*(x_)))*((f_.)*(x_))^(m_.), x_Symbol] :> Module[{u
= IntHide[F^(c*(a + b*x))*Cos[d + e*x]^n, x]}, Dist[(f*x)^m, u, x] - Dist[f*m, Int[(f*x)^(m - 1)*u, x], x]] /
; FreeQ[{F, a, b, c, d, e, f}, x] && IGtQ[n, 0] && GtQ[m, 0]
Rubi steps
\begin{align*} \int d^x x^2 \sin (x) \, dx &=-\frac{d^x x^2 \cos (x)}{1+\log ^2(d)}+\frac{d^x x^2 \log (d) \sin (x)}{1+\log ^2(d)}-2 \int x \left (-\frac{d^x \cos (x)}{1+\log ^2(d)}+\frac{d^x \log (d) \sin (x)}{1+\log ^2(d)}\right ) \, dx\\ &=-\frac{d^x x^2 \cos (x)}{1+\log ^2(d)}+\frac{d^x x^2 \log (d) \sin (x)}{1+\log ^2(d)}-2 \int \left (-\frac{d^x x \cos (x)}{1+\log ^2(d)}+\frac{d^x x \log (d) \sin (x)}{1+\log ^2(d)}\right ) \, dx\\ &=-\frac{d^x x^2 \cos (x)}{1+\log ^2(d)}+\frac{d^x x^2 \log (d) \sin (x)}{1+\log ^2(d)}+\frac{2 \int d^x x \cos (x) \, dx}{1+\log ^2(d)}-\frac{(2 \log (d)) \int d^x x \sin (x) \, dx}{1+\log ^2(d)}\\ &=\frac{4 d^x x \cos (x) \log (d)}{\left (1+\log ^2(d)\right )^2}-\frac{d^x x^2 \cos (x)}{1+\log ^2(d)}+\frac{2 d^x x \sin (x)}{\left (1+\log ^2(d)\right )^2}-\frac{2 d^x x \log ^2(d) \sin (x)}{\left (1+\log ^2(d)\right )^2}+\frac{d^x x^2 \log (d) \sin (x)}{1+\log ^2(d)}-\frac{2 \int \left (\frac{d^x \cos (x) \log (d)}{1+\log ^2(d)}+\frac{d^x \sin (x)}{1+\log ^2(d)}\right ) \, dx}{1+\log ^2(d)}+\frac{(2 \log (d)) \int \left (-\frac{d^x \cos (x)}{1+\log ^2(d)}+\frac{d^x \log (d) \sin (x)}{1+\log ^2(d)}\right ) \, dx}{1+\log ^2(d)}\\ &=\frac{4 d^x x \cos (x) \log (d)}{\left (1+\log ^2(d)\right )^2}-\frac{d^x x^2 \cos (x)}{1+\log ^2(d)}+\frac{2 d^x x \sin (x)}{\left (1+\log ^2(d)\right )^2}-\frac{2 d^x x \log ^2(d) \sin (x)}{\left (1+\log ^2(d)\right )^2}+\frac{d^x x^2 \log (d) \sin (x)}{1+\log ^2(d)}-\frac{2 \int d^x \sin (x) \, dx}{\left (1+\log ^2(d)\right )^2}-2 \frac{(2 \log (d)) \int d^x \cos (x) \, dx}{\left (1+\log ^2(d)\right )^2}+\frac{\left (2 \log ^2(d)\right ) \int d^x \sin (x) \, dx}{\left (1+\log ^2(d)\right )^2}\\ &=\frac{2 d^x \cos (x)}{\left (1+\log ^2(d)\right )^3}-\frac{2 d^x \cos (x) \log ^2(d)}{\left (1+\log ^2(d)\right )^3}+\frac{4 d^x x \cos (x) \log (d)}{\left (1+\log ^2(d)\right )^2}-\frac{d^x x^2 \cos (x)}{1+\log ^2(d)}-\frac{2 d^x \log (d) \sin (x)}{\left (1+\log ^2(d)\right )^3}+\frac{2 d^x \log ^3(d) \sin (x)}{\left (1+\log ^2(d)\right )^3}+\frac{2 d^x x \sin (x)}{\left (1+\log ^2(d)\right )^2}-\frac{2 d^x x \log ^2(d) \sin (x)}{\left (1+\log ^2(d)\right )^2}+\frac{d^x x^2 \log (d) \sin (x)}{1+\log ^2(d)}-2 \left (\frac{2 d^x \cos (x) \log ^2(d)}{\left (1+\log ^2(d)\right )^3}+\frac{2 d^x \log (d) \sin (x)}{\left (1+\log ^2(d)\right )^3}\right )\\ \end{align*}
Mathematica [A] time = 0.082667, size = 94, normalized size = 0.58 \[ \frac{d^x \left (\sin (x) \left (x^2 \log ^5(d)+2 \left (x^2+1\right ) \log ^3(d)+\left (x^2-6\right ) \log (d)-2 x \log ^4(d)+2 x\right )-\cos (x) \left (x^2 \log ^4(d)+2 \left (x^2+3\right ) \log ^2(d)-4 x \log ^3(d)-4 x \log (d)+x^2-2\right )\right )}{\left (\log ^2(d)+1\right )^3} \]
Antiderivative was successfully verified.
[In]
Integrate[d^x*x^2*Sin[x],x]
[Out]
(d^x*(-(Cos[x]*(-2 + x^2 - 4*x*Log[d] + 2*(3 + x^2)*Log[d]^2 - 4*x*Log[d]^3 + x^2*Log[d]^4)) + (2*x + (-6 + x^
2)*Log[d] + 2*(1 + x^2)*Log[d]^3 - 2*x*Log[d]^4 + x^2*Log[d]^5)*Sin[x]))/(1 + Log[d]^2)^3
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Maple [A] time = 0.032, size = 225, normalized size = 1.4 \begin{align*}{ \left ({\frac{{x}^{2}{{\rm e}^{x\ln \left ( d \right ) }}}{1+ \left ( \ln \left ( d \right ) \right ) ^{2}} \left ( \tan \left ({\frac{x}{2}} \right ) \right ) ^{2}}-{\frac{{x}^{2}{{\rm e}^{x\ln \left ( d \right ) }}}{1+ \left ( \ln \left ( d \right ) \right ) ^{2}}}-2\,{\frac{ \left ( 3\, \left ( \ln \left ( d \right ) \right ) ^{2}-1 \right ){{\rm e}^{x\ln \left ( d \right ) }}}{ \left ( 1+ \left ( \ln \left ( d \right ) \right ) ^{2} \right ) ^{3}}}+4\,{\frac{x\ln \left ( d \right ){{\rm e}^{x\ln \left ( d \right ) }}}{ \left ( 1+ \left ( \ln \left ( d \right ) \right ) ^{2} \right ) ^{2}}}+2\,{\frac{ \left ( 3\, \left ( \ln \left ( d \right ) \right ) ^{2}-1 \right ){{\rm e}^{x\ln \left ( d \right ) }} \left ( \tan \left ( x/2 \right ) \right ) ^{2}}{ \left ( 1+ \left ( \ln \left ( d \right ) \right ) ^{2} \right ) ^{3}}}-4\,{\frac{x\ln \left ( d \right ){{\rm e}^{x\ln \left ( d \right ) }} \left ( \tan \left ( x/2 \right ) \right ) ^{2}}{ \left ( 1+ \left ( \ln \left ( d \right ) \right ) ^{2} \right ) ^{2}}}+2\,{\frac{\ln \left ( d \right ){x}^{2}{{\rm e}^{x\ln \left ( d \right ) }}\tan \left ( x/2 \right ) }{1+ \left ( \ln \left ( d \right ) \right ) ^{2}}}-4\,{\frac{ \left ( \left ( \ln \left ( d \right ) \right ) ^{2}-1 \right ) x{{\rm e}^{x\ln \left ( d \right ) }}\tan \left ( x/2 \right ) }{ \left ( 1+ \left ( \ln \left ( d \right ) \right ) ^{2} \right ) ^{2}}}+4\,{\frac{\ln \left ( d \right ) \left ( \left ( \ln \left ( d \right ) \right ) ^{2}-3 \right ){{\rm e}^{x\ln \left ( d \right ) }}\tan \left ( x/2 \right ) }{ \left ( 1+ \left ( \ln \left ( d \right ) \right ) ^{2} \right ) ^{3}}} \right ) \left ( \left ( \tan \left ({\frac{x}{2}} \right ) \right ) ^{2}+1 \right ) ^{-1}} \end{align*}
Verification of antiderivative is not currently implemented for this CAS.
[In]
int(d^x*x^2*sin(x),x)
[Out]
(1/(1+ln(d)^2)*x^2*exp(x*ln(d))*tan(1/2*x)^2-1/(1+ln(d)^2)*x^2*exp(x*ln(d))-2*(3*ln(d)^2-1)/(1+ln(d)^2)^3*exp(
x*ln(d))+4/(1+ln(d)^2)^2*ln(d)*x*exp(x*ln(d))+2*(3*ln(d)^2-1)/(1+ln(d)^2)^3*exp(x*ln(d))*tan(1/2*x)^2-4/(1+ln(
d)^2)^2*ln(d)*x*exp(x*ln(d))*tan(1/2*x)^2+2/(1+ln(d)^2)*ln(d)*x^2*exp(x*ln(d))*tan(1/2*x)-4*(ln(d)^2-1)/(1+ln(
d)^2)^2*x*exp(x*ln(d))*tan(1/2*x)+4*ln(d)*(ln(d)^2-3)/(1+ln(d)^2)^3*exp(x*ln(d))*tan(1/2*x))/(tan(1/2*x)^2+1)
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Maxima [A] time = 1.01808, size = 144, normalized size = 0.89 \begin{align*} -\frac{{\left ({\left (\log \left (d\right )^{4} + 2 \, \log \left (d\right )^{2} + 1\right )} x^{2} - 4 \,{\left (\log \left (d\right )^{3} + \log \left (d\right )\right )} x + 6 \, \log \left (d\right )^{2} - 2\right )} d^{x} \cos \left (x\right ) -{\left ({\left (\log \left (d\right )^{5} + 2 \, \log \left (d\right )^{3} + \log \left (d\right )\right )} x^{2} + 2 \, \log \left (d\right )^{3} - 2 \,{\left (\log \left (d\right )^{4} - 1\right )} x - 6 \, \log \left (d\right )\right )} d^{x} \sin \left (x\right )}{\log \left (d\right )^{6} + 3 \, \log \left (d\right )^{4} + 3 \, \log \left (d\right )^{2} + 1} \end{align*}
Verification of antiderivative is not currently implemented for this CAS.
[In]
integrate(d^x*x^2*sin(x),x, algorithm="maxima")
[Out]
-(((log(d)^4 + 2*log(d)^2 + 1)*x^2 - 4*(log(d)^3 + log(d))*x + 6*log(d)^2 - 2)*d^x*cos(x) - ((log(d)^5 + 2*log
(d)^3 + log(d))*x^2 + 2*log(d)^3 - 2*(log(d)^4 - 1)*x - 6*log(d))*d^x*sin(x))/(log(d)^6 + 3*log(d)^4 + 3*log(d
)^2 + 1)
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Fricas [A] time = 1.84666, size = 333, normalized size = 2.06 \begin{align*} -\frac{{\left (x^{2} \cos \left (x\right ) \log \left (d\right )^{4} - 4 \, x \cos \left (x\right ) \log \left (d\right )^{3} + 2 \,{\left (x^{2} + 3\right )} \cos \left (x\right ) \log \left (d\right )^{2} - 4 \, x \cos \left (x\right ) \log \left (d\right ) +{\left (x^{2} - 2\right )} \cos \left (x\right ) -{\left (x^{2} \log \left (d\right )^{5} - 2 \, x \log \left (d\right )^{4} + 2 \,{\left (x^{2} + 1\right )} \log \left (d\right )^{3} +{\left (x^{2} - 6\right )} \log \left (d\right ) + 2 \, x\right )} \sin \left (x\right )\right )} d^{x}}{\log \left (d\right )^{6} + 3 \, \log \left (d\right )^{4} + 3 \, \log \left (d\right )^{2} + 1} \end{align*}
Verification of antiderivative is not currently implemented for this CAS.
[In]
integrate(d^x*x^2*sin(x),x, algorithm="fricas")
[Out]
-(x^2*cos(x)*log(d)^4 - 4*x*cos(x)*log(d)^3 + 2*(x^2 + 3)*cos(x)*log(d)^2 - 4*x*cos(x)*log(d) + (x^2 - 2)*cos(
x) - (x^2*log(d)^5 - 2*x*log(d)^4 + 2*(x^2 + 1)*log(d)^3 + (x^2 - 6)*log(d) + 2*x)*sin(x))*d^x/(log(d)^6 + 3*l
og(d)^4 + 3*log(d)^2 + 1)
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Sympy [B] time = 9.89357, size = 668, normalized size = 4.12 \begin{align*} \text{result too large to display} \end{align*}
Verification of antiderivative is not currently implemented for this CAS.
[In]
integrate(d**x*x**2*sin(x),x)
[Out]
Piecewise((x**3*exp(-I*x)*sin(x)/6 - I*x**3*exp(-I*x)*cos(x)/6 + I*x**2*exp(-I*x)*sin(x)/4 - x**2*exp(-I*x)*co
s(x)/4 + x*exp(-I*x)*sin(x)/4 + I*x*exp(-I*x)*cos(x)/4 - I*exp(-I*x)*sin(x)/4, Eq(d, exp(-I))), (x**3*exp(I*x)
*sin(x)/6 + I*x**3*exp(I*x)*cos(x)/6 - I*x**2*exp(I*x)*sin(x)/4 - x**2*exp(I*x)*cos(x)/4 + x*exp(I*x)*sin(x)/4
- I*x*exp(I*x)*cos(x)/4 + I*exp(I*x)*sin(x)/4, Eq(d, exp(I))), (d**x*x**2*log(d)**5*sin(x)/(log(d)**6 + 3*log
(d)**4 + 3*log(d)**2 + 1) - d**x*x**2*log(d)**4*cos(x)/(log(d)**6 + 3*log(d)**4 + 3*log(d)**2 + 1) + 2*d**x*x*
*2*log(d)**3*sin(x)/(log(d)**6 + 3*log(d)**4 + 3*log(d)**2 + 1) - 2*d**x*x**2*log(d)**2*cos(x)/(log(d)**6 + 3*
log(d)**4 + 3*log(d)**2 + 1) + d**x*x**2*log(d)*sin(x)/(log(d)**6 + 3*log(d)**4 + 3*log(d)**2 + 1) - d**x*x**2
*cos(x)/(log(d)**6 + 3*log(d)**4 + 3*log(d)**2 + 1) - 2*d**x*x*log(d)**4*sin(x)/(log(d)**6 + 3*log(d)**4 + 3*l
og(d)**2 + 1) + 4*d**x*x*log(d)**3*cos(x)/(log(d)**6 + 3*log(d)**4 + 3*log(d)**2 + 1) + 4*d**x*x*log(d)*cos(x)
/(log(d)**6 + 3*log(d)**4 + 3*log(d)**2 + 1) + 2*d**x*x*sin(x)/(log(d)**6 + 3*log(d)**4 + 3*log(d)**2 + 1) + 2
*d**x*log(d)**3*sin(x)/(log(d)**6 + 3*log(d)**4 + 3*log(d)**2 + 1) - 6*d**x*log(d)**2*cos(x)/(log(d)**6 + 3*lo
g(d)**4 + 3*log(d)**2 + 1) - 6*d**x*log(d)*sin(x)/(log(d)**6 + 3*log(d)**4 + 3*log(d)**2 + 1) + 2*d**x*cos(x)/
(log(d)**6 + 3*log(d)**4 + 3*log(d)**2 + 1), True))
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Giac [C] time = 1.24486, size = 3552, normalized size = 21.93 \begin{align*} \text{result too large to display} \end{align*}
Verification of antiderivative is not currently implemented for this CAS.
[In]
integrate(d^x*x^2*sin(x),x, algorithm="giac")
[Out]
-1/2*(((3*pi - pi^3*sgn(d) + 3*pi*log(abs(d))^2*sgn(d) + pi^3 - 3*pi*log(abs(d))^2 + 3*pi^2*sgn(d) - 3*pi^2 +
6*log(abs(d))^2 - 3*pi*sgn(d) - 2)*(pi^2*x^2*sgn(d) - pi^2*x^2 + 2*x^2*log(abs(d))^2 - 2*pi*x^2*sgn(d) + 2*pi*
x^2 - 2*x^2 - 4*x*log(abs(d)) + 4)/((3*pi - pi^3*sgn(d) + 3*pi*log(abs(d))^2*sgn(d) + pi^3 - 3*pi*log(abs(d))^
2 + 3*pi^2*sgn(d) - 3*pi^2 + 6*log(abs(d))^2 - 3*pi*sgn(d) - 2)^2 + (3*pi^2*log(abs(d))*sgn(d) - 3*pi^2*log(ab
s(d)) + 2*log(abs(d))^3 - 6*pi*log(abs(d))*sgn(d) + 6*pi*log(abs(d)) - 6*log(abs(d)))^2) - 2*(pi*x^2*log(abs(d
))*sgn(d) - pi*x^2*log(abs(d)) + 2*x^2*log(abs(d)) - pi*x*sgn(d) + pi*x - 2*x)*(3*pi^2*log(abs(d))*sgn(d) - 3*
pi^2*log(abs(d)) + 2*log(abs(d))^3 - 6*pi*log(abs(d))*sgn(d) + 6*pi*log(abs(d)) - 6*log(abs(d)))/((3*pi - pi^3
*sgn(d) + 3*pi*log(abs(d))^2*sgn(d) + pi^3 - 3*pi*log(abs(d))^2 + 3*pi^2*sgn(d) - 3*pi^2 + 6*log(abs(d))^2 - 3
*pi*sgn(d) - 2)^2 + (3*pi^2*log(abs(d))*sgn(d) - 3*pi^2*log(abs(d)) + 2*log(abs(d))^3 - 6*pi*log(abs(d))*sgn(d
) + 6*pi*log(abs(d)) - 6*log(abs(d)))^2))*cos(1/2*pi*x*sgn(d) - 1/2*pi*x + x) - (2*(3*pi - pi^3*sgn(d) + 3*pi*
log(abs(d))^2*sgn(d) + pi^3 - 3*pi*log(abs(d))^2 + 3*pi^2*sgn(d) - 3*pi^2 + 6*log(abs(d))^2 - 3*pi*sgn(d) - 2)
*(pi*x^2*log(abs(d))*sgn(d) - pi*x^2*log(abs(d)) + 2*x^2*log(abs(d)) - pi*x*sgn(d) + pi*x - 2*x)/((3*pi - pi^3
*sgn(d) + 3*pi*log(abs(d))^2*sgn(d) + pi^3 - 3*pi*log(abs(d))^2 + 3*pi^2*sgn(d) - 3*pi^2 + 6*log(abs(d))^2 - 3
*pi*sgn(d) - 2)^2 + (3*pi^2*log(abs(d))*sgn(d) - 3*pi^2*log(abs(d)) + 2*log(abs(d))^3 - 6*pi*log(abs(d))*sgn(d
) + 6*pi*log(abs(d)) - 6*log(abs(d)))^2) + (pi^2*x^2*sgn(d) - pi^2*x^2 + 2*x^2*log(abs(d))^2 - 2*pi*x^2*sgn(d)
+ 2*pi*x^2 - 2*x^2 - 4*x*log(abs(d)) + 4)*(3*pi^2*log(abs(d))*sgn(d) - 3*pi^2*log(abs(d)) + 2*log(abs(d))^3 -
6*pi*log(abs(d))*sgn(d) + 6*pi*log(abs(d)) - 6*log(abs(d)))/((3*pi - pi^3*sgn(d) + 3*pi*log(abs(d))^2*sgn(d)
+ pi^3 - 3*pi*log(abs(d))^2 + 3*pi^2*sgn(d) - 3*pi^2 + 6*log(abs(d))^2 - 3*pi*sgn(d) - 2)^2 + (3*pi^2*log(abs(
d))*sgn(d) - 3*pi^2*log(abs(d)) + 2*log(abs(d))^3 - 6*pi*log(abs(d))*sgn(d) + 6*pi*log(abs(d)) - 6*log(abs(d))
)^2))*sin(1/2*pi*x*sgn(d) - 1/2*pi*x + x))*abs(d)^x + 1/2*(((3*pi - pi^3*sgn(d) + 3*pi*log(abs(d))^2*sgn(d) +
pi^3 - 3*pi*log(abs(d))^2 - 3*pi^2*sgn(d) + 3*pi^2 - 6*log(abs(d))^2 - 3*pi*sgn(d) + 2)*(pi^2*x^2*sgn(d) - pi^
2*x^2 + 2*x^2*log(abs(d))^2 + 2*pi*x^2*sgn(d) - 2*pi*x^2 - 2*x^2 - 4*x*log(abs(d)) + 4)/((3*pi - pi^3*sgn(d) +
3*pi*log(abs(d))^2*sgn(d) + pi^3 - 3*pi*log(abs(d))^2 - 3*pi^2*sgn(d) + 3*pi^2 - 6*log(abs(d))^2 - 3*pi*sgn(d
) + 2)^2 + (3*pi^2*log(abs(d))*sgn(d) - 3*pi^2*log(abs(d)) + 2*log(abs(d))^3 + 6*pi*log(abs(d))*sgn(d) - 6*pi*
log(abs(d)) - 6*log(abs(d)))^2) - 2*(pi*x^2*log(abs(d))*sgn(d) - pi*x^2*log(abs(d)) - 2*x^2*log(abs(d)) - pi*x
*sgn(d) + pi*x + 2*x)*(3*pi^2*log(abs(d))*sgn(d) - 3*pi^2*log(abs(d)) + 2*log(abs(d))^3 + 6*pi*log(abs(d))*sgn
(d) - 6*pi*log(abs(d)) - 6*log(abs(d)))/((3*pi - pi^3*sgn(d) + 3*pi*log(abs(d))^2*sgn(d) + pi^3 - 3*pi*log(abs
(d))^2 - 3*pi^2*sgn(d) + 3*pi^2 - 6*log(abs(d))^2 - 3*pi*sgn(d) + 2)^2 + (3*pi^2*log(abs(d))*sgn(d) - 3*pi^2*l
og(abs(d)) + 2*log(abs(d))^3 + 6*pi*log(abs(d))*sgn(d) - 6*pi*log(abs(d)) - 6*log(abs(d)))^2))*cos(1/2*pi*x*sg
n(d) - 1/2*pi*x - x) - (2*(3*pi - pi^3*sgn(d) + 3*pi*log(abs(d))^2*sgn(d) + pi^3 - 3*pi*log(abs(d))^2 - 3*pi^2
*sgn(d) + 3*pi^2 - 6*log(abs(d))^2 - 3*pi*sgn(d) + 2)*(pi*x^2*log(abs(d))*sgn(d) - pi*x^2*log(abs(d)) - 2*x^2*
log(abs(d)) - pi*x*sgn(d) + pi*x + 2*x)/((3*pi - pi^3*sgn(d) + 3*pi*log(abs(d))^2*sgn(d) + pi^3 - 3*pi*log(abs
(d))^2 - 3*pi^2*sgn(d) + 3*pi^2 - 6*log(abs(d))^2 - 3*pi*sgn(d) + 2)^2 + (3*pi^2*log(abs(d))*sgn(d) - 3*pi^2*l
og(abs(d)) + 2*log(abs(d))^3 + 6*pi*log(abs(d))*sgn(d) - 6*pi*log(abs(d)) - 6*log(abs(d)))^2) + (pi^2*x^2*sgn(
d) - pi^2*x^2 + 2*x^2*log(abs(d))^2 + 2*pi*x^2*sgn(d) - 2*pi*x^2 - 2*x^2 - 4*x*log(abs(d)) + 4)*(3*pi^2*log(ab
s(d))*sgn(d) - 3*pi^2*log(abs(d)) + 2*log(abs(d))^3 + 6*pi*log(abs(d))*sgn(d) - 6*pi*log(abs(d)) - 6*log(abs(d
)))/((3*pi - pi^3*sgn(d) + 3*pi*log(abs(d))^2*sgn(d) + pi^3 - 3*pi*log(abs(d))^2 - 3*pi^2*sgn(d) + 3*pi^2 - 6*
log(abs(d))^2 - 3*pi*sgn(d) + 2)^2 + (3*pi^2*log(abs(d))*sgn(d) - 3*pi^2*log(abs(d)) + 2*log(abs(d))^3 + 6*pi*
log(abs(d))*sgn(d) - 6*pi*log(abs(d)) - 6*log(abs(d)))^2))*sin(1/2*pi*x*sgn(d) - 1/2*pi*x - x))*abs(d)^x + 1/2
*abs(d)^x*((4*I*pi^2*x^2*sgn(d) - 8*pi*x^2*log(abs(d))*sgn(d) - 4*I*pi^2*x^2 + 8*pi*x^2*log(abs(d)) + 8*I*x^2*
log(abs(d))^2 - 8*I*pi*x^2*sgn(d) + 8*I*pi*x^2 - 16*x^2*log(abs(d)) + 8*pi*x*sgn(d) - 8*pi*x - 8*I*x^2 - 16*I*
x*log(abs(d)) + 16*x + 16*I)*e^(1/2*I*pi*x*sgn(d) - 1/2*I*pi*x + I*x)/(24*I*pi - 8*I*pi^3*sgn(d) + 24*pi^2*log
(abs(d))*sgn(d) + 24*I*pi*log(abs(d))^2*sgn(d) + 8*I*pi^3 - 24*pi^2*log(abs(d)) - 24*I*pi*log(abs(d))^2 + 16*l
og(abs(d))^3 + 24*I*pi^2*sgn(d) - 48*pi*log(abs(d))*sgn(d) - 24*I*pi^2 + 48*pi*log(abs(d)) + 48*I*log(abs(d))^
2 - 24*I*pi*sgn(d) - 48*log(abs(d)) - 16*I) + (4*I*pi^2*x^2*sgn(d) + 8*pi*x^2*log(abs(d))*sgn(d) - 4*I*pi^2*x^
2 - 8*pi*x^2*log(abs(d)) + 8*I*x^2*log(abs(d))^2 - 8*I*pi*x^2*sgn(d) + 8*I*pi*x^2 + 16*x^2*log(abs(d)) - 8*pi*
x*sgn(d) + 8*pi*x - 8*I*x^2 - 16*I*x*log(abs(d)) - 16*x + 16*I)*e^(-1/2*I*pi*x*sgn(d) + 1/2*I*pi*x - I*x)/(-24
*I*pi + 8*I*pi^3*sgn(d) + 24*pi^2*log(abs(d))*sgn(d) - 24*I*pi*log(abs(d))^2*sgn(d) - 8*I*pi^3 - 24*pi^2*log(a
bs(d)) + 24*I*pi*log(abs(d))^2 + 16*log(abs(d))^3 - 24*I*pi^2*sgn(d) - 48*pi*log(abs(d))*sgn(d) + 24*I*pi^2 +
48*pi*log(abs(d)) - 48*I*log(abs(d))^2 + 24*I*pi*sgn(d) - 48*log(abs(d)) + 16*I)) + 1/2*abs(d)^x*((-4*I*pi^2*x
^2*sgn(d) + 8*pi*x^2*log(abs(d))*sgn(d) + 4*I*pi^2*x^2 - 8*pi*x^2*log(abs(d)) - 8*I*x^2*log(abs(d))^2 - 8*I*pi
*x^2*sgn(d) + 8*I*pi*x^2 - 16*x^2*log(abs(d)) - 8*pi*x*sgn(d) + 8*pi*x + 8*I*x^2 + 16*I*x*log(abs(d)) + 16*x -
16*I)*e^(1/2*I*pi*x*sgn(d) - 1/2*I*pi*x - I*x)/(24*I*pi - 8*I*pi^3*sgn(d) + 24*pi^2*log(abs(d))*sgn(d) + 24*I
*pi*log(abs(d))^2*sgn(d) + 8*I*pi^3 - 24*pi^2*log(abs(d)) - 24*I*pi*log(abs(d))^2 + 16*log(abs(d))^3 - 24*I*pi
^2*sgn(d) + 48*pi*log(abs(d))*sgn(d) + 24*I*pi^2 - 48*pi*log(abs(d)) - 48*I*log(abs(d))^2 - 24*I*pi*sgn(d) - 4
8*log(abs(d)) + 16*I) + (-4*I*pi^2*x^2*sgn(d) - 8*pi*x^2*log(abs(d))*sgn(d) + 4*I*pi^2*x^2 + 8*pi*x^2*log(abs(
d)) - 8*I*x^2*log(abs(d))^2 - 8*I*pi*x^2*sgn(d) + 8*I*pi*x^2 + 16*x^2*log(abs(d)) + 8*pi*x*sgn(d) - 8*pi*x + 8
*I*x^2 + 16*I*x*log(abs(d)) - 16*x - 16*I)*e^(-1/2*I*pi*x*sgn(d) + 1/2*I*pi*x + I*x)/(-24*I*pi + 8*I*pi^3*sgn(
d) + 24*pi^2*log(abs(d))*sgn(d) - 24*I*pi*log(abs(d))^2*sgn(d) - 8*I*pi^3 - 24*pi^2*log(abs(d)) + 24*I*pi*log(
abs(d))^2 + 16*log(abs(d))^3 + 24*I*pi^2*sgn(d) + 48*pi*log(abs(d))*sgn(d) - 24*I*pi^2 - 48*pi*log(abs(d)) + 4
8*I*log(abs(d))^2 + 24*I*pi*sgn(d) - 48*log(abs(d)) - 16*I))