\(\int \frac {(d \csc (a+b x))^{9/2}}{(c \sec (a+b x))^{3/2}} \, dx\) [263]

Optimal result

Integrand size = 25, antiderivative size = 135 \[ \int \frac {(d \csc (a+b x))^{9/2}}{(c \sec (a+b x))^{3/2}} \, dx=\frac {2 d^3 (d \csc (a+b x))^{3/2}}{21 b c \sqrt {c \sec (a+b x)}}-\frac {2 d (d \csc (a+b x))^{7/2}}{7 b c \sqrt {c \sec (a+b x)}}-\frac {2 d^4 \sqrt {d \csc (a+b x)} \operatorname {EllipticF}\left (a-\frac {\pi }{4}+b x,2\right ) \sqrt {c \sec (a+b x)} \sqrt {\sin (2 a+2 b x)}}{21 b c^2} \] Output:

2/21*d^3*(d*csc(b*x+a))^(3/2)/b/c/(c*sec(b*x+a))^(1/2)-2/7*d*(d*csc(b*x+a) 
)^(7/2)/b/c/(c*sec(b*x+a))^(1/2)-2/21*d^4*(d*csc(b*x+a))^(1/2)*InverseJaco 
biAM(a-1/4*Pi+b*x,2^(1/2))*(c*sec(b*x+a))^(1/2)*sin(2*b*x+2*a)^(1/2)/b/c^2
 

Mathematica [C] (verified)

Result contains higher order function than in optimal. Order 5 vs. order 4 in optimal.

Time = 1.55 (sec) , antiderivative size = 119, normalized size of antiderivative = 0.88 \[ \int \frac {(d \csc (a+b x))^{9/2}}{(c \sec (a+b x))^{3/2}} \, dx=-\frac {d^3 \cos (2 (a+b x)) (d \csc (a+b x))^{3/2} \left ((5+\cos (2 (a+b x))) \csc ^4(a+b x)-2 \left (-\cot ^2(a+b x)\right )^{3/4} \operatorname {Hypergeometric2F1}\left (\frac {1}{2},\frac {3}{4},\frac {3}{2},\csc ^2(a+b x)\right ) \sec ^2(a+b x)\right )}{21 b c \left (-2+\csc ^2(a+b x)\right ) \sqrt {c \sec (a+b x)}} \] Input:

Integrate[(d*Csc[a + b*x])^(9/2)/(c*Sec[a + b*x])^(3/2),x]
 

Output:

-1/21*(d^3*Cos[2*(a + b*x)]*(d*Csc[a + b*x])^(3/2)*((5 + Cos[2*(a + b*x)]) 
*Csc[a + b*x]^4 - 2*(-Cot[a + b*x]^2)^(3/4)*Hypergeometric2F1[1/2, 3/4, 3/ 
2, Csc[a + b*x]^2]*Sec[a + b*x]^2))/(b*c*(-2 + Csc[a + b*x]^2)*Sqrt[c*Sec[ 
a + b*x]])
 

Rubi [A] (verified)

Time = 0.69 (sec) , antiderivative size = 139, normalized size of antiderivative = 1.03, number of steps used = 10, number of rules used = 10, \(\frac {\text {number of rules}}{\text {integrand size}}\) = 0.400, Rules used = {3042, 3103, 3042, 3105, 3042, 3110, 3042, 3053, 3042, 3120}

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.

Input:

Int[(d*Csc[a + b*x])^(9/2)/(c*Sec[a + b*x])^(3/2),x]
 

Output:

(-2*d*(d*Csc[a + b*x])^(7/2))/(7*b*c*Sqrt[c*Sec[a + b*x]]) - (d^2*((-2*c*d 
*(d*Csc[a + b*x])^(3/2))/(3*b*Sqrt[c*Sec[a + b*x]]) + (2*d^2*Sqrt[d*Csc[a 
+ b*x]]*EllipticF[a - Pi/4 + b*x, 2]*Sqrt[c*Sec[a + b*x]]*Sqrt[Sin[2*a + 2 
*b*x]])/(3*b)))/(7*c^2)
 

Defintions of rubi rules used

Int[u_, x_Symbol] :> Int[DeactivateTrig[u, x], x] /; FunctionOfTrigOfLinear 
Q[u, x]
 

Int[1/(Sqrt[cos[(e_.) + (f_.)*(x_)]*(b_.)]*Sqrt[(a_.)*sin[(e_.) + (f_.)*(x_ 
)]]), x_Symbol] :> Simp[Sqrt[Sin[2*e + 2*f*x]]/(Sqrt[a*Sin[e + f*x]]*Sqrt[b 
*Cos[e + f*x]])   Int[1/Sqrt[Sin[2*e + 2*f*x]], x], x] /; FreeQ[{a, b, e, f 
}, x]
 

Int[(csc[(e_.) + (f_.)*(x_)]*(a_.))^(m_)*((b_.)*sec[(e_.) + (f_.)*(x_)])^(n 
_), x_Symbol] :> Simp[(-a)*(a*Csc[e + f*x])^(m - 1)*((b*Sec[e + f*x])^(n + 
1)/(f*b*(m - 1))), x] + Simp[a^2*((n + 1)/(b^2*(m - 1)))   Int[(a*Csc[e + f 
*x])^(m - 2)*(b*Sec[e + f*x])^(n + 2), x], x] /; FreeQ[{a, b, e, f}, x] && 
GtQ[m, 1] && LtQ[n, -1] && IntegersQ[2*m, 2*n]
 

Int[(csc[(e_.) + (f_.)*(x_)]*(a_.))^(m_)*((b_.)*sec[(e_.) + (f_.)*(x_)])^(n 
_.), x_Symbol] :> Simp[(-a)*b*(a*Csc[e + f*x])^(m - 1)*((b*Sec[e + f*x])^(n 
 - 1)/(f*(m - 1))), x] + Simp[a^2*((m + n - 2)/(m - 1))   Int[(a*Csc[e + f* 
x])^(m - 2)*(b*Sec[e + f*x])^n, x], x] /; FreeQ[{a, b, e, f, n}, x] && GtQ[ 
m, 1] && IntegersQ[2*m, 2*n] &&  !GtQ[n, m]
 

Int[(csc[(e_.) + (f_.)*(x_)]*(a_.))^(m_)*((b_.)*sec[(e_.) + (f_.)*(x_)])^(n 
_), x_Symbol] :> Simp[(a*Csc[e + f*x])^m*(b*Sec[e + f*x])^n*(a*Sin[e + f*x] 
)^m*(b*Cos[e + f*x])^n   Int[1/((a*Sin[e + f*x])^m*(b*Cos[e + f*x])^n), x], 
 x] /; FreeQ[{a, b, e, f, m, n}, x] && IntegerQ[m - 1/2] && IntegerQ[n - 1/ 
2]
 

Int[1/Sqrt[sin[(c_.) + (d_.)*(x_)]], x_Symbol] :> Simp[(2/d)*EllipticF[(1/2 
)*(c - Pi/2 + d*x), 2], x] /; FreeQ[{c, d}, x]
 

Maple [A] (verified)

Time = 2.65 (sec) , antiderivative size = 145, normalized size of antiderivative = 1.07

Input:

int((d*csc(b*x+a))^(9/2)/(c*sec(b*x+a))^(3/2),x,method=_RETURNVERBOSE)
 

Output:

1/b*(2/21*(-cot(b*x+a)+csc(b*x+a)+1)^(1/2)*(2*cot(b*x+a)-2*csc(b*x+a)+2)^( 
1/2)*(cot(b*x+a)-csc(b*x+a))^(1/2)*EllipticF((-cot(b*x+a)+csc(b*x+a)+1)^(1 
/2),1/2*2^(1/2))*(-1-sec(b*x+a))+2/21*(-cos(b*x+a)^2-2)*csc(b*x+a)^3)*(d*c 
sc(b*x+a))^(1/2)*d^4/(c*sec(b*x+a))^(1/2)/c
 

Fricas [C] (verification not implemented)

Result contains complex when optimal does not.

Time = 0.10 (sec) , antiderivative size = 183, normalized size of antiderivative = 1.36 \[ \int \frac {(d \csc (a+b x))^{9/2}}{(c \sec (a+b x))^{3/2}} \, dx=\frac {{\left (i \, d^{4} \cos \left (b x + a\right )^{2} - i \, d^{4}\right )} \sqrt {-4 i \, c d} F(\arcsin \left (\cos \left (b x + a\right ) + i \, \sin \left (b x + a\right )\right )\,|\,-1) \sin \left (b x + a\right ) + {\left (-i \, d^{4} \cos \left (b x + a\right )^{2} + i \, d^{4}\right )} \sqrt {4 i \, c d} F(\arcsin \left (\cos \left (b x + a\right ) - i \, \sin \left (b x + a\right )\right )\,|\,-1) \sin \left (b x + a\right ) + 2 \, {\left (d^{4} \cos \left (b x + a\right )^{3} + 2 \, d^{4} \cos \left (b x + a\right )\right )} \sqrt {\frac {c}{\cos \left (b x + a\right )}} \sqrt {\frac {d}{\sin \left (b x + a\right )}}}{21 \, {\left (b c^{2} \cos \left (b x + a\right )^{2} - b c^{2}\right )} \sin \left (b x + a\right )} \] Input:

integrate((d*csc(b*x+a))^(9/2)/(c*sec(b*x+a))^(3/2),x, algorithm="fricas")
 

Output:

1/21*((I*d^4*cos(b*x + a)^2 - I*d^4)*sqrt(-4*I*c*d)*elliptic_f(arcsin(cos( 
b*x + a) + I*sin(b*x + a)), -1)*sin(b*x + a) + (-I*d^4*cos(b*x + a)^2 + I* 
d^4)*sqrt(4*I*c*d)*elliptic_f(arcsin(cos(b*x + a) - I*sin(b*x + a)), -1)*s 
in(b*x + a) + 2*(d^4*cos(b*x + a)^3 + 2*d^4*cos(b*x + a))*sqrt(c/cos(b*x + 
 a))*sqrt(d/sin(b*x + a)))/((b*c^2*cos(b*x + a)^2 - b*c^2)*sin(b*x + a))
 

Sympy [F(-1)]

Timed out. \[ \int \frac {(d \csc (a+b x))^{9/2}}{(c \sec (a+b x))^{3/2}} \, dx=\text {Timed out} \] Input:

integrate((d*csc(b*x+a))**(9/2)/(c*sec(b*x+a))**(3/2),x)
 

Output:

Timed out
 

Maxima [F]

\[ \int \frac {(d \csc (a+b x))^{9/2}}{(c \sec (a+b x))^{3/2}} \, dx=\int { \frac {\left (d \csc \left (b x + a\right )\right )^{\frac {9}{2}}}{\left (c \sec \left (b x + a\right )\right )^{\frac {3}{2}}} \,d x } \] Input:

integrate((d*csc(b*x+a))^(9/2)/(c*sec(b*x+a))^(3/2),x, algorithm="maxima")
 

Output:

integrate((d*csc(b*x + a))^(9/2)/(c*sec(b*x + a))^(3/2), x)
 

Giac [F]

\[ \int \frac {(d \csc (a+b x))^{9/2}}{(c \sec (a+b x))^{3/2}} \, dx=\int { \frac {\left (d \csc \left (b x + a\right )\right )^{\frac {9}{2}}}{\left (c \sec \left (b x + a\right )\right )^{\frac {3}{2}}} \,d x } \] Input:

integrate((d*csc(b*x+a))^(9/2)/(c*sec(b*x+a))^(3/2),x, algorithm="giac")
 

Output:

integrate((d*csc(b*x + a))^(9/2)/(c*sec(b*x + a))^(3/2), x)
 

Mupad [F(-1)]

Timed out. \[ \int \frac {(d \csc (a+b x))^{9/2}}{(c \sec (a+b x))^{3/2}} \, dx=\int \frac {{\left (\frac {d}{\sin \left (a+b\,x\right )}\right )}^{9/2}}{{\left (\frac {c}{\cos \left (a+b\,x\right )}\right )}^{3/2}} \,d x \] Input:

int((d/sin(a + b*x))^(9/2)/(c/cos(a + b*x))^(3/2),x)
 

Output:

int((d/sin(a + b*x))^(9/2)/(c/cos(a + b*x))^(3/2), x)
                                                                                    
                                                                                    
 

Reduce [F]

\[ \int \frac {(d \csc (a+b x))^{9/2}}{(c \sec (a+b x))^{3/2}} \, dx=\frac {\sqrt {d}\, \sqrt {c}\, \left (\int \frac {\sqrt {\sec \left (b x +a \right )}\, \sqrt {\csc \left (b x +a \right )}\, \csc \left (b x +a \right )^{4}}{\sec \left (b x +a \right )^{2}}d x \right ) d^{4}}{c^{2}} \] Input:

int((d*csc(b*x+a))^(9/2)/(c*sec(b*x+a))^(3/2),x)
 

Output:

(sqrt(d)*sqrt(c)*int((sqrt(sec(a + b*x))*sqrt(csc(a + b*x))*csc(a + b*x)** 
4)/sec(a + b*x)**2,x)*d**4)/c**2