### 94 HFOPDE, chapter 3.8.4

94.1 Problem 1
94.2 Problem 2
94.3 Problem 3
94.4 Problem 4
94.5 Problem 5
94.6 Problem 6
94.7 Problem 7

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#### 94.1 Problem 1

problem number 806

Problem Chapter 3.8.4.1 from Handbook of ﬁrst order partial diﬀerential equations by Polyanin, Zaitsev, Moussiaux.

Solve for $$w(x,y)$$

$w_x + a w_y = f(x,y)$

Mathematica

$\left \{\left \{w(x,y)\to \int _1^x f(K[1],a K[1]-a x+y) \, dK[1]+c_1(y-a x)\right \}\right \}$

Maple

$w \left ( x,y \right ) =\int ^{x}\!f \left ({\it \_a},{\it \_a}\,a-ax+y \right ){d{\it \_a}}+{\it \_F1} \left ( -ax+y \right )$

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#### 94.2 Problem 2

problem number 807

Problem Chapter 3.8.4.2 from Handbook of ﬁrst order partial diﬀerential equations by Polyanin, Zaitsev, Moussiaux.

Solve for $$w(x,y)$$

$a x w_x + b y w_y = f(x,y)$

Mathematica

$\left \{\left \{w(x,y)\to \int _1^x \frac{f\left (K[1],y x^{-\frac{b}{a}} K[1]^{\frac{b}{a}}\right )}{a K[1]} \, dK[1]+c_1\left (y x^{-\frac{b}{a}}\right )\right \}\right \}$

Maple

$w \left ( x,y \right ) =\int ^{x}\!{\frac{1}{{\it \_a}\,a}f \left ({\it \_a},y{x}^{-{\frac{b}{a}}}{{\it \_a}}^{{\frac{b}{a}}} \right ) }{d{\it \_a}}+{\it \_F1} \left ( y{x}^{-{\frac{b}{a}}} \right )$

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#### 94.3 Problem 3

problem number 808

Problem Chapter 3.8.4.3 from Handbook of ﬁrst order partial diﬀerential equations by Polyanin, Zaitsev, Moussiaux.

Solve for $$w(x,y)$$

$f(x) w_x + g(x) y w_y = h(x,y)$

Mathematica

$\left \{\left \{w(x,y)\to \int _1^x \frac{h\left (K[2],y \exp \left (\text{Integrate}\left [\frac{g(K[1])}{f(K[1])},\{K[1],1,K[2]\},\text{Assumptions}\to \text{True}\right ]-\text{Integrate}\left [\frac{g(K[1])}{f(K[1])},\{K[1],1,x\},\text{Assumptions}\to \text{True}\right ]\right )\right )}{f(K[2])} \, dK[2]+c_1\left (y e^{-\int _1^x \frac{g(K[1])}{f(K[1])} \, dK[1]}\right )\right \}\right \}$

Maple

$w \left ( x,y \right ) =\int ^{x}\!{\frac{1}{f \left ({\it \_b} \right ) }h \left ({\it \_b},y{{\rm e}^{-\int \!{\frac{g \left ( x \right ) }{f \left ( x \right ) }}\,{\rm d}x+\int \!{\frac{g \left ({\it \_b} \right ) }{f \left ({\it \_b} \right ) }}\,{\rm d}{\it \_b}}} \right ) }{d{\it \_b}}+{\it \_F1} \left ( y{{\rm e}^{-\int \!{\frac{g \left ( x \right ) }{f \left ( x \right ) }}\,{\rm d}x}} \right )$

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#### 94.4 Problem 4

problem number 809

Problem Chapter 3.8.4.4 from Handbook of ﬁrst order partial diﬀerential equations by Polyanin, Zaitsev, Moussiaux.

Solve for $$w(x,y)$$

$f(x) w_x + (g_1(x) y+ g_0(x)) w_y = h(x,y)$

Mathematica

$\left \{\left \{w(x,y)\to c_1\left (-e^{-\int _1^x \frac{\text{g1}(K[1])}{f(K[1])} \, dK[1]} \left (e^{\int _1^x \frac{\text{g1}(K[1])}{f(K[1])} \, dK[1]} \int _1^x \frac{\text{g0}(K[2]) \exp \left (-\text{Integrate}\left [\frac{\text{g1}(K[1])}{f(K[1])},\{K[1],1,K[2]\},\text{Assumptions}\to \text{True}\right ]\right )}{f(K[2])} \, dK[2]-y\right )\right )+\int _1^x \frac{h\left (K[3],\exp \left (\text{Integrate}\left [\frac{\text{g1}(K[1])}{f(K[1])},\{K[1],1,K[3]\},\text{Assumptions}\to \text{True}\right ]\right ) \left (\text{Integrate}\left [\frac{\text{g0}(K[2]) \exp \left (-\text{Integrate}\left [\frac{\text{g1}(K[1])}{f(K[1])},\{K[1],1,K[2]\},\text{Assumptions}\to \text{True}\right ]\right )}{f(K[2])},\{K[2],1,K[3]\},\text{Assumptions}\to \text{True}\right ]-\exp \left (-\text{Integrate}\left [\frac{\text{g1}(K[1])}{f(K[1])},\{K[1],1,x\},\text{Assumptions}\to \text{True}\right ]\right ) \left (\exp \left (\text{Integrate}\left [\frac{\text{g1}(K[1])}{f(K[1])},\{K[1],1,x\},\text{Assumptions}\to \text{True}\right ]\right ) \text{Integrate}\left [\frac{\text{g0}(K[2]) \exp \left (-\text{Integrate}\left [\frac{\text{g1}(K[1])}{f(K[1])},\{K[1],1,K[2]\},\text{Assumptions}\to \text{True}\right ]\right )}{f(K[2])},\{K[2],1,x\},\text{Assumptions}\to \text{True}\right ]-y\right )\right )\right )}{f(K[3])} \, dK[3]\right \}\right \}$

Maple

$w \left ( x,y \right ) =\int ^{x}\!{\frac{1}{f \left ({\it \_f} \right ) }h \left ({\it \_f}, \left ( \int \!{\frac{{\it g0} \left ({\it \_f} \right ) }{f \left ({\it \_f} \right ) }{{\rm e}^{-\int \!{\frac{{\it g1} \left ({\it \_f} \right ) }{f \left ({\it \_f} \right ) }}\,{\rm d}{\it \_f}}}}\,{\rm d}{\it \_f}-\int \!{\frac{{\it g0} \left ( x \right ) }{f \left ( x \right ) }{{\rm e}^{-\int \!{\frac{{\it g1} \left ( x \right ) }{f \left ( x \right ) }}\,{\rm d}x}}}\,{\rm d}x+y{{\rm e}^{-\int \!{\frac{{\it g1} \left ( x \right ) }{f \left ( x \right ) }}\,{\rm d}x}} \right ){{\rm e}^{\int \!{\frac{{\it g1} \left ({\it \_f} \right ) }{f \left ({\it \_f} \right ) }}\,{\rm d}{\it \_f}}} \right ) }{d{\it \_f}}+{\it \_F1} \left ( -\int \!{\frac{{\it g0} \left ( x \right ) }{f \left ( x \right ) }{{\rm e}^{-\int \!{\frac{{\it g1} \left ( x \right ) }{f \left ( x \right ) }}\,{\rm d}x}}}\,{\rm d}x+y{{\rm e}^{-\int \!{\frac{{\it g1} \left ( x \right ) }{f \left ( x \right ) }}\,{\rm d}x}} \right )$

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#### 94.5 Problem 5

problem number 810

Problem Chapter 3.8.4.5 from Handbook of ﬁrst order partial diﬀerential equations by Polyanin, Zaitsev, Moussiaux.

Solve for $$w(x,y)$$

$f(x) w_x + (g_1(x) y+ g_0(x) y^k) w_y = h(x,y)$

Mathematica

$\left \{\left \{w(x,y)\to c_1\left ((k-1) \int _1^x \frac{\text{g0}(K[2]) \exp \left ((k-1) \text{Integrate}\left [\frac{\text{g1}(K[1])}{f(K[1])},\{K[1],1,K[2]\},\text{Assumptions}\to \text{True}\right ]\right )}{f(K[2])} \, dK[2]+y^{1-k} \exp \left ((k-1) \int _1^x \frac{\text{g1}(K[1])}{f(K[1])} \, dK[1]\right )\right )+\int _1^x \frac{h\left (K[3],\left (y^{-k} \exp \left (-(k-1) \text{Integrate}\left [\frac{\text{g1}(K[1])}{f(K[1])},\{K[1],1,K[3]\},\text{Assumptions}\to \text{True}\right ]\right ) \left ((k-1) y^k \text{Integrate}\left [\frac{\text{g0}(K[2]) \exp \left ((k-1) \text{Integrate}\left [\frac{\text{g1}(K[1])}{f(K[1])},\{K[1],1,K[2]\},\text{Assumptions}\to \text{True}\right ]\right )}{f(K[2])},\{K[2],1,x\},\text{Assumptions}\to \text{True}\right ]-(k-1) y^k \text{Integrate}\left [\frac{\text{g0}(K[2]) \exp \left ((k-1) \text{Integrate}\left [\frac{\text{g1}(K[1])}{f(K[1])},\{K[1],1,K[2]\},\text{Assumptions}\to \text{True}\right ]\right )}{f(K[2])},\{K[2],1,K[3]\},\text{Assumptions}\to \text{True}\right ]+y \exp \left ((k-1) \text{Integrate}\left [\frac{\text{g1}(K[1])}{f(K[1])},\{K[1],1,x\},\text{Assumptions}\to \text{True}\right ]\right )\right )\right )^{\frac{1}{1-k}}\right )}{f(K[3])} \, dK[3]\right \}\right \}$

Maple

$w \left ( x,y \right ) =\int ^{x}\!{\frac{1}{f \left ({\it \_f} \right ) }h \left ({\it \_f}, \left ( \left ( -k+1 \right ) \int \!{\frac{{\it g0} \left ({\it \_f} \right ) }{f \left ({\it \_f} \right ) }{{\rm e}^{ \left ( k-1 \right ) \int \!{\frac{{\it g1} \left ({\it \_f} \right ) }{f \left ({\it \_f} \right ) }}\,{\rm d}{\it \_f}}}}\,{\rm d}{\it \_f}+ \left ( k-1 \right ) \int \!{\frac{{\it g0} \left ( x \right ) }{f \left ( x \right ) }{{\rm e}^{ \left ( k-1 \right ) \int \!{\frac{{\it g1} \left ( x \right ) }{f \left ( x \right ) }}\,{\rm d}x}}}\,{\rm d}x+{y}^{-k+1}{{\rm e}^{ \left ( k-1 \right ) \int \!{\frac{{\it g1} \left ( x \right ) }{f \left ( x \right ) }}\,{\rm d}x}} \right ) ^{- \left ( k-1 \right ) ^{-1}}{{\rm e}^{\int \!{\frac{{\it g1} \left ({\it \_f} \right ) }{f \left ({\it \_f} \right ) }}\,{\rm d}{\it \_f}}} \right ) }{d{\it \_f}}+{\it \_F1} \left ( \left ( k-1 \right ) \int \!{\frac{{\it g0} \left ( x \right ) }{f \left ( x \right ) }{{\rm e}^{ \left ( k-1 \right ) \int \!{\frac{{\it g1} \left ( x \right ) }{f \left ( x \right ) }}\,{\rm d}x}}}\,{\rm d}x+{y}^{-k+1}{{\rm e}^{ \left ( k-1 \right ) \int \!{\frac{{\it g1} \left ( x \right ) }{f \left ( x \right ) }}\,{\rm d}x}} \right )$

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#### 94.6 Problem 6

problem number 811

Problem Chapter 3.8.4.6 from Handbook of ﬁrst order partial diﬀerential equations by Polyanin, Zaitsev, Moussiaux.

Solve for $$w(x,y)$$

$f(x) w_x + (g_1(x)+ g_0(x) e^{\lambda y}) w_y = h(x,y)$

Mathematica

$\text{DSolve}\left [f(x) w^{(1,0)}(x,y)+w^{(0,1)}(x,y) \left (\text{g0}(x) e^{\lambda y}+\text{g1}(x)\right )=h(x,y),w(x,y),\{x,y\}\right ]$

Maple

$w \left ( x,y \right ) =\int ^{x}\!{\frac{1}{f \left ({\it \_f} \right ) }h \left ({\it \_f},{\frac{1}{\lambda } \left ( \ln \left ( -{\frac{1}{\lambda } \left ( -{\frac{1}{\lambda } \left ( \lambda \,\int \!{\frac{{\it g0} \left ( x \right ) }{f \left ( x \right ) }{{\rm e}^{\lambda \,\int \!{\frac{{\it g1} \left ( x \right ) }{f \left ( x \right ) }}\,{\rm d}x}}}\,{\rm d}x+{{\rm e}^{-\lambda \, \left ( y-\int \!{\frac{{\it g1} \left ( x \right ) }{f \left ( x \right ) }}\,{\rm d}x \right ) }} \right ) }+\int \!{\frac{{\it g0} \left ({\it \_f} \right ) }{f \left ({\it \_f} \right ) }{{\rm e}^{\lambda \,\int \!{\frac{{\it g1} \left ({\it \_f} \right ) }{f \left ({\it \_f} \right ) }}\,{\rm d}{\it \_f}}}}\,{\rm d}{\it \_f} \right ) ^{-1}} \right ) +\lambda \,\int \!{\frac{{\it g1} \left ({\it \_f} \right ) }{f \left ({\it \_f} \right ) }}\,{\rm d}{\it \_f} \right ) } \right ) }{d{\it \_f}}+{\it \_F1} \left ( -{\frac{1}{\lambda } \left ( \lambda \,\int \!{\frac{{\it g0} \left ( x \right ) }{f \left ( x \right ) }{{\rm e}^{\lambda \,\int \!{\frac{{\it g1} \left ( x \right ) }{f \left ( x \right ) }}\,{\rm d}x}}}\,{\rm d}x+{{\rm e}^{-\lambda \, \left ( y-\int \!{\frac{{\it g1} \left ( x \right ) }{f \left ( x \right ) }}\,{\rm d}x \right ) }} \right ) } \right )$

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#### 94.7 Problem 7

problem number 812

Problem Chapter 3.8.4.7 from Handbook of ﬁrst order partial diﬀerential equations by Polyanin, Zaitsev, Moussiaux.

Solve for $$w(x,y)$$

$f_1(x) g_1(y) w_x + f_2(x) g_2(y) w_y = h(x,y)$

Mathematica

$\text{DSolve}\left [\text{f1}(x) \text{g1}(y) w^{(1,0)}(x,y)+\text{f2}(x) \text{g2}(y) w^{(0,1)}(x,y)=h(x,y),w(x,y),\{x,y\}\right ]$

Maple

$w \left ( x,y \right ) =\int ^{x}\!{\frac{1}{{\it f1} \left ({\it \_f} \right ) }h \left ({\it \_f},\RootOf \left ( \int \!{\frac{{\it f2} \left ({\it \_f} \right ) }{{\it f1} \left ({\it \_f} \right ) }}\,{\rm d}{\it \_f}-\int ^{{\it \_Z}}\!{\frac{{\it g1} \left ({\it \_a} \right ) }{{\it g2} \left ({\it \_a} \right ) }}{d{\it \_a}}-\int \!{\frac{{\it f2} \left ( x \right ) }{{\it f1} \left ( x \right ) }}\,{\rm d}x+\int \!{\frac{{\it g1} \left ( y \right ) }{{\it g2} \left ( y \right ) }}\,{\rm d}y \right ) \right ) \left ({\it g1} \left ( \RootOf \left ( \int \!{\frac{{\it f2} \left ({\it \_f} \right ) }{{\it f1} \left ({\it \_f} \right ) }}\,{\rm d}{\it \_f}-\int ^{{\it \_Z}}\!{\frac{{\it g1} \left ({\it \_a} \right ) }{{\it g2} \left ({\it \_a} \right ) }}{d{\it \_a}}-\int \!{\frac{{\it f2} \left ( x \right ) }{{\it f1} \left ( x \right ) }}\,{\rm d}x+\int \!{\frac{{\it g1} \left ( y \right ) }{{\it g2} \left ( y \right ) }}\,{\rm d}y \right ) \right ) \right ) ^{-1}}{d{\it \_f}}+{\it \_F1} \left ( -\int \!{\frac{{\it f2} \left ( x \right ) }{{\it f1} \left ( x \right ) }}\,{\rm d}x+\int \!{\frac{{\it g1} \left ( y \right ) }{{\it g2} \left ( y \right ) }}\,{\rm d}y \right )$ Contains RootOf