Matemática discreta Ejemplos

$\log_{x} (y) + \log_{y} (x) = 2.9$ , $x y = 128$

Paso 1

Resuelve la ecuación en $e$ .

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Paso 1.1

Divide cada término en $(2.9 - \log_{x} (y)) \ln (y) = \ln (x)$ por $\ln (y)$ y simplifica.

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Paso 1.1.1

Divide cada término en $(2.9 - \log_{x} (y)) \ln (y) = \ln (x)$ por $\ln (y)$ .

$\frac{(2.9 - \log_{x} (y)) \ln (y)}{\ln (y)} = \frac{\ln (x)}{\ln (y)}$

$y = \frac{128}{x}$

Paso 1.1.2

Simplifica el lado izquierdo.

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Paso 1.1.2.1

Cancela el factor común de $\ln (y)$ .

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Paso 1.1.2.1.1

Cancela el factor común.

$\frac{(2.9 - \log_{x} (y)) \ln (y)}{\ln (y)} = \frac{\ln (x)}{\ln (y)}$

$y = \frac{128}{x}$

Paso 1.1.2.1.2

Divide $2.9 - \log_{x} (y)$ por $1$ .

$2.9 - \log_{x} (y) = \frac{\ln (x)}{\ln (y)}$

$y = \frac{128}{x}$

$2.9 - \log_{x} (y) = \frac{\ln (x)}{\ln (y)}$

$y = \frac{128}{x}$

$2.9 - \log_{x} (y) = \frac{\ln (x)}{\ln (y)}$

$y = \frac{128}{x}$

$2.9 - \log_{x} (y) = \frac{\ln (x)}{\ln (y)}$

$y = \frac{128}{x}$

Paso 1.2

Resta $2.9$ de ambos lados de la ecuación.

$- \log_{x} (y) = \frac{\ln (x)}{\ln (y)} - 2.9$

$y = \frac{128}{x}$

Paso 1.3

Divide cada término en $- \log_{x} (y) = \frac{\ln (x)}{\ln (y)} - 2.9$ por $- 1$ y simplifica.

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Paso 1.3.1

Divide cada término en $- \log_{x} (y) = \frac{\ln (x)}{\ln (y)} - 2.9$ por $- 1$ .

$\frac{- \log_{x} (y)}{- 1} = \frac{\frac{\ln (x)}{\ln (y)}}{- 1} + \frac{- 2.9}{- 1}$

$y = \frac{128}{x}$

Paso 1.3.2

Simplifica el lado izquierdo.

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Paso 1.3.2.1

La división de dos valores negativos da como resultado un valor positivo.

$\frac{\log_{x} (y)}{1} = \frac{\frac{\ln (x)}{\ln (y)}}{- 1} + \frac{- 2.9}{- 1}$

$y = \frac{128}{x}$

Paso 1.3.2.2

Divide $\log_{x} (y)$ por $1$ .

$\log_{x} (y) = \frac{\frac{\ln (x)}{\ln (y)}}{- 1} + \frac{- 2.9}{- 1}$

$y = \frac{128}{x}$

$\log_{x} (y) = \frac{\frac{\ln (x)}{\ln (y)}}{- 1} + \frac{- 2.9}{- 1}$

$y = \frac{128}{x}$

Paso 1.3.3

Simplifica el lado derecho.

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Paso 1.3.3.1

Simplifica cada término.

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Paso 1.3.3.1.1

Mueve el negativo del denominador de $\frac{\frac{\ln (x)}{\ln (y)}}{- 1}$ .

$\log_{x} (y) = - 1 \cdot \frac{\ln (x)}{\ln (y)} + \frac{- 2.9}{- 1}$

$y = \frac{128}{x}$

Paso 1.3.3.1.2

Reescribe $- 1 \cdot \frac{\ln (x)}{\ln (y)}$ como $- \frac{\ln (x)}{\ln (y)}$ .

$\log_{x} (y) = - \frac{\ln (x)}{\ln (y)} + \frac{- 2.9}{- 1}$

$y = \frac{128}{x}$

Paso 1.3.3.1.3

Divide $- 2.9$ por $- 1$ .

$\log_{x} (y) = - \frac{\ln (x)}{\ln (y)} + 2.9$

$y = \frac{128}{x}$

$\log_{x} (y) = - \frac{\ln (x)}{\ln (y)} + 2.9$

$y = \frac{128}{x}$

$\log_{x} (y) = - \frac{\ln (x)}{\ln (y)} + 2.9$

$y = \frac{128}{x}$

$\log_{x} (y) = - \frac{\ln (x)}{\ln (y)} + 2.9$

$y = \frac{128}{x}$

$\log_{x} (y) = - \frac{\ln (x)}{\ln (y)} + 2.9$

$y = \frac{128}{x}$

Paso 2

Simplifica el lado derecho.

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Paso 2.1

Simplifica $- \frac{\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (x)}{\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (x))} + 2.9$ .

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Paso 2.1.1

Simplifica cada término.

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Paso 2.1.1.1

Simplifica el numerador.

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Paso 2.1.1.1.1

Para escribir $2.9$ como una fracción con un denominador común, multiplica por $\frac{\ln (y)}{\ln (y)}$ .

$\log_{x} (\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (x)) = - \frac{\log_{- \frac{\ln (x)}{\ln (y)} + 2.9 \cdot \frac{\ln (y)}{\ln (y)}} (x)}{\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (x))} + 2.9$

$y = \frac{128}{x}$

Paso 2.1.1.1.2

Combina $2.9$ y $\frac{\ln (y)}{\ln (y)}$ .

$\log_{x} (\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (x)) = - \frac{\log_{- \frac{\ln (x)}{\ln (y)} + \frac{2.9 \ln (y)}{\ln (y)}} (x)}{\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (x))} + 2.9$

$y = \frac{128}{x}$

Paso 2.1.1.1.3

Combina los numeradores sobre el denominador común.

$\log_{x} (\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (x)) = - \frac{\log_{\frac{- \ln (x) + 2.9 \ln (y)}{\ln (y)}} (x)}{\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (x))} + 2.9$

$y = \frac{128}{x}$

Paso 2.1.1.1.4

Simplifica el numerador.

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Paso 2.1.1.1.4.1

Factoriza $0.1$ de $- \ln (x) + 2.9 \ln (y)$ .

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Paso 2.1.1.1.4.1.1

Factoriza $0.1$ de $- \ln (x)$ .

$\log_{x} (\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (x)) = - \frac{\log_{\frac{0.1 (- 10 \ln (x)) + 2.9 \ln (y)}{\ln (y)}} (x)}{\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (x))} + 2.9$

$y = \frac{128}{x}$

Paso 2.1.1.1.4.1.2

Factoriza $0.1$ de $2.9 \ln (y)$ .

$\log_{x} (\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (x)) = - \frac{\log_{\frac{0.1 (- 10 \ln (x)) + 0.1 (29 \ln (y))}{\ln (y)}} (x)}{\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (x))} + 2.9$

$y = \frac{128}{x}$

Paso 2.1.1.1.4.1.3

Factoriza $0.1$ de $0.1 (- 10 \ln (x)) + 0.1 (29 \ln (y))$ .

$\log_{x} (\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (x)) = - \frac{\log_{\frac{0.1 (- 10 \ln (x) + 29 \ln (y))}{\ln (y)}} (x)}{\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (x))} + 2.9$

$y = \frac{128}{x}$

$\log_{x} (\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (x)) = - \frac{\log_{\frac{0.1 (- 10 \ln (x) + 29 \ln (y))}{\ln (y)}} (x)}{\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (x))} + 2.9$

$y = \frac{128}{x}$

Paso 2.1.1.1.4.2

Simplifica $- 10 \ln (x)$ al mover $10$ dentro del algoritmo.

$\log_{x} (\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (x)) = - \frac{\log_{\frac{0.1 (- \ln (x^{10}) + 29 \ln (y))}{\ln (y)}} (x)}{\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (x))} + 2.9$

$y = \frac{128}{x}$

Paso 2.1.1.1.4.3

Simplifica $29 \ln (y)$ al mover $29$ dentro del algoritmo.

$\log_{x} (\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (x)) = - \frac{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x)}{\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (x))} + 2.9$

$y = \frac{128}{x}$

$\log_{x} (\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (x)) = - \frac{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x)}{\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (x))} + 2.9$

$y = \frac{128}{x}$

$\log_{x} (\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (x)) = - \frac{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x)}{\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (x))} + 2.9$

$y = \frac{128}{x}$

Paso 2.1.1.2

Simplifica el denominador.

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Paso 2.1.1.2.1

Para escribir $2.9$ como una fracción con un denominador común, multiplica por $\frac{\ln (y)}{\ln (y)}$ .

$\log_{x} (\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (x)) = - \frac{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x)}{\log_{- \frac{\ln (x)}{\ln (y)} + 2.9 \cdot \frac{\ln (y)}{\ln (y)}} (\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (x))} + 2.9$

$y = \frac{128}{x}$

Paso 2.1.1.2.2

Combina $2.9$ y $\frac{\ln (y)}{\ln (y)}$ .

$\log_{x} (\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (x)) = - \frac{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x)}{\log_{- \frac{\ln (x)}{\ln (y)} + \frac{2.9 \ln (y)}{\ln (y)}} (\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (x))} + 2.9$

$y = \frac{128}{x}$

Paso 2.1.1.2.3

Combina los numeradores sobre el denominador común.

$\log_{x} (\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (x)) = - \frac{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x)}{\log_{\frac{- \ln (x) + 2.9 \ln (y)}{\ln (y)}} (\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (x))} + 2.9$

$y = \frac{128}{x}$

Paso 2.1.1.2.4

Simplifica el numerador.

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Paso 2.1.1.2.4.1

Factoriza $0.1$ de $- \ln (x) + 2.9 \ln (y)$ .

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Paso 2.1.1.2.4.1.1

Factoriza $0.1$ de $- \ln (x)$ .

$\log_{x} (\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (x)) = - \frac{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x)}{\log_{\frac{0.1 (- 10 \ln (x)) + 2.9 \ln (y)}{\ln (y)}} (\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (x))} + 2.9$

$y = \frac{128}{x}$

Paso 2.1.1.2.4.1.2

Factoriza $0.1$ de $2.9 \ln (y)$ .

$\log_{x} (\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (x)) = - \frac{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x)}{\log_{\frac{0.1 (- 10 \ln (x)) + 0.1 (29 \ln (y))}{\ln (y)}} (\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (x))} + 2.9$

$y = \frac{128}{x}$

Paso 2.1.1.2.4.1.3

Factoriza $0.1$ de $0.1 (- 10 \ln (x)) + 0.1 (29 \ln (y))$ .

$\log_{x} (\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (x)) = - \frac{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x)}{\log_{\frac{0.1 (- 10 \ln (x) + 29 \ln (y))}{\ln (y)}} (\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (x))} + 2.9$

$y = \frac{128}{x}$

$\log_{x} (\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (x)) = - \frac{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x)}{\log_{\frac{0.1 (- 10 \ln (x) + 29 \ln (y))}{\ln (y)}} (\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (x))} + 2.9$

$y = \frac{128}{x}$

Paso 2.1.1.2.4.2

Simplifica $- 10 \ln (x)$ al mover $10$ dentro del algoritmo.

$\log_{x} (\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (x)) = - \frac{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x)}{\log_{\frac{0.1 (- \ln (x^{10}) + 29 \ln (y))}{\ln (y)}} (\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (x))} + 2.9$

$y = \frac{128}{x}$

Paso 2.1.1.2.4.3

Simplifica $29 \ln (y)$ al mover $29$ dentro del algoritmo.

$\log_{x} (\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (x)) = - \frac{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x)}{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (x))} + 2.9$

$y = \frac{128}{x}$

$\log_{x} (\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (x)) = - \frac{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x)}{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (x))} + 2.9$

$y = \frac{128}{x}$

Paso 2.1.1.2.5

Para escribir $2.9$ como una fracción con un denominador común, multiplica por $\frac{\ln (y)}{\ln (y)}$ .

$\log_{x} (\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (x)) = - \frac{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x)}{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (\log_{- \frac{\ln (x)}{\ln (y)} + 2.9 \cdot \frac{\ln (y)}{\ln (y)}} (x))} + 2.9$

$y = \frac{128}{x}$

Paso 2.1.1.2.6

Combina $2.9$ y $\frac{\ln (y)}{\ln (y)}$ .

$\log_{x} (\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (x)) = - \frac{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x)}{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (\log_{- \frac{\ln (x)}{\ln (y)} + \frac{2.9 \ln (y)}{\ln (y)}} (x))} + 2.9$

$y = \frac{128}{x}$

Paso 2.1.1.2.7

Combina los numeradores sobre el denominador común.

$\log_{x} (\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (x)) = - \frac{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x)}{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (\log_{\frac{- \ln (x) + 2.9 \ln (y)}{\ln (y)}} (x))} + 2.9$

$y = \frac{128}{x}$

Paso 2.1.1.2.8

Simplifica el numerador.

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Paso 2.1.1.2.8.1

Factoriza $0.1$ de $- \ln (x) + 2.9 \ln (y)$ .

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Paso 2.1.1.2.8.1.1

Factoriza $0.1$ de $- \ln (x)$ .

$\log_{x} (\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (x)) = - \frac{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x)}{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (\log_{\frac{0.1 (- 10 \ln (x)) + 2.9 \ln (y)}{\ln (y)}} (x))} + 2.9$

$y = \frac{128}{x}$

Paso 2.1.1.2.8.1.2

Factoriza $0.1$ de $2.9 \ln (y)$ .

$\log_{x} (\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (x)) = - \frac{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x)}{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (\log_{\frac{0.1 (- 10 \ln (x)) + 0.1 (29 \ln (y))}{\ln (y)}} (x))} + 2.9$

$y = \frac{128}{x}$

Paso 2.1.1.2.8.1.3

Factoriza $0.1$ de $0.1 (- 10 \ln (x)) + 0.1 (29 \ln (y))$ .

$\log_{x} (\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (x)) = - \frac{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x)}{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (\log_{\frac{0.1 (- 10 \ln (x) + 29 \ln (y))}{\ln (y)}} (x))} + 2.9$

$y = \frac{128}{x}$

$\log_{x} (\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (x)) = - \frac{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x)}{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (\log_{\frac{0.1 (- 10 \ln (x) + 29 \ln (y))}{\ln (y)}} (x))} + 2.9$

$y = \frac{128}{x}$

Paso 2.1.1.2.8.2

Simplifica $- 10 \ln (x)$ al mover $10$ dentro del algoritmo.

$\log_{x} (\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (x)) = - \frac{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x)}{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (\log_{\frac{0.1 (- \ln (x^{10}) + 29 \ln (y))}{\ln (y)}} (x))} + 2.9$

$y = \frac{128}{x}$

Paso 2.1.1.2.8.3

Simplifica $29 \ln (y)$ al mover $29$ dentro del algoritmo.

$\log_{x} (\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (x)) = - \frac{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x)}{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x))} + 2.9$

$y = \frac{128}{x}$

$\log_{x} (\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (x)) = - \frac{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x)}{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x))} + 2.9$

$y = \frac{128}{x}$

$\log_{x} (\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (x)) = - \frac{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x)}{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x))} + 2.9$

$y = \frac{128}{x}$

$\log_{x} (\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (x)) = - \frac{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x)}{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x))} + 2.9$

$y = \frac{128}{x}$

Paso 2.1.2

Para escribir $2.9$ como una fracción con un denominador común, multiplica por $\frac{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x))}{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x))}$ .

$\log_{x} (\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (x)) = - \frac{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x)}{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x))} + 2.9 \cdot \frac{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x))}{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x))}$

$y = \frac{128}{x}$

Paso 2.1.3

Simplifica los términos.

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Paso 2.1.3.1

Combina $2.9$ y $\frac{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x))}{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x))}$ .

$\log_{x} (\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (x)) = - \frac{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x)}{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x))} + \frac{2.9 \log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x))}{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x))}$

$y = \frac{128}{x}$

Paso 2.1.3.2

Combina los numeradores sobre el denominador común.

$\log_{x} (\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (x)) = \frac{- \log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x) + 2.9 \log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x))}{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x))}$

$y = \frac{128}{x}$

$\log_{x} (\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (x)) = \frac{- \log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x) + 2.9 \log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x))}{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x))}$

$y = \frac{128}{x}$

Paso 2.1.4

Simplifica el numerador.

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Paso 2.1.4.1

Factoriza $0.1$ de $- \log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x) + 2.9 \log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x))$ .

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Paso 2.1.4.1.1

Factoriza $0.1$ de $- \log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x)$ .

$\log_{x} (\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (x)) = \frac{0.1 (- 10 \log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x)) + 2.9 \log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x))}{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x))}$

$y = \frac{128}{x}$

Paso 2.1.4.1.2

Factoriza $0.1$ de $2.9 \log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x))$ .

$\log_{x} (\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (x)) = \frac{0.1 (- 10 \log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x)) + 0.1 (29 \log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x)))}{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x))}$

$y = \frac{128}{x}$

Paso 2.1.4.1.3

Factoriza $0.1$ de $0.1 (- 10 \log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x)) + 0.1 (29 \log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x)))$ .

$\log_{x} (\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (x)) = \frac{0.1 (- 10 \log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x) + 29 \log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x)))}{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x))}$

$y = \frac{128}{x}$

$\log_{x} (\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (x)) = \frac{0.1 (- 10 \log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x) + 29 \log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x)))}{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x))}$

$y = \frac{128}{x}$

Paso 2.1.4.2

Simplifica $- 10 \log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x)$ al mover $10$ dentro del algoritmo.

$\log_{x} (\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (x)) = \frac{0.1 (- \log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x^{10}) + 29 \log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x)))}{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x))}$

$y = \frac{128}{x}$

Paso 2.1.4.3

Simplifica $29 \log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x))$ al mover $29$ dentro del algoritmo.

$\log_{x} (\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (x)) = \frac{0.1 (- \log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x^{10}) + \log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} ({\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}}}^{29} (x)))}{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x))}$

$y = \frac{128}{x}$

$\log_{x} (\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (x)) = \frac{0.1 (- \log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x^{10}) + \log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} ({\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}}}^{29} (x)))}{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x))}$

$y = \frac{128}{x}$

Paso 2.1.5

Simplifica con la obtención del factor común.

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Paso 2.1.5.1

Factoriza $- 1$ de $- \log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x^{10})$ .

$\log_{x} (\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (x)) = \frac{0.1 (- (\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x^{10})) + \log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} ({\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}}}^{29} (x)))}{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x))}$

$y = \frac{128}{x}$

Paso 2.1.5.2

Factoriza $- 1$ de $\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} ({\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}}}^{29} (x))$ .

$\log_{x} (\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (x)) = \frac{0.1 (- (\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x^{10})) - 1 (- \log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} ({\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}}}^{29} (x))))}{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x))}$

$y = \frac{128}{x}$

Paso 2.1.5.3

Factoriza $- 1$ de $- (\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x^{10})) - 1 (- \log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} ({\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}}}^{29} (x)))$ .

$\log_{x} (\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (x)) = \frac{0.1 (- (\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x^{10}) - \log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} ({\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}}}^{29} (x))))}{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x))}$

$y = \frac{128}{x}$

Paso 2.1.5.4

Simplifica la expresión.

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Paso 2.1.5.4.1

Reescribe $- (\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x^{10}) - \log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} ({\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}}}^{29} (x)))$ como $- 1 (\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x^{10}) - \log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} ({\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}}}^{29} (x)))$ .

$\log_{x} (\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (x)) = \frac{0.1 (- 1 (\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x^{10}) - \log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} ({\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}}}^{29} (x))))}{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x))}$

$y = \frac{128}{x}$

Paso 2.1.5.4.2

Mueve el negativo al frente de la fracción.

$\log_{x} (\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (x)) = - \frac{0.1 (\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x^{10}) - \log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} ({\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}}}^{29} (x)))}{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x))}$

$y = \frac{128}{x}$

$\log_{x} (\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (x)) = - \frac{0.1 (\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x^{10}) - \log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} ({\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}}}^{29} (x)))}{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x))}$

$y = \frac{128}{x}$

$\log_{x} (\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (x)) = - \frac{0.1 (\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x^{10}) - \log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} ({\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}}}^{29} (x)))}{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x))}$

$y = \frac{128}{x}$

$\log_{x} (\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (x)) = - \frac{0.1 (\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x^{10}) - \log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} ({\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}}}^{29} (x)))}{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x))}$

$y = \frac{128}{x}$

$\log_{x} (\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (x)) = - \frac{0.1 (\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x^{10}) - \log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} ({\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}}}^{29} (x)))}{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x))}$

$y = \frac{128}{x}$

Paso 3

Simplifica el lado derecho.

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Paso 3.1

Simplifica $- \frac{0.1 (\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x^{10}) - \log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} ({\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}}}^{29} (x)))}{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x))}$ .

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Paso 3.1.1

Usa la propiedad del cociente de los logaritmos, $\log_{b} (x) - \log_{b} (y) = \log_{b} (\frac{x}{y})$ .

$\log_{x} (\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (x)) = - \frac{0.1 \log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (\frac{x^{10}}{{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}}}^{29} (x)})}{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x))}$

$y = \frac{128}{x}$

Paso 3.1.2

Simplifica $0.1 \log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (\frac{x^{10}}{{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}}}^{29} (x)})$ al mover $0.1$ dentro del algoritmo.

$\log_{x} (\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (x)) = - \frac{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} ({(\frac{x^{10}}{{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}}}^{29} (x)})}^{0.1})}{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x))}$

$y = \frac{128}{x}$

Paso 3.1.3

Simplifica el numerador.

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Paso 3.1.3.1

Aplica la regla del producto a $\frac{x^{10}}{{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}}}^{29} (x)}$ .

$\log_{x} (\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (x)) = - \frac{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (\frac{{(x^{10})}^{0.1}}{{({\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}}}^{29} (x))}^{0.1}})}{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x))}$

$y = \frac{128}{x}$

Paso 3.1.3.2

Simplifica el numerador.

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Paso 3.1.3.2.1

Multiplica los exponentes en ${(x^{10})}^{0.1}$ .

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Paso 3.1.3.2.1.1

Aplica la regla de la potencia y multiplica los exponentes, ${(a^{m})}^{n} = a^{m n}$ .

$\log_{x} (\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (x)) = - \frac{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (\frac{x^{10 \cdot 0.1}}{{({\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}}}^{29} (x))}^{0.1}})}{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x))}$

$y = \frac{128}{x}$

Paso 3.1.3.2.1.2

Multiplica $10$ por $0.1$ .

$\log_{x} (\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (x)) = - \frac{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (\frac{x}{{({\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}}}^{29} (x))}^{0.1}})}{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x))}$

$y = \frac{128}{x}$

$\log_{x} (\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (x)) = - \frac{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (\frac{x}{{({\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}}}^{29} (x))}^{0.1}})}{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x))}$

$y = \frac{128}{x}$

Paso 3.1.3.2.2

Simplifica.

$\log_{x} (\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (x)) = - \frac{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (\frac{x}{{({\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}}}^{29} (x))}^{0.1}})}{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x))}$

$y = \frac{128}{x}$

$\log_{x} (\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (x)) = - \frac{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (\frac{x}{{({\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}}}^{29} (x))}^{0.1}})}{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x))}$

$y = \frac{128}{x}$

Paso 3.1.3.3

Multiplica los exponentes en ${({\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}}}^{29} (x))}^{0.1}$ .

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Paso 3.1.3.3.1

Aplica la regla de la potencia y multiplica los exponentes, ${(a^{m})}^{n} = a^{m n}$ .

$\log_{x} (\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (x)) = - \frac{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (\frac{x}{{(\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x))}^{29 \cdot 0.1}})}{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x))}$

$y = \frac{128}{x}$

Paso 3.1.3.3.2

Multiplica $29$ por $0.1$ .

$\log_{x} (\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (x)) = - \frac{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (\frac{x}{{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}}}^{2.9} (x)})}{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x))}$

$y = \frac{128}{x}$

$\log_{x} (\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (x)) = - \frac{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (\frac{x}{{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}}}^{2.9} (x)})}{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x))}$

$y = \frac{128}{x}$

$\log_{x} (\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (x)) = - \frac{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (\frac{x}{{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}}}^{2.9} (x)})}{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x))}$

$y = \frac{128}{x}$

$\log_{x} (\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (x)) = - \frac{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (\frac{x}{{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}}}^{2.9} (x)})}{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x))}$

$y = \frac{128}{x}$

$\log_{x} (\log_{- \frac{\ln (x)}{\ln (y)} + 2.9} (x)) = - \frac{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (\frac{x}{{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}}}^{2.9} (x)})}{\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (\log_{\frac{0.1 (- \ln (x^{10}) + \ln (y^{29}))}{\ln (y)}} (x))}$

$y = \frac{128}{x}$

$[\begin{array}{c} x^{2} & \frac{1}{2} \\ \sqrt{π} & \int x d x \end{array}]$