Simplify: $$\frac\fracxx+y - \fracxx-y\fracyx+y + \fracyx-y$$
Discriminant $\Delta = k^2 - 4(1)(9) = k^2 - 36 = 0$. Thus $k^2 = 36 \rightarrow k = \pm 6$. 10. The Final "Me las vas a pagar" Challenge Combine everything: me las vas a pagar mary rojas pdf %C3%A1lgebra
Let Mary = $M$, Rojas = $R$. $M = 3R$. $M + 10 = 2(R + 10) \rightarrow 3R + 10 = 2R + 20 \rightarrow R = 10$. Thus $M = 30$. 8. Absolute Value Equations (The Double Case) $$|x-3| + |x+2| = 7$$ The Final "Me las vas a pagar" Challenge
"Mary is three times as old as Rojas. In 10 years, Mary will be twice as old as Rojas. How old is Mary now?" Thus $M = 30$
$$x^2 + y^2 = 25$$ $$x^2 - y^2 = 7$$
Use change of base: $\log_4(x) = \frac\log_2(x)\log_2(4) = \frac\log_2(x)2$. Similarly, $\log_8(x) = \frac\log_2(x)3$. Let $\log_2(x) = L$. Equation: $L + \fracL2 + \fracL3 = \frac116$. Common denominator: $\frac6L + 3L + 2L6 = \frac11L6 = \frac116 \rightarrow L=1$. Thus $x = 2^1 = 2$. 4. Systems of Equations (Non-Linear) The infamous "Mary Rojas" problem often involves a system that looks impossible without a trick.
When dividing by $x^2 - 1$, the remainder is of the form $ax + b$. We know $x^2 = 1$, so $x^100 = (x^2)^50 = 1^50 = 1$. And $x^50 = (x^2)^25 = 1$. Thus $P(x) \equiv 1 + 2(1) + 1 = 4$. Since the remainder is a constant, $ax+b = 4$. Answer: $4$ (remainder is $0\cdot x + 4$). 7. Age Problems (Verbal Algebra) Classic word problem: