## Rational Expressions ### Question 1 a) Let $`S_r`$ be Ron's speed and $`S_m`$ be Mack's speed. Let $`t`$ be the time. $`t_a = \dfrac{30}{S_r}`$ $`t_b = \dfrac{20}{S_m}`$ $`t_{\text{total}} = \dfrac{30}{S_r} + \dfrac{20}{S_m} = \dfrac{30S_m + 20S_r}{(S_m)(S_r)}`$ ### Question 1 b) Here, $`S_r = 35, S_m = 25`$ (Because we want the faster guy to travel more distance to save time). We plug it into our formula above: $`t_{\text{tota}} = \dfrac{30(25) + (20)(35)}{(35)(25)} = 1.657`$ Therefore the minimum amount of time it will take to complete the race is $`1.657`$ hours, or about $`99.42`$ minutes or $`99`$ minutes and $`25.2`$ seconds. ### Question 2 a) I would first flip the second fraction and then cross-cross out the common factors like so: $`\dfrac{(x+3)(x-6)}{(x+4)(x+5)} \times \dfrac{(x+4)(x-7)}{(x-6)(x+8)}`$ We can cross out the $`(x+4)`$ and $`(x-6)`$ since they cancel each other out. The final fraction is therefore $`\dfrac{(x+3)(x-7)}{(x+5)(x+8)}`$ For restrictions, at each step, I would mark down the restrictions. Such without doing anthing, we know that $`x =\not -4, -5, 7`$, then after we flip the fraction, we know that $`x =\not 6, -8`$, and at the final step, we know that $`x=\not -5, -8`$. Therefore the final restrictions on $`x`$ would be: $`x=\not -4, -5,-8, 6, 7`$ ### Question 2 b) By using the restrictions and the final product, we know that the 2 fraction can only have the following as its denominator: $`(x+4), (x-2), (x-1)`$ And since we know there is a $`(x-2)`$ as the denominator and $`(x+5)`$ as the numerator for the final product, we just need one of the fractions to cancel out the denominators $`(x+4), (x-1)`$. Thus, 2 fractions such as below would work: $`\dfrac{(x+5)}{(x-4)(x-1)} \times \dfrac{(x-4)(x-1)}{(x-2)}`$ ### Question 2 c) The student forgot to multiply the numerator by the same number he used to multiply the denomiator. ### Question 3 a) Let $`V, SA`$ be the volume and surface area respectively. $`V = \pi r^2 h`$ $`SA = 2r\pi h + 2\pi r^2 \implies 2r \pi (h + r)`$ The ratio of $`V : SA`$ is equal to: $`\dfrac{\pi r^2 h}{2r\pi (h + r)}`$ $` = \dfrac{rh}{2(h+4)}`$ ### Question 3 b) The restrictions by looking at the fraction are $`h =\not r, r =\not h`$, also $`r =\not 0`$.