I am studying exponential functions and I was told to answer the question below:
I started off by making an equation (of the form [MATH]y=ab^x[/MATH]) to find the final volume for a snake at any given level: [MATH]V_f=V_iG^{n-1}[/MATH]
[MATH]V_i[/MATH] is the initial volume, [MATH]V_f[/MATH] is the final volume, [MATH]G[/MATH] is the "growth factor" (if it helps, my "growth factor" was 1.1), [MATH]n[/MATH] is the level that the snake is at ([MATH]n-1[/MATH] in the equation because level 1 is the initial volume). **Length and radius for level 1 are made by the student, here are mine (not sure if it can be done without values as teacher insisted we make some): Length: 5 units, Radius: 1 unit.
I am not sure how to manipulate this equation so that it will be in terms of the length of the cylinder. I feel it will be something to do with the constant [MATH]k[/MATH]. I have already tried to substitute [MATH]\pi r^2*L[/MATH] for [MATH]V_1[/MATH] but I found that I don't know both [MATH]r[/MATH] and [MATH]L[/MATH], making it impossible to solve. I see that the [MATH]k[/MATH] value could help by relating [MATH]\pi r^2[/MATH] to [MATH]L[/MATH], but I do not see how this can be done without knowing either value. Only the constant [MATH]k[/MATH] can be known since the values for radius and length on level 1 are made up.
Thanks in advance!
I started off by making an equation (of the form [MATH]y=ab^x[/MATH]) to find the final volume for a snake at any given level: [MATH]V_f=V_iG^{n-1}[/MATH]
[MATH]V_i[/MATH] is the initial volume, [MATH]V_f[/MATH] is the final volume, [MATH]G[/MATH] is the "growth factor" (if it helps, my "growth factor" was 1.1), [MATH]n[/MATH] is the level that the snake is at ([MATH]n-1[/MATH] in the equation because level 1 is the initial volume). **Length and radius for level 1 are made by the student, here are mine (not sure if it can be done without values as teacher insisted we make some): Length: 5 units, Radius: 1 unit.
I am not sure how to manipulate this equation so that it will be in terms of the length of the cylinder. I feel it will be something to do with the constant [MATH]k[/MATH]. I have already tried to substitute [MATH]\pi r^2*L[/MATH] for [MATH]V_1[/MATH] but I found that I don't know both [MATH]r[/MATH] and [MATH]L[/MATH], making it impossible to solve. I see that the [MATH]k[/MATH] value could help by relating [MATH]\pi r^2[/MATH] to [MATH]L[/MATH], but I do not see how this can be done without knowing either value. Only the constant [MATH]k[/MATH] can be known since the values for radius and length on level 1 are made up.
Thanks in advance!
