Algebra (all content)
- Interpreting equations graphically
- Interpreting equations graphically (example 2)
- Interpret equations graphically
- Solving equations graphically (1 of 2)
- Solving equations graphically (2 of 2)
- Solving equations graphically
- Solve equations graphically
Interpreting equations graphically
Sal interprets the intersection point of the graphs of functions f and g as the solution of the equation f(x)=g(x).
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- how would one solve 3^-x using log notation(2 votes)
- You do not have an equation yet, merely an expression which could be re-written as
3^(-x) = [ 3^(-1) ] ^x = ( 1 / 3 ) ^x
If you had had an equation, say 3^(-x) = 1 / 9
then once you got to ( 1 / 3 ) ^x = 1 / 9
you would take log base 1/3 of each side, getting
x = log_(1/3) ( 1 / 9 )
So, ask yourself what power of 1/3 equals 1/9?
x = 2(4 votes)
- Why is x=a a solution to the equalities shown near the end of the video(2 votes)
- anyone have easier explanation please?(2 votes)
- I have been working on this section of the course steadily. Up until this "solving equations graphically" point everything has been, although not easy, straightforward. It feels like i've missed a big section somewhere because this new coursework has me completely lost. am I missing something? Should I be working on something else as a prerequisite to this material?(1 vote)
- I'm not really sure how to help, could you be more specific with your question? What exactly do you not understand?(2 votes)
- how to find solve F(x) =x+1
and g(x)=-6+8 graph then classify(1 vote)
- [Voiceover] Let f of x equal three to the negative x minus five, and g of x equals negative x to the third minus four x-squared plus x plus six. The graphs of y equals f of x and y equals g of x are shown below, and we see them right over here. This y equals f of x is in that purplish color. Let me see if I can get that same purplish color. So, that is, in that. So, let me underline it now. So, f of x is in that purplish color. So y equal f of x, that's right over here in purple. And then y equals g of x, that is in blue. So y equals g of x. g of x is defined right over there. y equals g of x, well that is graphed in the blue. And we see that they intersect at the point a comma b. So there's a couple of ways to think about this. We could say that when x is equal to a, f of x and g of x equal each other. Or, we could say, f of a, and this is coming from this point of intersection. Let me draw a little arrow here. Or a big arrow. That point of intersection lets us know that f of a, f of a is equal to g of a. Is equal to g of a, which is equal to b. g of a, which is equal to b. They both, if you input a into the function f you're going to get b. If you input a into the function g, you're going to get b. And so the point a comma b is on both graphs. Both y equals g of x and y equals f of x. And so from here, you could make some interesting statements. For example, you could just say, well, what is f of a? f of a is 3 to the negative a power minus five, is going to be equal to, what's g of a? g of a is negative a to the third minus four a-squared plus a plus six, so you could say this. And that would be equal to that. Either of those would be equal to b. Alright, I think we've analyzed that a good bit, so now let's actually answer their questions. And normally I'd suggest you look at the questions before you actually try to solve it, but I just wanted to do this just to really squeeze out as much as we could out of the information they gave us. So they tell us the value x equals a is the solution to which of the following equations? Select all that apply. So this first one is three to the negative x minus five is equal to b. Well, we already know that, we already know that three to the negative a minus five, Three to the negative a minus is going to be equal to b. Is going to be equal to b. This over here, this is equivalent to saying, this is equivalent to saying f of x, f of x is equal to b. And we know f of x equals B when x equals a. When x equals a, f of x is equal to b. This expression is equal to b. So we know that that first one is true. Now the second one is just saying, f of x is equal to g of x. Well, we know that when x is equal to a, f of x is equal to g of x. That f of a is equal to g of a. Because, as a reminder, this right over here is our definition for f of x, and this over here is our definition of g of x. So this is just saying f of x equals g of x, when does that happen? Well, that happens when x equals a. We already saw it up here. f of a is equal to g of a. They both equal b. And so both of these are going to be equal to each other when x is equal to A. So I will check that one as well.