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In this video, weβll learn how to sketch logarithmic functions with different bases and their transformations, and weβll study their different characteristics.
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So, letβs begin by reminding ourselves what we actually mean when we call a function logarithmic.
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Now, a logarithmic function is the inverse of an exponential function.
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Itβs of the form π of π₯ is equal to log base π of π₯, where π is greater than zero and not equal to one.
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And we say if the point π₯, π¦ satisfies the exponential function, then the point π¦, π₯ satisfies the logarithmic function.
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And the fact that the exponential and logarithmic functions are inverses of one another is actually really helpful when it comes to sketching their graphs.
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And we will investigate that in a little more detail later on in this video.
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For now, letβs begin by investigating the shape of the curve given by a logarithmic function.
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Find the missing table values for β of π₯ equals log base two of π₯.
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And then we have a table with three missing values.
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So, what do we mean when we talk about a logarithm?
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Logarithmic functions are inverses to exponential functions.
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Imagine we have the given expression.
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We read this as log base π of π equals π.
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π is the base, π is set to be the exponent in this expression, and π is called the argument.
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And in fact, this is exactly the same way as describing the relationship between π, π, and π as π to the power of π equals π.
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So with this in mind, letβs take the function log base two of π₯, and weβll take our first value of π₯, negative two.
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Substituting π₯ equals negative two in the function for β of π₯ gives us β of negative two is equal to log base two of negative two.
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But we need to work out the value of β of negative two.
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So letβs call that π sub one.
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If we equivalently describe this relationship as two to the power of π sub one equals negative two, we see we need to find the value of π sub one that satisfies this equation.
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But there is no power of two that will give us a value of negative two.
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This could in fact only be achieved if the base itself was negative.
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So, π sub one is in fact not defined.
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β of negative two then, we say, is undefined.
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Letβs now move on to π₯ equals one.
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β of one in our table will be the value of log base two of one.
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Defining β of one to be equal to π sub two this time, we can equivalently write this relation as two to the power of π sub two equals one.
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To solve this equation, we ask ourselves, what power of two gives an answer of one?
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Well, in fact, the only way for this to be true is if π sub two equals zero.
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Any real number not equal to the power of zero raised to the power of zero will always be one.
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So β of one and the second value in our table is zero.
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Weβre now going to repeat this for π₯ equals two.
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β of two is log base two of two.
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Defining β of two as π sub three, we see that we can represent this relation as two to the power of π sub three equals two.
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So once again, we ask ourselves, what power of two gives two?
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Well, the only power of two that will give us two itself will be one.
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So π sub three, and in fact β of two, is equal to one.
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And so weβve completed the values in our table; they are undefined, zero, and one, respectively.
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We might now look to sketch the graph of this function.
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And to do so, weβll need to work out a few more values.
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And we could, of course, use the same method as before.
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Alternatively, we could simply type these into a calculator.
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Letβs suppose π₯ is equal to four.
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Log base two of four is equal to two.
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Similarly, if π₯ is equal to eight, we get log base two of eight, which is equal to three.
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Now, β of negative two is undefined.
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In fact, the function itself is undefined for any values of π₯ less than or equal to zero.
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So, we have an asymptote here, an asymptote of the line π₯ equals zero or the π¦-axis.
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So, the graph of our function β of π₯ equals log base two of π₯ looks a little bit as shown.
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The domain, we said, is the values of π₯ we can substitute in, and thatβs purely positive real numbers: π₯ is greater than zero or π₯ is contained in the open interval from zero to β.
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We also observe that the graph itself passes through the π₯-axis at π₯ equals one.
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And we can generalize these two properties for graphs of logarithmic functions.
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Consider graphs of the form π¦ equals log base π of π₯, where π is greater than zero and not equal to one.
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They have just one π₯-intercept.
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They pass through the π₯-axis at one.
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In fact, they will also pass through the point π, one.
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In our last example, the graph of π¦ equals log base two of π₯ passes through the point two, one.
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These graphs all have a vertical asymptote given by the π¦-axis or π₯ equals zero.
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Finally, these functions have a domain where π₯ is in the open interval zero to β and a range where the output, the π¦-values, are in the open interval from negative β to β.
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So it looks a little something like this.
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Now, in fact, just as with exponential graphs, the size of π can tell us a little bit more about the function.
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If π is greater than one, then the function itself is increasing.
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And if π is greater than zero or less than one, the function is decreasing.
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Now in fact, we might even look to compare the graph of this function with its inverse, π¦ is equal to π to the power of π₯.
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The graph of π¦ equals π to the power of π₯ looks a little something like this.
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As we might expect when we draw the graph of a function and its inverse, they will be reflections of each other in the line π¦ equals π₯.
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Now this can be a really useful fact if weβre struggling to remember what either graph looks like.
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So now letβs have a look at a question that involves identifying the graph of a logarithmic function.
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Which graph represents the function π of π₯ equals log base five of π₯?
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And we have five graphs to choose from.
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So, letβs begin by inspecting the function weβve been given.
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Itβs a logarithmic function, and it has the general form of the logarithmic function π of π₯ equals log base π of π₯ where, of course, our value of π, which is here five, cannot be equal to one and is greater than zero.
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Now, one of the features we know about this function is that it passes through the π₯-axis at one, but it also passes through the point π, one.
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So weβre looking for a graph which passes through one, zero and five, one.
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We also know that the π¦-axis or the line π₯ equals zero is an asymptote to this graph.
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In other words, the graph of our function approaches the π¦-axis but never actually reaches it.
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And we know that when π is greater than one, the graph itself is purely increasing.
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Itβs increasing over the entire domain of the function.
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Well, in fact, all of our graphs, if we look carefully, are increasing and they all have the π¦-axis as an asymptote.
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So we need to identify which of our graphs pass through the point one, zero and five, one.
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In fact, if we plot each of these points on every single graph, we see that only one graph passes through both points.
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The correct graph, then, is (A).
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Graph (A) represents the function π of π₯ equals log base five of π₯.
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Letβs now identify the graph of a second logarithmic function.
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Which curve is π¦ equals log base three of π₯?
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And then we have a coordinate plane with four individual graphs drawn on it.
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Well, here we have a logarithmic function, a function of the form log base π of π₯, where π is positive and not equal to one.
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One of the properties of this function is that its graph passes through the point one, zero and the point π, one.
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So our graph, since π is equal to three, will pass through one, zero and three, one.
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We also know that if our value of π is greater than one, then the graph is increasing over its entire domain.
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And this is really useful because we can actually disregard options (c) and (d) straightaway.
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We notice that those graphs, whilst they do pass through the point one, zero, are decreasing over their entire domain.
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And so they could be a transformation via reflection of a logarithmic graph or a logarithmic graph with a fractional base.
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But they certainly arenβt the curve of π¦ equals log base three of π₯.
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Finally, we know that all of these curves should have an asymptote given by the line π₯ equals zero or the π¦-axis.
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Well, all of our graphs do have this asymptote.
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We observe that the graphs seem to approach the π¦-axis but never quite reach it.
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So, we need to find the curve then that passes through the point one, zero and three, one.
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We have already shown that all curves pass through the point one, zero, but the only curve that also passes through the point three, one is curve (a).
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So, curve (a) is the graph of the equation π¦ equals log base three of π₯.
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So at this point, weβve considered how to generate a group of ordered pairs using a table of function values, and weβve identified a couple of logarithmic graphs.
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It might be clear, though, that we wonβt always be working with logarithmic functions on their own.
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Sometimes we might be dealing with composite functions or a function of a function.
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In these scenarios, it can be helpful to recall what we know about function transformations to help us identify the relevant graph.
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Letβs demonstrate one such transformation in our next example.
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Which function represents the following graph?
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Is it (A) π of π₯ equals log base four of two π₯?
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(B) π of π₯ equals log base four of π₯.
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Is it (C) π of π₯ equals log base two of two π₯?
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Is it (D) π of π₯ equals log base two of π₯?
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Or is it (e) π of π₯ equals log base eight of π₯?
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Weβll begin by inspecting the graph of the function itself.
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It certainly resembles the graph of a logarithmic function.
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We have a vertical asymptote of the π¦-axis.
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The graph certainly seems to approach this line but never quite reaches it, and the function itself is increasing.
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The domain is values of π₯ greater than zero and the range appears to be all real numbers.
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And so itβs likely that our function is of the form π of π₯ equals log base π of π₯.
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And, in fact, all of the equations that weβve been given are of this general form, although some of them have two π₯ as their argument.
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So one of the things we know about the function π of π₯ equals log base π of π₯ for positive values of π not equal to one is that they pass through the point one, zero and the point π, one.
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By plotting the point one, zero on the graph of our function, we see that it doesnβt actually pass through this point.
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In fact, it passes through the point one-half, zero, so it looks like it could be a transformation of our original function.
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We might then recall that say we have a function π¦ equals π of π₯, the function π¦ equals π of ππ₯, where π is not to be confused with the base in log base π of π₯, gives a horizontal compression but by a scale factor of one over π.
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So, if we had the function π of π₯ equals log base π of π₯, the function π of π₯ equals log base π of two π₯ would be a compression by a scale factor of one-half in that horizontal direction.
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So, this means that our graph could be (A) or (C).
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It could be log base four of two π₯ or log base two of two π₯.
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Letβs choose a point on the curve to deduce whether itβs π of π₯ equals log base four of two π₯ or π of π₯ equals log base two of two π₯.
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We see our curve passes through the point eight, two and the point two, one.
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For due diligence, weβll check both of these coordinates in our individual functions.
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When π₯ is equal to two, the first function, (A), gives us π of two equals log base four of two times two.
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Thatβs log base four of four, which we see is equal to one.
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So, this point satisfies the function π of π₯ equals log base four of two π₯.
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Then, π of eight is log base four of two times eight.
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Thatβs log base four of 16.
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And we know four squared is equal to 16, so this must be equal to two.
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Once again, our second point eight, two satisfies this function, so we can deduce that the function is π of π₯ equals log base four of two π₯.
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Letβs check, though, by substituting two and eight into our second function.
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When π₯ is equal to two, the function is log base two of four, which is two.
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And when π₯ is equal to eight, the function is log base two of 16, which is equal to four.
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Neither point two, two nor eight, four lie on the graph weβve been given, and so we can confirm that it cannot be option (C); itβs (A).
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Weβve now demonstrated how to identify and sketch graphs of logarithmic functions as well as looked at their various transformations.
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So, letβs finish up by recapping some of the key points from the lesson.
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In this lesson, we saw that the logarithmic function is the inverse of an exponential function.
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Itβs of the form π of π₯ equals log base π of π₯, where π is positive and not equal to one.
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Their graphs pass through the point one, zero and π, one.
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They have an asymptote given by the π¦-axis or the line π₯ equals zero, and the value of π can tell us about its shape.
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If π is greater than one, the graph is increasing over its entire domain.
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And if π is between zero and one, it is decreasing.