WEBVTT Kind: captions; language: en-us

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In this video, we will begin to talk about how we can deal with variability and in particular how to 

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derive a summary estimate from variable data. First of all, let us talk about a very important word 

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that will hear many times in the context of Statistics, the word error. This word doesn't mean what 

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it usually means in everyday communication. In the context of statistics when

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we talk about error, we usually mean some form of variability and usually about unwanted 

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variability. That is otherwise known as noise. Error may also mean the difference from some assumed 

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true value, which is unknown to us. There can be systematic error in which case it is also called 

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bias. 

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Error generally can mean uncertainty lack of confidence. Variability is always associated with 

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uncertainty. 

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Error often means difference from a prediction. If we have a model to predict some values and we 

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have some actual observed values, then the difference between these two is the prediction error or 

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the residual error. Whatever is left over after we're done predicting. The important thing here is 

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that error does not mean mistake. 

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Error means that our values are different from one another, different from what we want, or different 

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from what we predict. 

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To illustrate the ubiquity of error, when I was teaching statistics in an actual classroom I would 

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ask for six volunteers students in the beginning of the first class. And I would ask one of them to 

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stand out, give a measuring tape to the others and ask them to measure the height of the one brave 

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volunteer. So, each person would take the measuring tape go on and measure the 

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of the one designated person. Write down measurement on a piece of paper without announcing it fold 

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the paper so that it is not visible. And then the next person would do the same thing and on and on. 

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This is the result from 2019. These are the actual writings of the five students who wrote down the 

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height of one person measured in class. So we get these five 

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numbers, that are supposed to be the height of the same person measured at the same time in the 

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same place with the same instrument and you may be thinking that something is wrong. But this is 

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actually what always happens. These are the numbers from the year before. So we have five values for 

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person A's height and five values for person B's height. This kind of variability, which is known as 

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measurement error. 

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is very common. In fact, it's always happened. Every year. I've taught a class like this and it's a 

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very robust effect. If you think it's weird, you can ask five of your friends to do it and see it 

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for yourself. So this is the reality, reality is variability. And this raises an important question 

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that needs a principled and justified answer. And the question is, what is the person's height? 

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Of course, there is also the sobering consideration that in real life if you wanted to measure 

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someone's height you would only measure it once, which is like having only one of these five 

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numbers and not having the others. This prevents you from realizing that there is actually error 

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associated with your measurement. But if you repeat it several times, then the error just shows up 

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and you realize that no estimate is free from variability. 

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So what are we supposed to answer when someone asks, what is this person's height? 

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We need an answer, obviously based on the observations the data we have and these are the data we 

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have. How are we supposed to choose from these? What makes a good answer? 

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We could use in statistical criterion, which is to minimize error, in the sense of making the 

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smaller error or make smaller distance from the actual true height, but we don't know what 

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the true height is. So this is kind of a theoretical definition. In statistics we can actually find 

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out actually the mathematicians can find out for us, which procedure based on these data will give 

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us answers that are 

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as close as possible to the actual value using models. We're not going to do that. But it's good 

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to have in mind that we need to understand what we mean by a good answer before we can begin to 

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think about giving one. 

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Let us now see some common ways to produce summary answers from a set of data like this. 

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The simplest approach is democracy. Let them vote. So each value gets as many votes as the times 

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it appears in the data set. In this case we find the value that occurs most often. That's the value 

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162 centimeters and this is called the mode. The value that happens most often in the data set. 

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Unfortunately, there is one complication with the mode and that's that there may not be one value 

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that seem most often. For example, the measurement from 2019 for this same class exercise where the 

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numbers you saw before which have 172 twice and 171 twice. In this case there is no mode. 

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Another approach is to first sort the observations from smallest to largest. 

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So these are the numbers we obtained and we just put them in order. So this is the smallest 

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value, progressively going on  

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to the largest value. 

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And then pick the one in the middle and that is called the median. 

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Finally, the third approach one that you are certainly familiar with. Is to allow all values to 

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influence our answer in the same way. So, if we have these five observations, what we can do is to 

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add them up. 

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And divide by how many they are. 

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And this is the mean and it symbolized with this Greek letter ¦Ì. You already know how to do this. 

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The issue that arises with the mean is what happens if some values are not as good as other values. 

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I'm going to give you an example of what it what I mean with that. 

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So our original observations, these numbers have produced the indices we have already discussed: 

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the mode, the median and the mean. 

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And as you see these three possible answers are very close to each other. But now, let us imagine 

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that one of the five students actually made a mistake, the tape slipped, and instead of reporting 

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this value. We got this one. 

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But we don't know that a mistake was made. All we have are these five numbers to work with. So if we 

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just calculate the same indices, the mode is again, 162. The median is again, 162. The mean is now 

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almost 163, that's quite a bit higher than the previous one. So, what happened with the mean is it 

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was most affected by the occurrence 

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of a problem in the measurement process. And if we weren't aware of this mistake, and we're just 

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using the numbers as if everything was fine, then we would, we would, this would result in a biased 

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estimator, miss estimation of the height of this person using the mean. 

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Another example of a problem that can arise with the mean. Let's imagine that you have applied for a 

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summer job. And then you visited the place that you have applied to and you found five people 

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working there and you ask them how much they earn. You're interested to know what your salary maybe, 

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as you consider the possibility of working there. 

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So let's assume you asked everyone you saw there and they all answered truthfully and you got these 

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not these answers. 

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These are five numbers from five people. 

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The mode for these numbers is not defined because no value appears twice. 

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The median is 160. 

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And the mean is 222 kroner per hour. 

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How much would you expect to be paid based on these data? 

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Well, if you take up the job, you will realize that one of the five people that you asked actually 

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was the boss. So, this number is a different kind of number from all of these. They're not all 

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measuring the same thing. They hourly wage of an employee. Like the one that you would be. 

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So, by allowing the mean to be influenced equally by all the answers, you have, you have produced 

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an estimate of how much you would be paid using the procedure of the mean that is actually not a 

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good one. 

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So the mean which generally happens to have good properties and we tend to use it all the time for 

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very good reason, also comes with some assumptions and some issues. You need to be aware of. 

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All these things that we have talked about, are called indices of central tendency. Because they are 

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estimates of where the center of our observations might be, like, the center being 

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a value that would be reasonable to consider as the answer based on all of the observations, taken 

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together. The mode that we saw first can be used even with nominal level variable. So 

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nominal scales of measurement can be used with categorical variables because it only requires you to 

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count the values and you can always count how many labels you have in a categorical variable. 

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One difficulty with the mode is that it may not be defined if there is not one value that is more 

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frequent than all the others. But otherwise the mode can be very useful. The second index of central 

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tendency is the median. The median can be used for ordinal level data and above. As long as you can 

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rank your data. You can produce a median. 

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The median, like the mode, is a value from the data set. Not actually the median for the median, 

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that's only true if there is an odd number of measurements, in which case, the middle one 

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exist. If there is an even number, you have to do something about the two middle ones. And that's 

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easier to decide when their numbers done where their levels of an ordinal variable. 

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A very desirable property of the median is that is generally stable and it's not easily fooled 

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by having values that are far off, due to problems. Values that are distant from the others are 

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called outliers, as they lie outside the distribution of the rest. 

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And the third index of central tendency that we saw is the mean. The mean requires numbers to be 

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calculated on. So it can only be used for interval, or ratio level data. That is only with numeric 

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or quantitative variables. The mean produces a value that may not actually appear in the data, so 

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you can have a mean value of children per family be 2.5. 

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Although no family ever has 2.5 children. 

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And the mean has some difficulties in the sense that it depends on assumptions for where the data 

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points come from, and how they are distributed. So what are we supposed to choose then? What is 

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the best answer about this person height or about situations, when we have some set of data and need 

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one summary estimate from them? 

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What is the most appropriate statistic for the set? 

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Unfortunately different cases require different answers. So this is why you need to understand the 

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properties and assumptions of the different indices. So we can choose wisely which one to use in 

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each case. 

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For numeric that is quantitative variables. We usually use the mean and the mean is known to 

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minimize the error in the long term. That is, if you always use the mean to produce this kind of 

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answers. In the long run this will lead you to make the least error that is to be least distant from 

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the right answers. 

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However, the mean needs to be used with caution.