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Data Mining (and machine learning)

Data Mining (and machine learning). DM Lecture 3: Basic Statistics and Coursework 1. Communities and Crime. Here is an interesting dataset. -- state: US state (by number) - -- county: numeric code for county -- community: numeric code for community -

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Data Mining (and machine learning)

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  1. Data Mining(and machine learning) DM Lecture 3: Basic Statistics and Coursework 1 David Corne, and Nick Taylor, Heriot-Watt University - dwcorne@gmail.com These slides and related resources: http://www.macs.hw.ac.uk/~dwcorne/Teaching/dmml.html

  2. Communities and Crime Here is an interesting dataset David Corne, and Nick Taylor, Heriot-Watt University - dwcorne@gmail.com These slides and related resources: http://www.macs.hw.ac.uk/~dwcorne/Teaching/dmml.html

  3. David Corne, and Nick Taylor, Heriot-Watt University - dwcorne@gmail.com These slides and related resources: http://www.macs.hw.ac.uk/~dwcorne/Teaching/dmml.html

  4. -- state: US state (by number) - -- county: numeric code for county -- community: numeric code for community - -- communityname: community name – -- fold: fold number for non-random 10 fold cross validation, -- population: population for community: (numeric - decimal) -- householdsize: mean people per household (numeric - decimal) -- racepctblack: percentage of population that is african american (numeric - decimal) -- racePctWhite: percentage of population that is caucasian (numeric - decimal) -- racePctAsian: percentage of population that is of asian heritage (numeric - decimal) -- racePctHisp: percentage of population that is of hispanic heritage (numeric - decimal) -- agePct12t21: percentage of population that is 12-21 in age (numeric - decimal) -- agePct12t29: percentage of population that is 12-29 in age (numeric - decimal) -- agePct16t24: percentage of population that is 16-24 in age (numeric - decimal) -- agePct65up: percentage of population that is 65 and over in age (numeric - decimal) -- numbUrban: number of people living in areas classified as urban (numeric - decimal) -- pctUrban: percentage of people living in areas classified as urban (numeric - decimal) -- medIncome: median household income (numeric - decimal) – -- pctWWage: percentage of households with wage or salary income in 1989 (numeric - decimal) -- pctWFarmSelf: percentage of households with farm or self employment income in 1989 [etc etc etc --- 128 fields altogether] -- ViolentCrimesPerPop: total number of violent crimes per 100K popuation (numeric - decimal) GOAL attribute (to be predicted) David Corne, and Nick Taylor, Heriot-Watt University - dwcorne@gmail.com These slides and related resources: http://www.macs.hw.ac.uk/~dwcorne/Teaching/dmml.html

  5. Mining the C&C data Let’s do some basic preprocessing and mining of these data, to start to grasp whether we can find any patterns that will predict certain levels of violent crime David Corne, and Nick Taylor, Heriot-Watt University - dwcorne@gmail.com These slides and related resources: http://www.macs.hw.ac.uk/~dwcorne/Teaching/dmml.html

  6. etc … about 2,000 instances David Corne, and Nick Taylor, Heriot-Watt University - dwcorne@gmail.com These slides and related resources: http://www.macs.hw.ac.uk/~dwcorne/Teaching/dmml.html

  7. First: some sensible preprocessing The first 5 fields are (probably) not useful for prediction – they are more like “ID” fields for the record. So, let’s remove them. There are many cases of missing data here too – let’s remove any field which has any missing data in it at all. This is OK for the C&C data, still leaving 100 fields. David Corne, and Nick Taylor, Heriot-Watt University - dwcorne@gmail.com These slides and related resources: http://www.macs.hw.ac.uk/~dwcorne/Teaching/dmml.html

  8. First: some sensible preprocessing I downloaded the data. First I converted it to a space-separated form, rather than comma-separated, because I prefer it that way. I wrote an awk script to do this called cs2ss.awk, here: http://www.macs.hw.ac.uk/~dwcorne/Teaching/DMML/cs2ss.awk I did that with this command line on a unix machine: awk –f cs2ss.awk < communities.data > commss.txt Placing the new version in “commss.txt” Then, I wanted to remove the first 5 fields, and remove any field in which any record contained missing values. I wrote an awk script for that too: http://www.macs.hw.ac.uk/~dwcorne/Teaching/DMML/fixcommdata.awk and did this: awk –f fixcommdata.awk < comss.txt > commssfixed.txt David Corne, and Nick Taylor, Heriot-Watt University - dwcorne@gmail.com These slides and related resources: http://www.macs.hw.ac.uk/~dwcorne/Teaching/dmml.html

  9. Normalisation The fields in these data happen to be already min-max normalised into [0,1]; I wondered whether it would also be good to z-normalise the fields. So I wrote an awk script for z-normalisation, and produced a version that had that done http://www.macs.hw.ac.uk/~dwcorne/Teaching/DMML/znorm.awk awk –f znorm.awk < commsfixed.txt > commssfixedznorm.txt In these data, the class value is numeric, between 0 and 1, indicating (already normalized) the relative amount of violent crime in the community in question. To make it easier to find patterns and relationships, I produced new versions of each dataset where the class value was either 0 (low) or 1 (high) – 0 in the cases where it had been <= 0.4, and 1 otherwise. I used an awk script for that too, and did some renaming of files, and ended up with: • commssfixed.txt two-class • commssfixedznorm.txt two-class z-normlalised David Corne, and Nick Taylor, Heriot-Watt University - dwcorne@gmail.com These slides and related resources: http://www.macs.hw.ac.uk/~dwcorne/Teaching/dmml.html

  10. Now, I wonder: how good is 1-NN at predicting the class for these data? If only using fields 20—30 to work out the distance values, the answer is: Unchanged data (in this case, already min-max normalised to [0,1]): 81.1% Z-normalised: 81.5% But note that 81% of the data is class 0 – so if you always guess “0”, your accuracy will be 81.0%. David Corne, and Nick Taylor, Heriot-Watt University - dwcorne@gmail.com These slides and related resources: http://www.macs.hw.ac.uk/~dwcorne/Teaching/dmml.html

  11. Now let’s look at the data in more detail; some histograms of the fields Here is the distribution of values in field 6 for class 0 – it is a “5-bin” distribution. David Corne, and Nick Taylor, Heriot-Watt University - dwcorne@gmail.com These slides and related resources: http://www.macs.hw.ac.uk/~dwcorne/Teaching/dmml.html

  12. Let’s look at the distributions of field 6 for class 0 and class 1 together (% of pop that is Hispanic) David Corne, and Nick Taylor, Heriot-Watt University - dwcorne@gmail.com These slides and related resources: http://www.macs.hw.ac.uk/~dwcorne/Teaching/dmml.html

  13. An aside: similar histograms withclearer messages … David Corne, and Nick Taylor, Heriot-Watt University - dwcorne@gmail.com These slides and related resources: http://www.macs.hw.ac.uk/~dwcorne/Teaching/dmml.html

  14. Field 7 (% of pop aged 12--21) David Corne, and Nick Taylor, Heriot-Watt University - dwcorne@gmail.com These slides and related resources: http://www.macs.hw.ac.uk/~dwcorne/Teaching/dmml.html

  15. Field 8 (% of pop aged 12—29) David Corne, and Nick Taylor, Heriot-Watt University - dwcorne@gmail.com These slides and related resources: http://www.macs.hw.ac.uk/~dwcorne/Teaching/dmml.html

  16. Field 9 (% of pop aged 16—24) David Corne, and Nick Taylor, Heriot-Watt University - dwcorne@gmail.com These slides and related resources: http://www.macs.hw.ac.uk/~dwcorne/Teaching/dmml.html

  17. Field 10 (% of pop aged >= 65 David Corne, and Nick Taylor, Heriot-Watt University - dwcorne@gmail.com These slides and related resources: http://www.macs.hw.ac.uk/~dwcorne/Teaching/dmml.html

  18. Which two fields seem most useful for discriminating between classes 0 and 1? David Corne, and Nick Taylor, Heriot-Watt University - dwcorne@gmail.com These slides and related resources: http://www.macs.hw.ac.uk/~dwcorne/Teaching/dmml.html

  19. Fields 6 and 7 Maybe we will get better 1-NN results using only the important fields? 2 is (most often) too small a number of fields, but anyway … I produced versions of the dataset that had only fields 6, 7 and 100 (these two, and the class field): I then calculated 1-NN accuracy for these. Results: `Unchanged’ version: fields 6 and 7: 70.8% (was 81.1%) Z-normalised: fields 6 and 7: 70.9% (was 81.5%) Not very successful! But I didn’t expect that – working with several more of the important fields would quite possibly give better accuracies, but may take too much time to demonstrate, or do in your assignment. David Corne, and Nick Taylor, Heriot-Watt University - dwcorne@gmail.com These slides and related resources: http://www.macs.hw.ac.uk/~dwcorne/Teaching/dmml.html

  20. Coursework 1 You will do what we just did, for three datasets: Spambase EEG Eye State Urban Land Cover (& MScs / MEngs will do a bit more with the ULC data)

  21. For each dataset (for the ULC dataset only, some extra preparation is needed first) 1. Produce a version of the data set where each non-classfield is min-max normalised (in other words, scaled so that each value is between 0 and 1 (inclusive). 2. Calculate the accuracy of 1-nearest-neighbour classification for your dataset. 3. Generate histograms of the distribution of the first five fields, for each of the two classes. 4. Write 100—200 words describing how the distributions differ between the two classes, and describing what you think are the two most important fields (from those five) for discriminating between the classes. 5. Produce a reduced dataset which contains only three fields: the two you considered most important, and the class field. • Repeat step 2, but this time for the reduced dataset. MScs/MEngs: Producing 2 more versions of the ULC dataset and do extra 1-NN experiments. David Corne, and Nick Taylor, Heriot-Watt University - dwcorne@gmail.com These slides and related resources: http://www.macs.hw.ac.uk/~dwcorne/Teaching/dmml.html

  22. Your report One brief paragraph that tells me how you did it / what tools you used –This will not affect the marks – I would just like to know. The histograms and associated discussions for each of the three datasets A clear display and discussion of all the 1NN results Level 11 students only: Present and discuss the results of PART TWO in one page. If you did any additional work that you think is worth describing, describe and discuss it clearly. Everything must all be done within 5 sides of A4. FULL DETAILS are in the handout, not here

  23. How? What tools? Whatever you prefer: C, Java, Excel, Matlab, … Read what the handout says about ‘How’. Basically: • You don’t have to, but it’s a very good idea to learn to use scripting tools such as awk, • Once you get used to ‘awk’ (or perl, python, etc), you can do complex things with files (e.g. datasets) quickly and easily • This includes things that may be too difficult in Excel, or may take you too long to program and debug in C. Java, etc… David Corne, and Nick Taylor, Heriot-Watt University - dwcorne@gmail.com These slides and related resources: http://www.macs.hw.ac.uk/~dwcorne/Teaching/dmml.html

  24. You should know what Z-normalisation is, so here is a brief lecture on basic statistics, including that David Corne, and Nick Taylor, Heriot-Watt University - dwcorne@gmail.com These slides and related resources: http://www.macs.hw.ac.uk/~dwcorne/Teaching/dmml.html

  25. Fundamental Statistics Definitions • A Population is the total collection of all items/individuals/events under consideration • A Sample is that part of a population which has been observed or selected for analysis E.g. all students is a population. Students at HWU is a sample; this class is a sample, etc … • A Statistic is a measure which can be computed to describe a characteristic of the sample (e.g. the sample mean) The reason for doing this is almost always to estimate (i.e. make a good guess) things about that characteristic in the population David Corne, and Nick Taylor, Heriot-Watt University - dwcorne@gmail.com These slides and related resources: http://www.macs.hw.ac.uk/~dwcorne/Teaching/dmml.html

  26. E.g. • This class is a sample from the population of students at HWU (it can also be considered as a sample of other populations – like what?) • One statistic of this sample is your mean weight. Suppose that is 65Kg. I.e. this is the sample mean. • Is 65Kg a good estimate for the mean weight of the population? • Another statistic: suppose 10% of you are married. Is this a good estimate for the proportion that are married in the population? David Corne, and Nick Taylor, Heriot-Watt University - dwcorne@gmail.com These slides and related resources: http://www.macs.hw.ac.uk/~dwcorne/Teaching/dmml.html

  27. Some Simple Statistics • The Mean (average) is the sum of the values in a sample divided by the number of values • The Median is the midpoint of the values in a sample (50% above; 50% below) after they have been ordered (e.g. from the smallest to the largest) • The Mode is the value that appears most frequently in a sample • The Range is the difference between the smallest and largest values in a sample • The Variance is a measure of the dispersion of the values in a sample – how closely the observations cluster around the mean of the sample • The Standard Deviation is the square root of the variance of a sample David Corne, and Nick Taylor, Heriot-Watt University - dwcorne@gmail.com These slides and related resources: http://www.macs.hw.ac.uk/~dwcorne/Teaching/dmml.html

  28. Distributions / Histograms A Normal (aka Gaussian) distribution (image from Mathworld) David Corne, and Nick Taylor, Heriot-Watt University - dwcorne@gmail.com These slides and related resources: http://www.macs.hw.ac.uk/~dwcorne/Teaching/dmml.html

  29. Statistical moments • The m-th moment about the mean (μ) of a sample is: Where n is the number of items in the sample. • The first moment (m = 1) is 0! • The second moment (m = 2) is the variance • (and: square root of the variance is the standard deviation) • The third moment can be used in tests for skewness • The fourth moment can be used in tests for kurtosis David Corne, and Nick Taylor, Heriot-Watt University - dwcorne@gmail.com These slides and related resources: http://www.macs.hw.ac.uk/~dwcorne/Teaching/dmml.html

  30. Variation and Standard Deviation • The variance of a sample is the 2nd moment Where n is the number of items in the sample. square root of the variance is the standard deviation) David Corne, and Nick Taylor, Heriot-Watt University - dwcorne@gmail.com These slides and related resources: http://www.macs.hw.ac.uk/~dwcorne/Teaching/dmml.html

  31. Distributions / Histograms A Normal (aka Gaussian) distribution (image from Mathworld) David Corne, and Nick Taylor, Heriot-Watt University - dwcorne@gmail.com These slides and related resources: http://www.macs.hw.ac.uk/~dwcorne/Teaching/dmml.html

  32. `Normal’ or Gaussian distributions … • … tend to be everywhere • Given a typical numeric field in a typical dataset, it is common that most values are centred around a particular value (the mean), and the proportion with larger or smaller values tends to tail off. David Corne, and Nick Taylor, Heriot-Watt University - dwcorne@gmail.com These slides and related resources: http://www.macs.hw.ac.uk/~dwcorne/Teaching/dmml.html

  33. `Normal’ or Gaussian distributions … • We just saw this – fields 7—10 were Normal-ish • Heights, weights, times (e.g. for 100m sprint, for lengths of software projects), measurements (e.g. length of a leaf, waist measurement, coursework marks, level of protein A in a blood sample, …) all tend to be Normally distributed. Why?? David Corne, and Nick Taylor, Heriot-Watt University - dwcorne@gmail.com These slides and related resources: http://www.macs.hw.ac.uk/~dwcorne/Teaching/dmml.html

  34. Sometimes distributions are uniform Uniform distributions. Every possible value tends to be equally likely David Corne, and Nick Taylor, Heriot-Watt University - dwcorne@gmail.com These slides and related resources: http://www.macs.hw.ac.uk/~dwcorne/Teaching/dmml.html

  35. This figure is from: http://mathworld.wolfram.com/Dice.html One die: uniform distribution of possible totals: But look what happens as soon as the value is a sum of things; The more things, the more Gaussian the distribution. Are measurements (etc.) usually the sum of many factors? David Corne, and Nick Taylor, Heriot-Watt University - dwcorne@gmail.com These slides and related resources: http://www.macs.hw.ac.uk/~dwcorne/Teaching/dmml.html

  36. Probability Distributions • If a population (e.g. field of a dataset) is expected to match a standard probability distribution then a wealth of statistical knowledge and results can be brought to bear on its analysis • Many standard statistical techniques are based on the assumption that the underlying distribution of a population is Normal (Gaussian) • Usually this assumption works fine David Corne, and Nick Taylor, Heriot-Watt University - dwcorne@gmail.com These slides and related resources: http://www.macs.hw.ac.uk/~dwcorne/Teaching/dmml.html

  37. A closer look at the normal distribution This is the ND with mean mu and std sigma David Corne, and Nick Taylor, Heriot-Watt University - dwcorne@gmail.com These slides and related resources: http://www.macs.hw.ac.uk/~dwcorne/Teaching/dmml.html

  38. More than just a pretty bell shape Suppose mean of your sample is 1.8; and suppose std of your sample is 0.12 Theory tells us that if a population is Normal, the sample std is a fairly good guess at the population std So, we can say with some confidence, for example, that 99.7% of the populationlies between 1.44 and 2.16 David Corne, and Nick Taylor, Heriot-Watt University - dwcorne@gmail.com These slides and related resources: http://www.macs.hw.ac.uk/~dwcorne/Teaching/dmml.html

  39. Remember, MUCH of science relies on making guesses about populations The CLT helps us make the guesses reasonable rather than crazy. Assuming normal dist, the stats of a sample tells us lots about the stats of the population And, assuming normal dist helps us detect errors and outliers – how? David Corne, and Nick Taylor, Heriot-Watt University - dwcorne@gmail.com These slides and related resources: http://www.macs.hw.ac.uk/~dwcorne/Teaching/dmml.html

  40. Z-normalisation (or z-score normalisation) Given any collection of numbers (e.g. the values of a particular field in a dataset) we can work out the mean and the standard deviation. Z-score normalisation means converting the numbers into units of standard deviation. David Corne, and Nick Taylor, Heriot-Watt University - dwcorne@gmail.com These slides and related resources: http://www.macs.hw.ac.uk/~dwcorne/Teaching/dmml.html

  41. Simple z-normalisation example David Corne, and Nick Taylor, Heriot-Watt University - dwcorne@gmail.com These slides and related resources: http://www.macs.hw.ac.uk/~dwcorne/Teaching/dmml.html

  42. Simple z-normalisation example Mean: 11.12 STD: 5.93 David Corne, and Nick Taylor, Heriot-Watt University - dwcorne@gmail.com These slides and related resources: http://www.macs.hw.ac.uk/~dwcorne/Teaching/dmml.html

  43. Simple z-normalisation example Mean: 11.12 STD: 5.93 subtract mean, so that these are centred around zero David Corne, and Nick Taylor, Heriot-Watt University - dwcorne@gmail.com These slides and related resources: http://www.macs.hw.ac.uk/~dwcorne/Teaching/dmml.html

  44. Simple z-normalisation example Mean: 11.12 STD: 5.93 subtract mean, so that these are centred around zero Divide each value by the std; we now see how usual or unusual each value is David Corne, and Nick Taylor, Heriot-Watt University - dwcorne@gmail.com These slides and related resources: http://www.macs.hw.ac.uk/~dwcorne/Teaching/dmml.html

  45. The take-home lesson (for those new to statistics) Your data contains 100 values for x, and you have good reason to believe that x is normally distributed. Thanks to the Central Limit Theorem, you can: • Make a lot of good estimates about the statistics of the population • Make justified conclusions about two distributions being different (e.g. the distribution of field X for class 1, and the distribution of field X for class 2) • Maybe find outliers and spot other problems in the data David Corne, and Nick Taylor, Heriot-Watt University - dwcorne@gmail.com These slides and related resources: http://www.macs.hw.ac.uk/~dwcorne/Teaching/dmml.html

  46. Next week – a bit more statscorrelation / regression David Corne, and Nick Taylor, Heriot-Watt University - dwcorne@gmail.com These slides and related resources: http://www.macs.hw.ac.uk/~dwcorne/Teaching/dmml.html

  47. The Central Limit Theorem is this: As more and more samples are taken from a population the distribution of the sample means conforms to a normal distribution • The average of the samples more and more closely approximates the average of the entire population • A very powerful and useful theorem • The normal distribution is such a common and useful distribution that additional statistics have been developed to measure how closely a population conforms to it and to test for divergence from it due to skewness and kurtosis David Corne, and Nick Taylor, Heriot-Watt University - dwcorne@gmail.com These slides and related resources: http://www.macs.hw.ac.uk/~dwcorne/Teaching/dmml.html

  48. Skew: how much it’s like this: See: http://mvpprograms.com/help/mvpstats/distributions/SkewnessKurtosis

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