Descriptive Statistics

1. Spatial Statistics (SGG 2413) Descriptive Statistics Assoc. Prof. Dr. Abdul Hamid b. Hj. Mar Iman Director Centre for Real Estate Studies Faculty of Engineering and Geoinformation Science Universiti Tekbnologi Malaysia Skudai, Johor Spatial Statistics: Topic 3

2. Learning Objectives • Overall: To give students a basic understanding of descriptive statistics • Specific: Students will be able to: * understand the basic concept of descriptive statistics * understand the concept of distribution * can calculate measures of central tendency dispersion * can calculate measures of kurtosis and skewness Spatial Statistics: Topic 3

3. Contents • What is descriptive statistics • Central tendency, dispersion, kurtosis, skewness • Distribution Spatial Statistics: Topic 3

4. Descriptive Statistics • Use sample information to explain/make abstraction of population “phenomena”. • Common “phenomena”: * Association (e.g. σ1,2.3 = 0.75) * Tendency (left-skew, right-skew) * Trend, pattern, location, dispersion, range * Causal relationship (e.g. if X then Y) • Emphasis on meaningful characterisation of data (e.g. central tendency, variability), graphics, and description • Use non-parametric analysis (e.g. 2, t-test, 2-way anova) Spatial Statistics: Topic 3

5. E.g. of Abstraction of phenomena Spatial Statistics: Topic 3

6. Inferential Statistics • Using sample statistics to infer some “phenomena” of population parameters • Common “phenomena”: cause-and-effect • * One-way r/ship * Feedback r/ship * Recursive • Use parametric analysis (e.g. α and ) through regression analysis • Emphasis on hypothesis testing Y = f(X) Y1 = f(Y2, X, e1) Y2 = f(Y1, Z, e2) Y1 = f(X, e1) Y2 = f(Y1, Z, e2) Spatial Statistics: Topic 3

7. Parametric statistics • Statistical analysis that attempts to explain the population parameter using a sample • E.g. of statistical parameters: mean, variance, std. dev., R2, t-value, F-ratio, xy, etc. • It assumes that the distributions of the variables being assessed belong to known parameterised families of probability distributions Spatial Statistics: Topic 3

8. Examples of parametric relationship Dep=9t – 215.8 Dep=7t – 192.6 Spatial Statistics: Topic 3

9. Non-parametric statistics • First used by Wolfowitz (1942) • Statistical analysis that attempts to explain the population parameter using a sample without making assumption about the frequency distribution of the assessed variable • In other words, the variable being assessed is distribution-free • E.g. of non-parametric statistics: histogram, stochastic kernel, non-parametric regression Spatial Statistics: Topic 3

10. Descriptive & Inferential Statistics (DS & IS) • DS gather information about a population characteristic (e.g. income) and describe it with a parameter of interest (e.g. mean) • IS uses the parameter to test a hypothesis pertaining to that characteristic. E.g. Ho: mean income = RM 4,000 H1: mean income < RM 4,000) • The result for hypothesis testing is used to make inference about the characteristic of interest (e.g. Malaysian  upper middle income) Spatial Statistics: Topic 3

11. Sample Statistics: Central Tendency Spatial Statistics: Topic 3

12. Central Tendency – Mean • For individual observations, . E.g. X = {3,5,7,7,8,8,8,9,9,10,10,12} = 96 ; n = 12 • Thus, = 96/12 = 8 • The above observations can be organised into a frequency table and mean calculated on the basis of frequencies = 96; = 12 Thus, = 96/12 = 8 Spatial Statistics: Topic 3

13. Central Tendency - Mean and Mid-point • Let say we have data like this: Price (RM ‘000/unit) of Shop Houses in Skudai Can you calculate the mean? Spatial Statistics: Topic 3

14. Central Tendency - Mean and Mid-point (contd.) • Let’s calculate: Town A: (228+450)/2 = 339 Town B: (320+430)/2 = 375 • Are these figures means? M = ½(Min + Max) Spatial Statistics: Topic 3

15. Central Tendency - Mean and Mid-point (contd.) • Let’s say we have price data as follows: Town A: 228, 295, 310, 420, 450 Town B: 320, 295, 310, 400, 430 • Calculate the means? Town A: Town B: • Are the results same as previously? •  Be careful about mean and “mid-point”! Spatial Statistics: Topic 3

16. Central Tendency – Mean of Grouped Data • House rental or prices in the PMR are frequently tabulated as a range of values. E.g. • What is the mean rental across the areas? = 23; = 3317.5 Thus, = 3317.5/23 = 144.24 Spatial Statistics: Topic 3

17. Central Tendency – Median • Let say house rentals in a particular town are tabulated: • Calculation of “median” rental needs a graphical aids→ • Median = (n+1)/2 = (25+1)/2 =13th. Taman • 2. (i.e. between 10 – 15 points on the vertical axis of ogive). • 3. Corresponds to RM 140-145/month on the horizontal axis • 4. There are (17-8) = 9 Taman in the range of RM 140-145/month 5. Taman 13th. is 5th. out of the 9 Taman 6. The rental interval width is 5 7. Therefore, the median rental can be calculated as: 140 + (5/9 x 5) = RM 142.8 Spatial Statistics: Topic 3

18. Central Tendency – Median (contd.) Spatial Statistics: Topic 3

19. Central Tendency – Quartiles (contd.) Following the same process as in calculating “median”: Upper quartile = ¾(n+1) = 19.5th. Taman UQ = 145 + (3/7 x 5) = RM 147.1/month Lower quartile = (n+1)/4 = 26/4 = 6.5 th. Taman LQ = 135 + (3.5/5 x 5) = RM138.5/month Inter-quartile = UQ – LQ = 147.1 – 138.5 = 8.6th. Taman IQ = 138.5 + (4/5 x 5) = RM 142.5/month Spatial Statistics: Topic 3

20. Variability • Indicates dispersion, spread, variation, deviation • For single population or sample data: where σ2 and s2 = population and sample variance respectively, xi = individual observations, μ = population mean, = sample mean, and n = total number of individual observations. • The square roots are: standard deviation standard deviation Spatial Statistics: Topic 3

21. Variability (contd.) • Why “measure of dispersion” important? • Consider yields of two plant species: * Plant A (ton) = {1.8, 1.9, 2.0, 2.1, 3.6} * Plant B (ton) = {1.0, 1.5, 2.0, 3.0, 3.9} Mean A = mean B = 2.28% But, different variability! Var(A) = 0.557, Var(B) = 1.367 * Would you choose to grow plant A or B? Spatial Statistics: Topic 3

22. Variability (contd.) • Coefficient of variation – CV – std. deviation as % of the mean: • A better measure compared to std. dev. in case where samples have different means. E.g. * Plant X (ton/ha) = {1.2, 1.4, 2.6, 2.7, 3.9} * Plant Y (ton/ha) = {1.4, 1.5, 2.1, 3.2, 3.9} Spatial Statistics: Topic 3

23. Variability (cont.) Calculate CV for both species. CVx = (1.2/2.36) x 100 = 50.97% CVy = (1.2/2.42) x 100 = 49.46%  Species X is a little more variable than species Y Spatial Statistics: Topic 3

24. Variability (cont.) • Std. dev. of a frequency distribution E.g. age distribution of second-home buyers (SHB): Spatial Statistics: Topic 3

25. Probability distribution Logical probability: • If there 20 lecturers, the probability that A becomes a professor is: p = 1/20 = 0.05 • Out of 100 births, half of them were girls (p=0.5), as the number increased to 1,000, two-third were girls (p=0.67) but from a record of 10,000 new-born babies, three-quarter were girls (p=0.75) • The probability of a drug addict recovering from addiction is 50:50 • General rule: No. of times event X occurs Pr (event X) = ------------------------------------- Total number of occurrences • Probability of certain event X to occur has a specific form of distribution Experiential probability: Subjective probability: Spatial Statistics: Topic 3

26. Probability Distribution Classical example of tossing What is the distribution of the sum of tosses? Spatial Statistics: Topic 3

27. Probability Distribution (contd.) Discrete variable Values of x are discrete (discontinuous) Sum of lengths of vertical bars p(X=x) = 1 all x Spatial Statistics: Topic 3

28. Probability Distribution (cont.) Continuous variable Mean = 39.5 Std. dev = 2.45 Pr (Area under curve) = 1 Pr (Area under curve) = 1 Age distribution of second-home buyers in probability histogram Spatial Statistics: Topic 3

29. Probability Distribution (cont.) • Pr (Age ≤ 36) = 0.02 • Pr (Age ≤ 37) = Pr (Age ≤ 36) + Pr (Age = 37) = 0.02 + 0.07 = 0.09 • Pr (Age ≤ 38) = Pr (Age ≤ 37) + Pr (Age = 38) = 0.09 + 0.04 = 0.13 • Pr (Age ≤ 39) = Pr (Age ≤ 38) + Pr (Age = 39) = 0.13 + 0.18 = 0.31 • Pr (Age ≤ 40) = Pr (Age ≤ 39) + Pr (Age = 40) = 0.31 + 0.36 = 0.67 • Pr (Age ≤ 41) = Pr (Age ≤ 40) + Pr (Age = 41) = 0.67 + 0.14 = 0.81 • Pr (Age ≤ 42) = Pr (Age ≤ 41) + Pr (Age = 42) = 0.81 + 0.10 = 0.91 • Pr (Age ≤ 43) = Pr (Age ≤ 42) + Pr (Age = 43) = 0.91 + 0.09 = 1.00 Cumulative probability corresponds to the left tail of a distribution Spatial Statistics: Topic 3

30. Probability Distribution (cont.) Larger sample • As larger and larger samples are drawn, the probability distribution is getting smoother • Tens of different types of probability distribution: Z, t, F, gamma, etc • Most important: normal distribution Very large sample Spatial Statistics: Topic 3

31. Normal Distribution - ND • Salient features of ND: * Bell-shaped, symmetrical * Total area under curve = 1 * Area under curve between any two points = prob. of values in that range (shaded area) * Prob. of any exact value = 0 * Has a function of: μ = mean of variable x; σ = std. dev. of x; π = ratio of circumference of a circle to its diameter = 3.14; e = base of natural log = 2.71828. Spatial Statistics: Topic 3

32. Normal Distribution - ND Population 2 Population 1 2 1 1 2 * A larger population has narrower base (smaller variance) *  determines location while  determines shape of ND Spatial Statistics: Topic 3

33. Normal Distribution (cont.) * Has a mean  and a variance 2, i.e. X  N(, 2) * Has the following distribution of observation: “Home-buyers example…” Mean age = 39.3 Std. dev = 2.42 Spatial Statistics: Topic 3

34. Standard Normal Distribution (SND) • Since different populations have different  and  (thus, locations and shapes of distribution), they have to be standardised. • Most common standardisation: standard normal distribution (SND) or called Z-distribution • (X=x) is given by area under curve • Has no standard algebraic method of integration → Z ~ N(0,1) • To transform f(x) into f(z): x - µ Z = ------- ~ N(0, 1) σ Spatial Statistics: Topic 3

35. Z-Distribution • Probability is such a way that: * Approx. 68% -1< z <1 * Approx. 95% -1.96 < z < 1.96 * Approx. 99% -2.58 < z < 2.58 Spatial Statistics: Topic 3

36. Z-distribution (cont.) • When X= μ, Z = 0, i.e. • When X = μ + σ, Z = 1 • When X = μ + 2σ, Z = 2 • When X = μ + 3σ, Z = 3 and so on. • It can be proven that P(X1 <X< Xk) = P(Z1 <Z< Zk) • SND shows the probability to the right of any particular value of Z. Spatial Statistics: Topic 3

37. Normal distribution…Questions A study found that the mean age, A of second-home buyers in Johor Bahru is 39.3 years old with a variance of RM 2.45.Assuming normality, how sure are you that the mean age is: (a) ≥ 40 years old; (b) 39 to 42 years old? Answer (a): P(A ≥ 40) = P[Z ≥ (40 – 39.3)/2.4] = P(Z ≥ 0.2917 0.3000) = 0.3821 (b) P(39 ≤ A ≤ 42) = P(A ≥ 39) – P(A ≥ 42) = 0.45224 – P[A ≥ (42-39.3)/2.4] = 0.45224 – P(A ≥ 1.125) = 0.45224 – 0.12924 = 0.3230 Use Z-table! Spatial Statistics: Topic 3 Always remember: to convert to SND, subtract the mean and divide by the std. dev.

38. “Student’s t-Distribution” • Similar to Z-distribution (bell-shaped, symmetrical) • Has a function of where  = gamma distribution; v = n-1 = d.o.f;  = 3.147 • Flatter with thicker tails • Distributed with t(0,σ) and -∞ < t < +∞ • As n→∞ t(0,σ) → N(0,1) • Probability calculation requires information on d.o.f. Spatial Statistics: Topic 3

39. How Are t-dist. and Z-dist. Related? • Using central limit theorem, N(, 2/n) will become zN(0, 1) as n→∞ • For a large sample, t-dist. of a variable or a parameter is given by: • The interval of critical values for variable, x is: Spatial Statistics: Topic 3

40. Xi = indivudal sample observation, = sample mean;  = std. deviation; n = sample size Skewness, m3 & Kurtosis, m4 • Skewness, m3 measures degree of symmetry of distribution • Kurtosis, m4 measures its degree of peakness • Both are useful when comparing sample distributions with different shapes • Useful in data analysis Spatial Statistics: Topic 3

41.    Right (+ve) skew Left (-ve) skew Perfectly normal (zero skew)    Bimodal Uniform J-shaped Skewness Spatial Statistics: Topic 3

42. Leptokurtic (high peak) (+ve kurtosis) Mesokurtic (normal) (zero kurtosis) Platykurtic (low peak) (-ve kurtosis) Kurtosis Mesokurtic distribution…kurtosis = 3 Leptokurtic distribution…kurtosis < 3 Platykurtoc distribution…kurtosis > 3 Spatial Statistics: Topic 3

43. Occurrence of ganoderma Occurrence of ganoderma Spatial Statistics: Topic 3

44. Aluminium residues in the soil E.g. Al2++ + H2++O-- → Al2O + H2 Spatial Statistics: Topic 3

45. Weighted mean centre (Xcoord.) = Weighted mean centre (Ycoord.) = Standard distance = Distance(x1,y1) and (x2,y2) = Measures of spatial separation E.g. WCM = ((545.10-542.86)2 + (105.90-105.48)2)0.5 = (5.0176 + 0.1764)0.5 = 2.28 (i.e. 2,280 m) Spatial Statistics: Topic 3

46. Occurrence of ganoderma Spatial distribution – Spatial Statistics: Topic 3

47. Spatial distribution – point data Ethnic distribution of residence Spatial Statistics: Topic 3

48. Ethnic distribution of residence x f fx (x- )2 0 81 0 -0.49 1 50 50 0.51 2 9 18 1.51  140 68 1.54 0.49 s2 0.01 CV 0.02 Reject Ho…residence pattern is scattered sCV 0.12 tc -8.15 Ho: 2 = (pattern is random) H1: 2 > (pattern is clustered) or 2 < (pattern is scattered) X = no. of observations per quadrat; f = frequency of quadrats; = (fx)/f; 2 = (x- )2/(fx) -1; CV = 2/ ; CV = (2/(k-1))½. k = (fx) -1 Test statistics Spatial Statistics: Topic 3