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http://pluto.huji.ac.il/~mswiener/zvi.html 972-2-588-3049 FRM Zvi Wiener Following P. Jorion, Financial Risk Manager Handbook Financial Risk Management
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http://pluto.huji.ac.il/~mswiener/zvi.html 972-2-588-3049 FRM Chapter 3 Quantitative Analysis Fundamentals of Statistics Following P. Jorion 2001 Financial Risk Manager Handbook
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Ch. 3, HandbookZvi Wiener slide 3 Statistics and Probability Estimation Tests of hypotheses
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Ch. 3, HandbookZvi Wiener slide 4 Returns Past spot rates S 0, S 1, S 2,…, S t. We need to estimate S t+1. Random variable Alternatively we can do
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Ch. 3, HandbookZvi Wiener slide 5 Independent returns A very important question is whether a sequence of observations can be viewed as independent. If so, one could assume that it is drawn from a known distribution and then one can estimate parameters. In an efficient market returns on traded assets are independent.
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Ch. 3, HandbookZvi Wiener slide 6 Random Walk We could consider that the observations r t are independent draws from the same distribution N( , 2 ). They are called i.i.d. = independently and identically distributed. An extension of this model is a non-stationary environment. Often fat tails are observed.
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Ch. 3, HandbookZvi Wiener slide 7 Time Aggregation
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Ch. 3, HandbookZvi Wiener slide 8 Time Aggregation
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Ch. 3, HandbookZvi Wiener slide 9 FRM-99, Question 4 Random walk assumes that returns from one time period are statistically independent from another period. This implies: A. Returns on 2 time periods can not be equal. B. Returns on 2 time periods are uncorrelated. C. Knowledge of the returns from one period does not help in predicting returns from another period D. Both b and c.
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Ch. 3, HandbookZvi Wiener slide 10 FRM-99, Question 14 Suppose returns are uncorrelated over time. You are given that the volatility over 2 days is 1.2%. What is the volatility over 20 days? A. 0.38% B. 1.2% C. 3.79% D. 12.0%
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Ch. 3, HandbookZvi Wiener slide 11 FRM-99, Question 14
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Ch. 3, HandbookZvi Wiener slide 12 FRM-98, Question 7 Assume an asset price variance increases linearly with time. Suppose the expected asset price volatility for the next 2 months is 15% (annualized), and for the 1 month that follows, the expected volatility is 35% (annualized). What is the average expected volatility over the next 3 months? A. 22% B. 24% C. 25% D. 35%
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Ch. 3, HandbookZvi Wiener slide 13 FRM-98, Question 7
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Ch. 3, HandbookZvi Wiener slide 14 FRM-97, Question 15 The standard VaR calculation for extension to multiple periods assumes that returns are serially uncorrelated. If prices display trend, the true VaR will be: A. the same as standard VaR B. greater than the standard VaR C. less than the standard VaR D. unable to be determined
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Ch. 3, HandbookZvi Wiener slide 15 FRM-97, Question 15 Bad Question!!! “answer” is b. Positive trend assumes positive correlation between returns, thus increasing the longer period variance. Correct answer is that the trend will change mean, thus d.
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Ch. 3, HandbookZvi Wiener slide 16 Parameter Estimation Having T observations of an iid sample we can estimate the parameters. Sample mean. Equal weights. Sample variance
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Ch. 3, HandbookZvi Wiener slide 17 Parameter Estimation Note that sample mean is distributed When X is normal the sample variance is distributed
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Ch. 3, HandbookZvi Wiener slide 18 Parameter Estimation For large T the chi-square converges to normal Standard error
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Ch. 3, HandbookZvi Wiener slide 19 Hypothesis Testing Test for a trend. Null hypothesis is that =0. Since is unknown this variable is distributed according to Student-t with T degrees of freedom. For large T it is almost normal. This means that 95% of cases z is in [-1.96, 1.96] (assuming normality).
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Ch. 3, HandbookZvi Wiener slide 20 Example: yen/dollar rate We want to characterize monthly yen/USD exchange rate based on 1990-1999 data. We have T=120, m=-0.28%, s=3.55% (per month). The standard error of the mean is approximately se(m)= s/ T=0.32%. t-ratio is m/se(m) = -028/0.32=-0.87 since the ratio is less then 2 the null hypothesis can not be rejected at 95% level.
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Ch. 3, HandbookZvi Wiener slide 21 Example: yen/dollar rate Estimate precision of the sample standard deviation. se(s) = / (2T) = 0.229% For the null =0 this gives a z-ratio of z = s/se(s) = 3.55%/0.229% = 15.5 which is very high. Therefore there is much more precision in measurement of rather than m.
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Ch. 3, HandbookZvi Wiener slide 22 Example: yen/dollar rate 95% confidence intervals around the estimates: [m-1.96 se(m), m+1.96 se(m)]=[-0.92%, 0.35%] [s-1.96 se(s), s+1.96 se(s)]=[3.1%, 4.0%] This means that the volatility is between 3% and 4%, but we cannot be sure that the mean is different from zero.
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Ch. 3, HandbookZvi Wiener slide 23 Regression Analysis Linear regression: dependent variable y is projected on a set of N independent variables x. - intercept or constant - slope - residual
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Ch. 3, HandbookZvi Wiener slide 24 OLS Ordinary least squares assumptions are a. the errors are independent of x. b. the errors have a normal distribution with zero mean and constant variance, given x. c. the errors are independent across observations.
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Ch. 3, HandbookZvi Wiener slide 25 OLS Beta and alpha are estimated by
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Ch. 3, HandbookZvi Wiener slide 26 Since x and are independent.
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Ch. 3, HandbookZvi Wiener slide 27 Residual and its estimated variance The quality of the fit is given by the regression R- square (which is the square of correlation (x,y)).
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Ch. 3, HandbookZvi Wiener slide 28 R square If the fit is excellent and the errors are zero, R 2 =1. If the fit is poor, the sum of squared errors will beg as large as the sum of deviations of y around its mean, and R 2 =0. Alternatively R2R2
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Ch. 3, HandbookZvi Wiener slide 29 Linear Regression To estimate the uncertainty in the slope coefficient we use It is useful to test whether the slope coefficient is significantly different from zero.
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Ch. 3, HandbookZvi Wiener slide 30 Matrix Notation
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Ch. 3, HandbookZvi Wiener slide 31 Example Consider ten years of data on INTC and S&P 500, using total rates of returns over month. S&P500 INTC
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Ch. 3, HandbookZvi Wiener slide 32 Coeff.EstimateSE T-statP-value 0.01680.0094 1.780.77 1.3490.229 5.90.00 R-square0.228 SE(y)10.94% SE( )9.62% probability
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Ch. 3, HandbookZvi Wiener slide 33 The beta coefficient is 1.35 and is significantly positive. It is called systematic risk it seems that it is greater than one. Construct z-score: It is less than 2, thus we can not say that Intel’s systematic risk is bigger than one. R 2 =23%, thus 23% of Intel’s returns can be attributed to the market.
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Ch. 3, HandbookZvi Wiener slide 34 Pitfalls with Regressions OLS assumes that the X variables are predetermined (exogenous, fixed). In many cases even if X is stochastic (but distributed independently of errors and do not involve and ) the results are still valid. Problems arise when X include lagged dependent variables - this can cause bias.
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Ch. 3, HandbookZvi Wiener slide 35 Pitfalls with Regressions Specification errors - not all independent (X) variables were identified. Multicollinearity - X variables are highly correlated, eg DM and gilden. X will be non invertible, small determinant. Linear assumption can be problematic as well as stationarity.
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Ch. 3, HandbookZvi Wiener slide 36 Autoregression Here k is the k-th order autoregression coefficient.
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Ch. 3, HandbookZvi Wiener slide 37 FRM-99, Question 2 Under what circumstances could the explanatory power of regression analysis be overstated? A. The explanatory variables are not correlated with one another. B. The variance of the error term decreases as the value of the dependent variable increases. C. The error term is normally distributed. D. An important explanatory variable is excluded.
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Ch. 3, HandbookZvi Wiener slide 38 FRM-99, Question 2 D. If the true regression includes a third variable z that influences both x and y, the error term will not be conditionally independent of x, which violates one of the assumptions of the OLS model. This will artificially increase the explanatory power of the regression.
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Ch. 3, HandbookZvi Wiener slide 39 FRM-99, Question 20 What is the covariance between populations a and b: a17141213 b22263129 A. -6.25 B. 6.50 C. -3.61 D. 3.61
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Ch. 3, HandbookZvi Wiener slide 40 FRM-99, Question 20 a-14b-27(a-14)(b-27) 3-5-15 0-10 -24-8 -12-2 -25 Cov(a,b) = -25/4 = -6.25 Why not -25/3??
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Ch. 3, HandbookZvi Wiener slide 41 FRM-99, Question 6 Daily returns on spot positions of the Euro against USD are highly correlated with returns on spot holdings of Yen against USD. This implies that: A. When Euro strengthens against USD, the yen also tends to strengthens, but returns are not necessarily equal. B. The two sets of returns tend to be almost equal C. The two sets of returns tend to be almost equal in magnitude but opposite in sign. D. None of the above.
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Ch. 3, HandbookZvi Wiener slide 42 FRM-99, Question 10 You want to estimate correlation between stocks in Frankfurt and Tokyo. You have prices of selected securities. How will time discrepancy bias the computed volatilities for individual stocks and correlations between these two markets? A. Increased volatility with correlation unchanged. B. Lower volatility with lower correlation. C. Volatility unchanged with lower correlation. D. Volatility unchanged with correlation unchanged.
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Ch. 3, HandbookZvi Wiener slide 43 FRM-99, Question 10 The non-synchronicity of prices does not affect the volatility, but will induce some error in the correlation coefficient across series. Intuitively, this is similar to the effect of errors in the variables, which biased downward the slope coefficient and the correlation.
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Ch. 3, HandbookZvi Wiener slide 44 FRM-00, Question 125 If the F-test shows that the set of X variables explains a significant amount of variation in the Y variable, then: A. Another linear regression model should be tried. B. A t-test should be used to test which of the individual X variables can be discarded. C. A transformation of Y should be made. D. Another test could be done using an indicator variable to test significance of the model.
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Ch. 3, HandbookZvi Wiener slide 45 FRM-00, Question 125 The F-test applies to the group of variables but does not say which one is most significant. To identify which particular variable is significant or not, we use a t-test and discard the variables that do not display individual significance.
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Ch. 3, HandbookZvi Wiener slide 46 FRM-00, Question 112 Positive autocorrelation of prices can be defined as: A. An upward movement in price is more likely to be followed by another upward movement in price. B. A downward movement in price is more likely to be followed by another downward movement. C. Both A and B. D. Historic prices have no correlation with future prices.
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Ch. 3, HandbookZvi Wiener slide 47 FRM-00, Question 112 Positive autocorrelation of prices can be defined as: A. An upward movement in price is more likely to be followed by another upward movement in price. B. A downward movement in price is more likely to be followed by another downward movement. C. Both A and B. D. Historic prices have no correlation with future prices.
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