E&G, Ch. 8: Multi-Index Models & Grouping Techniques I. Multi-Index Models.

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1 E&G, Ch. 8: Multi-Index Models & Grouping Techniques I. Multi-Index Models. A. The General Multi-Index Model: R i = a i + b i1 I 1 + b i2 I 2 + + b il I L + c i Explanation: 1. Let I 1 = R m ; I 2 = interest rate; I 3 = industry; 2. b i1 is analogous to β i in Single-Index Model; likewise for other b ik. 3. a i = intercept; part of return, R i, unique to firm i; this is nonrandom. 4. c i = error term; part of return, R i, unique to firm i; this is random variation in R i not due to any I j. By Definition: 1. σ 2 ci = residual variance of stock i (for stock i = 1-N); 2 2. σ Ij = E(I j -I j ) 2 = variance of index j (for index j = 1-L). By Construction: 1. mean of c i = E(c i ) = 0; for any firm i = 1-N; 2. covariance between indexes = E[(I j -I j )(I k -I k )] = 0; for any pair of indexes, j k; j, k = 1-L. 3. covariance of residuals for stock i & index j; E[c i (I j -I j )] = 0; for any firm, i = 1-N, and any index, j = 1-L. By Assumption: 1. E(c i c j ) = 0; for any i, j = 1-N.

2 Consider By Construction 2. 2. covariance between indices = E[(I j -I j )(I k -I k )] = 0; for any pair of firms, i j; Implies different indexes (factors) are uncorrelated. Unrealistic? If we used actual R m and interest rates, Cov(I 1,I 2 ) 0. Fact: Can always construct a new set of indexes, I j, from the original set of indexes (say, I j * ) that are uncorrelated with each other. (See Appendix A.) Don t have to do this; could use actual I j *. However, doing this greatly simplifies: a. computation of risk; and b. selection of optimal portfolios.

3 Expressions for E(R i ), σ i 2, and σ ij (See Appendix B). Expected Return: R i = a i + b i1 I 1 + b i2 I 2 + + b il I L (Result 1) Variance of Return: σ i 2 = b i1 2 σ I1 2 + b i2 2 σ I2 2 + + b il 2 σ IL 2 + σ ci 2 (Result 2) Covariance of Returns for securities i and j: σ ij = b i1 b j1 σ I1 2 + b i2 b j2 σ I2 2 + + b il b jl σ IL 2 (Result 3) Can estimate E(R i ), σ 2 i, & σ ij if we have estimates of: (N) a i ; i = 1-N; (NL) b ik ; i = 1-N stocks, k = 1-L indexes; (N) σ 2 ci ; i = 1-N stocks; (L) E(I k ); k = 1-L indexes; (L) σ 2 Ik ; k = 1-L indexes. Requires (2N + 2L + LN) inputs.

4 B. The Industry Index Model. R i = a i + b im R m + b i1 I 1 + b i2 I 2 + + b il I L + c i where with R m = market index; I j = indexes for industries ( j = 1-L); all indexes constructed to be uncorrelated. 1. Suppose firm i operates mainly in one industry ( j); Assume b ik = 0 for other industries (k j): R i = a i + b im R m + b ij I j + c i for the i th firm in industry j ( j = industries 1-L). Again, each industry index is constructed to be be uncorrelated with R m and the other I k (k j). 2. This assumption implies the same 2-Index Model for all firms within a given industry, and a different 2-Index Model for firms in every other industry.

5 3. Simplifies correlation structure across firms (i & k): For firms in same industry ( j), σ ik = b im b km σ m 2 + b ij b kj σ Ij 2 ; For firms in different industries, σ ik = b im b km σ m 2. Note: If firms in same industry, 2 sources of covariance: common ρ with R m, and common ρ with industry (I j ). If 2 firms in different industries, only 1 source: common ρ with R m. 4. Inputs required: (N) a i ; i = 1-N; (N) b im ; i = 1-N stocks; (N) b ij ; i = 1-N stocks in industry j; (N) σ 2 ci ; i = 1-N stocks; (2) E(R m ) & σ 2 m ; (L) E(I j ); j = 1-L indexes (to compute E(R i ) & σ 2 Ij ); (L) σ 2 Ik ; k = 1-L indexes. Requires (4N + 2L + 2) inputs. (< N(N-1)/2!)

6 C. How Well Do Multi-Index Models Work? (Recall: S-I Model forecasts ρ better than hist. ρ matrix.) 1. Multi-Index Models perform somewhere in between Single-Index Models and Historical Correlation matrix. a. As more indexes are added, more complex, and historical correlation matrix is more closely reproduced. However, this does not imply that future correlation matrices will be better forecast! b. Tests (2 kinds): (1) Statistical Significance Is there improvement in forecasts (vs actuals) that is statistically significant? (2) Economic Significance Is there difference in return or profit to be made using one forecast technique versus another? - Examine future returns from selecting portfolios based on each technique. - From estimates of ρ ij matrix, determine opportunity locus & choose optimal pf s. - Does one set of estimates of ρ ij matrix lead to opportunity locus & pf s that perform better? (i.e., higher E(R p ) at various levels of σ p 2 ).

7 2. Elton & Gruber study. Found: Single-Index Model did better than Multi-Index Model in both (1) & (2). Adding indexes (beyond R m ) got higher R 2 ; i.e., better explanation of historical ρ s. However: (1) led to poorer prediction of future ρ s; (2) led to selection of pf s that tended to have lower returns at each risk level. Implication: The added indexes apparently introduced more random noise than useful info for forecasting. 3. Cohen & Pogue Study. Concentrated on (2) tests of economic significance. Divided stocks into industries using SIC codes. For each industry grouping, then ran: - Single-Index Models (with R m ) - Multi-Index Models (with R m and one I j ). Found (like E&G study): - Multi-Index Models got higher R 2. - BUT Single-Index Model had better properties; led to lower expected risks, & was simpler to use.

8 4. Comment: SIC code classifications may be bad. a. there are many multi-product firms; SIC classification is arbitrary for such firms. b. Companies in same industry may have different operating & risk characteristics. (Not the best grouping technique). 5. Another E&G study, & Farrell study. a. Considered Industry-Index Model again. Instead of SIC classifications, formed their own industry groupings according to tendency of firms to act alike. b. Formed homogeneous groups of firms; i. After removing ρ explained by R m, examine ρ s across residuals. ii. Stocks with highly correlated residuals grouped into pseudo-industry, called I j. iii. Indexes for each pseudo-industry (I j ) then used in Multi-Index Model. c. Found 4 major pseudo-industry groupings: i. growth stocks; ii. cyclical stocks; iii. stable stocks; iv. oil stocks.

9 Farrell study estimated 2-Index Model (R m & I j ) for each pseudo-industry. Results: 1. R m explained 30% of variation in R I ; 2. I j accounted for another 15%. Not surprising; include more variables, explain more of past behavior. Relevant question is how do pseudo-industries: 1. improve forecasts of ρ ij, 2. select portfolios that eventually perform better? Farrell investigated (2) economic significance; 2-Index Model based on pseudo-industries lead to: 1. better performance than Single-Index Models at some risk levels; 2. worse performance at other risk levels. 3. On the whole, Farrell concludes his Multi-Index Model better than Single-Index Model. Caution: 1. Dominance found by Farrell is not complete. 2. Based on one sample of stocks, one time period. 3. A different study (by Fertuck) found that pseudo-industries explained less than SIC groups.

10 II. Grouping Techniques or Avg Correlation Models. Two types, based on extent of aggregation. A. Overall Mean Model. (most aggregated) 1. Given R it ; i = 1,, N stocks; t = 1,, T periods. Compute historical correlation matrix (NxN) (pairwise ρ ij s for all pairs of stocks, i, j = 1,, N; Then average all (N(N-1)/2) pairwise ρ ij s; ρ ij. a. Then ρ ij (avg across all pairwise correlations) is the forecast for each pairwise correlaion, ρ ij. B. Traditional Mean Model. (disaggregated) 1. Assumes there is a common mean correlation within & between groups of stocks (such as traditional or pseudo-industry groupings). 2. Examples: a. avg ρ ij for all i, j within steel ind. (steel ρ ij ). b. avg ρ ij for all i in steel & all j in chemical ind. (steel/chemical ρ ij ).

11 C. Comparison of Performance. Overall Mean Model has been extensively tested against Single- and Multi-Index Models. (1) Statistical Significance of forecast improvement; (2) Economic Significance of stock selection perf. 1. Overall Mean Model (most aggregated). a. Outperforms Single-, Multi-Index Model, and Historical Correlation Matrix in both (1) & (2). b. For (1), improvements in forecast performance almost always signif. @ 5% level. c. For (2), big improvement achieved in performance at most risk levels. ( ed return 25% @ some risk levels!) 2. Traditional Mean Model (disaggregated). a. Based on SIC codes. b. Based on pseudo-industries. Again, Outperforms Single-, Multi-Index Models, and Historical Correlation Matrix in both (1) & (2). However, ranking of 1., 2.a., and 2.b. varies for different risk levels in same time period, and for different time periods. Thus, 2. not always superior to 1.; need more work.

12 D. Mixed Models. 1. Combine attributes of Single-Index Model, Multi-Index Model, & Averaging Techniques. Begin with Single-Index Model to account for covariance due to the Market. Then construct a second model to explain the extra-market covariance. a. S-I Model estimates covariance with R m. E&G, Ch. 7, assumed extra-mkt covariance = 0. E&G, Ch. 8, focuses on other indexes that help explain more of variation in R i. i.e., Multi-Index Models include other indexes of extra-mkt covariance. b. Mixed Models suggest different way to do this. Look at residuals of Single-Index Model; Compute ρ ij s from S-I Model residuals. 2. Rosenberg study (discussed in E&G, Ch. 7). Worked with fundamental β s; related β s to set of firm fundamental data. Here Rosenberg suggests computing the extra-mkt covariance matrix of ρ ij s after removing the mkt s influence i.e., compute ρ ij s from S-I Model residuals. Then regress these ρ ij s (extra-mkt covariance) on (114) firm fundamental variables forecast ρ ij. Results promising more work needed.

13 3. Combine S-I model and Averaging Techniques. a. Instead of averaging raw ρ ij, average the ρ ij computed from residuals of the S-I Model (i.e., the extra-mkt correlations). b. Could do all stocks (i.e., Overall Mean Model); or across firms within traditional industries or pseudo-industries, as well as across such groups (i.e., Traditional Mean Model). c. Then ρ ij could be predicted by combining the predicted ρ ij from the S-I Model with the extra-mkt ρ ij predicted from the avging model. More work needed.

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