first bibliography on the general agreement on trade and services
TRANSCRIPT
Anthony W. LynchNew York University
Richard R. MendenhallUniversity of Notre Dame
New Evidence on Stock PriceEffects Associated with Changesin the S&P 500 Index*
I. Introduction Since October 1989,Standard and Poor’s
Papers investigating Standard and Poor’s 500 has (when possible) an-nounced changes inStock Index (S&P 500) composition changesthe composition of theover the 1976–88 period find a change-day posi-S&P 500 index 1 weektive (negative) abnormal return of approximatelyin advance. Because in-3% (1.5%) for additions (deletions).1 During this dex funds hold S&P
period it was S&P’s policy to announce and im- 500 stocks to minimizetracking error, indexplement changes in the composition of the indexcomposition changessimultaneously. Their policy since October 1989,since this date providehowever, has been (whenever possible) to an-an opportunity to exam-nounce changes 1 week prior to their imple- ine the market reactionto an anticipatedchange in the demand
* We are very grateful to Standard and Poor’s Corporation for a stock. Usingfor providing data that made this research possible. We have post–October 1989benefited from helpful discussions with Yakov Amihud, Ste- data, we document sig-phen Brown, and Robert Schwartz and from the valuable com- nificantly positive (neg-ments of John Affleck-Graves, Pierluigi Balduzzi, Larry
ative) postannounce-Brown, Ned Elton, Silverio Foresi, Antti Ilmanen, Kose John,ment abnormal returnsJohn Liew, David Musto, Cathy Niden, Eli Ofek, Ross Stevens,that are only partiallyDavid Yermack, and seminar participants at New York Univer-
sity. The comments of an anonymous referee and the editor reversed following ad-(Doug Diamond) greatly improved the paper. The able research ditions (deletions).assistance of Tania Vital-Ahuja is also acknowledged. This re- These results indicatesearch was started when Mendenhall was a visiting faculty the existence of tempo-member at New York University. rary price pressure and
1. For deletions, see Goetzmann and Garry (1986) who ex- downward-slopingamined the seven deletions on November 30, 1983 (caused bylong-run demandthe breakup of AT&T), and Harris and Gurel (1986) who exam-curves for stocks andined the 1978–83 period (13 stocks). For additions, again seerepresent a violation ofHarris and Gurel (1986) (84 stocks); Shleifer (1986), who ex-
amined the 1976–83 period (102 stocks); and Dhillon and market efficiency.Johnson (1991), who examined the 1978–88 period (187stocks).
(Journal of Business, 1997, vol. 70, no. 3) 1997 by The University of Chicago. All rights reserved.0021-9398/97/7003-0002$02.50
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mentation. This article analyzes price and volume data for firms addedto or deleted from the S&P 500 from March 1990 through April 1995.
For additions, we find a significant positive announcement day ab-normal return. We also find a positive cumulative abnormal return of3.807% over the period starting the day after the announcement andending the day before the effective date of the change. Further, we findsignificant negative abnormal returns following the addition itself. Thepattern of price movements for deletions is very similar but inverted.That is, returns are significantly negative between announcement anddelisting and significantly positive following delisting.
Our results are interesting for a number of reasons. First, they canbe interpreted in the context of the efficient market hypothesis (seeFama [1970, 1991] for a detailed discussion of the theory and evidencepertaining to market efficiency). The significant abnormal returns fol-lowing the announcement date are inconsistent with semi–strong formmarket efficiency. It would have been possible for investors, using onlypublicly available information, to construct trading rules that earnedeconomically significant abnormal returns. This result can be con-trasted with studies examining the pre–October 1989 period, whichfind no significant daily abnormal returns following the announcement.Thus, while the pre–October 1989 results do not violate semi–strongform efficiency, those presented here clearly do.2
Second, the price reversal on and after the effective date of the indexchange indicates a significant temporary stock-price effect prior to thechange. The price reversal that we document is consistent with heavyindex-fund trading around the time of the change that moves stockprices temporarily away from their equilibrium values (the price-pres-sure hypothesis). This behavior is plausible since the managers of indexfunds are typically evaluated on the basis of their ‘‘tracking error’’ orthe difference between their fund’s return and the return on the indexover any period. This price reversal is also strong evidence that thepostannouncement-day abnormal returns do not simply represent aslow adjustment to any value-relevant information contained in S&P’sannouncement.
In contrast, the pre–October 1989 studies find no indication of ashort-run price reversal, and their evidence regarding the existence ofa longer-term reversal is mixed.3 The lack of a temporary effect beforeOctober 1989 is also consistent with index funds’ concern with tracking
2. Goetzmann and Garry (1986) provide some evidence that investors speculated onstocks to be dropped from the S&P 500 index at the time of the AT&T breakup. Theyfind, however, that these efforts did not earn abnormal returns.
3. Harris and Gurel (1986) find that the price effect on the announcement/change dateis gradually but completely reversed in the period after addition or deletion. Shleifer (1986)and Dhillon and Johnson (1991) find that the price effect is permanent. Dhillon and Johnsonargue that Harris and Gurel’s finding may be specific to their method of risk adjustment.
Stock Price Effects 353
error. Before this date, index funds could not buy an added stock untilafter it had become part of the index. Any price premium paid by anindex fund prior to October 1989, therefore, generated a negative ex-pected tracking error. Index funds would be motivated, therefore, todelay trading (and perhaps to break up their orders) to avoid payingsuch a premium. However, a trade-off was involved since trading laterexposed them to tracking error associated with not holding the already-added stock. Since October 1989, index funds have been able to pur-chase added stocks prior to their entering the index. Any price premiumpaid by index funds just prior to the change has no impact on expectedtracking error since the stock enters the index at the inflated price.Hence, index funds, post–October 1989, are prepared to pay a premiumto be able to buy an added stock just prior to its addition. Thus, indexfunds’ concern with tracking error explains why a price reversal is onlyobserved after October 1989.
Third, the finding of a significant temporary effect for additions aswell as deletions is relevant to results reported in the block-trade litera-ture. In particular, researchers studying block trades consistently finddifferent temporary effects for buyer- versus seller-initiated blocks;seller-initiated blocks induce significant temporary price effects whilebuyer-initiated blocks do not (see Holthausen, Leftwich, and Mayers1990; Chan and Lakonishok 1993; and Keim and Madhavan 1996).Any explanation for this asymmetry must also be able to explain theobserved symmetry in temporary effects that we observe.
One hypothesis that has been advanced to explain the block-tradeasymmetry is broker reluctance to take a short position to accommodatea block purchase. According to ‘‘street wisdom,’’ this reluctance resultsin a lack of intermediary involvement and no temporary effect for mostbuyer-initiated block trades (see Holthausen, Leftwich, and Mayers1990; and Chan and Lakonishok, 1993). Unless brokers are more in-clined to short stocks being added to the S&P 500 than they are toshort other stocks, our results are inconsistent with this explanation forthe block-trade asymmetry.
Fourth, the permanent price effect (excluding the announcement-dayabnormal return) is found to be weakly positive for additions and sig-nificantly negative for deletions. This finding provides new evidencein support of downward-sloping long-run demand curves for stocks(downward-sloping demand hypothesis).
Shleifer (1986) and Harris and Gurel (1986) were the first papers torecognize that a permanent price response associated with addition to ordeletion from the index is consistent with stocks possessing downward-sloping demand curves. As firms enter the S&P 500, index-fund buyingremoves a substantial fraction of the firm’s shares from circulation.This demand by index funds reduces the stock’s supply for nonindexinginvestors, causing the market clearing price to increase. For deletions,
354 Journal of Business
analogous logic predicts a price decrease. If long-term demand curvesfor stocks were horizontal, no permanent price effect would be ex-pected.
However, there are other explanations for the permanent price effectdocumented for pre–October 1989 changes. The price movement couldbe due to the information content of S&P’s addition and deletion an-nouncements (the information hypothesis). For these announcementsto have information content, S&P must have nonpublic informationabout firms and use this information to determine the composition ofthe index.4 Alternatively, if S&P 500 inclusion affects stocks’ liquidity,then this should have pricing implications (the liquidity hypothesis).Specifically, if being a member of the S&P 500 increases a stock’sliquidity, then there should be a price increase (decrease) upon the an-nouncement of addition (deletion; see Amihud and Mendelson 1986,1993).5
The post–October 1989 price patterns that we present are able todisentangle these effects. While the significant announcement-day ab-normal return (for additions and deletions) is consistent with all threehypotheses, the permanent price shift that we find after the announce-ment date is only consistent with downward-sloping long-run demandcurves for stocks. Assuming the response to any value-relevant infor-mation in S&P’s announcement or to perceived liquidity changeswould occur on the announcement day (as implied by an informa-tionally efficient market), the postannouncement price shift cannot beexplained by either of these two hypotheses.
Finally, we examine trading volume around the time of the an-nouncement and around the time of the index change. Consistent withindex-fund managers attempting to minimize tracking error by tradingimmediately prior to the index change, the largest volume occurs onthe day prior to the index modification. For example, for both additionsand deletions, the fraction of shares traded on the day prior to thechange is more than three times as great as that on the announcement
4. The information hypothesis is supported by Jain (1987), who observes significantstock-price movements when firms are added to (or deleted from) S&P auxiliary indexes(which are not mimicked by index funds), as well as by Dhillon and Johnson (1991), whoexamine the option and bond returns of firms being added to the S&P 500. Both Shleiferand Harris and Gurel discredit the information hypothesis using indirect arguments. Harrisand Gurel cite investors’ lack of interest in discovering index changes prior to September1976 (when S&P’s early notification service began) even though that information wasreadily available. Shleifer finds that firms with lower-rated debt (by S&P) do not have astronger addition-day response than those with higher-rated debt.
5. Although not a proponent of the liquidity hypothesis, Shleifer (1986) raises the possi-bility that inclusion in the index may lead to closer scrutiny of the company by analystsand investors. This, in turn, may lead to greater institutional interest, greater trading vol-ume, and lower bid-ask spreads. Harris and Gurel (1986) and Edmister et al. (1995), study-ing pre–October 1989 data, do find evidence of a permanent increase in trading volumefollowing S&P 500 inclusion.
Stock Price Effects 355
date, which also exhibits large volume relative to the preannouncementperiod.
It is beyond the scope of this article to develop in detail the theoreti-cal underpinnings of the various hypotheses described above. However,the empirical results presented here may facilitate their rigorous devel-opment. We leave that task to future work. The next section describesthe data and the research method used in this study, while Section IIIdiscusses the empirical implications of the four hypotheses describedabove and our results. Section IV offers a summary and a conclusion.
II. Data and Methodology
A. The Sample
We asked Standard & Poor’s Corporation to supply us with data, in-cluding announcement dates and effective change dates, on the changesto the S&P 500 since October of 1989. They were able to furnish uswith the 71 additions and deletions that occurred from March 1990through April 1995. Daily stock returns are obtained from the Centerfor Research in Security Prices (CRSP) for the pre-1994 period andfrom Bloomberg after that time. For the pre-1994 period, the CRSPvalue-weighted index of New York Stock Exchange–American StockExchange (NYSE-AMEX) stocks is used as the market portfolio inabnormal return calculations. After the end of 1993, the daily return onthe S&P 500 (obtained from Bloomberg) is used as the market return.
From the original sample of additions and deletions, we construct a‘‘complete’’ sample and a ‘‘clean’’ sample. To construct the completesample, observations were eliminated from the original sample for sev-eral reasons. First, we were unable to obtain announcement dates fromS&P for three additions and three deletions. Second, we required thatuseable return data be available for at least 1 day over the event studywindows. This constraint reduced the addition (deletion) sample bythree (five). Finally, since this study relies on a separation between theannouncement and change days, 10 observations from both the additionand deletion samples were omitted because the announcement did notprecede the change date by at least 2 days.6 The complete additionssample consists of 55 firms and the complete deletions sample consistsof 53 firms.
There are two points to note regarding this complete sample. Thefirst is that it includes some observations for which the index change
6. When a firm files for bankruptcy, it is S&P’s policy to announce, after the close oftrading on that day, that it is deleted from the index effective immediately. Seven of thecases failing to qualify for lack of separation between announcement and effective changedate (both additions and deletions) were attributable to the deletion firm declaring bank-ruptcy.
356 Journal of Business
does not lead to trading by index funds.7 Including these firms will tendto dampen any price effects associated with index-fund trading. Thesecond is that unrelated merger and spin-off activity around the timeof the announcement and change will add noise to the abnormal returns.In an effort to build ‘‘clean’’ samples of additions and deletions thatminimize these concerns, we eliminated any firm undergoing mergeror spin-off activity at the time of the announcement. Since market par-ticipants would be expected to know which firms were undergoing suchactivity, the implication is that our ‘‘clean’’ samples could be formedusing information available at the time of the announcement. To formthe clean sample, a firm was deleted from the complete sample if anymention of announcement date merger or spin-off activity was reportedin the Dow Jones News Retrieval Service, the Wall Street Journal orthe 1991–94 issues of the S&P 500 Directory.8 The clean additionssample contains 34 firms (9 mergers and 12 spin-offs are eliminatedfrom the complete sample) and the clean deletions sample contains 15firms (34 mergers and 4 spin-offs are eliminated).
Another concern is the impact of survivorship (see Brown et al.[1992] and Brown, Goetzmann, and Ross [1995] for discussions aboutthe effects of survivorship bias). In particular, S&P sometimes an-nounces that a change is conditional on approval of a corporate restruc-turing plan by a company’s shareholders. Such approval may not beindependent of the share price behavior of the sample firm, inducinga type of survivorship bias into the sample. This source of survivorshipbias is, however, eliminated for the clean sample since any firm under-going a merger or other restructuring activity at the time of the an-nouncement is omitted.
More generally, survivorship may still affect the abnormal returnpoint estimates if the probability of surviving is related to the criteriaused to form the sample (see Brown and Pope [1995] for a furtherdiscussion).9 However, it seems unlikely that survivorship can explainthe magnitude of the abnormal returns observed (a 0.79% abnormalreturn per day between announcement and the change day for cleanadditions) or their patterns (which include reversals).
7. For example, on May 6, 1991, USX Corp split into USX–Marathon Group and USX–U.S. Steel Group. On that day, USX Corp was deleted from the S&P 500 and the twonew firms were added. However, index funds would not trade since their shares in USXCorp would be converted into shares in the two new firms.
8. It seems unlikely that a firm in the S&P 500 or one large enough to be added to theindex could be undergoing merger or spin-off activity unreported in any of these threesources.
9. For example, the abnormal returns of the clean additions sample may be affected bysurvivorship if the probability of surviving conditional on being added to the S&P 500and not being associated with any merger activity differs from the unconditional probabilityof surviving.
Stock Price Effects 357
B. Methodology
We use an event-study methodology with two event dates for eachsample: the announcement date of the addition/deletion (AD) and theeffective date of the addition/deletion (CD). Since S&P typically an-nounce changes after the close of trading on a particular day, the fol-lowing day is taken as the announcement day (AD). Since the changeis implemented using the closing price of a particular day, the followingday is taken as the change day (CD).
Abnormal return calculation. The abnormal return for stock i onday τ [AR i(τ)] is defined as the deviation of the stock’s raw returnfrom that of the market. The sample mean abnormal return (MAR) forevent day τ is used as a measure of the abnormal price movement onthat day. We are also interested in determining the abnormal returnover windows whose lengths sometimes vary across firms, for example,the total abnormal return from being added to or deleted from theS&P 500. A stock’s cumulative abnormal return over the window fromτ1 to τ2 is calculated by summing the stock’s abnormal returns overthat window and is denoted CAR(τ1, τ2). The stock’s average abnormalreturn over the window, AAR(τ1, τ2), is the stock’s CAR(τ1, τ2) di-vided by the number of days in the window.
Two measures of the abnormal return over a window of interest (τ1,τ2) are obtained by taking sample averages of firm CARs and firmAARs. These averages are designated as MCAR(τ1, τ2) and MAAR(τ1,τ2), respectively, and are both weighted sums of the ARs in the window.If the window’s length varies across firms, however, the relativeweights assigned by each differ. MCAR gives the same weight to everyAR in the window while MAAR places a greater weight on the ARsof firms for whom the window is short. Consequently, MAAR (MCAR)has greater power when the abnormal performance is concentrated inshort (long) window firms.10
Clearly, more sophisticated models of the return generating processcan be used to calculate abnormal returns. However, the results ob-tained using the market model are very similar to those reported hereusing market-adjusted returns.11 The market model abnormal returnsfor additions (deletions) tend to be slightly less positive (negative) onaverage than market-adjusted returns, possibly reflecting the bias in the
10. When the number of days in the window is the same for all firms, only MCAR isreported since MAAR is just a scalar multiple of MCAR and the associated t-statistics arethe same for both.
11. Since index additions (deletions) are likely to have performed well (poorly) just priorto the change, using daily returns over this period to estimate market model parameters mayproduce upwardly (downwardly) biased alpha estimates. For this reason, the market modelis estimated using returns from 872 to 673 days prior to the announcement day (requiringat least 100 nonmissing daily returns).
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estimated alphas discussed in note 11. Even so, inferences are rarelyaffected. Any material differences are mentioned in the results section.
Abnormal volume calculation. Volume data are obtained fromCRSP for those firms added to or deleted from the S&P 500 up toDecember 1994. The measure of volume that we employ is defined asfollows:12
υ i(τ) 5 log[1 1 Vi(τ)]/log[1 1 Ei(τ)], (1)
where Vi(τ) is dollar volume on day τ for stock i, and Ei(τ) is the dollarvalue of the outstanding shares on stock i on day τ. This volume mea-sure approximates the dollar trading volume expressed as a fraction ofthe value of stock outstanding.13
Abnormal value (AV) is estimated using a procedure from Ajinkyaand Jain (1989).14 We begin by regressing the firm’s transformed vol-ume on that of the market:
υ i(τ) 5 φ0, i 1 φ1, iυM(τ) 1 ei(τ)
for τ 5 AD 2 258, . . . , AD 2 109,(2)
where υM(τ) is log[1 1 VM(τ)]/log[1 1 EM(τ)] and the market is repre-sented by all NYSE-AMEX stocks on the CRSP. A firm is omitted ifit has missing volume data over the 150-day estimation period. Ajinkyaand Jain find that the residual from this regression is AR(1) for U.S.equities and use an estimated generalized least squares (EGLS) proce-dure to estimate the regression coefficients.15 Since the events consid-ered here are likely to involve a sequence of days with abnormal vol-ume, abnormal volume is estimated treating the lagged residual asbeing equal to its unconditional value of zero, as discussed in Ajinkyaand Jain (1989). Thus, the abnormal volume for firm i on date τ is16
AV i(τ) 5 υ i(τ) 2 [φ0, i 1 φ1, i υM(τ)]. (3)
12. In the numerator of the volume measure, 1 is added to the dollar volume of sharestraded to accommodate zero volume. The denominator also adds one to the dollar valueof shares outstanding so that the measure equals 1 when volume equals the total numberof shares outstanding.
13. Ajinkya and Jain (1989) find that this transformed variable has a distribution thatis much closer to normal than are raw volume numbers.
14. Meulbroek (1992) and Yermack (1995) both use a market model approach to esti-mate abnormal volume, though their specification is slightly different from ours.
15. The EGLS procedure we employ involves estimating equation (2) using OLS regres-sion, then regressing the rresidual from that regression on its own lag and using the slopecoefficient from that regression as an estimate of the AR(1) coefficient used to transformthe data as in the Cochrane-Orcutt procedure. Finally, we perform an OLS regression usingthe transformed data to arrive at the estimates of φ0, i and φ1, i. See Judge et al. (1985) fora discussion of EGLS and the Cochrane-Orcutt procedure.
16. As an alternate measure of abnormal volume, we also use the deviation of υi(τ)from its sample average over the period from AD 2 258 to AD 2 109. Again a firm isomitted if it has missing volume data over this period. Inferences are not changed whenusing this alternate measure.
Stock Price Effects 359
Mean abnormal volume for event day τ, MAV(τ) is the sample averageAV for stocks with usable volume data on that date.
Significance tests. All significance tests are performed using across-sectional variance estimator as described in Asquith (1983) anda time-series variance estimator as in Ruback (1982). The latter hasthe advantage of a sample size that depends on the time-series lengthand not the number of firms in the sample, while the former is robustto an increase in the variance of AR around the event dates.17 Detailsof the variance calculations are provided in the appendix.
III. Hypotheses and Results
A. Empirical Implications of the Competing Hypotheses
Four possible explanations for price movements around the time of anindex change are discussed above: temporary price pressure associatedwith index-fund trading (the price-pressure hypothesis); downward-sloping long-run demand curves for stocks (the downward-sloping de-mand hypothesis); S&P’s change announcements contain value-rele-vant information (the information hypothesis); and addition or deletionaffects the stock’s liquidity (the liquidity hypothesis). To help untanglethese explanations, we focus attention on five windows over the eventperiod:
1. run-up window runs from the day after the announcement (AD1 1) through the day before the change day (CD 2 1);18
2. release window runs from the change day (CD) until the release-ending day;19
3. postrelease window runs from the day following the release-end-ing day until the end of the event window 10 days after the changeday (CD 1 10);
4. post-AD permanent effect window runs from the day after theannouncement (AD 1 1) until the release-ending day; and
17. The cross-sectional variance estimator is also robust to the variance effects of survi-vorship; i.e., the variance of a firm’s AR over the last 3 years conditioning on survivingthose 3 years may differ from its postannouncement AR variance conditional on beingincluded in the sample. For further details see Kothari and Warner (1996).
18. Keim and Madhavan (1996) present a model that predicts a positive relation betweenthe temporary price impact of a block trade and order size. In the context of the price-pressure hypothesis, their model suggests that the temporary price impact on each day isincreasing in the level of index-fund trading. Consistent with the notion that index fundscare about tracking error, it is assumed that most funds rebalance their portfolios on theday before the change (CD 2 1). It follows that the largest temporary effect occurs onthe day before the change. Consequently, the price-pressure hypothesis implies a pricereversal that commences on the change day (CD).
19. Under the price-pressure hypothesis, any price release ends when all index fundshave completed their trades. The criterion used to determine the release-ending day isdescribed in Sec. IIIB, ‘‘Price Results.’’
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5. total permanent effect window runs from the announcement day(AD) until the release-ending day.
Figure 1 depicts the time sequencing of the announcement and the changeand indicates exactly when the different windows begin and end.
Table 1 summarizes the implications of each hypothesis for the MARon AD and CD 2 1 and for the MCAR over the five windows. Whiletable 1 presents predictions only for additions, predictions are symmet-ric for deletions; that is, table entries of positive, zero, and negativeimply negative, zero, and positive abnormal returns, respectively, fordeletions. The posited effects for the price-pressure and downward-sloping demand hypotheses assume that most funds rebalance theirportfolios on the day before the change (CD 2 1). Predictions for twoextreme cases associated with each of these two hypotheses are pre-sented in table 1.
For the downward-sloping demand hypothesis, the associated per-manent price effect may not occur until index funds make the purchases(in the case of an addition) that reduce the stock’s supply for activeinvestors (no-anticipation case). At the other extreme, the price effectcould occur on the announcement day if the actions of risk arbitragers,anticipating the upcoming price change, move the price to its new equi-librium level on this day (full-anticipation case). In reality, arbitragersmay cause partial price movement on the announcement day. In addi-tion, trading by some arbitragers and index funds between AD andCD 2 1 may cause positive (negative) abnormal returns for additions(deletions) over this interval. Finally, testing for a nonzero MCAR overthe post-AD permanent effect window is a conservative test of thedownward-sloping demand hypothesis. It is conservative because some(or all) of the AD price movement may be caused by downward-slopingdemand curves, but this test attributes the entire AD abnormal returnto other causes (i.e., to price pressure, information, or liquidity).
We specify two similar extreme cases for the price-pressure hypothe-sis. Again, the timing of price movements depends on the extent towhich market participants attempt to profit from index-fund behaviorand the extent to which index funds concentrate their trading on dayCD 2 1. Either way, however, the price release starts on the changeday as index-fund trading starts to decline. Consequently, since thedownward-sloping demand hypothesis implies a zero MCAR over therelease window, the best test of the price-pressure hypothesis examinesthe release window for a price reversal.
The final rows in table 1 indicate abnormal return predictions forthe information and liquidity hypotheses. Under the information hy-pothesis, an addition announcement by S&P is assumed to be goodnews, while a deletion announcement is assumed to be bad news. Thepredictions for the liquidity hypothesis assume that inclusion in the
Stock Price Effects 361
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362 Journal of Business
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Stock Price Effects 363
S&P 500 increases liquidity, while being deleted decreases liquidity.The predictions for both the information and liquidity hypothesesassume that the market is informationally efficient.
Since trading-volume predictions are less extensive, they are notspecified in table 1. If index-fund trading is concentrated on the daybefore the change, then, for both additions and deletions, we shouldobserve the largest MAV over the run-up window occurring on the daybefore the change (CD 2 1). The liquidity hypothesis implies thatMAV is positive (negative) after the change day for additions (dele-tions).
B. Price Results
Tables 2 and 3 present mean abnormal returns around the two eventdays for additions, while tables 4 and 5 display the same results fordeletions. Figure 2 plots mean cumulative abnormal returns for theclean additions (part A) and clean deletions (part B). A natural concernis the small number of clean observations—especially deletions. Eachof the four hypotheses for price movements around index compositionchanges (price-pressure, downward-sloping demand, information, andliquidity) predicts a roughly symmetric price effect for additions anddeletions. Thus, we alleviate the small sample problems by combiningthe additions and deletions after multiplying the deletion firms’ abnor-mal returns by minus one. While the point estimates contain little newinformation, hypothesis testing is more powerful because of the largersample sizes. These results (unreported) are discussed whenever infer-ences are affected.
Part A of tables 2 and 4 presents daily mean abnormal returns relativeto the announcement date, while part B of tables 2 and 4 reports dailymean abnormal returns relative to the change date. Tables 3 and 5 dis-play multiple-day window results. Each table contains results for theclean sample and the complete sample. The subsequent discussion fo-cuses on the results for the clean samples since these show the effectsof addition to and deletion from the S&P 500 in those cases for whichwe are sure that index funds have an incentive to trade.
For each of the 10 event days after the announcement date shownin part A, only those firms for which the change date has not yet oc-curred are used. Thus, the sample size declines with the passage ofevent time past the announcement date. This presentation allows themagnitude of the abnormal returns between the announcement date andthe change date to be assessed using part A without contamination fromany reversal that may occur on or after the change date. Similarly, foreach of the 10 event days prior to the change date shown in part B,only those firms for which the announcement date has occurred on aprior day are used.
Results for AD appear as event day 0 in part A of tables 2 and 4.
364 Journal of Business
TA
BL
E2
Dai
lyM
arke
t-A
djus
ted
Abn
orm
alR
etur
ns(A
R)
for
Fir
ms
Add
edto
S&P
500,
Mar
ch19
90–A
pril
1995
Cle
anSa
mpl
eC
ompl
ete
Sam
ple
Eve
ntD
ayN
MA
Rt C
(MA
R)
t T(M
AR
)%
AR
.0
NM
AR
t C(M
AR
)t T
(MA
R)
%A
R.
0
A.
AD
50:
210
342
.018
2.0
62
.04
.53
482
.204
2.6
92
.63
.50
29
34.3
831.
52.9
8.7
1*49
.239
.98
.75
.61
28
342
.728
22.
882
1.86
.29*
492
.549
22.
352
1.73
.35*
27
342
1.00
42
2.46
22.
57.3
2*49
2.8
092
2.61
22.
54.3
92
634
.038
.11
.10
.41
49.4
191.
431.
32.5
32
534
2.1
622
.58
2.4
1.4
149
2.2
762
1.22
2.8
7.4
32
434
2.4
192
1.38
21.
07.3
549
2.1
072
.43
2.3
4.4
32
334
2.0
562
.20
2.1
4.4
749
.172
.65
.54
.51
22
34.0
52.1
3.1
3.5
650
.147
.45
.47
.54
21
342
.295
21.
022
.75
.41
502
.245
21.
002
.78
.44
034
3.15
86.
668.
08.9
1*50
2.85
97.
409.
07.8
8*
134
.825
2.20
2.11
.65
50.9
252.
742.
94.6
8*2
321.
129
3.58
2.80
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44.6
182.
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84.6
8*3
28.9
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582.
27.6
139
1.04
93.
382.
94.6
24
24.7
881.
521.
69.7
9*33
.891
1.92
2.30
.76*
56
2.6
242
.38
2.6
7.3
311
2.2
492
.26
2.3
7.3
66
:10
#4
#9
Stock Price Effects 365B
.C
D5
0:2
6:2
10#
4#
92
56
1.78
11.
971.
91.8
311
1.25
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211.
86.7
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1.64
1.56
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33.6
882.
031.
77.6
42
328
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2.33
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381.
37.5
62
232
1.32
74.
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29.7
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50.7
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1.12
72.
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88.7
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1.51
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2.7
262
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21.
872
6.41
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2.6
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1.95
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55.1
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2.6
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1.87
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21.
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1.20
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552
.380
21.
062
1.26
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334
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55.0
54.1
8.1
8.5
14
342
.216
2.6
82
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.47
55.1
28.5
1.4
3.5
65
342
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21.
532
1.57
.47
552
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132
1.24
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634
.292
.76
.75
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552
.119
2.4
12
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734
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55.1
56.5
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18
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1.13
1.06
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2.4
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2.6
0.4
410
332
.228
2.5
42
.57
.48
542
.350
21.
172
1.15
.41
Not
e.—
The
sam
ples
are
desc
ribe
din
Sec.
IIA
and
the
calc
ulat
ion
ofA
Ri(τ
)is
disc
usse
din
the
first
part
ofSe
c.II
B,
whi
chal
sode
fines
MA
R(τ
).N
isth
enu
mbe
rof
firm
sus
ed,a
ndt C
(MA
R)
uses
the
cros
s-se
ctio
nal
vari
ance
estim
ator
ineq
.(A
1);
t T(M
AR
)us
esth
etim
e-se
ries
vari
ance
estim
ator
ineq
.(A
2).A
lleq
uatio
nsar
ein
the
appe
ndix
.The
cros
s-se
ctio
nal
t-st
atis
tics
are
dist
ribu
ted
Stud
ent’
st
with
(N2
1)de
gree
sof
free
dom
,whi
leth
etim
e-se
ries
t-st
atis
tics
are
appr
oxim
atel
yno
rmal
lydi
stri
bute
d.A
Ris
expr
esse
das
ape
rcen
tage
.*
%.
0is
sign
ifica
ntly
diff
eren
tfr
om.5
usin
ga
bino
mia
lte
stw
itha
5%cu
toff
.
366 Journal of Business
TA
BL
E3
Lon
gW
indo
wSt
atis
tics
for
Dai
lyM
arke
t-A
djus
ted
Abn
orm
alR
etur
ns(A
R)
for
Fir
ms
Add
edto
S&P
500,
Mar
ch19
90–A
pril
1995
Cle
anSa
mpl
eC
ompl
ete
Sam
ple
Spec
ific
Eve
ntW
indo
wE
vent
Day
sN
MC
AR
t Ct T
%C
AR
.0
NM
CA
Rt C
t T%
CA
R.
0
Run
-up
AD
11,
CD
21
343.
807
4.15
4.25
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503.
490
5.22
4.79
.80*
Post
-AD
perm
anen
tA
D1
1,C
D1
734
1.70
11.
231.
22.7
1*50
.084
.05
.07
.66*
AD
11,
CD
110
331.
760
1.52
1.12
.73*
49.1
20.0
7.1
0.6
5*
Tot
alpe
rman
ent
AD
,C
D1
734
4.85
93.
443.
36.7
4*50
2.94
31.
732.
52.7
0*A
D,
CD
110
334.
864
3.86
3.02
.73*
492.
936
1.75
2.27
.69*
Rel
ease
CD
,C
D1
734
22.
106
21.
832
1.96
.32*
502
3.40
62
2.28
23.
94.3
6*
Post
rele
ase
CD
18,
CD
110
332
.165
2.2
02
.19
.58
542
.213
2.3
82
.32
.52
NM
AA
Rt C
t TM
NM
AA
Rt C
t TM
Run
-up
AD
11,
CD
21
34.7
944.
754.
3918
950
.811
5.70
5.43
282
Post
-AD
perm
anen
tA
D1
1,C
D1
734
.112
1.05
1.06
461
502
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2.1
22
.19
682
AD
11,
CD
110
33.1
101.
471.
1454
749
.001
.01
.01
816
Tot
alpe
rman
ent
AD
,C
D1
734
.339
3.42
3.35
495
50.1
951.
542.
3973
2A
D,
CD
110
33.2
913.
873.
1358
049
.169
1.64
2.26
865
Not
e.—
The
sam
ples
are
desc
ribe
din
Sec.
IIA
;de
finiti
ons
ofM
CA
R(τ
1,τ 2
)an
dM
AA
R(τ
1,τ 2
)ar
efo
und
inSe
c.II
B.
Mis
the
num
ber
ofda
ysin
the
win
dow
sum
min
gac
ross
firm
s;t C
(MC
AR
)an
dt C
(MA
AR
)us
eth
ecr
oss-
sect
iona
lva
rian
cees
timat
orin
eq.
(A1)
;t 1
(MC
AR
)an
dt T
(MA
AR
)us
eth
etim
e-se
ries
vari
ance
estim
ator
ineq
.(A
2).
Bot
heq
uatio
nsar
ein
the
appe
ndix
.The
cros
s-se
ctio
nalt
-sta
tistic
sar
edi
stri
bute
dSt
uden
t’s
twith
(N2
1)de
gree
sof
free
dom
,whi
leth
etim
e-se
ries
t-st
atis
tics
are
appr
oxim
atel
yno
rmal
lydi
stri
bute
d.A
Ris
expr
esse
das
ape
rcen
tage
.*
%.
0is
sign
ifica
ntly
diff
eren
tfr
om.5
usin
ga
bino
mia
lte
stw
itha
5%cu
toff
.
Stock Price Effects 367
In all four cases (addition and deletion samples both clean and com-plete) the announcement-day abnormal return is significantly differentfrom zero in the expected direction. For example, the abnormal returnis 3.158% (26.263%) with a cross-sectional t-statistic of 6.66 (23.56)for the clean additions (deletions). Table 1 indicates that these an-nouncement-day abnormal returns are consistent with all four hy-potheses described above. In particular, (partial) anticipation under theprice-pressure or downward-sloping demand hypotheses as well as theinformation or liquidity hypotheses all predict the observed announce-ment-day abnormal returns.
Results for the run-up window (AD 1 1, CD 2 1) appear as the toprow of tables 3 and 5. The MCAR and MAAR for this window aresignificantly positive for the additions and significantly negative fordeletions; for example, MCAR is 3.807% (212.690%) with a cross-sectional t-statistic of 4.15 (24.59) for the clean additions (deletions).These results are consistent with the price-pressure and downward-sloping demand hypotheses (as table 1 indicates), but inconsistent withmarket efficiency. Thus, it seems unlikely that the previously docu-mented returns around S&P 500 index composition changes can beattributed solely to the information and liquidity hypotheses. The CARfor additions over this period (AD 1 1, CD 2 1) can be interpretedas the sum of the daily returns on a strategy that each day goes longthe stock $1 and short the market $1. It seems unlikely that transactioncosts would completely eliminate the 3.807% return.20 Further, al-though this strategy is not a riskless arbitrage, it yields a positive return79% of the time. The magnitude of this abnormal return is highlightedby part A of figure 2. One interesting question is whether the profitfrom this type of strategy has eroded over time. Unfortunately, we donot have sufficient data to perform any reliable subperiod analyses.
As discussed above, the price-pressure hypothesis predicts a pricerelease beginning on the change day. Consistent with this implication,part B of table 2 reports a negative mean abnormal return of 20.726%on the addition date (denoted as event day 0 in pt. B) for the cleansample. This is significantly less than zero at the 2% (10%) level usingthe cross-sectional (time-series) t-statistic. The fraction of firms exhib-iting a positive abnormal return is 29% which is significantly lowerthan 50% at the 5% level.
To identify the release-ending day, a criterion based on abnormal
20. The average bid-ask spread would have to be of the order 3.8% to explain the meanCAR for the (AD 1 1, CD 2 1) window; this seems unlikely. Also, the strategy of goinglong $1 in the added ‘‘clean’’ stock on the announcement day and short $1 in the marketand holding this position until the day before the change (i.e., without rebalancing) earnsa return that is positive 79% of the time and has a mean of 3.968% (t-statistic 5 4.02).Thus, the AD 1 1 to CD 2 1 return does not depend on daily rebalancing and so is robustto the associated transaction costs.
368 Journal of Business
TA
BL
E4
Dai
lyM
arke
t-A
djus
ted
Abn
orm
alR
etur
ns(A
R)
for
Fir
ms
Del
eted
from
S&P
500,
Mar
ch19
90–A
pril
1995
Cle
anSa
mpl
eC
ompl
ete
Sam
ple
Eve
ntD
ayN
MA
Rt C
(MA
R)
t T(M
AR
)%
AR
.0
NM
AR
t C(M
AR
)t T
(MA
R)
%A
R.
0
A.
AD
50:
210
151.
674
1.47
2.64
.53
52.2
57.5
7.9
1.4
82
915
21.
778
21.
982
2.81
.33
52.6
63.6
02.
34.4
82
815
2.5
432
.57
2.8
6.3
352
2.3
682
1.10
21.
30.4
02
715
1.92
1.9
53.
03.7
352
.247
.37
.87
.58
26
152
.933
2.8
12
1.47
.47
52.1
31.3
3.4
6.5
82
515
3.27
91.
455.
17.8
7*52
1.08
51.
523.
83.6
5*2
415
.345
.29
.54
.47
52.3
16.7
91.
11.4
82
315
2.0
302
.03
2.0
5.4
052
2.4
732
.98
21.
67.4
82
215
21.
435
21.
532
2.26
.47
522
.188
2.5
22
.66
.46
21
152
.544
2.3
72
.86
.27
522
.063
2.1
42
.22
.44
015
26.
263
23.
562
9.88
.13*
522
1.46
32
2.15
25.
16.4
4
115
23.
609
23.
712
5.69
.13*
512
.787
21.
582
2.75
.45
212
2.3
212
.29
2.4
5.4
246
.638
.59
2.11
.48
312
23.
224
22.
802
4.55
.25
412
.882
22.
012
2.76
.37
48
26.
447
22.
052
7.43
.13
332
1.75
42
1.98
24.
93.3
65
42
10.5
282
2.65
28.
58.0
010
24.
901
22.
252
7.58
.30
6:1
00
#6
Stock Price Effects 369B
.C
D5
0:2
10:2
60
#6
25
42
1.71
32
1.47
21.
40.2
510
2.6
182
1.13
2.9
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02
48
23.
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23.
552
4.05
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172
2.49
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1.72
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1.38
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2.3
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3.97
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2.57
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0
014
5.59
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11.6
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2.6
532
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2.9
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337
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22.
019
2.8
42
3.08
.64
372
.299
2.3
22
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.62
314
.572
.61
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.50
36.2
02.4
7.5
9.5
64
142
.094
2.1
52
.14
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35.2
02.6
6.5
8.5
75
141.
243
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1.89
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35.7
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30.5
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14.7
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08.4
334
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1.21
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714
2.4
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2.6
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2.1
792
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2.5
0.5
58
142
1.48
42
2.30
22.
26.4
333
2.7
612
2.19
22.
14.3
99
142
.190
2.1
92
.29
.43
332
.118
2.2
52
.33
.45
1014
2.98
71.
974.
55.7
133
.779
1.05
2.19
.45
Not
e.—
See
note
tota
ble
2.*
%.
0is
sign
ifica
ntly
diff
eren
tfr
om.5
usin
ga
bino
mia
lte
stw
itha
5%cu
toff
.
370 Journal of Business
TA
BL
E5
Lon
gW
indo
wSt
atis
tics
for
Dai
lyM
arke
t-A
djus
ted
Abn
orm
alR
etur
ns(A
R)
for
Fir
ms
Del
eted
from
S&P
500,
Mar
ch19
90–A
pril
1995
Cle
anSa
mpl
eC
ompl
ete
Sam
ple
Spec
ific
Eve
ntW
indo
wE
vent
Day
sN
MC
AR
t Ct T
%C
AR
.0
NM
CA
Rt C
t T%
CA
R.
0
Run
-up
AD
11,
CD
21
152
12.6
902
4.59
210
.28
.07*
502
2.98
62
1.86
24.
62.3
8
Post
-AD
perm
anen
tA
D1
1,C
D1
514
28.
875
22.
902
4.54
.21
342
1.62
92
.73
21.
40.4
1A
D1
1,C
D1
1014
27.
308
22.
742
3.09
.14*
322
1.71
92
.78
21.
20.3
4
Tot
alpe
rman
ent
AD
,C
D1
514
215
.711
23.
692
7.69
.07*
342
4.55
22
1.61
23.
76.3
2*A
D,
CD
110
142
14.1
442
3.84
25.
80.1
4*32
24.
781
21.
742
3.24
.31*
Rel
ease
CD
,C
D1
514
4.63
91.
363.
13.7
134
2.99
01.
973.
58.6
5
Post
rele
ase
CD
16,
CD
110
141.
567
.78
1.15
.57
33.1
14.1
2.1
5.4
5
NM
AA
Rt C
t TM
NM
AA
Rt C
t TM
Run
-up
AD
11,
CD
21
152
2.86
92
5.04
29.
3866
502
.857
23.
182
6.22
264
Post
-AD
perm
anen
tA
D1
1,C
D1
514
2.8
842
2.59
24.
7414
834
2.2
642
1.43
22.
5539
6A
D1
1,C
D1
1014
2.4
752
2.64
23.
1221
832
2.1
722
1.50
21.
9753
5
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7
Not
e.—
See
note
tota
ble
3.*
%.
0is
sign
ifica
ntly
diff
eren
tfr
om.5
usin
ga
bino
mia
lte
stw
itha
5%cu
toff
.
Stock Price Effects 371
Fig. 2.—A, clean additions; B, clean deletions. MCAR plots for firms addedto and deleted from the S&P 500, 1990–95; mean cumulative abnormal returns(MCARs) around the announcement time (AD) and the effective change date(CD) for firms added to the S&P 500 (clean sample). Since the number of tradingdays between AD and CD varies across firms, the interval AD 1 1 through CD2 2 inclusive is displayed as 5 days (actual average 5 4.56 days) for additionsand 3 days (actual average 5 3.40 days) for deletions. The MCARs are displayedas if each daily MAR over this interval were the interval’s MCAR divided byfive for additions and three for deletions.
372 Journal of Business
volume is applied to the clean samples.21 This criterion relies on recenttheoretical work concerning block trades (see, e.g., Keim and Madha-van 1996) that explains the documented temporary price pressure asbeing compensation for the liquidity being provided by the counterpart-ies. These models predict a positive relation between order size andprice. Any temporary price pressure for index changes that is due toindex-fund trading would be driven by the same factors as those drivingthe temporary price pressure observed for block trades. Thus, it is thelarge index-fund trades associated with adding or deleting the relevantstock that drives any temporary price pressure. For this reason, theprice pressure ends once trading volume has returned to its normalpostchange level. The volume is estimated to have returned to its nor-mal postchange level on the earliest day after the change day with anMAV that is lower than the average MAV for all later days throughCD 1 10. The implied release-end day is CD 1 7 for additions andCD 1 5 for deletions.22
The mean CAR for the release window is reported in table 3 as22.106% for clean additions and significantly different from zero atthe 5% (10%) level using the time-series (cross-sectional) t-statistic.The fraction of CARs that are positive is significantly less than 50%at the 5% level. Deletions also exhibit a price reversal. The price releaseon the change day (CD) for the clean deletions sample is 5.59% andis significant at 5% using the cross-sectional or time-series t-statistic.The mean CAR over the release window is 4.639% but is only signifi-cant using the time-series t-statistic.
Taken together, the addition and deletion results provide strong evi-dence of a significant price reversal following S&P 500 compositionchanges. The combined sample (results not reported) further confirmsthis conclusion by exhibiting an MCAR over the release window thatis significantly negative at the 5% level using either t-statistic. We con-clude that price-pressure effects contribute to the abnormal return pat-terns that occur around index changes. It is possible, however, thatdownward-sloping demand curves also play a role, and we now addressthis issue.
Tables 3 and 5 report results for the post-AD permanent windowusing the volume-based release-end day and the end of the event win-dow (CD 1 10). As discussed above, the abnormal return over thispost-AD permanent window provides a lower bound on the permanent
21. Since longer-horizon CARs have greater sampling variability, extending the release,post-AD, and total permanent effect windows beyond the actual release-ending day reducesthe power of the tests. This reduced power motivates our attempts to determine the actualrelease-ending day instead of using the last day observed (CD 1 10).
22. For the combined sample, MAV for an event day is taken as a weighted averageof the MAVs for the additions and deletions on that day; the implied release-ending dayis CD 1 9.
Stock Price Effects 373
price effect associated with the downward-sloping demand curve hy-pothesis. Given the price reversal documented above, choosing a pre-mature release-ending day would overstate the abnormal return for thispost-AD permanent window. However, note that the MCAR for thepost-release window in tables 3 and 5 is insignificant for all four sam-ples. This suggests that the criterion for determining the release-endday probably does not end the release period prematurely. Despite this,the MCAR and MAAR for the post-AD permanent window are sig-nificant (using either t-statistic) for the clean deletions (table 5) andclean combined samples (unreported) regardless of the release-endingday employed. For the clean additions, the MCAR is of the predictedsign but not significant. Thus, the additions evidence is less supportiveof the downward-sloping demand hypothesis than the deletions or com-bined-sample evidence. Even so, the fraction of positive CARs is al-ways on the predicted side of 50% for all three clean samples (includingcombined, which is not reported) and is significant in five of six tests(three clean samples times two release-ending days). Taken together,this evidence provides additional support, relative to the pre–October1989 studies, that stocks possess downward-sloping demand curves.
A final question is the total magnitude of the CAR associated withbeing added to or deleted from the S&P 500 index. In table 3, the meanCAR for clean additions over the total permanent window is greaterthan 4.8% and is significant at the 5% level for each assumed release-ending day. For the complete additions sample, the mean CAR overthis window is about 2.94%, which is comparable to theannouncement/change-day effect found in earlier studies that usedanalogous samples (e.g., Harris and Gurel 1986; Shleifer 1986; andDhillon and Johnson 1991). For the clean deletion sample, the meanCAR over the total permanent window in table 5 is 215.7% using therelease-ending day (CD 1 5) and is 214.1% using CD 1 10; it isalways significant at the 1% level. The magnitude of this decline isillustrated in figure 2. It seems that a significant negative permanentprice effect is associated with deletion from the S&P 500.
To summarize, the abnormal price movements for the addition anddeletion samples provide consistent evidence concerning the fourhypotheses presented above and market efficiency. The significantlypositive (negative) abnormal return from AD 1 1 to CD 2 1 for addi-tions (deletion) is inconsistent with semi–strong form market effi-ciency. The price reversal on and following the effective change datesupports the price-pressure hypothesis. The weakly positive (signifi-cantly negative) abnormal return from AD 1 1 through the release-ending day for additions (deletions) supports the downward-slopingdemand hypothesis. Finally, while we can rule out the information andliquidity hypotheses as complete explanations for the price patterns ob-served around S&P 500 composition changes, we cannot rule out the
374 Journal of Business
possibility that they contribute to the announcement-day returns and,therefore, to the total permanent price effect.
C. Volume Results
Table 6 reports mean abnormal volume by day, relative to the event,for the two additions samples (complete and clean), while table 7 doesthe same for the two deletions samples. For both tables, part A’s eventtime is relative to the announcement date, while part B’s is relative tothe addition/deletion date. As with tables 2 and 4, only firms whosechange dates have not yet occurred are used to calculate any givenday’s mean AV in part A, and only firms whose announcement dateshave already past are used for any given day in part B. Since the logtransformation used to calculate AV understates high volumes, figure3 contains plots of the daily means for dollar volumes expressed as afraction of the dollar value of shares outstanding (mean fractional vol-umes, MFVs) for the clean additions (part A) and clean deletions(part B).
For additions, part A of table 6 shows that abnormal volume is unre-markable up until one day before the announcement. Each of six con-secutive days starting with the announcement day exhibits significantlypositive abnormal volume at the 5% level for each additions sample.Part B reveals that the largest abnormal volume occurs on the day priorto addition with a t-statistic greater than 13 for each sample. In particu-lar, the clean sample’s point estimate of AV is 11.612%, which com-pares to 5.784% for the announcement day and 1.334% for the dayprior to the announcement.23 This result is consistent with index fundsdoing most of their purchasing on this date to minimize tracking error.
It is interesting that this relatively large abnormal volume on theday preceding addition is not associated with relatively large abnormalreturn. Instead, the MAR for the clean sample on the day prior to addi-tion is 1.127%, which compares to 3.158% on the announcement day.Comparing the parts labeled ‘‘A’’ for figures 3 and 2 clearly illustratesthis pattern of volume and returns. Explaining the patterns in these twofigures is a challenge for future theoretical work.
As can be seen by comparing the two parts of figure 3, the volumeresults for deletions reported in table 7 are generally very similar tothose for additions. The largest abnormal volume is on the day beforedeletion (CD 2 1), followed by the announcement day (AD). Abnormalvolume is unremarkable until AD but the next 6 days (including AD)are all significantly positive. It is interesting that MAV remains sig-
23. The log transformation understates the difference in raw dollar volume across thesethree days. For the day before addition, the announcement day and the day before theannouncement, the MFVs are 4.39%, 1.39%, and 0.57%, respectively (see fig. 3).
Stock Price Effects 375
nificantly positive from CD through until CD 1 8 for the clean dele-tions sample.
IV. Conclusion
This article analyzes price and volume data for firms added to and de-leted from the S&P 500 since October 1989. Because of the temporalseparation of the announcements from the index changes during thisperiod, this new data set has the potential to contribute to our under-standing of several issues associated with the determination of market-clearing prices for individual stocks.
For both additions and deletions, the data reveal a distinct patternof stock-price movements. Specifically, for additions, while we finda significantly positive announcement effect, we also find a positiveabnormal return of about 3.8% over the period starting the day afterthe announcement and ending the day before the effective date of thechange. Further, we find a significant negative abnormal return follow-ing the addition. Firms being deleted from the index also exhibit asignificant postannouncement drift and a significant price reversal, butin directions opposite to those for additions.
Our results can be interpreted in the context of the efficient markethypothesis. The significant abnormal returns following the announce-ment date are inconsistent with semi–strong form market efficiency.It would have been possible to construct trading rules that use publiclyavailable information to earn positive abnormal returns, particularlybetween the announcement day and the change day. This violation ofmarket efficiency is anomalous. While the rationale for the trading pat-terns of index funds is clear, the reason why risk arbitragers do nottrade the profits away on the announcement day is less obvious. How-ever, with more data, it becomes possible to test whether the run-upeffect has declined over time. Evidence of such a decline would indi-cate that the inefficiency existed because the market was not fully awareof the implications of index-fund behavior around index changes. Weare currently gathering such evidence.
The price reversal after addition and deletion strongly suggests theexistence of temporary price effects, caused by index-fund trading as-sociated with S&P 500 composition changes. It also has implicationsfor a well-documented asymmetry in the block-trade literature: seller-initiated block trades exhibit a similar price reversal, but buyer-initiatedtrades do not. The symmetry of our price reversal results for additionsand deletions is a new empirical fact that any potential explanation ofthe block-trade asymmetry must also address. Fully reconciling ourfindings with the temporary effects documented for block trades andpre–October 1989 index composition changes is an issue requiring ad-ditional research.
376 Journal of Business
TA
BL
E6
Dai
lyM
arke
tM
odel
Abn
orm
alV
olum
e(A
V)
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Fir
ms
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Stock Price Effects 377B
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Not
e.—
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are
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Sec.
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and
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ifica
ntly
diff
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om.5
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ga
bino
mia
lte
stw
itha
5%cu
toff
.
378 Journal of Business
TA
BL
E7
Dai
lyM
arke
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odel
Abn
orm
alV
olum
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#4
Stock Price Effects 379B
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Not
e.—
See
note
tota
ble
6.*
%.
0is
sign
ifica
ntly
diff
eren
tfr
om.5
usin
ga
bino
mia
lte
stw
itha
5%cu
toff
.
380 Journal of Business
Fig. 3.—A, clean additions; B, clean deletions. MFV plots for firms added toand deleted from the S&P 500, 1990–94; mean volume as a fraction of sharesoutstanding (MFV) around the announcement date (AD) and the effective changedate (CD) for firms added to and deleted from the S&P 500 (clean sample). Sincethe number of trading days between AD and CD varies across firms, the intervalAD 1 1 through CD 2 2 inclusive is displayed as 4 days (actual average 5 4.00days) for additions and as 4 days (actual average 5 3.57 days) for deletions. TheMFVs are displayed as if each daily MFV over this interval was the interval’smean cumulative FV divided by 4.00 for additions and 3.57 for deletions. Dottedlines are two standard errors from the point estimates.
Stock Price Effects 381
We also find that, for additions, the cumulative abnormal return fromthe day following the announcement through the price reversal isweakly positive. We interpret this abnormal return as a lower boundon the price effect caused by index-fund trading in the presence ofdownward-sloping long-term demand curves. Results for firms beingdeleted from the S&P 500 are stronger than those for additions. Takentogether, the two results provide new evidence in support of downward-sloping long-run demand curves for stocks.
It is interesting that our postannouncement abnormal return resultsseem qualitatively similar to the significantly positive (negative) abnor-mal returns found by Eades, Hess, and Kim (1984) in the week priorto (following) stocks’ ex-dividend dates. In both cases, there is an eventknown in advance by the market (the change day in our sample, theex-dividend date in theirs) and abnormal returns prior to and after thisevent. A closer comparison of the market’s behavior around each eventmay lead to a greater understanding of the driving forces behind theseabnormal returns.
The article also presents volume results indicating that the day beforeaddition or deletion is associated with particularly high volume. Ex-plaining how the behavior of index funds and investors can generatethe observed patterns of returns and trading volume for the added anddeleted firms is an interesting task for future work.
Appendix
Significance Tests
Two types of standard error calculations are employed to assess the significanceof abnormal returns and abnormal volumes. The first uses the cross-sectionaldispersion of each metric to estimate its variance.24 For the MAR(τ) abnormalreturn measure, the cross-sectional variance is given by
s2C[MAR(τ)] 5
1N(τ) ^
N(τ)
i51
[AR i(τ) 2 MAR(τ)]2/[N(τ) 2 1]. (A1)
Under the assumption that the ARi(τ)’s are cross-sectionally independently andidentically distributed normal, the resulting t-statistic for MAR(τ) is Student-tdistributed with N(τ) 2 1 degrees of freedom. A directly analogous calculationgives a variance estimate for the MCAR(τ1, τ2) and MAAR(τ1, τ2) abnormalreturn measures and for the MAV(τ) abnormal volume measure.
The second method of calculating standard errors uses a times series of obser-
24. Asquith (1983) has used this cross-sectional error estimator for mean cumulativeabnormal return in a context where the number of days in the window varies across firms.The advantage of the cross-sectional estimator relative to the time-series estimator pre-sented below is its robustness to any increase in the variance of firm abnormal returnaround the two event dates. See Brown and Warner (1985) for a further discussion of thisissue.
382 Journal of Business
vations from a prior period as in Ruback (1982). The method assumes that eachfirm’s AR follows an MA(1) process and that these processes are identical andindependent across firms. Letting ni(τ1, τ2) be the number of days between τ1
and τ2 for firm i, this variance estimate for MCAR(τ1, τ2) is given by
s2T[MCAR(τ1, τ2)] 5
1N(τ1, τ2) ^
N(τ1, τ2)
i51
s2T[CAR i(τ1, τ2)], (A2)
where
s2T[CAR i(τ1, τ2)] 5 ni(τ1, τ2)s2
T[AR(τ0)]
1 2[ni(τ1, τ2) 2 1]sT[AR(τ0), AR(τ0 1 1)];
avT[AR i(τ0)] 51
48 ^τb147
τ5τb
ARi(τ);
s2T[AR(τ0)] 5
148 N(τb, τb 1 47) ^
N(τb, τb147)
i51^τb147
τ5τb
{AR i(τ) 2 avT[AR i(τ0)]}2;
and
sT[AR(τ0), AR(τ0 11)] 51
47N(τb, τb 147)
3 ^N(τb, τb147)
i51^τb146
τ5τb
{AR i(τ) 2avT [AR i(τ0)]}
3{AR i(τ11) 2avT[AR i(τ0)]}.
A directly analogous variance estimate can be derived for MAAR(τ1, τ2). Theassociated t-statistic is normally distributed asymptotically. Since MAR(τ0) isjust MCAR(τ0, τ0), setting ni(τ0, τ0) equal to one in (A2) provides a varianceestimate for MAR(τ). An analogous variance estimate can be obtained forMAV(τ).25 For MCAR, τb is equal to (AD 2 672) and for MAV(τ), τb is equalto (AD 2 108) which in each case is the day after the relevant market modelestimation period.
Finally, for each event day τ, the fraction of firms in the sample for whichAR(τ) is positive is reported. A test of the hypothesis that the sign of each AR(τ)has probability 0.5 of being positive is performed under the assumption that thesigns of the firms’ ARs are independent (see Hollander and Wolfe [1973] fordetails of this binomial test). Analogous tests are performed for the fraction offirms with positive CARs over various windows and for the fraction of firms withpositive AVs on each event-time day.
25. This time-series estimator is not identical to Ruback’s for two reasons. First, thewindow length here often varies across stocks, a condition that cannot be easily accommo-dated by Ruback’s estimator. Second, although the window length is the same across stocksfor MAR(τ) and MAV(τ), the number of firms used to calculate these measures is oftenmuch smaller than the number of firms with data over the variance estimation period.Ruback notes that if the number of firms used in the variance estimation period is morethan the number used to calculate MCAR(τ1, τ2), his t-statistic will be upward biased; ourt-statistic explicitly allows for sample size differences in the two periods.
Stock Price Effects 383
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