Untitled

PRECAUTIONARY PORTFOLIO BEHAVIOR
FROM A LIFE-CYCLE PERSPECTIVE

Carol C. Bertaut
Board of Governors of the Federal Reserve System

Michael Haliassos
Department of Economics, University of Cyprus

ABSTRACT
The literature on household asset accumulation draws a sharp distinction between "shortrun" precautionary motives to buffer consumption from annual income shocks, and "longrun" life cycle considerations under income certainty. However, estimates of shock persistence imply considerable career uncertainty. We study longrun precautionary motives for lifecycle wealth accumulation and portfolios allowing for uncertain returns, incomes, and lifespan. We separate the effects of various factors on mean and median asset holdings, including education, risk aversion, household heterogeneity, bequests, impatience, variance and serial correlation of income shocks. Numerical solutions are compared with data from the 1992 Survey of Consumer Finances.

Contact Author: Michael Haliassos
Department of Economics
University of Cyprus
P.O. Box 537
CY 1678 Nicosia
Cyprus

PRECAUTIONARY PORTFOLIO BEHAVIOR
FROM A LIFE-CYCLE PERSPECTIVE*

I. Introduction
Traditional models of life-cycle motives for wealth accumulation abstract from nondiversifiable labor income risk faced by households, and have tended to underpredict aggregate wealth in the United States and to overpredict "typical" behavior as captured by median wealth. Following Leland (1968) and Sandmo (1970), Kimball (1990) showed that such risk necessitates additional ("precautionary") wealth holding to buffer consumption from income shocks when utility exhibits "prudence" in the form of a positive third derivative.
Models of precautionary motives which employ the commonly used constant-relative-risk-aversion (CRRA) utility function require numerical solutions. Computational studies by Hubbard and Judd (1987), Skinner (1988), and Zeldes (1989) among others, have abstracted from portfolio choice and shown that if the objective of households is to buffer annual consumption from shocks to annual income, substantial wealth holding is required. In order to reduce unrealistically high predicted levels of wealth to observed levels, Deaton (1991) and Carroll (1992) proposed models which postulate considerable impatience in the form of a high rate of time preference. Hubbard et. al. (1995) introduce instead institutional factors such as asset-based, means-tested benefits to account for limited wealth holding by those with less than high school education. Hubbard, et.al. (1994) approximate observed wealth levels without assuming impatience by building a ninety-period model which incorporates not only income risk, but also uncertainty as to medical expenditures and lifespan. The few existing econometric tests of precautionary motives yield mixed results.
This paper explores the implications of an alternative assumption about household life-cycle objectives, and extends the analysis to discuss not only wealth holding but also the portfolio choice between riskless and risky assets. Empirical evidence on the frequency and extent of portfolio adjustments by households is hard to reconcile with the assumption that they continuously rebalance their portfolios to buffer annual consumption from shocks to annual incomes. We postulate that households choose portfolios so as to buffer consumption over longer periods from shocks to income over correspondingly long horizons, and we study the effects of such long-run precautionary motives on portfolio choice by young households. As seen below, the observed persistence of shocks to annual incomes implies that such households are subject to considerable "career uncertainty", and this is likely to have quantitatively important influence on their choice of portfolios for retirement and bequests.
Although households probably decide part of riskless asset holdings (e.g., checking and savings accounts) with other, shorter-run motives in mind (e.g., transactions motives), we investigate what proportion of their risky and riskless asset holding can be accounted for by this life-cycle precautionary motive alone. For this purpose, predictions from different variants of the model are compared to the most recent and comprehensive data on household portfolios, namely the 1992 Survey of Consumer Finances (SCF). The long-run nature of our model allows us to compute optimal portfolios under three sources of uncertainty (stock returns, incomes, and lifespan), to consider both representative agent models and effects of population heterogeneity, and to explore the separate contributions of several factors, including education, risk aversion, time preference, variance and serial correlation of income shocks, and utility from bequests. Predictions are compared to data on mean and median portfolios, by education group. This gives us two important perspectives on predictive performance in view of the limited incidence of stockholding analyzed in Haliassos and Bertaut (1995).
Section II describes mean and median portfolios by age and education group, using the 1992 SCF. Section III describes two variants of the basic expected-utility model. Section IV first describes calibration of income processes and two departures from certainty models. It then traces the effects of differences in the income processes, starting with the process relevant for the least educated households and gradually transforming it into that applicable to their most educated counterparts. Section V compares empirical wealth-to-income and stock-to-income ratios with those implied by the models. Section VI concludes. The Data Appendix gives definitions of variables and SCF codes.

II. Portfolio Holdings of U.S. Households
We divide total household financial net worth from the 1992 SCF into risky "stocks" and "riskless assets". For most of our discussion, we include under stocks shares of publicly traded stocks, shares in stock mutual funds, and other "directly held" stocks in IRAs and Keogh plans. We also consider a broader definition that includes stocks held in trusts, managed investment accounts, and definedcontribution pension plans. Our riskless assets include checking, saving, money market, and call accounts, CDs, saving and other bonds, and the cash value of life insurance. We subtract from riskless assets credit card balances, consumer loans, and other nonreal estate loans. When we consider our broader definition of stocks, we also include in financial net worth assets in managed accounts and defined contribution pension plans. Labor income includes wage and salary income, income derived from a professional business or practice, unemployment and worker's compensation payments, and income from Social Security and other pensions. We estimated aftertax labor income for nonretirement sources from information on each household's tax filing status and adjusted gross income (see Appendix 1).
Table 1 shows mean and median holdings of directly held stocks and total financial net worth by education and age. For all age groups, both mean holdings of stocks (col. 1) and mean financial net worth (col. 2) increase with education. For example, households aged 3039 with less than a high school education have a mean stock portfolio of $100, about 8 percent of their total financial net worth (col. 3). For those the same age and a high school degree, the mean stock portfolio increases to about $1,500, or 12 percent of total financial net worth, and to nearly $20,000, or 56 percent, for those with a college degree. Among older households without a college degree, the share of stocks in financial net worth is larger, reaching about half the portfolio of those at age 4059. In contrast, stocks comprise more than half the portfolio of young college graduates. Although the level of stocks is higher among older collegeeducated households, the share is lower.
In large part, mean stock portfolios for all education levels and ages reflect holdings by each group as a whole, but not typical behavior. Only 7 percent of households with less than a high school education actually hold stocks; this fraction increases to 23 percent for households who have completed high school, and to 48 percent for those with a college degree. Columns 4, 5 and 6 show median stock portfolios, financial net worth, and stock shares. For households with less than a college education, the median portfolio contains no stocks, nor does the portfolio of the median young, collegeeducated household. For older collegeeducated households, the median portfolio share in stocks is larger, reaching 11 percent for those aged 6069, and then drops to about 1 percent.
Table 2 gives the same breakdown of information as Table 1, but uses the broader definition of stocks and total financial net worth that includes indirectly held assets. This increases both the mean amount and portfolio share of stocks for almost all age and education levels. For households aged 3039 without a college degree, stockholding now comprises between 20 and 30 percent of the portfolio, and almost 60 percent for young collegeeducated households. However, adding indirectly held stocks makes little difference to the median portfolio unless the household has a college education. As in Table 1, the median portfolio still contains stocks only for these households, and the share of their median portfolio in stocks is considerably larger, reaching over 30 percent for those aged 50 to 69.

III. The Basic Models
We solve numerous variants of two basic models. For each calibrated model, we program analytically derived first-order conditions, identities, and constraints as a system of nonlinear equations, and compute solutions for all endogenous variables using Matlab's modified Newton method with line search to ensure global convergence.
Suppose that a household lives for three twenty-year periods, and receives exogenous real income from employment, unemployment, or retirement, Y_t, in period t. The household is subject to three sources of uncertainty: income risk, stock returns, and lifespan uncertainty. We follow the standard practice in the precautionary saving literature of assuming zero correlation between nondiversifiable income risk and asset returns. At the end of each of the first two periods, after all current variables are realized, the household chooses its holdings of stocks and riskless assets for the next period (and implicitly consumption) with a view to their cumulative returns and to present values of incomes over the twenty years. The algebraic sum of households' stock and bond holdings is defined as their financial net worth ("wealth"). In the third period, households repay any accumulated debts. In the model without bequests, they consume the remainder of their labor and interest income and asset holdings. Formally, the household solves:
(1)

where N_t denotes number of stocks held between periods t and t+1, B_t nominal riskless holdings, B is the probability of premature death, and * is the rate of time preference. The utility function is of the form
		(2)

where ( is the (constant) degree of relative risk aversion. The constraints are:
		(3)

(4)

(5)

(6)

S is the nominal stock price, d real dividends per share, I the nominal rate of interest on the riskless asset, P the price of the good, and t_b the tax rate on interest and dividend income. We abstract from capital gains taxation for simplicity. Short sales constraints on stocks are never binding in this model. If households need to borrow, they will do so at the (lower) riskless rate rather than at the risky rate which also has higher expected value. 
	The absence of borrowing constraints, in the form of either quantity constraints or of a wedge between borrowing and lending rates is a standard assumption in life-cycle models, which is still debated in the literature. It is employed here to investigate how far a standard life cycle model can go in accounting for portfolios when only the assumptions of continuous rebalancing and no income risk are relaxed. Nevertheless, households do not engage in unbounded borrowing. As also noted by Aiyagari (1994), constraint  6 ensures finiteness of net worth, since consumption must occur even in adverse labor income and/or stock return states. Under CRRA utility, such constraints are superfluous, since U'(0) is unbounded, ensuring positive optimal consumption. Moreover, finite net worth is not associated with infinite borrowing combined with infinite stockholding. Such a combination would involve bankruptcy in bad stock return states and would not be chosen by CRRA households.
	In the second model variant, we introduce utility from bequests, G. According to the 1992 SCF, 20.8% of households received or expected to receive a sizeable bequest, while 49.5% said they planned to leave a bequest. Third-period utility becomes:
		(7)

Bequests are uncertain because of income and stockholding risk. The parameter 8 controls the choice between last-period consumption and bequest. If households care about bequests (8>0), they behave so as to leave a bequest in any state of the world. The institutional requirement of nonnegative intentional bequests is met endogenously. Although we impose unconditionally positive bequests for 8>0, we understate bequest motives by eliminating the probability of premature death and household concern over the size of accidental bequests. We found that predictions move closer to the data, without the heavy informational requirements usually imposed by infinite-horizon dynastic models.
In the benchmark model without bequests, risk aversion is set at 3, as is usual in this literature, the probability of premature death at zero, and the rate of time preference at 3.13%, equal to the mean riskless rate estimated by Siegel (1992) over the period 1800-1990 and close to the value of 3% assumed in Hubbard et.al. (1994, 1995). Sensitivity of solutions to the values of these parameters is examined below.
Annual stock returns can take a high or low value with equal probability, matching the first two moments of the long-run empirical return distribution estimated by Mehra and Prescott (1985). Following Haliassos and Lyon (1994), we compute the expected value and the standard deviation of 20-year holding returns using the binomial process for annual returns. Finally, we choose a "high" and a "low" 20-year return that match these two moments. Expected dividend yields are set to about half the expected total pre-tax return on equity, which is consistent with the historical findings of Schwert (1990). The twenty-year riskless rate is the Mehra-Prescott mean annual riskless rate compounded over twenty years. We consider the case of no correlation between income and stock returns, which gives us four second-period states. In the absence of retirement income risk, there are eight third-period states (provided that the household survives).

IV. Precautionary Motives from a Longer-run Perspective
IV.1 Calibration of Income Processes
Households choose portfolios to buffer longer-run measures of consumption from shocks to the present values of their income over twenty-year periods, computed using the riskless rate at which they are able to borrow and lend. In the first version of the model, the representative household is faced with no income uncertainty and is guaranteed the average population income at each age. In the second, income is uncertain in the second period, but its expected value equals the level guaranteed in the certainty version. In the third, we consider a population of heterogeneous households generated by different income shock realizations during the first period. Our procedure ensures that average household incomes are equal to those guaranteed to the representative household under certainty and to their expected values under uncertainty. We account for serial correlation of annual income shocks not only within the second period of life, but also across the first and the second period. The second and third versions are solved both without and with bequest motives.
We distinguish between three groups based on education of the household head: (i) less than high school education (LTHS), (ii) high-school education but no college degree (HS), and (iii) college degree or more (COL). This classification is usually motivated by similarities of long-run income prospects [e.g., Hubbard et.al. (1994, 1995)], but it may also be relevant for the degree of financial sophistication. In the versions with income risk, annual incomes for each education group i and year t in a twenty-year period of life are given by
(8)

where Y* is the corresponding income value in the certainty version of the model. The logarithms of shocks U and V, denoted by lower-case letters, are assumed to follow the processes estimated by Hubbard et. al. (1994). While the logarithm of shock U exhibits considerable persistence for all education groups, the variances of transitory and persistent shocks decline with education:
		(9)

IV.1.1 Representative-household Model with Income Risk
	In this version, first-period income is set equal to the average income for the relevant age-education group. By construction, multiplicative income shocks are equal to unity, and serial correlation in the logarithms does not imply second-period effects of first-period shocks.
	We derive the implications of annual income shocks for the present value of incomes over the second twenty-year period. We first draw randomly 200,000 realizations of shocks e and v for each education group from the corresponding lognormal distributions in 9, and use them to construct 10,000 draws of 20-year income sequences. Using the resulting 10,000 realizations of present values, we compute the expected present value and its standard deviation by category. High and low income values are set to mean plus or minus one standard deviation respectively.
	Introduction of lognormally distributed income shocks increases mean incomes above their value under certainty. In order to eliminate this side-effect, annual income values used above are adjusted as follows:
		(10)

where Y^*_it  is the income value under certainty for education group i in year t, and  and  are the unconditional variances of the logarithms of persistent and transitory shocks respectively. Dropping the education group subscript, their sum in the first year of the period is . Its value in subsequent years can be obtained using the recursive formula
		(11)

Comparison of good and bad income states suggests that shocks to annual incomes generate substantial uncertainty for a representative household even with regard to twenty-year present values. Since we are used to thinking about annual incomes rather than present values, Table 3 presents "equivalent" annual incomes which would yield the corresponding twenty-year present value if received each year. This redefinition of units is useful for interpretation and harmless to results. It has been shown that scaling up or down incomes in all states of the world and time periods results in consumption levels and asset holdings which are also scaled by the same factor (Bar-Ilan, 1991).
Table 3 shows that all education groups experience their peak incomes in the absence of shocks, or their peak expected incomes in the presence of shocks, during the second period of life. For college graduates, incomes in the third period are higher than in the first, though this is not true for the other two groups. Those with less than high school education, unlike others, are faced with a prospect of lower income than in the first period of life.

IV.1.2 From a Representative Household to a Population of Households
Households with the same education and income process generally experience different income realizations. Nondiversifiable income risk generates a population of heterogeneous households by the end of the first period, and their average (median) asset holdings need not be the same as those of a representative household which earns average (median) income. In this set of calibrations, we explore the importance of any such differences.
Following the above procedure, we compute 10,000 present value realizations for the first period of life and break them up into ten categories (with equal ranges). We economize on computational effort by solving ten problems, where first-period income is set equal to the average for that income category. Predictions for each education group are computed by weighting predictions for each category by its relative frequency. The corresponding weighted average of incomes is equal to average income among all 10,000 households, to the income of the representative agent in version 2, and to that under certainty in version 1.
The major computational economy comes in calibrating the risk households face conditional on first-period income and in view of serially correlated shocks. Instead of generating 10,000 present value realizations for each of 10,000 households, we do so for each of 10 income categories. Suppose there are 50 households in a category. By replicating each household two hundred times, we come up with 10,000 households while preserving the relative frequency of incomes within the category. Randomly assigning shocks to each, allowing for serial correlation, and correcting for unwanted mean effects, we generate 10,000 present value realizations. Their mean and variance describe second-period income uncertainty, conditional on being in that category of first-period income.

IV. 2 Portfolio Effects of Differences in Income Processes
Table 3 and equation 9 show that income processes differ across education groups both in terms of no-shock levels and in terms of stochastic properties. In this subsection, we illustrate the effects of such differences in the context of the benchmark model with income risk but no bequests. Comparisons are not influenced by differences in random draws, since the same draws of e and v are used as in the original calibration. The direction and relative importance of effects are shown in Table 4 (cols. 4-6).
We first solve the model using the income process for households with less than high school education (step 1). In step 2, we use no-shock income levels of high-school graduates, but shocks applying to the least educated households. In step 3, we set the variance of persistent shocks to that of high-school graduates. In step 4, serial correlation is also adjusted. In step 5 the variance of transitory shocks is adjusted to replicate the process for high-school graduates. The sequence is repeated for transforming high-school graduates to college graduates, with one additional step. Step 7 changes the tax rate on dividend and interest income, t_b, from 15% to 30%, the rate assumed to apply to college-educated households.
College no-shock income profiles have the largest effects, substantially encouraging borrowing and stockholding. Smaller variance of the (logarithm of) persistent shocks, e_t, (step 3 or 8) encourages borrowing, lowers W/Y, but also increases stockholding. This is a generalization of a finding by Kimball (1993) in the context of an atemporal model: a mean-preserving reduction in the size of background income risk makes risky assets more desirable because of the property of CRRA utility functions termed "standard risk aversion". However, the reduction in variance of temporary shocks, v_t, associated with a higher education level (step 5 or 10) has negligible portfolio effects. A reduction in serial correlation (step 4), encourages both borrowing and stockholding, with a negative overall effect on W/Y. Step 9, which increases serial correlation, has the opposite effects. Finally, an increase in tax rates (step 7) reduces wealth by encouraging borrowing, while also encouraging stockholding. Increased borrowing arises because interest taxation is proportional, resulting in larger tax "refunds" from interest payments on loans when tax rates on interest increase. The positive effect on stockholding is attributable to the reduction in riskiness of after-tax stock returns when tax rates are higher.

IV. 3 Comparison of Model Predictions
Table 5 reports predicted ratios of average (median) wealth to average (median) income, for a subset of the models we have solved. Table 6 reports the corresponding ratios for stocks. Solutions for various degrees of risk aversion within the range of 2 to 10, which Mehra and Prescott consider appropriate for representative agent models, are presented. Regardless of education, higher risk aversion lowers optimal stockholding (S/Y), but discourages borrowing by more, lowering current consumption to boost consumption in bad states. This results in higher wealth-to-income ratios (Fig. 1).
The representative agent model which ignores income risk predicts positive stock to income ratios but also substantial borrowing which actually makes financial net worth negative (col. 1). If age-earnings profiles are guaranteed to the representative household in each education group and there are no bequest motives, then it should undertake considerable borrowing in the middle of its working life to finance consumption and to purchase stocks.
In column 2, income shocks are allowed only in the second period. The representative-agent nature of the model underestimates the importance of income risk, since shocks during the first period are not incorporated to differentiate households. Wealth to income ratios increase by 8 to 16 percentage points (pp), and the magnitude of the effect increases with risk aversion. Stock to income ratios are somewhat reduced because of background income risk.
In unreported calibrations, we varied the rate of time preference from .1% to 7.5%. Reduced concern about the future makes equity premia less important and discourages investment in stock. Current consumption increases and is financed both through increased borrowing and reduced stockholding. The schedules for S/Y, B/Y, and W/Y against time preference are essentially linear, negatively sloped, and steeper for college-educated households. The prediction that it is optimal for all groups to be net borrowers is robust to time preference. We also introduced perceived probabilities of premature death at the end of the second period ranging from 5 to 75 percent. Optimal wealth-to-income ratios are reduced. Since households are less likely to survive to retirement, when they would consume and leave bequests, they find equity premia less appealing and borrow to boost current consumption.
In column 3, we allow for first-period income shocks and for persistence of the serially correlated shocks into the second period. We now average across solutions for heterogeneous households based on first period incomes. Wealth to income ratios are further increased by 3 or 4 pp in all education groups. Stock to income ratios are either unaffected or further reduced by about 1 to 2 pp.
Substantial effects are obtained by introducing bequest motives in a representative agent model (col. 4), more so for larger degrees of risk aversion and higher education levels. For a high school dropout with risk aversion of 2, the wealth to income ratio rises above the population model without bequests by 5 pp and above the representative agent model with income risk by 9 pp. At the opposite end, the corresponding changes for college graduates with risk aversion of 10 are 24 and 28 pp respectively. Stock to income ratios increase, as households accumulate to provide for future consumption and bequests, essentially returning to levels implied by the certainty model. Generalization to a population model with bequests (col. 5) raises wealth to income ratios by a further 3 to 4 pp, while lowering stock to income ratios by 1 to 2 pp.
Population models allow computation of predicted ratios of median wealth and median stocks to median incomes. Again, introduction of bequest motives has substantial positive effects on the former, especially for college graduates, which range from 9 to 30 pp (columns 6 and 7). Effects on the latter are also positive but small.
All in all, the cumulative effect of allowing for long-run income risk, bequests, and population heterogeneity is to increase predicted ratios of average wealth to average income by 20 to 44 pp, while reducing stock to income ratios by between 1 and 7 pp relative to the representative agent model with no income risk. For each education level, increases in W/Y are larger and reductions in S/Y smaller the higher the degree of risk aversion. For any risk aversion, effects on W/Y are largest for college graduates and smallest for high school graduates. Effects on optimal S/Y are somewhat more pronounced among high school dropouts than among others.

V. A Comparison of Observed Portfolios with Model Predictions
Since we are focusing on longer-run motives, our objective is not to match model predictions to the data, but to examine the extent to which the level and composition of asset holdings depart from long-run objectives incorporated in the models. This also defines the direction in which short-run (e.g., transactions) and other motives must operate if they are to account for actual portfolios.
We focus on the extent to which the model accounts for (i) average behavior, (ii) typical behavior, and (iii) household heterogeneity in the age cell of 30 to 39 years for each education group. For (i), which is our main focus, the metric used is the ratio of average wealth (or stocks) to average labor income in the cell, which is equivalent to the ratio of total wealth (or stocks) to total income. Since asset holdings are often skewed, medians represent typical behavior more closely than means. So, for (ii) we use ratios of medians. An interesting puzzle in (iii) is the limited incidence of stockholding among US households. We have addressed this issue extensively in Haliassos and Bertaut (1995). The discussion here explores instead whether long-run models are versatile enough to generate the variety of nonzero portfolio combinations observed in household data (e.g., negative net worth combined with stockholding, or positive holdings of both assets, etc.).
For comparison with model predictions, cols. 1 and 2 of Table 7 give U.S. household mean financial net worth and mean stocks scaled by mean aftertax labor income (W/Y and S/Y), by age and education level. Columns 5 and 6 use the broader definitions of stocks and financial net worth. For all education levels, W/Y (cols. 1 and 5) is higher among older groups. For any given age, the ratio increases with education. For older households with at least a high school education, mean financial net worth is several times annual labor income. The ratios of S/Y (cols. 2 and 6) also show considerable variation by education level. For most households with less than high school education, the mean level of stocks never amounts to more than 40 percent of labor income. S/Y is especially small for young households, reflecting the low level of stocks held. Households with high school or college education have a substantially higher S/Y ratio. Older households in these education groups hold a mean stock portfolio that is greater than their mean aftertax labor income. Including indirectly held stocks increases this ratio considerably for these households. Columns 3, 4, 7, and 8 show ratios of median wealth or stocks to median incomes.

Average Household Behavior
Table 6 shows that for the two more educated categories, models which recognize life cycle precautionary motives yield ratios of stocks to income within the bands of data averages in Table 7. In the case of college graduates, risk aversion of 4 generates ratios between .35 and .45 when long-run uncertainty is recognized. For high school graduates, the empirical band is between .04 and .13, and risk aversion of 7 generates such ratios in the models with uncertainty. This ranking in terms of risk aversion is consistent with responses on attitudes towards financial risk taking in the Survey which suggest that risk aversion declines with education (Table 8). Thus, models which postulate that households decide asset holdings with a view to buffering consumption from shocks to longer run income measures can reasonably account for average stockholding among the two more educated categories.
With regard to riskless assets, Tables 5 and 7 suggest that life-cycle precautionary motives, especially in conjunction with heterogeneity and bequest motives, can explain a significant part of the discrepancy between a life cycle model under certainty and empirical observations. However, part of riskless holdings by the two more educated groups are attributable to shorter-run or other motives. For high school graduates, the long-run models account for about one third of the wealth to income ratio. For college graduates, they imply that long-run motives alone and the nature of the income process would justify substantial borrowing, to the point of making financial net worth negative early in life.
Households with less than high school education differ. As comparison of Tables 5 and 7 suggests, their entire wealth to income ratio can be accounted for by the model with bequests and population heterogeneity at degree of risk aversion of 6. However, their limited average stockholding cannot be explained for degrees of risk aversion between 2 and 12. Had we only looked at aggregate wealth, we would have concluded that the model matches their behavior exactly. This raises some interesting research questions regarding the predictive ability of other models which approximate wealth to income ratios but have not yet been extended to analysis of portfolio composition.
Limited average stockholding in this education group is primarily attributable to the very small proportion of stockholders, both in absolute terms and by comparison to other groups. This is true not only in 1992, but also in 1984 PSID [Mankiw and Zeldes (1991)] and in 1983 SCF data [Haliassos and Bertaut (1995)]. Haliassos and Bertaut showed that an expected-utility life cycle model without frictions (such as information costs or other sources of inertia) has trouble accounting for the limited incidence of stockholding. For low-education households, among whom stockholding incidence is minimal, this inherent limitation of the model distorts its prediction of average behavior, but not so for the other two categories.

b. Typical Household Behavior and Household Heterogeneity
Median direct stockholding is zero for each age-education group, except for college graduates over 40. The finding that not only the incidence but also the average level of stockholding by high school dropouts is below predictions gives further support to the view that inertia, information, and sophistication are important factors for stockholding behavior.
If we focus on median wealth and its relation to median income, we compare observed ratios (Table 7, cols. 3 and 7) to those predicted by our population models (Table 5, cols. 6 and 7). Our model with bequests explains about one half of the empirical ratio for high school dropouts if we constrain ourselves not to consider risk aversion in excess of 10. For high school graduates, the same model can fully account for the observed ratio for risk aversion of 9. However, the model yields consistently negative ratios for college graduates.
Although the typical (median) young household in the SCF has positive riskless holdings and no stocks, there is considerable heterogeneity within each age-education group. In all three education groups, some young households (between 10 and 25 percent) have negative financial net worth, and a fraction of these are stockholders under the broader asset definitions. The proportion of these stockholder households who borrow is slightly higher for college-educated households. Our population models yield (unreported) solutions for various categories consistent with the existence of such households and with their increased importance among households with college education. Even for college-educated households, for whom our models uniformly predict negative ratios of average wealth to average income, the population model with bequests generates positive wealth-to-income ratios for some income categories and degrees of risk aversion. The higher the degree of risk aversion, the larger is the number of such categories. Thus, there is nothing in these models to prevent them from predicting the variety of nonzero portfolio combinations observed in the data. Matching relative frequencies may require more elaborate models and/or greater precision in defining first-period income categories. We intend to pursue this in future research.

VI. Concluding Remarks
We explore the implications of a bold assumption about household portfolio behavior, namely that household wealth and portfolios around the middle of working life are chosen so as to buffer consumption over long periods of time from shocks to corresponding long-run income measures, i.e. "career uncertainty". Using numerical computation, we show how the predictions of an otherwise standard life-cycle model with no income risk can be brought closer to empirical observations by (i) incorporating long-run income risk, (ii) introducing bequest motives, and (iii) abandoning the representative-agent assumption to consider the effects of income shocks in creating a population of heterogeneous households.
We distinguish between three education groups and use empirically estimated income processes for each to calibrate the extent of career uncertainty it faces. Data on portfolios come from the most comprehensive and most recent source, the 1992 Survey of Consumer Finances. The simple career risk model can account for all of stockholding among the two more educated income groups at plausible degrees of risk aversion and other parameter values, but leaves part of riskless asset holding to be explained with reference to other considerations. It can also explain all of wealth holding by high-school dropouts without invoking a large degree of impatience or institutional factors. It overpredicts stockholding, primarily because its incidence is extremely low among this group, and standard expected-utility models need to be otherwise augmented to account for this fact, as we have shown elsewhere. The sensitivity of conclusions to parameter values and model variants is explored extensively.
Based on these first results from setups which do not impose any frictions, market imperfections or special factors, the life-cycle model with career risk appears as a useful benchmark for future research. The model and the calibration methods introduced here should prove quite versatile and computationally tractable in allowing for finer distinctions among risky assets, investigating correlations between incomes and asset returns, considering more education and/or income categories, exploring additional dimensions of household heterogeneity, matching population frequencies, introducing important frictions, and exploring the separate contributions of various factors.

Data Appendix

Numbers refer to variables in the 1992 Survey of Consumer Finances

1. Stocks (standard definition): dollar value of shares of publicly traded stocks (X3915) plus shares in stock mutual funds (X3822) plus 1/2 of shares in combination funds (X3830) plus stocks in IRAs and Keogh plans (= X3610 + X3620 + X3630 if X3631=2) plus 1/2 IRAs split between stocks and bonds or stocks and money market accounts (= 1/2*(X3610 + X3620 + X3630) if X3631=5 or X3631=6) + 1/3 of mixed stock/bond/money market accounts (= 1/3*(X3610 + X3620 + X3630) if X3631=4).

2. Stocks (broad definition) = Stocks (standard definition) plus dollar value of stocks in trusts or managed accounts (= X3942 if X3947=1) plus 1/2 (trusts and managed accounts split between stocks and bonds or money market (= 1/2*X3942 if X3947=5) + 1/3 other diversified accounts (= 1/3*X3942 if X3947=6 or X3947=-7) plus stocks in defined contribution pension plans plus 1/2 of defined contribution plans split between stocks and interest-earning assets (= X4226 if X4234=1or 1/2*X4226 if X4234=3) + (X4326 if X4334=1 or 1/2*X4326 if X4334=3) + (X4426 if X4434=1 or 1/2*X4426 if X4434=3).

3. Financial net worth (standard definition): dollar value of transactions, savings, and money market accounts (= X3506 + X3510 + X3514 + X3518 + X3522 + X3526 + X3529 + X3706 + X3711 + X3716 + X3718 + X3804 + X3807 + X3810 + X3813 + X3816 + X3818 + X3930) plus certificates of deposit (X3721) plus IRA/Keogh accounts (X3610 + X3620 + X3630) plus directly held mutual funds (X3822 + X3824 + X3826 + X3828 + X3830) plus saving bonds (X3902) plus other directly held bonds (X3910 + X3906 + X3908 + X7634 + X7633) plus cash value of whole life insurance (X4006) plus other financial assets (X4018 + X4022 if 61# X4020 # 66 or 72 # X4020 # 74 + X4026 if 61# X4024 # 66 or 72 # X4024 # 74 + X4030 if 61# X4028 # 66 or 72 # X4028 # 74) minus credit card balances (X427 + X413 + X421 + X430 + X424 + X7575) minus installment and other non-real estate loans (X2218 + X2318 + X2418 + X2424 + X2519 + X2619 + X2625 + (X2723 if X2710 not=67) + (X2740 if X2727 not=67) + (X2823 if X2810 not=67) + (X2840 if X2827 not=67) + (X2923 if X2910 not=67) + (X2940 if X2927 not=67) + X7824 + X7847 + X7870 + X7924 + X7947 + X7970 + X1044 + X1215 + X1219 + X1108 + X1119 + X1130 + X4229 + X4329 + X4429 + X4829 + X4929 + X5029 + X4010 + X4032 + X3932).

4. Financial net worth (broad definition): financial net worth (standard definition) plus dollar value of assets in managed or trust accounts (X3942) + amounts in defined-contribution pension plans that can be borrowed against or from which household can make a withdrawal (X4226 if (X4216=1 or 2) and (X4227=1 or X4231=1)) + (X4326 if (X4316=1 or 2) and (X4327=1 or X4331=1)) + (X4426 if (X4416=1 or 2) and (X4427=1 or X4431= 1)) + (X4826 if (X4816=1 or 2) and (X4827=1 or X4831=1)) + (X4926 if (X4916=1 or 2) and (X4927=1 or X9831=1)) + (X5026 if (X5016=1 or 2) and (X5027=1 or X5031=1)).

5. Riskless assets (standard definition) = financial net worth (standard definition) - stocks (standard definition).

6. Riskless assets (broad definition) = financial net worth (broad definition) - stocks (broad definition).

7. Household labor income for 1991: household income derived from wages and salaries (X5702) plus income from professional business or practice (X5704) plus unemployment or worker's compensation (X5716) plus income from Social Security or pensions (X5722).

8. After-tax labor income: For non-retirement sources of income, the average tax rate was imputed from information on household adjusted gross income (AGI) (=X5751, or X7651and X7652) and tax filing status (X5746). The average tax rates for AGI class and filing status were calculated from the Statistics of Income-1991, Individual Income Tax Returns, Table 1.2. AGI classes were: under $1,000; $1,000 to under $5,000; $5,000 to under $10,000; $10,000 to under $15,000; $15,000 to under $20,000; $20,000 to under $25,000; $25,000 to under $30,000; $30,000 to under $40,000; $40,000 to under $50,000; $50,000 to under $75,000; $75,000 to under $100,000; $100,000 to under $200,000; $200,000 to under $500,000; $500,000 to under $1,000,000; and $1,000,000 or more. Filing status was single, married filing a joint return, or married filing separate returns. For married couples filing separate returns, a weighted average tax rate (reflecting each spouse's AGI) was constructed. Total after-tax income = income from retirement sources (X5722) + (1-tax rate)*(X5702 + X5704 + X5716).

9. Age of household head: recoded from X8022 as 5-year spreads between 20 and over 85 for income calibrations, and as 10-year spreads between 20 and over 80 for portfolio estimates.

10. Education of household head: recoded from X5901, X5902, and X5904 as (i) no high school degree (ii) high school degree or equivalency certificate but no college degree and (iii) college degree or higher.

The final data set included 3,906 respondents. All variables were weighted with XWGT to produce population averages.
Appendix II

Table A1. Calibrated Income Processes for Population Models, by Education Group
			Equivalent Incomes in Period and State
Education: Less than High School
Income Category		frequency	Y1	Y2 High	Y2 Low	Y3
	1	0.2297	8778.3	21903.6	7780.4	13633
	2	0.5224	13947.1	30467.8	11026.2	13633
	3	0.1917	20907.4	40316	15200	13633
	4	0.0426	28279.0	50289	19551	13633
	5	0.0102	35624.3	60404	23780	13633
	6	0.0023	42741.5	68235	27777	13633
	7	0.0008	50821.6	67703	28423	13633
	8	0.0002	58421.8	55836	25324	13633
	9	0	--	--	--	--
	10	0.0001	77412.6	125043	61187	13633
High School Income Category
	1	0.0629	13202.1	33605.2	15174.8	22032
	2	0.3941	19806.9	43289	20081	22032
	3	0.3429	27444.9	53199	25383	22032
	4	0.1429	35971.5	63547	30573	22032
	5	0.0398	44459.3	73243	35293	22032
	6	0.0127	52907.1	81405	40183	22032
	7	0.0032	61325.9	94176	46884	22032
	8	0.0009	68909.3	100510	51582	22032
	9	0.0005	79660.9	123572	66474	22032
	10	0.0001	92801.6	165371	95669	22032
College or More Income Category
	1	0.1154	23738.1	70964	36698	49663
	2	0.4486	33606.2	88944	45850	49663
	3	0.3114	45252.4	109620	57380	49663
	4	0.0956	57920.9	129691	69023	49663
	5	0.0219	70548.4	146945	79755	49663
	6	0.0058	83099.4	164253	89567	49663
	7	0.001	96697.8	178094	102826	49663
	8	0.0002	105650.0	158597	91883	49663
	9	0	--	--	--	--
	10	0.0001	142906.0	246917	149563	49663
First-period incomes for each education level are derived from 10,000 random draws which are used to construct 10 income categories. Second-period incomes for each category are generated from additional random draws and allow for persistent effects of first-period shocks into the second period. Frequency: fraction of 10,000 households in simulated population which belong to that category based on first-period income.

References

Aiyagari, Rao, 1994, Uninsured idiosyncratic risk and aggregate saving, Quarterly Journal of Economics,  659-84.

Aiyagari, Rao and Mark Gertler, 1991, Asset returns with transactions costs and uninsured individual risk, Journal of Monetary Economics, 27,  311-31.

Auerbach, Alan and Lawrence Kotlikoff, 1987, Dynamic fiscal policy (Cambridge University Press, Cambridge).

Auerbach, Alan, Lawrence Kotlikoff, and Jonathan Skinner, 1983, The efficiency gains from dynamic tax reform, International Economic Review, 24,  81-100.

Bar-Ilan, Avner, 1991, On the proportionality and homogeneity of consumption and income, mimeograph, University of British Columbia.

Bernheim, Douglas and Karl Scholz, 1993, Private saving and public policy, in: James Poterba, ed., Tax policy and the economy, Vol. 7 (MIT Press, Cambridge, MA).

Carroll, Chris, 1992, The buffer stock theory of saving: Some macroeconomic evidence, Brookings Papers on Economic Activity, 1992:2,  61-135.

Carroll, Chris and Andrew Samwick, 1992, The nature and magnitude of precautionary wealth, working paper No. 124, Economic Activity Section, Board of Governors of the Federal Reserve System.

Constantinides, George and Darrell Duffie, 1992, Asset pricing with heterogeneous consumers, mimeograph, University of Chicago.

Dardanoni, V., 1991, Precautionary savings under income uncertainty: A cross-sectional analysis, Applied Economics, 23,  153-60.

Deaton, Angus, 1991, Saving and liquidity constraints, Econometrica, 59,  1221-48.

Elmendorf, Douglas and Miles Kimball, 1991, Taxation of labor income and the demand for risky assets, NBER Working Paper No. 3204.

Guiso, Luigi, Tullio Jappelli, and Daniele Terlizzesse, 1992, Earnings uncertainty and precautionary saving, Journal of Monetary Economics, 30,   307-21.

Guiso, Luigi, Tullio Jappelli, and Daniele Terlizzesse, 1994, Income risk, borrowing constraints, and portfolio choice, forthcoming, American Economic Review. 

Haliassos, Michael, 1994, On perfect foresight models of a stochastic world, The Economic Journal, 104,  477-91.

Haliassos, Michael and Carol C. Bertaut, 1995, Why do so few hold stocks?, The Economic Journal, 105,  1110-1129.


Haliassos, Michael and Andrew Lyon, 1994, Progressivity of capital gains taxation with optimal portfolio selection, in: Slemrod, Joel, ed., Tax Progressivity and Income Inequality (Cambridge University Press, Cambridge).

Heaton, John and Deborah Lucas, 1992, Evaluating the effects of incomplete markets on risk sharing and asset pricing, Mimeograph.

Hubbard, R. Glenn and Kenneth Judd, 1987, Social security and individual welfare: Precautionary saving, liquidity constraints, and the payroll tax, American Economic Review, 77,  630-46.

Hubbard, R. Glenn, Jonathan Skinner, and Steven Zeldes, 1995, Precautionary saving and social insurance, Journal of Political Economy, 103,  360-99.

Hubbard, R. Glenn, Jonathan Skinner, and Steven Zeldes, 1994, The importance of precautionary motives in explaining individual and aggregate saving, Carnegie-Rochester Conference Series on Public Policy, 40,  59-125.

Kimball, Miles, 1990, Precautionary saving in the small and in the large, Econometrica, 58,  53-73.

Kimball, Miles, 1991, Precautionary motives for holding assets, in: Newman, P., Murray Milgate, and John Eatwell, eds., The new Palgrave dictionary of money and finance, 3,  158-61, (Stockton Press, New York).

Kimball, Miles, 1993, Standard risk aversion, Econometrica, 61,  589-612.

Kotlikoff, Lawrence and Lawrence Summers, 1981, The role of intergenerational transfers in aggregate capital accumulation, Journal of Political Economy, 89,  706-32.

Leland, Hayne, 1968, Saving and uncertainty: The precautionary demand for saving, Quarterly Journal of Economics, 82, 456-73.

Mankiw, N. Gregory, and Steven Zeldes, 1991, The consumption of stockholders and non-stockholders, Journal of Financial Economics, 29,  97-112.

Mehra, Rahjnish and Edward Prescott, 1985, The equity premium: A puzzle, Journal of Monetary Economics, 15,  145-61.

Pratt, John and Richard Zeckhauser, 1987, Proper risk aversion, Econometrica, 55, 143-54.

Sandmo, Agnar, 1970, The effect of uncertainty on saving decisions, Review of Economic Studies, 37, 353-60.

Schwert, G.William, 1990, Indexes of U.S. stock prices from 1802-1987, Journal of Business, 63,  399-426.

Siegel, Jeremy, 1992, The real rate of interest from 1800-1990: A study of the U.S. and the U.K., Journal of Monetary Economics, 29,  227-52.

Skinner, Jonathan, 1988, Risky income, life-cycle consumption, and precautionary savings, Journal of Monetary Economics, 22,  237-55.



Venti, S. and D. Wise, 1987, IRAs and saving, in: Feldstein, Martin, ed., The effects of taxation on capital accumulation (Chicago University Press, Chicago).

Weil, Philippe, 1990, Equilibrium asset prices with undiversifiable labor income risk, Mimeograph.

White, B., 1978, Empirical tests of the life-cycle hypothesis, American Economic Review, 68,  546-60.

Zeldes, Steven, 1989, Optimal consumption with stochastic income: Deviations from certainty equivalence, Quarterly Journal of Economics,  275-98.

Table 1. Average and Median Dollar Holdings of Directly Held Stocks and Household Financial Net Worth for U.S. Households, by Age and Level of Education of Household Head
Age	Average Portfolio			Median Portfolio
	Stocks (1)	Financial Net Worth (2)	Stock Share (3)	Stocks (4)	Financial Net Worth (5)	Stock Share (6)
Education: less than high school degree
20 - 29 years	0	1977	0.00	0	3240	0.00
30 - 39 years	100	1191	0.08	0	3400	0.00
40 - 49 years	6701	16335	0.41	0	3510	0.00
50 - 59 years	3073	15040	0.20	0	3510	0.00
60 - 69 years	2310	23025	0.10	0	3710	0.00
70 - 79 years	1227	40885	0.03	0	6410	0.00
80+ years	28971	63886	0.45	0	4610	0.00
Education: high school degree
20 - 29 years	443	5152	0.09	0	3270	0.00
30 - 39 years	1531	12322	0.12	0	3510	0.00
40 - 49 years	19421	34698	0.56	0	4610	0.00
50 - 59 years	27416	64977	0.42	0	15010	0.00
60 - 69 years	30513	92990	0.33	0	25710	0.00
70 - 79 years	37663	123407	0.31	0	32590	0.00
80+ years	41244	87524	0.47	0	9060	0.00
Education: college degree
20 - 29 years	10610	18812	0.56	0	3111	0.00
30 - 39 years	19515	34972	0.56	0	8410	0.00
40 - 49 years	35604	97077	0.37	300	20310	0.01
50 - 59 years	73453	202835	0.36	2500	66461	0.04
60 - 69 years	105302	259167	0.41	8500	77600	0.11
70 - 79 years	73308	226199	0.32	1000	87410	0.01
80+ years	269942	526430	0.51	1000	127710	0.01
Data: 1992 Survey of Consumer Finances Directly held stocks include shares of publicly traded stocks, shares in mutual stock funds, and stocks in IRAs and Keoghs. Directly held household financial net worth includes directly held stocks, checking, saving, money market, and call accounts, CDs, saving and other bonds, and the cash value of life insurance, minus balances on credit cards, consumer loans, and other non-real estate loans.

Table 2. Average and Median Dollar Holdings of Directly and Indirectly Held Stocks and Household Financial Net Worth for U.S. Households, by Age and Level of Education of Household Head
Age	Average Portfolio			Median Portfolio
	Stocks (1)	Financial Net Worth (2)	Stock Share (3)	Stocks (4)	Financial Net Worth (5)	Stock Share (6)
Education: less than high school degree
20 - 29	216	3106	0.07	0	3510	0.00
30 - 39	314	1411	0.22	0	3510	0.00
40 - 49	6854	16792	0.41	0	3510	0.00
50 - 59	3431	15063	0.23	0	3510	0.00
60 - 69	2394	23039	0.10	0	3710	0.00
70 - 79	3019	46620	0.06	0	6410	0.00
80+	29305	66055	0.44	0	4610	0.00
Education: high school degree
20 - 29	1043	6468	0.16	0	3370	0.00
30 - 39	4321	15760	0.27	0	3610	0.00
40 - 49	24278	41204	0.59	0	5540	0.00
50 - 59	41131	76739	0.54	0	18510	0.00
60 - 69	33149	98974	0.33	0	29010	0.00
70 - 79	38614	127756	0.30	0	34060	0.00
80+	43738	93979	0.47	0	9060	0.00
Education: college degree
20 - 29	11567	22322	0.52	0	3170	0.00
30 - 39	25030	42792	0.58	250	9510	0.03
40 - 49	47792	116736	0.41	6000	28310	0.30
50 - 59	123783	258840	0.48	24000	86910	0.36
60 - 69	118998	285405	0.42	25000	89910	0.32
70 - 79	83792	245403	0.34	1250	93010	0.01
80+	316030	705758	0.45	1000	213410	0.01
Data: 1992 Survey of Consumer Finances. Directly and indirectly held stocks include all stocks listed in Table 1, plus stocks held in defined contribution pension plans, trusts, and managed investment accounts. Directly and indirectly held household financial net worth includes all assets listed in Table 1, plus assets held in defined contribution pension plans, trusts, and managed investment accounts.

Table 3. Calibrated Income Processes for Representative Agent Models, by Education Group
		Equivalent Income in Period and State
Income Certainty
Education:		Y1	Y2		Y3
	Less than High School	15019	21570		13633
	High School	25920	37583		22032
	College or More	39483	75527		49663
Income Risk
		Y1	Y2		Y3
	Education:		High	Low
	Less than High School	15019	30088.5	13219.5	13633
	High School	25920	48691	26219	22032
	College or More	39483	96010	55338	49663
Income values are "equivalent" incomes which, if received each year over a twenty-year period, would yield present values of income equal to those derived in the actual calibrations. Income Certainty: Income values for periods 1, 2, and 3 are based on mean incomes in the 1992 SCF for the age-education group specified. Income Risk: High and low income states in period 2 are derived on the basis of random draws of income shocks, and random draws of the corresponding income sequences, as described in the text. Incomes are adjusted to restore means to their certainty levels. Income definitions are given in the data appendix.

Table 4. Effects of Differences in Income Processes Across Education Groups on Portfolio Allocation
Changes in Portfolio Solutions from Previous Step
) B/Y
(6)
--
0.011 
­0.036 
­0.013 
0.000 
­0.405 
­0.077 
­0.064 
0.014 
­0.001 
Notes: LTHS:  less than high school education; HS:  high school degree; COL:  College degree. 
W/Y:  average wealth/average income; S/Y:  average stocks/average income; B/Y:  average bonds/average income.
The table shows the effects on portfolio allocation of gradually converting the income process for the representative agent household with less than high school education into the process for the college-educated household. Mean incomes are computed from the 1992 SCF. Income definitions are given in the data appendix. The calibration method is analogous to that used in Table 3.

Table 5:  Comparison of Model Predictions of First-Period Wealth to Income Ratios,
 by Education and Degree of Risk Aversion
Income Risk,  Population Models
Med W/Med Y
Bequests

(7)
Education: less than high school degree
­0.36 
­0.19 
­0.08 
­0.01 
0.04 
0.08 
0.10 
0.12 
0.14 
Education:  high school degree
­0.33 
­0.16 
­0.06 
0.01 
0.05 
0.09 
0.11 
0.13 
0.15 
Education:  college degree
­0.95 
­0.67 
­0.51 
­0.41 
­0.34 
­0.28 
­0.24 
­0.21 
­0.19 
Notes:  W/Y:  Ratio of average wealth to average income.
Med W/Med Y:  Ratio of median wealth to median income.  
Certain Income:  Baseline model with no second-period income shocks.  
Income Risk:  Adds transitory and persistent shocks to second-period incomes.  
Rep Agent:  Representative agent models.  
Population:  Models with populations of heterogenous agents.  
Bequests:  Models with bequest motives; the weight on the bequest motive 8 = 0.25 (see equation (7)). 
All models have rate of time preference * = 3.13 percent per annum.  

Table 6:  Comparison of Model Predictions of First-Period Stocks to Income Ratios, 
by Education and Degree of Risk Aversion
Income Risk,  Population Models
Med S/Med Y
Bequests

(7)
Education: less than high school degree
0.66 
0.39 
0.28 
0.21 
0.17 
0.15 
0.13 
0.11 
0.10 
Education:  high school degree
0.66 
0.40 
0.28 
0.21 
0.17 
0.15 
0.13 
0.11 
0.10 
Education:  college degree
0.91 
0.55 
0.39 
0.30 
0.25 
0.21 
0.18 
0.16 
0.14 
Notes:  W/Y:  Ratio of average wealth to average income.
Med W/Med Y:  Ratio of median wealth to median income.  
Certain Income:  Baseline model with no second-period income shocks.  
Income Risk:  Adds transitory and persistent shocks to second-period incomes.  
Rep Agent:  Representative agent models.  
Population:  Models with populations of heterogenous agents.  
Bequests:  Models with bequest motives;  the weight on the bequest motive 8 = 0.25 (see equation (7)).
All models have rate of time preference * = 3.13 percent per annum.    

Table 7. Ratios of Average and Median Financial Net Worth and Stocks to After-tax Labor Income, for U.S. Households, by Age and Level of Education of Household Head
Age	Directly Held Assets				Directly and Indirectly Held Assets
	W/Y (1)	S/Y (2)	Med W/ Med Y (3)	Med S/ Med Y (4)	W^b/Y (5)	S^b/Y (6)	Med W^b/ Med Y (7)	Med S^b/ Med Y (8)
Education: less than high school degree
20 - 29 years	0.16	0.00	0.32	0.00	0.25	0.02	0.35	0.00
30 - 39 years	0.07	0.01	0.27	0.00	0.08	0.02	0.28	0.00
40 - 49 years	0.88	0.36	0.27	0.00	0.90	0.37	0.27	0.00
50 - 59 years	0.61	0.12	0.21	0.00	0.61	0.14	0.21	0.00
60 - 69 years	1.48	0.15	0.31	0.00	1.48	0.15	0.31	0.00
70 - 79 years	3.54	0.11	0.75	0.00	4.04	0.26	0.75	0.00
80+ years	7.30	3.31	0.70	0.00	7.55	3.35	0.70	0.00
Education: high school degree
20 - 29 years	0.26	0.02	0.19	0.00	0.33	0.05	0.20	0.00
30 - 39 years	0.36	0.04	0.13	0.00	0.46	0.13	0.13	0.00
40 - 49 years	0.90	0.50	0.14	0.00	1.07	0.63	0.17	0.00
50 - 59 years	1.72	0.73	0.50	0.00	2.04	1.09	0.62	0.00
60 - 69 years	3.44	1.13	1.43	0.00	3.67	1.23	1.61	0.00
70 - 79 years	7.34	2.24	2.72	0.00	7.60	2.30	2.84	0.00
80+ years	7.84	3.69	0.98	0.00	8.41	3.92	0.98	0.00
Education: college degree
20 - 29 years	0.66	0.37	0.14	0.00	0.78	0.41	0.14	0.00
30 - 39 years	0.63	0.35	0.21	0.00	0.77	0.45	0.23	0.01
40 - 49 years	1.51	0.55	0.44	0.01	1.81	0.74	0.62	0.13
50 - 59 years	2.33	0.84	1.15	0.04	2.97	1.42	1.50	0.38
60 - 69 years	4.11	1.67	1.94	0.21	4.52	1.89	2.25	0.56
70 - 79 years	5.97	1.93	3.92	0.04	6.47	2.21	4.17	0.06
80+ years	14.86	7.62	7.98	0.06	19.93	8.92	13.34	0.09
Data: 1992 Survey of Consumer Finances. Directly held assets: See notes to Table 1. W: Directly held financial net worth. S: Directly held stocks. Directly and indirectly held assets: See notes to Table 2. W^b: Directly and indirectly held financial net worth S^b: Directly and indirectly held stocks. Y: After-tax labor income. W/Y and W^b/Y: Ratio of average financial net worth in age-education cell to average after-tax labor income in age-education cell. S/Y and S^b/Y: Ratio of average stocks to average after-tax labor income. Med W/Med Y and Med W^b/Med Y: ratio of median financial net worth in age-education cell to median after-tax labor income in age-education cell. Med S/Med Y and Med S^b/Med Y: Ratio of median stocks to median after-tax labor income.

Table 8. Declared Willingness to Undertake Financial Risks, by Education Level
Household Response	Total Population (%)	Less Than High School (%)	High School (%)	College (%)
High Risk	14	5	12	23
Average Risk	37	18	36	50
No Risk	48	78	52	27
Source: Computed from the 1992 Survey of Consumer Finances. High Risk: Willing to undertake substantial risk for substantial return or above average risk for above average return. Average Risk: Willing to take average risk expecting average return. No Risk: Not willing to undertake any financial risk.

FOOTNOTES
Legends for Figure 1.
Title:
Figure 1. Predicted Ratios of Average Wealth to Average Income for Five Model Variants.

Note to Figure 1:
Note: Model numbers refer to columns in Table 5 and to accompanying model descriptions.

Table 4. Effects of Differences in Income Processes Across Education Groups on Portfolio Allocation
Step	Changes to income process	First-Period Portfolio Solutions			Changes in Portfolio Solutions from Previous Step
		W/Y (1)	S/Y (2)	B/Y (3)	) W/Y (4)	) S/Y (5)	) B/Y (6)
1	income process for LTHS	0.320	0.363	0.683	--	--	--
2	from step 1, change non-shock income level to HS	0.311	0.362	0.672	0.009	0.001	0.011
3	from step 2, change variance of persistent shocks e to HS	0.335	0.374	0.709	0.024	0.012	0.036
4	from step 3, change serial correlation of shocks to HS	0.343	0.378	0.721	0.009	0.004	0.013
5	from step 4, change transitory shocks v to HS = income process for HS	0.343	0.378	0.721	0.000	0.000	0.000
6	from step 5, change no-shock income level to COL	0.663	0.464	1.126	0.319	0.086	0.405
7	from step 6, change tax rate on dividends and interest income	0.739	0.465	1.204	0.076	0.001	0.077
8	from step 7, change variance of persistent shocks e to COL	0.784	0.484	1.268	0.044	0.020	0.064
9	from step 8, change serial correlation shocks to COL	0.774	0.480	1.254	0.009	0.004	0.014
10	from step 9, change transitory shocks v to COL = income process for COL	0.775	0.480	1.255	0.001	0.000	0.001
Notes: LTHS: less than high school education; HS: high school degree; COL: College degree. W/Y: average wealth/average income; S/Y: average stocks/average income; B/Y: average bonds/average income. The table shows the effects on portfolio allocation of gradually converting the income process for the representative agent household with less than high school education into the process for the college-educated household. Mean incomes are computed from the 1992 SCF. Income definitions are given in the data appendix. The calibration method is analogous to that used in Table 3.

Table 5: Comparison of Model Predictions of First-Period Wealth to Income Ratios, by Education and Degree of Risk Aversion
Degree of Risk Aversion	Certain Income, No Bequests	Income Risk, No Bequests W/Y		Income Risk, Bequests W/Y		Income Risk, Population Models Med W/Med Y
	W/Y Rep Agent (1)	Rep Agent (2)	Population (3)	Rep Agent (4)	Population (5)	No Bequests (6)	Bequests (7)
Education: less than high school degree
2	0.58	0.45	0.41	0.36	0.32	0.45	0.36
3	0.45	0.32	0.28	0.19	0.15	0.32	0.19
4	0.37	0.24	0.20	0.08	0.05	0.23	0.08
5	0.33	0.18	0.14	0.01	0.02	0.18	0.01
6	0.29	0.15	0.10	0.03	0.07	0.14	0.04
7	0.27	0.12	0.07	0.07	0.10	0.11	0.08
8	0.25	0.09	0.05	0.10	0.13	0.09	0.10
9	0.24	0.08	0.04	0.12	0.15	0.07	0.12
10	0.22	0.06	0.02	0.13	0.17	0.05	0.14
Education: high school degree
2	0.55	0.47	0.44	0.38	0.35	0.42	0.33
3	0.43	0.34	0.31	0.21	0.18	0.29	0.16
4	0.35	0.26	0.23	0.10	0.08	0.21	0.06
5	0.31	0.21	0.18	0.04	0.01	0.16	0.01
6	0.27	0.17	0.14	0.01	0.04	0.12	0.05
7	0.25	0.14	0.11	0.05	0.07	0.09	0.09
8	0.23	0.12	0.09	0.07	0.10	0.07	0.11
9	0.22	0.11	0.07	0.09	0.12	0.06	0.13
10	0.21	0.09	0.06	0.11	0.14	0.04	0.15
Education: college degree
2	1.06	0.97	0.93	0.84	0.80	1.09	0.95
3	0.87	0.77	0.74	0.58	0.55	0.88	0.67
4	0.76	0.66	0.62	0.43	0.40	0.75	0.51
5	0.69	0.58	0.54	0.33	0.30	0.67	0.41
6	0.64	0.53	0.49	0.27	0.24	0.61	0.34
7	0.60	0.49	0.45	0.22	0.19	0.57	0.28
8	0.58	0.46	0.42	0.18	0.15	0.53	0.24
9	0.56	0.43	0.39	0.15	0.12	0.50	0.21
10	0.54	0.41	0.37	0.13	0.10	0.48	0.19
Notes: W/Y: Ratio of average wealth to average income. Med W/Med Y: Ratio of median wealth to median income. Certain Income: Baseline model with no second-period income shocks. Income Risk: Adds transitory and persistent shocks to second-period incomes. Rep Agent: Representative agent models. Population: Models with populations of heterogenous agents. Bequests: Models with bequest motives; the weight on the bequest motive 8 = 0.25 (see equation (7)). All models have rate of time preference * = 3.13 percent per annum.

Table 6: Comparison of Model Predictions of First-Period Stocks to Income Ratios, by Education and Degree of Risk Aversion
Degree of Risk Aversion	Certain Income, No Bequests	Income Risk, No Bequests S/Y		Income Risk, Bequests S/Y		Income Risk, Population Models Med S/Med Y
	S/Y Rep Agent (1)	Rep Agent (2)	Population (3)	Rep Agent (4)	Population (5)	No Bequests (6)	Bequests (7)
Education: less than high school degree
2	0.72	0.63	0.60	0.68	0.65	0.62	0.66
3	0.43	0.36	0.34	0.40	0.38	0.35	0.39
4	0.30	0.25	0.24	0.28	0.27	0.25	0.28
5	0.23	0.19	0.18	0.22	0.21	0.19	0.21
6	0.19	0.16	0.15	0.18	0.17	0.15	0.17
7	0.16	0.13	0.12	0.15	0.14	0.13	0.15
8	0.14	0.11	0.11	0.13	0.12	0.11	0.13
9	0.12	0.10	0.10	0.11	0.11	0.10	0.11
10	0.11	0.09	0.09	0.10	0.10	0.09	0.10
Education: high school degree
2	0.71	0.65	0.63	0.70	0.68	0.62	0.66
3	0.42	0.38	0.36	0.42	0.40	0.36	0.40
4	0.30	0.26	0.25	0.29	0.28	0.25	0.28
5	0.23	0.20	0.19	0.23	0.22	0.19	0.21
6	0.19	0.16	0.16	0.18	0.18	0.15	0.17
7	0.16	0.14	0.13	0.15	0.15	0.13	0.15
8	0.14	0.12	0.11	0.13	0.13	0.11	0.13
9	0.12	0.10	0.10	0.12	0.11	0.10	0.11
10	0.11	0.09	0.09	0.10	0.10	0.09	0.10
Education: college degree
2	0.87	0.80	0.78	0.86	0.84	0.84	0.91
3	0.53	0.48	0.46	0.53	0.51	0.50	0.55
4	0.38	0.34	0.33	0.38	0.36	0.35	0.39
5	0.29	0.26	0.25	0.29	0.28	0.27	0.30
6	0.24	0.21	0.20	0.24	0.23	0.22	0.25
7	0.20	0.18	0.17	0.20	0.19	0.18	0.21
8	0.18	0.15	0.15	0.17	0.17	0.16	0.18
9	0.15	0.13	0.13	0.15	0.15	0.14	0.16
10	0.14	0.12	0.12	0.13	0.13	0.12	0.14
Notes: W/Y: Ratio of average wealth to average income. Med W/Med Y: Ratio of median wealth to median income. Certain Income: Baseline model with no second-period income shocks. Income Risk: Adds transitory and persistent shocks to second-period incomes. Rep Agent: Representative agent models. Population: Models with populations of heterogenous agents. Bequests: Models with bequest motives; the weight on the bequest motive 8 = 0.25 (see equation (7)). All models have rate of time preference * = 3.13 percent per annum.