Estimating the early exercise premium of American put index options


The International Journal of Banking and Finance, 2008/09 Vol. 6. Number 1: 2008: 31-47 31

ESTIMATING THE EARLY EXERCISE 
PREMIUM OF AMERICAN PUT 
INDEX OPTIONS 

Ako Doffou
Sacred Heart University, United States of America

Abstract

This paper examines empirically the value of early exercise by testing the ability 
of two American put valuation models to predict the early exercise premium 
for the S&P 100 American put options. An accuracy test and a quality test are 
performed on (1) the MacMillan and Barone-Adesi and Whaley model, and (2) 
the Carr, Jarrow and Myneni model. The test results show that early exercise 
premium is significant regardless of moneyness. Moreover, consistent with the 
theory, the value of early exercise is significantly negatively related to moneyness 
and interest rates and significantly positively related to time to maturity and 
to the volatility of the underlying index. Both American put valuation models 
examined do not fully capture the value of early exercise embedded in American 
put prices.

JEL Classification: G13
Key words: Option prices, Early exercise, Moneyness, S&P American put 
option

1.  Introduction

The value of early exercise or early exercise premium is the difference in price 
between an American option and an otherwise identical European option. It is 
difficult to estimate the early exercise premium because American and European 
options rarely have the same state variable or underlying asset. Using transaction 
data on both American and European foreign currency options traded at the 
Philadelphia Stock Exchange, Jorion and Stoughton (1989) directly computed 
the actual value of early exercise for foreign currency options. The average value 
of the premium found was about two percent of the option price. They also tested 
the Geske and Johnson (1984) American option pricing model by regressing 
observed early exercise premium over model predicted early exercise premium. 
They concluded that the Geske-Johnson model tracks well the variation in 

IJBF



32  The International Journal of Banking and Finance, 2008/09 Vol. 6. Number 1: 2008: 31-47

the true early exercise premium. With the exception of foreign currencies, 
other state variables driving both the American option and otherwise identical 
European option do not exist. Hence, estimation of early exercise premium from 
direct comparison is not possible for options whose underlying assets are not 
currencies.  

Shastri and Tandon (1986) and Whaley (1986) propose an alternative 
approach to estimate the value of early exercise for futures options by computing 
the difference between the price given by an American option pricing model and 
that given by the Black-Scholes model. Using the Geske-Johnson futures options 
valuation model, Shastri and Tandon (1986) showed that the value of early 
exercise is significant only for in-the-money options with a fairly long time-to-
maturity. Whaley (1986) found identical result that early exercise premium for 
out-of-the –money futures options is negligible. 

Because of the significant and systematic pricing biases inherent in most 
American put option valuation models, using any model dependent technique to 
estimate the early exercise premium is problematic. Brenner and Galai (1986) 
proposed the use of the put-call parity relationship to estimate the value of early 
exercise for American options. Given the observable prices for put options, call 
options and the underlying stock, they derive the implied risk free interest rate 
from the put-call parity arbitrage condition and use this risk-free rate to estimate 
the value of early exercise.  Using IBM option data from the Chicago Board 
Options Exchange (CBOE) from June 1977 to August 1978, Brenner and Galai 
found an average early exercise premium of 0.9 per cent for at-the-money put 
options and 3.5 per cent for in-the-money put option.

Zivney (1991) takes a similar but modified approach to estimate early 
exercise premium as the difference between the American option price and the 
European option price derived from put-call parity. The data used consist of the 
S&P 100 index options for which Harvey and Whaley (1992) found the dividend 
stream to be distinctly discrete and early exercise for both calls and puts to occur 
frequently. Estimates of early exercise premium are analyzed separately for 
cases where calls are in-the-money and for cases where puts are in-the-money. 
Zivney found an average value of early exercise of 10 percent for put options 
and 3.5 per cent for call options on the S&P 100 index. This approach does not 
pick up the misspecification of the stochastic process for stock prices inherent in 
option pricing models and suffers from inherent biases induced when estimating 
a put-call parity implied riskless rate. Moreover, the estimated values for early 
exercise for put options were contaminated by those for call options, making it 
impossible to separate the two. 

Loudon (1990) compares the predictive ability of the put-pricing model 
developed by MacMillan (1986) and Barone-Adesi and Whaley (1987) to that 
of the Black-Scholes European model. He finds systematic pricing errors in the 
American put option pricing model with the American model put prices being 
significantly closer to market prices than are the Black-Scholes European model 
prices.



The International Journal of Banking and Finance, 2008/09 Vol. 6. Number 1: 2008: 31-47 33

Mispricing by American put valuation models may arise when these 
models misspecify the dynamics of stock prices and the behavior of other option 
parameters, and when the early exercise feature is not properly accounted for. 
Dueker and Miller (2003) measure directly the early exercise premium using 
American and European S&P 500 index options. Using mid-points from bid-ask 
quotes, Dueker and Miller find that the early exercise premium for the American 
S&P 500 index put options is between 7.97% and 10.86% of the option price 
and the estimated premium is most likely biased. This result is consistent with 
Dueker and Miller (1996) in which an adjustment to liquidity biases reduces the 
value of early exercise premium for the S&P 500 index options from $0.22 to 
$0.19.  

Carr, Jarrow, and Myneni (1992), herein refereed to as CJM model, show 
that the early exercise premium is an exact solution to the Black-Scholes or (BS) 
American put option price with moving boundary conditions in contrast to the 
approximations by MacMillan (1986) and Barone-Adesi and Whaley (1987) or 
MBAW model. Hence, the CJM model gives theoretically better results than the 
MBAW model which is a quadratic approximation of the Black-Schole’s partial 
differential equation.

The results from previous studies seem to indicate that existing American 
put option pricing models do not fully capture the market value of early exercise. 
This paper examines empirically the value of early exercise and tests the ability 
of the CJM and MBAW American put valuation models to predict the value of 
early exercise for American put options. The market values of early exercise are 
derived using Rhim and Kim (2000) methodology which does not rely on any 
particular option pricing model. Assuming that the European put-call parity holds 
and that investors are rational, the European put value embedded in an American 
put price can be derive from the put-call parity relationship. The market values 
of early exercise are then easily obtained as the difference between the observed 
market prices of American put options and the derived European put option 
values. Using the S&P 100 index options transaction prices , this study finds 
that the values of early exercise are statistically significant for in-the-money and 
at-the-money put options.

To get reliable estimates of the values of early exercise, the accuracy and 
quality of the MBAW and CJM American put valuation models are tested. 
The accuracy of each model is tested by comparing model-predicted values to 
observed market values. Pricing biases are measured as absolute differences 
between market prices and theoretical prices predicted by the MBAW and the 
CJM models. To further investigate the pricing biases, they are decomposed into 
two components: mispricing of the early exercise premium and mispricing of the 
European option price component caused by the misspecification of the Black-
Scholes formula.

The quality of an American put valuation model is tested by examining how 
well the model captures the true value of early exercise premium. The results are 
consistent with previous work and confirm that American put option valuation 
models do not fully capture the value of early exercise.  



34  The International Journal of Banking and Finance, 2008/09 Vol. 6. Number 1: 2008: 31-47

The rest of the paper is organized as follows. Section 2 introduces the 
model. The test methodologies are explained in section 3. Section 4 describes 
the data set used. The empirical results are analyzed in section 5. Finally, section 
6 concludes the paper.   

2.  The Model

The theoretical value of early exercise can be estimated as the difference between 
the option price generated by an American option pricing model and the price 
of a corresponding European option obtained from the Black-Scholes model. 
This approach implicitly assumes that both American and European option 
pricing models generate correct prices. Prior empirical studies show that both 
American and European option pricing models misprice actual market prices. 
The mispricing by theoretical models may arise from a misspecification of the 
stock price dynamics.

To avoid problems caused by model misspecification, an estimation 
method that does not rely on any particular option pricing model is used. It is 
assumed that option markets are efficient and therefore that the European put-
call parity holds. It is assumed further that investors are rational in that holders 
of American call options do not prematurely exercise their call options when no 
dividends are to be paid on the underlying stock until option maturity. Based on 
these assumptions, the European put-call parity relationship is reconstructed by 
replacing a European call with an American call as follows:

P
E
 + S = C

A
 + Ke-rT (1) 

where C
A
 and P

E
  are respectively the value of an American call option and 

the value of a European put option with the same strike price K and the same 
maturity T. From equation (1) above, we derive the market value of a European 
put option:

P
E
 = C

A
 - S + Ke-rT                                                                                    (2)

The early exercise premium embedded in the American put option, EEP
mkt

,  
can be obtained by subtracting the European put value imputable to put-call 
parity from the observed market price P

A
 of the American put option:

EEP
mkt 

= P
A
 - (C

A  
-

 
S + Ke-rT ) (3)

The four parameters that affect the option price also affect the option early 
exercise premium. These parameters are the option moneyness S/K, the volatility 
of the underlying stock/index price σ, the time to maturity of the option T, and 
the risk-free interest rate r. These parameters are picked up by two major factors 
that directly affect the value of early exercise. The first factor is the critical stock 
price which triggers immediate exercise of the put option. The other factor is 



The International Journal of Banking and Finance, 2008/09 Vol. 6. Number 1: 2008: 31-47 35

the time value of money. The critical stock price, S
C
, is the maximum stock 

price at which it is optimal to exercise the put option immediately. This critical 
stock price is reached when the time value is zero or close to zero so that the put 
price is equal to its intrinsic value. Hence, the critical stock price is obtained by 
solving the following equation

K - S
C
 = P(S

C
,K,t,r,σ) (4)

The critical stock price depends on all the option pricing parameters except 
the current stock price. A rise in the critical stock price leads to a greater value 
for the early exercise premium because it makes a put option more likely to be in 
the money and therefore more likely to be exercised early.

The value of early exercise is also affected by the interest to be earned on 
the strike price that would be received in the event the put option is exercised 
early. The interest earned on the strike price is the difference between the strike 
price and the present value of the strike price or K(1-e-rT).  Because the time 
value of money on interest income is a function of the strike price, interest rate, 
and the time to maturity, a greater time value of money creates a greater value 
of early exercise.

A decrease in moneyness due to a stock price increase will decrease the 
value of early exercise. Using the Black-Scholes formula, It can be shown that 
the partial derivative of the critical stock price with respect to the strike price in 
equation (4) is exactly equal to        which is strictly positive. Hence, a higher 
strike price increases the critical stock price and therefore increases the value 
of early exercise. Moreover, an increase in the strike price increases the interest 
income that can be earned on the strike price when the put option is exercised.

An increase in the volatility of the underlying stock price makes the put 
option more likely to be in the money and therefore increases the value of early 
exercise. An increase in the time-to-maturity increases the value of the put 
option as well as the time value of money and therefore increases the value of 
early exercise. When interest rates increase, the present value of the strike price 
decreases, making put options less valuable. Hence, as interest rates increase, it 
is more likely for put options to be out of the money, and therefore less likely for 
put options to be exercised early. Moreover, as interest rates increase, the time 
value of money increases. Therefore, the early exercise premium for a put option 
may increase, decrease, or remain constant when interest rates increase.

In the paragraph that follows, the test methodologies for both the MBAW 
and CJM models are discussed.

3.  Test Methodologies

3.1  MacMillan, Barone-Adesi and Whaley Model and Tests
Both American and European option prices satisfy the Black-Scholes partial 
differential equation. It follows that the early exercise premium which is the 
difference in prices between an American option and an otherwise identical 

N(d
2
)

N(d
1
)



36  The International Journal of Banking and Finance, 2008/09 Vol. 6. Number 1: 2008: 31-47

( )( )+=
2

1
2

1

8
1

2
1

2

2

1
tTre

rrr
y .

y

C
EA

S

S
PP += for CSS > , and SKPA = for CSS <

( )( )[ ]CC SdN
y

S
11= ,

European option must also satisfy the same partial differential equation. Using 
a quadratic approximation technique, a solution for an American put valuation 
formula P

A
 is

                                     (5)

where P
E
 is the Black-Scholes European put price,                               , 

and                                                                          The put option strike price is 

K. The critical stock price below which it is optimal to exercise the put option 

immediately is
 
S

C  
which is obtained by solving the following equation

                                                                                                       (6)

Assuming that the prices generated by both the MBAW and the Black-
Scholes models are correct, the theoretical value of early exercise, EEP

mdl
 , for 

an American put option can be estimated as follows 
                                                                           
                              (7)

where 
mdlA

P is the MBAW model American put option price and 
mdlE

P the 
Black-Scholes European put option price.

The theoretical value of early exercise given in equation (7) above is 
compared to the actual value of early exercise estimated directly from observed 
market put prices. The difference between model-predicted values of early 
exercise and actual observed market values of early exercise reveals the extent 
to which the American put option pricing models considered do not capture the 
early exercise premium embedded in American put option prices.

There are two critical problems in testing any option pricing model. The 
first problem is that a test of any option pricing model is a joint test of market 
efficiency and model validity. The second problem is that stock price volatility is 
not directly observable. To solve the first problem, a filtered sample is used which 
excludes all observations that violate the no-arbitrage boundary conditions for 
American put-call parity. To get a proper estimate of the stock price volatility, 
the MBAW model is assumed to generate a correct price for a put option when 
the put option is at-the-money. The implied volatility is derived from the MBAW 
model by fitting the model to the at-the-money put option prices. The resulting 
implied volatility is then used to predict remaining put prices. It follows that 
the validity of the tests conducted here lies on the accuracy of the volatility 
estimation.

The MBAW model is tested in two ways. First, the accuracy of the model 
is tested by comparing the model predicted prices to the observed market prices. 

( )+= CEC SPSK

mdlmdl EAmdl
PPEEP =



The International Journal of Banking and Finance, 2008/09 Vol. 6. Number 1: 2008: 31-47 37

mdlA
P  

mktA
P  

mdlA
P  mkt

AP  

Second, the quality of the MBAW model is tested by investigating how well 
this American put valuation model captures the actual value of early exercise. 
In measuring the accuracy of the MBAW model, its pricing biases PB

AM
 are 

computed as follows

                                                                                                           (8)

where 
           

is the observed market value of the American put option and   
            the MBAW model price.

The MBAW model implicitly assumes that the Black-Scholes model 
correctly prices the European portion of an American put option. It follows that 
pricing biases from the MBAW model may arise from the misvaluation of early 
exercise premium and from the misspecification of the Black-Scholes formula. 
Hence, the MBAW pricing biases can be decomposed as follows

                                                                                                      (9)

where PE
BS

 is the pricing error due to the Black-Scholes model 
misspecification and PE

EEX
 the pricing error associated with the misvaluation of 

early exercise premium. The pricing error related to the Black-Scholes model 
misspecification is evaluated as the difference between the Black-Scholes 
European put price,         , and the market value of a European put option,         , 
derived from European put-call parity as follows

                                                                                                         (10)

The pricing error caused by the misvaluation of early exercise premium 
is assessed as the difference between the actual market value of early exercise, 
EEP

mkt
, and the model predicted value of early exercise, EEP

mdl
, 

PE
EEX 

= EEP
mkt

 - EEP
mdl

      (11)

The quality or performance of the MBAW model is evaluated by examining 
how well this model captures the actual market value of early exercise. The 
degree to which the MBAW model misprices the true market values of early 
exercise, DM, is given by

DM = (1-EEP
mdl

/EEP
mkt

)(100).  (12)

To further evaluate the quality of the MBAW model, market values of early 
exercise premium are regressed over model-predicted values of early exercise 
premium. The regression equation is 

EEP
mkt

 = λ
1
 + λ

2
 (EEP

mdl
) + ω  (13)

mdlmkt AAAM
PPPB −=

EEXBSAM PEPEPB +=  

mdlmkt EEBS
PPPE −=  



38  The International Journal of Banking and Finance, 2008/09 Vol. 6. Number 1: 2008: 31-47

Under the null hypothesis that the model-predicted early exercise premium 
perfectly forecasts the true market value of early exercise premium, the intercept 
coefficient, λ

1
, should equal zero and the slope coefficient, λ

2
, should equal 

one.

3.2   Carr, Jarrow and Myneni Model and Tests
The Carr, Jarrow, and Myneni (1992) model or CJM model shows the early 
exercise premium as an exact solution to the Black-Scholes or BS model 
American put option price with moving boundary conditions as opposed to the 
approximation approach of the MBAW model. Consequently, the CJM model 
gives theoretically better results than the MBAW model which is a quadratic 
approximation of the Black-Scholes partial differential equation. However, 
the CJM model has a singularity problem at time zero (i.e., option at maturity) 
and therefore has no known analytic solution. If an option is at expiration, the 
numerical approximation is the only alternative to the CJM exact solution.

In this paper, the performance of the MBAW model and the CJM model are 
compared. The tests undertaken for the CJM model are exactly the same as those 
described above for the MBAW model. The MBAW model provides computing 
efficiency even though the CJM model is theoretically superior. Whether or not 
the CJM model performs significantly better than the MBAW model to offset its 
relative computing time inefficiency is an empirical question not yet answered

4.   The Data

Daily transaction data for put and call options on the S&P100 index (OEX) 
traded on the Chicago Board of Options Exchange (CBOE) are used. The data 
set spans over a ten-year period from January 3, 1995 to January 3, 2005. The 
data consist of the time and price of every transaction in which the price changed 
from the previous transaction for the ten-year period considered. The initial data 
set contains 362,847 OEX index options. All OEX put-call pairs that meet the 
requirements that follow are selected and are used to compute early exercise 
premium. Both put and call options in a put-call pair are options on the same 
underlying stock index, with the same strike price and the same maturity. Bid- 
and-ask data were discarded since no transactions were conducted at those 
prices. Only contracts with maturities between one and four months are retained. 
Longer maturities were too thinly traded, and shorter maturities were too close to 
the maturity date to contain useful information about early exercise premium. To 
avoid days with thin trading, at least 20 call and 20 put transactions are required 
for any given day’s data to be retained. Transactions in at least four strike 
classes for calls and four for puts are required to ensure a range of “moneyness” 
sufficient to provide a good picture of the distribution of early exercise premium. 
Deep-out-of-the-money call and put options defined as those with prices less 
than 5 cents, are deleted from the sample. For these options, the bid-ask spread 
is a big proportion of their time value. Therefore, their implied volatilities would 
be highly sensitive to the bid-ask bounce. Put and call option prices in a retained 



The International Journal of Banking and Finance, 2008/09 Vol. 6. Number 1: 2008: 31-47 39

put-call pair must satisfy the no-arbitrage boundary conditions for American 
put-call parity. Finally, the early exercise premium of a put option cannot be 
greater than the put option price.  

All of the above criteria eliminate 243,906 put and call options from the 
sample, leaving only a total of 118,941 put-call pairs for the estimation of early 
exercise premium. The daily risk-free interest rate is computed from the prices of 
Treasury bills maturing close to the maturity of the option. The tests conducted 
use two volatility measures. The historical volatility (HV) is obtained with daily 
index returns for the previous 180 trading days. The implied volatility (IV) is 
derived using the methodology proposed in Whaley (1982).

5.  Empirical Results

The actual market value of early exercise for American put options is given 
by equation (3). While previous empirical studies estimate the value of early 
exercise based on model-predicted prices, this study estimates early exercise 
premium from actual market prices. Table 1 shows the mean market values of 
early exercise for American put options on OEX Index for the period 01/03/1995 
– 01/03/2005, for all options and for all degrees of moneyness as percentage of 
the put option market prices. For all options, the average value of early exercise 
is $7.436 or 9.55 percent of the put option market price. The mean market value 
of early exercise for in-the-money put options ($11.013) is greater than that for 
at-the-money put options ($5.237) which in turn is greater than that for out-of-
the money put options ($4.411). The average value of early exercise is 3.427 
percent for all out-of-the-money put options compared to 14.622 percent for all 
in-the-money options. This finding is consistent with the fact that out-of-the-
money options contain a negligible value of early exercise.

Numbers in parentheses are mean market values of early exercise expressed as 
a  

Table 2 displays the model predicted mean values of early exercise for 
American put options on OEX Index for the period 01/03/1995 – 01/03/2005. 
Model predicted values of early exercise are estimated as the difference between 
(1) the theoretical American put option price given by the MacMillan, Barone-
Adesi and Whaley (MBAW) model or the Carr, Jarrow and Myneni (CJM) model, 
and (2) the Black Scholes European put option price. The values in parentheses 
are the mean values of model-predicted early exercise expressed as a percent of 
the put price given by the model. The computations based on implied volatility 
show that the MBAW model predicts a mean early exercise premium of $4.42 
for in-the-money put options and $0.33 for out-of-the-money put options, while 
the CJM model predicts a mean exercise premium of $4.62 for in-the-money 
put options and $0.29 for out-of-the-money put options. These models predicted 
mean values of early exercise are substantially lower than the mean market 
values of early exercise computed in Table 1, an indication that the MBAW and 
the CJM American valuation models undervalue the early exercise premium. 



40  The International Journal of Banking and Finance, 2008/09 Vol. 6. Number 1: 2008: 31-47

This result is sustained when the model predicted mean values of early exercise 
are computed based on historical volatility. Table 2 also shows that computations 
based on historical volatility lead to a wider gap for the mean value of early 
exercise between the in-the-money options and out-of-the-money options. 

TABLE 1: Mean market values of early exercise for American put options on 
OEX Index: 01/03/1995 – 01/03/2005.

Number of Observations Mean Market Value of Early 
Exercise

In-the-money 52,025
11.013

(14.622)

At-the-money 19,699
5.237

(10.829)

Out-of-the-money 47,217
4.411

(3.427)

All 111,941
7.436
(9.550

Consistent with equation (3), market values of early exercise premium are defined as ob-
served market price of American put option minus the European put value of the option 
derived from put/call parity. The average bid and ask yield quotations on Treasury bills 
that expire closest to the option’s expiration date are used as estimates for the risk-free 
rate of interest. The values in parentheses are mean market values of early exercise ex-
pressed as a percentage of the put option market price.

TABLE 2: Model Predicted Mean Values of Early Exercise for American Put 
Options on OEX Index: 01/03/1995 – 01/03/2005. 

Number of 
Observations

MBAW
H.V

CJM
H.V

MBAV
I.V

CJM
I.V

In-the-money
52,025 5.78129

(7.12458)
5.93864

(7.41797)
4.42129

(5.23872)
4.61518
(5.53892

At-the-
money 19,699

0.69173
(3.61192)

0.72479
(3.76726)

0.71026
(2.59809)

0.73148
(2.73949)

Out-of-the-
money 47,217

0.25164
(3.20478)

0.22471
(2.19897)

0.32812
(1.69968)

0.29036
(1.44648)

All
118,941

2.74320
(4.98674)

2.80680
(4.74151)

2.18177
(3.39646)

2.25510
(3.45067)

MBAW stands for the MacMillan, Barone-Adesi and Whaley model values, while CJM 
stands for the Carr, Jarrow and Myneni model values. Model predicted values of early 
exercise are estimated as the difference between (1) the theoretical American put option 
price given by the MBAW model or the CJM model, and (2) the Black Scholes European 
put option price. H.V. and I.V. are historical volatility and implied volatility respectively. 
The values in parentheses are mean values of model-predicted early exercise expressed 
as a percent of model put price.



The International Journal of Banking and Finance, 2008/09 Vol. 6. Number 1: 2008: 31-47 41

To test the relationship between early exercise premium and option 
parameters, market values of early exercise are regressed on four option 
parameters: option moneyness measured by the stock price over the strike price, 
time to maturity, volatility of the underlying stock/index price, and interest rates. 
The results of these regressions are displayed in Table 3. 

TABLE 3: Market Values of Early Exercise, EEP
mkt

 , are Regressed on Put 
Option Moneyness, Time to Maturity, Volatility of the Stock Price and Interest 
Rate:

The signs of the coefficient estimates are consistent with the theory. As the moneyness 
defined by S / K increases, the put option is more likely to be out-of-the money and 
therefore less valuable. Hence, the early exercise premium decreases as the moneyness 
increases which is consistent with a negative sign for the β

1
 coefficient. As the time to 

maturity increases, a put option value increases, making the early exercise premium more 
valuable. Hence, the sign of the β

2
 coefficient is positive. As the volatility increases, a 

put option price increases, making the early exercise premium more valuable. Therefore, 
the sign of the β

3
 coefficient is positive. As interest rates increase, the present value of 

the strike price decreases, making it more likely for the stock price to be above the strike 
price. Hence, as interest rates increase, the put option will more likely be out-of-the-
money, making the early exercise premium less valuable. This corresponds to a negative 
sign for the β

4  
coefficient. 

The value of early exercise premium, EEP
mkt

 , is computed as the difference between 
(1) the price of the American put option observed in the market and (2) the price of the 
European put option derived from put/call parity. Implied volatility measures are used 
to estimate this regression model. The time-to-maturity is derived as the number of days 
to maturity divided by 365 days. The daily risk-free interest rate is computed from the 
prices of Treasury bills maturing close to the maturity of the options. The numbers in 
parentheses are t-statistics.

 

The signs of the coefficient estimates are consistent with the theory. As the 
moneyness defined by S / K increases, the put option is more likely to be out-
of-the-money and therefore less valuable. Hence, the early exercise premium 
decreases as the moneyness increases which is consistent with a negative sign 
for the β

1
 coefficient. As the time to maturity increases, a put option value 

increases, making the early exercise premium more valuable, consistent with a 
positive sign for the β

2
 coefficient. As the volatility increases, a put option price 

21 ++=
K

S
EEPmkt (time to maturity) + 3 (volatility) + 4 (interest rate) +

Number of
Observations

1 2 3 4
2RAdj

118,941
- 0.03865
(-10.2735)

- 0.00239
(-21.3814)

0.34862
(87.5975)

0.00186
(17.9108)

- 0.05271
(- 41.3829)

0.3685



42  The International Journal of Banking and Finance, 2008/09 Vol. 6. Number 1: 2008: 31-47

increases, making the early exercise premium more valuable, consistent with a 
positive sign for the β

3
 coefficient. As interest rates increase the value of a put 

option decreases making the early exercise premium less valuable consistent 
with a negative sign for the β

4
 coefficient. The value of early exercise premium,  

EEP
mkt

, is computed as the difference between (i) the price of the American 
put option observed in the market and (ii) the price of the European put option 
derived from put/call parity as given in equation (3). Implied volatility measures 
are used to estimate this regression model. The time to maturity is measured as 
the number of days to maturity divided by 365 days. The daily risk-free interest 
rate is computed from the average bid and ask yield quotations on Treasury bills 
maturing closest to the maturity of the option. The numbers in parentheses are t-
statistics. Overall, the regression results show that the early exercise premium is 
significantly positively related to time to maturity and volatility and significantly 
negatively related to meneyness and interest rates.

The empirical results of the accuracy test of the valuation models used are 
reported in Tables 4. The accuracy of the model is tested by comparing model-
predicted values to observed market values. Table 4 shows the mean absolute 
percentage option pricing error by moneyness. This statistic is defined as the 
difference between the model price and the observed market price of the put 
option divided by the market price of the put option. The MBAW and CJM models 
perform more accurately under implied volatility (IV) than under historical 
volatility (HV), consistent with previous work in the finance literature. The 
Black-Scholes model (BS) performs better under historical volatility than under 
implied volatility. American put valuation models attempt to predict American 
put prices by approximating the value of early exercise. For in-the-money put 
options, market prices reflect mainly their intrinsic values. For out-of-the-money 
put options, market prices consist mainly of their time values. Hence, out-of-
the-money options are subject to more pricing errors than in-the-money options. 
This assertion is supported by the mean absolute percentage option pricing error 
by moneyness reported in Table 4. For the MBAW and CJM models with IV, 
the mean absolute percentage pricing error is 2.05 percent and 2.00 percent 
respectively, for all in-the-money options and 5.66 percent and 5.74 percent 
respectively, for all out-of-the-money put options. This result is consistent with 
Blomeyer and Johnson (1988).  The models with IV price more accurately than 
the same models with HV.

Because both the MBAW and CJM models implicitly assume that the Black-
Scholes model correctly prices European values of American put options, pricing 
biases reported for these models inherently contain pricing errors resulting from 
the Black-Scholes model’s misspecification of the stock price dynamics.  For 
the Black-Scholes model, Table 4 reports a mean absolute percentage pricing 
error of 7.81 percent and 6.42 percent using implied volatility and historical 
volatility respectively for in-the-money put options. For out-the-money options, 
the numbers are 19.45 percent and 17.27 percent under IV and HV respectively. 
Hence, the Black-Scholes model’s misspecification is more pronounced in 
pricing out-of-the-money put options than in pricing in-the-money put options. 



The International Journal of Banking and Finance, 2008/09 Vol. 6. Number 1: 2008: 31-47 43

TABLE 4: Option Models Pricing Biases: Mean Absolute Percentage Option 
Pricing Error by Moneyness.

Number of 
Observations

MBAW
(H.V)

CJM
(H.V)

BS
(H.V)

MBAW
(H.V)

CJM
(I.V)

BS
(I.V)

In-the-
money

52,025 4.2831 4.1937 6.4228 2.0543 2.0075 7.8109

At-the-
money

19,699 7.8694 7.8429 11.6481 4.5712 4.3918 15.1404

Out-
of-the-
money

47,217 12.2573 12.4521 17.2707 5.6628 5.7404 19.4461

All 118,941 8.0426 8.0765 11.5946 3.9036 3.8843 13.6437

The mean absolute percentage option pricing errors are computed for the MacMillan 
(1986) and Barone-Adesi & Whaley (1987) model (MBAW), the Carr, Jarrow and Myneni 
(1992) model (CJM), and the Black-Scholes (1973) model (BS). These computations are 
done using both historical volatility (H.V) and implied volatility (I.V). The mean absolute 
percentage option pricing error is defined as the absolute value of the difference between 
the model price and the observed market price divided by the market price of the put 
option

TABLE 5: Mispricing of Early Exercise Premium for American Put Options on 
OEX Index: 01/03/1995 - 01/03/2005.

Number of 
Observations

MBAW
(H.V)

CJM
(H.V)

BS
(H.V)

MBAW
(H.V)

In-the-
money

52,025
5.2317

(48.3105)
5.0744

(43.9843)
6.5917

(52.7835)
6.3978

(47.2425)

At-the-
money

19,699
4.5453

(71.3251)
4.5122

(68.4893)
4.5267

(71.8931)
4.5055

(68.5547)

Out-
of-the-
money

47,217
4.1594

(83.4691)
4.1863

(84.5722)
4.0829

(82.0743)
4.1206

(83.2172)

All 118,941
4.6923

(65.4271)
4.6257

(63.1082)
5.2538

(67.3314)
5.1804

(66.0452)

The mispricing of early exercise premium is computed for the MacMillan, Barone-
Adesi and Whaley model (MBAW) and, the Carr, Jarrow and Myneni model (CJM). The 
mispricing is the difference between the market value of early exercise premium and the 
model predicted value of early exercise premium. The computations are performed using 
both historical volatility (H.V.) and implied volatility (I.V.). The values in parentheses 
are mean values of the mispricing expressed as a percent of the market value of early 
exercise premium.                                                                            



44  The International Journal of Banking and Finance, 2008/09 Vol. 6. Number 1: 2008: 31-47

The quality of an American put valuation model is tested by examining 
how well the model captures the true values of early exercise premium. 
Mispricing of early exercise premium can be assessed by comparing model-
predicted values of early exercise premium to market values of early exercise 
premium. The computations are performed using both historical volatility (HV) 
and implied volatility (IV). Table 5 shows the mispricing of early exercise 
premium by moneyness for American put options on OEX Index for the period 
01/03/1995– 01/03/2005. The values in parentheses are mean values of the 
mispricing expressed as a percent of the market value of early exercise premium. 
For all options, only about 33% of the market value of early exercise is captured 
by the MBAW model with IV. For out-of-the-money options, more than 82% 
of the market value of early exercise is not captured by this model, whereas 
nearly 53% of the early exercise premium is not accounted for when the option 
is in-the-money. This large mispricing of early exercise premium for put options 
regardless of moneyness seems to explain the significantly high pricing biases 
reported in Table 4.

TABLE 6: Regression Results: The market value of early exercise premium, 
EEP

mkt 
, is regressed over the theoretical value of early exercise premium, EEP

mdl
, 

for put options on OEX Index: 01/03/1995 – 01/03/2005.

  

                                                   
The market values of early exercise premium are defined as observed market 
price of American put option minus the European put value of the option 
derived from put/call parity. The theoretical value of early exercise premium is 
computed as the difference between (1) the model price estimated using either 
the MBAW model or the CJM model, and (2) the Black-Scholes model price. 
Implied volatility and historical volatility are designated by (I.V.) and (H.V.) 
respectively. The values in parentheses are t-statistics computed by setting λ

1
 = 

1 and λ
2
 = 1.

( )++= mdlmkt EEPEEP 21

Model All Observations
1 2

2RAdj

MBAW
(H.V.)

118,941
-1.68735
(-6.9381)

0.62476
(49.5137)

0.70135

CJM
(H.V.)

118,941
-1.62067
(-3.8527)

0.62926
(27.3643)

0.70120

MBAW
(I.V.)

118,941
-0.98684
(-6.7985)

0.54234
(36.5764)

0.73694

CJM
(I.V.)

118,941
-0.91073
(-5.2941)

0.54298
(22.3641)

0.73158



The International Journal of Banking and Finance, 2008/09 Vol. 6. Number 1: 2008: 31-47 45

To investigate further the quality of the MBAW and the CJM models 
with both measures of volatility, market values of early exercise premium is 
regressed over model-predicted values of early exercise premium. Under the 
null hypothesis that the model-predicted early exercise premium perfectly 
forecasts the true market value of early exercise premium, the intercept and slope 
coefficients are expected to equal  zero and one respectively. The regression 
results appear in Table 6. The values in parentheses are t-statistics computed 
by setting the intercept and slope coefficients to zero and one respectively. The 
statistically significant t-values reported for both coefficients suggest that the 
null hypothesis is rejected. The explanatory power of the regression as provided 
by the Adjusted-R2 indicates that more than 70% and more than 73% of the 
variation in the market value of early exercise premium can be explained by the 
two models under HV and IV respectively. Overall, the results from the quality 
test suggest that both American put valuation models do not properly capture the 
value of early exercise embedded in American put prices. The ability of these 
models to capture the value of early exercise is particularly weak for out-of-the-
money put options.

6.   Conclusions

This paper examines empirically the value of early exercise for American put 
options. Market values of early exercise premium for put options on S&P 100 
Index are  directly derived from observable market prices of put options using the 
European put-call parity relationship. For the period 01/03/1995 – 01/03/2005, 
the mean market value of early exercise was about $7.44 per option or 9.55% 
of the option price. Consistent with prior empirical evidence, early exercise 
premium for out-of-the-money put options is not significant. Consistent with the 
theory, the value of early exercise found is significantly positively related to the 
time to maturity and to the volatility of the underlying Index, and significantly 
negatively related to moneyness and interest rates.

The quality of the American put option pricing models developed by (1) 
McMillan (1986) & Barone-Adesi and Whaley (1987) and (2) Carr, Jarrow 
and Myneni (1992) are tested by investigating the proportion of early exercise 
premium captured by the model-predicted prices.  The results indicate that for all 
options, on average, about 35% of the market value of early exercise is captured 
by either the MBAW model or the CJM model. Hence, the MBAW and the CJM 
American put valuation models do not fully capture the value of early exercise 
embedded in American put prices. These models ability to capture the value of 
early exercise is particularly weak for out-of-the-money put options.  

Assuming that the MBAW and CJM models correctly price at-the-money 
put options, a performance test is conducted comparing model-predicted prices 
to observed market prices. The result is that both American valuation models 
significantly misprice options regardless of moneyness. These pricing biases are 
mainly due to the misvaluation of early exercise premium and the misspecification 
of the Black-Scholes model. The results of this study lead to conclude that the 



46  The International Journal of Banking and Finance, 2008/09 Vol. 6. Number 1: 2008: 31-47

MBAW and the CJM American put valuation models predictions of put option 

market prices are acceptable.

Author statement: Aku Doffu is an associate professor of finance, John F. Welch 
College of Business, Sacred Heart University, United States. E-mail: adoff21@
yahoo.com. This paper was reviewed anonymously, and then edited to conform 
to the format of the Journal. The author wishes to record his appreciation to its 
editorial office for the invitation to submit this paper when it was presented at 
the 2007 FMA conference. The author takes full responsibility for the remaining 
errors.  

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Carr, Peter, Robert Jarrow, and Ravi Myneni, 1992, “Alternative Characterizations 
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Dueker, Michael, and Thomas W. Miller Jr., 2003, “Directly Measuring Early 
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Dueker, Michael, and Thomas W. Miller Jr., 1996, “Market Microstructure 
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MacMillan, L. W., 1986, “An Analytic Approximation for the American Put 
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Rhim, Jong C., and Yong H. Kim, 2000, “An Estimation of Early Exercise 
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The International Journal of Banking and Finance, 2008/09 Vol. 6. Number 1: 2008: 31-47 47

Shastri, Kuldeep, and Kishore Tandon, 1986, “An Empirical Test of a Valuation 
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	International Journal of Banking and Finance
	9-1-2008

	Estimating the early exercise premium of American put index options
	Ako Doffou
	Recommended Citation