Considering the uncertainty of a financial market includes two aspects: risk and vagueness; in this paper, fuzzy sets theory is applied to model the imprecise input parameters (interest rate and volatility). We present the fuzzy price of compound option by fuzzing the interest and volatility in Geske’s compound option pricing formula. For each α, the α-level set of fuzzy prices is obtained according to the fuzzy arithmetics and the definition of fuzzy-valued function. We apply a defuzzification method based on crisp possibilistic mean values of the fuzzy interest rate and fuzzy volatility to obtain the crisp possibilistic mean value of compound option price. Finally, we present a numerical analysis to illustrate the compound option pricing under fuzzy environment.
1. Introduction
Compound options are options with other options as underlying assets. Since Geske [1] derived the closed form pricing formula using the method of partial differential equations for the first time, some scholars have extended the pricing model and proposed some new pricing methods. For example, [2] used the martingale approach and the expectation of a truncated bivariate normal variables to prove the pricing formula for 2-fold compound options, respectively. The work of [3] extended the Geske model to a multivariate normal integral for the valuation of a compound real option. The work of [4–6] extended the Geske model to n-fold compound options. The work of [7, 8] introduced time dependent volatility and an interest rate to the pricing model of compound options. Fouque and Han [9] proposed perturbation approximation to compute the prices of compound options. There are few literature studied compound option pricing under jump-diffusion model, stochastic volatility model, or stochastic interest rate model, such as [10–12]. Compound option is widely employed in the field of financial derivatives pricing, for instance, American put option [13], sequential exchange options [14], and sequential American exchange property options [15]. Compound option is also widely used in the real options; examples include project valuation of new drug application [16], valuation of multistage BOT projects [17], and decision-making in petroleum exploration [18].
The literature mentioned above studied compound option within stochastic framework. The uncertainty of the financial market includes two aspects: risk and vagueness, and the two parts could not substitute each other. In the real financial market, due to market fluctuations and human errors, some parameters such as the interest rate and volatility sometimes cannot be recorded or collected precisely. The risk uncertainty could be modeled by the probability theory; the vagueness could be modeled by a fuzzy methodology, the fuzzy sets theory provides an appropriate tool for tackling this kind of uncertainty. Therefore, the fuzzy sets theory proposed by Zadeh [19] has been widely used in the option pricing recently. The existing literature on option pricing under the fuzzy stochastic model mainly studied the European option, based on the Black-Scholes model. For example, Yoshida [20] introduced fuzzy logic to the stochastic financial model and discussed the valuation of the European options with the uncertainty of both randomness and fuzziness. Wu [21] considered the fuzzy pattern of the Black-Scholes formula by fuzzing the interest rate, volatility, and stock price in his paper when the arithmetics in the Black-Scholes formula are replaced by fuzzy arithmetic. The work of [22, 23] presented a sensitivity analysis based on the Black-Scholes formula. The work of [24] introduced a crisp weighted possibilistic mean value Black-Scholes option pricing formula. There are only few papers that studied American options or exotic options pricing within the Black-Scholes framework, such as [25–27], and few papers for alternative models with jumps [28–30]. As far as we know, there is no literature research on compound option pricing under fuzzy environment; this paper will consider both the risk and vagueness to study compound option pricing. The main contribution of this paper is that we present the α-level set of fuzzy prices for each α and give a sensitivity analysis of the crisp possibilistic mean value of compound option price with respect to the core value of fuzzy interest rate and fuzzy volatility.
The remainder of the paper is organized as follows. In Section 2, the notions of fuzzy numbers and the arithmetics of fuzzy numbers are introduced. In Section 3, the pricing formula for compound option under stochastic model is introduced. Section 4 presents the fuzzy price, α-level set of fuzzy prices, and the crisp possibilistic mean value of compound option price. In Section 5, a numerical analysis is performed. Finally, the conclusions are stated in Section 6.
2. Fuzzy Numbers
In this section we follow the notations and concepts introduced in Wu [21, 31].
Let ℝ be the set of all real numbers. Then a fuzzy subset A~ of ℝ is defined by its membership function μA~:ℝ→[0,1]. We denote by A~α={x:μA~(x)≥α} the α-level set of A~ for all α∈(0,1]. The 0-level set A~0 of A~ is defined by the closure of the set {x:μA~(x)>0}. A~ is called a normal fuzzy set if there exists an x such that μA~(x)=1, and A~ is called a convex fuzzy set if μA~(λx+(1-λ)y)≥min{μA~(x),μA~(y)} for all λ∈[0,1].
Let f be a real-valued function defined on ℝ. Then f is said to be upper semicontinuous if {x:f(x)≥α} is a closed set for each α.
Let a~ be a fuzzy subset of ℝ. Then a~ is called a fuzzy number if the following conditions are satisfied:
a~ is a normal and convex fuzzy set;
its membership function μa~ is upper semicontinuous;
the 0-level set a~0 is bounded.
If a~ is a fuzzy number, then the α-level set a~α is a closed interval and the α-level set of a~ is denoted by a~α=[a~αL,a~αU].
Lemma 1.
Let a~ and b~ be two fuzzy numbers. Then a~⊕b~,a~⊖b~, and a~⊗b~ are also fuzzy numbers and their α-level sets are
(1)(a~⊕b~)α=[a~αL+b~αL,a~αU+b~αU],(a~⊖b~)α=[a~αL-b~αU,a~αU-b~αL],(a~⊗b~)α=[min{a~αLb~αL,a~αLb~αU,a~αUb~αL,a~αUb~αU},max{a~αLb~αL,a~αLb~αU,a~αUb~αL,a~αUb~αU}],
for all α∈[0,1]. If the α-level set b~α of b~ does not contain zero, then a~⊘b~ is also a fuzzy number, and its α-level set is
(2)(a~⊘b~)α=[min{a~αLb~αL,a~αLb~αU,a~αUb~αL,a~αUb~αU},max{a~αLb~αL,a~αLb~αU,a~αUb~αL,a~αUb~αU}],
for all α∈[0,1].
a~ is called a crisp number with value m if its membership function is
(3)μa~(x)={1ifx=m,0otherwise.
It is denoted by a~=1~{m}. We see that the real numbers are the special case of the fuzzy numbers when the real numbers are regarded as the crisp numbers.
Lemma 2.
Let f(x1,x2,…,xn) be a continuous real-valued function defined on ℝn and let a~1,a~2,…,a~n be n fuzzy numbers. Let f~:ℱn→ℱ be a fuzzy-valued function induced by f(x1,x2,…,xn) via the extension principle. Suppose that each {(x1,x2,…,xn):y=f(x1,x2,…,xn)} is a compact subset of ℝn for y in the range of f. Then f~(a~1,a~2,…,a~n) is a fuzzy number and its α-level set is
(4)(f~(a~1,a~2,…,a~n))α={f(x1,x2,…,xn):x1∈(a~1)α,…,xn∈(a~n)α}={f(x1,x2,…,xn):(a~1)αL≤x1≤(a~1)αU,…,(a~n)αL≤xn≤(a~n)αU}.
The membership function of a triangular fuzzy number a~ is defined by
(5)μa~(x)={1-ac-xγ
if
ac-γ≤x≤ac,1-x-acβ
if
ac≤x≤ac+β,0
otherwise
,
which is denoted by a~=(ac-γ,ac,ac+β), ac is called the core value of a~, and γ>0 and β>0 are called the left and right spreads of a~, respectively. The triangular fuzzy number a~ can be expressed as “around ac” or “being approximately equal to ac.” The α-level set of a~ is a~α=[ac-(1-α)γ,ac+(1-α)β].
Fullér and Majlender [32] defined the crisp possibilistic mean value of a fuzzy number a~ with α-level set a~α=[a~αL,a~αU] as
(6)M(a~)=∫01α(a~αL+a~αU)dα.
The crisp possibilistic mean value of a triangular fuzzy number a~=(ac-γ,ac,ac+β) is M(a~)=ac+(β-γ)/6.
3. Compound Option Pricing under Stochastic Model
A compound option is an option on an option. Therefore, a compound option has two expiration dates and two strike prices. There are four types of European compound options; in this paper we take a call on a call as an example. If an investor buys a compound option at time 0, then, on the first expiration date T1, the option holder has the right to buy a new call option with the strike price K1. The new option gives the holder the right to buy the underlying asset with the strike price K2 at time T2.
We suppose the underlying asset price S(t) satisfies the following stochastic differential equation:
(7)dS(t)=S(t)[μdt+σdW(t)],
where μ is the expected rate of return, σ is the volatility, and W(t) is a standard Brownian motion. The well-known closed form compound option pricing formula is presented in Geske [1] as the following lemma.
Lemma 3.
The closed form pricing formula for compound option at time 0 is
(8)C=SN2(d1,d2,ρ)-K2e-rT2N2(d3,d4,ρ)-K1e-rT1N(d3),
where
(9)d1=ln(S/S*)+(r+(1/2)σ2)T1σT1,d2=ln(S/K2)+(r+(1/2)σ2)T2σT2,d3=d1-σT1,d4=d2-σT2,ρ=T1T2.r is the risk-free interest rate, S is the underlying asset price at time 0, N(x) is the standard normal distribution function, N2(x,y,ρ) is the bivariate standard normal distribution function with x and y as upper limits and ρ as the correlation coefficient between the two variables, and S* is the unique solution of the equation
(10)xN(d+σT2-T1)-K2e-r(T2-T1)N(d)=K1,
where
(11)d=ln(x/K2)+(r-(1/2)σ2)(T2-T1)σT2-T1.
4. Compound Option Pricing under Fuzzy Environment
As discussed before, owing to the imprecise information and the fluctuations of the financial market from time to time, it is unreasonable to assume that the interest rate r and the volatility σ are constants. According to Wu [21] and Nowak and Romaniuk [29], we replace r and σ in (8) by fuzzy numbers r~ and σ~, respectively, and replace the arithmetics by fuzzy arithmetics to get the analytical formula for the compound option under fuzzy environment, which is given in Theorem 4.
Theorem 4.
Let the interest rate and the volatility be fuzzy numbers. Then the fuzzy price of compound option is
(12)C~=1~{S}⊗N~2(d~1,d~2,1~{ρ})⊝1~{K2}⊗e-r~⊗1~{T2}⊗N~2(d~3,d~4,1~{ρ})⊝1~{K1}⊗e-r~⊗1~{T1}⊗N~(d~3),
where
(13)d~1=[1~{ln(S/S*)}⊕(r~⊕1~{1/2}⊗σ~⊗σ~)⊗1~{T1}]⊘(σ~⊗1~{T1}),d~2=[1~{ln(S/K2)}⊕(r~⊕1~{1/2}⊗σ~⊗σ~)⊗1~{T2}]⊘(σ~⊗1~{T2}),d~3=d~1⊖(σ~⊗1~{T1}),d~4=d~2⊖(σ~⊗1~{T2}).S* is the unique solution of the equation
(14)xN(d*+M(σ~)T2-T1)-K2e-M(r~)(T2-T1)N(d*)=K1,
where
(15)d*=ln(x/K2)+(M(r~)-(1/2)[M(σ~)]2)(T2-T1)M(σ~)T2-T1,M(r~)=∫01α(r~αL+r~αU)dα,M(σ~)=∫01α(σ~αL+σ~αU)dα.r~αL and r~αU are the left-end point and right-end point of the α-level set of r~, respectively, and σ~αL and σ~αU are the left-end point and right-end point of the α-level set of σ~, respectively.
Proof.
It is easily obtained from Lemma 3 by replacing r and σ by the fuzzy numbers r~ and σ~, respectively, and replacing the arithmetics by fuzzy arithmetics.
Under fuzzy environment, the option price C~ is a fuzzy number, the α-level set of C~ may be denoted as C~α=[C~αL,C~αU], and C~αL and C~αU can be calculated as the following theorem.
Theorem 5.
The left-end point and right-end point of the α-level set C~α=[C~αL,C~αU] can be calculated as follows:
(16)C~αL=SN2((d~1)αL,(d~2)αL,ρ)-K2e-r~αLT2N2((d~3)αU,(d~4)αU,ρ)-K1e-r~αLT1N((d~3)αU),C~αU=SN2((d~1)αU,(d~2)αU,ρ)-K2e-r~αUT2N2((d~3)αL,(d~4)αL,ρ)-K1e-r~αUT1N((d~3)αL),
where
(17)(d~1)αL=min{a~αLb~αL,a~αLb~αU,a~αUb~αL,a~αUb~αU},(d~1)αU=max{a~αLb~αL,a~αLb~αU,a~αUb~αL,a~αUb~αU},a~αL=lnSS*+[r~αL+12(σ~αL)2]T1,a~αU=lnSS*+[r~αU+12(σ~αU)2]T1,b~αL=σ~αLT1,b~αU=σ~αUT1,(d~2)αL=min{m~αLn~αL,m~αLn~αU,m~αUn~αL,m~αUn~αU},(d~2)αU=max{m~αLn~αL,m~αLn~αU,m~αUn~αL,m~αUn~αU},m~αL=lnSK2+[r~αL+12(σ~αL)2]T2,m~αU=lnSK2+[r~αU+12(σ~αU)2]T2,n~αL=σ~αLT2,n~αU=σ~αUT2,(d~3)αL=(d~1)αL-σ~αUT1,(d~3)αU=(d~1)αU-σ~αLT1,(d~4)αL=(d~2)αL-σ~αUT2,(d~4)αU=(d~2)αU-σ~αLT2.
Proof.
Because the standard normal distribution function N(x) and the bivariate standard normal distribution function N(x,y,ρ) are increasing functions, e-x is a decreasing function; according to Lemmas 1 and 2, from (12) the left-end point of the α-level set C~α=[C~αL,C~αU] is
(18)C~αL=(1~{S}⊗N~2(d~1,d~2,1~{ρ}))αL-(1~{K2}⊗e-r~⊗1~{T2}⊗N~2(d~3,d~4,1~{ρ}))αU-(1~{K1}⊗e-r~⊗1~{T1}⊗N~(d~3))αU=SN2((d~1)αL,(d~2)αL,ρ)-K2e-r~αLT2N2((d~3)αU,(d~4)αU,ρ)-K1e-r~αLT1N((d~3)αU),
where (d~1)αL, (d~2)αL, (d~3)αU, and (d~4)αU are given as Theorem 5. In the same way, C~αU can be proved.
We provide a method to find a crisp number that synthesizes the fuzzy number by replacing r~ and σ~ in Theorem 4 by their crisp possibilistic mean values M(r~) and M(σ~), respectively, to get the crisp possibilistic mean value of compound option price.
Theorem 6.
The crisp possibilistic mean value of the compound option price is
(19)M(C~)=SN2(M(d~1),M(d~2),ρ)-K2e-M(r~)T2N2(M(d~3),M(d~4),ρ)-K1e-M(r~)T1N(M(d~3)),
where
(20)M(d~1)=ln(S/S*)+(M(r~)+(1/2)[M(σ~)]2)T1M(σ~)T1,M(d~2)=ln(S/K2)+(M(r~)+(1/2)[M(σ~)]2)T2M(σ~)T2,M(d~3)=M(d~1)-M(σ~)T1,M(d~4)=M(d~2)-M(σ~)T2.
Proof.
From Theorem 4 we have
(21)M(C~)=SM(N~2(d~1,d~2,1~{ρ}))-K2M(e-r~⊗1~{T2})M(N~2(d~3,d~4,1~{ρ}))-K1M(e-r~⊗1~{T1})M(N~(d~3))=SN2(M(d~1),M(d~2),ρ)-K2e-M(r~)T2N2(M(d~3),M(d~4),ρ)-K1e-M(r~)T1N(M(d~3)),
where M(d~i), i=1,2,3,4, are given as Theorem 6.
5. Numerical Analysis
In this section, we provide some numerical results of compound option pricing under fuzzy environment. For comparison, Table 1 presents the numerical results of the critical value S* and compound option price C under the Black-Scholes model, where the critical value S* can be obtained by solving (10) using the bisection method, and the precision is 10-5. All the computations are performed using Matlab software.
The numerical results of S* and C under Black-Scholes model.
S
K1
K2
T1
T2
r
σ
S*
C
90
5
90
0.5
1
0.05
0.3
82.8336
8.8868
95
5
90
0.5
1
0.05
0.3
82.8336
11.8885
105
5
90
0.5
1
0.05
0.3
82.8336
18.9879
100
4
90
0.5
1
0.05
0.3
80.3707
16.0888
100
4.5
90
0.5
1
0.05
0.3
81.6430
15.6766
100
6
90
0.5
1
0.05
0.3
85.0172
14.4955
100
5
80
0.5
1
0.05
0.3
74.8669
21.7684
100
5
85
0.5
1
0.05
0.3
78.8616
18.3432
100
5
95
0.5
1
0.05
0.3
86.7835
12.5739
100
5
90
0.25
1
0.05
0.3
78.3652
14.8361
100
5
90
0.55
1
0.05
0.3
83.8285
15.3843
100
5
90
0.75
1
0.05
0.3
88.2795
15.8987
100
5
90
0.5
0.75
0.05
0.3
88.2795
13.6596
100
5
90
0.5
1
0.05
0.3
82.8336
15.2744
100
5
90
0.5
1.25
0.05
0.3
78.3652
16.8882
100
5
90
0.5
1
0.04
0.3
83.1909
14.7403
100
5
90
0.5
1
0.055
0.3
82.6556
15.5449
100
5
90
0.5
1
0.06
0.3
82.4780
15.8173
100
5
90
0.5
1
0.05
0.25
85.4360
13.6727
100
5
90
0.5
1
0.05
0.32
81.7635
15.9318
100
5
90
0.5
1
0.05
0.35
80.1417
16.9306
Triangular fuzzy numbers are applied to denote the fuzzy parameters r~ and σ~ because of their simple properties. We take r~=(rc-0.002,rc,rc+0.001), where rc is the core value of r~ and the left and right spreads of r~ are 0.002 and 0.001, respectively, and σ~=(σc-0.01,σc,σc+0.02), where σc is the core value of σ~ and the left and right spreads of σ~ are 0.01 and 0.02, respectively. Table 2 presents the critical value S* and the crisp possibilistic mean value of compound option price M(C~) under fuzzy environment, where the critical value S* can be obtained by solving (14) using the bisection method, and the precision is 10-5. For each match group the values of parameters S, K1, K2, T1, and T2 in Table 2 are the same as those in Table 1, and the cores rc and σc are equal to r and σ in Table 1, respectively.
The numerical result of S* and M(C~) under the fuzzy environment.
S
K1
K2
T1
T2
rc
σc
S*
M(C~)
90
5
90
0.5
1
0.05
0.3
82.7509
8.9357
95
5
90
0.5
1
0.05
0.3
82.7509
11.9369
105
5
90
0.5
1
0.05
0.3
82.7509
19.0290
100
4
90
0.5
1
0.05
0.3
80.2813
16.1338
100
4.5
90
0.5
1
0.05
0.3
81.5571
15.7219
100
6
90
0.5
1
0.05
0.3
84.9404
14.5412
100
5
80
0.5
1
0.05
0.3
74.7967
21.7981
100
5
85
0.5
1
0.05
0.3
78.7852
18.3814
100
5
95
0.5
1
0.05
0.3
86.6946
12.6250
100
5
90
0.25
1
0.05
0.3
78.2638
14.8803
100
5
90
0.55
1
0.05
0.3
83.7505
15.4312
100
5
90
0.75
1
0.05
0.3
88.2253
15.9460
100
5
90
0.5
0.75
0.05
0.3
88.2253
13.7005
100
5
90
0.5
1
0.05
0.3
82.7509
15.3199
100
5
90
0.5
1.25
0.05
0.3
78.2638
16.9375
100
5
90
0.5
1
0.04
0.3
83.1077
14.7869
100
5
90
0.5
1
0.055
0.3
82.5732
15.5898
100
5
90
0.5
1
0.06
0.3
82.3959
15.8616
100
5
90
0.5
1
0.05
0.25
85.3576
13.7159
100
5
90
0.5
1
0.05
0.32
81.6798
15.9782
100
5
90
0.5
1
0.05
0.35
80.0567
16.9781
From Tables 1 and 2, the compound option prices derived from the Black-Scholes model are slightly lower than the prices derived from the crisp possibilistic mean value with the same parameters. This seems to be consistent with our intuition that the crisp possibilistic mean value model contains more uncertainty than the Black-Scholes model (see [28, 30]). But this intuition is not necessarily true, which one is bigger between C and M(C~) is related to the selected parameters. Similarly, from Tables 1 and 2, we notice that S* is slightly higher than S*; this conclusion is not surely true. For example, when S=100, K1=5, K2=90, T1=0.5, T2=1, r~=(0.049,0.05,0.052), and σ~=(0.28,0.3,0.31), then the computing result is S*=82.8336, C=15.2744, S*=82.9162, and M(C~)=15.2290; obviously, S*<S* and C>M(C~).
In order to perform the sensitivity analysis we set our base case with S=100, K1=5, K2=90, T1=0.5, T2=1, rc=0.05, and σc=0.3. Figures 1 to 7 give the sensitivity analysis of S* and M(C~) with respect to S, K1, K2, T1, T2, rc, and σc, respectively. We can see that S* does not vary with the change of S, because (14) does not contain S. S* is increasing with respect to K1, K2, and T1 and is decreasing with respect to T2, rc, and σc, because the value of call option increases with the increase of the stock price, interest rate, volatility and maturity time, and the value of call option falls with the increase of strike price; when the left and right spreads of r~ and σ~ are fixed (therefore,M(r~) and M(σ~) are increasing with respect to rc and σc, resp.) (14) means that S* is the underlying asset price at time T1 such that the value of call option with the strike price K2 and maturity time T2-T1 is equal to K1; therefore, when K1 is fixed (i.e., Figures 1, 3, 4, 5, 6, and 7), S* is increasing with respect to K2 and T1 and is decreasing with respect to T2, rc, and σc; when K2, T1, T2, rc, and σc are fixed (i.e., Figure 2), S* is an increasing function with respect to K1.
The sensitivity analysis of S* and M(C~) with respect to S.
The sensitivity analysis of S* and M(C~) with respect to K1.
The sensitivity analysis of S* and M(C~) with respect to K2.
The sensitivity analysis of S* and M(C~) with respect to T1.
The sensitivity analysis of S* and M(C~) with respect to T2.
The sensitivity analysis of S* and M(C~) with respect to rc.
The sensitivity analysis of S* and M(C~) with respect to σc.
We can see from Figures 1 to 7 that S, T1, T2, rc, and σc increase the value of M(C~) increases, and K1 and K2 increase the value of M(C~) decreases. This is consistent with [1, 7] that the compound option price is an increasing function with respect to S, T1, T2, r, and σ and is a decreasing function with respect to K1 and K2.
Table 3 presents the closed interval of α-level set of C~ calculated from Theorem 5 with S=100, K1=5, K2=90, T1=0.5, T2=1, r~=(0.048,0.05,0.051), and σ~=(0.29,0.3,0.32).
The closed interval of α-level set of C~.
α
Interval for fuzzy price
0.90
[14.9214, 15.6552]
0.91
[14.9566, 15.6171]
0.92
[14.9919, 15.5791]
0.93
[15.0271, 15.5410]
0.94
[15.0624, 15.5029]
0.95
[15.0977, 15.4649]
0.96
[15.1330, 15.4268]
0.97
[15.1683, 15.3887]
0.98
[15.2036, 15.3506]
0.99
[15.2390, 15.3125]
From Table 3, for α=0.95, it means that the option price will lie in the closed interval [15.0977,15.4649] with belief degree 0.95. This interval can provide reference for financial investors. That is to say, if a financial investor is satisfied with belief degree 0.95, then he can pick any value from the closed interval [15.0977,15.4649] as the option price. In addition, the financial investor may think the price is overvalued if the actual price option is higher than 15.4649 and sell the options; on the contrary, he may think the price is undervalued if the actual price option is less than 15.0977 and buy the options. We also notice that the length of the interval tends to become smaller with the increasing of belief degree and the interval with smaller belief degree contains the interval with larger belief degree.
6. Conclusions
Considering the uncertainty of the financial market includes both risk and vagueness; the compound option price will turn into a fuzzy number. We presented the fuzzy pricing formula for compound option by fuzzing the interest and volatility in Geske’s compound option pricing formula. For any belief degree, the closed interval of price is obtained according to the fuzzy arithmetics and the definition of fuzzy-valued function; this allows the financial investor to make more flexible investment decision. We applied a defuzzification method to obtain the crisp possibilistic mean value of compound option price. Numerical analysis and sensitivity analysis showed that the crisp possibilistic mean value of compound option price is increasing with respect to the core of fuzzy interest rate and fuzzy volatility. The research on option pricing under fuzzy environment is a necessary improvement and supplement for the existing option pricing theory under stochastic model. In the future, we will study the compound option pricing under fuzzy environment based on jump-diffusion model, stochastic interest rate model, or stochastic volatility model and their applications.
Conflict of Interests
The authors declare that there is no conflict of interests regarding the publication of this paper.
Acknowledgments
This research is supported by the Natural Science Foundation of China (71071034 and 71201023) and the Funding of Jiangsu Innovation Program for Graduate Education (CXZZ 13-0140). The authors sincerely thank the anonymous referees for their helpful comments.
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