Product Demand Forecasting and Dynamic Pricing

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(ProQuest: ... denotes non-US-ASCII text omitted.)

Wenjie Bi 1 and Mengqi Liu 2

Academic Editor:Li Guo

1, Business School, Central South University, Changsha 410083, China
2, Business School, Hunan University, Changsha 410082, China

Received 19 May 2014; Accepted 17 July 2014; 2 September 2014

This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

1. Introduction

Accurate demand forecasts are essential for companies including manufactures and distributors because they will drive more responsive customer service with lower inventories and reduced obsolescence [1, 2]. As Huang et al. [3] have shown, price-dependent demand models are the most commonly employed possibly because pricing strategy is the most effective tool that has been used to impact a firm's demand. Under consideration of an integrated demand and supply chain management, forecasting and pricing are related to each other. Therefore, we obviously should consider the impact of its price when predicting the consumers' demand of a certain product. A distinctive feature of this work is that it depends on descriptive models of consumer behavior to predict customers' demand and to derive pricing strategies under dynamic settings. Specifically, we incorporate both the consumers' mental accounting and the impact of reference price when modeling our demand function.

Traditional assumption of consumers' rationality sometimes cannot explain the realistic, complex world [4, 5]. In order to make accurate prediction about product purchase, we try to study the consumers' behavior impact on it. Mental accounting is an important concept in behavioral economics, which is the set of cognitive operations used by individuals and households to organize, evaluate, and keep track of financial activities [6]. And mental accounting theory can explain many economic anomalies about price such as the endowment effect and the sunk cost effect [7]. Since mental accounting was first formally proposed by Thaler in 1985 [8], it has been widely studied. One of the most outstanding models is the double-entry mental accounting model proposed by Prelec and Loewenstein [9], which obtain a variety of predictions that are against the traditional economics theory such as debt aversion and preferences for prepayment. The double-entry model describes the nature of the reciprocal interactions between the pleasure of consumption and the pain of paying and introduces the idea of prospective accounting and coupling which refers to the degree to which consumption calls to mind thoughts of payment and vice versa. Besides, the double-entry model introduces two coupling coefficients, that is, pleasure attenuation coefficient ψ and pain buffering coefficient γ , which represent and respect the degree to which payments attenuate the pleasure of consumption and the degree to which consumption buffers the pain of payments, respectively. And there are other important studies on mental accounting; see [10-16]. All these studies belong to empirical research, so it is essentially needed to explore how to incorporate mental accounting into theoretical models in economics, and now there have been a small number of behavioral operations management studies attempting to model mental accounting. Erat and Bhaskaran [17] formulate a simple model to formalize how (and why) the mental account associated with a base product impacts a consumers' add-on purchase decision, and they also develop a normative model to explicitly examine what (if any) implications the proposed consumer biases have on firm's pricing decisions. And Chen et al. [18] studied what effects the payment schemes have on inventory decisions in the newsvendor problem when considering mental accounting and found out that "prospective accounting" in the double-entry mental accounting model can explain that when keeping the net profit structure constant, inventory quantities exhibit a consistent decreasing pattern in the order of payment schemes O (where the order is financed by the newsvendor herself), S (where the order is financed by the supplier through delayed order payment), and C (where the order is financed by the customer through advanced revenue). To sum up, mental accounting is closely related to consumer behavior, but current studies on mental accounting are mostly empirical research, and there are seldom dynamic pricing models incorporating double-entry mental accounting yet.

On the other hand, mental accounting is always closely linked with reference price. According to [19], consumers keep a reference price in mind and perform two comparisons. First, they compare the reference price with the actual price and this comparison yields transaction utility. Second, they compare the benefits of consumption with the reference price yielding acquisition utility. And it is essential to note that the demand model in [20] is exactly established on this framework. Moreover, Baucells and Hwang [7] propose the MARA model of multiperiod purchase decision-making, which integrates the psychological mechanism of mental accounting and reference price adaptation. And the MARA model can capture some important underlying psychological processes (such as payment depreciation) that other mental accounting models (including Thaler's double-comparison model and Prelec and Loewenstein's double-entry mental accounting model) fail to do. Therefore, it is necessary to simultaneously incorporate consumers' mental accounting and reference-dependent behavior into dynamic pricing models. In particular, under the influence of double-entry mental accounting, not only the reference price will be constantly updated, but also the consumers' perceived price and perceived consumption benefit will be changed under different payment schemes; consequently, the demand function will vary, thus affecting the prediction of product demand quantity. This suggests that there may exist further research opportunities for using the combination of consumers' double-entry mental accounting and reference effect to forecast the demand of a product and to investigate the optimal pricing strategy of a monopolistic firm.

The remainder of this paper is organized as follows. Section 2 describes our model of double-entry mental accounting in product demand forecasting and further investigates the combined effect of consumers' double-entry mental accounting and reference-dependent behavior on firm's pricing strategies. Section 3 provides two-period dynamic pricing model under three different payment schemes and drives an explicit solution. In Section 4, we study infinite-period dynamic pricing model. Section 5 reports the numerical study and Section 6 concludes the paper with a summary of results.

2. The Basic Model

Consider a product sold by a monopolistic company over an infinite horizon through three different payment schemes. The first payment scheme (scheme O ), the most ordinary one, indicates that consumers pay for and consume a product simultaneously in each period. The second one is prepayment (scheme Pre) meaning that consumers pay at the beginning and consume at the end of each period, and the third scheme postpayment (scheme Post) shows completely opposite conditions of prepayment that consumers consume at first and pay in the end. And the impact of double-entry mental accounting on consumer is different under different payment schemes. In this section, we build demand forecasting and dynamic pricing models under each payment scheme and compare their impacts on the monopolist's profit.

To facilitate the analysis, we assume that product demand function is linear, as shown in Assumption 1.

Assumption 1.

The reference-dependent demand is D(p,r)=q(p)+R(r-p,r) where q(p)=_β0 -_β1 p , R(r-p,r)=_β2 min...(r-p,0)+_β3 max...(r-p,0) , and _β0 ,_β1 ,_β2 ,_β3 ...5;0 . Let the price interval be P=[p_,p¯] and let the product cost be 0.

The term _β0 ,_β1 ,_β2 ,_β3 ...5;0 ensures that the demand function is decreasing in price and increasing in reference price. For loss-averse consumers, the demand function is steeper for losses than for gains; for example, _β2 >_β3 while _β2 <_β3 for loss-seeking consumers. And for loss-neutral consumers, we have _β2 =_β3 so the demand function is smooth.

According to [20], R(x,r) measures the impact on demand of a perceived discount/surcharge where x=r-p , relative to the reference price r . And it can be seen from Assumption 1 that R(x,r)...5;0 for x>0 , R(x,r)...4;0 for x<0 , and R(0,r)=0 .

Let Π(p,r)=pq(p)+pR(r-p,r) be the short-term profit where _π0 (p)=pq(p) is the base profit without reference effect and ^ΠR (p,r)=pR(r-p,r) is the profit from the reference effect. Let κ(r)=_Rx (0,r) denote the slope of the reference demand at x=0 when consumers are loss neutral. Next, we give a typical technical assumption on Π(p,r) borrowed from Assumption 3 in [20].

Assumption 2.

(a) π(p) is nonmonotonic and concave in p . (b) _∏p (r,r)=^{π[variant prime]} (r)-rκ(r) is strictly decreasing in r . (c) ^ΠR (p,r) is concave in p and supermodular in (p,r) .

The reference price formation and updating mechanism in this paper is assumed to be peak-end anchoring, as shown in Assumption 3, which is the most commonly used and empirically validated reference price mechanism in the literature; for example, see [21, 22].

Assumption 3.

The reference price updating mechanism is given by _rt =η_mt-1 +(1-η)_pt-1 where _mt-1 =min...(_m0 ,_p1 ,...,_pt )=min...(_mt-2 ,_pt-1 ) , t>1 , _r1 =^m0 , and the memory parameter η∈[0,1] captures the fraction of consumers anchoring on the lowest price.

Based on this assumption we can know that for η=0 the model becomes a special case where the consumers anchor solely on the previous period price.

Given initial conditions ^m0 and ^p0 (we can regard ^p0 as ^m0 ), the monopolist maximizes infinite horizon β -discounted revenues [figure omitted; refer to PDF] where β∈[0,1] is the firm's discount factor.

The Bellman equation for this problem is [figure omitted; refer to PDF]

We can know from Lemma 1 of [23] that the value function V(m,p) is increasing in both arguments.

The infinite horizon model implicitly assumes that lowest prices can be remembered indefinitely. This is a reasonable approximation in a context where the frequency of transactions is high relative to the horizon length and the lowest prices are recalled because of their salience; their extremeness makes them stand out in the memory process.

Next, we analyze how different payment schemes influence consumers' perceived price and perceived consumption benefit. Table 1 describes, under prepayment scheme and postpayment scheme, how consumers' perceived price p^ and perceived consumption benefit θ^ are influenced by pleasure attenuation coefficient ψ , pain buffering coefficient γ , and consumers' discount factor [straight phi] for product price and consumption benefit because of the separation of consumption and payment where ψ , γ , and [straight phi]∈[0,1] .

Table 1: Perceived price p^ and perceived consumption benefit θ^ .

	Prepayment	Postpayment
Consumption	θ ^ = [straight phi] θ	θ ^ = ( 1 - ψ ) θ
Payment	p ^ = ( 1 - γ ) p	p ^ = [straight phi] p

On the basis of Prelec and Loewenstein's [9] double-entry mental accounting model, we can account for Table 1 as follows.

(1) Under prepayment scheme, consumers pay price p at first and their prospective accounting will think of future consumption benefits so that the pain of payments will be buffered, which leads perceived payment to be (1-γ)p . On the other hand, because of the delay of consumption, the perceived consumption benefit will be at discount and will become [straight phi]θ .

(2) Under postpayment scheme, consumers obtain consumption benefit θ at first and the prospective accounting will consider future payments so that the pleasure of consumption today will be attenuated, which leads perceived consumption benefit to be (1-ψ)θ . On the other hand, because of the delay of payment, the perceived price will be at discount and will become [straight phi]p .

Under the influence of mental accounting, consumers will make decision depending on perceived price and perceived consumption benefit instead of actual price and consumption benefit. Then we can know that when considering the dynamic pricing problem with consumers' double-entry mental accounting and reference-dependent behavior, the demand function _Dpre (p,r) and _Dpost (p,r) can be expressed as follows: [figure omitted; refer to PDF]

And accordingly, the updating of reference price is affected by perceived price instead of actual price; that is, _rt =η_mt-1 +(1-η)_pt-1 , _mt-1 =min...(_mt-2 ,_pt-1 ) .

Based on the above assumptions, the monopolist's profit _Πpre (p,r) under prepayment scheme is [figure omitted; refer to PDF] so that (2) under prepayment scheme can be rewritten as [figure omitted; refer to PDF]

Similarly, the monopolist's profit _Πpost (p,r) under postpayment scheme is [figure omitted; refer to PDF] so that (2) under postpayment scheme can be rewritten as [figure omitted; refer to PDF]

We assume consumers are loss neutral; namely, _β2 =_β3 . Then according to Assumption 1 we have [figure omitted; refer to PDF]

3. The Two-Period Dynamic Pricing Model

The two-period dynamic pricing model is the simplest and commonly used in practice. Generally, it is easy to calculate the analytical solution of optimal price path. Also the obtained properties and conclusions are clear at a glance and good for interpretation. Hence, we start with studying the two-period model.

Based on the analysis in Section 2, the single-period profits under scheme O , scheme Pre (prepayment scheme), and scheme Post (postpayment scheme) in two-period model _Πo (_pt ,_rt ) , _Πpre (_pt ,_rt ) , and _Πpost (_pt ,_rt ) can expressed below (t=1,2) , respectively: [figure omitted; refer to PDF]

As a result, the two-period dynamic pricing models under scheme O , scheme Pre, and scheme Post are (t=1,2) [figure omitted; refer to PDF]

Proposition 4.

Given the initial reference price ^m0 , let {^po,1* ,^po,2* } , {^ppre,1* ,^ppre,2* } , and {^ppost,1* ,^ppost,2* } be the optimal price path of models (12), (13), and (14), respectively.

Case 1.

If _m0 is large enough satisfying ^m0 =max...(^m0 ,p,(1-γ)_p1 ,[straight phi]_p1 ) , we obtain [figure omitted; refer to PDF] where [figure omitted; refer to PDF]

Case 2.

If ^m0 is small satisfying _m0 =min...(_m0 ,_p1 ,(1-γ)_p1 ,δ_p1 ) , we also have [figure omitted; refer to PDF] where [figure omitted; refer to PDF]

Proof.

See Appendices A, B, and C.

By Proposition 4, the ratios of each period's optimal price to the corresponding period's optimal price under scheme O are identical. In other words, if the optimal price path under scheme O is {^po,1* ,^po,2* } , the corresponding optimal paths of scheme Pre will be {^po,1* /(1-γ),^po,2* /(1-γ)} and the corresponding optimal paths of scheme Post will be {^po,1* /[straight phi],^po,2* /[straight phi]} .

After obtaining the optimal price paths, we can compare firm's profits under different payment schemes and provide theoretical support for firm's decision on how to choose payment scheme for higher profit.

Proposition 5.

Given the initial reference price ^m0 , let ^V0* (_m0 ) , ^Vpre* (_m0 ) , and ^Vpost* (_m0 ) be the maximal profit of models (12), (13), and (14), respectively. They satisfy the following equations: [figure omitted; refer to PDF]

Proof.

See Appendices A, B, and C.

Based on Proposition 5 it is straightforward to draw the following conclusions.

(1) If [straight phi]>1-γ , it will be better for the monopolist to provide prepayment scheme to consumers, or postpayment scheme.

For scheme O , the pleasure of consumption and the pain of paying are equal. And under scheme Pre, the bigger γ is, the more buffered the pain of paying is because of mental accounting; and the bigger 1-[straight phi] is, the more attenuated the pleasure of consumption is because of time discounting. As a result, [straight phi]>1-γ means the reduced pain is less than the reduced pleasure, and the benefit outweighs the disadvantage, which leads to the increasing in demand. And hence, it is profitable for providing scheme Pre where the firm's profit becomes higher. Similarly, we can explain the attractiveness of scheme Post in the case of [straight phi]...4;1-γ .

(2) For [straight phi]=1-γ , scheme Pre and scheme Post are indifferent in pricing strategies and profitability.

When [straight phi]=1-γ , the effects of pain buffering coefficient γ and consumers' discount factor [straight phi] are offset reciprocally. Consequently, we have ^Vpre* (_m0 )=^Vpost* (_m0 ) .

(3) In general, γ , [straight phi]∈[0,1] ; namely, ^Vpre* (_m0 )>^V0* (_m0 ) and ^Vpost* (_m0 )>^V0* (_m0 ) , so it is usually better to choose the scheme Pre and scheme Post.

4. The Infinite-Period Dynamic Pricing Model

With the fierce change of the market environment and the rapid development of Internet, price adjustments become more and more frequent and periodicity of pricing is growing fast. Hence, the pricing strategies and their related properties of the multiperiod dynamic pricing problem and the infinite-period dynamic pricing problem are worthy of further study. In this section, we study the infinite-period dynamic pricing problem considering consumers' double-entry mental accounting and reference-dependent behavior.

4.1. The Steady State

This section characterizes the long-term pricing strategy of the firm facing loss-neutralconsumers with demand given by Assumption 1 where _β2 =_β3 .

First, we will consider the scheme O in which case the Bellman equation is given in (2). To get the steady states of (2) requires a nonstandard approach, because the transition in the value function (memory structure) is nonsmooth. Our analysis is based on a bounding technique [23], which identifies the steady states of (2) based on those of a series of smooth problem.

For w∈[0,1] and m∈P consider the following smooth problem with one-dimensional state: [figure omitted; refer to PDF]

We first show that the family ^Vmw , w∈[0,1] , provides upper bounds for the value function V . Based on [23], we can know that for any m<p , we have V(m,p)...4;^Vmw (p) .

We next argue that by approximating the value function V by a smooth upper bound ^Vmw , for an appropriate subset of value V , the firm will charge optimal prices in the long run. Technically, this amounts to matching supergradients of the original problem with gradients for an appropriate smooth upper bound equation (2). We first identify steady states of problem (20) which will help characterize those of (2).

The structure of the problem leads us to consider three price-memory scenarios (low, medium, and high): _R1 =[p_,s] , _R2 =[s,S] , and _R3 =[s,S] where the thresholds s , S solve, respectively, [figure omitted; refer to PDF] where _π0 (p)=pq(p) represents the base profit.

Uniqueness of s and S follows because the above left hand sides (LHS) are strictly decreasing in p , by concavity of ^{π0[variant prime]} (p) . To understand s , S better, we will give Lemma 6 in which (21) and (22) are special case.

Lemma 6.

(a) For w∈[0,1] and m∈P , (2) under scheme O admits a unique steady state, which solves [figure omitted; refer to PDF]

(b) For any m∈[s,S] , there exists w∈[0,1] such that m is a steady state of the corresponding equation (20).

Proof.

See Lemma 4 of [23].

Denote ^p** (m) the unique steady state of problem (20) for w=0 by Lemma 6(a). ^p** (m) solves [figure omitted; refer to PDF]

In particular ^p** (s)=s ; the thresholds s and S defined above correspond to those values m for which the steady state of ^Jmw equals m , for w=0 , respectively, w=1 . It turns out that (s,s) and (S,S) are steady state of our equation (2). The next result identifies steady states of (2) based on the steady states of (20), identified in Lemma 6.

Based on Lemma 6, we can get Proposition 7 which gives the steady state.

Proposition 7.

(a) For m∈_R1 , (m,^p** (m)) is a steady state of (2) where ^p** (m) solves (10). (b) For m∈_R2 , (m,m) is a steady state of (6).

Proof.

See Appendices A, B, and C.

Proposition 7 suggests to partition the initial states space into the following region: _R1a ¯={(m,p)|"p...5;^p** (m),m...4;s} , _R1b ¯={(m,p)|"p...4;^p** (m),m...4;s} , _R2 ¯={(m,p)|"p...5;^p** (m), s...4;m...4;S} , and _R3 ¯={(m,p)|"p...5;m,m...5;S} .

The main results in Proposition 7 are indeed the only steady state of (2).

The result says that the lower the value of the steady state is, the more sensitive consumers are to deviations from the reference price. Furthermore, a more patient firm (higher β ) charges higher steady state prices.

Based on the analysis above, we can give the similar conclusions on the scheme Pre and scheme Post. Under the scheme Pre let us consider the following smooth problem with one-dimensional state which is similar to (5): [figure omitted; refer to PDF]

Similarly, we can obtain that _Vpre V(m,p)...4;^Vpre.mω (p) . Now we get Proposition 8 which gives the steady state of (5). The proof is similar to Proposition 7 and is omitted here.

Proposition 8.

(a) For w∈[0,1] and p∈P , (5) under scheme Pre admits a unique steady state, which solves the following equations: [figure omitted; refer to PDF]

(b) For any m∈[_spre ,_Spre ] , there exists w∈[0,1] such that m is a steady state of the corresponding equation (25), and _spre ,_Spre solve the following equations, respectively: [figure omitted; refer to PDF]

Also denote by ^ppre** (m) the unique steady state of problem (25) for w=0 . By Lemma 6(a), ^p** (m) solves [figure omitted; refer to PDF]

Similarly, we can get that (_spre ,_spre ) and (_Spre ,_Spre ) are steady state of our equation (5).

For the scheme Post, we also use the one-dimensional state which is similar to (7) as follows: [figure omitted; refer to PDF]

Similarly, we can obtain that _Vpost V(m,p)...4;^Vpost.mω (p) . Now we obtain Proposition 9 which gives the steady state of (7). The proof is also similar to Proposition 7 and is omitted here.

Proposition 9.

(a) For w∈[0,1] and p∈P , (7) under scheme Post admits a unique steady state, which solves the following equations: [figure omitted; refer to PDF]

(b) For any m∈[_spost ,_Spost ] , there exists w∈[0,1] such that m is a steady state of the corresponding equation (29), and _spost ,_Spost solve the following equations, respectively: [figure omitted; refer to PDF]

We denote ^ppost** (m) as the unique steady state of problem (29) for w∈[0,1] . By Lemma 6(a), ^ppost** (m) solves [figure omitted; refer to PDF]

4.2. The Optimal Policy and Price Paths

This section investigates the transient pricing policy of the monopolist. Firstly, we study convergence and monotonicity of the price paths of (2); then we can use the similar way to analyze (5) and (7), namely, under the scheme Pre and scheme Post. We start at an arbitrary initial state (_m0 ,_p0 ) , in which _m0 ...4;_p0 and _m0 can be regarded as _p0 . The optimal pricing policy of the monopolist is [figure omitted; refer to PDF] The optimal price path {_pt_}t is given by _pt =^p* (_mt-1 ,_pt-1 ) with _mt =min...(_mt-1 ,_pt ) , t...5;1 , and the state path is {(_mt ,_pt )} .

Our first result in this section shows that if (_m0 ,_p0 ) is in any of the three regions _Rt , t=1,2,3 , as defined in Section 4.1, the state path remains in that region. We can know that [23] if _m0 ∈_R1 ^∪ _R2 , then _pt ...5;_m0 for all t . If _m0 ∈_R3 , then _mt ∈_R3 for all t . Under the scheme Pre and scheme Post, we can get the similar conclusions as Proposition 10 and the proof is similar to Proposition 7.

Proposition 10.

(a) For the scheme Pre, if _m0 ∈_Rpre.1 ∪_Rpre.2 , then _pt ...5;_m0 for all t . If _m0 ∈_Rpre.3 , then _mt ∈_Rpre.3 for all t , where _Rpre.1 =[p_,_spre ], _Rpre.2 =[_spre ,_Spre ] , _Rpre.3 =[_spre ,p-] , and _spre , _Spre are defined in Section 4.1.

(b) For the scheme Post, if _m0 ∈_Rpost.1 ^∪ _Rpost.2 , then _pt ...5;_m0 for all t . If _m0 ∈_Rpost.3 , then _mt ∈_Rpost.3 for all t , where _Rpost.1 =[p_,_spost ] , _Rpost.3 =[_spost ,p-] , and _spost ,_Spost are defined in Section 4.1.

The first part of these three propositions shows that if the initial minimum price _m0 is not too high, the optimal price path stays above _m0 : for the scheme O , if _m0 <S (for the scheme Pre, if _m0 <_Spre ; for the scheme Post, if _m0 <_Spost ) the minimal price does not change over time, and so the state path will remain within the region. On the other hand if the initial minimal price _m0 is relatively high, for the scheme O , if _m0 >S (for the scheme Pre, if _m0 >_Spre ; for the scheme Post, if _m0 >_Spost ), the minimum price decreases over time, but it never drops below S under scheme O , _Spre under scheme Pre, and _Spost under scheme Post. These results identify the possible convergence points of the optimal price paths, starting at any initial state.

Proposition 10 implies that if the optimal price path of (2) under scheme O converges, it converges to a steady state in the same regions as the initial price path of (_m0 ,_m0 ) . These states are (_m0 ,^p0** ) for _mo ∈_R1 , (_m0 ,_m0 ) for _mo ∈_R2 , and (S,S) for _mo ∈_R3 .

Similarly, for scheme Pre, these steady states are (_m0 ,^ppre** ) for _mo ∈_Rpre.1 , (_m0 ,_m0 ) _mo ∈_Rpre.2 and (S,S) for _mo ∈_Rpre.3 ; for scheme Post, these steady states are (_m0 ,^ppost** ) for _mo ∈_Rpost.1 , (_m0 ,_m0 ) _mo ∈_Rpost.2 and (S,S) for _mo ∈_Rpost.3 .

We now turn to characterize the optimal price paths of problem (2), namely, under scheme O which can also be applied to scheme Pre and scheme Post. For _m0 ∈_R1 ∪_R2 , _mt =_m0 by Proposition 10, so (2) can be rewritten (with _mo as a parameter) as follows: [figure omitted; refer to PDF] where _rt =η_m0 +(1-η)_pt-1 . That is, V(m,p)=_Vm (p) for _m0 ∈_R1 ∪_R2 and m<p . Because ∏(_pt ,_rt ) is supermodular, the optimal policy in (2) is monotone, so ^pt* (_m0 ,_pt-1 ) is increasing in _pt-1 . There, the optimal path is monotonic in a bounded interval and hence converges to a steady state (_m0 ,^p** (_m0 )) .

For _mo ∈_R3 , we can get from Proposition 3 of [23] that the optimal price path is decreasing to S , by supermodularity of ∏(_pt ,_rt ) . Based on the analysis above, we can get the following conclusions.

Given initial state (_m0 ,_p0 ) and scheme O , the optimal price path of (2) converges monotonically to a steady state, which is (_a1 )^p** (_m0 ) if _mo ∈_R1 ; (_b1 )_mo , if _mo ∈_R2 ; (_c1 ) S , if _mo ∈_R3 . Under scheme Pre, the optimal price path of (5) converges monotonically to a steady state, which is (_a2 )^ppre** (_m0 ) , if _mo ∈_Rpre.1 ; (_b2 )_mo , if _mo ∈_Rpre.2 ; (_c2 )_Spre , if _mo ∈_Rpre.3 . Under scheme Post, the optimal price path of (7) converges monotonically to a steady state, which is (_a3 )^ppost** (_m0 ) , if _mo ∈_Rpost.1 ; (_b3 )_mo , if _mo ∈_Rpost.2 ; (_c3 )_Spost , if _mo ∈_Rpost.3 .

5. Numerical Examples

Based on Section 4, we know that in order to get the steady states under three schemes, respectively, we should know the ^p** (_m0 ),s S under scheme O , ^ppre** (_m0 ),_spre _Spre under scheme Pre, and ^ppost** (_m0 ),_spost _Spost under scheme Post.

According to (21), (22), and (24), we have [figure omitted; refer to PDF]

Based on Proposition 8 and (28), we have [figure omitted; refer to PDF]

Based on Proposition 9 and (32), we have [figure omitted; refer to PDF]

In order to analyze how the steady states under three schemes change with the parameters, we set β=0.95 , _β0 =20 , _β1 =20 , _β2 =40 , γ=0.3 , [straight phi]=0.6 , η=0.5 , and p=[p_,p-]=[0.2,1] . Then we can get Figures 1-3.

Figure 1: The steady price under scheme O .