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Optimal pricing decisions of centralized dual-channel supply chains in a duopoly: a study on the influence of competition structure

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Abstract

A price competition amongst two centralized dual-channel supply chains (DCSCs) has been investigated in this study. Three scenarios of competition are studied—a simultaneous move game and two sequential games (one in which the first supply chain is the leader and the second supply chain is the follower, and vice versa). The optimal prices and profits for these scenarios have been derived and compared. It is observed that prices and profits are higher under Stackelberg (Sequential move) competition as compared to Simultaneous move competition. Finally, the present study determines which type of competition structure would persist in the market by using a Wait or Declare two-strategy game. The game depicts the market entry decision of the competing supply chains. The results reveal that self interest in competing dual-channel supply chains leads to a sequential move competition and consequently to higher product prices. To reduce the price and thus induce a customer favourable equilibrium, regulatory authorities like the government can step in and provide incentives. We derive a lower bound on the incentive which would implement a low market price equilibrium in Dominant Strategies. Further, we note that under competition, dual-channel supply chains outperform traditional supply chains only upto a certain threshold of the retail channel market share and we derive an expression for the same threshold. This threshold is found to be independent of the nature of the product.

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Notes

  1. We do not consider the possibility implementing (WW) as a PSNE, as this equilibrium delays the market entry decisions.

References

  1. Aslani A and Heydari J 2019 Transshipment contract for coordination of a green dual-channel supply chain under channel disruption. Journal of Cleaner Production 223: 596–609. https://doi.org/10.1016/j.jclepro.2019.03.186

    Article  Google Scholar 

  2. Jamali M-B and Rasti-Barzoki M 2018 A game theoretic approach for green and non-green product pricing in chain-to-chain competitive sustainable and regular dual-channel supply chains. Journal of Cleaner Production 170: 1029–1043. https://doi.org/10.1016/j.jclepro.2017.09.181

    Article  Google Scholar 

  3. Wei J, Shao T and Zhao J 2018 Interactions of bargaining power and introduction of online channel in two competing supply chains. Mathematical Problems in Engineering 7952413: . https://doi.org/10.1155/2018/7952413

  4. Narenji M, Fathian M, Teimoury E and Naini S G J 2013 Price and delivery time analyzing in competition between an electronic and a traditional supply chain. Mathematical Problems in Engineering 596897: . https://doi.org/10.1155/2013/596897

  5. Ranjan A and Jha J K 2019 Pricing and coordination strategies of a dual-channel supply chain considering green quality and sales effort. Journal of Cleaner Production 218: 409–424. https://doi.org/10.1016/j.jclepro.2019.01.297

    Article  Google Scholar 

  6. Chen X, Zhang H, Zhang M and Chen J 2017 Optimal decisions in a retailer Stackelberg supply chain. International Journal of Production Economics 187: 260–270. https://doi.org/10.1016/j.ijpe.2017.03.002

    Article  Google Scholar 

  7. Li Z, Yang W, Liu X and Si Y 2020 Coupon promotion and its two-stage price intervention on dual-channel supply chain. Computers & Industrial Engineering 145: 106543. https://doi.org/10.1016/j.cie.2020.106543

    Article  Google Scholar 

  8. Xu G, Dan B, Zhang X and Liu C 2014 Coordinating a dual-channel supply chain with risk-averse under a two-way revenue sharing contract. International Journal of Production Economics 147: 171–179. https://doi.org/10.1016/j.ijpe.2013.09.012

    Article  Google Scholar 

  9. Saha S, Sarmah S P and Moon I 2016 Dual channel closed-loop supply chain coordination with a reward-driven remanufacturing policy. International Journal of Production Research 54: 1503–1517. https://doi.org/10.1080/00207543.2015.1090031

    Article  Google Scholar 

  10. Li B, Zhu M, Jiang Y and Li Z 2016 Pricing policies of a competitive dual-channel green supply chain. Journal of Cleaner Production 112: 2029–2042. https://doi.org/10.1016/j.jclepro.2015.05.017

    Article  Google Scholar 

  11. Batarfi R, Jaber M Y and Zanoni S 2016 Dual-channel supply chain: A strategy to maximize profit. Applied Mathematical Modelling 40: 9454–9473. https://doi.org/10.1016/j.apm.2016.06.008

    Article  MathSciNet  Google Scholar 

  12. Zhao J, Hou X, Guo Y and Wei J 2017 Pricing policies for complementary products in a dual-channel supply chain. Applied Mathematical Modelling 49: 437–451. https://doi.org/10.1016/j.apm.2017.04.023

    Article  MathSciNet  Google Scholar 

  13. Yang L, Wang G and Ke C 2018 Remanufacturing and promotion in dual-channel supply chains under cap-and-trade regulation. Journal of Cleaner Production 204: 939–957. https://doi.org/10.1016/j.jclepro.2018.08.297

    Article  Google Scholar 

  14. Li G, Li L, Sethi S P and Guan X 2019 Return strategy and pricing in a dual-channel supply chain. International Journal of Production Economics 215: 153–164. https://doi.org/10.1016/j.ijpe.2017.06.031

    Article  Google Scholar 

  15. Heydari J, Aslani A and Sabbaghnia A 2020 A collaborative scenario-based decision model for a disrupted dual-channel supply chain: Benchmarking against the centralized structure. Benchmarking: An International Journal 27: 933–957 https://doi.org/10.1108/BIJ-06-2019-0281

  16. Barman A, Das R and De P K 2021 Optimal pricing and greening decision in a manufacturer retailer dual-channel supply chain. Materials Today: Proceedings 42: 870–875. https://doi.org/10.1016/j.matpr.2020.11.719

    Article  Google Scholar 

  17. Barman A, De P K, Chakraborty A K, Lim C P and Das R 2023 Optimal pricing policy in a three-layer dual-channel supply chain under government subsidy in green manufacturing. Mathematics and Computers in Simulation 204: 401–429. https://doi.org/10.1016/j.matcom.2022.08.008

    Article  MathSciNet  Google Scholar 

  18. Das R, De P K and Barman A 2021 Pricing and ordering strategies in a two-echelon supply chain under price discount policy: a Stackelberg game approach. Journal of Management Analytics 8: 646–672. https://doi.org/10.1080/23270012.2021.1911697

    Article  Google Scholar 

  19. Sadeghi R, Taleizadeh A A, Chan F T S and Heydari J 2019 Coordinating and pricing decisions in two competitive reverse supply chains with different channel structures. International Journal of Production Research 57: 2601–2625. https://doi.org/10.1080/00207543.2018.1551637

    Article  Google Scholar 

  20. Barman A, Das R, De P K and Sana S S 2021 Optimal pricing and greening strategy in a competitive green supply chain: Impact of government subsidy and tax policy. Sustainability 13: 9178. https://doi.org/10.3390/su13169178

    Article  Google Scholar 

  21. Nair R B, Abijith K P, Abraham A, Kumar K R and Sridharan R 2022 Prices and profits in centralized dual-channel supply chains under competition. IFAC PapersOnLine 55: 2366–2371. https://doi.org/10.1016/j.ifacol.2022.10.062

    Article  Google Scholar 

  22. Taleizadeh A A and Sadeghi R 2019 Pricing strategies in the competitive reverse supply chains with traditional and e-channels: A game theoretic approach. International Journal of Production Economics 215: 48–60. https://doi.org/10.1016/j.ijpe.2018.06.011

    Article  Google Scholar 

  23. Ying-ying L 2018 Overview of research on dual-channel supply chain management. Advances in Economics, Business and Management Research. International Conference on Economic Management and Green Development (ICEMGD) 51: 204–212. https://doi.org/10.2991/icemgd-18.2018.34

    Article  Google Scholar 

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Correspondence to K Ratna Kumar.

Appendices

Appendix I. Proof of Lemma 1

The first order conditions of (7) with respect to \( p_{ij} \), \( i \in \{1,2 \} \), \( j \in \{r,d \} \) are given in (A1) through (A4) respectively. These constitute the necessary conditions.

$$\begin{aligned}{} & {} \frac{2ac}{3}+\frac{2ap_{1d}}{3}+\frac{ap_{2d}}{3}-2ap_{1r} +\frac{ap_{2r}}{3}+D\rho \theta =0 \end{aligned}$$
(A1)
$$\begin{aligned}{} & {} a(c-p_{1d})-ap_{1d}-\frac{a(c-p_{1r})}{3} \nonumber \\{} & {} \quad +\frac{a(p_{2d}+p_{1r}+p_{2r})}{3}-D\rho (\theta -1)=0 \end{aligned}$$
(A2)
$$\begin{aligned}{} & {} a(c-p_{2r})-\frac{a(c-p_{2d})}{3}-ap_{2r} \nonumber \\{} & {} \quad +\frac{a(p_{1d}+p_{2d}+p_{1r})}{3}-D\theta (\rho -1)=0 \end{aligned}$$
(A3)
$$\begin{aligned}{} & {} a(c-p_{2d})-ap_{2d}-\frac{a(c-p_{2r})}{3} \nonumber \\{} & {} \quad +\frac{a(p_{1d}+p_{1r}+p_{2r})}{3}+D(\rho -1)(\theta -1)=0 \end{aligned}$$
(A4)

Next, it is found that \( \frac{\partial ^{2}\pi _{i}}{\partial p_{ir}^2}=-2a<0 \). With respect to \( p_{ir} \) and \( p_{id} \), the determinant of the Hessian of (7) i.e. \( \left| \begin{matrix}-2a&{}\frac{2a}{3}\\ \frac{2a}{3}&{}-2a\\ \end{matrix}\right| =\frac{32a^2}{9}>0 \). As a result, Eq. (7) is strictly jointly concave in both \( p_{ir} \) and \( p_{id} \), satisfying the necessary and sufficient conditions for optimality. Thus, solving (A1) through (A4) simultaneously, we obtain eqs. (8), (9), (10) and (11). Hence proved.

Appendix II. Proof of Lemma 2

To begin, determine the first order conditions of \(\pi _{2}\) with respect to \( p_{2r} \) and \( p_{2d} \), as shown in eqs. (A5) and (A6), respectively. These are the necessary conditions that must be met.

$$\begin{aligned}{} & {} a(c-p_{2r})-\frac{a(c-p_{2d})}{3}-ap_{2r}+\frac{a(p_{1d}+p_{2d}+p_{1r})}{3} \nonumber \\{} & {} \quad -D\theta (\rho -1)=0 \end{aligned}$$
(A5)
$$\begin{aligned}{} & {} a(c-p_{2d})-ap_{2d}-\frac{a(c-p_{2r})}{3}+\frac{a(p_{1d}+p_{1r}+p_{2r})}{3} \nonumber \\{} & {} \quad + D(\rho -1)(\theta -1)=0 \end{aligned}$$
(A6)

Following that, we find \( \frac{\partial ^{2}\pi _{2}}{\partial p_{2r}^2}=-2a<0 \). The determinant of \( \pi _{2} \)’s Hessian with respect to \( p_{2r} \) and \( p_{2d} \), i.e. \( \left| \begin{matrix}-2a&{}\frac{2a}{3}\\ \frac{2a}{3}&{}-2a\\ \end{matrix}\right| =\frac{32a^2}{9}>0 \). The second supply chain’s profit function is thus strictly jointly concave with respect to \( p_{2r} \) and \( p_{2d} \), and the necessary and sufficient conditions are met. Solving eqs. (A5) and (A6) yields two temporary equations for \( p_{2r} \) and \( p_{2d} \) at the same time. The optimal equations are then obtained using the backward induction method. As a result, these temporary equations are substituted in the profit function of the first supply chain, yielding a new profit function for the first supply chain that we refer to as \( \pi _{1new} \). Now it is time to double-check the necessary and sufficient conditions for optimality. The first order conditions of \(\pi _{1}\) with respect to \( p_{1r} \) and \( p_{1d} \) are determined by the equations (A7) and (A8), respectively. These are the necessary conditions that must be met.

$$\begin{aligned}{} & {} \frac{D}{4}-\frac{D \rho }{4}+\frac{2ac}{3}+ap_{1d}-\frac{5ap_{1r}}{3}+D\rho \theta =0 \end{aligned}$$
(A7)
$$\begin{aligned}{} & {} \frac{D}{4}+\frac{3D \rho }{4}+\frac{2ac}{3}-\frac{5ap_{1d}}{3}+ap_{1r}-D\rho \theta =0 \end{aligned}$$
(A8)

After that, we discover that \( \frac{\partial ^{2}\pi _{1new}}{\partial p_{1r}^2}=-\frac{5a}{3}<0 \). The Hessian determinant of \( \pi _{1new} \) with respect to \( p_{1r} \) and \( p_{1d} \) is \( \left| \begin{matrix}-\frac{5a}{3}&{}a\\ a&{}-\frac{5a}{3}\\ \end{matrix}\right| =\frac{16a^2}{9}>0 \). As a result, \( \pi _{1new} \) is strictly jointly concave with respect to \( p_{1r} \) and \( p_{1d} \), and the necessary and sufficient conditions for optimality are met. We get eqs. (14) and (15) by solving eqs. (A7) and (A8) simultaneously. We get eqs. (16) and (17) by substituting the optimal prices of the leader in the temporary pricing equations of the follower found earlier. By considering the second supply chain as the leader and the first supply chain as the follower, eqs. (18), (19), (20), and (21) can be obtained. As a result, the proof.

Appendix III. Proof of Proposition 1

\( p_{1j}^{seqled*} - p_{1j}^{seqfol*}=\frac{3D\rho }{16a} \ge 0 \). Hence, \( p_{1j}^{seqled*}\ge p_{1j}^{seqfol*} \). \( p_{1j}^{seqfol*}-p_{1j}^{sim*}=\frac{D+D\left( 1-\rho \right) }{16a}>0 \). Hence, \( p_{1j}^{sim*}<p_{1j}^{seqfol*} \). So, \( p_{1j}^{sim*}<p_{1j}^{seqfol*}\le p_{1j}^{seqled*},\ j \in \{r,d\} \). Similarly, it can be proven that \( p_{2j}^{sim*}<p_{2j}^{seqfol*}\le p_{2j}^{seqled*},\ j \in \{r,d\} \). Thus, Eq. (26) is proved.

\(\pi _{1}^{seqfol*}-\pi _{1}^{seqled*}=\frac{D^2}{64a}[3+3\left( 1-\rho ^2\right) ]>0 \). Hence, \( \pi _{1}^{seqfol*}>\pi _{1}^{seqled*} \). \( \pi _{1}^{seqled*}-\pi _{1}^{sim*}=\frac{D^2}{96a}(\rho +1)^2>0 \). Hence, \( \pi _{1}^{seqled*}>\pi _{1}^{sim*} \). Thus, \( \pi _{1}^{sim*}<\pi _{1}^{seqled*}<\pi _{1}^{seqfol*} \). Similarly, it can be proven that \( \pi _{2}^{sim*}<\pi _{2}^{seqled*}<\pi _{2}^{seqfol*} \). Hence, Eq. (27) is proved.

Appendix IV. Proof of Proposition 2

We have to prove that \(\hat{\theta }_{1}^{sim}\) lies in [0,1] for any value of \(\rho \). For \(\hat{\theta }_{1}^{sim} \le 1 \), the denominator of \(\hat{\theta }_{1}^{sim}\) should be greater than or equal to its numerator. For \(\hat{\theta }_{1}^{sim} \ge 0 \), the numerator of \(\hat{\theta }_{1}^{sim}\) should be greater than or equal to 0. Thus, the following two conditions should be satisfied:

  1. 1.

    \( 2(8+16\rho -19\rho ^2) \ge 9(A_{2}-3\rho ^2+A_{1}) \)

  2. 2.

    \( 9(A_{2}-3\rho ^2+A_{1}) \ge 0 \)

1. Let

$$\begin{aligned} f_{1}(\rho ) = 2(8+16\rho -19\rho ^2) - 9(A_{2}-3\rho ^2+A_{1}) \end{aligned}$$

Here, \( f_{1}(\rho ) \) is the difference between the denominator and the numerator of \(\hat{\theta }_{1}^{sim}\).

The first order necessary condition for optimality is:

$$\begin{aligned} \frac{df_{1}(\rho )}{d \rho } = \frac{2 \sqrt{3} (10\rho -8)(\rho +1)}{\sqrt{(2-\rho )(2+5\rho )}} - 4\sqrt{3}\sqrt{(2-\rho )(2+5\rho )} - 22\rho + 32 = 0 \end{aligned}$$

Solving for \(\rho \), we get

$$\begin{aligned} \therefore \rho _{11}^{sim *} = 0.2494 \end{aligned}$$

(There are three values of \(\rho _{11}^{sim *}\). This is the only feasible value. The other two values are infeasible, one being negative and the other being greater than 1).

Again,

$$\begin{aligned}{} & {} \frac{d^2 f_{1}(\rho )}{d \rho ^2} = \frac{2[24\sqrt{3}\rho + 8\sqrt{3} + 240\sqrt{3}\rho ^2 - 100\sqrt{3}\rho ^3}{[(2-\rho )(2+5\rho )]^{3/2}} \nonumber \\{} & {} \quad - \frac{11[(2-\rho )(2+5\rho )]^{3/2}]}{[(2-\rho )(2+5\rho )]^{3/2}} \end{aligned}$$
(A9)

Now,

$$\begin{aligned} \frac{d^2 f_{1}(\rho _{11}^{sim *})}{d \rho ^2} = \frac{d^2 f_{1}(0.2494)}{d \rho ^2} = -15.0057 \end{aligned}$$

This means that the above value of \(\rho _{11}^{sim *}\) is a maximum. Since there is only a single feasible value of \(\rho _{11}^{sim *}\) (\(\rho _{11}^{sim *}\) is unimodal) and that value being a maximum, the minimum value(s) should lie at the extreme(s). Hence, the minimum value should lie at either 0 or 1.

$$\begin{aligned}{} & {} f_{1}(0) = 2.1436 \\{} & {} f_{1}(1) = 0.3394 \end{aligned}$$

The above values indicate that \( f_{1}(\rho ) \) has a minimum value at 1. Since the value of \( f_{1}(1) \) is positive and that value is a minimum, all the other values of \(f_{1}(\rho )\) should be greater than the value at \(\rho =1\). Thus, the denominator is greater than the numerator for all values of \(\rho \). Thus,

$$\begin{aligned}{} & {} 2(8+16\rho -19\rho ^2) - 9(A_{2}-3\rho ^2+A_{1}) \ge 0\\{} & {} \therefore 2(8+16\rho -19\rho ^2) \ge 9(A_{2}-3\rho ^2+A_{1}) \end{aligned}$$

Thus, the first condition is satisfied. Hence, \(\hat{\theta }_{1}^{sim} \le 1 \).

2. Let

$$\begin{aligned} g_{1}(\rho ) = 9(A_{2}-3\rho ^2+A_{1}) \end{aligned}$$

Here, \( g_{1}(\rho ) \) is the numerator of \(\hat{\theta }_{1}^{sim}\).

The first order necessary condition for optimality is:

$$\begin{aligned} \frac{dg_{1}(\rho )}{d \rho } = 4\sqrt{3}\sqrt{(2-\rho )(2+5\rho )} - 54\rho - \frac{2\sqrt{3}(10\rho -8)(\rho +1)}{\sqrt{(2-\rho )(2+5\rho )}} = 0 \end{aligned}$$

Solving for \(\rho \), we get

$$\begin{aligned} \therefore \rho _{12}^{sim *} = 0.4550 \end{aligned}$$

Again,

$$\begin{aligned}{} & {} \frac{d^2 g_{1}(\rho )}{d \rho ^2} = \frac{2[100\sqrt{3}\rho ^3 - 24\sqrt{3}\rho - 8\sqrt{3} - 240\sqrt{3}\rho ^2}{[(2-\rho )(2+5\rho )]^{3/2}} \nonumber \\{} & {} \quad - \frac{27[(2-\rho )(2+5\rho )]^{3/2}]}{[(2-\rho )(2+5\rho )]^{3/2}} \end{aligned}$$
(A10)

Now,

$$\begin{aligned} \frac{d^2 g_{1}(\rho _{12}^{sim *})}{d \rho ^2} = \frac{d^2 g_{1}(0.4550)}{d \rho ^2} = -66.0792 \end{aligned}$$

This means that the above value of \(\rho _{12}^{sim *}\) is a maximum. Since there is only a single feasible value of \(\rho _{12}^{sim *}\) (\(\rho _{12}^{sim *}\) is unimodal) and that value being a maximum, the minimum value(s) should lie at the extreme(s). Hence, the minimum value should lie at either 0 or 1.

$$\begin{aligned} g_{1}(0)= & {} 13.8564 \\ g_{1}(1)= & {} 9.6606 \end{aligned}$$

The above values indicate that \( g_{1}(\rho ) \) has a minimum value at 1. Since the value of \( g_{1}(1) \) is positive and that value is a minimum, all the other values of \(g_{1}(\rho )\) should be greater than the value at \(\rho =1\). Thus, the numerator is greater than or equal to 0 for all values of \(\rho \).

$$\begin{aligned} \therefore 9(A_{2}-3\rho ^2+A_{1}) \ge 0 \end{aligned}$$

Thus, the second condition is satisfied. Hence, \(\hat{\theta }_{1}^{sim} \ge 0 \).

Since both the conditions are satisfied, it is proved that \(\hat{\theta }_{1}^{sim}\) lies in [0,1] for any value of \(\rho \).

Similarly, it can be proven that \(\hat{\theta }_{2}^{sim}\) lies in [0,1] for any value of \(\rho \). Table 6 provides a detailed list of notations and their descriptions

Table 6 Notations and their descriptions.

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Nair, R.B., Abraham, A., Kumar, K.R. et al. Optimal pricing decisions of centralized dual-channel supply chains in a duopoly: a study on the influence of competition structure. Sādhanā 49, 1 (2024). https://doi.org/10.1007/s12046-023-02297-8

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