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A mean field game price model with noise

  • Received: 02 March 2020 Accepted: 23 May 2020 Published: 27 July 2020
  • In this paper, we propose a mean-field game model for the price formation of a commodity whose production is subjected to random fluctuations. The model generalizes existing deterministic price formation models. Agents seek to minimize their average cost by choosing their trading rates with a price that is characterized by a balance between supply and demand. The supply and the price processes are assumed to follow stochastic differential equations. Here, we show that, for linear dynamics and quadratic costs, the optimal trading rates are determined in feedback form. Hence, the price arises as the solution to a stochastic differential equation, whose coefficients depend on the solution of a system of ordinary differential equations.

    Citation: Diogo Gomes, Julian Gutierrez, Ricardo Ribeiro. A mean field game price model with noise[J]. Mathematics in Engineering, 2021, 3(4): 1-14. doi: 10.3934/mine.2021028

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  • In this paper, we propose a mean-field game model for the price formation of a commodity whose production is subjected to random fluctuations. The model generalizes existing deterministic price formation models. Agents seek to minimize their average cost by choosing their trading rates with a price that is characterized by a balance between supply and demand. The supply and the price processes are assumed to follow stochastic differential equations. Here, we show that, for linear dynamics and quadratic costs, the optimal trading rates are determined in feedback form. Hence, the price arises as the solution to a stochastic differential equation, whose coefficients depend on the solution of a system of ordinary differential equations.


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    [1] Burger M, Caffarelli LA, Markowich PA, et al. (2013) On a Boltzmann-type price formation model. P R Soc Lond Ser A Math Phys Eng Sci 469: 1-20.
    [2] Caffarelli LA, Markowich PA, Pietschmann JF (2011) On a price formation free boundary model by Lasry and Lions. C R Math Acad Sci Paris 349: 621-624. doi: 10.1016/j.crma.2011.05.011
    [3] Carmona R, Delarue F (2014) The master equation for large population equilibriums. arXiv:1404.4694.
    [4] Carmona R, Delarue F, Lacker D (2016) Mean field games with common noise. Ann Probab 44: 3740-3803. doi: 10.1214/15-AOP1060
    [5] Alasseur C, Taher IB, Matoussi A (2017) An extended mean field game for storage in smart grids. J Optim Theory Appl 184: 644-670.
    [6] Couillet R, Perlaza SM, Tembine H, et al. (2012) Electrical vehicles in the smart grid: A mean field game analysis. IEEE J Sel Area Commun 30: 1086-1096. doi: 10.1109/JSAC.2012.120707
    [7] De Paola A, Angeli D, Strbac G (2016) Distributed control of micro-storage devices with mean field games. IEEE T Smart Grid 7: 1119-1127.
    [8] De Paola A, Trovato V, Angeli D (2019) A mean field game approach for distributed control of thermostatic loads acting in simultaneous energy-frequency response markets. IEEE T Smart Grid, 10: 5987-5999. doi: 10.1109/TSG.2019.2895247
    [9] Gomes D, Lafleche L, Nurbekyan L (2016) A mean-field game economic growth model, In: Proceedings of the American Control Conference, 4693-4698.
    [10] Gomes DA, Saúde J (2020) A mean-field game approach to price formation. Dyn Games Appl, To appear.
    [11] Graber J, Mouzouni C (2017) Variational mean field games for market competition. arXiv:1707.07853.
    [12] Guéant O, Lasry JM, Lions PL (2011) Mean field games and applications. In: Paris-Princeton Lectures on Mathematical Finance 2010, Berlin: Springer, 205-266.
    [13] Kizilkale AC, Malhame RP (2014) A class of collective target tracking problems in energy systems: Cooperative versus non-cooperative mean field control solutions. In: Proceedings of the IEEE Conference on Decision and Control, 3493-3498.
    [14] Kizilkale AC, Malhame RP (2014) Collective target tracking mean field control for electric space heaters. In: 2014 22nd Mediterranean Conference on Control and Automation, MED 2014, 829-834.
    [15] Kizilkale AC, Malhame RP (2014) Collective target tracking mean field control for markovian jump-driven models of electric water heating loads. IFAC Proceedings Volumes 47: 1867-1872. doi: 10.3182/20140824-6-ZA-1003.00630
    [16] Malhamé R, Chong CY (1988) On the statistical properties of a cyclic diffusion process arising in the modeling of thermostat-controlled electric power system loads. SIAM J Appl Math 48: 465-480. doi: 10.1137/0148026
    [17] Malhamé R, Kamoun S, Dochain D (1989) On-line identification of electric load models for load management. In: Advances in Computing and Control, Berlin: Springer, 290-304.
    [18] Markowich PA, Matevosyan N, Pietschmann JF, et al. (2009) On a parabolic free boundary equation modeling price formation. Math Mod Meth Appl Sci 19: 1929-1957. doi: 10.1142/S0218202509003978
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