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خوش مو, محمد, گودرزی, مصطفی, نوروزی, قاسم. (1400). پیش بینی تقاضای آب در بخش کشاورزی استان های حاشیه دریای خزر: مقایسه الگوی مارکوف-سوئیچینگ و شبکه عصبی. سامانه مدیریت نشریات علمی, 29(4), 205-245. doi: 10.30490/aead.2022.353487.1304
محمد خوش مو; مصطفی گودرزی; قاسم نوروزی. "پیش بینی تقاضای آب در بخش کشاورزی استان های حاشیه دریای خزر: مقایسه الگوی مارکوف-سوئیچینگ و شبکه عصبی". سامانه مدیریت نشریات علمی, 29, 4, 1400, 205-245. doi: 10.30490/aead.2022.353487.1304
خوش مو, محمد, گودرزی, مصطفی, نوروزی, قاسم. (1400). 'پیش بینی تقاضای آب در بخش کشاورزی استان های حاشیه دریای خزر: مقایسه الگوی مارکوف-سوئیچینگ و شبکه عصبی', سامانه مدیریت نشریات علمی, 29(4), pp. 205-245. doi: 10.30490/aead.2022.353487.1304
خوش مو, محمد, گودرزی, مصطفی, نوروزی, قاسم. پیش بینی تقاضای آب در بخش کشاورزی استان های حاشیه دریای خزر: مقایسه الگوی مارکوف-سوئیچینگ و شبکه عصبی. سامانه مدیریت نشریات علمی, 1400; 29(4): 205-245. doi: 10.30490/aead.2022.353487.1304

پیش بینی تقاضای آب در بخش کشاورزی استان های حاشیه دریای خزر: مقایسه الگوی مارکوف-سوئیچینگ و شبکه عصبی

اقتصاد کشاورزی و توسعه
مقاله 8، دوره 29، شماره 4 - شماره پیاپی 116، اسفند 1400، صفحه 205-245    اصل مقاله (1.62 M)
نوع مقاله: مقاله پژوهشی
شناسه دیجیتال (DOI): 10.30490/aead.2022.353487.1304
نویسندگان
محمد خوش مو1؛ مصطفی گودرزی* 2؛ قاسم نوروزی3
1دانشجوی دکتری اقتصاد کشاورزی، دانشگاه آزاد اسلامی، واحد قائم‏شهر، قائم‏شهر، ایران.
2نویسنده مسئول و استادیار گروه اقتصاد کشاورزی، دانشگاه آزاد اسلامی، واحد قائم‏شهر، قائم‏شهر، ایران.
3استادیار گروه اقتصاد کشاورزی، دانشگاه آزاد اسلامی، واحد قائم‏شهر، قائم‏شهر، ایران.
چکیده
در جهان امروز، مدیریت عرضه و تقاضای آب نقش محوری در سامان‏دهی و برنامه ­ریزی تأمین آب شرب ساکنان شهر­ها و روستا­ها و همچنین،تأمین منابع آب کشاورزان و صنعت­ گران دارد، به ‏ویژه آنکه در وضعیت کنونی، تمام کشورهای جهان با تبعات تغییرات اقلیمی نیز مواجه ‏اند. در این راستا، در پژوهش حاضر، به پیش­بینی تقاضای آب بخش کشاورزی استان ­های حاشیه دریای خزر به روش زنجیره مارکوف- سوئیچینگ و مقایسه آن با مدل شبکه عصبی مصنوعی با بهره‌گیری از داده‌های فصلی دوره 1380:1 تا 1397:4 پرداخته شد. مقایسه کارآیی مدل­ های تقاضای آب برآوردشده به روش شبکه عصبی مصنوعی و چرخشی مارکوف با استفاده از معیارهای میانگین مربع خطا (MSE)، مجذور میانگین مربع خطا (RMSE)، میانگین قدرمطلق خطا (MAE)، و میانگین قدرمطلق درصد خطا (MAPE) نشان داد که رویکرد چرخشی مارکوف، نسبت به مدل ­های شبکه عصبی، برای پیش­بینی تقاضای آّب،کارآیی بیشتری دارد. همچنین، پیش‌بینی تقاضای آب کشاورزی برای دو دوره فصلی و سالانه، به ‏ترتیب،طی دوره‏های 1398:1 تا 1402:4 و 1398 تا 1402 صورت گرفت.
کلیدواژه‌ها
پیش بینی تقاضای آب؛ بخش کشاورزی؛ مارکوف- سوئیچینگ؛ شبکه عصبی
عنوان مقاله [English]
Prediction of Water Demand in the Agricultural Sector of the Caspian Littoral Provinces: Comparison of Markov-Switching and ANN Models
نویسندگان [English]
M. Khoshmo1؛ M. Goodarzi2؛ G. Norouzi3
1PhD Student in Agricultural Economics, Islamic Azad University, Qaemshahr Branch, Qaemshahr, Iran.
2and Assistant Professor, Department of Agricultural Economics, Islamic Azad University, Qaemshahr Branch, Qaemshahr, Iran
3Assistant Professor, Department of Agricultural Economics, Islamic Azad University, Qaemshahr Branch, Qaemshahr, Iran.
چکیده [English]
In today's world, water supply and demand management plays a pivotal role in organizing and planning the drinking water supply of urban and rural residents as well as the water supply of farmers and industrialists, especially in the current situation which all countries are facing the consequences of climate change. Therefore, in this study, the water demand of the agricultural sector of the Caspian littoral provinces was predicted by Markov-Switching method and compared with the Artificial Neural Network model using seasonal data for the period 2001: 1 to 2018: 4. Comparing the efficiency of water demand models estimated by Markov-Switching and ANN methods using Mean Square Error (MSE), Root Mean Square Error (RMSE), Mean Absolute Error (MAE), and Mean Absolute Percentage Error (MAPE) Showed that Markov-Switching approach was more efficient than water ANN models for predicting water demand. In addition, the forecast of agricultural water demand for both seasonal and annual periods was made for the periods of 2019: 1 to 2023: 4 and 2019 to 2023, respectively.
کلیدواژه‌ها [English]
Water Demand Prediction, Agriculture Sector, Markov-Switching, ANN
مراجع
  1. Adeba, D., Kansal, M.L. and Sen, S. (2015). Assessment of water scarcity and its impacts on sustainable development in Awash basin, Ethiopia. Sustainable Water Resources Management, 1(1): 71-87.
  2. Allouche, J. (2011). The sustainability and resilience of global water and food systems: political analysis of the interplay between security, resource scarcity, political systems and global trade. Food Policy, 36: S3-S8.
  3. Aram, A.R. and Agheli, L. (2012). A hybrid model for forecasting daily urban water demand. Quarterly Journal of Quantitative Economics, 9(1): 1-17.(Persian)
  4. Blanke, A., Rozelle, S., Lohmar, B., Wang, J. and Huang, J. (2007). Water saving technology and saving water in China. Agricultural Water Management, 87(2): 139-150.
  5. Cerra, V. and Saxena, S.C. (2005). Did output recover from the Asian crisis? IMF Staff Papers, 52(1): 1-23.
  6. Chauvet, M. and Hamilton, J.D. (2006). Dating business cycle turning points. Contributions to Economic Analysis, 276: 1-54.
  7. Clements, M.P. andKrolzig, H.M. (2002). Can oil shocks explain asymmetries in the US business cycle?. In: J.D. and Hamilton, B. Raj (eds) Advances in Markov-Switching Models. Studies in Empirical Economics. Physica, Heidelberg.
  8. Cologni, A. and Manera, M. (2009). The asymmetric effects of oil shocks on output growth: a Markov-Switching analysis for the G-7 countries. Economic Modelling, 26(1): 1-29.
  9. Dagnew, D.C. (2012). Factors determining residential water demand in north western Ethiopia, the case of Merawi. Doctoral Dissertation, Cornell University.
  10. Davig, T. (2004). Regime-switching debt and taxation. Journal of Monetary Economics, 51(4): 837-859.
  11. Denton, F.T. (1971). Adjustment of monthly or quarterly series to annual totals: an approach based on quadratic minimization.Journal of the American Statistical Association, 66(333): 99-102.
  12. Di Fonzo, T. (2003). Constrained retropolation of high-frequency data using related series: a simple dynamic model approach. Statistical Methods and Applications, 12(1): 109-119.
  13. Di Fonzo, T., Marini, M. and Zieschang, K. (2012). On the extrapolation with the Denton proportional benchmarking method. Washington, DC: International Monetary Fund (IMF).
  14. Esmaeili, A. and Vazirzadeh, S. (2009). Water pricing for agricultural production in the South of Iran. Water Resources Management, 23(5): 957-964.(Persian)
  15. García-valiñas, M.A. (2005). Efficiency and equity in natural resources pricing: a proposal for urban water distribution service. Environmental and Resource Economics, 32(2): 183-204.
  16. Gohar, A.A., Amer, S.A. and Ward, F.A. (2015). Irrigation infrastructure and water appropriation rules for food security. Journal of Hydrology, 520: 85-100.
  17. Goldfeld, S.M. and Quandt, R.E. (1973). A Markov model for switching regressions. Journal of Econometrics, 1(1): 3-15.
  18. Hajipour, M., Zakerinia, M., Ziaee, A. and Hesam, M. (2015). Water demand management in agriculture and its impact on water resources of Bojnourd basin with WEAP and MODFLOW models. Water and Conservation, 22(4): 85-101.(Persian)
  19. Hamilton, J.D. (1994). Time series econometrics. Princeton University Press.
  20. Hamilton, J.D. (1988). Rational-expectations econometric analysis of changes in regime: an investigation of the term structure of interest rates. Journal of Economic Dynamics and Control, 12(2-3): 385-423.
  21. Hamilton, J.D. (1989). A new approach to the economic analysis of nonstationary time series and the business cycle. Econometrica: Journal of the Econometric Society, 57(2): 357-384.
  22. Hamilton, J.D. (2005). What’s real about the business cycle? Federal Reserve Bank of St. Louis Review, 87(4): 435-452.
  23. Hurlimann, A., Dolnicar, S. and Meyer, P. (2009). Understanding behaviour to inform water supply management in developed nations: a review of literature, conceptual model and research agenda. Journal of Environmental Management, 91(1): 47-56.
  24. Janczura, J. and Weron, R. (2012). Efficient estimation of Markov regime-switching models: an application to electricity spot prices. AStA Advances in Statistical Analysis, 96(3): 385-407.
  25. Jeanne, O. and Masson, P. (2000). Currency crises, sunspots and Markov-Switching regimes‏. Journal of International Economics, 50(2): 327-350.
  26. Jebel-Ameli, F. and Goodarzi Farahani, Y. (2013). The effect of targeted subsidy on demand rate of urban water in Qom city. Quarterly Journal of Economic Modelling, 7(22): 101-119.(Persian)
  27. Kazemi , A., Modarres, M. and Mehregan, M. (2010). Transport energy demand forecasting using Markov Chain Grey model: case study of Iran. Industrial Management Journal, 3(2): 117-132.(Persian)
  28. Kazemi, M., Jalili Ghazizadeh, M. and Darabi, A. (2017). An overview of some methods for forecasting urban water demand. Tehran: Shahid Beheshti University.(Persian)
  29. Li, H., Zhang, C., Miao, D., Wang, T., Feng, Y., Fu, H., . . . Zhao, M. (2016). Water demand prediction of Grey Markov model based on GM (1.1). Proceedings of the 2016 3rd International Conference on Mechatronics and Information Technology, Atlantis Press.
  30. Liu, J., Savenije, H.H. and Xu, J. (2003). Forecast of water demand in Weinan City in China using WDF-ANN model. Physics and Chemistry of the Earth, Parts A/B/C, 28(4-5): 219-224.
  31. March, H., Therond, O. and Leenhardt, D. (2012). Water futures: reviewing water-scenario analyses through an original interpretative framework. Ecological Economics, 82: 126-137.
  32. Martin-Carrasco, F., Garrote, L., Iglesias, A. and Mediero, L. (2013). Diagnosing causes of water scarcity in complex water resources systems and identifying risk management actions. Water Resources Management, 27(6): 1693-1705.
  33. Martins, R. and Fortunato, A. (2007). Residential water demand under block rates: a Portuguese case study. Water Policy, 9(2): 217-230.
  34. McKellar, R.C. and Cholette, H. (1984). Synthesis of extracellular proteinase by Pseudomonas fluorescens under conditions of limiting carbon, nitrogen, and phosphate. Applied and Environmental Microbiology, 47(6): 1224-1227.
  35. Nauges, C. and Thomas, A. (2003). Long-run study of residential water consumption. Environmental and Resource Economics, 26(1): 25-43.
  36. Pereira, L.S., Oweis, T. and Zairi, A. (2002). Irrigation management under water scarcity. Agricultural Water Management, 57(3): 175-206.
  37. Quandt, R.E. (1972). A new approach to estimating switching regressions. Journal of the American Statistical Association, 67(338): 306-310.
  38. Qureshi, M.E., Hanjra, M.A. and Ward, J. (2013). Impact of water scarcity in Australia on global food security in an era of climate change. Food Policy, Elsewier, 38: 136-145.
  39. Rahimi Feyzabad, F., Yazdanpnah, M., Forouzani, M., Mohammadzadeh, M. and Borton, R. (2015). Investigation of the relationship between social capital and farmers' intention toward establishment of and membership in Water User's Associations: the case of Aleshtar County. Cooperation and Agriculture, 3(12): 77-95.(Persian)
  40. Ruijs, A., Zimmermann, A. and van den Berg, M. (2008). Demand and distributional effects of water pricing policies. Ecological Economics, 66(2-3): 506-516.
  41. Sadeghi Soghdel, H., Zolfaghari, M. and Aram, R. (2012). Modeling and forecasting of urban water short-run demand. The Journal of Economic Studies and Policies, 0(20): 159-172.(Persian)
  42. Sayyadi, O. (2008). Preliminary orientation with artificial neural network. PhD Thesis. Tehran: Sharif University of Technology. (Persian)
  43. Sims, C.A. and Zha, T. (2006). Were there regime switches in US monetary policy? American Economic Review, 96(1): 54-81.
  44. Statistical Center of Iran (2001-2018). Available at: https://www.amar.org.ir (Persian).
  45. Tabesh, M. and Dini, M. (2010). Forecasting daily urban water demand using artificial neural networks, a case study of Tehran urban water.Journal of Water and Wastewater, 21(1), 84-95.(Persian)
  46. Taghvaei , A., Pourjafar, M., Hosseinabadi, M. and Riyahi Medvar, H. (2011). Developing an expert system model for predicting annual urban residential water demand using artificial neural network (case study: Ilam city). Journal of Architect, Urban Design and Urban Planning, 4(6): 63-74.(Persian)
  47. Wang, F., Zhang, Y., Rao, Q., Li, K. and Zhang, H. (2017). Exploring mutual information-based sentimental analysis with kernel-based extreme learning machine for stock prediction. soft Computing, 21(12): 3193-3205.
  48. Wang, H., Wang, W., Cui, Z., Zhou, X., Zhao, J. and Li, Y. (2018). A new dynamic firefly algorithm for demand estimation of water resources. Information Sciences, 438: 95-106.
  49. Yazdani, Saeid, Abedi, Samaneh and Abedi, Sepideh (2014). Forecasting models for domestic and agricultural water consumptions in Tehran province (case study: Amirkabir dam). Iranian Journal of Agricultural Economics and Development Research, 45(1): 41-48.(Persian)
  50. Yazdanpanah, M., Hayati, D., Hochrainer-Stigler, S. and Zamani, G. (2014). Understanding farmers' intention and behavior regarding water conservation in the Middle-East and North Africa: a case study in Iran. Journal of Environmental Management, 135: 63-72.(Persian)
  51. Yazdanpanah, M., Hayati, D., Thompson, M., Zamani, G. and Monfared, N. (2014). Policy and plural responsiveness: taking constructive account of the ways in which Iranian farmers think about and behave in relation to water. Journal of Hydrology, 514, 347-357.
  52. Yazdanpanah, M., Rahimi Feyzabad, F., Forouzani, M., Mohammadzadeh, S. and Burton, R.J. (2015). Predicting farmers’ water conservation goals and behavior in Iran: a test of social cognitive theory. Land Use Policy, 47: 401-407.
  53. Yudhistira, M., Sastiono, P. and Meliyawati, M. (2020). Exploiting unanticipated change in block rate pricing for water demand elasticities estimation: evidence from Indonesian suburban area. Water Resources and Economics, 32: 100-161.
  54. Zamani, G., Zarafshani, K. and Moradi , K. (2010). Study of psychological coping strategies of Fars province farmers in drought. Scientific Journal of Rescue and Relief, 1(4): 14-23.(Persian)Zhang, M., Wang, H., Cui, Z. and Chen, J. (2018). Hybrid multi-objective cuckoo search with dynamical local search. Memetic Computing, 10(2): 199-
آمار
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