Page 93 - AJWEP-22-6
P. 93
ML-based C for side trapezoidal labyrinth weirs
d
doi: 10.1007/s40996-025-01820-7 algorithm applied to discharge coefficient prediction on
17. Ahmed AM, Altalib AN. Determination of discharge labyrinth weirs. Soft Comput. 2022;26:12197-12215.
coefficient of arced labyrinth weir with semicircular doi: 10.1007/s00500-022-07041-8
openings. Iran J Sci Technol Trans Civil Eng. 2025:1-12. 30. Majedi-Asl M, Fuladipanah M, Arun V, Tripathi RP.
doi: 10.1007/s40996-025-01747-z Using data mining methods to improve discharge
18. Masoudi MH, Yari A, Sadeghian J, Norouzi H. coefficient prediction in piano key and labyrinth weirs.
Experimental investigation of the discharge coefficient Water Supply. 2022;22(2):1964-1982.
of the rectangular and trapezoidal labyrinth weirs doi: 10.2166/ws.2021.304
considering variable congress lengths. Model Earth Syst 31. Mustafa M, Mansoor T, Muzzammil M. Support vector
Environ. 2024;10(2):2819-2832. machine (SVM) approach to develop the discharge
doi: 10.1007/s40808-023-01925-w prediction model for triangular labyrinth weir. Water
19. Hadi ZM, Majeed HQ. Experimental and Numerical Supply. 2022;22:8942-8956.
Study of the Discharge Capacity of a Labyrinth Side Weir doi: 10.2166/ws.2022.393
in a Straight Channel. In: AIP Conference Proceedings. 32. Wang F, Zheng S, Ren Y, Liu W, Wu C. Application of
Vol. 3091. Melville, NY: AIP Publishing; 2024. hybrid neural network in discharge coefficient prediction
20. Darvas LA. Discussion of performance and design of of triangular labyrinth weir. Flow Measure Instrument.
labyrinth weirs, by Hay and Taylor. J Hydraul Eng. 2022;83:102108.
1971;97:1246-51. doi: 10.1016/j.flowmeasinst.2021.102108
21. Lux F, Hinchliff D. Design and Construction of Labyrinth 33. Hu Z, Karami H, Rezaei A, et al. Using soft computing
Spillways. In: 15 Congress International Commission and machine learning algorithms to predict the discharge
th
on Large Dams ICOLD. Vol. 4. Lausanne, Switzerland: coefficient of curved labyrinth overflows. Eng Appl
1985. p. 249-274. Comput Fluid Mech. 2021;15(1):1002-1015.
22. Melo JF, Ramos CM, Magalhães AP. Descarregadores doi: 10.1080/19942060.2021.1934546
Com Soleira em Labirinto de um Ciclo em Canais 34. Mahmoud A, Yuan X, Hajilounezhad T, Yuan Y.
Convergentes. In: Determinação da Capacidade de Investigation on labyrinth spillway multi-objective
Vazão Proceedings 6 Congresso da Água. 2002. optimization with an emphasis on predicting discharge
th
23. Crookston BM. Labyrinth Weirs. Doctor of Philosophy, coefficient through different artificial neural networks.
Utah State University [PhD Dissertation]; 2010. Measurement. 2021;174:109036.
24. Emiroglu ME, Kaya N, Agaccioglu H. Discharge doi: 10.1016/j.measurement.2021.109036
capacity of labyrinth side weir located on a straight 35. Shafiei S, Najarchi M, Shabanlou SA. Novel approach
channel. J Irrig Drain Eng. 2009;136(1):37-46. using CFD and neuro-fuzzy-firefly algorithm in
doi: 10.1061/(ASCE)IR.1943-4774.0000112 predicting labyrinth weir discharge coefficient. J Braz
25. Karami H, Karimi S, Bonakdari H, Shamshirband S. Soc Mech Sci Eng. 2020;42:44.
Predicting discharge coefficient of triangular labyrinth doi: 10.1007/s40430-019-2109-9
weir using extreme learning machine, artificial neural 36. Norouzi P, Rajabi A, Izadbakhsh MA, Shabanlou S,
network and genetic programming. Neural Comput Appl. Yosefvand F, Yaghoubi B. A new non‐tuned self‐
2018;29(11):983-989. adaptive machine‐learning approach for simulating the
doi: 10.1007/s00521-016-2588-x discharge coefficient of labyrinth weirs. Irrig Drainag.
26. Bonakdari H, Ebtehaj I, Gharabaghi B, Sharifi A, 2020;69(3):398-416.
Mosavi A. Prediction of discharge capacity of labyrinth doi: 10.1002/ird.2423
weir with gene expression programming. In: Proceedings 37. Olyaie E, Banejad H, Heydari M. Estimating discharge
of SAI Intelligent Systems Conference. Cham: Springer coefficient of PK-weir under subcritical conditions based
International Publishing; 2020. p. 202-217. on high-accuracy machine learning approaches. Iran J
doi: 10.1007/978-3-030-55180-3_17 Sci Technol Trans Civil Eng. 2019;43:89-101.
27. Khani M, Shabanlou S. Assessment of discharge doi: 10.1007/s40996-018-0150-z
coefficient in trapezoidal and rectangular canals through 38. Roushangar K, Alami MT, Shiri J, Asl MM. Determining
regularized extreme learning machine. Measurement. discharge coefficient of labyrinth and arced labyrinth
2021;180:109493. weirs using support vector machine. Hydrol Res.
doi: 10.1016/j.measurement.2021.109493 2018;49(3):924-938.
28. Mahmoud A, Hu T, Zeng X, Jing P, Li X, Ribeiro EDC. doi: 10.2166/nh.2017.214
Hydraulic informed multi-layer perceptron for estimating 39. Uyumaz A, Danandeh Mehr A, Kahya E, Erdem H.
discharge coefficient of labyrinth weir. Eng Appl Artif Rectangular side weirs discharge coefficient estimation
Intell. 2023;123:106435. in circular channels using linear genetic programming
doi: 10.1016/j.engappai.2023.106435 approach. J Hydroinform. 2014;16(6):1318-1330.
29. Emami H, Emami S, Parsa J. A walnut optimization doi: 10.2166/hydro.2014.112
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