Odd-even dimension RUNge Kutta optimization algorithm and its application

doi:10.23919/JSEE.2026.000115

Abstract

Abstract:

This research proposes an odd-even dimension RUNge Kutta algorithm (ODRUN) to solve global optimization and a well-known NP-hard problem in inventory management. The rpoposed algorithm integrates odd-even dimensional, fourth-order Runge-Kutta method, and neighbor search strategies. This hybrid approach significantly improves population diversity, avoids local optima, and enhances convergence accuracy. To validate the performance of the proposed algorithm, a widely recognized benchmark function suit from CEC2022 is first employed. Results confirm that ODRUN achieves an overall effectiveness ratio of 66.67% across three statistical indicators (best, mean, and standard deviation) for 12 benchmark functions. The test shows this algorithm is ranked first compared to seven state-of-the-art metaheuristic algorithms. Furthermore, ODRUN is applied to the joint replenishment problem with imperfect items and trade credit. Numerical examples from 600 randomly generated large-scale instances highlight that the algorithm’s performance remains unaffected by an increase in problem scale. The significant cost savings brought by the ODRUN algorithm, with the maximum improvement ratio in average cost and best-found total cost ranging from 14.81% to 19.5%, are achieved in comparison to other algorithms. In conclusion, ODRUN is an effective and robust tool for complex optimization problems.

Key words: metaheturitics, RUNge Kutta algorithm, odd-even dimension search strategy, neighbor search strategy, joint replenishment problem with imperfect items and trade credit

Lin WANG, Yingying PI, Xuerui WANG. Odd-even dimension RUNge Kutta optimization algorithm and its application[J]. Journal of Systems Engineering and Electronics, 2026, 37(3): 878-896.

Figures/Tables 17

Table 1

Table 2

A comparison of the statistical measures on CEC2022 test functions"

Function	Indicator	COA	GA	DE	GBO	WO	GWO	RUN	ODRUN
$ C_{1}^{22} $	Best	2757.61	13543.42	34495.85	300.00	301.17	340.71	300.00	300.00
	Mean	8847.49	25304.91	77328.52	300.00	312.77	1644.17	300.00	300.00
	Std	3401.75	15086.33	14110.44	1.92E−08	9.89	1668.50	3.00E−03	6.63E−08
$ C_{2}^{22} $	Best	469.75	658.02	828.93	400.00	400.65	407.13	400.00	400.11
	Mean	1588.77	1388.33	1323.65	405.00	429.08	425.65	403.89	406.66
	Std	814.04	514.02	387.82	3.16	33.57	22.00	4.47	3.04
$ C_{3}^{22} $	Best	625.28	655.73	686.58	600.00	600.04	600.05	603.05	600.00
	Mean	648.79	660.77	704.95	600.89	600.78	601.21	614.61	600.07
	Std	9.88	4.50	9.80	2.95	0.75	1.69	6.75	0.14
$ C_{4}^{22} $	Best	834.37	872.53	907.16	810.94	808.06	803.98	812.93	801.99
	Mean	851.23	886.71	933.83	822.15	833.91	815.96	821.92	809.29
	Std	8.86	11.83	17.19	8.27	14.08	8.26	5.08	4.18
$ C_{5}^{22} $	Best	1021.00	2128.97	2467.22	900.09	900.00	900.02	933.47	900.00
	Mean	1426.36	2197.37	4896.78	908.20	904.37	910.98	1010.62	900.40
	Std	199.24	205.42	1352.10	11.00	4.88	19.59	46.63	0.41
$ C_{6}^{22} $	Best	4.42E+05	1.48E+08	1.38E+08	1803.36	1870.65	2016.12	1877.82	1835.92
	Mean	7.73E+07	1.40E+09	1.66E+09	2788.76	3394.99	5605.32	3378.26	3190.18
	Std	8.28E+07	6.81E+08	1.12E+09	1611.25	1722.46	2343.16	1016.88	1555.41
$ C_{7}^{22} $	Best	2053.61	2114.07	2120.44	2000.99	2020.07	2001.96	2024.98	2000.06
	Mean	2086.42	2251.26	2276.96	2021.79	2031.72	2026.91	2043.96	2015.94
	Std	19.89	61.35	61.76	8.93	14.79	12.63	13.11	8.53
$ C_{8}^{22} $	Best	2225.34	2269.30	2326.72	2200.86	2207.66	2207.04	2220.70	2200.49
	Mean	2249.37	3824.19	3378.14	2220.23	2224.19	2227.52	2223.38	2214.27
	Std	26.87	5009.21	2627.85	4.64	5.04	22.39	1.61	9.07
$ C_{9}^{22} $	Best	2661.42	2764.29	2679.05	2529.28	2529.28	2529.29	2529.28	2529.28
	Mean	2754.82	3115.66	3168.97	2534.18	2534.12	2571.68	2539.08	2529.28
	Std	58.90	229.40	274.86	26.83	10.55	39.98	37.28	0.00
$ C_{10}^{22} $	Best	2526.98	2517.95	2759.66	2500.32	2500.49	2500.31	2500.62	2500.18
	Mean	2781.64	2638.22	3950.97	2537.27	2558.58	2568.84	2555.17	2500.33
	Std	362.03	132.44	542.04	57.26	63.85	56.98	59.22	0.08
$ C_{11}^{22} $	Best	2983.33	5266.45	38417.93	2600.00	2600.07	2720.07	2600.01	2600.00
	Mean	3982.92	5267.08	84468.75	2753.79	2701.68	2983.52	2703.79	2600.00
	Std	332.46	0.33	19472.43	152.38	181.12	132.56	150.26	1.45E−04
$ C_{12}^{22} $	Best	2892.11	2880.28	2872.04	2861.40	2859.37	2859.56	2859.37	2859.37
	Mean	2973.51	2931.93	2882.94	2864.56	2863.87	2865.68	2864.51	2862.52
	Std	51.25	25.55	6.11	1.73	1.71	5.81	1.39	1.25
Friedman mean rank		6.42	7	7.58	2.67	3.33	4.33	3.33	1.33
Final rank		6	7	8	2	3	5	3	1

Table 2

Fig 1

Fig 2

Fig 3

Table 3

Table 4

Table 5

Table 6

Fig 4

Fig 5

Fig 6

Table 7

Fig 7

Table 8

Table 9

Comparative results of proposed algorithms under various scale problems (S=150)"

$ n $	Indicator	COA	GA	DE	GBO	WO	GWO	RUN	ODRUN	MIR/%
14	Best	13360.82	13280.98	13344.55	15589.10	13280.81	13280.98	13287.55	13280.81	14.81
	Mean	13873.80	13306.69	13408.01	15683.90	13284.57	13300.96	13336.34	13280.87	15.32
	Standrad	471.01	35.07	41.21	110.94	6.92	25.24	46.91	0.08	99.98
22	Best	20227.18	20399.64	19619.05	23036.99	19419.36	19423.16	19473.84	19417.17	15.71
	Mean	21218.65	20681.84	19724.16	23272.98	19436.99	19483.51	19606.78	19418.14	16.56
	Standrad	576.35	154.84	60.78	278.63	24.14	82.48	95.81	1.85	99.68
29	Best	26286.61	26554.24	25208.75	29874.27	24863.14	24865.78	25008.02	24851.06	16.81
	Mean	27214.02	26633.08	25338.24	30176.36	24909.13	24999.15	25182.16	24859.55	17.62
	Standrad	727.40	49.61	71.06	355.58	45.45	175.17	112.55	12.69	98.26
34	Best	31384.04	31487.49	30005.48	35156.72	29531.36	29542.37	29736.63	29512.66	16.05
	Mean	32327.33	31668.04	30144.23	35477.32	29612.97	29755.27	29958.42	29516.84	16.80
	Standrad	762.86	115.26	70.89	304.03	67.09	330.52	139.35	6.68	99.12
47	Best	41792.41	42412.31	40084.12	47206.52	39203.00	39214.49	39691.70	39128.89	17.11
	Mean	42800.57	42754.88	40257.54	47903.28	39358.40	39568.41	39992.77	39168.49	18.23
	Standrad	780.02	200.17	88.30	951.98	118.10	445.39	188.88	40.89	95.71
50	Best	45735.97	46467.23	43674.30	51908.69	42799.37	42805.35	43299.32	42745.50	17.65
	Mean	46727.50	46822.95	43837.39	52472.18	42965.72	43171.54	43586.39	42758.43	18.51
	Standrad	693.75	222.05	79.07	887.75	126.15	462.79	182.13	20.40	97.70
53	Best	47935.40	48769.61	45844.50	54336.15	44874.15	44869.02	45400.21	44788.27	17.57
	Mean	48988.86	49067.57	46004.07	55440.64	45043.92	45288.95	45718.49	44845.32	19.11
	Standrad	793.43	180.57	83.79	1632.03	130.83	547.71	191.04	56.71	96.52
60	Average	54525.74	55349.47	51975.04	61727.35	50841.37	50825.43	51528.87	50699.26	17.87
	Standrad	55458.57	55705.93	52126.53	62603.58	51042.73	51272.12	51863.33	50729.79	18.97
	Rank	698.79	221.37	82.85	1456.31	141.92	589.18	202.46	32.80	97.75
73	Average	65187.62	65953.77	61657.99	73773.35	60421.13	60319.52	61207.98	60166.58	18.44
	Standrad	65969.64	66447.32	61849.01	74847.00	60673.89	60839.22	61592.65	60297.17	19.44
	Rank	591.92	293.44	92.97	1371.03	181.29	701.74	222.35	106.59	92.23
80	Average	71996.13	72772.03	68383.16	80855.50	66872.49	66721.60	67845.62	66477.94	17.78
	Standrad	72771.34	73316.83	68539.46	82205.43	67167.15	67208.77	68228.04	66566.55	19.02
	Rank	570.60	323.06	85.55	2354.88	195.96	549.47	235.44	68.91	97.07

Table 9

Table 10

Comparative results of proposed algorithms under various scale problems (S=300)"

$ n $	Indicator	COA	GA	DE	GBO	WO	GWO	RUN	ODRUN	MIR/%
12	Best	13176.05	13173.18	13172.52	15009.06	13172.52	13172.62	13173.35	13172.52	12.24
	Mean	13198.99	13204.36	13172.52	15027.95	13176.27	13173.10	13184.35	13172.60	12.35
	Standard	18.34	71.75	0.00	21.13	7.09	1.41	15.84	0.04	99.94
14	Best	14269.00	14263.68	14263.09	16480.57	14263.09	14263.09	14263.94	14263.09	13.46
	Mean	14289.40	14314.37	14263.53	16499.80	14267.53	14264.59	14274.25	14263.27	13.55
	Standard	18.23	90.25	0.75	20.36	7.40	3.35	13.21	0.20	99.78
18	Best	18025.59	17989.39	17961.06	20889.83	17961.21	17961.12	17970.77	17961.06	14.02
	Mean	18074.02	18436.98	17961.81	20964.81	17983.46	17966.98	18026.19	17961.27	14.33
	Standard	31.65	528.98	1.36	57.75	28.06	10.55	43.53	0.52	99.90
20	Best	19979.44	20021.93	19930.90	23120.97	19928.45	19927.06	19937.75	19926.95	13.81
	Mean	20028.80	20701.39	19939.80	23199.79	19946.17	19931.85	19986.59	19927.15	14.11
	Standard	36.78	629.75	7.84	60.01	26.10	8.96	39.78	0.08	99.99
33	Best	30441.85	32473.26	32183.16	35725.52	30086.91	30075.03	30241.39	30066.21	15.84
	Mean	30536.76	33696.09	32709.69	36022.17	30187.02	30127.89	30406.70	30078.00	16.50
	Standard	54.41	720.17	281.69	389.33	80.28	49.39	115.56	17.32	97.59
49	Best	44144.82	47636.31	47799.17	51517.69	43371.83	43340.73	43803.39	43272.13	16.01
	Mean	44254.57	49017.05	48167.00	51857.90	43561.05	43482.69	44068.71	43314.49	16.47
	Standard	60.20	1088.73	236.74	348.67	130.70	108.10	159.48	45.85	95.79
54	Best	48622.66	52581.08	52932.77	56924.28	47734.65	47723.45	48324.95	47616.21	16.35
	Mean	48757.41	53989.87	53349.79	57423.08	47953.15	47896.60	48588.23	47642.40	17.03
	Standard	71.96	1134.34	264.34	696.64	154.16	132.27	157.59	31.01	97.27
56	Best	49335.94	53374.58	53692.51	57958.94	48418.33	48390.12	48932.75	48249.62	16.75
	Mean	49465.47	54789.61	54168.12	58324.35	48633.23	48561.93	49252.60	48284.09	17.21
	Standard	72.18	1122.85	302.91	426.30	152.58	127.72	189.03	38.48	96.57
69	Average	60809.67	66236.15	67423.51	71777.09	59699.85	59649.60	60404.50	59476.88	17.14
	Standard	60975.58	67790.59	67962.74	72544.73	59955.93	59880.43	60751.30	59582.37	17.87
	Rank	85.63	1231.32	353.65	1346.98	172.69	159.40	191.34	88.64	93.42
80	Average	69256.58	75356.31	76772.37	81922.72	67820.88	67858.41	68831.98	67483.35	17.63
	Standard	69431.03	76757.97	77349.30	82690.58	68161.41	68162.55	69201.00	67575.79	18.28
	Rank	87.79	994.13	356.35	1142.17	265.52	199.51	207.07	79.92	93.00

Table 10

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Algorithm	Parameter
COA	None
GA	$ F=0.7 $; $ {C}_{r}=0.3 $
DE	$ {P}_{c}=0.9 $; $ {P}_{m}=0.5 $
GBO	$ {\beta }_{\min}=0.2 $ $ {\beta }_{\max}=1.2, $ $ pr=0.5 $
WO	$ P=0.4 $
GWO	$ {a}_{\min}=0 $; $ {a}_{\max}=2 $
RUN	$ a=20 $; $ b=12 $
ODRUN	$ a=20 $; $ b=16 $

Function	Statistics	COA	GA	DE	GBO	WO	RUN
$ C_{1}^{22} $	Sig.	1.73E−06	1.73E−06	1.73E−06	2.84E−05	1.73E−06	1.73E−06
$ C_{1}^{22} $	H	1	1	1	1	1	1
$ C_{2}^{22} $	Sig.	1.73E−06	1.73E−06	1.73E−06	0.0030	4.29E−06	0.0001
$ C_{2}^{22} $	H	1	1	1	1	1	1
$ C_{3}^{22} $	Sig.	1.73E−06	1.73E−06	1.73E−06	0.0117	1.49E−05	1.13E−05
$ C_{3}^{22} $	H	1	1	1	1	1	1
$ C_{4}^{22} $	Sig.	1.73E−06	1.73E−06	1.73E−06	2.35E−06	0.0008	2.88E−06
$ C_{4}^{22} $	H	1	1	1	1	1	1
$ C_{5}^{22} $	Sig.	1.73E−06	1.73E−06	1.73E−06	2.60E−06	0.0001	4.73E−06
$ C_{5}^{22} $	H	1	1	1	1	1	1
$ C_{6}^{22} $	Sig.	1.73E−06	1.73E−06	1.73E−06	0.1254	3.72E−05	0.7499
$ C_{6}^{22} $	H	1	1	1	0	1	0
$ C_{7}^{22} $	Sig.	1.73E−06	1.73E−06	1.73E−06	0.0087	0.0012	6.34E−06
$ C_{7}^{22} $	H	1	1	1	1	1	1
$ C_{8}^{22} $	Sig.	1.73E−06	1.73E−06	1.73E−06	0.0039	5.79E−05	1.13E−05
$ C_{8}^{22} $	H	1	1	1	1	1	1
$ C_{9}^{22} $	Sig.	1.73E−06	1.73E−06	1.73E−06	3.11E−05	1.73E−06	1.73E−06
$ C_{9}^{22} $	H	1	1	1	1	1	1
$ C_{10}^{22} $	Sig.	1.73E−06	1.73E−06	1.73E−06	3.18E−06	2.16E−05	1.73E−06
$ C_{10}^{22} $	H	1	1	1	1	1	1
$ C_{11}^{22} $	Sig.	1.73E−06	1.73E−06	1.73E−06	0.0087	1.73E−06	1.73E−06
$ C_{11}^{22} $	H	1	1	1	1	1	1
$ C_{12}^{22} $	Sig.	1.73E−06	1.73E−06	1.73E−06	5.79E−05	0.0004	6.04E−03
$ C_{12}^{22} $	H	1	1	1	1	1	1

Variant	Enhanced solution quality scheme	Odd-even dimension strategy	Neighbor search strategy
RUN	Yes	No	No
RUNOD	Yes	No	Yes
RUNNS	Yes	Yes	No
RUNDS	Yes	Yes	Yes
ODRUN	No	Yes	Yes

Parameter	Description
$ n $	Number of items
$ {D}_{i} $	Demand rate for item $ i $
$ {Q}_{i} $	The order quantity for item $ i $
$ S $	Major ordering costs associated with each replenishment
$ {s}_{i} $	Minor ordering cost per order of item $ i $
$ {h}_{i} $	Holding cost per unit of item $ i $ at the retailer
$ {\rho }_{i} $	The percentage of imperfect products of item $ i $ in each replenishment cycle
$ {\gamma }_{i} $	The screening rate for item $ i $, $ {\gamma }_{i}> {D}_{i} $
$ {\alpha }_{i} $	The screening cost per unit time for item $ i $
$ M $	The length of the trade credit period
$ {p}_{i} $	Retail price per unit for the item $ i $
$ {c}_{i} $	Purchasing unit price for the item $ i $
$ {I}_{p} $	Interest charged per dollar by the supplier
$ {I}_{e} $	Interest earned per dollar for the retailer $ {I}_{e}\leq {I}_{p} $
$ {\theta }_{i} $	The discounted rate for the proportion of imperfect items
$ {r}_{i} $	The percentage of unusable imperfect items
$ {\delta }_{i} $	The loss per unit of unusable imperfect items for item $ i $
$ {t}_{i} $	The screening time for item $ i $
$ T $	Basic cycle time (decision variable)
$ {{k}}_{{i}} $	The integer number that decides the replenishment cycle time of item $ i $ (decision variable)

Parameter	Range
$ n $	$ \left[3{,}80\right] $
$ {D}_{i} $	$ \left[1\;000{,}\;5\;000\right] $
$ S $	$ \{150{,}300\} $
$ {s}_{i} $	$ \left[35{,}55\right] $
$ {h}_{i} $	$ \left[0.5{,}2.5\right] $
$ {\rho }_{i} $	$ \left[0.01{,}0.2\right] $
$ {\gamma }_{i} $	$ {\text{[1.25D}}_{i},2{\text{D}}_{i}] $
$ M $	$ [10/365{,}30/365] $
$ {p}_{i} $	$ [40{,}60] $
$ {c}_{i} $	$ [2{,}4] $
$ {\alpha }_{i} $	$ [0.01{c}_{i},0.05{c}_{i}] $
$ {I}_{e} $	$ [0.06{,}0.12] $
$ {I}_{p} $	$ [{1.2I}_{e},2{I}_{e}] $
$ {r}_{i} $	$ [0,0.2] $
$ {\theta }_{i} $	$ [0.05,0.5] $
$ {\delta }_{i} $	$ [0.1{c}_{i},0.2{c}_{i}] $