Application of Three Mathematical Methods in Quality Evaluation of Jujube Fruit

doi:10.11924/j.issn.1000-6850.casb2024-0363

Abstract

Abstract:

The study aims to investigate and identify feasible mathematical analysis methods to provide a reference for the quality evaluation of gray jujubes in Xinjiang. In this study, gray jujube fruits subjected to a compound treatment with four agents being used as test materials, and 12 fruit quality indicators were comprehensively analyzed using factor analysis, entropy value method and level-gray relation analysis, respectively. The results showed that there were different degrees of variability among the fruit traits, ranging from 1.56% to 37.58%. Among them, the coefficients of variation of single fruit weight and single plant yield were large (>10%), whereas the coefficients of variation of the remaining indicators were relatively small (<10%). The results of factor analysis demonstrated that the 12 quality indicators of the gray jujube were converted into three common factors, each with eigenvalues greater than 1. The cumulative variance contribution rate was 89.974%, which encompassed the majority of the information regarding the participating gray jujube fruit traits. Moreover, the results of the composite scores demonstrated that the comprehensive evaluation of fruit quality was highest after T₂ treatment (0.25 mmol/L SA+ 30 mg/L DA-6+ 0.01 g/L BR). The results of the entropy value method indicated that the coefficients of variation for the trait indices exceeded 10% in all cases, with the exception of four indices of longitudinal fruit diameter, fruit shape index, single fruit weight, and organic acid. Among these, the weight of fructose was the highest at 14.83%, followed by vitamin C, while the weight of transverse fruit diameter was the lowest, and the ranking of the scores revealed that the comprehensive quality of gray jujube was best after T₁ treatment (0.25 mmol/L SA+ 30 mg/L DA-6). The results of the level-gray relation analysis indicated that single fruit weight and single fruit yield had the highest weights, while organic acid and cellulose exhibited the lowest weights. Furthermore, the scoring results demonstrated that the integrated quality of gray jujube was optimal following the T₂ treatment. In evaluating the quality of gray jujube, the extensive data on fruit trait indices will lead the limited variation in key indices. Combined with the production performance of different treatments, the evaluation results of hierarchical-gray correlation degree are more in line with the actual situation.

Key words: grey jujube, fruit quality, factor analysis, entropy method, multi-level gray relation analysis, quality evaluation

WANG Huanhuan, WANG Jingjing, CHEN Qiling. Application of Three Mathematical Methods in Quality Evaluation of Jujube Fruit[J]. Chinese Agricultural Science Bulletin, 2025, 41(7): 138-144.

Figures/Tables 6

References 24

[1]	CUI N, DU T, KANG S, et al. Regulated deficit irrigation improved fruit quality and water use efficiency of pear-jujube trees[J]. Agricultural water management, 2008, 95(4):489-497.
[2]	LI G L, TANG Z S, SONG Z X, et al. Integrated transcriptomic and metabolomic analysis reveal the molecular and metabolic basis of flavonoids in Chinese sour jujube fruits in different harvest times[J]. Postharvest biology and technology, 2024,209:112685.
[3]	FARRAKH N, AAMIR N, SAJID A, et al. Xanthan gum coating delays ripening and softening of jujube fruit by reducing oxidative stress and suppressing cell wall polysaccharides disassembly[J]. Postharvest biology and technology, 2024,209:112689.
[4]	岳婉婉, 阿布都卡尤木·阿依麦提, 靳娟, 等. 不同植物生长调节剂对骏枣光合特性、果实品质及产量的影响[J]. 新疆农业科学, 2022, 59(12):3013-3021. doi: 10.6048/j.issn.1001-4330.2022.12.017
[5]	郑强卿, 陈奇凌, 王晶晶, 等. 不同植物生长调节剂对骏枣内源激素与果实品质的影响[J]. 新疆农业科学, 2019, 56(3):430-437. doi: 10.6048/j.issn.1001-4330.2019.03.005
[6]	李慧, 李百云, 李超. 不同时间采收的灵武长枣果实品质综合评价[J]. 经济林研究, 2022, 40(3):265-272.
[7]	袁野, 胡兰, 刘平, 等. ‘蜂蜜罐’枣实生后代果实性状变异分析与评价[J]. 植物遗传资源学报, 2018, 19(3):539-545. doi: 10.13430/j.cnki.jpgr.2018.03.020
[8]	王博. 宁夏引进枣种质资源生长表现及果实品质评价与分析[D]. 银川: 宁夏大学, 2022.
[9]	王文军, 陈奇凌, 郑强卿, 等. 灰枣不同栽培模式的产量构成与果实商品性评价[J]. 果树学报, 2021, 38(5):739-748.
[10]	樊保国, 李月梅, 张强, 等. 中阳木枣品种群果实制干品质性状及其综合评价[J]. 西北农林科技大学学报(自然科学版), 2019, 47(12):130-139.
[11]	郭雪飞, 周晓凤, 冯一峰, 等. 两种糖积累型枣品种果实糖积累生理代谢机制研究[J]. 植物生理学报, 2019(6):837-846.
[12]	段卞慧, 冯一峰, 林敏娟, 等. 引进16个鲜食枣品种品质性状的主成分分析和综合评价[J]. 新疆农业科学, 2017, 54(12):2198-2210. doi: 10.6048/j.issn.1001-4330.2017.12.006
[13]	田彦龙, 马永强, 王磊, 等. 西北不同生态区甜樱桃果实品质分析[J]. 果树学报, 2021, 38(4):509-519.
[14]	张艳霞, 吕丹桂, 耿康奇, 等. 水分胁迫对赤霞珠葡萄果实品质和甲氧基吡嗪含量的影响[J]. 果树学报, 2022(6):1017-1028.
[15]	梁丰志, 童盼盼, 张亚若, 等. 新疆南疆不同灰枣产区果实品质分析及优生区划分[J]. 华中农业大学学报, 2021, 40(4):123-132.
[16]	彭勇菲, 李学营, 彭建营. 19个早中熟鲜食枣品种果实品质分析与综合评价[J]. 河北农业大学学报, 2019, 42(06):51-56.
[17]	李慧, 魏天军. 基于主成分和灰色关联度分析的鲜食枣果实品质评价[J]. 经济林研究, 2021, 39(1):60-67.
[18]	张梅, 王利娜, 王姝婧, 等. 基于层次-关联度的新疆骏枣品质性状分析及综合评价[J]. 中南林业科技大学学报, 2022, 42(1):78-85.
[19]	贾朝爽, 王志华, 王文辉. 不同货架温度结合1-MCP处理对华红、华月苹果质地性状的影响[J]. 华北农学报, 2022, 37(4):128-140. doi: 10.7668/hbnxb.20192888
[20]	韩晓, 刘凤之, 王孝娣, 等. 3种综合评价法在葡萄砧穗组合环境适应性中的应用[J]. 果树学报, 2017, 34(10):1349-1356.
[21]	陈美艳, 赵婷婷, 刘小莉, 等. 猕猴桃品种‘金艳’果实品质因子分析与综合评价[J]. 植物科学学报, 2021, 39(1):85-92.
[22]	王靖, 张金锁. 综合评价中确定权重向量的几种方法比较[J]. 河北工业大学学报, 2001(2):52-57.
[23]	马文霞, 倪玉洁, 谢倩, 等. 鲜食百香果果实品质综合评价模型的建立及应用[J]. 食品科学, 2020, 41(13):53-60. doi: 10.7506/spkx1002-6630-20190625-327
[24]	王佳敏, 刘敏, 郭咏梅, 等. AHP法和灰色关联法在观赏辣椒果实外观品质评价中的应用[J]. 山西农业大学学报(自然科学版), 2019, 39(1):73-78.

处理	果实纵径 (X₁)/mm	果实横径 (X₂)/mm	果形指数 (X₃)	单果重 (X₄)/g	单株产量 (X₅)/kg	总糖 (X₆)/(mg/g)	还原糖 (X₇)/(mg/g)	果糖 (X₈)/(mg/g)	淀粉 (X₉)/(mg/g)	纤维素 (X₁₀)/(mg/g)	维生素C (X₁₁)/(μg/g)	有机酸 (X₁₂)/%
CK	28.57	18.93	1.51	4.89	1.34	238.47	45.99	33.16	26.98	13.47	364.68	0.83
T₁	29.48	21.06	1.40	6.28	1.92	240.58	46.03	33.58	26.75	12.85	370.67	0.81
T₂	29.57	21.21	1.39	6.22	3.19	206.56	44.79	37.96	25.80	11.24	317.49	0.76
T₃	29.35	21.14	1.39	5.88	3.04	209.41	43.55	34.16	24.59	11.73	313.18	0.73
均值	29.24	20.59	1.42	5.82	2.37	223.76	45.09	34.72	26.03	12.32	341.51	0.78
最大值	29.57	21.21	1.51	6.28	3.19	240.58	46.03	37.96	26.98	13.47	370.67	0.83
最小值	28.57	18.93	1.39	4.89	1.34	206.56	43.55	33.16	24.59	11.24	313.18	0.73
标准差	0.46	1.11	0.06	0.64	0.89	18.27	1.18	2.20	1.09	1.02	30.37	0.05
变异系数/%	1.56	5.37	4.11	11.05	37.58	8.16	2.61	6.34	4.18	8.27	8.89	5.84

处理	果实纵径 (X₁)/mm	果实横径 (X₂)/mm	果形指数 (X₃)	单果重 (X₄)/g	单株产量 (X₅)/kg	总糖 (X₆)/(mg/g)	还原糖 (X₇)/(mg/g)	果糖 (X₈)/(mg/g)	淀粉 (X₉)/(mg/g)	纤维素 (X₁₀)/(mg/g)	维生素C (X₁₁)/(μg/g)	有机酸 (X₁₂)/%
CK	28.57	18.93	1.51	4.89	1.34	238.47	45.99	33.16	26.98	13.47	364.68	0.83
T₁	29.48	21.06	1.40	6.28	1.92	240.58	46.03	33.58	26.75	12.85	370.67	0.81
T₂	29.57	21.21	1.39	6.22	3.19	206.56	44.79	37.96	25.80	11.24	317.49	0.76
T₃	29.35	21.14	1.39	5.88	3.04	209.41	43.55	34.16	24.59	11.73	313.18	0.73
均值	29.24	20.59	1.42	5.82	2.37	223.76	45.09	34.72	26.03	12.32	341.51	0.78
最大值	29.57	21.21	1.51	6.28	3.19	240.58	46.03	37.96	26.98	13.47	370.67	0.83
最小值	28.57	18.93	1.39	4.89	1.34	206.56	43.55	33.16	24.59	11.24	313.18	0.73
标准差	0.46	1.11	0.06	0.64	0.89	18.27	1.18	2.20	1.09	1.02	30.37	0.05
变异系数/%	1.56	5.37	4.11	11.05	37.58	8.16	2.61	6.34	4.18	8.27	8.89	5.84

指标	因子1	因子2	因子3
X₁	0.204	0.836	0.103
X₂	0.356	0.885	-0.255
X₃	0.360	0.743	-0.376
X₄	0.137	0.978	-0.002
X₅	0.831	0.532	-0.152
X₆	-0.965	-0.226	0.132
X₇	-0.805	-0.126	0.513
X₈	0.718	0.402	0.362
X₉	-0.759	-0.202	0.548
X₁₀	0.829	0.500	-0.169
X₁₁	-0.961	-0.169	0.203
X₁₂	0.159	0.067	-0.794
特征值	7.785	1.924	1.084
累计贡献率/%	64.873	80.905	89.943
权重/%	72.127	17.825	10.047

指标	因子1	因子2	因子3
X₁	0.204	0.836	0.103
X₂	0.356	0.885	-0.255
X₃	0.360	0.743	-0.376
X₄	0.137	0.978	-0.002
X₅	0.831	0.532	-0.152
X₆	-0.965	-0.226	0.132
X₇	-0.805	-0.126	0.513
X₈	0.718	0.402	0.362
X₉	-0.759	-0.202	0.548
X₁₀	0.829	0.500	-0.169
X₁₁	-0.961	-0.169	0.203
X₁₂	0.159	0.067	-0.794
特征值	7.785	1.924	1.084
累计贡献率/%	64.873	80.905	89.943
权重/%	72.127	17.825	10.047

指标	X₁	X₂	X₃	X₄	X₅	X₆	X₇	X₈	X₉	X₁₀	X₁₁	X₁₂
熵值	0.93	0.89	0.93	0.92	0.87	0.79	0.90	0.78	0.90	0.89	0.78	0.93
差异系数/%	6.99	10.76	7.16	7.69	13.17	21.47	10.39	22.28	10.07	11.08	22.09	7.13
权重/%	4.65	7.16	4.76	5.11	8.76	14.28	6.91	14.83	6.70	7.38	14.70	4.75