基于仿真区域性数据的服装团体定制归号机制

doi:10.13475/j.fzxb.20220405201

纺织学报 ›› 2023, Vol. 44 ›› Issue (05): 191-197.doi: 10.13475/j.fzxb.20220405201

基于仿真区域性数据的服装团体定制归号机制

聂梓萌¹, 杜劲松¹^,²(), 朱建龙³, 岳春明³, 葛旭光⁴

1.东华大学服装与艺术设计学院, 上海 200051
2.东华大学现代服装设计与技术教育部重点实验室, 上海 200051
3.海澜之家集团股份有限公司, 江苏江阴 214426
4.福建省希领服饰有限责任公司, 福建泉州 362201

收稿日期:2022-04-14 修回日期:2022-12-26 出版日期:2023-05-15 发布日期:2023-06-09
通讯作者: 杜劲松(1970—),男,副教授,博士。主要研究方向为服装智能制造。E-mail:ducccp@dhu.edu.cn。
作者简介:聂梓萌(1998—),女,硕士生。主要研究方向为服装工程数字化。
基金资助:
中央高校基本科研业务费专项资金资助项目(2232020G)

Garment group customization sizing mechanism based on simulated size data

NIE Zimeng¹, DU Jinsong¹^,²(), ZHU Jianlong³, YUE Chunming³, GE Xuguang⁴

1. College of Fashion and Design, Donghua University, Shanghai 200051, China
2. Key Laboratory of Clothing Design and Technology, Ministry of Education, Donghua University, Shanghai 200051, China
3. Hta Group Co., Ltd., Jiangyin, Jiangsu 214426, China
4. Fujian Xiling Clothing Co., Ltd., Quanzhou, Fujian 362201, China

Received:2022-04-14 Revised:2022-12-26 Published:2023-05-15 Online:2023-06-09

摘要/Abstract

摘要：

在服装团体定制市场快速发展的背景下,为探究适应不同团体客户的定制方案,解决区域性大规模人体尺寸数据收集难的问题,优化团体定制归号流程和提升团体订单风格统一性,采用蒙特卡罗方法仿真区域性团体尺寸测量数据,建立区域性团体号型规格表(RGS),并提出基于比例方法归号流程,优化归号结构链。结果表明:仿真数据与初始订单数据的散点图分布一致,仿真尺寸数据均呈正态分布,达到预期仿真目标。分别采用企业初始号型规格表(EIS)和区域性团体号型规格表对订单尺寸进行归号,RGS归号结果评价等级优秀转化为47.4%,表明优化的归号流程有效,且RGS更贴合目标区域人群体型,号型覆盖评价结果显示RGS对区域人群的整体覆盖效果显著。

关键词: 服装团体定制, 数据仿真, K-means聚类算法, 蒙特卡罗方法, 服装归号

Abstract:

Objective In the context of the rapid development of group customization of garment, this paper aims to solve the current problem of regional size system establishment of group customization, optimize the group customization number sizing process, and improve the style unity of group orders.

Method The Monte Carlo method was adopted to simulate the regional group size measurement data, and the regional group size system (RGS) was established based on the K-means clustering analysis results of the simulation data and the size proportion coefficient of the enterprise initial size system (EIS) and the sizing process of the group order was realized by using RGS. The sizing results were evaluated by comprehensive fit and aggregate loss.

Results The scatter diagram of chest grith/garment length of 10 000 sets of data was simulated by Monte Carlo method. The scatter diagram distribution and frequency distribution statistics of simulation data and real data were consistent (Fig.4), suggesting that the simulated data from the simulation model could be used as the target data of the next experiment. The clustering center of the simulation data clustering analysis results was tested (Tab.2). Based on the clustering center and EIS, the regional group size system RGS was established through the size system establishment process. 19 Types of RGS were involved in the research (Tab.4). Each size contained 4 important primary dimensions, i.e. chest grith, garment length, across shoulder and sleeve length. It was found that 4 sizes determining the style of garment were mid waist, hipline, sleeve bicep, and cuff. The same circumference or width transverse parameter has 3 length index values to match, and there were more size combination. Compared with EIS, RGS established on the basis of simulation data demonstrated a significant effect on the overall coverage of regional population. The comprehensive fit results showed that RGS can cover most target groups (Fig.5). The size data of the orders containing 218 people of the enterprise were matched by EIS and RGS, respectively. The sizing process and the sizing results were suggested 1 person cut individually for special body type. When using EIS for matching sizes, the evaluation result of the fit degree was as follows: 108 people fedback with excellent fitting (48%), 102 people good, 1 person general, and 6 people not ideal. When RGS was adopted to match the size of the order, and the fit degree evaluation results showed that 211 people returned excellent feedback, 4 people good, and 2 people general, with the proportion of excellent of 97.2%. The excellent conversion rate of RGS is 47.4% (Tab.5).

Conclusion The Monte Carlo method was adopted to simulate the regional size data accumulated by enterprise orders, and the enterprise size database was established. The simulation data reached the expected simulation goal, and the regional group size system could be optimized by using the simulation data. RGS establishment is shown to increase the coverage of target population, increase the fit degree of clothing, effectively improve the uniformity and consistency of garment customization, and thus reduce the probability of garment repair. The sizing mechanism considers the multidimensional size proportion of human body, changes the method of relying on a single dimension for the sizing process, and carries on the size matching through the proportion of different dimensions. The sizing process can effectively distinguish and classify the body size, and match the individual size with the size system. The sizing mechanism can provide theoretical basis for enterprise digital sizing process.

Key words: garment group customization, data simulation, K-means clustering algorithm, Monte Carlo method, garment sizing process

中图分类号:

TS941

聂梓萌, 杜劲松, 朱建龙, 岳春明, 葛旭光. 基于仿真区域性数据的服装团体定制归号机制[J]. 纺织学报, 2023, 44(05): 191-197.

NIE Zimeng, DU Jinsong, ZHU Jianlong, YUE Chunming, GE Xuguang. Garment group customization sizing mechanism based on simulated size data[J]. Journal of Textile Research, 2023, 44(05): 191-197.

图/表 10

表1

图1

图2

图3

图4

表2

聚类中心数据"

聚类中心序号	胸围 $C p 1$	衣长 $C p 2$	肩宽 $C p 3$	袖长 $C p 4$
1	95.51	69.79	42.77	57.86
2	97.97	73.37	43.81	61.04
3	100.08	70.27	44.10	57.92
4	101.44	73.13	44.72	60.19
5	102.59	75.83	45.27	62.58
6	104.03	71.19	45.19	58.23
7	104.44	73.64	45.57	60.50
8	106.42	77.88	46.45	63.82
9	106.49	75.25	46.24	61.43
10	107.18	72.53	46.17	58.95
11	109.28	76.34	47.13	62.33
12	109.81	74.26	47.04	60.06
13	110.85	78.95	47.81	64.24
14	112.65	76.14	48.02	61.40
15	115.22	78.74	48.94	63.52

表2

表3

HL企业Y版基础号型规格表"

号型	胸围 $E p 1$	衣长 $E p 2$	肩宽 $E p 3$	袖长 $E p 4$	中腰围 $E s 1$	臀围 $E s 2$	袖肥 $E s 3$	袖口 $E s 4$
90/71	90	71	40.8	56.5	79	90	17.4	12.5
92/71	92	71	41.4	56.5	81	92	17.7	12.7
94/71	94	71	42.0	56.5	83	94	18.0	12.9
96/71	96	71	42.6	56.5	85	96	18.3	13.1
98/71	98	71	43.2	56.5	87	98	18.6	13.3
100/73	100	73	43.8	58.0	89	100	18.9	13.5
102/73	102	73	44.4	58.0	91	102	19.2	13.7
104/73	104	73	45.0	58.0	93	104	19.5	13.9
106/75	106	75	45.6	59.5	95	106	19.8	14.1
108/75	108	75	46.2	59.5	97	108	20.1	14.3
110/75	110	75	46.8	59.5	99	110	20.4	14.5
112/75	112	75	47.4	59.5	101	112	20.7	14.7
114/77	114	77	48.0	61.0	103	114	21.0	14.9
116/77	116	77	48.6	61.0	105	116	21.3	15.1
118/77	118	77	49.2	61.0	107	118	21.6	15.3

表3

表4

Y版区域号型规格表"

RGS号型序号	胸围 $R p 1$	衣长 $R p 2$	肩宽 $R p 3$	袖长 $R p 4$	中腰围 $R s 1$	臀围 $R s 2$	袖肥 $R s 3$	袖口 $R s 4$	归号结果
1	91.0	69/71/73	40.9	57/58/59	80.0	91.0	17.6	12.6	1
2	92.5	69/71/73	41.4	57/58/59	81.5	92.5	17.8	12.8	0
3	94.0	69/71/73	41.8	57/58/59	83.0	94.0	18.0	12.9	0
4	95.5	71/73/75	42.3	58/59/60	84.5	95.5	18.2	13.1	0
5	97.0	71/73/75	427	58/59/60	86.0	97.0	18.5	13.2	3
6	98.5	71/73/75	43.2	58/59/60	87.5	98.5	18.7	13.4	9
7	100.0	71/73/75	43.6	58/59/60	89.0	100.0	18.9	13.5	10
8	101.5	71/73/75	44.1	58/59/60	90.5	101.5	19.1	13.7	0
9	103.0	71/73/75/77	44.5	58/59/60/61	92.0	103.0	19.4	13.8	33
10	104.5	71/73/75/77	45.0	58/59/60/61	93.5	104.5	19.6	14.0	31
11	106.0	7173/75/77	45.4	58/59/60/61	95.0	106.0	19.8	14.1	31
12	107.5	71/73/75/77	45.9	58/59/60/61	96.5	107.5	20.0	14.3	0
13	109.0	71/73/75/77	46.3	58/59/60/61	98.0	109.0	20.3	14.4	40
14	110.5	75/77/79	46.8	60/61/62	99.5	110.5	20.5	14.6	19
15	112.0	75/77/79	47.2	60/61/62	101.0	112.0	20.7	14.7	20
16	113.5	75/77/79	47.7	60/61/62	102.5	113.5	20.9	14.9	0
17	115.0	75/77/79	48.1	60/61/62	104.0	115.0	21.2	15.0	10
18	116.5	75/77/79	48.6	60/61/62	105.5	116.5	21.4	15.2	7
19	118.0	75/77/79	49.0	60/61/62	107.0	118.0	21.6	15.3	3

表4

表5

图5

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定制模式	应用模式	尺寸测量方案	号型标准制定	纸样生成方式	号型标准应用	版型变体方法	裁剪方案
大规模定制生产	C2M	控制尺寸、特征尺寸	国家标准、企业标准	企业版型、独立生成	服装通用号型标准	单独生成、批量修正	单件剪裁、粗裁+精裁
个性化定制	高级定制、C2M	控制尺寸、特征尺寸、其他尺寸	无标准、企业标准	独立生成	无	单独生成	单件剪裁
团体定制	制服、校服、团订	控制尺寸、特征尺寸	国家标准、企业标准、区域标准	企业版型,批量生成	区域性号型标准	批量修正	单件剪裁、粗裁+精裁

合体等级评价范围/cm	评价等级	统一性	EIS (优化前)	RGS (优化后)
0~1	一级	优秀	108	211
1~2	二级	良好	102	4
2~3	三级	一般	1	2
3~4	四级	不理想	6	0

基于仿真区域性数据的服装团体定制归号机制

Garment group customization sizing mechanism based on simulated size data

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