旱区城市扩展过程区位因素研究——以中国呼包鄂榆城市群为例

doi:10.31497/zrzyxb.20210416

自然资源学报 ›› 2021, Vol. 36 ›› Issue (4): 1021-1035.doi: 10.31497/zrzyxb.20210416

旱区城市扩展过程区位因素研究——以中国呼包鄂榆城市群为例

宋世雄¹^,²(), 张金茜¹^,², 刘志锋¹^,²(), 何春阳¹^,²

1.北京师范大学地表过程与资源生态国家重点实验室,人与环境系统可持续研究中心,北京 100875
2.北京师范大学地理科学学部自然资源学院,土地资源与区域发展研究中心,北京 100875

收稿日期:2019-11-08 修回日期:2020-05-27 出版日期:2021-04-28 发布日期:2021-06-28
通讯作者: 刘志锋（1986- ），男，江西景德镇人，博士，副教授，主要从事景观地理与景观可持续科学研究。E-mail: Zhifeng.Liu@bnu.edu.cn
作者简介:宋世雄（1990- ），男，陕西乾县人，博士研究生，主要从事城市扩展过程模拟及其影响研究。E-mail: ssx1990@126.com
基金资助:
国家自然科学基金项目(41971270,41971271)

Study on the location factors of urban expansion in the drylands: A case study in the Hohhot-Baotou-Ordos-Yulin Urban Agglomeration, China

SONG Shi-xiong¹^,²(), ZHANG Jin-xi¹^,², LIU Zhi-feng¹^,²(), HE Chun-yang¹^,²

1. Center for Human-Environment System Sustainability (CHESS), State Key Laboratory of Earth Surface Processes and Resource Ecology (ESPRE), Beijing Normal University, Beijing 100875, China
2. School of Natural Resources, Faculty of Geographical Science, Beijing Normal University, Beijing 100875, China

Received:2019-11-08 Revised:2020-05-27 Online:2021-04-28 Published:2021-06-28

摘要/Abstract

摘要：

认识城市扩展过程的区位因素特征对旱区城市可持续发展具有重要意义。为此,以中国呼包鄂榆城市群为例,利用随机森林方法量化区位因素对城市扩展过程的影响。研究发现：随机森林方法能够有效地量化旱区城市扩展过程区位因素的基本特征,模型的AUC（area under curve）值达到0.97。同时,到城市中心距离对区域1980—2017年城市扩展过程影响最大,重要性达到42.62%。国道、高速公路和铁路等交通因素也有重要的影响,重要性均大于10%。此外,所有区位因素对区域城市扩展过程的影响均存在尺度效应,其中地形、气候和河流对城市扩展过程影响的尺度效应相对比较明显。地形、气候和河流对大城市影响的重要性分别为27.17%、20.23%和8.12%,分别是其对小城市影响的4.02倍、3.91倍和2.36倍。因此,建议在旱区城市建设中,应该高度重视地形、气候和河流等自然要素的约束作用,因地制宜地进行城市规划和建设。

关键词: 随机森林, 区位因素, 城市扩展过程, 旱区, 呼包鄂榆城市群

Abstract:

Understanding the characteristics of location factors of urban expansion is important to urban sustainable development in the drylands. Taking the Hohhot-Baotou-Ordos-Yulin Urban Agglomeration in China as an example, this study assessed the impacts of location factors on urban expansion using the random forest model. The results indicated that the random forest model can effectively quantify the basic characteristics of location factors of urban expansion in the drylands, with the area under curve (AUC) index of 0.97. The distance to the urban centers had the greatest influence on urban expansion from 1980 to 2017, with the importance of 42.62%. The traffic factors such as highways, national roads, and railways also played an important role with the importance above 10%. All location factors had scaling effects on regional urban expansion, among which the topographic, the climate and the river factors had the most obvious effects. The importance of topography, climate and rivers to large cities was 27.17%, 20.23% and 8.12%, respectively, 4.02 times, 3.91 times and 2.36 times that of small cities. Thus, we suggest that the local governments should pay close attention to the constraint effects of the natural factors (e.g., topography, climate and rivers) on the urban construction in the drylands, and perform urban planning and construction according to local conditions.

Key words: random forest, location factor, urban expansion, drylands, Hohhot-Baotou-Ordos-Yulin Urban Agglomeration

宋世雄, 张金茜, 刘志锋, 何春阳. 旱区城市扩展过程区位因素研究——以中国呼包鄂榆城市群为例[J]. 自然资源学报, 2021, 36(4): 1021-1035.

SONG Shi-xiong, ZHANG Jin-xi, LIU Zhi-feng, HE Chun-yang. Study on the location factors of urban expansion in the drylands: A case study in the Hohhot-Baotou-Ordos-Yulin Urban Agglomeration, China[J]. JOURNAL OF NATURAL RESOURCES, 2021, 36(4): 1021-1035.

图/表 12

图1

图2

表1

图3

图4

图5

表2

1980—2017年区域城市扩展过程

地区	城市扩展过程			城市扩展模式
	面积/km²	占全区比例/%	年均增长率/%	边缘型		蛙跃型		内填型
	面积/km²	占全区比例/%	年均增长率/%	面积/km²	百分比/%	面积/km²	百分比/%	面积/km²	百分比/%
呼包鄂榆	1149.76	100	7.61	721.73	62.77	296.91	25.82	131.12	11.40
大城市	564.55	49.10	6.91	343.99	60.45	137.51	24.16	87.58	15.39
呼和浩特	226.12	19.67	7.39	139.60	59.00	71.35	30.15	25.67	10.85
包头	338.43	29.43	6.64	204.39	61.48	66.16	19.90	61.91	18.62
中等城市	211.80	18.42	9.18	173.36	75.13	45.21	19.59	12.18	5.28
鄂尔多斯	120.76	10.50	8.60	96.84	72.23	32.58	24.30	4.66	3.48
榆林	91.03	7.92	10.21	76.52	79.16	12.63	13.07	7.52	7.78
小城市	373.41	32.48	8.25	204.38	58.41	114.19	32.63	31.36	8.96
土默特左	37.93	3.30	10.31	10.98	37.30	16.01	54.38	2.45	8.32
托克托	15.44	1.34	11.55	10.95	70.97	3.13	20.29	1.35	8.75
和林格尔	9.63	0.84	7.22	6.04	62.59	2.80	29.02	0.81	8.39
清水河	3.85	0.34	8.40	2.50	63.94	1.06	27.11	0.35	8.95
武川	8.73	0.76	6.36	7.14	80.50	1.17	13.19	0.56	6.31
土默特右	32.21	2.80	8.06	20.63	64.09	8.38	26.03	3.18	9.88
固阳	8.58	0.75	6.44	6.35	72.41	1.78	20.30	0.64	7.30
达茂旗	7.92	0.69	7.61	0.98	12.36	6.67	84.11	0.28	3.53
达拉特	27.83	2.42	7.20	18.81	66.94	4.38	15.59	4.91	17.47
准格尔	13.86	1.21	8.60	6.00	43.01	6.80	48.75	1.15	8.24
鄂托克前	7.03	0.61	6.26	4.27	60.83	1.93	27.49	0.82	11.68
鄂托克	12.30	1.07	7.60	7.09	57.83	3.60	29.36	1.57	12.81
杭锦	9.86	0.86	4.05	7.32	72.69	1.43	14.20	1.32	13.11
乌审	11.57	1.01	6.88	6.56	56.65	4.45	38.43	0.57	4.92
伊金霍洛	35.93	3.13	10.81	11.98	49.79	11.51	47.84	0.57	2.37
靖边	30.95	2.69	12.77	21.50	69.13	7.06	22.70	2.54	8.17
定边	20.99	1.83	8.00	14.08	67.30	5.27	25.19	1.57	7.50
府谷	9.13	0.79	7.32	6.05	65.05	2.37	25.48	0.88	9.46
神木	36.18	3.15	11.83	15.83	42.85	17.79	48.16	3.32	8.99
佳县	1.26	0.11	10.17	1.12	83.58	0.15	11.19	0.07	5.22
横山	11.21	0.98	10.85	3.95	64.54	1.56	25.49	0.61	9.97
米脂	6.58	0.57	8.97	4.22	63.36	1.72	25.83	0.72	10.81
子州	3.15	0.27	6.81	2.16	69.90	0.88	28.48	0.05	1.62
绥德	6.65	0.58	8.09	4.92	74.89	0.70	10.65	0.95	14.46
吴堡	2.38	0.21	5.76	1.70	72.03	0.61	25.85	0.05	2.12
清涧	2.27	0.20	8.41	1.25	54.35	0.98	42.61	0.07	3.04

表2

图6

图7

图8

图9

图10

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类别	指标	空间化方法
自然因素	高程	基于DEM数据,利用ArcGIS的地表分析模型进行计算坡度和坡向;利用ArcGIS的距离分析模型计算到河流距离
	坡度
	坡向
	到河流距离
	干燥度	参考相关研究^[1],利用多年平均降雨量与多年平均潜在蒸散量之比计算
人文因素	到城市中心距离	利用ArcGIS的距离分析模型计算到城市中心、高速公路、铁路和国道距离
	到高速公路距离
	到铁路距离
	到国道距离

旱区城市扩展过程区位因素研究——以中国呼包鄂榆城市群为例

Study on the location factors of urban expansion in the drylands: A case study in the Hohhot-Baotou-Ordos-Yulin Urban Agglomeration, China

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