数据来源于王法辉教授的GIS和数量方法,以后有空,我会利用python来实现里面的案例,这里向王法辉教授致敬。
import numpy as np import pandas as pd import geopandas as gpd import matplotlib.pyplot as plt import arcpy from arcpy import env plt.style.use('ggplot')#使用ggplot样式 %matplotlib inline#输出在线图片
plt.rcParams['font.family'] = ['sans-serif'] plt.rcParams['font.sans-serif'] = ['SimHei']# 替换sans-serif字体为黑体 plt.rcParams['axes.unicode_minus'] = False # 解决坐标轴负数的负号显示问题
regions = gpd.GeoDataFrame.from_file('../Census.gdb',layer='County') regions
BRTrt = regions[regions.NAMELSAD10=='East Baton Rouge Parish']
BRTrt = BRTrt.to_crs('EPSG:26915') BRTrt.crs
BRTrt.to_file('BRTrt.shp')
Tract = gpd.GeoDataFrame.from_file('../Census.gdb',layer='Tract') Tract = Tract.to_crs('EPSG:26915')
TractUtm = gpd.GeoDataFrame.from_file('TractUtm.shp') BRTrtUtm = gpd.GeoDataFrame.from_file('BRTrt.shp')
# Set workspace env.workspace = r"MyProject" # Set local variables in_features = "TractUtm.shp" clip_features = "BRTrt.shp" out_feature_class = "BRTrtUtm.shp" xy_tolerance = "" # Execute Clip arcpy.Clip_analysis(in_features, clip_features, out_feature_class, xy_tolerance)
BRTrtUtm = gpd.GeoDataFrame.from_file('BRTrtUtm.shp') BRTrtUtm['area'] = BRTrtUtm.area/1000000
## 计算人口密度 BRTrtUtm['PopuDen'] = BRTrtUtm['DP0010001']/BRTrtUtm['area'] BRTrtUtm.to_file('BRTrtUtm.shp')
BRTrtUtm['PopuDen'].describe()
fig = plt.figure(figsize=(12,12)) #设置画布大小 ax = plt.gca() ax.set_title("巴吞鲁日市2010年人口密度模式",fontsize=24,loc='center') BRTrtUtm.plot(ax=ax,column='PopuDen',linewidth=0.5,cmap='Reds' ,edgecolor='k',legend=True,) # plt.savefig('巴吞鲁日市2010年人口密度模式.jpg',dpi=300) plt.show()
## 两种方法生成多重缓冲区的阈值 dis = list(np.arange(2000,26001,2000)) dis dis = list(range(2000,26001,2000)) dis
## 真的特别神奇distances只有这样写列表才可以运行 # Set local variables inFeatures = "BRCenter" outFeatureClass = "rings.shp" distances = [2000, 4000, 6000, 8000, 10000, 12000, 14000, 16000, 18000, 20000, 22000, 24000, 26000] bufferUnit = "meters" # Execute MultipleRingBuffer arcpy.MultipleRingBuffer_analysis(inFeatures, outFeatureClass, distances, bufferUnit, "", "ALL")
try: # Set the workspace (to avoid having to type in the full path to the data every time) arcpy.env.workspace = "MyProject" # Process: Find all stream crossings (points) inFeatures = ["rings", "BRTrtUtm"] intersectOutput = "TrtRings.shp" arcpy.Intersect_analysis(inFeatures, intersectOutput,) except Exception as err: print(err.args[0])
TrtRings = gpd.GeoDataFrame.from_file('TrtRings.shp') TrtRings['area'] = TrtRings.area/1000000
TrtRings['EstPopu'] = TrtRings['PopuDen'] * TrtRings['POLY_AREA']
arcpy.env.workspace = "C:/data/Portland.gdb/Taxlots" # Set local variables inFeatures = "TrtRings" outFeatureClass = "DissRings.shp" dissolveFields = ["distance"] statistics_fields = [["POLY_AREA","SUM"], ["PopuDen","SUM"]] # Execute Dissolve using LANDUSE and TAXCODE as Dissolve Fields arcpy.Dissolve_management(inFeatures, outFeatureClass, dissolveFields, statistics_fields,)
DissRings = gpd.GeoDataFrame.from_file('DissRings.shp') DissRings
DissRings['PopuDen'] = DissRings['SUM_PopuDe'] / DissRings['SUM_POLY_A'] DissRings.set_index('distance',inplace=True)
DissRings['PopuDen'].plot(kind='bar',x='distance', xlabel='',figsize=(8,6)) plt.savefig('同心环人口密度图.jpg',dpi=300) plt.show()
# Set environment settings env.workspace = "BR.gdb" # Set local variables inFeatures = "BRBlkUtm" outFeatureClass = "BRBlkPt.shp" # Use FeatureToPoint function to find a point inside each park arcpy.FeatureToPoint_management(inFeatures, outFeatureClass, "INSIDE")
env.workspace = "MyProject" # Set local parameters inFeatures = "BRBlkPt" idFeatures = "DissRings" outFeatures = "BRBlkPt_Identity.shp" # Process: Use the Identity function arcpy.Identity_analysis(inFeatures, idFeatures, outFeatures)
BRBlkPt_Identity = gpd.GeoDataFrame.from_file('BRBlkPt_Identity.shp') BRBlkPt_Identity.shape
BRBlkPt_Identity.tail()
## 选取数据 BRBlkPt_Identity = BRBlkPt_Identity[~(BRBlkPt_Identity['distance']==0.0)]
rigs_data = pd.DataFrame(BRBlkPt_Identity.groupby(by=['distance'])['POP10'].sum(),columns=['POP10']) rigs_data.reset_index(inplace=True) rigs_data
EstPopu = BRBlkPt_Identity[['distance','SUM_POLY_A','SUM_PopuDe']] PopuDen = pd.merge(rigs_data,EstPopu,how='inner',left_on='distance',right_on='distance') ## 删除重复值,按理来说,应该没有重复值了,可以试试外连接 PopuDen.drop_duplicates(inplace = True)
PopuDen.set_index('distance',inplace=True) PopuDen['EstPopu'] = PopuDen['SUM_PopuDe'] / PopuDen['SUM_POLY_A'] PopuDen['PopuDen1'] = PopuDen['POP10'] / PopuDen['SUM_POLY_A']
PopuDen['EstPopu'].plot(figsize=(10,6),marker='o',xlabel='距离(米)',ylabel='密度(人/平方千米)') PopuDen['PopuDen1'].plot(marker='s',xlabel='距离(米)',ylabel='密度(人/平方千米)') plt.legend(['基于街道','基于普查区']) plt.savefig('基于普查区和街区数据的人口密度模式对比.jpg',dpi=300) plt.show()
2022年的第一次写笔记,写的不是很好,而且发现许多问题,比如就是geopandas里面的area和arcpy里面的area不一样,可能是算法不一样,面积要使用投影坐标系,我相信这个应该没有人不知道了吧,要对ArcGIS Pro里面的arcpy大赞。最近感谢也比较多,比如疫情,已经有点常态化,很影响我们的生活了。心怀感恩,希望我们都有美好的未来。春燕归,巢于林木。接下来一段时间,我要忙我的毕业论文,可能会比较忙,需要数据的可以联系我。