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这篇文章主要介绍了怎么利用Python裁切tiff图像且读取tiff,shp文件,具有一定借鉴价值,感兴趣的朋友可以参考下,希望大家阅读完这篇文章之后大有收获,下面让小编带着大家一起了解一下。
1、简单易用,与C/C++、Java、C# 等传统语言相比,Python对代码格式的要求没有那么严格;2、Python属于开源的,所有人都可以看到源代码,并且可以被移植在许多平台上使用;3、Python面向对象,能够支持面向过程编程,也支持面向对象编程;4、Python是一种解释性语言,Python写的程序不需要编译成二进制代码,可以直接从源代码运行程序;5、Python功能强大,拥有的模块众多,基本能够实现所有的常见功能。
具体代码如下
from osgeo import gdal, gdalnumeric, ogr from PIL import Image, ImageDraw from osgeo import gdal_array import os import operator from functools import reduce gdal.UseExceptions() def readTif(fileName): dataset = gdal.Open(fileName) if dataset == None: print(fileName+"文件无法打开") return im_width = dataset.RasterXSize #栅格矩阵的列数 im_height = dataset.RasterYSize #栅格矩阵的行数 im_bands = dataset.RasterCount #波段数 band1=dataset.GetRasterBand(1) print(band1) print ('Band Type=',gdal.GetDataTypeName(band1.DataType)) im_data = dataset.ReadAsArray(0,0,im_width,im_height)#获取数据 im_geotrans = dataset.GetGeoTransform()#获取仿射矩阵信息 im_proj = dataset.GetProjection()#获取投影信息 im_blueBand = im_data[0,0:im_height,0:im_width]#获取蓝波段 im_greenBand = im_data[1,0:im_height,0:im_width]#获取绿波段 im_redBand = im_data[2,0:im_height,0:im_width]#获取红波段 im_nirBand = im_data[3,0:im_height,0:im_width]#获取近红外波段 return(im_width,im_height,im_bands,im_data,im_geotrans ,im_proj,im_blueBand,im_greenBand,im_redBand,im_nirBand) #保存tif文件函数 import gdal import numpy as np def writeTiff(im_data,im_width,im_height,im_bands,im_geotrans,im_proj,path): if 'int8' in im_data.dtype.name: datatype = gdal.GDT_Byte elif 'int16' in im_data.dtype.name: datatype = gdal.GDT_UInt16 else: datatype = gdal.GDT_Float32 if len(im_data.shape) == 3: im_bands, im_height, im_width = im_data.shape elif len(im_data.shape) == 2: im_data = np.array([im_data]) else: im_bands, (im_height, im_width) = 1,im_data.shape #创建文件 driver = gdal.GetDriverByName("GTiff") dataset = driver.Create(path, im_width, im_height, im_bands, datatype) if(dataset!= None): dataset.SetGeoTransform(im_geotrans) #写入仿射变换参数 dataset.SetProjection(im_proj) #写入投影 for i in range(im_bands): dataset.GetRasterBand(i+1).WriteArray(im_data[i]) del dataset # This function will convert the rasterized clipper shapefile # to a mask for use within GDAL. def imageToArray(i): """ Converts a Python Imaging Library array to a gdalnumeric image. """ a=gdalnumeric.fromstring(i.tobytes(),'b') a.shape=i.im.size[1], i.im.size[0] return a def arrayToImage(a): """ Converts a gdalnumeric array to a Python Imaging Library Image. """ i=Image.frombytes('L',(a.shape[1],a.shape[0]), (a.astype('b')).tobytes()) return i def world2Pixel(geoMatrix, x, y): """ Uses a gdal geomatrix (gdal.GetGeoTransform()) to calculate the pixel location of a geospatial coordinate """ ulX = geoMatrix[0] ulY = geoMatrix[3] xDist = geoMatrix[1] pixel = int((x - ulX) / xDist) line = int((ulY - y) / xDist) return (pixel, line) # # EDIT: this is basically an overloaded # version of the gdal_array.OpenArray passing in xoff, yoff explicitly # so we can pass these params off to CopyDatasetInfo # def OpenArray( array, prototype_ds = None, xoff=0, yoff=0 ): ds =gdal_array.OpenArray(array) if ds is not None and prototype_ds is not None: if type(prototype_ds).__name__ == 'str': prototype_ds = gdal.Open( prototype_ds ) if prototype_ds is not None: gdalnumeric.CopyDatasetInfo( prototype_ds, ds, xoff=xoff, yoff=yoff ) return ds def histogram(a, bins=range(0,256)): """ Histogram function for multi-dimensional array. a = array bins = range of numbers to match """ fa = a.flat n = gdalnumeric.searchsorted(gdalnumeric.sort(fa), bins) n = gdalnumeric.concatenate([n, [len(fa)]]) hist = n[1:]-n[:-1] return hist def stretch(a): """ Performs a histogram stretch on a gdalnumeric array image. """ hist = histogram(a) im = arrayToImage(a) lut = [] for b in range(0, len(hist), 256): # step size step = reduce(operator.add, hist[b:b+256]) / 255 # create equalization lookup table n = 0 for i in range(256): lut.append(n / step) n = n + hist[i+b] im = im.point(lut) return imageToArray(im) def main( shapefile_path, raster_path ): # Load the source data as a gdalnumeric array srcArray = gdalnumeric.LoadFile(raster_path) # Also load as a gdal image to get geotransform # (world file) info srcImage = gdal.Open(raster_path) geoTrans = srcImage.GetGeoTransform() # Create an OGR layer from a boundary shapefile shapef = ogr.Open(shapefile_path) lyr = shapef.GetLayer( os.path.split( os.path.splitext( shapefile_path )[0] )[1] ) poly = lyr.GetNextFeature() # Convert the layer extent to image pixel coordinates minX, maxX, minY, maxY = lyr.GetExtent() ulX, ulY = world2Pixel(geoTrans, minX, maxY) lrX, lrY = world2Pixel(geoTrans, maxX, minY) # Calculate the pixel size of the new image pxWidth = int(lrX - ulX) pxHeight = int(lrY - ulY) clip = srcArray[:, ulY:lrY, ulX:lrX] # # EDIT: create pixel offset to pass to new image Projection info # xoffset = ulX yoffset = ulY print ("Xoffset, Yoffset = ( %f, %f )" % ( xoffset, yoffset )) # Create a new geomatrix for the image geoTrans = list(geoTrans) geoTrans[0] = minX geoTrans[3] = maxY # Map points to pixels for drawing the # boundary on a blank 8-bit, # black and white, mask image. points = [] pixels = [] geom = poly.GetGeometryRef() pts = geom.GetGeometryRef(0) for p in range(pts.GetPointCount()): points.append((pts.GetX(p), pts.GetY(p))) for p in points: pixels.append(world2Pixel(geoTrans, p[0], p[1])) rasterPoly = Image.new("L", (pxWidth, pxHeight), 1) rasterize = ImageDraw.Draw(rasterPoly) rasterize.polygon(pixels, 0) mask = imageToArray(rasterPoly) # Clip the image using the mask clip = gdalnumeric.choose(mask, \ (clip, 0)).astype(gdalnumeric.uint8) # This image has 3 bands so we stretch each one to make them # visually brighter for i in range(4): clip[i,:,:] = stretch(clip[i,:,:]) # Save new tiff # # EDIT: instead of SaveArray, let's break all the # SaveArray steps out more explicity so # we can overwrite the offset of the destination # raster # ### the old way using SaveArray # # gdalnumeric.SaveArray(clip, "OUTPUT.tif", format="GTiff", prototype=raster_path) # ### # gtiffDriver = gdal.GetDriverByName( 'GTiff' ) if gtiffDriver is None: raise ValueError("Can't find GeoTiff Driver") gtiffDriver.CreateCopy( "beijing1.tif", OpenArray( clip, prototype_ds=raster_path, xoff=xoffset, yoff=yoffset ) ) print(raster_path) # Save as an 8-bit jpeg for an easy, quick preview clip = clip.astype(gdalnumeric.uint8) gdalnumeric.SaveArray(clip, "beijing1.jpg", format="JPEG") gdal.ErrorReset() if __name__ == '__main__': #shapefile_path, raster_path shapefile_path = r'C:\Users\Administrator\Desktop\裁切shp\New_Shapefile.shp' raster_path = r'C:\Users\Administrator\Desktop\2230542.tiff' main( shapefile_path, raster_path )
补充知识:python代码裁剪tiff影像图和转换成png格式+裁剪Png图片
先来看一下需要转换的tiff原始图的信息,如下图所示。
tiff转换成png和裁剪tiff的代码(opencv)
import cv2 as cv import os """ 转换tiff格式为png + 横向裁剪tiff遥感影像图 """ def Convert_To_Png_AndCut(dir): files = os.listdir(dir) ResultPath2 = "./RS_ToPngDir/" # 定义转换格式后的保存路径 ResultPath3 = "./RS_Cut_Result/" # 定义裁剪后的保存路径 ResultPath4 = "./RS_Cut_Result/" # 定义裁剪后的保存路径 for file in files: # 这里可以去掉for循环 a, b = os.path.splitext(file) # 拆分影像图的文件名称 this_dir = os.path.join(dir + file) # 构建保存 路径+文件名 img = cv.imread(this_dir, 1) # 读取tif影像 # 第二个参数是通道数和位深的参数, # IMREAD_UNCHANGED = -1 # 不进行转化,比如保存为了16位的图片,读取出来仍然为16位。 # IMREAD_GRAYSCALE = 0 # 进行转化为灰度图,比如保存为了16位的图片,读取出来为8位,类型为CV_8UC1。 # IMREAD_COLOR = 1 # 进行转化为RGB三通道图像,图像深度转为8位 # IMREAD_ANYDEPTH = 2 # 保持图像深度不变,进行转化为灰度图。 # IMREAD_ANYCOLOR = 4 # 若图像通道数小于等于3,则保持原通道数不变;若通道数大于3则只取取前三个通道。图像深度转为8位 cv.imwrite(ResultPath2 + a + "_" + ".png", img) # 保存为png格式 # 下面开始裁剪-不需要裁剪tiff格式的可以直接注释掉 hight = img.shape[0] #opencv写法,获取宽和高 width = img.shape[1] #定义裁剪尺寸 w = 480 # 宽度 h = 360 # 高度 _id = 1 # 裁剪结果保存文件名:0 - N 升序方式 i = 0 while (i + h <= hight): # 控制高度,图像多余固定尺寸总和部分不要了 j = 0 while (j + w <= width): # 控制宽度,图像多余固定尺寸总和部分不要了 cropped = img[i:i + h, j:j + w] # 裁剪坐标为[y0:y1, x0:x1] cv.imwrite(ResultPath3 + a + "_" + str(_id) + b, cropped) _id += 1 j += w i = i + h """ 横向裁剪PNG图 """ def toCutPng(dir): files = os.listdir(dir) ResultPath = "./RS_CutPng_Result/" # 定义裁剪后的保存路径 for file in files: a, b = os.path.splitext(file) # 拆分影像图的文件名称 this_dir = os.path.join(dir + file) img = Image.open(this_dir) # 按顺序打开某图片 width, hight = img.size w = 480 # 宽度 h = 360 # 高度 _id = 1 # 裁剪结果保存文件名:0 - N 升序方式 y = 0 while (y + h <= hight): # 控制高度,图像多余固定尺寸总和部分不要了 x = 0 while (x + w <= width): # 控制宽度,图像多余固定尺寸总和部分不要了 new_img = img.crop((x, y, x + w, y + h)) new_img.save(ResultPath + a + "_" + str(_id) + b) _id += 1 x += w y = y + h if __name__ == '__main__': _path = r"./RS_TiffDir/" # 遥感tiff影像所在路径 # 裁剪影像图 Convert_To_Png_AndCut(_path)
将转换成png后的图加载到软件中(专业软件ENVI5.3)查看结果详细信息如下图所示,成功的转换成png格式了。
下面是加载裁剪后的影像图(Tiff格式的)
def toCutPng(dir):函数效果图如下图所示。
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