hls是xilinx的高层次综合,本例子是本人手打经过验证没问题,快速上手hls,例子有部分注释,学习理解hls不错的
2024/5/29 0:57:02
10.38MB
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毕业设计和课程设计全套资料,主程序代码clc;clearall;closeall;warningoffall;I=imread('images\\1.jpg');I1=Image_Normalize(I,0);%图像归一化hsize=[33];sigma=0.5;I2=Image_Smooth(I1,hsize,sigma,0);I3=Gray_Convert(I2,0);bw2=Image_Binary(I3,0);%二值化处理[~,~,xy_long]=Hough_Process(bw2,I1,0);%霍夫变换angle=Compute_Angle(xy_long);%计算角度[I4,bw3]=Image_Rotate(I1,bw2,angle*1.8,0);%图像旋转[bw4,Loc1]=Morph_Process(bw3,0);%形态处理[Len,XYn,xy_long]=Hough_Process(bw4,I4,0);[bw5,bw6]=Region_Segmation(XYn,bw4,I4,0);[stats1,stats2,Line]=Location_Label(bw5,bw6,I4,XYn,Loc1,1);[Dom,Aom,Answer,Bn]=Analysis(stats1,stats2,Line,I4);
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MIMOOFDMSimulator:OFDM.m:OFDMSimulator(outerfunction)create_channel.m:GeneratesaRayleighfadingfrequency-selectivechannel,parametrizedbytheantennaconfiguration,theOFDMconfiguration,andthepower-delayprofile.svd_decompose_channel.m:Sincefullchannelknowledgeisassumed,transmissionisacrossparallelsingularvaluemodes.Thisfunctiondecomposesthechannelintothesemodes.BitLoad.m:Applythebit-loadingalgorithmtoachievethedesiredbitandenergyallocationforthecurrentchannelinstance.ComputeSNR.m:Giventhesubcarriergains,thissimplefunctiongeneratestheSNRvaluesofeachchannel(eachsingularvalueoneachtoneisaseparatechannel).chow_algo.m:ApplyChow'salgorithmtogenerateaparticularbitandenergyallocation.EnergyTableInit.m:GiventheSNRvalues,formatableofenergyincrementsforeachchannel.campello_algo.m:ApplyCampello'salgorithmtoconvergetotheoptimalbitandenergyallocationforthegivenchannelconditions.ResolvetheLastBit.m:Anoptimalbit-loadingofthelastbitrequiresauniqueoptimization.modulate.m:Modulatetherandominputsequenceaccordingtothebitallocationsforeachchannel.ENC2.mat:BPSKModulatorENC4.mat:4-QAMModulator(Graycoded)ENC16.mat:16-QAMModulator(Graycoded)ENC64.mat:64-QAMModulator(Graycoded)ENC256.mat:256-QAMModulator(Graycoded)precode.m:Precodethetransmittedvectorateachtimeinstancebyfilteringthemodulatedvectorwiththeright-inverseofthechannel'srightsingluarmatrix.ifft_cp_tx_blk.m:IFFTblockoftheOFDMsystem.channel.m:ApplythechanneltotheOFDMframe.fft_cp_rx_blk.m:FFTblockoftheOFDMsystem.shape.m:Completethediagonalizationofthechannelbyfilteringthereceivedvectorwiththeleft-inverseofthechannel'sleftsingularmatrix.demodulate.m:Performanearestneighborsearchknowingthetransmitconstellationused.
2024/5/11 19:05:15
1.65MB
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不怎么实用,希望各位批评指导,相互学习clearall,closeall,TestDatabasePath=uigetdir('E:\我的大学','Selecttestdatabasepath');%自己设置地址prompt={'Entertestimagename:'};dlg_title='fingerRecognitionSystem';num_lines=1;def={'1'};TestImage=inputdlg(prompt,dlg_title,num_lines,def);TestImage=strcat(TestDatabasePath,'\',char(TestImage),'.bmp');im=imread(TestImage);ticI=imresize(im,[200200]);figure(1),subplot(131),imshow(I),title('原图');set(gcf,'position',[11600600]);level=graythresh(I);J=im2bw(I,level);figure(1),subplot(132),imshow(J),title('二值图');
2024/4/30 20:53:47
4.47MB
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作者MoodA.M.,GraybillF.A.,BoesD.C.书名Introductiontothetheoryofstatistics(3rded.,McGraw-Hill,1974)统计理论介绍第三版方便大家学习
2024/3/31 7:43:26
23.64MB
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IMDropsImageTools3.6老朽痴拙汉化版(图像小工具)是一个屏幕捕获、文件共享和图像处理工具。
它具有多线程的批处理图像大小调整、转换、裁剪、旋转翻转、水印、脱色(灰度、消极、棕褐色)、和优化。
支持BMP、GIF、TIFF、JPEG、PNG和EMF图像类型。
它能与LinuxMONO(仅GNOME和Xfce)兼容。
ImageToolsisascreencapture,filesharingandimageprocessingtool.Itfeaturesmulti-threadedbatchimageresizing,conversion,cropping,flipping/rotating,watermarks,decolorizing(grayscale,negative,sepia),andoptimizing.TheBMP,GIF,TIFF,JPEG,PNG,andEMFimagetypesaresupported.ItiscompatiblewithLinuxMONO(onlyforGNOMEandXfce).
它具有多线程的批处理图像大小调整、转换、裁剪、旋转翻转、水印、脱色(灰度、消极、棕褐色)、和优化。
支持BMP、GIF、TIFF、JPEG、PNG和EMF图像类型。
它能与LinuxMONO(仅GNOME和Xfce)兼容。
ImageToolsisascreencapture,filesharingandimageprocessingtool.Itfeaturesmulti-threadedbatchimageresizing,conversion,cropping,flipping/rotating,watermarks,decolorizing(grayscale,negative,sepia),andoptimizing.TheBMP,GIF,TIFF,JPEG,PNG,andEMFimagetypesaresupported.ItiscompatiblewithLinuxMONO(onlyforGNOMEandXfce).
2024/2/28 9:18:54
86KB
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本人花了300块钱购买的图像处理教程-带开发版。
保证是一手资料,在别处你指定找不到。
7.HDL-VIPCMOS视频图像算法处理.................................................1087.1.Bingo版HDL-VIP时序约定.......................................................1087.1.1.VIP_Image_Processor接口约定............................................1087.1.2.VIP_Image_Processor时序约定............................................1117.2.【VGA】RGB888转YCbCr444算法的HDL-VIP实现..........1127.2.1.RGB888转YCbCr介绍........................................................1127.2.2.RGB888转YCbCr的HDL实现..........................................1137.2.3.RGB888转YCbCr功能测试................................................1187.3.【VGA】YCbCr422转RGB888的HDL-VIP实现..................1217.3.1.ITU-RBT.656格式简说.......................................................1217.3.2.YUV/YCbCr视频格式简说..................................................1237.3.3.YUV422格式的配置与拼接捕获.........................................1247.3.4.YUV422转YUV444的HDL-VIP实现..............................1257.3.5.YUV444转RGB888的HDL-VIP实现...............................1287.3.6.YCbCr422转RGB888功能测试..........................................1327.4.【USB】RGB888转Gray灰度的HDL-VIP实现.....................1357.5.【USB】YCbCr422转Gray灰度HDL-VIP实现.....................1377.6.【USB】灰度图像的均值滤波算法的HDL-VIP实现..............1387.6.1.均值滤波算法介绍.................................................................1387.6.2.3*3像素阵列的HDL实现...................................................138既然选择了HDL-VIP,便不顾风雨兼程,一路走下去……7.6.3.Mean_Filter均值滤波算法的实现........................................1447.7.【USB】灰度图像的中值滤波算法的HDL-VIP实现..............1497.7.1.中值/均值滤波对比...............................................................1497.7.2.中值滤波算法的HDL实现..................................................1507.8.【USB】灰度图像的Sobel边缘检测算法的HDL-VIP实现...1577.8.1.边缘检测算法介绍.................................................................1577.8.2.Sobel边缘检测算法研究......................
保证是一手资料,在别处你指定找不到。
7.HDL-VIPCMOS视频图像算法处理.................................................1087.1.Bingo版HDL-VIP时序约定.......................................................1087.1.1.VIP_Image_Processor接口约定............................................1087.1.2.VIP_Image_Processor时序约定............................................1117.2.【VGA】RGB888转YCbCr444算法的HDL-VIP实现..........1127.2.1.RGB888转YCbCr介绍........................................................1127.2.2.RGB888转YCbCr的HDL实现..........................................1137.2.3.RGB888转YCbCr功能测试................................................1187.3.【VGA】YCbCr422转RGB888的HDL-VIP实现..................1217.3.1.ITU-RBT.656格式简说.......................................................1217.3.2.YUV/YCbCr视频格式简说..................................................1237.3.3.YUV422格式的配置与拼接捕获.........................................1247.3.4.YUV422转YUV444的HDL-VIP实现..............................1257.3.5.YUV444转RGB888的HDL-VIP实现...............................1287.3.6.YCbCr422转RGB888功能测试..........................................1327.4.【USB】RGB888转Gray灰度的HDL-VIP实现.....................1357.5.【USB】YCbCr422转Gray灰度HDL-VIP实现.....................1377.6.【USB】灰度图像的均值滤波算法的HDL-VIP实现..............1387.6.1.均值滤波算法介绍.................................................................1387.6.2.3*3像素阵列的HDL实现...................................................138既然选择了HDL-VIP,便不顾风雨兼程,一路走下去……7.6.3.Mean_Filter均值滤波算法的实现........................................1447.7.【USB】灰度图像的中值滤波算法的HDL-VIP实现..............1497.7.1.中值/均值滤波对比...............................................................1497.7.2.中值滤波算法的HDL实现..................................................1507.8.【USB】灰度图像的Sobel边缘检测算法的HDL-VIP实现...1577.8.1.边缘检测算法介绍.................................................................1577.8.2.Sobel边缘检测算法研究......................
2024/2/9 13:02:26
10.38MB
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在日常工作中,钉钉打卡成了我生活中不可或缺的一部分。然而,有时候这个看似简单的任务却给我带来了不少烦恼。
每天早晚,我总是得牢记打开钉钉应用,点击"工作台",再找到"考勤打卡"进行签到。有时候因为工作忙碌,会忘记打卡,导致考勤异常,影响当月的工作评价。而且,由于我使用的是苹果手机,有时候系统更新后,钉钉的某些功能会出现异常,使得打卡变得更加麻烦。
另外,我的家人使用的是安卓手机,他们也经常抱怨钉钉打卡的繁琐。尤其是对于那些不太熟悉手机操作的长辈来说,每次打卡都是一次挑战。他们总是担心自己会操作失误,导致打卡失败。
为了解决这些烦恼,我开始思考是否可以通过编写一个全自动化脚本来实现钉钉打卡。经过一段时间的摸索和学习,我终于成功编写出了一个适用于苹果和安卓系统的钉钉打卡脚本。
2024-04-09 15:03
15KB