系统开发的目标是建立一个车辆管理派遗管理系统，与GIS/GPS联动，前端使用RFID监测车辆信息。...

小波包分析提取振动信号中的特征频率，基于负熵最大的独立分量分析，多抽样率信号处理。( Wavelet packet analysis to extract vibration signal characteristic frequency, Based on negative entropy largest independent component analysis, Multirate signal processing.)

通用数据库访问Helper 支持Oracle、SqlServer、MySQL、Access数据库访问方便简洁 using System; using System.Collections.Generic; using System.Linq; using System.Text; using System.Data; namespace PromotionDB.Interface {     public interface IDataSource     {         bool Open();         int ExecuteNonQuery(string _ConStr);         DataTable ExecuteQuery(string _ConStr);         bool Close();     } } using System; using System.Collections.Generic; using System.Text; using PromotionDB.Interface; using MySql.Data.MySqlClient; using System.Data; namespace PromotionDB.Util.DataAccess {     ///     /// 连接MySql数据库     ///

CAN通讯协议栈，完整程序包，基于STM32系统。简明易懂，是个学习的好基础包。(CAN communication protocol stack, a complete package, based STM32 systems. Easy to understand, it is a good learning base package.)

主要是matlab基于SIFT/SURF特征匹配和图像融合的图像拼接代码，也有少量的opencv c++的例子

换热器设计计算，基于matlab设计源码(The design of heat exchanger can be input parameters to obtain results)

Socket文件传输源码，实现了 服务端向客户端 发送文件 功能功能介绍：    使用socket实现文件传输同时使用了多线程，首先服务端选择文件，开始监听启动客户端，选择连接就实现了文件的传输。注意：    不同机器连接要修改源代码的的ip地址。    开发环境为Visual Studio 2010

基于PCA的人脸识别代码，识别率可达88 (PCA-based face recognition code, the recognition rate up to 88 )

用MFC实现用表格控件对数据进行显示和修正处理(MFC with tabular data display controls and correction process)

说明：  对采集图像的处理有很好的帮助,能在一定程度上加深地VC++的学习.(Collected images have a good deal of help to a certain extent, to deepen VC++ Learning.)

rgb编码成jpeg,验证通过的 /******************************************************************************// INTEL CORPORATION PROPRIETARY INFORMATION// This software is supplied under the terms of a license agreement or// nondisclosure agreement with Intel Corporation and may not be copied// or disclosed except in accordance with the terms of that agreement.// Copyright (c) 2003 Intel Corporation. All Rights Reserved.//// Description:// Intel(R) Integrated Performance Primitives Sample Code JPEG Encoder//******************************************************************************/#include #include #include "sampjpeg.h"/******************************************************************************// Name: encoder_init_alloc_jpeg// Description: // This function does the prepare work for the JPEG encoding, including:1.// Parse BMP header; 2. Read in the BMP data; 3 Convert the BGR data into// YUV format. 4. Load the table for quantization and huffman encoding.// Input Arguments:// src - File Pointer to the source BMP file// quality_ind - Quality indicator. 1: high quality; 0: low quality// Output Arguments:// enc_state - Pointer to the encoder state structure, its content// will be initialized in this function// picture - Pointer to the source picture in YUV format. The buffer// in it will be allocated and filled with YUV data in this // function.// bitstream - Pointer to the output JPEG bitstream. Its buffers will// be allocated in this function.// Returns:// SAMPLE_STATUS_NOERR - No error// SAMPLE_STATUS_NOMEM_ERR - Memory error// SAMPLE_STATUS_NOTSUPPORTED_ERR - Not supported input// SAMPLE_STATUS_ERR - Other errors******************************************************************************/sample_status encoder_init_alloc_jpeg(FILE *src, int quality_ind, jpeg_enc_state *enc_state, sample_picture *picture, sample_bitstream *bitstream){ int data_size; int x_num, y_num; int i, j; int num_bytes; void *rgb_buffer = NULL; void *src_buf, *buf; Ipp16s *dst_buf[3]; int yuv_size; int color_mode; int data32; short *buffer; sample_status status; Ipp8u *quant_table1, *table1; Ipp8u *quant_table2, *table2; /* Read the BMP file for format information */ status = read_bmp_file(src, enc_state, &color_mode, &data_size); if(SAMPLE_STATUS_NOERR != status) { return status; } /* Malloc the buffer for RGB data */ if(JPEG_BGR888 == color_mode) { rgb_buffer = (Ipp8u *)malloc(data_size 7); num_bytes = 3; } else { rgb_buffer = (Ipp16u *)malloc(data_size 7); num_bytes = 2; } if(rgb_buffer == NULL) { return SAMPLE_STATUS_NOMEM_ERR; } src_buf = (int *)SAMPLE_ALIGN8(rgb_buffer); data32 = fread(src_buf, 1, data_size, src); if(data32 != data_size) { return SAMPLE_STATUS_ERR; } /* Malloc the buffer for Y, Cb, Cr */ yuv_size = enc_state->width * enc_state->height; yuv_size = yuv_size (yuv_size >> 1); /* // Malloc the buffer for encoder input and output. // Half of the buffer is used for YUV, another half is used for // Output bitstream; */ enc_state->in_buf = NULL; enc_state->out_buf = NULL; enc_state->in_buf = (short *)malloc(yuv_size * 2); buffer = (short *)SAMPLE_ALIGN8(enc_state->in_buf); /* Initialize the input structure */ picture->pic_plane[0] = buffer; picture->pic_width = enc_state->width; picture->pic_height = enc_state->height; picture->pic_plane_step[0] = enc_state->width; picture->pic_plane_num = 1; /* // Assign the buffer for encoder ouput bitstream // It is assumed that the output size will not be larger than // input size a lot */ enc_state->out_buf = (short *)malloc(yuv_size * 3); buffer = enc_state->out_buf; bitstream->bs_buffer = (unsigned char *)buffer; bitstream->bs_bytelen = yuv_size * 3; bitstream->bs_cur_byte = bitstream->bs_buffer; bitstream->bs_cur_bitoffset = 0; /* // Check if the picture width and height is multiple of 16, if not, // return not supported information */ if(enc_state->width & 0xf) { return SAMPLE_STATUS_NOTSUPPORTED_ERR; } if(enc_state->height & 0xf) { return SAMPLE_STATUS_NOTSUPPORTED_ERR; } /* Do the color conversion, from BGR to Y:U:V = 4:1:1 */ /* // x_num is the horizontal MCU number. // x_num = width / 16 // y_num is the vertical MCU number // y_num = height / 16; */ x_num = enc_state->width >> 4; y_num = enc_state->height >> 4; /* Jump to the last MCU line */ src_buf = (char *)src_buf (y_num * JPEG_MCU_LINE - 1) * enc_state->step; buf = src_buf; /* Prepare the Y, U, V block pointer */ dst_buf[0] = picture->pic_plane[0]; dst_buf[1] = dst_buf[0] (64 step), dst_buf); /* Move to next MCU */ src_buf = (char *)src_buf JPEG_MCU_LINE * num_bytes; dst_buf[0] = 6 * JPEG_BLOCK_SIZE; dst_buf[1] = 6 * JPEG_BLOCK_SIZE; dst_buf[2] = 6 * JPEG_BLOCK_SIZE; } else if (JPEG_BGR555 == color_mode) { ippiBGR555ToYCbCr411LS_MCU_16u16s_C3P3R((const Ipp16u *)src_buf, -(enc_state->step), dst_buf); /* Move to next MCU */ src_buf = (char *)src_buf JPEG_MCU_LINE * num_bytes; dst_buf[0] = 6 * JPEG_BLOCK_SIZE; dst_buf[1] = 6 * JPEG_BLOCK_SIZE; dst_buf[2] = 6 * JPEG_BLOCK_SIZE; } else { ippiBGR565ToYCbCr411LS_MCU_16u16s_C3P3R((const Ipp16u *)src_buf, -(enc_state->step), dst_buf); /* Move to next MCU */ src_buf = (char *)src_buf JPEG_MCU_LINE * num_bytes; dst_buf[0] = 6 * JPEG_BLOCK_SIZE; dst_buf[1] = 6 * JPEG_BLOCK_SIZE; dst_buf[2] = 6 * JPEG_BLOCK_SIZE; } } /* Move to next line of slice */ buf = (char *)buf - JPEG_MCU_LINE * enc_state->step; } enc_state->color_mode = color_mode; /* // Notes: // In above code, because the input BMP file is stored up-bottom // inverted, so the src_buf storage order is also inverted. To make // it normal, the color conversion begins from the buffer end, and // step back to the buffer beginning. After the color conversion, // the pixel in the dst_buf is in normal up-down order. // Besides, the dst_buf contains the components in order of: // Y block, Y block, Y block, Y block, U block, V block */ free(rgb_buffer); /* This buffer is no longer in use */ /* Set the quality indicator */ enc_state->quality = quality_ind; /* Load the quantization table according to the quality indication*/ /* // Because of the DCT and quantization are integrated to enhance the // performance, the raw quantization tables must be modified by the // DCT coefficients. */ /* // The quality is indicated by quality_ind, its values can be: // 1: high quality encoding; 0: low quality encoding */ quant_table1 = malloc((JPEG_BLOCK_SIZE 4) * 2); table1 = (Ipp8u *)SAMPLE_ALIGN8(quant_table1); quant_table2 = malloc((JPEG_BLOCK_SIZE 4)* 2); table2 = (Ipp8u *)SAMPLE_ALIGN8(quant_table2); if(1 == quality_ind) { for(i = 0; i < 64; i ) { table1[i] = h_lum_quant_table[i]; table2[i] = h_chrom_quant_table[i]; } } else { for(i = 0; i < 64; i ) { table1[i] = l_lum_quant_table[i]; table2[i] = l_chrom_quant_table[i]; } } ippiDCTQuantFwdTableInit_JPEG_8u16u(table1, (Ipp16u *)SAMPLE_ALIGN8(enc_state->lum_quant_table)); ippiDCTQuantFwdTableInit_JPEG_8u16u(table2, (Ipp16u *)SAMPLE_ALIGN8(enc_state->chrom_quant_table)); free(quant_table1); free(quant_table2); /* Load and init the huffman table, use the default huffman table */ ippiEncodeHuffmanSpecInit_JPEG_8u(lum_dc_huffbits, lum_dc_huffvalues, &(enc_state->lum_dc_huffmansize_table)); ippiEncodeHuffmanSpecInit_JPEG_8u(lum_ac_huffbits, lum_ac_huffvalues, &(enc_state->lum_ac_huffmansize_table)); ippiEncodeHuffmanSpecInit_JPEG_8u(chrom_dc_huffbits, chrom_dc_huffvalues, &(enc_state->chrom_dc_huffmansize_table)); ippiEncodeHuffmanSpecInit_JPEG_8u(chrom_ac_huffbits, chrom_ac_huffvalues, &(enc_state->chrom_ac_huffmansize_table)); /* // Allocate the work buffer, this work buffer will be used as temporary // buffer for DCT-quantization output and huffman encoding input */ enc_state->work_buf = NULL; enc_state->work_buf = (short *)malloc((JPEG_MCU_SIZE 7) * 2); /* Reset the DC prediction value */ for(i = 0; i < 3; i ) { enc_state->dc_pred[i] = 0; } return SAMPLE_STATUS_NOERR;}/******************************************************************************// Name: encode_jpeg// Description: // This function encodes the input YUV data into JPEG format bitstream.// Input Arguments:// src_picture - Pointer to the source picture in YUV format. // enc_state - Pointer to the encoder state structure.// Output Arguments:// dst_stream - Pointer to the output JPEG bitstream. // Returns// SAMPLE_STATUS_NOERR - No error******************************************************************************/sample_status encode_jpeg(sample_picture *src_picture, sample_bitstream *dst_stream, jpeg_enc_state *enc_state){ int i, j; int x_num; int y_num; short *tmp_buf; short *in_buf; int used_bits_len = 0; int used_byte_len; /* Write the head of JPEG */ write_head_information(dst_stream, enc_state); /* Put the SOS and the table information into the bitstream */ write_sos_information(dst_stream); /* Compute the MCU number in x and y direction */ x_num = enc_state->width >> 4; y_num = enc_state->height >> 4; tmp_buf = (Ipp16s *)SAMPLE_ALIGN8(enc_state->work_buf); in_buf = src_picture->pic_plane[0]; for(i = 0; i < y_num; i ) { for(j = 0; j < x_num; j ) { /* First, the DCT transformation will be called followed by the quantization */ /* // The DCT and quantization are performed on each Y block and Cb, // Cr block. For this program only support Y:Cb:Cr = 4:1:1 mode. // There will be 6 DCT-quantization operations for each MCU */ /* DCT-quantization for 4 Y blocks */ ippiDCTQuantFwd_JPEG_16s(in_buf, tmp_buf, (Ipp16u *)SAMPLE_ALIGN8(enc_state->lum_quant_table)); ippiDCTQuantFwd_JPEG_16s(&in_buf[64], &tmp_buf[64], (Ipp16u *)SAMPLE_ALIGN8(enc_state->lum_quant_table)); ippiDCTQuantFwd_JPEG_16s(&in_buf[128], &tmp_buf[128], (Ipp16u *)SAMPLE_ALIGN8(enc_state->lum_quant_table)); ippiDCTQuantFwd_JPEG_16s(&in_buf[192], &tmp_buf[192], (Ipp16u *)SAMPLE_ALIGN8(enc_state->lum_quant_table)); /* DCT-quantization for Cb block */ ippiDCTQuantFwd_JPEG_16s(&in_buf[256], &tmp_buf[256], (Ipp16u *)SAMPLE_ALIGN8(enc_state->chrom_quant_table)); /* DCT-quantization for Cr block */ ippiDCTQuantFwd_JPEG_16s(&in_buf[320], &tmp_buf[320], (Ipp16u *)SAMPLE_ALIGN8(enc_state->chrom_quant_table)); in_buf = JPEG_MCU_SIZE; /* Now huffman encode the quantized coefficient */ /* First encode the 4 luminance(Y) blocks */ ippiEncodeHuffman8x8_Direct_JPEG_16s1u_C1 (tmp_buf, dst_stream->bs_cur_byte, &used_bits_len, &(enc_state->dc_pred[0]), &(enc_state->lum_dc_huffmansize_table), &(enc_state->lum_ac_huffmansize_table)); ippiEncodeHuffman8x8_Direct_JPEG_16s1u_C1 (&tmp_buf[64], dst_stream->bs_cur_byte, &used_bits_len, &(enc_state->dc_pred[0]), &(enc_state->lum_dc_huffmansize_table), &(enc_state->lum_ac_huffmansize_table)); ippiEncodeHuffman8x8_Direct_JPEG_16s1u_C1 (&tmp_buf[128], dst_stream->bs_cur_byte, &used_bits_len, &(enc_state->dc_pred[0]), &(enc_state->lum_dc_huffmansize_table), &(enc_state->lum_ac_huffmansize_table)); ippiEncodeHuffman8x8_Direct_JPEG_16s1u_C1 (&tmp_buf[192], dst_stream->bs_cur_byte, &used_bits_len, &(enc_state->dc_pred[0]), &(enc_state->lum_dc_huffmansize_table), &(enc_state->lum_ac_huffmansize_table)); /* Huffman encode the chrominance(Cb) block */ ippiEncodeHuffman8x8_Direct_JPEG_16s1u_C1 (&tmp_buf[256], dst_stream->bs_cur_byte, &used_bits_len, &(enc_state->dc_pred[1]), &(enc_state->chrom_dc_huffmansize_table), &(enc_state->chrom_ac_huffmansize_table)); /* Huffman encode the chrominance(Cr) block */ ippiEncodeHuffman8x8_Direct_JPEG_16s1u_C1 (&tmp_buf[320], dst_stream->bs_cur_byte, &used_bits_len, &(enc_state->dc_pred[2]), &(enc_state->chrom_dc_huffmansize_table), &(enc_state->chrom_ac_huffmansize_table)); } } /* Put EOI mark to the end of stream */ used_byte_len = used_bits_len >> 3; /* // Check if the last byte is completely filled, if not, stuff it and move // to the next byte for writing */ if(used_bits_len & 0x7) { used_byte_len = 1; } dst_stream->bs_cur_byte = used_byte_len; *dst_stream->bs_cur_byte = 0xff; /* Write the high part of EOI */ *dst_stream->bs_cur_byte = JPEG_MARKER_EOI; return SAMPLE_STATUS_NOERR;}/******************************************************************************// Name: encoder_free_jpeg// Description: // This function free the buffer malloced in the initialization function// Input arguments:// enc_state - Pointer to the JPEG encoder structure// Returns:// SAMPLE_STATUS_NOERR - No error******************************************************************************/sample_status encoder_free_jpeg(jpeg_enc_state *enc_state){ if(NULL != enc_state->in_buf) { free(enc_state->in_buf); } enc_state->in_buf = NULL; if(NULL != enc_state->out_buf) { free(enc_state->out_buf); } enc_state->out_buf = NULL; if(NULL != enc_state->work_buf) { free(enc_state->work_buf); } enc_state->work_buf = NULL; return SAMPLE_STATUS_NOERR;}/* EOF */