课程描述>教学大纲

生物医学信号处理》教学大纲(双语)

Syllabus of Biomedical Signal Processing (Bilingual course)

      课程编号:17078000    学分:4    参考学时:58     实验学时:12     

              Course No.: 17078000  credit 4   credit hours58   experiment hours12

       上机学时:             适用专业:生物医学工程系 各专业   

             Computer time:          Suitable Specialty: Biomedical Engineering   

      大纲执笔人:刘忠国      课程负责人:刘忠国 

             Written by: Zhongguo Liu     person in charge of course: Zhongguo Liu

一.课程目的和任务Objectives and tasks of the course

本课程是生物医学工程专业本科生必选的专业基础课。本课程旨在让学生掌握生物医学信号处理的基本原理、算法和设计应用技术。主要培养学生对获取的各种原始生物医学信息如何进行有效的信号加工处理的技能,为医疗、生命科学领域服务。本课程使学生牢固掌握离散时间信号和系统分析的基本原理和基本分析方法。深入理解离散傅里叶变换的基本原理,学会应用离散傅里叶变换快速算法解决信号分析问题的方法。掌握数字滤波器的设计原理和实现方法。学会生物医学信号分析的基本方法。本课程的目的是为学生进一步学习有关生物医学信号工程方面的课程打下良好的理论基础。

This course is one specialized core course among the compulsory courses of Specialty of Biomedical Engineering. The task of the course is to teach the students the knowledge of fundamental principle and analysis methods of biomedical signal processing. Through the course the students can learn the knowledge of fundamental principle and analysis methods of Discrete-Time Signals and Systems, principle of Fourier Transform, methods of solving problems of signal analysis through Fast Fourier Transform, Filter Design Techniques, and basic methods of analyzing biomedical signals. The objective of this course is to make the students be familiar with the fundamental theory of signal processing and be prepared for further study of other courses.

二.课程的基本要求 Basic requirements of the course

本课程的理论教学应使学生学会数字信号处理的理论、相应的算法及这些算法的软件实现。内容离散时间信号与离散时间系统的基本概念、及离散时间系统分析、Z变换、离散时间信号的傅立叶变换及DFT、傅立叶变换的快速算法、离散时间系统的相位、结构与状态变量描述、数字滤波器(IIRFIR及特殊形式的滤波器)设计。通过实验培养学生总体上了解和掌握利用计算机编程实现教科书中学过的数字信号常用的处理方法和技能,要求学生理解实验原理及实验方案等。

In theory teaching, the students can learn the theory, algorithms and the implementation of algorithms of digital signal processing from this course. The contents include the following: concepts of Discrete-Time Signals and Systems, Transform Analysis of Linear Time-Invariant Systems, The z-Transform, Structures for Discrete-Time SystemsFilter (IIRFIR) Design TechniquesThe Discrete Fourier Transform, Fast Computation of the Discrete Fourier Transform and Fourier Analysis of Biomedical Signals Using the Discrete Fourier Transform. In experiment teaching, the students can learn the programming techniques and methods to implement the basic signal processing algorithms.

该课程的前续课程为:《信号与系统》。后续课程为《DSP原理与应用》等。通过前续课程《信号与系统》的学习,让学生对信号与系统的基本概念有深刻理解,对信号变换与处理的基本方法有初步了解。从而在学习本课程时,具有基本的信号理论基础。在本课程中,将使学生对数字信号理论有深入的了解,并通过学习使学生掌握数字信号基本概念,数字信号处理的常用方法。从而为后续的DSP器件设计奠定良好的理论基础。

The course of signal and systems should be learned before this course and after this course follows the course of DSP theory and application. Since the students have learned the basic concepts and principle of signal and systems from the course of signal and systems, students can understand the theory and methods of biomedical signal processing easily, and can be prepared for further study of DSP device.

三.教学内容 contents of course

1章 生物医学信号处理绪论Biomedical signal processing introduction    2学时
2章 离散时间信号与系统Discrete-Time Signals and Systems           6学时
 2.1 离散时间信号:序列Discrete-time Signals: Sequences
 2.2 离散时间系统Discrete-time Systems

 2.3 线性时不变系统Linear Time-Invariant Systems
 2.4 线性时不变系统的性质Properties of Linear Time-Invariant Systems
 2.5 线性常系数差分方程Linear Constant-Coefficient Difference Equations.  

2.6离散时间信号与系统的频域表示Frequency-Domain Representation of  Discrete-Time Signals and Systems

2.7 用傅里叶变换表示序列Representation of Sequence by Fourier Transforms
 2.8 傅里叶变换的对称性质Symmetry Properties of the Fourier Transform
 2.9 傅里叶变换定理Fourier Transform Theorems

3章 Z变换The z-Transform                                    4学时
 3.1 Z变换The z-Transform
 3.2 Z变换收敛域的性质Properties of the Region of Convergence for the z-Transform
 3.3 Z反变换The Inverse z-Transform
 3.4 Z变换的性质z-Transform Properties  

4章 线性时不变系统的变换分析Transform Analysis of Linear Time-Invariant Systems 8学时

 4.1 LTI系统的频率响应The Frequency Response of LTI Systems

 4.2 用线性常系数差分方程表征系统的系统函数System Functions for Systems Characterized by Linear Constant-Coefficient Difference Equations

 4.3 有理系统函数的频率响应Frequency Response for Rational System Functions.

 4.4 幅度和相位之间的关系Relationship Between Magnitude and Phase
 4.5 全通系统All-Pass Systems

4.6 最小相位系统Minimum-Phase Systems

4.7 广义线性相位的线性系统Linear Systems with Generalized Linear Phase
5章 离散时间系统结构Structures for Discrete-Time Systems          10学时

5.1 线性常系数差分方程的方框图表示Block Diagram Representation of Linear Constant-Coefficient Difference Equations

5.2  线性常系数差分方程的信号流图表示Signal Flow Graph Representation of Linear Constant-Coefficient Difference Equations

5.3 IIR系统的基本结构Basic Structures for IIR Systems

5.4 转置形式Transposed Forms

5.5  FIR系统的基本网络结构Basic Network Structures for FIR Systems

6章 滤波器设计方法Filter Design Techniques                    8学时

6.1 由连续时间滤波器设计离散时间IIR滤波器Design of Discrete-Time IIR Filters from Continuous-Time Filters

6.2  用窗函数法设计FIR滤波器Design of FIR Filters by Windowing

6.3 Kaiser窗法设计FIR滤波器举例Examples of FIR Filter Design by the Kaiser Window Method

6.4 FIR滤波器的最佳逼近Optimum Approximations of FIR Filters

6.5 FIR等波纹逼近举例Examples of FIR Equiripple Approximation

7章 离散傅里叶变换The Discrete Fourier Transform              10学时

7.1 周期序列的表示:离散傅里叶级数Representation of Periodic Sequences: the Discrete Fourier Series

7.2  离散傅里叶级数的性质Properties of the DFS Representation of Periodic Sequences

7.3 周期信号的傅里叶变换The Fourier Transform of Periodic Signals

7.4 对傅里叶变换来样Sampling the Fourier Transform

7.5 有限长序列的傅里叶表示:离散傅里叶变换Fourier Representation of Finite-Duration Sequences: The Discrete-Fourier Transform

7.6 离散傅里叶变换的性质Properties of the Discrete Fourier Transform

7.7 用离散傅里叶变换实现线性卷积Linear Convolution Using the Discrete Fourier Transform

8章 离散傅里叶变换的计算Computation of the Discrete Fourier Transform   4学时

8.1 离散傅里叶变换的高效计算Efficient Computation of the Discrete Fourier Transform

8.2  按时间抽取的FFT算法Decimation-in-Time FFT Algorithms

8.3 按频率抽取的FFT算法Decimation-in-Frequency FFT Algorithms

9信号处理在生物医学中的应用Application of DSP in BME           4学时

主要讲述以MATLAB函数进行信号处理编程的例程,通过脑电、心电等生物医学信号的MATLAB编程处理实例阐述信号处理在生物医学中的应用方法

In this chapter programming of signal processing algorithms using MATLAB software is discussed especially the programming of biomedical signal such as EEG and ECG.

四、实验内容 Experiment contents

实验1:离散时间信号与系统的分析Discrete-Time Signals and Systems analysis

实验2:线性时不变系统的Z变换分析Z-transform analysis of LTI system

实验3:应用FFT对信号进行频谱分析Spectrum analysis of signal using FFT

实验4IIR滤波器的设计与信号滤波Design of IIR Filters

实验5:用窗函数法设计FIR数字滤波器Design of FIR Filters by Windowing

实验6:心电、脑电生理信号处理Processing of physiological signals of EEG and ECG

五、学时分配Credit hours schedule

   chapter         1     2    3    4      5      6    7     8    9

   学时Credit hours  2     6    6     8     10     8    10    4    4

六、实验学时分配Experiment credit hours schedule

   每个实验均为2学时Every experiment needs 2 credit hours.

七.推荐教材及主要参考书 Textbook and reference book

教材textbookDiscrete-time Signal Processing(Second Edition)Alan.V.Oppenheim, Prentice-Hall Signal Processing Series, 清华大学出版社影印,2005.

参考文献reference book

[1] D.C.Reddy. Biomedical Signal Processing: Principles and Techniques. TaTa McGraw – Hill Publishing Company Limited, 2005

[2] Eugene N. Bruce, Biomedical Signal Processing and Signal Modeling, John Wiley & Sons,2000

[3] Najarian Kayvan. Biomedical signal and image processing. Boca Raton :CRC/Taylor & Francis,2006.

[4] 胡光书. 数字信号处理导论(第二版. 清华大学出版社, 2005

[5] 杨福生, 高上凯生物医学信号处理. 高等教育出版社,1989

[6] 薛年喜.MATLAB在数字信号处理中的应用. 清华大学出版社, 2003

[7] 奥本海姆A.V., 谢弗R.W.(美), 刘树棠. 离散时间信号处理(2). 西安交通大学出版, 2001

八.考试方式Evaluating system

1.课程考核办法:期末考试(笔试)+平时成绩。

Examination MethodTerminal Exam plus Class Attendance plus Homework

2. 总评成绩构成:平时考核占 20%,期末考试成绩占 80%

Grading : Class Attendance and Homework : 20%; Terminal Exam: 80%