体外反搏装置控制系统的研制
摘要
体外反搏系统是一种无创伤的体外辅助循环装置,在增加心、脑等器官的血液供应,促进缺血组织器官侧支循环的建立等方面具有显著的临床疗效。体外反搏可以无创地提供与主动脉内气囊反搏相似的功能:提高舒张压和冠脉血流。其原理是通过检测心电信号和监控动脉血压波形,对包裹在患者的小腿、大腿和臀部的密闭气囊进行无创性序贯加压。整个过程的血液动力学可以提高舒张压和冠脉的血流灌注,降低收缩期心脏的负荷和心肌耗氧量。
本文设计的控制系统采用先进的PC机和16位单片机80C196Kc并行中断通讯控制技术组成的智能检测与控制系统。在算法上使用新的体外反搏充排气时序控制算法,使病人反搏时在舒张期出现的反搏波恰好发生在主动脉瓣关闭之际,从而使反搏血流以最充分的时间向缺血器官进行灌注,而又不加重心脏的负荷。在心脏进入收缩期能使收缩压降至最低,最大限度地降低心脏射血期负荷,从而达到最大的反搏效应。
为了精确实现算法,本文采用三阈值法完成对心电信号的QRS波进行识别,结合指脉脉搏波判定充排气时机。同时在系统中充分考虑系统的安全性,增强出错预警处理能力,保障病人在非正常情况下的安全。
最后为了保证本文设计的体外反搏控制系统可以适应于各种治疗环境,不干扰附件其他设备,亦不受别的设备干扰,在系统的设计上采取了多种抗干扰措施,保证设备的电磁兼容性。
External counterpulsation (EGP) is a noninvasive assisted circulation device. It plays a positive and curative role in increasing the blood supply for the heart and brain; promoting collateral circulation of the ischemic tissue and organs; This noninvasive technique provides augmentation of diastolic blood flow and coronary blood flow similar to the intraortic balloon pump, utilizing the serial inflation of three sets of cuffs which wrap around the calves, thighs and buttocks. Inflation and deflation is timed to the patient' s Electrocardiograph (ECG) and the arterial pressure waveform is monitored noninvasively. The overall hemodynamic effect is to provide diastolic augmentation and thus increase coronary perfusion pressure, to unload systolic cardiac workload and therefore decrease myocardial oxygen demand.
An intelligent test and control system, which consists of advanced computer and 16-bit microcontroller, is developed for controlling counterpulsation and monitoring the system and patient. A new algorithm about the inflation and deflation timing is adopted in this system, which makes the diastolic augmentation emerge as soon as the aortic valve closed. In this case, the blood has enough time to pour into the organs that are short of blood, by doing so, a best effect of the ECP will be achieved.
In this paper, "three thresholds" method is adopted to distinguish the R wave from the characteristic of ECG signal. Integrated with the finger pulse wave, the system can extract the start point of the inflation and deflation timing. Ensure the patients' safety, the "error early warning" function is designed in this system.
The electromagnetic compatibility (EMC) was an ability for electronic
equipment to work well under the anticipant electromagnetic environment, it is an important technical performance for electronic equipment especially the medical devices. So some kinds of analogue and digital circuitries were designed for ECP to enhance the EMC ability of the system.
本文设计的控制系统采用先进的PC机和16位单片机80C196Kc并行中断通讯控制技术组成的智能检测与控制系统。在算法上使用新的体外反搏充排气时序控制算法,使病人反搏时在舒张期出现的反搏波恰好发生在主动脉瓣关闭之际,从而使反搏血流以最充分的时间向缺血器官进行灌注,而又不加重心脏的负荷。在心脏进入收缩期能使收缩压降至最低,最大限度地降低心脏射血期负荷,从而达到最大的反搏效应。
为了精确实现算法,本文采用三阈值法完成对心电信号的QRS波进行识别,结合指脉脉搏波判定充排气时机。同时在系统中充分考虑系统的安全性,增强出错预警处理能力,保障病人在非正常情况下的安全。
最后为了保证本文设计的体外反搏控制系统可以适应于各种治疗环境,不干扰附件其他设备,亦不受别的设备干扰,在系统的设计上采取了多种抗干扰措施,保证设备的电磁兼容性。
External counterpulsation (EGP) is a noninvasive assisted circulation device. It plays a positive and curative role in increasing the blood supply for the heart and brain; promoting collateral circulation of the ischemic tissue and organs; This noninvasive technique provides augmentation of diastolic blood flow and coronary blood flow similar to the intraortic balloon pump, utilizing the serial inflation of three sets of cuffs which wrap around the calves, thighs and buttocks. Inflation and deflation is timed to the patient' s Electrocardiograph (ECG) and the arterial pressure waveform is monitored noninvasively. The overall hemodynamic effect is to provide diastolic augmentation and thus increase coronary perfusion pressure, to unload systolic cardiac workload and therefore decrease myocardial oxygen demand.
An intelligent test and control system, which consists of advanced computer and 16-bit microcontroller, is developed for controlling counterpulsation and monitoring the system and patient. A new algorithm about the inflation and deflation timing is adopted in this system, which makes the diastolic augmentation emerge as soon as the aortic valve closed. In this case, the blood has enough time to pour into the organs that are short of blood, by doing so, a best effect of the ECP will be achieved.
In this paper, "three thresholds" method is adopted to distinguish the R wave from the characteristic of ECG signal. Integrated with the finger pulse wave, the system can extract the start point of the inflation and deflation timing. Ensure the patients' safety, the "error early warning" function is designed in this system.
The electromagnetic compatibility (EMC) was an ability for electronic
equipment to work well under the anticipant electromagnetic environment, it is an important technical performance for electronic equipment especially the medical devices. So some kinds of analogue and digital circuitries were designed for ECP to enhance the EMC ability of the system.
引文
[1] 郑振声.增强型体外反搏装置的设计及工作原理.中国生物医学工程学报.1984,3:133-137
[2] 钱孝贤,郑振声.体外反搏的临床应用进展.新医学,2000,31(1):48-49
[3] Soroff HS, Hui J, Giron F. Current status of external counterpulsation. 1986, 2(2):277-295
[4] Zheng ZS, Yu LQ, Cai SR. New sequential external counterpulsation for the treatment of acute myocardial infarction. Artif Organs. 1984, 8(4): 470-474
[5] 张苗青.体外反搏治疗冠心病的临床应用及装置改进研究.医学研究通讯,2001,30(12):15-16
[6] Gregory W. Barsness. Enhanced External Counterpulsation in Unrevascularizable Patients. Current Interventional Cardiology Reports 2001, 3:37-43
[7] 马虹,郑振声,杜志民.体外反搏国内外发展动态与展望.岭南心血管病杂志,2003,9(3):154-158
[8] 杨辰园,蔡大卫.AECP-88全自动体外么博装置研制.1989,4:78-86
[9] 袁冬冬.介绍一种新型的体外反搏装置.医疗设备信息 2001,16(7):46-48
[10] 李海云,郑振声.一种新型的体外反搏控制系统的研究.中国医疗器械杂志,1999,23(4):187-189
[11] 黄智礼,郑振声.采用心阻抗血流图对体外反搏的控制研究.中国生物医学工程学报,1995,14(4):292-298
[12] 伍贵富,张苗青.心阻抗血流微分图用于体外反搏最佳充气时间调节的研究.现代医学仪器与应用,1995,7(2):87-91
[13] 杨栋,李静.体外反搏装置充排气序贯电路原理分析.医疗装备,1992,4:19-20
[14] Lawson WE, Hui JC, Zheng ZS. Can angiographic findings predict which coronary patients will benefit from enhanced external counterpulsation?. Am J Cardiol. 1996, 77(12): 1107-1109
[15] Ozawa ET, Bottom KE, Ziao X, et al. Numerical simulation of Enhanced External Counterpulsaton. Annals of Biomedical Engieering. 2001,29:284-297.
[16] 张瑞华.体外反搏治疗缺血性脑血管病.中国康复.2001,16(3):172-173
[17] 顾玥.体外反搏的临床应用及观察.中国航天医药杂志.2003,5(5):67
[18] Zheng ZS, Li TM, Kambic H. Sequential external counterpulsation (SECP) in China. Trans Am Soc Artif Intern Organs. 1983, 29(599): 599-603
[19] 余学飞.医学电子仪器原理与设计.第一版.广州:华南理工大学出版社.2000.75-94
[20] Daskalov IK, Dotsinsky IA. Development in ECG acquisition, preprocessing, parameter measurement and recording. IEEEBMEJ, 1998,17:3-4
[21] 刘崧,曹宇,林榕.监护仪用ECG放大电路的研制.医疗卫生设备.1995,2:3-8
[22] 王忠友,吴水才,林家瑞.三通道ECG信号微机检测系统前置放大器的研制.中国医疗器械杂志.2002,26(4):268-270
[23] 李刚,林凌.新型的高性能生物电放大器.电子产品世界.2002,11:52-53
[24] 何伟,陈良迟,许晓红.心电信号及各组分的频率分布和有效带宽研究;生物医学工程学杂志.1996,13(4):336-340
[25] 何伟.心电信号时频特性的对比研究.生物医学工程学杂志.2001,18(4):599-602
[26] 白凤山,黄威,张立倩.可编程增益放大器在小信号数据采集系统中的应用.电测与仪表.2003,2:52-56
[27] 杜丽冰.ECG中50Hz干扰的抑制及其性能.环境技术.1998:6:32-34
[28] 黎向宇,钱明,巩欣州.脉搏波分析系统的硬件电路与显示菜单设计.北京生物医学工程.1996,15(2):79-84
[29] Intel Corporation. 8XC196Kx, 8XC196Jx, 87C196CA Microcontroller Family User' s Manual. 1996.
[30] 孙涵芳.Intel16位单片机.第一版.北京:北京航空航天大学出版社.1995.144-170
[31] 陈龙聪,胡国虎.通用型Intel系列单片机在医学中的应用.北京生物医学工程.2003,22(4):308-312
[32] 谢宏韬,张永红,张菊鹏.基于80C196KC单片机的便携式家庭心电血压监护仪的研制.北京生物医学工程.2001,20(4):271-275
[33] 杨松岸,杨华,阳昌汉.一种新颖的ISA总线接口电路.信息技术.2000,9:3-6
[34] 李涛,张承学,胡志坚.基于ISA总线的高速同步数据采集系统设计.计算机应用.2004,4:20-23
[35] 邵鸿宇.微机原理与接口技术.第一版.北京:北京航空航天大学出版社.2002.254-272
[36] DonWiters.医疗器械与电磁干扰FDA动态报告.中国医疗器械信息 1997(3):22-25
[37] 李海云,郑振声.增强型体外反搏器的电磁兼容性.中山医科大学学报.1997,18:81-83
[38] 周佩白,马乃祥.基本概念与电磁干扰源及耦合途径.华东电力.1999(8):55-59
[39] 魏置.合理选择DC-DC转换器.单片机与嵌入式系统应用.2002,4:9-12
[40] 何立琴,魏守水,丁良.生物电信号的线性隔离技术.电子测量与仪器学报.2003,17(3):52-57
[41] 刘光斌,刘冬,姚志成.单片机系统实用抗干扰技术.第一版.北京:人民邮电出版社.2003.51-318
[42] 李天明.电子电路中的接地问题.天水师范学校.2000,3:61-65
[43] 马利滨.单片机系统的电磁兼容性技术.移动通信.2003(2)185-189
[44] 梁恩主,梁恩维.Protel 99 SE 电路设计与仿真应用.北京:清华大学出版社,2000:130-165.
[45] 江思敏,姚鹏翼,胡荣.Protel电路设计教程.第一版.北京:清华大学出版社.2002.184-248
[46] MCS-96 Macro Assemble Users Guide, Intel Corporation. 1996
[47] 陈军.Intel 80C196 单片机应用实践与C语言开发.第一版.北京:清华大学出版社.2002.
[48] 周航慈.单片机应用程序设计.第一版.北京:北京航空航天大学出版社.1994.
[49] 赵宏,逄志刚.80C196KC 单片机的应用设计.光电技术应用.2003,4:53-57
[50] 动态 ECG 分析系统用户界面的研制.张宇涛,林家瑞.中国医疗器械杂志.1993,17(6):45-52
[51] 吕沙里.医学监测仪器中叠加及滚动显示技术.医疗卫生设备.2003,8:15-16
[52] 高延滨,朱荣生,岳中贵.用INT08中断实现IBM—PC系列微机中断方式的数据采集系统.哈尔滨船舶工程学院学报.1994,15(2):9-20
[53] 邱书波,周东辉.利用定时器中断设计PC工控软件.电子技术应用.1996,10:14-15
[54] 周少武.用C语言编写短定时中断服务程序的方法.微型机与应用.1996,10:44-45
[55] 刘金琪,许万平,肖煜东.心电信号检测与体外反搏控制系统设计.机械与电子,2003(3):32-34
[56] 李海云,段元民.体外反搏治疗过程中病人的心电信号实时处理.北京生物医学工程.1999,18(4):232-237
[57] 边肇祺,张学工.模式识别.第二版.北京:清华大学出版社.2000.
[58] 孔玉,张乐平,周洪堂.QRS波群检测方法的研究进展.医学信息.2004,17(1):62-63
[59] Friesen, G. M, Jannett, T. C. Jadallah. A comparison of the noise sensitivity of nine QRS detection algorithms. IEEE TransBiomed Eng. 1990,37(1): 85-98
[60] Afonso VX, Tompk insWJ. ECG beat detect ion using filter banks. IEEE Trans BM E. 1999,46(2):192-202.
[61] Gomis P, Jones DL. Analysis of abnormal signals within the QRS complex of the high resolution electrocardiogram. IEEE Trans Biomed Eng. 1997,44: 681-693
[62] J.Neves Rodrigues, V. wall, and L.S rnmo. QRS Detection for Pacemakers in a Noisy Environment Using a Time Lagged Artificial Neural Network. IEEE Transactions on Biomedical Engineering. 1992, 317-328
[63] Szilagyi SM,SzilagyiL, David L. Comparison between neural-network-based adaptive filtering and wavelet transform for ECG characteristic points detection. Proceedings-19th International Conference IEEE/EMBS, Chicago, USA. 1997.272-274.
[64] Zumray Dokur, Tamer Olmez, Ertugrul Yazgan. Detection of ECG waveforms by neural networks. Medical Engineering and Physics. 1997,19(8):738-741
[65] Yang Ming Yao, HuW ei Chih, Shyu Liang Yu. ECG events detection and classification using wavelet and neural networks. Proceedings 19th International Conference-IEEE/EMBS, Chicago, USA. 1997.280-282.
[66] Sahambi JS, Tandon SN. Using wavelet trans-forms for ECG characterization. IEEE/BMEJ, 1997:16(2):245-249
[67] 周云波,林家瑞.用小波变换对ECG进行特征提取——一种在线数字信号处理系统.国外医学生物医学工程分册.1997,20(5):211-218
[68] 王林泓,杨浩.心电信号处理中滤波器设计的研究.北京生物医学工程.2002,21(3):218-222
[69] 沈谦,黄立霞,王涛,心电信号预处理的数字滤波器设计.电子技术.2002,11:60-62
[70] 孔令锋,谢锡城,卢志远.矫正心电信号中基线漂移的数字滤波技术及其实现.中国医疗器械信息.2003,9(6):12-15
[71] 刘文萍.图像分割中阈值选取方法比较研究.模式识别与人工智能,1997,10(3):34-39
[72] 姬军,董秀珍,王海滨.心电信号QRS波的识别算法及程序设计.北京生物医学工程.2001,20(2):119-124
[73] Daskalov IK, Christov Ⅱ. Electrocadiogram signal preprocessing for automatic detect ion of QRS boundaries. Medical Engineering and Physics. 1999,21: 37-44
[74] Pan Jiapu, Tompkins WJ. A Real-Time QRS Detection Algorithm. IEEE EMBS. 1985, 232 (3):230-236
[75] 黄国言,邹沐昌.动态心电图QRS波形检测算法的分析.燕山大学学报.2002,26(2):163-168
[76] 姜治中,宋有成.新编简明心电图学.第一版.北京:科学出版社.1999
[77] 杨振野,夏梦娜,李玲华.ECG分析中室扑、室颤快速识别方法的研究.华中理工大学学报.1997,25(2):98-101
[78] 卢才义.临床心律失常学.第一版.北京:中国医药科技出版社,1993. ,
[2] 钱孝贤,郑振声.体外反搏的临床应用进展.新医学,2000,31(1):48-49
[3] Soroff HS, Hui J, Giron F. Current status of external counterpulsation. 1986, 2(2):277-295
[4] Zheng ZS, Yu LQ, Cai SR. New sequential external counterpulsation for the treatment of acute myocardial infarction. Artif Organs. 1984, 8(4): 470-474
[5] 张苗青.体外反搏治疗冠心病的临床应用及装置改进研究.医学研究通讯,2001,30(12):15-16
[6] Gregory W. Barsness. Enhanced External Counterpulsation in Unrevascularizable Patients. Current Interventional Cardiology Reports 2001, 3:37-43
[7] 马虹,郑振声,杜志民.体外反搏国内外发展动态与展望.岭南心血管病杂志,2003,9(3):154-158
[8] 杨辰园,蔡大卫.AECP-88全自动体外么博装置研制.1989,4:78-86
[9] 袁冬冬.介绍一种新型的体外反搏装置.医疗设备信息 2001,16(7):46-48
[10] 李海云,郑振声.一种新型的体外反搏控制系统的研究.中国医疗器械杂志,1999,23(4):187-189
[11] 黄智礼,郑振声.采用心阻抗血流图对体外反搏的控制研究.中国生物医学工程学报,1995,14(4):292-298
[12] 伍贵富,张苗青.心阻抗血流微分图用于体外反搏最佳充气时间调节的研究.现代医学仪器与应用,1995,7(2):87-91
[13] 杨栋,李静.体外反搏装置充排气序贯电路原理分析.医疗装备,1992,4:19-20
[14] Lawson WE, Hui JC, Zheng ZS. Can angiographic findings predict which coronary patients will benefit from enhanced external counterpulsation?. Am J Cardiol. 1996, 77(12): 1107-1109
[15] Ozawa ET, Bottom KE, Ziao X, et al. Numerical simulation of Enhanced External Counterpulsaton. Annals of Biomedical Engieering. 2001,29:284-297.
[16] 张瑞华.体外反搏治疗缺血性脑血管病.中国康复.2001,16(3):172-173
[17] 顾玥.体外反搏的临床应用及观察.中国航天医药杂志.2003,5(5):67
[18] Zheng ZS, Li TM, Kambic H. Sequential external counterpulsation (SECP) in China. Trans Am Soc Artif Intern Organs. 1983, 29(599): 599-603
[19] 余学飞.医学电子仪器原理与设计.第一版.广州:华南理工大学出版社.2000.75-94
[20] Daskalov IK, Dotsinsky IA. Development in ECG acquisition, preprocessing, parameter measurement and recording. IEEEBMEJ, 1998,17:3-4
[21] 刘崧,曹宇,林榕.监护仪用ECG放大电路的研制.医疗卫生设备.1995,2:3-8
[22] 王忠友,吴水才,林家瑞.三通道ECG信号微机检测系统前置放大器的研制.中国医疗器械杂志.2002,26(4):268-270
[23] 李刚,林凌.新型的高性能生物电放大器.电子产品世界.2002,11:52-53
[24] 何伟,陈良迟,许晓红.心电信号及各组分的频率分布和有效带宽研究;生物医学工程学杂志.1996,13(4):336-340
[25] 何伟.心电信号时频特性的对比研究.生物医学工程学杂志.2001,18(4):599-602
[26] 白凤山,黄威,张立倩.可编程增益放大器在小信号数据采集系统中的应用.电测与仪表.2003,2:52-56
[27] 杜丽冰.ECG中50Hz干扰的抑制及其性能.环境技术.1998:6:32-34
[28] 黎向宇,钱明,巩欣州.脉搏波分析系统的硬件电路与显示菜单设计.北京生物医学工程.1996,15(2):79-84
[29] Intel Corporation. 8XC196Kx, 8XC196Jx, 87C196CA Microcontroller Family User' s Manual. 1996.
[30] 孙涵芳.Intel16位单片机.第一版.北京:北京航空航天大学出版社.1995.144-170
[31] 陈龙聪,胡国虎.通用型Intel系列单片机在医学中的应用.北京生物医学工程.2003,22(4):308-312
[32] 谢宏韬,张永红,张菊鹏.基于80C196KC单片机的便携式家庭心电血压监护仪的研制.北京生物医学工程.2001,20(4):271-275
[33] 杨松岸,杨华,阳昌汉.一种新颖的ISA总线接口电路.信息技术.2000,9:3-6
[34] 李涛,张承学,胡志坚.基于ISA总线的高速同步数据采集系统设计.计算机应用.2004,4:20-23
[35] 邵鸿宇.微机原理与接口技术.第一版.北京:北京航空航天大学出版社.2002.254-272
[36] DonWiters.医疗器械与电磁干扰FDA动态报告.中国医疗器械信息 1997(3):22-25
[37] 李海云,郑振声.增强型体外反搏器的电磁兼容性.中山医科大学学报.1997,18:81-83
[38] 周佩白,马乃祥.基本概念与电磁干扰源及耦合途径.华东电力.1999(8):55-59
[39] 魏置.合理选择DC-DC转换器.单片机与嵌入式系统应用.2002,4:9-12
[40] 何立琴,魏守水,丁良.生物电信号的线性隔离技术.电子测量与仪器学报.2003,17(3):52-57
[41] 刘光斌,刘冬,姚志成.单片机系统实用抗干扰技术.第一版.北京:人民邮电出版社.2003.51-318
[42] 李天明.电子电路中的接地问题.天水师范学校.2000,3:61-65
[43] 马利滨.单片机系统的电磁兼容性技术.移动通信.2003(2)185-189
[44] 梁恩主,梁恩维.Protel 99 SE 电路设计与仿真应用.北京:清华大学出版社,2000:130-165.
[45] 江思敏,姚鹏翼,胡荣.Protel电路设计教程.第一版.北京:清华大学出版社.2002.184-248
[46] MCS-96 Macro Assemble Users Guide, Intel Corporation. 1996
[47] 陈军.Intel 80C196 单片机应用实践与C语言开发.第一版.北京:清华大学出版社.2002.
[48] 周航慈.单片机应用程序设计.第一版.北京:北京航空航天大学出版社.1994.
[49] 赵宏,逄志刚.80C196KC 单片机的应用设计.光电技术应用.2003,4:53-57
[50] 动态 ECG 分析系统用户界面的研制.张宇涛,林家瑞.中国医疗器械杂志.1993,17(6):45-52
[51] 吕沙里.医学监测仪器中叠加及滚动显示技术.医疗卫生设备.2003,8:15-16
[52] 高延滨,朱荣生,岳中贵.用INT08中断实现IBM—PC系列微机中断方式的数据采集系统.哈尔滨船舶工程学院学报.1994,15(2):9-20
[53] 邱书波,周东辉.利用定时器中断设计PC工控软件.电子技术应用.1996,10:14-15
[54] 周少武.用C语言编写短定时中断服务程序的方法.微型机与应用.1996,10:44-45
[55] 刘金琪,许万平,肖煜东.心电信号检测与体外反搏控制系统设计.机械与电子,2003(3):32-34
[56] 李海云,段元民.体外反搏治疗过程中病人的心电信号实时处理.北京生物医学工程.1999,18(4):232-237
[57] 边肇祺,张学工.模式识别.第二版.北京:清华大学出版社.2000.
[58] 孔玉,张乐平,周洪堂.QRS波群检测方法的研究进展.医学信息.2004,17(1):62-63
[59] Friesen, G. M, Jannett, T. C. Jadallah. A comparison of the noise sensitivity of nine QRS detection algorithms. IEEE TransBiomed Eng. 1990,37(1): 85-98
[60] Afonso VX, Tompk insWJ. ECG beat detect ion using filter banks. IEEE Trans BM E. 1999,46(2):192-202.
[61] Gomis P, Jones DL. Analysis of abnormal signals within the QRS complex of the high resolution electrocardiogram. IEEE Trans Biomed Eng. 1997,44: 681-693
[62] J.Neves Rodrigues, V. wall, and L.S rnmo. QRS Detection for Pacemakers in a Noisy Environment Using a Time Lagged Artificial Neural Network. IEEE Transactions on Biomedical Engineering. 1992, 317-328
[63] Szilagyi SM,SzilagyiL, David L. Comparison between neural-network-based adaptive filtering and wavelet transform for ECG characteristic points detection. Proceedings-19th International Conference IEEE/EMBS, Chicago, USA. 1997.272-274.
[64] Zumray Dokur, Tamer Olmez, Ertugrul Yazgan. Detection of ECG waveforms by neural networks. Medical Engineering and Physics. 1997,19(8):738-741
[65] Yang Ming Yao, HuW ei Chih, Shyu Liang Yu. ECG events detection and classification using wavelet and neural networks. Proceedings 19th International Conference-IEEE/EMBS, Chicago, USA. 1997.280-282.
[66] Sahambi JS, Tandon SN. Using wavelet trans-forms for ECG characterization. IEEE/BMEJ, 1997:16(2):245-249
[67] 周云波,林家瑞.用小波变换对ECG进行特征提取——一种在线数字信号处理系统.国外医学生物医学工程分册.1997,20(5):211-218
[68] 王林泓,杨浩.心电信号处理中滤波器设计的研究.北京生物医学工程.2002,21(3):218-222
[69] 沈谦,黄立霞,王涛,心电信号预处理的数字滤波器设计.电子技术.2002,11:60-62
[70] 孔令锋,谢锡城,卢志远.矫正心电信号中基线漂移的数字滤波技术及其实现.中国医疗器械信息.2003,9(6):12-15
[71] 刘文萍.图像分割中阈值选取方法比较研究.模式识别与人工智能,1997,10(3):34-39
[72] 姬军,董秀珍,王海滨.心电信号QRS波的识别算法及程序设计.北京生物医学工程.2001,20(2):119-124
[73] Daskalov IK, Christov Ⅱ. Electrocadiogram signal preprocessing for automatic detect ion of QRS boundaries. Medical Engineering and Physics. 1999,21: 37-44
[74] Pan Jiapu, Tompkins WJ. A Real-Time QRS Detection Algorithm. IEEE EMBS. 1985, 232 (3):230-236
[75] 黄国言,邹沐昌.动态心电图QRS波形检测算法的分析.燕山大学学报.2002,26(2):163-168
[76] 姜治中,宋有成.新编简明心电图学.第一版.北京:科学出版社.1999
[77] 杨振野,夏梦娜,李玲华.ECG分析中室扑、室颤快速识别方法的研究.华中理工大学学报.1997,25(2):98-101
[78] 卢才义.临床心律失常学.第一版.北京:中国医药科技出版社,1993. ,