基于DDS的短波差分跳频频率合成器的研究与设计
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摘要
差分跳频技术是一种新型的跳频通信技术,它利用跳变的载波之间的相关性来传送信息。差分跳频技术应用于短波通信,可以在短波波段内实现宽频带、高速率的跳频,极大的提高了短波通信的数据速率,抗干扰、抗多径衰落能力,这种新型短波跳频系统将成为短波通信领域今后发展方向之一。
直接数字频率合成(DDS)是继直接式和锁相式频率合成技术之后的新一代频率合成技术。它是一种在数字域中产生和处理正弦波形或其它连续波形的数字技术;对于要求高速跳频、输出相位控制和优良相位噪声性能的应用是首选的技术。本文重点论述了DDS的工作原理、基本结构和输出频谱,分析了DDS输出频谱杂散的主要来源:相位截断误差、幅度量化误差、以及DAC非线性误差,并提出了减少杂散的方法。
跳频速度是决定整个跳频系统性能的主要参数。快速跳频频率合成器就成为跳频通信系统的关键。本文给出了提高锁相环频率合成锁定速度的方法,以及DDS的频率扩展方法,提出了适合短波差分跳频的频率合成器的独特设计方案。
最后,本文完成了基于DDS+DSP的短波差分跳频频率合成器的设计。采用ADI公司的新型高时钟DDS芯片AD9852作为频率合成器,TI公司的高性能DSP芯片TMS320C6201作为高速控制电路,同时DSP完成跳频图案的产生。主要内容包括DSP与DDS的接口设计,滤波器的设计,以及其他主要电路的设计等。本方案通过电路试验,达到了很高的跳频速度,高的频谱纯度,完全符合差分跳频的设计要求。
Differential Frequency Hopping (DFH) is a new type of frequency hopping (FH) communication technique. Its feature is the different method of carrying information with traditional FH technique. DFH transmits information by the correlation between hopping frequency carriers. When DFH is applied to HF communication, HF radio can achieve desirable performance of high hopping rate within a wide HF band, which will improve the data rate and capabilities of anti-jamming and anti multipath fading. This type of FH system will be the one of directions of future HF communication.
Direct Digital Synthesis (DDS) is a new generation of frequency synthesis after Direct Synthesis (DS) and PLL frequency synthesis. DDS is a technique for using digital data processing blocks as a means to generate a frequency- and phase- tunable sine wave or other continuous waveform. It’s the preferred technique for applications requiring high hopping rate and excellent phase noise performance. In this paper, we make a systemic research on DDS technique. The structure, basic principle and frequency spectrum are discussed in detail. As spur is the key reason limiting DDS’s application, we analyze three factors impact spectrum of DDS, and give the solutions to decrease the spur.
Hopping rate is the key parameter that determines performance of FH system, so fast FH synthesizer becomes very important. Several design schemes are discussed in this paper, including methods of improving locking speed of PLL and getting higher frequency from DDS. By comparison, a new scheme is put forward.
In the last part, the scheme of DFH HF synthesizer is described. DDS chip AD9852 is selected as synthesizer, and TI’s DSP chip TMS320C6201 is selected as controller. Interfaces between DSP and DDS, and other key circuit are discussed in detail. By practical circuit experiment, the design realizes high hopping rate, and pure spectrum, completely meets design requirements.
直接数字频率合成(DDS)是继直接式和锁相式频率合成技术之后的新一代频率合成技术。它是一种在数字域中产生和处理正弦波形或其它连续波形的数字技术;对于要求高速跳频、输出相位控制和优良相位噪声性能的应用是首选的技术。本文重点论述了DDS的工作原理、基本结构和输出频谱,分析了DDS输出频谱杂散的主要来源:相位截断误差、幅度量化误差、以及DAC非线性误差,并提出了减少杂散的方法。
跳频速度是决定整个跳频系统性能的主要参数。快速跳频频率合成器就成为跳频通信系统的关键。本文给出了提高锁相环频率合成锁定速度的方法,以及DDS的频率扩展方法,提出了适合短波差分跳频的频率合成器的独特设计方案。
最后,本文完成了基于DDS+DSP的短波差分跳频频率合成器的设计。采用ADI公司的新型高时钟DDS芯片AD9852作为频率合成器,TI公司的高性能DSP芯片TMS320C6201作为高速控制电路,同时DSP完成跳频图案的产生。主要内容包括DSP与DDS的接口设计,滤波器的设计,以及其他主要电路的设计等。本方案通过电路试验,达到了很高的跳频速度,高的频谱纯度,完全符合差分跳频的设计要求。
Differential Frequency Hopping (DFH) is a new type of frequency hopping (FH) communication technique. Its feature is the different method of carrying information with traditional FH technique. DFH transmits information by the correlation between hopping frequency carriers. When DFH is applied to HF communication, HF radio can achieve desirable performance of high hopping rate within a wide HF band, which will improve the data rate and capabilities of anti-jamming and anti multipath fading. This type of FH system will be the one of directions of future HF communication.
Direct Digital Synthesis (DDS) is a new generation of frequency synthesis after Direct Synthesis (DS) and PLL frequency synthesis. DDS is a technique for using digital data processing blocks as a means to generate a frequency- and phase- tunable sine wave or other continuous waveform. It’s the preferred technique for applications requiring high hopping rate and excellent phase noise performance. In this paper, we make a systemic research on DDS technique. The structure, basic principle and frequency spectrum are discussed in detail. As spur is the key reason limiting DDS’s application, we analyze three factors impact spectrum of DDS, and give the solutions to decrease the spur.
Hopping rate is the key parameter that determines performance of FH system, so fast FH synthesizer becomes very important. Several design schemes are discussed in this paper, including methods of improving locking speed of PLL and getting higher frequency from DDS. By comparison, a new scheme is put forward.
In the last part, the scheme of DFH HF synthesizer is described. DDS chip AD9852 is selected as synthesizer, and TI’s DSP chip TMS320C6201 is selected as controller. Interfaces between DSP and DDS, and other key circuit are discussed in detail. By practical circuit experiment, the design realizes high hopping rate, and pure spectrum, completely meets design requirements.
引文
张尔扬,王莹,路军,短波通信技术,北京:国防工业出版社,2002
孙建川,凌涛,短波战术跳频通信系统的技术现状和发展,通信与广播电视,2002(3):1~6
及燕丽,王友村,沈其聪等,现代通信系统,北京:电子工业出版社,2001
D.L.Herrick, P.K.Lee, CHESS: A New Reliable High Speed HF Radio, MILCOM’96, 1996.684~690
D.L.Herrick, P.K.Lee, Correlated Frequency Hopping: An Improved Approach to HF Spread Spectrum Communication, 1996 Tactical Communication Conference Proceedings, 1996: 319~324
李明,戚仁华,朱红琛,短波宽带快速跳频通信技术研究,通信技术,2000,110(3):34~37
J. Tierney, C. M. Rader, B. Gold. A digital frequency synthesizer. IEEE Transactions on Audio Electroacoustics, 1971, AU-19: 48~57
Kenneth A. Essenwanger, Sine Output DDSs A Survey of the State of the Art, IEEE International Frequency Control Symposium, 1998: 370~378
H.T.Nicholas,Ⅲ, Henry Samueli, An Analysis of the Output Spectrum of Direct Digital Frequency Synthesizers in the Presence of Phase-Accumulator Truncation, IEEE,41" AFCS,1987:495-502
H.T.Nicholas,Ⅲ, H. Samueli, B.kim, The optimization of direct digital frequency synthesizer performance in the presence of finite length effects. IEEE Proc.420d AFCS, 1988:357-363
Analog Devices, Inc., A Technical Tutorial on Digital Signal Synthesis, 1999
Michael J. Flangan and George A. Zimmerman. Spur-Reduced Digital Sinusoid Synthesis,IEEE, Transactions on communications, 43(7), 1995:2254~2262
M. J. Flanagan, G. A. Zimmerman. Spur-reduced Digital Sinusoid Synthesis, IEEE Transactions on COM., 1995,7: 2254~2262
朱红琛,CHESS系统的跳频通信技术,通信技术,1998,101(2):73~76
王秉均,居谧,沈保锁,孙学军,扩频通信,天津大学出版社,1993
沈保锁,侯春萍,现代通信原理,北京:国防工业出版社,2002
王秉均,居谧,沈保锁,孙学军,《锁相式调频器快速锁定的研究》研究报
告,天津大学电子工程系,1989
李振玉,卢玉民,扩频选址通信,北京:国防工业出版社,1988
张厥盛,郑继禹,万心平,锁相技术.,西安电子科技出版社,2000
庄卉等,锁相与频率合成技术,气象出版社,1996
李耀民,周正,AT89C51串行加载DDS芯片AD9835的设计与实现,电子产品世界,2002(09B):81~82
曾兴雯,张厥盛等,快速跳频电台频率合成器的研究,通信技术与发展,1997,(3):61~64
杨国逾,粟显义,采用DDS+PLL技术实现S波段频率合成的一种方法,电子科技大学,1999,28(3):388~391
杨建军,DDS+PLL组合系统及实例,电讯技术,2001,(1):72~75
孔京,郭黎利,战兴文,直接数字频率合成技术在跳频通信中的应用,应用科技,28(9):13~15
王秀芳,姜建国,李中需,跳频通信系统中频率台成器的研究,电信科学,2001,(11):61~63
AD9852 Datasheet, http://www.anolog.com
TMS320C6201 Peripherals Reference Guide, http://www.ti.com
TMS320C6000 McBSP Initialization, http://www.ti.com
TMS320C6000 McBSP Interface to SPI ROM, http://www.ti.com
C6x McBSP Initialization, http://www.ti.com
Howard W.Johnson, Martin Graham, High-speed Digital Design, Prentice Hall
张雄伟,陈亮,徐光辉,DSP芯片的原理与开发应用,电子工业出版社,2003
任丽香,马淑芬,李方慧,TMS320C6000系列DSPs的原理与应用,电子工业出版社,2000
安建平,DDS/PLL频率合成技术的研究:[博士学位论文],北京:北京理工大学
郭德淳,直接数字频率合成技术研究与设计:[博士学位论文],北京:北京理工大学,2001
武永军,提高跳频频率合成器锁定速度的研究与实现,[硕士学位论文],天津:天津大学,2002
刘光辉,并行DDS频率源技术研究,[硕士学位论文],电子科技大学,2002
高望,直接数字频率合成技术及其杂散分析,[硕士学位论文],南京:南京理工大学,2002
孙建川,凌涛,短波战术跳频通信系统的技术现状和发展,通信与广播电视,2002(3):1~6
及燕丽,王友村,沈其聪等,现代通信系统,北京:电子工业出版社,2001
D.L.Herrick, P.K.Lee, CHESS: A New Reliable High Speed HF Radio, MILCOM’96, 1996.684~690
D.L.Herrick, P.K.Lee, Correlated Frequency Hopping: An Improved Approach to HF Spread Spectrum Communication, 1996 Tactical Communication Conference Proceedings, 1996: 319~324
李明,戚仁华,朱红琛,短波宽带快速跳频通信技术研究,通信技术,2000,110(3):34~37
J. Tierney, C. M. Rader, B. Gold. A digital frequency synthesizer. IEEE Transactions on Audio Electroacoustics, 1971, AU-19: 48~57
Kenneth A. Essenwanger, Sine Output DDSs A Survey of the State of the Art, IEEE International Frequency Control Symposium, 1998: 370~378
H.T.Nicholas,Ⅲ, Henry Samueli, An Analysis of the Output Spectrum of Direct Digital Frequency Synthesizers in the Presence of Phase-Accumulator Truncation, IEEE,41" AFCS,1987:495-502
H.T.Nicholas,Ⅲ, H. Samueli, B.kim, The optimization of direct digital frequency synthesizer performance in the presence of finite length effects. IEEE Proc.420d AFCS, 1988:357-363
Analog Devices, Inc., A Technical Tutorial on Digital Signal Synthesis, 1999
Michael J. Flangan and George A. Zimmerman. Spur-Reduced Digital Sinusoid Synthesis,IEEE, Transactions on communications, 43(7), 1995:2254~2262
M. J. Flanagan, G. A. Zimmerman. Spur-reduced Digital Sinusoid Synthesis, IEEE Transactions on COM., 1995,7: 2254~2262
朱红琛,CHESS系统的跳频通信技术,通信技术,1998,101(2):73~76
王秉均,居谧,沈保锁,孙学军,扩频通信,天津大学出版社,1993
沈保锁,侯春萍,现代通信原理,北京:国防工业出版社,2002
王秉均,居谧,沈保锁,孙学军,《锁相式调频器快速锁定的研究》研究报
告,天津大学电子工程系,1989
李振玉,卢玉民,扩频选址通信,北京:国防工业出版社,1988
张厥盛,郑继禹,万心平,锁相技术.,西安电子科技出版社,2000
庄卉等,锁相与频率合成技术,气象出版社,1996
李耀民,周正,AT89C51串行加载DDS芯片AD9835的设计与实现,电子产品世界,2002(09B):81~82
曾兴雯,张厥盛等,快速跳频电台频率合成器的研究,通信技术与发展,1997,(3):61~64
杨国逾,粟显义,采用DDS+PLL技术实现S波段频率合成的一种方法,电子科技大学,1999,28(3):388~391
杨建军,DDS+PLL组合系统及实例,电讯技术,2001,(1):72~75
孔京,郭黎利,战兴文,直接数字频率合成技术在跳频通信中的应用,应用科技,28(9):13~15
王秀芳,姜建国,李中需,跳频通信系统中频率台成器的研究,电信科学,2001,(11):61~63
AD9852 Datasheet, http://www.anolog.com
TMS320C6201 Peripherals Reference Guide, http://www.ti.com
TMS320C6000 McBSP Initialization, http://www.ti.com
TMS320C6000 McBSP Interface to SPI ROM, http://www.ti.com
C6x McBSP Initialization, http://www.ti.com
Howard W.Johnson, Martin Graham, High-speed Digital Design, Prentice Hall
张雄伟,陈亮,徐光辉,DSP芯片的原理与开发应用,电子工业出版社,2003
任丽香,马淑芬,李方慧,TMS320C6000系列DSPs的原理与应用,电子工业出版社,2000
安建平,DDS/PLL频率合成技术的研究:[博士学位论文],北京:北京理工大学
郭德淳,直接数字频率合成技术研究与设计:[博士学位论文],北京:北京理工大学,2001
武永军,提高跳频频率合成器锁定速度的研究与实现,[硕士学位论文],天津:天津大学,2002
刘光辉,并行DDS频率源技术研究,[硕士学位论文],电子科技大学,2002
高望,直接数字频率合成技术及其杂散分析,[硕士学位论文],南京:南京理工大学,2002