论江泽民思想政治工作理论的创新
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摘要
坚持与时俱进、大力发展创新是江泽民思想政治工作理论体系的一个显著特征。本文从思想政治工作的地位作用、方针原则、基本内涵、教育主体、重点对象、评价标准等方面,系统地探讨了江泽民关于思想政治工作理论的创新。认为其创新亮点主要体现在:思想政治工作事关建设有中国特色社会主义事业的大局、经济发展需要坚强的政治保证等思政工作地位作用的论述;思想政治教育必须坚持以经济建设为中心、必须为全党全国工作大局服务的方针和必须坚持教育与管理相结合、解决思想问题同解决实际问题相结合的原则的论述;理想信念教育是思想政治工作的核心内容的论述;思想政治教育主体与社会主义政治文明辩证关系的论述;对思想政治教育两大重点客体(青年学生和青年干部)的新要求以及“三个代表”重要思想对思想政治工作的指导的论述等。
Progressing with time and innovation is one of the remarkable features of the complete system of Jiang Zemin's theory of ideological and political work. This thesis discusses on Jiang's innovation of ideological and political work from the status and function,guiding principle,basic connotation,education subject,education object and the standard of evaluation.The innovation as follows:The theory that ideological and political work exercises great influence on China's socialist cause with characteristics and that a firm political pledge reinforces the economic development, focuses on the vitality of ideological and political work;the ideological and political work must stick to the guiding principle of centering on the economic construction and serving the general situation of the whole Party and country; also stick to the principle of combining education with administration, and of combining solving ideological problems with practical ones;the education of ideal and belief is the major content of ideological
and political work;the theory of dialectical relations between the subject of ideological and political education and socialist political civilization, the theory of new requirements to the two major objects of ideological and political education (the young students and the young cadres), and the theory of representation of three advanced aspects as the standard theory for the quality evaluation of the ideological and political work.
Progressing with time and innovation is one of the remarkable features of the complete system of Jiang Zemin's theory of ideological and political work. This thesis discusses on Jiang's innovation of ideological and political work from the status and function,guiding principle,basic connotation,education subject,education object and the standard of evaluation.The innovation as follows:The theory that ideological and political work exercises great influence on China's socialist cause with characteristics and that a firm political pledge reinforces the economic development, focuses on the vitality of ideological and political work;the ideological and political work must stick to the guiding principle of centering on the economic construction and serving the general situation of the whole Party and country; also stick to the principle of combining education with administration, and of combining solving ideological problems with practical ones;the education of ideal and belief is the major content of ideological
and political work;the theory of dialectical relations between the subject of ideological and political education and socialist political civilization, the theory of new requirements to the two major objects of ideological and political education (the young students and the young cadres), and the theory of representation of three advanced aspects as the standard theory for the quality evaluation of the ideological and political work.
引文
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Nonferrous Metals,v8,n3,Sept. 1998,p557-562
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[38]徐殿斌.铝电解槽电解质温度自动控制.控制工程,2003.5(10):73-75
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[44]黄正瑾.在系统编程技术及其应用.东南大学出版社,1999.5
[45]喻方平等.MCS-96系列单片机PL/M语言编程及系统的设计与调试.北京:电子工业出版社,1998.5
[46]程军.Intel 80C196单片机应用实践与C语言开发.北京航空航天大学出版社,2000.11
[47]何立民。单片机应用技术选编(7).北京航空航天大学出版社,2000.8
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[3] 杨振海,孙淑萍,邱竹贤等。中国铝电解槽计算机控制技术发展的回顾与展望.东北大学学报,1999.6(3):283-285
[4] Peter M. Enter, Further Development of the Temperature Model, Light Metals, 1996:445-449
[5] Repetto M. Optimisation of an electrolysis cell for aluminium production. Proceedings of the 7th International Conference on Optimization of Electrical and Electronic Equipments, 2000, pt. 1, p 41-6 vol.1
[6] T. Moeu. Adaptive. Control of Alumina Reduction Cells With Point Feeders. Light Metal, 1985. 459-469
[7] Solberg I. Wave detection and characterization from current and voltage signals of an aluminium smelting cell, Modeling, Identification and Control, v 24, n 1, 2003, 3-13
[8] 戴小平.160kA预焙铝电解槽“四低一高”电解工艺技术条件的选择。轻金属,2000(3):31-34
[9] 蒋英刚.应用智能:控制技术后电解工艺技术条件的优化与选择.青海铝业科技,1998(4):28-30
[10] 邱竹贤.工业铝电解质分子比的演变与现状.中国有色金属学报,1996.6(4):13-18
[11] Kvande H. Bath chemistry and aluminium cell performance-facts, fictions, and doubts [J]. JOM, 1994,11:22 - 30
[12] 刘宝立,姜宝伟,马连武.135kA预焙铝阳极铝电解槽“四低一高”工艺实践.有色矿冶,2003.4(2):28-31
[13] 边友康等.大型预焙铝电解槽现代工艺技术条件的选择与实现.轻金属,2000,(11):34-35
[14] V.K.Mann. Cryolite Ratio and Bath Temperature Stabilization Problem in Aluminium Reduction cell, Light Metals, 1998:371-377
[15] 刘忠琼.铝电解“一高四低”工艺技术研究.轻金属,2001.4(2):10-13
[16] 轩林红 预焙铝电解槽“四低一高”电解工艺计算机控制.新疆有色金属2002:22-23
[17] P.M.Entner and G.A.Gud mundsson. Further Development of the Temperature
model. Light Metals, 1996 Warrendale.PA: TMS,1996:445-449
[18]姚昌仁.侧插自焙铝电解槽采用低分子比电解质生产工艺的研究.山东冶金,1998(8):32-35
[19]Johnson A Ⅲ. Wavelet packet time series analysis of aluminum electrolytic cells. Proceedings of the SPIE - The International Society for Optical Engineering, 2001, p 228-37
[20]田应甫.大型预焙铝电解槽生产实践.中南工业大学出版社,1997.1
[21]诸静等.模糊控制原理与应用.北京:机械工业出版社,1995.7
[22]蔡自兴.智能控制:基础与应用。北京:国防工业出版社,1998.10
[23]李士勇.模糊控制.神经控制和智能控制论.哈尔滨:哈尔滨工业大学出版社1996.10
[24]窦振中.模糊逻辑控制技术及其应用.北京:北京航空航天大学出版社,1995.7
[25]王耀南.智能控制系统模糊逻辑·专家系统·神经网络控制.湖南大学出版社,1996.10
[26]梁加山,袁艳,张泰山.人工气候室温度专家模糊控制系统的设计与实现.计算技术与自动化,2003.12(4):8-11
[27]P.M.Entner. Control of Bath Temperature. Light Metals , 1995 Warrendale.PA:TMS. 1995: 227-230
[28]李劫,丁凤其,李民军等.预焙铝电解槽阳极效应的智能预报方法.中南工业大学学报,2001.2(1):29-32
[29]陆义龙,韩丹群等.自动熄灭阳极效应在铝电解生产中的应用.有色金属节能,2001.5:4-6
[30]Meghlaoui A. Intelligent control of the feeding of aluminum electrolytic cells using neural networks. Computers & Chemical Engineering, v22,n 10,1998,19-28
[31]李琏.电解质中Al_2O_3浓度特性的研究.轻金属,2000(11):39-42
[32]Li Jiejia. The research of control method in aluminum electrolysis computer control system. Proceedings of the 3rd World Congress on Intelligent Control and Automation, 2000, 11-13 vol.5
[33]李劫,肖劲,张泰山等.铝电解槽点式下料的专家模糊控制方法.中南工业大学学报,1998.2:32-35
[34]曾水平,张秋萍,赵国鑫.铝电解槽氧化铝浓度的模糊控制。冶金自动化,2001(5):9-11
[35]Klaus Hofenbitzer. Improved Concept of alumina-feeding strategy. Light Metals. Warrendale,Permsylvania:The Minerals,Metals&Materials Society, 1999,293-296
[36]Li Jie. An intelligent controller for aluminum smelter potlines. Chinese Journal of
Nonferrous Metals,v8,n3,Sept. 1998,p557-562
[37]钱坤 谢寿尘等.铝电解模糊控制系统的研究与应用.自动化技术与应用,2003(1):11-13
[38]徐殿斌.铝电解槽电解质温度自动控制.控制工程,2003.5(10):73-75
[39]Panaitescu I. Magneto-hydro-dynamic analysis of an electrolysis cell for aluminum production. IEEE Transactions on Magnetics, v 36, n 4, pt.1, July 2000, p 1305-8
[40]Molina A. New approaches to model electric demand in aluminium smelter industry. Conference Record of the 2001 IEEE Industry Applications Conference. 2001, 26-31 vol.2
[41]孙涵芳等.Intell6位单片机.北京:北京航空航天大学出版社,1998.3
[42]梁合庆等.MCS-96系列十六位单片微机实用手册.北京: 电子工业出版社,1995.1
[43]应钢等.PLD/GAL可编程逻辑器件原理和应用.北京:中国科学院希望高级电脑技术公司,1994.2
[44]黄正瑾.在系统编程技术及其应用.东南大学出版社,1999.5
[45]喻方平等.MCS-96系列单片机PL/M语言编程及系统的设计与调试.北京:电子工业出版社,1998.5
[46]程军.Intel 80C196单片机应用实践与C语言开发.北京航空航天大学出版社,2000.11
[47]何立民。单片机应用技术选编(7).北京航空航天大学出版社,2000.8
[48]孟静.操作系统原理教程。清华大学出版社,2000.4
[49]MAXIM Welcome. MAXIM, 1999
[50]Maxim. Data Book and CD ROM, 2000.2
[51]周明德.微型计算机系统原理及应用.北京:清华大学出版社,1998.8
[52]公茂法等.单片机人机接口实例集.北京航空航天大学出版社,1998.4
[53]阳宪惠.现场总线技术及其应用.北京:清华大学出版社,1999
[54]邬宽明.CAN总线原理和应用系统设计.北京:北京航空航天大学出版社,1996
[55]广州周立功单片机发展有限公司. SJA1000独立的CAN控制器应用指南
[56]夏继强、满庆丰、段丛斌.计算机与CAN通信的一种方法。测控技术,第19卷第17期,2000年:58-60
[57]邱公伟等.实时控制与智能仪表多微机系统的通信技术.北京:清华大学出版社,1996.7
[58]张泰山.计算机控制系统.北京:冶金工业出版社,1986
[59]高鹏等.电路设计与制版—Protel 99.人民邮电出版社出版社,2001.6
[1] 张直平,李芬辰.城市电网谐波手册.北京:中国电力出版社,2001
[2] 国家技术监督局.电能质量公用电网谐波(GB/714549-93).北京:标准出版社,1993
[3] Christopher K.D. etc. Update of harmonic standard IEEE-519: IEEE recommended practices and requirements for harmonic control in electric power system. IEEE Trans on Industry Apllications, 1989.25(6): 1025~1034
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