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knowledge
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  知识
    The Research of Knowledge Management-Based Modern Office Information System
    基于知识管理的现代办公信息系统的研究
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    Theory and Application of Integrated Product Rapid Development Technology Based on Design Knowledge Reuse
    基于设计知识重用的集成产品快速开发技术的理论与实践
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    Research on Structural Methods of Knowledge Discovery
    构造性知识发现方法研究
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    Knowledge Model-Based Decesion Support System for Cotton Management
    基于知识模型的棉花管理决策支持系统的研究
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    Research on the Mechanism for Knowledge Services
    知识服务机制研究
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  知识
    The Research of Knowledge Management-Based Modern Office Information System
    基于知识管理的现代办公信息系统的研究
短句来源
    Theory and Application of Integrated Product Rapid Development Technology Based on Design Knowledge Reuse
    基于设计知识重用的集成产品快速开发技术的理论与实践
短句来源
    Research on Structural Methods of Knowledge Discovery
    构造性知识发现方法研究
短句来源
    Knowledge Model-Based Decesion Support System for Cotton Management
    基于知识模型的棉花管理决策支持系统的研究
短句来源
    Research on the Mechanism for Knowledge Services
    知识服务机制研究
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  “knowledge”译为未确定词的双语例句
    Research and Practice on Knowledge Management System of Collaborative Forging Products Development
    面向协同锻件产品开发的知识管理系统研究与实践
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    Research of Modeling and Applications of Knowledge Base System Based on Ontology
    基于Ontology知识库系统建模与应用研究
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    Research and Implementation of E-Government's Techniques Based on Knowledge Management
    基于KM的电子政务技术的研究与实现
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    Research on Product Knowledge Management System
    产品知识管理系统研究
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    Design and Implementation of Object-Oriented Intelligent Case Pattern Knowledge Base in IHSMTS
    IHSMTS中面向对象智能型实例模式库的设计与实现
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  knowledge
We shall show that the inverse spectral problem can be used to construct sampling type theorems from the knowledge of the sampling points only.
      
Calculations of those coefficients and many other situations where frames occur, requires knowledge of the inverse frame operator.
      
A quantitative structure-retention relationships (QSRR) approach, as one of the all-important areas in modern chemical science, gives knowledge that is practical and necessary for drug design, combinatorial, and medicinal chemistries.
      
The starting material used abroad is expensive and the yield is low (16%-28%); furthermore, to our best knowledge, no characterization of Compound A is available in the open literature.
      
An investigation on theory of information-knowledge-intelligence transforms
      
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In this paper, unknown variables will be introduced into the logic reasoning process, thus bringing the analytic technique into the range of automation. The analytic technique automation is included in a significant portion of artificial intelligence.The point raised in this article is that in future artificial intelligence machines (robot), the key problem does not involve that the robot is commanded to perform but involves how the robot is to search for an approach - the premises, in order to attain a certain...

In this paper, unknown variables will be introduced into the logic reasoning process, thus bringing the analytic technique into the range of automation. The analytic technique automation is included in a significant portion of artificial intelligence.The point raised in this article is that in future artificial intelligence machines (robot), the key problem does not involve that the robot is commanded to perform but involves how the robot is to search for an approach - the premises, in order to attain a certain aim - conclusion in any unknown environment. To achieve this ability, the robot must determine which premises are lacking for attaining this target and whether these premises exist or not in accordance with the objective environment and through analysis of its knowledge gained. The above-mentioned process is called analytic technique automation and can be achieved through analysis of the special solution subset in the solution sets of the logical equation.

在本文中将未知变量引入到逻辑推理的过程,使分析技术进入了自动化的范畴。分析技术的自动化是人工智能的一个重要组成部分。 本文提出的一个论点是:对未来的人工智能机器(机器人),关键的问题不是在于我们给机器规定了什么叫它去执行,而是要求机器人在任意未知的环境条件下,为了达到某一个目标——结论,如何去寻找为实现这个目标的途径——前提。机器人要是具有这种能力,就必须能按照客观的环境条件和已经学得的知识进行分析,判定为达到这个目标尚缺少几项前提,并寻找这些前提是否存在。上述过程可称之为分析技术自动化,可以通过分析逻辑方程的解集中的特殊形式的解来达到。

This paper describes a FORTRAN program for producing a perspective dr- awing of an arbitrarily curved surface with its hidden parts removed.The pro- gram is designed to work with surfaces descrided by parametric equations. Wi- th a knowledge of constructing "polygen" the algorithm calculates a number of points on a surface at which thee surface clisappears from view.Finally, a me- thod for generating silhovetee picture is presented.

本文讨论自由曲在消除隐藏线的一种方法,并通过一个FORTRAN程序来实现。这个程序适用于参数方程描述的曲面,采用构造多边形的方法求出曲面上从视线中消失的若干点。文章最后给出了产生曲面轮廓线投影的一个方法。

LISP primitive and basic LISP function, described in the first part of this article, are the simplest manipulation of LISP language and symbols and lists processing. They are analogous to the elementary calculation in algorithmic language, like addition, subtraction, multiplication and division etc,. Yet, the procedure in actual processing needs various strongly practicable LISP functions with stronger abilities and more complicated forms. Therefore, in LISP programming, it is necessary to augment these simple...

LISP primitive and basic LISP function, described in the first part of this article, are the simplest manipulation of LISP language and symbols and lists processing. They are analogous to the elementary calculation in algorithmic language, like addition, subtraction, multiplication and division etc,. Yet, the procedure in actual processing needs various strongly practicable LISP functions with stronger abilities and more complicated forms. Therefore, in LISP programming, it is necessary to augment these simple primitive and basic functons by continuously defining and rewriting new functions. Only in this way can we efficiently solve all kinds of non-numerical calculating problems.The second part of this article is written for those readers-unfamiliar with non-numerical processing,while having a knowledge of algorithmic language. It introduces, in more details, the forms of definition and characteristics of A function, recursive function and procedure function. It also points out the method of defining and generating new LISP functions by using them. This part gives niany examples of commonly used MINI-LISP functions and their executions. It also comments on and analyses the coding of these functins and their executive procedure. What should be pointed out is that the functions of LISP function, quoted and described in this part, are limited. It is not all-inclusive or exhaustive. To solve the complex problems like symbols and lists processing, artificial intelligence and data base systems design, etc., relevant LISP function should be chosen and defined, according to the actual cases of all sorts of application problems .Yet, even for the same application problems, the styles of LISP function definition (LISP programming) may vary from one user to another, for LISP programmers can choose different function definition methods and quote different functions, trains of thought and different habits. A LISP programming procedure should be like this: first of all, the user should change the problem into a kind of symbols (or lists) processing and design a non-numerical algorithm, then, according to the algorithm, by using the function defined earlier and the three above-described function definition methods, continuously define and generate groups of new functions. A LISP application program is: combining and listing the numerous LISP functions in parentheses, defining the outer-most LISP function by simply calling these functions, assigning real parameter to dummy argument, and then solving the problem.The third part of this article will give details about application examples of LISP language in symbols processing, artificial intelligence and data base systems design.

本文针对不熟悉非数值处理,但具有算法语言基础的读者,较为详细地介绍了λ函数、递归函数和PROC过程函数的定义形式及其特点,并指出用它们来定义和生成LISP新函数的方法;列举了许多MINI-LISP常用函数以及执行这些函数的实例;文中还对这些函数的编码和执行过程作了注释和分析。LISP程序的编制过程应该是:首先用户将他所要解决的问题转化为符号(表)处理形式,并设计出一种非数值算法,然后根据这种算法利用先前定义的函数及上述三种函数定义形式不断地定义和再生一批批新函数。一个LISP应用程序就是在括号内将众多的LISP函数进行有机地组合和罗列,而最外层的LISP函数只是非常简单地调用这批函数,将实在参数赋给函数中的形式参数,各种实际应用问题就得到解决。

 
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