信息技术与数学课程整合的思考

《普通高中数学课程标准(实验)》,其课程理念部分对现代信息技术与数学课程整合作了明确要求.提出课程设计与实施应重视信息技术的运用,把现代信息技术作为学生学习数学和解决问题的强有力工具,致力于改变学生的学习方式,使学生乐意并将更多的精力投入到现实性的、探索性的数学活动中去.信息技术与数学课程的整合越来越成为教育领域研究中一个值得关注的话题.1信息技术与数学课程整合的理解信息技术与数学学科的整合,是指信息技术有机地与数学课程结构、课程内容、课程资源以及课程实施等融合为一体,成为数学的有机组成部分,和谐、高效地实…     

试论信息技术与数学课程的整合策略

众所周知 ,以计算机技术为主的现代信息技术已经渗入现代数学的发展 ,不仅影响着数学的形式、内容与方法 ,而且影响着数学课程的建设与实施 .究其因 ,或许是因为“计算机是数学的创造物 ,又是数学的创造者”、“计算机是新的数学模式”、“计算机是具体化了的数学” .信息时代 ,数学课程的建设与实施应当充分发挥信息技术的优势 .本文拟对信息技术与数学课程整合的策略作初步的探索 .1　整合教学模式———根据学习任务的具体性质确定学生取向的数学教学模式　　信息技术介入数学课程领域 ,可以通过新旧数学教学模式的整合促进新数学教学模…     

几何画板中两类函数图象的绘制

普通高中新的<数学课程标准>中指出课程的基本理念之一是"注重信息技术与数学课程的整合".现代信息技术的广泛应用正在对数学课程内容、数学教学、数学学习等方面产生深刻的影响.高中数学课程应提倡实现信息技术与课程内容的有机整合,整合的基本原则是有利于学生认识数学的本质.     

《数学之友》投稿及查询启事

1.《数学之友》2020年选题范围涉及:数学教育基本理论研究、中国数学教育传统及其特征研究、数学核心素养问题研究、数学比较教育研究、中小学数学课程与教学改革的理论与实践研究、现代教育技术与数学课程及教学整合研究、解题的理论与实践研究、中学生数学学习的心理研究等.2.来稿论文务请格式规范、言之有物、有一定的独创性,作者信息要完备(姓名、单位、邮编),来稿一般应有参考文献.     

用信息技术开展"情境——探究"教学模式实验初探

根据《普通高中数学课程标准(实验)》倡导的理念:“高中数学课程应倡导自主探索、动手实践、合作交流、阅读自学等学习数学的方式,注重信息技术与数学课程的整合”,我对“情境——探究”教学模式进行了实验初探.“情境——探究”教学模式是信息技术与课程整合的一种基本模式,包     

信息技术支持下中学数学教学实践与思考

1 何谓信息技术与数学教学的整合 信息技术与数学教学的整合是教育信息化中一个重要的课题.比较而言,信息技术与数学教学的整合要比掌握信息技术的一般技能困难得多.所谓"整合"不是把数学教学整合到信息技术中,而是把信息技术有机地融入数学教学中去支持数学教学.因此,必须考虑结合学科教学的特点才能实现整合.     

浅谈新课标理念下TI图形计算器与几何整合的探索

所谓信息技术与数学课程整合，就是通过数学课把信息技术与数学教学有机地结合起来，将信息技术与数学课程的教与学融为一体，将技术作为一种工具，提高教与学的效率，改善教与学的效果．     

《数学教育技术引论——信息时代的数学教育基础》

著者:王凤春出版:上海教育出版社本书是作者多年从事信息技术与数学整合的研究成果。立足于中学理科教师提升信息技术素养和专业发展的需要,具有理论性、实践性、基础性与时代性。在研究和继承国内外信息技术与数学整合的基础上,借鉴了相关的课程论、学习论及现代教学理论。结合教学实践中的经典案例,论述数学教育技术化的     

《数学之友》投稿及查询启事

1．《数学之友》2014年选题范围涉及：数学教育基本理论研究、中国数学教育传统及其特征研究、数学比较教育研究、中小学数学课程与教学改革的理论与实践研究、现代教育技术与数学课程及教学整合研究、解题的理论与实践研究、中学生数学学习的心理研究等．     

大学数学数字化教学资源建设的探索与实践

随着计算机技术、网络技术的普及,利用先进的计算机技术、多媒体技术、网络技术,实现校园网络化、资源数字化、管理科学化,即教育信息化,已成为高等学校改革的重点.数字化教学资源建设是实现教学手段和教学方法改革的关键,是实现教育信息化的基础.大学数学数字化教学资源在高等学校数学课程建设和教学中正发挥着越来越大的作用.大学数学课程是高等院校中至关重要的基础课程,它包括大学数学类专业(数学与应用数学专业、信息与计算科学专业)的数学课程和非数学类专业数学基础课程.大学生的数学教育是所有专业教育和文化教育中非常基础、重要的…     

ICT integration in mathematics initial teacher training and its impact on visualization: the case of GeoGebra

This case study investigates the impact of the integration of information and communications technology (ICT) in mathematics visualization skills and initial teacher education programmes. It reports on the influence GeoGebra dynamic software use has on promoting mathematical learning at secondary school and on its impact on teachers’ conceptions about teaching and learning mathematics. This paper describes how GeoGebra-based dynamic applets – designed and used in an exploratory manner – promote mathematical processes such as conjectures. It also refers to the changes prospective teachers experience regarding the relevance visual dynamic representations acquire in teaching mathematics. This study observes a shift in school routines when incorporating technology into the mathematics classroom. Visualization appears as a basic competence associated to key mathematical processes. Implications of an early integration of ICT in mathematics initial teacher training and its impact on developing technological pedagogical content knowledge (TPCK) are drawn.     

大学数学与中学数学教学内容衔接研究

数学教育是一个完整的科学体系,对大学数学教育与中学数学教育进行衔接研究具有重要意义,而教学内容的衔接是二者衔接的一个重要方面.本文根据大学数学和中学数学教学中较普遍使用的经典教材,对大学数学和中学数学教学内容从数学符号使用、教学内容重叠、教学内容遗漏三个方面进行详细归纳总结,对于大学数学教学和大学数学教材的编写具有一定借鉴作用.     

“数学模型”课程教学模式的探讨

本文介绍了开设“数学模型”课程在工科院校数学教学改革中的重要性．并讨论如何组织“数学模型”课程的教学．     

立足教育创新瞩目大学数学教育

在回顾我国非数学专业数学教育、教学改革的基础上,对当今的大学数学教育进行了分析和展望.对大学数学教育的地位及作用进行了探讨.认为大学数学教育,要体现教育创新思想,要在改革中求生存,以成绩促发展.     

Mathematics university teachers' perception of pedagogical content knowledge (PCK)

Teaching mathematics in university levels is one of the most important fields of research in the area of mathematics education. Nevertheless, there is little information about teaching knowledge of mathematics university teachers. Pedagogical content knowledge (PCK) provides a suitable framework to study knowledge of teachers. The purpose of this paper is to make explicit the perception of mathematics university teachers about PCK. For this purpose, a phenomenological study was done. Data resources included semi-structured interviews with 10 mathematics university teachers who were in different places of the mathematics university teaching experience spectrum. Data analysis indicated a model consisting of four cognitive themes which are mathematics syntactic knowledge, knowledge about mathematics curriculum planning, knowledge about students' mathematics learning and knowledge about creating an influential mathematics teaching–learning environment. Besides, it was found out that three contextual themes influenced on PCK for teaching mathematics in university levels which were the nature of mathematics subjects, university teachers' features and terms of learning environment.     

Preservice Teachers of High School Mathematics: Success,Failure, and Persistence in the Face of Mathematical Challenges

The goal of this study was to identify variables related to success and resilience in an undergraduate, high school mathematics teacher education program. Over a five‐year period, we tracked the academic performance and achievement motivation goals of multiple cohorts of students. Students who successfully completed their degrees had higher grade point average (GPAs) upon entering the program, earned higher grades in their first college mathematics course, and failed fewer courses than students who left the program or university. Learning and performance motivational goals did not predict success in the program. Performance goals decreased over time. Nearly half the successful students repeated one or more mathematics courses. Ten students completed their degrees, obtained a teaching license, and are teaching despite the need for multiple repetitions of the same mathematics courses. These persistent students did not differ from their peers in motivational goals. Our results suggest that although students with higher GPAs and initial mathematics grades were more likely to complete the program, students who experienced challenges in mathematics courses were able to succeed. We discuss the implications of these results for recruiting, advising, and retention of students in mathematics education programs.     

利用现代教育技术优化高等数学教学

本根据《高等数学》的课程特点，结合现代教育技术的发展以及高等数学课程的教学现状，提出在教学中利用现代教育技术手段优化高等数学课程的教学，以达到现代教育培养综合素质高、应用能力强的复合型人才的总目标。     

Integrating Science and Mathematics Education: Historical Analysis

A number of national science and mathematics education professional associations, and recently technology education associations, are united in their support for the integration of science and mathematics teaching and learning. The purpose of this historical analysis is two‐fold: (a) to survey the nature and number of documents related to integrated science and mathematics education published from 1901 through 2001 and (b) to compare the nature and number of integrated science and mathematics documents published from 1990 through 2001 to the previous 89 years (1901–1989). Based upon this historical analysis, three conclusions have emerged. First, national and state standards in science and mathematics education have resulted in greater attention to integrated science and mathematics education, particularly in the area of teacher education, as evidenced by the proliferation of documents on this topic published from 1901–2001. Second, the historical comparison between the time periods of 1901–1989 versus 1990–2001 reveals a grade‐level shift in integrated instructional documents. Middle school science continues to be highlighted in integrated instructional documents, but surprisingly, a greater emphasis upon secondary mathematics and science education is apparent in the integration literature published from 1990–2001. Third, although several theoretical integration models have been posited in the literature published from 1990–2001, more empirical research grounded in these theoretical models is clearly needed in the 21st century.     

A Longitudinal Look at Attitudes and Perceptions Related to the Integration of Mathematics,Science, and Technology Education

The purpose of this study is to provide an in‐depth analysis of attitudes and perceptions related to the integration of mathematics, science, and technology education of preservice teachers preparing to teach STEM disciplines. Longitudinal data by individual cohort and across 7 years of the Integrated Mathematics, Science, and Technology (MSAT) Program are reported, analyzed, and interpreted to help design and improve preservice teacher education programs and improve teaching and learning in STEM classrooms. Results of quantitative analyses indicate that there was generally no change in preservice teacher attitudes and perceptions related to the value of the integration of mathematics, science, and technology education—they clearly valued integration at the onset and at the completion of the program. However, there was a significant change in preservice teacher attitudes and perceptions related to integration feasibility in terms of inefficiency and difficulty. Implications for teacher education programs include: (a) more exposure to concepts, processes, and skills in STEM that are similar, analogous, complementary, or synergistic; (b) familiarity with instructional strategies and access to resources; (c) deeper understanding of content across STEM; and (d) strategies for collaboration and team work to make integrated instruction time more efficient and less difficult to manage.