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1.
《赤峰学院学报(自然科学版)》2017,(22)
随着我国素质教育方式的不断完善,越来越多新式的教学思路融入到日常教学中来,本文从数学建模的思想和方法分析入手,阐述数学建模在提高学生数学知识水平及数学实际应用方面的能力培养,从而充分激发学生学习数学的兴趣,以教学经验、教材选取、教学计划制定、教学模式选择等多方面,分析数学建模思想及方法在高等数学课程教学中的应用,最终指出高等数学课程改革中,将建模思想融入其中是高等数学教育改革的重点方向. 相似文献
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高等数学课程融入建模思想方法的研究与实践 总被引:1,自引:0,他引:1
范国兵 《湖南科技学院学报》2013,(4):3-5,11
数学建模是数学走向应用的必经之路。分析了财经院校数学建模教学的内涵及在培养现代高级财经人才中的必要性,阐述了高等数学课程教学中融入数学建模思想方法的作用,结合教学实践给出了两个具体的融入数学建模思想方法的案例,并对财经院校高等数学课程融入数学建模思想方法相关问题提出了若干建议。高等数学课程教学中建模思想方法的融入,是财经院校高等数学课程教学改革的突破口和切入点,是提高大学生综合素质和培养创新能力的有效途径。 相似文献
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数学建模思想是指将现实性的问题通过建模,简化为简单的数学问题,并运用数学方法解决问题。高等数学是一门基础课程,也是学生全面发展的重要课程,其承担着培养学生数学素养和核心素养的重任。以数学建模思想为融点,高等数学教学可以创新教学模式,以混合式教学的方式帮助学生更好地解决实际问题,提升学生的创新能力。本文以数学建模思想为基础,探讨了高等数学混合式教学模式,分析数学建模思想在混合式教学模式中的应用。 相似文献
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将数学建模思想融入"高等数学"教材的研究与实践 总被引:5,自引:0,他引:5
文章通过探讨将数学建模思想融入“高等数学“教材的理论与实践,说明了将数学建模思想方法融入到“高等数学“教材中的重要意义,论述了教材渗透的指导思想、原则、方法,充分体现了数学内容的设计以应用为目的,以必需、够用为教学原则的思想. 相似文献
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介绍了数学建模与高等数学相结合的重要性,并通过几个数学建模案例说明如何在高职高专高等数学课程中应用数学建模思想. 相似文献
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高等数学作为高校理工科甚至部分文科专业的基础课程,在培养大学生数学素质和创新能力上起着重要作用。将数学建模思想融入到高等数学的教学实践中,可以有效提高学生应用数学解决实际问题的能力,增强学生的创造欲望和创新精神。本文从高等数学教学的现状出发,探讨了数学建模思想融入高等数学教学的理论意义和实现途径. 相似文献
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数学建模是理论知识与现实问题的桥梁,数学建模思想与高等数学的教学进行恰当融合,是优化教学质量和教学效果的有效方法.本文初步探讨了在高等数学课程教学中,较好地融入数学建模思想的几个实例,培养学生的创新与应用能力. 相似文献
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学习高等数学的目的在于应用数学思想方法解决实际问题,将数学建模思想融入到高等数学教学中,提高学生应用数学知识及方法解决实际问题的能力。本文阐述了在工科院校高等数学教学过程中融入数学建模思想的可行性和必要性,并讨论了融入过程中对数学教师提出的新要求。 相似文献
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本文简单阐述了将数学建模思想融入高等数学课程教学的必要性,并且给出了两个可以融入高等数学课程的数学建模教学案例,让大家了解数学建模思想和高等数学教学相结合的具体实现。 相似文献
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针对高职院校高等数学教学现状,分析在高等数学教学中融入数学建模思想与方法的可行性与必要性,并通过物理化学课程中的实例说明如何在高等数学教学过程中融入数学建模思想与方法。 相似文献
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龚雅玲 《南昌教育学院学报》2012,(4):81+86
数学实验教学的开展使计算机在数学学习中得到应用,由此激发学生的学习兴趣和积极性,让他们知道如何应用数学知识解决实际问题。将数学知识学习与计算机实验操作相结合,充实和发展了高等数学课程的内容及其作用,强化了对学生数学素质、计算机应用能力、创新意识和工程意识的培养。 相似文献
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赵海祥 《佳木斯教育学院学报》2012,(2):228-229
思维能力的培养是数学教学的核心任务,而问题的设计正是学生思维的导火索。在初中数学教学中,如果教师精于"问题设计",不但会影响学生的数学思维方式,而且还会激发学生的数学探究热情。笔者从事初中数学教学工作多年,在问题设计方面做了有益的尝试与探索。 相似文献
13.
张仕清 《廊坊师范学院学报(自然科学版)》2012,12(1):103-106
数学知识的掌握不全是教出来的,而是自己做出来的,数学建模正好是一个学数学、用数学、做数学的过程,它体现了学和用的统一。理论和近年来的教学实践都证明,开展数学建模教学对培养学生的全面素质,对学生进行创新教育,提高学生的创新能力和实践能力,推进和深化高校的教学改革都有重要作用。因此,探讨在大学数学课程教学中渗透数学建模思想的必要性、基本原则、具体措施,是目前大学数学教学研究的必要课题。 相似文献
14.
周祥 《湖北广播电视大学学报》2012,32(9):29-30
数学作为高职院校理工科重要的一门基础课,既为专业基础课和专业课提供了必要的数学知识和数学方法,又在培养具有良好数学素养的各类创新型人才、应用技术型人才方面起着特别重要的作用。针对高职学生的特点,展开关于"在高职数学教学进行操作性教学"的教学尝试,能够在有限的教学时间里,结合学生的个性特质,培养学生既能运用理论、定义等来解决问题,又能利用数学软件来解决数学问题。 相似文献
15.
《The Journal of educational research》2012,105(6):239-347
AbstractIn this article I described the means of identifying teaching behaviors that have cognitive and affective learning effects on students who are taking a course in mathematics. This study was conducted on 50 mathematics teachers who were teaching in the eighth grade. I obtained the data on teaching behaviors through direct systematic observation. Multiple regression was used as the method of analysis. For the cognitive domain, the results showed that effective teaching behaviors are: (a) high-level questions put to a large group of students; (b) probing, followed by a correct student response; (c) teacher waiting after asking a question; (d) successful redirecting; and (e) all forms of positive acknowledgement. Effective teaching behaviors in the affective domain are: (a) all forms of teacher lecture/explanations; (b) probing, followed by correct student response; and (c) all forms of positive acknowledgement. More teaching behaviors have a positive effect on mathematical knowledge than have a positive effect on students’ attitude toward mathematics. 相似文献
16.
Paula Catarino Eva Morais Helena Campos Paulo Vasco 《European Journal of Engineering Education》2019,44(4):449-460
ABSTRACTIn higher education, engineering students have to be prepared for their future jobs, with knowledge but also with several soft skills, among them creativity. In this paper, we present a study carried on with 128 engineering undergraduate students on their understanding of mathematical creativity. The students were in the first year of different engineering first degrees in a north-eastern Portuguese university and we analysed the content of their texts for the question ‘What do you understand by mathematical creativity?’. Data collection was done in the first semester of the academic years 2014/2015 and 2016/2017 in a Linear Algebra course. The results showed that ‘problem solving’ category had the majority of the references in 2014/2015, but not in the academic year 2016/2017 were ‘involving mathematics’ category had the majority. This exploratory study pointed out for ‘problem solving’ and ‘involving mathematics’ categories and gave us hints for teaching mathematics courses in engineering degrees. 相似文献
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郑红卫 《中国教育技术装备》2012,(6):156-157
传统的数学教学模式存在不少弊端,应当充分利用信息资源、网络技术和先进的多媒体设备来探究出一个符合"主导——主体"的教学模式,从而提高课堂教学效率和学生的自主学习能力,激发学生学习数学的兴趣。 相似文献
19.
Kenneth Ruthven 《Educational Studies in Mathematics》1989,20(4):449-467
There is little current use of more exploratory approaches to the teaching and learning of advanced mathematics. This article describes a simple exploratory teaching model, and reports the findings of a small-scale action-research project to implement and evaluate it. There are discussions of student perceptions and attitudes, and of student attainment. The principal findings are that there was no underachievement under the exploratory approach, and that student preferences for routinised mathematical activity and directed teaching style were strongly associated. 相似文献
20.
Although skilled mathematics teachers and teacher educators often “know” when interruptions in the flow of a lesson provide an opportunity to modify instruction to improve students’ mathematical understanding, others, particularly novice teachers, often fail to recognize or act on such moments. These pivotal teaching moments (PTMs), however, are key to instruction that builds on student thinking about mathematics. Video of beginning secondary school mathematics teachers’ instruction was analyzed to identify and characterize PTMs in mathematics lessons and to examine the relationships among the PTMs, the teachers’ decisions in response to them, and the likely impacts on student learning. These data were used to develop a preliminary framework for helping teachers learn to identify and respond to PTMs that occur during their instruction. The results of this exploratory study highlight the importance of teacher education preparing teachers to (a) understand the mathematical terrain their students are traversing, (b) notice high-leverage student mathematical thinking, and (c) productively act on that thinking. This preparation would improve beginning teachers’ abilities to act in ways that would increase their students’ mathematical understanding. 相似文献