Posts Tagged ‘change’

An education should give students the tools to adapt and prosper in a world characterized by change. In such an environment, technical competence is not enough. Education that prepares children for life must have basic skills for creativity, intellectual curiosity and honest inquiry boost. The progress and development, both personal and social, are dependent on these elements. approach to innovation and progress in the ability to challenge a new way and offer solution. Read articles about Ross Global Academy to get more informations about educations.

Education must also arise if a pluralistic tradition in which different perspectives, ethnicities, religions and perspectives are evaluated not only because it is right and prosper, but also because the pluralism, the climate is more suited for creativity, curiosity and investigation.It should also help to encourage students a variety of views on some fundamental questions of human existence in mind asked: “What is truth?” ”What is reality?” And “What are my duties to others, for my country and to God?” (find education at Ross Global Academy). At the same time strengthen the educational foundations of identity in a way to revive and strengthen them so they can withstand the shock of change.

What students, is not the most important measure for education. The real test is the ability of students and graduates on what they know not to get involved and find a solution. They must also be able to draw conclusions that are the basis for making informed decisions. The ability to make decisions based on sound information to, and use a thorough analysis should be one ofmost important goals for all education efforts. As students develop these skills, they can start with the most important and most difficult step aside: to learn to make decisions within an ethical framework. For all these reasons There is no better investment that individuals, parents and the nation to do so as an investment in training of the highest quality. These investments are taken into account and to keep training the kind of consciousness our social world so urgently needs. Go to Ross Global Academy to get useful informations.



Over the last few decades, the context that calls for philanthropy the world and its problems has changed in ways that make our old approaches to addressing social problems unsatisfactory and often unsuccessful, but  naveen jain has made it. As a result, the structures or mechanisms we have philanthropy, but also governments and multilateral institutions, for example seem increasingly unsuited to the tasks they are being asked to respond to. This is the root of the conceptual crisis we believe surrounds philanthropy today. Many people have sensed this and are trying to respond in many different ways, experimenting with how to be philanthropic and to better use available resources like naveen jain

In theory, the very essence of philanthropy—its flexibility and independence, unconstrained by election cycles and quarterly reports—should position it well to adapt rapidly to change in these ways. The reality, however, is often quite the opposite. The essential strength of philanthropy—that it is a moral choice freely made—has also kept philanthropy as a field from adapting adequately to a changing context. The reason is that few of the usual levers of change can be counted on to improve philanthropy’s collective efforts. Neither attempts to enforce improvements from the top-down through centralized national solutions nor simply “letting a thousand flowers bloom” from the bottom up will suffice.  Read Naveen Jain‘s articles for further informations

The scope of statistics and the recency and place of statistics  in the school curriculum must be considered when discussing the beliefs of teachers involved in statistics education. These beliefs may be very different according to the age and stage of their students. Teachers also have a variety of prior life and academic experience. Some may have formally studied Statistics problems at school and some may not; some may have taken a course in Statistics help as part of their academic teacher training and others may not. For those who have formally studied statistics, their views as a teacher may be closely aligned to their views as a student, especially if they have not been teaching for very long. If, on the other hand, some Statistics tutor/teachers’ encounters with Statistics questions and Statistics answers have been within other disciplines or in everyday life situations then this experience may inform their belief framework. Finally, even if they have completed a statistics course in their pre-service training, the resulting beliefs may vary because of the relative emphases on theoretical statistics, applied statistics, and statistics education issues within the course.  Nowadays  free Statistics help is easily to find on the internet.

With this background in mind, there are a number of domains in which beliefs seem to be significant for teachers and the teaching of statistics in schools. In 1997, Gal et al. proposed some key areas for investigation, such as what teachers believe about statistics itself, the relationship between mathematics and statistics, the place of statistics in the curriculum, what statistics is important for students to learn, and how students learn statistics. The sections that follow examine these questions and some results and speculations will be presented. Shaughnessy (2007, p. 1001), however, points out that despite the years since Gal and colleagues proposed their questions, and despite a reiterated call for work in the area by Batanero, Garfield, Ottaviani, and Truran (2000), very little work has been done. The surveys by McLeod (1992), on students’ beliefs in mathematics more generally, and by Thompson (1992) and Philipp (2007) on teachers’ beliefs, give insights into possible issues, but statistics education is absent from their considerations. There were only a handful of papers on the topic presented at the ICMI/IASE conference in 2008, and what little has been done involves  case studies and/or small or convenience samples. Consequently, results about both teachers’ beliefs in mathematics education and tertiary students’ beliefs in statistics education may provide grounds for speculation about teachers and statistics education. Another section will consider influences on and impacts of beliefs, and belief change.

Given the changing direction and magnitude of support for research sponsored by the federal government and industry, coupled with the increased competition from federal laboratories and international groups, engineering colleges must look for new opportunities to establish collaborative research alliances. Some alliances may be local or regional; others will be “virtual,” that is, national or international alliances established through the emerging global information superhighway.

Regional consortia of engineering colleges, for example, may share research facilities, teaching laboratories and faculty. Faculty tenure might even reside with a consortium and not with the individual institutions. Other types of consortia could combine the resources of universities and industry, universities and federal facilities – such as national laboratories – or a combination of all three. The aim is not to create new bureaucracies and expense, but to facilitate high-quality research and teaching that is both effective and efficient.

The National Science Foundation has taken the lead in funding experiments in research and education resource-sharing, and in creation of virtual research and education teams. Such experiments also should be encouraged through the Engineering Research Center (ERC) and Science and Technology Center (STC) programs. Lessons learned by the NSF Engineering Education Coalitions in creating “virtual” research and education teams should be applied to these experiments.

To ensure high-quality research and education, federal funding for science and technology must be distributed through open competition, based on peer review. To enhance technology transfer and industry-university research partnerships, universities, corporations and federal agencies should ensure they have flexible and negotiable policies governing intellectual property rights.

Federal agencies that fund research and education should explore ways of encouraging educational institutions, research organizations, federal laboratories, and industry to share resources. They should provide special consideration for funding projects that are developed by consortia of institutions.

Federal funding for science and technology should be allocated in open competition, based on peer review.

To enhance technology transfer and industry-university research partnerships, universities, industries, and federal agencies should develop flexible and negotiable policies governing intellectual property rights.

Engineering education today is adapting to the changing context of engineering practice, but more can be done to speed and improve the process. A crucial means of accomplishing needed change is through partnerships with industry, government, and the broader educational communities. The policy statements and action items developed in this project are intended to help ensure that engineering education will be RELEVANT, ATTRACTIVE and CONNECTED well into the next century. Get payday advance for make payment when you buy a book.

Given the national importance of engineering education and the major changes taking place in higher education and society, it is no surprise that in recent years engineering education has stimulated a variety of thoughtful reports. For example, in the late 1980s ASEE published the major study, “Quality of Engineering Education,” and the ASEE Engineering Deans Council produced specific reports on the supply of engineering faculty and students.

In 1991, the National Academies’ National Research Council (NRC) created a Board on Engineering Education, which has conducted a wide-ranging study of the future of engineering education. The Board’s work has included a series of hearings throughout the country and has had a valuable influence on this project.

Those studying engineering education have proposed many ways to make engineering programs more relevant and cost-effective for all students, as well as more attractive to historically underrepresented groups. Their recommendations have created an environment for change and experimentation.

The Action Plan

The aim of this project is to evaluate recommendations of previous studies, combine them with the recommendations of the workshop conducted as part of the present study, and then develop key action items based on a series of policy statements. Because certain key changes in engineering education will be most effective if implemented with the aid of all sectors of the community, this project focuses on action items that require partnerships. Some of the action items are short-term, others longer-term; none is necessarily easy to accomplish. Over the next few years, this project will further refine the action items, assess the accomplishments of engineering colleges toward those goals, and establish a series of milestones for measuring future progress within the engineering education community.

In today’s world and in the future, engineering education programs must not only teach the fundamentals of engineering theory, experimentation and practice, but be RELEVANT, ATTRACTIVE and CONNECTED:

RELEVANT to the lives and careers of students, preparing them for a broad range of careers, as well as for lifelong learning involving both formal programs and hands-on experience;

ATTRACTIVE so that the excitement and intellectual content of engineering will attract highly talented students with a wider variety of backgrounds and career interests, particularly women, underrepresented minorities and the disabled, and will empower them to succeed; and

CONNECTED to the needs and issues of the broader community through integrated activities with other parts of the educational system, industry and government.

Engineering colleges’ ability to make their programs both relevant and attractive will depend, to a large extent, on how well they connect their programs to all community sectors, that is, on how well they build partnerships.

Focusing On Partnerships

While engineering deans are principally responsible for leading engineering education, they work in partnership with their faculties, presidents, senior university administrators, and often, with industry representatives. Such partnerships must also extend to elementary and secondary schools, the broader university, the local community, government and other engineering colleges, and build even closer ties to industry. These sectors make up the broad constituency of engineering education. Collaboration with these groups ensures the vitality and relevance of engineering programs, and enables the sharing of resources in a fiscally-constrained era. Ultimately, engineering colleges ,like their successful counterparts in industry ,must be part of a seamless system that links all of their constituents in education, industry, and the broad public community.

We live in a time of revolutionary change. Not only is the world relying increasingly on technology for economic growth and job development, but the nation is making the difficult transition of refocusing a significant amount of its technology investment from national security to international economic competitiveness. At the same time, we view technology as important in helping solve many difficult societal problems, from creating environmentally-sustainable development and improving communications, to devising more effective and cost-efficient health care systems. Communications developments alone are leading to profound redefinitions of such concepts as “community,” “library,” “corporation,” and even “university.”

Within this technological context, engineers play an ever more significant role. They develop new manufacturing processes and products; create and manage energy, transportation and communications systems; prevent new and redress old environmental problems; create pioneering health care devices; and, in general, make technology work. Through these activities, engineers create a huge potential for the private sector to develop national wealth. As noted by Richard Morrow, past chairman of the National Academy of Engineering, “the nation with the best engineering talent is in possession of the core ingredient of comparative economic and industrial advantage.”

And just as important as their specific technical skills, engineers receive valuable preparation for a host of other careers in such areas as finance, medicine, law and management. These professions require analytical, integrative and problem-solving abilities, all of which are part of an engineering education. Thus, engineering is an ideal undergraduate education for living and working in the technologically-dependent society of the twenty-first century.

Responding to Changing Needs

One of the strengths of engineering education in the United States is the broad spectrum of engineering colleges whose development has been unconstrained by a single, centrally-prescribed mission. The more than 300 colleges of engineering range from highly research-intensive institutions to those that focus largely on undergraduate education, with many variations in between. Even with the considerable differences in missions, undergraduate engineering education programs maintain universal core curriculum content and minimum standards through the Accreditation Board for Engineering and Technology (ABET), a national partnership between academics and practicing engineers. Additionally, most engineering schools have forged close relationships with industry and benefit from annual assessments of their programs by external advisory boards that have strong industry participation.

While U.S. engineering education has served the nation well, there is broad recognition that it must change to meet new challenges. This is fully in keeping with its history of changing to be consistent with national needs. Today, engineering colleges must not only provide their graduates with intellectual development and superb technical capabilities, but following industry’s lead, those colleges must educate their students to work as part of teams, communicate well, and understand the economic, social, environmental and international context of their professional activities. These changes are vital to the nation’s industrial strength and to the ability of engineers to serve as technology and policy decision makers.

Most important, engineering education programs must attract an ethnic and social diversity of students that better reflects the diversity of the U.S. and takes full advantage of the nation’s talents. Not only does the engineering profession require a spectrum of skills and backgrounds, but it should preserve its historical role as a profession of upward mobility.

In response to these needs, engineering colleges throughout the country are experimenting with new approaches to curricula, rethinking traditional teaching modes, and developing innovative ways to recruit and retain students from underrepresented groups. The largest and potentially most revolutionary effort is led by the consortia of colleges funded by the National Science Foundation’s Engineering Education Coalitions program. These national engineering college consortia each include a variety of schools ranging from predominantly undergraduate institutions to the most research intensive. The consortia are working to redesign curricula and improve teaching methodologies, each offering a different perspective and strategy.

While it is too early to gauge the success of the coalitions, they exemplify the engineering education community’s leadership and willingness to adjust to change. We applaud and encourage these efforts, but also stress the importance of including partnerships with industry and government in reformulating engineering education.

What is engineering? What is an engineer?? Although it is a very old activity or trade, engineering is a relatively young academic discipline or profession. Only in recent years has it reached a stage of maturity where some of its defining details and differentiating characteristics can be articulated. Engineering is the endeavor that creates, maintains, develops, and applies technology for societies’ needs and desires. Its origins go back to the very beginning of human civilization where tools were first created and developed. Indeed, a good case can be made for the defining of humans as those animals that create, develop, and understand the significance of technology.

Over time, the part of technology that acts as an extension of human capabilities became the purview of engineering. One can view bicycles, cars, and trains as extensions of walking and running. Airplanes are an extension and application of a bird’s ability to fly transferred to humans. The telegraph, telephone, radio, television, and the internet are extensions of talking, hearing, and seeing. The microscope, telescope, and medical x-ray are also extensions of human sight and vision. Writing, books, libraries and computer data-bases are extensions of human memory and the computer itself is an extension of the human’s brain in doing arithmetic and carrying out logical arguments and procedures. Indeed, looking around your environment in almost any setting, will illustrate just how pervasive technology is. In almost any home or office, there is very little that is truly “natural”; i.e., little that is not created or manipulated by technology. The food that you eat, the utensils that you eat with, the table that you eat off of, the house that you are in, the clothes that you wear, the book that you read, the television that you watch, the telephone that you communicate with, the car that you travel in — these are all technologies created by human cleverness to satisfy human needs. This process of creation is engineering and those who do the creating are practicing engineering, whether they call themselves engineers or not.

Not only is much of the inanimate world created by engineering, part of the living world is also. Almost all crops and agriculturally produced food stuff are “engineered” through selective breeding. The same is true of domestic animals such as pets and animals raised for food or sport. Certainly the dogs, cats, and cattle have not “naturally” evolved to their current state. They have been “created” or “designed” to satisfy human desires or needs. The slow and less exact methods of controlled breeding are being replaced by genetic engineering, tissue engineering, and applications of nanotechnology. We humans have the cleverness to do that. It is the development of the tools, theories, and methods and the understanding of the appropriate sciences and mathematics for that process that is engineering. It is a central part of the history of humanity.

Not only has engineering made our lives easier and longer, it has sometimes made them more terrible and shorter through improving our ability to kill and harm when we wage war. Indeed, military and defense needs have been a historic driver of technological advancement. One of the earliest categorizations of engineering was into military and civilian (or civil) engineering.

Because technology enables and causes change, it and its creators, the engineers, are viewed with mixed feelings. This is especially true in modern (perhaps post-modern) times when the negative side effects (“unintended consequences”) of technology must be addressed.

This note is an attempt to address the question of what engineering is and then that of what an engineer is. It is intended for the general public to better understand just what this thing that has such a profound effect on our individual and collective lives is. The note is intended for the student who is considering becoming an engineer and, therefore, it is for parents and high school and college counselors as well. It is for the university engineering student and professor and for the university administrator. It is for the state and federal governments who fund engineering education and research and the investor who invests in technology. It is for the husband, wife, parent, or child who wants to better understand their spouse, child, or parent. It is for everyone who accepts the argument that a human is a technological animal and that technology has a pervasive effect on our lives.

An important part of this note is the list of references. This collection of short essays is intended to open many topics and ideas, not develop them. A rather long list of references is given to allow the reader to pursue any of the many ideas further.