工程科学理学学士

生物工程学是物理科学和生命科学的交汇处，它结合了物理学和化学原理来理解生命系统的运行。与其他工程领域一样，该方法是高度定量的：数学分析和建模用于捕获从亚细胞到生物规模的系统功能。通过生物医学工程学以及更广泛的工程学教育，学生可以将抽象的假设和科学知识转化为工作系统（例如，修复设备，成像系统和生物制药）。工程科学学士学位的BE轨道课程要求20个半课程。工程科学SB-生物工程轨道的学习计划表提供了易于掌握的浓缩要求摘要。宣布时，每个学生的批准的学习计划的副本将提交给学术计划办公室，并由学生及其集中顾问每年进行
Engineering innovation has long played a critical role in enhancing social progress and bringing about an improved quality of life. Within the past 50 years, the pace and impact of innovation have increased dramatically, facilitating modern health, energy, transportation, communications, and computational infrastructures that knit together the countries of the world. At the same time, engineering innovation has enabled dramatic advances in basic science. Imaging and manufacturing structures at the nanoscales, near-lossless transmission of information, and unprecedented levels of computational power have led to fantastic new discoveries. These types of technologies, for instance, have allowed us to decode the genome, understand the formation of galaxies, and make correlations between social networks and underlying human psychology. In the 21st century, rapid and efficient access to the new innovations, necessary to tackle today's myriad challenges, has become even more imperative. Equally important is the need to educate both those who will be future engineering innovators and those who will use those innovations, deploy them, and make critical legal and political decisions about them. Engineering has evolved over the years to not only dive deeply into specific fields, but also to seek out solutions to real-world problems by combining concepts from a broad range of scientific inquiries and innovations. For example, robotics is a highly interdisciplinary field that straddles multiple traditional engineering disciplines such as mechanical, electrical, and materials engineering and computer science. While roboticists have traditionally been trained in specific engineering disciplines, next generation roboticists must tackle large complex systems comprising multiple parts that span myriad disciplines-from the mechanical underpinnings of the physical device, to electronic control, materials properties, and high-level algorithms-all of which must work in concert to achieve broad-level objectives while adhering to numerous constraints. Alternative energy is another growing and immensely important field that requires integration of solutions across a wide range of science and engineering disciplines. Topics range from understanding the inherent properties of materials and devices that harness the sun's rays to thinking about challenges associated with large-scale production and distribution of electricity and addressing both the societal and environmental impacts of new technologies. The Engineering Sciences concentration is ideally positioned to provide students with both the breadth and depth of study needed to excel in these and other exciting integrative areas of engineering within the liberal arts setting of Harvard.