Bachelor of Science in Biology (STEM)

at EDUCO - Rose-Hulman Institute of Technology USA

The science of light, once confined to research labs and science fiction novels, has found its way into our everyday lives. The applications of optics can be seen everywhere. A list of more common examples of these applications include laser printers, fiber optic communication, internet switches, fiber optic telephone lines, compact disc players, credit cards bearing holograms, grocery checkout scanners, computers and eye surgery. The field of optics is an enabling technology and is growing at a rapid pace. Optical techniques are found in a wide range of areas such as surveying and construction, measurements of material parameters and deformation, flow measurements, communications, machine vision, laser cutting, drilling and welding, data storage, internet switches, optical computers and sensors etc. Surveys show that there is a growing demand for optical designers/scientists/ engineers every year. Opportunities for graduates in Optical Engineering are available in many industries, including automated inspection, consumer electronics, fiber optic communications, optical instrumentation, laser devices, radar systems, data storage etc.

The Optical Engineering bachelor’s degree program is one of the few in the country. This program provides a firm foundation for those interested in continuing thier studies in optics at the graduate level, as well as for those going into industry. The curriculum was developed by the faculty with input from industrial representatives as well as from renowned national and international optics educators. Because of the diverse applications of optics, the curriculum contains a mix of courses in physics and mathematics as well as humanities and social sciences. The Optical Engineering program at Rose-Hulman stresses laboratory instruction. We also encourage students to look at options for a double major, especially Optical Engineering with electrical, computer or mechanical engineering.

OE Program Educational Objectives

• Our graduates will set their career path and advance beyond their entry-level position or progress toward the completion of an advanced degree.
• Our graduates will make a positive impact on society.
• Our graduates will behave ethically and act as responsible members of the engineering and science community.
• Our graduates will continue to develop professionally

As an engineering design major, you'll tackle design challenges for real-world clients beginning your first quarter on campus. In fact, you'll experience six different design studios by your junior year.

Engineering Design is perfectly suited for today's rapidly changing, global job market. You'll gain critical communication skills, a global perspective, and a comprehensive engineering education, setting you up for a rewarding career in any field.

Some specifics:

• You'll gain a broad understanding of modeling systems, rapid prototyping, computer-aided design, machine shop techniques, electrical circuits, and software programming languages.
• During your second year, you'll choose an area of concentration and learn the process of on-boarding into existing projects as you work with seniors one quarter and freshmen another.
• In your junior year, you'll participate in two 20-week practicums and delve into the design process in your concentration area. The third-year curriculum is structured to allow for an international project and/or cooperative work experiences.
• During your senior year, you'll complete your concentration and participate in a year-long, multidisciplinary capstone design experience.

Computer Engineers (CPE) are electrical engineers that have additional training in the areas of software design and hardware-software integration. Common CPE tasks include writing embedded software for real-time microcontrollers, designing VLSI chips, working with analog sensors, designing mixed signal circuit boards, and designing operating systems. Computer engineers are also well-suited for research in the field of robotics, which relies on using computers together with other electrical systems. Below is a recommended plan of study for CPE.

Computer Engineering graduates shall:

• Practice excellence in their profession using a systems approach encompassing technological, economic, ethical, environmental, social, and human issues within a changing global environment;
• Function independently and in leadership positions within multidisciplinary teams;
• Continue life-long learning by acquiring new knowledge, mastering emerging technologies, and using  appropriate tools and methods;
• Adapt and independently extend their learning to excel in fields about which they are passionate;
• Strengthen teams and communities through collaboration, effective communication, public service, and leadership.

CPE Student Learning Outcomes

At the time of graduation, students will have demonstrated:

• An ability to identify, formulate, and solve complex engineering problems by applying principles of engineering, science, and mathematics
• An ability to apply engineering design to produce solutions that meet specified needs with consideration of public health, safety, and 2018-2019 Criteria for Accrediting Engineering Programs – Proposed Changes 40 welfare, as well as global, cultural, social, environmental, and economic factors
• An ability to communicate effectively with a range of audiences
• An ability to recognize ethical and professional responsibilities in engineering situations and make informed judgments, which must consider the impact of engineering solutions in global, economic, environmental, and societal contexts
• An ability to function effectively on a team whose members together provide leadership, create a collaborative and inclusive environment, establish goals, plan tasks, and meet objectives
• An ability to develop and conduct appropriate experimentation, analyze and interpret data, and use engineering judgment to draw conclusions
• An ability to acquire and apply new knowledge as needed, using appropriate learning strategies.

An increasing number of problems in the biological sciences are being solved using sophisticated mathematical and computational tools. The biomathematics degree blends mathematics, biology, and computer science in preparation for continued graduate studies and for careers in the quantitative life sciences. The degree's mission is to provide a world class undergraduate education in applied mathematics used in support of the life sciences.

The degree's mission is supported and motivated by these facts:

• Biological data is being generated with unprecedented precision and in unfathomable volumes.
• Quantifying biological observations requires mathematical and statistical analysis.
• The basic principles of complex biological systems support mathematical and computational modeling, which can lead to testable hypotheses and new discoveries.

PROGRAM GOALS AND OBJECTIVES
The biomathematics degree will provide a broad based undergraduate experience that

• Prepares students with a rigorous education in applied mathematics,
• Educates students in the fundamental principles of biology,
• Trains students to work in a computational arena,
• Introduces students to several of the sister disciplines of computational biology, mathematical biology, bioinformatics, systems biology, and biostatistics,
• Guides students through an advanced undergraduate research project. The degree will also liberally educate students through the study of the humanities and social sciences. Students of the program will be encouraged to participate in external and internal research programs and industrial internships and/or co-ops.

As an engineering design major, you'll tackle design challenges for real-world clients beginning your first quarter on campus. In fact, you'll experience six different design studios by your junior year.

Engineering Design is perfectly suited for today's rapidly changing, global job market. You'll gain critical communication skills, a global perspective, and a comprehensive engineering education, setting you up for a rewarding career in any field.

Some specifics:

• You'll gain a broad understanding of modeling systems, rapid prototyping, computer-aided design, machine shop techniques, electrical circuits, and software programming languages.
• During your second year, you'll choose an area of concentration and learn the process of on-boarding into existing projects as you work with seniors one quarter and freshmen another.
• In your junior year, you'll participate in two 20-week practicums and delve into the design process in your concentration area. The third-year curriculum is structured to allow for an international project and/or cooperative work experiences.
• During your senior year, you'll complete your concentration and participate in a year-long, multidisciplinary capstone design experience.

An increasing number of problems in the biological sciences are being solved using sophisticated mathematical and computational tools. The biomathematics degree blends mathematics, biology, and computer science in preparation for continued graduate studies and for careers in the quantitative life sciences. The degree's mission is to provide a world class undergraduate education in applied mathematics used in support of the life sciences.

The degree's mission is supported and motivated by these facts:

• Biological data is being generated with unprecedented precision and in unfathomable volumes.
• Quantifying biological observations requires mathematical and statistical analysis.
• The basic principles of complex biological systems support mathematical and computational modeling, which can lead to testable hypotheses and new discoveries.

PROGRAM GOALS AND OBJECTIVES
The biomathematics degree will provide a broad based undergraduate experience that

• Prepares students with a rigorous education in applied mathematics,
• Educates students in the fundamental principles of biology,
• Trains students to work in a computational arena,
• Introduces students to several of the sister disciplines of computational biology, mathematical biology, bioinformatics, systems biology, and biostatistics,
• Guides students through an advanced undergraduate research project. The degree will also liberally educate students through the study of the humanities and social sciences. Students of the program will be encouraged to participate in external and internal research programs and industrial internships and/or co-ops.

Graduates with a degree in chemistry will be well prepared for employment, graduate study in a chemistry-related field, or professional school. Chemists are employed in research, quality control, design, sales and management. Many graduates pursue masters and doctoral degrees in chemistry, biochemistry, medicinal chemistry, materials science, or environmental science, among others. A chemistry degree is excellent preparation for medical school and related fields, and also for careers in business, law or education.

The curriculum at Rose-Hulman Institute of Technology provides a rigorous introduction to all subdisciplines of chemistry. Students have access to modern instrumentation, a new biochemistry lab, and a new environmental chemistry lab. Rose-Hulman students are introduced to modern computational methods beginning in the sophomore year. There are many opportunities for research or other individual projects, and students are encouraged to present their results at regional and national chemistry conferences. Close interaction with engineering departments provides students with a point of view not available at most other undergraduate institutions.

Students may broaden their education by choosing a minor or second major. Many students, including chemistry majors, may be interested in a second major or minor in biochemistry and molecular biology. Other common choices include biology, chemical engineering and mathematics.

Student Outcomes

Student Outcomes are statements that describe what students are expected to have by the time of graduation.

• An ability to design and conduct experiments as well as to analyze and interpret data.
• An ability to recognize the professional and ethical responsibilities of a chemist.
• An ability to communicate effectively in presentations and reports.
• An ability to use the scientific method to investigate chemical systems.
• An ability to conduct chemistry in both academic and industrial settings.

As has been done since we awarded the nation’s first degree in chemical engineering in 1889, the undergraduate program in chemical engineering undertakes to prepare individuals for careers in the chemical process industries. These include all industries in which chemical and energy changes are an important part of the manufacturing process, such as the petroleum, rubber, plastics, synthetic fiber, pulp and paper, fermentation, soap and detergents, glass, ceramic, photographic and organic and inorganic chemical industries. In view of the dynamic nature of this technology, the course of study stresses fundamental principles rather than technical details. It prepares the student either for advanced study at the graduate level or for immediate entrance into industry. Opportunities in the process industries are found in a variety of activities, including design, development, management, production, research, technical marketing, technical service, or engineering.

Mission: The mission of the Department of Chemical Engineering at Rose-Hulman Institute of Technology is to provide an excellent chemical engineering education through a combination of theory and practice that prepares students for productive professional careers including postgraduate studies.

Program Educational Objectives
Program Educational Objectives are broad statements that describe what graduates are expected to attain within a few years of graduation.

• Our graduates will attain a promotion and/or responsibilities beyond their entry-level position, or progress toward the completion of an advanced degree.
• Our graduates will continue to develop professionally.
• Our graduates will collaborate professionally within or outside of their organizations at a regional, national and/or international leve

Software engineering is the creation of software using a process similar to other engineering disciplines. It allows for software to be reliable and developed within time and cost estimates. The software engineering curriculum prepares students for a career in reliable, economical software development.

Programming is only one phase (construction) of software engineering. There are many other aspects of the software engineering process, such as requirements definition, architectural design, and quality assurance, which need to be applied in order to develop reliable software on time and within budget constraints. The software engineering curriculum provides students a solid background in both the theory and practice of all phases in the software engineering process, beginning with their first course of study in the Department of Computer Science and Software Engineering, and continuing to the end of the senior year.

Since software is a non-physical product developed and executed on computers, the software engineering curriculum has computer science as its primary engineering science. The computer science courses taken by software engineering majors include the study of algorithms, data structures, database concepts, computer architecture, programming languages and operating systems. Software engineering majors also complete important courses in other closely related fields, such as discrete mathematics, digital logic design, and engineering statistics.

Software Engineering Student Outcomes

By the time students graduate with a Software Engineering degree from Rose-Hulman, they will be able to:

• An ability to identify, formulate, and solve complex engineering problems by applying principles of engineering, science, and mathematics
• An ability to apply engineering design to produce solutions that meet specified needs with consideration of public health, safety, and welfare, as well as global, cultural, social, environmental, and economic factors
• An ability to communicate effectively with a range of audiences
• An ability to recognize ethical and professional responsibilities in engineering situations and make informed judgments, which must consider the impact of engineering solutions in global, economic, environmental, and societal contexts
• An ability to function effectively on a team whose members together provide leadership, create a collaborative and inclusive environment, establish goals, plan tasks, and meet objectives
• An ability to develop and conduct appropriate experimentation, analyze and interpret data, and use engineering judgment to draw conclusions
• An ability to acquire and apply new knowledge as needed, using appropriate learning strategies.

Biomedical engineers use science, engineering, and mathematics to understand and solve medical problems. We focus on improving people’s quality of life. Biomedical engineers who specialize in biomechanics design and analyze biological systems or medical devices that have to do with forces, stresses, and strains. This includes studying the motions of bodies or joints, fluid flow, the deformation of tissues or materials, and the transport of molecules and chemicals through tissues and across membranes.

Biomedical engineers who specialize in bioinstrumentation use electronics and signal analysis to take measurements from and deliver stimuli to living cells and tissues. Examples include cochlear implants, pacemakers, and patient monitoring equipment. Biomedical engineers who specialize in biomaterials design and study materials to replace, repair, and interact with cells and tissues in the body. Examples include metal, ceramic, polymer, or tissue-engineered implants; these implants can be permanent or biodegradable. The United States Bureau of Labor Statistics has projected that jobs for biomedical engineers will increase by 23% between the years 2014 and 2024.

Biomedical Engineering Student Outcomes

By the time students graduate with an undergraduate Biomedical Engineering degree from Rose-Hulman, they will have:

• An ability to identify, formulate, and solve complex engineering problems by applying principles of engineering, science, and mathematics
• An ability to apply engineering design to produce solutions that meet specified needs with consideration of public health, safety, and welfare, as well as global, cultural, social, environmental, and economic factors
• An ability to communicate effectively with a range of audiences
• An ability to recognize ethical and professional responsibilities in engineering situations and make informed judgments, which must consider the impact of engineering solutions in global, economic, environmental, and societal contexts
• An ability to function effectively on a team whose members together provide leadership, create a collaborative and inclusive environment, establish goals, plan tasks, and meet objectives
• An ability to develop and conduct appropriate experimentation, analyze and interpret data, and use engineering judgment to draw conclusions
• An ability to acquire and apply new knowledge as needed, using appropriate learning strategies.