M S Ramaiah Institute of Technology

Vidya Soudha, M.S.R. Nagar, M.S.R.I.T. Post,BANGALORE-560054 (Karnataka) Tel : 080-23606934, 23600822, 23606936, Fax: 080-23603124, , India Estd. 1962 Ownership: Private
Affilated To: Visvesvaraya Technological University(VTU).

M S Ramaiah Institute of Technology Courses


Courses


  • Nursing
    Course Detail

    Bsc Nursing    


    Bachelor of nursing course structures vary at different nursing schools around the world, but will generally last three to four years. Your path to becoming a qualified nurse also varies. The Bsc Nursing programs includes classroom learning and practical sessions. B.Sc. Nursing - Stands for Bachelor of Science Nursing. Typically, a B.Sc. is a three year course, minimum eligibility for which is an intermediate (10+2) in science. Nursing is the branch of medicine that focuses on care of individuals, families, and communities. Subjects usually studied under this are Fundamentals of Nursing, Anatomy, Nutrition, Community Health, Family Welfare, Psychology, Sociology, Surgical Nursing, Gynecological Nursing, Child Health Nursing, Physiology, Microbiology etc. Bachelor of nursing courses is vocational, which means you will directly train to become a qualified nurse at the end of your degree. Teaching will begin with giving you a foundation in the basic knowledge and skills required of all nurses, including how to have a good ‘bedside manner’, observing how patients are responding to treatment, and how to administer medication. The nursing degree will then allow you to apply what you’ve learned in a practical setting such as a hospital ward, and also enable you to specialize in a particular branch of nursing that interests you. 
        
    Msc Nursing    


    M.Sc. Nursing - Stands for Master of Science Nursing. Typically, a M.Sc. is a two year course, minimum eligibility for which is a B.Sc.(Nursing). Nursing is the branch of medicine that focuses on care of individuals, families, and communities. Subjects usually studied under this are Gynecological Nursing, Anatomy, Fundamentals of Nursing, Anatomy, Nutrition, Child Health Nursing, Community Health, Family Welfare, Psychology and Surgical Nursing. 
    A Master of Science in Nursing (MSN) is an advanced-level postgraduate degree for registered nurses and is considered an entry-level degree for nurse educators and managers. The degree also may prepare a nurse to seek a career as a nurse administrator, health policy expert, or clinical nurse leader. The MSN may be used as a prerequisite for doctorate-level nursing education, and used to be required to become an advanced practice registered nurse such as a nurse practitioner, clinical nurse specialist, nurse anesthetist, or nurse midwife.
    This graduate-level degree may focus on one or more of many different advanced nursing specialties such as acute care, adult, family, gerontology, neonatology, palliative care, pediatric, psychiatric, or obstetrics and gynecological nursing.

  • Engineering
    Course Detail

    Engineering


    Engineering is the application of science and math to solve problems. Engineers figure out how things work and find practical uses for scientific discoveries. Scientists and inventors often get the credit for innovations that advance the human condition, but it is engineers who are instrumental in making those innovations available to the world. Engineers design, evaluate, develop, test, modify, install, inspect and maintain a wide variety of products and systems. They also recommend and specify materials and processes, supervise manufacturing and construction, conduct failure analysis, provide consulting services and teach engineering courses in colleges and universities.


    The field of engineering is divided into a large number of specialty areas:

     

    • Mechanical engineering: It involves design, manufacturing, inspection and maintenance of machinery, equipment and components as well as control systems and instruments for monitoring their status and performance. This includes vehicles, construction and farm machinery, industrial installations and a wide variety of tools and devices. 
    • Civil engineering: It involves design, construction, maintenance and inspection of large infrastructure projects such as highways, railroads, bridges, tunnels, dams and airports.
    • Electronics and Communication Engineering: Electronic communications engineering is the utilization of science and math applied to practical problems in the field of communications. Electronic communications engineers engage in research, design, development and testing of the electronic equipment used in various communications systems. It is due to electrical engineers that we enjoy such modern communication devices as cellular telephones, radios and television.
    • Electrical and Electronics Engineering: Electrical and electronics engineers are involved in a wide variety of technology ranging from huge global positioning systems which can pinpoint the location of a moving vehicle to gigantic electrical power generators. These engineers are responsible for designing, developing, testing as well supervising the production of electrical and electronic equipment and machinery. Broadcast and telecommunication systems, electric motors, controls of machinery, lights and wiring in building complexes, vehicles, aircraft, radar and navigation systems, power generation, control and transmission devices which are used by electric utilities are all examples of equipment built by these engineers. They may also work in fields which relate to computers and IT.
    • Computer Engineering: It is the practice of designing computer hardware components, computer systems, networks and computer software.
    • Aeronautical Engineering: It represents the degree of engineering that deals with the research, design, development, construction, testing, science and technology of aircraft. The field also covers investigation into aerodynamic characteristics of aircraft including behavior and related factors such as airfoil, control surfaces, lift and drug.
    • Aerospace Engineering: It involves design, manufacturing and testing of aircraft and spacecraft as well as parts and components such as airframes, power plants, control and guidance systems, electrical and electronic systems, and communication and navigation systems.
    • Nuclear Engineering: It involves design, manufacturing, construction, operation and testing of equipment, systems and processes involving the production, control and detection of nuclear radiation. These systems include particle accelerators and nuclear reactors for electric power plants and ships, radioisotope production and research. Nuclear engineering also includes monitoring and protecting humans from the potentially harmful effects of radiation.
    • Biomedical Engineering: It is the practice of designing systems, equipment and devices for use in the practice of medicine. It also involves working closely with medical practitioners, including doctors, nurses, technicians, therapists and researchers, in order to determine, understand and meet their requirements for systems, equipment and devices.
    • Chemical Engineering: It is the practice of designing equipment, systems and processes for refining raw materials and for mixing, compounding and processing chemicals to make valuable products.
    • Industrial Engineering: It is the practice of designing and optimizing facilities, equipment, systems and processes for manufacturing, material processing, and any number of other work environments.
    • Environmental Engineering: It is the practice of preventing, reducing and eliminating sources of pollution that affect air, water and land. It also involves detecting and measuring pollution levels, determining sources of pollution, cleaning up and rehabilitating polluted sites and ensuring compliance with local, state and federal regulations.

    Particularly, engineers require in-depth knowledge of mathematics, physics and computer applications such as simulations and computer-aided design. This is why most college programs include basic engineering courses in a wide range of topics before students choose to specialize in a particular area.
    Engineering has matured and expanded over the centuries along with our knowledge and understanding of science, mathematics and the laws of physics and their applications. Today, engineers apply both well-established scientific principles and cutting-edge innovations in order to design, build, improve, operate and maintain complex devices, structures, systems and processes.
    It was engineering that brought us out of the caves; it was engineering that took us to the moon; and if we ever make it to the stars, it will be engineering that takes us there. As our knowledge continues to advance, engineers will have new opportunities to find practical uses for scientific discoveries.