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About School of Engineering & Technology
The School of Engineering & Technology (SET) is typically a division within a university or college that focuses on education and research in various fields of engineering and technology. These schools offer undergraduate, graduate, and often doctoral programs in disciplines such as:
About School of Engineering & Technology
M.Tech. (All Streams): Master of Technology (M.Tech.) is a postgraduate academic degree program that focuses on advanced specialized engineering knowledge and skills.
M.Tech. in Data Mining/AI/Robotics/Blockchain: These programs specialize in cutting-edge technologies such as Data Mining, Artificial Intelligence (AI), Robotics, and Blockchain, focusing on their applications and advancements.
B.Tech. (All Streams): Bachelor of Technology (B.Tech.) is an undergraduate engineering degree program typically spanning four years of study.
B.Tech. in Data Mining/AI/Robotics/Blockchain: These B.Tech. programs provide specialized training in cutting-edge technologies, preparing graduates for exciting careers in their respective fields and contributing to technological and industry advancements.
Bachelor of Architecture (B.Arch): This professional undergraduate degree program equips students with the knowledge and skills to become licensed architects. It typically spans five years and focuses on architectural design.
B.Tech. (Lateral Entry): This specialized undergraduate engineering degree program is designed for students who have completed a diploma in engineering or a related field, allowing them to enter the program at an advanced stage.
Integrated B.Tech. + M.Tech.: This combined academic offering allows students to pursue both a Bachelor of Technology (B.Tech.) and a Master of Technology (M.Tech.) degree in a streamlined and integrated manner.
B.Tech. + M.B.A.: This program combines the technical expertise of a Bachelor of Technology (B.Tech.) degree with the business acumen and management skills of a Master of Business Administration (M.B.A.) degree.
Polytechnic/Diploma (All Streams): These advanced education options offer technical, practical, and hands-on training in various fields.
Certificate in Engineering (I.T.I.): The Industrial Training Institute (I.T.I.) program provides essential skills and knowledge in various engineering fields, offering hands-on training in areas such as mechanical and electrical engineering.
Industrial Trade Certificate in Household Electrical: This vocational qualification is designed to equip individuals with the skills and knowledge needed to work in the field of household electrical maintenance and repair.
Duration and Eligibility
S.NO | NAME OF PROGRAMME | DURATION | ELIGIBILITY |
---|---|---|---|
1 | M. Tech. (All Stream) | 4 Semesters | B. Tech. In Relevant Stream |
2 | M. Tech In Data Mining/AI/Robotics/Block Chain | 4 Semesters | B. Tech/BE |
3 | B.Tech. (All Stream) | 8 Semesters | 10+2/PCM Engineering |
5 | B.Tech (Data Mining/AI/Robotics/BlockChain) | 8 Semesters | 10+2/PCM |
6 | Bachelor Of Architecture | 10 Semesters | 10+2/PCM |
7 | B.Tech. (Lateral Entry) | 6 Semesters | Diploma |
8 | Integrated B.Tech.+ M.Tech | 10 Semesters | 10+2 / PCM |
9 | B.Tech. + M.B.A. | 10 Semesters | 10+2 /PCM |
10 | Polytechnic/Diploma (All Stream) | 4 Semesters | 10+2(PCM)/ITI |
11 | Polytechnic/Diploma (All Stream) | 6 Semesters | 10th |
12 | Certificate In Engineering (I.T.I.) | 4 Semesters | 10th |
13 | Industrial Trade Certificate In House Hold Electrical | 4 Semesters | 10th |
14 | Industrial Trade Certificate In Motor Winding | 4 Semesters | 10th |
15 | Industrial Trade Certificate In Auto Cad | 4 Semesters | 10th |
16 | Industrial Trade Certificate In CNC Machine | 4 Semesters | 10th |
Key Features of SET:
Curriculum: Includes foundational courses in mathematics, physics, and chemistry, as well as specialized courses in each engineering discipline.
Laboratories: Equipped with advanced technology and equipment for hands-on learning and research.
Research Opportunities: Often involves collaboration with industry, government, and other academic institutions.
Internships and Co-op Programs: Provide students with practical experience in their field of study.
Accreditation: Many programs are accredited by national and international accrediting bodies, ensuring that they meet high standards of education.
Goals and Objectives:
- To provide high-quality education that prepares students for professional engineering careers.
- To conduct cutting-edge research that advances technology and addresses societal needs.
- To foster innovation, creativity, and critical thinking among students and faculty.
- To engage with industry and community partners to solve real-world problems.
Future Scopes
Main Area | Sub-Area | Examples |
---|---|---|
Technological Advancements | Artificial Intelligence & Machine Learning | AI-driven Automation, Predictive Analytics, Natural Language Processing |
Internet of Things (IoT) | Smart Cities, Connected Devices, Industrial IoT | |
Robotics & Automation | Autonomous Vehicles, Industrial Robots, Service Robots | |
Cybersecurity | Advanced Threat Detection, Quantum Cryptography, Secure Communication Systems | |
Educational Innovations | Online and Distance Learning | Virtual Labs, Interactive E-learning Platforms, MOOCs |
Interdisciplinary Programs | Engineering & Business Integration, Biomedical Engineering, Environmental Engineering | |
Research & Development | Collaborative Research Initiatives, Industry-Academia Partnerships, Innovation Hubs | |
Sustainability and Green Technologies | Renewable Energy | Solar Power Innovations, Wind Energy Solutions, Energy Storage Technologies |
Sustainable Engineering | Green Building Design, Sustainable Manufacturing Processes, Waste Reduction Technologies | |
Environmental Engineering | Water Treatment Solutions, Air Quality Monitoring, Climate Change Mitigation Technologies | |
Industry 4.0 | Smart Manufacturing | Digital Twins, Predictive Maintenance, Additive Manufacturing (3D Printing) |
Big Data & Analytics | Data-Driven Decision Making, Real-time Analytics, Data Visualization | |
Advanced Materials | Nanotechnology, Biomaterials, Smart Materials | |
Student Development | Skill Development Programs | Coding Bootcamps, Soft Skills Training, Leadership and Management Workshops |
Entrepreneurship and Innovation | Startup Incubation Centers, Innovation Competitions, Patent Support and IP Management | |
Global Exposure | International Exchange Programs, Global Internships, Collaborative Projects with Foreign Universities | |
Community and Societal Impact | Public Health Engineering | Medical Device Innovations, Telemedicine Technologies, Health Informatics |
Infrastructure Development | Smart Transportation Systems, Sustainable Urban Planning, Disaster Management Technologies | |
Social Responsibility | Community Outreach Programs, Inclusive Education Initiatives, Technology for Rural Development |
FAQ’s on Engineering & Technology
Engineering encompasses various disciplines such as mechanical, electrical, civil, chemical, computer, aerospace, biomedical, and environmental engineering, among others.
Mechanical engineers design, develop, build, and test mechanical and thermal sensors and devices, including tools, engines, and machines.
Electrical engineering deals with the study and application of electricity, electronics, and electromagnetism. It plays a crucial role in the design and development of electrical systems, devices, and circuits.
Some of the latest trends in technology include artificial intelligence (AI), machine learning, Internet of Things (IoT), blockchain, virtual reality (VR), augmented reality (AR), and 5G technology.
Civil engineers design, build, and maintain infrastructure projects such as roads, bridges, dams, buildings, and transportation systems, contributing to the development and improvement of communities.
Renewable energy sources like solar, wind, hydro, and geothermal power are increasingly being adopted as alternatives to fossil fuels due to their sustainability and environmental benefits. The future of renewable energy looks promising with ongoing advancements in technology and increasing global awareness of climate change.
Ethical considerations in technology development include issues such as privacy, data security, fairness, transparency, accountability, and the impact of technology on society and the environment. Engineers and technologists need to consider these ethical implications when designing and implementing new technologies.
Aerospace engineers design, develop, and test aircraft, spacecraft, and related systems and equipment. Their contributions are vital to space exploration missions, including the design and operation of rockets, satellites, space probes, and manned spacecraft.
Challenges in implementing autonomous vehicles include technological limitations, regulatory issues, safety concerns, ethical dilemmas, and public acceptance. Overcoming these challenges requires interdisciplinary collaboration and continuous innovation.
Technology can be used for sustainable development by promoting renewable energy, improving resource efficiency, reducing waste and pollution, enhancing agricultural productivity, providing access to clean water and sanitation, and fostering sustainable urbanization and transportation systems.