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Fees
₹8,00,000
Placement
95.0%
Avg Package
₹7,00,000
Highest Package
₹15,00,000
Fees
₹8,00,000
Placement
95.0%
Avg Package
₹7,00,000
Highest Package
₹15,00,000
Seats
120
Students
1,200
Seats
120
Students
1,200
The Civil Engineering program at TRINITY INSTITUTE OF TECHNOLOGY AND RESEARCH is structured over 8 semesters, combining foundational science subjects with specialized core courses and departmental electives. The curriculum emphasizes practical learning through hands-on laboratory work, real-world projects, and industry exposure.
| Semester | Course Code | Course Title | Credits (L-T-P-C) | Prerequisites |
|---|---|---|---|---|
| 1 | CE101 | Engineering Mathematics I | 3-1-0-4 | - |
| 1 | CE102 | Engineering Physics | 3-1-0-4 | - |
| 1 | CE103 | Chemistry for Engineers | 3-1-0-4 | - |
| 1 | CE104 | Engineering Graphics and Design | 2-1-0-3 | - |
| 1 | CE105 | Introduction to Civil Engineering | 2-0-0-2 | - |
| 1 | CE106 | Computer Programming for Engineers | 3-0-2-4 | - |
| 1 | CE107 | Environmental Science | 2-0-0-2 | - |
| 2 | CE201 | Engineering Mathematics II | 3-1-0-4 | CE101 |
| 2 | CE202 | Mechanics of Materials | 3-1-0-4 | CE102 |
| 2 | CE203 | Surveying and Geomatics | 3-1-0-4 | CE104 |
| 2 | CE204 | Construction Materials | 3-1-0-4 | CE103 |
| 2 | CE205 | Fluid Mechanics | 3-1-0-4 | CE101 |
| 2 | CE206 | Engineering Economics | 2-0-0-2 | - |
| 3 | CE301 | Structural Analysis I | 3-1-0-4 | CE202, CE205 |
| 3 | CE302 | Geotechnical Engineering I | 3-1-0-4 | CE204 |
| 3 | CE303 | Hydrology and Irrigation Engineering | 3-1-0-4 | CE205 |
| 3 | CE304 | Transportation Engineering I | 3-1-0-4 | CE203 |
| 3 | CE305 | Water Resources Engineering | 3-1-0-4 | CE205 |
| 3 | CE306 | Construction Technology and Management | 3-1-0-4 | CE204 |
| 4 | CE401 | Structural Analysis II | 3-1-0-4 | CE301 |
| 4 | CE402 | Geotechnical Engineering II | 3-1-0-4 | CE302 |
| 4 | CE403 | Transportation Engineering II | 3-1-0-4 | CE304 |
| 4 | CE404 | Environmental Engineering I | 3-1-0-4 | CE205 |
| 4 | CE405 | Design of Concrete Structures | 3-1-0-4 | CE301 |
| 4 | CE406 | Advanced Engineering Mechanics | 3-1-0-4 | CE202 |
| 5 | CE501 | Steel Structures | 3-1-0-4 | CE401 |
| 5 | CE502 | Foundation Engineering | 3-1-0-4 | CE402 |
| 5 | CE503 | Hydraulic Structures | 3-1-0-4 | CE303 |
| 5 | CE504 | Urban Planning and Development | 2-0-0-2 | - |
| 5 | CE505 | Project Management | 3-1-0-4 | CE206 |
| 5 | CE506 | Smart Infrastructure Technologies | 3-1-0-4 | CE206 |
| 6 | CE601 | Advanced Structural Design | 3-1-0-4 | CE501, CE502 |
| 6 | CE602 | Environmental Engineering II | 3-1-0-4 | CE404 |
| 6 | CE603 | Advanced Transportation Systems | 3-1-0-4 | CE403 |
| 6 | CE604 | Disaster Risk Reduction | 2-0-0-2 | - |
| 6 | CE605 | Sustainable Development Practices | 3-1-0-4 | - |
| 6 | CE606 | Research Methodology | 2-0-0-2 | - |
| 7 | CE701 | Capstone Project I | 4-0-0-4 | CE601, CE602, CE603 |
| 7 | CE702 | Advanced Topics in Civil Engineering | 3-1-0-4 | - |
| 7 | CE703 | Internship | 4-0-0-4 | - |
| 8 | CE801 | Capstone Project II | 6-0-0-6 | CE701, CE702 |
| 8 | CE802 | Thesis Research | 6-0-0-6 | - |
| 8 | CE803 | Professional Ethics and Leadership | 2-0-0-2 | - |
These courses are designed to provide students with in-depth knowledge in specialized areas of civil engineering, enabling them to pursue advanced research or industry roles:
This elective introduces students to the integration of IoT, AI, and BIM in civil infrastructure systems. Students will learn how to design smart buildings, bridges, and transportation networks using real-time data analytics and sensor technologies. The course emphasizes practical applications through hands-on projects involving drone surveys, wireless sensor networks, and building automation systems.
This advanced course explores strategies for designing infrastructure that can withstand extreme weather events and climate change impacts. Topics include flood modeling, sea-level rise adaptation, heat island mitigation, and sustainable urban drainage systems. Students will work on case studies from regions affected by natural disasters, applying engineering principles to create resilient structures.
This elective focuses on complex foundation design issues such as deep foundations, pile groups, and foundation-soil interaction problems. Students will learn about advanced analysis methods, including finite element modeling, and gain practical experience through laboratory testing of soil samples and model foundation experiments.
This course addresses the challenges of urban transportation in rapidly growing cities. Students will study traffic flow theory, public transit systems, ride-sharing platforms, and smart mobility solutions. The curriculum includes field visits to major metropolitan areas and simulations using traffic modeling software to predict congestion patterns.
This course delves into the development and application of eco-friendly construction materials such as recycled aggregates, bio-composites, and self-healing concrete. Students will conduct experiments in lab settings, evaluate material performance, and explore lifecycle assessment methods for sustainable building practices.
This cutting-edge elective teaches students how to create virtual replicas of physical structures using data from sensors, satellite imagery, and simulation software. The course covers modeling techniques, real-time monitoring systems, predictive maintenance strategies, and applications in infrastructure asset management.
Focused on protecting coastal communities from erosion, flooding, and storm surges, this course examines wave mechanics, sediment transport, and coastal defense structures. Students will analyze real-world coastal projects and design solutions for vulnerable shoreline environments.
This elective provides a comprehensive understanding of water treatment processes, monitoring systems, and regulatory compliance in environmental engineering. Students will learn about advanced oxidation techniques, membrane filtration, and emerging contaminants in water supplies through laboratory experiments and site visits.
This course covers methodologies for assessing risks associated with infrastructure failures, natural hazards, and human factors. Students will study probabilistic risk analysis, fault tree analysis, and Monte Carlo simulations to evaluate potential consequences of engineering decisions.
This course focuses on designing resilient infrastructure that can withstand disasters such as earthquakes, hurricanes, and floods. Students will learn about emergency response planning, post-disaster recovery strategies, and community resilience building techniques, supported by case studies from recent catastrophic events.
The department places significant emphasis on project-based learning to ensure students gain practical experience in real-world engineering scenarios. The curriculum includes mandatory mini-projects in the second year and a comprehensive final-year thesis or capstone project.
Mini-projects are assigned at the beginning of each semester, with topics chosen from current industry challenges. These projects typically involve small teams (3-5 students) working under faculty supervision for 6-8 weeks. Evaluation criteria include technical feasibility, innovation, teamwork, and presentation quality.
The final-year capstone project is a multi-phase endeavor spanning two semesters. Students select their project topics based on their interests and available industry collaborations. Each student works closely with a faculty mentor to develop a detailed proposal, conduct research or fieldwork, and present findings in both written and oral formats. The projects often result in published papers, patents, or commercial products that benefit society.
