• WK1: A systematic, theory-based understanding of the natural sciences applicable to the discipline and awareness of relevant social sciences.
• WK2: Conceptually-based mathematics, numerical analysis, data analysis, statistics and formal aspects of computer and information science to support detailed analysis and modelling applicable to the discipline.
• WK3: A systematic, theory-based formulation of engineering fundamentals required in the engineering discipline.
• WK4: Engineering specialist knowledge that provides theoretical frameworks and bodies of knowledge for the accepted practice areas in the engineering discipline; much is at the forefront of the discipline.
• WK5: Knowledge, including efficient resource use, environmental impacts, whole-life cost, reuse of resources, net zero carbon, and similar concepts, that supports engineering design and operations in a practice area.
• WK6: Knowledge of engineering practice (technology) in the practice areas in the engineering discipline.
• WK7: Knowledge of the role of engineering in society and identified issues in engineering practice in the discipline, such as the professional responsibility of an engineer to public safety and sustainable development.
• WK8: Engagement with selected knowledge in the current research literature of the discipline, awareness of the power of critical thinking and creative approaches to evaluate emerging issues.
• WK9: Ethics, inclusive behavior and conduct. Knowledge of professional ethics, responsibilities, and norms of engineering practice. Awareness of the need for diversity by reason of ethnicity, gender, age, physical ability etc. with mutual understanding and respect, and of inclusive attitudes.

• PO1: Engineering Knowledge: Apply knowledge of mathematics, natural science, computing, engineering fundamentals and an engineering specialization as specified in WK1 to WK4 respectively to develop solutions for complex engineering problems.
• PO2: Problem Analysis: Identify, formulate, review research literature and analyze complex engineering problems reaching substantiated conclusions with consideration for sustainable development. (WK1 to WK4)
• PO3: Design/Development of Solutions: Design creative solutions for complex engineering problems and design/develop systems/components/processes to meet identified needs with consideration for public health and safety, whole-life cost, net zero carbon, culture, society and environment. (WK5)
• PO4: Conduct Investigations of Complex Problems: Conduct investigations of complex engineering problems using research-based knowledge including design of experiments, modelling, analysis & interpretation of data to provide valid conclusions. (WK8)
• PO5: Engineering Tool Usage: Create, select and apply appropriate techniques, resources and modern engineering & IT tools, including prediction and modelling, recognizing their limitations to solve complex engineering problems. (WK2 and WK6)
• PO6: The Engineer and The World: Analyze and evaluate societal and environmental aspects while solving complex engineering problems for sustainability with reference to economy, health, safety, legal framework, culture and environment. (WK1, WK5, and WK7)
• PO7: Ethics: Apply ethical principles and commit to professional ethics, human values, diversity and inclusion; adhere to national & international laws. (WK9)
• PO8: Individual and Collaborative Team Work: Function effectively as an individual, and as a member or leader in diverse and multidisciplinary teams.
• PO9: Communication: Communicate effectively and inclusively within the engineering community and society at large, including writing effective reports, preparing design documentation, and delivering presentations considering cultural, language, and learning differences.
• PO10: Project Management and Finance: Apply knowledge of engineering management principles and economic decision-making to manage projects and work effectively as a member or leader in multidisciplinary environments.
• PO11: Life-Long Learning: Recognize the need for and have the ability for (i) independent and life-long learning, (ii) adaptability to emerging technologies, and (iii) critical thinking in the context of technological change. (WK8)

PSO1: To prepare the students ready for industry usage by providing required training in cutting edge technologies.

PSO2: An Ability to use the core concepts of Computing and Optimization Techniques to develop more efficient and effective computing mechanisms.

PSO3: Prepare the graduates to Demonstrate a sense of Societal and Ethical Responsibility in their Professional Endeavors and will remain informed and involved as full participants in the profession and our society.

Students gain hands-on experience with microcontrollers (Arduino, Raspberry Pi), IoT platforms (ThingSpeak, Blynk), embedded C, Python, cloud integration, and networking protocols like MQTT and HTTP.

Yes, the department includes a fully equipped IoT lab where students prototype smart applications and build real-time systems using hardware and cloud technologies.

Students work on practical solutions in areas such as smart homes, healthcare monitoring, industrial automation, and environmental sensing—often as part of capstone projects or tech fests.

Graduates can pursue roles like IoT Developer, Embedded Systems Engineer, Firmware Developer, Cloud IoT Analyst, or continue with higher studies in AIoT, robotics, or smart systems.