Course Outcomes

MA3151: Matrices and Calculus

At the end of the course the students will be able to:

• Use the matrix algebra methods for solving practical problems.
• Apply differential calculus tools in solving various application problems.
• Able to use differential calculus ideas on several variable functions.
• Apply different methods of integration in solving practical problems.
• Apply multiple integral ideas in solving areas, volumes and other practical problems.

PH3151: Engineering Physics

After completion of this course, the students should be able to:

• Understand the importance of mechanics.
• Express their knowledge in electromagnetic waves.
• Demonstrate a strong foundational knowledge in oscillations, optics and lasers.
• Understand the importance of quantum physics.
• Comprehend and apply quantum mechanical principles towards the formation of energy bands.

CY3151: Engineering Chemistry

At the end of the course, the students will be able:

• To infer the quality of water from quality parameter data and propose suitable treatment methodologies to treat water.
• To identify and apply basic concepts of nanoscience and nanotechnology in designing the synthesis of nanomaterials for engineering and technology applications.
• To apply the knowledge of phase rule and composites for material selection requirements.
• To recommend suitable fuels for engineering processes and applications.
• To recognize different forms of energy resources and apply them for suitable applications in energy sectors.

GE3171: Problem Solving and Python Programming Laboratory

On completion of the course, students will be able to:

• CO1: Develop algorithmic solutions to simple computational problems.
• CO2: Develop and execute simple Python programs.
• CO3: Implement programs in Python using conditionals and loops for solving problems.
• CO4: Deploy functions to decompose a Python program.
• CO5: Process compound data using Python data structures.
• CO6: Utilize Python packages in developing software applications.

BS3171: Physics and Chemistry Laboratory

MA3251: Statistics and Numerical Methods

Upon successful completion of the course, students will be able to:

• Apply the concept of testing of hypothesis for small and large samples in real life problems.
• Apply the basic concepts of classifications of design of experiments in the field of agriculture.
• Appreciate the numerical techniques of interpolation in various intervals and apply the numerical techniques of differentiation and integration for engineering problems.
• Understand the knowledge of various techniques and methods for solving first and second order ordinary differential equations.
• Solve the partial and ordinary differential equations with initial and boundary conditions by using certain techniques with engineering applications.

PH3254: Physics for Electronics Engineering

At the end of the course, the students should be able to:

• Know basics of crystallography and its importance for varied materials properties.
• Gain knowledge on the electrical and magnetic properties of materials and their applications.
• Understand clearly of semiconductor physics and functioning of semiconductor devices.
• Understand the optical properties of materials and working principles of various optical devices.
• Appreciate the importance of nanotechnology and nanodevices.

BE3254: Electrical and Instrumentation Engineering

After completing this course, the students will be able to:

• CO1: Explain the working principle of electrical machines.
• CO2: Analyze the output characterizes of electrical machines.
• CO3: Choose the appropriate electrical machines for various applications.
• CO4: Explain the types and operating principles of measuring instruments.
• CO5: Explain the basic power system structure and protection schemes.

EC3251: Circuit Analysis

On successful completion of this course, the student will be able to:

• CO1: Apply the basic concepts of circuit analysis such as Kirchoff's laws, mesh current and node voltage method for analysis of DC and AC circuits.
• CO2: Apply suitable network theorems and analyze AC and DC circuits.
• CO3: Analyze steady state response of any R, L and C circuits.
• CO4: Analyze the transient response for any RC, RL and RLC circuits and frequency response of parallel and series resonance circuits.
• CO5: Analyze the coupled circuits and network topologies.

GE3271: Engineering Practices Laboratory

Upon completion of this course, the students will be able to:

• Draw pipe line plan; lay and connect various pipe fittings used in common household plumbing work; Saw; plan; make joints in wood materials used in common household wood work.
• Wire various electrical joints in common household electrical wire work.
• Weld various joints in steel plates using arc welding work; Machine various simple processes like turning, drilling, tapping in parts; Assemble simple mechanical assembly of common household equipments; Make a tray out of metal sheet using sheet metal work.
• Solder and test simple electronic circuits; Assemble and test simple electronic components on PCB.

EC3271: Circuit Analysis Laboratory

At the end of the course, the student will be able to:

• Design RL and RC circuits.
• Verify Thevinin & Norton theorem KVL & KCL, and Super Position Theorems.

CS3351: Data Structures

At the end of this course, the students will be able to:

• CO1: Define linear and non-linear data structures.
• CO2: Implement linear and non-linear data structure operations.
• CO3: Use appropriate linear/non-linear data structure operations for solving a given problem.
• CO4: Apply appropriate graph algorithms for graph applications.
• CO5: Analyze the various searching and sorting algorithms.

EC3354: Signals and Systems

At the end of the course, the student will be able to:

• CO1: Determine if a given system is linear/causal/stable.
• CO2: Determine the frequency components present in a deterministic signal.
• CO3: Characterize continuous LTI systems in the time domain and frequency domain.
• CO4: Characterize discrete LTI systems in the time domain and frequency domain.
• CO5: Compute the output of an LTI system in the time and frequency domains.

EC3353: Electronic Devices and Circuits

At the end of the course the students will be able to:

• CO1: Explain the structure and working operation of basic electronic devices.
• CO2: Design and analyze amplifiers.
• CO3: Analyze frequency response of BJT and MOSFET amplifiers.
• CO4: Design and analyze feedback amplifiers and oscillator principles.
• CO5: Design and analyze power amplifiers and supply circuits.

EC3352: Digital Systems Design

At the end of the course the students will be able to:

• CO1: Use Boolean algebra and simplification procedures relevant to digital logic.
• CO2: Design various combinational digital circuits using logic gates.
• CO3: Analyse and design synchronous sequential circuits.
• CO4: Analyse and design asynchronous sequential circuits.
• CO5: Build logic gates and use programmable devices.

EC3361: Electronic Devices and Circuits Laboratory

At the end of the laboratory course, the student will be able to understand the:

• CO1: Characteristics of PN Junction Diode and Zener diode.
• CO2: Design and Testing of BJT and MOSFET amplifiers.
• CO3: Operation of power amplifiers.

CS3361: Data Structures Laboratory

At the end of this course, the students will be able to:

• CO1: Implement Linear data structure algorithms.
• CO2: Implement applications using Stacks and Linked lists.
• CO3: Implement Binary Search tree and AVL tree operations.
• CO4: Implement graph algorithms.
• CO5: Analyze the various searching and sorting algorithms.

EC3401: Networks and Security

Upon successful completion of the course the student will be able to:

• CO1: Explain the Network Models, layers and functions.
• CO2: Categorize and classify the routing protocols.
• CO3: List the functions of the transport and application layer.
• CO4: Evaluate and choose the network security mechanisms.
• CO5: Discuss the hardware security attacks and countermeasures.

EC3451: Linear Integrated Circuits

At the end of the course the students will be able to:

• CO1: Design linear and nonlinear applications of OP - AMPS.
• CO2: Design applications using analog multiplier and PLL.
• CO3: Design ADC and DAC using OP - AMPS.
• CO4: Generate waveforms using OP - AMP Circuits.
• CO5: Analyze special function ICs.

EC3492: Digital Signal Processing

At the end of the course students will be able to:

• CO1: Apply DFT for the analysis of digital signals and systems.
• CO2: Design IIR and FIR filters.
• CO3: Characterize the effects of finite precision representation on digital filters.
• CO4: Design multirate filters.
• CO5: Apply adaptive filters appropriately in communication systems.

GE3451: Environmental Sciences and Sustainability

Note: The detailed course outcomes are not explicitly listed in the source text for this subject, though the syllabus units (Environment, Pollution, Renewable Energy, Sustainability) are provided.

EC3461: Communication Systems Laboratory

At the end of the laboratory course, the student will be able to understand the:

• 1: Design AM, FM & Digital Modulators for specific applications.
• 2: Compute the sampling frequency for digital modulation.
• 3: Simulate & validate the various functional modules of Communication system.
• 4: Demonstrate their knowledge in base band signaling schemes through implementation of digital modulation schemes.
• 5: Apply various channel coding schemes & demonstrate their capabilities towards the improvement of the noise performance of Communication system.

EC3462: Linear Integrated Circuits Laboratory

At the end of the course the students will be able to:

• Analyze various types of feedback amplifiers.
• Design oscillators, tuned amplifiers, wave-shaping circuits and multivibrators.
• Design and simulate feedback amplifiers, oscillators, tuned amplifiers, wave-shaping circuits and multivibrators, filters using SPICE Tool.
• Design amplifiers, oscillators, D-A converters using operational amplifiers.
• Design filters using op-amp and perform an experiment on frequency response.