The online registration requests for any 'current semester' will be completed before the commencement of SEEs (End of Semester Examinations) of the. A copy of it will be kept with the Head of Department, faculty advisor/counselor and the student. It will be evaluated by the departmental committee consisting of the Head of Department, seminar supervisor and a senior faculty member.
The semester grade point average (SGPA) is calculated by dividing the sum of credit points (CP) secured from all subjects/ courses registered in a semester, by the total
The student will be required to re-appear as a "supplementary student" in the end-of-semester examination as and when available. The corresponding 'credit points' (CP) are calculated by multiplying the grade by the credit points for the particular subject/. CGPA is thus calculated from I year II. semester onwards at the end of each semester according to the formula.
For merit ranking or comparison purposes or any other listing, only the ‘rounded off’
For calculations listed in regulations 9.6 to 9.9, performance in failed subjects/ courses (securing F grade) will also be taken into account, and the credits of such subjects/
Passing standards
After the completion of each semester, a grade card or grade sheet (or transcript) shall be issued to all the registered students of that semester, indicating the letter grades and
Declaration of results
Withholding of results
Transitory regulations
The maximum number of credit points a student can obtain for the award of a degree is the sum of the total number of credit points secured in all regulations of his study, including regulations R16. The student's performance assessment will be made after the exemption of two courses if the total credits obtained ≤ 206, three courses if the total credits gained > 206 (see Regulation R16 for details on the exemption). Note: If a student readmitted under the R16 regulations has not studied any subject/topic in their previous regulations of study which is a prerequisite for further subjects in the R16 regulations, the relevant Heads of Faculty will run supplementary hours to cover these subjects /topics for the benefit of students.
Student transfers
A student in the R09/R13/R15 regulations who has been held back for lack of credit shall be promoted to the next semester of the R16 regulations only after obtaining the required points according to the corresponding regulations for his/her first admission . A student who has passed a subject in accordance with a regulation must pass these subjects in the same regulation. If a student readmitted to the R16 regulations has a subject with 80% of the syllabus in common with his/her previous regulations, that subject in the R16 regulations will be replaced by another subject proposed by the University.
Scope
The student must register for 144 marks and secure 144 marks with CGPA ≥ 5 from II year to IV year B.Tech. Out of the secured 144 marks, the student can obtain exemption of up to 6 marks, i.e. one open elective and one professional elective or two professional electives, resulting in 138 marks for the B.Tech degree performance evaluation. The students who do not fulfill the requirement for the award of the degree for six academic years from the year of admission will lose their place in B.Tech.
Promotion rule
Expulsion from the examination room and cancellation of the performance in the relevant subject only of all students involved. Expulsion from the examination room and cancellation of the performance in the subject in question and all other subjects the student has already met, including practical tests and project work, and is not allowed for the remaining tests in the subjects in the semester/year in question. Students from upper secondary schools, expulsion from the examination hall and cancellation of the performance in the subject in question and everything else.
No Course
Renewable Energy Sources Material Handling Systems Additive Manufacturing CNC Technology Professional Elective - III NT731PE. Open Elective – Students must take open electives from the list of open electives offered only by other departments/branches. For example: - A Mechanical Engineering student can take Open Electives from all other departments/branches, except Open Electives offered by the Mechanical Engineering department.
TECH. III AND IV YEARS S
The Fibonacci sequence is defined as follows: the first and second terms in the sequence are 0 and 1. The next terms are found by adding the previous two terms in the sequence. 8 a) Write a C program that implements the Bubble sort method to sort the given list of integers in ascending order.
Kalam from "Fluency in English - A Course Book for Engineering Students" published by Orient BlackSwan, Hyderabad. Hill from Fluency in English – A Course book for Engineering Students” published by Orient Blackswan, Hyderabad. Chapter titled “Dear Father Father” by Raj Kinger from Fluency in English – A Course book for Engineering Students” Published by Orient BlackSwan, Hyderabad.
Computer Assisted Language Learning (CALL) Lab
Interactive Communication Skills Laboratory: A spacious room with movable chairs and audio-visual aids with a public address system, a T. To provide hands-on experience related to the use of various engineering materials, tools, equipment and processes that are common in the engineering field. It explains the construction, operation, use and application of various work tools, equipment and machinery.
TRADES FOR EXERCISES
Identify and use marking tools, hand tools, measuring equipment and to work within specified tolerances. Practice in the manufacture of components using shop trades including plumbers, assembly, carpentry, foundry, house wiring and welding. Identify and apply appropriate tools for various engineering process occupations including drilling, material removal, measuring, engraving.
TRADES FOR DEMONSTRATION & EXPOSURE
The course will provide an overview of the study of basic knowledge about different materials and their properties, applications. At the end of the course, the student is expected to have knowledge of different materials and their properties. To prepare students, will be broadly educated and will have an understanding of the impact of engineering on society and demonstrate awareness of contemporary issues.
A recognition of the need for and an ability to engage in lifelong learning with the concepts of composite, ceramic and nanomaterials for practical application UNIT – I. Course Objectives: The objective is to study the relative motion, velocity and accelerations of various elements in a mechanism. Recognition of the need for and an ability to engage in self-education and lifelong learning.
Course Outcomes: The primary focus of the Metallurgy and Materials Science program is to provide undergraduate students with a fundamental knowledge-based associated material properties, and their selection and application. A production engineer typically has a broad knowledge of engineering practices and is aware of the management challenges associated with production. Analyze Dynamics of the three-dimensional particle motion in various coordinate systems: Cartesian, natural and cylindrical.
Course objective: To learn the basic types of business, the impact of the economy on business and firms in particular.
METAL CASTING LAB
WELDING LAB
MECHANICAL PRESS WORKING
Course overview: At the end of the course, the student will be able to perform vibration analysis, balancing system and trajectory planning of a robot in a joint space scheme. Determination of the damped natural frequency of vibrations of the vibrating system with different viscous oils. Analyzing the operation of the basic components in the IC motors, compressors and cooling systems.
Understand the combustion process and also how it affects the performance of the combustion engines. Course Outcomes: At the end of the course, the student will be able to: Apply the finite element method to solve problems in solid mechanics, fluid mechanics and heat transfer. Course Outcomes: At the end of the course, the student will be able to: Understand the causes and effects of vibration in mechanical systems.
Course Objective: To apply the principles of thermodynamics to analyze various types of refrigeration and air conditioning systems and to understand the functionality of major components. Course outcomes: At the end of the course, the student should be able to distinguish between different types of cooling systems in relation to the application as well as conventional and non-conventional cooling systems. By the end of the course the student will be able to measure length, depth, diameter using calipers and vernier micrometers.
Analysis and preliminary design of the main systems of conventional fossil fuel steam cycle power plants. Course Outcomes: At the end of the course, the student will be able to understand the basic components of robots. Course outcome: At the end of the laboratory sessions, the student will be able to
TECH. AERONAUTICAL ENGINEERING INTRODUCTION TO SPACE TECHNOLOGY
TECH. AERONAUTICAL ENGINEERING INTRODUCTION TO AEROSPACE ENGINEERING
TECH. AERONAUTICAL ENGINEERING AIR TRANSPORTATION SYSTEMS
TECH. AERONAUTICAL ENGINEERING ROCKETS AND MISSILES
TECH. AUTOMOBILE ENGINEERING DISASTER MANAGEMENT
Organizational Structure for Disaster Management in India – Preparation of State and District Disaster Management Plans. National Disaster Management Plan, Ministry of Home Affairs, Government of India (http://www.ndma.gov.in/images/policyplan/dmplan/draftndmp.pdf).
TECH. AUTOMOBILE ENGINEERING INTELLECTUAL PROPERTY RIGHTS
TECH. AUTOMOBILE ENGINEERING DATA STRUCTURES
Trees - Terminology, Representation of Trees, Binary Tree ADT, Properties of Binary Trees, Binary Tree Representations-Array and Linked Representations, Binary Tree Traversals, Threaded Binary Trees, Max Priority Queue ADT Implementation-Max Heap-Definition, Inserting into a Max Heap Heap, deletion from a Max Heap. Sorting-Insertion sort, Selection sort, Radix sort, Quick sort, Heap sort, Comparison of sorting methods. Search Trees-Binary Search Trees, Definition, Operations- Search, Insertion and Deletion, AVL Trees-Definition and Examples, Insertion into an AVL Tree ,B-Trees, Definition, B-order m, Operations-Insertion and Search, Introduction for red-black and spray trees (definitions and examples for elementary treatment only), comparison of search trees.
Fundamentals of Data structures in C, 2nd Edition, E. Horowitz, S. Sahni and Susan Anderson-Freed, Universities Press. Data Structures and Algorithms made easy in JAVA, 2nd Edition, Narsimha Karumanchi and Career Monk Publications.
TECH. AUTOMOBILE ENGINEERING ARTIFICIAL NEURAL NETWORKS
Self-organizing maps (SOM): two basic feature mapping models, self-organizing map, SOM algorithm, feature map properties, computer simulations, learning vector quantization, adaptive pattern classification.
TECH. AUTOMOBILE ENGINEERING INTRODUCTION TO MECHATRONICS
Electromechanical drives: relays and solenoids - stepper motors - DC brush motors - DC brushless motors - DC servo motors - 4-quadrant servo drives, PWM - pulse width modulation - variable frequency drives, vector drives - drive system load calculation. Programmable Logic Controllers: Basic Structure - Programming: Ladder Diagram - Timers, Internal Relays and Counters - Shift Registers - Master and Skip Controllers - Data Handling - Analog Input/Output - PLC Selection - Application. Programmable motion controllers: Introduction - System transfer function - Laplace transform and its application in differential equation analysis of a control system - Feedback devices: position, velocity sensors - Optical incremental encoders - Proximity sensors: inductive, capacitive, infrared - continuous and discrete processes - Control System Performance and Setup - Digital Controllers - P, PI, PID Control - Control Modes - Position, Speed and Torque - Speed Profiles - Trapezoidal-S.
TECH. AUTOMOBILE ENGINEERING MICROPROCESSORS AND MICROCONTROLLERS
Advanced ARM Processors: Introduction to CORTEX processor and its architecture, OMAP processor and its architecture.
TECH. BIOMEDICAL ENGINEERING RELIABILITY ENGINEERING
Evaluation of network reliability using probability distributions: reliability evaluation of series systems, parallel systems – Partially redundant systems – determination of reliability measure – MTTF for series and parallel systems – Examples. Discrete Markov Chains: Basic Concepts - Stochastic Transition Probability Matrix - Time Dependent Probability Evaluation - Limit State Evaluation - Absorbing States - Examples. Continuous Markov processes: modeling concepts - State space diagrams - Evaluation of the unreliability of one- and two-component repairable systems.
Frequency and Time Techniques: Frequency and duration concepts, application to multistate problems, Frequency balance approach. Approximate System Reliability Evaluation: Series Systems – Parallel Systems- Network Reduction Techniques- Cut Set Approach- Common Mode Failure Modeling and Evaluation Techniques- Examples.
TECH. BIOMEDICAL ENGINEERING MEDICAL ELECTRONICS
TECH. BIOMEDICAL ENGINEERING TELEMETRY AND TELECONTROL
Telecontrol Methods and Applications of Telemetry and Remote Control – by Swoboda G., Reinhold Publishing Corp., London, 1991.
TECH. BIOMEDICAL ENGINEERING
