Introduction-Definition of Robots and Robotics, Various Components of Robotic System, Connectivity / Degrees of Freedom of a Joint, Representation of the Joints, Degrees of Freedom of a System, Classification of Robots, Resolution, Accuracy and Repeatability, , Robot End-Effectors, Classification of Grippers, Application of Robotics and various case studies. Electro-Hydraulic Robotic Systems – Engineering to Experimental Planning for Control, Robotic Mules as Logistic Workhorses.

Robot Kinematics (Forward and Inverse Kinematics)-Representation of an Object in 3-D Space, homogeneous transformation matrix, Representations of Position in Other Than Cartesian Coordinate System, Representation of Transformation, Position Analysis-DH Parameter, DH parameter rules, Forward Kinematics of two Link Planar Robot, Jacobian of two Link Planar Robot, Forward and Inverse Kinematics for 6 DOF Manipulator, Lab activities using various Simulation Software.

Mechanical CAD design- Designing of various robotic mechanical part using CAD software.

  

Design concepts- Transistor, MOSFET (n-channel and p-channel), SCR, Operational Amplifier, filter circuits, AC-DC Conversions, DC-DC conversions- Linear Power Supply basics, Switched Mode Power Supply basics, Buck, Boost and Buck Boost Configurations, Design of Battery charger, Battery Management System, various experiments using simulation software.

Robot drive systems: Electrical Drives – D.C. Servo Motors and Drivers, BLDC Motor and Drivers, Stepper Motor and Drivers Applications and Comparison of all these Drives.

  

Introduction to Linux, File systems, Linux Commands, some important environmental variables, file permissions.

C Programming – data types, operator precedence and associativity, type casting, control statements, loops, library function, pointer, structure, array, preprocessor, union, memory organization, file handling.

Python Programming- Introduction to Python and Basics , Flow Control, Strings, Tuples, Dictionaries, Lists, Functions, File Handling, OOPs in Python, Regular Expressions, Exception Handling, GUI Programming – Tkinter, Database operations with Python, Python Libraries, Plugins, Client-Server Arch, Debugging.

  

Elements of the Input box: environment sensors and human input Device, Switches and push-buttons, keypad, joystick, pointing devices, environment sensors for temperature, light, humidity. Need for analog processing and filtering of sensor outputs, Elements of the Output box: Actuators and human interface elements. LEDs (with multiplexing), LCD, temperature (heating/cooling. Micro-controller based Design Fundamentals - Reset Circuitry, Clocking options with dynamic clock scaling, RTC Interfacing, Watchdog and brownout. Peripheral interfacing -ADC, UART (RS232, RS422, RS485), SPI, I2C, CAN. Timer and counter modes. PWM, Sensor Interfacing with various development board.

Design Tools- Introduction, Part Selection, Schematic Entry, Component Packages and Library Creation, Board Design and Layout. PCB Concept- Design Rules, Vias, Tracks, Pads, Manual and Auto Routing, Gerber File Generation.

   Getting Started with ROS: Functionality and operation of ROS, Installation and Launching of ROS, Creating a catkin workspace,ROS Packages and manifest, ROS Nodes topics and messages, Turtlesim – the first ROS robot simulation, Movement of the turtle by publishing /turtle1/cmd_vel, Movement of the turtle using the keyboard or joystick, Parameter Server of Turtlesim, ROS services to move the turtle, ROS commands summary, Creating First Two-Wheeled ROS Robot (in Simulation),Creating and building a ROS package, Gazebo (Installation, Launching and other activities),Verification a Gazebo model, Viewing the URDF in Gazebo, Tweaking and moving the model around, Other ROS simulation environments, Driving Around with TurtleBot, Introducing TurtleBot 3,Loading TurtleBot 3 simulator software, Launching TurtleBot 3 simulator in Gazebo, Hardware assembly and testing, Loading TurtleBot 3 software (Installation and setup),Networking TurtleBot 3 and the remote computer, Introducing rqt tool solving the real TurtleBot 3,TurtleBot's Odometry, TurtleBot 3 automatic docking, Introducing TurtleBot 3,Loading TurtleBot 3 simulation software, Launching TurtleBot 3 simulation in rviz, Launching TurtleBot 3 simulation in Gazebo, Hardware assembly and testing, Loading TurtleBot 3 software, Networking TurtleBot 3 and the remote computer, Moving the real TurtleBot 3, Navigating the World with TurtleBot

  

Discrete Planning- Introduction and example Forward Search Method Dijkstra's algorithm Bidirectional Search.

Obstacle Avoidance-Bug algorithm, Tangent bug Visibility Graph, Cell Decomposition.

Sensor for Mobile Robots-Sensors, Gyroscope, GPS, Ultrasonic and Optical Position Location, Lab Work etc. Lab experiments with various development boards.

   Introduction Digital Image Processing, Camera basic, Design of Illumination system, Image formation, Image sensors, Image Sampling and quantization, Image type, Image format and pixel relationship, Image Enhancement techniques, Colour models (advantages and disadvantages), Image Segmentation, Image Morphology, Texture Analysis, Image Processing - Hands-on Using Standard Tools.

    Percentage, Profit & Loss, Ratio & Proportion, Average, Mixture & Allegation, Simple Interest & Compound Interest, Number Systems , Series, Cyclicity & Remainders, Data Interpretation, Syllogism, Coding & Decoding, Blood Relations, Seating Arrangements (Linear & Circular), Ages, Puzzles, Time, Speed & Distance, Trains, Boats & Streams, Time & Work, Wages (Man days), Pipes & Cisterns, Clocks, Permutations & Combinations, Probability, Calendar Fundamentals of Communication, The Art of Communication, Personality Development, English Grammar, Correct Usage of English, Common Mistakes in English Communication, Listening Skills, Reading Skills, Writing Skills, Public Speaking, Presentation Skills, Group Discussions, Interpersonal Skills, Personal Interviews