Track Categories

The track category is the heading under which your abstract will be reviewed and later published in the conference printed matters if accepted. During the submission process, you will be asked to select one track category for your abstract.

Automation is the system that works without the help or interferes of the human, this can be done by the electronic devices, it does not require any continuous monitoring of the operator. This automation technology is used for stabilizing the aircraft and ships, it also deals with the factories which operate mainly with the timing gadgets like heat treating ovens and boilers where the mistakes of the humans can be minimized. Robotics include all the abilities like designing, building, maintaining robots and production of Artificial Intelligence (AI) machines. The robots produced by this technique will fill instead of humans such exploration of deep sea and serving the environment which is not suitable for the earthlings. 

  • Track 1-1Time linked Automation
  • Track 1-2Cloud robotics
  • Track 1-3Cognitive robotics
  • Track 1-4Evolutionary robotics
  • Track 1-5Automated storage and retrieval system
  • Track 1-6Automation technician
  • Track 1-7Cultured neural network
  • Track 1-8Distributed robotics
  • Track 1-9Hyper reactive Robotics
  • Track 1-10Autonomous Vehicles

Flexible Automation has the capability of minimizing the time period for the production of different parts. It is also found in assembly system. Fixed Automation is the method which has an invariant sequence for the production special parts, it does not contain complicated moves. Programable Automation construct equipment which has the capacity to alternate its sequence to manufacture different products. This sequence of operation can be interrupted or can be changed by the set of program codes.

 

  • Track 2-1Autonomous Robot
  • Track 2-2Industrial Automation
  • Track 2-3Flexible manufacturing system
  • Track 2-4Numerical automation
  • Track 2-5Computer process control
  • Track 2-6Automation technician
  • Track 2-7Productivity improving technologies
  • Track 2-8Electromechanical System

Impact on society, automation has increased the rate of production and labour content has been reduced. The price of the product is minimized, and the comfort of the society is increased. Impact on Industry, automation helps the developing industries by eliminating the human trial error and performing the better quality of production. Impact on Business, when automation is included In the flow of work, employee have sufficient time for their work and the concentration in their field of work will be increased.

 

  • Track 3-1Automation benefits in society
  • Track 3-2Automation growth in industry
  • Track 3-3Automaton changes in business
  • Track 3-4Raise in economic growth by Automation
  • Track 3-5Business process automation
  • Track 3-6Data-driven control system
  • Track 3-7Feedforward control

With regards to computerization testing, huge numbers of us accept that it is only a piece of SDLC (Software Development Life Cycle), however to accomplish the best outcomes with mechanization testing, one  must follow the total pattern of robotization testing, known as Automation Testing Life Cycle. In Automation testing life cycle  technique, test configuration is built to depict test endeavours, to give undertaking and test group a structure on the extent of the test program like Deciding the Scope of Test Automation, Choosing the Right Tool for Automation, Test Plan + Test Design + Test Strategy, Setting Up the Test Environment, Robotization Test Script Development + Execution, Investigation + Generation of Test Reports.

 

  • Track 4-1Test case automation flexibility
  • Track 4-2Test management strategy
  • Track 4-3Automation framework implementation
  • Track 4-4Wrapping up
  • Track 4-5Graphical user interface testing
  • Track 4-6Behavior driven development
  • Track 4-7Continuous testing
  • Track 4-8Fuzzing

Robot is a combination of mechanical parts which moves according to the given coding, it can be controlled from external source for by embedding within it. Robots are tough sustainable and helpful for their researchers to do their research, have very complicated moves and responds to the human activity, are very sequential and are used for the manufacturing of parts, are user friendly; it can entertain or help with our daily needs.

 

  • Track 5-1Soft robots
  • Track 5-2Fixed job robots
  • Track 5-3Cartesian and Cylindrical robots
  • Track 5-4Polar Robotic Arm
  • Track 5-5Research purpose Robots
  • Track 5-6Medical purpose robots
  • Track 5-7Industrial purposed robots
  • Track 5-8Industrial purposed robots
  • Track 5-9Robots in Marine Technology

Sensors are the simple parts which are used to command the whole mechanism of the robots by sensing the environment around them. The more sensors we use, more the increase in ability of the robot. Sound sensor, Proximity sensor, Pressure sensor, Navigation sensor, Tilt sensor, Acceleration sensor, Gyroscope, Temperature sensors

 

  • Track 6-1Robotic sensing
  • Track 6-2Programmable Sensors
  • Track 6-3Flexible Sensor
  • Track 6-4Fixed type Sensors
  • Track 6-5Hap-tic technology
  • Track 6-6Robotic sensing
  • Track 6-7Tactile sensor
  • Track 6-8Robot locomotion

Artificial Intelligence is a mimicking mechanism which tends to act like human beings and performs like human brain. it can be used for the problem solving and for many complex mechanisms. AI has been continuously evolving itself by suggesting cure for disease and by taking the role of humans in many fields. AI mechanism is used for the simulation purpose in many fields like medical, aerospace, marine, and also in military.

 

  • Track 7-1Behavior of AI systems
  • Track 7-2Judgement making AI
  • Track 7-3Sense reactive AI
  • Track 7-4Self-awareness AI
  • Track 7-5Competitive AI
  • Track 7-6Outline of robotics
  • Track 7-7Liquid handling robot
  • Track 7-8Glossary of robotics

Weak Artificial Intelligence is used for competing and for answering purpose like chess game in the computer for competing and like Alexa and Siri for answering purpose. This type of AI is also used for time consuming task like calculating and other task which responds much faster than humans. Strong Artificial Intelligence this type of AI is more complex and complicated systems. It tends to be act more or better than humans. Strong AI includes the ability of self-judgement, reason, solving puzzle, communicate, plan and learn. It can be found in self driving cars and hospital room management.

 

  • Track 8-1Ability of AI
  • Track 8-2Simple AI response
  • Track 8-3Q&A response of AI
  • Track 8-4Self-learning AI
  • Track 8-5Cybernetics and Brain Simulation
  • Track 8-6Embodied intelligence
  • Track 8-7Natural language processing
  • Track 8-8Computational intelligence and soft computing
  • Track 8-9Ubiquitous network
  • Track 8-10Robot architectures

Networked Robotics is a region that straddles apply autonomy and system innovation. A robot framework controlled by means of the WWW misuses the Internet organize and henceforth is one acknowledgment of arranged mechanical technology. A lot of field robots that adventure remote systems to share and appropriate undertakings may likewise be viewed as a model of organized mechanical technology. The online robot framework, the Internet robot, the circulated robot engineering and the insight space is on the whole totally different perspectives on organized apply autonomy.

 

  • Track 9-1Tele-Robotics
  • Track 9-2Mobile networked Robotics
  • Track 9-3Operating networked Robotics
  • Track 9-4Artificial neural networks

Machine learning is the ability to automatically learn and to improving itself from experience without being programmed. Here it develops its own programme for the implementation of the particular field that can access data and use it learn for themselves.  The main aim of the machine learning is to allow the computer to learn by itself without intervention of humans or assistance and adjust actions accordingly.

 

  • Track 10-1Re-constructive learning
  • Track 10-2Deep learning
  • Track 10-3Contact learning
  • Track 10-4Statistical learning
  • Track 10-5Vision learning
  • Track 10-6Feature learning
  • Track 10-7Anomaly detection

Exoskeleton Robots is used for the human service purpose, unlike other robots it takes command from the human activities and serves according to that. These robots intend to mimic, augment or enhance the body’s own movements. The application of these are limitless from consumer products to military development. The main application of exoskeleton robots in today’s world is rehabilitation services in medical field, the application in medical field are training muscle movement and assisting in injury recovery. Development of these robots outside of the military field and healthcare sectors focuses on upper or lower body exoskeletons with a specific application. Full body powered exoskeleton are the next step of development.

 

  • Track 11-1External controlled exoskeleton
  • Track 11-2Full power exoskeleton
  • Track 11-3Replacement exoskeleton
  • Track 11-4Recovery exoskeleton
  • Track 11-53D printing in robotics
  • Track 11-6IOT and Globalization
  • Track 11-7Multi-agent system of robotics

Humanoid robots are the next level of mimicking process, it also has the ability to replicate the expression of the human face. They are proficient help robots worked to copy human movement and collaboration. Like all help robots, they offer some benefit via computerizing undertakings such that prompts cost-reserve funds and efficiency. Humanoid robots are a moderately new type of expert help robot. While long-imagined about, they're presently beginning to turn out to be economically reasonable in a wide scope of uses.

 

  • Track 12-1Expression mimicking Humanoid
  • Track 12-2Self-taught Humanoid
  • Track 12-3Fictional Humanoid
  • Track 12-4Partial Humanoid
  • Track 12-5Predictive analytics
  • Track 12-6Human sensing Humanoid
  • Track 12-7Dialog management system
  • Track 12-8Automatic speech recognition

Defence robots are proficient assistance robots that are sent by the military in battle situations. They're regularly planned to upgrade a trooper's current capacities while keeping them out of mischief's way however much as could be expected.Militaries in general addition a strategic bit of leeway using safeguard robots. UAVs, UGVs, USVs, ROVs, AUVs, and others are broadly utilized in the ISR application. Little UAVs are utilized in the military area for the most part to give front line knowledge. Right now, military worldwide never again depend on human scouts and rather utilize little robots, which can remain practically imperceptible to the foe.

 

  • Track 13-1Surface detecting robots
  • Track 13-2Rescuing robots
  • Track 13-3Carriage robots
  • Track 13-4Lethal autonomous weapon
  • Track 13-5Robot ethics
  • Track 13-6Robot combat
  • Track 13-7Network-centric warfare
  • Track 13-8Missile guidance robotics

Automated advancements show up in numerous territories that legitimately influence tolerant consideration. They can be utilized to clean patient rooms and working suites, lessening dangers for patients and restorative staff. They work in research centres to take tests and to move, examine, and store them. This is particularly uplifting news is you have ever had blood drawn by somebody who needed to attempt a few times to locate a "decent vein." The mechanical lab aide can find that vessel and draw the blood with less torment and comfort for the patient.

 

  • Track 14-1Rehabilitation Robotics
  • Track 14-2Pharmacy Automation
  • Track 14-3Telepresence Robotics
  • Track 14-4Disinfection Robotics
  • Track 14-5The Reality of Robot Surrogates
  • Track 14-6Robotics in Surgery

Nanorobotics alludes to the still to a great extent hypothetical nanotechnology building order of structuring and building nanorobots. Nanorobots (nanobots or naiads) are consistently contraptions running in size from 0.1-10 micrometres and worked of nanoscale or nuclear sections. Following this definition even an enormous mechanical assembly, for example, a nuclear power magnifying lens can be viewed as a nanorobotic instrument when designed to perform nanomanipulation. Additionally, macroscale robots or microrobots which can move with nanoscale accuracy can likewise be considered nanorobots.

 

  • Track 15-1Nano bots
  • Track 15-2Tissue repairing Nu-bots
  • Track 15-3Bio-chips
  • Track 15-4Positional nano assembly
  • Track 15-5Nanoelectromechanical systems
  • Track 15-6Nano-motors

Human-Robot Interaction (HRI) is a field of concentrate devoted to getting, planning, and assessing mechanical frameworks for use by or with people. Collaboration, by definition, requires correspondence among robots and people. Correspondence between a human and a robot may take a few structures, however these structures are generally impacted by whether the human and the robot are in nearness to one another or not. With the advances of man-made brainpower, self-ruling robots could be in the long run, have progressively proactive practices, arranging their movement in complex obscure situations. These new capacities keep wellbeing as the essential issue and effectiveness as auxiliary. To permit this new age of robots, investigate is being led on human recognition, movement arranging, scene reproduction, savvy conduct through errand arranging and agreeable conduct utilizing power control (impedance or induction control plans).

 

  • Track 16-1Face detection
  • Track 16-2Telematics of robotics
  • Track 16-3Hap-tic technology
  • Track 16-4Interactive system engineering
  • Track 16-5Computer supported collaboration network
  • Track 16-6Big data analysis

Biohybrid are the next evolution of the robotics which just exists in only imagination, where human being is no longer just biological. In future robots does not contain hard part, the jointed monoliths in the film interstellar are the best recent examples. Biohybrid robot’s evolution of robots which are built with soft robotic parts, built with Artificial Intelligence, adaptable and flexible materials to become more like earthlings. In this field there is a still a step beyond produces energy also like humans

 

  • Track 17-1Biological devices
  • Track 17-2Cyborg
  • Track 17-3Molecular machine
  • Track 17-4Bio inspired robotics
  • Track 17-5Biomimetics
  • Track 17-6Material replacement
  • Track 17-7Self-powered Bio-hybrid