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Manufacturing : 3D Printing, Robotics & Automation, will be organized around the theme “Exploring new technologies and innovations in manufacturing”

Advanced Manufacturing 2020 is comprised of 20 tracks and 65 sessions designed to offer comprehensive sessions that address current issues in Advanced Manufacturing 2020.

Submit your abstract to any of the mentioned tracks. All related abstracts are accepted.

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\r\n Robotics is the branch of technology that deals with the design, construction, operation, and application of robots and the use or introduction of automatic equipment in a manufacturing or other process or facility is automation.

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\r\n Related Journals of Robotics: Journal of Operations Management, MIS Quarterly: Management Information Systems, IEEE Communications Magazine, IEEE Wireless Communications, Wiley Interdisciplinary Reviews: Computational Molecular Science, IEEE Transactions on Industrial Electronics, Enterprise Information Systems, IEEE Transactions on Information Theory

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\r\n Telerobotics is the area of robotics concerned with the control of semi-autonomous robots from a distance, chiefly using Wireless network (like Wi-Fi, Bluetooth, the Deep Space Network, and similar) or tethered connections. It is a combination of two major subfields, teleoperation and telepresence

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\r\n Related Journals of Tele Robotics: IEEE Transactions on Fuzzy Systems, Journal of the ACM, IEEE Transactions on Industrial Electronics, Information Sciences, IEEE Transactions on Systems, Man, and Cybernetics, Part B: Cybernetics, IEEE Transactions on Automatic Control, IEEE Transactions on Industrial Informatics, Automatica, Journal of Machine Learning Research, Automobile Engineering Journals, Electrical & Electronic Journals, Lovotics Journals, Mechanical Engineering Journals

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\r\n Robotic Rehabilitation is a field of research described to understanding and augmenting rehabilitation through the application of robotic devices. Rehabilitation robotics includes development of robotic devices tailored for assisting different sensor motor functions.

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\r\n Related Journals of Robotics Rehabilitation: IEEE/ASME Transactions on Mechatronics, IEEE Transactions on Robotics, IEEE Transactions on Computational Intelligence and AI in Games, IEEE Transactions on Industry Applications, Mechanical Systems and Signal Processing, IEEE Transactions on Control Systems Technology, Annual Reviews in Control, Journal of Guidance, Control, and Dynamics, Automobile Engineering Journals, Electrical & Electronic Journals, Lovotics Journals, Mechanical Engineering Journals

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\r\n Neurorobotics are the robotic devices that have control systems based on principles of the nervous system. These models operate on the premise that the “brain is embodied and the body is embedded in the environment.

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\r\n Related Journals of Neuro Robotics Foundations and Trends in Machine Learning, IEEE Transactions on Pattern Analysis and Machine Intelligence, International Journal of Computer Vision, ACM Transactions on Intelligent Systems and Technology, IEEE Transactions on Fuzzy Systems, Journal of the ACM, IEEE Transactions on Neural Networks and Learning Systems, Information Sciences, Automobile Engineering Journals, Electrical & Electronic Journals, Lovotics Journals, Mechanical Engineering Journals

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\r\n Replacing humans with robots in personal assistance tasks is one of the more prominent goals of Medical robotics. In addition to promoting the right to health care, these robotic systems may bring about novel ways of protecting the dignity of both patients and their human assistants, by taking on unpleasant tasks (e.g., house cleaning), and allowing disabled or elderly people to perform basic everyday tasks (e. g., cooking, eating or self-cleaning tasks) without having to rely on human assistance.

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\r\n Related Journals of Medical Robotics: Annual Review of Biophysics,Quarterly Reviews of Biophysics, Biochimica et Biophysica Acta - Gene Regulatory Mechanisms, Biomaterials, Biochimica et Biophysica Acta  Bioenergetics, Biophysical Journal, Structural Health Monitoring, Biosensors and Bioelectronics, Automobile Engineering Journals, Electrical & Electronic Journals, Lovotics Journals, Mechanical Engineering Journals

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\r\n Lovotics, as a discipline, aims to elevate the Social Robotics and Human Robot Interaction towards affection and friendship between the robot and the human partner. The aim of the journal is to serve as a platform for researchers across the world to share their latest research, development and innovation in the field of Lovotics, for the benefit of the robotics community and with the vision to contribute for the betterment of the society.

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\r\n friendship between the robot and the human partner. The aim of the journal is to serve as a platform for researchers across the world to share their latest research, development and innovation in the field of Lovotics, for the benefit of the robotics community and with the vision to contribute for the betterment of the society.Intelligent robotics are the robots that functions as an intelligent machine, that is, it can be programmed to take actions or make choices based on input fromsensors.

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\r\n Related Journals of Lovotics, as a discipline, aims to elevate the Social Robotics and Human Robot Interaction towards affection and Intelligent robotics: Nature Nanotechnology, IEEE Communications Surveys and Tutorials, Digest of Technical Papers IEEE International Solid-State Circuits Conference, IEEE Journal of Solid-State Circuits, IEEE Communications Magazine, IEEE Wireless Communications, IEEE Journal on Selected Areas in Communications, Automobile Engineering Journals, Electrical & Electronic Journals, Lovotics Journals, Mechanical Engineering Journals

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\r\n An industrial robot is defined as an automatically controlled, reprogrammable, multipurpose manipulator programmable in three or more axes.

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\r\n Related Journals of Industrial Robotics: International Journal of Machine Tools and Manufacture, International Journal of Production Economics, Production and Operations Management, CIRP Annals - Manufacturing Technology, IEEE Industrial Electronics Magazine, International Journal of Robust and Nonlinear Control, Automobile Engineering Journals, Electrical & Electronic Journals, Lovotics Journals, Mechanical Engineering Journals

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\r\n Biomechanics relationship between external forces (e.g. body weight and external environment) and internal forces (e.g. active forces generated by muscle contraction and passive forces exerted on local structures by bones and joints) and the resultant effect of these forces on body movement. Biomechanics is the study of the structure and function of biological systems such as humans, animals, plants, organs, and cells by means of the methods of mechanics.

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\r\n Most Behavior-based systems are also reactive, which means they need no programming of internal representations of what a chair looks like, or what kind of surface the robot is moving on. Instead all the information is gleaned from the input of the robot's sensors. The robot uses that information to gradually correct its actions according to the changes in immediate environment. Behavior-based robots (BBR) usually show more biological-appearing actions than their computing-intensive counterparts, which are very deliberate in their actions. A BBR often makes mistakes, repeats actions, and appears confused, but can also show the anthropomorphic quality of tenacity. Comparisons between BBRs and insects are frequent because of these actions. BBRs are sometimes considered examples of weak artificial intelligence, although some have claimed they are models of all intelligence.

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\r\n 3D printing is a form of Additive manufacturing is a process of making three dimensional solid objects by laying down successive layers of material from a digital file. It is also known as rapid prototyping. According to Standard Terminology for Additive Manufacturing Technologies, The American Society for Testing and Materials (ASTM) group “ASTM F42 – Additive Manufacturing” developed a set of standards that classify the Additive Manufacturing processes into some categories.

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  • Track 11-1Stereolithography
  • Track 11-2Fused deposition modelling
  • Track 11-3Selective laser sintering
  • Track 11-4Multi-jet modelling
  • Track 11-5Electronic beam melting
  • Track 11-6Selective laser melting
  • Track 11-7Digital light processing
  • Track 11-8Laminated object manufacturing
  • Track 11-9Powder bed and inkjet head 3D printing
  • Track 11-10Composites Manufacturing

\r\n 3D Printing is moving in several directions as of now and all signs are that it will keep on expanding in numerous ranges later on. The absolute most encouraging zones incorporate medical applications, custom parts substitution, and customized buyer items. As materials enhance and expenses go down, different applications we can barely imagine today will become possible.

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  • Track 12-1Directed energy deposition
  • Track 12-2Sheet lamination
  • Track 12-3Material Extrusion
  • Track 12-4Vat photo polymerization
  • Track 12-5Material jetting
  • Track 12-6Binder jetting
  • Track 12-7Powder bed fusion

\r\n 3D Bio printing is the way towards making cell designs in a restricted space utilizing 3D printing technology, where cell capacity and viability are saved inside the printed build. 3D bioprinting adds to huge advances in the medicinal field of tissue engineering by allowing for research to be done on innovative materials called biomaterials. In bioprinting, there are three major types of printers that have been utilized. These are inkjet, laser-assisted, and extrusion printers. 3D Bio printers are streamlined to have the capacity to print skin tissue, heart tissue, and veins among other essential tissues that could be appropriate for surgical treatment and transplantation

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  • Track 13-1Rapid prototyping
  • Track 13-23D Bioprinting of Tissues and Organs
  • Track 13-3Skin 3D Bioprinting
  • Track 13-43D bioprinting of Neural stem
  • Track 13-53D bioprinting of Cell-Laden Microcarriers
  • Track 13-63D bioprinting of human chondrocytes
  • Track 13-7Bioprinting of 3D hydrogels
  • Track 13-83D bioprinting of cartilage
  • Track 13-93D bioprinting of Ear
  • Track 13-103D bioprinting of Aortic valves

\r\n 3D bio printing is the process of making cell designs in a bound space utilizing 3D printing technologies, where cell capacity and suitability are saved inside the printed build. 3D bioprinting contributes to huge advances in the medical field of tissue engineering by taking into account research to be done on inventive materials called biomaterials. Biomaterials are the materials adjusted and utilized for printing three-dimensional articles. Some of the most prominent bioengineered substances are normally stronger than the normal real materials, including soft tissue and bone. These constituents can act as future substitutes, even upgrades, for the original body materials

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  • Track 14-1Tissue engineering
  • Track 14-23D Bio plotting
  • Track 14-3Cell encapsulation
  • Track 14-4Photo polymerization
  • Track 14-5Biodegradable and bioresorsable polymers

\r\n 3D printing, or additive manufacturing, has been the concentration of some solid talks in the manufacturing industry in the most recent couple of years. While the idea of 3D printing has been around for some time, new progressions in the innovation have begun to bring down the cost of the procedure to levels that make it more achievable for general manufacturing use. The procedure of utilizing specialized equipment to gather an object layer by layer has some one of a kind and fascinating points of interest over traditional manufacturing.

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  • Track 15-1Material cost savings
  • Track 15-2Improvement to incremental cost calculations
  • Track 15-3Strategy transformation

\r\n 3D Printing, whether at an Industrial, local or individual level, brings a large group of advantages that conventional strategies for fabricate (or prototyping) simply can't. 3D Printing forms take into account mass customisation — the capacity to customize items as per individual needs and prerequisites. When you utilize a 3D printer over more conventional manufacturing Processes, the list of coming about advantages is entirely long. From significant cost investment funds and quicker generation times to more imaginative opportunity and a diminished carbon impression, there is no deficiency of focal points with these manufacturing methods. A 3D printer diminishes your overhead expenses altogether, and in more ways than one. Initially, it eliminates material expenses. Rather than utilizing a major square of plastic, metal or other material and removing the product out of it we can utilize just the materials totally essential for the construct (added substance producing). This not just cuts your forthright expenses for materials, it also reduces the funds you'd typically spend on transporting and discarding that waste.

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  • Track 16-1Quick production
  • Track 16-2Cheap Manufacturing
  • Track 16-3Better quality
  • Track 16-4Less waste
  • Track 16-5Accessibility
  • Track 16-6Sustainability
  • Track 16-7New shapes and structures
  • Track 16-8New combinations of materials
  • Track 16-9New business models

\r\n Metal 3D printing also known as Metal Additive Manufacturing (AM) and Direct Metal Laser Sintering (DMLS) is the procedure by which parts are fabricated by a laser fusing together high performance metals, layer by layer. Metal printing processes like powder bed fusion, metal binder jetting, and directed energy deposition developed at an explosive pace. There are various sorts of metal 3D printing that each have their own particular advantages. Here are some of the most common types used to digitally craft metal objects

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  • Track 17-1Selective Laser Melting (Powder Bed Based)
  • Track 17-2Selective Laser Sintering (Powder Bed Based)
  • Track 17-3Robocasting
  • Track 17-4Binder Jetting and Inkjet 3D Printing
  • Track 17-5Binder Jetting and Inkjet 3D Printing

\r\n A wide range of materials can be utilized for 3D printing, for example, ABS plastic, PLA, polyamide (nylon), glass filled polyamide, stereo lithography materials (epoxy gums), silver, titanium, steel, wax, photopolymers and polycarbonate. The materials accessible for 3D printing have progressed significantly since the beginning of the innovation. There is presently a wide assortment of various material types, which are provided in various states. Particular materials are now generally produced for particular stages performing dedicated applications with material properties that more precisely suit the application. The energy around the promise of 3D printing has opened the floodgates. New printers are being created each day to print a wide range of materials from plastics, metals, composites, and cement, to organic materials, paper, and food

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  • Track 18-1Plastics (polyactic acid, acrylonitrile butadiene styrene, polyvinyl alcohol plastic)
  • Track 18-2Powders (polyamide, alumide, multicolour)
  • Track 18-3Resins( high detail resin, paintable resin, transparent resin)
  • Track 18-4Other materias (Titanium, stainless steel, bronze, brass, silver, gold, ceramics)

\r\n 3D Printing technology is constantly evolving and definitely has a considerable measure in its pocket for the future. The level of customization that the technology offers opens up the door for its application in numerous enterprises, permitting it to take care of a considerable measure of issues. This review will abandon you with a look at work in advance in the 3D Printing Industry.

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  • Track 19-13D Printed Food
  • Track 19-23D Printed shoes
  • Track 19-33D Printed organs
  • Track 19-43D Printing Redefining Air travel
  • Track 19-5Consumer 3D Printing

\r\n 3D Printing has been applied in medicine since 2000s.  For manufacturing of custom pros-thetics and dental implants it was first used and then onwards the medical applications for 3D Printing has evolved significantly. By the use of 3D printing we can produce exoskeletons, windpipes, jaw bone, bones, ears, blood vessels, vascular networks, tissues, eye-glasses, cell cultures, stem cells and organs. The current medical applications of 3D Printing can be categorized into a number of categories that are creating im-plants, tissue and organ fabrication, prosthetics and pharmaceutical research concerning drug discovery and anatomical models

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  • Track 20-1Selective laser melting
  • Track 20-2Bio printing tissues and organs
  • Track 20-3Anatomical models for surgical preparation
  • Track 20-4Customized implants and prostheses
  • Track 20-5Drug delivery devices and dosage forms
  • Track 20-6Challenges in building 3D Vascularized organs
  • Track 20-7Cancer Research