M. Ramachandran.et.al / Computer Science, Engineering and Technology, 1(1), March 2023, 28-35 Copyright@ REST Publisher 28 Computer Science, Engineering and Technology Vol: 1(1), March 2023 REST Publisher; ISSN: 2583-9179 (Online) Website: https://restpublisher.com/journals/cset/ DOI: https://doi.org/10.46632/cset/1/1/4 Future Technology Development Using VIKOR Method *M. Ramachandran, Kurinjimalar Ramu, Chinnasami Sivaji, Chandrasekar Raja Indian Audit and Accounts Department, Raipur, Chhattisgarh, India. *Corresponding Author Email: ramachandran.manickam@restlabs.in Abstract: Future Technology Development. Future technologies could consist of tangible objects like robots, drones, and wearable technology. These can occasionally be utilized as human-powered tools to gather data, access information, or carry out helpful tasks nearby. Current and upcoming technologies are the main topics of Introduction to Technology. It covers the study of technology with a focus on management, operations, industries, specialized knowledge, security, interpersonal relationships, and developing technologies. India is now engaged in the development of cutting-edge technologies including 5G, AI, blockchain, augmented reality, virtual reality, robots, natural language processing, etc. Robotics, artificial intelligence, machine learning, and other technological advancements have greatly sped up transition. By 2025, 50 billion connected devices will make up the Industrial Internet of Things (IIoT), and 70 percent of manufacturers will be employing digital twins. Everybody who has access to virtual reality or augmented reality gadgets by the year 2040 will also have access to a digital virtual assistant. Virtual assistants can now be created on language model platforms that are significantly more powerful than previous language models, such as GPT-3. The VIKOR (VIšekriterijumsko Kompromisno Rangiranje) Optimal replacement Select method is used in Water, Carbon dioxide, Nitrogen gas, Oxygen, Silicon oxide, Calcium carbonate, Iron oxide, and Enthalpy (kJ/mol), Entropy (kJ/mol), Exergy (kJ/mol). Water, Carbon dioxide, Nitrogen gas, Oxygen, Silicon oxide, Calcium carbonate, and Iron oxide. Enthalpy (kJ/mol), Entropy (kJ/mol), Exergy (kJ/mol). Water got the first rank whereas Calcium carbonate is having the lowest rank. Keywords: TPS in reusable launch vehicles, The Changing Role for Technology, VIKOR Method. 1. INTRODUCTION Thermal protection equipment must be used for re-entry and entrance into the atmosphere (TPS). With the increased interest in interplanetary travel, the requirement to guarantee the safety of payloads (people and cargo) has refocused attention on TPS design and development internationally. By ensuring that the spacecraft's surface temperature does not go over a set limit due to high radiation, which could harm the internal measurement instruments, TPS is also used to protect solar probes. The TPS serves as a heat barrier in addition to being an aerodynamic body and structural element, ensuring the safety of the cargo. Extreme heat's detrimental consequences have complicated efforts to achieve controlled hypersonic flight since the earliest days of spaceflight, which prompted the creation of the first TPS. The interplay of convective and radiative heat transfer mechanisms at the vehicle surface, which results in chemical reactions and gas dynamic phenomena, makes TPS design and material selection difficult. These phenomena are still the subject of a lot of research today. It is necessary to fully comprehend these heat transfer mechanisms by modelling, computational methods, and experiments in order to choose the right materials for a vehicle's TPS. Therefore, an efficient TPS design can offer a trustworthy defense against aerodynamic loads without significantly increasing weight or jeopardizing vehicle integrity. The manufacturing sector has used additive manufacturing (AM) more frequently during the past 30 years, especially when creating part models and prototypes. In a recent report, the history of AM is outlined. Instruments used in stereolithography and 3D printing are examples of original AM processes. Polymers were initially used in these AM techniques as tools for communication or probing, and more recently as finished goods. Reduced product development steps are made possible by quick, direct prototyping from CAD models. In order to meet the demands of the aerospace, automotive, and fast tooling industries, the focus of AM research has recently shifted to creating intricately shaped metal components, notably titanium and nickel alloys, that cannot be manufactured economically using conventional processes. The creation and application of new and enhanced energy technologies will be necessary for the transition to a sustainable energy system. These new technologies must be less expensive if they are to be adopted because they frequently have higher investment costs than conventional energy methods. Making decisions for upcoming investments