TFT-1 Parameter Application Phase

Description of the TFT-1 parameter "Technological Fields Theory" (TFT) :

The Technological Fields Theory (TFT) is a comprehensive reference structure developed by the Rigene Project. Its main purpose is to provide an overview of the current technological fields and analyze the relationships between them. The TFT is designed to help take stock of the state of the art of technology and find innovative solutions to systemic problems. It aims to support and guide humans, technologies, technological processes, artificial intelligences, and other possible intelligent entities in identifying innovative technological solutions to solve systemic problems related to human civilization, technology, the economy, health, science, natural ecosystems, Planet Earth, and systems outside Planet Earth. The TFT is updated according to emerging technological developments.

Initially, the TFT is based on the following technologies and technological processes divided into 22 groups defined as "technological fields":

1. Blockchain, tokens, cryptocurrencies, smart contracts

2. Artificial Intelligence

3. Internet of Things (IoT) and Internet of Everything (IoE) [subfield: "Spatial Computing and Internet of Things" (SC-IoT)]

4. Robotics

5. Cloud Computing

6. Quantum Computing, Quantum Internet, Quantum Computer

7. 5G, 6G

8. Internet

9. Nanotechnology

10. Biotechnology

11. DNA Data Storage, DNA Data Computing, DNA Data Internet

12. Virtual Reality (VR), Augmented Reality (AR), Mixed Reality (MR), metaverse

13. Gene Editing technologies (CRISPR)

14. Cognitive Enhancement technologies

15. Digital DNA for control and orientation of Artificial Intelligences technologies

16. Nuclear Fusion technologies

17. 3D Printing, 4D Printing

18. Smart Materials, nanomaterials

19. Apps, Dapps, Software, Algorithms, Operating Systems

20. Industry 4.0, Industry 5.0, companies 4.0, companies 5.0, laboratories 4.0, laboratories 5.0

21. Sharing Economy technologies, Circular Economy technologies, Green Economy technologies, Blue Economy technologies

22. Digital transition technologies, Ecological transition technologies

As technology continues to evolve, the TFT will be updated to reflect new advancements and emerging fields. This dynamic structure ensures that the TFT remains relevant and useful in guiding and supporting the development of innovative solutions for the complex challenges facing humanity and the planet.

The TFT-1 parameter, "Technological Fields Theory" (TFT), serves as a reference map to identify the main technological areas and their interactions. It is based on the 22 technological fields outlined in the TFT. The purpose of the TFT-1 parameter is to provide a comprehensive understanding of the state of the art of technology, as well as to guide the development of innovative solutions for systemic problems.

The interactions between the 22 technological fields of the TFT-1 parameter are crucial for understanding how these fields can work together to address complex challenges. By analyzing the relationships and connections between these fields, it becomes possible to identify synergies, potential collaboration opportunities, and areas where technological advancements in one field can benefit another.

Rigene Project TFT classification of technological fields

The Rigene Project's Technological Fields Theory (TFT) classification system is designed to evaluate and compare different technological fields based on their level of development, impact, and potential. The classification system uses four main parameters:

1. TFTvpt: Potential progress rate

2. TFTpse: Potential social and environmental impact

3. TFTpss: Potential systemic solutions

4. TFTpsr: Potential scientific research

Each parameter is assigned a numerical value from 0 to 10, considering various criteria and indicators. These values are then used to rank and prioritize technological fields based on their importance for human development.

Criteria and indicators for the evaluation of TFT parameters:

TFTvpt - Potential progress rate:

• Criteria: Technological innovation, availability of financing, adoption of new business models, development of technical skills and abilities, customer focus.

• Indicators: Product development rate, product adoption rate, technological innovation rate, R&D expenditure.

TFTpse - Potential social and environmental impact:

• Criteria: Safety, environmental sustainability, accessibility, large-scale effect on society, social responsibility.

• Indicators: Environmental impact, health impact, data security, inclusion, equity, economic impact.

TFTpss - Potential systemic solutions:

• Criteria: Complexity of solvable problems, interdisciplinarity, scalability, interaction with other systems, innovation.

• Indicators: Number of solvable problems, innovation, adoption rate, impact on society, innovation rate.

TFTpsr - Potential scientific research:

• Criteria: Quantity of research and development, publication of scientific articles, significant scientific discoveries, attention to research quality.

• Indicators: Amount of research and development, publication of scientific articles, recognitions and awards, impact on the scientific community.

The Rigene Project's TFT classification system helps identify the most promising technological fields for future human development. By using these parameters, stakeholders can direct investment and research towards sectors that have the most significant positive impact on society and the environment.

Applications of the TFT-1 parameter:

The TFT-1 parameter, or the "Technological Fields Theory" (TFT), can have multiple practical applications. Here are some potential applications and ways to develop the TFT-1 to fit real cases:

Technological Innovation: The TFT-1 can be used as a foundation for the conception and development of new technologies, combining elements from different technological fields to create innovative solutions.

Solving complex problems: The TFT-1 can be employed as a tool to analyze and solve systemic problems involving different technological fields, facilitating collaboration between experts of different disciplines.

Public Policy Development: The TFT-1 can be used to guide the decisions of policy makers regarding technology investments, regulations and strategies, in order to promote sustainable and balanced development.

Education and research: The TFT-1 can be used as an educational tool for the education of students, researchers and professionals, providing a comprehensive overview of the main technological fields and their interactions.

Market Analysis: The TFT-1 can be applied to identify emerging trends, investment opportunities, and potential growth areas across technology sectors.

To develop the TFT-1 in such a way that it can be applied to concrete cases, the following steps can be followed:

Identify the specific problem or goal to be addressed.

Select the technological fields relevant to the problem or objective in question, taking into account the interactions between the different fields.

Analyze key developments and trends in selected technological fields and identify possible synergies and complementarities between technologies.

Engage experts from different technological fields to evaluate potential solutions and discuss the possible implications and consequences of different options.

Develop and implement the most suitable solution to the problem or objective at hand, continuously monitoring and evaluating the results and making any necessary changes and adjustments.

In summary, the TFT-1 parameter can be used as a basis for the analysis and development of innovative solutions involving different technological fields. To apply it to concrete cases, it is important to consider the interactions between the various fields, involve experts from different disciplines and continuously monitor the results to ensure an effective and sustainable approach.

Areas of application of the TFT-1 parameter

Global challenge of climate change and environmental sustainability area:

One current scope where the TFT-1 parameter can be applied is in addressing the global challenge of climate change and environmental sustainability. This complex, multidisciplinary issue requires innovative technological solutions from multiple fields working together to create a more sustainable future for our planet.

Applying the TFT-1 parameter to this scope would involve assessing the 22 technological fields mentioned earlier, based on their potential progress rate (TFTvpt), potential social and environmental impact (TFTpse), potential systemic solutions (TFTpss), and potential scientific research (TFTpsr).

Some of the most relevant technological fields for this scope include:

1. Renewable energy technologies, including solar, wind, and nuclear fusion (Field 16: Nuclear Fusion technologies).

2. Energy storage solutions, such as advanced batteries and hydrogen fuel cells.

3. Electric and hydrogen-powered vehicles, contributing to the reduction of greenhouse gas emissions.

4. Smart grid and energy management systems, improving the efficiency and resilience of energy distribution.

5. Carbon capture and storage technologies, mitigating the effects of greenhouse gas emissions.

6. Sustainable agriculture and precision farming techniques, enhancing food production while minimizing environmental impact (Field 10: Biotechnology).

7. Water management and purification technologies, ensuring access to clean water for all.

8. Waste management and recycling technologies, promoting a circular economy (Field 21: Sharing Economy technologies, Circular Economy technologies, Green Economy technologies, Blue Economy technologies).

9. Climate monitoring and prediction technologies, facilitating better decision-making and adaptation strategies (Field 2: Artificial Intelligence, Field 3: Internet of Things).

10. Environmental restoration and conservation technologies, protecting and restoring ecosystems and biodiversity.

By evaluating and prioritizing these fields using the TFT-1 parameter, decision-makers, researchers, and investors can allocate resources more effectively, focusing on the most promising technologies to combat climate change and achieve environmental sustainability.