Application of Techniques and Methods of Technical Creation for the Research and Refinement of the Pendulum-Type Oscillator
Abstract:
Current Status: Mechanics is not an exclusive branch of mathematics but also a component of the science of phys ics. Science works according to the scheme: hypothesis-prediction-denial-rejection. The rejection of the hypothesis is based on direct observation data, respectively, experiment. The results of the measurements of the pendulum experiments, analyzed in the Newtonian paradigm of interaction between bodies, also highlight unexpected results (anomalies). The pendulum-type oscillator is the physical system that has in the formula of the potential energy a cosine term, similar to the potential of the simple pendulum. The anomalies indicate a poor viability of the pen dulum measurement system (a fact reflected by the lack of measurement control, the lack of observation/causality, and the lack of other characteristic properties of a system) and, a reduced physical consistency of the paradigm of construction of the experiment, data collection and analysis of the measurement results, respectively. To date, there is no systematic research in the literature that highlights the heuristic approaches, techniques and methods of technical creation that have been used over time in the field of creation, development, validation and refinement of pendulum oscillators as a technical object/tool/system. The paper summarizes the results of the pendulum-type oscillator domain research (the appearance of the initial system, the development, testing and refinement of the gravitational, microscopic, quantum model). The results of the application of the logical-com binatorial methods of technical creation (the idea diagram method, respectively, the sequential-selective method) refer to the definition of new solutions for the pendulum oscillator. Also, the paper goes through the nine stages of the inventive problem-solving method (Synthesis of Solutions by Eliminating Contradictions) to find the optimal physical solution of the pendulum oscillator model.
Objectives: Increasing the viability of the pendulum oscillator by optimizing the physical consistency of the exper imental construction paradigm. Methods: Synthesis of solutions by eliminating the contradictions of the pendulum oscillator (Application of the Altshuller algorithm for innovative problem solving to find the optimal solution for the research topic). c)
Results: A new mechano-electrical paradigm for the construction, data collection and analysis of measurement results and a complex mechano-electrical oscillator (model)/system.
Conclusion: The optimal physical consistency of the mechano-electrical interaction paradigm used for the con struction, collection and analysis of data leads only to expected results of the measurements(perturbations).
