Abstract

Researchers identify natural science novelty by penetration into a linguistic, mathematical, natural science and natural environment based on available knowledge, skills and aspirations. The combination of interacting vibrations of processes, phenomena and objects, like living information, is the basis for detecting natural science novelty by ensembles of intellectual agents. Spectral measurement of living natural information determines natural science novelty at the level of vibrations. Spectral measurement of living information reveals communicative-associative consistency of vibrations of processes and phenomena. The vibrational associativity of communicative vibrations determines the dynamics of a process or phenomenon. Spectral measurement of living information reveals their vibrational communicative-associative natural dynamics of properties and characteristics. The vibrational communicative-associative coherence ensemble of intelligent agents can be mapped into a spectrogram. The accumulated intellectual technologies and methods in synergy with the spectral measurement of natural science living information and the reflection of vibrational communicative-associative consistency in spectrograms will help the ensemble of intellectual agents determine natural science novelty. Live information has qualitative properties and quantitative characteristics. Based on spectral measurement of properties and characteristics, the ensemble of intelligent agents represents a dynamic vibration pattern in the form of a spectrogram. By qualitative properties and quantitative characteristics, not only natural science novelty is determined, but the risks of approaching disasters. The natural science novelty of the ensemble of intellectual agents is discussed with experts, as is customary in the scientific community.

Keywords:

ensemble of intellectual agents, live natural information, spectral measurement, natural science novelty, disasters.

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