Modeling of psychosomatic-cognitive functions is considered, in the framework of combined hierarchical brain's and body's acupuncture neural networks. It is pointed out that presented models of brain's hierarchical neural networks demonstrate encourageing advances in modeling cognitive functions. However, for modeling most cognitive and psychosomatic functions, the subtle biophysical quantumholographic microwave Hopfield body's acupuncture neural networks are also necessary. On the one hand, they demonstrate existance of two cognitive modes of consciousness, and on the other hand, they represent natural framework for explaining contemporary meridian (psycho)therapies for very fast removing of psychosomatic disorders, demonstrating close relationship between acupuncture system and consciousnesswith significant psychosomatic and transpersonal implications.Keywords-Brain's hierarchical neural networks; body's acupuncture quantum-holographic neural networks; meridian (psycho)therapies; cognitive and psychosomatic implications.
This paper discusses the mechanisms of gas breakdown at low values of pressure and inter-electrode gap, i.e. in the vicinity of the Paschen minimum. In this area of pressure and inter-electrode gap values, breakdown occurs either through gas or vacuum mechanisms, and also the so called anomalous Paschen effect appears. Electrical breakdown of electropositive, electronegative and noble gases has been investigated theoretically, experimentally and numerically. Based on the results obtained, regions in which particular breakdown mechanisms appear have been demarcated. Special attention has been devoted to the anomalous Paschen effect as well as to the avalanche vacuum breakdown mechanism.
This paper investigates the validity of the similarity law in cases of dc and pulse breakdown of gases. Geometrically similar systems insulated with SF 6 gas were used during experiments. It is shown that the similarity law is valid for dc breakdown voltage if the electron mean free path is included in geometrical parameters of the system, but not for pulse breakdown voltages. The explanation for this is the mechanism of the pulse discharge. The similarity law was expanded to take into account mechanisms of pulse breakdown initiation. Thus, the general similarity law is obtained, the validity of which in case of a pulse breakdown is established experimentally.
The aim of this paper is to discuss the area left of the Paschen minimum, i.e., the area where the anomalous Paschen effect occurs. The experimental results and numerical simulation suggest a slightly different explanation of the anomalous Paschen effect. That is to say, that the anomalous Paschen effect is the result of the breakdown in a nonhomogenous electric field (edge electrode lines).Index Terms-Anomalous Paschen effect, electrical breakdown of gases, nonhomogenous electric field.
This paper investigates the possibility of applying the time enlargement law for predicting how gas-insulated systems would behave when exposed to pulse voltage loads of different shapes. For this purpose, the validity of the time enlargement law in this case has first been tested and the most suitable theoretical distribution function of the breakdown time random variable established. Pulse characteristics of the investigated insulating system have subsequently been determined, by applying the time enlargement law to experimental values of the breakdown time random variable, obtained in measurements with predefined shapes of the voltage load. Pulse characteristics thus obtained were compared with the corresponding pulse characteristics derived from the area law. The results demonstrate the advantages of the time enlargement law method, especially in the case of a non-homogeneous electric field. The experiments were conducted with SF 6 gas, at different values of the pd product (pressure × inter-electrode gap), in a wide frequency range of applied pulse voltages, for a homogeneous, radial and point-plane electrode configuration.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.