Energy Fields' Impact on Biological Objects

The paper deals with the impact on biological objects of the energy fields of the devices, which provide wireless charging of implant batteries and wireless power supply of non- accumulator implants. The device is intended for use in the area of medicine, pharmacology and human physiology. Implantable small-sized devices are introduced into the body surgically and autonomously monitor and control the functional state of individual organs and systems. Power sources have become the main limiting factor for increasing the service life of the implant. The main force field used in the device is magnetic. The magnetic field of any origin has an impact on individual areas and the biological organism as a whole. The article presents the main indicators that affect biological objects, namely: the relative magnetic permeability of the medium, the magnitude of the wave power that propagates in a dielectric material with losses, the depth of penetration of the electromagnetic wave and the magnitude of the wave resistance. Analysis of the data proves that the static magnetic field of increased intensity acting on a biological object causes disordering in the nervous, endocrine, vegetative, cardiovascular and other systems

System level modeling of dynamic reconfigurable system-on-chip

In this paper methods of dynamically reconfigurable multi-core System-on-chip (SoC) design are discussed, the approaches of system modeling for evaluation of these systems are presented. The dynamically reconfigurable SoC can be developed using the FPGA and the ASIC technologies. The implementations of dynamic reconfiguration using these approaches are essentially different. The system level modeling is used to evaluate the performance of dynamically reconfigured systems in the early stage of their development. The models of dynamically reconfigurable systems have very significant differences from the models of systems without a dynamical reconfiguration. The development of such models may require extensions of existing tools and specification of mechanisms functionality. In this paper the existing tools for SoC system design and the requirements for it to allow modeling of reconfigurable systems are considered. We propose mechanisms for system level modeling of the dynamically reconfigurable Networks-on-Chip (NoC) implemented on the ASIC technology