My doctoral dissertation addresses the topic of installing low-voltage architecture of electric power system for smart grids. The study presents all aspects of managing electric energy but the focus is on the method of gathering information, on the algorithm for balancing the voltage profile and on the reducing of consumers’ electric energy usage. New challenges that stand in front of the electric power systems can only be mitigated with the help of complete computerization of the distribution network, therefore their elements should be interlinked. The computerization for control and management coverage extends only to high-voltage grids but the medium-voltage grids are only partially covered. At the moment the low-voltage network is not included, which means that the information link to a large amount of consumers is not established both on the spending sector as well as the widespread electric energy production. Informational communication infrastructure plays an important role in smart networks as it participates with loss reduction, safety assurance and efficiency increase in the whole electric power system. Bluntly put, there can be no smart networks without the communication infrastructure. When constructing an electric power network the needed flow of information should be assured – therefore the informational communication technology has to achieve the necessary standards and reach all network users. Informational infrastructure is also essential for the connection of widespread sources and some users into so-called virtual power plants that provide simplified control, guidance and assurance of systemic solutions for widespread sources. It is of utter importance for safe and unfaltering performance of electric power network as the virtual power plants’ narrow access points can interfere with the flow input. It can also guarantee necessary voltage profiles, regulate reactive power and offer control over the distributed energy resources and the possibility of creating intentional islanding. A vital role in the smart network concept is the consumer side, more precisely the end user (including households), as they will actively participate in the managing of end energy via energy efficiency packages. The dissertation introduces a platform for smart networks, based on dual-layered communication architecture (IP/MPLS, which supports a large number of virtual networks and also the loop and ring topology, etc.) The platform establishes communication between suppliers, distributors and customers in real time, but at the same time uses a unified protocol – IEC61850. There is a new method for the intake of data on a high-voltage level which uses non-conventional instrument transformer that has a major technological advantage in electronic circuits and in the voltage and current measuring procedure (therefore all parameters) without the usage of high-voltage current transformer. Its advantage lies also in the fact that the current part “floats” between the grounded and high-voltage potential, and is compatible with low-voltage transformer measuring devices. With the proposed method of measuring you enable the mapping of signals on a higher frequency with foresight of phase discrepancies which permits a harmonic analysis of electric networks with higher harmonics. The suggested transformer possesses advantages over the conventional ones even in dimensions, compatible with the IEC61850-9-2 standard (it is used for control of new digital disconnection systems), in the reduction of consumption of valuable metals and transformer oils, which in turn means a maximization of transformer security. This thesis represents a new method of electric energy usage optimization for the end user, which bases mostly on wireless appliance control. It will be possible to control them through an application which operates the devices based on the geodetic position of the user or with a network alleviation scheme. An application was developed with this purpose in mind for the internet and for Android operation systems that engages with the smart receiver and smart switches that are installed in the smart house or apartment. A new algorithm was also introduced for controlling the voltage profile of the distribution network where the spread sources stand. The prevalence of this algorithm is in better power organization and does not use any reactive power injections, algorithms for control of active and reactive power, voltage regulators, voltage compensators and algorithms for power factor supervision. Together with the corresponding system it brings control interfaces to the structure which simultaneously registers the network status and instantly prompts errors, causing more efficient removal of faults and ensuring much higher electric energy quality. The algorithm also includes an idea of the distribution network process in an island mode which is not generally possible under the law (just under special condition) but we believe that for the purpose of smart networks this should soon be changed.