Implementasi Aplikasi Presisi Paten Dalam Peningkatan Pelayanan Cepat Dan Tepat

Penelitian ini untuk mengimplentasikan Presisi dalam bentuk aplikasi pelayanan cepat dan tepat Kepolisian Republik Indonesia dengan konsep  prediktif, responsibilitas, transparan dan berkeadilan (PRESISI). Konsep presisi terdapat pencegahan atau prediktif perlu dilakukan dalam upaya pencegahan kejahatan.  Kemudian terkait responsibilitas menekankan bahwa kepolisian memang harus cepat tanggap untuk menangani kasus hukum terkait dengan ketertiban dan keamanan di masyarakat. Dengan era 4.0 penggunaan teknologi informasi dapat membantu kepolisian untuk cepat merespons dan segera menangani segala bentuk laporan yang masuk. Bencana yang melanda dunia pandemic  Covid-19 yang membatasi ruang lingkup berkumpul dalam suatu tempat untuk menghindari tertularnya virus covid-19. Implemtasi aplikasi Presisi adalah menjadi sousi yang tepat dalam melayani perpanjngan SIM. Aplikasi ini di desain untuk memangkas waktu antrian sehingga masyarakat yang memperpanjang  surat izin mengemudi tanpa turun dari kenderaan dengan konsep drive trhu.

Power Quality Improvement of Distribution System With Dispersed Generation Using Novel Algorithm for Detection and Control of Islanding Process

Distribution engineers investigate economical and technical feasibility of new capacity expansion alternatives. Distributed generation (DG) can be used effectively to support the customer’s power quality requirements. DG is an imperative tool that can partially replace the need to erect new generating stations in order to cope with the increasing load demands. However, numerous complexities arise like parallel operation of DG within existing system, phenomena of islanding and its detection, micro grid operation, monitoring and control etc. Several techniques have been developed for the effective detection of islanding. These techniques have numerous deficiencies. First of all, a majority of these islanding detection techniques have been developed only for balanced three phase load. No single-phase load and unbalanced three phase loads have been considered. Secondly, successful transfer into autonomous micro grid operation requires islanding detection and a subsequent change in control strategy of micro grid DG units. Thirdly, this operation causes large amount of current flow out of the micro grid into the fault, resulting in severely depressed micro grid bus voltage. In this research work, the emphasis is to improve these problems and overcome the drawbacks of existing techniques. The aims and objectives of this study are to develop a novel islanding detection technique, reliable, effective and efficient operation of DG in coordination with main utility network as well as power quality improvement for essential load. In order to improve the power quality of distribution network and to detect the islanding phenomena with DG, innovative techniques are required to implement the solution and mitigate the problems effectively. In this research study, using an analytical approach, two algorithms have been designed; a comprehensive algorithm for the implementation of distributed generation (IDG) by finding the optimal size and location of ivDG for power quality improvement and a new islanding detection algorithm (NIDA) for islanding detection under multiple distributed generation scenarios. The proposed algorithms can be utilized effectively to enhance the feeder performance having randomly distributed loads. The algorithms have been designed in “C language” and are based upon the power quality improvement of distribution feeder in terms of node voltage profile enhancement, power loss reduction and islanding detection in multi-DG scenario. The newly designed algorithms outperform the conventional approaches, which encounter numerous complexities during their implementation. The designed algorithms have the capabilities to operate under uniform and non-uniform loads with low power factor for both single DG and multi-DG scenario. The suggested algorithms have been implemented on different feeders including, 11kV feeder, 12.5kV feeder and IEEE 34 bus feeder. The feeders have been simulated in “C-language” and the results have been verified. The simulation results show that the algorithms can be implemented efficiently to detect the islanding phenomena and enhance the distribution system performance in terms of node voltage profile improvement and power loss reduction.