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Equatorial Guinea has two main electricity systems, for Bioko Island, and for the continental Rio Muni region. SEGESA has 730 employees across the three business units in Malabo for the Bioko system, and 823 employees in Bata and the continental region.
The power grid in Equatorial Guinea is divided in two parts: the island grid (Malabo, Bioko Island) and the continental grid (Bata, Rio Muni). The high voltage power grid in the Rio Muni region has allowed the government to invest in interconnection points with Gabon and Cameroon.
Equatorial Guinea continues to invest heavily in the production and distribution of energy.
Electricity consumption in Equatorial Guinea in 2015 was 36 kilotonnes of oil equivalent (ktoe). The country produces all of the energy it consumes. As of 2012, renewable energy accounted for 29.2% of the final energy mix.
Enabling Ubiquitous Global Communications in Equatorial Guinea Via the Transformation of Getesa. Am. J. Eng. Technol.
This paper focuses on the modernization of the first national Mobile Network of Equatorial Guinea, called GETESA. Equatorial Guinea has three telecommunication companies: GETESA, Muni and Gecomsa. Getesa is the largest and the historical Equatorial Guinea telecommunication company established in 1987.
Equatorial Guinea has three telecommunication companies: GETESA, Muni and Gecomsa. Getesa is the largest and the historical Equatorial Guinea telecommunication company established in 1987. The Government of Equatorial Guinea holds 60% of the company whereas France Cable held 40% until it transferred its shares to Orange in 2010.
This paper focuses on the modernization of the first national Mobile Network of Equatorial Guinea, called GETESA. The government's decision to invest and take full control of the network was motivated by the lack of network quality, which had poor capacity, with 69% of the network coverage Received-Signal-Code-Power (RSCP) below 95dMm.
5G base station architecture is characterized by its flexibility, virtualization, and the ability to support diverse services through network slicing. The separation of CU and DU, along with the introduction of cloud-based technologies, allows for more efficient resource utilization and scalability.
5G networks divide coverage areas into smaller zones called cells, enabling devices to connect to local base stations via radio. Each station connects to the broader telephone network and the Internet through high-speed optical fiber or wireless backhaul.
With the rapid development of 5G mobile communication technology, the number of 5G users has significantly increased, leading to a corresponding expansion in network capacity . To meet the growing user demand, researchers have begun to focus on improving the throughput of base stations (e.g. Refs. [2, 3]).
It is known that there are 20 3/4G shared base stations in this area. According to Section 5, the number of base stations in general urban areas ranges from 20 to 36. Therefore, in the simulation experiment, the optimal results of the base station layout are shown in Table 10. Table 10. Layout results of 5G base station in general urban areas.
