![]() ![]() On the one hand, we present a solution combining spatial multiplexing (with up to 8 antennas) and non-coherent receiver to increase the spectral efficiency. For this use case, two strategies are discussed. This last scenario explores the feasibility of providing short-range subTHz connectivity between devices with low complexity. The considered scenario is a small hotspot area for which a low complexity non-coherent receiver based on the concatenation of a LDPC coded OOK modulator / energy detector is investigated and compared to a coherent receiver with P-QAM modulation. – Scenario #4: Hotspot with very low complexity transceiver. Different configurations (number of antennas, indexation strategies) are investigated, discussed and compared. In addition, a link budget estimation demonstrates the order of magnitude of the energy consumption for the envisaged schemes. Based on a fine model of the channel propagation in an office area, the potential of the index modulation schemes (e.g., GSM, DP-GSM and FSIM) is demonstrated from different perspectives (e.g., spectral/energy efficiencies, robustness to PN, cost and computational complexity). – Scenario #3: Kiosk and enhance WLAN in an office environment. As for scenario #1, Single carrier P-QAM modulation is assumed to derive figure of merits of the sub-THz network. In this use case, a shopping-mall area with strong required capacity for mobile and fixed wireless connectivity is investigated. – Scenario #2: Indoor Wireless backhaul in a shopping mall. The network deployment optimization is designed with an automatic planning tool. ![]() Based on a fine model of the environment and the performance abstraction of the single carrier P-QAM modulation, results and statistical analysis are discussed. – Scenario #1: Fixed wireless Access (FWA). The wireless systems performance are evaluated based on different metrics: data rate, bit error rate, coverage range, network capacity, and power consumption.ĭeliverable D3.1 describes and assesses the performance of the WP2 investigated concepts in five scenarios. Second, it must produce evaluation results to assess the feasibility and interest of the proposed solutions and scenarios, but also feed the demonstration and promotion tasks. ![]() First, it consists in integrating the building blocks developed in work-package WP2 for evaluation in a more sophisticated and realistic simulation environment. More precisely, the work-package WP3 has two main goals. 2019.Īfter definition of beyond-5G scenarios and new spectrum opportunities in work-package WP1 of BRAVE project, elaboration of new models for the sub-THz physical layer and design of adapted efficient waveforms within work-package WP2, the proposed solutions are demonstrated in work-package WP3. Release of D3.1: Performance assessments, Nov. This document gives a brief overview on few relevant publications (often in the form of white papers) sharing the vision of major equipment vendors, industry alliances, or researchers, on 6G communications and sub-THz/THz spectrum exploitation. The status on international and French sub-THz regulation remains roughly unchanged since the publication of our previous deliverable D1.1 in December 2019.įinally, investigations on future 6G technologies, applications, requirements, and impacts are gaining more and more intensity since 2018. The constraints coming from the propagation, namely the need for high-gain antenna and beam alignment processing, are common for the two paradigms. Illustration of the physical layer paradigms for sub-THz communication systems. This deliverable D1.2 gives an updated definition of use cases and requirements that were first published in deliverable D1.0 in November 2018, and then were considered in BRAVE studies.īesides, the two-fold BRAVE paradigm is exposed for the physical sub-THz layer that answers those use cases either with ultra-high data rates or a broadband low-complexity (and low-energy) system or in-between compromises. Three main use case families are targeted: high-capacity backhaul enhanced short-range hotspot and device-to device communications. ![]() 2019.Įnhanced or new wireless broadband applications will be enabled by the exploitation of sub-THz frequencies between 90 GHz and 300 GHz, arising with next 6G mobile network generation. Release of Deliverable D1.2: Final regulation status, Scenarios, and Requirements updates, Nov. ![]()
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