“…Since the study seeks to inform stakeholders (service providers, policymakers, etc.) how backhaul engineering can aid in achieving a low-cost broadband solution, TEA offers opportunities when it comes to assessing the commercial viability of the investments and hence inputs to strategic plans and investment decisions (E. Oughton & Lehr, 2021). To carry out TEA, engineering specifications for backhauls suiting broadband were revisited for the chosen technologies with respect to their performance.…”
Although broadband internet has proven to accelerate the fulfilment of the information and communication for development (ICT4D) agenda, connectivity issues persist in some regions of the world, particularly in rural areas of Low and Middle-Income Countries (LMICs) which host 93% of the unconnected global population. Due to the lack of economic feasibility in these locations for service providers, International Telecommunication Union (ITU) has been advocating for low-cost sustainable solutions in such areas. Among the challenging broadband infrastructure segment seems to be the backhaul (middle-mile) as rural areas are remotely located from the backbone end-points. With Tanzania exemplifying LMICs, this paper presents a Techno-Economic Analysis (TEA) to compare the widely utilized backhaul (Microwave) and the promising Broadband over Power Line (BPL) towards achieving low-cost broadband solutions. To demonstrate technical viability in terms of capacity, Pathloss and MATLAB were utilized from which both technologies demonstrated the broadband-suitably capacity (161Mbps for Microwave and 168.99Mbs for BPL). From economic perspective, the Total Cost of Ownership (TCOs) for both technologies were determined using a Cost Model; BPL fared better as the cost of establishing one microwave link could have established almost 6 BPL links. Apart from adding to the body of knowledge on TEAs involving backhauls, this paper informs policymakers and other related stakeholders on the potential cost-benefit of BPL towards curbing the existing broadband connectivity gap.
“…Since the study seeks to inform stakeholders (service providers, policymakers, etc.) how backhaul engineering can aid in achieving a low-cost broadband solution, TEA offers opportunities when it comes to assessing the commercial viability of the investments and hence inputs to strategic plans and investment decisions (E. Oughton & Lehr, 2021). To carry out TEA, engineering specifications for backhauls suiting broadband were revisited for the chosen technologies with respect to their performance.…”
Although broadband internet has proven to accelerate the fulfilment of the information and communication for development (ICT4D) agenda, connectivity issues persist in some regions of the world, particularly in rural areas of Low and Middle-Income Countries (LMICs) which host 93% of the unconnected global population. Due to the lack of economic feasibility in these locations for service providers, International Telecommunication Union (ITU) has been advocating for low-cost sustainable solutions in such areas. Among the challenging broadband infrastructure segment seems to be the backhaul (middle-mile) as rural areas are remotely located from the backbone end-points. With Tanzania exemplifying LMICs, this paper presents a Techno-Economic Analysis (TEA) to compare the widely utilized backhaul (Microwave) and the promising Broadband over Power Line (BPL) towards achieving low-cost broadband solutions. To demonstrate technical viability in terms of capacity, Pathloss and MATLAB were utilized from which both technologies demonstrated the broadband-suitably capacity (161Mbps for Microwave and 168.99Mbs for BPL). From economic perspective, the Total Cost of Ownership (TCOs) for both technologies were determined using a Cost Model; BPL fared better as the cost of establishing one microwave link could have established almost 6 BPL links. Apart from adding to the body of knowledge on TEAs involving backhauls, this paper informs policymakers and other related stakeholders on the potential cost-benefit of BPL towards curbing the existing broadband connectivity gap.
“…We note that P (θ c , θ s ) is still a random variable, since while channel fading is averaged out, the randomness stemming from Φ b remains. 2 In that respect, we leverage the concept of the SIR meta distribution in communication networks [11] and define the JCAS SIR meta distribution as the complementary cumulative distribution function (CCDF) of P (θ c , θ s ), i.e.,…”
In this paper, we introduce a novel mathematical framework for assessing the performance of joint communication and sensing (JCAS) in wireless networks, employing stochastic geometry as an analytical tool. We focus on deriving the meta distribution of the signal-to-interference ratio (SIR) for JCAS networks. This approach enables a fine-grained quantification of individual user or radar performance intrinsic to these networks. Our work involves the modeling of JCAS networks and the derivation of mathematical expressions for the JCAS SIR meta distribution. Through simulations, we validate both our theoretical analysis and illustrate how the JCAS SIR meta distribution varies with the network deployment density.
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