Sentence examples for indoor deployment from inspiring English sources

The algorithms and the framework implementation is illustrated with the results of two indoor deployment scenarios.

The combined results of the two scenarios will lead to a general low energy indoor deployment rule.

The average power delay profiles of indoor models related to indoor deployment scenarios (Table 5) are illustrated in Fig. 12.

Table 5 CEPD indoor deployment scenario Scenario Antenna gain (dBi), Tx-Rx Link Deployment scenario CM1 8–13 LOS Antenna alignment Residential typical home with multiple rooms.

The next paper entitled "Low energy indoor network: deployment optimization" by Siyi Wang, Weisi Guo, and Tim O'Farrell investigates indoor deployment with a minimum of energy to achieve downlink Quality of Service (QoS).

Our baseline simulation results are reinforced with a novel theoretical framework, which can be used to develop and optimise indoor deployment while causing very little SINR degradation for micro-cell users.

This model can be adapted to outdoor millimeter-wave overlay networks as well as to indoor deployments.

Figure 8 Optimising indoor femtocell deployment and the capacity and energy consumption improvements.

Considering an indoor femtocell deployment, we assume that the path loss is given by PL ij ( dB ) = 39.

This body of investigation has proposed a novel strategy for indoor AP deployment for both LTE-Femtocells and 802.11n Wi-Fi multiple access technologies.

The main contributions of this work are (a) a new clustering algorithm that minimizes indoor solution deployment costs, which can be integrated into a classical site location algorithm and (b) the results of the clustering algorithm in a real LTE heterogeneous environment.