Unmanned aerial vehicle‐enabled layered architecture based solution for disaster management

Utilizing unmanned aerial vehicles (UAVs) as aerial base stations is a new and promising technology that enables the connectivity of a large volume of devices such as sensors and machines, referred to as massive Internet of Things (mIoT). This article aims to analyze and optimize the area spectral efficiency (ASE) by investigating the efficient deployment of UAVs to ensure reliable uplink communication from ground IoT devices to UAVs. We utilize the tools from stochastic geometry to derive the closed form expression of the ASE in the interference-limited regime. We propose a novel framework for maximizing the ASE of UAV-enabled networks by simultaneous optimization of UAVs' altitude and density. The simulation results demonstrate that deploying UAVs with combined optimal density and altitude outperforms more conventional deployment strategies in terms of the ASE.

Section: Background and Motivationmentioning

confidence: 99%

“…Furthermore, in (10), the term log 2 (1 + 𝛽) > 0 for 𝛽 > 0 is independent of 𝜆 d and can be ignored.…”

Section: Data Availability Statementmentioning

confidence: 99%

“…As integral over a non-negative function is always greater than zero, hence, A (𝜆 d , h d , 𝛽) > 0. It should be noted that in (10)…”

Section: Data Availability Statementmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Altitude and density optimization over UAV‐enabled massive IoT wireless communications

Shabani

Faraji

Baghani

2022

“…Unmanned aerial vehicles (UAVs) are an increasingly growing technology that offers a wide variety of productive solutions in different smart applications in the real world, 1,2 which do not require human operator, or where human intervention is risky, dangerous, impossible or expensive. 3 A smart alliance of UAVs is inclusively used in the range of applications like in the public safety, military, and commercial use such as intelligence surveillance, inland-defense, border protection live video remote communication and setting up guidance units, 4,5 which operate in these bands leading to increased utilization of these bands, consequently, UAVs also face the problem of spectrum scarcity.…”

Section: Introductionmentioning

confidence: 99%

Quick cooperative spectrum sensing in cognitive unmanned aerial vehicles networks

Zhang

2022

In cognitive unmanned aerial vehicles (UAVs) networks (CUAVNs), cooperative spectrum sensing (CSS) has been recognized as a key technology to enable UAVs to detect spectrum holes and opportunistically access primary licensed spectrum band without harmful interference. Considering that the location flexibility of flying UAV spectrum sensors makes the collaborative working mode of multiple UAVs difficult to achieve, this article establishes an easy-to-implement intraframe CSS mode by considering the cooperation within the microsensing time slots of a single UAV. On the basis of this, we adopt sequential probability ratio test (SPRT) as the fusion criterion of sensing decisions from microsensing slots to implement quick CSS for multiple channels under the sensing delay limit and make an investigation the achievable throughput of truncated-SPRT for CUAVNs. Due to the uncertainty of the sensing decision number required in SPRT, we further propose a soft truncation (ST) way to terminate SPRT process and further evaluate the global CSS performance. At last, numerical simulation results show that the CSS efficiency of the proposed intraframe CSS outperforms that of the traditional interframe CSS, and the performance of ST-SPRT is also better than hard truncation (HT)-SPRT, in terms of the detection performance and throughput, especially in the multichannel spectrum sensing scenario.

An effective data routing for dynamic area coverage using multidrone network

Swain

Khilar

Senapati

2022

Drones equipped with visual sensors are extensively utilized in various area coverage applications such as area mapping, monitoring of crops and road traffic, rescue operations, and so on. To enhance the coverage process, a suitable mobility model and an effective way of data communication are required. In literature, many works have been performed by focusing on the above‐mentioned aspects individually. However, unwanted information processing and a less packet delivery ratio with high message flooding are some shortcomings that have been seen in existing works on mobility model and routing protocol respectively. The above‐mentioned issues motivate us to propose a three‐level working process of ground area coverage, which includes the design of a mobility model as well as a routing mechanism incorporating the above‐mentioned mobility pattern. A set of waypoints for the movement of a drone is generated by an optimized aerial decomposition process in order to maximize and minimize the actual and exterior ground area coverage respectively. The decomposition is performed by incorporating the position and orientation of the camera footprint. While moving through the waypoints, a drone finds a stable and energy‐enable path to transmit the collected information to other drones. To avoid the frequent link loss due to the high mobility and limited energy of drones, threshold values for the velocity and energy with an estimated link stability time are considered as three parametric for the proposed routing mechanism. The result shows that the proposed work outperforms the existing result in many folds, and is suitable for the area coverage applications.