Abstract
The digital revolution has changed the way we implement and use connected devices and systems by offering Internet communication capabilities to simple objects around us. The growth of information technologies, together with the concept of the Internet of Things (IoT), exponentially amplified the connectivity capabilities of devices. Up to this moment, the Long Range (LoRa) communication technology has been regarded as the perfect candidate, created to solve the issues of the IoT concept, such as scalability and the possibility of integrating a large number of sensors. The goal of this paper is to present an analysis of the communication collisions that occur through the evaluation of performance level in various scenarios for the LoRa technology. The first part addresses an empirical evaluation and the second part presents the development and validation of a LoRa traffic generator. The findings suggest that even if the packet payload increases, the communication resistance to interferences is not drastically affected, as one may expect. These results are analyzed by using a novel Software Defined Radio (SDR) technology LoRa traffic generator, that ensures a high-performance level in terms of generating a large LoRa traffic volume. Despite the use of orthogonal variable spreading factor technique, within the same communication channel, the collisions between LoRa packets may dramatically decrease the communication performance level.
Highlights
Over the last years, the number of IoT (Internet of Things) technologies has continually increased in our daily lives
The influence of collisions over performance is difficult to analyze in a classical setup, due to the fact that the integration of a large number of sensors demands a high cost. This is the reason we focus on the development, implementation and testing of a Long Range (LoRa) traffic generator that allows us to generate a large volume of data packets with the use of Software Defined Radio (SDR) technologies
The performance level is not affected, like the results shown in Section 3, obtained in an empirical simulation level
Summary
The number of IoT (Internet of Things) technologies has continually increased in our daily lives. The main goal of these technologies is to increase the quality of life These IoT architectures have generated new challenges and issues, many of them being impossible to be anticipated at the moment of design. Network) [2], NB-IoT (Narrow Band-Internet of Things) [3], Z-Wave [4], LinkLabs [5], Bluetooth LE (Low Energy) [6], Google Thread [7], and Wirepas Mesh [8] One may consider these technologies to be the focus of the research community. A new communication paradigm for applications featuring low data rates with low power use has been achieved through the integration of technologies, such as SigFox or LoRa [1], with the goal of ensuring large coverage area, ranging from a few to as much as tenths of square kilometers. The fifth section makes for the conclusion of this work and the discussion of the obtained results
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