135 research outputs found
Analysis of LoRaWAN Uplink with Multiple Demodulating Paths and Capture Effect
Low power wide area networks (LPWANs), such as the ones based on the LoRaWAN
protocol, are seen as enablers of large number of IoT applications and
services. In this work, we assess the scalability of LoRaWAN by analyzing the
frame success probability (FSP) of a LoRa frame while taking into account the
capture effect and the number of parallel demodulation paths of the receiving
gateway. We have based our model on the commonly used {SX1301 gateway chipset},
which is capable of demodulating {up to} eight frames simultaneously; however,
the results of the model can be generalized to architectures with arbitrary
number of demodulation paths. We have also introduced and investigated {three}
policies for Spreading Factor (SF) allocation. Each policy is evaluated in
terms of coverage {probability}, {FSP}, and {throughput}. The overall
conclusion is that the presence of multiple demodulation paths introduces a
significant change in the analysis and performance of the LoRa random access
schemes
Spatiotemporal Modelling of Multi-Gateway LoRa Networks with Imperfect SF Orthogonality
Meticulous modelling and performance analysis of Low-Power Wide-Area (LPWA)
networks are essential for large scale dense Internet-of-Things (IoT)
deployments. As Long Range (LoRa) is currently one of the most prominent LPWA
technologies, we propose in this paper a stochastic-geometry-based framework to
analyse the uplink transmission performance of a multi-gateway LoRa network
modelled by a Matern Cluster Process (MCP). The proposed model is first to
consider all together the multi-cell topology, imperfect spreading factor (SF)
orthogonality, random start times, and geometric data arrival rates. Accounting
for all of these factors, we initially develop the SF-dependent collision
overlap time function for any start time distribution. Then, we analyse the
Laplace transforms of intra-cluster and inter-cluster interference, and
formulate the uplink transmission success probability. Through simulation
results, we highlight the vulnerability of each SF to interference, illustrate
the impact of parameters such as the network density, and the power allocation
scheme on the network performance. Uniquely, our results shed light on when it
is better to activate adaptive power mechanisms, as we show that an SF-based
power allocation that approximates LoRa ADR, negatively impacts nodes near the
cluster head. Moreover, we show that the interfering SFs degrading the
performance the most depend on the decoding threshold range and the power
allocation scheme.Comment: IEEE Global Communications Conferenc
Extending the Lora modulation to add further parallel channels and improve the LoRaWAN network performance
In this paper we present a new modulation, called DLoRa, similar in principle
to the conventional LoRa modulation and compatible with it in terms of
bandwidth and numerology. DLoRa departs from the conventional LoRa modulation
as it is using a decreasing instantaneous frequency in the chirps instead of an
increasing one as for the conventional LoRa modulation. Furthermore we describe
a software environment to accurately evaluate the "isolation" of the different
virtual channels created both by LoRa and DLoRa when using different Spreading
Factors. Our results are in agreement with the ones present in literature for
the conventional LoRa modulation and show that it is possible to double the
number of channels by using simultaneously LoRa and DLora. The higher (double)
number of subchannels available is the key to improve the network level
performance of LoRa based networks.Comment: This work has been submitted on Feb.1 2020 to European Wireless 2020
conference for possible presentation and subsequent publication by the IEE
LoRa ๋คํธ์ํฌ์์ ์๋์ง ํจ์จ์ฑ์ ์ํ ๋ ธ๋ ๊ธฐ๋ฐ ADR ๋ฉ์ปค๋์ฆ
ํ์๋
ผ๋ฌธ (์์ฌ) -- ์์ธ๋ํ๊ต ๋ํ์ : ๊ณต๊ณผ๋ํ ์ปดํจํฐ๊ณตํ๋ถ, 2020. 8. ๊น์ข
๊ถ.Recently, as Internet of Things (IoT) systems have increased and Wireless Sensor Network (WSN) has been expanding, studies related to them are increasing. Among them, the interest in long range communication technologies has increased. In this regard, Low Power Wide Area (LPWA) network technologies such as Long Range (LoRa), Weightless, and Sigfox have emerged. Also, various studies related to LoRa and LoRaWAN, which are available in Industrial Scientific and Medical (ISM) bands, are being conducted. In LoRa networks, the nodes are connected to the gateway by one hop to form a start topology. LoRa nodes use the transmission parameters such as Spreading Factor (SF), Transmission Power (TP), Bandwidth (BW), Coding Rate (CR), and Carrier Frequency (CF) to transmit frames. In this process, the frame losses and the collisions between frames may occur because of the channel condition and transmission timing. To alleviate this problem, LoRaWAN utilizes the ADR mechanism to select appropriate transmission parameters considering the channel condition on the node side. In addition, there is the ADR mechanism for allocating the transmission parameters on the server side. The ADR mechanisms maintain the connection between the server and the nodes, and set appropriate transmission parameters. However, these existing ADR mechanisms have some limitations. First, the server side ADR mechanism increases the overhead of the server in proportion to the transmitted frames. Second, it is difficult to quickly and efficiently respond to dynamic channel. Third, the transmission parameters selected by these ADR mechanisms may not be the optimal transmission parameters for energy efficiency. These problems cause large energy consumption of the battery-powered nodes and decrease performance when the channel condition changes dynamically. In this paper, we propose a Node-based ADR Mechanism (NbADR), which is the ADR mechanism for Class A nodes in confirmed mode to minimize the server load and maximize energy efficiency. The proposed mechanism responds quickly to the channel condition based on the downlink pattern and selects the transmission parameters for efficient energy consumption by utilizing Efficiency of Energy (EoE) metric. We analyze the efficiency of the transmission parameters selected through EoE, and conduct extensive experiments. In conclusion, NbADR is more effective in terms of energy efficiency than the existing ADR mechanisms. Additionally, NbADR guarantees throughput of LoRa networks even in dynamically changing channel environments and improves fairness between the nodes.์ต๊ทผ IoT ์์คํ
์ด ์ฆ๊ฐํ๊ณ ๋ฌด์ ์ผ์ ๋คํธ์ํฌ๊ฐ ๋์ด์ง๋ฉด์ ์ด์ ๊ด๋ จ๋ ์ฐ๊ตฌ๊ฐ ์ฆ๊ฐํ๊ณ ์๋ค. ๊ทธ ์ค์์๋ ์ฅ๊ฑฐ๋ฆฌ ํต์ ๊ธฐ์ ์ ๋ํ ๊ด์ฌ์ด ์ฆ๊ฐํ๊ณ ์๋ค. ์ด์ ๊ด๋ จํ์ฌ LoRa, Weightless, Sigfox์ ๊ฐ์ LPWA๋คํธ์ํฌ ๊ธฐ์ ๋ค์ด ๋ฑ์ฅํ๊ณ ์๋ค. ๋ํ, ISM ๋ฐด๋์์ ์ฌ์ฉ ๊ฐ๋ฅํ LoRa์ LoRaWAN ๊ด๋ จ ๋ค์ํ ์ฐ๊ตฌ๊ฐ ์งํ๋๊ณ ์๋ค. LoRa ๋คํธ์ํฌ์์ ๋
ธ๋๋ค์ ์คํ ํ ํด๋ก์ง๋ฅผ ๊ตฌ์ฑํ๊ธฐ ์ํ์ฌ ๊ฒ์ดํธ์จ์ด์ 1ํ์ผ๋ก ์ฐ๊ฒฐ๋์ด ์๋ค. LoRa ๋
ธ๋๋ค์ ํ๋ ์์ ์ ์กํ๊ธฐ ์ํ์ฌ SF, TP, BW, CR, CF์ ๊ฐ์ ์ ์ก ํ๋ผ๋ฏธํฐ๋ฅผ ์ฌ์ฉํ๋ค. ์ด ๊ณผ์ ์์ ์ฑ๋ ์ํ์ ์ ์ก ํ์ด๋ฐ์ผ๋ก ์ธํ ํ๋ ์ ์์ค๊ณผ ํ๋ ์ ๊ฐ ์ถฉ๋์ด ๋ฐ์ํ ์ ์๋ค. ์ด๋ฌํ ๋ฌธ์ ๋ฅผ ์ํํ๊ธฐ ์ํ์ฌ LoRaWAN์์๋ ๋
ธ๋ ์ธก์์ ๋คํธ์ํฌ ์ํฉ์ ๊ณ ๋ คํ์ฌ ์ ์ ํ ์ ์ก ํ๋ผ๋ฏธํฐ๋ฅผ ์ ํํ๊ธฐ ์ํ ADR ๋ฉ์ปค๋์ฆ์ ์ฌ์ฉํ๋ค. ๊ฒ๋ค๊ฐ ์๋ฒ ์ธก์์ ์ ์ก ํ๋ผ๋ฏธํฐ๋ฅผ ํ ๋นํ๋ ADR ๋ฉ์ปค๋์ฆ์ด ์กด์ฌํ๋ค. ADR ๋ฉ์ปค๋์ฆ๋ค์ ์๋ฒ์ ๋
ธ๋์ ์ฐ๊ฒฐ์ ์ ์งํ๊ณ ์ ์ ํ ์ ์ก ํ๋ผ๋ฏธํฐ๋ฅผ ์ค์ ํ๋ค. ํ์ง๋ง ๊ธฐ์กด์ ADR ๋ฉ์ปค๋์ฆ๋ค์ ์ผ๋ถ ํ๊ณ์ ์ ๊ฐ์ง๊ณ ์๋ค. ์ฒซ ๋ฒ์งธ, ์๋ฒ ์ธก ADR ๋ฉ์ปค๋์ฆ์ ์ ์กํ๋ ํ๋ ์์ ๋น๋กํ์ฌ ์๋ฒ์ ๋ถํ๋ฅผ ์ฆ๊ฐ์ํจ๋ค. ๋ ๋ฒ์งธ, ๋์ ์ธ ์ฑ๋์์ ๋น ๋ฅด๊ณ ํจ์จ์ ์ผ๋ก ๋์ฒํ๊ธฐ ์ด๋ ต๋ค. ์ธ ๋ฒ์งธ, ์ด๋ฌํ ADR ๋ฉ์ปค๋์ฆ๋ค์์ ์ ํ๋ ์ ์ก ํ๋ผ๋ฏธํฐ๋ค์ด ์๋์ง ํจ์จ์ฑ์ ์ํ ์ต์ ์ ์ ์ก ํ๋ผ๋ฏธํฐ๊ฐ ์๋ ์ ์๋ค. ์ด๋ฌํ ๋ฌธ์ ์ ๋ค์ ๋ฐฐํฐ๋ฆฌ๋ก ๋์ํ๋ ๋
ธ๋๋ค์ ํฐ ์๋์ง ์๋ชจ๋ฅผ ์ผ๊ธฐํ๊ณ LoRa ๋คํธ์ํฌ์ ์ฑ๋์ด ๋์ ์ผ๋ก ๋ณ๊ฒฝ๋๋ ํ๊ฒฝ์์ ์ฑ๋ฅ์ ๊ฐ์์ํจ๋ค. ๋ณธ ๋
ผ๋ฌธ์์ ์ฐ๋ฆฌ๋ ์๋ฒ์ ๋ถํ๋ฅผ ์ต์ํํ๋ฉฐ ์๋์ง ํจ์จ์ฑ์ ์ต๋ํํ๋ ๋
ธ๋ ๊ธฐ๋ฐ์ ADR ๋ฉ์ปค๋์ฆ์ธ NbADR์ ์ ์ํ๋ค. ์ ์ํ๋ ๋ฉ์ปค๋์ฆ์ ๋
ธ๋ ์ธก์์ ์ ์ก ๋ฐ์ ๋ค์ด๋งํฌ ํจํด์ ๊ธฐ๋ฐ์ผ๋ก ์ฑ๋ ์ํฉ์ ๋น ๋ฅด๊ฒ ๋์ํ๊ณ , Efficiency of Energy (EoE) ๋ฉํธ๋ฆญ์ ํ์ฉํ์ฌ ํจ์จ์ ์ธ ์๋์ง ์๋ชจ๋ฅผ ์ํ ์ ์ก ํ๋ผ๋ฏธํฐ๋ฅผ ์ ํํ๋ค. ์ฐ๋ฆฌ๋ EoE ๊ธฐ๋ฐ์ผ๋ก ์ ํํ ์ ์ก ํ๋ผ๋ฏธํฐ์ ํจ์จ์ฑ์ ๋ถ์ํ๊ณ , ๊ด๋ฒ์ํ ์คํ์ ์งํํ๋ค. ๊ฒฐ๋ก ์ ์ผ๋ก, NbADR์ ๊ธฐ์กด์ ADR ๋ฉ์ปค๋์ฆ๋ค๊ณผ ๋น๊ตํ์ฌ ์๋์ง ํจ์จ์ฑ ์ธก๋ฉด์์ ํจ๊ณผ์ ์ด๋ค. ์ถ๊ฐ์ ์ผ๋ก, NbADR์ ๊ธ๊ฒฉํ๊ฒ ๋ณํํ๋ ์ฑ๋ ํ๊ฒฝ์์LoRa ๋คํธ์ํฌ์ ์ฒ๋ฆฌ๋์ ๋ณด์ฅํ๊ณ ๋
ธ๋ ๊ฐ ๊ณตํ์ฑ์ ํฅ์์ํจ๋ค.Chapter 1 Introduction 1
Chapter 2 Related Work 4
Chapter 3 Preliminaries 7
3.1 LoRa/LoRaWAN 7
3.2 Transmission Parameters 8
3.3 ADR Mechanism 9
Chapter 4 Channel Modeling 10
4.1 Loss 10
4.2 Collision 12
Chapter 5 Node-based ADR Mechanism 14
5.1 Approach for Energy Efficiency 15
5.2 Node-based ADR Mechanism (NbADR) 17
Chapter 6 Evaluation 21
6.1 Simulation Settings 22
6.2 Simulation Results 23
Chapter 7 Conclusion 33
Bibliography 35Maste
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