Development of Wireless Control System for Smart Street Lighting using ESP8266

Adiono, Trio; Siregar, Lindawani

doi:10.3991/ijim.v14i15.14081

Cited by 4 publications

(3 citation statements)

References 14 publications

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“…After the hardware and software are integrated carefully as in Fig. 2, we first test the system functionally by sending the command ON/OFF to the LED module through a web server as reported in [2]. Once the test was successfully done, later we test the Mesh connection in which the experimental setup is depicted in Fig.…”

Section: Results and Analysismentioning

confidence: 99%

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Internet-of-Things for Smart Street Lighting System using ESP8266 on Mesh Network

Adiono

Siregar

2021

Int. J. Recent Contrib. Eng. Sci. IT

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<p class="0abstract">IoT concept gained tremendous momentum in this century's technological advancements because it has efficiently connected various devices wirelessly. The ESP8266 Wi-Fi serial transceiver module is one of the most used devices for IoT applications. This paper designs the IoT-based smart street lighting system using ESP8266 configured as a Mesh network. The ESP8266 was instructed (programmed) to control the light level by producing a PWM signal, then it sends a dimmer value and reads the sensor's data. We can access our system wirelessly via a web server. The overall system was successful as a smart street lighting system in a wireless Mesh environment. This research result is also compared to the existing similar project in terms of the system complexity aspect.</p>

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Section: Results and Analysismentioning

confidence: 99%

“…as shown in Table I. In previous work [2], we have reported the ESP8266 application for street lighting with a single node. The results confirmed that the node (LED module) could be controlled and monitored its status through an HTML-based web server.…”

Section: Introductionmentioning

confidence: 99%

Internet-of-Things for Smart Street Lighting System using ESP8266 on Mesh Network

Adiono

Siregar

2021

Int. J. Recent Contrib. Eng. Sci. IT

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“…According to reference [12], the Wi-Fi module had a maximum range of 70 meters with RSSI reference of -93 dBm. RSSI is an important indicator that was used to assess the received signal strength parameters on a device [34], [35], in this case, ESP8266 module. Therefore, ESP8266 module was measured to determine the maximum RSSI value that could accurately control the node.…”

Section: Rssi Testingmentioning

confidence: 99%

Low-cost Wireless Lamp Socket and Power Plug for Smart Homes and Its Comparison with Available Commercial Competitors

Fuada,

Hendriyana,

Subashri Duttagupta

et al. 2023

Int. J. Interact. Mob. Technol.

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Smart home manufacturers widely produce Wireless Lamp Socket and Power Plug devices, which offer various features ranging from basic on/off control to more complex functionalities such as monitoring energy consumption, power losses, and harmonics. However, these devices tend to be expensive, as indicated by market surveys. To address this issue, the current study aimed to develop low-cost wireless control nodes for smart homes that operate using relays. The two nodes consisted of lamp socket and power plug built with lowcost electronic components, including a Wi-Fi built-in Microcontroller ESP8266 (Wemos D1 mini model) as the backbone to create ESP-Mesh wireless network and to provide control ports for high/low logic, a relay module, an AC-to-DC converter module, and terminals (E27 screw for lamp socket node and C-type plug for the power plug node). This paper primarily focuses on the hardware aspects. In order to evaluate the effectiveness of the nodes, the following tests are conducted: (1) product demonstration to assess the product functions, (2) power measurement in idle and active conditions, (3) ESP-Mesh connection testing, and (4) RSSI measurement. Functional testing is done using a smartphone with the UPISmartHome version 2.0 Android application, which successfully controlled the nodes wirelessly. In idle conditions, power plug and lamp socket nodes consume 426.36 mWatt and 418.275 mWatt of power, respectively. Further, in active conditions, power plug and lamp socket nodes consume 435.704 mWatt and 440.583 mWatt of power, respectively. RSSI testing results show that both nodes can be controlled within an optimal range of 60 meters (with reference to RSSI below –85 dBm) without the Internet, utilizing the ESP-Mesh feature of ESP8266. This range is deemed reasonable for smart homes of 21, 36, or 45 square meters. Both nodes could be controlled under the ESP-Mesh network that gets build. We also present the comparison with other products of competitors in this paper.

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