Design of IoT-Based Tomato Plant Growth Monitoring System in The Yard

Marcheriz, Isnan Nugraha; Fitriani, Endah

doi:10.33395/sinkron.v8i2.12226

Cited by 4 publications

(2 citation statements)

References 3 publications

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“…Cameras monitor plant height and fruit development. Through IoT technology, communities and farmers can monitor and control tomato plant conditions in real-time via smartphone apps, enabling proactive measures for disease prevention and improved crop production and quality [15].…”

Section: Related Workmentioning

confidence: 99%

Smart indoor gardening: elevating growth, health, and automation

Alrawashdeh,

Alkore Alshalabi,

Al-Jaafreh

et al. 2024

Bulletin EEI

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Recently, indoor systems for growing plants have emerged as a promising approach to address the problems related to extreme weather conditions outdoors. However, such systems must manage the plants surrounding environments to satisfy the environmental and the economical requirements. In this line, any proposed solution must address challenging factors such as plants diseases and unordinary climate situations. In this paper, propose an internet of things (IoT) indoor system that can be used to facilitate the plant growing process. The proposed system is designed to provide alternatives for outdoor climate dependency such as the vitamins provided through sunlight. Moreover, renewable energy sources (sunlight) are employed to reduce the impact on the environment. With the help of several types of sensors, the system continuously monitors the plants through their growing journey. Whereas actuator devices are employed to control the plant-feeding process based on the sensors’ reported values. All the collected data will be uploaded to the cloud for analysis, utilizing a website. Additionally, the architecture of the provided system eliminates the need for human involvement, which has a degrading effect on the plant growing process.

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Section: Related Workmentioning

confidence: 99%

Smart indoor gardening: elevating growth, health, and automation

Alrawashdeh,

Alkore Alshalabi,

Al-Jaafreh

et al. 2024

Bulletin EEI

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“…One infrastructure of IoT enabling resource and application access over the internet is cloud computing. Cloud computing comprises three parts: characteristics, service models, and implementation models (Amjad et al, 2017;Marcheriz & Fitriani, 2023). However, besides this option, another alternative is fog computing.…”

Section: Introductionmentioning

confidence: 99%

Analysis of Multi-Node QoS in Shrimp Pond Monitoring System with Fog Computing

Anisah,

Munadi,

Away

et al. 2024

SinkrOn

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Most of Indonesia’s territory consists of oceans, presenting a significant potential for developing the fisheries sector. Shrimp is among Indonesia’s flagship commodities with substantial export potential. Internationally, Indonesia holds the fourth position as the largest exporter of frozen shrimp globally. However, shrimp cultivation faces various challenges, including declining water quality due to factors such as water sources and weather, which can adversely affect harvest yields. To preempt potential failures, employing smart devices and technology in shrimp cultivation offers an effective and efficient solution for monitoring and management. This study aims to analyze water quality monitoring in ponds considering the speed of data transmission from end devices to fog using Quality of Service (QoS) parameters like delay/latency, throughput, and packet loss. Data transmission tests were conducted at data rates of 5 Mbps and 10 Mbps, with a bandwidth of 1500 Mbps. The study involves three sensors—water temperature, pH, and salinity—placed in shrimp ponds. Test results showed a decrease in throughput by 1.54% at the sensor node and 2.99% at the sink node when packet data delivery encountered barriers like obstacles. There was a 74.13% increase in latency when the delivery distance extended to 35 meters. The achievable delivery range with low latency was up to 10 meters with barriers and 25 meters without. Thus, latency and throughput values vary depending on the presence of barriers and transmission distance. Barriers tend to increase latency and decrease throughput.

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