Water Quality Monitoring Using Wireless Sensor Networks

Adu-Manu, Kofi Sarpong; Tapparello, Cristiano; Heinzelman, Wendi; Katsriku, Ferdinand Apietu; Abdulai, Jamal-Deen

doi:10.1145/3005719

Cited by 239 publications

(148 citation statements)

References 103 publications

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“…In addition, pollution and wreckage detection techniques have been presented to monitor the quality of water [305]. A comprehensive survey of water quality monitoring systems by using sensor networks is presented in [306].…”

Section: ) Ocean Samplingmentioning

confidence: 99%

Underwater optical wireless communications, networking, and localization: A survey

et al. 2019

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Underwater wireless communications can be carried out through acoustic, radio frequency (RF), and optical waves. Compared to its bandwidth limited acoustic and RF counterparts, underwater optical wireless communications (UOWCs) can support higher data rates at low latency levels. However, severe aquatic channel conditions (e.g., absorption, scattering, turbulence, etc.) pose great challenges for UOWCs and significantly reduce the attainable communication ranges, which necessitates efficient networking and localization solutions. Therefore, we provide a comprehensive survey on the challenges, advances, and prospects of underwater optical wireless networks (UOWNs) from a layer by layer perspective which includes: 1) Potential network architectures; 2) Physical layer issues including propagation characteristics, channel modeling, and modulation techniques 3) Data link layer problems covering link configurations, link budgets, performance metrics, and multiple access schemes; 4) Network layer topics containing relaying techniques and potential routing algorithms; 5) Transport layer subjects such as connectivity, reliability, flow and congestion control; 6) Application layer goals and state-of-the-art UOWN applications, and 7) Localization and its impacts on UOWN layers. Finally, we outline the open research challenges and point out the future directions for underwater optical wireless communications, networking, and localization research.

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Section: ) Ocean Samplingmentioning

confidence: 99%

Underwater optical wireless communications, networking, and localization: A survey

et al. 2019

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“…Obviously, land‐cover, human infrastructure, vegetation, and physiography are understood to be important variables, and for LR basins, there is a good chance that appropriate data layers derived from remote sensing already exist and might be freely available. Remote sensing of land‐cover and so forth is well established, and now, high‐frequency, automated monitoring of water quality is also becoming more accessible (Adu‐Manu, Tapparello, Heinzelman, Katsriku, & Abdulai, ; Hou et al, ). On the Hudson, there is a network of ~12 real‐time observation sites spread above the head of tide down to NYC allowing scientists, regulators, or other interested parties to watch the behaviour of the Hudson in near‐real time.…”

Section: Hudson River As Case Studymentioning

confidence: 99%

“…Remote sensing of land-cover and so forth is well established, and now, high-frequency, automated monitoring of water quality is also becoming more accessible (Adu-Manu, Tapparello, Heinzelman, Katsriku, & Abdulai, 2017;Hou et al, 2017). On the Hudson, there is a network of~12 real-time observation sites spread above the head of tide down to NYC allowing scientists, regulators, or other interested parties to watch the behaviour of the Hudson in near-real time.…”

Section: Hudson River As Case Studymentioning

confidence: 99%

The bright side of linking science and management in large river ecosystems: The Hudson River case study

Findlay

2018

River Research & Apps

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Large river ecosystems (LRE) are important components of global cycles, influence large parts of the earth's surface, and provide many services in support of human civilization. However, understanding their condition, functioning, and trajectory of change is difficult in part due to their scale and diversity of forcing factors but also due to multiple and potentially conflicting human uses. Although these challenges are generally applicable and probably true to some degree for any large river ecosystem, there are also attributes of LRE that foster scientific understanding, can lead to knowledge‐based management, and may catalyse their interaction. The absolute size of LRE means they will be complex, unique and the water quality, physical character, or habitat availability at any particular point may be the result of drivers acting further up the basin or legacies from previous times. On the bright side however, their absolute size also means there will be existing information on many important features, not least land cover and hydrology. Moreover, it is highly likely there will be a sizeable human population in the basin that derives some benefits from the river even if just in a narrow anthropocentric fashion and so there will be some motivation for understanding characteristics and potential change. Large size also suggests that the LRE will be viewed (perhaps with some basis in law) as a national or regional resource making it (at least nominally) worthy of study and management. I provide some examples of how science and management of the Hudson River in New York, USA, have benefitted from some of these perceived difficulties perhaps offering optimism for application in other systems.

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“…Perkembangan sistem pemantauan kualitas air saat ini cenderung mengarah ke sistem yang berbasis Wireless Sensor Network (WSN), terutama pada pemantauan kualitas air di daerah laut [6], [7]. Selain pemantauan kualitas air laut, sistem pemantauan ketinggian permukaan air sungai maupun air tanah berbasis WSN juga mulai dikembangkan [8].…”

Section: Pendahuluanunclassified

“…Dari penelitian yang sudah dilakukan ini, diharapkan purwarupa yang dibangun dapat dikembangkan lebih lanjut menjadi sistem pemantauan kualitas air pada daerah aliran sungai [11] yang siap digunakan. Sistem pemantauan kualitas air dengan menggunakan WSN [6]- [9] pada aliran sungai yang memanjang diharapkan dapat lebih maksimal karena menggunakan topologi mesh [5] yang bersifat multi-hop dibanding dengan menggunakan topologi star yang bersifat single-hop [3], [4].…”

Section: Hasil Dan Pembahasanunclassified

Web Monitoring System of pH Level, Temperature and Color on River Water using Wireless Sensor Network

Sabiq

Budisejati

2017

Jurnal Teknologi dan Sistem Komputer

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-Water is a very important natural resource for human life and other living things. Water pollution, especially in river water, should be controlled because of the rapid development. One technology to monitor multiple physical quantities scattered in a region is the Wireless Sensor Network (WSN). WSN technology has the ability to transmit data from sensor readings and forward data received from other nodes. In this study, prototype monitoring system of pH level, temperature, and color based on WSN that can be monitored through the developed web. The sensors at each node are connected to Arduino Uno as a processing unit, data read from the sensor is sent to the sync node via XBee wireless device. In the sink, the PC also serves as a database server and a web server is used. Test results with two different dispersion indicate that sensor readings can be read by all nodes and received by the sync node and can be displayed on web pages that have been built. Keywords -WSN; Web; River water Abstrak -Air merupakan sumber daya alam yang sangat penting bagi kehidupan manusia dan mahluk hidup lainnya. Pencemaran air khususnya air sungai perlu dikendalikan seiring makin cepatnya pembangunan. Salah satu teknologi untuk melakukan pemantauan besaran fisik dalam wilayah yang tersebar adalah Wireless Sensor Network (WSN), yang memiliki kemampuan untuk mengirimkan data hasil pembacaan sensor serta meneruskan data yang diterima dari node lain. Pada penelitian ini dikembangkan purwarupa sistem pemantauan kadar pH, suhu dan warna berbasis WSN yang dapat dipantau melalui web. Sensor pada setiap node dihubungkan ke Arduino Uno sebagai unit pemroses, data yang dibaca dari sensor dikirimkan ke node sink melalui perangkat XBee nirkabel. Pada sink digunakan PC yang berfungsi juga sebagai database server dan web server. Hasil dari pengujian dengan dua penyebaran yang berbeda didapatkan hasil bahwa pembacaan sensor dapat dibaca oleh seluruh node dan diterima oleh sink serta dapat ditampilkan melalui laman web yang telah dibangun. Kata Kunci -WSN; Web; Air sungai I. PENDAHULUANAir merupakan salah satu sumber daya alam yang penting bagi kehidupan manusia dan mahluk hidup lainnya, air juga dapat mempengaruhi dan dipengaruhi oleh kondisi/komponen lainnya [1]. Air permukaan yang ada seperti sungai dan situ banyak dimanfaatkan untuk keperluan manusia seperti tempat penampungan air, alat transportasi, mengairi sawah dan keperluan peternakan, keperluan industri, perumahan, sebagai daerah tangkapan air, pengendali banjir, ketersediaan air, irigasi, tempat memelihara ikan dan juga sebagai tempat rekreasi [1].Tetapi akibat pemanfaatan manusia tersebut, air dapat mengalami dampak kerusakan baik secara langsung maupun tidak langsung. Salah satu dampak dari kerusakan air adalah terjadinya pencemaran pada air sungai, yang umumnya berasal dari limbah domestik ataupun non domestik [2]. Dari hal tersebut, pencemaran air, khususnya air sungai, perlu dikendalikan seiring makin cepatnya pembangunan agar manfaat air sungai dapat terus dilestarikan.Sala...

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Water Quality Monitoring Using Wireless Sensor Networks

Cited by 239 publications

References 103 publications

Underwater optical wireless communications, networking, and localization: A survey

Underwater optical wireless communications, networking, and localization: A survey

The bright side of linking science and management in large river ecosystems: The Hudson River case study

Web Monitoring System of pH Level, Temperature and Color on River Water using Wireless Sensor Network

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