Toward automating post processing of aquatic sensor data

Jones, Amber Spackman; Jones, Tanner; Horsburgh, Jeffery S.

doi:10.31223/x5z62x

Cited by 3 publications

(4 citation statements)

References 36 publications

(102 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Applying the same R 2 coefficient to our simulations, we achieved R 2 values between 0.976 and 0.997 when 40% of the dataset was removed and between 0.119 and 0.994 (first quartile = 0.84) when sequences of 10 days were removed, indicating that our method attains a comparatively good performance, particularly for point and short periods of missing data. Blending ARIMA forecasts and backcasts has also shown promise for reconstruction of sensor-based water quality data, including temperature, pH, specific conductance, and dissolved oxygen [ 58 ]. However, we are unable to compare our results with this work given that performance of the correction method was assessed by comparing the ARIMA-based results with corrections done manually by technicians.…”

Section: Discussionmentioning

confidence: 99%

Reconstructing Missing and Anomalous Data Collected from High-Frequency In-Situ Sensors in Fresh Waters

Kermorvant

Liquet

Litt

et al. 2021

IJERPH

View full text Add to dashboard Cite

In situ sensors that collect high-frequency data are used increasingly to monitor aquatic environments. These sensors are prone to technical errors, resulting in unrecorded observations and/or anomalous values that are subsequently removed and create gaps in time series data. We present a framework based on generalized additive and auto-regressive models to recover these missing data. To mimic sporadically missing (i) single observations and (ii) periods of contiguous observations, we randomly removed (i) point data and (ii) day- and week-long sequences of data from a two-year time series of nitrate concentration data collected from Arikaree River, USA, where synoptically collected water temperature, turbidity, conductance, elevation, and dissolved oxygen data were available. In 72% of cases with missing point data, predicted values were within the sensor precision interval of the original value, although predictive ability declined when sequences of missing data occurred. Precision also depended on the availability of other water quality covariates. When covariates were available, even a sudden, event-based peak in nitrate concentration was reconstructed well. By providing a promising method for accurate prediction of missing data, the utility and confidence in summary statistics and statistical trends will increase, thereby assisting the effective monitoring and management of fresh waters and other at-risk ecosystems.

show abstract

Section: Discussionmentioning

confidence: 99%

Reconstructing Missing and Anomalous Data Collected from High-Frequency In-Situ Sensors in Fresh Waters

Kermorvant

Liquet

Litt

et al. 2021

IJERPH

View full text Add to dashboard Cite

show abstract

“…It is often the case that sensors and autoanalyzers have technical problems which can result in a signi cant number of gaps in the data. The post processing of the data, including identi cation of errors and lling missing values can be time consuming and the nal result depends on the individual who does the post processing (Jones et al, 2021). Furthermore, the amount of data collected by high-frequency sensors can easily exceed the amount of data that can be treated manually (Dupas et al, 2015;Kirchner & Neal, 2013).…”

Section: Introductionmentioning

confidence: 99%

Value and limitations of Machine Learning in high-frequency nutrient data for gap- filling, forecasting, and transport process interpretation

Barcala

Rozemeijer

Ouwerkerk

et al. 2022

Preprint

View full text Add to dashboard Cite

High-frequency monitoring of water quality in catchments brings along the challenge of post-processing large amounts of data. Moreover, monitoring stations are often remote and technical issues resulting in data gaps are common. Machine Learning algorithms can be applied to fill these gaps, and to a certain extent, for predictions and interpretation. The objectives of this study were (1) to evaluate six different Machine Learning models for gap-filling in a high-frequency nitrate and total-phosphorus concentration time series, (2) to showcase the potential added value (and limitations) of Machine Learning to interpret underlying processes, and (3) to study the limits of Machine Learning algorithms for predictions outside the training period. We used a four-year high-frequency dataset from a ditch draining one intensive dairy farm in the east of The Netherlands. Continuous time series of precipitation, evaporation, groundwater levels, discharge, turbidity, and nitrate or total-phosphorus were used as predictors for total-phosphorus and nitrate concentrations respectively. Our results showed that the Random Forest algorithm had the best performance to fill in data-gaps, with R2 higher than 0.92 and short computation times. The feature importance helped understanding the changes in transport processes linked to water conservation measures and rain variability. Applying the Machine Learning model outside the training period resulted in a low performance, largely due to system changes (manure surplus and water conservation) which were not included as predictors. This study offers a valuable and novel example of how to use and interpret Machine Learning models for post-processing high-frequency water quality data.

show abstract

“…Moreover, standardization of post-processing high-frequency data is also challenging as currently, the final result depends largely on the person who did the data analysis (Jones et al, 2021). To observe the bigger picture in nutrient transport and to evaluate trends related to rain variability and climate change, more long-term high-quality continuous water quality data series are needed.…”

Section: Relevant Previous Research On Iron-associated Phosphorus Ret...mentioning

confidence: 99%

“…It is often the case that sensors and autoanalyzers have technical problems which can result in a significant number of gaps in the data. The post processing of the data, including identification of errors and filling missing values can be time consuming and the final result depends on the individual who does the post processing (Jones et al, 2021). Furthermore, the amount of data collected by high-frequency sensors can easily exceed the amount of data that can be treated manually (Dupas et al, 2015;Kirchner & Neal, 2013).…”

Section: Introductionmentioning

confidence: 99%

Improving the management of drained agricultural areas to optimize the retention of iron-associated phosphorus

Barcala¹

View full text Add to dashboard Cite

This research was motivated by the impact of the diffuse P sources coming from agriculture on surface water quality and eutrophication. The goal of this Ph.D. thesis was to contribute to improving the management of drained agricultural areas to optimize the retention of Fe-associated P. Because of the legacy P in the soil, P-retention measures are needed in agricultural catchments to improve the surface water quality in the short- to middle-term. The first part of this thesis focused on monitoring the P transport at the farm scale. The second part of this thesis focused on investigating the mechanisms of P-retention by iron-coated sand (ICS), a Fe-rich by-product from drinking water production.

show abstract

Toward automating post processing of aquatic sensor data

Cited by 3 publications

References 36 publications

Reconstructing Missing and Anomalous Data Collected from High-Frequency In-Situ Sensors in Fresh Waters

Reconstructing Missing and Anomalous Data Collected from High-Frequency In-Situ Sensors in Fresh Waters

Value and limitations of Machine Learning in high-frequency nutrient data for gap- filling, forecasting, and transport process interpretation

Improving the management of drained agricultural areas to optimize the retention of iron-associated phosphorus

Contact Info

Product

Resources

About