Coupling high-resolution field monitoring and MODIS for reconstructing wetland historical hydroperiod at a high temporal frequency

Abstract In the era of Smart Cities, in which the paradigms of smart water and smart grid are keywords of technological progress, advancements in metering systems allow for water consumption data collection at the end-use level, which is necessary to profile users' behaviors and to promote sustainable use of water resources. In this paper, a real case study of residential water end-use consumption monitoring shows how data collected at a high-resolution rate allow for the evaluation of consumption profiles. The analysis was carried out by calculating consumption statistics, hourly consumption patterns, daily use frequency, and weekly use frequency. Then, the comparison of two consumption profiles, computed before and after the COVID-19 lockdown, allows us to understand how a change in social and economic factors can affect users' behavior. Finally, new perspectives for water demand modeling and management, based on data with high temporal frequency, are presented.

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STAIR 2.0: A Generic and Automatic Algorithm to Fuse Modis, Landsat, and Sentinel-2 to Generate 10 m, Daily, and Cloud-/Gap-Free Surface Reflectance Product

Remote Sensing ◽

10.3390/rs12193209 ◽

2020 ◽

Vol 12 (19) ◽

pp. 3209

Author(s):

Yunan Luo ◽

Kaiyu Guan ◽

Jian Peng ◽

Sibo Wang ◽

Yizhi Huang

Keyword(s):

Time Series ◽

High Resolution ◽

Satellite Data ◽

Temporal Frequency ◽

Fusion Product ◽

High Temporal Resolution ◽

Surface Reflectance ◽

Land Surfaces ◽

Fine Resolution ◽

Sentinel 2

Remote sensing datasets with both high spatial and high temporal resolution are critical for monitoring and modeling the dynamics of land surfaces. However, no current satellite sensor could simultaneously achieve both high spatial resolution and high revisiting frequency. Therefore, the integration of different sources of satellite data to produce a fusion product has become a popular solution to address this challenge. Many methods have been proposed to generate synthetic images with rich spatial details and high temporal frequency by combining two types of satellite datasets—usually frequent coarse-resolution images (e.g., MODIS) and sparse fine-resolution images (e.g., Landsat). In this paper, we introduce STAIR 2.0, a new fusion method that extends the previous STAIR fusion framework, to fuse three types of satellite datasets, including MODIS, Landsat, and Sentinel-2. In STAIR 2.0, input images are first processed to impute missing-value pixels that are due to clouds or sensor mechanical issues using a gap-filling algorithm. The multiple refined time series are then integrated stepwisely, from coarse- to fine- and high-resolution, ultimately providing a synthetic daily, high-resolution surface reflectance observations. We applied STAIR 2.0 to generate a 10-m, daily, cloud-/gap-free time series that covers the 2017 growing season of Saunders County, Nebraska. Moreover, the framework is generic and can be extended to integrate more types of satellite data sources, further improving the quality of the fusion product.

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Temporal and Spatial Interpolation Errors of High-Resolution Modeled Atmospheric Fields

Journal of Atmospheric and Oceanic Technology ◽

10.1175/jtech-d-15-0132.1 ◽

2016 ◽

Vol 33 (2) ◽

pp. 303-311 ◽

Cited By ~ 4

Author(s):

N. C. Privé ◽

R. M. Errico

Keyword(s):

High Resolution ◽

Spatial Resolution ◽

General Circulation ◽

Temporal Frequency ◽

General Circulation Models ◽

Specific Humidity ◽

Tropospheric Temperature ◽

Model Output ◽

Time Step ◽

Optimal Output

AbstractGeneral circulation models can now be run at very high spatial resolutions to capture finescale features, but saving the full-spatial-resolution output at every model time step is usually not practical because of storage limitations. To reduce storage requirements, the model output may be produced at reduced temporal and/or spatial resolutions. When this reduced-resolution output is then used in situations where spatiotemporal interpolation is required, such as the generation of synthetic observations for observing system simulation experiments, interpolation errors can significantly affect the quality and usefulness of the reduced-resolution model output. Although it is common in practice to record model output at the highest possible spatial resolution with relatively infrequent temporal output, this may not be the best option to minimize interpolation errors. In this study, two examples using a high-resolution global run of the Goddard Earth Observing System Model, version 5 (GEOS-5), are presented to illustrate cases in which the optimal output dataset configurations for interpolation have high temporal frequency but reduced spatial resolutions. Interpolation errors of tropospheric temperature, specific humidity, and wind fields are investigated. The relationship between spatial and temporal output resolutions and interpolation errors is also characterized for the example model.

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Understanding the PM2.5 imbalance between a far and near-road location: Results of high temporal frequency source apportionment and parameterization of black carbon

Atmospheric Environment ◽

10.1016/j.atmosenv.2017.10.063 ◽

2018 ◽

Vol 173 ◽

pp. 277-288 ◽

Cited By ~ 22

Author(s):

U.M. Sofowote ◽

R.M. Healy ◽

Y. Su ◽

J. Debosz ◽

M. Noble ◽

...

Keyword(s):

Black Carbon ◽

Source Apportionment ◽

Temporal Frequency ◽

High Temporal Frequency ◽

Frequency Source

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Hazardous nature of high-temporal-frequency strobe light stimulation: neural mechanisms revealed by magnetoencephalography

Neuroscience ◽

10.1016/j.neuroscience.2009.12.077 ◽

2010 ◽

Vol 166 (2) ◽

pp. 482-490 ◽

Cited By ~ 4

Author(s):

Y. Shigihara ◽

M. Tanaka ◽

N. Tsuyuguchi ◽

H. Tanaka ◽

Y. Watanabe

Keyword(s):

Temporal Frequency ◽

Neural Mechanisms ◽

Light Stimulation ◽

Strobe Light ◽

High Temporal Frequency

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A Development Strategy for SHM Applications

Journal of Nondestructive Evaluation Diagnostics and Prognostics of Engineering Systems ◽

10.1115/1.4051974 ◽

2021 ◽

pp. 1-17

Author(s):

Peter Cawley

Keyword(s):

Spatial Frequency ◽

Development Strategy ◽

Temporal Frequency ◽

High Spatial Frequency ◽

Operating Conditions ◽

Damage Growth ◽

Periodic Inspection ◽

High Temporal Frequency ◽

Industrial Use ◽

Signal Changes

Abstract Permanently installed SHM systems are now a viable alternative to traditional periodic inspection (NDT). However, their industrial use is limited and this paper reviews the steps required in developing practical SHM systems. The transducers used in SHM are fixed in location, whereas in NDT they are generally scanned. The aim is to reach similar performance with high temporal frequency, low spatial frequency SHM data to that achievable with conventional high spatial frequency, low temporal frequency NDT inspections. It is shown that this can be done via change tracking algorithms such as the Generalized Likelihood Ratio (GLR) but this depends on the input data being normally distributed, which can only be achieved if signal changes due to variations in the operating conditions are satisfactorily compensated; there has been much recent progress on this topic and this is reviewed. Since SHM systems can generate large volumes of data, it is essential to convert the data to actionable information, and this step must be addressed in SHM system design. It is also essential to validate the performance of installed SHM systems, and a methodology analogous to the model assisted POD (MAPOD) scheme used in NDT has been proposed. This uses measurements obtained from the SHM system installed on a typical undamaged structure to capture signal changes due to environmental and other effects, and to superpose the signal due to damage growth obtained from finite element predictions. There is a substantial research agenda to support the wider adoption of SHM and this is discussed.

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