Difference between revisions of "COSH-tool"

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{{Note|This technology has been enhanced in the FIThydro project! See [[Innovative technologies from FIThydro]] for a complete list.|reminder}}
 
=Quick summary=
 
=Quick summary=
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[[file:cosh_tool_lundesoka.png|thumb|250px|Figure 1: The river Lundesokna in Norway downstream of a peaking hydropower plant. COSH-Tool can be used to asses many aspects of peaking operations (source:SINTEF Energy Research).]]
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[[file:cosh_tool_parameters.png|thumb|250px|Figure 2: List of parameters computed by COSH-Tool (click to expand) (source:SINTEF Energy Research).]]
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[[file:cosh_tool_peaks_hour.png|thumb|250px|Figure 3: Distribution of peak events though the day (click to expand)(source:SINTEF Energy Research).]]
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[[file:cosh_tool_peaks_day.png|thumb|250px|Figure 4: Number of peak events per day for each year of the time series (click to expand)(source:SINTEF Energy Research).]]
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[[file:cosh_tool_light.png|thumb|250px|Figure 5: Distribution of peak events (increasing events) per month according to light conditions (click to expand)(source:SINTEF Energy Research).]]
 
Developed by: SINTEF Energy Research
 
Developed by: SINTEF Energy Research
  
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Type: Tool (computer model)  
 
Type: Tool (computer model)  
 
Suitable for the following [[::Category:Measures|measures]]: [[Mitigating_rapid,_short-term_variations_in_flow_(hydro-peaking_operations)|Mitigating rapid, short-term variations in flow (hydro-peaking operations)]] in all phases (planning, implementation, maintenance)
 
  
 
=Introduction=
 
=Introduction=
COSH-Tool is a software written in [https://www.python.org Python] used for quantifying fluctuations in water level and discharge which may occur in rivers subjected to hydropeaking. COSH-Tool was developed at SINTEF Energy as a part of the [https://www.cedren.no/english/home CEDREN] EnviPeak project (Norwegian Research Council, Grant number 193818) with the aim of providing characteristics of hydropeaking events in regulated rivers in order to classify the hydropeaking regimes of rivers.
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COSH-Tool is a software written in [https://www.python.org Python] used for quantifying fluctuations in water level and discharge which may occur in rivers subjected to hydropeaking. COSH-Tool was developed at SINTEF Energy as a part of the [https://www.cedren.no/english/home CEDREN] EnviPeak project (Norwegian Research Council, Grant number 193818), with the aim of providing characteristics of hydropeaking events in regulated rivers, in order to classify the hydropeaking regimes of rivers.
 
The tool enables the analysis of long time series of water level or discharge by applying an automated processing to the time series. It provides a set of indicators that characterize fluctuations of water level and discharge in rivers and lakes/reservoirs.
 
The tool enables the analysis of long time series of water level or discharge by applying an automated processing to the time series. It provides a set of indicators that characterize fluctuations of water level and discharge in rivers and lakes/reservoirs.
 
[[file:Lundesokna high low.png|800px|Figure 1. The river Lundesokna in Norway downstream a peaking hydropower plant. COSH-Tool can be used to asses many aspects of peaking operations]]
 
  
 
=Application=
 
=Application=
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Input files:  
 
Input files:  
The input file is a water level or discharge time series. COSH-Tool handles time series with typical time step ranging from minute to hour.  
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The input file is a water level or discharge time series. COSH-Tool handles time series with any resolution, typically with time steps ranging from minutes to hours.
  
 
Output files:  
 
Output files:  
COSH-Tool computes a set of parameters that characterise water level and discharge fluctuations. The parameters can be classified in three categories: 1) magnitude of the variations; 2) timing and rapidity; and 3) frequency. The parameters are listed in Table 1.
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COSH-Tool computes a set of parameters that characterise water level and discharge fluctuations. The parameters can be classified in three categories of fluctuations: 1) magnitude ; 2) timing and rapidity; and 3) frequency. The parameters are listed in Figure 2.
  
[[file:COSH parameters.JPG|650px|Table 1. List of parameters computed by COSH-Tool]]
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The output from COSH-Tool consists in a table with statistics of the magnitude and timing parameters (category 1 and 2) and a set of corresponding graphs. Statistics are min, max, mean, median, standard deviation and percentiles. They can be computed for the entire time series, as well as on a monthly, seasonal and annual basis. Statistics are also displayed in the form of box plots.
  
The output from COSH-Tool consists in a table with statistics of the magnitude and timing parameters (category 1 and 2) and a set of graphs of corresponding graphs. Statistics are min, max, mean, median, standard deviation and percentiles. They can be computed for the entire time series, as well as on a monthly, seasonal and yearly basis. Statistics are also displayed in the form of box plots.
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COSH-Tool also provides values and graphs for all frequency parameters (category 3), namely distribution of peaks throughout the day (Figure 3), number of peaks per day for each year of the time series (Figure 4), and total number of peak events per year.
  
COSH-Tool provides also values and graphs for all frequency parameters (category 3), namely distribution of peaks throughout the day (Figure 2), number of peaks per day for each year of the time series (Figure 3), and total number of peak events per year.
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Additionally, the light conditions (day, twilight, darkness) at the time of the occurrence of the peaks can be computed. A graph provides the proportion of peaks occurring at the different types of light conditions per month (Figure 5).
  
[[file:COSH_peaks.png|500px|Figure 2. Distribution of peaks events throughout the day.]]
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=Relevant mitigation measures and test cases=
[[file:COSH_peaks2.png|500px|Figure 3. Number of peak events per day for each year of the time series.]]
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{{Suitable measures for COSH-tool}}
 
 
Additionally, the light conditions (day, twilight, darkness) at the time of the occurrence of the peaks can be computed. A graph provides the proportion of peaks occurring at the different types of light conditions per month (Figure 4).
 
 
 
[[file:COSH_peaks3.png|300px|Figure 4.  Distribution of peak events (decreasing events) per month and according to light conditions]]
 
  
 
=Other information=
 
=Other information=
The COSH-Tool is free of use after agreement with SINTEF Energy Research.
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The COSH-Tool is free to use after agreement with SINTEF Energy Research.
 
=Contact information=
 
=Contact information=
 
Julie.charmasson@sintef.no
 
Julie.charmasson@sintef.no
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lennart.schonfelder@sintef.no
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=Relevant literature=
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*[https://www.researchgate.net/publication/260442647_A_computational_tool_for_the_characterisation_of_rapid_fluctuations_in_flow_and_stage_in_rivers_caused_by_hydropeaking Sauterleute J. and Charmasson J. 2014]. A computational tool for the characterisation of rapid fluctuations in flow and stage in rivers caused by hydropeaking. <i>Environmental Modelling & Software</i> <b>55</b>:266-278.
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*[http://proceedings.ise2016.org/tracks/1105/abstract/26774.html Charmasson, J. 2016]. COSH-Tool, a computational tool for the characterization of rapid fluctuations in flow and stage in rivers caused by hydropeaking. <i>Proceedings of 11th International Symposium on Ecohydraulics, Melbourne, Australia.</i>
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*Caetano, L., Pinheiro, A. and Boavida, I. 2018. Analysis of the effects of a hydropower plant in the downstream fish habitat. COSH-tool application. <i>Proceedings of 12th International Symposium on Ecohydraulics, Tokyo, Japan.</i>
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[[Category:Tools]] [[Category:Enhanced in FIThydro]]

Latest revision as of 13:03, 26 October 2020

This technology has been enhanced in the FIThydro project! See Innovative technologies from FIThydro for a complete list.

Quick summary

Figure 1: The river Lundesokna in Norway downstream of a peaking hydropower plant. COSH-Tool can be used to asses many aspects of peaking operations (source:SINTEF Energy Research).
Figure 2: List of parameters computed by COSH-Tool (click to expand) (source:SINTEF Energy Research).
Figure 3: Distribution of peak events though the day (click to expand)(source:SINTEF Energy Research).
Figure 4: Number of peak events per day for each year of the time series (click to expand)(source:SINTEF Energy Research).
Figure 5: Distribution of peak events (increasing events) per month according to light conditions (click to expand)(source:SINTEF Energy Research).

Developed by: SINTEF Energy Research

Date: 27-11-2018

Type: Tool (computer model)

Introduction

COSH-Tool is a software written in Python used for quantifying fluctuations in water level and discharge which may occur in rivers subjected to hydropeaking. COSH-Tool was developed at SINTEF Energy as a part of the CEDREN EnviPeak project (Norwegian Research Council, Grant number 193818), with the aim of providing characteristics of hydropeaking events in regulated rivers, in order to classify the hydropeaking regimes of rivers. The tool enables the analysis of long time series of water level or discharge by applying an automated processing to the time series. It provides a set of indicators that characterize fluctuations of water level and discharge in rivers and lakes/reservoirs.

Application

COSH-Tool can be applied to any water level or discharge time series provided by measurements (field work) or simulation (numerical modelling). The analysis of the time series with COSH-Tool does not require any coding from the user and is executed through an interface.

Input files: The input file is a water level or discharge time series. COSH-Tool handles time series with any resolution, typically with time steps ranging from minutes to hours.

Output files: COSH-Tool computes a set of parameters that characterise water level and discharge fluctuations. The parameters can be classified in three categories of fluctuations: 1) magnitude ; 2) timing and rapidity; and 3) frequency. The parameters are listed in Figure 2.

The output from COSH-Tool consists in a table with statistics of the magnitude and timing parameters (category 1 and 2) and a set of corresponding graphs. Statistics are min, max, mean, median, standard deviation and percentiles. They can be computed for the entire time series, as well as on a monthly, seasonal and annual basis. Statistics are also displayed in the form of box plots.

COSH-Tool also provides values and graphs for all frequency parameters (category 3), namely distribution of peaks throughout the day (Figure 3), number of peaks per day for each year of the time series (Figure 4), and total number of peak events per year.

Additionally, the light conditions (day, twilight, darkness) at the time of the occurrence of the peaks can be computed. A graph provides the proportion of peaks occurring at the different types of light conditions per month (Figure 5).

Relevant mitigation measures and test cases

Relevant measures
Fish refuge under hydropeaking conditions
Mitigating rapid, short-term variations in flow (hydro-peaking operations)
Mitigating reduced annual flow and low flow measures
Mitigating reduced flood peaks, magnitudes, and frequency
Relevant test cases Applied in test case?
Anundsjö test case -
Bragado test case Yes

Other information

The COSH-Tool is free to use after agreement with SINTEF Energy Research.

Contact information

Julie.charmasson@sintef.no

lennart.schonfelder@sintef.no

Relevant literature

  • Sauterleute J. and Charmasson J. 2014. A computational tool for the characterisation of rapid fluctuations in flow and stage in rivers caused by hydropeaking. Environmental Modelling & Software 55:266-278.
  • Charmasson, J. 2016. COSH-Tool, a computational tool for the characterization of rapid fluctuations in flow and stage in rivers caused by hydropeaking. Proceedings of 11th International Symposium on Ecohydraulics, Melbourne, Australia.
  • Caetano, L., Pinheiro, A. and Boavida, I. 2018. Analysis of the effects of a hydropower plant in the downstream fish habitat. COSH-tool application. Proceedings of 12th International Symposium on Ecohydraulics, Tokyo, Japan.