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You can edit the properties of the source node by: 

  • Double-clicking the left mouse button over the source node icon; or

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Navigating Through the Dialogue Boxes

You can click on any tab and  and can edit any of the data presented on in the active dialogue box. The Source Tab

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The Source contains 3 options:

  1. Generate: default option which generates both runoff and contaminants based on the provided parameters
  2. Custom Flow and Generate Contaminants: this allows you to import flow time series data, resulting in the stochastic generation of constituents
  3. Custom Flow and Contaminants: this allows you to import time series data of total runoff and associated contaminants 

Generate

This Tab contains Land Use/Zoning type, the total area, and the percentage of impervious and pervious area for that source node. It also contains the hydrologic parameters used by the rainfall-runoff model. For more information on model structure, operation and suggested parameter ranges see Rainfall Runoff Modelling.

Land Use/Zoning Type

For source nodes, select the zoning or surface type. This will change the water quality parameters used in the generation of pollutants from the source node to values appropriate for that zoning or surface type.  See below for more details. 

Total Area

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The area information forms part of the input to MUSIC’s rainfall runoff model, derived from a model developed by the CRC for Catchment Hydrology (Chiew & McMahon, 1997). For a diagram of the model structure and a brief description of its operation, see Appendix A : - Rainfall-Runoff Modelling. Further guidance on setting appropriate parameters for the rainfall runoff model is contained in the Appendices, especially for parameters specific to particular regions.

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Each component of runoff is calculated using the information above and a daily time-step. Each component is then disaggregated to the required time-step, using the detailed rainfall pattern and a technique appropriate to that component. For more information on disaggregation see Appendix A : - Rainfall-Runoff Modelling.


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Water Quality Parameter Dialogue Boxes

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Anchor
ZoningSurfaceTypes
ZoningSurfaceTypes
Land Use/ Zoning Types

For  source nodes, each land use/zoning type has appropriate base flow and storm flow pollutant concentrations for that zoning (eg. rural residential) or surface type (eg, sealed roads, unsealed roads). The selection of  Land Use/Zoning Type on Source Tab  changes the default values displayed on Total Suspended Solids, Total Phosphorous and Total Nitrogen Tabs. Prior to MUSIC version 6.2, MUSIC had three source nodes, Urban, Agricultural and Forest. The 'mixed' Zoning/Surface type contains the same pollutant concentration parameters as the prior default 'Urban' values. For all other Zoning/Surface types, the pollutant concentration parameters are Sydney Catchment Authority (2012).

Table 1. Default pollutant concentrations for each source node



Source Node Type



Zoning/Surface Type

Pollutant Concentration (log mg/L)
Total Suspended SolidsTotal PhosphorusTotal Nitrogen
Base FlowStorm FlowBase FlowStorm FlowBaseStorm
MeanStd DevMeanStd DevMeanStd DevMeanStd DevMeanStd DevMeanStd Dev
Agricultural -1.400.132.300.31-0.880.13-0.270.300.0740.1300.590.26
Forest

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0.900.131.900.20-1.500.13-1.100.22-0.140.13-0.0750.240






Urban

Mixed1.100.172.200.32-8.200.19-0.450.250.320.120.420.19
Roof1.100.171.300.32-8.200.19-0.890.250.320.120.300.19
Sealed Road1.200.172.430.32-8.500.19-0.300.250.110.120.340.19
Unsealed road1.200.173.000.32-8.500.19-0.300.250.110.120.340.19
Eroding gullies1.200.173.000.32-8.500.19-0.300.250.110.120.340.19
Revegetated land1.150.171.950.32-1.220.19-0.660.25-0.050.120.300.19
Quarries1.200.173.000.32-0.850.19-0.300.250.110.120.340.19
Residential1.200.172.150.32-0.850.19-0.600.250.110.120.300.19
Commercial1.200.172.150.32-0.850.19-0.600.250.110.120.300.19
Industrial1.200.172.150.32-0.850.19-0.600.250.110.120.300.19

Rural residential

1.150.171.950.32-1.220.19-0.660.25-0.050.120.300.19
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Tip Box

The default urban parameters were the basis for guidelines such as the Victoria Stormwater Committee (1999) BPEM Guidelines : Stormwater. It is generally recommended that these are adopted when modelling for the purposes of demonstrating compliance with this guideline. This is because using other landuse/surface types will result in larger/smaller treatment systems being required. The percentage reductions set in the guidelines combined with the 'diminishing returns' effect as concentrations decrease mean that if the starting point concentrations are lower, treatment to a percentage reduction will be harder to achieve and the required treatment size will be larger. Conversely, higher concentrations will typically require a smaller treatment system.

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Tip Box

The Mean and Standard Deviation values displayed in the text boxes are displayed as the Log of the concentration in mg/L. 


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 There are two options available for defining pollutant concentration in both the surface and baseflow components of the runoff:

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Time-stepAutocorrelation coefficient
BaseflowStormflow
6-min0.940.95
12-min0.820.93
30-min0.510.84
1-hour0.410.77
3-hour0.370.62
6-hour0.350.50
Day0.310.27

It is important to note that the autocorrelation coefficient will not significantly affect the treatment train effectiveness produced by music, but simply ensures that the variation over time in concentrations during storm events and baseflow conditions is more ‘realistic’.  Depending on the time-step and coefficient used, there can be variations in mean annual loads for the same model run on different computers, however the maximum difference is usually within 10% of the previous run.


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Tip Box

Serial correlation (also called autocorrelation) is the correlation between pollutant concentration at time t, and the previous time-step, t-1. music does not model autocorrelation for lag periods of more than one time-step.


Custom Flow and Generate Contaminants

Custom Flow and Generate Contaminants option as shown in the figure below allows you to import flow time series data, resulting in the stochastic generation of constituents. 

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Custom Flow and Contaminants

There are many situations where you may need to create a node in music which uses imported time-series data (flow, TSS, TP, TN and gross pollutants). It may be used for creating custom-made source nodes, or treatment nodes. For example, you may want to:

  • Import observed (monitored) flow and water quality data at the inflow and/or outflow of a treatment node (e.g. a wetland), to allow you to calibrate the wetland’s treatment performance to the observed data.
  • You may wish to simulate a ‘non-standard’ source of pollutants (e.g. a sewerage treatment plant, that has variable flow and water quality characteristics), for which you have monitoring data
  • You may wish to use monitored streamflow and water quality to create a "receiving node" into which a music simulation discharges, to allow you to monitor your proposed treatment train’s performance against water quality standards.

To create such node, you can choose Custom Flow and Contaminants option in Source node which will allow you to import Total flow along with contaminant time series data as shown below:

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