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What is Urban Developer?

Urban Developer (UD) is an integrated urban water cycle modelling (IUWM) tool designed to meet the needs of water professionals facing the challenges of integrated water cycle service planning and assessment arising from the ever-increasing pressures on Australia’s water resources.

Urban Developer is available as a plugin for eWater Source. The Urban Developer Plugin allows urban water cycle modelling to be integrated within Source's whole-of-river-system modelling framework.

Urban Developer Scope

The Urban Developer allows exploration of urban water systems in a level of detail and Plugin provides for the integration of detailed urban water demand modelling scenarios with whole-of-system Source scenarios with a degree of flexibility not offered by existing integrated models.

Urban Developer provides the ability to simulate all three urban water cycle service networks (water supply, stormwater, wastewater), ranging in scale from a single allotment up to large clusters or small subdivisions.

Allotment Scale

The allotment scale represents household-level water supply, water use and water disposal services, and allows you to evaluate Operating within a Source user environment, urban demand is simulated as one or more scenarios containing representative household-level end use, with outputs which can also be transferred to a water user node in a Source schematic or catchments scenario. This allows the modeller to evaluate, for example: the cumulative effects of individual water end use actions . For example, with Urban Developer's Water Use model, you can examine the cumulative such as the effect of installing water-saving showerheads or dual-flush toilets in individual households.

Cluster Scale

A small grouping of 2 - 30 allotments, businesses and/ or commercial premises.The cluster scale is particularly useful for exploring decentralised supply, treatment, reuse, and disposal options, as it enables potential for some economies of scale in infrastructure delivery, and ameliorates some of the need for expensive centralised distribution and collection infrastructure. 

Subdivision and Suburb Scale

Beyond the cluster scale are the subdivision and suburb scales. Again, there is no clear delineation between these terms as there can be crossovers between them.

For example the term subdivision can be applied to the creation of two or more allotments but is typically used to describe developments in the 10s or 100s of houses.

Beyond the subdivision scale lies the broader suburb / catchment scale. This scale presents a number of key challenges for modellers as the number of houses and service system components becomes computationally prohibitive for individual process modelling. A key application of Urban Developer is as a platform to explore the representation of urban water systems at this scale and understand the impacts of decentralised management practices at the suburb and city scale. 

Urban scenarios model water networks as a series of nodes and links. This lumped approach means that while some node models may have a spatial component, all activity at these nodes is assumed to occur at a single point. Modelling that requires spatial variation should use the functionality available in Source catchment scenarios.the impact of urban water use restrictions on total system water supply.

Figure 1. presents an outline of the steps and options available in creating and modelling Urban end-use demands within Source. While a Source Urban Developer Scenario can be run at a local scale representing single scenario urban demands, it is most powerful when run at a larger scale where modelled urban demands are incorporated into a Source scenario

While this documentation describes the configuration of a single Water Use node, multiple nodes can be added in an Urban Developer scenario, particularly if running the scenario in ‘stand-alone’ mode as a single Urban Configuration.

Figure 1. Using the Urban developer plugin to model urban demands in Source

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Contents

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Navigating the User Guide

The Urban Developer Plugin User Guide contains three two parts:

  1. Urban ScenariosBuilding and running an Urban Scenario in Source: describes how to create, configuration and run an urban water systems model
  2. Linked River System Scenarios: describes how to integrate an Urban Scenario with Source schematic or catchment Scenarios.
  3. A step-by-step /wiki/spaces/SD530/pages/55478087 on how to create and populate an Urban Developer node

The Urban Developer Plugin User Guide assumes that readers are familiar with the eWater Source modelling framework.

Acknowledgements

eWater gratefully acknowledges the leadership, financial and technical support of Melbourne Water in the preparation of the Urban Developer Plugin. eWater also acknowledges the work of Dr Mark Thayer in developing the behavioural end-use stochastic simulator (BESS) for household water simulation that is used in Urban Developer.

This material has been adapted from:

eWater Cooperative Research Centre (2011) Urban Developer User Guide: Urban Developer v1.0.0, eWater Cooperative Research Centre, Canberra, 29 June 2011. ISBN 978-1-921543-40-1

Further Reading

Kavetski, D., Binning, P., & Sloan, S. W. (2002) Adaptive backward Euler time-stepping with truncation error control for numerical modelling of unsaturated fluid flow. International Journal for Numerical Methods in Engineering, 53(6), 1301 - 1322.

Micevski, T., Thyer, M., Kuczera, G. (2011). A Behavioural Approach for Household Outdoor Water Use Modelling. Paper submitted to Water Resources Research (April 2011).

Roberts, P. (2005). 2004 Residential End Use Measurement Study, Final Report: Yarra Valley Water, Victoria.

Thyer, M.A., Duncan, H., Coombes, P., Kuczera, G. and Micevski, T. (2009) A Probabilistic Behavioural Approach for the Dynamic Modelling of Indoor Household Water Use. 32nd Hydrology and Water Resources Symposium, 30 November – 3 December 2009, Newcastle, Australia.

Thyer, M., Micevski, T., Kuczera, G., and Coombes, P. (2011) A Behavioural Approach to Stochastic End Use Modelling. Paper presented at Oz Water, 9-11 May 2011, Adelaide.