Urban Physics


Utilising advanced simulation and analysis techniques, we offer direction to key design decisions to ensure effective land use planning while protecting environmental assets.

A prerequisite to a successful masterplan design is the understanding and subsequent response to the environmental and natural context of the project site. Contextualising a project site means understanding its existing environmental and natural conditions such as climate and natural capital. The objective of assessing these conditions is to guide the design towards optimizing the microclimate within the development, as well as reduce overall environmental risk.

Using advanced simulation and analysis techniques, AESG’s urban physics team can provide specific, quantitative feedback to the design team, highlighting site opportunities and constraints at the briefing stage and allowing for effective land use planning to protect significant environmental assets, as well as the incorporation of passive design measures to enhance the outdoor microclimate, minimising the reliance on natural resources and improving the resiliency of the development.

Continued analysis and feedback throughout the design development offers further refinement, facilitating quantitative assessment and direction on key design decisions. Analysis can also allow for the assessment of predicted future climate conditions to ensure adaptability to climate change, resulting in an urban fabric that is environmentally responsive and resilient. Through the application of GIS Mapping, AESG’s in-house GIS specialists are able to provide geo-referenced, site specific environmental data to further inform and enhance the design from the early stages of the project to completion.

Get in touch

Urban Physics

Phillipa Grant
Partner and Global Sustainability Director info@aesg.com

CONTACT
Our Services include:
  • GIS Mapping
  • Flood Risk Assessment
  • Computational Fluid Dynamics (CFD) Analysis
  • Solar Insolation and Shading Analysis
  • Climatic Modelling and Analysis
  • Remote Sensing
  • Wind Simulation 
  • Thermal Comfort Studies (UTCI, PMV etc.)
  • Parametric Modelling and Optimisation
  • Daylight Potential