Geographical Model of Radio-Frequency Power Density: Difference between revisions

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* Geomorf User Guide: link to word document
* Geomorf User Guide: link to word document
* Geomorf parameters guidance: link to spreadsheet
* Geomorf parameters guidance: link to spreadsheet
{{IEHIAS}}

Latest revision as of 14:05, 13 October 2014

The text on this page is taken from an equivalent page of the IEHIAS-project.

GEOMORF is a GIS-based model, designed to simulate power density around EMF transmitters such as mobile phone masts.

Model description

Purpose

The Geographical Model of Radio-Frequency Power Density (Goemorf) is a GIS–based exposure model designed to estimate power densities at receptor locations around mobile phone base stations. The model uses a semi-Gaussian formulation to represent spatial variations in power densities around mobile phone masts, on the basis of power output, antenna height, tilt and the surrounding propagation environment.

Boundaries

Outdoor exposure

Spatial resolution: address or postcode

Input

Mx,My Mast location metres x and y co-ordinates of the source mast
Rx,Ry Receptor location metres x and y co-ordinates of the receptor
Em Elevation of mast metres Height of the ground surface above ordnance datum, at the mast location
Er Elevation of receptor metres Height of the ground surface above ordnance datum at the receptor location
Ha Antenna height metres Height of the centre point of the antenna, above the ground surface. Default = surface height + 20 metres.
Hr Receptor height Metres Height of the midpoint of the receptor, above the ground surface.
Tt Net tilt degrees Total tilt due to electrical and mechanical tilt. Default = 6.5o
P Power output W Maximum operational effective isotropic radiated power output of the source antenna
Zb Azimuth degrees Direction (degrees from true north) of the centreline of the mainbeam of the antenna
BWd Vertical beam width degrees Specified vertical beam width of the source antenna Default = 6o.
BWl Horizontal beam width degrees Specified horizontal beam width of the source antenna. Default = 67o.
Tlos Topographic line of site Topographic line of site from antenna to receptor (0,1); modelled using visibility function in GIS.
C Land cover type Categorisation of land cover in area surrounding the receptor (urban, forested, open); determined by intersecting land cover data with receptor locations in GIS.

Output

Output: Power density (mW/m2)

Data type: point estimate(s)

Data sources: mobile phone operators

Data format: ESRI ArcGIS shape files

Description of processes modelled and of technical details

  • Operating System: WINDOWS
  • Software requirements: ArcGIS9.3 + Spatial Analyst extension
  • Programming language: VBA
  • Developed by Imperial College London
  • Model is free to use
  • Intellectual property rights Imperial College London
  • Canned model - cannot be modified

Rationale

THe GEOMORF model is based on the free-space equation for electromagnetic radiation, adapted to take account of the reduction in power density both along the beam and transverse to the beam. The model has been developed and validated on the basis of field measurements made around a series of mobile phone transmission masts (macrocells) in Great Britain, where it was shown to give good approximation of measured power densities (r2 ~0.6) across a wide range of conditions. In densely built-up urban areas, performance is poorer, due to local variations caused by buildings.

See also

  • Geomorf model: link to download ArcMap document
  • Geomorf User Guide: link to word document
  • Geomorf parameters guidance: link to spreadsheet
Integrated Environmental Health Impact Assessment System
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