Isotropic Transmitters

Isotropic transmitters are used for cellular networks in indoor scenarios and broadcasting applications in rural /suburban scenarios.

These transmitters have the following settings:

Figure 1. The Cell dialog to adjust isotropic transmitter settings.

Number (Nr)
The number of the transmitter is the internal ID and used by ProMan to separate the transmitters of one project. This is not relevant for the project settings.
The name of the antenna/transmitter is important because it is added to the basic output file name. If the basic output file name is xy and the antenna name is TRX 1 the results will be saved in files xy_TRX 1.*. Concerning the name of the antenna the following rules must be considered:  
  • Only characters which are allowed in file names can be used.
  • The name must be unique within the project to avoid collisions with other transmitters.
Status of Cell/Transmitter in Project

The transmitter can be enabled or disabled. Only enabled transmitters will be computed. If no modifications were made, the transmitter can be disabled to save computation time and so only the modified (and enabled) transmitters are computed when starting the computation. The transmitter status can also be changed via the project toolbar using the icon and by clicking with the mouse on the transmitter. The individual cells within the project can be included or excluded from the network optimization process.

The transmitter can be defined as a repeater by selecting the Set as Repeater check box. Upon selecting this check box, a pull-down menu appears to define the mode of operation. Two modes of operation are available for a repeater, Reconfigurable Mode and Transparent Mode.
  • A reconfigurable repeater will retransmit the signal it receives from the gateway after amplifying it to a certain user-defined power. Its transmission may be at a different frequency, but doesn’t have to be.
  • A transparent repeater will retransmit the signal it receives from the gateway after amplifying it by a certain user-defined gain. Its transmission will be at the same frequency.
A few rules apply:
  • A repeater has to be a member of a site that includes at least one transmitter that is not a repeater. This can be the Gateway.
  • In network planning, for the calculation of interference, the signal from a repeater always belongs to the same Signal Group as the signal from the Gateway. Hence, the repeater will not cause undue interference with the gateway and other repeaters in the same site.
Transmitter and Receiver Settings
The frequency is defined in this section as well as the output power (which is required for the determination of the received power or field strength). The output power can either be defined in Watt or dBm and the output power can be defined either as the output power of the PA (power amplifier), as ERP (equivalent radiated power, for example, relative to dipole antenna), or as EIRP (equivalent isotropic radiated power, for example, relative to isotropic antenna). If G is the gain of the antenna (in dBi), the values can be determined via the following equation:
P EIRP = P ERP +2.1 dB=  P output power +G
Prediction Area (Cell / Transmitter)
  • Default Prediction Area
  • Individual Prediction Area
This option can be switched on if measurement data is available for the transmitters included in the project for calibration. This feature allows to automatically calibrate the wave propagation model based on imported measurement data. Supported measurement files are power results (.fpp), field strength results (.fpf) and path loss results (.fpl). The files are generated during the propagation prediction and not during the network computation. These files can then be processed with a separate stand-alone tool to derive the calibrated settings for the propagation exponents (before / after the breakpoint for LOS/NLOS conditions).
When using GTD/UTD and Fresnel coefficients for the calculation of diffractions or reflections and transmissions, respectively, arbitrary linear polarizations (between +90° and –90°) or circular polarizations can be considered for the ray-tracing models (SBR, SRT & IRT), the dominant path model and the empirical multi-wall model. The corresponding polarization can be defined for each Tx antenna individually. X-polarization combines +45 and -45 degrees in one antenna for convenience.
Figure 2. The Polarization dialog.

Tip: Specify polarization for cells in indoor prediction projects and cells of network projects.

Rural and urban wave propagation simulations do not consider individual polarizations, except if the IRT model is used. If the urban IRT model is not used, vertical polarization is assumed for all transmitters. For rural and urban network planning projects, polarization is only taken into account for the computation of co-channel interference and is not considered during wave propagation prediction.

Location of antenna
Location coordinates of the antenna. The same coordinate system as used for the database must be used. The coordinates can be entered in the dialog, or the transmitter can also be moved/placed with the mouse via the menu Project > Transmitter > Transmitter: Move or via the toolbar using the icon.
Type of antenna
Select between an isotropic antenna or a directional / sector antenna. An antenna pattern must only be defined if the directional antenna is enabled. If omnidirectional antennas should be considered, an isotropic antenna can be selected, and the gain of the omnidirectional antenna can be added to the EIRP value of the output power.
Tip: As soon as the horizontal orientation is changed with the mouse via the corresponding function in the Edit > Transmitter > Transmitter: Azimuth menu, Directional antenna is set. If directional antenna is chosen, an antenna file has to be specified.
Antenna Pattern
Not available.
Vertical Orientation
Not available.
Horizontal Orientation
Not available.