Nokia S60V3 Applications

CellTrack 1.0.9 [SIG..> 03-Sep-2009 16:09   294k  
CellTrack 1.0.9.sis     03-Sep-2009 16:09   287k 

ActiveFile 1.42.1 Ma..> 03-Sep-2009 16:09   211k  
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+HelloOX 1.03.zip       08-May-2009 14:56   379k 

First method.zip        08-May-2009 14:57   765k  
Modo 0.50 [FILES].zip   08-May-2009 14:57    29k 

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Intermodulation

INTERMODULATION 

1. Introduction

The INTMOD program performs harmonic and intermodulation analysis of 2 and/or 3 signals of 3^rd, 5^th or 7^th order mixing.  The user enters the transmitter and receiver frequencies in MHz with their corresponding bandwidths in kHz.  The user may enter the lists interactively or use a database built from a previous run.

2. Harmonics and Intermodulation analysis

            Background

Mutual interference may occur between two circuits operating at different frequencies because of radiation at frequencies other than the operating frequencies.  A transmitter may radiate harmonics of its operating frequency, which may affect a receiver tuned to one of the harmonics.

Intermodulation products result in interference, when two or more signals combine in a nonlinear device and produce an undesired signal on or near the tuned frequency of the victim receiver.  The combination process can occur in the final stage of a transmitter or in the RF of first mixer circuitry of a receiver.

When the number of transmitters is increased, the number of possible intermodulation frequencies increases rapidly.  The most serious of these frequencies are the third order products of the form 2f₁ – f₂ or f₁ + f₂ – f₃, where f₁, f₂ and f₃ are operating frequencies of the transmitters.  The interference will be most serious when all or several of the frequencies, both transmitting and receiving, are in close proximity.  To minimize intermodulation, frequencies should be selected such that the frequency difference between any pair of frequencies is unlike the difference between any other pair.  In some cases, the specific operating frequencies can be chosen so that no third order product frequency coincides with a receiving channel frequency at the same or a nearby site.

Harmonic Analysis Equation

The mixing of frequencies whereby the largest frequency is greater than twice the smallest frequency is not analyzed.  Harmonic interference is defined below.

A f_t = f_r ± BW                                                             (2.1)

where, A is either 1 or 2, f_t is the transmitter frequency, f_r is the receiver frequency and BW is the receiver bandwidth.

Intermodulation Analysis Equations

The interference due to intermodulation is defined by the following equations.  The analysis only considers in-band modulation products.

Two Signal Case

3^rd order:                            2 f_t1 – f_t2 = f_r ± BW                                                     (2.2)

5^th order:                          3 f_t1 – 2 f_t2 = f_r ± BW                                                    (2.3)

7^th order:                          4 f_t1 – 3 f_t2 = f_r ± BW                                                    (2.4)

Three Signal Case

3^rd order:                        f_t1 – f_t2 + f_t3 = f_r ± BW                                                    (2.5)

5^th order:                    2 f_t1 - 2f_t2 + f_t3 = f_r ± BW                                                    (2.6)

                                   3 f_t1 – f_t2 – f_t3 = f_r ± BW                                                     (2.7)

7^th order:               2 f_t1 – 3 f_t2 + 2 f_t3 = f_r ± BW                                                    (2.8)

                                3 f_t1 – 3 f_t2 + f_t3 = f_r ± BW                                                    (2.9)

                                4 f_t1 – 2 f_t2 – f_t3 = f_r ± BW                                                     (2.10)  

        

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Line of sight antenna coverage Model (Shado)

Line of sight antenna coverage Model (Shado)

1. Introduction

The SHADO program is a line-of-sight antenna coverage model, which can handle up to two antennas. It generates a plot of a specified area and will shade the areas that are within the line-of-sight of either antenna or both antennas. SHADO uses terrain/topographic database.

2. Analysis

Terrain profiles are generated for each antenna site. Profile analysis is then performed to determine whether the end point of each profile is in the radio line-of-sight (LOS) or it lies within the earth’s shadow (Figure 1). In Figure 1, q_n is the radio horizon elevation angle to n^th profile point. Primary objective is to determine the elevation that constitutes the limiting LOS along each profile.

Figure 1. A profile path from an antenna site

Two factors must be taken into consideration: the bending of radio waves as they propagate through the atmosphere due to refractivity and the effects of earth’s curvature with respect to the elevations. The program uses the user specified refractivity value to compute the amount of ray bending. If the default refractivity of 301 is used, a 4/3 radius earth is assumed to be correct for ray bending. Radio horizon angles are then calculated from the beginning of the profile to the end-point, which represents a grid point coordinate. The rays representing waves from the antenna site along the profile to the end point are represented as straight lines for a 4/3 earth’s radius.

If the elevation angle of the profile end-point, with respect to the antenna site, is less than the calculated radio horizon angle, then the grid point coordinate lies within the earth’s shadow (Figure 2).

Figure 2. Profile path with an end-point within earth’s shadow

For an end-point within the LOS, the radio horizon angle is that formed by a direct ray from the antenna site to the profile end-point (Figure 3).

Figure 3. Profile path with an end-point within LOS

Plots are generated where each grid point is shaded to indicate whether it is within the LOS with respect to each antenna site (Figures 4 and 5). The program generates 3721 (61 X 61) profiles along a number of equally spaced radials emanating from each antenna site to each grid point on the plot as an extension of the PROFILE program. These sites do not have to be within the area of the overlay.

Figure 4. Path 1 shows a radial with Figure 5. Path 1 end-point within

end-point within LOS, Path 2 with LOS and is clear at bin 3,7, path 2

end-point within earth’s shadow. End-point within earth’s shadow

and is black at bin 5,9.

Analysis of the profiles makes it possible to determine the grid coordinates at which signals approaching or emanating from the site will be detected on a LOS basis. This information is consolidated to produce LOS shading contours around the site, which provide a composite of the sites’ coverage, as determined by terrain features. The engineer can determine a site location with the best use of the terrain characteristics by locating the proposed antenna at each point on the grid.

3. Input Parameters

The input parameters are the latitudes and longitudes of the southwest and northeast corners of the plot area, the latitude(s) and longitude(s) of antenna(s), surface refractivity, the antenna height(s), and optionally the antenna site elevation(s). The latitudes and longitudes are expressed in degrees North and West respectively. The default site elevation is calculated from the terrain profile. The antenna heights and the site elevation can be in English or Metric units.

4.Output

The output from the program SHADO is a map, which shows the location(s) of one or two antennas and the LOS coverage by the antenna(s)