Attachment RHS for RVN

This document pretains to SES-MOD-20091210-01567 for Modification on a Satellite Earth Station filing.

IBFS_SESMOD2009121001567_786914

                                        RADIATION HAZARD EVALUATION
                                                                     For
                                                         Raven .98 M Antenna

1     Overview
      Determining the region around an antenna where radiation hazardous to human health is a consideration of many
      factors. With a parabolic dish antenna, the region is highly directional and the actual hazardous region is dependent
      on the antenna elevation angle. The following formulae are used to determine the near and far field regions. These
      regions are in the main beam of the radiation pattern, which we will assume consists of a conical angle extending +/-
      3 degrees from the center axis of the antenna.

      The analysis contained herein predicts the radiation levels around the proposed antenna. The calculations contained
      in this report are in accordance with FCC guidelines as contained in CFR 47 Part 1.1310 and OET Bulletin 65. The
      maximum level of non-ionizing radiation to which the general public is exposed is defined for controlled and
      uncontrolled environments as follows:
                                                                                                                         Exposure Limit
      Environment                                                                                                  Power      Duration
      Controlled - (applicable to system operators and technicians in the service area of the antenna):            5 mW/cm 2  6 Minutes

      Uncontrolled - (applicable to general public in proximity of the antenna):                                   1 mW/cm 2     30 Minutes



2.1   Earth Station Technical Parameters - Input Data

          1A      Antenna Diameter - Standard Parabola                      0.98        meters
          1B      Antenna Diameter - Elliptical Reflector                               meters
            1B1     Major Axis Diameter                                                 meters
            1B2     Minor Axis Diameter                                                 meters
           2      G = Antenna Isotropic Gain                                 41         dBi
           3      h = Nominal Antenna Efficiency                             68         Percent
           4      Nominal Frequency                                        14.125       GHz
           5      Maximum Transmit Power Amplifier Size                       8         Watts
           6      Number of Carriers                                          1         each
           7      W/G Loss from Transmitter to Feed                         0.25        dB
           8      Multicarrier Fixed Backoff                                  2         dB
           9      Desired Object Clearance Height                             2         meters

2.2   Earth Station Technical Parameters - Calculated Data
          10      A = Antenna Surface Area                                       0.75   sq meters
           10A      Standard Parabolic Reflector                        0.754296396     sq meters
           10B      Elliptical Reflector                                         0.00   sq meters
          11      D = Effective Antenna Diameter                                 0.98   meters
          12      Total Transmit Power                                              8   Watts
          13      P = Total Feed Input Power (watts)                             4.77   Watts
          14      E = Maximum E/S EIRP - Calculated                             47.78   dBW
          15      λ = Wavelength (= c/f in m/GHz)                             0.0212    m/GHz
          16      p = Pi                                                     3.14159
          17      Rnf = Near Field Limit (D2/4λ)                                   11 meters                    36 feet
          18      Rff = Far Field Limit (Rff=0.6D2/λ )                             27 meters                    89 feet
          19      Rnf to Rff = Transition Region                             11 to 27 meters              36 to 89 feet



3     Power Density at the Antenna Surface
      The power density at the reflector surface is expected to exceed the safe limits. The reflector is not accessible to the
      public and will not present a hazard. Terminal operators and technicians receive training identifying the area as
      presenting high exposure levels. Procedures are incorporated requiring that transmitters are not operating when
      access to the reflector surface is required.

      The power density at the antenna reflector surface can be calculated by the expression:
                PDREFL = 4P/A =                                                                                              2.53 mW/cm 2
      Where:        P = Total power at the feed, milliwatts
                    A = Total area of reflector, sq cm
      Evaluation:


               Controlled Environment (less than 5 mW/cm2 in 6 minutes):                                                     SAFE
               Uncontrolled environment (less than 1 mW/cm2 in 30 minutes):                                          Mitigation Required



4   On-Axis Power Density in the Near Field Region
    The Radiating Near Field Region for a parabolic, circular reflector, is defined as extending from the reflector to
    a distance equal to the diameter squared divided by twice the wavelength. This distance is referred to as the
    Rayleigh distance. In this region the power is nearly all contained within a cylinder of radius 0.5D. As a safety
    measure the highest possible power density is applied to the whole of this region.

    The power density in the Near Field Region of the antenna can be calculated by the expression:
              16*P*h/π*D 2 =                                                                                              1.72 mW/cm
                                                                                                                                     2

    Where:      P = Total power at the feed, milliwatts
                h = Nominal antenna efficiency
                D = Effective antenna diameter, meters

    Evaluation:
               Controlled Environment (less than 5 mW/cm2 in 6 minutes):                                                     SAFE
               Uncontrolled environment (less than 1 mW/cm2 in 30 minutes):                                          Mitigation Required



5   On-Axis Power Density in the Transition Region
    The transition region is located between the Near Field and Far Field regions. The power density begins to vary
    inversely with distance from the antenna in the transition region. The maximum power density in this region will not
    exceed the power density calculated for the Near Field region. Once again the power density figures are for the On-
    Axis and contained with a cylinder extending within +/- 1 degree of beam center. Where the antennas are normally
    operated at an elevation angle typically greater than 10°, the actual safe distance in front of the antenna may be found
    in paragraph 10. The formula for the calculation is used to evaluate the power density at any given distance in the
    transition as expressed below:

    The power density in the On-Axis Transition Region can be calculated by the expression:
              PDt=(PD nf)(Rnf)/R
    Where:        PDnf = The Near Field power density, mW/cm2
                  Rnf = Near Field maximum distance, meters
                  R = Distance to point of interest
    For:          11 < R < 27 meters

    Evaluation:
               Controlled Environment Safe Operating Distance, meters:                                                       4 meters
               Uncontrolled environment Safe Operating Distance, meters:                                                    19 meters



6   On-Axis Power Density in the Far Field Region
    The On-Axis power density in the far field region (PDff) varies inversely with the square of the distance. The
    calculation is performed below:

    The Power Density at the start of the Far Field region can be calculated by the expression:
               E-10log(4pR 2)                                                                                             8.16 dBW/m 2
               antilog((E-10log(4pR 2)/10)/10                                                                             0.65 mW/cm
                                                                                                                                     2




    Evaluation:
               Controlled Environment (less than 5 mW/cm2 in 6 minutes):                                                     SAFE
               Uncontrolled environment (less than 1 mW/cm2 in 30 minutes):                                                  SAFE



7   Off-Axis Power Density Levels at the Far Field Limit and Beyond
    In the far field region, the power is distributed in a pattern of sidelobes as a function of the off-axis angle between the
    antenna center line and the point of interest. Off-axis power density in the far field can be estimated using the antenna
    radiation patterns prescribed for the antenna in use. Usually this will correspond to the antenna gain pattern envelope
    defined by the FCC or the ITU, which takes the form of:
                 Goff = 32 - 25log(θ)
               for θ from 1 to 48 degrees; -10 dBi from 48 to 180 degrees


                (Applicable for commonly used satellite transmit antennas)
     For example: At one (1) degree off axis At the far-field limit, we can calculate the power density as:
                Goff = 32 - 25log(1) = 32 - 0 dBi =                                                                      1585 numeric
                PD1 deg off-axis = PDffx 1585/G                                                                        0.0824 mW/cm²

     Evaluation:
     Considering that satellite antenna beams are aimed skyward, power density in the far field will usually not be a
     problem except at low look angles. In these cases, off axis gain reduction techniques may be used to further reduce the
     power density levels.



8    Off-Axis Power Density Levels at the Near Field and Transitional Regions
     According to Bulletin 65, off-axis calculations in the near field may be performed as follows: assuming that the point
     of interest is at least one antenna diameter removed from the center of the main beam, the power density at that point
     is at least a factor of 100 (20 dB) less than the value calculated for the near field main beam power density. This may
     be calculated as follows:
                   PDnf(off-axis) = PDnf/100 =                                                                           0.0172 mW/cm²



9    Region Between the Feed Horn and Reflector/Sub-Reflector
     Transmissions from the feed horn are directed toward the main reflector or the sub-reflector depending on the type of
     antenna (prime focus, Gregorian or Cassegrain). The transmission is confined within a conical shape defined by the
     feed horn. The energy between the feedhorn and the reflector/sub-reflector is assumed to be in excess of any limit for
     permissible exposure. This region is not accessible to the general public, and operators and technicians should be
     suitable trained and procedures in place to preclude access to this region during active transmission.



10   Evaluation of Safe Occupancy Area in Front of the Antenna
     The distance (L) from a vertical axis passing through the dish center to a safe off-axis point in front of the antenna
     can be determined based on the dish diameter. Assuming a flat terrain and a point on the horizontal plane with the
     center point of the antenna, the relationship is determined by the following formula:
                L = (D/sin a) + (2h - D - 2)/(2 tan a)
      Where:    a = minimum elevation angle of antenna
                D = Dish diameter in meters
                h = Maximum height of object to be cleared, meters
     For distances equal to or greater than determined by the equation above, the radiation hazard will be below safe levels

        For:    D=                                                             0.98 meters
                h=                                                                2 meters
     Safe distance for the following elevation angles (a):
                            a - Elevation Angle (degrees)                L - Safe Distance
                                          10                             8.54      meters
                                          15                             5.69      meters
                                          20                             4.27      meters
                                          25                             3.41      meters
                                          30                             2.84      meters
                                          40                             2.13      meters
                                          50                             1.71      meters



11   Mitigation Analysis
     Mitigation of accessibility to hazardous regions may take several forms depending on the antenna application and
     location. In instances such as mobile applications, the antenna may be located such that the hazardous region is not
     accessible during operation. An example may be in a mobile configuration where the antenna is located on top of a
     vehicle during operation. In other fixed installation instances the hazardous area may be fenced off to prevent access.
     In areas where only operators and technicians have access, training in safeguards and proper markings of hazardous
     areas may be sufficient. This analysis tool is designed to identify the hazardous exposure regions around an operating
     antenna system in accordance with the defined power density limits in CFR 47, part 1.1310 and OET bulletin 65.



Document Created: 2009-12-10 08:28:58
Document Modified: 2009-12-10 08:28:58

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