Attachment Exhibit B

This document pretains to SES-LIC-INTR2019-03318 for License on a Satellite Earth Station filing.

IBFS_SESLICINTR201903318_1912312

                                               Nunam Iqua, Alaska 3.6m C-Band Radiation Hazard Study




                                                 ANALYSIS OF NON‐IONIZING RADIATION
                               FOR THE GCI C‐BAND 3.6M EARTH STATION ANTENNA AT NUNAM IQUA, ALASKA
                                                         Completed 9/16/2019

This report analyzes the non‐ionizing radiation levels for the GCI 3.6m C‐band hub earth station antenna employed at the Nunam Iqua, Alaska
site. The analysis and calculations performed in this report comply with the methods described in the FCC Office of Engineering and
Technology Bulletin, No. 65 entitled "Evaluating Compliance with FCC Guidelines for Human Exposure to Radiofrequency Electromagnetic
Fields" ‐ first published in 1985 and revised in 1997 in Edition 97‐01. Bulletin No. 65 specifies that there are two separate tiers of exposure
limits that are dependant on the situation in which the exposure takes place and/or the status of the individuals who are subject to the
exposure. The Maximum Permissible Exposure (MPE) limits for persons in a General Population/Uncontrolled Environment are shown in
Table 1, below. The General Population/Uncontrolled MPE is a function of the transmit frequency and is for an exposure period of thirty (30)
minutes or less. The MPE limits for persons in an Occupational/Controlled environment are shown in Table 2, below. The
Occupational/Controlled MPE is a function of the transmit frequency and is for an exposure period of six (6) minutes or less. The purpose of
the analysis described in this report is to determine the power flux density levels of the earth station ni the far‐field, near‐field, transition
region, between the subreflector or feed and the main reflector surface, and at the main reflector surface and to compare these levels to the
specified MPE limits.


                        Table 1. Limits for General Population/Uncontrolled Exposure (MPE)
                     Frequency Range (MHz)                                  Power Density(mW/cm2)
                            30‐300                                                    0.2
                           300‐1500                                          Frequency (MHz)/1500
                         1500‐100,000                                                 1.0

                             Table 2. Limits for Occupational/Controlled Exposure (MPE)
                     Frequency Range (MHz)                                  Power Density(mW/cm2)
                            30‐300                                                   1.0
                           300‐1500                                          Frequency (MHz)/300
                         1500‐100,000                                                 5.0

The following parameters were used to calculate the various power flux densities for this earth station:

           Location:                                  Nunam Iqua, Alaska
           Latitude:                                   62.530603 °N
           Longitude:                                 164.852053 °W
           Operating Frequency:                              6175 MHz
           Wavelength (λ)                                 0.04855 meters
           Antenna Diameter (D):                          3.60    meters
           Antenna Area (A):                             10.18    meters²
           Transmit Antenna Gain:                         45.8    dBi
           Transmit Antenna Gain (G):                   38018.9 numeric
           Maximum 5° Off Axis Gain:                      34.3    dBi
           Maximum 5° Off Axis Gain (G5°):               2675.6 numeric
           Antenna Efficiency (ƞ):                       0.701    numeric
           Feed Power (P):                                200     Watts


1. Antenna/Main Reflector Surface Calculation
The power density in the main reflector region can be estimated by:
                                                                      Antenna Diameter
                                                            3.60   meters
   Power Density at Reflector Surface,       Ssurface = 4P/A
                                             Ssurface =    78.60   W/m²
                                             Ssurface =    7.86    mW/cm²
   Ssurface = maximum power density at antenna surface
         P = power fed to the antenna
         A = physical area of the antenna
2. Near Field Calculations
In the near field region, of the main beam, the power density can reach a maximum before it begins to decrease with distance.

 GCI PROPRIETARY INFORMATION                                                                                                           Page 1 of 3


                                                 Nunam Iqua, Alaska 3.6m C-Band Radiation Hazard Study




The magnitude of the on axis (main beam) power density varies according to location in the near‐field.
The distance to the end of the near field can be determined by the following equation:
                                                                         Antenna Diameter
                                                            3.60      meters
                       Extent of Near Field,      Rnf = D²/4(λ)
                                                  Rnf =    66.74      meters
       Rnf = extent of near field
        D = maximum dimension of antenna (diameter if circular)
        λ = wavelength
The maximum near‐field, on‐axis, power density is determined by:
                                                                         Antenna Diameter
                                                            3.60      meters
    On Axis Near Field Power Density,             Snf = 16ƞP/πD²
                                                  Snf =    55.06      W/m²
                                                  Snf =    5.51       mW/cm²
The maximum near‐field, 5° off‐axis, power density is determined by:
                                                                        Antenna Diameter
                                                             3.60    meters
                Power Density at 5° Off Axis     Snf 5°= (Snf/G)*G5°
                                                 Snf 5°= 0.3875 mW/cm²
       Snf=     maximum near‐field power density
     Snf 5° =   maximum near‐field power density (5° off axis)
         ƞ=     aperture efficiency
         P=     power fed to antenna
        D=      maximum dimension of antenna (diameter if circular)

3. Far Field Calculations

The power density in the far‐field region decreases inversely with the square of the distance.

The distance to the beginning of the far field region can be found by the following equation:

                                                                         Antenna Diameter
                                                            3.60      meters
       Distance to the Far Field Region,          Rff = 0.6D²/λ
                                                  Rff = 160.17        meters

       Rff = distance to beginning of far field
        D = maximum dimension of antenna (diameter if circular)
        λ = wavelength

The maximum main beam power density in the far field can be calculated as follows:
                                                                         Antenna Diameter
                                                              3.60    meters
On‐Axis Power Density in the Far Field,            Sff = (P)(G)/4π(Rff)2
                                                   Sff =     23.59    W/m²
                                                   Sff =     2.36     mW/cm²
The maximum far‐field, 5° off‐axis, power density is determined by:
                                                                        Antenna Diameter
                                                             3.60    meters
                Power Density at 5° Off Axis     Sff 5°= (Sff/G)*G5°
                                                 Sff 5°= 0.1660 mW/cm²
        Sff= power density (on axis)
     Sff 5°= power density (5° off axis)

 GCI PROPRIETARY INFORMATION                                                                             Page 2 of 3


                                                Nunam Iqua, Alaska 3.6m C-Band Radiation Hazard Study




        P= power fed to antenna
       G= power gain of antenna in the direction of interest relative to an isotropic radiator
      Rff = distance to beginning of far field




4. Transition Region Calculations

The transition region is located between the near and far field regions. The power density decreases inversely with distance in the transition
region, while the power density decreases inversely with the square of the distance in the far‐field region. The maximum power density in the
transition region will not exceed that calculated for the near‐field region. The power density in the near field region, as shown above will not
exceed:
                                                                             Antenna Diameter
                                                                3.60      meters
                                                    St=    (Snf*Rnf)/R
                                                 St 5° =   (Snf 5°*Rnf)/R
                                                    St=         5.51      mW/cm²
                                                 St 5° =      0.3875 mW/cm²

                                                                         Table 3
                                                  Summary of Expected Radiation Levels
                                          Calculated Maximum Distance to                         Maximum Permissible Exposure (MPE)
Region                                  Radiation Level (mW/cm² Region (m)                       Occupational        General Population
1.8m Earth Station Antenna
 1. Antenna Surface                           Ssurface=    7.86                                 Potential Hazard         Potential Hazard
 2. Near Field                                     Snf=    5.51            66.7                 Potential Hazard         Potential Hazard
 3. Far Field                                      Sff=    2.36           160.2                  Satisfies MPE           Potential Hazard
 4. Transition Region                               St=    5.51                                 Potential Hazard         Potential Hazard
 5. Near Field 5° Off Axis                      Snf 5°=    0.3875                                Satisfies MPE            Satisfies MPE
 6. Far Field 5° Off Axis                       Sff 5°=    0.17                                  Satisfies MPE            Satisfies MPE
 7. Transition Region 5° Off Axis               St 5° =    0.3875                                Satisfies MPE            Satisfies MPE


7. Conclusions
Based on the above analysis, it is concluded that the OET/FCC Radiofrequency Electromagnetic Fields guidelines for Maximum Permissible
Exposure (MPE) have been exceeded in the region(s) specified in Table 3. However, it should be noted that General Population/Uncontrolled
MPE limit is always satisifed at angles 5° off of boresite or greater. As this earth station antenna will never be operated with an elevation angle of
less than the minimum specified in 47 C.F.R. Ch. 1 §25.205 (namely 5°), then the MPE associated with the General Population/Uncontrolled limits
will always be satisfied. GCI will post appropriate RF Radiation Hazard placards and other signage in the areas near these antennas and/or will
restrict access to the antenna by means of fencing or other appropriate devices. Finally, the transmitter will be disabled during maintenance
activities in these areas to protect personnel from exposure.




                                                                       Patrick Goodyear                 9/16/2019
                                                                       Senior Staff Engineer
                                                                       GCI Communication Corp.




 GCI PROPRIETARY INFORMATION                                                                                                             Page 3 of 3



Document Created: 2019-09-16 13:48:25
Document Modified: 2019-09-16 13:48:25

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