Attachment Technical Annex

This document pretains to SES-MFS-20150911-00571 for Modification w/ Foreign Satellite (earth station) on a Satellite Earth Station filing.

IBFS_SESMFS2015091100571_1102238

                                             ECHOSTAR-15

                                            ATTACHMENT A
                   Technical Information to Supplement Schedule S



A.1        Scope


This attachment contains the information required by §25.114(c) and other sections of the FCC
Part 25 rules that cannot be captured by the Schedule S form.


A.2        General Description of Overall System Facilities, Operations and Services
           (§25.114(d)(1))


The ECHOSTAR-15 satellite will serve as in-orbit spare in the EchoStar fleet at 72.6° W.L.,
collocated with the NIMIQ-5 satellite. The ECHOSTAR-15 satellite will operate under the
authority of the Canadian ITU TT&C filing at the nominal 72.7° W.L. orbital location. The
satellite will only be operated using the TT&C portion of the satellite which are located at the
upper and lower 12 MHz guardbands of the ITU’s Region 2 BSS Plan (Article 2A of Appendices
30 and 30A) 1. EchoStar is not planning to operate is not seeking authority to operate the
communications payload of ECHOSTAR-15 while located at 72.6° W.L.


Primary TT&C functions will take place from EchoStar’s TT&C earth station and satellite
control facilities located in Cheyenne, WY and Gilbert, AZ.




1
    The ITU Region 2 BSS Plan frequencies used for space operations functions (TT&C) are 12.2-12.212, 12.688-
    12.7, 17.3-17.312 and 17.788-17.8 GHz.


A.3     TT&C Characteristics
        (§25.114(c)(4)(i) and §25.114(c)(9))


The information provided in this section complements that provided in the associated Schedule S
submission.


The ECHOSTAR-15 TT&C subsystem provides for communications during transfer orbit and
on-station operations, as well as during spacecraft emergencies. The TT&C subsystem operates
in the 12 MHz guardbands for both uplink and downlink during all phases of the mission. The
TT&C subsystem consists of 6 near omni-directional command antennas, 4 near omni-
directional telemetry antennas, and 2 Ku-band communication antennas that can receive
commands and transmit telemetry.      TT&C operations will be conducted from EchoStar’s
Cheyenne, WY and Gilbert, AZ facilities. Other EchoStar TT&C facilities in Blackhawk, SD
and Mt. Jackson, VA may be used in the event of an emergency or contingency requirement.
The spacecraft is capable of operating at two command frequencies shown in Table A-1 below.
During normal on-station and emergency operations at 72.6° W.L, command signals will be
received by the near omni-directional antennas on the 17,793.5 MHz command frequency.             The
spacecraft is capable of operating at four transmit frequencies shown in Table A-1 below.
During normal on-station and emergency operations at 72.6° W.L., the telemetry signals will be
transmitted by the near omni-directional antennas on the 12,698.5 MHz telemetry frequency.


A summary of the TT&C subsystem characteristics is given in Table A-1.


                         Table A-1: TT&C Performance Characteristics
   Command Modulation                                               PCM/PSK

                                                                  17,791.5 MHz
   Command/Ranging Frequencies
                                                                  17,793.5 MHz

                                                  Omni Rx antenna: > -83 dBW/m2 (Command)
   Uplink Flux Density (Minimum)                                      -78 dBW/m2 (Ranging)
                                                  Comms Rx antenna: > -93 dBW/m2 (Command)
                                                                      -87 dBW/m2 (Ranging)
                                                  Omni antenna during transfer orbit and on-station
   Satellite Receive Antenna Types                emergencies for telecommand.
   and Modes of Operation                         Communications antenna during normal on-station
                                                  operations for telecommand.


   Polarization of Satellite Rx/Tx Antennas               RHCP for omni antenna
                                                          RHCP for communications antenna
   Peak Deviation (Command/Ranging)                                         ± 400 kHz

                                                                          12,692.0 MHz
   Telemetry/Ranging Frequencies                                          12,693.0 MHz
                                                                          12,694.5 MHz
                                                                          12,698.5 MHz
   Satellite Transmit Antenna Types                       Omni antenna during transfer orbit, on-station
                                                          emergencies and normal on-station operations for
   and Modes of Operation
                                                          telemetry.

   Maximum Downlink EIRP                                  15.2 dBW (Omni antenna)
                                                          18 dBW (Communications antenna)
   Telemetry/Ranging Modulation Index:
         1 sub-carrier                                                   1.0 ± 0.2 rad pk
         2 sub-carriers                                                   0.7± 0.2 rad pk
         3 sub-carriers                                                  0.58± 0.2 rad pk



A.4     Orbital Debris Mitigation Plan
        (§25.114(d)(14))


A.4.1   Debris Release Assessment
        (§25.144(d)(14)(i))

To protect the spacecraft from small body collisions, the design of the ECHOSTAR-15
spacecraft allows for individual faults without losing the entire spacecraft.                    All critical
components (i.e., computers and control devices) have been built within the structure and
shielded from external influences.            Items that could not be built within the spacecraft nor
shielded (such as antennas) are redundant and/or are able to withstand impact.                               The
ECHOSTAR-15 spacecraft can be controlled through both the normal payload antenna and wide
angle antennas. The likelihood of both being damaged during a small body collision is minimal.
The wide angle antennas on this spacecraft are basically open waveguides that point towards the
Earth (there is one set on each side of the spacecraft; either set could be used to successfully de-
orbit the spacecraft). These wide angle antennas would continue to operate even if struck and
bent.


Based on the above structural design and critical component redundancy, EchoStar believes this
satellite has a limited probability of becoming a source of debris from small body collisions.


A.4.2     Accidental Explosion Assessment
          (§25.144(d)(14)(ii))

In order to ensure that the spacecraft does not explode on orbit the satellite controller takes
specific precautions. All batteries and fuel tanks are monitored for pressure or temperature
variations. Alarms in the Satellite Control Center (“SCC”) inform controllers of any variations.
Additionally, long term trending analysis will be performed to monitor for any unexpected
trends.


Operationally, batteries are operated utilizing the manufacturer’s automatic recharging scheme.
Doing so ensures that charging terminates normally without building up additional heat. As this
process occurs wholly within the spacecraft, it also affords protection from ground command
link failures.


In order to protect the propulsion system, fuel tanks have been operated in a “blow down” mode.
This means that at the completion of the orbit raising phase of the mission, the pressurant was
isolated from the fuel system, thereby causing the pressure in the tanks to decrease over the life
of the spacecraft. This also protects against a pressure valve failure causing the fuel tanks to
become over pressurized.


In order to ensure that the spacecraft has no explosive risk after it has been successfully de-
orbited, all stored energy onboard the spacecraft will be removed. Upon successful de-orbit of
the spacecraft, all propulsion lines and latch valves will be vented and left open. All battery
chargers will be turned off and batteries will be left in a permanent discharge state. These steps
will ensure that no buildup of energy can occur resulting in an explosion in the years after the
spacecraft is de-orbited.


Based on the above structural design and planned flight control precautions during and after the
mission completion, EchoStar believes this satellite has a limited probability of becoming a
source of debris from accidental explosions.


A.4.3   Safe Flight Profiles
        (§25.144(d)(14)(iii))

In considering current and planned satellites that may have a station-keeping volume that
overlaps the ECHOSTAR-15 satellite, EchoStar has reviewed the lists of FCC-licensed satellite
networks, as well as those that are currently under consideration by the FCC. In addition, non-
U.S. networks for which a request for coordination has been published by the International
Telecommunication Union (“ITU”) within ±0.15° of 72.6° W.L. have been reviewed.


As already mentioned, the NIMIQ-5 satellite operates at 72.7° W.L. with an east-west station-
keeping tolerance of ±0.05° with which EchoStar is coordinating.


There are no pending applications before the Commission to use an orbital location ±0.15° from
72.7° W.L and EchoStar is not aware of any satellite with an overlapping station-keeping volume
with the ECHOSTAR-15 satellite that is the subject of an ITU filing and that is either in orbit or
progressing towards launch.


Based on the preceding, EchoStar seeks to locate the ECHOSTAR-15 satellite at 72.6° W.L., and
operated with an east-west station-keeping tolerance of ±0.05°, in order to eliminate the
possibility of any station-keeping volume overlap with the NIMIQ-5 satellite.           EchoStar
therefore concludes that physical coordination of the ECHOSTAR-15 satellite with another party
is not required at the present time.


A.4.4   Post Mission Disposal Plan
        (§25.144(d)(14)(iv))

At the end of the operational life of the ECHOSTAR-15 satellite, EchoStar will maneuver the
satellite to a disposal orbit with a minimum perigee of 330 km above the normal GSO
operational orbit.   This proposed disposal orbit altitude exceeds the minimum required by
§25.283, which is calculated below.

The input data required for the calculation is as follows:

        Total Solar Pressure Area “A” = 111 m2
        (includes area of solar array, satellite body and deployed antennas)


       “M” = Dry Mass of Satellite = 2364 kg
       “CR” = Solar Pressure Radiation Coefficient (worst case) = 2


Using the formula given in §25.283, the Minimum Disposal Orbit Perigee Altitude is calculated
as follows:

               =      36,021 km + 1000 x CR x A/M
               =      36,021 km + 1000 x 2 x 111/2364
               =      36,115 km
               =      329 km above GSO (35,786 km)

Adequate margin has already been accounted for in the calculation of the designed disposal orbit
of 330 km above GSO, which includes margin relative to the above calculation. Attaining the
altitude of 330 km above the GSO orbit will require approximately 12 kg of propellant, which
will be reserved, taking account of all fuel measurement uncertainties, to perform the final orbit
raising maneuvers.


Propellant tracking is accomplished using a bookkeeping method. Using this method, the ground
control station tracks the number of jet seconds utilized for station keeping, momentum control
and other attitude control events. From the number of jet seconds, the amount of fuel used is
determined. This process has been calibrated using data collected from thruster tests conducted
on the ground and has been found to be accurate to within a few months of life on the spacecraft.


In addition to the bookkeeping method, a pressure, volume and temperature (PVT) test is done to
support the findings of the bookkeeping method. Lastly, propellant depletion gauges allow for
monitoring of the propellant through the telemetry.


A.5     Interference Analysis


The ECHOSTAR-15 satellite at 72.6° W.L. will operate under authority of the Canadian
administration. Canada has an Article 2A satellite network filing, CAN-BSS3 TTAC, pending at
the ITU. The Canadian administration is responsible for coordinating the operation of any satellite
operating pursuant to this ITU satellite network filing following the appropriate ITU articles and
procedures.


EchoStar is not seeking operating authority of the communications payload on ECHOSTAR-15.
Accordingly, no interference analysis is provided for the operations of the communication payload.


EchoStar has reviewed the interference potential that could be caused by the TT&C functions
while the ECHOSTAR-15 satellite is operated at the 72.6° W.L. orbital location with particular
attention given to the collocation with NIMIQ-5. Since these satellites operate in the Appendices
30 and 30A BSS Plan bands, EchoStar has specifically selected TT&C frequencies (see Section
A.3) that do not overlap with the NIMIQ-5 satellite TT&C frequencies and has coordinated the use
of these frequencies with the operator of the NIMIQ-5 satellite.


The next adjacent satellites with potential TT&C frequency overlap with ECHOSTAR-15 are
located at 77° W.L., QUETZSAT-1, ECHOSTAR-8 and ECHOSTAR-3 are nominally 4.3° away,
and at 61.5° W.L., ECHOSTAR-16, ECHOSTAR-12 and ECHOSTAR-3 are nominally 11.1°
away. Given this large orbital separation and the use of large earth stations for both command and
telemetry, negligible interference will be received from them or caused by the ECHOSTAR-15
satellite.



                           ___________________________________


              CERTIFICATION OF PERSON RESPONSIBLE FOR PREPARING
                          ENGINEERING INFORMATION




       I hereby certify that I am the technically qualified person responsible for preparation of

the engineering information contained in this application, that I am familiar with Part 25 of the

Commission’s rules, that I have either prepared or reviewed the engineering information

submitted in this application and that it is complete and accurate to the best of my knowledge

and belief.




                                                                     /s/

                                                             Zachary Rosenbaum
                                                             Senior    Manager,          Advanced
                                                             Programs       and          Spectrum
                                                             Management



Document Created: 2015-09-10 17:13:33
Document Modified: 2015-09-10 17:13:33

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