The document proposes developing a mobile ground station to communicate with satellites using software defined radios. It would allow satellite contacts from remote locations, increasing opportunities. A receptor system would let operators establish communication within 10 minutes. Key components are a FunCube Dongle, low-noise amplifier, tracking Yagi-Uda antenna, FPGA for signal processing, and general processor for control and processing. A schedule and budget are provided to guide development and implementation in a recreational vehicle.

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Mobile Ground Station Proposal
Prepared for: Mahmud Rahman, Phd
Prepared by: Paulo Borges, Kris Sanford
December 5, 2013
Proposal number: 01
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SANTA CLARA UNIVERSITY

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EXECUTIVE SUMMARY
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Problem Statement
The current ground control architecture used by the Robotic Systems Laboratory (RSL) at Santa Clara
University uses a static facility to communicate with NASA nanosatellites, confining the satellite contacts
to whenever the satellite is overhead. For our design project we are attempting to build a satellite
communication station using the software defined radio architecture that is housed in a mobile vehicle to
allow for communication at remote locations. A mobile satellite communication station would increase
the number of potential satellite contacts as well as provide the ability for contacts with higher elevation.
Project Objective
The purpose of our project is to design a software defined radio system and implement it in the
Mobile Ground Station. The project includes the design of a receptor which the operator could
access and easily execute the steps required to establish a satellite communication within 10
minutes, which is the time range our customers require. The system includes a USB dongle
(FunCube Dongle) capable of performing band selection, filtering, and mixed signal capabilities.
A low noise pre amplifier will increase the strength of the receptor maximizing the performance of
the overall system. The antenna plays an essential role in the design and its directional
functionality will be coupled to a tracking system capable of point the structure directly to the
satellite position. An easy way of integrating the software and designing a LCD display for a
graphical design interface is to integrate our project into a field-programmable gate array (FPGA).
Although the processing power is enough to process all the data and perform the decodification
and demodulation of the signal, our design chose to include a general purpose processor (GPP)
to specifically do signal control and digital signal processing. The hardware and software that will
be on the completed mobile ground station will allow for interoperability which is the capability of
communicating with multiple satellites (in fact, radios); cognitive radio which increases the
available spectrum, and it can adapt the waveform to maximize a key metric.
Technical Background
This project will utilize a Yagi-Uda antenna to perform MMO, Beam forming, and Nulling.
The antenna is a directional antenna consisting of a driven element dipole element and additional
parasitic elements which consists of a reflector and a director. The only excited element of the
antenna is the dipole element and all the other elements help to either reflect or transmit energy
in a particular direction. The Mast Mount Omnidirectional (MMO) property) provides outstanding
coverage in a rugged U.V. stable, plastic radome with an aluminum base that is ideal for indoor
or outdoor applications.
SANTA CLARA UNIVERSITY

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The USB dongle, FunCube, will perform the band selection, down conversion data rate,
and A/D conversion. The hardware itself allows to operate the device in the 100 MHz to 1 GHz
region. Our goal aims a 430 Mhz communication with satellites, which according to the Nyquist
Criterion, the project requires a sampling frequency of at least 860 MHz. The down conversion
process converts a digitized real signal centered at 430 MHz to a basebanded complex signal
centered at zero frequency. This process is required for a lower processing period.
The Digital Signal Processing will be performed using a Field Programmable Gate Array
(FPGA). The acquisition, demodulation, tracking, synchronization, and decoding will be
performed using the processor of the FPGA and some tasks will be redirected to the General
Purpose Processor. The Xilinx Spartan-3A DSP with DSP48A Slice FPGA is the primary option
for this project since the on-chip microcontroller is active upon power-up and does not require
the FPGA to be programmed. In that way, there is no need of developing any extra drivers to
turn on the GPP when the FPGA is initialized. Along the 2,200 Gbps memory bandwith, this
solution has 53,172 logic cells and 519 I/O pins which is enough power processing to establish
a solid and robust connection at 430 MHz. Finally, the data gathered from the satellite and
process by our system could possibly be hosted in a MySQL database and the FPGA could be
connected through an Ethernet port to insert that data into the online Database.
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Methods
The team will purchase the development kit board in the Fall quarter. There will be used the GNU Radio
development platform to generate the C and C++ scripts which will run in the FPGA. The Mechanical
sub team will simultaneously be working on implementing the Yagi-Uda antenna on the Recreational
Vehicle and they will provide the tracking data for the FPGA to add a real time satellite tracking feature
into the system.
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SANTA CLARA UNIVERSITY

4. !4
SCHEDULE
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Grant Chart
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5. !5
Budget
Classification
Part
Name /
Descrip
tion
Vendor
Part
Number
Cost QTY Total
Workstation
Rack
Mount
Comput
er
(tracking
, ops)
SuperLo
gics
SL-1U-
CL-
M900-
LA
399 3 1197
Hardware, Data
RS232-
RS485
Bidirecti
onal
Convert
er
Jameco 117701 59.69 2 119.38
Antenna
S-Band
Antenna
Suite
RF Ham
Design
5000 1 5000
Cabling, Connector
Rotor,
Receptic
al, Male,
4
Conduct
or,
Weather
proof
Digi-Key
HR1125-
ND
11.7 2 23.4
Cabling, Connector
Rotor,
Plug,
Female,
4
Conduct
or
Digi-Key
HR1768
-ND
12.78 4 51.12
Cabling, Connector
Rotor,
Receptic
al, Male,
4
Conduct
or
Digi-Key
HR1778
-ND
8.83 2 17.66
Connector, Data
Data
Feedthr
u, Plug
10 wires
(data)
Digi-Key
PT06SE
12-10S(
470)
31.32 1 31.32
Connector, Power
Power
Feedthr
u, Plug 3
wires
(power)
Digi-Key
PT06A-1
2-3S(47
0)
28.34 1 28.34

6. !6
Cabling, Connector
DB9
(Female
) / DB25
Adaptor
(Male)
Fry's 508835 2.99 1 2.99
Cabling, Connector
DB9
(Male) /
DB25
(Male)
Fry's 5088855 2.99 1 2.99
Cabling, Data
USB <->
Serial
Convert
er,
Airlink
Fry's 4071282 14.99 2 29.98
Cabling, Data
DB9
(Male) /
DB9
(Female
)
Fry's 5289447 6.99 1 6.99
Cabling, Power
Extensio
n cord,
3-outlet,
short
Fry's 3783056 1.99 1 1.99
Mobile Vehicle
Recreati
onal
Vehicle
- - ~$8000 1 8000
Workstation
Rack
Mount
Tray
Fry's 2222638 39.99 3 119.97
Cabling, RF
LMR600
, N-Male
to N-
Male,
15ft
length
Talley
TIMA60
A-XX
78.1 1 78.1
Hardware, Interface
ICOM
CT-17
HRO - 129.95 1 129.95
Hardware, Interface
Kantroni
cs 9612
Plus
TNC
Modem
HRO - 369.95 1 369.95
Hardware, Power
ICOM
PS-125
HRO - 299.95 1 299.95
Hardware, Radio
ICOM
910H
HRO - 1279.95 1 1279.95
Classification
Part
Name /
Descrip
tion
Vendor
Part
Number
Cost QTY Total

7. !7
Workstation
Operatio
ns
Comput
er
Dell
OPTIPL
EX 9010
900 1 900
Total: 17691.03
Classification
Part
Name /
Descrip
tion
Vendor
Part
Number
Cost QTY Total