As the S-band spectrum becomes crowded, future space missions will need to consider moving command and telemetry services to Ka-band. NASA's Space Communications and Navigation (SCaN) Testbed provides a software-defined radio (SDR) platform that is capable of supporting investigation of this service transition. The testbed contains two S-band SDRs and one Ka-band SDR. Over the past year, SCaN Testbed has demonstrated Ka-band communications capabilities with NASAs Tracking and Data Relay Satellite System (TDRSS) using both open- and closed-loop antenna tracking profiles. A number of technical areas need to be addressed for successful transition to Ka-band. The smaller antenna beamwidth at Ka-band increases the criticality of antenna pointing, necessitating closed loop tracking algorithms and new techniques for received power estimation. Additionally, the antenna pointing routines require enhanced knowledge of spacecraft position and attitude for initial acquisition, versus an S-band antenna. Ka-band provides a number of technical advantages for bulk data transfer. Unlike at S-band, a larger bandwidth may be available for space missions, allowing increased data rates. The potential for high rate data transfer can also be extended for direct-to-ground links through use of variable or adaptive coding and modulation. Specific examples of Ka-band research from SCaN Testbeds first year of operation will be cited, such as communications link performance with TDRSS, and the effects of truss flexure on antenna pointing

Chelmins, David T.

Downey, Joseph

Evans, Michael

Mortensen, Dale

Reinhart, Richard C.

Welch, Bryan

As the S-band spectrum becomes crowded, future space missions will need to consider moving command and telemetry services to Ka-band. NASAs Space Communications and Navigation (SCaN) Testbed provides a software-defined radio (SDR) platform that is capable of supporting investigation of this service transition. The testbed contains two S-band SDRs and one Ka-band SDR. Over the past year, SCaN Testbed has demonstrated Ka-band communications capabilities with NASAs Tracking and Data Relay Satellite System (TDRSS) using both open- and closed-loop antenna tracking profiles. A number of technical areas need to be addressed for successful transition to Ka-band. The smaller antenna beamwidth at Ka-band increases the criticality of antenna pointing, necessitating closed loop tracking algorithms and new techniques for received power estimation. Additionally, the antenna pointing routines require enhanced knowledge of spacecraft position and attitude for initial acquisition, versus an S-band antenna. Ka-band provides a number of technical advantages for bulk data transfer. Unlike at S-band, a larger bandwidth may be available for space missions, allowing increased data rates. The potential for high rate data transfer can also be extended for direct-to-ground links through use of variable or adaptive coding and modulation. Specific examples of Ka-band research from SCaN Testbeds first year of operation will be cited, such as communications link performance with TDRSS, and the effects of truss flexure on antenna pointing

Chelmins, David

Reinhart, Richard

Evans, Mike

NASA Technical Reports Server

Studying NASA’s Transition to Ka-Band 
Communications for Low Earth Orbit
David Chelmins, Richard Reinhart, Dale Mortensen, 
Bryan Welch, Joseph Downey, and Mike Evans
dchelmins@nasa.gov
+1 (216) 433-3304
NASA Glenn Research Center (GRC)
Cleveland, Ohio, United States
IAC 2014, Toronto, Ontario, Canada
https://ntrs.nasa.gov/search.jsp?R=20150000880 2019-08-31T14:05:27+00:00Z
Overview
i Introduction and Background
i Recent Mission Use of 26 GHz Ka-Band
i SCaN Testbed
x Ka-Band Components
x SCaN Testbed Radios and Capabilities
x Ka-Band Tracking Considerations
i Experiments on SCaN Testbed
x Ka-Band Launch Waveform Performance
x Antenna Pointing Quality Metric
x High-Rate, Bandwidth-Efficient Waveform
i Toward the Future: Ka-Band User Spacecraft
2
Introduction and Background
i NASA is considering use of Ka-band for Low Earth Orbit (LEO)
x Large data volumes drive the need for higher data rates
x Short pass times drive the need for more bandwidth and higher-order 
modulation schemes
i Int’l Telecommunications Union (ITU) allocations favor Ka-band
x S-band space science: ~10 MHz
x X-band earth science: ~375 MHz
x Ka-band space-to-space: ~2250 MHz
i NASA developed the Space Communications and Navigation 
(SCaN) Testbed to research software-defined radio techniques for 
Ka-band transition in LEO
x First NASA space-qualified Ka-band transceiver (Harris Corp.)
x Research capabilities for modulation, pointing/tracking, etc.
3
Recent Mission Use of 26 GHz Ka-Band
i NASA
x SCaN Testbed
x Solar Dynamics Observatory
x Lunar Reconnaissance Orbiter
i JAXA
x Advanced Earth Observing Satellite
x Advanced Land Observation Satellite
x Japanese Experiment Module (Int’l Space Station – ISS)
i ESA
x Envisat (concluded in 2012)
i Transition to Ka-band has been slow for a number of reasons…
x Reusing hardware and systems from previous missions (reduce risk)
x Increased complexity of narrow-beam antenna pointing
4
SCaN Testbed (STB) Ka-Band
i RF Components
x Traveling Wave Tube Amplifier (TWTA)
 L3 Corporation, 40 Watts (25.5 to 25.8 GHz)
x High Gain Antenna (HGA)
 0.5 meter parabolic reflector
 39 dB peak gain at 22 GHz receive
 39.8 dB peak gain at 25 GHz transmit
x Integrated Gimbal Assembly (IGA)
 Waveguide rotary joints
 2-axis gimbaled pedestal
i Harris Corporation Software-Defined Radio (SDR)
x AITech s950 single board computer
x 4 Xilinx Virtex-IV field programmable gate arrays (FPGAs)
x Compact Peripheral Component Interconnect (cPCI) chassis
x Output: ~1 mW at Ka-band with an S-band intermediate frequency
5
STB Capabilities
i SCaN Testbed – studying advanced communications, navigation, 
and networking applications of SDR for space
x Jet Propulsion Laboratory SDR: S-band transceiver, L-band receiver
x General Dynamics SDR: S-band transceiver
i NTIA Frequency Allocation and Data Capability
x Ka-band: 225 MHz; launch data rates from 1 to 100 Mbps
x S-band: 6 MHz; launch data rates from 24 kbps to 1 Mbps
6
STB Ka-Band Tracking
i SCaN Testbed antenna pointing system
x Reprogrammable algorithm
x Open loop or closed loop
 Acquisition spiral & autotrack modes
 Programmable threshold based recv’d power
i Small beamwidth Æ sensitive pointing
x STB 3 dB beamwidth is approximately 1 degree
x ISS two line element (TLE) staleness tends to create azimuth errors
 Azimuth error == altitude; elevation error == ascending node
x ISS truss flexure can induce 1 to 2 degrees of pointing error
 See Dean Schrage “ISS Truss Flexure Measurement Applying Ka-Band Closed-Loop 
Tracking”, 3rd Annual ISS Research and Development Conference
i Closed loop is preferred
x Many pointing error sources: TLE staleness, truss flexure, attitude uncertainty
x Open loop is sufficient for high link margin and recent TLEs. 
7
STB Launch Waveform Performance
i Space-to-space Ka-band links have been evaluated
x Full duplex links with NASA’s Tracking and Data Relay Satellite System
x Waveform installed on Harris SDR at payload launch
x Stable signal with ~2.4 dB margin at 100 Mbps user data rate
i Successful link demonstrations
x No observed bit errors after 40+ minutes at 100 Mbps return link
8
Parameter Forward Link
(SDR Receive)
Return Link
(SDR Transmit)
Frequency (GHz) 22.68 25.65
Data Rate (Mbps) 9.5 100
Modulation BPSK SQPSK
Convolutional 
Coding
½ rate ½ rate
Bandwidth (MHz) 38 200
EIRP (dBW) 63 49.2
G/T (dB/K) 2.69 26.51
Required BER 10-8 10-8
Range (km) 43550
Link Margin 3.0 dB 2.4 dB
STB Antenna Pointing Quality Metric
i Antenna pointing quality metric (APQM) is important for closed 
loop tracking.
x STB uses a linear signal strength indicator
x Strong out-of-band signal rejection (noise/interference)
i Developed an APQM algorithm at NASA GRC
x Allows tracking of any modulation type or noise signal
9
Launch WF
STB High-Rate Bandwidth-Efficient Waveform
i Objective: Maximize data rate and improve spectral efficiency
x Demonstrated 300 Mbps data rate over 225 MHz bandwidth and SQPSK
x Implements high-order modulation techniques and LDPC coding
 Gaussian Minimum Shift Keying (GMSK)
 Pulse-shape filtered M-order phase-shift keying (M-PSK)
 M-order quadrature amplitude modulation (M-QAM)
x Implements digital pre-distortion techniques to account for channel issues
i NASA’s Space Network Ground
Segment Sustainment Project
x TDRSS will support 8-PSK
modulation and LDPC
decoding
x Other modulation and coding
support can be provided through
user modems on-site
10
25.2 25.3 25.4 25.5 25.6 25.7 25.8 25.9 26 26.1
-70
-60
-50
-40
-30
-20
-10
0
Frequency (GHz)
A
v
e
r
a
g
e
 
R
M
S
 
P
o
w
e
r
 
i
n
 
1
 
M
H
z
OQPSK Modulation, through L3 Flight Spare TWTA
 
 
New WF (262.5 Mbps)
Launch WF (100 Mbps)
NTIA Spectral Mask
Future Ka-Band User Spacecraft
i Interagency Operations Advisory Group (IOAG) study examined 
direct-to-ground feasibility of 26-GHz Ka-band from LEO.
x Adaptive coding and modulation schemes
x On-board steerable antennas and pointing algorithms
x High-rate data interfaces and on-board storage
i SCaN Testbed can simulate the direct-to-ground environment 
through antenna mis-pointing.
11
Final Remarks
i Although mission adoption has been slow, full duplex Ka-band is 
viable for low earth orbit applications.
i SCaN Testbed has the capability and location to support ongoing 
Ka research for LEO.
x Antenna pointing and tracking
x Received power estimation algorithms
x Modulation and coding
i More time must be dedicated to study the Ka user spacecraft.
x Omni-directional antennas for mission recovery
x Pointing requirements
12
13


Studying NASA's Transition to Ka-Band Communications for Low Earth Orbit

Abstract

Similar works

Full text

Available Versions

NASA Technical Reports Server

NASA Technical Reports Server