Federal Aviation Administration Aeronautical Mobile Airport Communications System (AeroMACS) Status Briefing ACP WG-M, Bangkok, Thailand FAA/Brent Phillips February 1, 2011
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Federal Aviation Administration Aeronautical Mobile Airport Communications System (AeroMACS) Status Briefing ACP WG-M, Bangkok, Thailand FAA/Brent Phillips February 1, 2011 Agenda of Topics • Background FCS (AP-17) and resulting PLAs • Overview and status of FY10 activities: • Prototype AeroMACS network in the Cleveland Test Bed • Spectrum interference results • Channelization studies. • Status of AeroMACS profile development under RTCA • Plans for FY11 activities AeroMACS Status Briefing to ACP WG-M 1 Feb 2011 2 Background • Future Communications Study (AP-17), ICAO Aeronautical Communications Panel, Recommendation #1: – Develop a new system based on the IEEE 802.16e standard operating in the C-band and supporting the airport surface environment. NextGen Implementation Plans (FY09, FY10 & FY11) to improve collaborative Air Traffic Management includes “New ATM Requirements: Future Communications” – Test bed infrastructure to enable validation of aviation profile B-AMC P34/TIA-902 Continental LDL AMACS B-AMC P34/TIA-902 LDL AMACS Oceanic / Remote Inmarsat SBB Custom Satellite Inmarsat SBB Custom Satellite Oceanic / Remote Airport IEEE 802.16e IEEE 802.16e Airport Continental Custom Satellite Communication Roadmap (1 of 4) SWIM CY 09 10 11 12 13 14 15 16 17 SWIM Segmt. 1 SWIM Segmt. 2 SWIM-Core Services 214 LDRCL 18 19 20 21 22 23 24 25 SWIM Segmt. 3 X RCL X 215 BWM Telecom – Concepts of use, preliminary requirements, and architecture for C-band airport surface wireless communication system Europe AMACS-001rev1 X DMN 102 NADIN PSN ANICS X Discontinued X25 Service Users transferred to FTI IP 130 FID 74 FID ASTI 129 NADIN MSN NMR FTI-1 Supporting Activities • Common Shortlist United States X X FTI-2 216 Airport IID CRDR 497 FID Wireless 217JARD 498 Note: Fixed User Ground Communications as a Communication 496 component of a Mobile User Communications Network System Airport Wireless Communications System (R&D Effort) 344 NASA R&D on airport vehicles (with ADS-B out) surface location 345 Inventory Navigation Time and Frequency Requirements and Assess GPS Outage Impact Approved AMACS-002rev1 AeroMACS Status Briefing to ACP WG-M 1 Feb 2011 3 Potential AeroMACS Service Categories in U.S. Potential AeroMACS Services Air Traffic Mobile Air Traffic Control Advisory Services Fixed Airline Airport Mobile Mobile AOC Services AAC Services Advisory Services Port Authority Ops Safety Services Fixed Fixed Surface CNS Services • FAA, FTI, Others? TBD Port Authority Ops Security Services • ARINC, SITA, Airlines, Others? • Port Authority, Commercial? AeroMACS Status Briefing to ACP WG-M 1 Feb 2011 4 AeroMACS Service Examples and Provision Options Air Traffic Services Service Examples Provision Options Airline Services Service Examples Provision Options Air traffic control commands beyond Data Comm Segment 3 Surface communications, navigation, and surveillance (CNS) fixed assets Government-owned (licensed)/Government-operated (GO/GO) Government-owned (licensed)/Commercially-operated (GO/CO) Non-competed service extension via FAA Telecommunications Infrastructure (FTI) Open commercial competition by FAA Airline Operational Control (AOC) Airline Administrative Communications (AAC) Advisory information System Wide Information Management (SWIM) Aeronautical Information Management (AIM) Meteorological (MET) data services Commercially-owned (licensed)/Commercially-operated (CO/CO) Non-competed service extension via exiting AOC service providers Airline service provision internally Open commercial competition by airlines Airport Operator/Port Authority Services Service Examples Provision Options Security video Routine and emergency operations De-icing/snow removal Local Government-owned (licensed)/Commercially-operated (GO/CO) Commercially-owned (licensed)/Commercially-operated (CO/CO) Open commercial competition by Operator/Port Authority AeroMACS Status Briefing to ACP WG-M 1 Feb 2011 5 AeroMACS NASA-CLE CNS Test Bed • CNS Test Bed at NASA Glenn and adjacent Cleveland Hopkins International Airport (CLE) already includes Sensis’ precision multilateration (MLAT) surveillance and unlicensed WiFi network • ITT’s AeroMACS prototype implements features required to support mobile and stationary wideband communications for safety and regularity of flight services in an operational airport environment • Full prototype network has been installed, including user verification and security with Authentication, Authorization, and Accounting (AAA) server function • AeroMACS hardware and network installation completed in October 2009 with two multi-sector base stations providing wide area coverage and redundancy (one on Glenn property, one on CLE) and eight subscriber stations (two on Glenn, six on CLE) • AeroMACS operational capability established in March 2010 AeroMACS Status Briefing to ACP WG-M 1 Feb 2011 6 NASA-Cleveland Test Bed AeroMACS Network Layout NASA Glenn Research Center AZ = 55° ° Subscriber Stations AZ = 200° AZ = 45° AZ = 295° AZ = 185° Core Server Base Stations Cleveland-Hopkins International Airport AeroMACS Status Briefing to ACP WG-M 1 Feb 2011 7 Two-Sector Base Station Located at NASA Glenn Hangar Building 4 GPS ODU BTS 1-1 ODU GPS ODU BTS 1-2 ODU 11 GHz Backhaul ODU AeroMACS Status Briefing to ACP WG-M 1 Feb 2011 8 Three-Sector Base Station Located at CLE Aircraft Rescue and Firefighting (ARFF) Building GPS ODUs ARFF Building and Observation Deck 11 GHz Data Backhaul to B110 BS ODUs (3) AeroMACS Status Briefing to ACP WG-M 1 Feb 2011 9 Subscriber Station Installation Example on Sensis MLAT Equipment at NASA Glenn Building 500 Sensis Multilateration MLAT Remote Unit Equipment ITT AeroMACS Subscriber Station Electronics Enclosure ITT AeroMACS Subscriber Station ODU AeroMACS Status Briefing to ACP WG-M 1 Feb 2011 10 AeroMACS FY10 Evaluations • Measure data throughput and packet integrity for the following conditions: – – – – 5 and 10 MHz channel bandwidths Stationary and mobile subscriber stations at speeds of at least 40 knots Line-Of-Sight (LOS) and Non-LOS (N-LOS) propagation links Presence of adjacent channel activity • Mobility tests with hand-off transition between base station coverage sectors and between base stations • Determine minimum transmit power required to maintain a minimum level of link performance: – Single subscriber station antenna – MIMO antenna diversity • Characterize link performance when transferring sensor data from MLAT sensors in test bed – Mixture of data traffic streams – Traffic priority setting with Quality of Service (QoS) settings AeroMACS Status Briefing to ACP WG-M 1 Feb 2011 Initial Data Throughput Measurements Between Buildings 500 and 4 • Initial data throughput measurement results available for links between NASA Building 500 and two Base Station sectors at NASA Building 4 – > 6.5 Mbps in Downlink direction (BS to SS) – > 4 Mbps in Uplink direction (SS to BS) • Conditions – 5 MHz Channel bandwidth – TDD ratio 60% (DL), 40% (UL) – TCP data traffic BTS Sector BTS1_1 BTS1_2 Measured Throughput DL, Mbps 6.82 6.54 Expected DL Throughput, Mbps 6.5 6.5 Measured Throughput UL, Mbps 5.40 4.19 AeroMACS Status Briefing to ACP WG-M 1 Feb 2011 Expected Throughput UL, Mbps 4.0 4.0 12 Initial Channelization Methodology/Channel Plan • Select common channel bandwidths of 5 MHz or 10 MHz, not both • Proposed channel plan consisting of 11 usable 5 MHz channels (with stringent channel mask) or 5 usable 10 MHz channels within the current 59 MHz AM(R)S allocation (5091-5150 MHz) • Out-of-band (OOB) interference into adjacent aeronautical band (5030-5091 MHz) may be coordinated via ICAO for 11th 5 MHz channel Current AM(R)S Allocation for AeroMACS Other Aviation Allocation NonAviation Allocation 5091 MHz 5150 MHz AeroMACS Status Briefing to ACP WG-M 1 Feb 2011 13 Spectrum Interference Initial Assessment • Establish limits on aggregated AeroMACS transmissions to not exceed interference threshold for MSS feeder links • Model based on Visualyse Professional 7 software from Transfinite Systems Limited – Includes: antennas, stations, carriers, links, and interference paths to determined signal, interference, and noise levels. – Preliminary model included all 703 US towered airports; Refined model benchmarks MITRE case for omni antennas at 497 major US towered airports Power Flux Density at Low Earth Orbit from 497 US Airports – Interference threshold (-157.374 dB) met with maximum base station transmitted power of 447 mW for 10-MHz channels and 224 mW for 5-MHz channels • Plan to increase complexity and realism of interference models: – Multi-sector antennas; multiple base and subscriber stations per airport; co-channel and adjacent band; proximity; frequency reuse; multipath signal propagation AeroMACS Status Briefing to ACP WG-M 1 Feb 2011 Acceptable Interference Threshold for 5 MHz Channels 14 Funded Research Activities in FY11 • Evaluate a selected ATC mobile application on the aeronautical mobile airport communications system (AeroMACS) • Investigate and resolve remaining issues affecting the final AeroMACS profile inputs to the MOPS process Evaluate and recommend mobile Source Station (SS) MIMO antenna configurations for mobile SSs Optimize AeroMACS system-level performance (QoS, data throughput, latency, error rate) within ITU limitations on radiated power Resolve channel BW and center frequency spacing plans to satisfy US and European objectives while preserving Spectrum Office flexibility and compatibility with WiMAX Forum practices Validate that the proposed AeroMACS complies with interference requirements for the US proposed allocation at World Radiocommunications Conference in 2012. AeroMACS Status Briefing to ACP WG-M 1 Feb 2011 15 RTCA SC-223 • RTCA Program Management Council approved SC-223 in July 2009 for Airport Surface Wireless Communications standard development – Aeronautical Mobile Airport Communications System (AeroMACS) profile is based on IEEE 802.16-2009 standard – Recent Meetings held: – 17-18 August 2010 at NASA in Cleveland, Ohio (USA) – 28-30 September 2010 as joint RTCA-223 and EUROCAE WG-82 at EUROCONTROL in Brussels – 16-17 November 2010 at Washington D.C. (USA) – Next meeting 22-23 Melborne, FL (USA) – Draft AeroMACS profile complete. Document out for Final Recommendations and Comments (FRAC). – Minimum Operational Performance Standard (MOPS) process begins in February. AeroMACS Status Briefing to ACP WG-M 1 Feb 2011 16 Approach for Technical Parameter Profile • • • System profile define AeroMACS operation in the unique airport surface environment Profile based on IEEE 802.16-2009 broadband mobility standard Leverages commercial mobile Worldwide Interoperability for Microwave Access (WiMAX) for profiles, hardware, software, and network architecture • Testing, analyses, and demos will validate that application needs are met • RTCA SC-223 is developing FAA profile recommendations; EUROCAE WG-82 is developing common profile for EUROCONTROL in parallel Profile Area RF/Radio parameters Frequency band Channel BWs Channel center frequencies Power class Max DL TX power Max UL TX power Duplex Mode TDD/FDD Physical Layer M-ary QAM range Coding options MIMO MAC Layer ARQ Security protocols Mobile protocols QoS options AeroMACS Status Briefing to ACP WG-M 1 Feb 2011 Key Parameter Selections 5091 to 5150 MHz 5, 10 MHz Center frequencies at 5 MHz increments Unchanged from IEEE 802.16e TDD Performance profiles – Min. performance defined in 802.16e and sensitivity values scaled for frequency Unchanged from IEEE 802.16e 17