First time offered!
Instructor: Bruce R. Elbert
Wednesday, 28 March 2018 - 9:00am to 4:30pm EDT
Online via WebEx
- Course Description
- Course Content
- Learning Objectives
- Who Should Attend
- Course Materials
- About the Instructor: Bruce R. Elbert
Satellite data networks have become an important tool of corporations, government agencies as well as consumers needing remote access to the Internet. In this intermediate level, one-day course the instructor reviews the design and use of such networks, which employ inexpensive very small aperture terminals (VSATs). The instructor will provide up-to-date information and methodologies to employ communications satellites specifically for data communications and the Internet. The focus is unique because it combines theory and practice, addressing currently available technology solutions as well as the foundations needed to understand them.
Who Should Attend
Communications engineers and networking specialists who wish to understand how communications satellites are employed to provide data communications services, particularly with TCP/IP-based very small aperture terminals (VSATs). A background in satellite communications or radio frequency systems is desirable but not essential. This course will apply to any commercial or government organization that currently employs satellite communications for data applications, or to those considering how to do so.
Bruce R. ElbertBEE, MSEE, MBA, President, Application Technology Strategy, LLC
Bruce R. Elbert is president of his own satellite technology consulting firm, Application Technology Strategy, L.L.C., Austin, Texas; and Adjunct Professor (ret), College of Engineering, University of Wisconsin, Madison. Mr. Elbert is a recognized radio engineer and satellite communications expert, and has been involved in the satellite and telecommunications industries for over 40 years. His consulting practice has assisted major organizations, both public and private, in the selection of the best space and ground resources, and the optimization of elements of the system at the user and provider ends. During 25 years with Hughes Electronics (in divisions now part of Boeing Satellite Systems, Intelsat and DIRECTV), he directed communications engineering of several major satellite projects, including Palapa A, Indonesia's original satellite system; the Galaxy follow-on system; direct-to-home-satellite broadcasting satellites at Ku and Ka bands, and the development of the first GEO mobile satellite system capable of serving handheld user terminals. Mr. Elbert also worked as a communications engineer for the INTELSAT system, contributing to the early development of Ka-band satellite-switched multi-beam systems and mobile satellite service to ships and aircraft. He was a radio officer in the U.S. Army and taught microwave and VHF radio at the Signal School. He has written eight books on telecommunications and IT.
- Understand how communications satellites are applied to two-way data communications
- Be able to configure a satellite data network to provide Internet-based services
- Identify the strengths and weaknesses of satellite data links as compared to land-based fixed and wireless data communications
Principles of Modern SATCOM Systems
- Architecture of the space segment - GEO and non-GEO orbits, impact on performance and coverage
- Satellite construction: program requirements and duration; major suppliers: Boeing, EADS Astrium, Lockheed Martin, Northrop Grumman, Orbital Sciences, Space Systems/Loral, Thales Alenia
- Basic design of the communications satellite - repeater, antennas, spacecraft bus, processor; requirements for launch, lifetime, and retirement from service
- Network arrangements for one-way (broadcast) and two-way (star and mesh); relationship to requirements in government and military
- Satellite operators and service providers: Intelsat, SES, Inmarsat, Eutelsat, Telenor, et al
- The uplink and downlink
- Radio wave propagation in various bands: L, C, X, Ku and Ka
- Standard and adaptive coding and modulation: DVB-S2, Turbo Codes, Joint IP Modem
- Link margin, adjacent channel interference, error rate
Time Division, Frequency Division and Code Division Multiple Access on satellite links
Very Small Aperture Terminals
- Star and mesh architectures
- Random Access protocols
- Streaming and Transaction Reservation
- VSAT terminal configuration and design
Internet Protocol Operation and Application
- TCP/IP protocol suite: TCP, UDP, IP
- TCP protocol design: windowing; packet loss and retransmissions; slow start and congestion, bandwidth-delay product, acknowledgement and retransmissions, congestion control
- TCP/IP performance enhancement over satellite links
- TCP acceleration, HTTP acceleration, CIFS acceleration, compression and caching Survey of available standards-based and proprietary optimization solutions: SCPS, XTP, satellite-specific optimization products, application-specific optimization products, solution section criteria
Quality of service (QoS), IP multicast fundamentals and multicast deployment issues
User Application Considerations
- Network design and capacity planning
- Voice over IP, voice quality, compression algorithms
- VPN: resolving conflicts with TCP and HTTP acceleration
- Video Teleconferencing: H.320 and H.323
- Network management architectures
Each registered participant receives a copy of instructor slides and access to the recording of the course for 15 business days after the live lecture. Earn 0.6 IEEE Continuing Education Units for participating.
Course Cancellation and Refund Policy: Requests for online course cancellations must be received 3 business days prior to the course date for a full refund. Once course materials have been shared with a participant, a cancellation request cannot be accommodated.