Wireless Communications & Spread Spectrum Design- E222
$2295 per person
This three-day course is designed for wireless communication engineers involved with spread spectrum systems, and managers who wish to enhance their understanding of the wireless techniques that are being used in all types of communication systems and products. It provides an overall look at many types and advantages of spread spectrum systems that are designed in wireless systems today. This course covers an intuitive approach that provides a real feel for the technology, with applications that apply to both the government and commercial sectors.
Students will receive a copy of the instructor’s textbook, Transceiver and Systems Design for Digital Communications, 4th Edition.
What you will learn:
- How to perform link budgets for types of spread spectrum communications?
- How to evaluate different types of wireless communication transceivers?
- What methods are used for spread spectrum modems, multiple access, OFDM, error detection/correction for digital communication systems?
- What is multipath and how to reduce multipath and jammers?
- What is a Global Positioning System?
- How to use satellite communications for data communication links?
- What techniques are being used for Broadband Communications in both commercial and military radios including networking, JTRS, Link 16, clusters, and gateway?
- How to solve a 3 dimension Direction Finding system using interferometry?
From this course you will obtain the knowledge and ability to evaluate and develop the system design for wireless communication digital transceivers including spread spectrum systems
- Provides an understanding of concepts in wireless, data link, and digital communication techniques for both commercial and military sectors.
- Covers digital modulation, spread spectrum modulation and demodulation, link budgets, error detection and correction, probability applications, and a broad coverage of all the elements that make up a digital modulated data link.
- Includes extra topics such as: adaptive process to mitigate narrow band jammers in a broadband communications link, GPS, multipath, and satellite communications. Also includes Link 16, JTRS, military radios, networking link budgets, Eb/No, BER, Pe, direct sequence spread spectrum transmitters, PN code generators, DSPs, AGC, pulsed matched fi lters, PPM, CDMA, carrier recovery, matched fi lters & sliding correlators, eye pattern, phase detection, Gaussian processes, quantization error, antijam, adaptive fi lters, intercept receivers, GPS.
- Transceiver Design. dB power, link budgets, system design tradeoffs, gains/losses, Signal-to-Noise, Probability of Error, Bit Error Rate, Eb/No, link margin, tracking noise and signal level through a complete system, effects and advantages of using spread spectrum techniques.
- Transmitter Design. Various types and system designs of spread spectrum transmitters, PSK, MSK, QAM, OFDM, Other, Pseudo-Random code generator, multiple access TDMA/CDMA/FDMA, antenna sizing, transmit/receive, local oscillator, upconverters, sideband elimination, power amplifiers, standing wave ratios.
- Receiver Design. Dynamic range, image rejection, limiters, minimum discernable signal, superheterodyne receivers, importance of low noise amplifiers, 3rd order intercept point for intermodulation products, two tone dynamic range, tangential sensitivity, phase noise, mixers, spurious signals, filters, A/D converters, aliasing and anti-aliasing filters, digital signal processors DSPs.
- Automatic Gain Control Design & Phase Lock Loop Comparison. AGCs, linearizer, detector, loop filter, integrator, using control theory and feedback systems to analyze AGCs, PLL and AGC comparison.
- Demodulation. Demodulation and despreading techniques for spread spectrum systems, pulsed matched filters, sliding correlators, pulse position modulation, CDMA, coherent demod, despreading, carrier recovery, squaring loops, Costas and modified Costas loops, symbol synch, eye pattern, inter-symbol interference, phase detection, Shannon’ s limit.
- Basic Probability and Pulse Theory. Simple approach to understanding Probability, Gaussian process, quantization error, probability of error, bit error rate, probability of detection vs probability of false alarm, error detection and correction, interleaving, types of FECs, digital pulsed systems, pseudo-random codes for spread spectrum systems.
- Multipath. Specular and diffuse reflections, Rayleigh criteria, earth curvature, pulse systems, vector and power analysis.
- Improving the System Against Jammers. Burst jammers, digital filters, adaptive filters simulations and actual design results, quadrature method to eliminate unwanted sidebands, orthogonal methods to reduce jammers, types of intercept receivers.
- Global Navigation Satellite Systems. Basic understand of the Global Positioning System GPS and the spread spectrum BPSK modulated signal from space, Satellite transmission, signal structure, GPS receiver, errors, narrow correlator, selective availability SA, carrier smoothed code, Differential DGPS, Relative GPS, widelane/narrowlane, carrier phase tracking KCPT, double difference.
- Satellite Communications. Communication Satellites, General Satellite Operation, Fixed Satellite Service, Geosynchronous and Geostationary Orbits, Ground Station Antennas, Carrier power, Equivalent Temperature Analysis, Multiple Channels in the Same Frequency Band, Multiple Access Schemes, Propagation Delay, Cost for Use of the Satellites, Regulations, Types of Satellites Used for Communications
- Broadband Communications and Networking. Mobile Users, Home networking, Power Line Communicatins PLC, Orthogonal Frequency Division Multiplexing OFDM, IEEE 802.11, Bluetooth, Military Radios and Data Links, The Joint Tactical Radio System (JTRS), Software Design Radios, The Software Communications Architecture, Clusters, JTRS Network Challenge, Gateway and Network Configurations, Link 16, TDMA, “Stacked” nets, Time Slot Re-allocation, Bit/Message Structure.
- DF & Interferometer Analysis. Positioning and direction finding using a simpified interferometer analysis, direction cosines, basic interferometer equation, three dimensional approach, antenna position matrix, coordinate conversion for moving baseline.
If this course is not on the current schedule of open enrollment courses and you are interested in attending this or another course as an open enrollment, please contact us at (410) 956-8805 or email@example.com. Please indicate the course name, number of students who wish to participate. and a preferred time frame. ATI typically schedules open enrollment courses with a 3-5 month lead time. For on-site pricing, you can use the request an on-site quote form, call us at (410) 956-8805, or email us at firstname.lastname@example.org.
Scott R. Bullock, P.E., MSEE, specializes in Wireless Communications including Spread Spectrum Systems and Broadband Communication Systems, Networking, Software Defined Radios and Cognitive Radios and Systems for both government and commercial uses. He holds 18 patents and 22 trade secrets in communications and has published several articles in various trade magazines. He was active in establishing the data link standard for GPS SCAT-I landing systems, the first handheld spread spectrum PCS cell phone, and developed spread spectrum landing systems for the government. He is the author of two books, Transceiver and System Design for Digital Communications & Broadband Communications and Home Networking, Scitech Publishing. He has taught seminars for several years to all the major communication companies, an adjunct professor at two colleges, and was a guest lecturer for Polytechnic University on “Direct Sequence Spread Spectrum and Multiple Access Technologies.” He has held several high level engineering positions including VP, Senior Director, Director of R&D, Engineering Fellow, and Consulting Engineer.
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