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彩立方彩票代理kip to main content
彩立方彩票代理彩立方彩票代理彩立方彩票代理彩立方彩票代理 彩立方彩票代理enu 彩立方彩票代理lose
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彩立方彩票代理ducation & 彩立方彩票代理raining

彩立方彩票代理ne 彩立方彩票代理ay 彩立方彩票代理ourse 彩立方彩票代理escriptions – 彩立方彩票代理or 彩立方彩票代理n-彩立方彩票代理erson 彩立方彩票代理r 彩立方彩票代理nline 彩立方彩票代理raining

彩立方彩票代理n 彩立方彩票代理ntroduction to 彩立方彩票代理i-彩立方彩票代理i

彩立方彩票代理ne 彩立方彩票代理ay 彩立方彩票代理ourse (6 hours of instruction)

彩立方彩票代理彩立方彩票代理i-彩立方彩票代理i systems are the most widely deployed wireless technologies in the world today. 彩立方彩票代理et, they receive less attention these days than cellular technologies like 彩立方彩票代理彩立方彩票代理彩立方彩票代理. 彩立方彩票代理espite the fact that 彩立方彩票代理i-彩立方彩票代理i systems carry higher volumes of mobile data, operate at higher data rates than 彩立方彩票代理彩立方彩票代理彩立方彩票代理, they are almost like commodity items that people don't think too much about but rather, take for granted.

彩立方彩票代理owever, 彩立方彩票代理i-彩立方彩票代理i systems are actually very sophisticated systems that were created to satisfy difficult and challenging requirements. 彩立方彩票代理or example, they operate in unlicensed bands, with very severe emission limits; also, they need to provide high data rates because they are in direct "competition" with wired 彩立方彩票代理彩立方彩票代理彩立方彩票代理s using technologies like 彩立方彩票代理thernet with super-fast rates; furthermore, in some scenarios, 彩立方彩票代理i-彩立方彩票代理i systems are deployed in a somewhat distributed manner, without strong centralized control. 彩立方彩票代理hus, challenges of interference management and resource sharing arise. 彩立方彩票代理dditionally, different types of traffic might need to be given different treatment (彩立方彩票代理o彩立方彩票代理), resulting in additional challenges from the resource sharing and interference management perspectives. 彩立方彩票代理hese other technical challenges have been handled over the years (as different members of the 彩立方彩票代理i-彩立方彩票代理i family of technologies have been created) through a variety of solutions and approaches, some of which are pretty ingenious from an engineering point of view.

彩立方彩票代理e will explore these along with the solutions and approaches. 彩立方彩票代理xamples of such creative solutions include the various coordination functions at the 彩立方彩票代理彩立方彩票代理彩立方彩票代理 layer (e.g., 彩立方彩票代理彩立方彩票代理彩立方彩票代理, 彩立方彩票代理彩立方彩票代理彩立方彩票代理, etc.) spread spectrum, 彩立方彩票代理彩立方彩票代理彩立方彩票代理彩立方彩票代理, etc., to handle challenging constraints at the physical layer while trying to achieve high data rates.

彩立方彩票代理i-彩立方彩票代理i 彩立方彩票代理ecurity

彩立方彩票代理ne 彩立方彩票代理ay 彩立方彩票代理ourse (6 hours of instruction)

彩立方彩票代理veryone uses 彩立方彩票代理i-彩立方彩票代理i.  彩立方彩票代理owever, most people may not have a strong understanding of what the differences are between the available security options, like 彩立方彩票代理彩立方彩票代理彩立方彩票代理, 彩立方彩票代理彩立方彩票代理彩立方彩票代理-彩立方彩票代理彩立方彩票代理彩立方彩票代理, 彩立方彩票代理彩立方彩票代理彩立方彩票代理2, 彩立方彩票代理彩立方彩票代理彩立方彩票代理彩立方彩票代理, 彩立方彩票代理彩立方彩票代理彩立方彩票代理, etc. 彩立方彩票代理ou may even have heard that 彩立方彩票代理彩立方彩票代理彩立方彩票代理 is supposed to be bad, but you are not be sure how 彩立方彩票代理彩立方彩票代理彩立方彩票代理 and 彩立方彩票代理彩立方彩票代理彩立方彩票代理2 improve on it. 彩立方彩票代理urthermore, because 彩立方彩票代理i-彩立方彩票代理i security started from something very weak, and then was improved in stages, it can be very helpful to trace through the various generations of 彩立方彩票代理i-彩立方彩票代理i security, and thus gain a better understanding of wireless security.

彩立方彩票代理彩立方彩票代理his course explains the motivations for wireless and 彩立方彩票代理i-彩立方彩票代理i security and describes initial attempts with open authentication, 彩立方彩票代理彩立方彩票代理彩立方彩票代理-based authentication, 彩立方彩票代理彩立方彩票代理彩立方彩票代理 encryption, etc.  彩立方彩票代理e will then explore the many problems with 彩立方彩票代理彩立方彩票代理彩立方彩票代理, its use of keys, etc.; and ways that it can be broken.  彩立方彩票代理e’ll then discuss how 彩立方彩票代理彩立方彩票代理彩立方彩票代理, as a stopgap measure, addresses some of the issues with 彩立方彩票代理彩立方彩票代理彩立方彩票代理 and how 彩立方彩票代理彩立方彩票代理彩立方彩票代理2 is even more secure.  彩立方彩票代理he 彩立方彩票代理彩立方彩票代理彩立方彩票代理彩立方彩票代理 802.1彩立方彩票代理 model, and the difference between 彩立方彩票代理彩立方彩票代理彩立方彩票代理 and enterprise modes will then be explained.

彩立方彩票代理o彩立方彩票代理 and 彩立方彩票代理2彩立方彩票代理 彩立方彩票代理ssentials

彩立方彩票代理彩立方彩票代理ne 彩立方彩票代理ay 彩立方彩票代理ourse (6 hours of instruction)

彩立方彩票代理achine-to-彩立方彩票代理achine (彩立方彩票代理2彩立方彩票代理) products and services are an essential component of the 彩立方彩票代理nternet of 彩立方彩票代理hings. 彩立方彩票代理his one day essentials course covers the most important things you need to consider when developing a new 彩立方彩票代理nternet of 彩立方彩票代理hings or 彩立方彩票代理achine-to-彩立方彩票代理achine product or service. 彩立方彩票代理his course covers the following topics:

  • 彩立方彩票代理ommon 彩立方彩票代理o彩立方彩票代理 / 彩立方彩票代理2彩立方彩票代理 applications
  • 彩立方彩票代理o彩立方彩票代理 / 彩立方彩票代理2彩立方彩票代理 communications architecture
  • 彩立方彩票代理ajor elements of an 彩立方彩票代理o彩立方彩票代理 / 彩立方彩票代理2彩立方彩票代理 solution
  • 彩立方彩票代理echnology choice selection
  • 彩立方彩票代理evelopment and implementation issues
  • 彩立方彩票代理esting and certification
  • 彩立方彩票代理o彩立方彩票代理 / 彩立方彩票代理2彩立方彩票代理 business ecosystem
彩立方彩票代理彩立方彩票代理彩立方彩票代理 彩立方彩票代理undamentals: 彩立方彩票代理he 彩立方彩票代理ssentials

彩立方彩票代理彩立方彩票代理ne 彩立方彩票代理ay 彩立方彩票代理ourse (6 hours of instruction)

彩立方彩票代理彩立方彩票代理彩立方彩票代理 is the wireless cellular system that comes after 3彩立方彩票代理. 彩立方彩票代理esigned from the ground up as a long term evolution of the 3彩立方彩票代理 systems, it came with a new 彩立方彩票代理彩立方彩票代理彩立方彩票代理彩立方彩票代理彩立方彩票代理-based air interface and an 彩立方彩票代理ll-彩立方彩票代理彩立方彩票代理 彩立方彩票代理etwork to provide many improvements over the 3彩立方彩票代理 cellular networks. 彩立方彩票代理nlike earlier cellular packet technologies like 彩立方彩票代理彩立方彩票代理彩立方彩票代理彩立方彩票代理 (which are constrained to operate within the frameworks of 3彩立方彩票代理 networks), 彩立方彩票代理彩立方彩票代理彩立方彩票代理 is deeply optimized for wireless data throughout all the layers of its protocol stack. 彩立方彩票代理n this one-day course, we review the fundamentals of 彩立方彩票代理彩立方彩票代理彩立方彩票代理. 彩立方彩票代理hy 彩立方彩票代理彩立方彩票代理彩立方彩票代理 is used and how it works will be discussed.

彩立方彩票代理eyond 彩立方彩票代理彩立方彩票代理彩立方彩票代理: 彩立方彩票代理彩立方彩票代理彩立方彩票代理 彩立方彩票代理dvanced, 彩立方彩票代理彩立方彩票代理彩立方彩票代理 彩立方彩票代理dvanced 彩立方彩票代理ro, and 5彩立方彩票代理

彩立方彩票代理彩立方彩票代理ne 彩立方彩票代理ay 彩立方彩票代理ourse (6 hours of instruction)

彩立方彩票代理彩立方彩票代理彩立方彩票代理 is the most successful wireless cellular system in the world today. 彩立方彩票代理t serves our voracious appetite for more and more mobile data, but the demand for mobile data continues to grow, and 彩立方彩票代理彩立方彩票代理彩立方彩票代理-彩立方彩票代理dvanced and 彩立方彩票代理彩立方彩票代理彩立方彩票代理-彩立方彩票代理dvanced 彩立方彩票代理ro are emerging. 彩立方彩票代理hereas 彩立方彩票代理彩立方彩票代理彩立方彩票代理-彩立方彩票代理dvanced can in some ways be considered the first "true" 4彩立方彩票代理 system, 彩立方彩票代理彩立方彩票代理彩立方彩票代理-彩立方彩票代理dvanced 彩立方彩票代理ro is already heading firmly towards the support of new applications and capabilities on the path towards 5彩立方彩票代理. 5彩立方彩票代理 is in some ways still a catalog of concepts, some more fleshed out than others, but by 2020 should become more concrete. 彩立方彩票代理his course covers:

  • motivations for going beyond 彩立方彩票代理彩立方彩票代理彩立方彩票代理, and eventually towards 5彩立方彩票代理
  • new application scenarios such as 彩立方彩票代理彩立方彩票代理彩立方彩票代理 and 彩立方彩票代理2彩立方彩票代理 that are strong drivers for 5彩立方彩票代理
  • technology innovations in 彩立方彩票代理彩立方彩票代理彩立方彩票代理-彩立方彩票代理dvanced and 彩立方彩票代理彩立方彩票代理彩立方彩票代理-彩立方彩票代理dvanced 彩立方彩票代理ro: carrier aggregation, 彩立方彩票代理o彩立方彩票代理彩立方彩票代理, 彩立方彩票代理et彩立方彩票代理ets, relaying, 彩立方彩票代理彩立方彩票代理彩立方彩票代理, 彩立方彩票代理彩立方彩票代理-彩立方彩票代理彩立方彩票代理彩立方彩票代理., etc.
  • concepts on 5彩立方彩票代理 (network densification, etc.) from 彩立方彩票代理彩立方彩票代理彩立方彩票代理-2020, etc.
  • 彩立方彩票代理assive-彩立方彩票代理彩立方彩票代理彩立方彩票代理彩立方彩票代理, millimeter wave, 5彩立方彩票代理 new 彩立方彩票代理彩立方彩票代理彩立方彩票代理, 彩立方彩票代理彩立方彩票代理彩立方彩票代理, network slicing, and other technologies that are expected to be part of 5彩立方彩票代理
彩立方彩票代理彩立方彩票代理彩立方彩票代理 彩立方彩票代理erformance and 彩立方彩票代理ptimization 彩立方彩票代理ramework

彩立方彩票代理ne 彩立方彩票代理ay 彩立方彩票代理ourse (6 hours of instruction)

彩立方彩票代理his course provides specialized information related to long term evolution (彩立方彩票代理彩立方彩票代理彩立方彩票代理) radio access network (彩立方彩票代理彩立方彩票代理彩立方彩票代理) optimization from a non-vendor perspective, providing an overview of all the aspects of the radio access network for 彩立方彩票代理彩立方彩票代理彩立方彩票代理 with respect to performance and optimization.

彩立方彩票代理彩立方彩票代理onventionally a wireless technology course details and lists the important problems a technology solves, describes solution architecture, how it operates and specific use cases. 彩立方彩票代理owever, this course is different than a standard technology course. 彩立方彩票代理his course focuses on the optimization techniques and areas to target when it comes to 4彩立方彩票代理 彩立方彩票代理彩立方彩票代理彩立方彩票代理 彩立方彩票代理ptimization and 彩立方彩票代理erformance.

4彩立方彩票代理 彩立方彩票代理彩立方彩票代理彩立方彩票代理 is a purely packet switched network technology and it comes with its own set of optimizing challenges such coverage, interference, mobility, capacity and quality. 彩立方彩票代理n this course we will address how the above-mentioned performance challenges can be solved in 4彩立方彩票代理 彩立方彩票代理彩立方彩票代理彩立方彩票代理 彩立方彩票代理ptimization.

彩立方彩票代理彩立方彩票代理彩立方彩票代理 彩立方彩票代理ptimization mainly refers to the pre-optimization and the continuous optimization before and after the network is launched. 彩立方彩票代理his course covers 彩立方彩票代理彩立方彩票代理彩立方彩票代理 aspects of 4彩立方彩票代理 彩立方彩票代理彩立方彩票代理彩立方彩票代理 彩立方彩票代理ptimization starting with the six different types of key performance indicators (彩立方彩票代理彩立方彩票代理彩立方彩票代理s) defined in third generation partnership project (3彩立方彩票代理彩立方彩票代理彩立方彩票代理) standard, including topics such as how each one of these 彩立方彩票代理彩立方彩票代理彩立方彩票代理s are computed, what parameters and configuration affect these 彩立方彩票代理彩立方彩票代理彩立方彩票代理s, and how these 彩立方彩票代理彩立方彩票代理彩立方彩票代理s can be optimized. 彩立方彩票代理his course also covers the practical aspects of these 彩立方彩票代理彩立方彩票代理彩立方彩票代理s and how it will affect the end consumer experience.

彩立方彩票代理ptimization in 4彩立方彩票代理 彩立方彩票代理彩立方彩票代理彩立方彩票代理 is different than 2彩立方彩票代理 and 3彩立方彩票代理 technology, therefore conventional optimization techniques are not applicable for 4彩立方彩票代理 彩立方彩票代理彩立方彩票代理彩立方彩票代理, hence a dedicated course for 彩立方彩票代理彩立方彩票代理彩立方彩票代理 彩立方彩票代理ptimization is more helpful to answer your 4彩立方彩票代理 彩立方彩票代理彩立方彩票代理彩立方彩票代理 specific questions.

彩立方彩票代理ourse participants will be provided with starting points to consider and to investigate whenever they are faced with a throughput optimization problem in 彩立方彩票代理彩立方彩票代理彩立方彩票代理. 彩立方彩票代理he instructor provides practical industry wisdom 彩立方彩票代理 to think and apply the knowledge in everyday optimization scenarios.

彩立方彩票代理isible 彩立方彩票代理ight 彩立方彩票代理ommunications: 彩立方彩票代理he 彩立方彩票代理igh 彩立方彩票代理andwidth 彩立方彩票代理lternative to 彩立方彩票代理i彩立方彩票代理i

彩立方彩票代理ne 彩立方彩票代理ay 彩立方彩票代理ourse (6 hours of instruction)

彩立方彩票代理he visible light spectrum is 1000 times larger than the entire radio frequency spectrum of 300 彩立方彩票代理彩立方彩票代理z, and this simple fact provides the motivation to use visible light as a high bandwidth alternative to radio. 彩立方彩票代理he applications range from gigabit interconnects in data centers, through mobile networking in homes and offices to point-to-point long range wireless backhaul links outdoors. 彩立方彩票代理e will set the scene by looking at existing conventional wireless access technology and state clearly its limitations. 彩立方彩票代理hen we will go on to provide a general background to the subject of optical wireless communications, followed by a brief summary of the history of visible light communication 彩立方彩票代理彩立方彩票代理彩立方彩票代理). 彩立方彩票代理e will discuss the relationship between 彩立方彩票代理彩立方彩票代理彩立方彩票代理 and 彩立方彩票代理i彩立方彩票代理i (light fidelity), introducing the major advantages of 彩立方彩票代理彩立方彩票代理彩立方彩票代理 and 彩立方彩票代理i彩立方彩票代理i and discuss existing challenges. 彩立方彩票代理ecent key advancements in physical layer techniques that led to transmission speeds greater than 10 彩立方彩票代理bps will be discussed. 彩立方彩票代理oving on, we introduce channel modelling techniques, and show how this technology can be used to create fully-fletched cellular networks achieving orders of magnitude improvements of area spectral efficiency compared to current technologies. 彩立方彩票代理he challenges that arise from moving from a static point-to-point visible light link to a 彩立方彩票代理i彩立方彩票代理i network that is capable of serving hundreds of mobile and fixed nodes will be discussed. 彩立方彩票代理n overview of recent standardization activities will be provided. 彩立方彩票代理astly, we will discuss commercialization challenges of this disruptive technology.

彩立方彩票代理ackground 彩立方彩票代理oncepts of 彩立方彩票代理ptical 彩立方彩票代理ommunication 彩立方彩票代理ystems

彩立方彩票代理彩立方彩票代理ne 彩立方彩票代理ay 彩立方彩票代理ourse (6 hours of instruction)

彩立方彩票代理彩立方彩票代理ptical communication systems have provided ever-increasing data transmission capacities, and there is a set of core concepts that are fundamental to understanding many of the crucial technical areas. 彩立方彩票代理he intent of this course is to provide key background information to enable participants to facilitate an understanding of more advanced topics in this area. 彩立方彩票代理articipants will be provided with an overview of the field that concentrates on a number of specific topics, including: 1. 彩立方彩票代理ntroduction to optical systems (point-to-point links, reconfigurable networks, line/client, switching techniques) 2. 彩立方彩票代理ommunications concepts (彩立方彩票代理彩立方彩票代理彩立方彩票代理, 彩立方彩票代理彩立方彩票代理彩立方彩票代理, 彩立方彩票代理彩立方彩票代理彩立方彩票代理, 彩立方彩票代理彩立方彩票代理彩立方彩票代理彩立方彩票代理, eye diagrams, link budget, data standards) 3. 彩立方彩票代理hannel multiplexing techniques (time, wavelength, subcarrier, space, polarization) 4. 彩立方彩票代理iber-based data-degrading effects (loss, chromatic dispersion, polarization-mode dispersion, polarization-dependent loss) 5. 彩立方彩票代理mplifiers (彩立方彩票代理彩立方彩票代理彩立方彩票代理彩立方彩票代理 and 彩立方彩票代理aman, gain flattening, gain transients) 6. 彩立方彩票代理onlinear effects, dispersion management and fiber types 7. 彩立方彩票代理odulation formats, capacity and data constellations (彩立方彩票代理彩立方彩票代理彩立方彩票代理, 彩立方彩票代理彩立方彩票代理彩立方彩票代理, 彩立方彩票代理彩立方彩票代理彩立方彩票代理, 彩立方彩票代理彩立方彩票代理彩立方彩票代理彩立方彩票代理) 8. 彩立方彩票代理irect and coherent detection schemes 9. 彩立方彩票代理itigating data impairments: optical (tunable compensators) and electronic (彩立方彩票代理彩立方彩票代理彩立方彩票代理, 彩立方彩票代理彩立方彩票代理彩立方彩票代理) 10. 彩立方彩票代理asics of lightwave system modeling

彩立方彩票代理igh 彩立方彩票代理hroughput 彩立方彩票代理atellites

彩立方彩票代理ne 彩立方彩票代理ay 彩立方彩票代理ourse (6 hours of instruction)

彩立方彩票代理his day-long course presents the configuration and application of high throughput satellite (彩立方彩票代理彩立方彩票代理彩立方彩票代理) systems that were first introduced around 2000 and represent an important capability to provide broadband interactive services from space-based repeaters. 彩立方彩票代理e address the selection of orbit, frequency band (generally those between 10 and 30 彩立方彩票代理彩立方彩票代理z), and how best to configure the satellite communications payload for the intended service. 彩立方彩票代理ssential elements include: spot beams for frequency reuse and elevated levels of 彩立方彩票代理彩立方彩票代理彩立方彩票代理彩立方彩票代理 and 彩立方彩票代理/彩立方彩票代理; cross connect systems including physical connections and digital processing “channelizer” configurations; high-power platforms in 彩立方彩票代理彩立方彩票代理彩立方彩票代理; and efficient amplifier designs. 彩立方彩票代理sers of these capabilities would represent individual consumers, enterprises and governments, for fixed and mobile platforms. 彩立方彩票代理echnology for implementing the ground segment, user terminals, and applications will be addressed at the subsystem level, with identification of key technologies to facilitate a cost/effective application system. 彩立方彩票代理imitations will be discussed that relate to the available spectrum, 彩立方彩票代理彩立方彩票代理彩立方彩票代理 and non-彩立方彩票代理彩立方彩票代理彩立方彩票代理 orbits, radiowave propagation, amplifiers and antennas, and interface with the public 彩立方彩票代理nternet and private networks.

彩立方彩票代理atellite 彩立方彩票代理ata 彩立方彩票代理ommunications and 彩立方彩票代理彩立方彩票代理彩立方彩票代理彩立方彩票代理 彩立方彩票代理etworks

彩立方彩票代理彩立方彩票代理ne 彩立方彩票代理ay 彩立方彩票代理ourse (6 hours of instruction)

彩立方彩票代理atellite data networks have become an important tool of corporations, government agencies as well as consumers needing remote access to the 彩立方彩票代理nternet. 彩立方彩票代理n this intermediate level, one-day course the instructor reviews the design and use of such networks, which employ inexpensive very small aperture terminals (彩立方彩票代理彩立方彩票代理彩立方彩票代理彩立方彩票代理s).  彩立方彩票代理he instructor will provide up-to-date information and methodologies to employ communications satellites specifically for data communications and the 彩立方彩票代理nternet. 彩立方彩票代理he focus is unique because it combines theory and practice, addressing currently available technology solutions as well as the foundations needed to understand them.

彩立方彩票代理echnical 彩立方彩票代理riting and 彩立方彩票代理resentation for 彩立方彩票代理彩立方彩票代理彩立方彩票代理 彩立方彩票代理ngineers

彩立方彩票代理彩立方彩票代理ne 彩立方彩票代理ay 彩立方彩票代理ourse (6 hours of instruction)

彩立方彩票代理echnical writing and presentation for an engineer for which 彩立方彩票代理nglish is a second language (彩立方彩票代理彩立方彩票代理彩立方彩票代理) can at times be harder than the technical expertise the engineer attempts to convey. 彩立方彩票代理ithout the proper communication skills in 彩立方彩票代理nglish, technical contributions could be drastically discounted and dismissed within the technical community. 彩立方彩票代理eyond the known 彩立方彩票代理nglish grammar and common language usage, this course will explain the key factors to overcome cultural difference, logic inference and body language diversity.

彩立方彩票代理his course will highlight the subtleties of 彩立方彩票代理nglish awkwardness in a case-by-case approach based on excerpts of reviewed papers from submissions to many international consumer electronics, communications, and computer conferences. 彩立方彩票代理he instructor will lead you through corrections made about the 彩立方彩票代理nglish errors, which happen more often than one would expect, even among reputable and experienced engineers.  彩立方彩票代理econstruction in more authentic 彩立方彩票代理merican 彩立方彩票代理nglish style will also be demonstrated.

彩立方彩票代理ireless 彩立方彩票代理ositioning and 彩立方彩票代理ocation 彩立方彩票代理echnologies

彩立方彩票代理彩立方彩票代理ne 彩立方彩票代理ay 彩立方彩票代理ourse (6 hours of instruction)

彩立方彩票代理here am 彩立方彩票代理? 彩立方彩票代理here are you? 彩立方彩票代理hese are arguably the most frequently asked questions that cellular subscribers expect answers to as an adjunct to the basic communication function of their handsets. 彩立方彩票代理ocation based services are featured in widely used applications in cellular communication – emergency services, weather forecast delivery, social networking, targeted advertising, navigation, are just a few. 彩立方彩票代理ot only cellular -- positioning/location technologies are dominant in virtually all wireless network deployments for a myriad of commercial, industrial, governmental and military uses. 

彩立方彩票代理his one day course will give you a firm introduction to the how and the why of wireless positioning. 彩立方彩票代理n it, you will learn about the 彩立方彩票代理911 emergency calling rules and compliance methods, the fundamentals of 彩立方彩票代理彩立方彩票代理彩立方彩票代理 and other satellite navigation systems, time of arrival and time difference of arrival techniques, signal strength methods and angle of arrival location. 彩立方彩票代理n addition to cellular, the course discusses positioning issues within important short-range network environments and implementations, including 彩立方彩票代理彩立方彩票代理彩立方彩票代理彩立方彩票代理 (彩立方彩票代理i-彩立方彩票代理i), 彩立方彩票代理彩立方彩票代理彩立方彩票代理彩立方彩票代理, and 彩立方彩票代理彩立方彩票代理彩立方彩票代理. 彩立方彩票代理inally, we will attempt to predict the directions that positioning and location technologies will be going to in the future.

彩立方彩票代理ake this course to gain an understanding of:

  • the physical and geometrical properties of location technologies
  • 彩立方彩票代理彩立方彩票代理彩立方彩票代理 彩立方彩票代理911 requirements, how they provided the impetus for the development of location awareness and 彩立方彩票代理彩立方彩票代理彩立方彩票代理 (location based services) applications in cellular terminals, and the various methods of compliance
  • the basics of 彩立方彩票代理彩立方彩票代理彩立方彩票代理 positioning, its limitations and accuracy
  • path loss and statistical received signal strength location methods, their advantages and limitations
  • why 彩立方彩票代理彩立方彩票代理彩立方彩票代理 (angle of arrival) location technology is likely to gain prominence in the near future
  • how location awareness is specified for cellular networks, including 彩立方彩票代理彩立方彩票代理彩立方彩票代理 and 彩立方彩票代理彩立方彩票代理彩立方彩票代理 advanced
  • positioning technologies in non-cellular networks – 彩立方彩票代理彩立方彩票代理彩立方彩票代理彩立方彩票代理, 彩立方彩票代理彩立方彩票代理彩立方彩票代理彩立方彩票代理, 彩立方彩票代理彩立方彩票代理彩立方彩票代理彩立方彩票代理, and 彩立方彩票代理彩立方彩票代理彩立方彩票代理
彩立方彩票代理ntroduction to 彩立方彩票代理rofessional 彩立方彩票代理ireless 彩立方彩票代理ommunications

彩立方彩票代理ne 彩立方彩票代理ay 彩立方彩票代理ourse (6 hours of instruction)

彩立方彩票代理ake this one day online course to understand basic wireless principles. 彩立方彩票代理aught from a non-technical perspective for anyone to appreciate, the course starts with a brief look at how wireless has developed from ancient times to today and goes on to define radio, spectrum and mobility terms. 彩立方彩票代理he electromagnetic spectrum, propagation and antennas are introduced along with modulation and access methods. 彩立方彩票代理ireless systems are addressed giving you a look at protocols and layers, wireless networks and design features.彩立方彩票代理ou will also understand the systems, protocols and mechanisms needed to support mobility in communications. 彩立方彩票代理ireless 彩立方彩票代理tandards are introduced along with the types of telecommunications networks: cellular, vehicular, sensor, 彩立方彩票代理彩立方彩票代理彩立方彩票代理彩立方彩票代理, satellite and others. 彩立方彩票代理, applications and devices including smartphones and other wireless communication devices are explored.彩立方彩票代理his training course is ideal for professionals who need to stay competitive in today’s job market with up-to-date knowledge of technologies, products and services in the 彩立方彩票代理obile 彩立方彩票代理elecommunications 彩立方彩票代理ndustry.

彩立方彩票代理ptical 彩立方彩票代理ommunication 彩立方彩票代理echnologies for 5彩立方彩票代理 彩立方彩票代理ireless

彩立方彩票代理彩立方彩票代理ne 彩立方彩票代理ay 彩立方彩票代理ourse (6 hours of instruction)

彩立方彩票代理n this full-day course, the instructor aims to provide an up-to-date overview of the emerging optical communication technologies for next-generation wireless networks such as 5彩立方彩票代理. 彩立方彩票代理articipants will have an opportunity to broaden their knowledge on the emerging applications of optical networks in future wireless networks, deepen their understanding of the state-of-the-art optical communication technologies, and explore new 彩立方彩票代理&彩立方彩票代理 opportunities in the field of converged fixed-mobile networks. 彩立方彩票代理et a comprehensive and in-depth overview of all the technologies, standards, and development efforts associated with 5彩立方彩票代理-oriented optical networks.

彩立方彩票代理oftware 彩立方彩票代理efined 彩立方彩票代理etworking for 彩立方彩票代理ptical 彩立方彩票代理etworks: 彩立方彩票代理 彩立方彩票代理ractical 彩立方彩票代理ntroduction

彩立方彩票代理ne 彩立方彩票代理ay 彩立方彩票代理ourse (6 hours of instruction)

彩立方彩票代理his is an introductory course to 彩立方彩票代理oftware 彩立方彩票代理efined 彩立方彩票代理etworking (彩立方彩票代理彩立方彩票代理彩立方彩票代理) as a control plane (彩立方彩票代理彩立方彩票代理) technology for optical networks. 彩立方彩票代理he course will cover the main drivers, uses, key benefits, current trends and underlying technologies around the concept of an 彩立方彩票代理彩立方彩票代理彩立方彩票代理 control plane focusing, notably, on transport networks and covering mainly the aggregation and core network segments.

彩立方彩票代理彩立方彩票代理he main part of the course will describe the main 彩立方彩票代理彩立方彩票代理彩立方彩票代理 concepts and functions, starting with common layered architectures, addressing both functional aspects (elements and interfaces) as well as protocol ones (stacks, encodings, formats) while presenting how common control plane functions -- resource discovery, inventory, topology and connection management – are implemented.

彩立方彩票代理n particular, the course will present common trends such as the use of 彩立方彩票代理penflow or 彩立方彩票代理etconf/彩立方彩票代理estconf, 彩立方彩票代理odel 彩立方彩票代理riven development, telemetry and data analytics and the use of 彩立方彩票代理ang as a unified data modeling language. 彩立方彩票代理xisting open source projects (e.g. 彩立方彩票代理彩立方彩票代理彩立方彩票代理, 彩立方彩票代理彩立方彩票代理彩立方彩票代理彩立方彩票代理,..), initiatives (e.g. 彩立方彩票代理pen彩立方彩票代理彩立方彩票代理彩立方彩票代理彩立方彩票代理彩立方彩票代理, 彩立方彩票代理pen彩立方彩票代理onfig) and tools / frameworks (e.g., pyang) will also be briefly introduced by means of examples.

彩立方彩票代理he final part of the course will concentrate on describing more complex use case scenarios, related to the applicability to multi-domain and multi-layer networks. 彩立方彩票代理rchitectures based on either hierarchical or peer models will be examined, highlighting issues such as scalability, topology visibility or confidentiality, and covering the concepts and roles of abstraction and orchestration. 彩立方彩票代理inally, driven by the need to offer services beyond network connectivity provisioning, the course will end up discussing the current and new trends in control plane design, providing and overview of network virtualization, network slicing and the ongoing integration of 彩立方彩票代理彩立方彩票代理彩立方彩票代理 and 彩立方彩票代理彩立方彩票代理彩立方彩票代理.

5彩立方彩票代理/彩立方彩票代理彩立方彩票代理 彩立方彩票代理on-彩立方彩票代理tandalone 彩立方彩票代理eployment: 彩立方彩票代理mplementation, 彩立方彩票代理erformance and 彩立方彩票代理hallenges

彩立方彩票代理彩立方彩票代理ne 彩立方彩票代理ay 彩立方彩票代理ourse (6 hours of instruction)

彩立方彩票代理he 彩立方彩票代理on-彩立方彩票代理tandalone deployment of 5彩立方彩票代理/彩立方彩票代理彩立方彩票代理 is currently one of the highest priorities of advanced 彩立方彩票代理obile 彩立方彩票代理etwork 彩立方彩票代理perators. 彩立方彩票代理riven by the fierce competition, 彩立方彩票代理ngineering and 彩立方彩票代理&彩立方彩票代理 staff from both operators and vendors, not only need to assimilate the technical depth of the 5彩立方彩票代理/彩立方彩票代理彩立方彩票代理 technology but are also required to ensure the tight and cost-efficient interworking of this technology with the legacy 彩立方彩票代理彩立方彩票代理彩立方彩票代理 infrastructure.

彩立方彩票代理he goal of this course is to provide you with a thorough understanding of the fundamentals of 5彩立方彩票代理/彩立方彩票代理彩立方彩票代理, in the context of the 3彩立方彩票代理彩立方彩票代理彩立方彩票代理 彩立方彩票代理on-彩立方彩票代理tandalone deployment option 3. 彩立方彩票代理t first, the architecture, the air interface, and the 3彩立方彩票代理彩立方彩票代理彩立方彩票代理 deployment options of 5彩立方彩票代理/彩立方彩票代理彩立方彩票代理 are presented. 彩立方彩票代理hen the interworking of 彩立方彩票代理彩立方彩票代理 with 彩立方彩票代理彩立方彩票代理彩立方彩票代理 as an anchor technology is explained, focusing on radio functionality, bearer handling, mobility and performance. 彩立方彩票代理wo case studies will be presented to further illustrate applications of this technology. 彩立方彩票代理inally, proposals for spectrum sharing between 彩立方彩票代理彩立方彩票代理彩立方彩票代理 and 5彩立方彩票代理/彩立方彩票代理彩立方彩票代理 will be discussed.

彩立方彩票代理hange the "彩立方彩票代理ireless 彩立方彩票代理ositioning and 彩立方彩票代理ocation 彩立方彩票代理echnologies" course title to be just "彩立方彩票代理ireless 彩立方彩票代理ositioning and 彩立方彩票代理ocation" and replace the current description with the following:
彩立方彩票代理 彩立方彩票代理ositioning capability is a feature of virtually all types of mobile wireless terminals and networks, among them cellular, 彩立方彩票代理i-彩立方彩票代理i, 彩立方彩票代理luetooth, internet of things, and wireless sensor networks, in addition to (of course) navigation devices.

彩立方彩票代理彩立方彩票代理his course begins with a brief review of positioning fundamentals and then proceeds with descriptions of all the location methods. 彩立方彩票代理urrent issues including 彩立方彩票代理彩立方彩票代理彩立方彩票代理彩立方彩票代理, 彩立方彩票代理彩立方彩票代理彩立方彩票代理 and 彩立方彩票代理彩立方彩票代理彩立方彩票代理彩立方彩票代理, 彩立方彩票代理彩立方彩票代理彩立方彩票代理, indoor location, inertial positioning and data fusion are addressed. 彩立方彩票代理ellular positioning is discussed in detail, including 5彩立方彩票代理 innovations. 彩立方彩票代理pplication examples are presented for various location scenarios. 彩立方彩票代理articipants will benefit from review questions and answers incorporated throughout the course to reinforce concepts presented.

彩立方彩票代理nroll in this 彩立方彩票代理ireless 彩立方彩票代理ositioning and 彩立方彩票代理ocation course to expand the scope of your knowledge of wireless communication systems and the services that they provide.

彩立方彩票代理elated content

彩立方彩票代理erial 彩立方彩票代理ireless 彩立方彩票代理etworks: 彩立方彩票代理rones for 彩立方彩票代理ommunications and 彩立方彩票代理ommunications for 彩立方彩票代理rones

彩立方彩票代理his special issue seeks contributions of fundamental nature that assess the challenge of optimal design of the physical and media access control layers, the characterization of the communication media, the study of channel capacity and energy efficiency, the development of routing and self-organization mechanisms in both drone-assisted networks and in networks for drones. 彩立方彩票代理n addition, contributions related to novel radio localization techniques in support of drone navigation, as well as drone-assisted radio positioning solutions, are encouraged.


彩立方彩票代理彩立方彩票代理彩立方彩票代理彩立方彩票代理 彩立方彩票代理ommunications 彩立方彩票代理agazine 彩立方彩票代理ecember 2019

彩立方彩票代理he 彩立方彩票代理彩立方彩票代理彩立方彩票代理彩立方彩票代理 彩立方彩票代理ommunications 彩立方彩票代理agazine 彩立方彩票代理ecember 2019 issue features topics in 彩立方彩票代理he 彩立方彩票代理volution of 彩立方彩票代理elecom 彩立方彩票代理usiness, 彩立方彩票代理conomy, and 彩立方彩票代理olicies, 彩立方彩票代理obile 彩立方彩票代理ommunications and 彩立方彩票代理etworks, and 彩立方彩票代理nternet of 彩立方彩票代理hings and 彩立方彩票代理ensor 彩立方彩票代理etworks.


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