Conferences related to Wireless Infrastructure

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ICC 2021 - IEEE International Conference on Communications

IEEE ICC is one of the two flagship IEEE conferences in the field of communications; Montreal is to host this conference in 2021. Each annual IEEE ICC conference typically attracts approximately 1,500-2,000 attendees, and will present over 1,000 research works over its duration. As well as being an opportunity to share pioneering research ideas and developments, the conference is also an excellent networking and publicity event, giving the opportunity for businesses and clients to link together, and presenting the scope for companies to publicize themselves and their products among the leaders of communications industries from all over the world.


2020 IEEE International Conference on Robotics and Automation (ICRA)

The International Conference on Robotics and Automation (ICRA) is the IEEE Robotics and Automation Society’s biggest conference and one of the leading international forums for robotics researchers to present their work.


2020 IEEE International Conference on Systems, Man, and Cybernetics (SMC)

The 2020 IEEE International Conference on Systems, Man, and Cybernetics (SMC 2020) will be held in Metro Toronto Convention Centre (MTCC), Toronto, Ontario, Canada. SMC 2020 is the flagship conference of the IEEE Systems, Man, and Cybernetics Society. It provides an international forum for researchers and practitioners to report most recent innovations and developments, summarize state-of-the-art, and exchange ideas and advances in all aspects of systems science and engineering, human machine systems, and cybernetics. Advances in these fields have increasing importance in the creation of intelligent environments involving technologies interacting with humans to provide an enriching experience and thereby improve quality of life. Papers related to the conference theme are solicited, including theories, methodologies, and emerging applications. Contributions to theory and practice, including but not limited to the following technical areas, are invited.


GLOBECOM 2020 - 2020 IEEE Global Communications Conference

IEEE Global Communications Conference (GLOBECOM) is one of the IEEE Communications Society’s two flagship conferences dedicated to driving innovation in nearly every aspect of communications. Each year, more than 2,900 scientific researchers and their management submit proposals for program sessions to be held at the annual conference. After extensive peer review, the best of the proposals are selected for the conference program, which includes technical papers, tutorials, workshops and industry sessions designed specifically to advance technologies, systems and infrastructure that are continuing to reshape the world and provide all users with access to an unprecedented spectrum of high-speed, seamless and cost-effective global telecommunications services.


IEEE INFOCOM 2020 - IEEE Conference on Computer Communications

IEEE INFOCOM solicits research papers describing significant and innovative researchcontributions to the field of computer and data communication networks. We invite submissionson a wide range of research topics, spanning both theoretical and systems research.


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Periodicals related to Wireless Infrastructure

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Automation Science and Engineering, IEEE Transactions on

The IEEE Transactions on Automation Sciences and Engineering (T-ASE) publishes fundamental papers on Automation, emphasizing scientific results that advance efficiency, quality, productivity, and reliability. T-ASE encourages interdisciplinary approaches from computer science, control systems, electrical engineering, mathematics, mechanical engineering, operations research, and other fields. We welcome results relevant to industries such as agriculture, biotechnology, healthcare, home automation, maintenance, manufacturing, pharmaceuticals, retail, ...


Broadcasting, IEEE Transactions on

Broadcast technology, including devices, equipment, techniques, and systems related to broadcast technology, including the production, distribution, transmission, and propagation aspects.


Communications Magazine, IEEE

IEEE Communications Magazine was the number three most-cited journal in telecommunications and the number eighteen cited journal in electrical and electronics engineering in 2004, according to the annual Journal Citation Report (2004 edition) published by the Institute for Scientific Information. Read more at http://www.ieee.org/products/citations.html. This magazine covers all areas of communications such as lightwave telecommunications, high-speed data communications, personal communications ...


Communications Surveys & Tutorials, IEEE

Each tutorial reviews currents communications topics in network management and computer and wireless communications. Available tutorials, which are 2.5 to 5 hours in length contains the original visuals and voice-over by the presenter. IEEE Communications Surveys & Tutorials features two distinct types of articles: original articles and reprints. The original articles are exclusively written for IEEE Communications Surveys & Tutorials ...


Communications, IEEE Transactions on

Telephone, telegraphy, facsimile, and point-to-point television, by electromagnetic propagation, including radio; wire; aerial, underground, coaxial, and submarine cables; waveguides, communication satellites, and lasers; in marine, aeronautical, space and fixed station services; repeaters, radio relaying, signal storage, and regeneration; telecommunication error detection and correction; multiplexing and carrier techniques; communication switching systems; data communications; and communication theory. In addition to the above, ...


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Most published Xplore authors for Wireless Infrastructure

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Xplore Articles related to Wireless Infrastructure

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A 64 channel programmable receiver chip for 3G wireless infrastructure

Proceedings of the IEEE 2005 Custom Integrated Circuits Conference, 2005., 2005

We present a CDMA wireless infrastructure chip that handles digital baseband receive functions for up to 64 voice channels, representing over 150 GOPS of computation, and dissipating 32mW/channel. Vector datapaths and two embedded ARM cores are employed for flexibility and high channel density. The chip is fabricated in a 130 nm 7 layer metal process and contains 75M transistors.


Cross layer awareness optimization between physical layer and MAC layer of wireless infrastructure based network using bio inspired algorithm

2013 Fourth International Conference on Computing, Communications and Networking Technologies (ICCCNT), 2013

Cross Layer Awareness Optimization removes such boundaries allowing flow of information or communication between layers by allowing access among the layer for information exchange. The strict boundaries create dependency problem for the concerned layer as well as other layers. The prime question arises whether this attitude can be applied to wireless infrastructure based network to map different layer (PHY and ...


On Quality of Monitoring for Multichannel Wireless Infrastructure Networks

IEEE Transactions on Mobile Computing, 2014

Passive monitoring utilizing distributed wireless sniffers is an effective technique to monitor activities in wireless infrastructure networks for fault diagnosis, resource management, and critical path analysis. In this paper, we introduce a quality of monitoring (QoM) metric defined by the expected number of active users monitored, and investigate the problem of maximizing QoM by judiciously assigning sniffers to channels based ...


Wireless infrastructure enhances on body health monitoring systems

2016 IEEE MIT Undergraduate Research Technology Conference (URTC), 2016

Due to recent advancements in wireless communication and on body sensing technologies, real time on body health monitoring systems are now becoming more feasible. This paper presents an overview of such newly evolving real time on body health monitoring technologies. A broad overview is provided on the modern wireless mobile communication infrastructure that is relevant to these real time wireless ...


F1: Advanced transmitters for wireless infrastructure

2011 IEEE International Solid-State Circuits Conference, 2011

This forum will cover present and future transmitters in wireless infrastructure applications, like base stations for cellular mobile communication. Future digitized transmitter architectures will most likely be based upon the use of advanced RF DACs or ultra high speed DACs in combination with up conversion techniques. These digital transmitter architectures need flexible (re-configurable) power amplifiers which make use of advanced ...


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Educational Resources on Wireless Infrastructure

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IEEE.tv Videos

Affordable Wireless Networks - GHTC 2012 Session - Marco Zennaro
Wireless networks for humanitarian use - GHTC 2012 Sessions - Emmanuel Togo
The Path to Field Trials: Testing the Networks of the Future - Panel from NIWeek 5G Summit
Fog Software and Software Infrastructure Panel - Fog World Congress 2017
NSF's Platforms for Advanced Wireless Research (PAWR) - IEEE Future Networks Webinar
Commercial 5G Technology as a Building Block for Tactical Wireless Communications - Leland Brown and Issy Kipnis - 5G Technologies for Tactical and First Responder Networks 2018
Industry Panel on V2X and 5GAA - Brooklyn 5G Summit 2018
5G Non-Public Networks: Edge, Networks & Slicing - Hans Schotten - B5GS 2019
Aerial Experimentation & Research Platform for Advanced Wireless - Rudra Dutta - IEEE Sarnoff Symposium, 2019
Nebbiolo Technologies Pitch: Fog Tank - Fog World Congress
NXP
From ‘Green & Soft’ to ‘Open & Smart’ - Chih-Lin I - 5G World Forum Santa Clara 2018
5G and the Next Industrial Revolution - The transformative power of low-latency services - Ken Budka: Brooklyn 5G Summit 2017
Is It Time for 6G Yet? - Thyaga Nandagopal - 5G World Forum Dresden, 2019
Lew Tucker, IEEE GLOBECOM'13 Keynote Address - Lew Tucker, CTO, Cisco Systems
Modeling Device-to-Device Communications for Wireless Public Safety Networks - David Griffith - 5G Technologies for Tactical and First Responder Networks 2018
The Next G: What does 5G mean for Critical Communications and Electromagnetic Spectrum Dominance? - Manuel Uhm - 5G Technologies for Tactical and First Responder Networks 2018
Edge To Core To Cloud IoT infrastructure For Distributed Analytics - Yogev Shimony and Phil Hummel, Fog World Congress 2017
IEEE Wireless Communication Engineering Technologies (WCET) Certification Program
Verizon 5G: Building the Platform of Innovation - Bill Stone - Brooklyn 5G Summit 2018

IEEE-USA E-Books

  • A 64 channel programmable receiver chip for 3G wireless infrastructure

    We present a CDMA wireless infrastructure chip that handles digital baseband receive functions for up to 64 voice channels, representing over 150 GOPS of computation, and dissipating 32mW/channel. Vector datapaths and two embedded ARM cores are employed for flexibility and high channel density. The chip is fabricated in a 130 nm 7 layer metal process and contains 75M transistors.

  • Cross layer awareness optimization between physical layer and MAC layer of wireless infrastructure based network using bio inspired algorithm

    Cross Layer Awareness Optimization removes such boundaries allowing flow of information or communication between layers by allowing access among the layer for information exchange. The strict boundaries create dependency problem for the concerned layer as well as other layers. The prime question arises whether this attitude can be applied to wireless infrastructure based network to map different layer (PHY and MAC layer) of protocol stack in cross layer framework. Now the optimization algorithm becomes the prime feature for optimizing among the Physical (PHY) and MAC layer. In this work, cross layer awareness is optimized at physical (PHY) layer for wireless infrastructure based network of smart antennas or adaptive antennas consisting of uniform linear array (ULA) using Genetic Algorithm for optimizing or minimizing the cost function.

  • On Quality of Monitoring for Multichannel Wireless Infrastructure Networks

    Passive monitoring utilizing distributed wireless sniffers is an effective technique to monitor activities in wireless infrastructure networks for fault diagnosis, resource management, and critical path analysis. In this paper, we introduce a quality of monitoring (QoM) metric defined by the expected number of active users monitored, and investigate the problem of maximizing QoM by judiciously assigning sniffers to channels based on the knowledge of user activities in a multichannel wireless network. Two types of capture models are considered. The user-centric model assumes the frame-level capturing capability of sniffers such that the activities of different users can be distinguished while the sniffer-centric model only utilizes the binary channel information (active or not) at a sniffer. For the user-centric model, we show that the implied optimization problem is NP-hard, but a constant approximation ratio can be attained via polynomial complexity algorithms. For the sniffer- centric model, we devise stochastic inference schemes to transform the problem into the user-centric domain, where we are able to apply our polynomial approximation algorithms. The effectiveness of our proposed schemes and algorithms is further evaluated using both synthetic data as well as real- world traces from an operational WLAN.

  • Wireless infrastructure enhances on body health monitoring systems

    Due to recent advancements in wireless communication and on body sensing technologies, real time on body health monitoring systems are now becoming more feasible. This paper presents an overview of such newly evolving real time on body health monitoring technologies. A broad overview is provided on the modern wireless mobile communication infrastructure that is relevant to these real time wireless technologies. Conversely, examples of specific newly published work on wearable health monitoring sensing technologies are briefly described such as a non-invasive blood glucose monitoring system for diabetes, a dietary monitoring system for weight control, and a Wireless Electrocardiograph (WECG) monitoring system for heart disease management. In addition, this paper also shows that today's modern wireless infrastructure as provided by the current advanced mobile device and cellular industries such as iPhone, tablets, AT&T, and Verizon are really the cornerstone support for such real time health monitoring systems. These mobile phones or PDA like devices provide a very affordable and convenient solution to enhance the aforementioned wireless sensing for real time on body health monitoring. In conclusion, the upcoming mobile 5G performance standards with significantly higher data rate, spectral and power efficiencies can easily make this revolutionary real time on body health monitoring technology within reach of becoming a reality. This is a remarkable example of how wireless RF sensor and antenna technologies in concert with medical industry can provide effective and yet affordable solutions to the challenging chronic medical problems.

  • F1: Advanced transmitters for wireless infrastructure

    This forum will cover present and future transmitters in wireless infrastructure applications, like base stations for cellular mobile communication. Future digitized transmitter architectures will most likely be based upon the use of advanced RF DACs or ultra high speed DACs in combination with up conversion techniques. These digital transmitter architectures need flexible (re-configurable) power amplifiers which make use of advanced techniques like multi-way Doherty or envelope tracking. Enhanced linearization techniques need to be applied in the transmitter to cope with the stringent linearity demands, while advanced calibration techniques and other design techniques will be needed to overcome circuit block impairments.

  • Engineering an HL7 interface and wireless infrastructure to improve the efficiency of ECG analysis at Hartford Hospital

    This paper describes the integration of Hartford Hospital's current 12-lead electrocardiogram (ECG) software with the hospital's information systems (admit, discharge, transfer (ADT); orders; and billing) by engineering a Health Level Seven Standard Interface (HL7) specifically for the hospital's unique software amalgamation. Data formats for the wireless transmission of information were investigated. Distinctive requirements, work-flow, and validation procedures for interfacing the 12-lead ECG system using the HL7 standard were configured. Lastly, the implementation of a wireless transmission component was also developed so completed ECGs could be instantaneously sent to the ECG software directly from the ECG machine, where the analysis was performed. Spectrum analysis was utilized to scrutinize the hospital's current unique wireless infrastructure.

  • A GaN HFET Device Technology on 3" SiC Substrates for Wireless Infrastructure Applications

    This report presents a GaN HFET technology for wireless infrastructure applications. Using an optimized process, low DC-RF dispersion is seen via pulsed I-V measurements. At a drain bias of 48 V and frequency of 2.14 GHz, devices with 0.3 mm gate periphery produce 10-11 W/mm with associated PAE's in the range of 62-67%. Devices with 12.6 mm gate widths produce a saturated output power of 74 W (5.9 W/mm) with an associated power-added efficiency (PAE) of 55%. Under single-carrier W-CDMA conditions, an output power of approximately 10 W and 27% associated power-added efficiency (PAE) is realized at an ACPR of -40 dBc

  • Benefits of inter-flow bandwidth sharing in broadband wireless infrastructure networks

    Broadband wireless infrastructure networks are increasingly becoming common in metro areas. To improve spatial bandwidth usage, the nodes in such networks employ directional transmissions over multiple orthogonal channels. In this paper, we study the benefits of sharing channel bandwidth across multiple flows. Every connection is assumed to require a bandwidth that is half of the channel bandwidth. We model the routing and channel assignment problem in two different ways to account for the presence and absence of inter-flow bandwidth sharing. Through simulations, we demonstrate that supporting inter-flow bandwidth sharing through simple time-sharing mechanism results in improved network throughput.

  • The digital power amplifier for the wireless infrastructure: Status and prospects

    In digital power amplifiers the analog signal is not handled directly but encoded in a pulse train. It is restored only at the output by a bandpass filter. Due to the discretization in amplitude, this principle, often referred to as class S, allows for efficient and versatile amplifiers. While in widespread use for audio frequencies, digital PAs have been introduced at microwave frequencies only a few years ago. The paper reviews the state of the art of such PAs for applications in the wireless infrastructure. The key factors determining transmitter performance are addressed and recent results are presented.

  • An application of robust template matching to user location on wireless infrastructure

    Instead of using a conventional template matching with the sum of squared distance (SSD) for signal strength matching to provide user location on wireless infrastructure, we propose the use of robust template matching methods for providing robust user location. Our method expects and handles the noisy data common within a wireless setting, and provides the user with relevant information as to the reliability of their location within the system. In our experiments, we compare our method with the conventional SSD based and sum of absolute difference (SAD) based template matching and a state of the art method, support vector machines. Our experimental results show that some of robust template matching methods can outperform compared methods very much.



Standards related to Wireless Infrastructure

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No standards are currently tagged "Wireless Infrastructure"


Jobs related to Wireless Infrastructure

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