Wireless In Vivo Communications and Networking

Similar documents
MIMO-LTE A relevant Step towards 4G. Prof. Dr.-Ing. Thomas Kaiser CEO mimoon GmbH

ULP Wireless Technology for Biosensors and Energy Harvesting

Long Term Evolution (LTE) and 5th Generation Mobile Networks (5G) CS-539 Mobile Networks and Computing

Long Term Evolution (LTE) Radio Network Planning Using Atoll

Technical challenges for high-frequency wireless communication

5G - The multi antenna advantage. Bo Göransson, PhD Expert, Multi antenna systems Systems & Technology

5G ANTENNA TEST AND MEASUREMENT SYSTEMS OVERVIEW

(some) Device Localization, Mobility Management and 5G RAN Perspectives

University of Bristol - Explore Bristol Research. Peer reviewed version. Link to published version (if available): /ICCE.2012.

Device Pairing at the Touch of an Electrode

OBJECTIVES. Understand the basic of Wi-MAX standards Know the features, applications and advantages of WiMAX

Wireless TDMA Mesh Networks

High-end vector signal generator creates complex multichannel scenarios

Mobile Broadband Multimedia Networks

Antennas and Propagation for Body-Centric Wireless Communications

Resource Allocation in a Cognitive Digital Home

Handset MIMO antenna measurement using a Spatial Fading Emulator

2015 The MathWorks, Inc. 1

G.T. Hill.

A Miniaturized Ultrasonic Power Delivery System Tzu-Chieh Chou, Ramkumar Subramanian, Jiwoong Park, and Patrick P. Mercier

COGNITIVE RADIO TECHNOLOGY: ARCHITECTURE, SENSING AND APPLICATIONS-A SURVEY

Wireless InSite. Simulation of MIMO Antennas for 5G Telecommunications. Copyright Remcom Inc. All rights reserved.

Lecture 9: Case Study -- Video streaming over Hung-Yu Wei National Taiwan University

COGNITIVE ANTENNA RADIO SYSTEMS FOR MOBILE SATELLITE AND MULTIMODAL COMMUNICATIONS ESA/ESTEC, NOORDWIJK, THE NETHERLANDS 3-5 OCTOBER 2012

What s Behind 5G Wireless Communications?

SMart wearable Robotic Teleoperated surgery

Motivation. Approach. Requirements. Optimal Transmission Frequency for Ultra-Low Power Short-Range Medical Telemetry

HOW DO MIMO RADIOS WORK? Adaptability of Modern and LTE Technology. By Fanny Mlinarsky 1/12/2014

Enhancing Future Networks with Radio Environmental Information

NI Technical Symposium ni.com

DURIP Distributed SDR testbed for Collaborative Research. Wednesday, November 19, 14

Multiband NFC for High-Throughput Wireless Computer Vision Sensor Network

Planning of LTE Radio Networks in WinProp

Prototyping Next-Generation Communication Systems with Software-Defined Radio

Battery lifetime modelling for a 2.45GHz cochlear implant application

Antennas Multiple antenna systems

NIST Activities in Wireless Coexistence

Channel Modelling ETI 085. Antennas Multiple antenna systems. Antennas in real channels. Lecture no: Important antenna parameters

Cognitive Cellular Systems in China Challenges, Solutions and Testbed

Wireless technologies Test systems

This is a preview - click here to buy the full publication

Introduction to Medical Electronics Industry Test Analysis and Solution

Implementation and Complexity Analysis of List Sphere Detector for MIMO-OFDM systems

The Case for Optimum Detection Algorithms in MIMO Wireless Systems. Helmut Bölcskei

Self-Organisation in LTE networks: Soft integration of new base stations

LTE Aida Botonjić. Aida Botonjić Tieto 1

RF Communication for Active Implant Medical Devices. Communication with Active Implantable Medical Devices AIMD

A Novel Reconfigurable Spiral-Shaped Monopole Antenna for Biomedical Applications

Real-Time Through-Wall Imaging Using an Ultrawideband Multiple-Input Multiple-Output (MIMO) Phased-Array Radar System

PoC #1 On-chip frequency generation

Optimizing future wireless communication systems

For Immediate Release. For More PR Information, Contact: Carlo Chatman, Power PR P (310) F (310)

5G: implementation challenges and solutions

Amplitude and Phase Distortions in MIMO and Diversity Systems

Guide to Wireless Communications, Third Edition Cengage Learning Objectives

mm Wave Communications J Klutto Milleth CEWiT

A Worldwide Broadband Mobile Internet Standard

Towards Reliable Underwater Acoustic Video Transmission for Human-Robot Dynamic Interaction

Multi-Aperture Phased Arrays Versus Multi-beam Lens Arrays for Millimeter-Wave Multiuser MIMO

M A R C H 2 6, Sheri DeTomasi 5G New Radio Solutions Lead Keysight Technologies. 5G New Radio Challenges and Redefining Test

Impact of an Aortic Valve Implant on Body Surface UWB Propagation: A Preliminary Study

COSMOS Millimeter Wave June Contact: Shivendra Panwar, Sundeep Rangan, NYU Harish Krishnaswamy, Columbia

Contents. Introduction Why 5G? What are the 4G limitations? Key consortium and Research centers for the 5G

Technical Aspects of LTE Part I: OFDM

User Conference Title

AN ADAPTIVE MOBILE ANTENNA SYSTEM FOR WIRELESS APPLICATIONS

Summer of LabVIEW. The Sunny Side of System Design. 30th June - 18th July. spain.ni.com/foro-aeroespacio-defensa

Simulation Analysis of the Long Term Evolution

Haptic Feedback in Laparoscopic and Robotic Surgery

Maximizing MIMO Effectiveness by Multiplying WLAN Radios x3

Towards 100 Gbps: Ultra-high Spectral Efficiency using massive MIMO with 3D Antenna Configurations

A Business Case for Employing Direct RF Transmission over Optical Fiber In Place of CPRI for 4G and 5G Fronthaul

3GPP: Evolution of Air Interface and IP Network for IMT-Advanced. Francois COURAU TSG RAN Chairman Alcatel-Lucent

MIMO in 3G STATUS. MIMO for high speed data in 3G systems. Outline. Information theory for wireless channels

Massive MIMO and mmwave

Multiple Antenna Processing for WiMAX

University of Jordan. Faculty of Engineering & Technology. Study Plan. Master Degree. Year plan

System Performance of Cooperative Massive MIMO Downlink 5G Cellular Systems

Application Note. StarMIMO. RX Diversity and MIMO OTA Test Range

Integrated Solutions for Testing Wireless Communication Systems

Outline / Wireless Networks and Applications Lecture 2: Networking Overview and Wireless Challenges. Protocol and Service Levels

OFDMA and MIMO Notes

Performance Analysis of Optimal Scheduling Based Firefly algorithm in MIMO system

arxiv: v2 [eess.sp] 20 Jul 2018

S T U DENT P ROFILES M.T ECH I N R A D I O F R EQUENCY D ES I G N AND T ECHNOLOGY

Extraction of Antenna Gain from Path Loss Model. for In-Body Communication

TRI-BAND COMPACT ANTENNA ARRAY FOR MIMO USER MOBILE TERMINALS AT GSM 1800 AND WLAN BANDS

Introduction to Computational Intelligence in Healthcare

Overview. Measurement of Ultra-Wideband Wireless Channels

Does anybody really know what 5G is? Does anybody really care?

Multiple Input Multiple Output (MIMO) Operation Principles

VA L U E A N A LY S I S B R I E F

Hardware-Software Co-Design Cosynthesis and Partitioning

Addressing the Design-to-Test Challenges for SDR and Cognitive Radio

Project: IEEE P Working Group for Wireless Personal Area Networks N (WPANs)

MIMO in 4G Wireless. Presenter: Iqbal Singh Josan, P.E., PMP Director & Consulting Engineer USPurtek LLC

Development of a Wireless Communications Planning Tool for Optimizing Indoor Coverage Areas

Going Beyond RF Coverage: Designing for Capacity

Modeling & Simulating Antenna Arrays and RF Beamforming Algorithms Giorgia Zucchelli Product Marketing MathWorks

Effect of Body Motion and the Type of Antenna on the Measured UWB Channel Characteristics in Medical Applications of Wireless Body Area Networks

Transcription:

Wireless In Vivo Communications and Networking Richard D. Gitlin Minimally Invasive Surgery Wirelessly networked modules Modeling the in vivo communications channel Motivation: Wireless communications and networking has the potential to significantly advance healthcare delivery solutions by creating in vivo wirelessly networked cyber-physical systems of implanted devices. These systems can use real-time data to enable rapid, correct, and cost-conscious responses in surgical, diagnostic, and emergency circumstances. Our initial research focus is on creating a new paradigm for Minimally Invasive Surgery (MIS). Research Challenges: (1) Modeling the in vivo wireless channel, (2) inventing new communications and networking solutions for embedded devices of limited complexity, (3) meeting the high bit rate and low latency requirements of surgical applications (e.g., HDTV), (4) developing new approaches to privacy and security for devices of limited processing capabilities, and (5) machine learning of optimal clinical decisions/actions that are determined in real time by processing the stream of sensor data vectors. Research Objectives: (1) Architecting and realizing a network of wirelessly controlled and communicating in vivo devices that will facilitate a new paradigm for Minimally Invasive Surgery (MIS), (2) creating novel in vivo wireless communications and networking technologies, and (3) inventing learning systems to make optimal decision to support these devices and advance the performance wireless body area networks (WBANs) that will support MIS and other biomedical healthcare applications. In vivo wireless communications systems: invention, analysis, design, and implementation

MARVEL: Miniature Advanced Remote Videoscope for Expedited Laparoscopy MARVEL: A wirelessly controlled and communicating high-definition video system that provides the visual advantages of open-cavity surgery for Minimally invasive Surgery (MIS). Key Issues and Challenges: (1) achieving reliable, high- throughput and low-latency in vivo wireless communications and networking, (2) electronic and mechanical miniaturization of complex systems, (3) localization and mapping of the intra-body camera unit and surrounding organs and tissues and (4) networking of multiple embedded devices with different functions. Research Directions: In vivo wireless MARVEL devices that enable control of various functions including motion, video zoom and LED illumination. These devices will also include full digital HD video transmission implemented on a field programmable logic array (FPGA) with near zero latency and will be scalable in architecture and design with the goal of transferring the capabilities of a 30 mm diameter research platform to a 10 mm commercial device. Impact: The development and demonstration of a semi-autonomous wirelessly controllable in vivo device for minimally invasive surgery with scalable architecture can be the first step in a paradigm shift in MIS. MARVEL CMs inside a porcine subject Image of porcine internal organs taken by a MARVEL CM CAD model of MARVEL 30 mm CM and exploded circuit board stack

In vivo Channel Modeling Goal: Understanding the characteristics of the in vivo channel and optimizing the in vivo physical layer signal processing for high-performance wireless body area networks (WBANs) and remote health monitoring platforms. Challenges: High data rate RF communications from in vivo devices will likely be challenging given (1) the frequency and spatially dependent dielectric properties of human body tissues (2) the in vivo environment is an inhomogeneous and very lossy medium, (3) the far field assumption is not always valid, and (4) additional factors such as highly variable propagation speeds due to different organs and tissues that lead to angular dependent dispersive properties. Approaches: The ANSYS HFSS human body model software includes muscles, bones and organs modeled to 1 mm. The software computes the total electromagnetic fields produced by radiating elements in the in vivo environment and are used to derive path loss and the corresponding channel impulse response as a function of frequency, antenna type and form factor, and antenna location. Impact: Knowledge of the in vivo channel facilitates the design of optimized implanted antennas, the optimal location of the transmitters and receivers, and the design of MIMO in vivo systems. Channel Impulse Response of signals traveling in different direction from center of body Top view of the E field (in the XY plane) radiated by Hertzian-Dipole at 2.4GHz. In vivo wireless channel

MIMO in vivo Motivation: The lossy and highly dispersive nature of the in vivo environment, makes achieving high data rates with reliable performance a challenge. Power levels are limited by the specified specific absorption rate (SAR). Approach: Demonstrating increased data rates and reliable in vivo communications by the use of multiple-input multiple-output (MIMO in vivo) antenna technology. Performance is evaluated by SystemVue/HFSS simulation methods considering various factors such as antenna separation, antenna angular positions, and channel bandwidth. Objectives: Analyze and optimize MIMO in vivo performance based upon static and statistical in vivo channels to explore the potential of MIMO in vivo to achieve stringent requirements of high data rate applications. Results: Compared with single-input single-output (SISO) systems, MIMO in vivo achieves significant performance gains, while meeting the maximum SAR levels, making it possible to achieve target data rates of 100 Mbps with a system bandwidth of 40 MHz. MIMO vs SISO in vivo FER (Frame Error Rate) Capacity vs distance Capacity vs Rx antenna locations

HAMCR---Holistically Application-Aware Multi-Dimensional Cognitive Radio Motivation: In today s wireless 4G LTE networks, the spectral allocation of resources relies on a set of predefined fixed priorities. The QoS [Quality of Service] required by a given application can be quite variable for different users. For example, the spectral content of voice and video can be reduced for older people to improve quality for other users and/or to increase capacity. Approach: We created: (1) User-specific utility functions to differentiate categories of users, (2) resource schedulers that process the User-Specific QoS [US-QoS] to optimize the spectral allocation, and (3) a wireless testbed to evaluate the quality and capacity gain of US-QoS schedulers in realistic communication scenarios. Objectives: Design US-QoS aware wireless resource MAC schedulers to (1) improve user satisfaction, as measured by the Mean Opinion Score (MOS), and/or (2) improve system capacity by trading off the spectral resource allocations for the US-QoS requirements, while still maintaining acceptable levels of MOS. Results: Approximately 10% MOS or system capacity improvements can be achieved if US-QoS requirements are considered in the user-specific QoS aware schedulers. VoIP MOS utility function VoIP MOS improvement VoIP MOS and capacity tradeoff

Cardiac Rhythm Monitoring Vectorcardiogram (VCG) Motivation: The vectorcardiogram (VCG) is a compact external cardiac rhythm monitor that uses three orthogonal signal (leads) to obtain a 24x7 big data electrical representation of the heart that is equivalent to the 12-lead gold standard electrocardiogram (ECG). The VCG wirelessly communicates data to a server and/or a physician. Key Issue and Challenges: To provide long-term and, continuous cardiac rhythm monitoring, the research challenges include (1) miniaturization of the VCG system, (2) develop highly sensitive contact and noncontact voltage sensing electrodes, and (3) post-processing of the measured heart signals to remove noise, restore signal orthogonality and converting to 12-lead ECG format (4) designing an implanted VCG. Research Directions: (1) A VCG with a very small form factor (the size of a band aid), (2) integrate learning and wireless communication capabilities into the VCG, (3) feasibility of using the VCG as a multi-sensor platform, and (4) predictive algorithms that can leverage VCG BIG DATA for cardiac event forecasting. Impact: The VCG is a breakthrough CRM technology that allows long term and continuous remote diagnostic-quality monitoring of a patient s electrical heart activity. Prototype VCG system VCG signals at minimum distances VCG System

Sponsors 7

2024 © hobbydocbox.com Privacy Policy | Terms of Service | Feedback