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Difference between revisions of "Ultra-wideband Concurrent Ranging"

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(Introduction)
(Introduction)
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= Introduction =
 
= Introduction =
[[File:uwb_scenario.png|thumb|right|320px| test]]
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[[File:uwb_scenario.png|thumb|right|200px| UWB Localization]]
 
Ultra-wideband (UWB) is one of the most promising and adopted ranging (i.e., distance measuring) technologies used for positioning and localization, as it enables centimeter-precision distance estimation and data transmission. In our applications, we use UWB with the time-of-arrival (ToA) technique, which determines the distance between two UWB nodes based on the travel time of a radio signal from the transmitter to the receiver. Due to its high-precision ranging, UWB enables range-based localization.
 
Ultra-wideband (UWB) is one of the most promising and adopted ranging (i.e., distance measuring) technologies used for positioning and localization, as it enables centimeter-precision distance estimation and data transmission. In our applications, we use UWB with the time-of-arrival (ToA) technique, which determines the distance between two UWB nodes based on the travel time of a radio signal from the transmitter to the receiver. Due to its high-precision ranging, UWB enables range-based localization.
  

Revision as of 22:58, 18 January 2022


Overview

Status: Available

Introduction

UWB Localization

Ultra-wideband (UWB) is one of the most promising and adopted ranging (i.e., distance measuring) technologies used for positioning and localization, as it enables centimeter-precision distance estimation and data transmission. In our applications, we use UWB with the time-of-arrival (ToA) technique, which determines the distance between two UWB nodes based on the travel time of a radio signal from the transmitter to the receiver. Due to its high-precision ranging, UWB enables range-based localization.

Project

Character

  • 20% Literature / familiarization with UWB
  • 30% Bare-metal / FreeRTOS C programming
  • 30% Signal processing / machine learning
  • 20% Evaluation

Prerequisites

  • Strong interest in computer architecture
  • Experience with digital design in SystemVerilog as taught in VLSI I
  • Experience with low-level programming


References