34 research outputs found
TagScan: Simultaneous target imaging and material identification with commodity RFID devices
National Research Foundation (NRF) Singapore under IDM Futures Funding Initiativ
Enabling RAN Slicing Through Carrier Aggregation in mmWave Cellular Networks
The ever increasing number of connected devices and of new and heterogeneous
mobile use cases implies that 5G cellular systems will face demanding technical
challenges. For example, Ultra-Reliable Low-Latency Communication (URLLC) and
enhanced Mobile Broadband (eMBB) scenarios present orthogonal Quality of
Service (QoS) requirements that 5G aims to satisfy with a unified Radio Access
Network (RAN) design. Network slicing and mmWave communications have been
identified as possible enablers for 5G. They provide, respectively, the
necessary scalability and flexibility to adapt the network to each specific use
case environment, and low latency and multi-gigabit-per-second wireless links,
which tap into a vast, currently unused portion of the spectrum. The
optimization and integration of these technologies is still an open research
challenge, which requires innovations at different layers of the protocol
stack. This paper proposes to combine them in a RAN slicing framework for
mmWaves, based on carrier aggregation. Notably, we introduce MilliSlice, a
cross-carrier scheduling policy that exploits the diversity of the carriers and
maximizes their utilization, thus simultaneously guaranteeing high throughput
for the eMBB slices and low latency and high reliability for the URLLC flows.Comment: 8 pages, 8 figures. Proc. of the 18th Mediterranean Communication and
Computer Networking Conference (MedComNet 2020), Arona, Italy, 202
RF-Transformer: A Unified Backscatter Radio Hardware Abstraction
This paper presents RF-Transformer, a unified backscatter radio hardware
abstraction that allows a low-power IoT device to directly communicate with
heterogeneous wireless receivers at the minimum power consumption. Unlike
existing backscatter systems that are tailored to a specific wireless
communication protocol, RF-Transformer provides a programmable interface to the
micro-controller, allowing IoT devices to synthesize different types of
protocol-compliant backscatter signals sharing radically different PHY-layer
designs. To show the efficacy of our design, we implement a PCB prototype of
RF-Transformer on 2.4 GHz ISM band and showcase its capability on generating
standard ZigBee, Bluetooth, LoRa, and Wi-Fi 802.11b/g/n/ac packets. Our
extensive field studies show that RF-Transformer achieves 23.8 Mbps, 247.1
Kbps, 986.5 Kbps, and 27.3 Kbps throughput when generating standard Wi-Fi,
ZigBee, Bluetooth, and LoRa signals while consuming 7.6-74.2 less power than
their active counterparts. Our ASIC simulation based on the 65-nm CMOS process
shows that the power gain of RF-Transformer can further grow to 92-678. We
further integrate RF-Transformer with pressure sensors and present a case study
on detecting foot traffic density in hallways. Our 7-day case studies
demonstrate RFTransformer can reliably transmit sensor data to a commodity
gateway by synthesizing LoRa packets on top of Wi-Fi signals. Our experimental
results also verify the compatibility of RF-Transformer with commodity
receivers. Code and hardware schematics can be found at:
https://github.com/LeFsCC/RF-Transformer
Symphony: Localizing Multiple Acoustic Sources with a Single Microphone Array
Sound recognition is an important and popular function of smart devices. The
location of sound is basic information associated with the acoustic source.
Apart from sound recognition, whether the acoustic sources can be localized
largely affects the capability and quality of the smart device's interactive
functions. In this work, we study the problem of concurrently localizing
multiple acoustic sources with a smart device (e.g., a smart speaker like
Amazon Alexa). The existing approaches either can only localize a single
source, or require deploying a distributed network of microphone arrays to
function. Our proposal called Symphony is the first approach to tackle the
above problem with a single microphone array. The insight behind Symphony is
that the geometric layout of microphones on the array determines the unique
relationship among signals from the same source along the same arriving path,
while the source's location determines the DoAs (direction-of-arrival) of
signals along different arriving paths. Symphony therefore includes a
geometry-based filtering module to distinguish signals from different sources
along different paths and a coherence-based module to identify signals from the
same source. We implement Symphony with different types of commercial
off-the-shelf microphone arrays and evaluate its performance under different
settings. The results show that Symphony has a median localization error of
0.694m, which is 68% less than that of the state-of-the-art approach
A baseband wireless spectrum hypervisor for multiplexing concurrent OFDM signals
The next generation of wireless and mobile networks will have to handle a significant increase in traffic load compared to the current ones. This situation calls for novel ways to increase the spectral efficiency. Therefore, in this paper, we propose a wireless spectrum hypervisor architecture that abstracts a radio frequency (RF) front-end into a configurable number of virtual RF front ends. The proposed architecture has the ability to enable flexible spectrum access in existing wireless and mobile networks, which is a challenging task due to the limited spectrum programmability, i.e., the capability a system has to change the spectral properties of a given signal to fit an arbitrary frequency allocation. The proposed architecture is a non-intrusive and highly optimized wireless hypervisor that multiplexes the signals of several different and concurrent multi-carrier-based radio access technologies with numerologies that are multiple integers of one another, which are also referred in our work as radio access technologies with correlated numerology. For example, the proposed architecture can multiplex the signals of several Wi-Fi access points, several LTE base stations, several WiMAX base stations, etc. As it able to multiplex the signals of radio access technologies with correlated numerology, it can, for instance, multiplex the signals of LTE, 5G-NR and NB-IoT base stations. It abstracts a radio frequency front-end into a configurable number of virtual RF front ends, making it possible for such different technologies to share the same RF front-end and consequently reduce the costs and increasing the spectral efficiency by employing densification, once several networks share the same infrastructure or by dynamically accessing free chunks of spectrum. Therefore, the main goal of the proposed approach is to improve spectral efficiency by efficiently using vacant gaps in congested spectrum bandwidths or adopting network densification through infrastructure sharing. We demonstrate mathematically how our proposed approach works and present several simulation results proving its functionality and efficiency. Additionally, we designed and implemented an open-source and free proof of concept prototype of the proposed architecture, which can be used by researchers and developers to run experiments or extend the concept to other applications. We present several experimental results used to validate the proposed prototype. We demonstrate that the prototype can easily handle up to 12 concurrent physical layers
Towards Touch-to-Access Device Authentication Using Induced Body Electric Potentials
This paper presents TouchAuth, a new touch-to-access device authentication
approach using induced body electric potentials (iBEPs) caused by the indoor
ambient electric field that is mainly emitted from the building's electrical
cabling. The design of TouchAuth is based on the electrostatics of iBEP
generation and a resulting property, i.e., the iBEPs at two close locations on
the same human body are similar, whereas those from different human bodies are
distinct. Extensive experiments verify the above property and show that
TouchAuth achieves high-profile receiver operating characteristics in
implementing the touch-to-access policy. Our experiments also show that a range
of possible interfering sources including appliances' electromagnetic
emanations and noise injections into the power network do not affect the
performance of TouchAuth. A key advantage of TouchAuth is that the iBEP sensing
requires a simple analog-to-digital converter only, which is widely available
on microcontrollers. Compared with existing approaches including intra-body
communication and physiological sensing, TouchAuth is a low-cost, lightweight,
and convenient approach for authorized users to access the smart objects found
in indoor environments.Comment: 16 pages, accepted to the 25th Annual International Conference on
Mobile Computing and Networking (MobiCom 2019), October 21-25, 2019, Los
Cabos, Mexic