3,048 research outputs found
The effect of coupling circuits on impulsive noise in power line communication
Abstract: Most researchers in the Power Line Communications (PLC) field have adopted the practice of using idealized impulse noise models directly at the input of the demodulator, as is widely done in simulations. The effect of the coupling circuit on the impulse noise tend to be ignored. However, coupling circuits produce transients. This paper focuses on investigating the effect of the coupling circuit on the impulse noise. Experimental measurements are used to determine the effect of the coupling circuit. An equivalent circuit of the coupling circuit is developed and further simulations are conducted to gain in-depth knowledge on how the impulse noise is affected by the coupling circuit. A literature survey suggests that this topic has not been studied yet
A new coupling solution for G3-PLC employment in MV smart grids
This paper proposes a new coupling solution for transmitting narrowband multicarrier power line communication (PLC) signals over medium voltage (MV) power lines. The proposed system is based on an innovative PLC coupling principle, patented by the authors, which exploits the capacitive divider embedded in voltage detecting systems (VDS) already installed inside the MV switchboard. Thus, no dedicated couplers have to be installed and no switchboard modifications or energy interruptions are needed. This allows a significant cost reduction of MV PLC implementation. A first prototype of the proposed coupling system was presented in previous papers: it had a 15 kHz bandwidth useful to couple single carrier PSK modulated PLC signals with a center frequency from 50–200 kHz. In this paper, a new prototype is developed with a larger bandwidth, up to 164 kHz, thus allowing to couple multicarrier G3-PLC signals using orthogonal frequency division multiplexing (OFDM) digital modulation. This modulation ensures a more robust communication even in harsh power line channels. In the paper, the new coupling system design is described in detail. A new procedure is presented for tuning the coupling system parameters at first installation in a generic MV switchboard. Finally, laboratory and in-field experimental test results are reported and discussed. The coupling performances are evaluated measuring the throughput and success rate in the case of both 18 and 36 subcarriers, in one of the different tone masks standardized for the FCC-above CENELEC band (that is, from 154.6875–487.5 kHz). The experimental results show an efficient behavior of the proposed coupler allowing a two-way communication of G3-PLC OFDM signals on MV networks
Basics of RF electronics
RF electronics deals with the generation, acquisition and manipulation of
high-frequency signals. In particle accelerators signals of this kind are
abundant, especially in the RF and beam diagnostics systems. In modern machines
the complexity of the electronics assemblies dedicated to RF manipulation, beam
diagnostics, and feedbacks is continuously increasing, following the demands
for improvement of accelerator performance. However, these systems, and in
particular their front-ends and back-ends, still rely on well-established basic
hardware components and techniques, while down-converted and acquired signals
are digitally processed exploiting the rapidly growing computational capability
offered by the available technology. This lecture reviews the operational
principles of the basic building blocks used for the treatment of
high-frequency signals. Devices such as mixers, phase and amplitude detectors,
modulators, filters, switches, directional couplers, oscillators, amplifiers,
attenuators, and others are described in terms of equivalent circuits,
scattering matrices, transfer functions; typical performance of commercially
available models is presented. Owing to the breadth of the subject, this review
is necessarily synthetic and non-exhaustive. Readers interested in the
architecture of complete systems making use of the described components and
devoted to generation and manipulation of the signals driving RF power plants
and cavities may refer to the CAS lectures on Low-Level RF.Comment: 36 pages, contribution to the CAS - CERN Accelerator School:
Specialised Course on RF for Accelerators; 8 - 17 Jun 2010, Ebeltoft, Denmar
Assessment and control of spacecraft electromagnetic interference
Design criteria are presented to provide guidance in assessing electromagnetic interference from onboard sources and establishing requisite control in spacecraft design, development, and testing. A comprehensive state-of-the-art review is given which covers flight experience, sources and transmission of electromagnetic interference, susceptible equipment, design procedure, control techniques, and test methods
Emulation of Narrowband Powerline Data Transmission Channels and Evaluation of PLC Systems
This work proposes advanced emulation of the physical layer behavior of NB-PLC channels and the application of a channel emulator for the evaluation of NB-PLC systems. In addition, test procedures and reference channels are proposed to improve efficiency and accuracy in the system evaluation and classification. This work shows that the channel emulator-based solution opens new ways toward flexible, reliable and technology-independent performance assessment of PLC modems
Radio Frequency Interference /RFI/ design guide for aerospace communications systems
Radio frequency interference design guide for aerospace communications system
Characterization and Emulation of Low-Voltage Power Line Channels for Narrowband and Broadband Communication
The demand for smart grid and smart home applications has raised the recent interest in power line communication (PLC) technologies, and has driven a broad set of deep surveys in low-voltage (LV) power line channels. This book proposes a set of novel approaches, to characterize and to emulate LV power line channels in the frequency range from0.15to 10 MHz, which closes gaps between the traditional narrowband (up to 500 kHz) and broadband (above1.8 MHz) ranges
Characterization and Emulation of Low-Voltage Power Line Channels for Narrowband and Broadband Communication
The demand for smart grid and smart home applications has raised the recent interest in power line communication (PLC) technologies, and has driven a broad set of deep surveys in low-voltage (LV) power line channels. This book proposes a set of novel approaches, to characterize and to emulate LV power line channels in the frequency range from0.15to 10 MHz, which closes gaps between the traditional narrowband (up to 500 kHz) and broadband (above1.8 MHz) ranges
Ultra wideband gigabit powerline communication
PhDPowerline Communication (PLC) has long been established for low
data rate applications by the electric supply companies. Since 1991,
the European CENELEC standard EN 50065 has ruled the use of 3
- 148.5KHz frequency range for narrow band PLC applications. Sim-
ilar standard has been established by the IEEE in the US, where a
frequency range of 50 - 450KHz is available.
The fast growth of Internet since the 1990s accelerated the demands
for digital communication services. Furthermore, with the develop-
ment of in-home networking, there is a need to establish high speed
data links between multiple household devices. This makes PLC sys-
tems march rapidly into the high frequency range above 1MHz. Exist-
ing broadband PLC system in the 1.6 - 30MHz frequency range only
provides data rates smaller than 200Mbps. With the growing demand
of multimedia services such as High De nition (HD) video streaming,
much faster transmission speed up to Gigabits per second is required
and this can be achieved by increasing the operating frequencies.
Ultra Wideband (UWB) transmission in free space provides extremely
broad bandwidth for short-range, high data rate applications. If UWB
signals could be transmitted over the powerline channels in the high
frequency range above 30MHz, data rates up to gigabits per second
could be achieved.
In this thesis, the possibility of implementing ultra wideband trans-
mission over the low voltage indoor powerline is investigated. The
starting point is to understand the signal propagation characteristics
over powerline cables, in the UWB frequency range. Experimental re-
sults indicate that the signal degrades at an acceptable rate over the
mains cable in a scaled down UWB frequency band (50MHz - 1GHz),
which provides a potential operation band for UWB over PLC ap-
plications. Key component for the PLC system, a broadband Radio
Frequency (RF) coupler is designed and developed, to introduce UWB
signals to the transmission channel. With the channel properties and
coupling unit, extensive experimental investigations are carried out
to analyse the powerline network environment, including channel loss,
noise and radiated emission. Furthermore, theoretical channel capac-
ity and link budget are derived from measured parameters. It is shown
that the indoor powerline is a suitable media for data transmission in
the high frequency range from 50 to 550MHz in the home environment.
Finally, system level performance is analysed by modelling the Phys-
ical Layer (PHY) data transmission. The Multiband-OFDM UWB
proposal for IEEE 802.15.3a standard is used to predict the transmis-
sion performance under di erent propagation paths and data rates.
The research work conducted in this project has proven that UWB
over PLC is highly feasible for future in-home applications. With the
global promotion of smart grid applications, UWB over PLC will play
an important role in providing high speed data transmission over the
power networks
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