163 research outputs found
On the Performance of Single- and Multi-carrier Modulation Schemes for Indoor Visible Light Communication Systems
In this paper, we investigate and compare the performance of single- and
multi-carrier modulation schemes for indoor visible light communication (VLC).
Particularly, the performances of single carrier frequency domain equalization
(SCFDE), orthogonal frequency division multiplexing (OFDM) and on-off keying
(OOK) with minimum mean square error equalization (MMSE) are analyzed in order
to mitigate the effect of multipath distortion of the indoor optical channel
where nonlinearity distortion of light emitting diode (LED) transfer function
is taken into account. Our results indicate that SCFDE system, in contrast to
OFDM system, does not suffer from high peak to average power ratio (PAPR) and
can outperform OFDM and OOK systems. We further investigate the impact of LED
bias point on the performance of OFDM systems and show that biasing LED with
the optimum value can significantly enhance the performance of the system.
Bit-interleaved coded modulation (BICM) is also considered for OFDM and SCFDE
systems to further compensate signal degradation due to inter-symbol
interference (ISI) and LED nonlinearity.Comment: 6 Pages, IEEE Globecom conference 201
Performance analysis of modified asymmetrically-clipped optical orthogonal frequency-division multiplexing systems
A modification to the Asymmetrically-Clipped Optical Orthogonal Frequency-Division Multiplexing (ACO-OFDM) technique is proposed through unipolar encoding. A performance analysis of the Bit Error Rate (BER) is developed and Monte Carlo simulations are carried out to verify the analysis. Results are compared to that of the corresponding ACO-OFDM system under the same bit energy and transmission rate; an improvement of 1 dB is obtained at a BER of 10-4. In addition, the performance of the proposed system in the presence of atmospheric turbulence is investigated using single-input multiple-output (SIMO) configuration and its performance under that environment is compared to that of ACO-OFDM. Energy improvements of 4 dB and 2.2 dB are obtained at a BER of 10-4 for SIMO systems of 1 and 2 photodetectors at the receiver for the case of strong turbulence, respectively
Flip-OFDM for Optical Wireless Communications
We consider two uniploar OFDM techniques for optical wireless communications:
asymmetric clipped optical OFDM (ACO-OFDM) and Flip-OFDM. Both techniques can
be used to compensate multipath distortion effects in optical wireless
channels. However, ACO-OFDM has been widely studied in the literature, while
the performance of Flip-OFDM has never been investigated. In this paper, we
conduct the performance analysis of Flip-OFDM and propose additional
modification to the original scheme in order to compare the performance of both
techniques. Finally, it is shown by simulation that both techniques have the
same performance but different hardware complexities. In particular, for slow
fading channels, Flip-OFDM offers 50% saving in hardware complexity over
ACO-OFDM at the receiver.Comment: published in IEEE Information Theory Workshop, Paraty Brazil, Sept
201
System design and performance analysis of asymmetrically and symmetrically clipped optical (ASCO)-OFDM for IM/DD optical wireless communications
As the quantity of mobile communication devices, such as cellphones, tablets, and laptops, dramatically increase, the demand for high speed wireless service has been growing. Optical wireless communications (OWCs), which offer unlimited transmission bandwidth, have received a lot of attention and been studied in recent decades. They can be an effective alternative to radio frequency communications (RFCs) for indoor high speed data transmission. Intensity modulation direct detection (IM/DD) is a simple way to realize the transmission of optical wireless signals in an indoor environment. Information data streams are modulated into the intensity of optical carriers and transmitted by light emitting diodes (LEDs). At the receiver, the instantaneous power of optical signals can be directly detected by photodiodes. Multipath distortion, especially in an indoor environment, caused by reflection from walls or furniture, severely affects the transmission quality of optical signals. Orthogonal frequency division multiplexing (OFDM) is a promising modulation technique and has been widely used to combat inter-symbol-interference (ISI) resulting from multipath propagation in RFCs. So far, the technique of OFDM has also been successfully applied into IM/DD optical wireless systems. In this dissertation, the author focuses on the system design and performance analysis of a novel power-efficient scheme based on OFDM for IM/DD OWCs. This dissertation is divided into four main sections.
In the first part, a novel power-efficient scheme, called asymmetrically and symmetrically clipped optical (ASCO)-OFDM, for intensity modulation direct detection (IM/DD) optical wireless systems is proposed. The average bit rate versus (vs.) normalized bandwidth and the optical power per bit of this novel scheme are expressed by a closed form, respectively. The symbol error rate (SER) performance is investigated when optical signals are transmitted in a flat fading channel. Simulation results show that this proposed scheme can achieve better performances in terms of both power efficiency and symbol error rate (SER) when the optical power of transmitted signals is limited.
In the second part, an improved receiving technique is applied into the conventional receiver of ASCO-OFDM to improve the SER performance. This technique can explore and reuse some useful information hidden in the received signals. The detection procedure is described in detail and the improved SER performances are presented for different constellation cases.
In the third part, the information rates of ADO-OFDM and ASCO-OFDM are obtained for an additive white Gaussian noise (AWGN) channel with an average transmitted optical power constraint.
In the last part, this novel power efficient scheme, ASCO-OFDM, is extended into two-dimensional (2D) IM/DD optical wireless systems. The theoretical analysis and simulation results show that this technique not only achieves high average bit rate, but reduces the Peak-to-average power ratio (PAPR) as well
Study And Analysis Of An Optical OFDM Based On The Discrete Hartley Transform For IM/DD Systems
Projecte fet en col.lboració amb CTTC. Centre Tecnològic de Telecomunicacions de CatalunyaOrthogonal frequency division multiplexing (OFDM) is used extensively in
broadband wired and wireless communication systems because it is an
effective solution to inter
channel. While many details of OFDM systems are very complex, the basic
concept of OFDM is quite simple: data is transmi
number of different frequencies, and as a result the symbol period is much
longer than for a serial system with the same total data rate. Because the
symbol period is longer, ISI affects at most one symbol, and equalization
is simplified. In most OFDM implementations any residual ISI is removed
by using a form of guard interval called a cyclic prefix
Robust Timing Synchronization for AC-OFDM Based Optical Wireless Communications
Visible light communications (VLC) have recently attracted a growing interest
and can be a potential solution to realize indoor wireless communication with
high bandwidth capacity for RF-restricted environments such as airplanes and
hospitals. Optical based orthogonal frequency division multiplexing (OFDM)
systems have been proposed in the literature to combat multipath distortion and
intersymbol interference (ISI) caused by multipath signal propagation. In this
paper, we present a robust timing synchronization scheme suitable for
asymmetrically clipped (AC) OFDM based optical intensity modulated direct
detection (IM/DD) wireless systems. Our proposed method works perfectly for
ACO-OFDM, Pulse amplitude modulated discrete multitone (PAM-DMT) and discrete
Hartley transform (DHT) based optical OFDM systems. In contrast to existing
OFDM timing synchronization methods which are either not suitable for AC OFDM
techniques due to unipolar nature of output signal or perform poorly, our
proposed method is suitable for AC OFDM schemes and outperforms all other
available techniques. Both numerical and experimental results confirm the
accuracy of the proposed method. Our technique is also computationally
efficient as it requires very few computations as compared to conventional
methods in order to achieve good accuracy.Comment: Accepted for publication in IEEE ICNS 2015, 10 Pages, 7 fig
A novel unipolar transmission scheme for visible light communication
This paper proposes a novel unipolar transceiver for visible light communication (VLC) by using orthogonal waveforms. The main advantage of our proposed scheme over most of the existing unipolar schemes in the literature is that the polarity of the real-valued orthogonal frequency division multiplexing (OFDM) sample determines the pulse shape of the continuous-time signal and thus, the unipolar conversion is performed directly in the analog instead of the digital domain. Therefore, our proposed scheme does not require any direct current (DC) biasing or clipping as it is the case with existing schemes in the literature. The bit error rate (BER) performance of our proposed scheme is analytically derived and its accuracy is verified by using Matlab simulations. Simulation results also substantiate the potential performance gains of our proposed scheme against the state-of-the-art OFDM-based systems in VLC; it indicates that the absence of DC shift and clipping in our scheme supports more reliable communication and outperforms the asymmetrically clipped optical-OFDM (ACO-OFDM), DC optical-OFDM (DCO-OFDM) and unipolar-OFDM (U-OFDM) schemes. For instance, our scheme outperforms ACO-OFDM by at least 3 dB (in terms of signal to noise ratio) at a target BER of 10 −4 , when considering the same spectral efficiency for both schemes
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