Frequency domain processing techniques for continuous phase modulation

Park, Cheol Hee

14 February 2012

The continuous phase modulation (CPM) has a constant envelope and compact output power spectrum that makes it a promising underlying technology for power and spectrum efficient broadband wireless communications. However, high implementation complexity (especially the complexity of the receiver) required to deal with the phase memory and inter-symbol interference has impeded its adoption for broadband wireless communications, and only a few simple CPM modulation schemes have mainly been used, e.g. binary MSK and GMSK. Thus, research on efficient CPM transceivers to reduce the computational and hardware complexity is important. The major contribution of this dissertation is the development of novel frequency domain processing techniques and transceiver strategies to improve power and spectral efficiency, and reduce the complexity of CPM modulation schemes. First, this dissertation presents simplified frequency domain receiver structures and decoding schemes in the frequency domain for binary and M-ary CPM block transmission. The frequency domain receivers utilize parallel and serial structures with frequency domain processing which considerably reduces hardware and computational complexity compared to conventional time-domain processing. In addition, the decoding schemes in the frequency domain eliminate the controlled phase memory through frequency domain phase equalization instead of maximum-likelihood sequential decoders, e.g. Viterbi decoders. Second, frequency domain channel estimation schemes for CPM block transmission are presented, which adopt superimposed training signals to achieve bandwidth and power efficiency while reducing the complexity. In these schemes, the proposed frequency domain channel estimation uses the superimposed training signals as a reference signal to reduce the throughput loss caused by conventionally multiplexed training signals. Superimposed training signal design is presented, and the trade-off between bandwidth efficiency and power efficiency is also analyzed. Third, block transmission schemes and frequency domain equalization methods for CPM are proposed, which consider linear processing instead of conventional decomposition-based processing. The schemes of frequency domain linear processing avoid the complexity overhead (both in computation and hardware) of conventional orthogonal- or Laurent decomposed-based equalizers. Finally, this dissertation extends CPM block transmission and frequency domain equalization to phase-coded (time-varying modulation index) CPM, which shows better error performance and bandwidth efficiency than fixed modulation index CPM's. / text

Continuous phase modulation

Frequency domain equalization

Superimposed training schemes

Space-Frequency Equalization in Broadband Single Carrier Systems

Kongara, Gayathri

January 2009

Broadband wireless access systems can be used to deliver a variety of high data rate applications and services. Many of the channels being considered for such applications exhibit multipath propagation coupled with large delay spreads. Cur- rently, orthogonal frequency division multiplexing is employed in these channels to compensate the effect of dispersion. Single carrier (SC) modulation in conjunc- tion with frequency-domain equalization (FDE) at the receiver has been shown to be a practical alternate solution as it has lower peak to average power ratio and is less sensitive to frequency offsets and phase noise compared to OFDM. The effect of multipath propagation increases with increasing data rate for SC systems. This leads to larger inter-symbol-interference (ISI) spans. In addition the achievable ca- pacity of SC-broadband systems depends on their ability to accommodate multiple signal transmissions in the same frequency band, which results in co-channel inter- ference (CCI) when detecting the desired data stream. The effects of CCI and ISI are more pronounced at high data rates. The objective of this research is to investi- gate and a develop low-complexity frequency domain receiver architectures capable of suppressing both CCI and ISI and employing practical channel estimation. In this thesis, a linear and a non-linear receiver architecture are developed in the frequency domain for use in highly dispersive channels employing multiple input multiple output (MIMO) antennas. The linear receiver consists of parallel branches each corresponding to a transmit data stream and implements linear equalization and demodulation. Frequency domain joint CCI mitigation and ISI equalization is implemented based on estimated channel parameters and is called space-frequency Broadband wireless access systems can be used to deliver a variety of high data rate applications and services. Many of the channels being considered for such applications exhibit multipath propagation coupled with large delay spreads. Cur- rently, orthogonal frequency division multiplexing is employed in these channels to compensate the effect of dispersion. Single carrier (SC) modulation in conjunc- tion with frequency-domain equalization (FDE) at the receiver has been shown to be a practical alternate solution as it has lower peak to average power ratio and is less sensitive to frequency offsets and phase noise compared to OFDM. The effect of multipath propagation increases with increasing data rate for SC systems. This leads to larger inter-symbol-interference (ISI) spans. In addition the achievable ca- pacity of SC-broadband systems depends on their ability to accommodate multiple signal transmissions in the same frequency band, which results in co-channel inter- ference (CCI) when detecting the desired data stream. The effects of CCI and ISI are more pronounced at high data rates. The objective of this research is to investi- gate and a develop low-complexity frequency domain receiver architectures capable of suppressing both CCI and ISI and employing practical channel estimation. In this thesis, a linear and a non-linear receiver architecture are developed in the frequency domain for use in highly dispersive channels employing multiple input multiple output (MIMO) antennas. The linear receiver consists of parallel branches each corresponding to a transmit data stream and implements linear equalization and demodulation. Frequency domain joint CCI mitigation and ISI equalization is implemented based on estimated channel parameters and is called space-frequency

Single carrier

frequency domain equalization

MIMO

DFE

channel estimation

Frequency-domain equalization of single carrier transmissions over doubly selective channels

Liu, Hong

14 September 2007

No description available.

doubly selective channel

frequency domain equalization

frequency domain channel estimation

soft-interference-cancellation

Kalman filter

A Low Complexity Cyclic Prefix Reconstruction Scheme for Single-Carrier Systems with Frequency-Domain Equalization

Hwang, Ruei-Ran

25 August 2010

The cyclic prefix (CP) is usually adopted in single carrier frequency domain equalization (SC-FDE) system to avoid inter-block interference (IBI) and inter-symbol interference (ISI) in multipath fading channels. In addition, the use of CP also converts the linear convolution between the transmitted signal and the channel into a circular convolution, leading to significant decrease in receiver equalization. However, the use of CP reduces the bandwidth efficiency. Therefore the SC-FDE system without CP is investigated in this thesis. A number of schemes have been proposed to improve the performance of systems without CP, where both IBI and ICI are dramatically increased. Unfortunately, most of the existing schemes have extremely high computational complexity and are difficult to realize. In this thesis, a novel low-complexity CP reconstruction (CPR) scheme is proposed for interference cancellation, where the successive interference cancellation (SIC) and QR decomposition (QRD) are adopted. In addition, the system performance is further improved by using the fact that the interferences of different symbols are not the same. Simulation experiments are conducted to verify the system performance of the proposed scheme. It is shown that the proposed scheme can effectively reduce the interference, while maintain a low computational complexity.

cyclic prefix (CP)

inter-block interference (IBI)

inter-symbol interference (ISI)

Investigation on the Frequency Domain Channel Equalization and Interference Cancellation for Single Carrier Systems

Chan, Kuei-Cheng

11 August 2008

In the single carrier systems with cyclic-prefix (CP), the use of CP does not only eliminate the inter-block interference (IBI), but also convert linear convolution of the transmitted signal with the channel into circular convolution, which leads to the computation complexity of the frequency domain equalization (FDE) at the receiver is reduced. Unfortunately, the use of CP considerably decreases the bandwidth utilization. In order to increase the bandwidth utilization, the single carrier systems with frequency domain equalization (SC-FDE) is investigated. When FDE is used in a single carrier system without CP, the IBI is induced by the modulated symbols and then the bit-error rate (BER) is increased. To reduce the interference and then improve the system performance, a novel interference cancellation scheme is proposed in this thesis. After FDE, it is shown that interference is induced from the right end of a time domain signal block and most of the interference is located at both ends of an equalized time domain signal block. Based on this observation, the modulated symbols which induce the interference are detected according to the maximum-likelihood (ML) principle and then the interference is regenerated and eliminated. For simplifying the computation complexity, we further propose a successive interference cancellation scheme, which is implemented by using the Viterbi algorithm. The simulation results demonstrate that the proposed scheme improves BER performance significantly in SC-FDE systems. In addition, the proposed architecture has comparable BER performance with the SC-CP systems when the multi-path channel is exponentially decayed.

Viterbi algorithm

inter-block interference (IBI)

interference cancellation

Channel Shortening Equalizer for Cyclic Prefixed Systems Based on Shortening Signal-to-Interference Ratio Maximization

Chen, I-Wei

11 August 2008

Considering the communication systems with cyclic prefix (CP), such as orthogonal frequency-division multiplexing (OFDM) modulation and single-carrier cyclic prefixed (SCCP) modulation, when the length of CP is longer than the channel length, the use of cyclic prefix (CP) does not only eliminate the inter-block interference, but also convert linear convolution of the transmitted signal with the channel into circular convolution. Unfortunately, the use of CP significantly decreases the bandwidth utilization. Therefore, to reduce the length of CP is a critical issue. The thesis investigates that how to design a channel-shortening equalizer (CSE) at receiver which forces the length of the effective channel response as short as the CP length. The thesis describes the signal model as a matrix form. The effect channel response after CSE is investigated and then the coefficient of channel shortening filter is obtained using singular value decomposition method under various criterions. We further propose a novel CSE maximizing the shortening signal-to-interference ratio. In addition, it is demonstrated that the proposed CSE has the same performance as the conventional scheme but a lower computation complexity.

Time-Domain Equalizer(TEQ)

Single-Carrier Cyclic Prefixed(SCCP)

Channel Shortening Equalizer(CSE)

Modélisation du canal intra-bâtiment et transmission haut-débit pour les communications optiques dans le spectre visible / Indoor channel modeling and high data-rate transmission for visible light communication systems

Long, Shihe

21 September 2016

Les communications optiques dans le spectre visible (VLC pour Visible-Light Communications) ont attiré une attention particulière depuis quelques années en tant qu'une solution prometteuse pour les réseaux sans fil à très haut-débit dans les milieux intra-bâtiment. Ainsi, cette technique exploite l'infrastructure d’éclairage basée sur les diodes électroluminescentes (LED) pour la transmission de l'information. Pour cette raison, elle offre de nombreux avantages, comparée aux techniques « classiques » basées sur les transmissions radiofréquences (RF), tels que l'existence d'une grande largeur de bande non réglementée, une sécurité de transmission intrinsèque et une immunité aux interférences électromagnétiques.Les principales contraintes liées à l'établissement d'une transmission VLC à très haut-débit dans ce contexte sont la propagation en trajets multiples et les caractéristiques non-idéales des LEDs commerciales, dites « blanches ». L'objectif de cette thèse est d'étudier l'impact réel de ces contraintes sur la transmission des données et de proposer des solutions efficaces de traitement du signal pour atténuer leurs effets. Nous commençons par étudier la réponse impulsionnelle du canal VLC grâce à l'élaboration d'un outil de simulation efficace. Nous évaluons ensuite la sélectivité en fréquence du canal de propagation en considérant différents critères, tels que la réponse fréquentielle, l'étalement temporelle du canal et le rapport signal à interférences. Dans un deuxième temps, compte tenu de la possibilité de la sélectivité en fréquence du canal et aussi la limitation de la bande passante des LEDs, nous étudions la pertinence de l'emploi de différentes techniques de transmission de signaux, notamment celle de l'OFDM optique (pour Orthogonal Frequency-Division Multiplexing) afin de garantir des débits de transmission compétitifs avec la RF. Etant donné le facteur de crête ou PAPR (pour Peak-to-Average Power Ratio) élevé des signaux modulés en OFDM et la dynamique limitée des LEDs, nous proposons ensuite un nouveau schéma de transmission basé sur la modulation CAP (pour Carrier-less Amplitude and Phase) en plus de l'égalisation dans le domaine fréquentiel (FDE pour Frequency-Domain Equalization) au niveau du récepteur. Nous analysons les performances des liaisons VLC utilisant cette technique et les comparons à l'OFDM optique, en prenant particulièrement en compte la non-linéarité des LEDs. Enfin, nous démontrons l'intérêt de l'utilisation du schéma de transmission CAP-FDE à travers des résultats expérimentaux. / Visible Light Communications (VLC) have attracted particular attention in the research community since a few years as a promising solution for high-speed indoor wireless networks. By exploiting the existing solid-state light-emitting diode (LED) lighting infrastructure, VLC offer numerous advantages such as a large unlicensed bandwidth, transmission security, and immunity to electro-magnetic interference compared to their radiofrequency counterparts. Within the context of indoor VLC, the multipath propagation channel and the non-ideal characteristics of the commercial white LEDs cause the main limitations for achieving high data-rate transmission. The objective of this thesis is to investigate the true impact of these limitations on the data transmission and to propose efficient signal processing solutions to mitigate their adverse effects. We start by the study of the indoor VLC channel impulse response by developing an efficient simulation tool. We then consider evaluating the channel frequency selectivity through different metrics. Next, given the potentially frequency-selective channel and the limited modulation bandwidth of the LEDs, we investigate the suitability of employing different signal transmission techniques including optical orthogonal frequency-division multiplexing (O-OFDM) in order to achieve high data-rate transmission. Given the high peak-to-average power ratio (PAPR) of O-OFDM signals and the limited dynamic range of the LEDs, we then propose a novel transmission scheme, which consists of using carrier-less amplitude and phase (CAP) modulation together with frequency domain equalization (FDE) at the receiver. We analyze the performance of the VLC link using this technique and compare it with the O-OFDM schemes, especially by taking the non-linear characteristics of the LED into account. Lastly, we demonstrate the merits of using the CAP-FDE transmission scheme via some experimental results.

Modélisation du canal

Transmission haut-Débit

Optical OFDM

Visible-Light communication

Indoor channel modeling

High data-Rate transmission

Optical OFDM

Frequency domain equalization

Carrierless amplitude phase modulation