Full Paper
Transcription
Full Paper
ISSN 2394-3777 (Print) ISSN 2394-3785 (Online) Available online at www.ijartet.com International Journal of Advanced Research Trends in Engineering and Technology (IJARTET) Vol. II, Special Issue XXIII, March 2015 in association with FRANCIS XAVIER ENGINEERING COLLEGE, TIRUNELVELI DEPARTMENT OF ELECTRONICS AND COMMUNICATION ENGINEERING INTERNATIONAL CONFERENCE ON RECENT ADVANCES IN COMMUNICATION SYSTEMS AND TECHNOLOGIES (ICRACST’15) TH 25 MARCH 2015 Timing and Frequency Synchronized MIMO-OFDM System using Phase Locked Loop with Low Fault Rate 1 M.Anita PG Scholar Department of Applied Electronics St.Joseph’s College of Engineering Chennai-600119, India Abstract---Great attention has been received by various wireless communication techniques and is widely used in wireless communication systems for its high spectrum efficiency and robustness to narrowband interference and multipath fading. The Wireless communication technique used in this project is MIMO-OFDM. MIMO-OFDM can provide enormous data rates which is tolerable to radio channel impairments. But in OFDM system, there may occur a mismatch between transmitted and received signal. To overcome the mismatch and for timing and frequency synchronization between transmitted and received signal, we use a PLL with low fault rate. This project mainly investigates the effect of phase noise in the system and the system performance is evaluated by calculating the signal to noise ratio due to phase noise, in terms of BERsimulations with and without PLL for different channel conditions. Keywords—PLL, MIMO-OFDM, Synchronization, Phase noise I.INTRODUCTION 2 P.Thenmozhi AssistantProfessor Department of ECE, St.Joseph’s College of Engineering, Chennai-600119, India to each other. Thus, the cross-talk between the sub-channels is eliminated and inter-carrier gaurd bands are not required. The orthogonality also allows high spectral efficiency, with a total symbol rate near the nyquist rate for the equivalent baseband signal. Almost the whole available frequency band can be utilized. A convolutional channel-coder encodes the bit stream of each user. The encoded bits are interleaved by the outer interleaver and passed to the symbol mapped.With respect to different modulation alphabets (e.g., PSK or QAM), the bits are mapped to complex-valued data symbols.We use the Additive White Gaussian Noise (AWGN) channel for the Wireless Network.For system level simulations, the simulation of all interfering signal paths is complex. Thus, a simplification of the interference model is done by the Gaussian approximation (GA) which assumes the entire interference as Gaussian noise. Here by, the noise variance has to be scaled appropriately. Inorder to achieve timing and frequency synchronization between transmitted and received signal, PLL is used in this project. Signal is transmitted with the help of MIMO-OFDM technique and its synchronization error is calculated without using PLL and with using PLL and the results are compared. II. RELATED WORKS Phase Locked Loops are used in almost every communication system. Some of its uses are recovering clock from digital data signals, performing frequency modulation, phase modulation and demodulation, recovering carrier from satellite transmission signals and as a frequency synthesizer. There are many designs in communication that require frequency synthesizer to generate a range of frequencies; such as cordless telephones, mobile radios and other wireless products. The accuracy of the required frequencies is very important in these designs as the performance is based on this parameter. OFDMis a frequency division multiplexing sheme which converts high data rate signal into low data rate signal and transmits it through parallel narrowband channels. In OFDM transceiver, the sub-carrier frequencies are orthogonal Inproject [1] fractional N PLL based synthesizer is equipped with a VCO, which is realized with CMOS transistors in a current reuse technique and a DLL. And also shows a good performance in terms of phase noise and can be easily realized in a standard CMOS technology.In work [2] GNSS receiver is considered in which the PLL’s phase performance is degraded due to both thermal and oscillatorphase noise. To overcome this noise rejection and tracking error present in GNSS Receiver, PLL is designed using optimal and Weiner filter. The paper [3]has used MIMO-OFDM technique which can achieve reliable high data rate transmission over 56 All Rights Reserved © 2015 IJARTET ISSN 2394-3777 (Print) ISSN 2394-3785 (Online) Available online at www.ijartet.com International Journal of Advanced Research Trends in Engineering and Technology (IJARTET) Vol. II, Special Issue XXIII, March 2015 in association with FRANCIS XAVIER ENGINEERING COLLEGE, TIRUNELVELI DEPARTMENT OF ELECTRONICS AND COMMUNICATION ENGINEERING INTERNATIONAL CONFERENCE ON RECENT ADVANCES IN COMMUNICATION SYSTEMS AND TECHNOLOGIES (ICRACST’15) TH 25 MARCH 2015 Fig. 3.1:Proposed broadband wireless channels. Channel state information for System Block Diagram both SISO and MIMO systems based on pilot aided A.Input Data arrangement is also investigated in this paper.In [4] phase The input Data to the OFDM is given in terms of noise and frequency accuracy of the frequency synthesizer high bit stream with 9.6 KHz baud rate. The high bit streams are analysed. The channel efficiency, the frequency are converted to low bit stream by applying data segmentation switching performance and the output spectral purity are technique. investigated at 2.5GHZ.Project [5]deals with the phase noise performance of the PLL CMOS technology which is used to B.Serial to Parallel Conversion analyze the system. The input serial data stream is formatted into the In project [6] avoids significant amplification of the word size required for transmission, e.g. 2 bits/word for reference clock jitter, and loop gain is minimized. Jitter QAM, and shifted into a parallel format. The data is then transfer attenuation techniques through loop filtering and transmitted in parallel by assigning each word to one carrier phase filtering have also been discussed. in the transmission. In the work [7]conventional RF Frequency synthesizer architecture based on a VCO and phase/ frequency detector and charge pump combination, has been replaced with a digitally controlled oscillator.The ADPLL phase noise performance is also significantly improved. In the paper [8]PLLs are used for synchronization technique in grid connection applications and Moving Average filter Based PLL is used to precisely and fastly estimate the phase and frequency when the grid voltage is unbalanced and/ or distorted. III. PROPOSED SYSTEM Block diagram of MIMO-OFDM system using PLL is given as below. Input QAM Coding Interleaving Modulation IFFT P/S FFT P/S O OO S/P Pilot Insertion Cyclic Extension S/P Channel Remove cyclic extension Removal of Pilot data QAM Demodulation Output PLL Decoder Deinterleaving C.Modulation of Data The data to be transmitted on each carrier is then differentially encoded with previous symbols, then mapped into a Phase Shift Keying (PSK) format. Since differential encoding requires an initial phase reference, an extra symbol is added at the start for this purpose. The data on each symbol is then mapped to a phase angle based on the modulation method. For example, for QAM the phase angles used are 0, 90, 180, and 270 degrees. The use of phase shift keying produces a constant amplitude signal and is chosen for its simplicity and to reduce problems with amplitude fluctuations due to fading. D.Inverse Fourier Transform After the required spectrum is worked out, an inverse Fourier transform is used to find the corresponding time waveform. The guard period is then added to the start of each symbol. OFDM uses the available spectrum efficiently by spacing the channels much closer together. This is achieved by making all the carriers orthogonal to one another, preventing interference between the carriers. To generate OFDM successfully the relationship between all carriers must be carefully to maintain the orthogonality of the carriers. For that, after choosing the spectrum required, we have to convert it back to its time domain signal using an Inverse Fourier Transform. In most applications, an Inverse Fast Fourier Transform is used, it performs the transformation very efficiently, and provides a simple way of ensuring the carrier signals produced are orthogonal. E.Guard Period One way to avoid the inter symbol interference is to set a small gap equal to the duration of delay spread between 57 All Rights Reserved © 2015 IJARTET ISSN 2394-3777 (Print) ISSN 2394-3785 (Online) Available online at www.ijartet.com International Journal of Advanced Research Trends in Engineering and Technology (IJARTET) Vol. II, Special Issue XXIII, March 2015 in association with FRANCIS XAVIER ENGINEERING COLLEGE, TIRUNELVELI DEPARTMENT OF ELECTRONICS AND COMMUNICATION ENGINEERING INTERNATIONAL CONFERENCE ON RECENT ADVANCES IN COMMUNICATION SYSTEMS AND TECHNOLOGIES (ICRACST’15) TH 25 MARCH 2015 the symbols. So, each symbol does not affect the next one. The guard period used is made up of two sections. Half of the guard period is a zero amplitude transmission. The other half of the guard period is a cyclic extension of the symbol to be transmitted. This is to allow for symbol timing to be easily recovered by envelope detection. STEP -1: A high speed data with baud rate of 9600 Hz is given as input. I n p u t Da t a 1 0.9 0.8 AWGN is often used as a channel model in which the only impairment to communicate is a linear addition of wideband or white noise with a constant spectral density (expressed as watts per hertz of bandwidth) and a Gaussian distribution of amplitude. The model does not account for fading, frequency selectivity, interference, nonlinearity or dispersion. However, it produces simple and tractable mathematical models which are useful for gaining insight into the underlying behaviour of a system before other phenomena are considered. G.Receiver The receiver basically does the reverse operation to the transmitter. The guard period is removed. The FFT of each symbol is then taken to find the original transmitted spectrum. The phase angle of each transmission carrier is then evaluated and converted back to the data word by demodulating the received phase. The data words are then combined back to the same word size as the original data. 0.6 0.5 0.4 0.3 0.2 0.1 0 0 2000 4000 6000 Time in ms 8000 10000 Fig 5.1 Input data STEP – 2: 9600 bits are separated into hundred 96 low bit data stream. S e g me n t e d D a t a 1 0.9 0.8 0.7 Amplitude in Volt F.Channel noise (AWGN) Amplitude in Volt 0.7 0.6 0.5 0.4 0.3 0.2 IV.SOFTWARE AND ITS DESCRIPTION MATLAB (matrix laboratory) is a multi-paradigm numerical computing environment and fourth-generation programming language developed by MathWorks, MATLAB allows matrix manipulations, plotting of functions and data, implementation of algorithms, creation of user interfaces, and interfacing with programs written in other languages, including C, C++, Java, Fortran and Python. Although MATLAB is intended primarily for numerical computing, an optional toolbox uses the MuPAD symbolic engine, allowing access to symbolic computing capabilities. An additional package, Simulink, adds graphical multi-domain simulation and Model-Based Design for dynamic and embedded systems. MIMO-OFDM system is simulated with the help of MATLAB software. 0.1 0 0 20 40 60 Time in ms 80 100 Fig 5.2 Segmented data STEP – 3: The low bit data’s are encrypted with the help of convolutional encoder for security purpose. V.RESULTS AND DISCUSSIONS This section will suggest the output and its description. 58 All Rights Reserved © 2015 IJARTET ISSN 2394-3777 (Print) ISSN 2394-3785 (Online) Available online at www.ijartet.com International Journal of Advanced Research Trends in Engineering and Technology (IJARTET) Vol. II, Special Issue XXIII, March 2015 in association with FRANCIS XAVIER ENGINEERING COLLEGE, TIRUNELVELI DEPARTMENT OF ELECTRONICS AND COMMUNICATION ENGINEERING INTERNATIONAL CONFERENCE ON RECENT ADVANCES IN COMMUNICATION SYSTEMS AND TECHNOLOGIES (ICRACST’15) TH 25 MARCH 2015 En c o d e d Da t a 1 QA M Mo d u l a t e d D a t a 4.5 0.9 4 0.8 3.5 Amplitude in volt Amplitude in volt 0.7 0.6 0.5 0.4 3 2.5 2 0.3 1.5 0.2 0.1 1 0 0 0 50 100 Time in ms 150 200 10 20 30 Time in ms 40 50 Fig 5.5 QAM modulated signal Fig 5.3 Encoded data STEP – 4: The data sequence is converted into matrix format with the help of matrix interleaver. STEP – 6: In the receiver side, error will occur in first few bits, so cyclic extension is used to convert 64bits into 80 bits Cy c l i c E xt e n d e d Da t a 0.8 I FF T Da t a S u b c a r r i e r S i gn al 1.4 0.6 1.2 0.4 Amplitude in volt Amplitude in volt 1 0.8 0.6 0.4 0 -0.2 0.2 0 0 0.2 -0.4 10 20 30 40 Time in ms 50 60 70 Fig 5.4 Sub carrier signal -0.6 0 10 20 30 40 50 Time in ms 60 70 80 Fig 5.6 Cyclic extended data STEP – 5: The signal is modulated with the help of QAM modulator. STEP – 7: Output without PLL 59 All Rights Reserved © 2015 IJARTET ISSN 2394-3777 (Print) ISSN 2394-3785 (Online) Available online at www.ijartet.com International Journal of Advanced Research Trends in Engineering and Technology (IJARTET) Vol. II, Special Issue XXIII, March 2015 in association with FRANCIS XAVIER ENGINEERING COLLEGE, TIRUNELVELI DEPARTMENT OF ELECTRONICS AND COMMUNICATION ENGINEERING INTERNATIONAL CONFERENCE ON RECENT ADVANCES IN COMMUNICATION SYSTEMS AND TECHNOLOGIES (ICRACST’15) TH 25 MARCH 2015 OF D M S i g n a l t h r o u g h t h e c h a n n e l 1.4 C h a n n e l E s t i ma t i o n 0 10 1.2 -1 10 0.8 Fault Rate Amplitude in volt 1 0.6 -2 0.4 10 0.2 0 0 10 20 30 40 50 Time in ms 60 70 80 -3 10 0 5 10 Fig 5.7 OFDM signal 20 25 Fig 5.9 Output with PLL STEP – 8: Channel estimation without PLL STEP – 10: Comparison between OFDM without PLL and OFDM with PLL C h a n n e l E s t i ma t i o n 2 15 SNR in (dB) 10 C h a n n e l E s t i ma t i o n 2 10 OFDMwithout PLL OFDMwith PLL 1 10 1 Fault Rate 10 Fault Rate 0 0 10 10 -1 10 -2 10 -1 10 1 2 3 4 5 SNR in (dB) 6 Fig 5.8 Output without PLL 7 8 -3 10 0 5 10 15 SNR in (dB) 20 25 Fig 5.10 Comparison between output without PLL and with PLL STEP – 9: Channel estimation with PLL 6.CONCLUSION In MIMO-OFDM systems the interference due to phase noise can be separated into the common phase error (CPE) and the random or ICI term similar to SISO OFDM systems. The CPE can be estimated using pilots and corrected. In a power constrained MIMO system the CPE decreases as more antennas are added. An important system level tradeoff is the issue of correlated v/s uncorrelated phase noise. Presence of correlated phase noise can be corrected to a larger extent than CPE when the phase noise is uncorrelated at the various transmit/receive RF chains. We also showed that in the case of uncorrelated phase noise with pilots dedicated to each data stream performs better than a joint estimate across all the data streams. 60 All Rights Reserved © 2015 IJARTET ISSN 2394-3777 (Print) ISSN 2394-3785 (Online) Available online at www.ijartet.com International Journal of Advanced Research Trends in Engineering and Technology (IJARTET) Vol. II, Special Issue XXIII, March 2015 in association with FRANCIS XAVIER ENGINEERING COLLEGE, TIRUNELVELI DEPARTMENT OF ELECTRONICS AND COMMUNICATION ENGINEERING INTERNATIONAL CONFERENCE ON RECENT ADVANCES IN COMMUNICATION SYSTEMS AND TECHNOLOGIES (ICRACST’15) TH 25 MARCH 2015 REFERENCES [1] Herman Jalli Ng and Alexander Fischer.(2013) ‘A DLL- Supported, low phase noise fractional-N PLL with a wideband VCO and a highly linear frequency ramp generator for FMCW radars’, ReinhardFeger., IEEE transactions on circuits and systems, vol.60, no.12. [2] James T. Curran and Gerard Lachapelle. (2012) ‘Digital GNSS PLL Design Conditioned on Thermal and Oscillator Phase Noise’ Colin C. Murphy, IEEE transactions on aerospace and electronic systems Vol.48, No.1. [3] Kala Praveen Bagadi (2010) ‘MIMO – OFDM channel estimation using pilot carriers’- International journal of computer applications, Vol 2, no.3. [4] Kim Fung Tsang.(2006) ‘A Low Voltage Fast Switching Frequency Synthesizer for FHSS Applications’ Chung Ming Yuen, IEEE transactions on circuits and systems,Vol.53,No.12. [5] Manish Kumar.(2012) ‘Design and Simulation of Low Power Phase Lock Loop for Wireless Communication Applications’ International journal of emerging trends in electronics and computer science, Vol 1,Issue 4. [6] M-J Edward Lee and William J. Dally.(2003) ‘Jitter Transfer Characteristics of Delay Locked Loops-Theories and Design Techniques’ Trey Greer., IEEE journal of solid state circuits, Vol.38,No.4. [7] Robert BogdanStaszewski and John L.Wallberg.(2005) ‘All Digital PLL and Transmitter for Mobile Phones’ SamehRezeq., IEEE journal of solid state circuits, Vol.40,No.12. [8] SaaeedGolestan and MalekRamezani. (2014) ‘Moving Average Filter Based Phase Locked Loops: Performance Analysis and Design Guidelines’ Josep M. Guerrero., IEEE transactions on power electronics Vol.29, No.6. [9] YaoHong Liu.(2009) ‘A Wideband PLL Based G/FSK Transmitter in 0.18um CMOS’ TsungHsien Lin, IEEE journal of solid state circuits, Vol.44,No.9. 61 All Rights Reserved © 2015 IJARTET