a novel weighted subspace fitting cfo estimation in the ofdm
Transcription
a novel weighted subspace fitting cfo estimation in the ofdm
Volume 2, Issue 4 MAY 2015 A NOVEL WEIGHTED SUBSPACE FITTING CFO ESTIMATION IN THE OFDM SYSTEMS K. LIGI (PG Scholar) 1 Mr. P. GIRIBABU, M.TECH2 1 2 Department of Electronics and Communication Engineering Associate Professor, Department of Electronics and Communication Engineering ABSTRACT Whenever we INTRODUCTION are designing the wireless communication systems that must possess of high reliability and low latency and also the optimization when switching is takes place in different circuits. and in that system it contains of lot of hardware impairments regarding power supply . when the supply load changes in circuit suddenly the carrier frequency drifts it results in transient carrier frequency offset(CFO) in cannot be estimated by using of the traditional estimators and is typically addressed by inserting or extending guard intervals. In this paper we are presenting the modeling and estimation of the transient CFO , which is modeled as the response of an under damped second order system. To compensate for the transient CFO, we are proposed a low complexity parametric estimation algorithm by using of the null space of Hankel-like matrix. It was constructed from the phase difference of the two halves of the repetitive training sequence. Here a weighted subspace fitting algorithm is derived with a slight increase in complexity to minimize the mean squared error of the estimated parameters in Since cooperation was first projected for wireless networks, it's communications performance become and gains a preferred networking for area analysis. cooperation stem of The from mitigating long path-loss and shadowing ef fects and short multipath fading effects. The combined path-loss of a two-hop transmission is also but direct transmission, and RF absorbing objects within the atmosphere are often circumvented to scale back shadowing. this can be analogous to multi-hop routing and might be performed at either net work (NET) or medium access (MAC) layer, with larger potency at the latter. Relaying also can give a receiver with redundant messages that travel through spatially distinct ways, reducing the impact of multipath. This creation of special diversity, referred to as cooperative diversity, provides better average performance and might be achieved at either the mack or physical (PHY) layer, with larger performance gains at the latter. the tip results of path-loss and variety gains provided through cooperation is improved network performance, realizable as varied combinations of noise. IJOEET 32 Volume 2, Issue 4 MAY 2015 power savings, rate will increase, network coverage protocols. Experimentation is a chance to get growth, and interference reduction. A number of realistic quantifications of performance gains for characteristics of cooperative schemes make planned cooperative schemes in actual propagation experimentation essential for transitioning proposed environments and network topologies. schemes to practical applications. Information flowing through a cooperative link visits multiple nodes Finally, modeling and simulation typically create idealistic assumptions regarding the capabilities Within the network, suggesting cooperation of the physical radio platforms on that planned can have implications for multiple layers of the protocols ar to be run. Common limitations in realprotocol stack, together with at a minimum the PHY, world radios like a scarcity of frequency and temporal MAC, and internet layers. Decisions made at one layer arrangement can impact the potency of the others, increasing estimation, and quantization errors have an oversized protocol quality opportunities however for providing cross-layer synchronization, imperfect channel several impact on the effectiveness of the many cooperative improvement. schemes. though a considerable quantity of the Performance metrics to guage such cross-layer literature addresses these problems directly, schemes, like output and delay at the mack and experimentation is that the solely thanks to establish internet layers, need giant networks to get realistic alternative impediments and make sure devised estimates. Modeling and simulation will become solutions are so solutions. unwieldy because the variety of nodes at intervals a network grows, creating experimentation “one of the Proposed method: factual approaches for benchmarking”. complicated The Traditional CFO Estimation: interactions between layers will be not possible to fully We assume that the receiver estimates the CFO through predict, creating full implementation necessary to spot the preamble OFDM symbol, whose first and second conflicts that will degrade performance. halves are identical. Cooperative gains determined by theoretical work and simulation vary considerably relying upon Then, we can express the transmitted preamble signal as the models chosen for the network topology and therefore the wireless channel. Real-world propagation environments area unit notoriously difficult to model; the foremost faithful models quickly become cross-layer nature of cooperation, and experimentation becomes the sole sensible thanks to measure full IJOEET 0≤ ≤ ≤ ≤2 (1) Where T is the time interval between the two halves. Thus, the received signal impaired by CFO can be written as intractable for each theoretical work and simulation. increase this the multi-layer simulation needed by the ( ) ( − ) ( )= ( )= ∫ ( ) ∞ ℎ( ) ( − ) + ( ) ∫ ∆ ( ) + (2) Where h(t) is the channel response, s(t) is the 33 Volume 2, Issue 4 MAY 2015 transmitted preamble and n(t)andˇ n(t) are the additive , ∆ ( ) = sin 1− + > 0, Gaussian noise at the receiver before and after RF 0 < < 1 (5) down-conversion, respectively. Δω(t) is the CFO Where ζ and are the damping factor and undamped between the transmitter and receiver. ˇ n(t)is much less natural frequency, respectively.0< ζ<1means that the than n(t). Hence, we drop this noise term thereafter. second order system is underdamped .φ and α are the For the traditional CFO estimation, we assume that the initial phase and gain of the response, respectively. CFO is constant, then (2) reduces to To model the transient CFO, we define the ∞ ( )= ℎ( ) ( − ) ∆ + ( ) 0 overall CFO in terms of two parts: a transient CFO and a steady state CFO. We assume that the steady state CFO, denoted by ΔωS, is constant during the preamble (3) ≤ ≤2 The first and second halves of the received preamble OFDM symbol. Then, the overall CFO can be written as Δω(t)=Δ (t)+Δ . Thus, the received signal can be written as ( )= ∫ ∞ ℎ( ) ( − ) + ∆ ( ) 0≤ ( )= ≤ ∫ ( )= ∫ become ∞ ℎ( ) ( − ) + ( ) ∆ ( ) 0≤ ≤ ∞ ( ) ℎ( ) ( − ) ( ) ∆ (∆ ∫ + ) (6) In this paper, we assume that the steady state Where n1(t) and n2(t) are the additive noise in CFO is estimated and removed from the baseband r1(t) and r2(t), respectively. Therefore, the first and signal to simplify the estimation of the transient CFO. second halves of the received preamble symbol have a This assumption is reasonable in practice since a fixed phase difference of Δω Tin sample-wise with the terminal first detects the downlink preamble signal to absence of the additive noise. The traditional CFO obtain the time synchronization, the steady state CFO, estimation is to compute this fixed phase difference. and other necessary information to access to the The maximum likelihood estimation of the CFO, wireless network during the initialization stage. The terminal stays in RX state during this stage and does denoted by Δˆω , is ∆ = ∠(∑ ∗( ) ( )) not have to be running in TDD mode. (4) Let us now consider the received preamble symbol in Transient CFO Model: Then, we claim that the two halve transient CFO, denoted by Δω T(t), can be model as the step response of a second order underdamped ( )= ∫ IJOEET ℎ( ) ( − ) ( ) + ∫ ∆ ( ) ( )= system, which can be expressed as an exponentially damped sinusoid, i.e. ∞ ∫ ∞ ℎ( ) ( − ) + ( ) ∫ ∆ ( ) 34 Volume 2, Issue 4 MAY 2015 The phase difference between the first and second The prediction filter order, L, which is also the number halves is denoted by ψ(t) of columns of the Hankel matrix, is chosen to optimize ( )=∠ ∗( ) ( ) the estimation performance in the subspace based linear prediction problems, such as the Kumaresan– = ( ) ∆ + ( ) (7) ( ) is the noise term in the phase difference. Where Tuft (KT) method ,and matrix pencil method . the first order perturbation analysis for the KT method as ( Note that ψ(t) is just the definite integral of the )≈ 4 3 ( − ) 1≤ transient CFO over interval[t, t+T]. Then ψ(t)is still an ≤ exponentially damped sinusoid with the same damping The proposed subspace based algorithm is described − factor and frequency, but different initial phase and below. gain, i.e., ( )= We construct the prediction matrix: ∆ ( ) + = + ( ) sin + ( ) 1− (0) (1) ⋮ ( − 2 − 1) = ( ) ( + 1) ⋮ ( − − 1) (2 ) (2 + 1) ⋮ ( − 1) (8) (9) Subspace Based Estimation of a and : Wr is a Hankel-like matrix composed of noise, i.e. Estimating the parameters of damped sinusoid (0) (1) ⋮ ( − 2 − 1) has been extensively. The existing algorithms are, ⎡ however, rather generic and can be generally put into = ⎢ ⎢ ⎢ four categories: direct fitting in time domain using ⎣ signal samples, direct fitting in frequency domain with DFT based algorithms, covariance based linear prediction, and subspace(SVD) based linear prediction. Then, the complex roots of the prediction Assume that the singular value decomposition (SVD) of is =[ ] Performance = (0) (1) ⋮ ( − − 2) IJOEET (1) ⋯ (2) ⋯ ⋮ ⋱ ( − − 1) ⋯ ( − 1) ( ) ⋮ ( − 1) ( + 1) ⋮ ( − − 1) (2 ) ⎤ (2 + 1) ⎥ ⎥ ⋮ ⎥ ( − 1) ⎦ (10) polynomial are found to compute the damping factor and frequency. ( ) 0 0 = Analysis and 0 (11) Weighted Subspace Fitting: The WSF algorithm is proposed based on the perturbation analysis of the subspace based estimator. We use the first order subspace perturbation analysis 35 Volume 2, Issue 4 MAY 2015 The Hankel-like matrix is are = + , where 0 = defined + and Where = 0 ( ) ⎡ =⎢ ⎢ ⎣ ( ) (12) is a Vandermonde matrix defined as 1 ( ( 1 ) . . ( )( ) ( ) . . )( ) ⎤ ⎥ ⎥ ⎦ (20) a first-order approximation of the perturbation at high SNR is given by ∆ Estimation of the Initial Phase and Gain :Observe (13) ≈ − Assumev0=[ , , that the noise of the phase difference vector is not ] T. Defining the instantaneous SNR as ρ(nTs),we have Assume the covariance matrix of ψ is R, and the [ ], = | | ( ) [ ], positive definite matrix R−1 can be factored as | + | ( ( ( ( (14) ) ( covariance matrix of Sψ is an identity matrix. The (16) ) estimation of r with prewhitened least squares method We propose a weighted subspace fitting method in is order to reduce the MSE of the estimatedv0. The weighted subspace fitting can be modeled as = = + (21) = Then S acts as a prewhitening matrix since the (15) ) ∗ = | ∗ + ) | + ) ∗ = [ ], white. We can use a whitening solution as follows. ( ) ̂= ( ) ( ) (22) EXPERIMENTAL RESULTS (17) 4 Estimated Original 3 2 Selection of Time Lag r : In constructing the matrix Sigh 1 Hr, it is important to select the time lag r. 0 In this section, we investigate the best strategy to -1 -2 select r. Let us recall that the mean square error of -3 0 ΔvD in ‖ ]= ( ) ≤ (( ) 10 (( ( )∑ ≤ ) ) ( ( The sample covariance matrix of noise free matrix Hr →∞ = ( ) ( ) (19) 40 50 Time 60 70 80 90 100 -3 10 10 -4 -5 is asymptotically equivalent to lim 30 ) (18) ) 20 Figure: compaison between original And estimated signals ) --MSE of damping Factor [‖∆ 10 10 Proposed KT MP CRB -6 5 10 15 20 25 30 ---SNR figure: Comparison of the MSE of the estimated damping IJOEET 36 Volume 2, Issue 4 MAY 2015 --MSE of Estimated Frequency 10 10 10 10 -3 -4 -5 Proposed KT MP CRB -6 5 10 15 20 ---SNR between SNR to MSE Figure: plot frequencies estimation Figure : no CFO correction 32 26 24 Proposed with WSF Without WSF No Compensation 30 28 Proposed with WSF No Compensation Without WSF 22 Estimated SNR Estimated SNR 26 20 18 16 24 22 20 14 18 12 16 10 14 14 16 18 20 22 ---Input snr 24 26 28 Figure: Estimated SNR 12 14 16 18 20 22 ---Input snr 24 26 28 Figure: Extension under SUI channel Figure: after CFO correction without WSF CONCLUSION: Here in this paper we are analyzed a unique problem in the wireless communication system i.e. CFO (carrier frequency offset).it was mainly observed in switching systems of transmitter and receiver .to reduce this problem we are proposed a algorithm based on the subspace decomposition of the Hankel-like matrix. 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