0.75 V micro-power SI memory cell with feedthrough error reduction

A simple technique to realise a switched current memory cell operating from low supply voltage (0.75 V) with clock-feedthough (CFT) error reduction is presented. Unlike previous techniques that try to minimise current error by compensation at the output, this technique prevents the occurrence of current error by removing the feedthrough voltage from the input port of the memory transistor directly. As a result, the CFT error current at the output is almost completely eliminated employing a simple and compact circuit structure. Simulation results are given, showing good agreement to the theory.     

Optimal resynchronization marker positioning method using a novel information measure

This paper presents a new resynchronization marker (RM) positioning technique to effectively block the error propagation caused by channel errors. The optimal technique can be defined as the one minimizing the information loss under an error condition. For realization of the optimal technique, the amount of the information lost by errors needs to be measured. Thus, we introduce a novel measure that is successful in reflecting the actual importance of the lost data, which is measured by using error concealment techniques. That is, the amount of information lost by an error at a certain location is numerically specified by the difference between the image recovered by the error concealment and the image normally decoded without any error. Since such a measurement method is appropriate for reflecting the actual damage by errors, it is very useful for determining the RM positions. With the new measure, the optimal RM positioning technique is proposed and verified by experiments.     

Robust transmission based on variable-rate error control andgenetic programming

This paper presents a novel variable-rate error control design algorithm matched to full-search vector quantizers (VQs) for robust transmission. In the algorithm, different locations of binary strings obtained from VQ encoders are protected by channel codes with different protection levels. The degree of protection at each location is determined by a genetic programming technique minimizing the end-to-end average distortion of transmission systems. The technique outperforms the equal error protection method. Moreover, as compared with a full search algorithm for optimal unequal error protection, our technique attains comparable performance with significantly lower computational complexities     

Tracking of fast-fading channels in long-code CDMA

A new technique for blind tracking of fast-fading channels in long-code code division multiple access (CDMA) is proposed by exploiting multipath diversity. Based on a linear interpolation channel model, the proposed method blindly identifies a time-varying channel at arbitrary estimating points within a block up to a scale factor and increases bandwidth efficiency allowing only one pilot symbol within a block, which is much larger than channel coherence time. The proposed method can be implemented using an efficient state-space inversion technique for multiuser cases. The mean square error (MSE) performance of the proposed estimator is compared with the Cramer-Rao bound (CRB) for interpolated channel. Modeling error and bit error rate (BER) are also evaluated using Monte-Carlo simulations and compared with the block fading model and a decision-directed tracking technique.     

A 200 mA CMOS low-dropout regulator with double frequency compensation techniques for SoC applications

This paper presents a 200 mA low-dropout(LDO) linear regulator using two modified techniques for frequency compensation.One technique is that the error amplifier uses a common source stage with variable load, which is controlled by the output current,is served as the second stage for a stable frequency response.The other technique is that the LDO uses a pole-zero tracking compensation technique at the error amplifier to achieve a good frequency response.The proposed circuit was fabricated and tested in HJTC 0.18μm CMOS technology. The designed LDO linear regulator works under the input voltage of 2.8-5 V and provides up to 200 mA load current for an output voltage of 1.8 V.The total error of the output voltage due to line and load variation is less than 0.015%.The LDO die area is 630×550μm~2 and the quiescent current is 130μA.     

复杂流场的代数迭代重建算法

提出了简单自相关代数迭代重建算法（SSART）。采用数值模拟的方法,对当前有代表性的基本代数迭代法（ART）、联合代数迭代法（SART）、改进的联合代数迭代法（MSART）以及SSART进行了计算模拟,对比分析了各种算法的模拟效果和重建精度。结果发现,SSART的均方误差（MSE）在10^-4数量级,比ART的降低了78．2％;峰值相对误差（PE）在10^-2,降低了92．9％;计算程序上,SSART仅比ART多1个除数因子。所以SSART具有算法简单、重建精度高、稳定性好和自愈能力强等优点。     

A technique for extrapolating the end-to-end performance of HDLClinks for a range of lost packet rates

A technique based on importance sampling is presented for extrapolating the end-to-end delay performance of a high-level data link control (HDLC) network. The lost packets can arise from bit errors or discarding due to network congestion. The technique works well for a substantial range of loads, as long as the desired performance is at an error rate less than the observed rate (the environment most frequently encountered). It is applicable across a range of error rates. The technique was tested on a simple HDLC link but would generalize to other link-level protocols. The extrapolation technique can be based on simulation or measurement. Simulation results are presented to demonstrate its effectiveness     

Performance of STTC-MC-CDMA Systems with Imperfect Channel Estimation

Since, in a practical system perfect channel state information (CSI) is not possible due to presence of noise. This paper deals with the performance of space-time trellis code (STTC) in multi-carrier code-division multiple-access systems in presence of channel estimation (CE) error and results are compared with perfect CSI at the receiver. The pilot symbol assisted (PSA) technique is used for CE employing minimum mean-square error method. The symbol error rate (SER) performance is observed by employing Viterbi decoding algorithm to decode STTC code at the receiver in multi-path fading channel. The simulated SER performances in presence of CE error and with perfect CSI are compared with the theoretical performances to validate the theoretical analysis.     

Low sampling rate technique based frequency-domain random demodulation for broadband digital predistortion

This paper proposes a combination technique of the frequency-domain random demodulation (FRD) and the broadband digital predistorter (DPD). This technique can linearize the power amplifiers (PAs) at a low sampling rate in the feedback loop. Based on the theory of compressed sensing (CS), the FRD method preprocesses the original signal using the frequency domain sampling signal with different stages through multiple parallel channels. Then the FRD method is applied to the broadband DPD system to restrict the sampling process in the feedback loop. The proposed technique is assessed using a 30 W Class-F wideband PA driven by a 20 MHz orthogonal frequency division multiplexing (OFDM) signal, and a 40 W GaN Doherty PA driven by a 40 MHz 4-carrier long-term evolution (LTE) signal. The simulation and experimental results show that good linearization performance can be achieved at a lower sampling rate with about 24 dBc adjacent channel power ratio (ACPR) improvement by applying the proposed combination technique FRD-DPD. Furthermore, the performance of normalized mean square error (NMSE) and error vector magnitude (EVM) also has been much improved compared with the conventional technique.     

Generalized burst-trapping codes

The burst-trapping error control technique developed by Tong [1] corrects both random and burst errors adaptively. A generalization of this scheme, called generalized burst trapping (GBT), is presented here. Generalized burst-trapping codes (GBTC) also correct both random and burst errors adaptively but, in addition, are capable of correcting random errors in the guard space following a correctable burst. This added capability is obtained at the expense of a longer guard space or a lower rate and a modest increase in complexity of implementation. Nevertheless, these codes are simple to encode and decode and, in particular, the storage-saving technique used with the original burst-trapping codes is directly applicable to the generalized codes. Also it is shown that at most one block of error propagation can occur if a simple and reasonable condition is met. Thus the generalized codes have better propagation properties than the original burst-trapping codes. This new error control technique is well suited to error correction on channels where it cannot be assumed that bursts are isolated events separated by error-free intervals. Thus, for example, this technique appears well suited to error correction on telephone facilities that incorporate multiple-level signaling.     

Image Error Concealment Using Watermarking with Subbands for Wireless Channels

Transmission of block-coded images through error-prone wireless channels often results in lost blocks. In this study, we investigate a novel error concealment method for covering up these high packet losses and reconstructing a close approximation. Our scheme is a modified discrete wavelet transform (DWT) technique (namely, subbands based image error concealment (SIEC)) for embedding downsized replicas of original image into itself. We propose that this technique can be implemented for wireless channels to combat degradations in a backward-compatible scheme. We show that the proposed error concealment technique is promising, especially for the erroneous channels causing a wider range of packet losses, at the expense of computational burden     

Analysis of the error performance of trellis-coded modulations inRayleigh-fading channels

This work presents an exact expression for the pairwise error event probability of trellis-coded modulation (TCM) transmitted over Rayleigh-fading channels. It includes phase shift keying (PSK) and multilevel quadrature amplitude modulation (QAM) codes, as well as coherent and partially coherent (e.g. differential, pilot tone, etc.) detection. Due to the form of the exact pairwise error event probabilities, this calculation technique cannot be used with the transfer function technique to obtain an upper (union) bound on the overall bit error probability. For this reason, the authors estimate the bit error probability by considering only a small number of short error events. Through simulations, they found that the estimation is usually very accurate at high signal-to-noise ratios but not as accurate at lower signal-to-noise ratios. They study several coded modulation schemes this way. Among the results are the fact that TCM provides significant improvement in the error floor when detected differentially, and an asymmetry in the pairwise error event probability for 16 QAM     

Pilot symbol-assisted detection of CPM schemes operating in fastfading channels

We present a coherent detection technique for continuous phase modulation (CPM) operating in the Rayleigh flat fading channel. The technique is based on the idea of inserting periodically data dependent pilot symbols that force the CPM signal to pass through known phase states. This transmission format enables the receiver to extract from the received signal the channel fading gains at regularly spaced instants. When coupled with proper channel estimation filters, very accurate channel state information (CSI) can be estimated at the receiver for fading compensation. Moreover, the accuracy of the CSI can be further refined by adopting a multiple-pass decoding approach. The paper discusses (a) the pilot symbol encoding technique required to force a M-level CPM scheme with a modulation index of p/M, p is an integer, to return periodically to a set of known phase states, (b) the optimal channel estimation filters, (c) a trellis-based precoding technique that can reduce the bit error rate in M-level CPM systems by close to 50%, and (d) a multiple-pass channel estimator/demodulator. Analytical and simulation results are presented for minimum shift keying (MSK), Gaussian MSK, and four-level continuous phase frequency shift keying with a modulation index of 1/4. It is observed that our pilot symbol-assisted CPM schemes exhibit no irreducible error floor even at a channel fade rate of three percent the symbol rate. The implicit phase coding in CPM and the accurate CSI provided by the pilot symbols lead to a diversity effect in the bit error rate curves of these modulation schemes     

Improved current-regulated delta Modulator for reducing switching frequency and low-frequency current error in permanent magnet brushless AC drives

The conventional current-regulated delta modulator (CRDM) results in a high current ripple and a high switching frequency at low rotational speeds, and in low-frequency current harmonics, including a fundamental current error, at high rotational speeds. An improved current controller based on CRDM is proposed which introduces a zero-vector zone and a current error correction technique. It reduces the current ripple and switching frequency at low speeds, without the need to detect the back-emf, as well as the low-frequency error at high speeds. The performance of the modulator is verified by both simulation and measurements on a permanent magnet brushless ac drive.     

An error-protected speech recognition system for wirelesscommunications

Future wireless multimedia terminals will have a variety of applications that require speech recognition capabilities. We consider a robust distributed speech recognition system where representative parameters of the speech signal are extracted at the wireless terminal and transmitted to a centralized automatic speech recognition (ASR) server. We propose two unequal error protection schemes for the ASR bit stream and demonstrate the satisfactory performance of these schemes for typical wireless cellular channels. In addition, a "soft-feature" error concealment strategy is introduced at the ASR server that uses "soft-outputs" from the channel decoder to compute the marginal distribution of only the reliable features during likelihood computation at the speech recognizer. This soft-feature error concealment technique reduces the ASR error rate by more than a factor of 2.5 for certain channels. Also considered is a channel decoding technique with source information that improves ASR performance     

Characterizing,modeling, and analyzing soft error propagation in asynchronous and synchronous digital circuits

Soft errors, due to cosmic radiations, are one of the major challenges for reliable VLSI designs. In this paper, we present a symbolic framework to model soft errors in both synchronous and asynchronous designs. The proposed methodology utilizes Multiway Decision Graphs (MDGs) and glitch-propagation sets (GP sets) to obtain soft error rate (SER) estimation at gate level. This work helps mitigate design for testability (DFT) issues in relation to identifying the controllable and the observable circuit nodes, when the circuit is subject to soft errors. Also, this methodology allows designers to apply radiation tolerance techniques on reduced sets of internal nodes. To demonstrate the effectiveness of our technique, several ISCAS89 sequential and combinational benchmark circuits, and multiple asynchronous handshake circuits have been analyzed. Results indicate that the proposed technique is on average 4.29 times faster than the best contemporary state-of-the-art techniques. The proposed technique is capable to exhaustively identify soft error glitch propagation paths, which are then used to estimate the SER. To the best of our knowledge, this is the first time that a decision diagram based soft error identification approach is proposed for asynchronous circuits.     

Retransmission Error Control with Memory

Automatic-repeat-request (ARQ) is one of the most commonly used error control techniques today. In this paper, an error control technique that is a basic improvement over ARQ is presented. The technique uses the simple idea of utilizing erroneously received blocks in an ARQ system for error control, retaining most of the other aspects of ARQ. The technique is termed ARQ-with-memory (MRQ). The general MRQ system is described, and simple upper and lower bounds are derived on the throughput achievable by MRQ. The performance of MRQ with respect to throughput, message delay and probability of error is compared to that of ARQ by simulating both systems using error data from a VHF satellite channel being operated in the ALOHA packet broadcasting mode [9].     

CFCET: A hardware-based control flow checking technique in COTS processors using execution tracing

This paper presents a behavioral-based error detection technique called control flow checking by execution tracing (CFCET) to increase concurrent error detection capabilities of commercial off-the-shelf (COTS) processors. This technique traces the program jumps graph (PJG) at run-time and compares it with the reference jumps graph to detect possible violations caused by transient faults. The reference graph is driven by a preprocessor from the source program.The idea behind the CFCET is based on using an external watchdog processor (WDP) and also the internal execution tracing feature available in COTS processors to monitor the addresses of taken branches in a program, externally. This is done without any modification of application programs, thus, the program overhead is zero. This technique is analytically evaluated based on three different fault models. The results show that the error detection coverage varies between 79.74% and 96.43% depending on the different workload programs. The errors are detected with about zero latency. The external hardware overhead is about 3% using the Altera flex 10K30 FPGA and the execution time overhead is between 33.26% and 140.81% for different workload programs. The overheads have been measured experimentally by executing the workloads on a Pentium system.     

Semianalytic BER evaluation by simulation for noisy nonlinearbandpass channels

The bit error rate (BER) of channels including a memoryless bandpass nonlinearity is evaluated by simulation. This would typically be an onboard travelling wave tube (TWT) amplifier in a satellite repeater, when the noise at the input of such a nonlinear element is non-negligible. The usual evaluation technique, error counting, requires a large amount of computer time if small error probabilities are to be estimated. It is shown that faster semianalytic procedures can be used, provided that a proper model for the nonlinear element is adopted. The output process is decomposed into a signal component plus an additional term representing an equivalent noise component, and an equivalent nonlinear transformation, relating the input useful signal to the output signal component, is derived. In addition, several modes for the probability density function (PDF) of the uplink noise component at the output of the transmission chain are discussed and compared. The procedure has been tested on a transparent satellite link using 4-CPSK modulation format. The results compare well with those of the error-counting technique if a composite rectangular PDF with exponential tails as adopted