Wave-pipeline Technique Research Articles

Design and Analysis of (5, 10) Regular LDPC Encoder Using MRP Technique

An efficient compact encoding process with the pipelining design of Low Density Parity Check (LDPC) Encoder with a two stage, three stage and Maximal Rate Pipelining (MRP) structures are proposed in this work. Comparatively, LDPC encoding is more complex than decoding. The complexity mainly referred to the mathematical computation involved in the design of LDPC encoder. There are several methods used to design reduced parity check matrix, one of the methods involved is the Gauss Elimination method. Conventional and wave pipelining techniques are implemented to overcome the disadvantages of the area, latency, etc., The designed architectures are synthesized in SYNOPSYS tool and implemented in the XC3S-250E FPGA device. The overheads like power and area are efficiently reduced by wave pipelining and their efficiency can be proved by synthesis report. This showcases that the LDPC Encoders require less memory by using MRP structure.

Wave Pipelined VLSI Architecture for a Viterbi Decoder Using Self Reset Logic with 0.65nm Technology

In 3G mobile terminals the Viterbi Decoder consumes approximately one third of the power consumption of a base band mobile transceiver. Viterbi decoders employed in digital wireless communications are complex and dissipate large power. A low power Viterbi decoder is designed in circuit level using self reset logic and wave pipelining technique is implemented for high speed operation. The Viterbi decoder consists of four units like branch metric unit, add compare and select unit and the survivor path memory unit. All these units are designed using the self reset logic and wave pipelining, and simulated with its layout using MICROWIND TOOL in the 0.65nm technology, 1.8V Vdd and at a frequency of 10GHz. The simulation result shows that the power consumption is reduced by 70.55% and the speed of the circuit is increased by 45.83% compared to the Single Rail Domino Logic for constraint length of K =3 to 7.

Wave Pipelined Structure for Pipelined FFT Architecture

Wave Pipelining has been used in order to reduce the area without degrading its performance and also to improve the speed. In pipelining the throughput is achieved with the compensation of area and the critical path will be same as the original architecture. While considering of larger circuits the area places an important role where the cost is a major issue. Hence in order to reduce the area the latches are removed which produces the technique of wave pipelining. The concept of Wave Pipelining optimize the area and speed when compared to the pipelining architectures. Thus the Wave Pipelining is applied in the FFT architecture for achieving less area. The FFT pipelined architecture is based on splitting the architecture by stages. Each stage is evaluated with effective structure. It’s noted that by using the internal clock which increases both speed and reduces clock loads the number of gates used in the pipelined structure is reduced in using wave pipelining. The Wave Pipelining technique have to be implemented in a 32-bit FFT Pipelined architecture which is suitable for a digital signal processing applications for image processing and for conversion of frequency domain to time domain. And to compare the area and speed of the WP architecture and pipelined architecture.

14 GSps Four-Bit Noninterleaved Data Converter Pair in 90 nm CMOS With Built-In Eye Diagram Testability

This paper presents the design and test of a 14 GSps, four-bit data converter pair in 90 nm CMOS suitable for implementing advanced serial links. The data converter pair consists of a noninterleaved flash analog-to-digital converter (ADC) and a noninterleaved current-steering digital-to-analog converter (DAC). Both the converter designs adopt the wave-pipelining technique to increase the available signal settling time. Through detailed analysis, we show that cascading three active feedback preamplifiers to implement the cores of the comparators in the ADC balances the power budget and the design difficulty when we push the sampling rate to the process limit. Current mode logic gates are used to alleviate the power bouncing issue. To address the difficulty and high cost of testing the extremely high-speed converters, the design embeds the simple design-for-testability circuits cooperating with the on-chip resources to provide two cost-effective test modes. The first test mode cascades the ADC and DAC so that they can be tested at the rated speed without the need of a very high speed logic analyzer. The second test mode enables the eye diagram tests by shuffling the digital outputs of ADC as the inputs of the DAC instead of adopting conventional linear feedback shift register. The experimental results show that the cascaded ADC and DAC pair achieves a 31.0 dBc spurious-free dynamic range and a 25.9 dB signal-to-noise-and-distortion ratio with a 1.11 GHz, -1 dBFS stimulus at 14 GSps. The ADC and DAC consume 214 mW and 85 mW from a 1.0-V supply and occupy 0.1575 mm <sup xmlns:mml="http://www.w3.org/1998/Math/MathML" xmlns:xlink="http://www.w3.org/1999/xlink">2</sup> and 0.0636 mm <sup xmlns:mml="http://www.w3.org/1998/Math/MathML" xmlns:xlink="http://www.w3.org/1999/xlink">2</sup> , respectively.

An Improved Direct Digital Synthesizer Using Hybrid Wave Pipelining and CORDIC algorithm for Software Defined Radio

The improved Direct Digital Synthesizer (DDS) using the Hybrid Wave Pipelining (HWP) technique and COordinate Rotation DIgital Computer (CORDIC) algorithm for Software Defined Radio (SDR) is presented in this paper. In order to achieve high throughput, the hybrid wave pipelining technique is adopted. The HWP can be used to speed up the circuits without insertion of storage elements. The CORDIC algorithm is used for phase-to-amplitude conversion and utilized for dynamic transformation rather than Read Only Memory (ROM) static addressing. The frequency resolution and phase resolution are achieved as 0.023 Hz and 0.088 degree, respectively, at the maximum operating frequency of 199.288 MHz for the proposed DDS architecture. The spectral purity of the proposed design has been improved to 114 dBc with a throughput of 94 %. This paper is focused on the design and implementation of DDS using hybrid wave pipelining with CORDIC approach to target on Xilinx Spartan 3 (XC3S400-5PQ208) Field Programmable Gate Array (FPGA) with a speed grade of −5. The proposed DDS design reduces the gate count from 49.4 % to 18.2 % as compared to the conventional pipelined Read Only Memory Look Up Table (ROMLUT) DDS method. The throughput of the proposed method has been improved from 78 % to 94 % and 55 % of total power reduction as compared with conventional DDS. The performance of the improved DDS architecture is compared with several existing DDS architectures and it is found that the present design is outperforming and can be used for software defined radios.

Reliability Modeling and Analysis of Clockless Wave Pipeline Core for Embedded Combinational Logic Design

This paper presents a model for analyzing the reliability of a clockless wave pipeline as an intellectual property (IP) core for embedded design. This design requires different clocking requirements by each embedded IP core during integration. Therefore, either partial or global lack of synchronization of the embedded clocking is considered for the data flow. The clockless wave pipeline represents an alternative to a traditional pipeline scheme; it requires an innovative computing model that is readily suitable for high-throughput computing by heterogeneous IP logic cores embedded in system-on-chip (SoC). A clockless wave pipeline technique relies on local asynchronous operation for seamless integration of a combinational core into an SoC. The basic computational components of a clockless wave pipeline are the datawaves, together with the request signals and switches. The coordination of the processing of the datawaves throughout the pipeline by the request signals is accomplished with no intermediate access in the clock control. Furthermore, the reliability of clockless-wave-pipeline-based cores is of importance when designing a reliable SOC. In this paper, the <i xmlns:mml="http://www.w3.org/1998/Math/MathML" xmlns:xlink="http://www.w3.org/1999/xlink">reliability</i> in the clockless operations of the wave pipeline is analyzed by considering the datawaves and the request signals. The effect of the so-called out-of-orchestration between the datawaves and the request signals (which is referred to as a <i xmlns:mml="http://www.w3.org/1998/Math/MathML" xmlns:xlink="http://www.w3.org/1999/xlink">datawave fault</i> ) is proposed in the reliability analysis. A clockless-induced datawave fault model is proposed for clockless fault-tolerant design.

VLSI Implementation of Hybrid Wave-Pipelined 2D DWT Using Lifting Scheme

A novel approach is proposed in this paper for the implementation of 2D DWT using hybrid wave-pipelining (WP). A digital circuit may be operated at a higher frequency by using either pipelining or WP. Pipelining requires additional registers and it results in more area, power dissipation and clock routing complexity. Wave-pipelining does not have any of these disadvantages but requires complex trial and error procedure for tuning the clock period and clock skew between input and output registers. In this paper, a hybrid scheme is proposed to get the benefits of both pipelining and WP techniques. In this paper, two automation schemes are proposed for the implementation of 2D DWT using hybrid WP on both Xilinx, San Jose, CA, USA and Altera FPGAs. In the first scheme, Built-in self-test (BIST) approach is used to choose the clock skew and clock period for I/O registers between the wave-pipelined blocks. In the second approach, an on-chip soft-core processor is used to choose the clock skew and clock period. The results for the hybrid WP are compared with nonpipelined and pipelined approaches. From the implementation results, the hybrid WP scheme requires the same area but faster than the nonpipelined scheme by a factor of 1.25–1.39. The pipelined scheme is faster than the hybrid scheme by a factor of 1.15–1.39 at the cost of an increase in the number of registers by a factor of 1.78–2.73, increase in the number of LEs by a factor of 1.11–1.32 and it increases the clock routing complexity.

Automation techniques for implementation of hybrid wave-pipelined 2D DWT

In the literature, techniques such as pipelining and wave-pipelining (WP) are proposed for increasing the operating frequency of a digital circuit. In general, use of pipelining results in higher speed at the cost of increase in the area and clock routing complexity. On the other hand, use of WP results in less clock routing complexity and less area but enables the digital circuit to be operated only at moderate speeds. In this paper, a hybrid wave-pipelining scheme is proposed to get the benefits of both pipelining and WP techniques. Major contributions of this paper are: proposal for the implementation of 2D DWT using lifting scheme by adopting the hybrid wave-pipelining and proposal for the automation of the choice of clock frequency and clock skew between the input and output registers of wave-pipelined circuit using built in self test (BIST) and system-on-chip (SOC) approaches. In the hybrid scheme, different lifting blocks are interconnected using pipelining registers and the individual blocks are implemented using WP. For the purpose of evaluating the superiority of the schemes proposed in this paper, the system for the computation of one level 2D DWT is implemented using the following techniques: pipelining, non-pipelining and hybrid wave-pipelining. The BIST approach is used for the implementation on Xilinx Spartan-II device. The SOC approach is adopted for implementation on Altera and Xilinx field programmable gate arrays (FPGAs) based SOC kits with Nios II or Micro blaze soft-core processors. From the implementation results, it is verified that the hybrid WP circuit is faster than non-pipelined circuit by a factor of 1.25–1.39. The pipelined circuit is in turn faster than the hybrid wave-pipelined circuit by a factor of 1.15–1.38 and this is achieved with the increase in the number of registers by a factor of 1.79–3.15 and increase in the number of LEs by a factor of 1.11–1.65. The soft-core processor based automation scheme has considerably reduced the effort required for the design and testing of the hybrid wave-pipelined circuit. The techniques proposed in this paper, are also applicable for ASICs. The optimization schemes proposed in this paper are also applicable for the computation of other image transforms such as DCT, DHT.

Fast multiplication in VLSI using wave pipelining techniques

Wave pipelining is a design methodology that can increase the clock frequency of digital systems. Also known asmaximum-rate pipelining, it has long been considered a technique for approaching the physical speed limit of a digital circuit. Unlike conventional pipelining, wave pipelining does not require internal clocked elements to increase throughput. The synchronization of internal computations is achieved by balancing inherent RC delays of combinational logic elements, thus allowing circuits to be pipelined at a very fine-grain level. In this article, we describe the design of a 16×16 wave-pipelined multiplier using a 1.0 μm CMOS process. The multiplier is designed using a conventional static CMOS technology. Simulation results show a speedup of about 7× over a nonpipeline implementation.