对数跳跃加法器的静态CMOS实现

介绍了一种32位对数跳跃加法器结构.该结构采用EL M超前进位加法器代替进位跳跃结构中的组内串行加法器,同EL M相比节约了30 %的硬件开销.面向该算法,重点对关键单元进行了晶体管级的电路设计.其中的进位结合结构利用L ing算法,采用支路线或电路结构对伪进位产生逻辑进行优化;求和逻辑的设计利用传输管结构,用一级逻辑门实现“与-异或”功能;1.0 μm CMOS工艺实现的32位对数跳跃加法器面积为0 .6 2 mm2 ,采用1μm和0 .2 5 μm工艺参数的关键路径延迟分别为6 ns和0 .8ns,在10 0 MHz下功耗分别为2 3和5 .2 m W.     

对数跳跃加法器的算法及结构设计

本文介绍一种新型加法器结构——对数跳跃加法器,该结构结合进位跳跃加法器和树形超前进位加法器算法,将跳跃进位分组内的进位链改成二叉树形超前进位结构,组内的路径延迟同操作数长度呈对数关系,因而结合了传统进位跳跃结构面积小、功耗低的特点和ELM树形CLA在速度方面的优势.在结构设计中应用Ling's算法设计进位结合结构,在不增加关键路径延迟的前提下,将初始进位嵌入到进位链.32位对数跳跃加法器的最大扇出为5,关键路径为8级逻辑门延迟,结构规整,易于集成.spectre电路仿真结果表明,在0.25μmCMOS工艺下,32位加法器的关键路径延迟为760ps,100MHz工作频率下功耗为5.2mW.     

一种适合VLSI实现的快速加法器

本文提出一种规整结构超前进位加法器,其加法时间与位数的对数成比例;而且其结构规整、逻辑简单、互连容易。SPICE模拟表明,采用2μm CMOS工艺的16位加法器最坏情况延时为5.4ns,并具有位数加倍延时仅增加1.2ns的扩展特性。它可以方便地用全定制或半定制等VLSI设计方法实现。     

基于并行前缀结构的十进制加法器设计

针对硬件实现BCD码十进制加法需要处理无效码的问题,设计了一种基于并行前缀结构的十进制加法器。该十进制加法器依据预先加6,配合二进制加法求中间和,然后再减6修正的算法,并将减6修正步骤整合到重新设计的减6修正进位选择加法器中,充分利用并行前缀结构大幅提高了电路运算的并行度。采用Verilog HDL对加法器进行实现并利用Design Compiler进行综合,得到设计的32位,64位,128位的十进制加法器的延时分别为0.56 ns,0.61 ns,0.71 ns,面积分别为1 310 μm2,2 681 μm2,5 485 μm2。     

64位超前进位对数加法器的设计与优化

设计一个应用于高性能微处理器的快速64位超前进位对数加法器.通过分析超前进位对数加法器原理,提出了改进四进制Kogge-Stone树算法的64位超前进位对数加法器结构,并结合使用多米诺动态逻辑、时钟延迟多米诺逻辑和传输门逻辑等技术来设计和优化电路.该加法器采用SMIC 0.18 μm CMOS工艺实现,在最坏情况下完成一次加法运算时间为486.1 ps,与相同工艺和相同电路结构采用静态CMOS实现相比,大大减少了加法器各级门的延迟时间,取得良好的电路性能.     

基于逻辑结构的超前进位加法器的设计

通过对计算机加法器的研究,从门电路标准延迟模型出发,在对超前进位加法器逻辑公式研究的基础上,在主要考虑速度的前提下,给出了超前进位加法器的逻辑电路的设计方案。主要对16位、32位加法器的逻辑电路进行分析设计,通过计算加法器的延迟时间来对比超前进位加法器与传统串行进位链加法器,得出超前进位算法在实际电路中使加法器的运算速度达到最优。     

一种32位高速浮点乘法器设计

文章介绍一种32位浮点乘法器软IP的设计,其部分积缩减部分采用修正Booth算法,部分积加法采用4-2压缩树结构,最终carry、sum形式部分积采用进位选择加法器完成,乘法器可以进行32位浮点数或24位定点数的乘法运算。采用VerilogHDLRTL级描述,采用SMIC0.18μm工艺库进行综合,门级仿真结果表明乘法器延时小于4.05ns。     

32位高速浮点乘法器优化设计

设计了一种用于频率为200 MHz的32位浮点数字信号处理器(DSP)中的高速乘法器.采用修正Booth算法与Wallace压缩树结合结构完成Carry Sum形式的部分积压缩,再由超前进位加法器求得乘积.对乘法器中的4-2压缩器进行了优化设计,压缩单元完成部分积压缩的时间仅为1.47 ns,乘法器延迟时间为3.5 ns.     

用于加法器的功耗延迟积优化混合进位算法

为了实现高性能的加法器,提出了面向功耗延迟积(PDP)优化的混合进位算法。该算法能快速搜索加法器的混合进位,以优化PDP。采用超前进位算法和行波进位算法交替混合,兼具超前进位算法速度快和行波进位算法功耗低的特点。该算法采用C语言实现并编译,结果应用于MCNC Benchmark电路,进行判定测试。与应用三种传统算法的加法器相比,应用该算法的加法器在位数为8位、16位、32位和64位时,PDP改进量分别为40.0%、70.6%、85.6%和92.9%。     

基于功能复用的高性能ALU设计

算术逻辑单元(ALU)是处理器中不可或缺的重要部分,可以进行两输入逻辑和加减法运算.设计了一款通用数字信号处理器中使用的高性能ALU.提出了一种高效的逻辑与算术运算复用的电路结构,提高复用度的同时,减少了ALU的面积.并提出一种融合进位选择和超前进位加法器结构的优化进位链设计,该进位链可以提高加法器的速度,并同时支持数字信号处理器的双16位运算.     

Design and analysis of low power high-speed 1-bit full adder cells for VLSI applications

This paper presents a low power and high speed two hybrid 1-bit full adder cells employing both pass transistor and transmission gate logics. These designs aim to minimise power dissipation and reduce transistor count while at the same time reducing the propagation delay. The proposed full adder circuits utilise 16 and 14 transistors to achieve a compact circuit design. For 1.2 V supply voltage at 0.18-μm CMOS technology, the power consumption is 4.266 μW was found to be extremely low with lower propagation delay 214.65 ps and power-delay product (PDP) of 0.9156 fJ by the deliberate use of CMOS inverters and strong transmission gates. The results of the simulation illustrate the superiority of the newly designed 1-bit adder circuits against the reported conservative adder structures in terms of power, delay, power delay product (PDP) and a transistor count. The implementation of 8-bit ripple carry adder in view of proposed full adders are finally verified and was observed to be working efficiently with only 1.411 ns delay. The performance of the proposed circuits was examined using Mentor Graphics Schematic Composer at 1.2 V single ended supply voltage and the model parameters of a TSMC 0.18-μm CMOS.     

Power-delay product minimization in high-performance 64-bit carry-select adders

This paper analyzes methods to minimize the power-delay product of 64-bit carry-select adders intended for high-performance and low-power applications. A first realization in 0.18-/spl mu/m partially depleted (PD) silicon-on-insulator (SOI), using complex branch-based logic (BBL) cells, results in a delay of 720 ps and a power dissipation of 96 mW at 1.5 V. The reduction of the stack height in the critical path, combined with the optimization of the global carry network with cell sharing and the selection of 8-bit pre-sums, leads to a reduction of the power-delay product by 75%. The automatic tuning of the transistor widths in 0.13-/spl mu/m PD SOI produces an energy-efficient 64-bit adder which has a delay of 326 ps and a power dissipation of 23 mW only at 1.1 V.     

64-bit reconfigurable adder for low power media processing

A new, highly reconfigurable carry-skip adder for media signal processing is presented. The proposed circuit can be partitioned to perform one 64-, two 32-, four 16- and eight 8-bit additions. Partitioning is obtained without increasing the critical path. When the AMS 0.35 μm two-poly three-metal 3.3 V CMOS (CSD) process is used to produce the layout, the worst propagation delay and dissipation obtained is about 6.5 ns and 148 μW/ MHz     

A 64-bit carry look ahead adder using pass transistor BiCMOS gates

This paper describes a 64-bit two-stage carry look ahead adder utilizing pass transistor BiCMOS gate. The new pass transistor BiCMOS gate has a smaller intrinsic delay time than conventional BiCMOS gates. Furthermore, this gate has a rail-to-rail output voltage. Therefore the next gate does not have a large degradation of its driving capability. The exclusive OR and NOR gate using the pass transistor BiCMOS gate shows a speed advantage over CMOS gates under a wide variance in load capacitance. The pass transistor BiCMOS gates were applied to full adders, carry path circuits, and carry select circuits. In consequence, a 64-bit two-stage carry look ahead adder was fabricated using a 0.5 μm BiCMOS process with single polysilicon and double-metal interconnections. A critical path delay time of 3.5 ns was observed at a supply voltage of 3.3 V. This is 25% better than the result of the adder circuit using CMOS technology. Even at the supply voltage of 2.0 V, this adder is faster than the CMOS adder     

一种适用于通信系统的异步加-选择-比较器

介绍了一种适用于Viterbi解码器的异步ACS(加法器-比较器-选择器)的设计.它采用异步握手信号取代了同步电路中的整体时钟.给出了一种异步实现结构的异步加法单元、异步比较单元和异步选择单元电路.采用全定制设计方法设计了一个异步4-bit ACS,并通过0.6μm CMOS工艺进行投片验证.经过测试,芯片在工作电压5V,工作频率20MHz时的功耗为75.5mW.由于采用异步控制,芯片在"睡眠"状态待机时不消耗动态功耗.芯片的平均响应时间为19.18ns,仅为最差响应时间23.37ns的82%.通过与相同工艺下的同步4-bit ACS在功耗和性能方面仿真结果的比较,可见异步ACS较同步ACS具有优势.     

Current sensing differential logic: a CMOS logic for highreliability and flexibility

In this paper, we present a highly reliable and flexible CMOS differential logic called current sensing differential logic (CSDL). This CSDL eliminates the timing constraints between the enable signal and input signals, which cause difficulties in design with conventional differential logic families, by employing a simple clocking scheme. The power-delay product of CSDL is also reduced by using a swing suppression technique. To verify the reliability and the applicability of the proposed CSDL in large very large-scale-integration systems, a 64-bit carry-lookahead adder has been fabricated in a 0.6 μm CMOS technology. Experimental results show that the critical path delay is 3.5 ns with a power consumption of 27 mW at 50 MHz     

A 270ps 20mW 108-bit End-around Carry Adder for Multiply-Add Fused Floating Point Unit

A power and area efficient 108-bit end-around carry adder is implemented using IBM 65nm SOI technology. The adder is used for a multiply-add fused (MAF) floating point unit. Careful balance of the adder structure and structure-aware layout techniques enabled this adder to have a latency of 270ps at power consumption of 20mW with 1V supply.     

32位定/浮点乘法器设计

针对Wallace树连接线复杂度高,版图实现比较困难的缺点,提出了一种新的加法器阵列结构.这种结构在规则性和连接复杂度方面优于ZM树和OS树.同时提出一种新的CLA加法器结构以提高乘法器的性能.乘法器采用1.5μm CMOS工艺实现,完成一次定点与浮点乘法操作的时间分别是56ns和76ns.     

Low-Power Mixed-Signal CVNS-Based 64-Bit Adder for Media Signal Processing

In this paper, design of a mixed-signal 64-bit adder based on the continuous valued number system (CVNS) is presented. The 64-bit adder is generated by cascading four 16-bit radix-2 CVNS adders. Truncated summation of the CVNS digits reduced the number of required interconnections in the system, which in turn reduced design complexity and hardware costs. This adder can perform one 64-bit, two 32-bit, four 16-bit, or eight 8-bit additions on demand for media signal processing applications. The compact and low-power and low-noise design of the adder is suitable for this type of application. The 64-bit adder designed in TSMC CMOS 0.18-$mu$ m technology, has a worst case delay of 1.5 ns, energy dissipation of about 14 pJ with the core area of 13$thinspace$ 250 $mu{hbox {m}}^{2}$.