Real-time data processing of interferential imaging spectrometer based on FPGA

Based on the data processing technologies of interferential spectrometer, a sort of real-time data processing system on chip of interferential imaging spectrometer was studied based on large capacitance and high speed field programmable gate array( FPGA) device. The system integrates both interferograrn sampling and spectrum rebuilding on a single chip of FPGA and makes them being accomplished in real-time with advantages such as small cubage, fast speed and high reliability. It establishes a good technical foundation in the applications of imaging spectrometer on target detection and recognition in real-time.

针对一种多模式逻辑单元结构FPGA的工艺映射

结合FPGA设计的特点,提出一种可灵活配置的多模式FPGA逻辑单元结构及对其进行工艺映射的工具VMAP.该工具中除了采用一般的工艺映射算法外,还结合逻辑单元结构特点提出了专门的合并优化算法.该算法基于图的最大基数匹配,将部分查找表进行合并,减小了映射结果的面积开销.实验结果表明.对于标准的测试电路,结合文中的逻辑单元结构和合并算法得到的工艺映射结果平均可以减少15.7%的基本逻辑单元使用个数.

Design for an IO block array in a tile-based FPGA

A design for an IO block array in a tile-based FPGA is presented.Corresponding with the characteristics of the FPGA, each IO cell is composed of a signal path, local routing pool and configurable input/output buffers.Shared programmable registers in the signal path can be configured for the function of JTAG, without specific boundary scan registers/latches, saving layout area.The local routing pool increases the flexibility of routing and the routability of the whole FPGA.An auxiliary power supply is adopted to increase the performance of the IO buffers at different configured IO standards.The organization of the IO block array is described in an architecture description file, from which the array layout can be accomplished through use of an automated layout assembly tool.This design strategy facilitates the design of FPGAs with different capacities or architectures in an FPGA family series.The bond-out schemes of the same FPGA chip in different packages are also considered.The layout is based on SMIC 0.13μm logic 1P8M salicide 1.2/2.5 V CMOS technology.Our performance is comparable with commercial SRAM-based FPGAs which use a similar process.

FPGA中专用可重构乘法器的设计

提出了一种新的嵌入在FPGA中可重构的流水线乘法器设计.该设计采用了改进的波茨编码算法,可以实现18×18有符号乘法或17×17无符号乘法.还提出了一种新的电路优化方法来减少部分积的数目,并且提出了一种新的乘法器版图布局,以便适应tilebased FPGA芯片设计所加的约束.该乘法器可以配置成同步或异步模式,也町以配置成带流水线的模式以满足高频操作.该设计很容易扩展成不同的输入和输出位宽.同时提出了一种新的超前进位加法器电路来产生最后的结果.采用了传输门逻辑来实现整个乘法器.乘法器采用了中芯国际0.13μm CMOS工艺来实现,完成18×18的乘法操作需要4.1ns.全部使用2级的流水线时,时钟周期可以达到2.5ns.这比商用乘法器快29.1%,比其他乘法器快17.5%.与传统的基于查找表的乘法器相比,该乘法器的面积为传统乘法器面积的1/32.