This paper describes the implementation of a Euclidean squared classifier with a charge based synaptic matrix and discriminator, based on a previously implemented Hamming classifier. The discriminator circuit is a generalized n-port version of the two-port differential charge-sensing amplifier that is conventionally used in DRAM's for bitline sensing. Both the quantifier and discriminator are implemented by charge based techniques, granting the simultaneous availability of high integration density, low power consumption, and high speed. The analog-to-digital (A/D) implementation was chosen to illustrate the network's classification characteristics, since A/D conversion can be interpreted as classifying an input in terms of A/D quantization levels. A detailed analysis of the classifier configuration is presented. Design issues are addressed at both the system and circuit levels, and some limitations are identified. Both simulation results and measurements of the implemented chip are presented to confirm the theoretical analysis. The circuit occupies an area of 500 /spl mu/m/spl times/250 /spl mu/m, operates with a single 5 V power supply, and consumes less than 1 mW of static power.
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机译:本文描述了基于先前实现的汉明分类器的欧几里德平方分类器的实现,该分类器具有基于电荷的突触矩阵和鉴别器。鉴别器电路是两端口差分电荷感测放大器的通用n端口版本,通常在DRAM中用于位线感测。量化器和鉴别器均通过基于电荷的技术实现,从而可以同时实现高集成度,低功耗和高速的可用性。选择A / D来说明网络的分类特性,因为A / D转换可以解释为按照A / D量化级别对输入进行分类。提出了对分类器配置的详细分析。在系统和电路级都解决了设计问题,并确定了一些限制。给出了仿真结果和所实现芯片的测量结果,以证实理论分析。该电路的面积为500 / spl mu / m / spl乘以/ 250 / spl mu / m,使用5 V单电源供电,消耗的静态功率不到1 mW。
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