基于Nios Ⅱ的井下静态随机存取存储器管理
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摘要
针对测井仪器中高速数据缓存的问题,提出了一种基于Nios Ⅱ的静态随机存储器(Static Random-Access Memory,SRAM)控制器的IP核的设计方法,详细介绍了IP核的设计和实现过程并基于一定的硬件平台对SRAM控制器IP核的稳定性进行了测试;测试结果表明,所设计的SRAM控制器IP核能够在高温环境下实现对SRAM的有效管理而且通过修改配置参数就可应用在不同位宽和容量的SRAM上且运行稳定;该设计不仅实现测井仪器中高速数据缓存的管理,也提供了一套SRAM选型测试系统;另外设计介绍的可编程片上系统(System-on-a-Programmable-Chip,SOPC)开发流程对其它SOPC系统开发也具有一定的参考价值。
Aiming at the problem of high speed data cache in logging tool,proposes a design method of IP core of SRAM controller based on Nios Ⅱ,introduces the design and implementation process of IP core in detail,and tests the stability of IP core of SRAM controller based on certain hardware platform.The test results show that the designed SRAM controller IP core can effectively manage SRAM in high temperature environment and can be applied to SRAM with different bit widths and capacities by modifying configuration parameters and running stably.The design not only realizes the management of high speed data cache in logging tool,but also introduces a set of SRAM selection test system.In addition,the development process of SOPC system introduced in the design has certain reference value for the development of other SOPC systems.
Aiming at the problem of high speed data cache in logging tool,proposes a design method of IP core of SRAM controller based on Nios Ⅱ,introduces the design and implementation process of IP core in detail,and tests the stability of IP core of SRAM controller based on certain hardware platform.The test results show that the designed SRAM controller IP core can effectively manage SRAM in high temperature environment and can be applied to SRAM with different bit widths and capacities by modifying configuration parameters and running stably.The design not only realizes the management of high speed data cache in logging tool,but also introduces a set of SRAM selection test system.In addition,the development process of SOPC system introduced in the design has certain reference value for the development of other SOPC systems.
引文
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[4]卢俊强,鞠晓东,乔文孝,等.数字信号处理器在随钻声波测井仪中的应用[J].测井技术,2013,37(05):527-530.
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[7]梁浩,陈波,良华.基于NIOSII的VGA控制器IP核的设计[J].工矿自动化,2010(3):73-74.
[8]刘兆庆,黄敏,罗杰俊.SOPC中定制功能实现方法比较及性能分析[J].测控技术,2010,29(10):103-106.
[9]Cyclone Ⅱ Device Handbook,Volume 1[Z].http://www.altera.com,2008.
[10]余毅,马骋,贾惠波.基于Nios Ⅱ的PWM控制电路设计[J].微计算机信息(测控自动化)2008,24:7.
[11]林振营,马刚.基于NiosⅡ的SOPC嵌入式系统开发解决方案[J].现代电子技术,2007(6):79-80.
[12]陈建,张天宏,刘冬冬.基于SOPC的微型涡喷发动机控制器设计与验证[J].测控技术,2012,31(7):50-52.
[13]潘宗树.基于NiosⅡ的SOPC系统设计与研究[D].武汉:武汉科技大学,2007.
[2]王任重.基于SOPC技术芯片自动测试系统的设计与实现[D].湘潭:湘潭大学,2018.
[3]刘忠超.基于NIOS Ⅱ嵌入式系统的芯片自动测试系统设计[J].电子质量,2016(12):84-87.
[4]卢俊强,鞠晓东,乔文孝,等.数字信号处理器在随钻声波测井仪中的应用[J].测井技术,2013,37(05):527-530.
[5]周新淳.基于DSP+FPGA的实时信号采集系统设计与实现[J].计算机测量与控制,2017,25(08):210-213.
[6]CY1011DV33datasheet[Z].2006-07-14.
[7]梁浩,陈波,良华.基于NIOSII的VGA控制器IP核的设计[J].工矿自动化,2010(3):73-74.
[8]刘兆庆,黄敏,罗杰俊.SOPC中定制功能实现方法比较及性能分析[J].测控技术,2010,29(10):103-106.
[9]Cyclone Ⅱ Device Handbook,Volume 1[Z].http://www.altera.com,2008.
[10]余毅,马骋,贾惠波.基于Nios Ⅱ的PWM控制电路设计[J].微计算机信息(测控自动化)2008,24:7.
[11]林振营,马刚.基于NiosⅡ的SOPC嵌入式系统开发解决方案[J].现代电子技术,2007(6):79-80.
[12]陈建,张天宏,刘冬冬.基于SOPC的微型涡喷发动机控制器设计与验证[J].测控技术,2012,31(7):50-52.
[13]潘宗树.基于NiosⅡ的SOPC系统设计与研究[D].武汉:武汉科技大学,2007.
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