Application of EDA technology and μClinux operating system in the earthquake precursor instruments
Anhua He1, Gang Zhao1, Na Xue2, Jun Wang3, Bailin Guo1, Miaoxi Guo1, and, Zizhong Fu1
1 Institute of Crustal Dynamics, China Earthquake Administration, Beijing 100085, China 2 Earthquake Administration of Tianjin Municipality, Tianjin 300201, China 3 China Earthquake Networks Center, Beijing 100036, China
Application of EDA technology and μClinux operating system in the earthquake precursor instruments
Anhua He1, Gang Zhao1, Na Xue2, Jun Wang3, Bailin Guo1, Miaoxi Guo1, and, Zizhong Fu1
1 Institute of Crustal Dynamics, China Earthquake Administration, Beijing 100085, China 2 Earthquake Administration of Tianjin Municipality, Tianjin 300201, China 3 China Earthquake Networks Center, Beijing 100036, China
摘要Using Altera’s Quartus II, Nios II IDE and Sopc Builder development tools, the proton precession magnetometer principle host hardware platform is designed in a cyclone II series FPGA chip (EP2C35). The proton precession magnetometer principle host core circuit’s single-chip system-logic design is achieved by building and configuring the Nios II soft-core processor, developing the IO interface and sensor control circuits, programming some hardware units’ VHDL code, for example the equal precision cymometer and the DPLL. Through researching the embedded operating system configuration technology and building the NIOS II soft-core processor’s μClinux cross-compile environment, the μClinux system is transplanted to the NIOS II environment. Another important task is writing the device drivers’ and user programs’ code. Through these work, the design realize the host function and achieve the expected target.
Abstract:Using Altera’s Quartus II, Nios II IDE and Sopc Builder development tools, the proton precession magnetometer principle host hardware platform is designed in a cyclone II series FPGA chip (EP2C35). The proton precession magnetometer principle host core circuit’s single-chip system-logic design is achieved by building and configuring the Nios II soft-core processor, developing the IO interface and sensor control circuits, programming some hardware units’ VHDL code, for example the equal precision cymometer and the DPLL. Through researching the embedded operating system configuration technology and building the NIOS II soft-core processor’s μClinux cross-compile environment, the μClinux system is transplanted to the NIOS II environment. Another important task is writing the device drivers’ and user programs’ code. Through these work, the design realize the host function and achieve the expected target.
基金资助:Public Benefit Research Sector (No. H200708045); Basic R&D Operations Special (Nos. ZDJ2008-01 and J220780804)
通讯作者:
Anhua He
E-mail: hua98611@163.com
引用本文:
Anhua He, Gang Zhao, Na Xue, Jun Wang, Bailin Guo, Miaoxi Guo, and,Zizhong Fu. Application of EDA technology and μClinux operating system in the earthquake precursor instruments[J]. 《地震学报》英文版, 2009, 22(1): 101-106.
Anhua He, Gang Zhao, Na Xue, Jun Wang, Bailin Guo, Miaoxi Guo, and,Zizhong Fu. Application of EDA technology and μClinux operating system in the earthquake precursor instruments. Earthquake Science, 2009, 22(1): 101-106.