Radiation-induced errors in memory chips

Peterson, R.J.

doi:10.1590/s0103-97332003000200013

Cited by 7 publications

(5 citation statements)

References 10 publications

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“…Neutrons present in the accelerator's chamber provoke SEUs in an SRAM chip [19]- [21]. A random bit-pattern must be written into the memory chip before the measurement process starts.…”

Section: Distributed System For Radiation Monitoringmentioning

confidence: 99%

A Distributed System for Radiation Monitoring at Linear Accelerators

Makowski¹,

Grecki²,

Napieralski³

et al. 2006

IEEE Trans. Nucl. Sci.

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This paper discusses a system for an on-line neutron fluence monitoring at linear accelerators. The system consists of a SRAM-based detector and a radiation-tolerant read-out system. The neutron fluence was measured in several locations of the accelerator. Monitoring of the radiation environment in an accelerator tunnel is necessary to assure reliable long-term operation of electronic systems placed in the tunnel. Monitoring of the chamber is especially important during the design stage of a linear accel- erator. The new design of 20 GeV linear accelerator X-ray Free Electron Laser (X-FEL) is currently approved for construction at DESY Research Centre in Hamburg [1], [2]. The presented paper is based on our research and experimental measurement carried out at 1.2 GeV superconducting electron linac driving the Vacuum UltraViolet Free Electron Laser (VUV-FEL). The application of a pair of TLD-700 and TLD-500 or superheated emulsion (bubble) dosimeters enables the supervision of neutron fluence in accelerators [3]. This process requires continuous and arduous calibration of TLDs, therefore this method is not convenient. Moreover, it is impossible to monitor the radiation environment in real-time. The presented system fills the market niche of real-time neutron monitoring for high-energy accelerators. Neutron fluence and gamma dose measured in this way can be used for the detailed analysis of the VUV-FEL or X-FEL environments. Monitoring of the radioactive area in a linear accelerator tunnel could be helpful to the diagnosis and reduction of beam losses [4], [5]. We have conducted experiments with the distributed system dedicated to neutron flux measurement at the DESY Research Centre in Hamburg. The devices were exposed to a neutron field from an Americium-Beryllium (n ) source 241 AmBe. The systems were installed in two accelerators: Linac II and VUV-FEL.Index Terms-Linear accelerator, neutron fluence, single event effect, single event upset, static random access memory.

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“…Neutrons present in the accelerator's chamber provoke SEUs in an SRAM chip [19]- [21]. A random bit-pattern must be written into the memory chip before the measurement process starts.…”

Section: Distributed System For Radiation Monitoringmentioning

confidence: 99%

A Distributed System for Radiation Monitoring at Linear Accelerators

Makowski¹,

Grecki²,

Napieralski³

et al. 2006

IEEE Trans. Nucl. Sci.

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“…This leads to a current spike that can have an important influence on the electronic system. For example, in a SRAM memory cell, this can cause a bit-flip [13].…”

Section: Radiation Influencementioning

confidence: 99%

<title>DSP-based system for advanced radiation tolerant algorithms evaluation</title>

et al. 2006

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Radiation produced during the operation of high energy linear accelerators can pose a real danger to electronic devices. The electronics of X-Ray Free Electron Laser (X-FEL) accelerator will be placed in the main tunnel, therefore the system will be subjected to gamma bremsstrahlung radiation and neutrons [1].Digital Signal Processors (DSPs) and high-density Field Programmable Gate Array (FPGA) devices are used to design the control system of the X-FEL accelerator. Influence of gamma on electronic systems can be decreased by implementation of suitable shielding. Despite the plurality of available methods protecting digital devices against neutrons influence, designing complex systems dedicated to operate in radiation environments is still a challenge. The mechanisms improving immunity of the digital systems can be achieved as an implementation of hardware redundancy or software algorithms modifications [2][3][4][5]. In both cases additional resources are necessary.This paper highlights a DSP-based development environment, based on Texas Instruments TM5320C6713 digital signal processor, dedicated to test software in radioactive environment. The master-board of the system is connected to the slave controller through ETA 485 differential interface, which assures reliable transmission for a long distance even in EMI polluted area. The developed programs can be downloaded through the interface and stored in a Flash memory.Methods allowing improving the immunity to neutrons generated events, particularly Single Event Upsets (SEUs), were developed using triple redundancy, Hamming codes and doubled multipliers. Different experiments were carried out in Linac II accelerator to evaluate the designed programs and examine the whole system.

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“…Neutrons present in the accelerator's chamber provoke SEUs in a SRAM chip [19]- [21] . A random bit-pattern must be written into the memory chip before the measurement process starts.…”

Section: B Main Control System Of the X-felmentioning

confidence: 99%

A distributed System for Radiation Monitoring at Linear Accelerators

Makowski

Grecki

Napieralski

et al. 2005

2005 8th European Conference on Radiation and Its Effects on Components and Systems

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The paper presents a system for an on-line neutron fluence monitoring at a linear accelerator. The system consists of a SRAM-based detector and a radiation-tolerant read-out system. The neutron fluence is measured in several locations of the accelerator. Monitoring of the radiation environment in an accelerator tunnel is necessary to assure a reliable long-term operation of electronic systems placed in the tunnel. The monitoring of the chamber is especially important during the design stage of a linear accelerator. The new design of 20 GeV linear accelerator X-FEL (X-ray Free Electron Laser) is currently approved for construction at DESY Research Centre in Hamburg [1], [2]. The presented paper is based on our research and experimental measurement carried out at 1.2 GeV superconducting electron linac driving the VUV-FEL. The application of a pair of TLD-700 and TLD-500 or superheated emulsion (bubble) dosimeters enables the supervision of neutrons fluence in accelerators [3]. This process requires continuous and arduous calibration of TLD, therefore this method is not convenient. Moreover, it is impossible to monitor the radiation environment in real time. The presented system fill the market nitche of real-time neutron monitoring for high-energy accelerators. Neutron fluence and gamma dose measured in this way can be used for the detailed analysis of the VUV-FEL or X-FEL environments. Monitoring of the radioactive area in a linear accelerator tunnel could be helpful to diagnose and reduce beam losses [4], [5]. We have conducted experiments with the distributed system dedicated to neutron flux measurement at the DESY Research Centre in Hamburg. The devices were exposed to a neutron field from an Americium-Beryllium (n, a) source 241AmBe. The systems were installed in two accelerators: Linac II and VUV-FEL.

show abstract

Radiation-induced errors in memory chips

Cited by 7 publications

References 10 publications

A Distributed System for Radiation Monitoring at Linear Accelerators

A Distributed System for Radiation Monitoring at Linear Accelerators

<title>DSP-based system for advanced radiation tolerant algorithms evaluation</title>

A distributed System for Radiation Monitoring at Linear Accelerators

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