In Situ Analog In-Memory Computing Under Ionizing Radiation Exposure

T. Patrick Xiao; Maximilian Siath; Matthew Spear; Donald Wilson; Christopher H. Bennett; Ben Feinberg; David R. Hughart; Jereme Neuendank; William E. Brown; Hugh Barnaby; Vineet Agrawal; Helmut Puchner; Sapan Agarwal; Matthew J. Marinella

doi:10.1109/TNS.2025.3537985

In Situ Analog In-Memory Computing Under Ionizing Radiation Exposure

T. Patrick Xiao, Maximilian Siath, Matthew Spear, Donald Wilson, Christopher H. Bennett, Ben Feinberg, David R. Hughart, Jereme Neuendank, William E. Brown, Hugh Barnaby, Vineet Agrawal, Helmut Puchner, Sapan Agarwal, Matthew J. Marinella

Research output: Contribution to journal › Article › peer-review

Abstract

We experimentally performed in situ analog in-memory computing (IMC) under ionizing radiation, using a 40-nm silicon-oxide–nitride-oxide–silicon (SONOS) charge-trap memory array with peripheral circuits that support analog matrix-vector multiplication (MVM) operations. The SONOS array used analog MVMs to process the last layer of a convolutional neural network (CNN) for TinyImageNet image classification while being irradiated by gamma rays from a Co-60 source. We experimentally characterized how the following quantities were gradually degraded by increasing the total ionizing dose (TID), up to 3.2 Mrad(Si): neural network weights that were mapped to SONOS states, dot products that were computed by analog MVMs, and the resulting image classification accuracy of the neural network. Using multiscale modeling, we confirmed that the experimentally observed accuracy loss originates almost entirely from the state-dependent current shifts induced by ionizing radiation in the SONOS memory cells. Our experimentally validated model of radiation effects in SONOS analog computing can be used to guide the design of reliable space-grade analog IMC accelerators.

Original language	English (US)
Pages (from-to)	1243-1251
Number of pages	9
Journal	IEEE Transactions on Nuclear Science
Volume	72
Issue number	4
DOIs	https://doi.org/10.1109/TNS.2025.3537985
State	Published - 2025
Externally published	Yes

Keywords

Analog computing
charge-trap memory
flash memory
in-memory computing (IMC)
ionizing radiation
machine learning (ML)
neural networks
silicon–oxide–nitride-oxide–silicon (SONOS)
total ionizing dose (TID)

ASJC Scopus subject areas

Nuclear and High Energy Physics
Nuclear Energy and Engineering
Electrical and Electronic Engineering

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10.1109/TNS.2025.3537985

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Patrick Xiao, T., Siath, M., Spear, M., Wilson, D., Bennett, C. H., Feinberg, B., Hughart, D. R., Neuendank, J., Brown, W. E., Barnaby, H., Agrawal, V., Puchner, H., Agarwal, S., & Marinella, M. J. (2025). In Situ Analog In-Memory Computing Under Ionizing Radiation Exposure. IEEE Transactions on Nuclear Science, 72(4), 1243-1251. https://doi.org/10.1109/TNS.2025.3537985

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abstract = "We experimentally performed in situ analog in-memory computing (IMC) under ionizing radiation, using a 40-nm silicon-oxide–nitride-oxide–silicon (SONOS) charge-trap memory array with peripheral circuits that support analog matrix-vector multiplication (MVM) operations. The SONOS array used analog MVMs to process the last layer of a convolutional neural network (CNN) for TinyImageNet image classification while being irradiated by gamma rays from a Co-60 source. We experimentally characterized how the following quantities were gradually degraded by increasing the total ionizing dose (TID), up to 3.2 Mrad(Si): neural network weights that were mapped to SONOS states, dot products that were computed by analog MVMs, and the resulting image classification accuracy of the neural network. Using multiscale modeling, we confirmed that the experimentally observed accuracy loss originates almost entirely from the state-dependent current shifts induced by ionizing radiation in the SONOS memory cells. Our experimentally validated model of radiation effects in SONOS analog computing can be used to guide the design of reliable space-grade analog IMC accelerators.",

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year = "2025",

doi = "10.1109/TNS.2025.3537985",

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AU - Siath, Maximilian

AU - Spear, Matthew

AU - Wilson, Donald

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AU - Feinberg, Ben

AU - Hughart, David R.

AU - Neuendank, Jereme

AU - Brown, William E.

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AB - We experimentally performed in situ analog in-memory computing (IMC) under ionizing radiation, using a 40-nm silicon-oxide–nitride-oxide–silicon (SONOS) charge-trap memory array with peripheral circuits that support analog matrix-vector multiplication (MVM) operations. The SONOS array used analog MVMs to process the last layer of a convolutional neural network (CNN) for TinyImageNet image classification while being irradiated by gamma rays from a Co-60 source. We experimentally characterized how the following quantities were gradually degraded by increasing the total ionizing dose (TID), up to 3.2 Mrad(Si): neural network weights that were mapped to SONOS states, dot products that were computed by analog MVMs, and the resulting image classification accuracy of the neural network. Using multiscale modeling, we confirmed that the experimentally observed accuracy loss originates almost entirely from the state-dependent current shifts induced by ionizing radiation in the SONOS memory cells. Our experimentally validated model of radiation effects in SONOS analog computing can be used to guide the design of reliable space-grade analog IMC accelerators.

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In Situ Analog In-Memory Computing Under Ionizing Radiation Exposure

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Keywords

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