On-chip Built-In Self-Calibration of Thermal Variations for Mixed-Signal In-Memory Computing

Gaurav Singh; Omar Numan; Dipesh Monga; Martin Andraud; Kari Halonen

doi:10.1109/ETS61313.2024.10567960

On-chip Built-In Self-Calibration of Thermal Variations for Mixed-Signal In-Memory Computing

Gaurav Singh^*
, Omar Numan
, Dipesh Monga
, Martin Andraud
, Kari Halonen

^*Corresponding author for this work

Not published at VTT

Aalto University
Catholic University of Louvain

Research output: Chapter in Book/Report/Conference proceeding › Conference article in proceedings › Scientific › peer-review

3 Citations (Scopus)

Abstract

In-memory computing (IMC) accelerators have become a pivotal architecture for enhancing AI algorithm computations, particularly critical for embedding deep neural networks (DNNs) in edge devices. The efficiency of these systems is paramount, yet IMC cores are prone to fluctuations due to process, temperature, and voltage variations, which can detrimentally impact DNN accuracy. This research introduces an innovative Built-In Self-Calibration (BISC) methodology, specifically designed to compensate for temperature-induced variations in mixed-signal IMC cores. The methodology enables real-time, on-chip adjustment of DNN weights during computation within the IMC core without modifying the computation path. The proposed approach, implemented on a silicon prototype, not only maintained DNN computation accuracy under substantial temperature variations but also fully compensated for almost 90% of the offset caused by these variations, without introducing any non-idealities.

Original language	English
Title of host publication	2024 IEEE European Test Symposium (ETS)
Publisher	IEEE Institute of Electrical and Electronic Engineers
ISBN (Electronic)	979-8-3503-4932-0, 979-8-3503-4931-3
DOIs	https://doi.org/10.1109/ETS61313.2024.10567960
Publication status	Published - 2024
MoE publication type	A4 Article in a conference publication
Event	29th IEEE European Test Symposium, ETS 2024 - The Hague, Netherlands Duration: 20 May 2024 → 24 May 2024

Conference

Conference	29th IEEE European Test Symposium, ETS 2024
Country/Territory	Netherlands
City	The Hague
Period	20/05/24 → 24/05/24

Funding

This work is partially supported by Academy of Finland projects EHIR (grant 13334487) and WHISTLE (grant 332218).

Keywords

In-memory computing (IMC)
multiply-and-accumulate (MAC)
temperature sensor
thermal compensation

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10.1109/ETS61313.2024.10567960

Cite this

@inproceedings{60d86dcb1f094cbba16a69435ef8e9d8,

title = "On-chip Built-In Self-Calibration of Thermal Variations for Mixed-Signal In-Memory Computing",

abstract = "In-memory computing (IMC) accelerators have become a pivotal architecture for enhancing AI algorithm computations, particularly critical for embedding deep neural networks (DNNs) in edge devices. The efficiency of these systems is paramount, yet IMC cores are prone to fluctuations due to process, temperature, and voltage variations, which can detrimentally impact DNN accuracy. This research introduces an innovative Built-In Self-Calibration (BISC) methodology, specifically designed to compensate for temperature-induced variations in mixed-signal IMC cores. The methodology enables real-time, on-chip adjustment of DNN weights during computation within the IMC core without modifying the computation path. The proposed approach, implemented on a silicon prototype, not only maintained DNN computation accuracy under substantial temperature variations but also fully compensated for almost 90\% of the offset caused by these variations, without introducing any non-idealities.",

keywords = "In-memory computing (IMC), multiply-and-accumulate (MAC), temperature sensor, thermal compensation",

author = "Gaurav Singh and Omar Numan and Dipesh Monga and Martin Andraud and Kari Halonen",

year = "2024",

doi = "10.1109/ETS61313.2024.10567960",

language = "English",

booktitle = "2024 IEEE European Test Symposium (ETS)",

publisher = "IEEE Institute of Electrical and Electronic Engineers",

address = "United States",

note = "29th IEEE European Test Symposium, ETS 2024 ; Conference date: 20-05-2024 Through 24-05-2024",

}

Singh, G, Numan, O , Monga, D, Andraud, M & Halonen, K 2024, On-chip Built-In Self-Calibration of Thermal Variations for Mixed-Signal In-Memory Computing. in 2024 IEEE European Test Symposium (ETS). IEEE Institute of Electrical and Electronic Engineers, 29th IEEE European Test Symposium, ETS 2024, The Hague, Netherlands, 20/05/24. https://doi.org/10.1109/ETS61313.2024.10567960

On-chip Built-In Self-Calibration of Thermal Variations for Mixed-Signal In-Memory Computing. / Singh, Gaurav; Numan, Omar ; Monga, Dipesh et al.
2024 IEEE European Test Symposium (ETS). IEEE Institute of Electrical and Electronic Engineers, 2024.

Research output: Chapter in Book/Report/Conference proceeding › Conference article in proceedings › Scientific › peer-review

TY - GEN

T1 - On-chip Built-In Self-Calibration of Thermal Variations for Mixed-Signal In-Memory Computing

AU - Singh, Gaurav

AU - Numan, Omar

AU - Monga, Dipesh

AU - Andraud, Martin

AU - Halonen, Kari

PY - 2024

Y1 - 2024

N2 - In-memory computing (IMC) accelerators have become a pivotal architecture for enhancing AI algorithm computations, particularly critical for embedding deep neural networks (DNNs) in edge devices. The efficiency of these systems is paramount, yet IMC cores are prone to fluctuations due to process, temperature, and voltage variations, which can detrimentally impact DNN accuracy. This research introduces an innovative Built-In Self-Calibration (BISC) methodology, specifically designed to compensate for temperature-induced variations in mixed-signal IMC cores. The methodology enables real-time, on-chip adjustment of DNN weights during computation within the IMC core without modifying the computation path. The proposed approach, implemented on a silicon prototype, not only maintained DNN computation accuracy under substantial temperature variations but also fully compensated for almost 90% of the offset caused by these variations, without introducing any non-idealities.

AB - In-memory computing (IMC) accelerators have become a pivotal architecture for enhancing AI algorithm computations, particularly critical for embedding deep neural networks (DNNs) in edge devices. The efficiency of these systems is paramount, yet IMC cores are prone to fluctuations due to process, temperature, and voltage variations, which can detrimentally impact DNN accuracy. This research introduces an innovative Built-In Self-Calibration (BISC) methodology, specifically designed to compensate for temperature-induced variations in mixed-signal IMC cores. The methodology enables real-time, on-chip adjustment of DNN weights during computation within the IMC core without modifying the computation path. The proposed approach, implemented on a silicon prototype, not only maintained DNN computation accuracy under substantial temperature variations but also fully compensated for almost 90% of the offset caused by these variations, without introducing any non-idealities.

KW - In-memory computing (IMC)

KW - multiply-and-accumulate (MAC)

KW - temperature sensor

KW - thermal compensation

UR - https://www.scopus.com/pages/publications/85197562975

U2 - 10.1109/ETS61313.2024.10567960

DO - 10.1109/ETS61313.2024.10567960

M3 - Conference article in proceedings

AN - SCOPUS:85197562975

BT - 2024 IEEE European Test Symposium (ETS)

PB - IEEE Institute of Electrical and Electronic Engineers

T2 - 29th IEEE European Test Symposium, ETS 2024

Y2 - 20 May 2024 through 24 May 2024

ER -

On-chip Built-In Self-Calibration of Thermal Variations for Mixed-Signal In-Memory Computing

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Keywords

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