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1. Analog System High-Level Synthesis for Energy-Efficient Reconfigurable Computing

   https://doi.org/10.3390/jlpea13040058  

   Ige, Afolabi; Yang, Linhao; Yang, Hang; Hasler, Jennifer; Hao, Cong (December 2023, Journal of Low Power Electronics and Applications)

   The design of analog computing systems requires significant human resources and domain expertise due to the lack of automation tools to enable these highly energy-efficient, high-performance computing nodes. This work presents the first automated tool flow from a high-level representation to a reconfigurable physical device. This tool begins with a high-level algorithmic description, utilizing either our custom Python framework or the XCOS GUI, to compile and optimize computations for integration into an Integrated Circuit (IC) design or a Field Programmable Analog Array (FPAA). An energy-efficient embedded speech classifier benchmark illustrates the tool demonstration, automatically generating GDSII layout or FPAA switch list targeting. 

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2. Memristive Field‐Programmable Analog Arrays for Analog Computing

   https://doi.org/10.1002/adma.202206648  

   Li, Yunning; Song, Wenhao; Wang, Zhongrui; Jiang, Hao; Yan, Peng; Lin, Peng; Li, Can; Rao, Mingyi; Barnell, Mark; Wu, Qing; et al (December 2022, Advanced Materials)

   Abstract The increasing interests in analog computing nowadays call for multipurpose analog computing platforms with reconfigurability. The advancement of analog computing, enabled by novel electronic elements like memristors, has shown its potential to sustain the exponential growth of computing demand in the new era of analog data deluge. Here, a platform of a memristive field‐programmable analog array (memFPAA) is experimentally demonstrated with memristive devices serving as a variety of core analog elements and CMOS components as peripheral circuits. The memFPAA is reconfigured to implement a first‐order band pass filter, an audio equalizer, and an acoustic mixed frequency classifier, as application examples. The memFPAA, featured with programmable analog memristors, memristive routing networks, and memristive vector‐matrix multipliers, opens opportunities for fast prototyping analog designs as well as efficient analog applications in signal processing and neuromorphic computing. 

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3. Modeling and Simulation of Circuit-Level Nonidealities for an Analog Computing Design Approach with Application to EEG Feature Extraction

   https://doi.org/10.1109/TCAD.2022.3170248  

   Mirchandani, Nikita; Zhang, Yuqing; Abdelfattah, Safaa; Onabajo, Marvin; Shrivastava, Aatmesh (April 2022, IEEE Transactions on Computer-Aided Design of Integrated Circuits and Systems)

   This paper presents a design approach for the modeling and simulation of ultra-low power (ULP) analog computing machine learning (ML) circuits for seizure detection using EEG signals in wearable health monitoring applications. In this paper, we describe a new analog system modeling and simulation technique to associate power consumption, noise, linearity, and other critical performance parameters of analog circuits with the classification accuracy of a given ML network, which allows to realize a power and performance optimized analog ML hardware implementation based on diverse application-specific needs. We carried out circuit simulations to obtain non-idealities, which are then mathematically modeled for an accurate mapping. We have modeled noise, non-linearity, resolution, and process variations such that the model can accurately obtain the classification accuracy of the analog computing based seizure detection system. Noise has been modeled as an input-referred white noise that can be directly added at the input. Device process and temperature variations were modeled as random fluctuations in circuit parameters such as gain and cut-off frequency. Nonlinearity was mathematically modeled as a power series. The combined system level model was then simulated for classification accuracy assessments. The design approach helps to optimize power and area during the development of tailored analog circuits for ML networks with the ability to potentially trade power and performance goals while still ensuring the required classification accuracy. The simulation technique also enables to determine target specifications for each circuit block in the analog computing hardware. This is achieved by developing the ML hardware model, and investigating the effect of circuit nonidealities on classification accuracy. Simulation of an analog computing EEG seizure detection block shows a classification accuracy of 91%. The proposed modeling approach will significantly reduce design time and complexity of large analog computing systems. Two feature extraction approaches are also compared for an analog computing architecture. 

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4. Programmable Analog System Benchmarks Leading to Efficient Analog Computation Synthesis

   https://doi.org/10.1145/3625298  

   Hasler, Jennifer; Hao, Cong (March 2024, ACM Transactions on Reconfigurable Technology and Systems)

   This effort develops the first rich suite of analog and mixed-signal benchmark of various sizes and domains, intended for use with contemporary analog and mixed-signal designs and synthesis tools. Benchmarking enables analog-digital co-design exploration as well as extensive evaluation of analog synthesis tools and the generated analog/mixed-signal circuit or device. The goals of this effort are defining analog computation system benchmarks, developing the required concepts for higher-level analog and mixed-signal tools to utilize these benchmarks, and enabling future automated architectural design space exploration (DSE) to determine the best configurable architecture (e.g., a new FPAA) for a certain family of applications. The benchmarks comprise multiple levels of anacoustic, avision, acommunications, and an analogfiltersystem that must be simultaneously satisfied for a complete system. 

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5. Towards Decrypting the Art of Analog Layout: Placement Quality Prediction via Transfer Learning

   https://doi.org/10.23919/DATE48585.2020.9116330  

   Liu, Mingjie; Zhu, Keren; Gu, Jiaqi; Shen, Linxiao; Tang, Xiyuan; Sun, Nan; Pan, David Z. (March 2020, 2020 Design, Automation & Test in Europe Conference & Exhibition (DATE))

   Despite tremendous efforts in analog layout automation, little adoption has been demonstrated in practical design flows. Traditional analog layout synthesis tools use various heuristic constraints to prune the design space to ensure post layout performance. However, these approaches provide limited guarantee and poor generalizability due to a lack of model mapping layout properties to circuit performance. In this paper, we attempt to shorten the gap in post layout performance modeling for analog circuits with a quantitative statistical approach. We leverage a state-of-the-art automatic analog layout tool and industry-level simulator to generate labeled training data in an automated manner. We propose a 3D convolutional neural network (CNN) model to predict the relative placement quality using well-crafted placement features. To achieve data-efficiency for practical usage, we further propose a transfer learning scheme that greatly reduces the amount of data needed. Our model would enable early pruning and efficient design explorations for practical layout design flows. Experimental results demonstrate the effectiveness and generalizability of our method across different operational transconductance amplifier (OTA) designs. 

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