Could We Realize the Fully Flexible System by Real-Time Computing with Thin-Film Transistors?

Q, Li; Liu, Zheyu; Qiao, Fei; Wei, Qi; Yang, Huazhong

doi:10.3390/app7121224

Cited by 3 publications

(1 citation statement)

References 28 publications

(43 reference statements)

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“…Li et al is interested in the realization of flexible system with more flexible devices (such as thin-film transistors) for usage in sensors, wearable devices and energy suppliers, including in the computation parts [42]. Therefore, they propose a new circuit architecture for the purposes of an image processing accelerator based on thin-film transistors.…”

Section: Dineva Et Al Propose a New Methodology For Multi-label Classification At The Diagnosis Of Multiple Faults Occurring In Electricamentioning

confidence: 99%

Machine Learning and Fuzzy Logic in Electronics: Applying Intelligence in Practice

2021

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The paper presents an analysis and summary of the current research state concerning the application of machine learning and fuzzy logic for solving problems in electronics. The investigated domain is conceptualized with aim the achievements, trending topics and future research directions to be outlined. The applied research methodology includes a bibliographic approach in combination with a detailed examination of 66 selected papers. The findings reveal the gradually increasing interest over the last 10 years in the machine learning and fuzzy logic techniques for modeling, implementing and improving different hardware-based intelligent systems.

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Section: Dineva Et Al Propose a New Methodology For Multi-label Classification At The Diagnosis Of Multiple Faults Occurring In Electricamentioning

confidence: 99%

Machine Learning and Fuzzy Logic in Electronics: Applying Intelligence in Practice

2021

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Reviews of wearable healthcare systems: Materials, devices and system integration

Lou

Wang

Jiang

et al. 2020

Materials Science and Engineering: R: Reports

292

169

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Ultra-Efficient Low-Power Retinal Nano Electronic Circuit for Edge Enhancement and Detection Using 7 nm FinFET Technology

Turiqul Islam,

Al-Shidaifat,

Jooq

et al. 2024

Journal of Nanoelectronics and Optoelectronics

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This study proposed a 7 nm FinFET based analog one pixel circuit block inspired by lateral inhibition phenomenon to perform edge enhancing and edge detection of optoelectronic image. This plays a crucial role in retinomorphic applications like artificial human retinal functions. Proposed Edge enhancement and edge detection circuits are constructed using two distinct 750×750-pixel silicon networks. First the single pixel circuit cell is reconstructed with the lateral inhibition phenomenon, then the circuit using GPDK (Generic Process Design Kit) in 180 nm, 90 nm, and 45 nm CMOS technology is designed. We used 3×3 convolution process for image masking in digital and analog image signal processing which gives more accuracy in term of object recognition. The power consumption in each case is obtained to be approximately 19.71 μW, 4.18 μW and 1.62 μW for edge enhancing and 23.76 μW, 7.99 μW and 3.41 μW for edge detection which is much larger than the power consumed by the same circuit is implemented with 7 nm FinFET (Fin Field Effect Transistor) technology, 21.91 pW and 24.85 pW. In addition, the size reduction of the circuit reduced by 84% compared with 45 nm CMOS, increases the accuracy of the circuit by 30%. Results confirm that FinFET based single pixel circuit consumes less power, reduces size, and gives higher accuracy. The output from all the circuits has been matched with the biological response.

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Could We Realize the Fully Flexible System by Real-Time Computing with Thin-Film Transistors?

Cited by 3 publications

References 28 publications

Machine Learning and Fuzzy Logic in Electronics: Applying Intelligence in Practice

Machine Learning and Fuzzy Logic in Electronics: Applying Intelligence in Practice

Reviews of wearable healthcare systems: Materials, devices and system integration

Ultra-Efficient Low-Power Retinal Nano Electronic Circuit for Edge Enhancement and Detection Using 7 nm FinFET Technology

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