Sensor applications of thin‐film devices originating in display technologies

Kimura, Mutsumi

doi:10.1002/jsid.839

Cited by 4 publications

(2 citation statements)

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“…[17][18][19] The physical separation of the sensing module and other modules leads to large energy consumption and significant delay in data transformation, resulting in difficult frequent data interaction. [20][21][22] Correspondingly, to pursue more realistic display effects, traditional display technology focuses on improving the color brightness and purity of light-emitting pixels, [23] reducing pixel size, [24] fabricating large-scale complex array circuits, [25,26] and designing more complex driving circuits. [27] However, traditional display technology essentially adopts the storage-compute separation strategy.…”

Section: Introductionmentioning

confidence: 99%

Toward Intelligent Display with Neuromorphic Technology

Zhang,

Liu,

Liu

et al. 2024

Advanced Materials

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In the era of the Internet and the Internet of Things, display technology has evolved significantly toward full‐scene display and realistic display. Incorporating ‘intelligence’ into displays is a crucial technical approach to meet the demands of this development. Traditional display technology relies on distributed hardware systems to achieve intelligent displays but encounters challenges stemming from the physical separation of sensing, processing, and light‐emitting modules. The high energy consumption and data transformation delays limited the development of intelligence display, breaking the physical separation is crucial to overcoming the bottlenecks of intelligence display technology. Inspired by the biological neural system, neuromorphic technology with all‐in‐one features is widely employed across various fields. It proves effective in reducing system power consumption, facilitating frequent data transformation, and enabling cross‐scene integration. Neuromorphic technology shows great potential to overcome display technology bottlenecks, realizing the full‐scene display and realistic display with high efficiency and low power consumption. In this review, we offer a comprehensive summary of recent advancements in the application of neuromorphic technology in displays, with a focus on interoperability. We delve into its state‐of‐the‐art designs and potential future developments aimed at revolutionizing display technology.This article is protected by copyright. All rights reserved

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Section: Introductionmentioning

confidence: 99%

Toward Intelligent Display with Neuromorphic Technology

Zhang,

Liu,

Liu

et al. 2024

Advanced Materials

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“…PVD techniques (Physical Vapor deposition) form an important class of techniques which are widely explored for the preparation of technologically important optical and electronic devices including optical filters [1], high reflecting (HR) mirrors [2], photovoltaics [3], display, sensors [4] etc In almost every such application one common concern is the spatial uniformity in terms of thickness and physical attributes of the film deposited in different lateral spots of the substrate. This gains increasing attention, as the batch production and large area manufacturing of thin film devices becomes necessary to fulfill the criteria of cost reduction.…”

Section: Introductionmentioning

confidence: 99%

In-situ optimization of lateral film uniformity in PVD system by using Fiber Bragg grating temperature sensors

Haque,

Jagannadha Raju,

Kumar

et al. 2024

Phys. Scr.

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Fiber Bragg grating (FBG) based temperature sensing method has been employed in this work for measuring the lateral temperature distribution on substrate plane during pulse DC magnetron sputtering deposition for optimization of lateral film uniformity. The evolution of temperature distribution with the variation of important process parameters like pulse width (496–1616 ns), deposition pressure (3.1 × 10−3–1.9 × 10–2 mbar) and sputtering power (25–250 W) have been measured over 40 mm radial distance on glass substrate horizon. To investigate the effect of substrate height on the temperature distribution, the later has been measured at two different substrate heights (60 mm and 90 mm) for varying sputtering power. Finally, the effect of variation in temperature distribution on uniformity of thickness and optical, morphological and structural properties have been investigated by separately depositing two HfO2 thin films at two representative extreme deposition powers (75 W and 200 W). The correlation of film non-uniformity of the above properties with the temperature distribution suggests that FBG based multipoint temperature sensing can be possibly used as an indicative tool for in situ optimization of the lateral film uniformity. In addition, the fast response and workability in plasma environment of FBG sensors enables precise in situ mapping of temperature distribution in sputtering process.

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