Mutual Capacitive Sensing Touch Screen Controller for Ultrathin Display with Extended Signal Passband Using Negative Capacitance

Lee, Chang-Ju; Park, Jong Kang; Piao, Canxing; Seo, Haneol; Choi, Jaehyuk; Chun, Jung-Hoon

doi:10.3390/s18113637

Cited by 19 publications

(11 citation statements)

References 10 publications

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“…Finally, a capacitive touch-screen panel was fabricated with the films exhibited the highest transmittance (i.e., ITO/SiO 2 /ITO structure annealed at 823 K) by using conducting pads with an individual pattern size of 1 × 1 mm to pattern the ITO layer, as is shown in schematic design Figure 7a. There are various shapes and structures of capacitive TSPs based on the method used to form the touch sensor electrodes [33]. Among various methods, a method of forming a touch screen pattern in a low surface of a window and an on-cell TSP method for forming a touch screen pattern in an upper surface of a display effectively increases the display area while reducing the thickness [34].…”

Section: Resultsmentioning

confidence: 99%

ITO/SiO2/ITO Structure on a Sapphire Substrate Using the Oxidation of Ultra-Thin Si Films as an Insulating Layer for One-Glass-Solution Capacitive Touch-Screen Panels

Joo

Loka

et al. 2020

Coatings

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The SiO2 generated by low-temperature oxidation of ultra-thin metallic silicon (thickness = 50 nm) film was evaluated for implementation in one-glass-solution capacitive touch-screen panels (OGS-TSPs) on sapphire-based substrates. Our results show that the silicon films oxidized at 823 K exhibited the highest visible transmittance about 91% at 550 nm, compared to ~72% transmittance of the as-deposited silicon films which were deposited at room temperature. Additionally, the annealed films exhibited a more uniform, dense, and smooth surface microstructure than that of the as-deposited Si films. X-ray photoelectron spectroscopy (XPS) results revealed that the low-temperature oxidation of Si films at 823 K yielded SiO2. Furthermore, when the insulating SiO2 film obtained by low-temperature oxidation was sandwiched between two indium tin oxide (ITO) layers (ITO/SiO2/ITO) on a sapphire substrate, the SiO2 film resulted in the dielectric strength of approximately 3 MV/cm. In addition, the highest optical transmittance obtained by the ITO/SiO2/ITO films is about 88.3%. The change in capacitance of the ITO/SiO2/ITO structure was approximately 3.2 pF, which indicates the possibility of implementation in capacitive touch-screen panel devices.

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Section: Resultsmentioning

confidence: 99%

ITO/SiO2/ITO Structure on a Sapphire Substrate Using the Oxidation of Ultra-Thin Si Films as an Insulating Layer for One-Glass-Solution Capacitive Touch-Screen Panels

Joo

Loka

et al. 2020

Coatings

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“…[ 81,82 ] Thus, conductive elements for a conventional capacitive sensor are fabricated by designing the geometries of traditional materials, such as percolating network, [ 83 ] wavy geometry [ 84,85 ] serpentine [ 86 ] and helical structure, [ 87 ] and mesh shapes. [ 88 ] In addition, the flexibility of the electrode can be achieved through the incorporation of conductive materials, such as graphene, [ 89,90 ] carbon black, [ 91 ] metal nanowires, [ 60,92 ] metal nanoparticles, [ 93 ] and CNTs, [ 62,94,95 ] into a polymer matrix. Recently, some studies introduced secondary fillers to improve the mechanical, chemical, and electrical properties of the stretchable composite electrodes.…”

Section: Mechanisms and Sensitivitymentioning

confidence: 99%

Strain Sensing by Electrical Capacitive Variation: From Stretchable Materials to Electronic Interfaces

Nesser

Lubineau

2021

Adv Elect Materials

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Sensing the motion of objects and humans is essential for various applications, including human‐machine interfaces. Over the past few years, motion sensing has been extensively studied using capacitive strain sensors that can be utilized for wireless communications. The performance and functionality of capacitive strain sensors have been improved by achieving high sensitivity, large‐area sensing, ultra‐stretchability, and simplicity in design, measurement methods, and wireless integration. This review article highlights recent developments in capacitive strain sensors, including their characteristics and applications. First, the mechanisms and techniques employed to enhance the sensitivity of capacitive strain sensors are reviewed. Then, the notable features of this sensing strategy are highlighted, such as its ability to cover a wide area, properties of the required electronic interface, and sensor implementation inside a remote measurement system via an oscillating circuit. Therefore, a global review of the capacitive strain sensor that has been previously attempted can participate in developing an effective sensing method to meet the market need.

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“…In addition, when using signals of other waveforms such as sine waves instead of accurate pulses such as ΔVREF in the self-capacitance readout circuit or ΔVTX in the mutualcapacitance readout circuit, there may be an error source if the accurate negative polarity of compensation voltage driving is not realized. To solve this problem, a structure that compensates for a negative capacitance circuit using an additional Op amplifier without applying a negative polarity signal has been proposed [13,14,15]. Another method of compensation uses an another sensor instead of a compensation capacitor.…”

Section: Charge-balancing Compensation: Using a Compensation Capacitormentioning

confidence: 99%

Readout Circuits for Capacitive Sensors

Yoo

Choi

2021

Micromachines

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The development of microelectromechanical system (MEMS) processes enables the integration of capacitive sensors into silicon integrated circuits. These sensors have been gaining considerable attention as a solution for mobile and internet of things (IoT) devices because of their low power consumption. In this study, we introduce the operating principle of representative capacitive sensors and discuss the major technical challenges, solutions, and future tasks for a capacitive readout system. The signal-to-noise ratio (SNR) is the most important performance parameter for a sensor system that measures changes in physical quantities; in addition, power consumption is another important factor because of the characteristics of mobile and IoT devices. Signal power degradation and noise, which degrade the SNR in the sensor readout system, are analyzed; circuit design approaches for degradation prevention are discussed. Further, we discuss the previous efforts and existing studies that focus on low power consumption. We present detailed circuit techniques and illustrate their effectiveness in suppressing signal power degradation and achieving lower noise levels via application to a design example of an actual MEMS microphone readout system.

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Mutual Capacitive Sensing Touch Screen Controller for Ultrathin Display with Extended Signal Passband Using Negative Capacitance

Cited by 19 publications

References 10 publications

ITO/SiO2/ITO Structure on a Sapphire Substrate Using the Oxidation of Ultra-Thin Si Films as an Insulating Layer for One-Glass-Solution Capacitive Touch-Screen Panels

ITO/SiO2/ITO Structure on a Sapphire Substrate Using the Oxidation of Ultra-Thin Si Films as an Insulating Layer for One-Glass-Solution Capacitive Touch-Screen Panels

Strain Sensing by Electrical Capacitive Variation: From Stretchable Materials to Electronic Interfaces

Readout Circuits for Capacitive Sensors

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