Taeyoung Chung scite author profile

A flexible, three-axis carbon nanotube (CNT)–polymer composite-based tactile sensor is presented. The proposed sensor consists of a flexible substrate, four sensing cells, and a bump structure. A CNT–polydimethylsiloxane (PDMS) composite is produced by a solvent evaporation method, and thus, the CNTs are well-dispersed within the PDMS matrix. The composite is directly patterned onto a flexible substrate using a screen printing technique to fabricate a sensor with four sensing cells. When a force is applied on the bump, the magnitude and direction of force could be detected by comparing the changes in electrical resistance of each sensing cell caused by the piezoresistive effect of the composite. The experimentally verified sensing characteristics of the fabricated sensor exhibit a linear relationship between the resistance change and the applied force, and the measured sensitivities of the sensor for the normal and shear forces are 6.67 and 86.7%/N for forces up to 2.0 and 0.5 N, respectively. Experiments to verify the load-sensing repeatability show a maximum 2.00% deviation of the resistance change within the tested force range.

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A Wideband Differential Low-Noise-Amplifier With IM3 Harmonics and Noise Canceling

Lee

Chung

Seo

et al. 2015

IEEE Microw. Wireless Compon. Lett.

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A Wideband CMOS Noise-Canceling Low-Noise Amplifier With High Linearity

Chung

Lee

Jeong

et al. 2015

IEEE Microw. Wireless Compon. Lett.

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This letter presents a wideband noise-canceling LNA focusing on canceling IMD2 and IMD3. By using a complementary CMOS parallel push-pull structure, the IMD2 is cancelled. The modified noise-canceling circuit properly suppresses the IMD3. Although the optimum canceling points for the noise and distortions are different, the noise figure is not degraded by the choice. The LNA implemented in a 65 nm CMOS process delivers an IIP2 of 25 dBm, an IIP3 of 5.5 dBm with a power gain of 13 dB and an noise figure of 2.1-3.5 dB in a frequency range from 0.1 to 1.6 GHz. The power consumption is 20.8 mW at 1.2 V and the chip area is only .Index Terms-IM2 distortion-canceling, IM3 distortion-canceling, noise-canceling, wideband low-noise amplifier.

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Laser Dicing and Subsequent Die Strength Enhancement Technologies for Ultra-thin Wafer

Hwang

Ahn

et al. 2007

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Current mechanical wafer dicing process adopting diamond grit shows advantages of low cost and high productivity. However, mechanical process for ultra-thin wafers would induce residual stress or mechanical damage, which can lead to wafer broken and die cracking. With the development of laser technology, laser precision micromachining has been employed for thin semiconductor wafer singulation, which shows advantages of no chipping, small kerf width, and high throughput over mechanical blade dicing. However, thermal damage to the chip induced by laser ablation results in die strength degradation. For ultra thin chip, low die strength tends to induce die crack in packaging process. Thus, thermal damage to the chip needs to be studied.In this study, first we made a comparison between mechanical blade sawing and laser ablation processes. Die strength and microstructure changes were studied by means of bending test and transmission electron microscope (TEM) analysis, respectively. Die strength results showed that the die strength obtained by laser dicing was far lower than that obtained by blade sawing. TEM analysis demonstrated that formation of microcracks and porosities in laser diced face, caused the die strength degradation. In addition, significant deviation between frontside and backside die strength was found in the laser micromachinned dies. The reason for this deviation was clarified as the defects density difference existing in top and bottom layer of the chip sidewall. Experiments results showed that the die strength obtained by laser dicing can not meet the demand of the packaging process. It tends to crack or fracture in the die attach or wire bonding process. Thus, it is essential to improve the die strength. Thus, in this investigation, etching processes including wet-etch and dry-etch were attempted to recover the die strength by removing the chip side wall damage. SEM and TEM images indicated that, before etching, the laser diced side walls were with rough surfaces, voids and microcracks. After etching, the surfaces got smooth and most of the voids and microcracks were removed. Chip strength measurement also verified the partial die strength recovery after etching process.

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Taeyoung Chung

8 Gb 3-D DDR3 DRAM Using Through-Silicon-Via Technology

Development of a flexible three-axis tactile sensor based on screen-printed carbon nanotube-polymer composite

A Wideband Differential Low-Noise-Amplifier With IM3 Harmonics and Noise Canceling

A Wideband CMOS Noise-Canceling Low-Noise Amplifier With High Linearity

Laser Dicing and Subsequent Die Strength Enhancement Technologies for Ultra-thin Wafer

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