Moojong Lim scite author profile

Recent electronic applications require an efficient computing system that can perform data processing with limited energy consumption. Inspired by the massive parallelism of the human brain, a neuromorphic system (hardware neural network) may provide an efficient computing unit to perform such tasks as classification and recognition. However, the implementation of synaptic devices (i.e., the essential building blocks for emulating the functions of biological synapses) remains challenging due to their uncontrollable weight update protocol and corresponding uncertain effects on the operation of the system, which can lead to a bottleneck in the continuous design and optimization. Here, we demonstrate a synaptic transistor based on highly purified, preseparated 99% semiconducting carbon nanotubes, which can provide adjustable weight update linearity and variation margin. The pattern recognition efficacy is validated using a device-to-system level simulation framework. The enlarged margin rather than the linear weight update can enhance the fault tolerance of the recognition system, which improves the recognition accuracy.

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Transparent, Flexible Strain Sensor Based on a Solution-Processed Carbon Nanotube Network

Lee

Lim

Yoon

et al. 2017

ACS Appl. Mater. Interfaces

146

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The demands for transparent, flexible electronic devices are continuously increasing due to their potential applications to the human body. In particular, skin-like, transparent, flexible strain sensors have been developed to realize multifunctional human-machine interfaces. Here, we report a sandwich-like structured strain sensor with excellent optical transparency based on highly purified, solution-processed, 99% metallic CNT-polydimethylsiloxane (PDMS) composite thin films. Our CNT-PDMS composite strain sensors are mechanically compliant, physically robust, and easily fabricated. The fabricated strain sensors exhibit a high optical transparency of over 92% in the visible range with acceptable sensing performances in terms of sensitivity, hysteresis, linearity, and drift. We also found that the sensitivity and linearity of the strain sensors can be controlled by the number of CNT sprays; hence, our sensor can be applied and controlled based on the need of individual applications. Finally, we investigated the detections of human activities and emotions by mounting our transparent strain sensor on various spots of human skins.

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Evaluating liquid crystal properties for use in terahertz devices

et al. 2012

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Despite the wide application of liquid crystals (LCs) in the visible frequency range, their properties in the terahertz range have not yet been extensively investigated. In this paper we have investigated the terahertz properties of LCs E7, BL037, RDP-94990 and RDP-97304 using terahertz time-domain-spectroscopy. We find that RDP-94990 has the largest birefringence and smallest absorption in the terahertz range compared to E7 and BL037. We highlight the importance of investigating all parameters, not just the birefringence, when designing fast, efficient and transmissive terahertz LC devices.

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Impact of Synaptic Device Variations on Pattern Recognition Accuracy in a Hardware Neural Network

Kim

Lim

Kim

et al. 2018

Sci Rep

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Neuromorphic systems (hardware neural networks) derive inspiration from biological neural systems and are expected to be a computing breakthrough beyond conventional von Neumann architecture. Interestingly, in neuromorphic systems, the processing and storing of information can be performed simultaneously by modulating the connection strength of a synaptic device (i.e., synaptic weight). Previously investigated synaptic devices can emulate the functionality of biological synapses successfully by utilizing various nano-electronic phenomena; however, the impact of intrinsic synaptic device variability on the system performance has not yet been studied. Here, we perform a device-tosystem level simulation of different synaptic device variation parameters in a designed neuromorphic system that has the potential for unsupervised learning and pattern recognition. The effects of variations in parameters such as the weight modulation nonlinearity (NL), the minimum-maximum weight (G min and G max ), and the weight update margin (ΔG) on the pattern recognition accuracy are analyzed quantitatively. These simulation results can provide guidelines for the continued design and optimization of a synaptic device for realizing a functional large-scale neuromorphic computing system.The mammalian neocortex offers extremely energy-efficient information processing performance in tasks such as pattern recognition with a power consumption of only 10-20 watts 1 . By mimicking both the functional and structural advantages of this biological neural system, the recent development of power-efficient computing systems, i.e., neuromorphic systems (hardware neural networks) 2 , has been expected to offer a promising breakthrough for applications, ranging from mobile platforms 3 to artificial intelligence operations 4 , where power consumption is a concern.A unique feature of neuromorphic systems is efficient parallel data processing, where the processing of information can be performed by modulating the connection strength of synapses (referred to as the synaptic weight) 5 . This synaptic weight can be modulated by either potentiating or depressing neural spikes (pulses) from pre-and post-synaptic neurons, following appropriate learning rules, such as spike-timing-dependent plasticity (STDP) 6 . Therefore, a key element in the neuromorphic system is the implementation of an ideal synaptic device that can emulate the functionality of biological synapses.To date, various nano-electronic devices have successfully reproduced a specific learning rule of biological synapses through their internal analog conductance states that can be modulated intentionally with an applied pulse's timing or level [7][8][9][10][11][12][13][14][15] . Moreover, the potential of ultralow energy consumption per synaptic operation 16 , as well as the possibility of realizing three-dimensional integration 17 , have shown the promising feasibility of large-scale neuromorphic system implementation in the near future. However, the sustainability of such devices is still in dou...

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Quantitative coherent scattering spectra in apertureless terahertz pulse near-field microscopes

Moon¹,

Do²,

Lim³

et al. 2012

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We present quantitative coherent measurements of scattering pulses and spectra in terahertz apertureless near-field microscopes. Broadband near-field image contrasts for both amplitude and phase spectra are measured directly from time-domain scattering signals with an unprecedentedly high single-scan signal-to-noise ratio (∼48 dB), with approach curves for both short (<200 nm) and long (up to 82 μm) ranges. By using the line dipole image method, we obtain quantitative broadband THz imaging contrasts with nanoscale resolution.

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Moojong Lim

Pattern Recognition Using Carbon Nanotube Synaptic Transistors with an Adjustable Weight Update Protocol

Transparent, Flexible Strain Sensor Based on a Solution-Processed Carbon Nanotube Network

Evaluating liquid crystal properties for use in terahertz devices

Impact of Synaptic Device Variations on Pattern Recognition Accuracy in a Hardware Neural Network

Quantitative coherent scattering spectra in apertureless terahertz pulse near-field microscopes

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