• JSTS:Journal of Semiconductor Technology and Science
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• v.14 no.6
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• pp.818-823
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• 2014

A high-gain wideband low noise amplifier (LNA) using $0.25-{\mu}m$ Gallium-Nitride (GaN) MMIC technology is presented. The LNA shows 8 GHz to 15 GHz operation by a distributed amplifier architecture and high gain with an additional common source amplifier as a mid-stage. The measurement results show a flat gain of $25.1{\pm}0.8dB$ and input and output matching of -12 dB for all targeted frequencies. The measured minimum noise figure is 2.8 dB at 12.6 GHz and below 3.6 dB across all frequencies. It consumes 98 mA with a 10-V supply. By adjusting the gate voltage of the mid-stage common source amplifier, the overall gain is controlled stably from 13 dB to 24 dB with no significant variations of the input and output matching.

• Proceedings of the Korea Contents Association Conference
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• 2004.11a
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• pp.461-465
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• 2004

In this paper, we examined receiving parameters of IMT-2000 receiving system and also analyzed them through simulation based on the minimum specification of DCS and PCS mobile station. As a result of simulation, noise figure which is the parameter of specification of the receiving sensitivity is 7.21dB, 6.03dB, and 7.89dB in case of DCS, PCS and IMT-2000 respectively. Therefore we found the receiving sensitivity of IMT-2000 mobile station lower than that of DCS and PCS.

• Journal of the Korea Computer Industry Society
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• v.2 no.11
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• pp.1477-1482
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• 2001

In this paper, we examined receiving parameters of receiver and also analyzed them through simulation based on J-STD-018, which is the minimum specification of PCS mobile station. Receiving system was made a passive double balance mixer which has low gain and high IIP3, and an intermediate frequency amplifier for enhancing the low gain. The result of simulating receiving parameter is as follows: noise figure which is the parameter of specification of the receiving sensitivity is 6.746dB, IIP3 which is the parameter of specification of the intermodulation spurious response attenuation is -11.358dBm.

• JSTS:Journal of Semiconductor Technology and Science
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• v.3 no.1
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• pp.42-46
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• 2003

In this paper, an MMIC broadband amplifier for wireless communication systems has been developed by using an active feedback method. This active feedback operates at much higher frequencies than a method by a spiral inductor feedback and its size is independent of the inductance value. The MMIC broadband amplifier was designed using a $0.5{\;}{\mutextrm{m}}$ MESFET library. The fabricated chip area was $1.4{\;}mm{\;}{\times}{\;}1.4{\;}mm. Measurement showed a gain of 18 dB with a gain flatness of ${\pm}3$ dB in a 1.5 GHz~3.5 GHz band. The maximum output power and the minimum noise figure were 14 dBm and 2.5 dB in the same band, respectively.

• The Transactions of The Korean Institute of Electrical Engineers
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• v.61 no.11
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• pp.1671-1675
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• 2012

In this paper, we fabricate multi-channel receiver for radar system. This receiver at X-band can be received 8 signal of an identical characteristic, dynamic range has more than 80[dB]. To process direct received signals, this system has the built-in two digital de-modulators which offer the minimum loss on the receiving signal path and has high stability by adding Built-In Test. The gain, noise figure, difference of amplitude and phase on the signal path is respectively $14{\pm}2$[dB], 19[dB], ${\pm}2$[dB], $10^{\circ}$ and below.

• Journal of the Korean Institute of Telematics and Electronics A
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• v.30A no.11
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• pp.58-65
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• 1993

The Ku-band GaAs MESFET mixer is designed and implemented using the LINMIC+, the microwave CAD simulator. The RF and IF is 14.0GHz and 1.0GHz, respectively. P$_{LO}$ is 0dBm, it can be obtained 5.8dB of the minimum noise figure at 1.4GHz and 5.8dB of the maximum conversion gain at 1.45GHz. Effects of bias and power level of local oscillator frequency are observed and the characteristics are verified.

• KSII Transactions on Internet and Information Systems (TIIS)
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• v.2 no.1
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• pp.37-49
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• 2008

At the present time the task of designing a highly integrated ZigBee radio frequency (RF) receiver with an excellent coexistence performance is still very demanding and challenging. This paper presents a number of system issues and design considerations for a ZigBee RF receiver, namely IEEE 802.15.4, for coexistence with wireless devices in the 2.4-GHz ISM-band. With regard to IEEE 802.15.4, the paper analyzes receiver performance requirements for; system noise figure (NF), system third-order intercept point (system-IIP3), local oscillator phase noise and selectivity. Based on some assumptions, the paper illustrates the relationship between minimum detectable signal (MDS) and various situations that involve the effects of electromagnetic interference generated by other wireless devices. We infer the necessity of much more stringent specification requirements than the published standard for various wireless communication field environments

• ETRI Journal
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• v.27 no.6
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• pp.685-690
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• 2005

DC and RF characteristics of $0.15{\mu}m$ GaAs power metamorphic high electron mobility transistors (MHEMT) have been investigated. The $0.15{\mu}m{\times}100{\mu}m$ MHEMT device shows a drain saturation current of 480 mA/mm, an extrinsic transconductance of 830 mS/mm, and a threshold voltage of -0.65 V. Uniformities of the threshold voltage and the maximum extrinsic transconductance across a 4-inch wafer were 8.3% and 5.1%, respectively. The obtained cut-off frequency and maximum frequency of oscillation are 141 GHz and 243 GHz, respectively. The $8{\times}50{\mu}m$ MHEMT device shows 33.2% power-added efficiency, an 18.1 dB power gain, and a 28.2 mW output power. A very low minimum noise figure of 0.79 dB and an associated gain of 10.56 dB at 26 GHz are obtained for the power MHEMT with an indium content of 53% in the InGaAs channel. This excellent noise characteristic is attributed to the drastic reduction of gate resistance by the T-shaped gate with a wide head and improved device performance. This power MHEMT technology can be used toward 77 GHz band applications.

• The Journal of Korean Institute of Electromagnetic Engineering and Science
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• v.11 no.1
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• pp.102-109
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• 2000

In this paper, a Low Noise Amplifier for B-WLL was designed using the MMIC technology with GaAs PHEMTs fabricated at our lab. The PHEMT for LNA has a $0.35\mu\textrm{m}$ gate and a total gate width of $120\mu\textrm{m}$. The designed MMIC LNA consists of three stages. The first stage of the LNA has a series inductive feedback for obtaining minimum noise and high stability as well. And the designed MMIC LNA has not an interstage matching circuit between the second and the third stage for minimization of the chip size. From simulation results, noise figure and S21 gain of the designed MMIC LNA are 0.85~1.25 dB and 22.08~23.65 dB in the frequency range of 25.5~27.5 GHz respectively. And the chip size is $3.7\times1.6 mm^2$.

• Journal of electromagnetic engineering and science
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• v.14 no.2
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• pp.61-67
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• 2014

This paper presents a zero-IF CMOS RF receiver, which supports three channel bandwidths of 5/10/40MHz for LTE-Advanced systems. The receiver operates at IMT-band of 2,500 to 2,690MHz. The simulated noise figure of the overall receiver is 1.6 dB at 7MHz (7.5 dB at 7.5 kHz). The receiver is composed of two parts: an RF front-end and a baseband circuit. In the RF front-end, a RF input signal is amplified by a low noise amplifier and $G_m$ with configurable gain steps (41/35/29/23 dB) with optimized noise and linearity performances for a wide dynamic range. The proposed baseband circuit provides a -1 dB cutoff frequency of up to 40MHz using a proposed wideband OP-amp, which has a phase margin of $77^{\circ}$ and an unit-gain bandwidth of 2.04 GHz. The proposed zero-IF CMOS RF receiver has been implemented in $0.13-{\mu}m$ CMOS technology and consumes 116 (for high gain mode)/106 (for low gain mode) mA from a 1.2 V supply voltage. The measurement of a fabricated chip for a 10-MHz 3G LTE input signal with 16-QAM shows more than 8.3 dB of minimum signal-to-noise ratio, while receiving the input channel power from -88 to -12 dBm.