Won Namgoong scite author profile

The application of ultra-wideband (UWB) technology to low-cost short-range communications presents unique challenges to the communications engineer. The impact of the US FCC's regulations and the characteristics of the low-power UWB propagation channels are explored, and their effects on UWB hardware design are illustrated. This tutorial introduction includes references to more detailed explorations of the subject

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A channelized digital ultrawideband receiver

Namgoong

2003

IEEE Trans. Wireless Commun.

160

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Abstract-A channelized digital ultrawideband (UWB) receiver that efficiently samples the UWB signal at a fraction of the chip frequency is proposed. The received signal is channelized in the frequency domain by employing a bank of mixers and low-pass filters. After sampling at a much reduced frequency, digital synthesis filters optimally estimate the transmitted signals. The signal-to-noise ratio (SNR) of the proposed receiver has been solved and compared against an ideal conventional receiver, which is defined as a receiver that samples at the signal Nyquist rate. When finite resolution analog-to-digital converters (ADC) are employed in the presence of a large narrowband interferer, the proposed receiver significantly outperforms the ideal conventional receiver. For example, the SNR of the proposed receiver is as much as 20 dB higher than the ideal conventional receiver when a 4-bit ADC is used in the presence of a 50 dB (relative to the noise floor) brickwall narrowband interferer with a bandwidth of 15% of the chip frequency.

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A high-efficiency variable-voltage CMOS dynamic dc-dc switching regulator

Namgoong¹,

Meng

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Direct-conversion RF receiver design

Namgoong

Meng

2001

IEEE Trans. Commun.

101

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Direct-conversion radio-frequency receiver architecture promises superior performances in power, size, and cost over existing superheterodyne-based receivers. The use of direct-conversion receiver (DCR) architecture, however, has been limited due to two well-known problems, namely, the 1=f noise and the direct-current offset noise, to which conventional architectures are less sensitive. This paper analyzes these noise effects on reception performance of a DCR with alternating-current (ac) coupling filter in the receive path. A mathematical treatment of the performance of a DCR is provided. A performance bound of a DCR given its 1=f noise roll-off frequency and ac-coupling filter cutoff frequency is first obtained using vector coding. Then, the performance of a more practical adaptive reception method using a linear equalizer is discussed. Adaptability is especially important in rapidly time-varying channels such as in the wireless environment. Linear equalizer is effective at signal-to-noise ratios (SNRs) below 9 dB, but its performance degrades significantly at larger SNR. To achieve high performance at large SNR (9 dB), a spectrum shaping method using line codes for direct-conversion reception is proposed. This method achieves near-optimum direct-conversion reception at high SNR while maintaining low complexity and adaptability at the receiver.

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Modeling and analysis of nonlinearities and mismatches in AC-coupled direct-conversion receiver

Namgoong

2005

IEEE Trans. Wireless Commun.

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A channelized DSSS ultra-wideband receiver

Namgoong

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A High Data-Rate Energy-Efficient Interference-Tolerant Fully Integrated CMOS Frequency Channelized UWB Transceiver for Impulse Radio

Medi

Namgoong

2008

IEEE J. Solid-State Circuits

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Won Namgoong

A Non-Iterative Technique for Phase Noise ICI Mitigation in Packet-Based OFDM Systems

Ultra-Wideband Radio

A channelized digital ultrawideband receiver

A high-efficiency variable-voltage CMOS dynamic dc-dc switching regulator

Direct-conversion RF receiver design

Modeling and analysis of nonlinearities and mismatches in AC-coupled direct-conversion receiver

A channelized DSSS ultra-wideband receiver

A High Data-Rate Energy-Efficient Interference-Tolerant Fully Integrated CMOS Frequency Channelized UWB Transceiver for Impulse Radio

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