This study proposes an energy detector for a noncoherent impulse-radio UWB receiver, designed in a 0.18-mum CMOS technology. The squaring functionality is realized exploiting the quadratic characteristic of MOS transistors, and the deviation from such a characteristic due to short channel effects and device mismatch is carefully considered in the paper. The squared signal is integrated using a Gm-C integrator that is interfaced with the squarer using a flipped voltage follower current sensor as a current to voltage converter. The proposed circuit dissipates 5.4 mW for a receiver sensitivity at the antenna of -89 dBm. Synchronization is demonstrated at the system level and some considerations on robustness to narrowband interferers are presented
The increasing interest in impulse radio UWB communication links focuses the research interest on building blocks optimized for these specific systems. In this context, this paper proposes a ring oscillator for an impulse radio UWB transmitter. A multiloop ring oscillator is considered because it holds the potential of both high oscillation frequency and fast switch-on time. The novelty of the proposed inverter cell is found in the possibility to adjust the oscillation frequency digitally, rather than with an analog voltage. This leads to larger tuning range and less sensitivity to control noise. The digitally controlled oscillator is designed in 0.13μm CMOS technology and according to simulations the tuning range is from 4 GHz to 12.5 GHz. The power consumption is below 8 mW
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