I. Introduction

Ultra-wideband technology, regulated by the Federal Communications Commission (FCC) in February 2002 for commercial communication use in the 3.1–10.6 GHz frequency band [1], is promising for short and medium-range wireless data communication, imaging, and high-precision ranging application. There are several approaches within the UWB developed to satisfy the communication market requirements. The carrier-based transmission approaches (multiband orthogonal frequency division multiplexing-MB-OFDM, and direct-sequence - DS) demand complex digital-signal processing, modulation and deep compression for achieving necessary data rate [2], [3], and thus apparently increase the complexity, power and costs of the UWB transceiver. Impulse radio ultra wideband (IR-UWB) technique uses extremely short pulses (duration less than 1 ns) which spectrum occupies a few GHz frequency range. The approach has advantageous features such as low complexity (without mixer and power amplifier), low-cost and energy efficient UWB transmitter architecture allowing simple modulation scheme (e.g. on-off keying - OOK) [4]. Additionally, the protocol offers high fading margin for communication systems in multipath environments, high time and range resolution, and low probability of undesired detection and interception [4]. The IR-UWB transceivers appear to be greatly attractive for very high data rate short-range communication, low data rate communication related to localization or/and positioning systems [5], [6], biomedical applications such as wireless personal area networks [7], interchip communications [8], [9], and UWB biotelemetry [10], [11].