17-01-2012, 12:21 PM
Ultra Wide Band
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INTRODUCTION
Ultra Wide Band (UWB) is a revolutionary technology with incomparable potential in terms of throughput, performance and low cost implementation. The uniqueness of UWB is that it transmits across extremely wide bandwidth of several GHz, around a low center frequency, at very low power levels.
ULTRA WIDE BAND
This concept doesn't stand for a definite standard of wireless communication. This is a method of modulation and data transmission which can entirely change the wireless picture in the near future. The diagram given below demonstrates the basic principle of the UWB:
INNER WORKINGS
UWB uses a kind of pulse modulation. To transfer data, a UWB transmitter emits a single sine wave pulse (called a monocycle) at a time. This monocycle has no data in it. On the contrary, it is the timing between monocycles (the interval between pulses) that determines whether data transmitted is a 0 or a 1. A UWB pulse typically ranges between .2 and 1.5 nanoseconds. If a monocycle is sent early (by 100 pico seconds), it can denote a 0, while a monocycle sent late (by 100 pico seconds) can represent
Modulation Methods
Several modulation techniques can be used to create UWB signals, some more efficiently than others. In its formative years, some of the most popular methods to create UWB pulse streams used mono-phase techniques such as pulse amplitude (PAM), pulse position (PPM), or on-off keying (OOK). In these techniques, a ‘1’ is differentiated from a ‘0’ either by the size of the signal or when it arrives in time – but all the pulses are the same shape. A more efficient approach, bi-phase ultra-wideband, is also being deployed. Bi-phase differentiates a ‘1’ with a ‘right-side-up’ pulse and a ‘0’ with an ‘upside-down’ pulse and works by reading pulses both “backwards”