Abstract
With its fine immunity to multipath fading, ultra-wideband (UWB) is considered to be a potential technique in constructing intravehicle wireless sensor networks. In the UWB literature, extensive measuring and modeling work have been done for indoor or outdoor propagation, but very few measurements were performed in intravehicle environments. This paper reports our effort in measuring and modeling the UWB propagation channel in commercial vehicle environment. In our experiment, channel sounding is performed in time domain for two environments. In one environment, the transmitting and the receiving antennas are put beneath the chassis. In another environment, both antennas are located inside the engine compartment. It is observed that paths arrive in clusters in the latter environment but such clustering phenomenon does not exist in the former case. Different multipath models are used to describe the two different propagation channels. For the engine compartment environment, we describe the multipath propagation with the classical S-V model. And for the chassis environment, the channel impulse response is just represented as the sum of multiple paths. Observation reveals that the power delay profile (PDP) in this environment does not start with a sharp maximum but has a rising edge. A modified S-V PDP model is used to account for this rising edge. Based on the analysis of the measured data, channel model parameters are extracted for both environments.
Highlights
Electronic subsystems are essential components of modern vehicles
A great challenge in constructing such an intravehicle wireless sensor network is to provide the same level of reliability, end-to-end latency, and data rate as what is offered by the current wiring system
Based on the observation that the clustering phenomenon exists for the UWB propagation inside the engine compartment but not for that under the chassis, different models should be used to describe the channels in these two environments
Summary
Electronic subsystems are essential components of modern vehicles. For the purpose of safety, comfort, and convenience, more and more sensors are being deployed in the new models of automotives to collect information such as temperature, speed, pressure, and so on. This greatly increases the complication of vehicle design and negatively affects the cost, fuel economy, and environment friendliness required for vehicles To counteract these disadvantages of the existing intravehicle wired sensor network, Elbatt et al proposed wireless sensor network as a potential way to replace the cable bundles for the transmission of data and control information between sensors and ECU [4]. UWB technology is considered by us to be a competitive candidate for physical layer solution in constructing such an intravehicle wireless sensor network due to its robustness in solving multipath fading problem, low power consumption, resistance to narrow band interference, safe and high rate of data transmission as well as free availability of bandwidth.
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