RH-mote for Next-generation Wireless Sensor Networks

AbstractMany Wireless Sensor Networks (WSNs) applications are new and their requirements may not be fully anticipated during the sensor networks design and development stage. We are presenting a sensor network infrastructure that support motes’ with remote hardware and software modification to match the target applications need. Using the proposed infrastructure in next-generation WSNs will produce flexible infrastructures that will provide over-the-air remote design modification even after the deployment of WSNs on the sensing field.In this paper, we are presenting the design concept and challenges of such infrastructure. Also, we present the use of the infrastructure in one possible environmental monitoring application such as forest fire. The development of such infrastructure will have an impact on advances the research on the real- time remote sensing, heterogeneous WSN, and WSNs applications

Wireless Sensor Networks’ Node Supported with Remote Hardware Modifications Capability

Wireless Sensor Networks (WSNs) nodes are generally have simple hardware design that can be classified as inflexible, support one or more applications, and inexpensive. These nodes are designed and programmed before their release on the application field and will stay on the field to support the need of the target application. Although the existing wireless sensor nodes are designed to support remote software modifications, they are, however, are not supporting remote hardware modifications. Using wireless sensor nodes that can support remote nodes’ modification capability for both hardware and software will provide WSNs with flexible infrastructures that can support nodes with over-the-air design modification even after the deployment of WSNs on the sensing field. In this paper, we are presenting the design concept and challenges of such infrastructure. Also, we present the use of such flexible infrastructure in potential WSNs applications. DOI: 10.17762/ijritcc2321-8169.16044

Runtime Hardware Reconfiguration in Wireless Sensor Networks for Condition Monitoring

The integration of miniaturized heterogeneous electronic components has enabled the deployment of tiny sensing platforms empowered by wireless connectivity known as wireless sensor networks. Thanks to an optimized duty-cycled activity, the energy consumption of these battery-powered devices can be reduced to a level where several years of operation is possible. However, the processing capability of currently available wireless sensor nodes does not scale well with the observation of phenomena requiring a high sampling resolution. The large amount of data generated by the sensors cannot be handled efficiently by low-power wireless communication protocols without a preliminary filtering of the information relevant for the application. For this purpose, energy-efficient, flexible, fast and accurate processing units are required to extract important features from the sensor data and relieve the operating system from computationally demanding tasks. Reconfigurable hardware is identified as a suitable technology to fulfill these requirements, balancing implementation flexibility with performance and energy-efficiency. While both static and dynamic power consumption of field programmable gate arrays has often been pointed out as prohibitive for very-low-power applications, recent programmable logic chips based on non-volatile memory appear as a potential solution overcoming this constraint. This thesis first verifies this assumption with the help of a modular sensor node built around a field programmable gate array based on Flash technology. Short and autonomous duty-cycled operation combined with hardware acceleration efficiently drop the energy consumption of the device in the considered context. However, Flash-based devices suffer from restrictions such as long configuration times and limited resources, which reduce their suitability for complex processing tasks. A template of a dynamically reconfigurable architecture built around coarse-grained reconfigurable function units is proposed in a second part of this work to overcome these issues. The module is conceived as an overlay of the sensor node FPGA increasing the implementation flexibility and introducing a standardized programming model. Mechanisms for virtual reconfiguration tailored for resource-constrained systems are introduced to minimize the overhead induced by this genericity. The definition of this template architecture leaves room for design space exploration and application- specific customization. Nevertheless, this aspect must be supported by appropriate design tools which facilitate and automate the generation of low-level design files. For this purpose, a software tool is introduced to graphically configure the architecture and operation of the hardware accelerator. A middleware service is further integrated into the wireless sensor network operating system to bridge the gap between the hardware and the design tools, enabling remote reprogramming and scheduling of the hardware functionality at runtime. At last, this hardware and software toolchain is applied to real-world wireless sensor network deployments in the domain of condition monitoring. This category of applications often require the complex analysis of signals in the considered range of sampling frequencies such as vibrations or electrical currents, making the proposed system ideally suited for the implementation. The flexibility of the approach is demonstrated by taking examples with heterogeneous algorithmic specifications. Different data processing tasks executed by the sensor node hardware accelerator are modified at runtime according to application requests