A Power Management Architecture for Sensor Nodes

Eliasson, Jens; Lindgren, Per; Delsing, Jerker; Thompson, Simon; Cheng, Yi‐Bing

doi:10.1109/wcnc.2007.557

Cited by 5 publications

(3 citation statements)

References 15 publications

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“…Many techniques have focused on overall system power management. Examples of the work include the automated sensor-specific power management system [13], Qos-driven dynamic power management framework [14], and context-and power-aware-based task manager [15]. We have done some work on the power management of the audio sensor.…”

Section: Power Managementmentioning

confidence: 99%

Design and Implementation of Enhanced Surveillance Platform with Low-Power Wireless Audio Sensor Network

Zhao

Sun

et al. 2012

International Journal of Distributed Sensor Networks

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Video surveillance system, which can provide real-time display of the monitored scene and video playback, has been employed in many areas including commercial security, accident investigation, law enforcement, and emergency response. However, audio which carries important information not available in video is usually not taken seriously and used effectively. In this paper, we develop an enhanced surveillance platform by organically integrating the low-power wireless audio sensor network (WASN) with the traditional visual surveillance network. We can obtain more comprehensive and precise monitoring without the limitation of the line-of-sight and lighting condition. Moreover, this platform is designed and built for providing key support to varieties of applications in wireless multimedia sensor networks. This paper describes the platform architecture, including design, implementation, and performance. We describe the hardware and software components of the audio/video sensors. Then, we present the multimedia synchronization mechanism in the heterogeneous network which is the foundation of applications in the proposed platform. Besides, we describe a sample application and data management mechanism that we have implemented to show the usefulness of our platform. Our experiments include an in-depth analysis of the bottlenecks within the platform as well as measurements for the various components.

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Section: Power Managementmentioning

confidence: 99%

Design and Implementation of Enhanced Surveillance Platform with Low-Power Wireless Audio Sensor Network

Zhao

Sun

et al. 2012

International Journal of Distributed Sensor Networks

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“…A Mulle in sleep mode consumes only 4 µA, but when it has its Bluetooth module active, the power consumption is much higher, typically 20-40 mA. The use of renewable energy from solar panels put high demands on the nodes' software [14]. The software should be both energy-and context aware for highest efficiency.…”

Section: A Power Consumptionmentioning

confidence: 99%

Towards road surface monitoring: Experiments and technical challenges

Eliasson

Birk

2009

2009 IEEE International Conference on Control Applications

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Abstract-This paper discusses results from real-life tests with intelligent road marking units (RMU), placed on the surface of a highway in northern Sweden, to monitor passing vehicles and road properties, as well as making the information available through a wireless sensor network. Wireless sensor networks are starting to gain interest in the area of cooperative safety and efficiency in transport as they can contribute to the reduction of accidents and emissions as well as enhanced driver experiences. Intelligent road markings are another key element for the creation of intelligent transport systems, complementing road side units, devices placed near a road equipped with highperformance computational platforms and long range communication capabilities. This paper shows that RMUs are feasible from the perspectives of low-power consumption, durability, and sensing performance.

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“…The Mulle software is based on a few major components: Bluetooth-and IP-stacks, a Hardware Abstraction Layer (HAL) which encapsulates low-level hardware behavior, an optional Real-time Operating System (RTOS), RTXC [52], and the sensor system. To resolve the issue of having multiple software components trying to utilize different low-power modes simultaneously, a new type of power management was developed for the Mulle: the energyaware Task Manager [53]. The Task Manager, as shown in Fig.…”

Section: Mulle Low-power Architecturementioning

confidence: 99%

A Bluetooth-based Sensor Node for Low-Power Ad Hoc Networks

Eliasson¹,

Lindgren²,

Delsing

2008

JCP

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TCP/IP has recently taken promising steps toward being a viable communication architecture for networked sensor nodes. Furthermore, the use of Bluetooth can enable a wide range of new applications, and in this article, an overview of the performance and characteristics of a networked sensor node based on TCP/IP and Bluetooth is presented. The number of Bluetooth-enabled consumer devices on the market is increasing, which gives Bluetooth an advantage compared to other radio technologies from an interoperability point of view. However, this excellent ability to communicate introduces disadvantages since neither TCP/IP nor Bluetooth were designed with resource-constrained sensor nodes in mind. We, however, argue that the constraints imposed by general purpose protocols and technologies can be greatly reduced by exploiting characteristics of the communication scheme in use and efficient and extensive use of available low-power modes. Furthermore, we claim that a Bluetooth-enabled networked sensor node can achieve an operating lifetime in the range of years using a total volume of less than 10 cm3. The Mulle Embedded Internet System (EIS), along with its advanced power management architecture, is presented as a case-study to support the claims.

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A Power Management Architecture for Sensor Nodes

Cited by 5 publications

References 15 publications

Design and Implementation of Enhanced Surveillance Platform with Low-Power Wireless Audio Sensor Network

Design and Implementation of Enhanced Surveillance Platform with Low-Power Wireless Audio Sensor Network

Towards road surface monitoring: Experiments and technical challenges

A Bluetooth-based Sensor Node for Low-Power Ad Hoc Networks

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