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Adjusting DICOM specifications when using wireless LANs: The MedLAN example
Wireless networks will become increasingly useful in point-of-care areas such as hospitals, because of their ease of use and their flexibility. A system called MedLAN has been developed by the Central Middlesex Hospital and Brunei University to take advantage of the above desirable properties of WLANs for use in accident & emergency departments to broadcast live, high quality video images and sound over a LAN or the Internet. However, in many cases, the limited available throughput of such a WLAN system makes the use of high demanding specifications, such as DICOM, problematic especially when using no compression during transmission. In this paper we will present some practical results when combining low compression with wireless LANs. We will conclude with the assessment of images and sounds by several doctors showing that the system we have devised is very useful in this setting
OFDM over IEEE 802.11b hardware for telemedical applications
Using a wireless Local Area Network (WLAN) to transmit live high-quality video suitable for a telemedical application presents many challenges, including ensuring sufficient Quality of Service (QoS) for the end-user to be able to make an accurate diagnosis. One of the many problems that exist when developing such a system is the multipath effect caused by the reflections of the transmitted signals on various surfaces including walls, floors, furniture and people. This degrades the signal quality and reduces the amount of available bandwidth and, thus, the quality of the image. Presently, most of Europe is using the IEEE 802.11b hardware for such applications. As an alternative to the existing modulation of 802.11b, Orthogonal Frequency Division Multiplexing (OFDM) is investigated, especially for use inside hospitals. The advantages of using this modulation over IEEE 802.11b hardware for a telemedicine application are examined by means of simulation using three different simulation packages
Concurrent Auditory Stream Discrimination in Auditory Graphing
This paper is concerned with enhancing human computer interaction and communication in concurrent streams of auditory display. Auditory display or auditory graphing is the sonic representation of numerical data (the auditory equivalent of visualization). It provides an additional channel for information representation, in which a participant 's response may be more intuitive and immediate than (visual) graphical display. but auditory graph design requires understanding and multi-disci plinary investigatio n of listening due to instantaneous characteristics of sound. Our aims are to explore (I) the impact of spatial separation for a divided attention task and (2) the efficiency of timbre (tone color) to assist pitch contour identification. Our findings about timbral and spatial discrimination are scalable and useful for auditory display in a wide variety of contexts. The results provide empirical evidence for a further investigat ion of spatialization and timbre and contribute to applications within an auditory display context for real-world scenarios (e.g. social, statistical and other datasets likely to be encountered in the workplace)
A Remote Markerless Human Gait Tracking for E-Healthcare Based on Content-Aware Wireless Multimedia Communications
Remote human motion tracking and gait analysis over wireless networks can be used for various e-healthcare systems for fast medical prognosis and diagnosis. However, most existing gait tracking systems rely on expensive equipment and take lengthy processes to collect gait data in a dedicated biomechanical environment, limiting their accessibility to small clinics located in remote areas. In this work we propose a new accurate and cost-effective e healthcare system for fast human gait tracking over wireless networks, where gait data can be collected by using advanced video content analysis techniques with low-cost cameras in a general clinic environment. Furthermore, based on video content analysis, the extracted human motion region is coded, transmitted, and protected in video encoding with a higher priority against the insignificant background area to cope with limited communication bandwidth. In this way the encoder behavior and the modulation and coding scheme are jointly optimized in a holistic way to achieve the best user-perceived video quality over wireless networks. Experimental results using H.264/AVC demonstrate the validity and efficacy of the proposed system
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