We are grateful to the NSF for providing access to the data. Data collection and analysis were partially supported by a grant from the Heinz School. We are indebted to Ruth Williams of the NSF for help in getting access to the data, and for patiently answering our questions and queries. Dan Newlon and Lynn Pollnow of the NSF, educated us about the intricacies of the NSF grant procedures in economics, and we thank them for their help and support. We thank Paul David for long and stimulating conversations, and Josh Angrist, Dan Black, Ron Ehrenberg, and Seth Sanders for helpful suggestions and advice. We have also benefited from comments and suggestions we received from members of the "Statisticians Lunch Seminar" at the NSF. Wei Kong provided enthusiastic and skillful research assistance. We alone are responsible for all remaining errors.
The Kansei testbed at The Ohio State University is designed to facilitate research on networked sensing applications at scale. Kansei embodies a unique combination of characteristics as a result of its design focus on sensing and scaling: (i) Heterogeneous hardware infrastructure with dedicated node resources for local computation, storage, data exfiltration and back-channel communication, to support complex experimentation. (ii) Time accurate hybrid simulation engine for simulating substantially larger arrays using testbed hardware resources. (iii) High fidelity sensor data generation and real-time data and event injection. (iv) Software components and associated job control language to support complex multi-tier experiments utilizing real hardware resources and data generation and simulation engines. In this paper, we present the elements of Kansei testbed architecture, including its hardware and software platforms as well as its hybrid simulation and sensor data generation engines.
Ultrawideband radar-enabled wireless sensor networks have the potential to address key detection and classification requirements common to many surveillance and tracking applications. However, traditional radar signal processing techniques are mismatched with the limited computational and storage resources available on typical sensor nodes. The mismatch is exacerbated in noisy, cluttered environments or when the signals have corrupted spectra. To explore the compatibility of ultrawideband radar and mote-class sensor nodes, we designed and built a new platform called the Radar Mote. An early prototype of this platform was used to detect, classify, and track people and vehicles moving through an outdoor sensor network deployment. This paper describes the sensor's theory of operation, discusses the design and implementation of the Radar Mote, and presents sample signal waveforms of people, vehicles, noise, and clutter. We demonstrate that radar sensors can be successfully integrated with mote-class devices and imbue them with an extraordinarily useful sensing modality.
Since the advent of human immunodeficiency virus infection, with its profound and progressive effect on the cellular immune system, a group of human opportunistic pathogens has come into prominence. Opportunistic parasitic infection can cause severe morbidity and mortality. Because many of these infections are treatable, an early and accurate diagnosis is important. This can be accomplished by a variety of methods such as direct demonstration of parasites and by serological tests to detect antigen and/or specific antibodies. However, antibody response may be poor in these patients and therefore immunodiagnostic tests have to be interpreted with caution. Cryptosporidium parvum, Isospora belli, Cyclospora cayetanensis, Microsporidia, Entamoeba histolytica and Strongyloides stercoralis are the commonly detected parasites. Detection of these parasites will help in proper management of these patients because drugs are available for most of these parasitic infections.
Early surgery in enteric perforation is the only accepted form of treatment in modem day medicine and gives excellent results. Exploratory laparotomy continues to be the mainstay of surgical treatment and several different procedures are recommended in literature. Between January 1998 and November 2001, we have successfully managed 6 consecutive cases of enteric perforation laparoscopically with complete resolution of the disease. There were 4 males and 2 females in our study. The mean time of presentation to us was 38 hours after the perforation (range 22 hours to 63 hours). The mean age was 32 years (range 28 years to 43 years). All patients presented with free air under the diaphragm. A laparoscopic approach was carried out through a 10 mm supraumbilical port and two 5 mm additional ports in the midline infraumbilical area and the left iliac fossa area. Simple one layer closure of the perforation was carried out with 2-0 silk intracorporeally and the peritoneal cavity was washed out and adequately drained. All perforations were localised to the terminal ileum and were single in number. The mean operating time was 54 minutes-(range 42 to 75 minutes). All patients received parenteral ofloxacin and metrogyl. Postoperative recovery was uneventful in all patients and there were no major complications. All patients were discharged from hospital by the 4th postoperative day. Follow up over a period of 12 to 16 months revealed all patients to be in normal health. We strongly recommend a first line laparoscopic approach in all patients with typhoid perforation; as it is a safe and effective method of managing such cases.
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