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Radio identification

Radio Identifications of extragalactic IRAS sources [4], Conditions flux at 12fmi > 1.2Jy, at 25/am > 2.5Jy, at 60ym > 25Jy and at 100ytm > AOJy... [Pg.337]

A quantitative evaluation of potential radio identifications for 3EG EGRET sources [7]. Condition the sources to be quasars. [Pg.337]

In Table 1 we show the probabilities obtained using AGASA data and then all available and reliable data. P is the probability double counting the hits due the doublets from the data. We get very low probabilities for the radio identifications of IRAS sources (0.007%). We can see that the probability of correlation becomes weaker if we do not double count (0.75%). The first probability is 100 times smaller than the second, so it is a product of the second probability and the probability of having clusters in UHECRs (of order 10-2 ). Another low probability to be the correlation by chance is with the Veron catalogue Pi = 0.14%, but P = 5.25%. [Pg.338]

Spark Source Mass Spectrometry (SSMS) is a method of trace level analysis—less than 1 part per million atomic (ppma)—in which a solid material, in the form of two conducting electrodes, is vaporized and ionized by a high-voltage radio frequency spark in vacuum. The ions produced from the sample electrodes are accelerated into a mass spectrometer, separated according to their mass-to-charge ratio, and collected for qualitative identification and quantitative analysis. [Pg.45]

Dynamic differential thermal analysis is used to measure the phase transitions of the polymer. IR is used to determine the degree of unsaturation in the polymer. Monitoring of the purity and raw is done commercially using gas phase chromatography for fractionization and R1 with UV absorption at 260 nanometers for polystyrene identification and measurement Polystyrene is one of the most widely used plastics because of fabrication ease and the wide spectrum of properties possible. Industries using styrene-based plastics are packaging, appliance, construction, automotive, radio and television, furniture, toy, houseware and baggage. Styrene is also used by the military as a binder in expls and rocket propints... [Pg.327]

Kymissis et al. have examined the possibility of generation of electrical power parasitically from devices built in a shoe, a wearable subsystem for the soldier. Merits of three different types of piezoelectric devices are compared. They are a unimorph strip piezoceramic composite, a stave of multilayer laminate of PVDF foil, and a shoe-mounted rotary magnetic generator as a part of technology demonstration a piezoelectric embedded shoe has also been postulated to periodically broadcast a digital radio frequency identification (RFID) signal as the wearer walks. [Pg.291]

It can be expected that, in the future, other organic electronic devices and circuits, such as sensors [72], radio-frequency identification tags (RFIDs) [73], and ring oscillators [74] may be fabricated using dissipative structures. [Pg.197]

S. D. (2003) Pentacene-based radio-frequency identification circuitry. Appl. Phys. Lett., 82, 3964—3966. [Pg.201]

PAL has been known for 30 years, but a new era of applications has appeared recently through the evolution of more efficient photophores and activation, as well as new high-resolution separation and detection techniques. The photo-covalent modification of the binding site, which has an irreversible effect on activity and places a (radio)label, enables a multilevel analysis and identification on the biological target. [Pg.174]

The result of a standard photoaffinity experiment can provide an output in three levels [8] as shown in Scheme 2. The photolytically induced targeted introduction of a (radio )label onto the target biopolymer helps to identify any specific binding proteins (first level of identification) responsible for a particular action in the signaling cascade or to identify the binding domain within the target protein (second level of identification) or allows one to identify the amino acid sequence of the binding protein (third level of identification). [Pg.174]

In this study, a nonchemical means of encoding the identity of each compound was used. The original polymer-bound reagent was placed in a porous microreactor equipped with a radio-frequency device that can be used for identification.168 The porous micro-... [Pg.907]

Reliable criteria to identify the (individual) patients suitable for high-LET radiation therapy need to be developed. At present, the available criteria are derived (mainly) from the clinical fast neutron experience. It can be expected that novel approaches based on modern techniques involving molecular biology or gene identification may provide appropriate and still missing information. They may also provide information on the susceptibility or risk for secondary radio-induced cancer. [Pg.780]

UV curable flexo ink for RFID antennas Radio frequency identification (RFID) devices and contactless smart cards are capable of uniquely identifying an individual or object when they are interrogated by an external radio frequency signal. Recently, a process of printing with the use of UV curable conductive flexo inks has been introduced. The inks are based on polyfunctional acrylates with silver flakes added for the electrical conductivity. The advantages of these inks are ... [Pg.245]

Ranky, P. G., Focus on RFID (radio frequency identification) methods, technologies and education, presented as part of the NCME Mission (National Center for Manufacturing Education), sponsored by NSF (National Science Foundation, USA) and industry, Jan. 2006. [Pg.195]

Knights, P. F., Henderson, E., and Daneshmend, L. K. (2004), Drawpoint control using radio frequency identification systems, CIM Bull., 89(1003), 53-58. [Pg.196]

Ranky, P. G. (2006), Introduction to RFID—Radio frequency identification methods and solutions, Assembly Automation, 26(1), 28-33. [Pg.196]

Ranky, P. G. (2005), An introduction to RFID, radio frequency identification methods and applications, DVD video, available www.cimwareukandusa.com (approximately 30 min). [Pg.199]

Sangoi, R., Smith, C. G., et al. (2004), Printing radio frequency identification (RFID) tag antennas using inks containing silver dispersions, J. Dispersion Sci. Technol. 25(4), 513-521. [Pg.200]

Chemical6-8 or radio frequency 9,10 tagging methods can be used for compound identification. [Pg.150]

Radiolabeled photoaffinity ligands, in which the radio-tag is an integral part of the photo-phore, are used to simplify the analysis of the ligand-acceptor conjugate. 92 Identification of the photo-insertion site requires that both the photophore and the radio-tag will remain bound to the fragmented acceptor. To this end, introduction of Phe(3,5-3H2,4-NH2) offers an efficient and supposedly facile solution to this problem. [Pg.100]

See other pages where Radio identification is mentioned: [Pg.35]    [Pg.747]    [Pg.230]    [Pg.81]    [Pg.2]    [Pg.333]    [Pg.386]    [Pg.361]    [Pg.515]    [Pg.69]    [Pg.323]    [Pg.23]    [Pg.69]    [Pg.49]    [Pg.381]    [Pg.382]    [Pg.187]    [Pg.88]    [Pg.59]    [Pg.172]    [Pg.127]    [Pg.670]    [Pg.132]    [Pg.186]    [Pg.681]    [Pg.99]   


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