15,561 research outputs found
Letter to Stephen Patterson from J.K. Reynolds dated July 7, 1864
Get PDFLetter to Stephen Patterson from J.K. Reynolds dated July 7, 1864. In the letter the friend asks Stephen to meet them at the depot.https://corescholar.libraries.wright.edu/special_ms236_correspond/1076/thumbnail.jp
Service-oriented models for audiovisual content storage
No full textWhat are the important topics to understand if involved with storage services to hold digital audiovisual content? This report takes a look at how content is created and moves into and out of storage; the storage service value networks and architectures found now and expected in the future; what sort of data transfer is expected to and from an audiovisual archive; what transfer protocols to use; and a summary of security and interface issues
Stephen Reynolds
No full textPhotograph of Stephen Reynolds. Reynolds was a Founding Faculty member at the University of Texas at San Antonio. Founding Faculty are defined as: Tenure-track or tenured faculty, faculty members hired between 1972 and 1978, and faculty that retired at UTSA, passed away while employed at UTSA, or are still employed at UTSA
Rick Reynolds in the film processing room holding a silent Bell and Howell film camera at the CBN 8 television studio, Orange, New South Wales, October 1969 [transparency] /
No full textTitle devised by cataloguer based on information from acquisitions documentation.; Also available in an electronic version via the Internet at: http://nla.gov.au/nla.pic-vn4789770; Donated by Stephen Fleay, 2010. Rick Reynolds was CBN 8 chief cameraman in 1968 to 1970. He processed the cine sound and silent film on this processor. Unloading of the cine camera and sound cine camera had to take place in complete darkness in this processing room. Rick is holding a very rugged silent Bell and Howell film camera. Rarely was a flash allowed in this room. The film department was always airconditioned as was the vision switching, master control and telecine areas--Information from acquisitions documentation
An active viscoelastic metamaterial for isolation applications
No full textMetamaterials are of interest due to their ability to produce novel acoustic behaviour beyond that seen in naturally occurring media. Of particular interest is the appearance of band gaps which lead to very high levels of attenuation within narrow frequency ranges. Resonant elements within metamaterials allow band gaps to form within the long wavelength limit at low frequencies where traditional passive isolation solutions suffer poor performance. Hence metamaterials may provide a path to high performance, low frequency isolation. Two metamaterials are presented here. An acoustic material consisting of an array of split hollow spheres is developed, and its performance is validated experimentally. The application of an acoustic/mechanical analogy allows the development of an elastodynamic metamaterial that could be employed as a high performance vibration isolator at low frequencies. A prototype isolator is manufactured, and its performance is measured. The passively occurring band gap is enhanced using an active control architecture. The use of the active control system in conjunction with the natural passive behaviour of the metamaterial enables high levels of isolation across a broad frequency range. An eventual goal of the work is to produce such materials on a small scale, and as such the metamaterials developed are designed for, and produced using, additive layer manufacturing technique
Stephen E. Reynolds
No full textRaised in Sebastian, Florida, Stephen E. Reynolds became interested, and proficient, in computers as a child. By the time he was in high school, he was designing websites for local business. Reynolds attended the University of Florida where he studied to be a computer engineer, while also working as a software tester for an aviation textbook and software manufacturer. During his final year of college, however, he took some introductory law classes and decided he would become a lawyer. Reynolds received his B.A. from Florida in 2004 and then spent a year as a computer programmer and IT analyst, before enrolling at the Indiana University School of Law. Reynolds received his JD degree from Indiana in 2008.
Since graduating from Maurer Law, Reynolds has been employed in the Indianapolis offices of Ice Miller. He is currently a partner in the firm’s Litigation Group and co-chair of the firm’s Data Security and Privacy Practice. Reynolds has been a member of the Maurer School of Law’s Black Law Student Association Advisory Board since 2015 and served as President in 2018. In addition, Reynolds was named the inaugural recipient of the law school’s Young Alumni Distinguished Service Award in 2018.https://www.repository.law.indiana.edu/notablealumni/1246/thumbnail.jp
Stephen E. Reynolds
No full textRaised in Sebastian, Florida, Stephen E. Reynolds became interested, and proficient, in computers as a child. By the time he was in high school, he was designing websites for local business. Reynolds attended the University of Florida where he studied to be a computer engineer, while also working as a software tester for an aviation textbook and software manufacturer. During his final year of college, however, he took some introductory law classes and decided he would become a lawyer. Reynolds received his B.A. from Florida in 2004 and then spent a year as a computer programmer and IT analyst, before enrolling at the Indiana University School of Law. Reynolds received his JD degree from Indiana in 2008.
Since graduating from Maurer Law, Reynolds has been employed in the Indianapolis offices of Ice Miller. He is currently a partner in the firm’s Litigation Group and co-chair of the firm’s Data Security and Privacy Practice. Reynolds has been a member of the Maurer School of Law’s Black Law Student Association Advisory Board since 2015 and served as President in 2018. In addition, Reynolds was named the inaugural recipient of the law school’s Young Alumni Distinguished Service Award in 2018.https://www.repository.law.indiana.edu/notablealumni/1246/thumbnail.jp
Wellcome Witnesses to Twentieth Century Medicine: Volume 1
No full textAnnotated and edited transcript of four Witness Seminars. Introduction by E M Tansey First published by the Wellcome Trust, 1997. ©The Trustee of the Wellcome Trust, London, 1997.In Volume One (Occasional Publication no. 4, 1997).All volumes are freely available online at: www.history.qmul.ac.uk/research/modbiomed/wellcome_witnesses/Annotated and edited transcript of four Witness Seminars. Introduction by E M Tansey.Annotated and edited transcript of four Witness Seminars. Introduction by E M Tansey.Annotated and edited transcript of four Witness Seminars. Introduction by E M Tansey.Annotated and edited transcript of four Witness Seminars. Introduction by E M Tansey.Four Witness Seminar transcripts of meetings held between 1993 and 1996: ‘Technology Transfer in Britain: The case of Monoclonal Antibodies’ (E M Tansey and P P Catterall, eds); ‘Self and Non-Self: A History of Autoimmunity’ (E M Tansey, S V Willhoft and D A Christie, eds); ‘Endogenous Opiates’ (E M Tansey and D A Christie, eds); ‘The Committee on Safety of Drugs’ (E M Tansey and L A Reynolds, eds). Introduction by E M Tansey, ‘What is a Witness Seminar’, separate index for each meeting. Tansey E M, Catterall P P, Christie D A, Willhoft S V, Reynolds L A. (eds) (1997) Wellcome Witnesses to Twentieth Century Medicine, volume 1. London: The Wellcome Trust.The Wellcome Trust is a registered charity, no. 210183
An active viscoelastic metamaterial with enhanced band gap properties
No full textMetamaterials have been the subject of significant interest over the past decade due to their ability to produce novel acoustic behaviour beyond that seen in naturally occurring media. Of particular interest is the appearance of band gaps which lead to very high levels of attenuation across the material within narrow frequency ranges. Unlike traditional periodic materials which have been employed at high frequencies, the resonant elements within metamaterials allow band gaps to form within the long wavelength limit. It is at low frequencies where it is most difficult to design satisfactory passive isolation solutions, and hence metamaterials may provide a useful path to high performance, low frequency isolation. A locally resonant, periodic metamaterial is presented that could be employed as a high performance vibration isolator at low frequencies. The passively occurring band gap is enhanced using an active control architecture. The use of the active control system in conjunction with the natural passive behaviour of the metamaterial enables high levels of isolation across a broad frequency range. An eventual goal of the work is to produce such materials on a small scale, and as such the metamaterial developed has been designed for, and produced using, additive layer manufacturing techniques
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