Institution
University of Colorado Colorado Springs
Education•Colorado Springs, Colorado, United States•
About: University of Colorado Colorado Springs is a education organization based out in Colorado Springs, Colorado, United States. It is known for research contribution in the topics: Population & Poison control. The organization has 6664 authors who have published 10872 publications receiving 323416 citations. The organization is also known as: UCCS & University of Colorado at Colorado Springs.
Topics: Population, Poison control, Thin film, Capacitor, Ferroelectricity
Papers published on a yearly basis
Papers
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TL;DR: This article used student level data from New York City to study the relationship between a public school losing enrollment to charter school competitors and the academic achievement of students who remain enrolled in it, finding evidence that students in schools losing more students to charter schools either are unaffected by the competitive pressures of the choice option or benefit mildly in both math and English.
75 citations
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TL;DR: In this article, the authors developed and tested the construct of duty orientation that is valuable to advancing knowledge about ethical behavior in organizations and found that duty orientation mediates the relationship between ethical leadership and ethical and unethical behaviors.
75 citations
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27 Jul 1999TL;DR: In this article, the error control in a communication system where a group of more than one messages is transmitted by one entity to a second entity in the communication system, i.e., a receiving entity, is discussed.
Abstract: Methods and mechanisms for error control in a communication system where a group of more than one message is transmitted by one entity of the communication system, i.e., a transmitting entity, to a second entity in the communication system, i.e., a receiving entity. A transmitting entity transmits a group of more than one message to a receiving entity. The receiving entity thereafter generates a responsive message (400) to transmit in response to the transmission of the group of messages. The responsive message indicates each message in the group of messages that was successfully transmitted to the receiving entity. The responsive message is also indicative of each message in the group of messages that was not successfully transmitted. After generating the responsive message, the receiving entity transmits it to the transmitting entity. The transmitting entity, upon receiving the responsive message, determines what messages in the group of messages, if any, were successfully transmitted. The transmitting entity does not retransmit any of these successfully transmitted messages to the receiving entity.
75 citations
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03 May 2000TL;DR: An enhanced memory algorithmic processor (MAP) as discussed by the authors is an architecture for multiprocessor computer systems which comprises an assembly that may include an array of field programmable gate arrays (FPGAs) functioning as the memory algorithms.
Abstract: An enhanced memory algorithmic processor (“MAP”) architecture for multiprocessor computer systems comprises an assembly that may comprise, for example, field programmable gate arrays (“FPGAs”) functioning as the memory algorithmic processors. The MAP elements may further include an operand storage, intelligent address generation, on board function libraries, result storage and multiple input/output (“I/O”) ports. The MAP elements are intended to augment, not necessarily replace, the high performance microprocessors in the system and, in a particular embodiment of the present invention, they may be connected through the memory subsystem of the computer system resulting in it being very tightly coupled to the system as well as being globally accessible from any processor in a multiprocessor computer system.
75 citations
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18 Nov 1993TL;DR: In this article, a layered superlattice material having the formula A1 w1 +a1 A2 w2 +a2... Aj wj +aj S1 x1 +s1 S2 x2 +s2, where A1, A2, Aj represent A-site elements in a perovskite-like structure, S1, S2.
Abstract: An integrated circuit includes a layered superlattice material having the formula A1 w1 +a1 A2 w2 +a2 . . . Aj wj +aj S1 x1 +s1 S2 x2 +s2 . . . Sk xk +ak B1 y1 +b1 B2 y2 +b2 . . . Bl yl +bl Q z -2 , where A1, A2 . . . Aj represent A-site elements in a perovskite-like structure, S1, S2 . . . Sk represent superlattice generator elements, B1, B2 . . . Bl represent B-site elements in a perovskite-like structure, Q represents an anion, the superscripts indicate the valences of the respective elements, the subscripts indicate the number of atoms of the element in the unit cell, and at least w1 and y1 are non-zero. Some of these materials are extremely low fatigue ferroelectrics and are applied in non-volatile memories. Others are high dielectric constant materials that do not degrade or breakdown over long periods of use and are applied in volatile memories.
75 citations
Authors
Showing all 6706 results
Name | H-index | Papers | Citations |
---|---|---|---|
Jeff Greenberg | 105 | 542 | 43600 |
James F. Scott | 99 | 714 | 58515 |
Martin Wikelski | 89 | 420 | 25821 |
Neil W. Kowall | 89 | 279 | 34943 |
Ananth Dodabalapur | 85 | 394 | 27246 |
Tom Pyszczynski | 82 | 246 | 30590 |
Patrick S. Kamath | 78 | 466 | 31281 |
Connie M. Weaver | 77 | 473 | 30985 |
Alejandro Lucia | 75 | 680 | 23967 |
Michael J. McKenna | 70 | 356 | 16227 |
Timothy J. Craig | 69 | 458 | 18340 |
Sheldon Solomon | 67 | 150 | 23916 |
Michael H. Stone | 65 | 370 | 16355 |
Christopher J. Gostout | 65 | 334 | 13593 |
Edward T. Ryan | 60 | 303 | 11822 |