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\"Learn the properties of division with such topics as inverse operations, key words, interpreting remainders, and dividing great numbers\"-- Provided by publisher.

List of Garantor, Director, Division of Secretarial, Division of Papers and Review, Division of Program, Division of Information System and Publicity, Division of Paper Publication, Division of Equipment, Division of Accommodation, Division of Documentation are available in this pdf.

The world of division is explored in the setting of a hardware store. Through modeling, readers will explore the meaning of division, the connection between division and subtraction, and the relationship between division and multiplication.

The encirclement of the German 6th Army at Stalingrad in mid-November 1942 and its final collapse in February 1943 was a signature defeat for Hitler, as more than 100,000 of his soldiers were marched off into captivity. Frank Ellis tackles this oft-told tale from the unique perspective of the German officers and men trapped inside the Red Army's ever-closing ring of forces. This approach makes palpable the growing desperation of an army that began its campaign confident of victory but that long before the end could see how hopeless their situation had become. Highlighting these pages are three previously unpublished German army division accounts, translated here for the first time by Ellis. Each of these translations follows the combat experiences of a specific division-the 76th Infantry, the 94th Infantry, and the 16th Panzer-and take readers into the cauldron (or Kessel) that was Stalingrad. Together they provide a ground-level view of the horrific fighting and yield insights into everything from tactics and weapons to internal disputes, the debilitating effects of extreme cold and hunger, and the Germans' astonishing sense of duty and the abilities of their junior leaders. Along with these first-hand accounts, Ellis himself takes a new and closer look at a number of fascinating but somewhat neglected or misunderstood aspects of the Stalingrad cauldron including sniping, desertion, spying, and the fate of German prisoners. His coverage of sniping is especially notable for new insights concerning the duel that allegedly took place between Soviet sniper Vasilii Zaitsev and a German sniper, Major Konings, a story told in the film Enemy at the Gates (2001). Ellis also includes an incisive reading of Oberst Arthur Boje's published account of his capture, interrogation, and conviction for war crimes, and explores the theme of reconciliation in the works of two Stalingrad veterans, Kurt Reuber and Vasilii Grossman. Rich in anecdotal detail and revealing moments, Ellis's historical mosaic showcases an army that managed to display a vital resilience and professionalism in the face of inevitable defeat brought on by its leaders. It makes for compelling reading for anyone interested in one of the Eastern Front's monumental battles.

\"Anyone who knows how to share equally knows how to divide. It's important to understand that division is more than a part of a math class; it's a math operation used every day in many ways. This valuable book reviews 'fast facts' of division, such as the zero property which states that zero divided by any number is zero. The accessible text and illustrative photographs help make concepts like this more tangible. Learners can test their understanding by completing the questions in the Math Mania! boxes throughout the text, which are accompanied by answer keys for self-assessment opportunities\"--Provided by the publisher.

Oceans and deep seas have always been a root of great paradox to mankind. The oceans, covering greater than 75% of the Earth surface, are unexplored and implausible to investigate because of diverse phenomena practices in the underwater medium. Under water communication plays a significant role in observation of water pollution, natural disaster surveillance, coastal securities naval tactical activities, marine life and to investigate the variations in the underwater environment. However, under water channel is ambiguous in nature and causes low bandwidth, security issue, low transmission range and cost limitations because of interaction with the water channel. In this regards, a high speed hybrid passive optical network (PON) and visible light communication (VLC) using red-green-blue light emitting diodes system for land-to-underwater applications has been proposed and investigated for the data transmission over a hybrid fiber-wireless link under different water types. Time and wavelength division multiplexing wavelength division multiplexing PON employing different optical code division multiple access codes offering data security to different under ocean connected devices with minimum energy consumption, is analysed. The results shows that shift zero cross-correlation code offers a faithful 100 km fiber length and 5 m VLC range at high data rate of 10 Gbps having 76 dB optical signal to noise ratio for 200 undersea devices in both downstream and upstream transmission. Moreover, undersea VLC range can be improved up to 10 m with blue LED. The mathematical analysis and comparative performance reveal the superiority of proposed system than existing literature.

Two bugs, Ralph and Flora, try to divide thirteen beans so that the unlucky thirteenth bean disappears, but they soon discover that the math is not so easy.

Software implementations of brain-inspired computing underlie many important computational tasks, from image processing to speech recognition, artificial intelligence and deep learning applications. Yet, unlike real neural tissue, traditional computing architectures physically separate the core computing functions of memory and processing, making fast, efficient and low-energy computing difficult to achieve. To overcome such limitations, an attractive alternative is to design hardware that mimics neurons and synapses. Such hardware, when connected in networks or neuromorphic systems, processes information in a way more analogous to brains. Here we present an all-optical version of such a neurosynaptic system, capable of supervised and unsupervised learning. We exploit wavelength division multiplexing techniques to implement a scalable circuit architecture for photonic neural networks, successfully demonstrating pattern recognition directly in the optical domain. Such photonic neurosynaptic networks promise access to the high speed and high bandwidth inherent to optical systems, thus enabling the direct processing of optical telecommunication and visual data. An optical version of a brain-inspired neurosynaptic system, using wavelength division multiplexing techniques, is presented that is capable of supervised and unsupervised learning.

\"When it was originally published [in 1893, this book] was an entirely original work on the nature of labor and production as they were being shaped by the industrial revolution. Emile Durkheim's seminal work studies the nature of social solidarity and explores the ties that bind one person to the next in order to hold society together. This revised and updated second edition ... conveys Durkheims arguments for contemporary readers\"--Amazon.com.

Key Points Microtubule organization and dynamics are controlled by proteins that associate with the two microtubule extremities, the plus end and the minus end. Proteins accumulating at microtubule ends can promote or inhibit microtubule polymerization, enhance or block microtubule disassembly, or induce transitions between microtubule growth and shortening. Microtubule plus-end-tracking proteins (+TIPs) can accumulate at microtubule ends by recognizing the stabilizing GTP cap at growing microtubule tips or the curvature of the outermost part of the microtubule, or by plus-end-directed motor activity. This accumulation can be enhanced by electrostatic interactions between positively charged protein domains and the negatively charged microtubule lattice. +TIPs form extensive interaction networks, which depend on a limited number of protein motifs and modules that bind to each other with moderate affinity, allowing rapid remodelling of the end-associated complexes during microtubule growth and shortening. The recruitment of proteins with SxIP and cytoskeleton-associated protein Gly-rich (CAP-Gly) domains by the 'autonomous' +TIPs of the end-binding protein (EB) family plays a major part in the formation of these networks. +TIP networks are responsible for a large range of cellular functions, such as microtubule guidance along other cytoskeletal elements, microtubule attachment to the cell cortex, kinetochores and intracellular membrane organelles, positioning of microtubule arrays and signalling. Microtubule minus-end-targeting proteins (−TIPs) of the calmodulin-regulated spectrin-associated protein (CAMSAP) and Patronin family accumulate at free, growing microtubule minus ends and control the architecture of microtubule networks by stabilizing non-centrosomal microtubules. A wide range of diverse pharmacological agents can target microtubule tips either directly or indirectly and cooperate with +TIPs in regulating the dynamics of microtubule ends. Microtubule plus ends and minus ends accumulate specific sets of proteins that can regulate microtubule dynamics, connect microtubules to cellular structures and recruit signalling molecules that collectively control cellular behaviour. Our knowledge of the factors that associate with microtubule ends, and the mechanisms through which they do this, has strongly increased in recent years. Microtubules have fundamental roles in many essential biological processes, including cell division and intracellular transport. They assemble and disassemble from their two ends, denoted the plus end and the minus end. Significant advances have been made in our understanding of microtubule plus-end-tracking proteins (+TIPs) such as end-binding protein 1 (EB1), XMAP215, selected kinesins and dynein. By contrast, information on microtubule minus-end-targeting proteins (−TIPs), such as the calmodulin-regulated spectrin-associated proteins (CAMSAPs) and Patronin, has only recently started to emerge. Here, we review our current knowledge of factors, including microtubule-targeting agents, that associate with microtubule ends to control the dynamics and function of microtubules during the cell cycle and development.