I Can Do That! Color & Draw

I Can Do That! Color & Draw
Title I Can Do That! Color & Draw PDF eBook
Author
Publisher Downtown Bookworks
Pages 0
Release 2018-02-27
Genre Juvenile Nonfiction
ISBN 9781941367483

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This extraordinary activity book helps young artists to transform sqiggles and scribbles into amazing creations! La ZOO is a hugely popular illustrator in Japan where her children's books have sold millions of copies. La ZOO's totally engaging art and time-tested strategies can coax out the artist in anyone old enough to hold a crayon. Whether they are drawing swirls of hair on adorable faces, patterns on the sails of a sailboat, or decorating a bunch of balloons, every creation looks spectacular, boosts confidence, and provides children with the opportunity to explore their imagination (and build fine motor skills). Offering the perfect combination of open-ended play with just enough guidance to get things rolling, these fun, beautiful workbooks have tons of appeal.

I Can Color, Grade Toddler

I Can Color, Grade Toddler
Title I Can Color, Grade Toddler PDF eBook
Author
Publisher Carson-Dellosa Publishing
Pages 83
Release 2012-09-01
Genre Juvenile Nonfiction
ISBN 1620577895

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The Big Skills for Little Hands series features fun activity pages that teach your child important skills necessary for kindergarten. Your child will have fun cutting, pasting, folding, drawing, tracing, and coloring his or her way to school success! After completing this book, your child will be proud to say . . . I Can Color!

Atlantic Coast Fishes You Can Color!

Atlantic Coast Fishes You Can Color!
Title Atlantic Coast Fishes You Can Color! PDF eBook
Author Howard Reisman
Publisher Rowman & Littlefield
Pages 41
Release 2022-06-01
Genre Juvenile Nonfiction
ISBN 1493069381

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Over 25,000 fish species live in the world. The Atlantic coastline is home to a few hundred of these. The seventeen species illustrated and described in this book are commonly found between the “Capes”: Cape Cod in Massachusetts and Cape Hatteras in North Carolina, but the ranges for some are much greater, even extending as far south as South America. Species illustrated include the American Eel, Pufferfish, Northern Pipefish, Oyster Toadfish, Striped Bass and a dozen others.

Color with Me, Mom!

Color with Me, Mom!
Title Color with Me, Mom! PDF eBook
Author Jasmine Narayan
Publisher Side-By-Side Book
Pages 131
Release 2016-04-15
Genre Art
ISBN 1631061984

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Color with Me, Mom!has a distinct design that allows mother and child to color together and connect on a physical and creative level.

House Painting and Decorating ...

House Painting and Decorating ...
Title House Painting and Decorating ... PDF eBook
Author A. Ashmun Kelly
Publisher
Pages 1172
Release 1893
Genre House painting
ISBN

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The Four-Color Problem

The Four-Color Problem
Title The Four-Color Problem PDF eBook
Author
Publisher Academic Press
Pages 277
Release 2011-08-29
Genre Mathematics
ISBN 0080873391

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The Four-Color Problem

Classic graph problems made temporal – a parameterized complexity analysis

Classic graph problems made temporal – a parameterized complexity analysis
Title Classic graph problems made temporal – a parameterized complexity analysis PDF eBook
Author Molter, Hendrik
Publisher Universitätsverlag der TU Berlin
Pages 227
Release 2020
Genre Computers
ISBN 3798331723

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This thesis investigates the parameterized computational complexity of six classic graph problems lifted to a temporal setting. More specifically, we consider problems defined on temporal graphs, that is, a graph where the edge set may change over a discrete time interval, while the vertex set remains unchanged. Temporal graphs are well-suited to model dynamic data and hence they are naturally motivated in contexts where dynamic changes or time-dependent interactions play an important role, such as, for example, communication networks, social networks, or physical proximity networks. The most important selection criteria for our problems was that they are well-motivated in the context of dynamic data analysis. Since temporal graphs are mathematically more complex than static graphs, it is maybe not surprising that all problems we consider in this thesis are NP-hard. We focus on the development of exact algorithms, where our goal is to obtain fixed-parameter tractability results, and refined computational hardness reductions that either show NP-hardness for very restricted input instances or parameterized hardness with respect to “large” parameters. In the context of temporal graphs, we mostly consider structural parameters of the underlying graph, that is, the graph obtained by ignoring all time information. However, we also consider parameters of other types, such as ones trying to measure how fast the temporal graph changes over time. In the following we briefly discuss the problem setting and the main results. Restless Temporal Paths. A path in a temporal graph has to respect causality, or time, which means that the edges used by a temporal path have to appear at non-decreasing times. We investigate temporal paths that additionally have a maximum waiting time in every vertex of the temporal graph. Our main contributions are establishing NP-hardness for the problem of finding restless temporal paths even in very restricted cases, and showing W[1]-hardness with respect to the feedback vertex number of the underlying graph. Temporal Separators. A temporal separator is a vertex set that, when removed from the temporal graph, destroys all temporal paths between two dedicated vertices. Our contribution here is twofold: Firstly, we investigate the computational complexity of finding temporal separators in temporal unit interval graphs, a generalization of unit interval graphs to the temporal setting. We show that the problem is NP-hard on temporal unit interval graphs but we identify an additional restriction which makes the problem solvable in polynomial time. We use the latter result to develop a fixed-parameter algorithm with a “distance-to-triviality” parameterization. Secondly, we show that finding temporal separators that destroy all restless temporal paths is Σ-P-2-hard. Temporal Matchings. We introduce a model for matchings in temporal graphs, where, if two vertices are matched at some point in time, then they have to “recharge” afterwards, meaning that they cannot be matched again for a certain number of time steps. In our main result we employ temporal line graphs to show that finding matchings is NP-hard even on instances where the underlying graph is a path. Temporal Coloring. We lift the classic graph coloring problem to the temporal setting. In our model, every edge has to be colored properly (that is,the endpoints are colored differently) at least once in every time interval of a certain length. We show that this problem is NP-hard in very restricted cases, even if we only have two colors. We present simple exponential-time algorithms to solve this problem. As a main contribution, we show that these algorithms presumably cannot be improved significantly. Temporal Cliques and s-Plexes. We propose a model for temporal s-plexes that is a canonical generalization of an existing model for temporal cliques. Our main contribution is a fixed-parameter algorithm that enumerates all maximal temporal s-plexes in a given temporal graph, where we use a temporal adaptation of degeneracy as a parameter. Temporal Cluster Editing. We present a model for cluster editing in temporal graphs, where we want to edit all “layers” of a temporal graph into cluster graphs that are sufficiently similar. Our main contribution is a fixed-parameter algorithm with respect to the parameter “number of edge modifications” plus the “measure of similarity” of the resulting clusterings. We further show that there is an efficient preprocessing procedure that can provably reduce the size of the input instance to be independent of the number of vertices of the original input instance.