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Free math games for kids at Fun4theBrain!

Free math games for kids at Fun4theBrain!
Page NEW 1 2 3 View All Lucy is ready to dress the actor and actress from the lates movie, Zomie Prom! Thanks for all the help from her assisstants, Z. Agicthein and S. Snowy is having tons of fun this winter, but he is a little bit lonely when all the kids go home in the evening. The parents from this town decided that it was too easy getting the candy at the door, so they made an obstacle course around the neighborhood. Security Officer Hubert could use your help down by the docks. Come fight 'tis new platform battle featurin' a ruckas band 'o pirates! Muddy lives in the marsh in Murb. Sasha delivers all the orders for Murb Grocery. Tory Tools has opened his shop! Those crazy penguins from Cone Crazy are back again in a new game - Flurry of Flavors. You have gotten a job as an marine photographer! The crazy crows have stolen Lucky's coins and luck. There is a large group of reindeer that want to get some delicious cookies from your Reindeer Café. It is lunchtime at the Alien Academy.

Interactive Whiteboard Resources: Maths, Key Stage 2 Caterpillar OrderingTablet friendly A flexible game for ordering numbers and for number sequences. Fantastic on an interactive whiteboard and tablet friendly. Varying levels of difficulty make it suitable for use throughout the primary age range. OrderingFlash You'll love this ordering game! Compare Numbers on a Number LineFlash Compare numbers on two different number lines and decide which is bigger. Comparing NumbersFlash A teaching tool which is good for demonstrating greater than and less than with 2 and 3 digit numbers and rounding to 10 and 100. CountersquareFlash A hundred square with movable counters and lots of different ideas on how you can use this as a teaching aid. Higher and LowerFlash Lots of examples of ordering numbers from simple ordering numbers to 10 to fractions, decimals or negative and positive numbers. Thinking of a NumberFlash Children need to guess a number below 100 from clues on the clouds. Chinese Dragon GameTablet friendly SequencesFlash EstimateFlash Number LineFlash

3.NF | Search Results In this fraction operation and representation activity, students are asked to decide how much of my cake was eaten. Using fraction multiplication (or angle measure if that is where you need an activity) they find out how much someone owes… Read more → Victor Espinoza riding California Chrome The Kentucky Derby was just run. Read more → Act One: Drill bits are measured by the diameter of the bit in inches. Read more → Martin Luther King, Jr. Read more → I make the best, best, really best pie. Read more → In this activity students decide how to divide 2 pizzas amongst 6 adults and 3 pizzas amongst 8 kids. Read more → Hey, the playoffs are about to begin. Read more → Using his famous mashed potato recipe, Brian has asked students to change decimals to fractions, to calculate ingredient measures for various-sized Thanksgiving gatherings, to explain their thinking in calculating these figures and to judge how many servings could be created… Read more → Read more → Read more → Read more → Read more →

Multiplication Worksheets We have multiplication sheets for timed tests or extra practice, as well as flashcards and games. Includes Multiplication Flashcards, Multiplication Bingo, Multiplication Tables, Multiplication I Have - Who has, and lots more! To see the Common Core Standards associated with each multiplication worksheet, select the apple core logo ( ) below the worksheet's description. Games Multiplication Game: I Have / Who HasFree A super-fun chain reaction game that teaches times tables! Multiplication Board Game: To the Moon Member Printable multiplication board game with a space theme. Multiplication Game: Memory Match (up to 9s)Free This fun memory card game will help students learn their multiplication facts up to 9 x 9. Multiplication Game: Memory Match (up to 12s) Member This version of Multiplication memory match includes 10s, 11s, and 12s. Multiplication Roll 'Em Member Play this multiplication dice game to make your math lesson more fun! Multiplication Bingo Member Flashcards Fact Family Flashcards Member

Learn To Use Base Ten Blocks at Crewton Ramone's House of Math. Cool Math 4 Kids Times Tables Help - How Multiplying Works (times tables) Here's another one: This means that you have three groups of 5! Put the three groupstogether... How many pentagons do you have? Count them... So, our answer is: Let's switch the numbers around and do it the different way! This means that you have five groups of 3! Put the five groupstogether... Count them... Degrees (Angles) We can measure Angles in Degrees. There are 360 degrees in one Full Rotation (one complete circle around). (Angles can also be measured in Radians) (Note: "Degrees" can also mean Temperature, but here we are talking about Angles) The Degree Symbol: ° We use a little circle ° following the number to mean degrees. For example 90° means 90 degrees One Degree This is how large 1 Degree is The Full Circle A Full Circle is 360° Half a circle is 180° (called a Straight Angle) Quarter of a circle is 90° (called a Right Angle) Measuring Degrees We often measure degrees using a protractor: The normal protractor measures 0° to 180°

Hasse diagram Hasse diagrams are named after Helmut Hasse (1898–1979); according to Birkhoff (1948), they are so-called because of the effective use Hasse made of them. However, Hasse was not the first to use these diagrams; they appear, e.g., in Vogt (1895). Although Hasse diagrams were originally devised as a technique for making drawings of partially ordered sets by hand, they have more recently been created automatically using graph drawing techniques.[1] The phrase "Hasse diagram" may also refer to the transitive reduction as an abstract directed acyclic graph, independently of any drawing of that graph, but this usage is eschewed here. A "good" Hasse diagram[edit] Although Hasse diagrams are simple as well as intuitive tools for dealing with finite posets, it turns out to be rather difficult to draw "good" diagrams. The following example demonstrates the issue. . Upward planarity[edit] Notes[edit] References[edit] External links[edit] Related media at Wikimedia Commons:

Geometry Geometry is all about shapes and their properties. If you like playing with objects, or like drawing, then geometry is for you! Geometry can be divided into: Plane Geometry is about flat shapes like lines, circles and triangles ... shapes that can be drawn on a piece of paper Solid Geometry is about three dimensional objects like cubes, prisms, cylinders and spheres. Point, Line, Plane and Solid A Point has no dimensions, only position A Line is one-dimensional A Plane is two dimensional (2D) A Solid is three-dimensional (3D) Why? Why do we do Geometry? Plane Geometry Plane Geometry is all about shapes on a flat surface (like on an endless piece of paper). Perimeter General Drawing Tool Polygons A Polygon is a 2-dimensional shape made of straight lines. Here are some more: The Circle Circle Theorems (Advanced Topic) Symbols There are many special symbols used in Geometry. Geometric Symbols Congruent and Similar Angles Types of Angles Transformations and Symmetry Transformations: Symmetry: Symmetry Artist

Benford's law The distribution of first digits, according to Benford's law. Each bar represents a digit, and the height of the bar is the percentage of numbers that start with that digit. Frequency of first significant digit of physical constants plotted against Benford's law Benford's law, also called the first-digit law, is a phenomenological law about the frequency distribution of leading digits in many (but not all) real-life sets of numerical data. It has been shown that this result applies to a wide variety of data sets, including electricity bills, street addresses, stock prices, population numbers, death rates, lengths of rivers, physical and mathematical constants,[3] and processes described by power laws (which are very common in nature). The graph here shows Benford's law for base 10. It is named after physicist Frank Benford, who stated it in 1938,[4] although it had been previously stated by Simon Newcomb in 1881.[5] Mathematical statement[edit] Example[edit] History[edit] Explanations[edit]

Paper Models of Polyhedra Chaos theory A double rod pendulum animation showing chaotic behavior. Starting the pendulum from a slightly different initial condition would result in a completely different trajectory. The double rod pendulum is one of the simplest dynamical systems that has chaotic solutions. Chaos: When the present determines the future, but the approximate present does not approximately determine the future. Chaotic behavior can be observed in many natural systems, such as weather and climate.[6][7] This behavior can be studied through analysis of a chaotic mathematical model, or through analytical techniques such as recurrence plots and Poincaré maps. Introduction[edit] Chaos theory concerns deterministic systems whose behavior can in principle be predicted. Chaotic dynamics[edit] The map defined by x → 4 x (1 – x) and y → x + y mod 1 displays sensitivity to initial conditions. In common usage, "chaos" means "a state of disorder".[9] However, in chaos theory, the term is defined more precisely. where , and , is: .

Binary Game Skip to Content | Skip to Footer Cisco Binary Game The Cisco Binary Game is the best way to learn and practice the binary number system. It is great for classes, students and teachers in science, math, digital electronics, computers, programming, logic and networking. Boulanger: la saga continue (2/2) PART 2 Les mystères du monde continu Je vous ai montré dans le billet précédent pourquoi en mélangeant de façon très méthodique une image faite de pixels (j’étale dans un sens, je replie et je recommence) on revient tôt ou tard à la l’image initiale. Mais aujourd’hui nous allons voir que cet éternel recommencement est un privilège réservé aux images numériques. Pétrissage décimalPour vous le montrer simplement, je vais modifier légèrement la méthode de pétrissage: le boulanger étire son carré de 10 fois sa longueur initiale (au lieu de deux) et il coupe les neuf morceaux qui dépassent afin de retrouver la forme initiale du carré une fois empilés. C’est un peu plus compliqué à première vue mais vous allez vite comprendre pourquoi ça simplifie les calculs… Supposons que notre carré ait une longueur 1 de côté et divisons le verticalement en 10 bandes de largeur 0,1 chacune. La transformation consiste donc à simplement déplacer la séparation entre abscisse (écrite à l’envers) et ordonnée.

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