### Simple Solutions To Rubiks Magic

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Every piece left to be solved has yellow on it somewhere. Now, we are going to solve the edges of the top layer in two steps. The first of the two steps involves orienting all of the yellow pieces so that they are all facing up.

## Rubik’s cube for dummies quick and easy solution

The second step involves moving these pieces around and thus solving the puzzle. Are you ready? Ignore the corners at first. Look at the edges only. Are they oriented correctly? Here are the possible edge positions that you can have:.

Are your edges currently solved in a cross pattern the way that we began this process? If so, you can go on and skip this step. If not, listen carefully. Besides the cross shape, it is possible to have a dot, L-shape, or a line as pictured above. Now, you should have an L shape, where the two yellow pieces that are showing are adjacent to one another. The four edges should now be oriented correctly.

## Anyways Rubik's Magic Solution in 17 Steps!

Sune and antisune are beloved by many puzzlers due to their simplicity. After you have oriented the edges, there are seven different corner positions available to you. Sune and antisune are two of these which we will discuss in a minute. How do you get to the spot where you only need to orient one more corner? When you get to this desired spot, there are two variations that can occur. They will look something like this:. The yellow front-facing corner can be in two positions.

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It can face either the front or the right. In the first image above, the yellow is facing the front. This means that you have a sune position. To solve sune, do the aforementioned algorithm one more time to solve the top layer The antisune position occurs when the right-facing corner appears as it does in the second picture illustrated above. We are almost there! Hang on. Step six is the last part to solve the cube.

While there are twenty-one cases for the top layer, we only need a few algorithms to figure them out and get it all sorted. First, we want to locate the headlights. There are only two cases without headlights. After you performed the above algorithm in step six, there are five possible positions that your cube can be in now. Perform the necessary amount of U moves to ensure that each corner is in its right place.

Do you have a completely solved bar?

### Solve the cube with only 4 sequences!

If your cube is still unsolved, perform the above algorithm one more time, keeping the completed bar at the back of the cube. If you do not have a solved bar, you can perform this algorithm from any angle that you would like to. This will give you a solved bar and then you can do the algorithm one more time in order to complete the puzzle. Congratulations, you have completed the cube! On this show, magicians are given the challenge to trick two of the greatest minds in magic, Penn and Teller. Believe it or not, this is actually one of the simpler magic tricks to accomplish.

The action involves the magician first taking a scrambled cube and showing it to the audience. Then, he attempts to solve it before throwing it up in the air. So how is this trick done? There are actually a few ways to perform this magic trick. How exactly did he do it? Read through each of the possible methods and see if you can identify which one he used.

We have to say that we are particularly impressed with Steven Brundage. See if you can figure it out. When it is solved, one of the sides appears to be scrambled.

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By carrying out six simple moves on the cube, the cube appears to be completely scrambled. Using this cube, you can show the audience all sides. Then, hold the scrambled side facing the audience and undo the six moves you previously did, pretending to solve it. With a slight sleight of hand, the audience will believe they have seen all of the sides. After the cube is taken out of the bag, it is solved.

How can this be?

Popular opinion is that this trick is a gimmick. In every performance with this trick, the paper bag is immediately thrown away without the audience being able to get a second look at it. This is the most likely speculation for how Brundage could have pulled off the magic trick. Brundage then asks Teller to hold the cube in his hands. When he opens his hands, the cube matches the one that Brundage had scrambled. Brundage performed a set of moves on one cube and then repeats it on the scrambled cube while talking to the audience later on. While this sounds highly plausible, there is one thing wrong with this method.

The theory would not work unless Brundage already knew which cube Teller would choose from the two that were scrambled.

It is highly likely he had a plan for both cubes but we cannot know for sure. What an a mazing sleight of hand!

## Rubik's Cube Solution

If you look at it over and over, you can see that he actually makes 4 moves. There was always one guy in geometry class who could whiz through the thing in no time. But for everyone else it was pure frustration. The competition brings the cube back to its home where it was created 30 years ago by Erno Rubik. Just like that kid in geometry class, he was passionate about the subject. Not satisfied with working problems out on paper, he brought them into 3d form.