The Rubik’s cube is one of the most popular puzzles in the world, but it may seem like a very intimidating challenge. In reality, it can be solved quite easily with a few algorithms and a great deal of determination. For beginners, the easiest way to learn to solve the Rubik’s cube is to use a guide.
Roux method
The Roux method isn’t widely known, but has shown great promise in sub-15 attempts by Thom Barlow, Jules Manalang, Austin Moore, Alexander Lau, and Kian Mansour. It involves building a block by block structure, using the CMLL rule, only using M and U-turns, and orienting the remaining “bad edges” so that each block has the same orientation. The first few stages can be challenging, but will get easier with practice.
First, learn to solve the first layer. After solving the first layer, move to the middle layer. This will solve two-thirds of the cube. This will allow you to solve the final four edges. This method takes a little longer depending on where you place the white corners, so start out by solving the first layer.
After that, move onto the next step. Hold the center piece in the middle and try to make the center piece the same color as the edges. This will make the cube easier to solve. Once you’ve mastered this step, you can move on to more advanced algorithms. If you’d like to master this method, YouTube is your friend! Alternatively, you can ask a friend for help in solving the puzzle.
Fridrich method
If you’re a beginner, you may be interested in the Fridrich method to solve Rubik’s cube. This method is designed to help you solve the puzzle in less time than you might expect. It combines intuitive learning with algorithmic solution. First, learn to solve the two edges, which are on opposite sides of the cube.
Then, solve the cross on the bottom layer. This way, you’ll have an easier time focusing on the unsolved faces. You can also avoid flipping the cube once you finish solving the cross. This method will help you avoid the 20-second threshold and give you more time to practice.
Once you’ve solved the two first layers, you can move on to the middle layer. You can move the edge pieces in groups of three. You can’t have two unsolved edges, but it’s okay to leave four. This method is a universal one, but it takes longer depending on where the corner pieces are placed.
ZZ method
There are several ways to solve a Rubik’s cube. You can use the standard notation to start. The easiest way to solve a Rubik’s cube is to start from the white side of the cube. That’s the side that shows the Rubik’s logo. Then, you’ll solve the puzzle by solving the four edges that match.
This method is easier to master than the previous two methods. You’ll need to have a good sense of organization in order to solve the cube correctly. You can arrange the yellow pieces in three ways: an individual yellow dot in the center, a line or an L shape. When you have the correct arrangement, rotate the cube until the edges are encased and the line is horizontal.
There are several variations of the ZZ method. The original version was designed by Zbigniew Zborowski and is a high-speed method. It uses very few moves and high turning speed. In addition, this method doesn’t require a rotation, which helps you solve a cube faster.
Building a white cross to solve a rubik’s cube
Building a white cross is a good way to familiarize yourself with the mechanics of a Rubik’s cube. To build a white cross, you need to grab pieces from the middle and bottom layers. The white corners of the cube should match those of the pieces on the top layer.
Building a white cross is the first step to solving the cube. It requires a little practice and will take some time. The final product should look like the one in the picture below. If you’re a beginner, spend some time experimenting with the cube and building it yourself, or watch a video tutorial on how to do it.
Once you’ve built the cross, you can build the other two. The first cross is tricky, and you may want to read the instructions several times to get the hang of it. The image below will help you understand the end result of each step.