FAQ

Are Qubits® are better with STEM concepts than Brick Toys?



Qubits Toy is a toy that uses principles of quantum physics to teach children about quantum computing. It is designed to help children learn about quantum physics and quantum computing in a hands-on and interactive way.
There are several reasons why Qubits Toy may be considered better for STEM education than Brick/Block Toys. One reason is that it is specifically designed to teach children about quantum physics and quantum computing, which are important and rapidly-growing fields in science and technology.
In contrast, Block/Bricks are a general-purpose stacking construction toy that does not have a specific focus on STRUCTURAL education. Bricks have been used in architecture since the beginning of time and are largely old fashioned and teach students only about compression. Qubits teach compression, tension, structural shear planes, geometric patterns and design.

Another reason is that Qubits Toy is important to STEM is that it uses a hands-on and interactive approach to learning, which can be more engaging and effective for children than simply reading about or watching videos about quantum physics and quantum computing. By using Qubits Toy, children can actively explore and experiment with concepts related to quantum physics and quantum computing, which can help them understand and remember the material more effectively. Quantum science is an important and rapidly growing field that has the potential to change the way we think about the world and to lead to many important technological innovations.
Overall, Qubits Toy may be a better choice for STEM education than Brick/Block toys because it is specifically designed to teach children about quantum physics and quantum computing, and it uses a hands-on and interactive approach to learning that can be more engaging and effective for children.


Is one building toy better than the others?


It is difficult to say which toy is "better" overall, as different toys may be more suitable for different purposes and age groups. Here is a brief overview of several building toys:
1. Tinker Toy: Tinker Toy is a building toy that consists of wooden rods, spools, and connectors that can be used to build a wide variety of structures and models. It is suitable for children ages 3 and up.

2. K'nex: K'nex is a building toy that consists of interlocking plastic rods, connectors, and other components that can be used to build a wide variety of structures and models. It is suitable for children ages 7 and up.

3. Lego: Lego is a popular line of construction toys that consists of interlocking plastic bricks. Lego bricks can be used to build a wide variety of structures, models, and other objects, and the toys are popular with children and adults around the world.

4. Qubits STEM Construction Kit: Qubits toys are sold in sets that vary in size and complexity, ranging from simple starter sets to larger, more advanced sets. They are intended for use by teachers, children and adults of all ages, and are suitable for both solo play and group activities. Qubits toys are widely available, and can be purchased at toy stores, online retailers, and thru the Qubits website.
Overall, it is difficult to compare these toys directly, as they are designed for different age groups and have different focus areas. Tinker Toy is a good choice for younger children, while K'nex is suitable for slightly older children who are interested in engineering and building more complex structures. Lego Bricks are a good choice for very young children who are just starting to explore building toys, while Qubits is a good choice for children who are interested in learning about modular form design and engineering, it teaches about the principal aspects of architectural design which are shear plain and lateral support. Qubits does that in a hands-on and interactive way.
 
Why is Qubits Toy geometry important?

Qubits toy geometry is important because it is one of the key aspects of the toy system that allows for a wide range of building possibilities and encourages creative thinking and problem-solving skills. Qubits toys are designed to be flexible and easy to connect and disconnect, allowing for a high degree of freedom in building structures and shapes.
The geometry of Qubits toys allows for the creation of a variety of two-dimensional and three-dimensional structures, including simple shapes such as triangles, hexagons, pentagons, and rombus, as well as more complex and intricate inter-meshed designs. The ability to build a wide range of shapes and structures encourages spatial reasoning and visualization skills, as well as creativity and problem-solving abilities.
In addition to the basic geometry of the toy system, Qubits also offers examples of projects built with Qubits including towers, bridges, stairways, ladders, rovers, and even simple projects such as a bird feeder. This allows for even greater flexibility and creativity in building, as well as the opportunity to explore concepts related to engineering and physics. Overall, the geometry of Qubits toys is an important aspect of the toy system that helps to promote learning and development in a fun and engaging way.

Please describe what Qubits look like.

Qubits Toy is a flat flexible plastic toy consisting of six equilateral triangles that connect with hexagonal snaps to create big strong geometric configurations. The toy system allows for a wide range of building possibilities and encourages creativity and problem-solving skills. It is intended for use by children and adults of all ages, and is suitable for both solo play and group activities. Qubits Toy is widely available and can be purchased at toy stores, online retailers, and through the Qubits website. I hope this information is helpful.

How can Qubits® build geometric polyhedrons like the icosidodecahedron and cuboctahedron?

Qubits Toy is a flat flexible plastic toy consisting of six equilateral triangles that connect with hexagonal snaps to create big strong geometric configurations. The toy system allows for a wide range of building possibilities, and it is possible to use Qubits Toy to build a variety of geometric polyhedrons, including the icosidodecahedron and cuboctahedron.

To build a geometric polyhedron using Qubits Toy, you will need to connect the flat plastic triangles in specific configurations to create the desired shape. The specific number and arrangement of the triangles needed to create a particular polyhedron will depend on the geometry of the polyhedron and the number of the Qubits Toy pieces.

To build a cuboctahedron, for example, you will need to connect 14 Qubits Toy triangles in a specific configuration, with eight of the triangles forming the faces of a cube and the remaining six triangles forming the faces of an octahedron. Similarly, to build an icosidodecahedron, you will need to connect 30 Qubits Toy triangles in a specific configuration, with 20 of the triangles forming the faces of an icosahedron and the remaining 10 triangles forming the faces of a dodecahedron.

Building geometric polyhedra using Qubits Toy requires a good understanding of geometry and spatial reasoning skills, as well as patience and persistence. It can be a challenging but rewarding activity that helps to develop problem-solving and critical thinking skills.


Are Qubits STEM Building Kits good for STEM Classrooms?


Qubits STEM Building Kits can be a good tool for educational purposes, particularly in STEM (science, technology, engineering, and math) education. Building sets like Qubits can help students to learn about and explore concepts related to geometry, spatial reasoning, and engineering, while fostering creativity, problem-solving skills, and a love of hands-on learning.
Some specific ways in which Qubits STEM Building Kits might be used include:

* Encouraging creativity and problem-solving skills: The ability to build and create a wide range of structures and designs using Qubits can help to encourage creativity and encourage students to think critically and solve problems.

* Teaching concepts related to geometry and spatial reasoning: The unique geometric shape of the Qubits pieces and the ability to connect them in various ways can provide a hands-on way for students to learn about and explore concepts related to geometry and spatial reasoning.

* Enhancing fine motor skills: Manipulating the Qubits pieces to create structures and designs can help students to develop their fine motor skills and hand-eye coordination.

* Providing a fun and engaging way to learn: Building with Qubits can be a fun and enjoyable activity for students, which can help to keep them engaged and motivated to learn.

Overall, Qubits STEM Building Kits can be a valuable tool for educational purposes, helping students to learn about and explore a wide range of concepts while fostering creativity, problem-solving skills, and a love of hands-on learning.
 
The Qubits STEM Building kit is a construction toy that allows students to build and explore a variety of geometric shapes and structures. If you want to create a curriculum around the icosidodecahedron using the Qubits STEM Building kit, here are some steps you could follow:


1. Begin by introducing students to the concept of three-dimensional shapes and the properties of polyhedra. You may want to start by reviewing some of the basic shapes, such as cubes, pyramids, and spheres, and discussing their properties (e.g., number of faces, edges, and vertices).

2. Introduce the icosidodecahedron specifically, and discuss its unique properties. The icosidodecahedron is a polyhedron with 20 equilateral triangles and 12 pentagons, and has a total of 32 faces, 60 edges, and 30 vertices.

3. Use the Qubits STEM Building kit to construct an icosidodecahedron, either as a class or in small groups. You may want to provide students with a set of instructions or have them work from a diagram to guide them through the construction process.

4. Encourage students to explore and manipulate the icosidodecahedron, paying attention to its geometric properties. They could measure the angles between faces, count the number of edges and vertices, or look at how the shape changes as it is manipulated.

5. Use the icosidodecahedron as a starting point for other activities and investigations. For example, students could design their own polyhedra, create models of real-world objects using the Qubits, or explore the mathematics behind different three-dimensional shapes.

6. As students work with the icosidodecahedron, be sure to encourage them to ask questions, make predictions, and draw connections to other concepts and ideas. This will help to engage them in the learning process and encourage deeper understanding of the material.
 
When you build a polyhedron with Qubits STEM building kit, the number of pieces you need matches the number of edges. Knowing that, how many Qubits are needed to build the icosidodecahedron?

To build an icosidodecahedron using the Qubits STEM Building kit, you will need a total of 60 Qubits. This is because an icosidodecahedron is a polyhedron with 60 edges.

The Qubits STEM Building kit is a construction toy that allows students to build a variety of three-dimensional shapes and structures by connecting small plastic pieces called "Qubits." Each Qubit has a pair of connectors on opposite ends, which allows it to be attached to other Qubits to form a structure.
To build an icosidodecahedron with the Qubits STEM Building kit, you will need to connect the Qubits in a specific pattern to form the shape. This may require some trial and error, as well as a good understanding of the geometric properties of the icosidodecahedron. You may want to start by constructing some simpler shapes, such as pyramids, or snowflakes before moving on to the more complex icosidodecahedron.
 
Explain in one paragraph the Qubits® Patent.

The modular building element described in the patent is a building block that is made up of three pairs of symmetrical prisms that are stacked on top of each other in three overlapping tiers. These prisms can have rectangular or obliquely parallelogram-shaped sides, and the end walls are always equilateral triangles. The modular building element is designed to be congruently meshed with other similar elements in multiple different ways, allowing for a wide variety of structures to be constructed. The building element is intended to have high compressive strength, stability, and resistance to multi-directional stresses. It is classified in the field of building blocks and building devices, and it is specifically designed to be assembled without the use of mortar. The building element is intended to be used in a variety of applications, including architectural structures, emergency shelters, STEM educational kits, and toys.