Determining Basis for Eclidean Topology on R Squared

In summary, to determine whether a collection is a basis for the Euclidean topology on R squared, one can start by writing out the definition of "basis for a topology". Then, check if the given collections satisfy the conditions in the definition. This can be done by defining the topology for R2 using either open disks or open rectangles as the basis.
  • #1
Iuriano Ainati
1
0
In the topic of the topology, how to determine whether or not these collections is the basis for the Eclidean topology, on R squared.

1. the collection of all open squares with sides parallel to the axes.

2. the collection of all open discs.
3. the collection of all open rectangle.
4. the collection of all open triangles.
 
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  • #2
What have you tried? Where are you stuck?
 
  • #3
Start by writing out the definition of "basis for a topology".

Then see which of those satisfy the conditions in the definition!
 
  • #4
How have you defined the topology for R2? Usually you do it by setting the open disks as a basis (ie, considering it as a metric space with the usual metric), or else considering it as a product space of R (with the open intervals as a basis for R), which would make the open rectangles your basis. Since you're asked to show both of these is a valid basis, I'm curious what else you'd use to do this.
 

FAQ: Determining Basis for Eclidean Topology on R Squared

What is the basis for the Euclidean topology on R squared?

The basis for the Euclidean topology on R squared is the collection of all open balls with rational radii centered at points with rational coordinates. This basis is countable and generates the open sets of the Euclidean topology on R squared.

How is the Euclidean topology on R squared determined?

The Euclidean topology on R squared is determined by the metric space structure of R squared, where the distance between two points is defined as the length of the line segment connecting them. This metric induces a topology on R squared, where the open sets are defined as the unions of all possible open balls with rational radii centered at points with rational coordinates.

Why is the basis for the Euclidean topology on R squared defined in terms of open balls?

The basis for the Euclidean topology on R squared is defined in terms of open balls because it allows for a convenient way to describe the open sets in the topology. Open balls are also a natural choice since they align with our intuition of an open set as a set that contains all of its interior points.

Are there other possible bases for the Euclidean topology on R squared?

Yes, there are infinitely many possible bases for the Euclidean topology on R squared. One example is the collection of all open squares with rational side lengths centered at points with rational coordinates. This basis is also countable and generates the same topology as the basis of open balls.

How does the basis for the Euclidean topology on R squared relate to the open sets in the topology?

The basis for the Euclidean topology on R squared is a subset of the collection of all open sets in the topology. However, this basis is not exhaustive and there are open sets in the topology that cannot be expressed as a union of open balls with rational radii centered at points with rational coordinates. This is because the topology on R squared contains uncountably many open sets, while the basis only contains countably many sets.

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