Anki Deck Changes

Note 1: ETH::A&D

Deck: ETH::A&D
Note Type: Horvath Cloze
GUID: M,?u9cw(S%

modified

Before

Front

{{c1:: \(\sum_{i = 1}^{n} i\log(i)\)}} \(\leq\) \(O(n \log(n))\) (O-notation)

Back

{{c1:: \(\sum_{i = 1}^{n} i\log(i)\)}} \(\leq\) \(O(n \log(n))\) (O-notation)

After

Front

{{c1:: \(\sum_{i = 1}^{n} i\log(i)\)::Sum}} \(\leq\) \(O(n \log(n))\)

Back

{{c1:: \(\sum_{i = 1}^{n} i\log(i)\)::Sum}} \(\leq\) \(O(n \log(n))\)

Field-by-field Comparison

Field	Before	After
Text	{{c1:: \(\sum_{i = 1}^{n} i\log(i)\)}}  \(\leq\) {{c2::\(O(n \log(n))\)~~ (~~O-notation)}}	{{c1:: \(\sum_{i = 1}^{n} i\log(i)\)::Sum}}  \(\leq\) {{c2::\(O(n \log(n))\)::O-notation}}

Tags: ETH::1._Semester::A&D::02._Asymptotic_Notation::3._O-Notation::Sums

Note 2: ETH::A&D

Deck: ETH::A&D
Note Type: Horvath Cloze
GUID: PvmYSo9Bj_

modified

Before

Front

In the edge \(e = (u, v)\), we call \(u\) the start vertex and \(v\) the end vertex

Back

In the edge \(e = (u, v)\), we call \(u\) the start vertex and \(v\) the end vertex

After

Front

In the edge \(e = (u, v)\), we call \(u\) the start vertex and \(v\) the end vertex.

Back

In the edge \(e = (u, v)\), we call \(u\) the start vertex and \(v\) the end vertex.

Field-by-field Comparison

Field	Before	After
Text	In the edge \(e = (u, v)\), we call \(u\) the {{c1::start}} vertex and \(v\) the {{c1::end}} vertex	In the edge \(e = (u, v)\), we call \(u\) the {{c1::start}} vertex and \(v\) the {{c1::end}} vertex.

Tags: ETH::1._Semester::A&D::07._Graphs::1._Introduction_to_Graphs

Note 3: ETH::DiskMat

Deck: ETH::DiskMat
Note Type: Horvath Cloze
GUID: F6#_)#wBbP

modified

Before

Front

For a field \(F\), the polynomial extension \(F[x]\) is an integral domain (name most constrained property).

Back

For a field \(F\), the polynomial extension \(F[x]\) is an integral domain (name most constrained property).

After

Front

For a field \(F\), the polynomial extension \(F[x]\) is an integral domain.

Back

For a field \(F\), the polynomial extension \(F[x]\) is an integral domain.

Field-by-field Comparison

Field	Before	After
Text	For a field \(F\), the polynomial extension \(F[x]\) is {{c1:: an integral domain}} (name most constrained property).	For a field \(F\), the polynomial extension \(F[x]\) is {{c1:: an integral domain::(name most constrained property)}}.

Tags: ETH::1._Semester::DiskMat::5._Algebra::6._Polynomials_over_a_Field

Note 4: ETH::LinAlg

Deck: ETH::LinAlg
Note Type: Horvath Classic
GUID: eUCQYkiYf@

modified

Before

Front

What is a property that always hold for linear transformations?

Back

What is a property that always hold for linear transformations?

\(T(0) = 0\)

After

Front

What is a property that always holds for linear transformations?

Back

What is a property that always holds for linear transformations?

\(T(0) = 0\)

Field-by-field Comparison

Field	Before	After
Front	What is a property that always hold for linear transformations?	What is a property that always holds for linear transformations?

Tags: ETH::1._Semester::LinAlg::2._Matrices::2._Matrices_and_linear_transformations::2._Linear_transformations_and_linear_functionals