User:RJGray/Sandboxcantor2

Let the smaller of the two numbers ω_κ₁, ω_κ₂ be denoted by α', the larger by β'. (Their equality is impossible because we assumed that our sequence consists of nothing but unequal numbers.)

     Then according to the definition:
            α < α' < β' < β ,
furthermore:
                 κ₁ < κ₂ ;
and all numbers ω_μ of our sequence, for which μ ≤ κ₂, do not lie in the interior of the interval [α', β'], as is immediately clear from the definition of the numbers κ₁, κ₂. Similarly, let ω_κ₃ and ω_κ₄ be the two numbers of our sequence with smallest indices that fall in the interior of the interval [α', β'] and let the smaller of the numbers ω_κ₃, ω_κ₄ be denoted by α'', the larger by β''.

     Then one has:
            α' < α'' < β'' < β' ,
              κ₂ < κ₃ < κ₄ ;
and one sees that all numbers ω_μ of our sequence, for which μ ≤ κ₄, do not fall into the interior of the interval [α'', β''].

After one has followed this rule to reach an interval [α^{(ν - 1)}, β^{(ν - 1)}], the next interval is produced by selecting the first two (i. e. with lowest indices) numbers of our sequence (ω) (let them be ω_{κ_{2ν - 1}} and ω_{κ_2ν}) that fall into the interior of [α^{(ν - 1)}, β^{(ν - 1)}]. Let the smaller of these two numbers be denoted by α^(ν), the larger by β^(ν).

     The interval [α^(ν), β^(ν)] then lies in the interior of all preceding intervals and has the specific relation with our sequence (ω) that all numbers ω_μ, for which μ ≤ κ_2ν, definitely do not lie in its interior. Since obviously:
            κ₁ < κ₂ < κ₃ < . . . , ω_{κ_{2ν – 2}} < ω_{κ_{2ν – 1}} < ω_{κ_2ν} , . . .
and these numbers, as indices, are whole numbers, so:
            κ_2ν ≥ 2ν ,
and hence:
            ν < κ_2ν ;
thus, we can certainly say (and this is sufficient for the following):

That if ν is an arbitrary whole number, the [real] quantity ω_ν lies outside the interval [α^(ν) . . . β^(ν)].

Cantor's new proof first handles the easy case of the sequence P not being dense in the interval. Then it deals with the more difficult case of P being dense. This division into cases not only indicates which sequences are most difficult to handle, but it also reveals the important role denseness plays in the proof.^{[proof 1]}

In the first case, P is not dense in [a, b]. By definition, P is dense in [a, b] if and only if for all subintervals (c, d) of [a, b], there is an x ∈ P such that x ∈ (c, d). Taking the negation of each side of the "if and only if" produces: P is not dense in [a, b] if and only if there exists a subinterval (c, d) of [a, b] such that for all x ∈ P : x ∉ (c, d). Therefore, every number in (c, d) is not contained in the sequence P.^{[proof 1]} This case handles case 1 and case 3 of Cantor's 1874 proof.

In the second case, P is dense in [a, b]. The denseness of P is used to recursively define a nested sequence of intervals that excludes all elements of P. The definition begins with a₁ = a and b₁ = b. The definition's inductive case starts with the interval (a_n, b_n), which because of the denseness of P contains infinitely many elements of P. From these elements of P, the two with smallest indices are used to define a_n + 1 and b_n + 1; namely, a_n + 1 is the least of these two numbers and b_n + 1 is the greatest. Cantor's 1874 proof demonstrates that for all n : x_n ∉ (a_n, b_n). The sequence a_n is increasing and bounded above by b, so it has a limit a_∞, which satisfies a_n < a_∞. The sequence b_n is decreasing and bounded below by a, so it has a limit b_∞, which satisfies b_∞ < b_n. Also, a_n < b_n implies a_∞ ≤ b_∞. Therefore, a_n < a_∞ ≤ b_∞ < b_n. If a_∞ < b_∞, then for every n: x_n ∉ (a_∞, b_∞) because x_n is not in the larger interval (a_n, b_n). This contradicts P being dense in [a, b]. Therefore, a_∞ = b_∞. Since for all n: a_∞ ∈ (a_n, b_n) but x_n ∉ (a_n, b_n), the limit a_∞ is a real number that is not contained in the sequence P.^{[proof 1]} This case handles case 2 of Cantor's 1874 proof.

Fraktur[edit]

$\qquad \quad \;\,{\textbf {Fraktur}}$

$\qquad \quad {\text{A}}\quad \;\;{\mathfrak {A}}\quad {\mathfrak {a}}$

$\qquad \quad {\text{B}}\quad \;\;{\mathfrak {B}}\quad {\mathfrak {b}}$

$\qquad \quad {\text{C}}\quad \;\;{\mathfrak {C}}\quad {\mathfrak {c}}$

$\qquad \quad {\text{D}}\quad \;\;{\mathfrak {D}}\quad {\mathfrak {d}}$

$\qquad \quad {\text{E}}\quad \;\;{\mathfrak {E}}\quad {\mathfrak {e}}$

$\qquad \quad {\text{F}}\quad \;\;{\mathfrak {F}}\quad {\mathfrak {f}}$

$\qquad \quad {\text{G}}\quad \;\;{\mathfrak {G}}\quad {\mathfrak {g}}$

$\qquad \quad {\text{H}}\quad \;\;{\mathfrak {H}}\quad {\mathfrak {h}}$

$\qquad \quad {\text{I}}\quad \;\;\;\,{\mathfrak {I}}\quad \;{\mathfrak {i}}$

$\qquad \quad {\text{J}}\quad \;\;\;\,{\mathfrak {J}}\quad \;{\mathfrak {j}}$

$\qquad \quad {\text{K}}\quad \;\;\;{\mathfrak {K}}\quad \;{\mathfrak {k}}$

$\qquad \quad {\text{L}}\quad \;\;\;\,{\mathfrak {L}}\quad \;{\mathfrak {l}}$

$\qquad \quad {\text{M}}\quad \;\;{\mathfrak {M}}\quad {\mathfrak {m}}$

$\qquad \quad {\text{N}}\quad \;\;{\mathfrak {N}}\quad {\mathfrak {n}}$

$\qquad \quad {\text{O}}\quad \;\;{\mathfrak {O}}\quad {\mathfrak {o}}$

$\qquad \quad {\text{P}}\quad \;\;{\mathfrak {P}}\quad {\mathfrak {p}}$

$\qquad \quad {\text{Q}}\quad \;\;{\mathfrak {Q}}\quad {\mathfrak {q}}$

$\qquad \quad {\text{R}}\quad \;\;{\mathfrak {R}}\quad {\mathfrak {r}}$

$\qquad \quad {\text{S}}\quad \;\;{\mathfrak {S}}\quad {\mathfrak {s}}$

$\qquad \quad {\text{T}}\quad \;\;{\mathfrak {T}}\quad {\mathfrak {t}}$

$\qquad \quad {\text{U}}\quad \;\;{\mathfrak {U}}\quad {\mathfrak {u}}$

$\qquad \quad {\text{V}}\quad \;\;{\mathfrak {V}}\quad {\mathfrak {v}}$

$\qquad \quad {\text{W}}\quad \;\;\!{\mathfrak {W}}\quad {\mathfrak {w}}$

$\qquad \quad {\text{X}}\quad \;\;{\mathfrak {X}}\quad {\mathfrak {x}}$

$\qquad \quad {\text{Y}}\quad \;\;{\mathfrak {Y}}\quad {\mathfrak {y}}$

$\qquad \quad {\text{Z}}\quad \;\;{\mathfrak {Z}}\quad \;{\mathfrak {z}}$

Cite error: There are <ref group=proof> tags on this page, but the references will not show without a {{reflist|group=proof}} template (see the help page).

[proof 1]