helicoidal flat surfaces in s3 - universidad de granadarcamino/meetingcmc/manfio.pdfaim...
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Helicoidal flat surfaces in S3
Fernando Manfio
Universidade de São Paulo
Joint work with João Paulo dos Santos
Geometric aspects on capillary problems and related topics
Fernando Manfio Helicoidal flat surfaces in S3
![Page 2: Helicoidal flat surfaces in S3 - Universidad de Granadarcamino/meetingcmc/manfio.pdfAim Classification of helicoidal flat surfaces in S3 in terms of their first and second fundamental](https://reader035.vdocument.in/reader035/viewer/2022071607/6145104034130627ed50bf41/html5/thumbnails/2.jpg)
Aim
Classification of helicoidal flat surfaces in S3 in terms oftheir first and second fundamental forms and by linearsolutions of the corresponding angle function.
Helicoidal surfaces are generalizations of rotationalsurfaces
In R3, a helicoidal surface can be written as
X (u, v) = (u cos v ,u sin v , λ(u) + hv),
where h ∈ R and λ(u) is a smooth function.
Fernando Manfio Helicoidal flat surfaces in S3
![Page 3: Helicoidal flat surfaces in S3 - Universidad de Granadarcamino/meetingcmc/manfio.pdfAim Classification of helicoidal flat surfaces in S3 in terms of their first and second fundamental](https://reader035.vdocument.in/reader035/viewer/2022071607/6145104034130627ed50bf41/html5/thumbnails/3.jpg)
Aim
Classification of helicoidal flat surfaces in S3 in terms oftheir first and second fundamental forms and by linearsolutions of the corresponding angle function.Helicoidal surfaces are generalizations of rotationalsurfaces
In R3, a helicoidal surface can be written as
X (u, v) = (u cos v ,u sin v , λ(u) + hv),
where h ∈ R and λ(u) is a smooth function.
Fernando Manfio Helicoidal flat surfaces in S3
![Page 4: Helicoidal flat surfaces in S3 - Universidad de Granadarcamino/meetingcmc/manfio.pdfAim Classification of helicoidal flat surfaces in S3 in terms of their first and second fundamental](https://reader035.vdocument.in/reader035/viewer/2022071607/6145104034130627ed50bf41/html5/thumbnails/4.jpg)
Aim
Classification of helicoidal flat surfaces in S3 in terms oftheir first and second fundamental forms and by linearsolutions of the corresponding angle function.Helicoidal surfaces are generalizations of rotationalsurfaces
In R3, a helicoidal surface can be written as
X (u, v) = (u cos v ,u sin v , λ(u) + hv),
where h ∈ R and λ(u) is a smooth function.
Fernando Manfio Helicoidal flat surfaces in S3
![Page 5: Helicoidal flat surfaces in S3 - Universidad de Granadarcamino/meetingcmc/manfio.pdfAim Classification of helicoidal flat surfaces in S3 in terms of their first and second fundamental](https://reader035.vdocument.in/reader035/viewer/2022071607/6145104034130627ed50bf41/html5/thumbnails/5.jpg)
G the 1-parameter subgroup of the isometries φα,β(t) : S3 → S3:
G =
{φα,β(t) =
(eiαt 00 eiβt
): t ∈ R
}.
Each φα,β(t) can be seen as the composition of a translationand a rotation in S3,
φα,β(t) = ψα(t) ◦ ϕβ(t) :
1 0 0 00 1 0 00 0 cosβt − sinβt0 0 sinβt cosβt
,
cosαt − sinαt 0 0sinαt cosαt 0 0
0 0 1 00 0 0 1
.
When β 6= 0, ϕβ(t) fixes the set l = {(z,0) ∈ S3}. So, {ϕβ(t)}consists of rotations around l and {ψα(t)} are translationsalong l .
Fernando Manfio Helicoidal flat surfaces in S3
![Page 6: Helicoidal flat surfaces in S3 - Universidad de Granadarcamino/meetingcmc/manfio.pdfAim Classification of helicoidal flat surfaces in S3 in terms of their first and second fundamental](https://reader035.vdocument.in/reader035/viewer/2022071607/6145104034130627ed50bf41/html5/thumbnails/6.jpg)
G the 1-parameter subgroup of the isometries φα,β(t) : S3 → S3:
G =
{φα,β(t) =
(eiαt 00 eiβt
): t ∈ R
}.
Each φα,β(t) can be seen as the composition of a translationand a rotation in S3,
φα,β(t) = ψα(t) ◦ ϕβ(t) :
1 0 0 00 1 0 00 0 cosβt − sinβt0 0 sinβt cosβt
,
cosαt − sinαt 0 0sinαt cosαt 0 0
0 0 1 00 0 0 1
.
When β 6= 0, ϕβ(t) fixes the set l = {(z,0) ∈ S3}. So, {ϕβ(t)}consists of rotations around l and {ψα(t)} are translationsalong l .
Fernando Manfio Helicoidal flat surfaces in S3
![Page 7: Helicoidal flat surfaces in S3 - Universidad de Granadarcamino/meetingcmc/manfio.pdfAim Classification of helicoidal flat surfaces in S3 in terms of their first and second fundamental](https://reader035.vdocument.in/reader035/viewer/2022071607/6145104034130627ed50bf41/html5/thumbnails/7.jpg)
G the 1-parameter subgroup of the isometries φα,β(t) : S3 → S3:
G =
{φα,β(t) =
(eiαt 00 eiβt
): t ∈ R
}.
Each φα,β(t) can be seen as the composition of a translationand a rotation in S3,
φα,β(t) = ψα(t) ◦ ϕβ(t) :
1 0 0 00 1 0 00 0 cosβt − sinβt0 0 sinβt cosβt
,
cosαt − sinαt 0 0sinαt cosαt 0 0
0 0 1 00 0 0 1
.
When β 6= 0, ϕβ(t) fixes the set l = {(z,0) ∈ S3}. So, {ϕβ(t)}consists of rotations around l and {ψα(t)} are translationsalong l .
Fernando Manfio Helicoidal flat surfaces in S3
![Page 8: Helicoidal flat surfaces in S3 - Universidad de Granadarcamino/meetingcmc/manfio.pdfAim Classification of helicoidal flat surfaces in S3 in terms of their first and second fundamental](https://reader035.vdocument.in/reader035/viewer/2022071607/6145104034130627ed50bf41/html5/thumbnails/8.jpg)
G the 1-parameter subgroup of the isometries φα,β(t) : S3 → S3:
G =
{φα,β(t) =
(eiαt 00 eiβt
): t ∈ R
}.
Each φα,β(t) can be seen as the composition of a translationand a rotation in S3,
φα,β(t) = ψα(t) ◦ ϕβ(t) :
1 0 0 00 1 0 00 0 cosβt − sinβt0 0 sinβt cosβt
,
cosαt − sinαt 0 0sinαt cosαt 0 0
0 0 1 00 0 0 1
.
When β 6= 0, ϕβ(t) fixes the set l = {(z,0) ∈ S3}.
So, {ϕβ(t)}consists of rotations around l and {ψα(t)} are translationsalong l .
Fernando Manfio Helicoidal flat surfaces in S3
![Page 9: Helicoidal flat surfaces in S3 - Universidad de Granadarcamino/meetingcmc/manfio.pdfAim Classification of helicoidal flat surfaces in S3 in terms of their first and second fundamental](https://reader035.vdocument.in/reader035/viewer/2022071607/6145104034130627ed50bf41/html5/thumbnails/9.jpg)
G the 1-parameter subgroup of the isometries φα,β(t) : S3 → S3:
G =
{φα,β(t) =
(eiαt 00 eiβt
): t ∈ R
}.
Each φα,β(t) can be seen as the composition of a translationand a rotation in S3,
φα,β(t) = ψα(t) ◦ ϕβ(t) :
1 0 0 00 1 0 00 0 cosβt − sinβt0 0 sinβt cosβt
,
cosαt − sinαt 0 0sinαt cosαt 0 0
0 0 1 00 0 0 1
.
When β 6= 0, ϕβ(t) fixes the set l = {(z,0) ∈ S3}. So, {ϕβ(t)}consists of rotations around l and {ψα(t)} are translationsalong l .
Fernando Manfio Helicoidal flat surfaces in S3
![Page 10: Helicoidal flat surfaces in S3 - Universidad de Granadarcamino/meetingcmc/manfio.pdfAim Classification of helicoidal flat surfaces in S3 in terms of their first and second fundamental](https://reader035.vdocument.in/reader035/viewer/2022071607/6145104034130627ed50bf41/html5/thumbnails/10.jpg)
Definition
A helicoidal surface in S3 is a surface invariant under the actionφα,β : S1 × S3 → S3 of S1 on S3 given by
φα,β(t , (z,w)) = (eiαtz,eiβtw).
M is a helicoidal surface in S3 ⇔ M is invariant under allelements of G.
When α = β, the orbits are all great circles, and they areequidistant from each other (Clifford translations);α = −β is also, up to a rotation in S3, a Clifford translation.
Fernando Manfio Helicoidal flat surfaces in S3
![Page 11: Helicoidal flat surfaces in S3 - Universidad de Granadarcamino/meetingcmc/manfio.pdfAim Classification of helicoidal flat surfaces in S3 in terms of their first and second fundamental](https://reader035.vdocument.in/reader035/viewer/2022071607/6145104034130627ed50bf41/html5/thumbnails/11.jpg)
Definition
A helicoidal surface in S3 is a surface invariant under the actionφα,β : S1 × S3 → S3 of S1 on S3 given by
φα,β(t , (z,w)) = (eiαtz,eiβtw).
M is a helicoidal surface in S3 ⇔ M is invariant under allelements of G.
When α = β, the orbits are all great circles, and they areequidistant from each other (Clifford translations);α = −β is also, up to a rotation in S3, a Clifford translation.
Fernando Manfio Helicoidal flat surfaces in S3
![Page 12: Helicoidal flat surfaces in S3 - Universidad de Granadarcamino/meetingcmc/manfio.pdfAim Classification of helicoidal flat surfaces in S3 in terms of their first and second fundamental](https://reader035.vdocument.in/reader035/viewer/2022071607/6145104034130627ed50bf41/html5/thumbnails/12.jpg)
Definition
A helicoidal surface in S3 is a surface invariant under the actionφα,β : S1 × S3 → S3 of S1 on S3 given by
φα,β(t , (z,w)) = (eiαtz,eiβtw).
M is a helicoidal surface in S3 ⇔ M is invariant under allelements of G.
When α = β, the orbits are all great circles, and they areequidistant from each other (Clifford translations);
α = −β is also, up to a rotation in S3, a Clifford translation.
Fernando Manfio Helicoidal flat surfaces in S3
![Page 13: Helicoidal flat surfaces in S3 - Universidad de Granadarcamino/meetingcmc/manfio.pdfAim Classification of helicoidal flat surfaces in S3 in terms of their first and second fundamental](https://reader035.vdocument.in/reader035/viewer/2022071607/6145104034130627ed50bf41/html5/thumbnails/13.jpg)
Definition
A helicoidal surface in S3 is a surface invariant under the actionφα,β : S1 × S3 → S3 of S1 on S3 given by
φα,β(t , (z,w)) = (eiαtz,eiβtw).
M is a helicoidal surface in S3 ⇔ M is invariant under allelements of G.
When α = β, the orbits are all great circles, and they areequidistant from each other (Clifford translations);α = −β is also, up to a rotation in S3, a Clifford translation.
Fernando Manfio Helicoidal flat surfaces in S3
![Page 14: Helicoidal flat surfaces in S3 - Universidad de Granadarcamino/meetingcmc/manfio.pdfAim Classification of helicoidal flat surfaces in S3 in terms of their first and second fundamental](https://reader035.vdocument.in/reader035/viewer/2022071607/6145104034130627ed50bf41/html5/thumbnails/14.jpg)
Background...
Helicoidal surfaces in R3:
do Carmo, Dajczer, 1982:Description of the space of all helicoidal surfaces in R3 thathave constant mean (Gaussian) curvature.Baikoussis, Koufogiorgos, 1998:Helicoidal surfaces with prescribed mean or Gaussiancurvature.
Fernando Manfio Helicoidal flat surfaces in S3
![Page 15: Helicoidal flat surfaces in S3 - Universidad de Granadarcamino/meetingcmc/manfio.pdfAim Classification of helicoidal flat surfaces in S3 in terms of their first and second fundamental](https://reader035.vdocument.in/reader035/viewer/2022071607/6145104034130627ed50bf41/html5/thumbnails/15.jpg)
Background...
Helicoidal surfaces in R3:
do Carmo, Dajczer, 1982:Description of the space of all helicoidal surfaces in R3 thathave constant mean (Gaussian) curvature.
Baikoussis, Koufogiorgos, 1998:Helicoidal surfaces with prescribed mean or Gaussiancurvature.
Fernando Manfio Helicoidal flat surfaces in S3
![Page 16: Helicoidal flat surfaces in S3 - Universidad de Granadarcamino/meetingcmc/manfio.pdfAim Classification of helicoidal flat surfaces in S3 in terms of their first and second fundamental](https://reader035.vdocument.in/reader035/viewer/2022071607/6145104034130627ed50bf41/html5/thumbnails/16.jpg)
Background...
Helicoidal surfaces in R3:
do Carmo, Dajczer, 1982:Description of the space of all helicoidal surfaces in R3 thathave constant mean (Gaussian) curvature.Baikoussis, Koufogiorgos, 1998:Helicoidal surfaces with prescribed mean or Gaussiancurvature.
Fernando Manfio Helicoidal flat surfaces in S3
![Page 17: Helicoidal flat surfaces in S3 - Universidad de Granadarcamino/meetingcmc/manfio.pdfAim Classification of helicoidal flat surfaces in S3 in terms of their first and second fundamental](https://reader035.vdocument.in/reader035/viewer/2022071607/6145104034130627ed50bf41/html5/thumbnails/17.jpg)
Background...
Helicoidal surfaces in H3:
Galvéz, Martínez, Milán, 2000:Flat surfaces in H3 admit a Weierstrass Representationformula in terms of meromorphic data.Kokubu, Umehara, Yamada, 2004:Global properties of flat surfaces with admissiblesingularities.Martinéz, dos Santos, Tenenblat, 2013:Complete classification of the helicoidal flat surfaces interms of meromorphic data as well as by means of linearharmonic functions.
Fernando Manfio Helicoidal flat surfaces in S3
![Page 18: Helicoidal flat surfaces in S3 - Universidad de Granadarcamino/meetingcmc/manfio.pdfAim Classification of helicoidal flat surfaces in S3 in terms of their first and second fundamental](https://reader035.vdocument.in/reader035/viewer/2022071607/6145104034130627ed50bf41/html5/thumbnails/18.jpg)
Background...
Helicoidal surfaces in H3:
Galvéz, Martínez, Milán, 2000:Flat surfaces in H3 admit a Weierstrass Representationformula in terms of meromorphic data.
Kokubu, Umehara, Yamada, 2004:Global properties of flat surfaces with admissiblesingularities.Martinéz, dos Santos, Tenenblat, 2013:Complete classification of the helicoidal flat surfaces interms of meromorphic data as well as by means of linearharmonic functions.
Fernando Manfio Helicoidal flat surfaces in S3
![Page 19: Helicoidal flat surfaces in S3 - Universidad de Granadarcamino/meetingcmc/manfio.pdfAim Classification of helicoidal flat surfaces in S3 in terms of their first and second fundamental](https://reader035.vdocument.in/reader035/viewer/2022071607/6145104034130627ed50bf41/html5/thumbnails/19.jpg)
Background...
Helicoidal surfaces in H3:
Galvéz, Martínez, Milán, 2000:Flat surfaces in H3 admit a Weierstrass Representationformula in terms of meromorphic data.Kokubu, Umehara, Yamada, 2004:Global properties of flat surfaces with admissiblesingularities.
Martinéz, dos Santos, Tenenblat, 2013:Complete classification of the helicoidal flat surfaces interms of meromorphic data as well as by means of linearharmonic functions.
Fernando Manfio Helicoidal flat surfaces in S3
![Page 20: Helicoidal flat surfaces in S3 - Universidad de Granadarcamino/meetingcmc/manfio.pdfAim Classification of helicoidal flat surfaces in S3 in terms of their first and second fundamental](https://reader035.vdocument.in/reader035/viewer/2022071607/6145104034130627ed50bf41/html5/thumbnails/20.jpg)
Background...
Helicoidal surfaces in H3:
Galvéz, Martínez, Milán, 2000:Flat surfaces in H3 admit a Weierstrass Representationformula in terms of meromorphic data.Kokubu, Umehara, Yamada, 2004:Global properties of flat surfaces with admissiblesingularities.Martinéz, dos Santos, Tenenblat, 2013:Complete classification of the helicoidal flat surfaces interms of meromorphic data as well as by means of linearharmonic functions.
Fernando Manfio Helicoidal flat surfaces in S3
![Page 21: Helicoidal flat surfaces in S3 - Universidad de Granadarcamino/meetingcmc/manfio.pdfAim Classification of helicoidal flat surfaces in S3 in terms of their first and second fundamental](https://reader035.vdocument.in/reader035/viewer/2022071607/6145104034130627ed50bf41/html5/thumbnails/21.jpg)
Natural parametrization
S2+ =
{(x1, x2, x3,0) ∈ S3 : x3 > 0
},
γ : I ⊂ R→ S2+ curve parametrized by arclength (profile):
γ(s) =(
cosϕ(s) cos θ(s), cosϕ(s) sin θ(s), sinϕ(s),0).
A helicoidal surface can be locally parametrized by
X (t , s) = φα,β(t) · γ(s), (1)
Then we have
Xt = φα,β(t) · (−αx2, αx1,0, βx3),Xs = φα,β(t) · γ′(s),
and
N = φα,β(t)·(βx3(x ′2x3−x2x ′3, βx3(x1x ′3−x ′1x3), βx3(x ′1x2−x1x ′2),−αx ′3
).
Fernando Manfio Helicoidal flat surfaces in S3
![Page 22: Helicoidal flat surfaces in S3 - Universidad de Granadarcamino/meetingcmc/manfio.pdfAim Classification of helicoidal flat surfaces in S3 in terms of their first and second fundamental](https://reader035.vdocument.in/reader035/viewer/2022071607/6145104034130627ed50bf41/html5/thumbnails/22.jpg)
Natural parametrization
S2+ =
{(x1, x2, x3,0) ∈ S3 : x3 > 0
},
γ : I ⊂ R→ S2+ curve parametrized by arclength (profile):
γ(s) =(
cosϕ(s) cos θ(s), cosϕ(s) sin θ(s), sinϕ(s),0).
A helicoidal surface can be locally parametrized by
X (t , s) = φα,β(t) · γ(s), (1)
Then we have
Xt = φα,β(t) · (−αx2, αx1,0, βx3),Xs = φα,β(t) · γ′(s),
and
N = φα,β(t)·(βx3(x ′2x3−x2x ′3, βx3(x1x ′3−x ′1x3), βx3(x ′1x2−x1x ′2),−αx ′3
).
Fernando Manfio Helicoidal flat surfaces in S3
![Page 23: Helicoidal flat surfaces in S3 - Universidad de Granadarcamino/meetingcmc/manfio.pdfAim Classification of helicoidal flat surfaces in S3 in terms of their first and second fundamental](https://reader035.vdocument.in/reader035/viewer/2022071607/6145104034130627ed50bf41/html5/thumbnails/23.jpg)
Natural parametrization
S2+ =
{(x1, x2, x3,0) ∈ S3 : x3 > 0
},
γ : I ⊂ R→ S2+ curve parametrized by arclength (profile):
γ(s) =(
cosϕ(s) cos θ(s), cosϕ(s) sin θ(s), sinϕ(s),0).
A helicoidal surface can be locally parametrized by
X (t , s) = φα,β(t) · γ(s), (1)
Then we have
Xt = φα,β(t) · (−αx2, αx1,0, βx3),Xs = φα,β(t) · γ′(s),
and
N = φα,β(t)·(βx3(x ′2x3−x2x ′3, βx3(x1x ′3−x ′1x3), βx3(x ′1x2−x1x ′2),−αx ′3
).
Fernando Manfio Helicoidal flat surfaces in S3
![Page 24: Helicoidal flat surfaces in S3 - Universidad de Granadarcamino/meetingcmc/manfio.pdfAim Classification of helicoidal flat surfaces in S3 in terms of their first and second fundamental](https://reader035.vdocument.in/reader035/viewer/2022071607/6145104034130627ed50bf41/html5/thumbnails/24.jpg)
Natural parametrization
S2+ =
{(x1, x2, x3,0) ∈ S3 : x3 > 0
},
γ : I ⊂ R→ S2+ curve parametrized by arclength (profile):
γ(s) =(
cosϕ(s) cos θ(s), cosϕ(s) sin θ(s), sinϕ(s),0).
A helicoidal surface can be locally parametrized by
X (t , s) = φα,β(t) · γ(s), (1)
Then we have
Xt = φα,β(t) · (−αx2, αx1,0, βx3),Xs = φα,β(t) · γ′(s),
and
N = φα,β(t)·(βx3(x ′2x3−x2x ′3, βx3(x1x ′3−x ′1x3), βx3(x ′1x2−x1x ′2),−αx ′3
).
Fernando Manfio Helicoidal flat surfaces in S3
![Page 25: Helicoidal flat surfaces in S3 - Universidad de Granadarcamino/meetingcmc/manfio.pdfAim Classification of helicoidal flat surfaces in S3 in terms of their first and second fundamental](https://reader035.vdocument.in/reader035/viewer/2022071607/6145104034130627ed50bf41/html5/thumbnails/25.jpg)
Natural parametrization
S2+ =
{(x1, x2, x3,0) ∈ S3 : x3 > 0
},
γ : I ⊂ R→ S2+ curve parametrized by arclength (profile):
γ(s) =(
cosϕ(s) cos θ(s), cosϕ(s) sin θ(s), sinϕ(s),0).
A helicoidal surface can be locally parametrized by
X (t , s) = φα,β(t) · γ(s), (1)
Then we have
Xt = φα,β(t) · (−αx2, αx1,0, βx3),Xs = φα,β(t) · γ′(s),
and
N = φα,β(t)·(βx3(x ′2x3−x2x ′3, βx3(x1x ′3−x ′1x3), βx3(x ′1x2−x1x ′2),−αx ′3
).
Fernando Manfio Helicoidal flat surfaces in S3
![Page 26: Helicoidal flat surfaces in S3 - Universidad de Granadarcamino/meetingcmc/manfio.pdfAim Classification of helicoidal flat surfaces in S3 in terms of their first and second fundamental](https://reader035.vdocument.in/reader035/viewer/2022071607/6145104034130627ed50bf41/html5/thumbnails/26.jpg)
Flat surfaces in S3
If c is a regular curve in S2, then h−1(c) is a flat surface inS3, where h : S3 → S2 is the Hopf fibration.
Proposition 1A helicoidal surface, locally parametrized as before, is a flatsurface if and only if the following equation
β2ϕ′′ sin3 ϕ cosϕ− β2(ϕ′)2 sin4 ϕ+ α2(ϕ′)4 cos4 ϕ = 0 (2)
is satisfied.
Proof: Exercise.
Fernando Manfio Helicoidal flat surfaces in S3
![Page 27: Helicoidal flat surfaces in S3 - Universidad de Granadarcamino/meetingcmc/manfio.pdfAim Classification of helicoidal flat surfaces in S3 in terms of their first and second fundamental](https://reader035.vdocument.in/reader035/viewer/2022071607/6145104034130627ed50bf41/html5/thumbnails/27.jpg)
Flat surfaces in S3
If c is a regular curve in S2, then h−1(c) is a flat surface inS3, where h : S3 → S2 is the Hopf fibration.
Proposition 1A helicoidal surface, locally parametrized as before, is a flatsurface if and only if the following equation
β2ϕ′′ sin3 ϕ cosϕ− β2(ϕ′)2 sin4 ϕ+ α2(ϕ′)4 cos4 ϕ = 0 (2)
is satisfied.
Proof: Exercise.
Fernando Manfio Helicoidal flat surfaces in S3
![Page 28: Helicoidal flat surfaces in S3 - Universidad de Granadarcamino/meetingcmc/manfio.pdfAim Classification of helicoidal flat surfaces in S3 in terms of their first and second fundamental](https://reader035.vdocument.in/reader035/viewer/2022071607/6145104034130627ed50bf41/html5/thumbnails/28.jpg)
Flat surfaces in S3
If c is a regular curve in S2, then h−1(c) is a flat surface inS3, where h : S3 → S2 is the Hopf fibration.
Proposition 1A helicoidal surface, locally parametrized as before, is a flatsurface if and only if the following equation
β2ϕ′′ sin3 ϕ cosϕ− β2(ϕ′)2 sin4 ϕ+ α2(ϕ′)4 cos4 ϕ = 0 (2)
is satisfied.
Proof: Exercise.
Fernando Manfio Helicoidal flat surfaces in S3
![Page 29: Helicoidal flat surfaces in S3 - Universidad de Granadarcamino/meetingcmc/manfio.pdfAim Classification of helicoidal flat surfaces in S3 in terms of their first and second fundamental](https://reader035.vdocument.in/reader035/viewer/2022071607/6145104034130627ed50bf41/html5/thumbnails/29.jpg)
Flat surfaces in S3
If c is a regular curve in S2, then h−1(c) is a flat surface inS3, where h : S3 → S2 is the Hopf fibration.
Proposition 1A helicoidal surface, locally parametrized as before, is a flatsurface if and only if the following equation
β2ϕ′′ sin3 ϕ cosϕ− β2(ϕ′)2 sin4 ϕ+ α2(ϕ′)4 cos4 ϕ = 0 (2)
is satisfied.
Proof: Exercise.
Fernando Manfio Helicoidal flat surfaces in S3
![Page 30: Helicoidal flat surfaces in S3 - Universidad de Granadarcamino/meetingcmc/manfio.pdfAim Classification of helicoidal flat surfaces in S3 in terms of their first and second fundamental](https://reader035.vdocument.in/reader035/viewer/2022071607/6145104034130627ed50bf41/html5/thumbnails/30.jpg)
The Bianchi-Spivak representation
f : M → S3 flat isometric immersion,
Gauss equation⇒ Kext = −1
There exist Tschebycheff coordinates around every point. Wecan choose local coordinates (u, v) such that
I = du2 + 2 cosωdudv + dv2,
II = 2 sinωdudv .(3)
The angle function satisfies
0 < ω < π
ωuv = 0
The aim here is to characterize the flat surfaces when ω islinear, i.e.,
ω(u, v) = ω1(u) + ω2(v) = λ1u + λ2v + λ3, λi ∈ R.
Fernando Manfio Helicoidal flat surfaces in S3
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The Bianchi-Spivak representation
f : M → S3 flat isometric immersion,
Gauss equation⇒ Kext = −1
There exist Tschebycheff coordinates around every point. Wecan choose local coordinates (u, v) such that
I = du2 + 2 cosωdudv + dv2,
II = 2 sinωdudv .(3)
The angle function satisfies
0 < ω < π
ωuv = 0
The aim here is to characterize the flat surfaces when ω islinear, i.e.,
ω(u, v) = ω1(u) + ω2(v) = λ1u + λ2v + λ3, λi ∈ R.
Fernando Manfio Helicoidal flat surfaces in S3
![Page 32: Helicoidal flat surfaces in S3 - Universidad de Granadarcamino/meetingcmc/manfio.pdfAim Classification of helicoidal flat surfaces in S3 in terms of their first and second fundamental](https://reader035.vdocument.in/reader035/viewer/2022071607/6145104034130627ed50bf41/html5/thumbnails/32.jpg)
The Bianchi-Spivak representation
f : M → S3 flat isometric immersion,
Gauss equation⇒ Kext = −1
There exist Tschebycheff coordinates around every point.
Wecan choose local coordinates (u, v) such that
I = du2 + 2 cosωdudv + dv2,
II = 2 sinωdudv .(3)
The angle function satisfies
0 < ω < π
ωuv = 0
The aim here is to characterize the flat surfaces when ω islinear, i.e.,
ω(u, v) = ω1(u) + ω2(v) = λ1u + λ2v + λ3, λi ∈ R.
Fernando Manfio Helicoidal flat surfaces in S3
![Page 33: Helicoidal flat surfaces in S3 - Universidad de Granadarcamino/meetingcmc/manfio.pdfAim Classification of helicoidal flat surfaces in S3 in terms of their first and second fundamental](https://reader035.vdocument.in/reader035/viewer/2022071607/6145104034130627ed50bf41/html5/thumbnails/33.jpg)
The Bianchi-Spivak representation
f : M → S3 flat isometric immersion,
Gauss equation⇒ Kext = −1
There exist Tschebycheff coordinates around every point. Wecan choose local coordinates (u, v) such that
I = du2 + 2 cosωdudv + dv2,
II = 2 sinωdudv .(3)
The angle function satisfies
0 < ω < π
ωuv = 0
The aim here is to characterize the flat surfaces when ω islinear, i.e.,
ω(u, v) = ω1(u) + ω2(v) = λ1u + λ2v + λ3, λi ∈ R.
Fernando Manfio Helicoidal flat surfaces in S3
![Page 34: Helicoidal flat surfaces in S3 - Universidad de Granadarcamino/meetingcmc/manfio.pdfAim Classification of helicoidal flat surfaces in S3 in terms of their first and second fundamental](https://reader035.vdocument.in/reader035/viewer/2022071607/6145104034130627ed50bf41/html5/thumbnails/34.jpg)
The Bianchi-Spivak representation
f : M → S3 flat isometric immersion,
Gauss equation⇒ Kext = −1
There exist Tschebycheff coordinates around every point. Wecan choose local coordinates (u, v) such that
I = du2 + 2 cosωdudv + dv2,
II = 2 sinωdudv .(3)
The angle function satisfies
0 < ω < π
ωuv = 0
The aim here is to characterize the flat surfaces when ω islinear, i.e.,
ω(u, v) = ω1(u) + ω2(v) = λ1u + λ2v + λ3, λi ∈ R.
Fernando Manfio Helicoidal flat surfaces in S3
![Page 35: Helicoidal flat surfaces in S3 - Universidad de Granadarcamino/meetingcmc/manfio.pdfAim Classification of helicoidal flat surfaces in S3 in terms of their first and second fundamental](https://reader035.vdocument.in/reader035/viewer/2022071607/6145104034130627ed50bf41/html5/thumbnails/35.jpg)
The Bianchi-Spivak representation
f : M → S3 flat isometric immersion,
Gauss equation⇒ Kext = −1
There exist Tschebycheff coordinates around every point. Wecan choose local coordinates (u, v) such that
I = du2 + 2 cosωdudv + dv2,
II = 2 sinωdudv .(3)
The angle function satisfies
0 < ω < π
ωuv = 0
The aim here is to characterize the flat surfaces when ω islinear, i.e.,
ω(u, v) = ω1(u) + ω2(v) = λ1u + λ2v + λ3, λi ∈ R.
Fernando Manfio Helicoidal flat surfaces in S3
![Page 36: Helicoidal flat surfaces in S3 - Universidad de Granadarcamino/meetingcmc/manfio.pdfAim Classification of helicoidal flat surfaces in S3 in terms of their first and second fundamental](https://reader035.vdocument.in/reader035/viewer/2022071607/6145104034130627ed50bf41/html5/thumbnails/36.jpg)
The Bianchi-Spivak representation
f : M → S3 flat isometric immersion,
Gauss equation⇒ Kext = −1
There exist Tschebycheff coordinates around every point. Wecan choose local coordinates (u, v) such that
I = du2 + 2 cosωdudv + dv2,
II = 2 sinωdudv .(3)
The angle function satisfies
0 < ω < π
ωuv = 0
The aim here is to characterize the flat surfaces when ω islinear, i.e.,
ω(u, v) = ω1(u) + ω2(v) = λ1u + λ2v + λ3, λi ∈ R.
Fernando Manfio Helicoidal flat surfaces in S3
![Page 37: Helicoidal flat surfaces in S3 - Universidad de Granadarcamino/meetingcmc/manfio.pdfAim Classification of helicoidal flat surfaces in S3 in terms of their first and second fundamental](https://reader035.vdocument.in/reader035/viewer/2022071607/6145104034130627ed50bf41/html5/thumbnails/37.jpg)
The Bianchi-Spivak representation
Theorem (Bianchi-Spivak)
ca, cb : I ⊂ R→ S3 curves parametrized by arclength, withcurvatures κa and κb, and whose torsions are τa = 1 andτb = −1.
Suppose that 0 ∈ I, ca(0) = cb(0) = (1,0,0,0) andc′a(0) ∧ c′b(0) 6= 0. Then the map
X (u, v) = ca(u) · cb(v)
parameterize a flat surface in S3,the fundamental forms are as before,ω satisfies ω′1(u) = −κa(u) and ω′2(v) = κb(v).
Fernando Manfio Helicoidal flat surfaces in S3
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The Bianchi-Spivak representation
Theorem (Bianchi-Spivak)
ca, cb : I ⊂ R→ S3 curves parametrized by arclength, withcurvatures κa and κb, and whose torsions are τa = 1 andτb = −1. Suppose that 0 ∈ I, ca(0) = cb(0) = (1,0,0,0) andc′a(0) ∧ c′b(0) 6= 0.
Then the map
X (u, v) = ca(u) · cb(v)
parameterize a flat surface in S3,the fundamental forms are as before,ω satisfies ω′1(u) = −κa(u) and ω′2(v) = κb(v).
Fernando Manfio Helicoidal flat surfaces in S3
![Page 39: Helicoidal flat surfaces in S3 - Universidad de Granadarcamino/meetingcmc/manfio.pdfAim Classification of helicoidal flat surfaces in S3 in terms of their first and second fundamental](https://reader035.vdocument.in/reader035/viewer/2022071607/6145104034130627ed50bf41/html5/thumbnails/39.jpg)
The Bianchi-Spivak representation
Theorem (Bianchi-Spivak)
ca, cb : I ⊂ R→ S3 curves parametrized by arclength, withcurvatures κa and κb, and whose torsions are τa = 1 andτb = −1. Suppose that 0 ∈ I, ca(0) = cb(0) = (1,0,0,0) andc′a(0) ∧ c′b(0) 6= 0. Then the map
X (u, v) = ca(u) · cb(v)
parameterize a flat surface in S3,
the fundamental forms are as before,ω satisfies ω′1(u) = −κa(u) and ω′2(v) = κb(v).
Fernando Manfio Helicoidal flat surfaces in S3
![Page 40: Helicoidal flat surfaces in S3 - Universidad de Granadarcamino/meetingcmc/manfio.pdfAim Classification of helicoidal flat surfaces in S3 in terms of their first and second fundamental](https://reader035.vdocument.in/reader035/viewer/2022071607/6145104034130627ed50bf41/html5/thumbnails/40.jpg)
The Bianchi-Spivak representation
Theorem (Bianchi-Spivak)
ca, cb : I ⊂ R→ S3 curves parametrized by arclength, withcurvatures κa and κb, and whose torsions are τa = 1 andτb = −1. Suppose that 0 ∈ I, ca(0) = cb(0) = (1,0,0,0) andc′a(0) ∧ c′b(0) 6= 0. Then the map
X (u, v) = ca(u) · cb(v)
parameterize a flat surface in S3,the fundamental forms are as before,
ω satisfies ω′1(u) = −κa(u) and ω′2(v) = κb(v).
Fernando Manfio Helicoidal flat surfaces in S3
![Page 41: Helicoidal flat surfaces in S3 - Universidad de Granadarcamino/meetingcmc/manfio.pdfAim Classification of helicoidal flat surfaces in S3 in terms of their first and second fundamental](https://reader035.vdocument.in/reader035/viewer/2022071607/6145104034130627ed50bf41/html5/thumbnails/41.jpg)
The Bianchi-Spivak representation
Theorem (Bianchi-Spivak)
ca, cb : I ⊂ R→ S3 curves parametrized by arclength, withcurvatures κa and κb, and whose torsions are τa = 1 andτb = −1. Suppose that 0 ∈ I, ca(0) = cb(0) = (1,0,0,0) andc′a(0) ∧ c′b(0) 6= 0. Then the map
X (u, v) = ca(u) · cb(v)
parameterize a flat surface in S3,the fundamental forms are as before,ω satisfies ω′1(u) = −κa(u) and ω′2(v) = κb(v).
Fernando Manfio Helicoidal flat surfaces in S3
![Page 42: Helicoidal flat surfaces in S3 - Universidad de Granadarcamino/meetingcmc/manfio.pdfAim Classification of helicoidal flat surfaces in S3 in terms of their first and second fundamental](https://reader035.vdocument.in/reader035/viewer/2022071607/6145104034130627ed50bf41/html5/thumbnails/42.jpg)
Given r > 1, consider the curve γr : R→ S3 (base curve) givenby
γr (u) =1√
1 + r2
(r cos
ur, r sin
ur, cos ru, sin ru
).
We have
κ =r2 − 1
rand τ2 = 1.
Consider now
ca(u) =1√
1 + a2(a,0,−1,0) · γa(u),
cb(v) =1√
1 + b2T (γb(v)) · (b,0,0,−1),
where
T =
1 0 0 00 1 0 00 0 0 10 0 1 0
.
Fernando Manfio Helicoidal flat surfaces in S3
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Given r > 1, consider the curve γr : R→ S3 (base curve) givenby
γr (u) =1√
1 + r2
(r cos
ur, r sin
ur, cos ru, sin ru
).
We have
κ =r2 − 1
rand τ2 = 1.
Consider now
ca(u) =1√
1 + a2(a,0,−1,0) · γa(u),
cb(v) =1√
1 + b2T (γb(v)) · (b,0,0,−1),
where
T =
1 0 0 00 1 0 00 0 0 10 0 1 0
.
Fernando Manfio Helicoidal flat surfaces in S3
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Given r > 1, consider the curve γr : R→ S3 (base curve) givenby
γr (u) =1√
1 + r2
(r cos
ur, r sin
ur, cos ru, sin ru
).
We have
κ =r2 − 1
rand τ2 = 1.
Consider now
ca(u) =1√
1 + a2(a,0,−1,0) · γa(u),
cb(v) =1√
1 + b2T (γb(v)) · (b,0,0,−1),
where
T =
1 0 0 00 1 0 00 0 0 10 0 1 0
.
Fernando Manfio Helicoidal flat surfaces in S3
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Theorem 1The map X (u, v) = ca(u) · cb(v) is a parametrization of a flatsurface in S3, whose the fundamental forms are given by
I = du2 + 2 cos((
1−a2
a
)u +
(b2−1
b
)v + c
)dudv + dv2,
II = 2 sin((
1−a2
a
)u +
(b2−1
b
)v + c
)dudv .
Moreover, X is invariant under helicoidal motions.
Proof: X (u, v) can be written as
X (u, v) = ga · Y (u, v) · gb,
wherega =
1√1 + a2
(a,0,−1,0),
gb =1√
1 + b2(b,0,0,−1),
Y (u, v) = γa(u) · T (γb(v)).
Fernando Manfio Helicoidal flat surfaces in S3
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Theorem 1The map X (u, v) = ca(u) · cb(v) is a parametrization of a flatsurface in S3, whose the fundamental forms are given by
I = du2 + 2 cos((
1−a2
a
)u +
(b2−1
b
)v + c
)dudv + dv2,
II = 2 sin((
1−a2
a
)u +
(b2−1
b
)v + c
)dudv .
Moreover, X is invariant under helicoidal motions.
Proof: X (u, v) can be written as
X (u, v) = ga · Y (u, v) · gb,
wherega =
1√1 + a2
(a,0,−1,0),
gb =1√
1 + b2(b,0,0,−1),
Y (u, v) = γa(u) · T (γb(v)).
Fernando Manfio Helicoidal flat surfaces in S3
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Theorem 1The map X (u, v) = ca(u) · cb(v) is a parametrization of a flatsurface in S3, whose the fundamental forms are given by
I = du2 + 2 cos((
1−a2
a
)u +
(b2−1
b
)v + c
)dudv + dv2,
II = 2 sin((
1−a2
a
)u +
(b2−1
b
)v + c
)dudv .
Moreover, X is invariant under helicoidal motions.
Proof: X (u, v) can be written as
X (u, v) = ga · Y (u, v) · gb,
wherega =
1√1 + a2
(a,0,−1,0),
gb =1√
1 + b2(b,0,0,−1),
Y (u, v) = γa(u) · T (γb(v)).
Fernando Manfio Helicoidal flat surfaces in S3
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Theorem 1The map X (u, v) = ca(u) · cb(v) is a parametrization of a flatsurface in S3, whose the fundamental forms are given by
I = du2 + 2 cos((
1−a2
a
)u +
(b2−1
b
)v + c
)dudv + dv2,
II = 2 sin((
1−a2
a
)u +
(b2−1
b
)v + c
)dudv .
Moreover, X is invariant under helicoidal motions.
Proof: X (u, v) can be written as
X (u, v) = ga · Y (u, v) · gb,
wherega =
1√1 + a2
(a,0,−1,0),
gb =1√
1 + b2(b,0,0,−1),
Y (u, v) = γa(u) · T (γb(v)).
Fernando Manfio Helicoidal flat surfaces in S3
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Y (u, v) is invariant by helicoidal motions if
φα,β(t) · Y (u, v) = Y(u(t), v(t)
),
where u(t) and v(t) are smooth functions.
A straightforwardcomputation shows that
u(t) = u + z(t) and v(t) = v + w(t),
where
z(t) =a(b2 − 1)a2b2 − 1
βt and w(t) =b(1− a2)
a2b2 − 1βt ,
with
α =b2 − a2
a2b2 − 1β.
Fernando Manfio Helicoidal flat surfaces in S3
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Y (u, v) is invariant by helicoidal motions if
φα,β(t) · Y (u, v) = Y(u(t), v(t)
),
where u(t) and v(t) are smooth functions. A straightforwardcomputation shows that
u(t) = u + z(t) and v(t) = v + w(t),
where
z(t) =a(b2 − 1)a2b2 − 1
βt and w(t) =b(1− a2)
a2b2 − 1βt ,
with
α =b2 − a2
a2b2 − 1β.
Fernando Manfio Helicoidal flat surfaces in S3
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Constant angle surfaces
For the Hopf map h : S3 → S2, consider the orthogonal basis:
E1(z,w) = (iz, iw), E2(z,w) = (−iw , iz), E3(z,w) = (−w , z).
E1 is vertical (Hopf vector field) and E2, E3 are horizontal.
Definition
A constant angle surface in S3 is a surface whose its unitnormal vector field makes a constant angle with E1.
Proposition 2
Let M be a helicoidal surface in S3, parametrized as before.Then, M is flat if and only if it is a constant angle surface.
Proof: It is an application of the preview characterization of flatsurfaces in S3 (Proposition 1).
Fernando Manfio Helicoidal flat surfaces in S3
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Constant angle surfaces
For the Hopf map h : S3 → S2, consider the orthogonal basis:
E1(z,w) = (iz, iw), E2(z,w) = (−iw , iz), E3(z,w) = (−w , z).
E1 is vertical (Hopf vector field) and E2, E3 are horizontal.
Definition
A constant angle surface in S3 is a surface whose its unitnormal vector field makes a constant angle with E1.
Proposition 2
Let M be a helicoidal surface in S3, parametrized as before.Then, M is flat if and only if it is a constant angle surface.
Proof: It is an application of the preview characterization of flatsurfaces in S3 (Proposition 1).
Fernando Manfio Helicoidal flat surfaces in S3
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Constant angle surfaces
For the Hopf map h : S3 → S2, consider the orthogonal basis:
E1(z,w) = (iz, iw), E2(z,w) = (−iw , iz), E3(z,w) = (−w , z).
E1 is vertical (Hopf vector field) and E2, E3 are horizontal.
Definition
A constant angle surface in S3 is a surface whose its unitnormal vector field makes a constant angle with E1.
Proposition 2
Let M be a helicoidal surface in S3, parametrized as before.Then, M is flat if and only if it is a constant angle surface.
Proof: It is an application of the preview characterization of flatsurfaces in S3 (Proposition 1).
Fernando Manfio Helicoidal flat surfaces in S3
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Constant angle surfaces
For the Hopf map h : S3 → S2, consider the orthogonal basis:
E1(z,w) = (iz, iw), E2(z,w) = (−iw , iz), E3(z,w) = (−w , z).
E1 is vertical (Hopf vector field) and E2, E3 are horizontal.
Definition
A constant angle surface in S3 is a surface whose its unitnormal vector field makes a constant angle with E1.
Proposition 2
Let M be a helicoidal surface in S3, parametrized as before.Then, M is flat if and only if it is a constant angle surface.
Proof: It is an application of the preview characterization of flatsurfaces in S3 (Proposition 1).
Fernando Manfio Helicoidal flat surfaces in S3
![Page 55: Helicoidal flat surfaces in S3 - Universidad de Granadarcamino/meetingcmc/manfio.pdfAim Classification of helicoidal flat surfaces in S3 in terms of their first and second fundamental](https://reader035.vdocument.in/reader035/viewer/2022071607/6145104034130627ed50bf41/html5/thumbnails/55.jpg)
Constant angle surfaces
For the Hopf map h : S3 → S2, consider the orthogonal basis:
E1(z,w) = (iz, iw), E2(z,w) = (−iw , iz), E3(z,w) = (−w , z).
E1 is vertical (Hopf vector field) and E2, E3 are horizontal.
Definition
A constant angle surface in S3 is a surface whose its unitnormal vector field makes a constant angle with E1.
Proposition 2
Let M be a helicoidal surface in S3, parametrized as before.Then, M is flat if and only if it is a constant angle surface.
Proof: It is an application of the preview characterization of flatsurfaces in S3 (Proposition 1).
Fernando Manfio Helicoidal flat surfaces in S3
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Constant angle surfaces
For the Hopf map h : S3 → S2, consider the orthogonal basis:
E1(z,w) = (iz, iw), E2(z,w) = (−iw , iz), E3(z,w) = (−w , z).
E1 is vertical (Hopf vector field) and E2, E3 are horizontal.
Definition
A constant angle surface in S3 is a surface whose its unitnormal vector field makes a constant angle with E1.
Proposition 2
Let M be a helicoidal surface in S3, parametrized as before.Then, M is flat if and only if it is a constant angle surface.
Proof: It is an application of the preview characterization of flatsurfaces in S3 (Proposition 1).
Fernando Manfio Helicoidal flat surfaces in S3
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Theorem 2
Let M be a helicoidal flat surface in S3. Then M admits a localparametrization such that the fundamental forms are given asbefore and ω is a linear function.
Proof: Consider the unit normal vector field N associated tothe local parametrization X of M given in (1).
Proposition 2⇒ M is a constant angle surface.
Remark:Montaldo, Onnis, 2014:Characterization of constant angle surfaces in the Bergersphere: such surfaces are determined by a 1-parameterfamily of isometries of the Berger sphere and by ageodesic of a 2-torus in S3.
Fernando Manfio Helicoidal flat surfaces in S3
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Theorem 2
Let M be a helicoidal flat surface in S3. Then M admits a localparametrization such that the fundamental forms are given asbefore and ω is a linear function.
Proof: Consider the unit normal vector field N associated tothe local parametrization X of M given in (1).
Proposition 2⇒ M is a constant angle surface.
Remark:Montaldo, Onnis, 2014:Characterization of constant angle surfaces in the Bergersphere: such surfaces are determined by a 1-parameterfamily of isometries of the Berger sphere and by ageodesic of a 2-torus in S3.
Fernando Manfio Helicoidal flat surfaces in S3
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Theorem 2
Let M be a helicoidal flat surface in S3. Then M admits a localparametrization such that the fundamental forms are given asbefore and ω is a linear function.
Proof: Consider the unit normal vector field N associated tothe local parametrization X of M given in (1).
Proposition 2⇒ M is a constant angle surface.
Remark:Montaldo, Onnis, 2014:Characterization of constant angle surfaces in the Bergersphere: such surfaces are determined by a 1-parameterfamily of isometries of the Berger sphere and by ageodesic of a 2-torus in S3.
Fernando Manfio Helicoidal flat surfaces in S3
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Theorem 2
Let M be a helicoidal flat surface in S3. Then M admits a localparametrization such that the fundamental forms are given asbefore and ω is a linear function.
Proof: Consider the unit normal vector field N associated tothe local parametrization X of M given in (1).
Proposition 2⇒ M is a constant angle surface.
Remark:Montaldo, Onnis, 2014:Characterization of constant angle surfaces in the Bergersphere: such surfaces are determined by a 1-parameterfamily of isometries of the Berger sphere and by ageodesic of a 2-torus in S3.
Fernando Manfio Helicoidal flat surfaces in S3
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Theorem 2
Let M be a helicoidal flat surface in S3. Then M admits a localparametrization such that the fundamental forms are given asbefore and ω is a linear function.
Proof: Consider the unit normal vector field N associated tothe local parametrization X of M given in (1).
Proposition 2⇒ M is a constant angle surface.
Montaldo, Onnis, 2014:Characterization of constant angle surfaces in the Bergersphere: such surfaces are determined by a 1-parameterfamily of isometries of the Berger sphere and by ageodesic of a 2-torus in S3.
Given a number ε > 0, the Berger sphere S3ε is defined as the
sphere S3 endowed with the metric
〈X ,Y 〉ε = 〈X ,Y 〉+ (ε2 − 1)〈X ,E1〉〈Y ,E1〉.Fernando Manfio Helicoidal flat surfaces in S3
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Using the Montaldo-Onnis characterization, there exists a localparametrization F (u, v) of M given by
F (u, v) = A(v)b(u),
where
b(u) =(√
c1 cos(α1u),√
c1 sin(α1u),√
c2 cos(α2u),√
c2 sin(α2u))
is a geodesic curve in the torus S1(√
c1)× S1(√
c2),
with
c1,2 =12∓ε cos ν
2√
B, α1 =
2Bε
c2, α2 =2Bε
c1, B = 1+(ε2−1) cos2 ν,
and A(v) = A(ξ, ξ1, ξ2, ξ3)(v) is a 1-parameter family of 4× 4orthogonal matrices commuting with a complex structure of R4,ξ is a constant and the functions ξi(v), 1 ≤ i ≤ 3, satisfy
cos2(ξ1(v))ξ′2(v)− sin2(ξ1(v))ξ′3(v) = 0. (4)
Fernando Manfio Helicoidal flat surfaces in S3
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Using the Montaldo-Onnis characterization, there exists a localparametrization F (u, v) of M given by
F (u, v) = A(v)b(u),
where
b(u) =(√
c1 cos(α1u),√
c1 sin(α1u),√
c2 cos(α2u),√
c2 sin(α2u))
is a geodesic curve in the torus S1(√
c1)× S1(√
c2), with
c1,2 =12∓ε cos ν
2√
B, α1 =
2Bε
c2, α2 =2Bε
c1, B = 1+(ε2−1) cos2 ν,
and A(v) = A(ξ, ξ1, ξ2, ξ3)(v) is a 1-parameter family of 4× 4orthogonal matrices commuting with a complex structure of R4,ξ is a constant and the functions ξi(v), 1 ≤ i ≤ 3, satisfy
cos2(ξ1(v))ξ′2(v)− sin2(ξ1(v))ξ′3(v) = 0. (4)
Fernando Manfio Helicoidal flat surfaces in S3
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Using the Montaldo-Onnis characterization, there exists a localparametrization F (u, v) of M given by
F (u, v) = A(v)b(u),
where
b(u) =(√
c1 cos(α1u),√
c1 sin(α1u),√
c2 cos(α2u),√
c2 sin(α2u))
is a geodesic curve in the torus S1(√
c1)× S1(√
c2), with
c1,2 =12∓ε cos ν
2√
B, α1 =
2Bε
c2, α2 =2Bε
c1, B = 1+(ε2−1) cos2 ν,
and A(v) = A(ξ, ξ1, ξ2, ξ3)(v) is a 1-parameter family of 4× 4orthogonal matrices commuting with a complex structure of R4,ξ is a constant and the functions ξi(v), 1 ≤ i ≤ 3, satisfy
cos2(ξ1(v))ξ′2(v)− sin2(ξ1(v))ξ′3(v) = 0. (4)
Fernando Manfio Helicoidal flat surfaces in S3
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Taking ε = 1, we can reparametrize the curve b such that thenew curve is a base curve γa:
writing s = 2√
c1c2, we have
b(s) =1√
1 + a2
(a cos
sa,a sin
sa, cos(as), sin(as)
),
where a =√
c1/c2.
Fernando Manfio Helicoidal flat surfaces in S3
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Taking ε = 1, we can reparametrize the curve b such that thenew curve is a base curve γa: writing s = 2
√c1c2, we have
b(s) =1√
1 + a2
(a cos
sa,a sin
sa, cos(as), sin(as)
),
where a =√
c1/c2.
Fernando Manfio Helicoidal flat surfaces in S3
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The matrix
A(v) = A(ξ, ξ1, ξ2, ξ3)(v) =
α(v)
J1α(v)cos ξJ2α(v) + sin ξJ3α(v)− cos ξJ3α(v) + sin ξJ2α(v)
,
where
α(v) = (cos ξ1 cos ξ2,− cos ξ1 sin ξ2, sin ξ1 cos ξ3,− sin ξ1 sin ξ3)
and J1, J2 and J3 are orthogonal matrices given explicitly, canbe written as
A(v) = A(ξ) · A(v),where
A(ξ) =
1 0 0 00 1 0 00 0 sin ξ cos ξ0 0 − cos ξ sin ξ
and A(v) =
α(v)
J1α(v)J3α(v)J2α(v)
.
A(v) · b(s) = A(ξ)X (v , s).
Fernando Manfio Helicoidal flat surfaces in S3
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The matrix
A(v) = A(ξ, ξ1, ξ2, ξ3)(v) =
α(v)
J1α(v)cos ξJ2α(v) + sin ξJ3α(v)− cos ξJ3α(v) + sin ξJ2α(v)
,
where
α(v) = (cos ξ1 cos ξ2,− cos ξ1 sin ξ2, sin ξ1 cos ξ3,− sin ξ1 sin ξ3)
and J1, J2 and J3 are orthogonal matrices given explicitly, canbe written as
A(v) = A(ξ) · A(v),where
A(ξ) =
1 0 0 00 1 0 00 0 sin ξ cos ξ0 0 − cos ξ sin ξ
and A(v) =
α(v)
J1α(v)J3α(v)J2α(v)
.
A(v) · b(s) = A(ξ)X (v , s).
Fernando Manfio Helicoidal flat surfaces in S3
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X (v , s) can be written as
X (v , s) =1√
1 + a2(x1, x2, x3, x4),
with
x1 = a cos ξ1 cos(s
a+ ξ2
)+ sin ξ1 cos(as + ξ3),
x2 = a cos ξ1 sin(s
a+ ξ2
)+ sin ξ1 sin(as + ξ3),
x3 = −a sin ξ1 cos(s
a− ξ3
)+ cos ξ1 cos(as − ξ2),
x4 = −a sin ξ1 sin(s
a− ξ3
)+ cos ξ1 sin(as − ξ3).
Fernando Manfio Helicoidal flat surfaces in S3
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x1 = a cos ξ1 cos(s
a+ ξ2
)+ sin ξ1 cos(as + ξ3),
x2 = a cos ξ1 sin(s
a+ ξ2
)+ sin ξ1 sin(as + ξ3),
x3 = −a sin ξ1 cos(s
a− ξ3
)+ cos ξ1 cos(as − ξ2),
x4 = −a sin ξ1 sin(s
a− ξ3
)+ cos ξ1 sin(as − ξ3).
On the other hand,
φα,β(t) · X (v , s) =1√
1 + a2(z1, z2, z3, z4),
where
z1 = a cos ξ1 cos(s
a+ ξ2 + αt
)+ sin ξ1 cos (as + ξ3 + αt) ,
z2 = a cos ξ1 sin(s
a+ ξ2 + αt
)+ sin ξ1 sin (as + ξ3 + αt) ,
z3 = −a sin ξ1 cos(s
a− ξ3 + βt
)+ cos ξ1 cos (as − ξ2 + βt) ,
z4 = −a sin ξ1 sin(s
a− ξ3 + βt
)+ cos ξ1 sin (as − ξ2 + βt) .
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Sketch of the proof (second part):
As the surface is helicoidal, we have
φα,β(t) · X (v , s) = X (v(t), s(t)),
for some smooth functions v(t) and s(t). Comparing theexpressions in the preview systems, we have:
the surface is helicoidal⇔ dξ1
dv· dv
dt= 0.
(i) v(t) constant⇒ a2 = 1, contradiction.
(ii) ξ1(v) constant. In this case, v(t) and s(t) are given by
s(t) = s +a(b2 − 1)a2b2 − 1
βt and v(t) = v +b(1− a2)
a2b2 − 1βt ,
that coincide with the expressions obtained in Theorem 1.
Fernando Manfio Helicoidal flat surfaces in S3
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Sketch of the proof (second part):
As the surface is helicoidal, we have
φα,β(t) · X (v , s) = X (v(t), s(t)),
for some smooth functions v(t) and s(t).
Comparing theexpressions in the preview systems, we have:
the surface is helicoidal⇔ dξ1
dv· dv
dt= 0.
(i) v(t) constant⇒ a2 = 1, contradiction.
(ii) ξ1(v) constant. In this case, v(t) and s(t) are given by
s(t) = s +a(b2 − 1)a2b2 − 1
βt and v(t) = v +b(1− a2)
a2b2 − 1βt ,
that coincide with the expressions obtained in Theorem 1.
Fernando Manfio Helicoidal flat surfaces in S3
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Sketch of the proof (second part):
As the surface is helicoidal, we have
φα,β(t) · X (v , s) = X (v(t), s(t)),
for some smooth functions v(t) and s(t). Comparing theexpressions in the preview systems, we have:
the surface is helicoidal⇔ dξ1
dv· dv
dt= 0.
(i) v(t) constant⇒ a2 = 1, contradiction.
(ii) ξ1(v) constant. In this case, v(t) and s(t) are given by
s(t) = s +a(b2 − 1)a2b2 − 1
βt and v(t) = v +b(1− a2)
a2b2 − 1βt ,
that coincide with the expressions obtained in Theorem 1.
Fernando Manfio Helicoidal flat surfaces in S3
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Sketch of the proof (second part):
As the surface is helicoidal, we have
φα,β(t) · X (v , s) = X (v(t), s(t)),
for some smooth functions v(t) and s(t). Comparing theexpressions in the preview systems, we have:
the surface is helicoidal⇔ dξ1
dv· dv
dt= 0.
(i) v(t) constant
⇒ a2 = 1, contradiction.
(ii) ξ1(v) constant. In this case, v(t) and s(t) are given by
s(t) = s +a(b2 − 1)a2b2 − 1
βt and v(t) = v +b(1− a2)
a2b2 − 1βt ,
that coincide with the expressions obtained in Theorem 1.
Fernando Manfio Helicoidal flat surfaces in S3
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Sketch of the proof (second part):
As the surface is helicoidal, we have
φα,β(t) · X (v , s) = X (v(t), s(t)),
for some smooth functions v(t) and s(t). Comparing theexpressions in the preview systems, we have:
the surface is helicoidal⇔ dξ1
dv· dv
dt= 0.
(i) v(t) constant⇒ a2 = 1, contradiction.
(ii) ξ1(v) constant. In this case, v(t) and s(t) are given by
s(t) = s +a(b2 − 1)a2b2 − 1
βt and v(t) = v +b(1− a2)
a2b2 − 1βt ,
that coincide with the expressions obtained in Theorem 1.
Fernando Manfio Helicoidal flat surfaces in S3
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Sketch of the proof (second part):
As the surface is helicoidal, we have
φα,β(t) · X (v , s) = X (v(t), s(t)),
for some smooth functions v(t) and s(t). Comparing theexpressions in the preview systems, we have:
the surface is helicoidal⇔ dξ1
dv· dv
dt= 0.
(i) v(t) constant⇒ a2 = 1, contradiction.
(ii) ξ1(v) constant.
In this case, v(t) and s(t) are given by
s(t) = s +a(b2 − 1)a2b2 − 1
βt and v(t) = v +b(1− a2)
a2b2 − 1βt ,
that coincide with the expressions obtained in Theorem 1.
Fernando Manfio Helicoidal flat surfaces in S3
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Sketch of the proof (second part):
As the surface is helicoidal, we have
φα,β(t) · X (v , s) = X (v(t), s(t)),
for some smooth functions v(t) and s(t). Comparing theexpressions in the preview systems, we have:
the surface is helicoidal⇔ dξ1
dv· dv
dt= 0.
(i) v(t) constant⇒ a2 = 1, contradiction.
(ii) ξ1(v) constant. In this case, v(t) and s(t) are given by
s(t) = s +a(b2 − 1)a2b2 − 1
βt and v(t) = v +b(1− a2)
a2b2 − 1βt ,
that coincide with the expressions obtained in Theorem 1.
Fernando Manfio Helicoidal flat surfaces in S3
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Figura: a=2 and b=3.
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Figura: a=2 and b=2.
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Figura: a=√
2 and b=3.
Fernando Manfio Helicoidal flat surfaces in S3