Notes:Homology/Real projective plane

[ilmath]\mathbb{RP}^2_A[/ilmath]

Set up 1, denoted [ilmath]\mathbb{RP}^2_A[/ilmath]
[ilmath]\xymatrix{ v\ \bullet \ar@/^.75pc/@{<-}[rr]^a \ar@/_.75pc/[rr]_a & & \bullet\ v }[/ilmath] Try and consider this as a solid disk called [ilmath]P[/ilmath] orientated clockwise (so the boundary of [ilmath]P[/ilmath] is [ilmath]a+a[/ilmath])

The chain complexes are [ilmath]\xymatrix{ 0 \ar[r]^{\partial_3} & C_2 \ar[r]^{\partial_2} \ar@2{->}[d] & C_1 \ar[r]^{\partial_1} \ar@2{->}[d] & C_1 \ar[r]^{\partial_0=0} \ar@2{->}[d] & 0 \\ & \langle P\rangle\cong\mathbb{Z}^1 & \langle a\rangle\cong\mathbb{Z}^1 & \langle v\rangle\cong\mathbb{Z}^1 }[/ilmath]

with:

[ilmath]\partial_2(P)=a+a=2a[/ilmath]
[ilmath]\partial_1(a)=v-v=0[/ilmath]
[ilmath]\partial_0(v)=0[/ilmath]

On paper I ended up with:

[ilmath]H_0\cong\mathbb{Z}[/ilmath]
[ilmath]H_1\cong\frac{\mathbb{Z} }{2\mathbb{Z} }[/ilmath]
[ilmath]H_2\cong 0[/ilmath]

Notes:Homology/Real projective plane

[ilmath]\mathbb{RP}^2_A[/ilmath]

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