Description: Lemma for trlsegvdeg . (Contributed by AV, 21-Feb-2021)
Ref | Expression | ||
---|---|---|---|
Hypotheses | trlsegvdeg.v | |- V = ( Vtx ` G ) |
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trlsegvdeg.i | |- I = ( iEdg ` G ) |
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trlsegvdeg.f | |- ( ph -> Fun I ) |
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trlsegvdeg.n | |- ( ph -> N e. ( 0 ..^ ( # ` F ) ) ) |
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trlsegvdeg.u | |- ( ph -> U e. V ) |
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trlsegvdeg.w | |- ( ph -> F ( Trails ` G ) P ) |
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trlsegvdeg.vx | |- ( ph -> ( Vtx ` X ) = V ) |
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trlsegvdeg.vy | |- ( ph -> ( Vtx ` Y ) = V ) |
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trlsegvdeg.vz | |- ( ph -> ( Vtx ` Z ) = V ) |
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trlsegvdeg.ix | |- ( ph -> ( iEdg ` X ) = ( I |` ( F " ( 0 ..^ N ) ) ) ) |
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trlsegvdeg.iy | |- ( ph -> ( iEdg ` Y ) = { <. ( F ` N ) , ( I ` ( F ` N ) ) >. } ) |
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trlsegvdeg.iz | |- ( ph -> ( iEdg ` Z ) = ( I |` ( F " ( 0 ... N ) ) ) ) |
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Assertion | trlsegvdeglem7 | |- ( ph -> dom ( iEdg ` Y ) e. Fin ) |
Step | Hyp | Ref | Expression |
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1 | trlsegvdeg.v | |- V = ( Vtx ` G ) |
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2 | trlsegvdeg.i | |- I = ( iEdg ` G ) |
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3 | trlsegvdeg.f | |- ( ph -> Fun I ) |
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4 | trlsegvdeg.n | |- ( ph -> N e. ( 0 ..^ ( # ` F ) ) ) |
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5 | trlsegvdeg.u | |- ( ph -> U e. V ) |
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6 | trlsegvdeg.w | |- ( ph -> F ( Trails ` G ) P ) |
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7 | trlsegvdeg.vx | |- ( ph -> ( Vtx ` X ) = V ) |
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8 | trlsegvdeg.vy | |- ( ph -> ( Vtx ` Y ) = V ) |
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9 | trlsegvdeg.vz | |- ( ph -> ( Vtx ` Z ) = V ) |
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10 | trlsegvdeg.ix | |- ( ph -> ( iEdg ` X ) = ( I |` ( F " ( 0 ..^ N ) ) ) ) |
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11 | trlsegvdeg.iy | |- ( ph -> ( iEdg ` Y ) = { <. ( F ` N ) , ( I ` ( F ` N ) ) >. } ) |
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12 | trlsegvdeg.iz | |- ( ph -> ( iEdg ` Z ) = ( I |` ( F " ( 0 ... N ) ) ) ) |
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13 | 1 2 3 4 5 6 7 8 9 10 11 12 | trlsegvdeglem5 | |- ( ph -> dom ( iEdg ` Y ) = { ( F ` N ) } ) |
14 | snfi | |- { ( F ` N ) } e. Fin |
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15 | 13 14 | eqeltrdi | |- ( ph -> dom ( iEdg ` Y ) e. Fin ) |