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<metadata xmlns:xsi="http://www.w3.org/2001/XMLSchema-instance" xmlns:dc="http://purl.org/dc/elements/1.1/"><dc:title>Controlled surgery and ▫$\mathbb{L}$▫-homology</dc:title><dc:creator>Hegenbarth,	Friedrich	(Avtor)
	</dc:creator><dc:creator>Repovš,	Dušan	(Avtor)
	</dc:creator><dc:subject>generalized manifold</dc:subject><dc:subject>resolution obstruction</dc:subject><dc:subject>controlled surgery</dc:subject><dc:subject>controlled structure set</dc:subject><dc:subject>▫$\mathbb{L}_q$▫-surgery</dc:subject><dc:subject>Wall obstruction</dc:subject><dc:description>This paper presents an alternative approach to controlled surgery obstructions. The obstruction for a degree one normal map ▫$(f,b) \colon M^n \to X^n$▫ with control map ▫$q \colon X^n \to B$▫ to complete controlled surgery is an element ▫$\sigma^c (f,b) \in H_n(B, \mathbb{L})$▫, where ▫$M^n, \, X^n$▫ are topological manifolds of dimension ▫$n \ge 5$▫. Our proof uses essentially the geometrically defined ▫$\mathbb{L}$▫-spectrum as described by Nicas (going back to Quinn) and some well-known homotopy theory. We also outline the construction of the algebraically defined obstruction, and we explicitly describe the assembly map ▫$H_n(B,L) \to L_n(\pi_1(B))$▫ in terms of forms in the case ▫$n \equiv 0(4)$▫. Finally, we explicitly determine the canonical map ▫$H_n(B,L) \to H_n(B, \, L_0)$▫.</dc:description><dc:date>2019</dc:date><dc:date>2019-07-25 07:42:04</dc:date><dc:type>Članek v reviji</dc:type><dc:identifier>108784</dc:identifier><dc:identifier>UDK: 515.1</dc:identifier><dc:identifier>ISSN pri članku: 1660-5446</dc:identifier><dc:identifier>DOI: 10.1007/s00009-019-1354-6</dc:identifier><dc:identifier>COBISS_ID: 18630745</dc:identifier><dc:identifier>OceCobissID: 13561433</dc:identifier><dc:language>sl</dc:language></metadata>
