Hostname: page-component-cd9895bd7-p9bg8 Total loading time: 0 Render date: 2024-12-22T23:59:01.859Z Has data issue: false hasContentIssue false

Fixed point sets and the fundamental group II: Euler characteristics

Published online by Cambridge University Press:  10 October 2023

Sylvain Cappell
Affiliation:
Courant Institute of Mathematical Sciences, New York University, New York, NY, USA ([email protected])
Shmuel Weinberger
Affiliation:
University of Chicago, Chicago, IL, USA ([email protected])
Min Yan
Affiliation:
Hong Kong University of Science and Technology, Hong Kong, People's Republic of China ([email protected])
Rights & Permissions [Opens in a new window]

Abstract

For a finite group $G$ of not prime power order, Oliver showed that the obstruction for a finite CW-complex $F$ to be the fixed point set of a contractible finite $G$-CW-complex is determined by the Euler characteristic $\chi (F)$. (He also has similar results for compact Lie group actions.) We show that the analogous problem for $F$ to be the fixed point set of a finite $G$-CW-complex of some given homotopy type is still determined by the Euler characteristic. Using trace maps on $K_0$ [2, 7, 18], we also see that there are interesting roles for the fundamental group and the component structure of the fixed point set.

Type
Research Article
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (https://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution, and reproduction in any medium, provided the original work is properly cited.
Copyright
Copyright © The Author(s), 2023. Published by Cambridge University Press on behalf of The Royal Society of Edinburgh

1. Introduction

The classical problem of what are the possible homotopy types of fixed sets of cellular group actions on contractible finite CW-complexes was solved by L. Jones [Reference Jones8] in the case of $p$-groups, and R. Oliver [Reference Oliver10] for non-$p$-groups. Our aim in this paper is to put the work of Oliver into a more general context, exposing where the fundamental group does and where it does not play a role. The analogous generalization of Jones’ work has very different features, which we discuss in the companion paper [Reference Cappell, Weinberger and Yan4].

The following is our original motivation. Suppose $G$ is a finite group acting by isometries on a compact Riemannian manifold $X$ with non-positive curvature, and the centre of the fundamental group $\pi _1(X)$ is trivial. Then the $G$-action has a fixed point if and only if the induced homomorphism $G\to \text {Out}(\pi _1(X))$ lifts to $\text {Aut}(\pi _1(X))$. Here $\text {Out}(\pi _1(X))$ is the group of outer automorphisms, and $\text {Aut}(\pi _1(X))$ is the group of genuine automorphisms. By taking the fundamental group to be based at a fixed point, we see the lift is necessary. The sufficiency of the condition follows by considering the group $\Gamma$ of lifts of $G$ to the universal cover. Since the centre of $\pi _1(X)$ is trivial, the map $\Gamma \to G$ splits. By Cartan's fixed point theorem [Reference Bridson and Haefliger3], any finite group of isometries of a simply connected non-positively curved manifold has a fixed point.

If the action is not required to be by isometries, would the action still have a fixed point? For a $p$-group acting on a finite $K(\pi,1)$ CW-complex with centreless $\pi$, Smith theory implies that any action satisfying the lifting condition must have a fixed point.

What about actions by a non-$p$-group?

Theorem 1.1 For any finite group $G$ of not prime power order, there is a $G$-action on some compact aspherical manifold $X$, with centreless $\pi =\pi _1(X)$, such that the induced homomorphism $G\to \text {Out}(\pi _1(X))$ lifts to $\text {Aut}(\pi _1(X))$, and yet the action has no fixed point.

This result uses the method of Davis [Reference Davis5], which promotes constructions involving finite CW-complexes and compact aspherical manifolds with boundary to closed aspherical manifolds. Consequently, we were led to investigate the role of the fundamental group in generalizing the theory of Oliver. In [Reference Cappell, Weinberger and Yan4], we will see a contrastingly different role in generalizing the theory of Jones.

It would be reasonable to believe that $\pi _1(X)$ plays a role in understanding the possible fixed sets of group actions on $X$. In both [Reference Jones8, Reference Oliver10], at key points in the construction, an obstruction in $\widetilde {K}_0({\mathbb {Z}}[G])$ arises, and one would expect that for non-simply connected $X$, an analogous element of $\widetilde {K}_0({\mathbb {Z}}[\Gamma ])$ arises. However, in this paper, we shall see that the fundamental group does not intervene in this way for non-$p$-groups (though, as we shall see, it does affect the possible trade-offs between Euler characteristics of different components of fixed points). On the other hand, we shall see in [Reference Cappell, Weinberger and Yan4] that this is the case for $p$-groups.

We begin with some definitions. We say that a $G$-map $f\colon X \to Y$ between two finite $G$-CW-complexes is a pseudo-equivalence if it is an unequivariant homotopy equivalence. The pseudo-equivalence property is equivalent to requiring that the induced map $X\times EG\to Y\times EG$ on the Borel constructions is a $G$-homotopy equivalence. Note that $X\times EG\to X$ is a $G$-map and an unequivariant homotopy equivalence. However, the Borel construction is usually not a finite CW-complex, so that the map is not a pseudo-equivalence in the sense of the present paper.

A pseudo-equivalent $G$-map does not necessarily have an inverse pseudo-equivalent $G$-map. To make pseudo-equivalence into an equivalence relation, therefore, we need to allow two finite $G$-CW-complexes $X,Y$ to be pseudo-equivalent if they are related by a zig-zag sequence of pseudo-equivalent $G$-maps (all $Z_i,W_i$ are finite $G$-CW-complexes)

\[ X\xleftarrow{f_1} Z_1 \xrightarrow{g_1} W_1 \xleftarrow{f_2} Z_2 \xrightarrow{g_2} W_2 \leftarrow \cdots \to W_{n-1}\xleftarrow{f_n} Z_n \xrightarrow{g_n} Y. \]

Then for any $p$-subgroup $P$ of $G$, the Smith theory [Reference Smith17] can be applied to the fixed sets of $P$ to give $H_*(X^P;{\mathbb {F}}_p)\cong H_*(Y^P;{\mathbb {F}}_p)$. In particular, this implies that, if a $p$-group $G$ acts freely on $X$, then the $G$-action on $Y$ must also be free. If we allowed infinite CW-complexes in our definition, we could not make this assertion as $EG\to *$ would be a pseudo-equivalence.

If $G$ is not a $p$-group, however, it is still possible for $X$ to have no $G$-fixed point, and for $Y$ to have $G$-fixed point. For the case $Y$ is a single point, i.e., $X$ is contractible, Oliver [Reference Oliver10] proved the following.

Theorem (Oliver): For any finite group $G$ of not prime power order, there is a number $n(G)$, such that a contractible finite CW-complexes $F$ is (homotopy equivalent to) the fixed set of a finite contractible $G$-CW-complex, if and only if $\chi (F)=1$ mod $n(G)$.

By [Reference Oliver10, theorem 5] and the subsequent corollary, we know $n(G)=1$, i.e., there is no condition at all on $F$, if and only if $G$ is not of the form $P\lhd H\lhd G$, with $P$ and $G/H$ having prime power orders, and $H/P$ cyclic. For example, for $G$ a non-solvable group or an abelian group with at least three non-cyclic Sylow subgroups, we have $n(G)=1$.

We also know $n(G)=0$, i.e., the obstruction is exactly the Euler characteristic, if and only if $G$ has a normal subgroup $P$ of prime power order, such that $G/P$ is cyclic. In particular, a cyclic group has $n(G)=0$.

For the complete determination of $n(G)$, see [Reference Oliver12, Reference Oliver13].

The following is our extension of Oliver's theorem to general $Y$.

Theorem 1.2 Suppose $G$ is a group of not prime power order, and $Y$ is a finite $G$-CW-complex with non-empty and connected fixed set $Y^G$. Then a finite CW-complex $F$ is the fixed set of a finite $G$-CW-complex pseudo-equivalent to $Y$ if and only if $\chi (F)=\chi (Y^G)$ mod $n(G)$.

Remark 1.3 Given the Euler characteristic condition, we actually construct a finite $G$-CW-complex $X$ and a pseudo-equivalence $X\to Y$, such that $F=X^G$. In particular, there is no need to use a zig-zag sequence of maps for the pseudo-equivalence between $X$ and $Y$.

Oliver introduces another number $m(G)$. This number is the largest square-free factor of $n(G)$; it is the number for which the congruence $\chi (F) = 1$ mod $m(G)$ follows directly from the combination of the Lefshetz theorem and Smith theory. The extra divisibility by $n(G)$ in Oliver's theorem above for finite $G$-CW complexes comes from deeper algebraic $K$-theory considerations. As shown in [Reference Quinn15, § 2], this arises in answering the question about fixed sets of compact $G$-ANRs (equivariant absolute neighbourhood retracts) that are not necessarily homotopy finite.Footnote 1 The same method, combined with the arguments of the present paper, proves the $G$-ANR analogues of all our results, with $m(G)$ replacing $n(G)$. Such results are relevant to locally linear group actions on topological manifolds. The following is the $G$-ANR analogue of theorem 1.2. Of course, the statement requires us to slightly extend pseudo-equivalence to the compact $G$-ANR category.

Theorem 1.4 Suppose $G$ is a group of not prime power order, and $Y$ is a compact $G$-ANR with non-empty and connected fixed set $Y^G$. Then a finite CW-complex $F$ is the fixed set of a compact $G$-ANR pseudo-equivalent to $Y$ if and only if $\chi (F)=\chi (Y^G)$ mod $m(G)$.

An interesting class of actions is pseudo-trivial action, which means a finite $G$-CW-complex $X$ equivariantly homotopy equivalent to $X$ with trivial action. This is tantamount to saying that the G-map $X\to X/G$ splits. Any action on a contractible CW-complex is pseudo-trivial. These actions frequently arise as $G$-subspaces of more general $G$-spaces, and their analysis is important for inductive arguments. Indeed this is implicit in the proof of our theorem 1.7 below, and is also used in solving our motivating problem about aspherical manifolds.

If we apply theorem 1.2 to the case the action on $Y$ is trivial, we find that $F$ is the fixed set of a pseudo-trivial, finite $G$-CW-complex homotopy equivalent to $Y$ if and only if $\chi (F)=\chi (Y)$ mod $n(G)$.

The fundamental group does not appear in theorem 1.2. However, there is an important role for the fundamental group when $Y^G$ is not connected. The fundamental group and the action group interact as follows: As before, let $\Gamma$ be the group of liftings of $G$-actions on $Y$ to the universal cover $\widetilde {Y}$. We have an exact sequence, with some modification needed if the action is not effective [see discussion after (6.1)],

\[ 1\to \pi_1(Y) \to \Gamma\to G\to 1. \]

If $\widetilde {y}\in \widetilde {Y}$ covers $y\in Y$, then we have isomorphism of isotropy groups $\Gamma _{\widetilde {y}}\cong G_y$. For $y\in Y^G$, this gives a splitting of the exact sequence. Various choices of $\widetilde {y}$ over $y$ give a conjugacy class of splittings, and the conjugacy class depends only on the connected component of $Y^G$ containing $y$.

To see the interaction of $G$ with $\pi _1(Y)$ at the level of fixed sets, we introduce the following definition.

Definition A $G$-action on $Y$ is weakly $G$-connected if each connected component of $Y^G$ corresponds to a different conjugacy class of lifts of $G$ to $\Gamma$.

Recall that a $G$-space $Y$ is said to be $G$-connected, if $Y^H$ is non-empty and connected for every subgroup $H$ of $G$. Evidently, $G$-connected implies weakly $G$-connected, but the converse is often false. For example, a free action is weakly $G$-connected but not $G$-connected. Another example is actions by isometries on non-positively curved spaces, again by Cartan's fixed point theorem.

Theorem 1.5 Suppose $G$ is a cyclic group or more generally satisfies $n(G)=0$, $F$ is a finite CW-complex, and $Y$ is a finite $G$-CW-complex. If $Y$ is weakly $G$-connected, then a $G$-map $f\colon F\to Y$ can be extended to a pseudo-equivalence $g\colon X\to Y$, with $X$ a finite $G$-CW-complex satisfying $F=X^G$, if and only if for each connected component $C$ of $Y^G$, we have $\chi (f^{-1}(C))=\chi (C)$.

As in [Reference Cappell, Weinberger and Yan4], we call $g\colon X\to Y$ a pseudo-equivalence extension of $f\colon F\to Y$. Specifically, in such an extension, we require all spaces to be finite $G$-CW-complexes (unless otherwise stated), and $F=X^G$.

Since connected $Y^G$ implies weakly $G$-connected, theorem 1.5 generalizes theorem 1.2 in case $n(G)=0$.

The theorem allows $f^{-1}(C)=\emptyset$ for some connected components. It also allows $f^{-1}(C)$ to be disconnected for some connected component $C$. Then $X$ will no longer be weakly $G$-connected, but our weakly $G$-connected hypothesis is on $Y$. Our proof of the theorem uses the Hattori–Stallings trace [Reference Bass2, Reference Hattori7, Reference Stallings18], perhaps the most classical of the trace maps from $K$-theory to Hochschild (or even cyclic) homology.

Even without the weakly $G$-connected assumption, our methods apply to give some new constructions of actions, and some new necessary congruence conditions. In this general setting, our results can be profitably compared to earlier work of Oliver and Petrie [Reference Oliver and Petrie14] (which deals with a somewhat different problem) and Morimoto and Iizuka [Reference Morimoto and Iizuka9] (which is about pseudo-equivalence of $G$-CW-complexes with finite fundamental groups).

Theorem 1.6 Suppose $G$ is a finite group of not prime power order, and $Y$ is a finite $G$-CW-complex. Then there is a subgroup $N(Y)$ of ${\mathbb {Z}}^{\pi _0Y^G}$, such that a $G$-map $f\colon F\to Y$ from a finite CW-complex $F$ with trivial $G$-action has pseudo-equivalence extension, if and only if

\[ (\chi(f^{{-}1}(C))-\chi(C))\in N(Y). \]

For $f\colon F\to Y$ to have pseudo-equivalence extension $g\colon X\to Y$, it is necessary that the global Euler characteristic condition $\chi (F)=\chi (Y^G)$ mod $n(G)$ is satisfied. The reason is that the mapping cone $cX\cup _g Y$ of the homotopy equivalence $g$ is a contractible $G$-CW-complex with fixed set $(cX\cup _g Y)^G=cF\cup Y^G$. Then Oliver's theorem implies $\chi (cF\cup Y^G)=1+\chi (Y^G)-\chi (F)=1$ mod $n(G)$.

Conversely, the following result says that, if the local Euler characteristic condition is satisfied for each connected component of $Y^G$, then we have the pseudo-equivalence extension.

Theorem 1.7 Suppose $G$ is a group of not prime power order, $F$ is a finite CW-complex with trivial $G$-action, $Y$ is a connected finite $G$-CW-complex, and $f\colon F\to Y$ is a $G$-map. If $\chi (f^{-1}(C))=\chi (C)$ mod $n(G)$ for every connected component $C$ of $Y^G$, then $f$ has pseudo-equivalence extension.

The discussion on global versus local Euler characteristic conditions means exactly that the group $N(Y)$ introduced in theorem 1.6 satisfies 

\[ n(G){\mathbb{Z}}^A\subset N(Y) \subset \{(a_C)\in {\mathbb{Z}}^A\colon n(G)\text{ divides }\textstyle\sum a_C\},\quad A=\pi_0Y^G. \]

We note two cases in which the two bounds for $N(Y)$ coincide. If $Y^G$ is connected, then $N(Y)=n(G){\mathbb {Z}}$, and we recover theorem 1.2. If $n(G)=1$, then $N(Y)={\mathbb {Z}}^A$, which means there is no obstruction at all.

Under the condition of theorem 1.5, we know $N(Y)$ is the lower bound $n(G){\mathbb {Z}}^A$, i.e., the local Euler characteristic condition is sufficient. To get a somewhat non-trivial example where $N(Y)$ is isomorphic to the upper bound, we consider a finite contractible $G$-CW-complex $Y$, and any $G$-map $f\colon F\to Y$ satisfying the global Euler characteristic condition $\chi (F)=\chi (Y^G)=1$ mod $n(G)$. By Oliver's theory [Reference Oliver10], there is a finite contractible $G$-CW-complex $X$, such that $F=X^G$. If we extend $f\colon F\to Y$ to a $G$-map $g\colon X\to Y$, then $g$ is a pseudo-equivalence due to the contractibility of $X$ and $Y$. The extension exists as long as all the fixed sets $Y^H$ are sufficiently highly connected. There is a $G$-representation $V$, such that the representation sphere $S(V)$ has no fixed point by $G$, and is highly connected for the fixed sets of proper subgroups (see the first remark after the proof of lemma 4.2). Then $Z=Y*S(V)$ is still contractible, and satisfies $Z^G=Y^G$. Moreover, $Z$ becomes highly connected for the fixed sets of proper subgroups. The contractibility implies that the natural map $h\colon Y\to Z$ is a pseudo-equivalence. Therefore, $h\circ f\colon F\to Z$ can be extended to a pseudo-equivalent $G$-map $g\colon X\to Z$.

In general, we have not yet completely ascertained the pattern which determines where between the two given extremes $N(Y)$ actually is, although one can easily produce examples where either extreme is realized.

Remark 1.8 That being said, if $Y^G=\emptyset$, then it is impossible to construct a pseudo-equivalent action with non-empty fixed set in the context of this paper. However, using zig-zag compositions of pseudo-equivalence maps, sometimes, but not always, it is possible to get from such an action to one whose fixed set is arbitrary.

Our results about finite $G$-CW-complexes (and compact $G$-ANRs) apply to compact Lie group actions, as well. In [Reference Oliver11], Oliver extended his theorem to the case $G$ is a compact Lie group. He calls $G$ $p$-toral if the identity component $G_0$ is a torus, and $G/G_0$ is a $p$-group. This is precisely the case Smith theory applies. Then Oliver's (and Quinn's) results apply to his problem in the case when $G$ is not $p$-toral, for any prime $p$. This means two possibilities: (1) if $G/G_0$ is not of prime power order and $G_0$ is a torus, then the results for $G$ are the same as those for $G/G_0$; (2) if $G_0$ is not a torus, then we have $n(G)=1$, and there is no Euler characteristic obstruction to making fixed sets. By the direct geometric arguments in § 3 and 4, this also holds in our general setting.

The paper is organized as follows. In § 2 and 3, we prove theorem 1.7 for the case all $F_C=f^{-1}(C)$ are not empty. The case some $F_C=\emptyset$ requires separate treatment, and we prove this case in § 4. This completes the proof of theorem 1.7. Theorem 1.2 immediately follows from theorem 1.7. The special case $F_C=\emptyset$ is geometrically significant because it gives actions without fixed points. In fact, we also prove theorem 1.1 in § 4.

In § 5, we use a formal construction and theorem 1.7 to prove theorem 1.6. In § 6, we prove two results that give necessary conditions on the Euler characteristics. Theorem 6.2 is for rational pseudo-equivalence under a cyclic group action. Theorem 6.3 is for pseudo-equivalence under the action by a group satisfying $n(G)=0$. Theorem 1.5 is a consequence of the two theorems.

We would like to thank K. Pawałowski, R. Oliver and M. Morimoto for valuable conversations about this work. We would also like to thank the referee for suggesting a number of improvements to the exposition.

2. Cell-wise partition of Euler characteristic

The proof of theorem 1.7 starts with the observation that we can inductively apply Oliver's construction to cells of $Y^G$. Recall that a CW-complex $Y$ is regular if every cell $\sigma$ is given by an embedding $D^k\to Y$. This implies that the boundary $\partial \sigma$ of the cell is a sphere $S^{k-1}$ embedded in $Y$. Then $\chi (\sigma )=\chi (D^{\dim \sigma })=1$, and $\chi (\partial \sigma )=\chi (S^{\dim \sigma -1})=1-(-1)^{\dim \sigma }$.

Lemma 2.1 Suppose $Y$ is a finite CW-complex, and $f\colon F\to Y$ is a map. If $\chi (f^{-1}(\sigma ))=1$ mod $n$ for every cell $\sigma$ of $Y$, then $\chi (F)=\chi (Y)$ mod $n$.

The lemma allows $n=0$, which means dropping ‘mod $n$’ in the statement. In the following proof, all Euler characteristic equalities are true mod $n$.

Proof. If $\dim Y=0$, then $Y$ consists of finitely many points $y_1,y_2,\dots,y_k$, and $F=\cup _{i=1}^k f^{-1}(y_i)$ is a disjoint union. By the assumption, we have $\chi (f^{-1}(y_i))=1$. Therefore, $\chi (F)=\sum _{i=1}^k \chi (f^{-1}(y_i))=k=\chi (Y)$.

Suppose $\dim Y=d$, and the lemma is proved for finite CW-complexes of dimension $< d$. We have $Y^{d-1}=Y_0\subset Y_1\subset \cdots \subset Y_{k-1}\subset Y_k=Y$, where $Y^{d-1}$ is the $(d-1)$-skeleton of $Y$, and $Y_i$ is obtained by attaching one $d$-cell to $Y_{i-1}$. By the inductive assumption, we have $\chi (f^{-1}(Y^{d-1}))=\chi (Y^{d-1})$. Suppose we already proved $\chi (f^{-1}(Y_{i-1}))=\chi (Y_{i-1})$. Let $Y_i=Y_{i-1}\cup \sigma$ for a $d$-cell $\sigma$. Then $Y_{i-1}\cap \sigma$ is a CW-complex of dimension $< d$. Therefore, we have $\chi (f^{-1}(Y_{i-1}\cap \sigma ))=\chi (Y_{i-1}\cap \sigma )$ by the inductive assumption. Combined with $\chi (f^{-1}(\sigma ))=1=\chi (\sigma )$, we get

\begin{align*} \chi(f^{{-}1}(Y_i)) & =\chi(f^{{-}1}(Y_{i-1}))+\chi(f^{{-}1}(\sigma))-\chi(f^{{-}1}(Y_{i-1}\cap \sigma)) \\ & =\chi(Y_{i-1})+\chi(\sigma)-\chi(Y_{i-1}\cap \sigma) =\chi(Y_i). \end{align*}

Inductively, this proves $\chi (F)=\chi (f^{-1}(Y_k))=\chi (Y_k)=\chi (Y)$.

The converse of lemma 2.1 is true up to homotopy equivalence.

Lemma 2.2 Suppose $Y$ is a finite connected regular CW-complex. Suppose $F\ne \emptyset$ and $f\colon F\to Y$ is a map, such that $\chi (F)=\chi (Y)$ mod $n$. Then there is a homotopy equivalence $\phi \colon F\simeq \widehat {F}$ and a map $\widehat {f}\colon \widehat {F}\to Y$, such that $\widehat {f}\phi \simeq f$, and $\chi (\widehat {f}^{-1}(\sigma ))=1$ mod $n$ for every cell $\sigma$ of $Y$.

Proof. We call a cell top cell if it is not in the boundary of any other cell. Fix $c\in F$ and a top cell $\beta$ containing $f(c)$. We regard $\beta$ as the ‘base cell’ of $Y$. For each top cell $\sigma$ different from $\beta$, there is a continuous path $\gamma \colon [-1,1]\to Y$, such that $\gamma (-1)=f(c)$, $\gamma (-1,0)\cap \sigma =\emptyset$ and $\gamma (0,1]\subset \mathring {\sigma }=\sigma -\partial \sigma$. This implies that $\gamma (0)\in \partial \sigma$, and $f(c)$ is the only other possible point on the path lying inside $\partial \sigma$.

For any two spaces $A$ and $B$, we glue cones $cA$ and $cB$ to $F$ by identifying the cone points with $c$. The new space $F'=F\cup _c(cA\cup cB)$ is homotopy equivalent to $F$. We further extend $f$ to $f'\colon F'\to Y$ by mapping the cones to the path $\gamma$ in $Y$. The map is ‘straightforward’ on $cA$ and is ‘twisted’ on $cB$, as illustrated by the picture. Let $\chi (A)=a$ and $\chi (B)=b$. Then we have

\begin{align*} \chi(f'^{{-}1}(\sigma)) & =\chi(f^{{-}1}(\sigma))+a+2b, \\ \chi(f'^{{-}1}(\partial\sigma)) & =\chi(f^{{-}1}(\partial\sigma))+a+3b, \\ \chi(f'^{{-}1}(Y-\mathring{\sigma})) & =\chi(f^{{-}1}(Y-\mathring{\sigma}))+b. \end{align*}

It is therefore possible to choose $a$ and $b$, such that $\chi (f'^{-1}(\sigma ))=\chi (\sigma )=1$ and $\chi (f'^{-1}(\partial \sigma ))=\chi (\partial \sigma )=1-(-1)^{\dim \sigma }$. By $\chi (F)=\chi (Y)$ mod $n$, this implies that $\chi (f'^{-1}(Y-\mathring {\sigma }))=\chi (Y-\mathring {\sigma })$ mod $n$.

The basic construction above reduces the problem to the restriction map $f'|\colon f'^{-1}(Y-\mathring {\sigma })\to Y-\mathring {\sigma }$, which still satisfies the Euler characteristic condition in the lemma. This accommodates an inductive argument. We make the stronger inductive assumption that $f'^{-1}(Y-\mathring {\sigma })$ can be extended to $F''$ by glueing cones (identifying cone points with $c$), and $f'|\colon f'^{-1}(Y-\mathring {\sigma })\to Y-\mathring {\sigma }$ can be extended to $f''\colon F''\to Y-\mathring {\sigma }$, such that $\chi (f''^{-1}(\tau ))=1$ mod $n$ for every cell $\tau$ of $Y-\mathring {\sigma }$. Then $\widehat {F}=F''\cup _c(cA\cup cB)$ is obtained by glueing cones to $F$ (identifying cone points with $c$). Therefore, $\widehat {F}$ is homotopy equivalent to $F$, and $\widehat {f}=f'\cup f''\colon \widehat {F}\to Y$ is homotopy equivalent to $f$. Moreover, we still have $\chi (\widehat {f}^{-1}(\tau ))=\chi (f''^{-1}(\tau ))=1$ for every cell $\tau$ of $Y-\mathring {\sigma }$. By applying lemma 2.1 to the restriction $\widehat {f}|\colon \widehat {f}^{-1}(\partial \sigma )\to \partial \sigma$, where cells of $\partial \sigma$ are cells of $Y-\mathring {\sigma }$, we get

\[ \chi(\widehat{f}^{{-}1}(\partial\sigma)) =\chi(\partial\sigma) =1-({-}1)^{\dim\sigma} =\chi(f'^{{-}1}(\partial\sigma)). \]

On the other hand, we have

\[ \chi(\widehat{f}^{{-}1}(\sigma))-\chi(\widehat{f}^{{-}1}(\partial\sigma)) =\chi(\widehat{f}^{{-}1}(\mathring{\sigma})) =\chi(f'^{{-}1}(\mathring{\sigma})) =\chi(f'^{{-}1}(\sigma))-\chi(f'^{{-}1}(\partial\sigma)). \]

Therefore, $\chi (\widehat {f}^{-1}(\sigma ))=\chi (f'^{-1}(\sigma ))=1$.

There are two problems with the induction argument. The first is that $Y-\mathring {\sigma }$ may not be connected. The second is that there may be only one top cell $\beta$.

The case $Y-\mathring {\sigma }$ not connected happens only when $\sigma$ is a $1$-cell, with only one end $v_0$ attached to $Y-\mathring {\sigma }$, and other end $v_1$ being ‘free’. In addition to glueing $cA$ and $cB$, we may further glue a cone $cC$, with the map from $cC$ to $Y$ extending all the way to $v_1$. Then we have

\begin{align*} \chi(f'^{{-}1}(\sigma)) & =\chi(f^{{-}1}(\sigma))+a+2b+c, \\ \chi(f'^{{-}1}(v_0)) & =\chi(f^{{-}1}(v_0))+a+3b+c, \\ \chi(f'^{{-}1}(v_1)) & =\chi(f^{{-}1}(v_1))+c, \\ \chi(f'^{{-}1}(Y-\mathring{\sigma})) & =\chi(f^{{-}1}(Y-\mathring{\sigma}))+b. \end{align*}

It is then possible to choose $a,b,c$, such that $\chi (f'^{-1}(\sigma ))=\chi (f'^{-1}(v_0))=\chi (f'^{-1}(v_1))=1$. The rest of the inductive argument is the same.

Finally, we consider the case $Y$ has only one top cell $\beta$. In this case, the assumption already says $\chi (f^{-1}(\beta ))=1$, and additional cone construction over $\beta$ does not change this fact. What we need to do is to improve $\chi (f^{-1}(\sigma ))$ to $1$ for cells $\sigma$ in $\partial \beta$. The problem is then reduced to the restriction map $f|\colon f^{-1}(\partial \beta )\to \partial \beta$. The induction may continue over $\partial \beta$.

3. Non-empty fixed point set

We prove theorem 1.7, for the case $F_C=f^{-1}(C)$ is not empty for every connected component $C$ of $Y^G$. The next section deals with the case some $F_C=\emptyset$.

To construct the pseudo-equivalence extension, we will first homotopically modify $f\colon F\to Y^G$ to a better map described in lemma 2.2. Then we construct the extension by inducting on skeleta of $Y^G$. The following justifies the homotopy modification of $f$.

Lemma 3.1 Suppose $Y$ is a finite $G$-CW-complex, and $F$ is a finite CW-complex with trivial $G$-action. If a $G$-map $f\colon F\to Y$ has pseudo-equivalence extension, and we change $f,F,Y$ by equivariant homotopy, then the new map also has pseudo-equivalence extension.

Proof. Suppose $g\colon X\to Y$ is a pseudo-equivalence extension of $f\colon F\to Y$. We homotopically change $f,F,Y$ one by one, and argue about the pseudo-equivalence extension of the new map.

First, suppose $f$ is $G$-homotopic to $f'\colon F\to Y$. By the equivariant version of the homotopy extension property, the $G$-homotopy extends to a $G$-homotopy from $g\colon X\to Y$ to another $G$-map $g'\colon X\to Y$. Then the $G$-map $g'$ extends $f'$, and $g'$ is still a pseudo-equivalence.

Second, suppose $\phi \colon F\to F'$ is a $G$-homotopy equivalence. Then there is a $G$-map $f'\colon F'\to Y$, such that $f\colon F\to Y$ is $G$-homotopic to $f'\circ \phi \colon F\to F'\to Y$. By the argument above, $f'\circ \phi$ has pseudo-equivalence extension $g'\colon X\to Y$. Then $X'=X\cup _{\phi } F'$ (glueing $F\subset X$ to $F'$ by $\phi$) is a $G$-CW-complex with $F'$ as the fixed set, and the $G$-map $g'\cup f'\colon X'\to Y$ is a pseudo-equivalence extension of $f'$.

Finally, suppose $\psi \colon Y\to Y'$ is a $G$-homotopy equivalence. Then $\psi \circ f\colon F\to Y'$ is extended to a pseudo-equivalence $\psi \circ g\colon X\to Y'$.

For the inductive construction (on skeleta of $Y^G$) of pseudo-equivalence extension, we use the following result.

Lemma 3.2 Suppose $G$ is a group of not prime power order, $K$ is a finite $G$-CW-complex and $F=K^G$.

  1. 1. If $\chi (F)=1$ mod $m(G)$, then $K$ can be extended to a finite $G$-CW-complex $X$, such that $F=X^G$, $X$ is $(\dim X-1)$-connected and $H_{\dim X}(X;{\mathbb {Z}})$ is a projective ${\mathbb {Z}}G$-module.

  2. 2. If $\chi (F)=1$ mod $n(G)$, then $K$ can be extended to a finite contractible $G$-CW-complex $X$, such that $F=X^G$.

Proof. The first statement is [Reference Oliver10, theorem 2], and Oliver called the $G$-CW-complex $X$ in the statement a $G$-resolution. The second statement is essentially the corollary to [Reference Oliver10, theorem 3]. More precisely, we may use [Reference Oliver11, theorem 2], which is even applicable to compact Lie group actions: Let ${\mathcal {F}}$ be a family of subgroups of $G$ as defined by tom Dieck, meaning closed under subgroup and conjugation. If ${\mathcal {F}}$ contains all the prime toral subgroups, $X$ and $Z$ are finite $G$-CW-complexes, $Z$ is contractible and $\chi (X^H/NH)=\chi (Z^H/NH)$ for all $H\not \in {\mathcal {F}}$, then $X$ can be extended to a finite contractible $G$-CW-complex $Y$, such that the isotropy subgroups of $Y-X$ are in ${\mathcal {F}}$.

Let

\[ \delta_H=\sum_j({-}1)^j(\text{number of cells of type }G/H\times D^j). \]

Then the proof of [Reference Oliver11, lemma 14] shows that $\chi (X^H/NH)=\chi (Z^H/NH)$ for all $H\not \in {\mathcal {F}}$ if and only if $\delta _H(X)=\delta _H(Z)$ for all $H\not \in {\mathcal {F}}$.

By [Reference Oliver11, theorem 3], the assumption $\chi (F)=1$ mod $n(G)$ implies $F=Z^G$ for a finite contractible $G$-CW-complex $Z$. Let ${\mathcal {F}}$ be the family of all the prime toral subgroups of $G$. By adding $G/H\times D^j$ to $K$, for $H\not \in {\mathcal {F}}\cup \{G\}$, it is easy to get a finite $G$-CW-complex $L$, such that $\delta _H(L)=\delta _H(Z)$ for all $H\not \in {\mathcal {F}}\cup \{G\}$. Since $H\ne G$ in the construction of $L$, we have $L^G=K^G=F=Z^G$. Therefore, we also have $\delta _G(L)=\chi (L^G)=\chi (Z^G)=\delta _G(Z)$, and we get $\delta _H(L)=\delta _H(Z)$ for all $H\not \in {\mathcal {F}}$. This implies $\chi (L^H/NH)=\chi (Z^H/NH)$ for all $H\not \in {\mathcal {F}}$. Then by the interpretation of [Reference Oliver11, theorem 2] above, $L$ extends to a finite contractible $G$-CW-complex $X$, such that the isotropy subgroups of $X-L$ are in ${\mathcal {F}}$. Since $G$ is not an isotropy subgroup of $X-L$, we have $X^G=L^G=F$.

Proof Proof of theorem 1.7 in case all $F_C\ne \emptyset$

The $G$-CW-complex $Y$ is $G$-homotopy equivalent to a regular $G$-CW-complex. If all $F_C$ are not empty, then we apply lemma 2.2 to homotopically modify all $F_C\to C$, such that $\chi (f^{-1}(\sigma ))=1$ mod $n(G)$ for every cell $\sigma$ of $Y^G$. By lemma 3.1, it is sufficient to construct a pseudo-equivalence extension under the additional assumption.

Denote $Z=Y^G$, which has trivial $G$-action. We first extend $f\colon F\to Z$ to a pseudo-equivalence $h\colon W\to Z$ by inducting on the skeleta of $Z$.

We assume $F^{k-1}=f^{-1}(Z^{k-1})$ is already extended to a $G$-CW-complex $W^{k-1}$ with $(W^{k-1})^G=F^{k-1}$. Moreover, we assume that $f|_{F^{k-1}}$ is extended to a $G$-map $h_{k-1}\colon W^{k-1}\to Z^{k-1}$, such that $h_{k-1}^{-1}(\sigma )$ is contractible for every cell $\sigma$ of $Z^{k-1}$. The inductive assumption holds for $k=0$, because $Z^{-1}=F^{-1}=\emptyset$.

Let $\sigma$ be a $k$-cell of $Z$. Then $\chi (f^{-1}(\sigma ))=1$ mod $n(G)$ by our assumption. Taking $f^{-1}(\sigma )$ and $f^{-1}(\sigma )\cup h_{k-1}^{-1}(\partial \sigma )$ as $F$ and $K$ in the second part of lemma 3.2, we may extend $f^{-1}(\sigma )\cup h_{k-1}^{-1}(\partial \sigma )$ to a finite contractible $G$-CW-complex $W_{\sigma }$, such that $W_{\sigma }^G=f^{-1}(\sigma )$. Since $\sigma$ is contractible and has trivial $G$-action, we may further arrange to extend $f|_{\sigma }\cup h_{k-1}|_{\partial \sigma }$ to a $G$-map $h_{\sigma }\colon W_{\sigma }\to \sigma$, such that $h_{\sigma }^{-1}(\partial \sigma )= h_{k-1}^{-1}(\partial \sigma )$.

Let $W^k=W^{k-1}\cup (\cup _{\dim \sigma =k}W_{\sigma })$, where the union identifies $h_{k-1}^{-1}(\partial \sigma )\subset W_{\sigma }$ with the same subset in $W^{k-1}$. Then we have $G$-map $h_k=h_{k-1}\cup (\cup _{\dim \sigma =k}h_{\sigma })\colon W^k\to Z^k$, such that $(W^k)^G=F^{k-1}\cup (\cup _{\dim \sigma =k}f^{-1}(\sigma ))=F_k$. Moreover, we have $h_k^{-1}(\sigma )=W_{\sigma }$ if $\dim \sigma =k$, and $h_k^{-1}(\sigma )=h_{k-1}^{-1}(\sigma )$ if $\dim \sigma < k$. Therefore $h_k^{-1}(\sigma )$ is contractible for every cell $\sigma$ of $Z^k$.

When $k=\dim Z$, we get $h=h_{\dim Z}\colon W=W^{\dim Z}\to Z$, such that $W^G=F$, and $h^{-1}(\sigma )$ is contractible for every cell $\sigma$ of $Z$. This implies that $h\colon W\to Z=Y^G$ is a homotopy equivalence.

Next, we further extend $h\colon W\to Z=Y^G\subset Y$ to a pseudo-equivalence ${g\colon X\to Y}$.

The equivariant neighbourhood $\text {nd}(Z)$ of $Z$ in $Y$ is the mapping cylinder of a $G$-map $\lambda \colon E\to Z$. We try to factor $\lambda$ through a $G$-map $\widetilde {\lambda }\colon E\to W$. Then $\lambda =h\circ \widetilde {\lambda }$, and we have a $G$-map from the mapping cylinder of $\widetilde {\lambda }\colon E\to W$ to the mapping cylinder of $\lambda \colon E\to Z$. The $G$-map extends to a $G$-map $g=id\cup h\colon X=(Y-\text {nd}(Z))\cup _{\widetilde {\lambda }}W\to Y=(Y-\text {nd}(Z))\cup _{\lambda }Z$. We have $X^G=W^G=F$, and $g$ extends $f$. Moreover, since $h$ is a pseudo-equivalence, $g$ is also a pseudo-equivalence.

It remains to construct the lifting $\widetilde {\lambda }$. Since $G$ fixes no points on $E$, we can construct the lifting if $h\colon W\to Z$ is highly connected for the fixed sets of proper subgroups of $G$ acting on $W$. Recall that we actually constructed $h\colon W\to Z$ in such a way that, for every cell $\sigma$ in the (regular) CW-complex $Z$, $h^{-1}(\sigma )$ is contractible. Let $S$ be the disjoint union of all the $G$-orbits appearing in $E$. Then $S$ is a compact set, such that all the isotropies on $E$ appear in $S$. Then we may take the cell-wise join of $h\colon W\to Z$ with $S\times Z\to Z$ several times to get $h'\colon W'\to Z$. This means $h'^{-1}(\sigma )=h^{-1}(\sigma )*S*\cdots *S$. Since $h^{-1}(\sigma )$ is contractible, $h'^{-1}(\sigma )$ is still contractible. Since $G$ fixes no points of $S$, we get $W'^G=W^G=F$. Therefore, $h'$ is still a pseudo-equivalence extension of $f$. On the other hand, the fixed sets of proper subgroups of $G$ acting on $h'^{-1}(\sigma )$ become more and more highly connected as we repeat the join construction more and more times. Therefore, we may construct the lifting $\widetilde {\lambda }$ by using $h'$ instead of $h$.

For the $G$-ANR case, we only need to modify the proof in the very last cell. We may use Quinn's ‘wrinkling’ trick from [Reference Quinn15, § 2] to remove the $\widetilde {K}_0$-obstruction arising in the first part of lemma 3.2, or more systematically, use his exact sequence in [Reference Quinn16] for the topological Whitehead groups and Wall finiteness groups where the relevant $K$-groups are quotiented by the image of the assembly map.

4. Empty fixed point

We still need to prove theorem 1.7 for the case some $F_C=\emptyset$. In this case, $\chi (F_C)=\chi (C)$ mod $n(G)$ means $\chi (C)=0$ mod $n(G)$. A typical example is that $C$ is the circle $S^1$, and our proof starts with this special case. In fact, we first concentrate on the case $Y=Y^G=S^1$.

Lemma 4.1 Suppose $G$ is a group of not prime power order. Then there is a pseudo-equivalence $X\to S^1$, such that $X$ is a finite $G$-CW-complex without fixed points, and $G$ fixes $S^1$.

The idea is to find a finite and simply connected $G$-CW-complex $Z$ without fixed points, and a $G$-map $h\colon Z\to Z$ inducing zero homomorphism on the reduced homology. Then the mapping torus $X$ of $h$ together with the natural map to $S^1$ gives what we want. We may take $Z=S(V)$ and take $h$ to be the self map of $S(V)$ in the following result.

Lemma 4.2 Suppose $G$ is a group of not prime power order, and $V$ is a linear $G$-representation. If $V^G=0$ and all Sylow subgroups of $G$ are isotropy groups of $V$, then there is a degree $0$ $G$-map from the unit sphere $S(V)$ to itself.

Proof. Let $P$ be a Sylow subgroup and let $NP$ be its normalizer in $G$. Since $P$ is an isotropy subgroup, the fixed subspace $V^P$ is not a zero subspace. Let $D$ be a small equivariant disk neighbourhood of a point $x\in S(V^P)$. Then $D$ is an $NP$-representation. Moreover, since $V$ is a linear representation, the $NP$-representation is independent of the size of $D$. This means that the radial extension gives an $NP$-equivariant homeomorphism $D/\partial D\cong S(V)$ sending $*=\partial D/\partial D$ to $x$. Then we may construct an $NP$-map

\[ S(V)=(S(V)-D)\cup_{\partial D} D\to S(V)\vee_x D/\partial D\to S(V). \]

The first map collapses $\partial D$ to $x$, and the second map uses the $NP$-equivariant homeomorphism $D/\partial D\cong S(V)$. The map can be extended to a $G$-map

\[ h_x\colon S(V)\to S(V)\cup_{Gx}(G\times_{NP} D/\partial D)\to S(V). \]

If we fix an orientation of $S(V)$, then $D$ inherits the orientation, and the homeomorphism $D/\partial D\cong S(V)$ has degree $\pm 1$. By composing with the $-1$ map along a $1$-dimensional subspace of $V^P$, we may change the sign of the degree of the homeomorphism. Therefore, we may arrange to have the degree of $h_x$ to be $1+|G/NP|$ or to be $1-|G/NP|$. If we apply the construction at several points $x\in S(V^P)$ with disjoint orbits $Gx$, then we get a $G$-map $S(V)\to S(V)$ of degree $1+a|G/NP|$ for any integer $a$. If we apply the construction to the Sylow subgroups $P_1,P_2,\dots,P_n$ for all the distinct prime factors of $|G|$, then we get a $G$-map $S(V)\to S(V)$ of degree $1+\sum a_i|G/NP_i|$, where $a_1,a_2,\dots,a_n$ can be any prescribed integers. Since $|G/NP_1|,|G/NP_2|,\dots,|G/NP_n|$ are coprime, we get degree $0$ by suitable choice of the integers $a_i$.

Remark 4.3 We may further make $S(V)$ highly connected for the fixed sets of proper subgroups. Specifically, the kernel of the augmentation $\epsilon (\sum _{g\in G}a_gg)=\sum a_g\colon {\mathbb {R}}G\to {\mathbb {R}}$ is a representation satisfying the condition of the lemma. The direct sum of several copies of this kernel also satisfies the condition of the lemma. By taking the direct sum of sufficiently many copies, the fixed sets of $S(V)$ for proper subgroups are highly connected.

Remark 4.4 Lemma 4.1 is valid for non-prime toral compact Lie groups. Moreover, the remark above on the high connectivity is also valid.

Suppose a compact Lie group $G$ is not prime toral. If the identity component $G_0$ is not abelian (i.e., not torus), then by [Reference Oliver11, theorem 5], there is a finite contractible $G$-CW-complex $Z$ without fixed points. In fact, $Z$ can be a disk with smooth $G$-action. Then $X=Z\times S^1\to S^1$ is a pseudo-equivalence, and $X^G=\emptyset$.

If $G_0$ is abelian, then the order of $G/G_0$ is not prime power. We may apply lemma 4.2 to $G/G_0$, and then take the mapping cylinder to construct $X$. We obtain a $G/G_0$-pseudo-equivalence $X\to S^1$, and $X$ has no $G/G_0$-fixed points. This induces a $G$-pseudo-equivalence $X\to S^1$, and $X$ still has no $G$-fixed points.

Alternatively, we may use Bartsch's study of the existence of Borsuk–Ulam theorems [Reference Bartsch1] to find degree $0$ $G$-map from a fixed point free representation sphere to itself. The equivalence of properties ($c$) and ($d$) of his theorem 1 gives such a map for finite groups of non-prime power order. The equivalence of properties ($c$) and ($d'$) of his theorem 2 gives such a map for non-prime toral compact Lie groups. The map on the representation sphere has degree $0$ because it takes the whole sphere into a proper sub-sphere.

Proof Proof of theorem 1.7 in case some $F_C=\emptyset$

Assume $F_C=\emptyset$ for some $C$. Then the condition $\chi (F_C)=\chi (C)$ mod $n(G)$ means $\chi (C)=0=\chi (S^1)$ mod $n(G)$.

If $F_C=\emptyset$, then we introduce $F'_C=S^1\to C$, where the map can be any one. If $F_C\ne \emptyset$, then we let $F'_C=F_C$, and let the map $F'_C\to C$ be $F_C\to C$. Then $f\colon F\to Y^G$ extends to $f'\colon F'=\cup F'_C\to Y^G$. The modification $f'$ satisfies the Euler characteristic condition in the theorem, and all $F'_C$ are not empty. Since the theorem is already proved for the case all $F_C\ne \emptyset$, $f'$ has a pseudo-equivalence extension $X'\to Y$, with $X'^G=F'$.

It remains to homotopically replace the extra circles added to $F$ by something that have no fixed points. The equivariant neighbourhood $\text {nd}(S^1)$ of one such circle in $X'$ is the mapping cylinder of a $G$-map $\lambda \colon E\to S^1$. By lemma 4.1 and the remarks after the proof of lemma 4.2, there is a highly connected (for the fixed sets of proper subgroups) pseudo-equivalence $\mu \colon W\to S^1$, such that $W$ has no fixed point. By the high connectivity, $\lambda$ can be lifted to a $G$-map $\widetilde {\lambda }\colon E\to W$. Then we have $\lambda =\mu \circ \widetilde {\lambda }$. Let $X=(X'-\text {nd}(S^1))\cup _{\widetilde {\lambda }}W$ be obtained by glueing the boundary $E$ of $\text {nd}(S^1)$ to $W$, and this is done for all $F'_C=S^1\subset X'$ that were used to replace empty $F_C$. Then $\lambda =\mu \circ \widetilde {\lambda }$ and the pseudo-equivalence $\mu$ induce a pseudo-equivalence $X\to X'=(X'-\text {nd}(S^1))\cup _{\lambda }S^1$. The composition $X\to X'\to Y$ is then a pseudo-equivalence extension of $f$ with $X^G=F$.

We end the section by using lemma 4.1 to prove theorem 1.1.

Proof of theorem 1.1 By lemma 4.1, there is a $G$-CW-complex $X$ without fixed point, and a pseudo-equivalence $f\colon X\to S^1$, where $G$ fixes $S^1$. By thickening, we may assume $X$ is a manifold with boundary. Let $C$ be the mapping cylinder of $f$. Then the inclusion $X\to C$ is a pseudo-equivalence. We can now do a Davis construction [Reference Davis5, Reference Davis and Hausmann6] equivariantly on $X$ (by triangulating the boundary) and mapping to the Davis construction on $C$ (with respect to the boundary of $X$). This produces a $G$-action on a closed aspherical manifold $M$, with a pseudo-equivalence to the same construction on $C$. Since $C$ has a fixed point, the $G$-action on $\pi =\pi _1(C)=\pi _1(X)$ lifts to $\text {Aut}(\pi )$. On the other hand, the $G$-action on $M$ has no fixed point, because the original action on $X$ did not.

It is an interesting problem whether the action constructed in the proof can exist on classical aspherical manifolds, e.g., hyperbolic manifolds. For odd order cyclic group (or the order is a power of $2$), [Reference Weinberger19] shows the answer is negative.

5. Obstruction group

We prove theorem 1.6.

For a finite $G$-CW-complex $Y$, let $N(Y)\subset {\mathbb {Z}}^{\pi _0Y^G}$ be the collection of

\[ \nu(g) =(\chi(F_C)-\chi(C))_{C\in \pi_0Y^G},\quad F_C=g^{{-}1}(C)\cap X^G, \]

for all pseudo-equivalences $g\colon X\to Y$. We prove $N(Y)$ is a group, by showing that it is closed under negative and addition operations.

For a pseudo-equivalence $g\colon X\to Y$, we construct its negative to be the double mapping cylinder of $g$

\[ \overline{g}\colon \overline{X}=Y\cup X\times[0,1]\cup Y\to Y. \]

Then $\overline {g}$ is still a pseudo-equivalence, with $\overline {F}_C=C\cup F_C\times [0,1]\cup C$, and $\chi (\overline {F}_C)-\chi (C)=-(\chi (F_C)-\chi (C))$. Therefore, $\nu \in N(Y)$ implies $-\nu \in N(Y)$.

The negative construction has the following properties:

  1. 1. $\overline {X}$ contains a copy of $Y$, and the non-equivariant homotopy equivalence can be a homotopy retraction of $\overline {X}$ to $Y$.

  2. 2. $\overline {F}_C$ is connected. Therefore, the connected components of the fixed sets of $\overline {X}$ and $Y$ are in one-to-one correspondence.

We call a pseudo-equivalence with the two properties retracting equivalence. Since the double negative satisfies $\nu (\overline {\overline {g}})=\nu (g)$, every element in $N(Y)$ is represented by a retracting equivalence.

For two retracting equivalences $g_1\colon X_1\to Y$ and $g_2\colon X_2\to Y$, the addition $g_1\cup g_2\colon X_1\cup _Y X_2\to Y$ is still a retracting equivalence. It is also easy to see that $\nu (g_1\cup g_2)=\nu (g_1)+\nu (g_2)$. Therefore, $\nu _1,\nu _2\in N(Y)$ implies $\nu _1+\nu _2\in N(Y)$.

This completes the proof that $N(Y)$ is an abelian subgroup. Next, we prove that $N(Y)$ is indeed the obstruction to pseudo-equivalence extension.

By the definition of $N(Y)$, if $f\colon F\to Y$ extends to a pseudo-equivalence $g\colon X\to Y$, such that $X^G=F$, then $(\chi (F_C)-\chi (C))_{C\in \pi _0Y^G}=\nu (g)\in N(Y)$.

Conversely, suppose $f\colon F\to Y$ satisfies $(\chi (F_C)-\chi (C))_{C\in \pi _0Y^G}\in N(Y)$. Then $(\chi (F_C)-\chi (C))_{C\in \pi _0Y^G}=\nu (g')$ for a pseudo-equivalence $g'\colon X'\to Y$. This means $\chi (F_C)=\chi (F'_C)$, where $F'_C=g'^{-1}(C)\cap X'^G$.

As remarked earlier, we may further assume that $g'$ is a retracting equivalence. Then we may regard $f$ as mapped into $Y\subset X'$. This means $f$ is the composition ($i\colon Y\to X'$ is the inclusion)

\[ f=g'\circ(i\circ f)\colon F\xrightarrow{i\circ f}X'\xrightarrow{g'} Y. \]

Since $Y\subset X'$, and connected components of the fixed sets of $X'$ and $Y$ are in one-to-one correspondence, we have

\[ C=Y\cap F'_C,\quad F_C=f^{{-}1}(Y\cap F'_C)=(i\circ f)^{{-}1}(F'_C), \]

and

\[ \chi((i\circ f)^{{-}1}(F'_C)) =\chi(F_C) =\chi(F'_C). \]

By theorem 1.7, this implies that $i\circ f$ has pseudo-equivalence extension $h\colon X\to X'$. Then $g'\circ h\colon X\to Y$ is a pseudo-equivalence extension of $f$. This completes the proof of theorem 1.6.

6. The role of the fundamental group

In this section, we develop an equivariant Euler–Wall characteristic of a finite $G$-CW-complex; it lies in $K_0(R[\Gamma ])$, for rings $R$ in which the orders of isotropy groups are invertible. We apply this to get further restrictions on the Euler characteristics of components of fixed sets under pseudo-equivalences.

We first elaborate on the lifted $G$-actions to the universal cover that we use to define the weakly $G$-connected property in the introduction.

Let $p\colon \widetilde {Y}\to Y$ be the universal cover, with free action on $\widetilde {Y}$ by the fundamental group $\pi =\pi _1(Y)$. A $G$-action on $Y$ lifts to self homeomorphisms of $\widetilde {Y}$. All the liftings form a group $\Gamma$ fitting into an exact sequence

(6.1)\begin{equation} 1\to \pi\to \Gamma\to G\to 1. \end{equation}

Strictly speaking, we only get an exact sequence with $G/G_0$ in place of $G$, where $G_0$ consists of all the elements of $G$ that act trivially on $Y$. Then we replace $\Gamma$ by the pullback of $\Gamma \to G/G_0\leftarrow G$ and still get (6.1) with $G$ instead of $G/G_0$.

Let $\widetilde {y}\in \widetilde {Y}$, $y=p(\widetilde {y})$. The induced homomorphism $\Gamma _{\widetilde {y}}\to G_y$ of isotropy groups is an isomorphism. If $y\in Y^G$, then we get a splitting $G=G_y\cong \Gamma _{\widetilde {y}}\subset \Gamma$ of (6.1). If $\widetilde {y}$ and $\widetilde {y}'$ are in the same connected component $\widehat {C}$ of $p^{-1}(Y^G)$, then $\Gamma _{\widetilde {y}}=\Gamma _{\widetilde {y}'}$. Therefore, we may denote $\Gamma _{\widetilde {y}}=\Gamma _{\widehat {C}}$, and the splitting $G\cong \Gamma _{\widehat {C}}\subset \Gamma$ depends only on $\widehat {C}$.

The connected component $\widehat {C}$ covers a connected component $C$ of $Y^G$. The other connected components of $p^{-1}(C)$ are $a\widehat {C}$, $a\in \pi$. Therefore, a connected component $C$ of $Y^G$ gives a $\pi$-conjugacy class of splittings of (6.1),

\[ \Gamma_C =\{\Gamma_{a\widehat{C}}=a\Gamma_{\widehat{C}}a^{{-}1}\colon a\in \pi\}. \]

Example 6.1 The complex conjugation action of $G={\mathbb {Z}}_2$ on circle $Y=S^1$ has fixed point components $C_1=\{1\}$ and $C_{-1}=\{-1\}$. The universal cover is $p(t)=e^{it}\colon \widetilde {Y}={\mathbb {R}}\to Y$. The group $\Gamma$ consists of $\sigma _n(t)=t+2n\pi$ (liftings of the identity, which form $\pi _1(Y)$) and $\rho _n(t)=-t+2n\pi$ (liftings of the conjugation). We have

\begin{align*} & p^{{-}1}(C_1) =\{2n\pi\colon n\in {\mathbb{Z}}\}, \quad p^{{-}1}(C_{{-}1}) =\{(2n+1)\pi\colon n\in {\mathbb{Z}}\}; \\ & \widehat{C}_1 =\{0\}, \quad \widehat{C}_{{-}1} =\{\pi\}; \\ & \Gamma_{\{2n\pi\}} =\{1,\rho_{2n}\} =\sigma_1^n\Gamma_{\widehat{C}_1}\sigma_1^{{-}n}, \quad \Gamma_{\{(2n+1)\pi\}} =\{1,\rho_{2n+1}\} =\sigma_1^n\Gamma_{\widehat{C}_{{-}1}}\sigma_1^{{-}n}. \end{align*}

We have two conjugate families of splittings

\[ \Gamma_{C_1}=\{\Gamma_{\{2n\pi\}}\},\quad \Gamma_{C_{{-}1}}=\{\Gamma_{\{(2n+1)\pi\}}\}. \]

A splitting of (6.1) corresponds to a semi-direct product decomposition $\Gamma =\pi \rtimes G$. The $\pi$-conjugacy classes of splittings form the cohomology set $H^1(G;\pi )$ (not necessarily a group because $\pi$ may not be commutative).

A $G$-map $g\colon X\to Y$ has a pullback $\widetilde {g}\colon \widetilde {X}\to \widetilde {Y}$ along the universal cover $p\colon \widetilde {Y}\to Y$. The map $\widetilde {g}$ is a $\Gamma$-map, and induces a map of ${\mathbb {Z}}[\Gamma ]$-chain complexes $\widetilde {g}_*\colon C(\widetilde {X})\to C(\widetilde {Y})$. If $g$ is a pseudo-equivalence, then $\widetilde {g}_*$ has a ${\mathbb {Z}}[\pi ]$-chain homotopy inverse $\varphi$.

Let $R$ be a ring, say the rational numbers ${\mathbb {Q}}$, such that $|G|$ is invertible in $R$. Then we may use one splitting $\Gamma =\pi \rtimes G$ to get a $R[\Gamma ]$-chain map $\frac {1}{|G|}\sum _{u\in G}u\varphi \colon C(\widetilde {Y})\to C(\widetilde {X})$. This is a $R[\Gamma ]$-chain homotopy inverse of

\[ \widetilde{g}_*\otimes R\colon C(\widetilde{X})\otimes R\to C(\widetilde{Y})\otimes R. \]

In particular, $\widetilde {g}_*\otimes R$ is a $R[\Gamma ]$-chain homotopy equivalence.

Since $|G|$ is invertible in $R$, and the isotropy groups of the $\Gamma$-action are isomorphic to subgroups of $G$, we know $C(\widetilde {X})\otimes R$ and $C(\widetilde {Y})\otimes R$ consist of finitely generated projective $R[\Gamma ]$-modules. Then the $R[\Gamma ]$-chain complexes give the Euler characteristic elements $\chi _{\Gamma }(\widetilde {X})$ and $\chi _{\Gamma }(\widetilde {Y})$ in $K_0(R[\Gamma ])$. The $R[\Gamma ]$-chain homotopy equivalence $\widetilde {g}_*\otimes R$ implies $\chi _{\Gamma }(\widetilde {X})=\chi _{\Gamma }(\widetilde {Y})$.

The $G$-cells $G\sigma$ of $Y$ are in one-to-one correspondence with $\Gamma$-cells $\Gamma \widetilde {\sigma }$ of $\widetilde {Y}$, where $\widetilde {\sigma }$ is any cell of $\widetilde {Y}$ over $\sigma$. The Euler characteristic of $C(\widetilde {Y})\otimes R$ is

\[ \chi_{\Gamma}(\widetilde{Y}) =\sum_{G\text{-cells of}\ Y}({-}1)^{\dim\sigma}[R[\Gamma\widetilde{\sigma}]]\in K_0(R[\Gamma]). \]

Here $\Gamma \widetilde {\sigma }=\Gamma /\Gamma _{\widetilde {\sigma }}$ is a $\Gamma$-orbit, and $R[\Gamma \widetilde {\sigma }]$ is a projective $R[\Gamma ]$-module. For a finite subgroup $H$, the rank [Reference Bass2, Reference Hattori7, Reference Stallings18] of the projective $R[\Gamma ]$-module $R[\Gamma /H]$ is ($(\gamma )$ is the conjugacy class of $\gamma$ in $\Gamma$)

\[ \text{rank}(R[\Gamma/H]) =\frac{1}{|H|}\sum_{h\in H}h \in \oplus_{(\gamma)\subset \Gamma}R(\gamma). \]

By $\chi _{\Gamma }(\widetilde {X})=\chi _{\Gamma }(\widetilde {Y})$, we have $\text {rank}(\chi _{\Gamma }(\widetilde {X}))=\text {rank}(\chi _{\Gamma }(\widetilde {Y}))$.

Theorem 6.2 Suppose $G$ is a cyclic group acting on a finite $G$-CW-complex $Y$. Suppose $\gamma \in \Gamma$ is mapped to a generator of $G$, and $\langle \gamma \rangle$ is the cyclic subgroup generated by $\gamma$. If $g\colon X\to Y$ is a rational pseudo-equivalence, then

\[ \sum_{\langle\gamma\rangle\in \Gamma_C}\chi(F_C) =\sum_{\langle\gamma\rangle\in \Gamma_C}\chi(C). \]

The sum is over all components $C$ of $Y^G$ satisfying $\langle \gamma \rangle \in \Gamma _C$.

If $Y$ is weakly $G$-connected, then there is at most one $C$ satisfying $\langle \gamma \rangle \in \Gamma _C$, and the proposition says $\chi (F_C)=\chi (C)$ for each $C$. In other words, the local Euler characteristic condition in theorem 1.7 is necessary and sufficient. This proves theorem 1.5 for the case $G$ is cyclic, and we have $N(Y)=n(G){\mathbb {Z}}^{\pi _0Y^G}$.

Proof. Since $\gamma \in \Gamma$ is mapped to a generator of $G$, by the formula for $\text {rank}({\mathbb {Q}}[\Gamma \widetilde {\sigma }])=\text {rank}({\mathbb {Q}}[\Gamma /\Gamma _{\widetilde {\sigma }}])$, the conjugacy class $(\gamma )$ appears in $\text {rank}({\mathbb {Q}}[\Gamma \widetilde {\sigma }])$ if and only if a conjugate of $\gamma$ fixes $\widetilde {\sigma }$. Moreover, for such $\widetilde {\sigma }$, we have

\[ \text{rank}({\mathbb{Q}}[\Gamma\widetilde{\sigma}]) =\frac{1}{n}\sum_{i=0}^{n-1}(\gamma^i),\quad n=|G|. \]

The elements $\gamma ^i$ are not $\Gamma$-conjugate because they are mapped to non-conjugate elements of the cyclic group $G$. Therefore, the coefficient of $(\gamma )$ in $\text {rank}({\mathbb {Q}}[\Gamma \widetilde {\sigma }])$ is $\frac {1}{n}$.

The terms ${\mathbb {Q}}[\Gamma \widetilde {\sigma }]$ of $C(\widetilde {Y})\otimes {\mathbb {Q}}$ are in one-to-one correspondence with $G$-cells $G\sigma$ of $Y$. If a conjugate of $\gamma$ fixes $\widetilde {\sigma }$, by $\gamma$ mapped to a generator of $G$, we know $G$ fixes $\sigma$. Therefore, $\sigma$ is in a connected component $C$ of $Y^G$ satisfying $\langle \gamma \rangle \in \Gamma _C$. Conversely, any such $\sigma$ gives $\frac {1}{n}(\gamma )$ in the corresponding $\text {rank}({\mathbb {Q}}[\Gamma \widetilde {\sigma }])$. Therefore, the coefficient of $(\gamma )$ in

\[ \text{rank}(\chi_{\Gamma}(\widetilde{Y})) =\sum_{\text{$G$-cells $G\sigma$ of $Y$}} ({-}1)^{\dim\sigma}\text{rank}({\mathbb{Q}}[\Gamma\widetilde{\sigma}]) \]

is

\[ \sum_{\text{$G$-cell $G\sigma$ of $C$ satisfying $\langle\gamma\rangle\in \Gamma_C$}}({-}1)^{\dim\sigma}\frac{1}{n} =\frac{1}{n}\sum_{\langle\gamma\rangle\in \Gamma_C}\chi(C). \]

We have the same calculation for the pullback $\widetilde {X}$, and find that the coefficient of $(\gamma )$ in $\text {rank}(\chi _{\Gamma }(\widetilde {X}))$ is $\frac {1}{n}\sum _{\langle \gamma \rangle \in \Gamma _C}\chi (F_C)$. Then we conclude $\frac {1}{n}\sum _{\langle \gamma \rangle \in \Gamma _C}\chi (F_C)=\frac {1}{n}\sum _{\langle \gamma \rangle \in \Gamma _C}\chi (C)$.

Next, we apply the idea to $G$ satisfying $n(G)=0$. This means there is a normal subgroup $P$, such that $|P|=p^l$ for a prime $p$, and $G/P$ is cyclic of order $n$. We may further assume that $p$ and $n$ are coprime. The liftings of $P$-actions give an exact sequence

(6.2)\begin{equation} 1\to\pi\to \Pi\to P\to 1. \end{equation}

Here $\Pi$ is the pre-image of $P$ under $\Gamma \to G$, and (6.2) is part of (6.1).

Each connected component $C$ of $Y^G$ is contained in a connected component $D$ of $Y^P$. Then $p^{-1}(C)\subset p^{-1}(D)$, and each connected component $\widehat {C}$ of $p^{-1}(C)$ is contained in a connected component $\widehat {D}$ of $p^{-1}(D)$. The pair $(\widehat {C},\widehat {D})$ gives a pair of compatible splittings $G\cong \Gamma _{\widehat {C}}\subset \Gamma$ and $P\cong \Gamma _{\widehat {D}}\subset \Pi$ of (6.1) and (6.2). All the pairs $(\widehat {C},\widehat {D})$ are related by $\pi$-translations, and the corresponding pairs of splittings are $\pi$-conjugate. Then we get a $\pi$-conjugacy class of compatible splittings (we fix one pair $(\widehat {C},\widehat {D})$ in the second expression)

\[ \Gamma_{CD} =\{\text{all }(\Gamma_{\widehat{C}},\Gamma_{\widehat{D}})\} =\{(a\Gamma_{\widehat{C}}a^{{-}1},a\Gamma_{\widehat{D}}a^{{-}1})\colon a\in \pi\}. \]

Theorem 6.3 Suppose $P$ is a normal $p$-subgroup of $G$, and $G/P$ is a cyclic group of order prime to $p$. Suppose $X,Y$ are finite $G$-CW-complexes, and a $G$-map $g\colon X\to Y$ is a pseudo-equivalence. Then for connected components $C_0,D_0$ of $Y^G,Y^P$ satisfying $C_0\subset D_0$, we have

\[ \sum_{\Gamma_{CD_0}=\Gamma_{C_0D_0}}\chi(F_C) =\sum_{\Gamma_{CD_0}=\Gamma_{C_0D_0}}\chi(C). \]

The sum is over all connected components $C$ of $Y^G$ satisfying $\Gamma _{CD_0}=\Gamma _{C_0D_0}$.

The condition $\Gamma _{CD_0}=\Gamma _{C_0D_0}$ means the following: We fix one connected component $D$ (denoted $D_0$ in the proposition) of $Y^P$, and consider all the connected components $C$ of $Y^G$ that are contained in $D$. Then we further distinguish these $C$ by the conjugation classes of the associated splittings. The sum of Euler characteristics is over such conjugation classes.

If all connected components $C$ inside $D$ have non-conjugate splittings, then the sum is over a single $C$, and we get $\chi (F_C)=\chi (C)$ for every $C$ inside $D$. Furthermore, suppose $Y$ has the property that, if connected components $C$ and $C'$ of $Y^G$ give conjugate splittings, then $C$ and $C'$ belong to different connected components of $Y^P$. Of course, a weakly $G$-connected $Y$ has this property. Under this property, we get $\chi (F_C)=\chi (C)$ for every connected component $C$ of $Y^G$. This proves theorem 1.5 for the case $n(G)=0$.

Proof. The cyclic group $H=G/P$ acts on $Y^P$, and the group $\widetilde {H}$ of liftings of $H$-actions to $p^{-1}(Y^P)$ fits into an exact sequence

(6.3)\begin{equation} 1\to\pi\to \widetilde{H}\to H\to 1. \end{equation}

By Smith theory [Reference Cappell, Weinberger and Yan4, Reference Smith17], we know $g^P\colon X^P\to Y^P$ is an ${\mathbb {F}}_p[\widetilde {H}]$-homology equivalence. This implies $g^P$ is a ${\mathbb {Z}}_{p^k}[\widetilde {H}]$-homology equivalence for all $k$.

The homology equivalence is a sum of homology equivalences on connected components [Reference Cappell, Weinberger and Yan4]. Let $C,D,\widehat {C},\widehat {D}$ be given as in the discussion before the proposition. Since $G$ has fixed set $C$ in $D$, we know $H=G/P$ acts on $D$. Then $\widehat {D}$ covers $D$, and the group $H_{\widehat {D}}$ of liftings of $H$-actions to $\widehat {D}$ fits into an exact sequence

(6.4)\begin{equation} 1\to\pi_{\widehat{D}}\to H_{\widehat{D}}\to H\to 1. \end{equation}

Here $\pi _{\widehat {D}}$ is the subgroup of translations $a\in \pi$ satisfying $a\widehat {D}=\widehat {D}$, and (6.4) is part of (6.3). Let $\widehat {F}_D$ be the pullback of $g^{-1}(D)\cap X^P\to D\leftarrow \widehat {D}$, then the restriction of $g^P$ induces a ${\mathbb {Z}}_{p^k}[H_{\widehat {D}}]$-chain homology equivalence

(6.5)\begin{equation} g^P_*\colon C(\widehat{F}_D)\otimes{\mathbb{Z}}_{p^k} \to C(\widehat{D})\otimes{\mathbb{Z}}_{p^k}. \end{equation}

We note that $\Gamma _{\widehat {C}}/\Gamma _{\widehat {D}}\cong H$. In fact, by $\Gamma _{\widehat {C}}/\Gamma _{\widehat {D}}\subset H_{\widehat {D}}$, we have a splitting of (6.4). For fixed $D,\widehat {D}$, the other choices of $\widehat {C}\subset \widehat {D}$ over the same $C$ give $\pi _{\widehat {D}}$-conjugations of the splitting. These conjugations are in one-to-one correspondence with the conjugations of the pair $(\Gamma _{\widehat {C}},\Gamma _{\widehat {D}})$. Therefore, $\Gamma _{CD}$ is also the $\pi _{\widehat {D}}$-conjugacy class of the splittings of (6.4).

Let $\gamma \in \Gamma _{\widehat {C}}/\Gamma _{\widehat {D}}$ correspond to a generator of the cyclic group $H$. Since $p$ and $n$ are coprime, the order $n=|H|=|\Gamma _{\widehat {C}}/\Gamma _{\widehat {D}}|$ is invertible in the ring ${\mathbb {Z}}_{p^k}$. Therefore, both chain complexes in (6.5) consist of projective ${\mathbb {Z}}_{p^k}[H_{\widehat {D}}]$-modules, and the homology equivalence is a ${\mathbb {Z}}_{p^k}[H_{\widehat {D}}]$-chain homotopy equivalence. Then we may apply the same idea as in the proof of theorem 6.2, with ${\mathbb {Q}}$ replaced by ${\mathbb {Z}}_{p^k}$, and get a similar conclusion. We fix $C_0,D_0,\widehat {C}_0,\widehat {D}_0$, and get the generator $\gamma \in \Gamma _{\widehat {C}_0}/\Gamma _{\widehat {D}_0}\subset H_{\widehat {D}_0}$. Using the conjugacy class $\Gamma _{CD_0}$ explained above, we conclude

\[ \sum_{\langle\gamma\rangle\in \Gamma_{CD_0}}\chi(F_C) =\sum_{\langle\gamma\rangle\in \Gamma_{CD_0}}\chi(C)\quad \text{mod}\ p^k. \]

Here the equality is mod $p^k$ because it is an equality in ${\mathbb {Z}}_{p^k}$. We note that $\langle \gamma \rangle \in \Gamma _{CD_0}$ is the same as $\Gamma _{CD_0}=\Gamma _{C_0D_0}$. Moreover, this equality holds mod $p^k$ for all $k$, which means the equality holds as integers.

Acknowledgements

Sylvain Cappell’s research was partially supported by NYU Silver Professorship. Shmuel Weinberger’s research was partially supported by NSF grant DMS-2105451. Min Yan’s research was supported by Hong Kong RGC General Research Fund 16308018.

Footnotes

1 Recall that for $G$ trivial, according to West's celebrated theorem [Reference West20], any finite dimensional compact ANR is homotopy equivalent to a finite CW-complex. When $G$ is non-trivial, as examples of Quinn [Reference Quinn15, Reference Quinn16] show, this is not true. Moreover, elementary examples show that there is no analogue of Oliver's theorem for general topological actions.

References

Bartsch, T.. On the existence of Borsuk-Ulam theorems. Topology 31 (1992), 533543.CrossRefGoogle Scholar
Bass, H.. Euler characteristics and characters of discrete groups. Invent. Math. 35 (1976), 155196.CrossRefGoogle Scholar
Bridson, M. and Haefliger, A.. Metric spaces of non-positive curvature (Berlin, Heidelberg: Springer-Verlag, 1999).CrossRefGoogle Scholar
Cappell, S., Weinberger, S. and Yan, M.. Fixed point sets and the fundamental group I: Semi-free actions on G-CW-complexes. Proceedings of the Royal Society of Edinburgh Section A: Mathematics (2023), 1–22, doi:10.1017/prm.2023.63.CrossRefGoogle Scholar
Davis, M.. Groups generated by reflections and aspherical manifolds not covered by Euclidean space. Ann. Math. 117 (1983), 293324.CrossRefGoogle Scholar
Davis, M. and Hausmann, J. C.. Aspherical manifolds without smooth or PL structure. LNM 1370 (1986), 135142.Google Scholar
Hattori, A.. Rank element of a projective module. Nagoya J. Math. 25 (1965), 113120.CrossRefGoogle Scholar
Jones, L.. The converse to the fixed point theorem of P.A. Smith: I. Ann. Math. 94 (1971), 5268.CrossRefGoogle Scholar
Morimoto, M. and Iizuka, K.. Extendability of $G$-maps to pseudo-equivalences to finite $G$-CW-complexes whose fundamental groups are finite. Osaka J. Math. 21 (1984), 5969.Google Scholar
Oliver, R.. Fixed-point sets of group actions on finite cyclic complexes. Comment. Math. Helvetici 50 (1975), 155177.CrossRefGoogle Scholar
Oliver, R.. Smooth compact Lie group actions on disks. Math. Z. 149 (1976), 7996.CrossRefGoogle Scholar
Oliver, R.. $G$-actions on disks and permutation representations. J. Algebra 50 (1978), 4462.CrossRefGoogle Scholar
Oliver, R.. $G$-actions on disks and permutation representations II. Math. Z. 157 (1977), 237263.CrossRefGoogle Scholar
Oliver, R. and Petrie, T.. $G$-CW-surgery and $K_0(\mathbb {Z}G)$. Math. Z. 179 (1982), 1142.CrossRefGoogle Scholar
Quinn, F.. Ends of maps II. Invent. Math. 68 (1982), 353424.CrossRefGoogle Scholar
Quinn, F.. Homotopically stratified sets. JAMS 1 (1988), 441499.Google Scholar
Smith, P. A.. Fixed-Point theorems for periodic transformations. Am. J. Math. 63 (1941), 18.CrossRefGoogle Scholar
Stallings, J.. Centerless groups – an algebraic formulation of Gottlieb's theorem. Topology 4 (1965), 129134.CrossRefGoogle Scholar
Weinberger, S.. A fixed point theorem for periodic maps on locally symmetric manifolds. Algebra Anal. 29 (2017), 6069. Reprinted in St. Petersburg Math. J., 29 (2018), 43–50.Google Scholar
West, J.. Mapping Hilbert cube manifolds to ANR's: a solution of a conjecture of Borsuk. Ann. Math. 106 (1977), 118.CrossRefGoogle Scholar