ABSOLUTELY CONTINUOUS INVARIANT MEASURES OF PIECEWISE LINEAR LORENZ MAPS YIMINGDING,AIHUAFANANDJINGHUYU 0 1 Abstract. Consider piecewise linear Lorenz maps on [0, 1] of the following 0 form 2 ax+1−ac x∈[0,c) n fa,b,c(x)=(cid:26) b(x−c) x∈(c,1]. a We prove that fa,b,c admits an absolutely continuous invariant probability J measure(acim)µwithrespecttotheLebesguemeasureifandonlyiffa,b,c(0)≤ 8 fa,b,c(1), i.e. ac+(1−c)b≥1. Theacim isunique and ergodicunless fa,b,c 1 isconjugatetoarationalrotation. Theequivalencebetweentheacimandthe Lebesguemeasureisalsofullyinvestigated viatherenormalizationtheory. ] S D . h 1. Introduction t a m Lorenz maps are one-dimensional maps with a single singularity, which arise [ as Poincar´e return maps for flows on branched manifolds that model the strange attractors of Lorenz systems. A Lorenz map on the interval I := [0,1] is a map 1 v f :I I such that for some critical point c (0,1) we have → ∈ 4 (i) f is continuous and strictly increasing on [0,c) and on (c,1]; 1 (ii) lim f(x)=1, lim f(x)=0. x↑c x↓c 0 A Lorenz map f is said to be piecewise linear if it is linear on both intervals [0,c) 3 and (c,1]. Such a map is of the form . 1 0 ax+1 ac x [0,c) 0 (1. 1) fa,b,c(x)=(cid:26) b(x c)− x∈(c,1], 1 − ∈ : where a>0,b>0, 0<c<1, ac 1 and b(1 c) 1. v ≤ − ≤ i Let β >1. The map Tβ(x)=βx ( mod 1) is the well known β-shift related to X β-expansion ([25]). Assume 0 α<1. The transformation T defined by β,α r ≤ a T (x)=βx+α ( mod 1) β,α is a natural generalization of β-shift. There are many works done on T (see β,α [11, 13, 16, 21, 22, 23, 24, 26]). When 1<β 2, T is a piecewise linear Lorenz β,α ≤ map. In fact, T = f with c = (1 α)/β. Recently, Dajani et al [5] studied β,α β,β,c − another variation S of β-shift. For 0<α<1 and 1<β <2, β,α βx x [0, 1/β) (1. 2) Sβ,α(x)=(cid:26) α(x 1/β) x∈(1/β, 1], − ∈ which is the piecewise linear Lorenz map f . β,α,1/β Lorenz maps arise as return maps to a cross-section of a semi-flow on a two dimensional branched manifold (cf. [1], [15], [27]). The flow lines starting from c never return to I. So usually the map is considerednot defined at c (cf. [12]). But it is also convenient to regard c as two points c+ and c , the right and left of c, − 1 2 AcimsofpiecewiselinearLorenzmaps so that the Lorenz map is a continuous map defined on the disconnected compact space [0, c ] [c+, 1]. Differentdynamicalaspects of Lorenzmaps are studied in − theliteraturesSsuchasrotationinterval,asymptoticperiodicity,topologicalentropy and renormalization etc (see [2], [7], [8], [12]). In this paper we shall study the absolutely continuous invariant probability measures (acim for short) of piecewise linearLorenzmaps. Theexistenceofacimandtheequivalenceofacimwithrespect to the Lebesgue measure are studied. The Lebesque measure is clearly quasi invariant under f . Let P be the a,b,c a,b,c associated Perron-Frobenius operator and let n−1 1 A (h)= Pi h, h L1([0,1]). n n a,b,c ∈ Xi=0 Our results are stated in the following two theorems. Theorem A. The piecewise linear Lorenz map f admits an absolutely contin- a,b,c uous invariant probability measure µ with respect to the Lebesgue measure if and only if f (0) f (1), i.e. ac+b(1 c) 1. More precisely, a,b,c a,b,c ≤ − ≥ (1) If ac+b(1 c) = 1 and loga/logb is rational, then there exists positive − integer n such that fn (x) = x for all x [0,1]. Consequently, for each a,b,c ∈ density g on [0, 1], A (g) is the density of an invariant measure of f . n a,b,c (2) If ac+b(1 c) = 1 and loga/logb is irrational, then the acim is unique − and its density is bounded from below and from above by the two constants a 4 a −4 and . b b (cid:16) (cid:17) (cid:16) (cid:17) (3) If ac+b(1 c) > 1, then the acim is unique and its density is of bounded − variation. (4) If ac+b(1 c)<1, then f admits no acim. a,b,c − It is well known to Lasota and Yorke ([19]) that a strongly expanding interval map f (i.e. f′(x) > λ > 1 except finite points) admits an acim with respect to | | the Lebesgue measure. It is also known that a piecewise linear Lorenz map with a fixed point also admits an acim with respect to the Lebesgue measure (cf. [5, 6]). These results don’t apply to the Lorenz maps defined by (1. 1) which, in general, are not strongly expanding and admit no fixed point. Suppose thatf admits a unique acimwith respectto the Lebesgue measure. a,b,c Iff isahomeomorphism(i.e.,ac+b(1 c)=1)withirrationalrotationnumber, a,b,c − we shall see from the proof of Theorem A that the acim of f is equivalent to a,b,c the Lebesgue measure. If ac+b(1 c) > 1, the acim is not necessarily equivalent − to the Lebesgue measure, even if f is strongly expanding (i.e.a>1 and b>1). a,b,c For example,Parry[24]provedthat the acimof symmetric piecewise linear Lorenz map f is not equivalent to the Lebesgue measure if and only if 1 < a < √2. a,a,1/2 We point out that the support of the acim of T was studied in [11, 16]. β,α Assume that ac+ b(1 c) > 1. As we shall see in Lemma 4.1, the acim of − f is equivalent to the Lebesgue measure if and only if f is transitive, i.e. a,b,c a,b,c fn (U) is dense in I for each non-empty open set U I. In general, the n≥0 a,b,c ⊂ tSransitivityofaLorenzmapisnoteasytocheck. Palmer[21]studiedthetransitivity of T by using so-called primary cycle (see also [11]). Alves et al introduced a β,α topologicalinvariant to study the transitivity of T ([3]). The conditions of both β,α primary cycle and the topologicalinvariantof Alves et al are difficult to check too. We will provide a rather simple criterionof the transitivity for the piecewise linear Lorenz maps f with ac+b(1 c)>1. a,b,c − Yi-MingDingAi-HuaFanandJing-HuYu 3 Let us describe our criterion. Assume ac+b(1 c) > 1. Then f admits a,b,c − periodic points, because it admits positive topological entropy ([2]). Let κ be the minimal period of the periodic points of f . Assume 2 κ < . Then f a,b,c a,b,c ≤ ∞ admits a unique κ periodic orbit. Let P and P be adjacent κ periodic points L R − − such that c [P , P ]. It can be proved that fκ is linear on [P , c) and on ∈ L R a,b,c L (c, P ] (Lemma 2.6). Write R A:=fκ (c+), B :=fκ (c ). a,b,c a,b,c − That κ = 2 means f has no fixed point, f (0) = A < B = f (1) and a,b,c a,b,c a,b,c c [A, B]. When κ=2, let ∈ c A B c M :=min − , − . (cid:26)B c c A(cid:27) − − Theorem B. Suppose ac+b(1 c) > 1. If κ = 1, then the acim of f is a,b,c − equivalent to the Lebesgue measure. If 2 κ < , then the acim of f is a,b,c ≤ ∞ equivalent to the Lebesgue measure if and only if [A, B] [P , P ]= or [A, B]=[P , P ]. L R L R \ 6 ∅ In particular, when κ=2, the acim of f is equivalent to the Lebesgue measure a,b,c if and only if ab>1+M if M <1 (cid:26) ab 2 if M =1. ≥ See Figure 1 for a piecewise linear map whose acim is not equivalent to the Lebesgue measure. Parry [24] proved that the acim of f (1 < a 2) is not equivalent to the a,a,1/2 ≤ Lebesgue measure if and only if 1 < a < √2. This may be obtained as a special case of Theorem B. We shall collect some basic useful facts in 2, including rotation number, Lya- § punov exponent, Frobenius-Perron operator and renormalization. Theorem A is provedin 3 andTheoremB in 4. Densities ofsome piecewise linear Lorenzmaps § § will be presented in 5. § 2. Preliminaries In this section, we present some facts concerning the rotation number, Lya- punov exponent, Frobenius-Perron operator and the renormalization of Lorenz maps, which will be useful later. 2.1. Rotation number and Lyapunov exponent. We denote by e : R S1 = z C : z = 1 the natural covering map → { ∈ | | } e(x) = exp(2πix). Let f be a Lorenz map, not necessarily linear. There exists a map F : R R such that e F = f e and F(x+1) = F(x)+1. F is called → ◦ ◦ a degree one lifting of f. Furthermore, if F(0) = f(0), then there exists a unique such lifting (cf. [2]). The rotation number of f at x is defined by Fn(x) x ρ(x)=limsup − . n→∞ n 4 AcimsofpiecewiselinearLorenzmaps f(1) f(0) 0 PL C PR 1 Figure 1. A piecewise linear Lorenz map with κ = 2, and [f2(c+), f2(c )] = [f(0), f(1)] (P , P ), whose acim is not L R − ⊆ equivalent to the Lebesgue measure. Itisknownthatthesetofallrotationnumbersρ(x)off isanintervalandthatthis interval is reduced to a singleton when f(0)=f(1) ([17]). The rotation number is tightly relate to the number of returns of x into the interval (c, 1], defined by (2. 1) m (x)=# 0 i<n:fi(x) (c, 1] n ≤ ∈ (cid:8) (cid:9) Lemma 2.1. Let f be a Lorenz map (not necessarily piecewise linear). Let F be the unique degree one lifting map of f such that F(0)=f(0). Then for any n 1 ≥ and any x [0, 1] we have ∈ Fn(x)=m (x)+fn(x). n Proof. The proof of this Lemma would be found in the literatures, we give a proof for completeness. We prove it by induction. First note that F(x) x [0,c) f(x)= ∈ (cid:26) F(x) 1 x (c,1] − ∈ which implies the desired equality for n=1: F(x)=1 (x)+f(x). (c, 1] Supposenowthattheequalityistrueforanarbitraryn. SinceF(x+k)=F(x)+k for all positive integers k, by the hypothesis of induction we have n−1 Fn+1(x)=F(Fn(x))= 1 (fi(x))+F(fn(x)). (c, 1] Xi=0 Yi-MingDingAi-HuaFanandJing-HuYu 5 According to what we have proved for n = 1, we get F(fn(x)) = 1 (fn(x))+ [c,1) fn+1(x) so that n Fn+1(x)= 1 (fi(x))+fn+1(x)=m (x)+fn+1(x). (c, 1] n+1 Xi=0 (cid:3) Write C = f−n(c). f n[≥0 When f =f we write C :=C . The Lyapunov exponent of f at x / C a,b,c a,b,c fa,b,c ∈ f is defined by 1 λ(f,x)=limsup log(fn)′(x). n→∞ n For piecewise linear Lorenz map f , a,b,c dfn (x) (2. 2) a,b,c =an−mn(x)bmn(x), x C . a,b,c dx ∀ ∈ For any linear Lorenz map such that f (0) = f (1), its rotation number a,b,c a,b,c and its Lyapunov exponent are determined in the following way. Lemma 2.2. Let f be a piecewise linear Lorenz map such that f (0) = a,b,c a,b,c f (1). Let ρ be the rotation number of f . Then we have a,b,c a,b,c Fn(x) x (2. 3) lim sup − ρ =0. n→∞x∈[0,1](cid:12)(cid:12) n − (cid:12)(cid:12) (cid:12) (cid:12) The rotational number ρ is the soluti(cid:12)on of the equati(cid:12)on a1−ρbρ =1. The number ρ is rational if and only if loga/logb is rational. Furthermore, we have λ(f ,x)=0 ( x / C ). a,b,c a,b,c ∀ ∈ Proof. The uniform convergence follows from the observation Fn(0)<Fn(x)<Fn+1(0) ( x [0, 1]) ∀ ∈ Fn(0) and the fact that ρ= lim . n→∞ n According to Lemma 2.1, the rotation number ρ of f is nothing but the a,b,c frequency of visits to (c, 1] of any given point of [0, 1]. Since f is piecewise a,b,c linear, for x / C we have a,b,c ∈ n−1 (2. 4) (fn )′(x)= f′ (fi (x))=an−mn(x)bmn(x) a,b,c a,b,c a,b,c iY=0 where m (x) is defined by (2. 1). It follows that n 1 λ(f ,x)= lim logan−mn(x)bmn(x) =loga1−ρbρ. a,b,c n→∞n Let λ = loga1−ρbρ. We will prove a1−ρbρ = 1 by showing λ = 0, which implies that logb ρ=1+ . loga logb − 6 AcimsofpiecewiselinearLorenzmaps So ρ is rational if and only if loga/logb is rational. Suppose λ > 0. According to Lemma 2.1, (2. 3) and (2. 4), there exists a positive integer N such that (fN )′(x)>1 ( x / C ). a,b,c ∀ ∈ a,b,c This and the piecewise linearity of f imply that fN is piecewise expanding. a,b,c a,b,c However,it is not possible because fN is a homeomorphism. Thus λ 0. In the a,b,c ≤ same way, one proves λ 0 by considering f−1 . Hence we get λ=0. (cid:3) ≥ a,b,c Lemma 2.3. Let f be a piecewise linear Lorenz map such that f (0) = a,b,c a,b,c f (1). Let ρ be the rotation number of f . If ρ is irrational, then a,b,c a,b,c (2. 5) m (x) nρ 4 ( x [0, 1], n 1). n | − |≤ ∀ ∈ ∀ ≥ Proof. Since ρ is irrational, f is topologically conjugate to the rigid irrational a,b,c rotation R , i.e. R (x) = ρ+x (cf. [20], p. 38-39). In other words, there exists a ρ ρ continuous strictly increasing function π on [0, 1] onto [0, 1] such that (2. 6) π f π−1 =R . a,b,c ρ ◦ ◦ Let F, G and G−1 be the degree one lifting map of f , π and π−1 respectively. a,b,c The lifted form of (2. 6) is G F G−1(x)=x+ρ. ◦ ◦ By induction, we have (2. 7) G Fn G−1(x)=x+nρ. ◦ ◦ Write m (x) nρ m (x) Fn(x) + Fn(x) G Fn(x) n n | − | ≤ | − | | − ◦ | (2. 8) + G Fn(x) G Fn G−1(x) | ◦ − ◦ ◦ | + G Fn G−1(x) nρ. | ◦ ◦ − | Now we estimate the four terms on the righthand side. Notice first that F, G and G−1 areincreasingfunctions onRandthatF(x) x, G(x) xandG−1(x) x are − − − 1-periodic functions on R taking with values in [0,1]. So when x y 1 we have | − |≤ (2. 9) F(x) F(y) 1, G(x) G(y) 1, G−1(x) G−1(y) 1. | − |≤ | − |≤ | − |≤ According to Lemma 2.1, we have the following estimate for the first term: m (x) Fn(x) 1. n | − |≤ The fact 0 G(x) x 1 implies immediately an estimate for the second term: ≤ − ≤ Fn(x) G Fn(x) 1. | − ◦ |≤ Repeatingthefirstinequalityin(2. 9)weget Fn(x) Fn(y) 1when x y 1. | − |≤ | − |≤ This and the fact G−1(x) x 1 imply an estimate for the third term: | − |≤ G Fn(x) G Fn G−1(x) 1. | ◦ − ◦ ◦ |≤ A direct consequence of (2. 7) is the following estimate for the fourth term: G Fn G−1(x) nρ 1. | ◦ ◦ − |≤ The estimation (2. 5) is thus proved. (cid:3) Yi-MingDingAi-HuaFanandJing-HuYu 7 a a a 0 b b 0 b 0 c 1 0 c 1 Figure 2. The comparisons between piecewise linear Lorenz maps. 2.2. Comparison of rotation numbers in different maps. Let f be a a,b,c piecewise linear Lorenz map. If a > 1 and b > 1, it is well known that f is a,b,c expanding and then admits a unique acim. If a<1 and b<1, f is contracting a,b,c and then admits no acim. So we may assume that a > 1 b or b > 1 a. In ≥ ≥ thesecases,wewillcomparef withhomeomorphicpiecewiselinearLorenzmaps a,b,c f andf ,wherea = 1−b(1−c) andb = 1−ac. SeeFigure2forthepictures a0,b,c a,b0,c 0 c 0 1−c of f and f . More precisely, in the case a>1 b, we compare f with a0,b,c a,b0,c ≥ a,b,c a x+1 ac x [0, c) (2. 10) fa0,b,c(x)=(cid:26) b(0x c)− x∈(c, 1] − ∈ if f (0)<f (1), and compare f with a,b,c a,b,c a,b,c ax+1 ac x [0, c) (2. 11) fa,b0,c(x)=(cid:26) b0(x −c) x∈(c, 1] − ∈ if f (0)>f (1). a,b,c a,b,c In the case b > 1 a, we compare f with f when f (0) > f (1), ≥ a,b,c a,b0,c a,b,c a,b,c and compare f with f when f (0)<f (1). a,b,c a0,b,c a,b,c a,b,c Lemma 2.4. Let f and f be defined as above. We have the following a0,b,c a,b0,c conclusions: (1) If f (0)<f (1), then for all x [0,1], a,b,c a,b,c ∈ ρ(f ,x) ρ(f ) if a>1 b a,b,c ≤ a0,b,c ≥ (cid:26) ρ(fa,b,c,x)≥ρ(fa,b0,c) if a≤1<b. (2) If f (0)>f (1), then for all x [0,1], a,b,c a,b,c ∈ ρ(f ,x) ρ(f ) if a 1>b a,b,c ≥ a0,b,c ≥ (cid:26) ρ(fa,b,c,x)≤ρ(fa,b0,c) if a<1≤b. Proof. Let F be the degree one lifting of f and F be the degree one lifting of a,b,c 0 f . For the case f (0) < f (1) and a > 1 b, since f (x) f (x) a0,b,c a,b,c a,b,c ≥ a,b,c ≤ a0,b,c forallx∈[0, 1],wehaveF(y)≤F0(y)forally ∈R. ItfollowsthatFn(y)≤F0n(y) ofotrheyr∈inRequaanlditifeosrceavnerbyepsoimsitiliavrelyinptergoevredn.. Therefore ρ(fa,b,c,x) ≤ ρ(fa,b0,c). Th(cid:3)e 8 AcimsofpiecewiselinearLorenzmaps 2.3. Frobenius-Perronoperatorandinvariantdensity. TheFrobenius-Perron operator associated with f is defined as follows: for any h L1(I), a,b,c ∈ 1[1−ac, 1](x) x (1 ac) 1[0, b(1−c)](x) x+bc P h(x)= h − − + h . a,b,c a (cid:18) a (cid:19) b (cid:18) b (cid:19) The invariant density h of the Frobenius-Perronoperator corresponds to an acim ∗ µ of f , µ(A) = h dm, where A is a Borel set and m is the Lebesgue a,b,c A ∗ ∈ B measure on I. R Lemma 2.5. Let P be the Frobenius-Perron operator associated with f . Then a,b,c we have the following statements: (1) If there exists positive integer n 1 such that fn (x) = x for all x I, ≥ a,b,c ∈ then for each density g on [0, 1], A (g) is an invariant density of P . n a,b,c (2) If there exists a constant r >0 such that for all positive integer n, rm(A) m(f−n (A)) m(A)/r, A , ≤ a,b,c ≤ ∀ ∈B then f admits a unique acim whose density is bounded by r and 1/r. a,b,c (3) Ifthereexists apositive integer nsuchthat fn is stronglyexpanding, i.e., a,b,c (fn )′(x) >λ >1 for all x I except finite points, then f admits an a,b,c ∈ a,b,c acim whose density is of bounded variation. (4) If there exists a positive integer n such that (fn )′(x) < λ < 1 for all a,b,c x I except finite points, then f admits no acim. a,b,c ∈ Proof. The assertions (1) and (4) are obvious. The assertion (3) is a direct con- sequence of Lasota and Yorke’s Theorem ([18, 19]). Now we prove (2). The as- sumption in this case means that r Pn 1 1/r. So A (1) is weakly ≤ a,b,c ≤ { n }n≥0 precompactin L1(I). From the weaklycompactness of A (1) we canextract n n≥0 { } a subsequence A (1) that converges weakly to g and P g =g. By the abstract nk a,b,c ergodic Theorem of Kakutani and Yosida ([18]), A (1) converges strongly to g. n This implies that g is an invariant density of P and r g(x) 1/r. (cid:3) a,b,c ≤ ≤ In the third case, f is said to be eventually piecewise expanding [14]. a,b,c 2.4. Renormalization of Lorenz map. Let f be a piecewise linear Lorenz a,b,c map satisfying ac+b(1 c) > 1. The equivalence between the acim of f and a,b,c − the Lebesgue measure is a question of transitivity of f (see Lemma 4.1). One a,b,c can describe the transitivity of f by using the device of renormalization. a,b,c A Lorenz map f : I I is said to be renormalizable if there is a proper subin- → terval [u, v] which contains the critical point c, and integers ℓ,r>1 such that the map g :[u, v] [u, v] defined by → fℓ(x) x [u, c), (2. 12) g(x)= ∈ (cid:26) fr(x) x (c, v], ∈ is itself a Lorenz map on [u, v]. A Lorenz map f is said to be expanding if the preimages of the critical point is denseinI. TherenormalizationtheoryofexpandingLorenzmapiswellunderstood (see [7, 12]). The transitivity of an expanding Lorenz map can be characterizedby its renormalization. For example, f is transitive if it is not renormalizable ([7]). Letf be anexpandingLorenzmap. The renormalizabilityoff is closelyrelated to the periodic orbit with minimal period. Denote κ the smallest period of the periodic points of f. If κ=1 (i.e., f admits a fixed point), we must have f(0)=0 or f(1)=1 because f is expanding. It follows that f is transitive ([7]). If κ = , ∞ Yi-MingDingAi-HuaFanandJing-HuYu 9 i.e. f admits no periodic point, then f is topologically conjugates to an irrational rotation on the circle because f is expanding ([12]). For the case 1 < κ < , we ∞ have the following Lemma. Lemma 2.6. ([7]) Let f : [0, 1] [0, 1] be an expanding Lorenz map with 1 < → κ< . ∞ (1) The minimal period of f is equal to κ=m+2, where m=min i 0:f−i(c) [f(0), f(1)] . { ≥ ∈ } (2) f admits a unique κ-periodic orbit O. (3) Let P and P be adjacent points in O such that c [P , P ]. Then fκ is L R L R ∈ continuous on [P , c) and on (c, P ]. Moreover, we have L R κ−1 (2. 13) fi([P , P ])=I. L R i[=0 For general expanding Lorenz map f, it is difficult to check wether f is renor- malizable or not. However, for piecewise linear Lorenz map f satisfying ac+ a,b,c b(1 c)>1, one can check the renormalizability easily. According to the proof of − Theorem A, f is expanding. Denote O as the κ-periodic orbit, and a,b,c D := f−n (O). a,b,c n[≥0 Lemma 2.7. ([4]) If D =O, then f is not renormalizable. a,b,c 6 3. Existence of absolutely continuous invariant measure Now we prove Theorem A by distinguishing four cases: f (0)=f (1) and a,b,c a,b,c loga/logb is rational, f (0) = f (1) and loga/logb is irrational, f (0) < a,b,c a,b,c a,b,c f (1) andf (0)>f (1). In the firstcase,we will show that some powerof a,b,c a,b,c a,b,c f is identity, i.e., there exists n>0 such that fn (x)=x for all x I. In the a,b,c a,b,c ∈ second case we will prove rm(A) m(f−n (A)) m(A)/r, A , ≤ a,b,c ≤ ∀ ∈B for some constant r and n 0. In the third case we will show that some power ≥ of f is expanding. In the forth case, we will compare f with a suitable a,b,c a,b,c homeomorphic piecewise linear Lorenz map and prove that some power fn is a,b,c contracting. 3.1. Proof of Theorem A when f (0) = f (1) and loga/logb is ratio- a,b,c a,b,c nal. According to Lemma 2.5, it suffice to prove the following proposition. Proposition 3.1. Suppose f (0) = f (1) and loga/logb is rational. Then a,b,c a,b,c there exists positive integer n such that fn (x)=x for all x I. a,b,c ∈ Proof. In this case, f can be regarded as a homeomorphism on the unit circle. a,b,c Since loga/logb is rational, the rotation number of f is also rational (Lemma a,b,c m 2.2). Write ρ(f )= with (m, n) = 1. We shall prove that fn (x) = x for a,b,c n a,b,c all x [0, 1]. ∈ 10 AcimsofpiecewiselinearLorenzmaps m Sinceρ(f )= , f admitsann periodicorbit([2]). Letp <p < < a,b,c a,b,c 1 2 n − ··· p be an n-periodic orbit. The orbit forms a partition of I: n [p , p ), ,[p , p ), [p ,1] [0,p ), 1 2 n−1 n n 1 ··· ∪ and f maps one subinterval onto the next one in the partition. Each subin- a,b,c terval in the partition contains only one point in C . Since ρ(f ) = m, a,b,c a,b,c n c [p ,p ). n−m n−m+1 ∈ If c doesn’t belong to the periodic orbit, c (p , p ). Consider the n−m n−m+1 ∈ interval[p ,c),itfollowsthatfn iscontinuousandlinearon[p ,c)because n−m a,b,c n−m fn has only one discontinuity c in [p ,p ]. Notice that fn (p ) = a,b,c n−m n−m+1 a,b,c n−m p and (fn )′(p ) = 1, we obtain that fn (x) = x on [p ,c), which n−m a,b,c n−m a,b,c n−m implies that c is an n-periodic point. So 1 is also an n-periodic point. − We denote the n-periodic orbit of 1 as 0 < q < q < < q < q = 1 2 n−m−1 n−m ··· c < q < < q = 1. Since fn is linear on [q ,q ), it follows that n−m+1 ··· n a,b,c i i+1 fn (x)=x on [q ,q ), i=1,2,...,n. So fn (x)=x on I. (cid:3) a,b,c i i+1 a,b,c 3.2. Proof of Theorem A when f (0) = f (1) and loga/logb is irra- a,b,c a,b,c tional. Inthiscase,accordingtoLemma2.5,wehaveonlytoprovethefollowingpropo- sition. Proposition 3.2. Suppose f (0) = f (1) and loga/logb is irrational, there a,b,c a,b,c exists a constant r >0 such that rm(A) m(f−n (A)) m(A)/r, A . ≤ a,b,c ≤ ∀ ∈B 1 b Proof. The condition f (0) = f (1) means c= − . Consider f := a,b,c a,b,c a b a1,b1,c1 f−1 , the inverse map of f . It is also a piecewise lin−ear Lorenz map such that a,b,c a,b,c f (0)=f (1). In fact, we have a1,b1,c1 a1,b1,c1 1 1 (a 1)b (3. 1) a = , b = , c = − . 1 1 1 b a a b − Let ρ:=ρ(f ) be its rotation number. Write a1,b1,c1 m∗(x)=# 0 i<n:fi (x) (c , 1] . n ≤ a1,b1,c1 ∈ 1 By Lemma 2.2, we have a1−ρb(cid:8)ρ =1. Thus for all x / C ,(cid:9)we have 1 1 ∈ a1,b1,c1 (fn )′(x) = an−m∗n(x)bm∗n(x) a1,b1,c1 1 1 m∗(x)−nρ m∗(x)−nρ b n b n = an(1−ρ)bnρ 1 = 1 . 1 1 ·(cid:18)a (cid:19) (cid:18)a (cid:19) 1 1 Accordingto Lemma 2.3, m∗(x) nρ 4. Itfollowsthat for all x / C and | n − |≤ ∈ a1,b1,c1 all n 0 we have ≥ r (fn )′(x) 1/r, ≤ a1,b1,c1 ≤ where r = min b4a−4, b−4a4 = min b4a−4, b−4a4 . Consequently, by making a { 1 1 1 1} { } change of variables we get rm(A) m(f−n (A)) = 1 (fn (x))dx ≤ a,b,c Z A a,b,c = 1 (y) (fn )′(y)dy m(A)/r. Z A · a1,b1,c1 ≤ (cid:3)