Journal of Inequalities in Pure and Applied Mathematics NORM INEQUALITIES IN STAR ALGEBRAS A.K. GAUR Math Department Duquesne University Pittsburgh, PA 15282, U.S.A. EMail: Gaur@mathcs.duq.edu volume 3, issue 1, article 1, 2002. Received 21 June, 2001; accepted 21 June, 2001. Communicated by: S.P. Singh Abstract Contents JJ J II I Home Page Go Back Close c 2000 Victoria University ISSN (electronic): 1443-5756 051-01 Quit Abstract A norm inequality is proved for elements of a star algebra so that the algebra is noncommutative. In particular, a relation between maximal and minimal extensions of regular norm on a C ∗ -algebra is established. 2000 Mathematics Subject Classification: 46H05, 46J10, 47A50. Key words: W ∗ -algebras, C ∗ -algebras, Self-adjoint elements (operators), Maximal and minimal extensions of a regular norm, Furuta type inequalities. Contents References Norm Inequalities in Star Algebras A.K. Gaur Title Page Contents JJ J II I Go Back Close Quit Page 2 of 12 J. Ineq. Pure and Appl. Math. 3(1) Art. 1, 2002 http://jipam.vu.edu.au Let H be a Hilbert space and B(H) be the algebra of all bounded linear operators on H. A subset of B(H) is a W ∗ -algebra on H if X is a C ∗ -algebra which is closed in the weak operator topology, see [1]. Also, a W ∗ -algebra is a C ∗ -subalgebra of B(H) which is weakly closed. In particular, a W ∗ -algebra is an algebra of operators. We note that a C ∗ -algebra acting on H is commutative if and only if zero is the only nilpotent element of the algebra. Let X be a W ∗ -algebra and XSA be the set of self-adjoint elements of X, that is if T ∈ S (X) =⇒ T = T ∗ , where T ∗ is the adjoint of T . Here we prove the following theorem. Norm Inequalities in Star Algebras A.K. Gaur ∗ Theorem 1. A unital W -algebra X of operators is noncommutative if ∀A, B ∈ XSA , kAk = 1 = kBk =⇒ kA + Bk > 1 + kABk . Proof. Since X is noncommutative, there exists an operator T in X such that T 2 = 0. Suppose X1 is the range of T and X2 is the orthogonal complement of X1 . Then H = X1 ⊕ X2 . Let S be an operator with kSk = 1. Then 0 S 0 0 ∗ T = and T = . 0 0 S∗ 0 We use these representations for T and T ∗ to define the operators A and B as follows: For σ1 > 0, σ2 > 0 and σ1 + σ2 = 1, we have SS ∗ 0 A= = T T ∗, 0 0 Title Page Contents JJ J II I Go Back Close Quit Page 3 of 12 J. Ineq. Pure and Appl. Math. 3(1) Art. 1, 2002 http://jipam.vu.edu.au B= σ1 SS ∗ σ2 S σ2 S ∗ σ1 S ∗ S = σ1 (T T ∗ + T ∗ T ) + σ2 (T + T ∗ ) . Clearly, A = A∗ , B = B ∗ and A, B ∈ X. Next, we consider the following two cases. Case 1. Let σ1 = σ2 = 12 and 1 1 SS ∗ S B= = (T T ∗ + T ∗ T + T + T ∗ ) . ∗ ∗ S S S 2 2 It is not difficult to see that kAk = 1 and kBk ≤ 1. To obtain kBk ≥ 1, let kSk = 1 then ∃an ∈ X 3: kan k = 1. Also, ∗ 2 ∗ 2 ∗ 2 and if kS ∗ an k → 1 then SS ∗ an − an → 0. Further, (Bb − b) → 0, where b = (an + S ∗ an ) and hence, kBk ≥ 1, which concludes that kBk = 1. Let 1 SS ∗ S AB = and S ∗ S ∗S 2 ∗ S 1 SS ∗ + SS2 2 A+B = = (T T ∗ + T ∗ T + T + T ∗ ) . S∗ S∗S 2 2 2 Choose an as above and bn = where µ > 1. Let 1 1 1 2 µ1 = σ1 + + σ2 + 2 4 A.K. Gaur 2 kSS an − an k = kSS an k − 2 kS an k + kan k ≤ 2 kan k2 − kS ∗ an k2 S ∗ an , (2µ−1) Norm Inequalities in Star Algebras Title Page Contents JJ J II I Go Back Close Quit Page 4 of 12 J. Ineq. Pure and Appl. Math. 3(1) Art. 1, 2002 http://jipam.vu.edu.au so that it satisfies the equation (µ1 − σ1 − 1) (µ1 − σ1 ) = σ22 . Then [(A + B) (an + bn ) − µ (an + bn )] → 0 and kA + Bk ≥ µ > 1. If we choose σ1 and σ2 so that 1 1 1 1 2 σ1 + + σ2 + > 1 + σ12 + σ22 2 , 2 4 Norm Inequalities in Star Algebras A.K. Gaur then we have kA + Bk > 1 + kABk . For example, it is sufficient to take σ1 = 32 and σ2 = 13 . We note that σ1 > σ2 . If √ σ1 < σ2 then the above inequality fails. Since µ > 1 + 2σ1 the proof in this case is complete. Case 2. Let σ1 6= σ2 . Then kABk ≤ a0 , (by mimicking the proof of Case 1), where q 2 2 2 a0 = sup σ1 kak + σ2 kbk : kak + kbk = 1 = σ1 + σ22 . Let bn (µ1 − σ1 ) = σ2 S ∗ an , where µ1 depends on σ1 and σ2 . Then kA + Bk ≥ µ p1 and one can have the following form of µ1 , that is, 2µ1 = (2σ1 + 1) + 1 + σ12 . Hence, µ1 > 1 + a0 and this concludes the proof of the theorem. Title Page Contents JJ J II I Go Back Close Quit Page 5 of 12 J. Ineq. Pure and Appl. Math. 3(1) Art. 1, 2002 http://jipam.vu.edu.au Remark 1. If X is commutative then for A, B ∈ XSA with kAk = 1 = kBk, we have 0 ≤ I − B − A + AB, where I is the identity operator. Thus kA + Bk ≤ 1 + kABk. Let 0 < p, q, r be real numbers such that q (2r + 1) ≥ (2r + p) and q ≥ 1. If two bounded linear operators A, B ∈ B (H) on a Hilbert space H satisfy p 1 2r 0 ≤ B ≤ A then (B r Ap B r ) q ≥ B q B q . This inequality is called the Furuta inequality and can be found in [3]. Recently, Kotaro and others in [6] have extended this inequality in a unital hermitian Banach ∗-algebras with continuous involution. We give a slightly different version of these inequalities in the following corollary. A.K. Gaur ∗ Corollary 2. Suppose that X is a C -algebra acting on H. Let λ, µ and σ be three real numbers with σ > 0, λ > 0. Then there exists operators T1 , T2 and T3 in X 3: λT1 + µT2 + σT3 ≥ 0 ⇐⇒ λσ ≥ µ2 . C∗ Proof. We recall that an operator O ∈ B (H) is positive if hOh, hi ≥ 0 for every vector h. Using the techniques of Theorem 1, the following operators belong to XC ∗ . That is, √ SS ∗ 0 0 SS ∗ S √ T1 = , T2 = , and 0 0 S ∗ SS ∗ 0 0 0 T3 = 0 S ∗S Title Page Contents JJ J II I Go Back Close Quit Page 6 of 12 are in XC ∗ . In this case we have λT1 + µT2 + σT3 = Norm Inequalities in Star Algebras √ ∗ ∗S λSS µ SS √ . µS ∗ SS ∗ σS ∗ S J. Ineq. Pure and Appl. Math. 3(1) Art. 1, 2002 http://jipam.vu.edu.au Let λT1 + µT2 + σT3 = Λ. Then we observe that the determinant of Λ is zero if λσ = µ2 . If ε < 0 and h ∈ H, then we have k(Λ − ε) hk2 = kΛhk2 − 2ε hΛh, hi + ε2 khk2 ≥ −2ε hΛh, hi + ε2 khk2 ≥ +ε2 khk2 . Thus ε ∈ / SPap (Λ) , the approximate point spectrum of Λ. This means that (Λ − ε) is left invertible. Since (Λ − ε) is hermitian, it must also be right invertible. That is, ε ∈ / SP (Λ) and so Λ ≥ 0 ⇐⇒ λσ ≥ µ2 . Alternatively, for a ∈ X1 and b ∈ X2 , we have 2 r √ SS ∗ µ2 hΛ (a + b) , (a + b)i = σSb + µ a + λ − kS ∗ ak2 . σ σ Since a ∈ X1 , therefore ∃bn ∈ X2 3: √ r σ (Sbn ) + µ SS ∗ µ2 a → 0 =⇒ Λ ≥ 0 ⇐⇒ λ − ≥ 0. σ σ Hence the proof of the corollary is complete. Remark 2. By reducing the matrix Λ into a product of three matrices the above corollary can also be proved. That is, Λ = L∗ DL, where µ√ ∗ √ ∗ I W L= and W = SS S S S. 0 I σ Norm Inequalities in Star Algebras A.K. Gaur Title Page Contents JJ J II I Go Back Close Quit Page 7 of 12 J. Ineq. Pure and Appl. Math. 3(1) Art. 1, 2002 http://jipam.vu.edu.au By the partial commutation relation, we have √ √ SS ∗ S = S S ∗ S and hence λ− µ2 σ SS ∗ D= 0 σS ∗ S 0 . Under the above assumption about σ and S ∗ S, the Sylvester type test applies. 2 That is, Λ is positive (semi definite) if and only if σ > 0 and λ − µσ ≥ 0. Let A, B > 0 be invertible operators on H. In this case a Furuta type inequality is obtainable by replacing 1 with 0 in the original Furuta inequality in Remark 1. In fact, we have A2r ≥ (Ar B p Ar ) 2r (2r+p) . Also, if A ≥ B ≥ 0, 3: A > 0, then for each α ∈ [0, 1] and p ≥ 1 we have (1+r−α) n r −α s r o [(p−α)s+r] α −α 2 2 2 2 A A B A A ≤ A(1+r−α) for s ≥ 1 and r ≥ α. For more details, see [3]. The following examples give an application of these inequalities in case of C ∗ -algebras. ∗ Example 1. Let X be a commutative C -algebra acting on H. If we take A = 6T1 + 0T2 + 3T3 and B = 3T1 + 2T2 + T3 Norm Inequalities in Star Algebras A.K. Gaur Title Page Contents JJ J II I Go Back Close Quit Page 8 of 12 J. Ineq. Pure and Appl. Math. 3(1) Art. 1, 2002 http://jipam.vu.edu.au then A − B = 3T1 − 2T2 + T3 and by the Corollary 2 we have A − B ≥ 0. We further note that A2 is not greater than or equal to B 2 , since for b ∈ X2 , 2 A − B 2 b, b + (S ∗ S)2 b, b = 0. Example 2. Let A = 2T1 , B = T1 + T2 + T3 and C = 4T1 + T2 + T3 . Then A ≥ 0 and B+C ≥ 0. Further, by the Corollary 2, we have B+C−A ≥ 0. Let Ψ ≤ B and Φ ≤ C, where A = Ψ+Φ. Then Ψ ≤ A. Hence, from Corollary 2, for a ∈ X1 and b ∈ X2 , we have √ 2 ∗ h(T1 + T2 + T3 ) (a + b) , (a + b)i = SS a + Sb . Also, bn ∈ X2 =⇒ Ψ = 0, because Sbn + √ SS ∗ a → 0. Thus Norm Inequalities in Star Algebras A.K. Gaur Title Page Contents JJ J II I Go Back A = Φ = 2T1 ≤ 4T1 + T2 + T3 . Example 3. Let Close Quit 1 A = T1 , B = T1 + T2 + T3 and 3 C = 4T1 + 2T2 + T3 . Page 9 of 12 J. Ineq. Pure and Appl. Math. 3(1) Art. 1, 2002 http://jipam.vu.edu.au Then A ≥ 0 and B+C ≥ 0. Next, by Corollary 2, we get B+C−A ≥ 0. Now by Example 2 it follows that A = Φ = 13 T1 ≤ C. This contradicts Corollary 2, since for (C − A) , λσ < µ2 . Remark 3. The algebra norm k·k on a non-unital Banach algebra J can be extended to an algebra norm on the unitization J+ = Ce + J, (where e is the unit in the algebra) in many ways. In particular, the following two norms, l1 − norm = k(λ) e + ak1 = |λ| + kak and the operator norm, Norm Inequalities in Star Algebras A.K. Gaur k(λ) e + akOP = sup {k(λ) b + abk , k(λ) b + bak ; b ∈ J, kbk ≤ 1} , λ ∈ C, a ∈ J are the maximal and the minimal extensions of the original norm respectively, if it is a regular norm, that is, kak = sup {kabk , kbak ; b ∈ J, kbk ≤ 1} , see [4]. The unitization J+ is complete under both k·k1 and k·kOP , so by the two norm lemma, [2, II, 2.5] these two norms are equivalent. If J is a C ∗ -algebra, a ∈ J is self-adjoint, and λ is complex, then k(λ) e + ak1 ≤ 3 k(λ) e + akOP . So far the constant 3 is the best possible in this case. Recently, in [5], we extended the above result to locally m-convex algebras. Now we prove the following corollary. Title Page Contents JJ J II I Go Back Close Quit Page 10 of 12 J. Ineq. Pure and Appl. Math. 3(1) Art. 1, 2002 http://jipam.vu.edu.au Corollary 3. If is a commutative non-unital C ∗ -algebra A, B ∈ YSA with kAk = 1 = kBk, and λ is complex, then k(λI + Ψ)k1 ≤ λ0 + 3 kΦkOP , where λ0 > 0, Ψ = A + B, and Φ = AB. Proof. Since k(λI + A + B)k1 ≤ 3 k(λI + A + B)kOP , we have Norm Inequalities in Star Algebras A.K. Gaur 1 k(λI + A + B)k1 ≤ |λ|+k(A + B)kOP =⇒ k(λI + Ψ)k1 ≤ λ0 +3 kΦkOP , 3 Title Page whereλ0 = 3 (|λ| + 1) > 0. This concludes the proof of the corollary. Contents Remark 4. k(λi + Ψ)kOP ≤ λ0 3 + kΦkOP . JJ J II I Go Back Close Quit Page 11 of 12 J. Ineq. Pure and Appl. Math. 3(1) Art. 1, 2002 http://jipam.vu.edu.au References [1] R.G. DOUGLAS, Banach Algebra Techniques in Operator Theory, Academic Press, Inc., (1970). [2] N. DUNFORD AND J.T. SCHWARTZ , Linear Operators, Part I, Interscience, New York, (1958). [3] T. FURUTA, M. HASHIMOTO AND M. ITO, Equivalence relation between generalized Furuta inequality and related operator functions, Sci. Math. I (electronic), 2 (1998), 257–259. [4] A.K. GAUR AND Z.V. KOVARIK, Norms on unitizations of Banach algebras, Proc. Amer. Soc., 117(1) (1993), 111–113. [5] A.K. GAUR, Maximal and minimal semi-norms and g-bounded operators, IJNSNS, 2 (2001), 283–288. [6] T. KOTARO AND U. ATSUSHI, The Furuta inequality in Banach *algebras, Proc. Amer. Math. Soc. 128(6) (2000), 1691–1695. Norm Inequalities in Star Algebras A.K. Gaur Title Page Contents JJ J II I Go Back Close Quit Page 12 of 12 J. Ineq. Pure and Appl. Math. 3(1) Art. 1, 2002 http://jipam.vu.edu.au