Generalized 3-circular projections in some Banach spaces
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Recently in a series of papers it is observed that in many Banach spaces, which include classical spaces $C(\Omega)$ and $L_p$-spaces, $1 \leq p < \infty, p \neq 2$, any generalized bi-circular projection $P$ is given by $P = \frac{I+T}{2}$, where $I$ is the identity operator of the space and $T$ is a reflection, that is, $T$ is a surjective isometry with $T^2 = I$. For surjective isometries of order $n \geq 3$, the corresponding notion of projection is generalized $n$-circular projection as defined in \cite{AD}. In this paper we show that in a Banach space $X$, if generalized bi-circular projections are given by $\frac{I+T}{2}$ where $T$ is a reflection, then any generalized $n$-circular projection $P$, $n \geq 3$, is given by $P = \frac{I+T+T^2+...+T^{n-1}}{n}$ where $T$ is a surjective isometry and $T^n = I$. We prove our results for $n=3$ and for $n > 3$, the proof remains same except for routine modifications.
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