Unconditional and absolute almost everywhere convergence of series by the general Franklin system (Q1587183)

Let \(P_0=\{0,1\}\), \(P_j=\{t_{j,i}:0\leq i \leq 2^j\}\) where \(0=t_{j,0}<t_{j,1}<\dots<t_{j,2^j}=1\) satisfying \(t_{j+1,2k}=t_{j,k}\), \(0\leq k\leq 2^j\), such that \(t_{j,i}\subset t_{j,i+1}\) and \(P_j\subset P_{j+1}\). Let us introduce \(P^{2^m}=P_m\), \(m\geq 0\), and \(P^n=P^{2^m}\cup\{ t_{m+1,2k-1}\}\) for \(n=2^m+\nu\), \(1\leq\nu\leq 2^m\). The points of \(P^n\) we denote by \(\{t_k^n\}^n_{k=0}\) in ascending order, \(\lambda_k^n=t_k^n-t_{k-1}^n\), \(f_0(t)\equiv 1\), \(f_1(t)=2\sqrt{3}(t-\frac{1}{2})\). By definition \(f_n(x)\) is a continuous and linear function on each \([t_{k-1}^n,t_{k}^n]\) such that \(1)f_n \) is orthogonal to \(f_0,\dots,f_{n-1}\) in \(L_2[0,1]\); \(2)f_n(t_{2\nu-1}^n)>0\); 3)\(\|f_n\|_{L_2}=1\). If we have \(\frac{1}{\gamma}\leq \frac{\lambda_{k-1}^n}{\lambda_k^n}\leq \gamma\) for \(n\geq 2\), \(1\leq k\leq n\), then \(\{f_n\}\) is an \((SR)\)-system (strongly regular). For these systems the unconditional almost everywhere convergence on a set \(E\subset[0,1]\) of positive Lebesgue measure is equivalent to almost everywhere absolute convergence on \(E\).