Schematic diagram of the proposed fusion framework for the lithium-ion battery capacity estimation.

<p>Schematic diagram of the proposed fusion framework for the lithium-ion battery capacity estimation.</p

Remaining capacity estimation of lithium-ion batteries based on the constant voltage charging profile - Fig 7

<p><b>Capacity and RUL estimation for battery No.5 at different starting points:</b> (a) at the 80th point; (b) at the 90th point; (c) at the 100th point.</p

A typical CC-CV charging curve of the lithium-ion battery.

<p>A typical CC-CV charging curve of the lithium-ion battery.</p

Aging phenomena during the CV profile at several cycles.

<p>Aging phenomena during the CV profile at several cycles.</p

Remaining capacity estimation of lithium-ion batteries based on the constant voltage charging profile - Fig 8

<p><b>Capacity estimation for battery No.7 at different starting points:</b> (a) at the 80th point; (b) at the 90th point; (c) at the 100th point.</p

Correlation analysis of the extracted aging feature and battery capacity.

<p>Correlation analysis of the extracted aging feature and battery capacity.</p

CV charging capacity of lithium-ion batteries.

<p>CV charging capacity of lithium-ion batteries.</p

Comparison of capacity and RUL estimation results among different methods (battery No.5).

<p>Comparison of capacity and RUL estimation results among different methods (battery No.5).</p

Additional file 2: Table S4. of Epigenetic synergy between decitabine and platinum derivatives

Primers for bisulfite pyrosequencing.Table S5. Primers for ChIP Q-PCR

Additional file 1: Table S1. of Epigenetic synergy between decitabine and platinum derivatives

Top functional annotation categories of genes upregulated by carboplatin. Table S2. Top functional annotation categories of genes downregulated by carboplatin. Table S3. Functional annotation of genes upregulated by decitabine and carboplatin (DAC+Carbo)