%0 Journal Article %A Wilson, Rory %A Holton, Mark %A Walker, James %A Shepard, Emily %A Scantlebury, D. %A Wilson, Vianney %A Wilson, Gwendoline %A Tysse, Brenda %A Gravenor, Mike %A Ciancio, Javier %A McNarry, Melitta %A Mackintosh, Kelly %A Qasem, Lama %A Rosell, Frank %A Graf, Patricia %A Quintana, Flavio %A Gomez-Laich, Agustina %A Sala, Juan-Emilio %A Mulvenna, Christina %A Marks, Nicola %A Jones, Mark %D 2016 %T Additional file 1: of A spherical-plot solution to linking acceleration metrics with animal performance, state, behaviour and lifestyle %U https://springernature.figshare.com/articles/journal_contribution/Additional_file_1_of_A_spherical-plot_solution_to_linking_acceleration_metrics_with_animal_performance_state_behaviour_and_lifestyle/4345043 %R 10.6084/m9.figshare.c.3605192_D1.v1 %2 https://springernature.figshare.com/ndownloader/files/7071047 %K Spherical plots %K Tri-axial acceleration %K G-sphere %K Visualisation %X Methods. Changing shapes for frequency distributions. Figure S1. A 3-d scatter plot (g-sphere) of static (orthogonal) tri-axial acceleration data. Figure S2. A spherical coordinate’s visualization of (a) postural state plotted onto the surface of a sphere in three-dimensional space, (b) points joined together in chronological order, (c) projecting the data outwards from the sphere according to other parameters. Figure S3. A spherical histogram (Dubai plot) visualization to depict frequent postural states. Figure S4. Histogram, Frequency shape (stacked), fixed shape (skittle) from urchin plots. Figure S5. G-urchin of skittle shape and stacked frequency urchins emitted from the centre of each facet of the sphere. Figure S6. Overview of user interface for a program in which spherical plots can be created. Figure S7. G-spheres and comparable g-urchins derived from a rod-mounted tri-axial accelerometer showing fly-fishing visualisations. (DOCX 5289 kb) %I figshare