I programmed this in Logic Pro. It's not written in my usual orchestral style. It's more contemporary and experimental combined with a little sound design. "Sphere" Relaxing Experimental Contemporary Avant Garde Music
YouTube Channel: JonBrooksComposer
This music is subject to copyright and is provided for demonstration purposes only. © 2009 Jon Brooks.
Some of my musical influences include: Jerry Goldsmith, Gustav Mahler, Danny Elfman, R. Strauss, John Williams, James Newton-Howard, Wagner, Debussy, Patrick Doyle, Shostakovich, Vaughan Williams, Bill Conti, Sibelius, Elgar, Klaus Badelt, Michael Giacchino, Aerosmith, Elliot Goldenthal, Harry Gregson-Williams, James Horner, Def Leppard, Michael Kamen, Ennio Morricone, Hans Zimmer, Christopher Young, Gabriel Yared, Bon Jovi, Debbie Wiseman, Shirley Walker, Brian Tyler, Alan Silvestri, Howard Shore, The Beach Boys, Marc Shaiman, Wishbone Ash, Graeme Revell, John Powell, Mozart, Rachel Portman, Michael Nyman...... and many more!!!
SPHERE (As cited on Wikipedia)
A sphere (from Greek σφαῖρα — sphaira, "globe, ball") is a perfectly round geometrical object in three-dimensional space, such as the shape of a round ball. Like a circle, which is in two dimensions, a sphere is the set of points which are all the same distance r from a given point in space. This distance r is known as the "radius" of the sphere, and the given point is known as the center of the sphere. The maximum straight distance through the sphere is known as the "diameter". It passes through the center and is thus twice the radius.
In mathematics, a careful distinction is made between the sphere (a two-dimensional surface embedded in three-dimensional Euclidean space) and the ball (the three-dimensional shape consisting of a sphere and its interior).
Pairs of points on a sphere that lie on a straight line through its center are called antipodal points. A great circle is a circle on the sphere that has the same center and radius as the sphere, and consequently divides it into two equal parts. The shortest distance between two distinct non-antipodal points on the surface and measured along the surface, is on the unique great circle passing through the two points. Equipped with the great-circle distance, a great circle becomes the Riemannian circle.