Robotic vacuum cleaning system

What is claimed is: 1. A resilient compressible roller rotatably engaged with an autonomous coverage robot, the resilient compressible roller comprising: a resilient tubular member having a longitudinal axis spanning between a first end and a second end of the resilient tubular member and including: an outer surface, and one or more vanes integrally formed with the resilient tubular member and extending outwardly from the outer surface, the one or more vanes defining V-shaped chevrons, each chevron having a central tip, a first leg extending from the central tip to near the first end of the resilient tubular member and a second leg extending from the central tip to near the second end of the resilient tubular member; a resilient compressible material disposed within the resilient tubular member; and a bushing housing extending into the first or second end of the tube and forming an overlap region where the tube does not deform. 2. The resilient compressible roller of claim 1 , further comprising a hub disposed along the longitudinal axis of the resilient tubular member within the outer surface. 3. The resilient compressible roller of claim 2 , wherein the hub occupies about 10% to 20% of a length of the resilient tubular member. 4. The resilient compressible roller of claim 1 , further comprising a plurality of resilient spokes extending between an inner surface of the resilient tubular member and the hub. 5. The resilient compressible roller of claim 4 , wherein the tube, the spokes, and the hub are integrally and homogenously formed from a resilient material having a durometer of between 60 A and 80 A. 6. The resilient compressible roller of claim 1 , the bushing housing further comprising a busing surrounding a pin in axial alignment with the longitudinal axis. 7. The resilient compressible roller of claim 1 , wherein the resilient compressible material is glued to an inner surface of the resilient tubular member. 8. The resilient compressible roller of claim 1 , wherein the resilient compressible material comprises a foamed elastomer. 9. The resilient compressible roller of claim 1 , the resilient compressible material further comprising two foam inserts. 10. The resilient compressible roller of claim 8 , where the foamed elastomer is one of thermoplastic polyurethane foam, ethylene vinyl acetate foam, or polypropylene foam. 11. The resilient compressible roller of claim 1 , wherein the one or more vanes are equidistantly spaced around a circumference of the resilient tubular member. 12. The resilient compressible roller of claim 11 , wherein the one or more vanes comprises at least five vanes. 13. The resilient compressible roller of claim 1 , wherein the one or more vanes have a height that is at least 10% of a diameter of the resilient tubular member. 14. The resilient compressible roller of claim 1 , wherein resilient tubular member has a wall thickness between ½ mm and 3 mm. 15. A cleaning robot, comprising: a debris collection volume; a vacuum inlet configured to deliver debris to the debris collection volume; a roller housing in pneumatic communication with the vacuum inlet; and a compressible roller opposing the vacuum inlet, the compressible roller comprising a resilient tubular member having a longitudinal axis spanning between a first end and a second end of the resilient tubular member and including: an outer surface, one or more vanes integrally formed with the resilient tubular member and extending outwardly from the outer surface, the one or more vanes defining V-shaped chevrons, each chevron having a central tip, a first leg extending from the central tip to near the first end of the resilient tubular member and a second leg extending from the central tip to near the second end of the resilient tubular member, and a resilient compressible material disposed within the resilient tubular member. 16. The cleaning robot of claim 15 , the compressible roller further comprising a bushing housing extending into the first or second end of the tube and forming an overlap region where the tube does not deform. 17. The cleaning robot of claim 15 , wherein the one or more vanes extend from the circumferential wall by a height of at least 10% of a diameter of the shape-changing tube. 18. The cleaning robot of claim 15 , wherein the roller housing is spaced from a radially outermost part of the compressible roller by less than or equal to about 1 mm. 19. The cleaning robot of claim 15 , wherein the longitudinal axis is in parallel longitudinal alignment with the vacuum inlet. 20. The cleaning robot of claim 15 , further comprising a hub disposed along the longitudinal axis of the resilient tubular member within the outer surface. 21. The cleaning robot of claim 20 , wherein the hub occupies about 10% to 20% of a length of the resilient tubular member. 22. The cleaning robot of claim 15 , wherein the resilient compressible material comprises two foam inserts.