Linear motion device with extending tube for positioning

What is claimed: 1. A linear motion device comprising: a band comprising a sheet that is configured to be helically interlinked into a tube, the sheet including a plurality of protrusions, and defining a plurality of recesses that engage the plurality of protrusions to link the sheet with itself; a sliding guide configured to link and unlink the sheet, the sliding guide including an outer layer, an inner layer, and a ramp between the outer and inner layers having a helical incline to support a bottom portion of the sheet; and a driving mechanism in contact with the band, the driving mechanism configured to move the band through the sliding guide up the helical incline to link the sheet, thereby extending the tube, and to move the band through the sliding guide down the helical incline to unlink the sheet, thereby retracting the tube. 2. The linear motion device of claim 1 , wherein the driving mechanism is configured to move the band down the ramp so as to cause the plurality of protrusions on a top portion of the sheet to disengage from the plurality of recesses on the bottom portion of the band sheet, thereby causing the tube structure to retract in the linear direction. 3. The linear motion device of claim 1 , the band further comprising a plurality of slots and the driving mechanism comprising a gear including a plurality of teeth configured to engage the plurality of slots when the gear is rotated. 4. The linear motion device of claim 1 , wherein the plurality of protrusions are castellated. 5. The linear motion device of claim 1 , wherein the sliding guide is circular and the driving mechanism is a gear positioned non-concentrically with respect to the circular sliding guide. 6. The linear motion device of claim 1 , wherein the outer layer comprises an elevated wall configured to interlink the plurality of protrusions with the plurality of recesses when the band is linked with itself. 7. The linear motion device of claim 1 , wherein the outer layer comprises a wedged portion configured to disengage the plurality of protrusions on a top portion of the band from the plurality of recesses on the bottom portion of the band when the band is unlinked. 8. A positioning device comprising: a linear motion device comprising a structure configured to expand and contract along a linear direction; a base; at least one base joint connecting the linear motion device to the base; and at least one cable connected between a distal end of the linear motion device and the base; wherein the at least one cable is actuated by at least one winch positioned between the base and the distal end of the tube. 9. The positioning device of claim 8 , wherein a number of the at least one base joints connecting the linear motion device to the base is equal to a number of the at least one cable connected between the distal end of the linear motion device and the base. 10. The positioning device of claim 8 , wherein at least one of gravity or a spring is used to passively keep the cables taut. 11. The positioning device of claim 8 , further comprising: at least one tension control cable configured to actively control the tension in the at least one cable connected between the distal end of the linear motion device and the base. 12. The positioning device of claim 8 , further comprising at least one end joint positioned at the distal end of the linear motion device. 13. The positioning device of claim 12 , further comprising an attachment mounted to the at least one end joint. 14. The positioning device of claim 13 , wherein the attachment is a gripper. 15. The positioning device of claim 8 , wherein the structure is a single band linking tube structure. 16. A method for determining whether contact is made on a cable in a positioning device, the method comprising the steps of: determining, by a processor, a natural vibration frequency of the cable; sensing, by at least one vibration sensor, a current dominant vibration frequency of the cable; comparing, by a processor, the sensed current dominant vibration frequency of the cable with the natural vibration frequency of the cable; and determining, by a processor and based on the comparing step, a discrepancy between the sensed current dominant vibration frequency and the natural vibration frequency of the cable to indicate contact. 17. The method of claim 16 , wherein the at least one vibration sensor comprises an electric guitar pick-up sensor. 18. The method of claim 16 , further comprising the step of determining, by a processor and using the sensed vibration frequency as the natural vibration frequency, a location at which contact by an obstruction is made on the cable. 19. The linear motion device of claim 1 , wherein the sheet comprises a top edge and a bottom edge, and the sheet defines a plurality of top recesses that extend into the top edge towards the bottom edge and are spaced from one another so as to define the plurality of protrusions therebetween. 20. The linear motion device of claim 19 , wherein the sheet comprises first and second broadsides that are spaced opposite one another and that extend from the top edge to the bottom edge, and the plurality of recesses and the plurality of top recesses extend entirely through the sheet from the first broadside to the second broadside.