Fluid driven position sensor

1 . A sensor for measuring the position of an object relative to a reference, comprising: a reference component and a displacement component, the displacement component being moveable linearly, rotatably, or both, relative to the reference component; and an input port for receiving a pressurized fluid, wherein: the reference and displacement components are configured such that a fluidic flow resistance through a predetermined flow path varies in a predetermined way as a function of a linear position, an angular position, or both, of the reference component relative to the displacement component; the reference and displacement components are configured such that the object can engage with the sensor in such a way that a linear displacement, an angular displacement, or both, of the object relative to the reference causes a corresponding linear displacement, angular displacement, or both, between the reference and displacement components; the sensor further comprises a detector adapted to obtain a measure of the flow resistance or of a change in the flow resistance and thereby measure a linear position, an angular position, or both, of the object relative to the reference; and the reference and displacement components are configured to allow detection of at least three different flow resistances associated respectively with at least three different linear positions, at least three different angular positions, or a combination of at least three different linear and angular positions, of the object relative to the reference. 2 . The sensor according to claim 1 , further comprising a fluid source for supplying the pressurized fluid to the input port, wherein the fluid source is configured to provide the pressurized fluid with a pulsatile pressure variation at the input port. 3 . The sensor according to claim 2 , wherein the displacement component is moveable linearly relative to the reference component; the reference and displacement components are configured such that a fluidic flow resistance through a predetermined flow path varies in a predetermined way as a function of a linear position of the reference component relative to the displacement component; the reference and displacement components are configured such that the object can engage with the sensor in such a way that a linear displacement of the object relative to the reference causes a corresponding linear displacement between the reference and displacement components; the detector is adapted to obtain a measure of the flow resistance or of a change in the flow resistance and thereby measure a linear position of the object relative to the reference; and the reference and displacement components are configured to allow detection of at least three different flow resistances associated respectively with at least three different linear positions of the object relative to the reference. 4 . The sensor according to claim 3 , wherein the detector is configured to measure the linear position based on a differential measurement using the flow resistance or the change in the flow resistance measured at two different pressures in the pressurized fluid at the input port, provided by the pulsatile pressure variation. 5 . The sensor according to claim 1 , wherein the predetermined flow path comprises a path passing through an interface between the reference component and the displacement component. 6 . The sensor according to claim 1 , wherein the reference component comprises a cylinder and the displacement component comprises a piston configured to move linearly, to rotate, or both, within the cylinder. 7 . The sensor according to claim 6 , wherein: the flow resistance depends predominantly on the flow resistance encountered by the pressurized fluid passing through a region of closest approach between an outer surface of the piston and an inner surface of the cylinder; and the length of the region varies as a function of the position of the reference component relative to the displacement component. 8 . The sensor according to claim 7 , wherein an outer surface of the piston or an inner surface of the cylinder is provided with a structure that causes the flow resistance of the region of closest approach to vary non-linearly as a function of the position of the reference component relative to the displacement component. 9 . The sensor according to claim 8 , wherein the non-linear variation comprises a plurality of steps. 10 . The sensor according to claim 7 , wherein the piston comprises: a first internal lumen into which the pressurized fluid is channelled so as to flow from a proximal end to a distal end of the piston and to leave the piston at the distal end; and a second internal lumen, separate from the first internal lumen, wherein: the detector is configured to measure a pressure in a volume adjacent to the distal end of the piston, via the second internal lumen, in order to obtain the measure of the flow resistance or of the change in the flow resistance. 11 . sensor according to claim 6 , wherein: the piston comprises an internal lumen into which the pressurized fluid is channelled and a plurality of piston ducts each connecting the internal lumen to a different opening in a lateral surface of the piston, wherein the extent to which the openings are covered by an internal surface of the cylinder varies as a function of the longitudinal position, the angular position, or both, of the piston relative to the cylinder, such that the flow resistance detected by the detector is a measure of the longitudinal position, the angular position, or both, of the piston relative to the cylinder and therefore of the linear position, the angular position, or both, of the object relative to the reference. 12 . The sensor according to claim 6 , further comprising a channelling system adapted to channel the pressurized fluid in such a way that the pressurized fluid causes the cylinder to rotate continuously and applies a longitudinal biasing force to the cylinder. 13 . The sensor according to claim 12 , wherein: the channelling system is adapted also to channel the pressurized fluid from the input port into a lumen within the piston; the piston comprises a piston duct connecting the lumen to an opening in a lateral surface of the piston; the cylinder comprises a plurality of cylinder ducts at different longitudinal positions along the cylinder; the reference component comprises a reading port that allows fluid to flow out of the lumen through the piston duct and one or more of the cylinder ducts to the detector when the reading port overlaps with the one or more of the cylinder ducts; and the spatial distribution of the cylinder ducts is such that the detector detects a sequence of pulses that uniquely identifies a longitudinal position of the piston relative to the cylinder, thereby detecting a linear position of the object relative to the reference. 14 . The sensor according to claim 13 , wherein the size of the reading duct and the longitudinal separation or separations of the cylinder ducts is/are such that for at least a portion of a longitudinal range of motion of the cylinder relative to the piston the reading duct overlaps with at least two different cylinder ducts during at least a portion of one complete rotation of the cylinder. 15 . The sensor according to claim 14 , wherein the time difference or differences between different ones of the pulses corresponding to the at least two different cylinder ducts is/are characteristic of the longitudinal position of the piston relative to the cylinder. 16 . The sensor accordi