Absolute encoder scale configuration with unique coded impedance modulations

The invention claimed is: 1. An absolute scale configuration for use in an absolute position encoder comprising an absolute scale and a readhead that move relative to one another along a measuring axis of the absolute scale, the absolute scale configuration comprising: a plurality of scale loops which include signal coupling loop portions distributed periodically along the measuring axis and configured to inductively couple to a spatially modulated signal coupling configuration of the readhead to produce at least one position-dependent signal in the readhead that varies spatially periodically depending on a relative position between the scale loops and the readhead during a position dependent signal generating state, wherein: at least some of the plurality of scale loops are connected to respective impedance modulating circuits, a respective impedance modulating circuit comprising: an energy coupling portion that receives energy from a current induced in the connected scale loop by the readhead; and a controller portion which is powered by the energy coupling portion and which does not modulate a scale loop impedance during the position dependent signal generating state and which does modulate the scale loop impedance using a unique coded modulation during a code signal generating state to produce a unique coded signal in the readhead, the unique coded signal indicative of a coarse resolution absolute position of the scale loops relative to the readhead; and the coarse resolution absolute position is usable in combination with the at least one position-dependent signal to provide an absolute position of the scale loops relative to the readhead with a resolution better than the coarse resolution absolute position. 2. The absolute scale configuration of claim 1 , wherein the respective impedance modulating circuit is configured to provide a relatively low scale loop impedance at an excitation frequency provided by the readhead during the position dependent signal generating state. 3. The absolute scale configuration of claim 1 , wherein the respective impedance modulating circuit is configured to provide at least one transition between a first scale loop impedance and a second scale loop impedance during the code signal generating state. 4. The absolute scale configuration of claim 1 , wherein the respective impedance modulating circuit is configured to provide the unique coded modulation comprising at least one transition between a first scale loop impedance and a second scale loop impedance produced at a unique timing within the code signal generating state, wherein the unique timing defines the unique coded signal that is indicative of the coarse resolution absolute position. 5. The absolute scale configuration of claim 1 , wherein the respective impedance modulating circuit is configured to provide the unique coded modulation comprising a plurality of transitions between a first scale loop impedance and a second scale loop impedance during the code signal generating state. 6. The absolute scale configuration of claim 5 , wherein the plurality of transitions produce a sequence of binary values that define the unique coded signal that is indicative of the coarse resolution absolute position. 7. The absolute scale configuration of claim 1 , wherein: the spatially modulated signal coupling configuration of the readhead comprises a first spatially modulated signal coupling configuration and a second spatially modulated signal coupling configuration; the plurality of scale loops include a first set of signal coupling loop portions aligned along the measuring axis direction and distributed periodically along the measuring axis based on a spatial wavelength P 1 and configured to inductively couple to the first spatially modulated signal coupling configuration of the readhead to produce at least a first position-dependent signal in the readhead that varies spatially periodically at the spatial wavelength P 1 depending on a relative position between the scale loops and the readhead during the position dependent signal generating state; the plurality of scale loops include a second set of signal coupling loop portions aligned along the measuring axis direction and distributed periodically along the measuring axis based on a spatial wavelength P 2 and configured to inductively couple to the second spatially modulated signal coupling configuration of the readhead to produce at least a second position-dependent signal in the readhead that varies spatially periodically at the spatial wavelength P 2 depending on a relative position between the scale loops and the readhead during the position dependent signal generating state; the spatial wavelengths P 1 and P 2 have a unique phase relationship along the measuring axis direction over a range defining a medium spatial wavelength Pmed; and respective impedance modulating circuits are connected to scale loops that are located along the measuring axis at a spacing that is at least 0.25*Pmed, and at most Pmed. 8. The absolute scale configuration of claim 7 , wherein the respective impedance modulating circuits are connected to scale loops that are located along the measuring axis at a spacing that is at least 0.5*Pmed and less than at least one of (Pmed-P 1 ) or (Pmed-P 2 ). 9. An absolute position encoder, comprising: a readhead, comprising: a spatially modulated signal coupling configuration; and a readhead processor; and an absolute scale extending along a measuring axis of the position encoder, the readhead being movable relative to the absolute scale along the measuring axis, the absolute scale comprising: a plurality of scale loops which include signal coupling loop portions distributed periodically along the measuring axis and configured to inductively couple to the spatially modulated signal coupling configuration of the readhead to produce at least one position-dependent signal in the readhead that varies periodically spatially depending on a relative position between the scale loops and the readhead during a position dependent signal generating state; and a plurality of impedance modulating circuits connected to at least some of the plurality of scale loops, each respective impedance modulating circuit comprising: an energy coupling portion that receives energy from a current induced in the connected scale loop by the readhead; and a controller portion which is powered by the energy coupling portion and which does not modulate a scale loop impedance during the position dependent signal generating state and which does modulate the scale loop impedance using a unique coded modulation during a code signal generating state to produce a unique coded signal in the readhead, the unique coded signal indicative of a coarse resolution absolute position of the scale loops relative to the readhead; and wherein the readhead processor analyzes the coarse resolution absolute position in combination with the at least one position-dependent signal to provide an absolute position of the scale loops relative to the readhead with a resolution that is better than the coarse resolution absolute position. 10. The absolute position encoder of claim 9 , wherein: the spatially modulated signal coupling configuration comprises an excitation winding which is excited by the readhead processor at an excitation frequency during the position dependent signal generating state, and a first set of spatially modulated receiver windings; scale loops in the plurality of scale loops comprise the signal coupling loop portion and an excitation coupling portion, separated along a direction transverse to the measuring axis; the signal coupling loop portions are aligned along the measuring axis d