Absolute position encoder scale having layers in a stacked configuration

The invention claimed is: 1. A position sensing device usable to measure a position of a first member with respect to a second member along a measuring axis, the position sensing device comprising: a scale comprising first and second layers that extend along the measuring axis and that are stacked on one another along a depth direction that is approximately normal to the scale layers, the first layer comprising material forming a first spatial modulation pattern along the measuring axis, and the second layer comprising material forming a second spatial modulation pattern along the measuring axis that is different than the first spatial modulation pattern over an absolute range along the measuring axis; and a read head for being moved relative to the scale along a direction of the measuring axis, the read head comprising a sensing portion arranged along the depth direction relative to the scale and configured to produce at least one scale sensing field that may be modulated by the first and second spatial modulation patterns of the first and second layers and provide first and second position signal components based on using first and second circuit configurations to provide a first smaller signal-sensing depth and a second smaller signal-sensing depth for the at least one scale sensing field; and configured wherein: the first layer is closer to the read head along the depth direction than the second layer, and the first spatial modulation pattern of the first layer provides a dominant first position signal component sensed using the first circuit configuration; the second spatial modulation pattern of the second layer provides a significant second position signal component sensed using the second circuit configuration and a less significant second position signal component when using the first circuit configuration; and the first and second spatial modulation patterns are configured such that the second position signal component includes a signal characteristic that provides a plurality of unique values relative to the first position signal component at corresponding positions along the absolute range. 2. The position sensing device of claim 1 , configured wherein the second spatial modulation pattern of the second layer provides an insignificant second position signal component when using the first circuit configuration. 3. The position sensing device of claim 1 , wherein the at least one scale sensing field is a changing field and the first circuit configuration corresponds to a higher temporal frequency or frequency range of the scale sensing field, and the second circuit configuration corresponds to a lower temporal frequency or frequency range of the scale sensing field. 4. The position sensing device of claim 3 , wherein the first and second circuit configurations are operate according to at least one of one of a) or b), comprising: a) the first circuit configuration provides a first scale sensing field at the higher temporal frequency or frequency range at a first time, the second circuit configuration provides a second scale sensing field at the lower temporal frequency or frequency range at a second time, and the read head senses the first position signal component at the first time and the second position signal component at the second time, or b) the first circuit configuration senses the modulation of the at least one scale sensing field using a higher limited or filtered frequency range which corresponds to the higher temporal frequency or frequency range, and the second circuit configuration senses the modulation of the at least one scale sensing field using a lower limited or filtered frequency range which corresponds to the lower temporal frequency or frequency range. 5. The position sensing device of claim 4 , wherein the first and second circuit configurations operate according to b), and the read head is configured to generate a changing scale sensing field that simultaneously includes both the higher and lower temporal frequencies or frequency ranges. 6. The position sensing device of claim 3 , wherein the first and second circuit configurations are responsive to respective eddy currents that arise in a material of the first and second spatial modulation patterns and modulate the at least one scale sensing field in order to provide the first and second position signal components. 7. The position sensing device of claim 3 , wherein the first layer has a thickness along the depth direction that is at least one times a first skin depth, wherein that first skin depth is determined based on a material forming the first spatial modulation pattern and the higher temporal frequency or frequency range corresponding to the first circuit configuration. 8. The position sensing device of claim 3 , wherein the first layer has a thickness along the depth direction that is at most 0.5 times a second skin depth, wherein that second skin depth is determined based on a material forming the first spatial modulation pattern and the lower temporal frequency or frequency range corresponding to the second circuit configuration. 9. The position sensing device of claim 3 , wherein a thickness along the depth direction of the material forming the second spatial modulation pattern of the second layer is at least two times a thickness along the depth direction of the material forming the first spatial modulation pattern of the first layer. 10. The position sensing device of claim 1 , wherein the scale further comprises an isolating layer comprising one of a) a material forming a uniform layer, or b) a material forming a third spatial modulation pattern, that extends along the measuring axis and is located between the first and second layers. 11. The position sensing device of claim 10 , wherein the isolating layer is a material forming a uniform layer, and a thickness of the first layer added to a thickness of the isolating layer along the depth direction is at least one times a first skin depth, wherein that first skin depth is determined based on the material forming the uniform layer and the higher temporal frequency or frequency range corresponding to the first circuit configuration. 12. The position sensing device of claim 10 , wherein: the isolating layer is a material forming a third spatial modulation pattern; and the third spatial modulation pattern of the isolating layer is configured in relation to the first spatial modulation pattern of the first layer to at least partially nullify the modulation effect of the first spatial modulation pattern when using the second circuit configuration and thereby at least partially nullify the first position signal component when using the second circuit configuration. 13. The position sensing device of claim 12 , wherein: the material forming the first and third spatial modulation patterns is the same material; and the first and third spatial modulation patterns are complements such that a combined thickness along the depth direction of the material forming the first and third spatial modulation patterns is nominally constant between the read head and the second layer. 14. The position sensing device of claim 13 , wherein the first spatial modulation pattern is periodic and has a wavelength P, the third spatial modulation is periodic and has the wavelength P, and the first and third spatial modulation patterns are shifted along the measuring axis by approximately 180 degrees of spatial phase shift relative to one another. 15. The position sensing device of claim 13 , wherein each of the first and third spatial modulation patterns comprise one of a) material thickness modulations a