Wire-bond transmission line RC circuit

What is claimed is: 1. An RC circuit component for insertion in a transmission line, comprising: a monolithic substrate having a top surface; a capacitor supported on said substrate top surface and having first and second electrodes separated at least in part by a dielectric layer; and a thin-film resistor comprising a layer of resistive material received between said first and second electrodes of said capacitor, said layer of resistive material connected in parallel with said capacitor, and wherein said layer of resistive material has a resistance that is selected for tailoring a frequency response of said component; wherein the frequency response of said RC circuit component depends on applied frequencies over the component's useful frequency range. 2. The RC circuit component as in claim 1 , wherein: said monolithic substrate has opposing first and second longitudinal ends; and said component further comprises a pair of wire bond pads supported on said substrate top surface respectively at said first and second longitudinal ends thereof, and with said wire bond pads coupled respectively with said first and second electrodes of said capacitor. 3. The RC circuit component as in claim 2 , wherein the capacitance value of said capacitor and the resistive value of said layer of resistive material of said thin-film resistor are chosen such that the impedance at each of said pair of wire bond pads is about 50Ω. 4. The RC circuit component as in claim 1 , wherein said layer of resistive material comprises at least one of tantalum nitride (TaN), nickel-chromium alloys (NiCr), and ruthenium oxide (RuO2), and has sheet resistance up to about 100Ω. 5. The RC circuit component as in claim 1 , wherein said substrate comprises at least one of fused silica, quartz, alumina, and glass. 6. The RC circuit component as in claim 1 , wherein: said monolithic substrate has a bottom surface; and said component further comprises a ground electrode received on said substrate bottom surface. 7. The RC circuit component as in claim 1 , wherein: said first and second electrodes at least partially overlap; and said layer of resistive material of said thin-film resistor is received in such overlap. 8. The RC circuit component as in claim 1 , wherein said dielectric layer comprises at least one of silicon oxynitride (SiON) and barium titanate (BaTiO3). 9. The RC circuit component as in claim 1 , wherein said resistance ranges from about 2 Ohms to about 20 Ohms. 10. The RC circuit component as in claim 1 , wherein: said monolithic substrate has a bottom surface and opposing first and second longitudinal ends; and said component further comprises a pair of wire bond pads supported on said substrate top surface respectively at said first and second longitudinal ends thereof, and with said wire bond pads coupled respectively with said first and second electrodes of said capacitor; and further comprises a ground electrode received on said substrate bottom surface; and wherein said layer of resistive material is trimmed to provide said resistance; said substrate comprises at least one of fused silica, quartz, alumina, and glass; and said first and second electrodes at least partially overlap, with said resistor is received in such overlap. 11. A wire-bond transmission line RC circuit, comprising: a monolithic substrate having a top surface, a bottom surface, and opposing first and second longitudinal ends; a capacitor supported on said substrate top surface and having a first electrode, and a second electrode at least partially overlapping said first electrode so as to define an electrode overlap area there between, said capacitor further comprising a dielectric layer received in at least part of said electrode overlap area; a pair of wire bond pads, supported on said substrate top surface respectively at said first and second longitudinal ends thereof, and coupled respectively with said first and second electrodes of said capacitor; and a thin-film resistor connected in parallel with said capacitor; wherein said thin-film resistor comprises a layer of resistive material received in said electrode overlap area and formed to provide a determined resistive value for selectively tailoring the frequency response of said RC circuit over the circuit's useful frequency range. 12. The wire-bond transmission line RC circuit as in claim 11 , further comprising a ground electrode received on said substrate bottom surface. 13. The wire-bond transmission line RC circuit as in claim 11 , wherein said layer of resistive material comprises at least one of tantalum nitride (TaN), nickel-chromium alloys (NiCr), and ruthenium oxide (RuO2), and has sheet resistance up to 100Ω. 14. The wire-bond transmission line RC circuit as in claim 11 , wherein said substrate comprises at least one of fused silica, quartz, alumina, and glass. 15. The wire-bond transmission line RC circuit as in claim 11 , wherein said dielectric layer comprises at least one of silicon oxynitride (SiON) and barium titanate (BaTiO3). 16. The wire-bond transmission line RC circuit as in claim 11 , wherein the capacitance value of said capacitor and the resistive value of said layer of resistive material of said thin-film resistor are chosen such that the impedance at each of said pair of wire bond pads is about 50Ω. 17. Methodology for tailoring the frequency response of an RC circuit component for insertion in a transmission line, such circuit component comprising the type having a monolithic substrate having a top surface, a capacitor supported on such substrate top surface and having at least partially overlapping first and second electrodes separated at least in part by a dielectric layer, with a signal pathway through such circuit component, said methodology comprising: including a thin-film resistor comprising a layer of resistive material received between the first and second electrodes of the capacitor, and connected in parallel with such capacitor; and selecting a resistive value of said layer of resistive material so as to passively adjust the impedance characteristic of the circuit signal pathway for selectively tailoring the frequency response of said RC circuit component over the circuit component's useful frequency range. 18. Methodology as in claim 17 , further comprising selecting the capacitance value of such capacitor and the resistive value of said layer of resistive material of said thin film resistor so that the primary response of the RC circuit component operating at relatively lower frequencies is tailored to that of the RC time-constant, while at higher frequencies the RC circuit component response is based more on the capacitive component, so that the fixed RC circuit component has tailored variations in frequency response depending on the applied frequencies over the circuit component's useful frequency range. 19. Methodology as in claim 18 , wherein the capacitance value of such capacitor and the resistive value of said layer of resistive material of said thin film resistor are chosen such that the impedance at each of said pair of wire bond pads is about 50Ω. 20. Methodology as in claim 17 , wherein said selecting the resistive value step comprises trimming said layer of resistive material to provide said resistive value for tailoring the frequency response of such RC circuit component. 21. Methodology as in claim 20 , wherein said layer of resistive material comprises at least one of tantalum nitride (TaN), nickel-chromium allo