The following specification relates to electronic components. Electrical components operating, for example, at Radio Frequency (RF), microwave and millimeterwave frequencies are typically designed so that the electrical component operates as expected throughout a desired frequency band (or specified operational band). For example, an inductor can be designed to provide inductance throughout a specified operational band. However, there are circumstances in which an inductor in operation will provide capacitance to a circuit instead of inductance. The materials, packaging, and to a large extent the physical structure (i.e., the geometry) of a component contribute intrinsic parasitic resistances, capacitances, and inductances to the make up of the component that can result in a component not operating as desired.
At different frequencies, component parasitics can dominate component performance. Moreover, the parasitics can combine with one another, or other circuit elements, to induce undesired changes—such as glitches, nulls or phase shifts—in signals (narrowband or broadband) traveling through a circuit (or assembly).
Consequently, conventional electrical components are specified and designed to operate over a relatively narrow band, within which the parasitics contributed by the geometry, materials, and packaging of a component can be effectively mitigated. For example, most inductors are designed for operation over a relatively narrow band and may become capacitive past a parasitic resonant frequency due to the above identified intrinsic sources of parasitics.
In developing ultra broadband technologies, for example, back-haul systems provided by the use of OC768 opto-electrical equipment, extremely wide bandwidths are specified and designed for despite the existing narrow band limitation imposed by conventional electrical components included in the equipment design. Ultra broadband networks require undistorted handling of signals through the optical and electrical components. Ultra broadband electrical components must therefore operate well over a continuous band of spectrum.
The present specification describes systems and apparatuses for providing a broadband inductor.
In general, in one aspect, the specification provides a broadband inductor assembly. The broadband inductor assembly includes a conical coil inductor having a broad end with radius r1 and a narrow end with radius r2, the conical coil inductor also having a broad end terminal and a narrow end terminal. The broadband inductor assembly includes a base. The broadband inductor assembly includes at least one support, such that the conical coil inductor is supported by the at least one support above the base at a distance greater than or equal to r1 from the base.
In general, in another aspect, the specification provides for an ultra broadband bias tee. The ultra broadband bias tee includes a broadband inductor assembly. The broadband inductor assembly includes a conical coil inductor having a broad end with radius r1 and a narrow end with radius r2, the conical coil inductor also having a broad end terminal and a narrow end terminal. The broadband inductor assembly includes a base. The broadband inductor assembly includes at least one support; such that the conical coil inductor is supported above the base at a distance greater than or equal to r from the substantially flat surface of the base. The ultra broadband bias tee includes a DC block assembly coupled to the broadband inductor.
Implementations may include one or more of the following features. The narrow end terminal of the conical coil can be positioned at a minimum height above the substantially flat surface of the base. The narrow end can be operable to provide a high end of an operational band of frequencies for a broadband inductor assembly. The broad end can be operable to provide a low end of an operational band of frequencies for a broadband inductor assembly. The base can include a substantially flat surface. The conical coil inductor can be supported by the at least one support such that such that an imaginary center line through the conical coil is substantially parallel to the base, and also such that the broad end of the conical coil is supported above the base. The at least one support can be composed of a low loss dielectric material. The at least one support can be composed of glass or ceramic. The broadband inductor can further include a cylindrical winding extension coupled to the broad end of the conical coil inductor. The broadband inductor can further include a magnetic core inductor coupled in series to the broad end of the conical coil inductor. The DC block assembly can include an ultra broadband capacitor assembly. The DC block assembly can be integrated into a coplanar waveguide.
The details of the following specification can be implemented to provide one or more of the following advantages. A conical broadband inductor is provided which supports ultra broadband signal transmission from the tens of kilohertz to the tens of gigahertz. By positioning the conical inductor above a circuit surface on both high frequency and low frequency ends, proximity dependant parasitic effects can be reduced or eliminated. The conical inductor can be combined with an ultra broadband capacitor assembly in order to form a ultra broadband bias tee in which the high frequency terminal of the conical broadband inductor can be integrated into the ultra broadband capacitor assembly.
The details of one or more implementations are set forth in the accompanying drawings and the description below.
Like reference symbols in the various drawings indicate like elements.
In order to provide an inductor that maintains a desired value of inductance from very low frequencies to at least the tens of gigahertz (GHz), an ultra broadband inductor assembly (UBIA) is provided.
Shown in
In alternative implementations, the one or more supports 61 and 62 can be rods. In another implementation, conical coil inductor 47 can be supported by a dielectric material. For example, glass rods can be used to replace supports 61 and 62. Additionally, supports 61 and 62 can be replaced with a single low loss duroid support or ceramic form that supports conical coil 47 above package base surface 50. In other implementations, package base surface 50 can be a surface or plate that is used within a larger circuit assembly.
Conical coil 47 has a broad end 47a and a narrow end 47b with respective radius r1 and r2. Conical coil 47 also has a broad end terminal 45 and a narrow end terminal 49 to which other components can be coupled. In one implementation, conical coil 47 can be mounted so that narrow end terminal 49 is positioned close to a top of support 62. In one implementation, narrow end terminal 49 is positioned to directly contact a component positioned at a same height as h2. Alternatively, contact can be made with a component through a lead line to a component at a different height as compared to h2 (e.g., lower). In some implementations, the lead line is designed to be short in order to minimize interference or other detrimental effects. Similarly, the lead line connecting the broad end terminal 45 with another component or transmission medium can also be designed with a length that minimizes detrimental circuit effects.
In one implementation, the height h1 of support 61 is set to be at least equal to and just slightly longer than the value of r1. By raising conical coil 47 off package base surface 50 on both the broad and narrow ends, 47a and 47b, the parasitic coupling paths between conical coil 47 and package base surface 50 can be minimized. Raising the conical conductor by at least r1 equal to or greater than r1 reduces or eliminates parasitic effects.
In operation, narrow end 47b of conical coil 47 has the greatest impact on the high frequency signal components traveling through conical coil 47. Similarly, broad end 47a of conical coil 47 impacts, in part, the low frequency signal components traveling through conical coil 47. The two radii r1 and r2 are respectively scaled to set, in part, the low and high ends of the operational frequency bandwidth of UBIA 100. The lowest frequency and the highest frequency thereby defining the continuous frequency band over which the UBIA 100 operates at a desired value of inductance.
UBIA 100 can be integrated into a hybrid microwave integrated circuit environment. In one implementation, UBIA is integrated into a hybrid microwave integrated circuit including a coplanar waveguide in combination with UBIA 100 instead of a microstrip line as the transmission medium near UBIA 100. In another implementation, the coplanar waveguide is a suspended and truncated coplanar waveguide (STCPW). Examples of coplanar waveguides are described in a U.S. patent application filed Feb. 11, 2004 by the same inventors and assigned to Oplink Communications, Inc. entitled “Suspended and Truncated Coplanar Waveguide.” In a STCPW the electromagnetic field of the fundamental mode supported by the STCPW is tightly bound to the slots between the signal and coplanar ground conductors of the STCPW. The fringing fields that will interact with other nearby components such as the UBIA 100 causing deterioration in the broadband performance of conical coil 47 are thereby reduced. In implementations incorporating microstrip transmission lines, the fringing fields around microstrip transmission lines are far less tightly bound to the proximity of the microstrip transmission line as compared to the fringing fields of the STCPW line.
In another implementation shown in
Additionally, an UBIA can be used to implement practical circuits such as an ultra broadband bias tee (UBBT).
UBIA 305 includes conical coil inductor 47, broad end terminal 45 and narrow end terminal 79, and supports 61 and 62. Magnetic core inductor 83 is positioned within a recess 84 in support base 51 away from the UBIA 305 conical coil inductor 47 and other active circuit elements. A wire jump 80 couples the resistor 82 and magnetic core inductor 83 to the broad end terminal 45 of conical coil inductor 47. Narrow end terminal 49 of UBIA 305 is coupled to UBCA 310, which is integrated into a STCPW 85.
A number of implementations have been described. Nevertheless, it will be understood that various modifications may be made without departing from the spirit and scope of the present specification. Accordingly, other embodiments are within the scope of the following claims.
This application claims the benefit of U.S. Provisional application No. 60/446,249, filed on Feb. 11, 2003, which is incorporated by reference herein.
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Number | Date | Country | |
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20040227596 A1 | Nov 2004 | US |
Number | Date | Country | |
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60446249 | Feb 2003 | US |