Bias tees are generally used to supply direct current (DC) voltages or currents to radio frequency (RF) circuits or devices, such as field-effect transistors (FETs) that are typically used in amplifiers, for example. When incorporating a bias tee into a circuit or system, a designer must pay particular attention to a number of certain properties, such as RF bandwidth, insertion loss, mismatch at the two RF ports, and the maximum DC current, for example.
In the example 100, the bias tee is implemented by way of a first capacitor 104 situated between the tee 110 and RF port 102, an inductor 122 situated between the first tee 110 and the second tee 124, and a second capacitor 132 coupled with the DC port 130. An RF signal incident to the RF/DC port 106 is delivered to the RF port 102, while a DC signal is injected at the DC port 130.
Bias tees are often used to place a DC or other low frequency signal on a RF/microwave signal without otherwise disturbing the microwave signal. This has usually accomplished by way of a coil of wire or, for higher frequencies, a very long bond wire. However, coils are plagued with parasitics that limit performance.
Bond wires tend to be long, thus requiring special cavities to contain them. In current systems and devices, bond wires cannot be folded to reduce space. Current systems generally require extremely long bond wires and special cavities to contain them. These bond wires are attached to metal-insulator-metal (MIM) capacitors, which typically requires epoxy to secure them thereto, as well as additional bond wires.
Accordingly, a need remains for bias tees that have a reduced size without reducing or otherwise limiting performance
Embodiments of the disclosed technology generally allow for an inductance to be folded, thus reducing the space required therefor. Since part of the inductance is thus placed on the substrate metalization, the consistancy of the resulting product is improved. Also, effective wide bandwidth capacitors may be built into different layers of the substrate to reduce the number of assembly components.
A bias tee in accordance with the disclosed technology generally requires only one bond wire, and the capacitor and additional filtering may be incorporated into the substrate. The net result is thus a smaller bias tee having associated therewith a more efficient assembly process.
Embodiments of the disclosed technology generally include reduced size bias tees, such as would be suitable to be implemented in any of a number of different circuits and systems. These and other features and embodiments of the present invention proceed with reference to each of the figures.
Either or both of the first and second lines 304 and 308, respectively, may be implemented as an RF microstrip. In certain embodiments, a single RF microstrip includes both lines 304 and 308. Alternatively or in addition thereto, either or both of the lines 304 and 308 may be implemented as wires or other suitable component or device for electrically coupling the corresponding RF port with the first tee 310.
In the example, a bias tee is implemented by way of a first catch pad 316, a connecting pin 318, a second catch pad 320, an inductor 322, and a radial stub 326. The first tee 310 is electrically coupled with the first catch pad 316 by way of a first wire 312, a second wire 314, and a connection point 313 therebetween. Either or both of the first and second wires 312 and 314, respectively, may be implemented as a wire bond. Alternatively or in addition thereto, either or both of the wires 312 and 314 may be at least substantially co-planar with or otherwise integrated on or with a surface of the underlying substrate, e.g., layer, at or on which the first catch pad 316 is situated.
The connecting pin 318 may be implemented as any suitable component or mechanism for electrically coupling the first catch pad 316 to the second catch pad 320, which may be situated on or at a surface of the substrate opposite that associated with the first catch pad 316. The connecting pin 318 typically is a via in the layer or substrate. In alternative embodiments, the connecting pin 318 may couple the first and second catch pads 316 and 320, respectively, independent of a via.
The inductor 322 serves to electrically couple the second catch pad 320 with a second tee 324. As with the first tee, 310, the second tee 324 may be a discrete component or simply a point at which multiple lines may connect. The inductor 322 may be situated on or at the same surface of the substrate, e.g., layer, as the second catch pad 320.
The second tee 324 is electrically coupled with the radial stub 326, and also with the DC port 330 by way of a line 328. In certain embodiments, either or both of the radial stub 326 and DC port 330 may be situated at least substantially at or on the same surface of the layer or substrate associated with the inductor 322.
The example also includes a first RF port 402 and a second RF port 406, such as the first and second RF ports 302 and 306, respectively, of
Either or both of the first and second wires 412 and 414, respectively, may be implemented as a bond wire. Either or both of the wires 412 and 414 may be at least substantially co-planar with or otherwise integrated on or with the same surface of the underlying substrate, e.g., layer, at or on which the first catch pad 416 is situated, e.g., the top layer 401. A connecting pin 418 serves to electrically couple the first catch 416 with a second catch pad, described below with regard to
Having described and illustrated the principles of the invention with reference to illustrated embodiments, it will be recognized that the illustrated embodiments may be modified in arrangement and detail without departing from such principles, and may be combined in any desired manner. And although the foregoing discussion has focused on particular embodiments, other configurations are contemplated. In particular, even though expressions such as “according to an embodiment of the invention” or the like are used herein, these phrases are meant to generally reference embodiment possibilities, and are not intended to limit the invention to particular embodiment configurations. As used herein, these terms may reference the same or different embodiments that are combinable into other embodiments.
Consequently, in view of the wide variety of permutations to the embodiments described herein, this detailed description and accompanying material is intended to be illustrative only, and should not be taken as limiting the scope of the invention. What is claimed as the invention, therefore, is all such modifications as may come within the scope and spirit of the following claims and equivalents thereto.