Patent Grant
9922763
The disclosure relates in general to a transformer having two largely different transformation ratios (TR).
Transformers are widely used in modern radio frequency (RF) transceiver design to control signal flow. There are many conventional ways to implement the transformer using metal conductors routed in an integrated circuit. For example, an on-chip transformer can be implemented using a one-side coplanar design, a two-side coplanar design, a broadside design, or a hybrid design. The impedance transformation is critical in RF transceiver design to improve power efficiency.
How to achieve the on-chip transformer having better coupling efficiency and less coupling loss is highly desired.
The disclosure is directed to a transformer having two largely different transformation ratio (TR) wherein the transformer operated in a low coupling, high TR mode is used in low output power condition while the transformer operated in a high coupling, low TR mode is used in high output power condition.
According to one embodiment, a transformer is provided. The transformer includes a first winding conductor and a second winding conductor, magnetically coupled to the first winding conductor. A first transformation ratio is achieved between the second winding conductor and the first winding conductor. A first distance between the first winding conductor and the second winding conductor is higher than a distance threshold, and accordingly, a first coupling factor between the first winding conductor and the second winding conductor is lower than a coupling factor threshold.
According to another embodiment, a transformer is provided. The transformer includes a first winding conductor, routed in an inner part on a first metal layer of the transformer; a second winding conductor, magnetically coupled to the first winding conductor, routed in an outer part on a second metal layer of the transformer; and a third winding conductor, magnetically coupled to the second winding conductor, routed in an outer part on the first metal layer of the transformer. The second winding conductor and the third winding conductor are vertically stacked. A first transformation ratio is based on a first distance and an inductance ratio between the first and the second winding conductors. A second transformation ratio is based on a second distance and an inductance ratio between the third and the second winding conductors. The first transformation ratio is higher than the second transformation ratio.
According to yet another embodiment, a transformer is provided. A transformer includes: a first winding conductor; a second winding conductor, magnetically coupled to the first winding conductor; and a third winding conductor, magnetically coupled to the second winding conductor. A first coupling factor is achieved between the first and the second winding conductors. A second coupling factor, higher than the first coupling factor, is achieved between the second and the third winding conductors.
According to still another embodiment, a transformer is provided. A transformer includes: a first winding conductor; a second winding conductor, magnetically coupled to the first winding conductor; and a third winding conductor, magnetically coupled to the second winding conductor. A first coupling factor and a first transformation ratio are achieved between the first and the second winding conductors. A second coupling factor and a second transformation ratio are achieved between the second and the third winding conductors, the first coupling factor lower than the second coupling factor, the first transformation ratio higher than the second transformation ratio. An inductance of the first winding conductor is bigger than both inductances of the second and the third winding conductors, and a surrounding area of the first winding conductor is smaller than both surrounding areas of the second and the third winding conductors.
In the following detailed description, for purposes of explanation, numerous specific details are set forth in order to provide a thorough understanding of the disclosed embodiments. It will be apparent, however, that one or more embodiments may be practiced without these specific details. In other instances, well-known structures and devices are schematically shown in order to simplify the drawing.
Technical terms of the disclosure are based on general definition in the technical field of the disclosure. If the disclosure describes or explains one or some terms, definition of the terms is based on the description or explanation of the disclosure.
Each of the disclosed embodiments has one or more technical features. In possible implementation, one skilled person in the art would selectively implement part or all technical features of any embodiment of the disclosure or selectively combine part or all technical features of the embodiments of the disclosure.
In the following, the term “couple” is intended to mean either an indirect or a direct electrical connection. Thus, if a first device is coupled to a second device, that connection may be through a direct electrical connection, or through an indirect electrical connection via other devices and connections.
As is well known, transformers include a primary winding and a secondary winding. A current coming into the primary winding induces a magnetic field that, in turn, generates the current so that power is transferred from the primary winding to the secondary winding. The relationship between the voltage/current input to the primary winding and the voltage/current output by the secondary winding is defined by the transformation ratio (TR) of the transformer.
The first winding conductor 110 and the third winding conductor 130 are routed on the same metal layer (i.e. the first winding conductor 110 and the third winding conductor 130 are lateral), while the second winding conductor 120 is routed on another metal layer. In other possible embodiments of the application, the first winding conductor 110 and the third winding conductor 130 are stacked. Details of the first winding conductor 110, the second winding conductor 120 and the third winding conductor 130 are as follows.
The first winding conductor 110 is electrically coupled to a first terminal (P1) and a second terminal (P2) of a first one of the corresponding input/output ports coupled to the transformer 100. The first winding conductor 110 is formed on the first metal layer M1. The first winding conductor 110 is routed in an inner part on the first metal layer M1 of the transformer 100. For example but not limited by, the first winding conductor 110 is routed in a center of the first metal layer M1 of the transformer 100.
The first winding conductor 110 includes a plurality of first sections 210 routed on the first metal layer M1, and a plurality of first interconnection sections 220 interconnecting the sections 210 through vias 230. The first interconnection sections 220 are formed on the second metal layer M2. Besides, a plurality of interconnection sections 240, formed on a third metal layer, are used to interconnect the first winding conductor 110 with the first terminal (P1) and the second terminal (P2) of the corresponding input/output port. The terminal TP is coupled to the first winding conductor 110 via the interconnection section 240. The terminal TP is a center tap of the balun and is connected to the supply voltage.
The first winding conductor 110 is magnetically coupled to the second winding conductor 120. In some embodiments of the application, the first winding conductor 110 is a primary winding of the transformer 100; while in other embodiments of the application, the first winding conductor 110 is a secondary winding of the transformer 100. Whether the first winding conductor 110 acts as the primary winding or the secondary winding depends on the signal flow direction. That is, if the corresponding port (having the terminals P1 and P2) coupled to the first winding conductor 110 is designed to receive a differential input signal, then the first winding conductor 110 acts as the primary winding. On the contrary, if the corresponding port (having the terminals P1 and P2) coupled to the first winding conductor 110 is designed to output a single-ended output signal, then the first winding conductor 110 acts as the secondary winding.
The second winding conductor 120 is electrically coupled to a first terminal (S1) and a second terminal (S2) of a second one of the corresponding input/output ports coupled to the transformer 100. The second winding conductor 120 is formed on the second metal layer M2. The second winding conductor 120 is routed in an outer part on the second metal layer M2 of the transformer 100.
Please note that the naming of the metal layers M1, M2 is not meant to limit the position relationship of the first and the second metal layers. For example, in one embodiment, the first metal layer M1 is configured to be disposed under the second metal layer M2; however, in another implementation, the first metal layer M1 could be alternatively disposed above the second metal layer M2. In short, the metal layers on which the winding conductors are routed depend upon design requirements. In addition, it should be noted that the layout design shown in the drawing is for illustrative purposes only, and is not meant to be a limitation of the present invention. That is to say, other alternative layout designs obeying the spirit of the present invention still fall within the scope of the present invention.
The second winding conductor 120 includes a plurality of second sections 250 routed on the second metal layer M2, and at least one second interconnection section 260 interconnecting the sections 250 through vias. The second interconnection section 260 is for example, but not limited by, formed on the first metal layer M1.
The second winding conductor 120 is magnetically coupled to the first winding conductor 110 and the third winding conductor 130. In some embodiments of the application, the second winding conductor 120 is a secondary winding of the transformer 100 (if the first winding conductor 110 is a primary winding of the transformer 100); while in other embodiments of the application, the second winding conductor 120 is a primary winding of the transformer 100 (if the first winding conductor 110 is a secondary winding of the transformer 100). Whether the second winding conductor 120 acts as the primary winding or the secondary winding depends on the signal flow direction. That is, if the corresponding port (having the terminals S1 and S2) coupled to the second winding conductor 120 is designed to output a single-ended output signal, then the second winding conductor 120 acts as the secondary winding. On the contrary, if the corresponding port (having the terminals S1 and S2) coupled to the second winding conductor 120 is designed to receive a differential input signal, then the second winding conductor 120 acts as the primary winding.
The second winding conductor 120 is vertically stacked with the third winding conductor 130. That is to say, in the embodiment of the application, the second winding conductor 120 is routed on the outer part of the second metal layer M2 and the third winding conductor 130 is routed on the outer part of the first metal layer M1. Besides, the second winding conductor 120 may be not precisely aligned with the third winding conductor 130.
The third winding conductor 130 is electrically coupled to a first terminal (P3) and a second terminal (P4) of a third one of the corresponding input/output ports coupled to the transformer 100. The third winding conductor 130 is formed on the first metal layer M1. The third winding conductor 130 is routed in the outer part on the first metal layer M1 of the transformer 100. The third winding conductor 130 surrounds the first winding conductor 110.
The third winding conductor 130 includes a plurality of third sections 270 routed on the first metal layer M1, and at least one third interconnection section 280 interconnecting the sections 270 through vias. The third interconnection section 280 is formed on the third metal layer which is different from the first and the second metal layers M1 and M2.
The third winding conductor 130 is magnetically coupled to the second winding conductor 120. In some embodiments of the application, the third winding conductor 130 is a primary winding of the transformer 100 (if the second winding conductor 120 is a secondary winding of the transformer 100); while in other embodiments of the application, the third winding conductor 130 is a secondary winding of the transformer 100 (if the second winding conductor 120 is a primary winding of the transformer 100). Whether the third winding conductor 130 acts as the primary winding or the secondary winding depends on the signal flow direction. That is, if the corresponding port (having the terminals P3 and P4) coupled to the third winding conductor 130 is designed to receive a differential input signal, then the third winding conductor 130 acts as the primary winding. On the contrary, if the corresponding port (having the terminals P3 and P4) coupled to the third winding conductor 130 is designed to output a single-ended output signal, then the third winding conductor 130 acts as the secondary winding.
The transformation ratio (TR) is expressed by the formula (1):
TR=neq2 (1)
The parameter “neq” refers to an equivalent turn ratio, which is expressed by the following formula (2):
The parameter “n” refers to the turn ratio of the primary winding and the secondary winding, the parameter “k” refers to a coupling factor between the primary winding and the secondary winding, “L” refers to the inductance of the secondary winding, and “RL” refers to the load resistance of the secondary winding. In the transformer 100, the small inductance L is used and thus the term “(1−k)2(ωL/RL)2” is very small.
In an embodiment of the application, the parameter “k” is related to the distance between the primary winding and the secondary winding. Further, if the distance between the primary winding and the secondary winding is far, then the parameter “k” is small.
The first winding conductor 110 and the second winding conductor 120 achieve a low coupling “k” because the distance between the first winding conductor 110 and the second winding conductor 120 is far. The third winding conductor 130 and the second winding conductor 120 achieve a high coupling “k” because the distance between the third winding conductor 130 and the second winding conductor 120 is close.
Further, an inductance of the first winding conductor 110 is bigger than both inductances of the second and the third winding conductors 120 and 130, and a surrounding area of the first winding conductor 110 is smaller than both surrounding areas of the second and third winding conductors 120 and 130. Further, a first transformation ratio is based on a first distance and an inductance ratio between the first and the second winding conductors 110 and 120. A second transformation ratio is based on a second distance and an inductance ratio between the third and the second winding conductors 130 and 120. The first transformation ratio is higher than the second transformation ratio.
For example, as shown in
However, as shown in
As shown in the drawing, the first winding conductor 110 leaves the metal space on the first metal layer M1 for the second input inductor to form the high transformation ratio mode. In other words, the first winding conductor 110 leaves the metal space on the first metal layer M1 for the third winding conductor 130. The first winding conductor 110 and the third winding conductor 130 are both routed on the first metal layer M1 for saving circuit areas.
In other words, in the embodiment of the application, the stacked transformer structure and the lateral transformer structure are used to achieve two largely different transformation ratios. The stacked transformer structure is achieved by the second winding conductor 120 (routed on the outer part of the second metal layer M2) and the third winding conductor 130 (routed on the outer part of the first metal layer M1) which are vertically stacked. The lateral transformer structure is achieved by the second winding conductor 120 (routed on the outer part of the second metal layer M2) and the first winding conductor 110 (routed on the inner part of the first metal layer M1) which are lateral, although the second winding conductor 120 and the first winding conductor 110 are routed on the different metal layers.
Now refer to
As shown in
As shown in
The transformer 100 combines the features of the low coupling and the high coupling. When the input feeds into the first port coupled to the first winding conductor 110 (i.e. the first winding conductor 110 is as the primary winding), the transformer 100 operates in the low coupling, high TR mode which is suitable in low output power condition. When the input feeds into the third port coupled to the third winding conductor 130 (i.e. the third winding conductor 130 is as the primary winding), the transformer 100 operates in the high coupling, low TR mode which is suitable in high output power condition. Thus, the transformer 100 of the embodiment of the application may efficiently utilize available headroom at low output power to maximize power efficiency.
For example but not limited by, the transformer 100 of the embodiment of the application is suitable for being coupled to the PGA (programmable gain amplifier) of the RF transceiver design. Further, the transformer 100 of the embodiment of the application is suitable in RF circuit which meets two or more different output power requirements.
Further, by the low coupling, high transformation ratio mode of the transformer 100, the impedance transformation ratio is boosted. Because the low coupling “k” is used to realize the low coupling, high transformation ratio mode of the transformer 100, the de-Q effect on the high coupling, low transformation ratio mode is reduced. The circuit area is efficiently used because the metal layer space is left and available for the high coupling, low transformation ratio transformer structure.
It will be apparent to those skilled in the art that various modifications and variations can be made to the disclosed embodiments. It is intended that the specification and examples be considered as exemplary only, with a true scope of the disclosure being indicated by the following claims and their equivalents.
This application claims the benefit of U.S. provisional application Ser. No. 62/069,499, filed Oct. 28, 2014, the disclosure of which is incorporated by reference herein in its entirety.
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