The present disclosure relates generally to the field of lumped element radio frequency (RF) tuning and more specifically to the field of a calibration process for lumped element RF tuning.
Electronics devices (e.g., cell phones, smart phones, wireless-enabled portable computing devices) that incorporate radio frequency (RF) components may require complicated and time-consuming RF tuning before they are able to be properly tested and assembled. As illustrated in
As also illustrated in
The RF tuning (or impedance matching) of a port 106 to the testing environment may follow one or more RF tuning design approaches. For example, graphical RF tuning designs may utilize a Smith Chart methodology. An exemplary, simplified Smith chart is illustrated in
These RF tuning component location uncertainties along with path losses and non-ideal component behaviors due to parasitics, may effectively render any Smith Chart approach for RF tuning useless. The distance between the DUT and the testing resources also produces latency problems which renders the Smith chart approach even more inadequate. Therefore, because a strictly graphical RF tuning design approach is impracticable, other approaches are needed.
The above described graphical RF tuning process is often replaced by time consuming, trial-and-error methodology. Such trial-and-error RF tuning processes tend to be highly empirical, serial, and time consuming. For example, when following a trial-and-error process, one or more RF tuning elements 108 are laboriously varied over time until adequate RF tuning element matches are achieved for each RF path (that is, for each port 106 of the DUT 104). As the number of RF ports 106 for wireless devices increases, the complexity and time required to achieve optimal RF tuning increases undesirably.
Not only is trial-and-error costly and inefficient, it can also damage the DUT because constant heating and reheating of the circuit board while populating and removing the various tuning elements. This damage can not only render the DUT inoperable, but may result in a DUT that does not act as an undamaged DUT such that the testing would be faulty and unreliable.
What is therefore needed is a method and apparatus to more accurately and methodically tune the RF port.
Embodiments of this present invention provide solutions to the challenges inherent in efficiently tuning RF ports while avoiding conventional labor intensive, step-by-step processes. In a method according to one embodiment of the present invention, a process for simultaneously adjusting and tuning a plurality of RF devices is disclosed.
A preferred method uses at least three tuning blocks (comprised of capacitors and inductors) in a series topology and at least three tuning blocks in a shunt topology. These tuning blocks will yield two circles that can be charted on the Smith chart. Those circles are then centered along the centerline of the Smith chart to adjust for latency, and then expanded to adjust for the losses. In particular, the series circle is expanded until its edge reaches the edge of the Smith chart (i.e., infinite resistance), and the shunt circle is expanded until its edge reaches the other edge of the Smith chart (i.e., zero resistance). Once those circles have been expanded, the circle (either series or shunt) that encompasses one the Smith chart reference circles is used and the traditional Smith chart methodology can be used to tune the circuit.
The process of centering the created shunt and series circles calibrates for the lag/delay inherent in the testing environment where the testing resource is a non-negligible distance from the DUT. The process of expanding the shunt and series circle calibrates for the losses between the DUT and the testing resource. Thus by accounting for loss and latency, the testing equipment is calibrated such that it more accurately interfaces with the DUT enabling more accurate and reliable testing.
The method described herein can be incorporated as part of the testing equipment. For example, the testing equipment may include three series block and three shunt blocks on a circuit board, which may be incorporated with the interface board. The testing equipment may then obtain measurements from each of the blocks and execute the method described above. In this fashion, the testing equipment can calibrate and achieve more accurate RF tuning.
The present invention will be better understood from the following detailed description, taken in conjunction with the accompanying drawing figures in which like reference characters designate like elements and in which:
Reference will now be made in detail to the preferred embodiments of the present invention, examples of which are illustrated in the accompanying drawings. While the invention will be described in conjunction with the preferred embodiments, it will be understood that they are not intended to limit the invention to these embodiments. On the contrary, the invention is intended to cover alternatives, modifications and equivalents, which may be included within the spirit and scope of the invention as defined by the appended claims. Furthermore, in the following detailed description of embodiments of the present invention, numerous specific details are set forth in order to provide a thorough understanding of the present invention. However, it will be recognized by one of ordinary skill in the art that the present invention may be practiced without these specific details. In other instances, well-known methods, procedures, components, and circuits have not been described in detail so as not to unnecessarily obscure aspects of the embodiments of the present invention. The drawings showing embodiments of the invention are semi-diagrammatic and not to scale and, particularly, some of the dimensions are for the clarity of presentation and are shown exaggerated in the drawing Figures. Similarly, although the views in the drawings for the ease of description generally show similar orientations, this depiction in the Figures is arbitrary for the most part. Generally, the invention can be operated in any orientation.
This present invention provides a solution to the increasing challenges inherent in lumped element radio frequency (RF) tuning, and more specifically to a calibration process for lumped element RF tuning Various embodiments of the present disclosure provide an efficient process for lumped element RF tuning. As discussed in detail below, exemplary embodiments adopt a parallel parametric sweep approach to RF tuning, in contrast to a conventional, empirical step-by-step serial process. By adopting a controlled parametric sweep, the RF tuning network may be characterized thoroughly and systematically.
In the theoretical Smith graphical tuning scheme, the impedance of the DUT is plotted on the Smith chart. By way of background and referring to
The shunt circles 210 refer to the tuning elements placed in a shunt topology—i.e., where they are in parallel to the DUT and grounded. This is shown in
The general method is to plot the impedance of the DUT on the Smith chart. The impedance of the DUT can be tuned either in a shunt or series topology, thus traveling along either a shunt circle or series circle. Since the goal of tuning is the reach the desired impedance of the DUT (i.e., position 230) and the impedance can only travel along the shunt/series circles, it becomes evident that either the shunt circle 235 or the series circle 240 must be the final circle that must be used to reach position 230.
Turning to
1. Upward direction uses an inductor, downward direction uses a capacitor;
2. Impedance tuning circle uses a series element, Admittance tuning circle uses a shunt element.
3. The paths passing through R=0 and R=∞ are forbidden.
Using the Smith chart tuning method, at least theoretically, allows for impedance matching for more accurate testing of the DUT. But that is the problem, the Smith graphical tuning method tunes the DUT at a location that is extremely close to the DUT such that the Smith tuning method does not account for losses or latency effects. And that is why the Smith graphical tuning method is often not used because it is inaccurate, and those in the art instead use the laborious and damaging trial-and-error method to tune the DUT.
As shown in
The method essentially places a number of tuning elements in series with the DUT and maps those locations to the Smith chart. Then the same is done for a number of tuning elements in a shunt topology and maps those locations to the Smith chart. As will be apparent to one of skill in the art, only three alternate tuning elements need to be used for each of the shunt and series circles to define a circle. Once the circles are defined, they are centered along the centerline, then expanded to reach either conductance of ∞ (R=0) for the shunt circles or conductance of 0 (R=∞) for the series circles. This essentially calibrates the testing system to account for loss and latency. The method can be done quickly in the testing resource 110 which includes an electronic processor.
Referring to
Then at step 308, a network analyzer port extension is calculated that rotates the circle (shown by arrow 408) to a correct position in the Smith Chart—i.e., the fitted circle is placed on the centerline of the Smith Chart as shown in
With the tuning circle rotated properly, at step 310 the tuning circle may then be scaled outward (shown by arrow 409) to touch the Smith Chart unit circle to account for any path loss (see
Because a shunt topology was used, the preferred method determines whether the fitted and calibrated circle can then be used in the theoretical Smith graphical tuning method discussed above. In
For this reason, step 312A determines whether for a shunt topology, the fitted shunt circle 410 is within the shunt circle 235. If it is, then the method proceeds to step 314A and repeats to calculate a fitted series circle. If the answer at decision step 312A is no, then either the fitted circle is the same as the shunt circle 235 or larger. In either case, there is a path to reach the reference impedance at position 230.
It should be apparent, that if instead of beginning with a shunt topology, a series topology was chosen as the starting point, steps 302 through 310 are the same. At step 312B, the method checks to see if a path exists to reach position 230.
Now that the RF tuning element data points fall on a proper series or shunt Smith Chart circle, specific component value locations on the circle may be displaced from an ideal element due to component parasitics. Since there is now both measured data for the RF tuning elements, as well as for the ideal values, the real RF component behaviors may be mathematically calibrated.
Instead of requiring a technician to manually vary the tuning elements to achieve the at least three measurements needed to create the shunt (or series) circle, the tuning elements may be placed on a printed circuit board such that the analyzer can automatically take the measurements and calibrate.
The printed circuit board may also include four tuning components in a shunt topology as shown in
To initially calibrate the system, a device with a known and stable resistance/conductance may be selected (for example, a resistor with a highly accurate and stable value, say 200Ω) and used as the DUT. The system then performs the calibration knowing precisely what the DUT impedance should measure.
Although certain preferred embodiments and methods have been disclosed herein, it will be apparent from the foregoing disclosure to those skilled in the art that variations and modifications of such embodiments and methods may be made without departing from the spirit and scope of the invention. It is intended that the invention shall be limited only to the extent required by the appended claims and the rules and principles of applicable law.
Number | Date | Country | |
---|---|---|---|
61912388 | Dec 2013 | US |