Patent Grant
8838045
The embodiments described herein relate to duplexers used in the frontend circuitry of communication devices. More particularly, the embodiments relate to real-time programmable duplexers.
Duplexers are an essential part of 3G cellular communication handsets. The overall purpose of a duplexer is to allow both the transmit (TX) and receive (RX) portions of a cellular radio to share a common antenna (ANT). Typically, a duplexer is a passive device with three ports: (1) a transmit port that connects to the output of the power amplifier (PA) stage of the radio, (2) a receive port that connects to the input of the low-noise-amplifier (LNA) receive stage of the radio, and (3) an antenna port which connects directly to the handset's antenna.
At present, surface acoustic wave (SAW) technology is the most ubiquitous for cellular handset duplexer applications. However, the requirements for some communications standards (notably 3G-PP Bands 2, 3, and 8) are extremely difficult or impossible to meet with standard SAW devices. The problem with respect to these bands is the very narrow frequency separation between the transmission and receiver bands.
This separation in frequency is usually referred to as the “transition band.” The steepness of the filters in this region is proportional to their quality factor (Q). Even SAW filter having Qs in the neighborhood of 300-500 cannot meet the rigorous requirements of the aforementioned 3GPP bands. Not only do those bands require very narrow transition bands, the problem is exacerbated by the necessary addition of margins for manufacturing and temperature variations.
Thus, there is a need for an improved duplexer that can meet the requirements of the 3GPP bands.
Embodiments disclosed in the detailed description relate to programmable duplexers. The frequency pass band of the duplexer is changed according to a selection of a channel pair selection to control or maximize the transition band between the receiver path and the transmitter path. The programmable duplexer permits selections of desired pass bands without the need for multiple duplexer filters. As an additional advantage, the transmission band requirements become less sensitive to manufacturing tolerances and temperature variations.
An exemplary embodiment of a duplexer for a communication device includes a receiver path. The receiver path may include a programmable receiver filter that provides a programmable receiver pass band. In addition, the duplexer includes a transmitter path including a programmable transmitter filter that provides a programmable transmitter pass band. The programmable transmitter filter may be separated from the programmable receiver filter by a transition band, where the programmable receiver pass band has an edge adjacent to the transition band, and the programmable transmitter pass band has an edge adjacent to the transition band. A controller may be configured to identify a channel pair selection provided for communication between the communication device and a base station. Thereafter, the controller may adjust at least one of the edge of the programmable transmitter pass band, the edge of the programmable receiver pass band, and a combination thereof depending upon the channel pair selection.
Another exemplary embodiment includes a programmable duplexer of a communication device. The exemplary embodiment may include a receiver filter having a receiver input and a receiver output, the receiver filter having a programmable receiver pass band. The exemplary embodiment may further include a transmitter filter including a transmitter input and a transmitter output, where the transmitter output is coupled to the receiver input, and wherein the transmitter filter has a programmable transmitter pass band. A controller may be coupled to the receiver filter and the transmitter filter. The controller may be adapted to identify a receiver-transmitter channel pair provided for communication between a mobile terminal and a base station. The controller may be further adapted to control at least one of the programmable receiver pass band, the programmable transmitter pass band, and a combination thereof, to maintain at least a minimum transition band between the programmable receiver pass band and the programmable transmitter pass band based upon the receiver-transmitter channel pair.
Another exemplary embodiment of a duplexer includes a receiver filter. The receiver filter includes a radio frequency receiver input and a radio frequency receiver output. The receiver filter further includes a receiver pass band having a programmable receiver pass band edge. The exemplary duplexer further includes a transmitter filter. The transmitter filter includes a radio frequency transmitter input and a radio frequency transmitter output. The radio frequency transmitter output may be coupled to the radio frequency receiver input. The transmitter filter may further include a transmitter pass band having a programmable transmitter pass band edge. The duplexer may also include a controller coupled to the receiver filter and the transmitter filter. The controller may modify at least one of the programmable receiver pass band edge and the programmable transmitter pass band edge based upon selection of a channel pair of a transmit frequency band and a receiver frequency band.
Those skilled in the art will appreciate the scope of the disclosure and realize additional aspects thereof after reading the following detailed description in association with the accompanying drawings.
The accompanying drawings incorporated in and forming a part of this specification illustrate several aspects of the disclosure, and together with the description serve to explain the principles of the disclosure.
a) depicts a plot of the impedance of a typical one-port resonator, broken into its real part (resistance) and imaginary part (reactance).
b) depicts a plot of the impedance of a typical one-port resonator having a series reactive component.
a) depicts a plot of the real part of the admittance (conductance) for a typical one-port resonator, along with the imaginary part (susceptance).
b) depicts a plot of the real part of the admittance (conductance) and imaginary part (susceptance) for a typical one-port resonator achieved by adding a reactive element in parallel with the one-port resonator.
The embodiments set forth below represent the necessary information to enable those skilled in the art to practice the disclosure and illustrate the best mode of practicing the disclosure. Upon reading the following description in light of the accompanying drawings, those skilled in the art will understand the concepts of the disclosure and will recognize applications of these concepts not particularly addressed herein. It should be understood that these concepts and applications fall within the scope of the disclosure and the accompanying claims. Embodiments disclosed herein relate to programmable duplexers. The frequency pass band of the duplexer is changed according to a selection of a channel-pair selection to control or maximize the transition band between the receiver path and the transmitter path. The programmable duplexer permits selections of desired pass bands without the need for multiple duplexer filters. As an additional advantage, the transmission band requirements become less sensitive to manufacturing tolerances and temperature variations.
An exemplary embodiment of a duplexer for a communication device includes a receiver path. The receiver path may include a programmable receiver filter that provides a programmable receiver pass band. In addition, the duplexer includes a transmitter path including a programmable transmitter filter that provides a programmable transmitter pass band. The programmable transmitter filter may be separated from the programmable receiver filter by a transition band, where the programmable receiver pass band has an edge adjacent to the transition band, and the programmable transmitter pass band has an edge adjacent to the transition band. A controller may be configured to identify a channel pair selection provided for communication between the communication device and a base station. Thereafter, the controller may adjust at least one of the edge of the programmable transmitter pass band, the edge of the programmable receiver pass band, or a combination thereof, depending upon the channel pair selection.
Another exemplary embodiment includes a programmable duplexer of a communication device. The exemplary embodiment may include a receiver filter including a receiver input and a receiver output, the receiver filter having a programmable receiver pass band. The exemplary embodiment may further include a transmitter filter including a transmitter input and a transmitter output, where the transmitter output is coupled to the receiver input, and wherein the transmitter filter has a programmable transmitter pass band. A controller may be coupled to the receiver filter and the transmitter filter. The controller may be adapted to identify a receiver-transmitter channel pair provided for communication between a mobile terminal and a base station. The controller may be further adapted to control at least one of the programmable receiver pass band, the programmable transmitter pass band, or a combination thereof, to maintain at least a minimum transition band between the programmable receiver pass band and the programmable transmitter pass band based upon the receiver-transmitter channel pair.
Another exemplary embodiment of a duplexer includes a receiver filter. The receiver filter includes a radio frequency receiver input and a radio frequency receiver output. The receiver filter further includes a receiver pass band having a programmable receiver pass band edge. The exemplary duplexer further includes a transmitter filter. The transmitter filter includes a radio frequency transmitter input and a radio frequency transmitter output. The radio frequency transmitter output may be coupled to the radio frequency receiver input. The transmitter filter may further include a transmitter pass band having a programmable transmitter pass band edge. The duplexer may also include a controller coupled to the receiver filter and the transmitter filter. The controller may modify at least one of the programmable receiver pass band edge and the programmable transmitter pass band edge based upon selection of a channel pair of a transmit frequency band and a receiver frequency band.
In typical SAW duplexers, the receiver filters and transmitter filters each include a multiplicity of synchronous one-port resonators configured alternately in series and in shunt arrangements to form a ladder filter or ladder topology.
The transmit signal and receiver signal are broadcast and received respectively within different frequency bands. The duplexer, therefore, is required to perform five primary functions. First, the duplexer permits TX-band signals to travel efficiently and with low insertion loss from the power amplifier (PA) to the antenna (ANT). Second, the duplexer allows RX-band signals to travel efficiently and with low insertion loss from the antenna (ANT) to the low noise amplifier (LNA). Third, the duplexer efficiently blocks TX-band signals at the antenna (ANT) port from getting through to the low noise amplifier (LNA). Fourth, the duplexer efficiently blocks spurious RX-band signals from the power amplifier (PA) from reaching the antenna (ANT) port. Fifth, the duplexer efficiently blocks any signals in either band from passing between the TX port and the RX port.
As depicted in
The resonant and anti-resonant frequencies of the one-port resonators are determined mostly by fixed fabrication parameters, such as mask layout, metal thickness, and photolithographic bias. However, the resonant and anti-resonant frequencies may be influenced by the addition of reactive elements in series or parallel with the resonators. Example reactive elements include capacitors and inductors.
a) depicts a plot of the impedance of a typical one-port resonator, broken into its real part (resistance) and imaginary part (reactance). The resonant and anti-resonant frequencies correspond to the points where the reactance equals zero. As depicted in
In contrast,
As mentioned previously, the lower pass band edge of a ladder filter is determined primarily by the resonant frequencies of the shunt resonators, while the upper pass band edge is determined by the anti-resonant frequencies of the series resonators. Thus, as depicted in
As further depicted in
The second series one-port resonator 32 is coupled in series with the first series one-port resonator 24. The second series one-port resonator 32 further includes a second switchable reactive element 34 in parallel with the second series one-port resonator 32. The second series one-port resonator 32 is in parallel with a second switchable reactive element 34. The second switchable reactive element 34 may include a reactive device 36 in series with a second switch 38 coupled to the controller 22. The reactive device 36 may be either a capacitor or an inductor. As illustrated in
The second series one-port resonator 32 may be coupled in series with a third series one-port resonator 40. The third series one-port resonator 40 further includes a third switchable reactive element 42 in parallel with the third series one-port resonator 40. The third series one-port resonator 40 is in parallel with a third switchable reactive element 42. The third switchable reactive element 42 may include a reactive device 44 in series with a third switch 46 that is coupled to the controller 22. The reactive device 44 may be either a capacitor or an inductor. As illustrated in
The example programmable transmitter filter 18 of
The programmable transmitter filter 18 of
As further depicted in
Although not shown, controller 22 may be configured to control each of the capacitor arrays. For example, the first capacitor array 74 and second capacitor array 78 may be coupled to a controller 22 (not shown), which controls the first capacitor arrays 74 and the second capacitor array 78, respectively. Based upon a channel-pair selection, the controller 22 configures each respective capacitor to maximize the transition band between the receiver channel and the transmit channel.
A first series one-port resonator 94 is coupled in parallel with a first switchable reactive element 96. A second series one-port resonator 98 is coupled in parallel with the second switchable reactive element 100. A third series one-port resonator 102 is coupled between the second series one-port resonator 98 and the antenna 104.
The first shunt one-port resonator 106 and the second shunt one-port resonator 108 are coupled in series with the third switchable reactive component 110.
The first shunt one-port resonator 122, the second shunt one-port resonator 124, and the third shunt one-port resonator 126 coupled in parallel may be coupled in series with a fourth switchable reactive element 128.
The output of the coupled resonator filter 116 is in cooperative function with the first shunt one-port resonator 122 and the second shunt one-port resonator 124 to form the first receiver output 118 and the second receiver output 120, respectively.
In some embodiments, the third switchable reactive component 110, the first shunt one-port resonator 122, and the second shunt one-port resonator 124 may be eliminated to form a simpler system, as depicted in
As an example operation 200, depicted in
Those skilled in the art will recognize improvements and modifications to the embodiments of the present disclosure. All such improvements and modifications are considered within the scope of the concepts disclosed herein and the claims that follow.
This application claims the benefit of provisional patent application Nos. 61/266,402, filed Dec. 3, 2009, and 61/297,172, filed Jan. 21, 2010, the disclosures of which are incorporated herein by reference in their entirety.
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| Number | Date | Country | |
|---|---|---|---|
| 20110299432 A1 | Dec 2011 | US |
| Number | Date | Country | |
|---|---|---|---|
| 61266402 | Dec 2009 | US | |
| 61297172 | Jan 2010 | US |
