HIGH EFFICIENCY LINEARIZATION POWER AMPLIFIER FOR WIRELESS COMMUNICATION

Abstract

A predistortion system for linearizing the output of a power amplifier includes a first signal representative of an RF modulated signal and a feedback signal representative of nonlinear characteristics of a power amplifier. The system also includes a predistortion controller, comprising at least one lookup table, adapted to receive the first signal and the feedback signal and to generate a correction factor for correcting the nonlinear characteristics of the power amplifier and combining logic which combines the RF modulated signal with a signal corresponding to the correction factor and supplies it to the power amplifier to linearize the output of the power amplifier.

Claims

1. A method for routing and switching signals comprising: providing a plurality of remote radio units, each remote radio unit configured to transmit one or more downlink signals and to receive one or more uplink signals; providing at least one digital access unit configured to communicate with the plurality of remote radio units; translating the uplink and downlink signals between RF and base band; packetizing the uplink and downlink base band signals, wherein the packetized signals correspond to a plurality of carriers, each remote radio unit configured to receive or transmit a respective subset of the plurality of carriers; routing and switching the packetized signals among the plurality of remote radio units via the at least one digital access unit; reconfiguring at least one of the plurality of remote radio units by increasing or decreasing the number of carriers in the respective subset of the plurality of carriers; and thereafter routing and switching the packetized signals among the plurality of remote radio units via the at least one digital access unit according to a result of the reconfiguring.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0010] FIG. 1 shows a block diagram of the PA module with a predistortion controller in accordance with an embodiment of the invention.

[0011] FIG. 2 presents a simplified architecture of an embodiment of the predistortion controller of FIG. 1.

[0012] FIG. 3 illustrates in greater detail the embodiment of FIG. 2.

[0013] FIG. 4 shows the operation and arrangement of the lookup table in the predistortion controller shown in FIG. 3.

DETAILED DESCRIPTION OF THE INVENTION

[0014] The present invention relates generally to wireless communications systems, and more particularly relates to systems, apparatus and methods for correcting the nonlinearity of a Power Amplifier (PA) such as might be used in a wireless RF transmitter.

[0015] The present invention provides a novel predistortion controller to linearize the power amplifier (PA) used in wireless base stations operating in wireless networks using a wide variety of signal types including CDMA, TDMA, GSM, GPRS, 3G systems (UMTS, W-CDMA, CDMA2000, TDS-CDMA, 3GPP and others), WLAN, WiFi, WiMax and the like, as well as other proposed and upcoming wireless systems (4G/5G) that transmit a complex modulated signal by using a high power amplifier. Because the high power amplifier in wireless RF transmitters typically distorts the RF output signal, the adaptive predistortion controller of the present invention is useful to correct that non-linearity. Embodiments of the present invention are suitable for use with ail wireless base stations, access points and other wireless communication systems such as microwave and satellite communications. The predistortion controller of the present invention offers the additional advantage that it can be added to existing wireless RF transmitters without otherwise changing or modifying the base station structure while at the same time yielding significant performance improvements. Included in these improvements is a substantial increase in the efficiency of the base station, which yields a significant reduction in power usage because, in current systems, significant power is wasted due to the nonlinear characteristics of typical PA's.

[0016] From the following description, it will be appreciated that the high-efficiency linearization predistortion controller disclosed herein offers the following benefits to the wireless industry:

1. It significantly enhances the transmitted signal quality and increases wireless network capacity by improving the PA's transmission characteristics and decreasing the adjacent channel interference.
2. It can be implemented as an add-on module to the PA, which permits the aforementioned improvements to the performance of the PA without changing or modifying the existing RF and base band circuits in the base station. This differs from the traditional feedback and feed-forward predistortion approach, and therefore is a comparatively low cost, easy to install solution for the wireless network infrastructure whenever the operators desire to upgrade performance and reduce energy costs.
3. The predistortion control operation is fast and dynamic, which permits it to track and correct for nonlinearities of the PA in a wider, and makes it particularly suitable for use in base stations, repeaters and handsets.
4. It can be integrated into the design of the PA for convenient installation and replacement of aging PA's already installed in a wireless system.

[0017] Referring first to FIG. 1, the basic arrangement of the present invention can be appreciated. A predistortion controller 5 received as an input a modulated RF signal 6 and also receives a feedback signal 7 which correlates to the output signal of a power amplifier 12. The predistortion controller modifies the RF signal 6 in accordance with the nonlinear and distortion characteristics of the output signal of the power amplifier 12 as characterized by the feedback signal 7, such that the output of the predistortion controller 5 is supplied to the power amplifier 12 to yield a substantially linearized and improved out put signal of the power amplifier 12.

[0018] Referring next to FIGS. 2 and 3, an embodiment of the present invention may be appreciated in greater detail. More particularly, the illustrated embodiment includes an Analog Multiplier I1 which receives a modulated RF signal V.sub.RF from the RF modulator portion 10 FIG. 3 of the base station, and also receives a predistortion correction signal V.sub.p from a predistortion processor 200, shown generally in FIG. 2 and in greater detail in FIG. 3, and discussed in greater detail below. The output of the analog multiplier 11 is provided as the input V.sub.in to the power amplifier (PA) 12, which in turn transmits an output signal V.sub.o to an Antenna 13. The RF modulator 10 is typically although not necessarily a quadrature modulator or an orthogonal modulator. It will be appreciated that multiplier 11 can be implemented as multiple multipliers, each associated with one or more quadrature signals.

[0019] An input down-converter circuit 20 receives an idealized reference signal V.sub.RF from modulator in base station, and is biased by a local oscillator 40, such that it provides an output V.sub.ct to an analog-to-digital converter 21. The ADC 21 converts the signal V.sub.ct to digital form, whereupon it is provided as one input to a Digital Predistortion Processor 200.

[0020] A feedback down-converter circuit 26, also biased by a local oscillator 40, receives a raw feedback signal V.sub.o(t) from the output of the PA, and provides a feedback signal V.sub.f to an feedback ADC 25. The digital output of the ADC 25 then provides a second input, i.e., feedback signal, to the Digital Predistortion Processor 200. The Digital Predistortion Processor 200, discussed in greater detail below, provides a digital output signal V.sub.r to a DAC 30, which converts the digit signal to an analog form, where it is combined with the modulated RF signal in the multiplier 11.

[0021] As shown in FIG. 3, address data formers 32I-32Q receive inputs from the ADC 211/Q, and are designed to generate the required signal format for a lookup table 33I/Q. The data formers 32I/Q address memory units within the lookup tables 33I/Q, where the lookup table provides separate I and Q outputs to an adder 31. It will be appreciated that the lookup table 33 can be implemented as one or more lookup tables. The address provided by the address formers 32I-32Q can be considered a lookup-table key or address.

[0022] The predistortion controller lookup tables 33I-33Q are designed memory units to store the predistortion signal for high power amplifier linearization. The predistortion signals in the tables are based on the error generated by a comparison of the ideal signal V.sub.d and the feedback signal V.sub.f and the presented adaptive algorithm. The data stored in the tables 331-Q can be updated by adaptive iteration as described hereinafter, and forms digitally indexed data reflecting the nonlinear characteristics of the power amplifier.

[0023] By comparison of AM-AM and AM-PM information between the idealized signal V.sub.RF(t) and the feedback signal V.sub.o(t), the Digital Predistortion Processor calculates the error in the amplitude and phase components of the output signal V.sub.o(t) caused by the non-linear transmission characteristics of the high power amplifier 12.

[0024] Based on the error information obtained by the foregoing comparison, the predistortion processor, based on the lookup table algorithm disclosed in U.S. Pat. No. 6,985,704, the disclosure of which is hereby incorporated by reference, calculates and generates adaptively a compensation signal that is of inverse characteristics with the transform function of the PA 12 to pre-distort the AM-AM and AM-PM distortion caused by the PA 12.

[0025] The outputs V.sub.p of the predistortion lookup table 331-33Q are fed to multiplier 11, after an adder 31 and a digital-to-analog converter 30, to modify the modulated RF signal from modulator 10. The output of the multiplier is the required predistortion signal V.sub.in(k) that is of an inverse non-linearity with that of the power amplifier 12 to yield a pre-compensation to the input of high power amplifier.

[0026] It will be appreciated by those skilled in the art that there can be a signal difference between two signals, ideal signal V.sub.RF and feedback signal, V.sub.o(t), when they arrive at predistortion controller 5 [FIG. 1], or, in FIG. 2, at processor 200. The time difference results from the time-delay differences between the two signals, which is caused by the different paths each travels in arriving at the processor 200. This signal time-delay can vary randomly based on the parameters of the circuits and parts, as well as other environmental factors. The result is that it is difficult to estimate, calculate and adjust for such signal differences in the field application environment. To overcome this issue, the present invention adaptively adjusts for this time-delay through the use of an algorithm taught by the previously cited U.S. Pat. No. 6,985,704.

[0027] The use of the look-up tables 33 permits a memory function to be introduced into at least some embodiments of the present invention. The lookup table of the predistortion controller is based on a stored compensation principle that maps a set of input data into a digital output, and updated adaptively. Based on the stored function, each output signal of lookup table is actually related to both the current and the previously transmitted signal, and therefore has a memory function which compensate not only for the non-linearity of the PA, but also avoids the need for a special time-delay compensation circuit such as typically used in the prior art. See particularly U.S. Provisional Patent Application No. 60/898,312, filed Jan. 29, 10 2007, entitled Power Amplifier Time-delay Invariant Predistortion Methods and Apparatus.

[0028] The architecture of an embodiment of a lookup table which can implement the compensation principle discussed above is shown in FIG. 4. The data from ADC 21 is supplied to address former 32, which in turn forms an address and applies it to the look-up tables 33. At the same time, the feedback signal V.sub.feedback from ADC 25 and the ideal signal V.sub.ideal from ADC 21 are compared in the error generator 23 and the resulting error signal is multiplied by a numerical value I1 in multiplier 35. The value of I1 is typically between 0 and 1, and represents a convergence factor that can be better understood from the teachings in U.S. Pat. No. 6,985,704. The scaled error factor is then added with a feedback factor in adder 34 and supplied back to the lookup table 33. The result is an output of the lookup table which provides compensation for the time delay as well as nonlinearities of the PA 12.

[0029] Due to introducing the memorized lookup table processing, there is unnecessary to build another special time-delay circuit for the signal delay processing. Therefore, the memorized lookup table in this patent shows two functions, the nonlinear predistortion of high power amplifier and adaptive signal time-delay adjusting.

[0030] The lookup table of predistortion controller is based on a stored compensation principle that maps a set of input data into a digital output, and are updated adaptively. Based on the stored function, each output signal of lookup table is actually related to both the current and previous transmitted signal, and therefore has a memory function when compensate the non-linearity of PA W. The architecture of lookup table based on the compensation principle is shown in FIG. 4.

[0031] It will be appreciated further that the performance of the predistortion controller is, in some respects, related to the number of bits in the analog-to-digital converters in the original and feedback channels, whereby the bigger the number of bits in the ADC, the better the performance or the predistortion controller is. Similarly, the memory function of the predistortion controller is also related to the number of bits in the address-shifting register, such that, within reasonable sizes, the performance of the predistortion controller improves as the number of bits in the register increases. It will further be appreciated that the PA may be operated in any region, such that, for example, its bias or static operation point can be set either in the saturation region or the cut-off region, with appropriate adjustments for operation in each region. It will further be appreciated that the output signal of predistortion controller is a stochastic control signal rather than a modulated high-frequency signal, and the signal is of the inverse characteristic with the AM-AM and AM-PM distortion component of power amplifier. Those skilled in the art will also appreciate that the output signal of the predistortion controller is not a high-frequency signal, and its frequency typically match the bandwidth of the signal to be transmitted by a power amplifier in a wireless transmitter.

[0032] The combination of both memory and store function performed by the lookup table extends the ability of the present system to compensate for the PA's non-linear characteristics to time-independent aspects. The time-independent feature of the lookup table's adaptive processing is a key benefit of the addressing arrangement of the lookup table. In an embodiment, the addressing of the lookup table is implemented by a set of N-bit vector data that contains the current input signal and previous N input signal as well. Therefore, the address of the lookup table is a combination of series of input sequences with the length of N. The longer the address of the lookup table, the wider the time-delay information range that the system can accommodate (i.e. the longer duration of time-delay effects that the system can tolerate).

[0033] Having described the invention in detail, including several embodiments and alternatives, those skilled in the art will appreciate that numerous other alternatives and equivalents exist which are within the scope of the present invention. Therefore the invention is intended not to be limited by the above description, but rather only by the appended claims.