Patent Publication Number: US-7899414-B2

Title: Control of power amplifiers in devices using transmit beamforming

Description:
CROSS REFERENCE TO RELATED APPLICATION(S) 
     This application is a continuation of U.S. application Ser. No. 11/326,630, filed Jan. 06, 2006 which in turn is a continuation of U.S. application Ser. No. 10/867,249 filed Jun. 14, 2004 which is also a continuation of U.S. application Ser. No. 10/249,063, filed Mar. 13, 2003, now U.S. Pat. No. 6,871,049, which in turn claims priority to U.S. Provisional Application No. 60/365,811, filed Mar. 21, 2002, to U.S. Provisional Application No. 60/365,775 filed Mar. 21, 2002 and to U.S. Provisional Application No. 60/365,797, filed Mar. 21, 2002, which are incorporated by reference as if fully set forth. 
    
    
     BACKGROUND OF THE INVENTION 
     The present invention relates to radio communication devices. 
     In a radio transmitter, a power amplifier is included to amplify the radio frequency signal to be transmitted via an antenna. The power amplifier is controlled through a variety of mechanisms to output radio frequency energy at a desired power level. Generally, the maximum transmit power at the antenna is limited by regulatory requirements in the band of operation. 
     Typically, the power amplifier dominates the power consumption in the radio transmitter. Power amplifier efficiency is the ratio of the output power of the power amplifier to the power it consumes, PA eff =P out /P cons . 
     The gain of the power amplifier is the ratio of the output power to the input power, PA gain =PA out /PA in . The output power can be controlled by changing the input power level. For a desired maximum output power, the efficiency of the power amplifier can be controlled by adjusting the bias current of the power amplifier. The power consumption of the power amplifier is a function of the DC current which is determined by the power amplifier bias current and the output power:
 
 P   cons   =PA   dc   +f ( P   out ).
 
     High power amplifier efficiency introduces non-linearities that affect the integrity of the transmit signal. Therefore, the operating point of the power amplifier is selected by trading efficiency versus linearity. 
     Transmit beamforming has been proposed as a way to improve data rate and range of signals transmitted to another device. Multiple transmit antennas are used at the transmitter of one device when transmitting signals to another device, whereby weighted versions of the baseband signal are upconverted and transmitted by corresponding ones of a plurality of antennas. The transmit antenna weights are computed by maximizing a cost function (e.g., signal-to-noise ratio at the receiver of the other device). One example and application of transmit beamforming is disclosed in U.S. patent application Ser. No. 10/174,728, filed Jun. 19, 2002 and entitled “System and Method for Antenna Diversity Using Joint Maximal Ratio Combining,” the entirety of which is incorporated herein by reference. 
     According to these techniques each transmitter requires a power amplifier to amplify the signal at the input to the antenna to a desired level. For N antennas, the total power consumption could reach N times the power consumption of a single antenna system. Any given power amplifier may be required to transmit at a level up to a maximum power level. What is needed is a procedure and system to optimize the DC power consumption of the power amplifiers when transmitting from multiple antennas. 
     SUMMARY OF THE INVENTION 
     A method optimizes the efficiency of each of a plurality of power amplifiers that amplify a corresponding one of a plurality of radio frequency signals for a beamforming transmission by a corresponding one of a plurality of antennas. Using transmit beamforming, the power of each amplified signal output by the power amplifiers may not be the same for all the power amplifiers, and may vary with changes in the communication channel between the transmitting device and receiving device. Each of the plurality of power amplifiers is controlled to operate with one or more operating parameters that optimize the efficiency for an output power level of corresponding ones of the radio frequency signals. By adjusting one or more operating parameters of each power amplifier according to changing requirements (e.g., the destination device and channel conditions), the efficiency of each power amplifier can be optimized. Consequently, one or more of the power amplifiers are operated with one or more operating parameters that reflects the output power actually needed for the corresponding radio frequency signal to be transmitted. 
     Other objects and advantages will become more apparent when reference is made to the following description taken in conjunction with the accompanying drawings. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         FIG. 1  is a block diagram of a system that optimizes the efficiency of a plurality of power amplifiers in a beamforming radio transmitter system according to a first embodiment. 
         FIG. 2  is a block diagram showing multiple communication devices that may communicate between each other using transmit beamforming techniques. 
         FIG. 3  is a diagram that illustrates the data that may be used to generate parameters that optimize the efficiency of the power amplifiers. 
         FIG. 4  is a flow chart depicting a method for controlling the power amplifiers in the system shown in  FIG. 1 . 
         FIG. 5  is a block diagram of a system that optimizes the efficiency of a plurality of power amplifiers in a beamforming radio transmitter system according to a second embodiment. 
         FIG. 6  is a flow chart depicting a method for controlling the power amplifiers in the beamforming radio transmitter system of  FIG. 5 . 
         FIG. 7  is a block diagram of a system that optimizes the efficiency of a plurality of power amplifiers in a beamforming radio transmitter system according to a third embodiment. 
         FIG. 8  is a flow chart depicting a method for controlling the power amplifiers in the system shown in  FIG. 7 . 
     
    
    
     DETAILED DESCRIPTION OF THE DRAWINGS 
     Referring first to  FIG. 1 , a beamforming radio transmitter system is shown generally at reference numeral  100 . The system  100  comprises a plurality of power amplifiers  110 ( 1 ) through  110 (N), each of which is coupled to a corresponding one of a plurality of transmit antennas  120 ( 1 ) through  120 (N). Each power amplifier  110 ( 1 ) to  110 (N) has a corresponding power amplifier bias circuit  130 ( 1 ) to  130 (N). 
     In a radio frequency (RF) transmitter section  140 , there are a plurality of RF upconverters  140 ( 1 ) through  140 (N) each of which supplies a radio frequency signal to a corresponding one of the power amplifiers  110 ( 1 ) to  110 (N). The details of each RF upconverter  140 ( 1 ) through  140 (N) are not relevant to the beamforming transmitter system described herein. Further details of a suitable radio transmitter section are disclosed in, for example, commonly assigned and co-pending U.S. patent application Ser. No. 10/065,388 filed Oct. 11, 2002, and entitled “Multiple-Input Multiple-Output Radio Transceiver,” the entirety of which is incorporated herein by reference. For example, there may be filters, oscillators, etc., between the RF section  140  and the power amplifiers  110 ( 1 ) to  110 (N), as well as filters between the power amplifiers  110 ( 1 ) to  110 (N) and transmit antennas  120 ( 1 ) to  120 (N). 
     The inputs to the RF section  140  are baseband signals w 1 (f)S(f) through wN(f)S(f), which are individual baseband signals produced by weighting the baseband signal S(f) with each of the plurality of transmit weights w 1 (f)S(f) through w N (f)S(f). Transmit weight w 1 (f) corresponds to the signal to be transmitted by antenna  120 ( 1 ), transmit weight w 2 (f) corresponds to the signal to be transmitted by antenna  120 ( 2 ), and so on. The signal S(f) may be one signal or packet to be weighted, upconverted and transmitted simultaneously by the plurality of antennas  120 ( 1 ) through  120 (N), or may be a stream of multiple packets to weighted, upconverted and transmitted simultaneously by the plurality of antennas  120 ( 1 ) through  120 (N). 
     The weighting computations may be performed in a baseband signal processor  150 . For example, the baseband signal processor  150  may perform the necessary baseband modulation and formatting depending on the particular communication protocol employed, such as, for example, IEEE 802.11x. The baseband signal processor  50  may be implemented by a plurality of gates that execute the necessary instructions in an application specific integrated circuit (ASIC), dedicated microprocessor programmed with suitable instructions encoded on a memory medium, etc. The weighted baseband signals w 1 (f)S(f) through w N (f)S(f) are supplied as input to a corresponding one of the RF upconverters  140 ( 1 ) through  140 (N). 
     When transmitting RF signals representing the weighted signals, the power consumption characteristics of the power amplifiers are controlled by adjusting one or more power amplifier operational parameters in order to optimize the efficiency of the power amplifiers. There are several ways in which the power amplifier efficiency can be optimized.  FIG. 1  shows one mechanism in which the power amplifier bias circuits are controlled,  FIG. 5  shows another mechanism in which the operating voltage to each power amplifier is adjusted and  FIG. 7  illustrates still another mechanism in which the self-bias boosting circuits are used to automatically bias the power amplifiers. In each of these embodiments, one or more of the power amplifiers are operated with one or more operating parameters that reflects the output power actually needed for the corresponding transmit signal. 
     The maximum total radiated power from all the transmit antennas  120 ( 1 ) through  120 (N), PA out     —     total , must not exceed the limits of the regulatory requirements:
 
 PA   out     —     total   =PA   out(1)   +PA   out(2)   + . . . +PA   out(N) &lt;Max. power.
 
     The regulatory requirements on the maximum transmit power is independent of the number of transmit antennas. 
     With reference to  FIG. 2 , a plurality of radio communication devices  200 ,  210 ,  220 ,  230  and  240  having transmit beamforming capabilities is shown. The channel transfer function between any two communication devices is different. The optimum transmit weights depend on the channel transfer function between any two devices. The transmit weights of the transmitting device are different for each intended receiving device. Each communication device shown in  FIG. 2  has two antennas for transmission and receptions, as an example. 
     It is statistically possible that for a particular channel, the optimum transmit antenna weights may dictate that all of the transmit power be generated through one antenna, and for a different channel, that all of the transmit power be generated through a different antenna. The power amplifiers would have to be biased such that they are all capable of transmitting all of the power. Therefore, the DC power consumption of each power amplifier is the same as the DC power of a single power amplifier when a single antenna is used
 
 PA   dc     —     total   =PA   dc(1)   +PA   dc(2)   + . . . +PA   dc(N)   =N PA   dc(1)  
 
     Although the total output power is the same, the DC power consumption of N power amplifiers is N times the DC power of a single power amplifier in the single antenna case. This would result in substantial power consumption and is inefficient because for one or more of the transmit signals, the corresponding power amplifier need not be operated with parameters sufficient for maximum power amplification. 
     With reference to  FIG. 3  in conjunction with  FIG. 1 , a procedure is described to dynamically adjust the bias supplied to the power amplifiers so as to optimize their DC power consumption. In any given communication device, the transmit antenna weights for each destination device are computed a priori and stored in a table at the transmitting station. For example, the transmit antenna weights may be stored indexed against an identifier of the destination device, such as the medium access control (MAC) address of the destination device. Techniques that a device may use to compute the transmit antenna weights may vary, and one such technique is described in the aforementioned co-pending U.S. non-provisional patent application referred to above. 
     In each communication device, transmit weights are used to weight a baseband signal to produce weighted signals representing a packet of information to be transmitted to a destination device. The bias circuits  130 ( 1 ) through  130 (N) for power amplifiers  110 ( 1 ) through  110 (N) control the bias voltage or current for each power amplifier. Information necessary to control the bias circuits is derived from the transmit weights. The bias circuits  130 ( 1 ) through  130 (N) for power amplifiers  110 ( 1 ) through  110 (N) can be adjusted on a per-packet basis to account for changes in the transmit weights that are the result of changing channel conditions between the transmitting device and a particular destination device. By adjusting the bias for each power amplifier, the gain and linearity for each power amplifier, as well as the DC current drain, is adjusted, to optimize the efficiency of the power amplifier at a required level of output power. 
     A microprocessor  160  may be used to control the bias voltages or currents of the bias circuits  130 ( 1 ) through  130 (N) by deriving digital current (or voltage values) that are converted to analog signals for each bias circuit by one or more digital-to-analog converters (DAC(s))  170 . The intelligence to derive the bias circuit control signals may alternatively be included in the baseband signal processor. Updated values for the transmit weights are stored in a memory  162  associated with the microprocessor and/or in a memory  152  associated with the baseband signal processor  150 . 
     It may be desirable for all the power amplifiers to have the same efficiency. When a transmit packet is being prepared for transmission, the transmit antenna weights are used to compute the maximum transmit power at each antenna: 
     The maximum transmit power at each antenna is used to compute the power amplifier bias (voltage or current) for the specified output power to optimize efficiency. As shown in  FIG. 3 , the bias control signals (e.g., bias control current values or bias control voltage values) are computed from the transmit weights using a mathematic formula computation, or a look-up-table (LUT) that stores control values corresponding to antenna weights. The power amplifier biases may be adjusted with the computed values before the start of the packet transmission for every transmitted packet so that there is no need to store state for the bias control signals. This process is repeated for every new packet. Alternatively, the biases can be left unchanged from transmit packet to transmit packet until there is a change in the transmit weights. 
     To explain this in connection with a specific example, reference is made to a process  300  represented by the flow chart shown in  FIG. 4 , in which device  210  is preparing to transmit a packet to device  200 . In step  310 , a processor (baseband signal processor  150  or microprocessor  160 ) in device  210  determines that a packet is to be transmitted to device  200 . The transmit weights for device  200  (stored in device  210 ) are retrieved in step  320 , and in step  330 , the bias control signals are computed for the bias circuits for each power amplifier. In step  340 , the bias control signals are converted to analog signals and coupled to the bias circuits. In step  350 , the RF signals coupled to each amplifier are amplified by the corresponding power amplifier for transmission by the corresponding antenna. This procedure optimizes the DC power consumption of each power amplifier and will approach the total power amplifier DC power consumption of the single antenna/single power amplifier case. The transmit weights may be updated (based on each packet received from device  200 ) in step  360 . 
     Turning to  FIG. 5 , a beamforming radio transmitter system  100 ′ having many elements in common with the beamforming radio transmitter system  100  shown in  FIG. 1 , with the exception of a plurality of DC/DC converter circuits  135 ( 1 ) to  135 (N) for each power amplifier  110 ( 1 ) to  110 (N). Rather than control the power amplifier bias circuits  130 ( 1 ) to  130 (N), operation of the power amplifiers  110 ( 1 ) to  110 (N) is controlled by adjusting the operating voltage used by each power amplifier through the DC/DC converter circuits  135 ( 1 ) to  135 (N). Normally, the operating voltage used by a power amplifier, referred to as Vcc, is fixed. However, if a signal is to be amplified by the power amplifier at a relatively low level compared to Vcc, then the power amplifier will not be operated efficiently at an operating voltage equal to Vcc when amplifying a signal at that lower level. Accordingly, the operating voltage to each power amplifier is adjusted according to the output power level required by that amplifier. Each DC/DC converter  135 ( 1 ) to  135 (N) is coupled to Vcc, and is controlled by a control signal to convert the voltage Vcc to an operating voltage at a level anywhere from a minimum voltage level up to Vcc, according to the transmit weight for the corresponding power amplifier. 
     The operating voltage control signals for each DC/DC converter  135 ( 1 ) to  135 (N) may be generated from the transmit weights in a manner similar to that shown in  FIG. 3 , either by way of a mathematical computation or a look-up-table. Digital DC/DC converter control signals computed by either the microprocessor  160  or baseband signal processor  150  are converted to analog operating voltage control signals by one or more DAC(s)  170  and coupled to the corresponding DC/DC converter  135 ( 1 ) to  135 (N). 
     A procedure  400  for optimizing the power amplifiers in the embodiment of  FIG. 5  is shown in  FIG. 6 , again in connection with the example where device  210  is preparing to transmit a packet to device  200 . In step  410 , a processor (baseband signal processor  150  or microprocessor  160 ) in device  210  determines that a packet is to be transmitted to device  200 . The transmit weights for device  200  (stored in device  210 ) are retrieved in step  420 , and in step  430 , the operating voltage control signals are computed for the DC/DC converter for each power amplifier. In step  440 , the operating voltage control signals are converted to analog signals and coupled to the DC/DC converters. In step  450 , the RF signals coupled to each amplifier are amplified by the corresponding power amplifier for transmission by the corresponding antenna. The transmit weights may be updated (based on each packet received from device  200 ) in step  460 . 
     It may be desirable to control both the bias and operating voltage of each power amplifier, thereby combining the techniques shown in  FIGS. 1 and 5 . 
     Turning to  FIG. 7 , a beamforming radio transmitter system  100 ″ is shown according to a third embodiment. The system  100 ″ is similar to radio transmitter system  100  except that it includes power amplifier self-bias boosting circuits  145 ( 1 ) to  145 (N) instead of the bias circuits  130 ( 1 ) to  130 (N). As is known in the art, self-bias boosting circuits automatically bias a power amplifier by an amount according to the level of the input signal supplied to the power amplifier, thereby providing the necessary bias to the power amplifier to amplify that input signal with optimized efficiency. Self-bias boosting circuits are known in the art and are not described in detail herein. The plurality of RF signals output by the RF upconverters  140 ( 1 ) to  140 (N) are weighted according to the transmit weights w 1 (f)S(f) through wN(f)S(f), and therefore will be at respective power levels according to these weights. The self-bias boosting circuits  145 ( 1 ) to  145 (N) will detect the power levels of these signals and automatically provide the appropriate bias to the associated power amplifiers  110 ( 1 ) to  110 (N) to optimize the efficiency of those power amplifiers when amplifying the corresponding RF signal. 
     A procedure  500  for optimizing the power amplifiers in the embodiment of  FIG. 7  is shown in  FIG. 8 , in connection with the example where device  210  is preparing to transmit a packet to device  200 . In step  510 , a processor (baseband signal processor  150  or microprocessor  160 ) in device  210  determines that a packet is to be transmitted to device  200 . The transmit weights for device  200  (stored in device  210 ) are retrieved in step  520 , and in step  530  transmit weights are applied to the baseband signal to be transmitted to generate a plurality of weighted baseband signals. In step  540 , the corresponding upconverted RF signals are coupled to the power amplifiers  110 ( 1 ) to  110 (N) and their corresponding self-bias boosting circuits  145 ( 1 ) to  145 (N). The self-bias boosting circuits  145 ( 1 ) to  145 (N) sense the power level of the RF signals and adjust the bias to the corresponding power amplifiers accordingly to optimize their operation when amplifying the corresponding RF signal. In step  550 , the RF signals are amplified and coupled to the corresponding antenna for transmission. The transmit weights may be updated (based on each packet received from device  200 ) in step  560 . 
     It may be desirable to control the operating voltage of each power amplifier in conjunction with the self-bias boosting circuits, thereby combining the techniques shown in  FIGS. 5 and 7 . 
     Furthermore, it may be desirable to adjust one or more operating parameters of one, some, but not all of the power amplifiers according to changing requirements. For example, in order to save implementation complexity, certain ones of the power amplifiers can be operated with operational parameters at nominal conditions suitable for any degree of power amplification, while other ones of the power amplifiers can be adjusted dynamically using any of the techniques described herein. 
     The processes shown in  FIGS. 4 and 6  for computing the control signals for the power amplifier may be implemented by instructions stored or encoded on a processor readable medium (e.g., memory associated with the microprocessor shown in  FIGS. 1 and 5 ). The microprocessor would execute those instructions to generate the power amplifier control signals. 
     In summary, a method and a radio frequency transmission system is provided for optimizing the efficiency of each of a plurality of power amplifiers that amplify corresponding ones of a plurality of radio frequency signals for transmission by corresponding ones of a plurality of antennas. Each of the power amplifiers is controlled to operate with one or more operating parameters that optimize the efficiency for corresponding output power levels of corresponding radio frequency signals. The operating parameters that are optimized may be the bias voltage or current supplied to the power amplifiers, the operating voltage of the power amplifiers, or a combination thereof. In addition, the power amplifiers may be automatically biased by supplying signals to self-bias boosting circuits, each associated with a corresponding power amplifier, whereby the self-bias boosting circuit sets the bias of the corresponding amplifier depending on the level of input signal supplied to the power amplifier for amplification. 
     Further, a radio frequency signal transmission system is provided comprising a plurality of power amplifiers that amplify corresponding ones of a plurality of radio frequency signals for transmission by corresponding ones of a plurality of antennas. Each power amplifier is responsive to a corresponding control signal that adjusts at least one operational parameter to optimize the power amplifier efficiency for a corresponding output power level of the corresponding radio frequency signal. The at least one operational amplifier may be a bias current or voltage or an operating voltage, or a combination of both. Alternatively, a plurality of self-bias boosting circuits may be provided, each associated with corresponding ones of the plurality of power amplifiers, wherein each self-bias boosting circuit biases the corresponding power amplifier according to the power level of the corresponding radio frequency signal supplied as input to it. 
     Moreover, a processor readable medium is provided, wherein the medium is encoded with instructions that, when executed by a processor, cause the processor to generate power amplifier control signals based on corresponding ones of a plurality of transmit weights associated with the plurality of radio frequency signals to be simultaneously transmitted by corresponding antennas, wherein the power amplifier control signals adjust at least one operational parameter that optimizes the efficiency of a corresponding power amplifier for a corresponding output power level of the corresponding radio frequency signal 
     The above description is intended by way of example only.