Abstract:
An inexpensive method and means for generating high power envelope-modulated radio frequency signals is disclosed. Embodiments provide EER amplification and separate modulation of information encoded as phase angle and as amplitude. An envelope modulated signal generation apparatus comprising a source of carrier signal, a source of a binary data stream, a pulse deletion logic and a current switch is disclosed.

Description:
BACKGROUND AND DESCRIPTION OF PRIOR ART 
     Power efficiency is important in high power radio frequency (RF) amplifiers especially for reasons of thermal management and, typically in portable equipment, battery life. 
     In high power RF amplifiers it is common to use highly non-linear amplifiers in order to achieve efficiency. Such power amplifiers (PA) are commonly termed output stages. In simple terms, if an active device used in an output stage is operated in a linear region then it may have significant heat dissipation and hence relatively poor efficiency and resultant thermal issues. Conversely, if the active device is used essentially as a binary (two-state) switch then it dissipates little power in either on or off state and the only significant power consumption occurs during transitional periods between states. Good efficiency thus dictates fast switching. Energy recovery circuits are used to provide waveform shaping for spectral purity while maintaining efficiency according to well known techniques such as the simple and effective tank circuits used since the early days of vacuum tube amplifiers. 
     As is well known, the use of non-linear amplifiers works well with constant envelope modulation techniques such as frequency shift keying (FSK), frequency modulation (FM) and other forms of angle modulation. 
     The use of non-linear active devices for envelope-modulation signals such as amplitude modulation (AM), quadrature AM (QAM), or single sideband AM (SSB) is not so straightforward. Techniques such as corrective and adaptive pre-distortion, feedforward linearization, envelope elimination and restoration (EER) using the Kahn technique, linear amplification with non-linear components (LINC), and Cartesian feedback are each successful but are typically complex and expensive. In previous implementations for consumer grade (i.e. inexpensive) products, overall linearity has been achieved by sacrificing energy efficiency and biasing active devices into a linear region to build linear amplifiers. 
     Thus, a need exists for an inexpensive method or means for generating high power envelope-modulated radio frequency signals. 
     SUMMARY OF THE INVENTION 
     Accordingly, the invention presents an inexpensive method and means for generating high power envelope-modulated radio frequency signals. 
     According to an embodiment of the invention an analog signal, which may be a baseband signal, becomes envelope-modulated upon a high power RF carrier. Further, the creation of envelope modulation by pulse deletion may be impressed, not merely onto a pure carrier, but upon an RF signal that may be modulated with an essentially constant envelope form of modulation. For example, envelope modulation by pulse deletion may be applied to a signal containing angle modulation such as quadrature phase shift keying (QPSK). Thus a separate and additional channel of information may be passed as envelope modulation through a system that formerly carried only angle modulation signals without material degradation of those angle modulated signals. 
     According to a still further aspect of the invention, control signal may be derived by recovery from a low-level envelope modulated RF signal. Thus, inventive output stages may be fed by a demodulator or similar to create an EER amplifier system. Such an EER amplifier system may, but need not, provide for envelope feedback control. 
    
    
     DESCRIPTION OF DRAWINGS 
     FIG. 1 shows a block diagram of a power amplifier using EER according to an embodiment of the invention. 
     FIG. 2 shows a block diagram of high power amplifier-modulator according to an embodiment of the invention. 
     FIG. 3 a  shows a circuit block diagram of a digitizer and pulse deletion logic according to one particular embodiment of the invention. 
     FIG. 3 b  shows some waveforms of signals present in the circuit of FIG. 3 a.    
     FIG. 4 shows an equivalent circuit of an exemplary embodiment of energy recovery waveform shaping circuit, switching device and load. 
    
    
     For simplicity in description, identical components are labeled by the same numerals in this application. 
     DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS 
     According to an aspect of the present invention, an output stage may comprise an active switching device used as a class D RF amplifier. A low-level RF signal in the form of a train of pulses may feed a control terminal of the active device. The low-level RF signal may be, loosely speaking, a clipped waveform swinging between an earthy potential and a substantially constant positive voltage, though this is not a critical feature. Such signals may be generated by high-speed digital logic gates or otherwise by techniques well known in the art. The low-level RF input signal can be gated with a control signal derived from digitization of the baseband analog signal. The control signal, when activated, may cause a pulse (or a number of pulses) to be deleted from the low level RF input signal. An effect of deleting pulses from the low-level RF input signal is to reduce the overall amplitude (and hence envelope power) of the high power RF signal generated at the output stage. Peak envelope power (PEP) may, however, be relatively unaffected. To a reasonable approximation the average envelope will be reduced in proportion to the percentage of pulses deleted. The proportion of pulses deleted may typically be fairly small where an additional channel of data is being superimposed on a phase-modulated carrier that carries orthogonal data. Perhaps on the order of 1% of all pulses may be deleted in such a case, resulting in a lightly modulated carrier. Conversely a large proportion of pulses may be deleted to depress the carrier by as much as about 8 dB or roughly 80% of pulses. Typically the bandwidth may be on the order of 1% of the carrier frequency so even if 80% of pulses were eliminated there would still be on the order of 20 pulses left per modulated phase state. The control signal may be derived by sampling the baseband analog signal according to conventional techniques, for example, pulse coded modulation (PCM) or Sigma-Delta modulation. Forms of Delta modulation have advantages of low cost and provide good price-performance trade-offs especially when deployed in lossy (as opposed to lossless) systems. Error containment due to errors due to imperfect signal recovery may be superior with Sigma-Delta modulation and inferior with PCM. Using single bit resolution Sigma-Delta modulation, the single bit oversampling rate might typically be on the order of 100:1. Thus, an example embodiment using a 1 GHz RF carrier might have a Sigma-Delta bit rate of 10 Mbit/sec (equivalent to 10 MHz with 2:1 allowed as an anti-aliasing margin) and an analog signal bandwidth of 100 kHz. Such a 100 kHz channel could typically support a single hi-fi channel or a few dozen toll grade voice channels. The ostensibly poor spectral efficiency of such an envelope—modulated signal may not be critical in all applications, especially when envelope modulation is combined with angle modulation. 
     Systems and apparatuses for developing high-power envelope modulated RF signals are disclosed. The RF signals may, but need not, contain information encoded as phase modulation (PM) or other forms of constant envelope modulation such as the various forms of angle modulation, for example FSK. 
     FIG. 1 shows a block diagram of a power amplifier using EER according to an embodiment of the invention. Referring to FIG. 1, a modulated RF signal source  101  containing both phase and amplitude information is split into two parts. Envelope detector  120  creates a first part-signal  121  containing only amplitude (envelope) information. Envelope detectors are sometimes termed envelope demodulators in the art. A second part-signal  111  containing only phase information and of substantially constant envelope is created by envelope eliminator  110 . Envelope eliminator may, for example, be embodied as a simple transistor amplifier operating in a saturated region. Techniques for envelope detection and envelope elimination are well known in the art. The first part-signal is fed to Sigma-Delta modulator  126  which produces output signal  127 . Sigma-Delta modulators are fairly well known in the art, see for example “Switched-Current Sigma-Delta modulation for A/D conversion” authors Crawley and Roberts, EE department, McGill University, 1992. Pulse deletion logic  130  eliminates half-cycles (pulses) from second part-signal  111  in response to Sigma-Delta output signal  127  to create pulse train  131 . Pulse deletion logic may be embodied as described herein in connection with FIG. 3 a  or by other methods well known in the art. Pulse train  131  is fed to high power amplifier  140  which operates in a highly non-linear mode, essentially as an on/off switch to create high power signal  141 . High power signal  141  is shaped by high power bandpass filter  150  to create high power output signal  160 . High power bandpass filter  150  may be embodied as an energy recovery waveform shaping circuit as discussed herein in connection with FIG. 2 or otherwise. 
     FIG. 2 shows a block diagram of high power amplifier-modulator according to an embodiment of the invention. Referring to FIG. 2, high-speed switching device  280  has two high current terminals  282  and a control terminal  281 . High-speed switching device  280  may be embodied as any of a number of types of active devices, for example, as a GaAsFET (Gallium Arsenide Field-Effect Transistor). Under the direction of the signal at control terminal  281 , high-speed switching device  280  turns on and off, passing alternately high current (sourced from power rail  201 ) and zero current, to produce a squarewave current  285 . Energy recovery waveform shaping circuit  210 , acts as a bandpass filter and may be a simple parallel Inductance-Capacitance “tank” circuit. Energy recovery waveform shaping circuit  210  provides for a well formed output waveform  212  into a substantially resistive load ZL  290 , according to well known principles for tank circuits. 
     Still referring to FIG. 2, time variant analog signal  260  is converted into a representative bit stream by digitizer  240 , the bit stream being then fed to pulse deletion logic  230  which produces a pulse deletion control signal  231  in the form of a binary data stream. The pulse deletion control signal  231  is gated using an AND (and) gate  232  with a signal from a low level (unamplified) source  220  of carrier signal  221 . The resultant gated signal is fed to the control terminal  281  of the high-speed switching device  280 . Taken together, the actions of on/off current switching synchronized to the input low level carrier signal with pulse deletion and the energy recovery waveform shaping, produce a high power output signal  212 . The high power output signal  212  has an envelope modulation that contains information from the original analog input signal  260 . 
     The energy recovery waveform shaping bandpass circuit  210  operates at high power, it can be constructed from low loss purely reactive devices. Low loss at high power is a necessary feature of a high-efficiency power amplifier. Another high power subsystem is the high-speed switch  280 ; as intimated above this device will have low loss and high efficiency to the extent it approximates a perfect switch. Such a switch exhibits near zero resistance in the “on” state and near zero conductance in the “off” state. 
     FIG. 3 a  shows a circuit block diagram of a digitizer  240  and pulse deletion logic  230  according to one particular embodiment of the invention. Digitizer  240  comprises a Sigma-Delta modulator  126 , which receives analog baseband signal  260 . The output from Sigma-Delta modulator is a one bit wide “non-return to zero” (NRZ) bit stream  127  at sampling rate. The pulse deletion logic  230  receives NRZ bit stream  127  and low-level RF carrier signal  221 . These signals are gated and clocked by inverter  360 , flip-flops  320 ,  330 , and by XOR (exclusive-or) gate  340 , NAND (and-negate) gate  350  to produce pulse deletion control signal  231 . Pulse deletion control signal  231  is gated by AND gate  232  with low level RF carrier  221  to produce RF signal  361  having missing (deleted) pulses. Alternatives to the use of a Sigma-Delta modulator may be, for example, a pulse code modulator or a straight delta modulator (with some loss of signal compatibility). 
     FIG. 3 b  shows waveforms of some of the signals present in the circuit depicted as FIG. 3 a , low level RF carrier  221  is shown to be a distorted sine wave although the shape of the waveform is merely exemplary and is not critical. Still referring to FIG. 3 b , the waveform of the bit stream  127  output from Sigma-Delta modulator is shown. Exemplary RF signal  361  having two missing (deleted) pulses is also shown in FIG. 3 b.    
     FIG. 4 shows an alternating current (AC) diagram of an exemplary embodiment of energy recovery waveform shaping circuit  210  and high power high speed switch  280  according to an embodiment of the invention. Energy recovery waveform shaping circuit  210  is a simple tank circuit with a high Q, comprising low loss capacitor  410  and low loss mutual inductance (transformer)  420  feeding a complex load  450 . High power high-speed switch  280  is embodied as a junction field-effect transistor (JFET)  430 . It can be seen that the parallel resonant circuit formed by capacitor  410  and self-inductance of transformer  420  is loaded by transformed load  450  and also any stray circuit parameters such as parasitic capacitance of JFET  430 . Component values must be chosen with some care, but according to simple well-known principles for RF filters. Circulating currents in the inductance-capacitance tank drive the load and these are refreshed by the switching action of the JFET. Deleting a single pulse certainly impacts phase noise (jitter) effectively rotating the phase constellation of the carrier, assuming it is phase modulated. Happily, deleting pulses causes least phase distortion at moments of greatest amplitude and for a typical modulation constellation those are the very moments that phase information is most critical. Conversely, amplitude is minimal at the mid-point of some state transitions so that phase is most distorted when it matters least. Deleting a series of pulses introduces spurs (spurious out of band frequency components) into the output signal. Nonetheless, application of the invention provides substantially higher power efficiency for the same linearity (or equivalently the same out of band emission limits) as compared to other methods of envelope modulation/linear amplification using comparable components. 
     While the invention has been described above by reference to various embodiments, it will be understood that changes and modifications may be made without departing from the scope of the invention, which is to be defined only by the appended claims and their equivalent. For example, the invention is applicable to QPSK modems. Such and other variations are within the scope of the invention. All references referred to herein are incorporated by reference in their entireties.