The present application claims priority under 35 U.S.C. §365 to International Patent Application No. PCT/IB2008/050017 filed Jan, 4, 2008, entitled “ENHANCED PREDISTORTION FOR SLEWING CORRECTION.” International Patent Application No. PCT/IB2008/050017 claims priority to European Patent Application No. 07100266.1 filed Jan, 9, 2007. Both of these applications are incorporated by reference into the present disclosure as if fully set forth herein.
The present invention relates to a circuit arrangement, method, and computer program product for applying predistortion to a baseband signal which may be used as a modulating signal for a pulse modulator.
Normal baseband signals have an amplitude A(t) and a phase variation ΦP(t). For transmission there may be a need for an radio frequency (RF) carrier which contains a desired baseband information, i.e., s(t)=Re(A(t)ejΦp(t)ejωt). Thus, an upconverter is needed. For transmission, high power levels are needed, and to improve efficiency of the power amplifier (PA) switching PA concepts may be applied (e.g., class D). An important key problem for power amplifiers (PAs) is their efficiency. For this reason new concepts based on polar modulation, synchronous and asynchronous sigma-delta and combined pulse width and pulse phase modulation (PWM-PPM modulation) are of interest. Two-level or binary signals are very suitable in combination with switching PA's. For PWM-PPM modulation and high frequencies new modulators types have been proposed. In such modulators, the predistorted modulating signal can be directly modulated on the first harmonic of the PWM-PPM modulated signal. However, the PWM-PPM-based modulation methods mentioned above are in general sensitive to slewing distortions and especially in case of small duty cycles of the binary baseband signal. The pulse-shaping will change from a trapezium waveform (large duty cycle) of constant amplitude into a triangle waveform of varying amplitude for small duty cycles. This results in amplitude and phase distortions of the modulating signal at the radio frequency (RF) carrier of the PWM-PPM signal. In former ideas PWM & PPM modulator concepts have been proposed, which were suitable for these switching PA-concepts. In practice however and specially for RF high power levels, slewing will result in a performance degradation (distortion) of these PWM modulated signals.
An object of the present invention is to provide an improved method and circuit arrangement, by means of which slewing distortions can be reduced.
The invention is defined by the independent claims. Dependent claims define advantageous embodiments.
Accordingly, slewing correction is achieved by applying (additional) predistortion to the baseband input signal. As a parameter for this slewing predistortion, an information about the envelope of the baseband signal is used. This envelope information thus determines the pulse width of the pulse-shaped signal and also the predistortion to be applied to the baseband signal, so that slewing distortions in the pulse-shaped signal can be removed or at least reduced. The envelope information may be determined based on a normalized envelope of the baseband signal. In a specific example, the envelope information may be derived by calculating a level of a first harmonic of the normalized envelope of the baseband signal. The use of a normalized envelope ensures that the pulse-shaped signal is generated with the right duty cycle to, obtain a less distorted first harmonic of the RF fundamental of the pulse-shaped signal.
As an example, the duty cycle modulation or the phase modulation may be calculated based on the envelope information, wherein the calculation is changed when the envelope information exceeds a predetermined threshold value. Thereby, the fact that the waveform of the pulse-shaped signal changes from a trapezium into a triangle can be considered. In a particular example, the predetermined threshold value may be determined based on an amplitude and at least one slew rate value of the pulse-shaped signal.
As an additional option for the case that the pulse-shaped signal is an asymmetrical signal, a control loop may be provided for controlling at least one of a rising edge and a falling edge of the pulse-shaped signal to obtain a symmetrical slew of the pulse-shaped signal. In a specific example, this control loop may comprise a slope detector for measuring slopes of the at least one of said rising edge and said falling edge of the pulse-shaped signal, and a slew rate correction unit for controlling the slew rate of at least one of the rising edge and the falling edge of the pulse-shaped signal to obtain a substantially symmetrical slewing of the pulse-shaped signal.
In an embodiment, the baseband signal may be applied as a modulating signal to a pulse modulation circuit, which generates said pulse-shaped signal.
The circuit arrangement may be implemented by using discrete hardware components or circuits, or, alternatively, by using a processor or computer device which is controlled by software routines so as to perform the above the claimed method steps. Consequently, the present invention may be implemented as a computer program product comprising code means for performing the claimed method steps when run on a computer or processor device.
In the following, the present invention will be described in greater detail based on embodiments with reference to the accompanying drawings in which:
The embodiments of the present invention will now be described in greater detail based on a predistortion concept for a PWM-PPM modulator circuit. Before starting with the description of the embodiments, underlying principles will be briefly discussed.
A complex baseband signal in cartesian format can be described as follows:
Sbaseband(t)=I(t)+jQ(t) (1)
The phase and the normalized envelope of this signal are then given by:
In the embodiments, the normalized envelope of the baseband signal Aenv(t) is used to generate a PWM signal with the right duty cycle, which will result in a distortion free AM-modulation on the first harmonic of the RF fundamental of the PWM signal. The relation between the duty cycle and the envelope for quasi-stationary conditions is calculated below.
The Fourier series of the pulsetrain shown in
where the duty cycle d is defined as:
The equation (3) shows the relation between the amplitude of the fundamental frequency and its harmonics and the duty cycle. The relation between the nth harmonic of the pulse train and the duty cycle d can be described by the following equations:
The normalized envelope Aenv of the baseband signal is used to generate a PWM signal with the right duty cycle given by equation (5), which will result in a desired level of the nth harmonic of the pulse width modulated signal. The relation between the normalized envelope Aenv and the duty cycle d for modulation of the first harmonic is:
Equation (6) shows that the duty cycle d will become 0.5 when the envelope Aenv has its maximum value of “1”.
In practice, however, and especially for RF high power levels the PWM signal will suffer from slewing with the result of unwanted distortions. Such slewing distortions may appear when the signal has passed limiter or gating circuits, because at this point in the signal processing chain the signal will have its largest bandwidth and signal level.
For τ≧a the following relations can be derived:
For τ<a the following relations are valid:
In the case of a trapezium waveform, the amplitude of the nth harmonic can be expressed as:
For an amplitude change of the nth harmonic component of the trapezium waveform the duty cycle d has to change according the following relation:
The delay of the trapezium-shaped waveform will then become:
Which results in the following distorting phase shift for the nth harmonic of the trapezium waveform:
On the other hand, the amplitude of the nth harmonic of the triangle waveform can be expressed as:
An,Δ=2.τ.slew.d.Sinc(nπd)2 (14)
For small duty cycles d which is the case here, the above equation (14) can be approximated for the fundamental (n=1):
A1,Δ≈2.τ.slew.d=2.Tc.slew.d2 (15)
Which results in a duty cycle:
The delay of the triangle shaped waveform is:
This leads to the following distorting phase shift for the nth harmonic of the triangle waveform.
φnΔ=n·ωC·delayΔ=n·π·d (18)
At the threshold value where the shape of the waveform changes from a trapezium waveform into a triangle waveform, the amplitude of the first harmonic is given by:
Assuming that the envelope of the baseband signal will be modulated at the first harmonic of the pulse width modulated signal (largest carrier), the complete algorithm needed to combat the above distortions caused by stewing can be derived as follows.
The normalized envelope of the baseband signal is given by:
The level range of the first harmonic is:
The duty cycle modulation of the PWM modulator and the additional phase modulation for a distortion free AM modulation of the first harmonic is given by the conditional functions below, which depend on the level of the first harmonic in relation to the above threshold value of equation (19).
The composite phase signal for the PWM-PPM modulation is build from the following parts:
Phase modulation PWM part:
Phase modulation PPM part:
ΦP(t)=arg(Sbaseband(t)) (25)
Hence, the total phase modulation of the modulating baseband signal including signals to combat slewing distortion can be expressed as follows:
θ1(t)=ΦP(t)+ΦM(t)+ψ(t)
θ2(t)=ΦP(t)−ΦM(t)+ψ(t) (26)
Thus, according to the embodiments, slewing distortions are removed or at least reduced by applying a first phase component to the baseband signal, which is determined by the desired duty cycle d(t) (and thus indirectly by the level A1(t) of the first harmonic of the baseband signal), and a second phase component which is directly determined by the level A1(t) of the first harmonic. Dependent on the applied PWM-PPM modulator type these phase components are used for the baseband signal generator.
sin(θ1(t)), cos(θ1(t)), sin(θ2(t)), cos(θ2(t)) (27)
According to
On the other hand,
However, the above-proposed (additional) predistortion to overcome intermodulation distortions caused by slewing is most effective in the case the pulse modulation (e.g., PWM-PPM-type modulation) has a symmetrical slew. For this reason there is a need for an additional control of the slewing symmetry of the pulse-shaped output signal.
The slope detector unit 50 may be arranged to generate three output signals, namely slp, sln, and h, wherein slp and sln indicate values of the slope of the rising and falling edges and h indicates an information about the amplitude level at the input of the slope detector unit 50. These output signals are passed via the digital baseband circuit 10, where a slew correction signal slc is generated and supplied to the slew rate correction circuit 30 to modify any possible asymmetrical slewing signal into a signal with has a symmetrical slew. This can be achieved by decreasing the slew rate of the edge with the highest slew rate until the slew rate is made symmetrical. Such a selective decrease can be achieved for example by suitably modifying the load at the output of the PA 40. It is however not necessary that the slew rate correction circuit 30 is controlled by the slew rate detection circuit 50 via the digital domain (i.e. the digital baseband circuit 10). As an alternative or modification, a direct control is also possible, as indicated by the dotted arrow in
In summary, a circuit arrangement and method of applying predistortion to a baseband signal used for modulating a pulse-shaped signal have been described, wherein an envelope information of the baseband signal is detected and slewing distortions of the pulse-shaped signal are reduced by applying at least one of a phase modulation and a duty cycle modulation to the baseband signal as additional predistortion in response to the detected envelope information. Thereby, stewing distortions in the pulse-shaped signal are removed or at least reduced.
The proposed circuit arrangement according to the first and second embodiment may be used in any application requiring pulse-modulated signals, such as modulated transmitters for wireless local area networks (WLAN), wireless area networks (WPAN), Bluetooth, orthogonal frequency division multiple network (OFDM), global system for mobile communication (GSM), universal mobile telecommunication system (UMTS), code division multiple access (CDMA), low-power mobile communication devices, and other suitable applications. In general, the present invention is not restricted to the above two embodiment and can be implemented in any connection with any processing of pulse-shaped signals so as to remove slewing distortions. Based on a detected envelope or amplitude information of the baseband signal at least one of the duty cycle or phase of the baseband signal is modulated or controlled to generate an additional predistortion for reducing stewing distortions. The above embodiments may thus vary within the scope of the attached claims.
It is remarked that the scope of protection of the invention is not restricted to the embodiments described herein. Neither is the scope of protection of the invention restricted by the reference numerals in the claims. The word “comprising” does not exclude other parts than those mentioned in the claims. The word “a(n)” preceding an element does not exclude a plurality of those elements. Means forming part of the invention may both be implemented in the form of dedicated hardware or in the form of a programmed purpose processor. The invention resides in each new feature or combination of features.
Number | Date | Country | Kind |
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07100266 | Jan 2007 | EP | regional |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/IB2008/050017 | 1/4/2008 | WO | 00 | 2/19/2010 |
Publishing Document | Publishing Date | Country | Kind |
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WO2008/084419 | 7/17/2008 | WO | A |
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4509017 | Andren et al. | Apr 1985 | A |
5617058 | Adrian et al. | Apr 1997 | A |
20090180527 | Asami | Jul 2009 | A1 |
Number | Date | Country |
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1 271 870 | Jan 2003 | EP |
Number | Date | Country | |
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20100148834 A1 | Jun 2010 | US |