1. Field of the Invention
The present invention relates to pulse modulators. More specifically, the invention pertains to a pulse modulator for conversion of a complex input signal to a pulsed signal, and to a method for pulse modulation of a complex input signal.
2. Description of the Prior Art
Digital/analog converters may be employed to convert digital input signals to analog signals. They are, however, expensive and require a relatively large amount of electrical power as well as a number of supply voltages (frequently). They are also difficult to integrate with digital electronics and, thus, limit miniaturization.
As a result, digital/analog converters are being replaced by digital pulse modulators (e.g., sigma-delta converters) in many applications. A conventional sigma-delta modulator includes an integrator that integrates the difference signal between an input signal and a fed-back quantized signal, as well as a quantizer that quantizes the integrated signal. A quantized pulsed signal can then be tapped off at the output of the quantizer. It is fed back as a feedback signal to the input of the sigma-delta converter. Sigma-delta modulators are distinguished by a noise characteristic in which the quantization noise is shifted from the low-frequency range in the vicinity of ω=0 towards higher frequencies. The noise that occurs at higher frequencies can then be suppressed with the aid of a downstream low-pass filter. Sigma-delta converters can be implemented at low cost and integrated with digital electronics. However, for some applications, it would be advantageous to be able to keep the quantization noise low at higher frequencies.
It is therefore an of the invention to provide a pulse modulator and a method for pulse modulation in which the spectral distribution of quantization noise can be flexibly adapted.
The present addresses the preceding object by providing, in a first aspect, a pulse modulator for conversion of a complex input signal to a pulsed signal. Such modulator includes a subtraction stage that produces a control error signal from the difference between the complex input signal and a feedback signal. A signal conversion stage is provided that converts the control error signal to a control signal.
A first multiplication stage multiplies the control signal by a complex mixing signal oscillating at the frequency ω0 to produce at least one of a real part and an imaginary part of a control signal that has been up-mixed by ω0. A quantization stage quantizes at least one of the real part and imaginary part of the control signal that has been up-mixed by ω0 and thus produces the pulsed signal. A feedback unit uses the pulsed signal to produce the feedback signal for the subtraction stage.
In a second aspect, the invention provides a method for pulse modulation of a complex input signal. Such method includes the production of a control error signal from the difference between the complex input signal and a feedback signal. The control error signal is then converted to a control signal.
The control signal is multiplied by a complex mixing signal that oscillates at the frequency ω0. At least one of the real and imaginary parts of a control signal, up-mixed by ω0, is produced. At least one of the real and imaginary parts of the control signal, up-mixed by ω0, is quantized to produce a pulsed signal. The feedback signal is then produced from the pulsed signal.
The preceding and other features of the invention will become further apparent from the detailed description that follows. Such description is accompanied by a set of drawing figures. Numerals of the drawing figures, corresponding to those of the written description, point to the features of the invention. Like numerals refer to like features throughout both the written text and the drawing figures.
The quantizer 12 of the embodiment of
The sequence of functional units illustrated in
The addition of the real part of the control error to the previous integrator value produces a new integrator value that is once again stored in the delay element 18. The integrated signal 20 in the in-phase signal path is scaled by the factor “a” at an amplifier 21, and is then passed as an amplified signal 22 to a first multiplier 23. The first multiplier 23 multiplies the real, amplified signal 22 by the real signal cos(ω0t), (i.e. by the real part of exp(−jω0t)). The first multiplier 23 determines the product R·cos(ω0t), which is supplied as a signal 24 to an adder 25.
The quadrature signal path 15 of the pulse modulator includes an addition node 26 in which the difference between the imaginary part I of the input signal and an imaginary part 27 of the feedback signal is calculated. This difference, which corresponds to the imaginary part of the control error, is added to the previous content of a delay element 28 that is passed to the addition node 26 via a signal line 29. The new value, which is obtained as the sum of the previous value and the imaginary part of the control error, is written to the delay element 28. Together with the signal line 29, the delay element 28 forms an integrator with the transfer function H(z)=1/(1−z−1). The integrated signal 30 from the quadrature signal path is produced at the output of the integrator, and is scaled by the factor “a” of an amplifier 31. An amplified signal 32 obtained in this way is then multiplied by the signal sin(ω0t) in a second multiplier 33. The product I·sin(ω0t) obtained in this way is supplied as a signal 34 to the adder 25. The adder 25 adds the signals R·cos(ω0t) and I·sin(ω0t) and produces the signal R·cos(ω0t)+I·sin(ω0t) as a signal 35. The signal 35 corresponds precisely to the real part of the up-mixed signal as the complex multiplication of x(t) and exp(−jω0t)shows:
The real part of this signal is R·cos(ω0t)+I·sin(ω0t). The signal 35 thus represents the real part of the complex up-mixed signal, and, to such extent, corresponds to the signal 11 illustrated in
The digital real signal 35 is applied to a quantizer 36 that converts it to the quantized pulsed signal y(t). The three-stage (ternary) quantizer of
The real part 17 and the imaginary part 27 of the complex feedback signal are derived from the quantized pulsed signal y(t). For this, the pulsed signal y(t) is multiplied by the complex-conjugate mixing signal exp(−jω0t)
y(t)·exp(−jω0t)=y(t)·cos(ω0t)+j·y(t)·sin(ω0t)
The real part y(t)·cos(ω0t) of the complex feedback signal is produced by the third multiplier 37 that multiplies the pulsed signal y(t) by cos(ω0t). The real part 17 of the feedback signal is thus produced at the output of the third multiplier 37 and fed back to the addition node 16. In order to produce the imaginary part y(t)·sin(ω0t) of the complex feedback signal, the pulsed signal y(t) is multiplied by sin(ω0t) at the fourth multiplier 38. The imaginary part 27 of the feedback signal is produced at the output of the fourth multiplier 38 and fed back to the addition node 26.
Integrators are provided on the input side in the exemplary embodiments of
lim H(z)=∞z→1.
The transfer function H(z) should thus tend to infinity as the frequency ω tends to zero (z→1). The additional free parameters of H(z) may be employed to optimize specific characteristics of the modulator (e.g. signal-to-noise ratio) or of the overall system.
The pulse modulator of the invention may be used for digital synthesis of a pulsed signal. In this case, the main spectral component of the pulsed signal can be predetermined by the mixing frequency ω0. The phase angle of the pulsed signal produced can be set exactly by the ratio of the real to the imaginary part of the input signal. This results in a pulsed signal whose phase is stable.
When using a pulse modulator in accordance with the invention for frequency synthesis, the pulsed signal y(t) should be filtered by means of an electrical bandpass filter, whose passband is centered around the frequency ω0. Such a filter which may, for example, be in the form of a crystal or ceramic filter, makes it possible to suppress spectral ranges further removed from ω0 where the noise level is undesirably high. A bandpass filter such as this makes it possible to significantly improve the signal-to-noise ratio.
The pulse modulator of the invention is suitable, inter alia, for stimulation of electromechanical oscillators to carry out harmonic oscillations. In particular, the electrostatic forces required for oscillation stimulation can be produced by a ternary-quantized pulsed signal applied to the stimulation electrodes of a micromechanical resonator. The frequency ω0 of the pulsed signal y(t) is preferably chosen to be equal to the resonant frequency of the micromechanical oscillator in this case. If the pulsed signal, as illustrated in
Specific ratios of the frequencies ω0/ωA exist that result in conversion of the noise-like quantization product in y(t) to a series of more or less periodic functions. An example is illustrated in
The central linearity of the quantizer can be improved by adding a noise signal to the input signal to prevent the creation of relaxation oscillations. A spectrally uniformly distributed noise signal is preferably employed for this purpose.
The pulse modulator of the invention can be used, in particular, for electrostatic stimulation of micromechanical oscillators. For such purpose, by way of example, a ternary-quantized pulsed signal of the type shown in
Resonators that can oscillate in two mutually perpendicular directions y1 and y2 are employed in rotation rate sensors and Coriolis gyros. The two-dimensional pulse modulator illustrated in
In summary, the operation of a pulse modulator in accordance with the invention represents an advantageous modification of a conventional sigma-delta converter. It has been explained above, for an input signal that is kept constant without any restriction to generality. The subtraction and signal conversion stages convert the input signal to a control signal that also varies only slightly in time. In contrast to conventional sigma-delta converters, the control signal is, however, now multiplied by the first multiplication stage by a complex mixing signal at the frequency ω0 to produce a control signal up-mixed to the frequency ω0. The real or the imaginary part of the control signal, oscillating at the frequency ω0, is then quantized by the quantization stage, resulting in a real pulsed signal with a dominant frequency component at the frequency ω0 at the output of the quantization stage. The real pulsed signal, together with the aid of positive or negative pulses, simulates a sinusoidal signal at the frequency ω0. Such pulsed signal represents the point of origin for calculation of the feedback signal. Such feedback signal is fed back to the subtraction stage where it is subtracted from the input signal to determine the control error.
It is not absolutely essential to calculate both the real and imaginary parts of the control signal up-mixed by ω0 to produce the pulsed signal. If the intention is to derive the pulsed signal from the real part of the up-mixed control signal, the imaginary part of the up-mixed control signal need not necessarily be produced.
The major advantage of the pulse modulator of the invention over conventional sigma-delta modulators is that the range of low quantization noise is shifted from the vicinity of ω=0 toward the operating frequency ω0. This is achieved by complex up-mixing of the control signal in the first multiplication stage. It results in a pulsed signal that has a low noise level in the relevant spectral range around ω0.
The starting point for understanding the noise characteristic is that the signal conversion stage, which may be formed, for example, by an integrator, has a low-pass characteristic. This means that relatively high-frequency components are partially suppressed by the signal conversion stage. In conventional sigma-delta converters, this suppression of the higher-frequency components in the control loop causes a rise in the quantization noise at higher frequencies. In contrast, the quantization noise in the low-frequency range is low. In the case of the pulse modulator of the invention, the control signal, which can be tapped off at the output of the signal conversion stage, is up-mixed to the frequency ω0 by multiplication by the complex mixing signal at the frequency ω0. The range of low quantization noise is thus also shifted from the frequency ω=0 toward the mixing frequency ω0, even though the signal conversion stage on the input side is still processing a signal which has not been up-mixed. This results in a pulsed signal with a noise level which is low in the vicinity of ω0.
The pulse modulator according to the invention can be implemented at low cost, requires relatively little electrical power, and can easily be integrated together with the digital electronics.
It is advantageous for the pulse modulator to have an in-phase signal path for processing of the real part of the input signal, as well as a quadrature signal path for processing of the imaginary part of the input signal. It is also advantageous for the control error signal, the control signal and the feedback signal to be complex signals with each having a real signal component as well as an imaginary signal component. To insure that the real pulsed signal reflects the real or the imaginary part of the control signal up-mixed by ω0 in the correct phase, the subtraction stage, the signal conversion stage, the first multiplication stage and the feedback unit are complex signal processing units which have an in-phase signal path and a quadrature signal path. Only the real part (or the imaginary part) of the output signal from the first multiplication stage is required to derive the real pulsed signal from it with the aid of the quantization stage. The quantization stage may thus be a real processing stage. In fact, the real pulsed signal is then once again converted to a complex feedback signal in the feedback unit. This design of the pulse modulator makes it possible to synthesize a real pulsed signal, which reproduces a harmonic oscillation at the frequency ω0 with low phase and amplitude noise, with the correct phase.
According to one advantageous embodiment of the invention, the signal conversion stage has an integrator stage that integrates the control error signal and produces an integrated signal as the control signal. Integration of the control error signal makes it possible to slave the (complex) integrated signal continuously to the complex input signal. Since an integrator stage has a low-pass filter characteristic, this results in a control signal at the output of the integrator stage with a reduced noise level in the region around ω0. If this control signal is then up-mixed by the first multiplication stage, and then quantized, a pulsed signal with the desired noise characteristic results.
It is advantageous for the integrator stage to have a first integrator for the in-phase signal path and a second integrator for the quadrature signal path. The first integrator integrates the real part and the second integrator integrates the imaginary part of the control error signal. A complex integrator stage for the complex control error signal can be produced in this way with the aid of two separate integrators.
It is advantageous for the signal conversion stage to have an amplifier stage. The gain factor is chosen so that the quantizer receives the correct input signal level.
According to a further advantageous embodiment of the invention, the first multiplication stage has a first multiplier for the in-phase signal path and a second multiplier for the quadrature signal path. The first multiplier multiplies the real part of the control signal by the real part of the complex mixing signal oscillating at the frequency ω0, and thus produces a first result signal. The second multiplier multiplies the imaginary part of the control signal by the imaginary part of the complex mixing signal oscillating at the frequency ω0, and thus produces a second result signal. According to a further advantageous embodiment, the pulse modulator has an adder that adds the first result signal from the first multiplier and the second result signal from the second multiplier to form a sum signal to determine the real part of the up-mixed control signal.
If it is assumed that the complex control signal is in the form R+j·I, and, by way of example, the complex mixing signal is represented in the form exp(−jω0t), then the first result signal from the first multiplier becomes R·cos(ω0t). The second result signal from the second multiplier assumes the form I·sin(ω0t), and the adder produces the signal R·cos(ω0t)+I·sin(ω0t) as the sum signal. However, this signal corresponds precisely to the real part of (R+j·I)·exp(−jω0t). The real part of the complex multiplication of the control signal and mixing signal can thus be determined by the first multiplier, the second multiplier and the adder.
According to an advantageous embodiment of the invention, the sum signal produced by the adder is then quantized by the quantization stage to produce the real pulsed signal. In this case, it is advantageous for a noise level to be added to the input signal to the quantization stage. The pulse modulator is clocked at a sampling frequency ωA that must be considerably higher than the mixing frequency ω0. Certain ratios of ω0 to ωA result in relaxation oscillations being formed in the pulse modulator. These can be seen as additional peaks in the frequency spectrum of the pulsed signal. Since a noise signal is added to the input signal to the quantizer, the result of the quantization process is statistically rounded. This trick makes it possible to prevent the formation of relaxation oscillations.
The quantization stage preferably carries out binary or ternary quantization of its respective input signal. In the case of binary quantization, the pulsed signal may assume only the values 0 and 1. A pulsed signal is thus produced that contains only positive voltage pulses. A ternary-quantized pulsed signal may assume the values −1, 0, 1. A pulsed signal such as this comprises both positive and negative voltage pulses. Ternary quantization is carried out whenever a pulsed signal is required with both positive and negative pulses.
The feedback unit preferably has a second multiplication stage that multiplies the pulsed signal by a complex-conjugate mixing signal oscillating at the frequency ω0. It thus produces the feedback signal down-mixed by ω0 for the subtractor. The pulsed signal is produced by quantization of the real part of the up-mixed control signal, and thus has its dominant frequency component at the frequency ω0. Before the pulsed signal can be used as a feedback signal, it must be down-mixed again to baseband. For this purpose, the pulsed signal is multiplied by a complex-conjugate mixing signal at the frequency ω0 to obtain a down-mixed complex feedback signal.
The second multiplication stage preferably has a third multiplier for production of the real part of the feedback signal and a fourth multiplier for production of the imaginary part of the feedback signal. The third multiplier multiplies the pulsed signal by the real part of the complex-conjugate mixing signal oscillating at the frequency ω0. The fourth multiplier multiplies the pulsed signal by the imaginary part of the complex-conjugate mixing signal at the frequency ω0. The multiplication of the pulsed signal by the mixing signal must be carried out in complex form to shift that frequency component of the pulsed signal at the frequency ω0 in the correct direction. The pulsed signal y(t) is a real signal, while the complex-conjugate mixing signal can be represented in the form exp(−jω0t). The complex multiplication thus produces a complex feedback signal with the real part y(t)·cos(ω0t) and the imaginary part y(t)·sin(ω0t).
The pulse modulator is preferably operated at a sampling frequency ωA which is 2 to 1000 times higher than the mixing frequency ω0. This is necessary to satisfy the Nyquist condition for the up-mixed signals.
According to a further advantageous embodiment, the pulse modulator is implemented with the aid of a digital signal processor (DSP). All of the operations which are required for operation of the pulse modulator can be programmed with the aid of signal processing routines.
The drive circuit of the invention for a micromechanical resonator has at least one pulse modulator of the type described above. The pulsed signal produced by the at least one pulse modulator is preferably used for electrostatic oscillation stimulation of the resonator. The pulsed signal produced can be directly connected to the stimulation electrodes of the resonator. In this case, it is advantageous for the mixing frequency ω0 of the pulse modulator to correspond to one resonant frequency of the resonator, as this then insures effective stimulation of the oscillator.
A frequency generator in accordance with the invention for synthesis of a pulsed signal at a predetermined frequency with a predetermined phase has at least one pulse modulator of the type described above. The pulse modulator according to the invention can be used to produce a corresponding pulsed signal y(t) at a predetermined frequency with a predetermined phase. In this case, the phase angle of the pulsed signal produced can be very precisely predetermined by the ratio of the real to the imaginary part of the input signal x(t). The pulsed signal produced has a low noise level in the vicinity of ω0.
According to a further advantageous embodiment, the pulse modulator is followed by a bandpass filter, preferably a crystal or ceramic filter. This downstream bandpass filter allows those frequency components remote from ω0 and in which the noise level is high to be filtered out.
While the invention has been described with reference to its presently-preferred embodiment, it is not limited thereto. Rather, the invention is limited only insofar as it is defined by the following set of claims and includes within its scope all equivalents thereof.
Number | Date | Country | Kind |
---|---|---|---|
103 20 674.4 | May 2003 | DE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
---|---|---|---|---|
PCT/EP04/04845 | 5/6/2004 | WO | 11/7/2005 |