DE2208661A1 - ACTIVE FREQUENCY FILTER WITH LARGE EDGE PITCH AND FIXED-ADJUSTABLE OR CHANGEABLE BANDWIDTH - Google Patents

Description

Draft for patent application Active frequency filter with large edge part unity and fixed adjustable or variable bandwidth The invention relates on a frequency-selective filter for any frequencies, with which the pass bandwidth can be changed regardless of the slope.

So far known filters consist in their simplest form as LC circles, where the resonance curve of the rice is used to screen out a certain frequency is used from a frequency spectrum. Disadvantageous with these filter arrangements is that when the circular quality Q is increased by undamping by means of feedback or by other known means the flanks = steepness of the filter and thus the filter effect can be increased as much as desired, but on the other hand the pass band width with increasing filter quality Q is more and more narrowed. This fact is at this type of filter is physically conditioned and unalterable. That is why in practice one is forced to always compromise between Elevation or degree of attenuation of the filter to be filtered = the frequency and the required bandwidth f.

Furthermore, band filter circuits are known which essentially from parallel or series connection or from other combinations of the two exist. In such arrangements, the resonance points of the individual links are ol f02 .. on shifted one below the other in such a way that the filter curve of the synchronizing element comes more or less close to the ideal right-angled curve. These types of filters are available although the increase or

Attenuation of the frequency to be filtered and the achievable bandwidth not in an immediate context, but the bandwidth is not continuously changeable, or with changeable bandwidth the also changes Shape of the filter curve. In addition, these band filters are relatively expensive, provided a large slope with good selectivity - attenuation or increase - the band pass is to be achieved.

It is also known that such filters or individual elements # of Filters from frequency-dependent electrical, piezoelectric or mechanical-electrical Structures, or can be built up from combinations of the same.

In addition, filter circuits are known by phase-selective gain elements be able to amplify or weaken frequency-selective feedback with suitable feedback. However, these arrangements also have the physical property that with increasing Quality of the filter circuit the transmission bandwidth is getting smaller. Are such Circuits equipped with active amplifier elements, so you can undamping increase at will, so that finally self-excitation occurs and the filter arrangement oscillates with the frequency to be filtered and acts as an oscillator.

The object of the invention is now to provide a or to improve several of the aforementioned filter circuits in such a way that the Bandwidth of the arrangement can be changed or enlarged as desired without the To reduce quality Q of the filter or a damping of the filter circuit or the To have to make arrangement. Such a circuit could be undamped to such an extent because it works shortly before the point of self-excitation. You would have thus the advantage of a very high edge = steepness of the filter curve and mean very close to the ideal square wave of a filter.

To change the bandwidth in such a resonance arrangement to be able to, according to the invention, one or more components of the circuit, which determine the resonance frequency fo of the filter arrangement designed so that you can control the resonance frequency with a voltage u = f (t) or a current i = f (t) be able to move f0. Another feature of the invention is that the control voltage or the control current has a saw = tooth-shaped course that allows the Re = to control the resonance frequency of the arrangement f0 from f01 to f02 in such a way that each frequency piece Run through #f within the bandwidth (f02 - f01) at equal time intervals will. In such an arrangement, the resonance frequency fQ shifts Filter arrangement during a period of the control voltage or the control current from fO1 to fo2. In the sense of the invention, the stroke of the resonance position (f02 - f01) directly dependent on the amplitude of the control signal, i.e. the transmission bandwidth is continuously adjustable with the help of the amplitude of the control signal.

Another essential feature of the invention is that the control frequency in this arrangement is chosen to be considerably higher than the pass frequencies of the Filters. The right choice of the control frequency is crucial for the function of the filter. It is a multiple of the filter center frequency fom. When choosing the control frequency, care must be taken that the control frequency and filter pass frequencies are identical do not affect each other. The knowledge needed to avoid Frequency mixed products are assumed to be known.

The arrangement described does indeed have an increasing bandwidth a gain loss result. It is characteristic, however, that in contrast to the disadvantages listed above of conventional filter arrangements of the amplification ratio lust does not affect the shape of the filter curve.

It is also within the meaning of the invention to this gain loss with a separate gain controller in the feedback branch of the filter arrangement to compensate and thus to increase the filter quality at will.

In addition, a gain controller is conceivable according to the invention the one with the tape = controller is coupled in such a way that that the attenuation and thus the filter quality are independent of the set bandwidth remains constant or approximately constant.

An embodiment of the invention is based on one from the literature known phase = selective amplifier and is described in more detail below. The drawings show Fig. 1 A basic circuit known from the literature frequency-selective Ihasenbrücke.

Fi. 2 Example of an embodiment known from the literature with Phase bridges built up filter, in which the resonance frequency f0 with the help of two potentiometers can be set and the undamping through Change in the degree of feedback also with the aid of a potentiometer can be adjusted.

FIG. 3 block diagram according to the embodiment according to FIG.

2 for selective boosting of a frequency.

4 is a block diagram of a filter for selective attenuation of a Frequency.

Fig. 5 is a block diagram of an embodiment improved according to the invention the shown in Fig. 2 = th circuit for selective enhancement of a frequency band.

Fig. 6 Graphical representation of the filter effect in the Sirne Invention improved circuit, i.e., dependence of the resonance position on the control signal u = f f (t), bo i - f (t) for selective boosting of a frequency band.

Fig. 7 Graphical representation of the filter effect in the sense of Invention improved circuit, i.e., dependence of the resonance position on the control signal u = f (t), or 1 «f (t) for selective attenuation of a frequency band.

The known phase bridge shown in Fig. 1 has the following spheres of activity: If an alternating voltage uE = f (t) is applied to input 1, then is the voltage occurring at the source of the field effect transistor 5 in phase, while phase the voltage occurring at the drain electrode by 180 ° a = shifted to Input voltage UE = f (t). The voltage appearing at output 2 is only at a certain frequency f0 phase shifted by 900 to the input voltage u, = f (t). To achieve a phase shift of 900 at output 2, it is necessary to that the capacitive resistance of the capacitor 3 Rc = at the frequency f0 genzu is as great as the ohmic resistance R of the potentiometer 4. For all others Frequencies at input 1, the phase shift at output 2 is greater or less than 900. By changing the ohmic resistance at potentiometer 4, the frequency f0, for which the phase shift at the output is 2,900, can be varied.

In Fig. 2 is an embodiment known from the literature a filter constructed with phase bridges according to FIG. 1 is shown.

The input voltage at 6 uE = f (t) with the frequency f0 is with Using the two phases = bridge 7 and 8 each phase shifted by 900, so that at the gate of the transistor 9 a phase ver = shift from 1800 is available. The in-phase voltage occurring at the source electrode is capacitively coupled on the gate of transistor 10, amplified and phase shifted by another 180 ° removed at the drain electrode of transistor 10, so that they then over the Feedback line 11 is fed back to the input 6 of the filter. This fed back The voltage is only phase shifted by 3600 for the frequency fO and thus again in phase with the input signal. For all other frequencies at input 6 is the phase shift of the feedback voltage greater or less than 90 °. Through this a frequency, elective amplification of the filter is enough. With this filter According to Fig. 2, the components that determine the resonance frequency are the two Potentiometer and the two capacitors in phase bridges 7 and 8.

FIG. 3 shows the block diagram of the filter constructed according to FIG. For the frequency, the phase shift of the signal is 90 ° at (12), 180 ° at (13), at (14) 180 °, at (15) 360 °., Fig. 4 shows the block diagram of a corresponding filter constructed according to FIG. 2, in which through anti-phase positive feedback a signal phase-rotated by 180 ° results in an attenuation of the frequency to be filtered occurs. For the frequency f0 the phase shift of the signal at (16) is 900, at (17) 1800, at (18) 3600, at (19) 00, at (20) 180 °.

The circuit shown in FIG. 5 of an improved according to the invention Execution of the filter according to FIG. 2 has the following effect: The oscillator 21 oscillates at the control frequency fst and generates a sawtooth-shaped at its output 22 Voltage uSt. With this control voltage, the stages 23 and 24 controlled. The stages change their output resistance at the outputs 2r, and 26 as a linear function of the control voltage uet. This output resistance becomes in the stages 27 and 28, which as phases = bridges in principle as shown in FIG work, coupled. The output resistances of 23 and 24 then replace accordingly the potentiometer 4 of the two phase bridges 27 and 28. This measure is according to the invention the resonance frequency of the filter periodically with the control voltage uSt shifted, whereby the desired transmission curve is achieved.

Otherwise, the filter that consists of stages 27, 28, 29 and 30 works exists, exactly as shown and described in FIG. 3.

In the context of the invention, it is also the steps 23 and 24 in the In contrast to the design described above, to remain as reactance stages or but to be equipped with a capacitance variation diode (varicap diode). In this case the output signal at 25 and 26 would be a capacitance or inductance. The value the reactance changes periodically linearly with the control signal. The reactance will then in the stages 27 and 28, which as described above as phase bridges in the Prin = zip work as shown in Fig. 1, coupled = coupled. The reactance replacer then accordingly the capacitance 3 of the phase bridges 27 and 28, while the potentiometer 4 is replaced by a fixed resistor. In this form, too, it can be = according to the invention periodically shift the resonance frequency of the filter with the control signal, where = is achieved by the desired transmission curve.

In Fi £. 6 is the graphic representation of the filter effect at selective increase of a frequency band shown. The curve 31 of the periodic Sawtooth voltage uSt = f (t) is the recording of the signal that is output 22 of Oscillator 21 is available. The resonance position of the filter changes periodically with the control voltage uSt from (f01) (32) via the filter center frequency (f0m) 33 until after (f02) 34.

The representation shows the relationship between the control signal and the resonance position of the filter immediately.

In Fig. 7 the graphic representation of the filter effect is at selective attenuation of a frequency band shown. In the context of the invention a selective attenuation of a frequency band is achieved by using the basic circuit after i? ig. 4. is expanded with the steps 21, 23 and 24 from FIG. The perio = output resistances or reactances that change with the control signal 22 25 and 26 then replace the frequency-determining resistors or capacitors the filter circuit according to Fig.

4. The resonance position also changes for a filter constructed in this way of the filter periodically with the control voltage (uSt) 35 of (f01) 36 over the filter center frequency (f0m) 37 to after (f02) 38. The illustration shows the relationship between the control signal and recognize the resonance position of the filter immediately.

The idea on which this invention is based is shown in FIGS. 7 can be seen particularly clearly. The sawtooth-shaped control voltage 31 and 35 is instead of the known "wedge-shaped" filter effect corresponding to the partial curves 32 - 34 and 36 - 38 achieve an almost rectangular filter effect, with the width of the rectangle of the amplitude of the saw = tooth voltage 71 and 35 corresponds. For the practical implementation of a filter circuit implemented within the meaning of the invention it is of course also conceivable that instead of the saw tooth-shaped control voltage a periodic sawtooth-like control voltage is used in which the increasing Branch of the curve has the same steepness as the falling branch of the sawtooth voltage owns. Furthermore, it is conceivable for the practical implementation that the sawtooth = voltage may have to be somewhat distorted so that the filter for the lower band limit o has the same gain as for the. upper band limit f02

Claims (7)

Claims 1. Frequency filter with a steep slope and permanently adjustable or variable bandwidth for any frequencies d a = it is indicated that one or more components of the scarf = device, which determine the resonance frequency of the filter arrangement, with a current or a voltage can be controlled, and that with periodic control of this Components with a control frequency that is greater than the frequency to be filtered is, the resonance position of the filter periodically with the control frequency = within the pass band width of the filter is shifted back and forth. 2. Filter according to claim 1, d a d u r c h g e = k e n n z e i c h n e t, d the curve shape of the control voltage or the control current is sawtooth Has a course that allows the resonance frequency of the arrangement to be controlled in such a way that that the 5th frequency segment within the transmission band width at equal time intervals is run through. 3. Filter according to claim 1, d a d u r c h g e = k e n n z e i e h n e t that the curve shape of the control voltage or the control current is non-sawtooth Has a course that allows the resonance frequency of the arrangement to be controlled in such a way that that each frequency segment within the passband width is equal in time Intervals through = will run. 4. Filter according to claim 1, 2 or 3, d a d u r c h g e k e ri n z e 1 c h n e t, dsß the transmission bandwidth with the help of and by changing the Amplitude of the control voltage or the control current can be adjusted or varied can. 5. Filter according to claim 2, t, or 4, = d u r c h g e k e n n d a E i c h n e t that the installation of active components reduces the attenuation of the filter arrangement is made by means of feedback, which allows gain losses increase = to compensate for the bandwidth and the steepness of the filter curve Increase the Q factor. 6. Filter according to claim 1, 2, 3, 4 or 5, d a d u r c h g e k c n N z e i c h n e t that the gain controller with the bandwidth controller is electrical or is mechanically coupled in such a way that d the attenuation and thus the filter quality Q is constant or approximately constant regardless of the bandwidth set remain. 7. Filter according to claim 1, 2, 3, 4, 5 or 6, d a d u r c h g e k It is noted that the filter arrangement does not work as a bandpass filter and in the Passband raises certain frequencies, but rather as a bandstop filter or notch filter and thus attenuates certain frequencies. The words pass = bandwidth, undamping and gain are then to be changed accordingly.