DE3727778A1 - RC filter - Google Patents

Abstract

In the case of an RC filter (1) for receivers in ripple-control installations, in the form of a resonator circuit having a dissipation admittance (2), two filter admittances (3, 4), one feedback admittance (5), two tuning admittances (6, 7) and two operational amplifiers (8, 9), in the case of which the dissipation admittance (2), the first filter admittance (3) and the non-inverting input of the first operational amplifier (8) are connected at one end to the input (10) of the resonator circuit, and the dissipation admittance (2) is connected to earth at the other end, the feedback admittance (5) is connected at one end to the other end of the first filter admittance (3) and to the output of the second operational amplifier (9), the other end of the feedback admittance (5) and one end of the second filter admittance (4) are connected to the inverting input of the second operational amplifier (9), the other end of the second filter admittance (4), the output of the first operational amplifier (8) and one end of the first tuning admittance (6) are connected to the output (11) of the resonator circuit, the other end of the first tuning admittance (6) is connected to earth via the second tuning admittance (7), and the non-inverting input of the second operational amplifier (9) is connected to the junction point (12) of the two tuning admittances (6, 7), high-frequency interference at the input is regulated out more quickly, while maintaining the filter characteristic, by the first operational amplifier (8) in ... Original abstract incomplete. <IMAGE>

Description

The invention relates to an RC filter according to the preamble of claim 1.

Filters can u. a. differentiate according to the following criteria:

• a) According to the type of components determining the frequency; if the frequency-determining components are coils and capacitors, then LC filters are available, if resistors and capacitors are used as the frequency-determining components, RC filters are obtained.
• b) According to the type of implementation of the coupling factor; is the coupling factor through the relationship of substantially or objectively existing Given coupling components, one speaks of a coupling filter, the coupling factor is not substantive or objective through the relationship given existing coupling components, speaks one from a detuning filter.
• c) Depending on whether the four-pole system used includes active components or not; one speaks of active or passive filters.

For example, an RC coupling filter in the form of a band filter with two filter stages is known (DE-PS 24 36 966). This two-circuit active RC filter has a number of advantages, including:

• a) The damping d are excellent constant as pure resistance and capacitance ratios, so that no temperature compensation is required.
• b) Any damping d can be realized. So you can adapt the well-known active RC band filter to all practical requirements, e.g. B. narrow or broadband or slow or fast swinging.
• c) The decoupling load has no influence on the selectivity, because the amplifier of the last RC four-pole delivers the power and prevents any feedback; additional power amplifiers are therefore not required.
• d) The amplifier of the last RC four-pole always allows high output levels. Threshold values, e.g. B. of transistors, meaningless, and you achieve a real switch function.
• e) You can always couple optimally (= critically), so that you get relatively large attenuations d and consequently short settling times (and the associated low impulse distortion).
• f) The coupling factor k and thus the amplification factor V is largely stable, since the coupling factor k is only determined by two identical (capacitive or ohmic) coupling admittances.

Although excellent results have already been achieved with the known dual-circuit RC coupling filter, it has nevertheless been considered to achieve even more improved properties by connecting a plurality of such dual-circuit RC coupling filters in series, in particular an improved settling time compared to a dual-circuit RC coupling filter (again DE-PS 24 36 966). With such series connections (chain connections) of two-circuit RC coupling filters, however, the problem arises that the coupling factors between the individual two-circuit RC coupling filters are not given by the ratio of substantially or objectively existing coupling components. The problems with the coupling factors, which are eliminated in a two-circuit RC coupling filter, therefore occur again to a certain extent in such chain circuits, since the detuning coupling factors between the individual chain links are very sensitive to element variations as a small difference in large frequencies.

In addition, active RC four-poles of various designs are known, namely as low-pass filters, high-pass filters, band-pass filters (band filters, selective filters), notch filters, notch filters, all-pass filters, etc. (Tietze, Schenk "Semiconductor Circuit Technology", 3rd edition 1974, chapter 11 , Page 306 ff.).

The best possible selectivity and the shortest settling times are associated with a high degree of stability in relation to variations in the coupling components used in an advanced RC filter in the form of a coupling filter, in which the RC four poles of the filter form a continuous chain and are connected to one another via nested feedbacks (DE-PS 32 18 098). With this RC filter, practically all types of RC four poles can be used, the type of RC four poles used determining the character of the entire RC filter. It is essential in any case that all coupling factors result as quotients of the same coupling components, so that temperature changes, for example, have no influence on the coupling factors.

The known RC filter explained above can be implemented with filter stages in the form of a resonator circuit of the type explained above. Such resonator circuits are known as such ("Handbook for High Frequency and Electrical Technicians", Volume 5, Dr. Alfred Hüthig Verlag, Heidelberg, 1981, Section IV, in particular Part 2.6 and Figure 23, p. 384). They work extremely low loss, so they have an extremely low attenuation at the corresponding frequency. In addition, such resonators are even less sensitive to element variations, that is, they are even more stable, since they have a very high idle gain because of the two amplifiers.

An analysis of the signals occurring at the input of an RC filter of the type in question when used in ripple control systems shows that high-frequency interference in the MHz range often occurs with considerable amplitudes, for example between 10 and 250 MHz with amplitudes up to 3 kV. The known resonator circuits, which are distinguished by the fact that the two operational amplifiers are connected to one another with their inverting inputs ("Manual for...", Table 3 on pages 387, 388), regulate these high-frequency interference only relatively slowly because of the integrator effect of these circuits out.

The invention is therefore based on the object of designing and developing the circuit arrangement of the known RC filter in such a way that high-frequency interference at the input is corrected faster while maintaining the filter characteristic.

The task outlined above is distinctive with the features Part of claim 1 solved. Regarding the filter characteristic is the resonator circuit with the first connected in the electrometer circuit Operational amplifier of the known resonator circuit equivalent, because of Elimination of the integrator effect and the extremely high differential input resistance of the first operational amplifier results in a considerably faster correction of high-frequency interference at the input.

In the following, the invention is based on an exemplary embodiment only illustrative drawing explained in more detail; it shows

Fig. 1 is a diagram of an RC -filter in the form of a normal resonator,

Fig. 2 is a circuit diagram of an RC filter in the form of a resonator circuit according to the invention and

Fig. 3 is a two-circuit RC -Koppelfilter with two RC filters care of FIG. 2.

Fig. 1 shows an RC filter 1 , which is intended and suitable for receivers of ripple control systems, in the form of a resonator circuit. The resonator circuit has a discharge admittance 2 , two filter admittances 3, 4 , a feedback admittance 5 , two tuning admittances 6, 7 and two operational amplifiers 8, 9 . In the exemplary embodiment shown, the discharge admittance 2 and the feedback admittance 5 are implemented as capacitors and the filter admittances 3, 4 and the tuning admittances 6, 7 as ohmic resistances, but this need not necessarily be the case (cf. the circuit examples in the "Manual for..." loc. cit.).

From Fig. 1 it follows that here, in the normal circuit of the RC filter 1 , the discharge admittance 2 , the first filter admittance 3 and the non-inverting input of the first operational amplifier 8 are connected at one end to the input 10 of the resonator circuit and the discharge admittance 2 at the other end to ground the feedback admittance 5 is connected at one end to the other end of the first filter admittance 3 and to the output of the second operational amplifier 9 , the other end of the feedback admittance 5 and one end of the second filter admittance 4 are connected to the inverting input of the second operational amplifier 9 , the other end of the second filter admittance 4 , the output of the first operational amplifier 8 and one end of the first tuning admittance 6 are connected to the output 11 of the resonator circuit, the other end of the first tuning admittance 6 is connected to ground via the second tuning admittance 7 and the non-inverting one Entry of the second operat ion amplifier 9 is connected to the connection point 12 of the two tuning admittances 6, 7 . Here, the inverting input of the first operational amplifier 8 is then further connected to the connection point of the second filter admittance 4 and feedback admittance 5 and at the same time to the inverting input of the second operational amplifier 9 .

The normal connection of a resonator circuit of a RC -filter 1 shown in FIG. 1 is, as has been explained above, subject to an integrator effect that prevents a sufficiently rapid response to high-frequency disturbances at the input 10 of the resonator circuit. The integrator effect is now prevented according to the invention in the circuit according to FIG. 2 in that the first operational amplifier 8 is connected in an electrometer circuit, namely the inverting input of the first operational amplifier 8 is also connected to the connection point 12 of the two tuning admittances 6, 7 . The electrometer circuit of operational amplifier 8 is characterized by the elimination of the integrator effect and the particularly high differential input resistance which results from the transformation of the differential input resistance of the operational amplifier with the loop gain as a factor at the input.

It follows from the above explanation that the properties of the RC filter 1 according to the invention become particularly good when the first operational amplifier 8 has a high idle gain, in particular an idle gain above 100 dB. In the same way, it is advantageous if the first operational amplifier 8 has a high cut-off frequency, namely a cut-off frequency greater than 10 Hz, in particular greater than 100 Hz.

From Fig. 2 further 1 results in connection with Fig. That the input 10 is connected upstream of the resonator circuit or an input resistor 13 so that the external input 14 of the resonator circuit is connected through input resistor 13 with the actual inner input 10.

Fig. 3 now provides a two-circuit RC is -Koppelfilter, the filter stages are each RC filter 1 according to FIG. 2. Also shown here are the output 15 of the overall circuit arrangement, which is connected to the inner output 11 of the second RC filter 1 via a decoupling circuit 16 . A supply line with a positive supply voltage and the ground line and further admittances 17 for setting the operating points and coupling admittances 18, 19 , in particular coupling capacitors 19, can also be seen here . For this purpose, reference may be made in detail to DE-PS 32 13 098, which in principle shows the feedback shown here, as well as to DE-PS 24 36 966.

Claims (3)

1. RC filter ( 1 ) for receivers of ripple control systems, in the form of a resonator circuit with a discharge admittance ( 2 ), two filter admittances ( 3, 4 ), a feedback admittance ( 5 ), two tuning admittances ( 6, 7 ) and two operational amplifiers ( 8 , 9 ), wherein the discharge admittance ( 2 ), the first filter admittance ( 3 ) and the non-inverting input of the first operational amplifier ( 8 ) are connected at one end to the input ( 10 ) of the resonator circuit and the discharge admittance ( 2 ) at the other end to ground, the feedback admittance ( 5 ) is connected at one end to the other end of the first filter admittance ( 3 ) and to the output of the second operational amplifier ( 9 ), the other end of the feedback admittance ( 5 ) and one end of the second filter admittance ( 4 ) to the inverting input of the second operational amplifier ( 9 ) are connected, the other end of the second filter admittance ( 4 ), the output of the first operational amplifier ( 8 ) and one end of it Most tuning admittance ( 6 ) are connected to the output ( 11 ) of the resonator circuit, the other end of the first tuning admittance ( 6 ) is connected to ground via the second tuning admittance ( 7 ) and the non-inverting input of the second operational amplifier ( 9 ) is connected to the connection point ( 12 ) of the two tuning admittances ( 6, 7 ), characterized in that the first operational amplifier ( 8 ) is connected in an electrometer circuit, namely the inverting input of the first operational amplifier ( 8 ) also to the connection point ( 12 ) of the two tuning admittances ( 6 , 7 ) is connected. 2. RC filter ( 1 ) according to claim 1, characterized in that the first operational amplifier ( 8 ) has a high idle gain, in particular greater than 100 dB. 3. RC filter ( 1 ) according to claim 1 or 2, characterized in that the first operational amplifier ( 8 ) has a high cut-off frequency, namely a cut-off frequency greater than 10 Hz, in particular greater than 100 Hz.