RU2194359C2 - Synchronous comb filter - Google Patents

Abstract

FIELD: radio engineering and electronics; signal processing systems such as those for machine diagnostics. SUBSTANCE: comb filter has adder 7, low-frequency filter 8, and potentiometer 6 built in feedback circuit of operational amplifier 5. Common point of connection of resistor 4 and switched capacitors 3 of RC filter 1, 2, 3, 4 is connected to noninverting input of operational amplifier 5. Potentiometer wiper 6 is connected to noninverting input of operational amplifier 5 and to adder 7 whose noninverting input is connected to input of comb filter and to input of resistor 4, and its output is connected to input of low-frequency filter 8; output of the latter functions as output of comb-filter band-elimination section and that of operational amplifier 5, as output of comb-filter band-pass section. Low- frequency filter 8 incorporates provision for cutoff frequency control and its input is connected to clock pulse input of distributor 1. EFFECT: enlarged functional capabilities, improved selectivity of synchronous rejection filter, eliminated pulse noise across operational amplifier output. 2 cl, 2 dwg

Description

 The invention relates to the field of radio engineering and electronics, and in particular to synchronous comb filters, and can be used in signal processing systems, for example, in machine diagnostic systems.

 Known synchronous obstruction filter (see, for example, UK patent 1323918, CL NKI N 03 H, 1973) containing an operational amplifier and a synchronously-switched RC filter, the input of which is connected to the output of the operational amplifier.

 A disadvantage of filters of this type is their lack of functionality, since they cannot simultaneously provide a comb characteristic of both transmission and blocking types, and this is necessary when processing vibroacoustic signals in machine diagnostic systems.

 Known synchronous obstruction filter (see, for example, AS USSR 629625, class MKI N 03 N 7/10), containing an operational amplifier and a synchronously switched RC filter, the input of which is connected to the output of the operational amplifier, while between The output and the inverting input have feedback with the built-in capacitor, and the output of the synchronously-switched RC filter is connected to the inverting input of the operational amplifier.

 A synchronously switched RC filter includes a resistor, a line of switched capacitors and a switching device.

 The disadvantage of this synchronous obstruction filter is its lack of functionality, since it cannot simultaneously provide a comb characteristic of both transmitting and obstructing types, and this is necessary when processing vibroacoustic signals in machine diagnostic systems.

 This is due to the fact that the input resistance of the inverting input of the operational amplifier when it is turned on during its operation on a linear section of the amplitude characteristic is practically zero (see, for example, Alekseenko A.G. "Fundamentals of Microcircuitry" Sov. Radio M., 1977, p.261 "Current Amplifier"). Therefore, the synchronous-switched filter capacitors are almost instantly charged to the input voltage, the level of which changes little during the detuning of the filter switching frequency relative to the frequency of the input signal. This leads to poor selectivity of the synchronous obstruction filter, which is its second drawback.

 In addition, the disadvantage is that when the signal is suppressed, for example, in a sinusoidal form, the voltage difference between the smoothly changing input voltage and the accumulated voltage "step" on the switched capacitors is applied directly to the differential input of the operational amplifier, which leads to the appearance of large noise pulses at its output with the switching frequency of the filter capacitors.

 An object of the invention - the proposed synchronous comb filter - is to expand the functionality of the filter by providing comb characteristics of both a transmission type and a trap type, improving the selectivity of a synchronous trap filter, and also preventing interference pulses from appearing at the output of an operational amplifier.

 The technical result in the inventive synchronous comb filter containing a feedback operational amplifier and an RC filter including a resistor, a line of switched capacitors, a switch and a distributor is achieved by the fact that the synchronous comb filter is equipped with an adder, a low-pass filter and a potentiometer built into feedback circuit of the operational amplifier, while the connection point of the resistor and switched capacitors of the RC filter is connected to the non-inverting input of the operational amplifier, the potentiometer’s jumper is connected to the inverting inputs of the operational amplifier and adder, the non-inverting input of which is connected to the input of the comb filter and the input of the resistor, and the output is connected to the input of the low-pass filter, the output of which is the output of the blocking link of the comb filter, and the output of the operational amplifier is the output of the transmitting link of the comb filter.

 The technical result in the claimed synchronous comb filter is also achieved by the fact that the low-pass filter is made with an electrically controlled cut-off frequency, and the control input of the low-pass filter is connected to the input of the clock pulses of the distributor.

The analysis of the distinguishing features of the claimed synchronous comb filter and the technical results achieved by them showed that:
- supplying a synchronous comb filter with an adder, a low-pass filter and a potentiometer built into the feedback circuit of the operational amplifier, as well as the indicated connections of the potentiometer engine provide a synchronous comb filter with a comb characteristic of both a trapping type and a transmitting type;
- connecting the connection point of the resistor and switched capacitors of the RC filter to the non-inverting input of the operational amplifier provides a high selectivity to the synchronous comb filter, since the input impedance in this connection is very large and does not summarize the switched errors;
- the connection of the non-inverting input of the adder with the input of the comb filter and the input of the resistor and the connection of its output to the input of the low-pass filter, the output of which is the output of the blocking link of the comb filter, provides a synchronous comb filter to clear the signal that is removed from the blocking link, eliminating all interference;
- the fact that the output of the operational amplifier is the output of the transmitting link of the comb filter provides a synchronous comb filter with high-frequency selectivity of the signal that is removed from the transmitting link, eliminating all interference;
- the implementation of the low-pass filter with an electrically controlled cut-off frequency and the connection of the control input of the low-pass filter with the input of the clock pulses of the distributor provides a synchronous comb filter at the output of the blocking link signal isolation without interference.

The invention is illustrated by drawings, which depict:
figure 1. - synchronous comb filter circuit;
figure 2 is a timing diagram of the synchronous comb filter.

 The synchronous comb filter (Fig. 1) contains an RC filter, which includes a serially connected distributor 1, switch 2, a line of switched capacitors 3 and a resistor 4. And also the feedback amplifier, 5, is included in the synchronous comb filter, into which built-in potentiometer 6, adder 7 and low-pass filter 8.

 The potentiometer engine 6 is connected to the inverting inputs of the operational amplifier 5 and the adder 7.

 The connection point of the resistor 4 and the line of switched capacitors 3 of the RC filter is connected to the non-inverting input of the operational amplifier 5.

 The non-inverting input of the adder 7 is connected to the input of the comb filter and the output of the resistor 4.

 The output of the adder 7 is connected to the input of the low-pass filter 8, and the output of the low-pass filter 8 is the output of the blocking link of the comb filter.

 The output of the operational amplifier 5 is the output of the transmission link of the comb filter.

 The low-pass filter 8 is made with an electrically controlled cutoff frequency.

 The control input of the low-pass filter 7 is connected to the input of the clock pulses of the distributor 1.

The synchronous comb filter operates as follows:
The signal input 10 receives the input signal S, which is a mixture of sinusoids with different frequencies (see figure 2 - ordinate 10), and the input signals of the clock pulses 9 receive signals that control the operation of the distributor 1, which moves to the right by 1 bit in the ring upon receipt each new pulse and through the switch 2 connects the bottom according to the scheme (Fig. 1) the lining of the corresponding capacitor line 3, which is charged through the resistor 4 for a time equal to the period of the clock pulses Tu.

The frequency of the clock pulses is selected from the ratio:
fu = 1 / Tu = fin • n / k
where f _I - the frequency of the allocated and suppressed signal;
n is the number of switched capacitors in line 3;
k = 1,2,. . . = constant coefficient reflecting the fact that a signal is accumulated on the filter capacitors containing both the first (k = 1) harmonic and the higher harmonics (k = 2, 3 ...).

 The waveform stored on the capacitor bar 3 is shown in FIG. 2 - ordinate 3. This signal is fed to the non-inverting input of the operational amplifier 5 (op-amp) and through negative feedback to the potentiometer 6 and further from the potentiometer 6 engine to the inverting inputs of the operational amplifier 5 and adder 7.

In this inclusion, on the non-inverting input side, the operational amplifier 5 has a very high input impedance. This resistance can be tens or hundreds of times greater than the resistance of resistor 4. This allows you to achieve high selectivity of the filter, the passband of which is determined by the product R • C and is made less than 1 Hz with low power losses of the emitted signal, which are determined by the ratio R ₄ / R _I operational amplifier 5 and brought to a value of less than 1%.

 The transmission coefficient of the non-inverting amplifier on the operational amplifier 5 is regulated by a potentiometer 6, adjusting the position of which we set the signal gain at the output 12 of the transmission filter link.

 On the inverting input side, the operational amplifier 5 has a low output impedance and a transmission coefficient with high accuracy equal to 1.

The signal from the inverting input of the operational amplifier 5 is fed to the inverting input of the adder 7, in which the signal f _in accumulated by the line of capacitors 3 is subtracted from the input signal S. The output signal f _{out of the} adder 7 no longer contains the frequency f _in and its harmonics - they are suppressed . The suppression coefficient f _in is determined by the degree of identity of this signal at both inputs of the adder 7 and in the proposed circuit is at least 35 decibels without additional adjustments and when the transmission coefficient of the transmitting link is changed by potentiometer 6 over a wide range.

The output signal of adder 7 contains interference with the switching frequency, due to the finite value of the voltage difference at its inputs between the smoothly varying input voltage and the accumulated "steps" on the switched capacitors of line 3. Since the transfer coefficient of the adder 7 is small and equal to 1 (unity), then the switching interference its output is much smaller than that of the prototype (for an operational amplifier, the transmission coefficient = 10 ⁴ ... 10 ⁵ ). Next, the signal is fed to a low-pass filter 8 (low-pass filter 8), where switching interference is further attenuated, and from the output of the low-pass filter 8 to the output of the blocking link 11 of the filter.

The frequency of the low frequency cutoff filter 8 f _cf. usually selected lower frequency clock pulses and is determined by f _and the required degree of attenuation of switching noise (number of units) low frequency filter 8.

When reconstructing the comb filter to isolate and block signals whose frequencies may be lower than f _cf low-pass filter 8, an increase in the level of switching noise will be observed at the filter output. To eliminate this, the low-pass filter 8 is made electrically tunable, depending on the frequency of the switching pulses f _and received at input 9. For this, the tuning control input of the low-pass filter 8 is connected to the input of the clock pulses 9. This embodiment of the low-pass filter 8 allows you to save the ratio f _cf / f _and constant and ensure the prevention of switching noise at the output in the entire frequency range of the output signals.

 Thus, the proposed synchronous comb filter provides an extension of the filter's functionality by providing a comb characteristic of both a transmitting type and a blocking type, improving the selectivity of the synchronous blocking filter, and also preventing the appearance of interference pulses with a switching frequency of capacitors at the output of the operational amplifier.

Claims (2)

 1. Synchronous comb filter containing an operational amplifier with feedback and an RC filter including a resistor, a line of switched capacitors, a switch and a distributor, characterized in that the synchronous comb filter is equipped with an adder, a low-pass filter and a potentiometer built into the feedback circuit connection of the operational amplifier, while the connection point of the resistor and switched capacitors of the RC filter is connected to the non-inverting input of the operational amplifier, the potentiometer engine is connected to tiruyuschimi inputs of the operational amplifier and adder, a non-inverting input of which is connected to the input of the comb filter and the input resistor, and an output connected to the input of the low pass filter whose output is the output of the comb filter fence unit, and the output of the operational amplifier is an output of the comb filter transmissive member.  2. The synchronous comb filter according to claim 1, characterized in that the low-pass filter is made with an electrically controlled cut-off frequency, and the control input of the low-pass filter is connected to the input of the clock pulses of the distributor.

Images