DE2405783C2 - Low frequency amplifier - Google Patents

Description

The invention relates to a low frequency amplifier with a plurality of smoothing filters. Such Low-frequency amplifiers are known from "Funkschau" (1971), Issue 23, pages 759 to 761.

Amplifiers of this type are often used in electro-acoustic studio systems because of the acoustic Properties of a room that are different for each hall and therefore separately empirical need to be determined, the amplifier is given away with a number of smoothing filters. The acoustic Properties of a room are irregular and have several peaks. These spikes cause acoustic feedback when the amplifier is at full output. To avoid this, smoothing filters are used provided in the amplifier so that these tips are cut off. For every effective Frequency range there is a separate smoothing filter. For a frequency range between 125 Hz and 8 kHz 24 smoothing filters were used in a known arrangement.

The object of the invention is to provide a low frequency amplifier, its filter easier to adjust and also easier to assemble. This task is carried out by Jie in the mark of the Main claim specified measures resolved. Developments of the invention are in the subclaims described.

An embodiment of the invention is shown in the drawings and will be described in more detail below described.

Show it

1 shows a smoothing filter according to the invention with a filter circuit in the form of a Wien bridge,

F i g. 2 a modification of the filter circuit, F i g. 3 and 4 frequency characteristics of the smoothing filter,

F i g. 5 shows an example of improving a hall characteristic, among others. by using inventive Smoothing filter.

The smoothing filter according to Fig. 1 consists essentially of a first adder, a filter circuit and a second adder in the first adder, the input signal of the smoothing filter and a feedback signal with a variable ratio and variable amplitude are superimposed on the input signal of the first adder via connection point P ₁ The feedback signal is fed to the first adding arrangement via connection point P _3. Between the connection points P \ and Pi there is a series connection of three resistors 55, 56 and 57, one of which 56 is a potentiometer. Parallel to this series connection is a series connection of two resistors 60 and 67 between the connecting points P \ and Pi connected the junction of resistors 60 and 67 is connected to one input of a differential amplifier 50 whose output 82 forms the output of the first adder, the wiper of the potentiometer 56 is over a series circuit of three resistors 58, 59 and 66 connected to a point of constant potential. The resistor 59 is a potentiometer, the slider of which is connected to the other input of the differential amplifier 50. The output of the first adding arrangement ran a first output signal which is derived from the combination of the signals fed to the two connection points P _t and Pi. The setting of the potentiometers 56 and 59 and the values of the other resistors 55, 57, 58, 60, 66 and 67 in the first adding arrangement is responsible for this.

The output of the first adding arrangement is connected to the input of a filter circuit 54.

The transfer function μ of the filter circuit 54 must conform to the general equation below:

w ⁷ -jBw - 1

(D

40

where w represents the frequency normalized to the resonance frequency. The output of the filter circuit 54 supplies a second output signal. This second output signal and the input signal of the smoothing filter are fed to a second adding arrangement

This second adder includes a Diffsrenzverstärker 51, one input of which is connected to a point of constant potential, the other input of the differential amplifier * 51 is on the one hand via a series circuit of two resistors 61 and 62 connected to the one input P * of the second adder and on the other hand, via a Series connection of two resistors 64 and 65 connected to the other input Ps of the second adding arrangement. The other input of the differential amplifier 5i is also connected to its output via a resistor 63. The input signal of the smoothing filter is supplied to one input A and the output signal of the filter circuit is supplied to the second adder arrangement, possibly via an isolating amplifier 52, at the other w> input P%. A third output signal, which represents the output signal of the smoothing filter and the feedback signal, arises at the output P _{1 of the second adding arrangement.}

The third output signal is derived from the signals fed to the two inputs Pt and Ps /.

The setting of the resistors 61 and 65 designed as potentiometers and the values of the other resistors 62, 63 and 64 in the second adding arrangement are responsible for this. The amplifier 53 is not necessary since it is only an inverter. The output of the differential amplifier 51 is connected to the connection point P ₃ , so that the feedback signal can be fed to the first adding arrangement.

The transfer function of the smoothing filter according to Fig. List

w ² - 3jpw - 1
w ² - 3jqw— 1

where w is the normalized frequency ρ and q are constant factors in which the values of the separate resistors, in particular those of the potentiometers 56 and 59, are worked out, which determine the transfer factor at the frequency w = 1 and the bar freite.

A Fiiterschaitung 54, whose transfer function corresponds to equation (1) is given in FIG. The filter circuit, in the form of a Wien bridge with the factor 5 = 3 (see equation (I)), contains a series circuit of a first capacitor 70 and between its input 82 and output a first variable resistor 68. Between the output and a point of constant potential the filter circuit also contains a parallel connection of a second capacitor 71 and a second variable resistor 69. The change of the first resistor 68 and that of the second resistor 69 are coupled to one another and determine the resonance frequency of the smoothing filter continuously over a frequency range from 125 Hz to 8000 Hz. The changes in the potentiometer 56 and 59 determine the transmission factor at the resonance frequency and the quality.

Instead of the filter circuit 54 according to FIG. 1 is also the filter circuit 54 'corresponding to FIG. 2 usable. The filter shaft shown there contains an amplifier stage 73, the input of which is connected to the input terminal 82 and the output of which is connected to a connection point of two potentiometers 78 and 79 connected in parallel. The other connection point of the two potentiometers 78 and 79 is connected to a point of constant potential. The tap of the first potentiometer 79 is connected to the input terminal 82 via a series circuit comprising a second amplifier stage 75 and a capacitor 76, and the tap of the second potentiometer 78 is connected to the input terminal 82 via a series circuit comprising a third amplifier stage 74 and an inductance 77. The input terminal 82 is also the output terminal of the filter circuit 54 '.

The amplifier stages 73, 74 and 75, which have a gain of 1, have a high input impedance and a low output impedance. Via the amplifier stage 73, the resistor 78, the amplifier stage 74 and the amplifier stage 73, the resistor 79, the amplifier stage 75 one can also couple part of the voltage at the point 82 in series with the inductance 77 and the capacitance 76. If one calls the voltage at point S3 (Ax V (82)) and the voltage at point 84 (A'x V (82)), where V (82) is the voltage at point 82, the inductance and change

Capacity according to their value

\ -A

Q ₀ = C ₀

With the help of the double potentiometer 78, 79 you can set the value of A and A ' . This value fluctuates between 0 and I. With the aid of this double potentiometer, the frequency of the filter circuit 54 'can be set in this way. Because you change the inductance as well as the capacitance, it is possible. Realize a continuous detuning over a large area. The quality remains constant if the inductance and the capacitance are changed to the same extent. This can be done with a load on the potentiometer between the tip and the grinder. Resistors 80 and 81 can be provided for this purpose.

The transmission factor at the resonance frequency is doubled due to a non-ideal synchronization Potentiometer not influenced. This therefore makes the circuit arrangement to be used as a selective one Network suitable in active filters. The maximum possible voltage on the circle is determined by displacement the resonance frequency is not affected.

In Fig. 3 and 4, the respective frequency lines of the Smoothing filter shown. Each curve corresponds to the above formula (2).

Fig. 3 shows four curves at a certain resonance frequency and the same transfer factor at the resonance frequency, each curve has a different bandwidth and therefore a different one Quality.

Fig. 4 shows four frequency curves with the same Bandwidth, but with different distribution factors at the resonance frequency. A number of broad, heavily damped curves are also shown.

Above the F i g. 3 and 4 a horizontal arrow in two directions is indicated, which is intended to mean that below Maintaining the shape, each curve to the left as well as to the right, i.e. by changing the resonance frequency, can be moved.

In Fig. 5 is illustrated using an example (the reception

-, hall in the Provinciehuis in 's-Hertogenbosch, Netherlands) with the help of a number of frequency diagrams, that the acoustics of a hall can be significantly improved.

In diagram 100 (which is shown twice) is the

to the frequency characteristic curve of the hall, as it was determined empirically by measurements.

The result after improvement by the invention is shown in diagram 101. The lower frequency curve 102 is the middle curve of diagram 100. This was

ii with a microphone with a circular directional pattern with the characteristic curve 103 and a loudspeaker with a circular directional diagram with the curve 104 measured. By using a cardioid-shaped microphone with the characteristic curve 105, a

: <! Improvement at a frequency of 1000 Hz and 5 dB (the dashed curve is that of the microphone with the circular directional diagram according to curve 103).

This becomes the frequency curve 106 in diagram 101

obtain.

By having the loudspeaker with the circular directional diagram through a loudspeaker a cardioid directional diagram with the curve 107 is replaced in the diagram 101 the Frequency curve 108 with a gain of 4 dB at a

i "obtained frequency of 1000 Hz. (The dashed curve in diagram 107 corresponds to the frequency characteristic of diagram 104.) Starting from the highest peak 109 of curve 108 is an increase for the low and high frequency range on either side thereof

ti can be achieved by using smoothing filters. In this case, the smoothing curve according to diagram 110 is compiled with the aid of four filters. The hall characteristic is now given the shape of diagram 111. The overall resulting frequency

■■ 'curve is curve 112 from diagram 101. The mean gain as a result of the smoothing filter is 1OdB.

Here / u 4 Bi, iit

Claims (5)

Claims; 1. Low frequency amplifier, especially for studio purposes with several smoothing filters, thereby characterized in that all filters are identical and that the quality, the Transfer factor at the resonance frequency and the resonance frequency of the frequency characteristic each Filters can be set separately, with each smoothing filter being provided with: - A first adding arrangement (50; 55 ... 60; 66, 67), in which an input signal of the smoothing filter and a feedback signal with variable Ratio and variable amplitude are superimposed, and a first input to the Supplying the input signal, a second input for supplying the feedback signal, and an output (82) for providing a first output signal derived from the combination of the signals fed to the two inputs is derived, - A filter circuit (54, 54 ') coupled to the output of the first adding arrangement adjustable resonance frequency for deriving a second output signal from the first Output signal, the filter circuit having a transfer function μ of the type -JW w ² -jBw - 1 owns, where w the au? represents the resonance frequency normalized frequency, and a second adding arrangement (51; 61 ... 65), in which the input signal of the smoothing filter and the second output signal are superimposed, and which contains an output for supplying a third output signal which is the output signal of the smoothing filter and the feedback signal. 2. Low frequency amplifier according to claim 1, characterized in that the filter circuit a series circuit of a first capacitor (70) and between its input and output a first variable resistor (68), and constant between the output and a point Potential a parallel connection of a second capacitor (71) and a second variable Resistance (69) contains, and that the change of the first resistance (68) with that of the second Resistance (69) is coupled. 3. Low frequency amplifier according to claim 1, characterized in that the filter circuit has an input terminal (82) which is connected to the output of the first adding arrangement as well as with coupled to an input of the second adder arrangement, that the filter circuit is an amplifier stage (73), whose input is connected to the input terminal and whose output is connected to a connection point between two potentiometers connected in parallel (78,79) is connected, the other connection point with a point constant Is connected potential that the tap of the first potentiometer (79) via a series circuit a second amplifier stage (75) and one Capacitor (76) and the tap of the second potentiometer (78) via a series connection a third amplifier stage (74) and an inductance (77) of the input terminal are connected (Fig. 2). 4. Low frequency amplifier according to one of claims 1 to 3, characterized in that for Setting the quality and the transfer factor at the resonance frequency of the smoothing filter is the first Adder arrangement contains a first potentiometer (56) connected between its inputs, whose tap is connected to a point of constant potential via a second potentiometer (59) and the tap of the second potentiometer (53) with an input of an amplifier stage (50) is connected, the output (82) of which forms the output of the first adding arrangement, the position of the tap of the first or second potentiometer, the quality or the transfer function in the Determines the resonance frequency of the smoothing filter 5. Low frequency amplifier according to one of the preceding claims, characterized in that that between the output of the Fiiterschaitung (54) and the second input of the second adding arrangement an impedance converter, preferably an emitter follower (52), is provided