DE1288639B - Device for tone control of amplifiers, differential tone screen for two-sided continuous tone color adjustment - Google Patents

Description

The invention relates to a differential tone screen for two-sided continuous tone color adjustment with two capacitors that share a common Potentiometers interact with each other and one component of which one the higher Preferring audio frequencies, running from a signal input to a signal output Branch forms.

Sound panels can be adjusted either continuously or in stages. In the case of the gradual control, there is an independence of the increase and the trimming of the treble and bass, as between the switching elements for the Elevation and circumcision have no enforced relationship, however this level control has the disadvantage that only a limited number of discrete settings is possible. The continuous modulation actually has the advantage of infinite many settings, but to achieve a straight frequency response is one Compensation required, which cannot be achieved for all adjustment points can. Also, exaltation and circumcision are related, so that it is not possible, for example, to increase the frequency at the same time to receive circumcision at a different frequency.

Sound panels with such a continuous level control are for example from P i t s c h, Textbook of Radio Reception Technology, Vol. 2, 1964, §§ 378 to 391 are known.

From US Pat. No. 3,059,190 there is also a sound screen for the use in amplifiers in the radio frequency range known, in which a continuous Manual level control is provided for increasing and cutting the treble and bass is. In this arrangement, too, the control of the treble is coupled with that of the bass (Treble increase and bass trimming take place simultaneously and vice versa); to achieve a straight frequency response, a circuit is used in which the two Controls have a mutually compensating effect. Such a circuit represents one A compromise, the success of which depends on the tolerances of the components. The circuit according to the cited patent has the further disadvantage that at certain frequencies the signal amplitude must be amplified beyond the normal value, whereby the distortion increases and the average output power is limited.

According to the invention, the disadvantages mentioned are associated with a differential tone diaphragm Avoided the type mentioned in that both to control the bass as well as elevation and pruning are done independently of each other. Preferably a differential tone diaphragm is used to control the bass, in which the two Capacitors each with one pole together on the wiper forming the signal output and with the other pole on one of the two fixed connections of the potentiometer lie, one of which forms the signal input, and that the wiper of the potentiometer is designed as a double wiper, the contacts of which have a fixed distance and in a middle position each touch one of the fixed connections, both as Contact bars of vanishing resistance as well as one the distance between the sliding contacts corresponding length are formed. A Differential tone screen used, in which the two capacitors with one pole each, one of which forms the signal input, at the two fixed connections of the potentiometer and the other pole is connected to an associated shunt resistor, that also the ends of the shunt resistors facing away from the capacitors the potentiometer wiper forming the signal input and that the Potentiometer about in the middle between the two fixed connections an interruption which is greater than the contact width of the wiper, in each potentiometer setting one of the two capacitors is switched off.

The invention is characterized in that it admittedly simplicity and economy of the timbre control by potentiometer maintains, at the same time, however, the advantages of continuous control with the previous one only combined by gradual control achieved flat frequency response.

Further details of the differential tone diaphragm according to the invention result can be derived from the following description of some exemplary embodiments and application examples in connection with the drawings. In it, F i g. 1 is a circuit diagram of a passive Bass level control arrangement, FIG. 2 is a circuit diagram of an active bass level control arrangement with a single stage of tone shutter feedback, FIG. 3 is a circuit diagram of a passive height control arrangement, F i g. 4 is a circuit diagram of an active tone shutter arrangement with bass and treble feedback control, FIG. 5 shows a schematic plan view one for the bass control of the circles in FIG. 1, 2 and 4 potentiometers used, F i g. 5 a a plan view of a modification of the arrangement according to FIG. 5, Fig. 6 is a schematic circuit diagram of a combined passive bass and treble control and F i g. 7 is a schematic circuit diagram of a transistor amplifier with tone shutter circuits according to the F i g. 1 and 3.

According to FIG. 1, the bass control circuit is provided with an audio signal input connection 10 and an audio signal output connection 11 . Fixed current limiting resistors 12 and 13 are provided at the input and ground ends of the assembly, between which there is a shutter network generally designated 14. The network 14 contains two capacitors 15 and 16 in series, which may be different but are shown in the same way, and a connection point 17 which is connected directly to the output terminal 11. A novel potentiometer is connected across the capacitors 15 and 16, which consists of a first section 18 with the resistance zero, an adjoining resistor section 19 and a further adjoining section 20 with the resistance zero. All sections can be the same length. A double wiper is provided with the contacts 21 and 22, which are electrically connected by the line 23 and are spaced apart from one another such that they spread over the resistor section 19 in the central position and rest completely on the sections 18 and 20.

If contacts 21 and 22 are in the middle position, so are the capacitors 15 and 16 across the circle with the elements 18, 21, 23, 22 and 20 and point 17, which is directly connected to line 23, short-circuited. At point 17 there is a lower voltage than at connection 10, because of the resistors 12 and 13 a voltage division takes place. The circle is purely ohmic and therefore the tone aperture setting flat.

When the contacts 21 and 22 are moved upwards (as seen in FIG. 1), the capacitor 15 remains short-circuited, but the resistor section 19 and the capacitor 16 are connected in series with the resistor 13 as seen from point 17. When contacts 21 and 22 move downward, capacitor 16 is short-circuited and capacitor 15 and resistor 19 are connected in series with resistor 12. Accordingly, an upward movement of the contacts 21 and 22 brings the impedance into the shunt path, resulting in a bass boost, since this effect increases the impedance between point 17 and ground, while a downward movement of the wiper contacts 21 and 22 shorts the capacitor 16 and an impedance in introduces the direct signal path while leaving the shunt path unchanged, resulting in bass clipping.

In the arrangement according to FIG. 2, a triode 30 with an anode 31, a grid 32 and a grounded cathode 33 is provided. An anode load 34 is between terminals B -L. and the anode 31 switched. A tone diaphragm 14 which, exactly as in FIG. 1, but possibly designed with other circular values, is connected between the anode 31 and the signal input terminal 10 . The input signal for the grid 32 is now controlled by the capacitor 16 and the resistor section 19 , while the feedback circuit is controlled by the capacitor 15 and the resistor section 19. When the slider is moved to the right (FIG. 2), the entire feedback signal is applied directly to grid 32 via resistor 12, capacitor 15 being short-circuited. The feedback signal appears at the grid bleeder resistor 35. The input resistor 36 is in a circle with at least part of the resistor section 19 shunted to the capacitor 16, which leads to the grid bleeder resistor 35, and thus the signal at the grid 32 is reduced, that is, a bass clipping takes place. On the other hand, if the contacts are moved to the left, resistor section 19 and capacitor 15 are shunted thereto in the feedback path, while the DC signal path includes resistors 36 and 35 and capacitor 16 is bridged.

It follows that the total feedback for all positions of the Contacts on one side of the center position is available and that a changeable one Resistance between resistors 35 and 36 is switched on, while at opposite Position of the contacts, the resistors 35 and 36 always directly in series with the intermediate one Impedance are zero and the feedback path is a variable impedance.

F i g. 3 shows a passive height control. A signal is supplied through the input terminal 40 . A sound diaphragm with a capacitor 43, a resistor 44, a gap 45, a resistor 46 and a capacitor 47 is connected between the input terminal 40 and ground. The wiper 48 is connected to the output terminal 49 and can move via the resistors 44 and 46 and the gap 45 which forms the central position. The resistors 50 a and 50 b are connected between the terminal 40, the terminal 49 and earth in order to provide a switched-through circuit with fixed attenuation at all times.

When the wiper 48 is at gap 45 , the shunt path across the tone shutter capacitors is completely eliminated and the frequency response of the circuit is flat. When the wiper 48 slides on the resistor 44, the resistor 46 and capacitor 47 are ineffective and the capacitor 43 provides a treble boost by removing the attenuation at high frequencies. When the wiper 48 is on the resistor 46, the resistor 44 and capacitor 43 are ineffective and the capacitor 47 provides a treble clipping by increasing the attenuation at high frequencies.

F i g. 4 shows a multi-stage feedback loop with a height and bass control. The circle essentially corresponds to that of the USA patent specification 3 059190, but contains the special tone control circuit and potentiometers of the F i g. 1 to 3.

According to FIG. 4, the input signal is fed to the connection 10, which is connected directly to the control grid 53 of the triode 53. The triode contains the anode 54 and the cathode 55, which are provided in the usual manner with an anode load resistor 56 and a non-bridged cathode resistor 57. The anode 54 has a RC-coupling across the series capacitor 58 and the Gitterableitwiderstand 59 to the grid 60 of the second triode 61. The triode 61 includes an anode 62 and a cathode 63 which in a conventional manner with an anode load resistor 64 and a nichtüberbrückten cathode resistor 65 are provided.

The anode 62 is connected back to the cathode 55 via a tone diaphragm circle 66 which contains a bass control part 67 and a treble control part 68 which correspond to the circles in FIG. 1 and 3, but correspond in feedback. Accordingly, corresponding parts of FIG. 1 and 3 on the one hand and FIG. 4, on the other hand, are provided with the same reference numerals. As in US Pat. No. 3,059,190, the tone diaphragm circuit consists of a two-stage amplifier in the feedback path.

The height control section 68 , the input of which is essentially point 41, is considered first. When the wiper 48 is located at the gap 45, the modulating part 68 is switched off and the feedback signal goes to earth via the resistors 42 and 57. The treble frequency response is then flat.

When the wiper 48 contacts the resistor 44, there is a frequency sensitive shunt path across the resistor 42 which increases the feedback and results in a height clipping. When the wiper 48 contacts the resistor 46 , the cathode resistor 57 is shunted by a frequency-sensitive path, which leads to a reduced feedback voltage at the cathode 55 and thus to an increase in height.

The input to the bass control section 67 is at the junction 17 between the capacitors 15 and 16. When the wiper touches the sections 20 and 18 with the resistance zero, the capacitors 15 and 16 are short-circuited and the signal goes directly to the resistor 13 in one direction and through the feedback resistor 42 in the other direction. A tone diaphragm effect results from the change in resistor section 19 which bypasses capacitor 15 in the feedback path of the amplifier and thus produces a variable treble boost, ie less feedback at low frequencies when a higher resistance is introduced into the circuit. On the other hand, when the contact 22 moves across the resistor 19, the capacitor 15 is shorted and a variable impedance is placed in series with the resistor 13, resulting in a variable height clipping. In the case of trimming and raising, there is only one type of modulation at the same time and in the middle position of contacts 21 and 22, that is, if both are on sections 18 and 20 of the potentiometer with zero resistance, both capacitors 15 and 16 are short-circuited and the frequency response is flat.

In Fig. 5, an exemplary embodiment of a bass level potentiometer is shown in which contacts 21 and 22 are attached for simultaneous rotation by the same amount by turning knob 70. The length of the resistor section 19 is at least as great as the lengths of the sections 18 and 20 with the resistance zero or almost zero, and when the button 70 is in the middle position, both contacts 21 and 22 lie on the sections 18 and 20, respectively. The button 70 can thus 120 ° clockwise or 120 ° counterclockwise from its center position can be moved during normal operation of the potentiometer.

In Fig. 5 a, which the F i g. 5 is analog, the contacts are arranged 21a and 22a for translational movement, and the resistive portions 18 a, 19 a and 20a are straight, whereby corresponding parts in the F i g. 5 and 5 a by inserting the index a in FIG. 5 a are different.

According to FIG. 7 resistors Ria and R1.1 are located between a terminal 107 with negative voltage and ground and act as a voltage divider which determines the bias voltage for the base electrode of a transistor T1. A transistor T2 is connected directly at its base electrode to the collector 101 of the transistor T1, so that the voltage at the collector 101 also determines the bias voltage of the transistor T2. Since this value does not need to be suitable, an RC Gleichvorspannungskreis B is provided at the emitter of the transistor 7 2, enabling the generation of an accurate overall bias.

A feedback signal for bass trimming and bass enhancement is provided derived from the collector 105 of the transistor T2 and the connection point 17 fed, which corresponds to the state in FIG. 4 corresponds. The point 41 of the bass control part 67 is connected to the emitter 102 of the transistor T1 via the resistor R2. Capacitor 16 and resistor 13 control the bass clipping by increasing it the attenuation at low frequencies. The capacitor 15 and the resistor R2 control bass boost by reducing feedback at low frequencies.

Resistor R8 alone produces DC feedback because it applies collector 105 of transistor Z'2 to AC ground formed by capacitor C5. The point 41 emits a direct current signal to the height control section 68, which contains the capacitor 43, the resistor 44, the gap 45, the resistor 46 and the capacitor 47 in series. The height control section 68 controls the height cutting and height increase essentially as in FIG. 4, which is why further description is unnecessary except to point out that with appropriate movement of the wiper 48, the resistor R3 and the capacitor C3 are provided in the treble boost, in which the feedback is reduced at high frequencies, while the resistor R2 and the Capacitor C4 are provided to control the height clipping, in which the feedback is increased at high frequencies. When the grinder 48 is located at the gap 45, the entire height control section 68 is switched off, and a feedback signal goes from the point 41 via the resistors R2 and R3 to the alternating current earth at the capacitor C5. The treble frequency response is then flat, and a firm feedback is given by the relative values of R2 and R3, which act as voltage dividers. If the grinder 48 is set to the resistor 44, the feedback is increased and the height cropping is controlled; if it is set to the resistor 46, the treble increase is controlled.

The arrangement of the F i g. 6 results in a complete passive treble and bass control and essentially contains the passive treble control circuit of FIG. 3 and the passive bass control circuit of FIG. 3 connected in parallel to it. 1 with the common input connection 40 and the output connection 49, the wiper 48 being used for the height control and the contacts 21 and 22, which can be moved independently of the wiper 48, for the bass control. All of the sliding contacts are electrically connected to one another and to the output terminal 49. Corresponding parts in the different figures are indicated by the same reference numerals and the operation corresponds to that previously described.

Claims (7)

Claims: 1. Differential tone diaphragm for two-sided continuous tone color adjustment with two capacitors interacting with each other via a common potentiometer, one component of which forms a treble-preferring branch running from a signal input to a signal output, characterized in that both capacitors (15, 16) each have one Pole lie together on the wiper (21, 22) forming the signal output and with the other pole in each case on one of the two fixed connections of the potentiometer, one of which forms the signal input, and that the wiper (21, 22) of the potentiometer is designed as a double wiper, the contacts of which are at a fixed distance and in a central position each touch one of the fixed connections, both of which are designed as contact rails (18, 20) of vanishing resistance and a length corresponding to the distance between the wiper contacts. 2. Differential tone diaphragm for two-sided continuous tone color adjustment with two capacitors cooperating with one another via a common potentiometer, one component of which forms a treble-preferring branch running from a signal input to a signal output, characterized in that both capacitors (43, 47) each have a pole, one of which forms the signal input, on the two fixed connections of the potentiometer (44, 46, 48) and in each case with the other pole on an associated shunt resistor (50 a, 50 b) that the ends of the capacitors (43, 47) facing away from Shunt resistors (50 a, 50 b) are located on the wiper (48) of the potentiometer forming the signal output and that the potentiometer has an interruption (45) approximately in the middle between the two fixed connections, which is larger than the contact width of the wiper (48) , whereby in each setting of the potentiometer one of the two capacitors is switched off et is. 3. Differential tone screen according to claim 1, characterized in that the potentiometer is designed as a ring potentiometer, in which the two contact rails (18, 207) and the intermediate resistor section (19) each occupy an arc of almost 120 ° and the two sliding contacts (21, 22) are attached to a common rotary knob (70) offset from one another by essentially 120 ° (FIG. 5). 4. Differential tone screen according to claim 1, characterized in that the potentiometer comprises two parallel branches, one of which consists of a contact bar (18 a) and a first part (19 a) of the resistor and the other of which consists of the one contact bar (18 a) opposite arranged second part (19 a) opposite arranged other contact bar (20 a) is that the double wiper can be moved parallel to the two potentiometer branches and the contacts (21 a, 22 a) each tap one of the branches (Fig. 5 a) . 5. Differential tone screen according to one of claims 1, 3 or 4, characterized by the downstream connection of an amplifier stage, the input of which is connected to the Double grinder is connected and its output (11) on the other fixed connection of the potentiometer is fed back (Fig. 2). 6. Combined differential tone screen according to claim 2 in connection with one of claims 1, 3 or 4, characterized in that both signal inputs are connected to a common input terminal (40) and all sliding contacts (21, 22, 48) are connected to a common output terminal (49) are (Fig. 6). 7. Combined differential tone screen according to claim 2 in connection with one of claims 1, 3 or 4, characterized by their inclusion in the Feedback from an amplifier (Figs. 4, 7). B. Circuit according to claim 7, characterized characterized in that the potentiometer of each of the two differential tone apertures is one has middle slider position, in which the respective differential tone diaphragm is switched off from the feedback path (Figs. 4, 7).