DE4134578A1 - Circuitry for superimposing sound effect waves on audio signals - has linear and nonlinear circuits with common input and having outputs added to give audio output - Google Patents

Abstract

The circuitry has a non-linear transmission element which superimposes waves onto an audio input signal (Ua) so that the circuit produces an audio output signal (Uc) including the superimposed signal. The circuitry has a non-linear signal transmission branch (N) including the non-linear element. It also has a linear signal transmission branch (L) and a signal adder (S). The two branches (N, L) share a common input (A). The common input (A) is the input terminal for the audio input signal (Ua). The outputs of each branch (N,L) are connected to the adder (S) which combines the signals from each branch. The audio output signal (Uc) can be picked up from the output (C) of the adder (S). USE/ADVANTAGE - Electric superimposition of waves for providing acoustic effects in audio signals. Superimposes waves without changing other signal parameters such as frequency, amplitude and noise reduction.

Description

The invention relates to a circuit arrangement for elec trical generation of audio signals sound / sound effects issuing harmonics, comprising a nonlinear overs Supporting element that harmonics an audio input signal adds, so that the circuit on the harmonics produces audio output signal.

It is well known that by a nonlinear Transmission element harmonics or harmonic frequencies be generated. Such use of a not linear transmission element, e.g. B. an electron tube, a semiconductor device or another nonlinear transformer leads to the fact that not only Harmonics are generated and / or changed, but that other parameters such. B. upper limit frequency, Level or signal-to-noise ratio changed and affected to be flowed.

In a circuit arrangement of the type mentioned, the one Sound effects device forms and one in the audio signal path Sound transmission system for recording or playing back Audio signals for the sole purpose of harmonic Generation is inserted, however, it is desirable that Parameters such as frequency response, level and noise voltage distance of the transmission system remain unaffected, so that standard values for such parameters, especially according to HiFi DIN standard (HiFi DIN 45 500) should be maintained.

The object of the present invention is therefore a Circuit arrangement for the electrical generation of upper waves for audio signals so that an audio Input signal harmonics can be added without  other parameters of the signals such as Fre in particular Frequency response, level and signal-to-noise ratio changed will.

According to the invention, this object is in connection with the Features of the circuit arrangement of the aforementioned Art solved in that the circuit arrangement a the non-linear transfer element does not have linear signal transmission branch and a linear Signal transmission branch with common input for the comprises two branches and a signal adder circuit, where the input common to the branches of the input connection for the audio input signal and the off gears of the two transmission branches with the adder circuit are connected to that of the two transmissions signals emitted in the adder scarf device, at the output of which the audio off output signal can be removed.

With the circuit arrangement according to the invention Recording or transmission of audio signals in the Signal path of a sound transmission system is switched, is achieved that the audio signal has particular to achieve rer sound / tone effects harmonics without adverse change or influencing other audio signal para meters can be added. So in the listening area (audio range, approx. 20 to 20,000 Hz) does not affect the sound quality of the audio signal sound and reliably reproducible sound / tone effects achievable. With the harmonic Generating circuit produced sound / tone effects are characterized by increased spatial sound, sound presence and clarity of sound. The Signal of each partial vibration without changing the rest Tone / sound parameters an additional, a compression of the spectrum of harmonics causing the sound spectrum added. A major advantage of the invention is that the harmonics are unaffected  other audio signal parameters regarding type and Strength through the wiring at the input and / or output of the non-linear transmission branch are adjustable. It has been found that in particular the tone quality of CD (compact disc) systems at with the inventor according to the circuit generated sound / sound effects preserved.

A particularly advantageous embodiment of the invention is that in the nonlinear transmission branch at least one electrical component such as one Resistance potentiometer or a control circuit ge is switched to the signal input level and / or the Signal output level of non-linear transmission to change branches and / or to fix them. By the setting or changing the type and strength of the Harmonics are the other parameters of the sound / Audio signal having sound effect is not affected.

According to a special embodiment of the invention the two transmission branches in the opposite coupling branch of an amplifier, in particular an Opera tion amplifier, inserted, resulting in high input resistance stood and low output resistance of the overall scarf tung leads.

With a further embodiment according to the invention achieved that the nonlinear transfer element in Audio range not only harmonics, but also linear ones Distortion generated. This leads to a frequency selec tive generation of harmonics, but the Fre quenzgang of the entire circuit arrangement in the Audiobe remains richly linear, so in particular a linear Ensure frequency response according to DIN standard (HiFi-DIN 45 500) remains constant. For this purpose, a diode circuit of the non-linear transmission element, a capacitor connected in parallel and / or a capacitor upstream tet.

Still other embodiments of the invention are based Sub-claims emerge, and further advantages and Aus leadership forms or possibilities of the invention below with reference to that in the schematic drawing illustrated embodiments described. It demonstrate

Fig. 1 shows a circuit arrangement according to the invention,

Fig. 2 shows the circuit of an amplifier to complete the circuit of Fig. 1,

FIGS. 3 and 4 non-linear transfer elements for fiction, modern circuit arrangements,

Fig. 5 is a characteristic curve of a diode comprising a non-linear transmission element for an inventive circuit arrangement and

FIGS. 6 and 7 are graphs of voltage harmonic distortion factors as a function of the input voltage-inventive circuit arrangements.

According to Fig. 1 comprises a Schaltungsan invention proper to the electronic generation of harmonics for generating a sound / sound effect to an audio An output signal voltage Vout are added to a non-linear signal transmission path N, and a linear signal transfer path L. This circuit with an input terminal A and an output terminal C is inserted as an electronic harmonic generator in the signal path of an audio transmission system, not shown, in particular a CD (compact disc) sound transmission system for recording or reproducing audio signals.

The circuit branch N for the nonlinear signal transmission supply and the circuit branch L for the linear signal  Transmission are connected in parallel so that the on a common circuit input for the two branches form N, L, so that the input span voltage Ua both at the input of the linear branch L as is also present at the input of the non-linear branch N; the Outputs of the two branches N, L are according to the invention an adder S connected.

The adder S comprises three resistors R4, R5 and R6, which each have a connection with the output terminal C are connected. Resistor R6 is grounded switches; at it is the audio output signal voltage Tapped uc.

The linear transmission branch L consists in the execution example from a simple wire or line bridge, which the input terminal A with the other connection of the Add resistor R4 connects.

The non-linear branch N comprises a non-linear signal electronic circuit that causes transmission a T-circuit of resistors R1, R2 and R3 and one parallel to the resistor R2 connected to ground lel switched diode D exists. One connection each of resistors R1, R2 and R3 as well as the anode of the diode are connected to node B. The other Resistor R1 is connected to input terminal A connected while the other connection of the contr stood R3 with the other connection of the adding counter R5 is connected.

The resistor R1 forms a non-linear with the diode D. res circuit transmission element that contains the harmonics generated. As is known, the harmonics (overtones) an integer multiple of a fundamental frequency or of a keynote. The measure of overtones or distortions is the so-called distortion factor given in percent. in the 0 dB / V level range for music / speech creates that  existing resistor R1 and diode D usually a too high distortion factor. Therefore, the one consisting of resistors R1 and R2 Voltage divider provided with which the input voltage for the nonlinear branch N is set so that in this way the input sensitivity of the diode limiter (transmission link) is selected.

Fig. 5, the input / output voltage characteristic of Ub = F (Ua) shows the Diodenbegrenzers. In particular, the resistors R1 and / or R2 are designed to adjust the input sensitivity of the diode limiter as potentiometer resistors.

According to an embodiment of the invention shown in FIG. 2, the circuit shown in FIG. 1 is supplemented with an operational amplifier V. The input terminal A of the circuit of FIG. 1 is connected to the amplifier V to the output terminal E, while the output terminal C of the sound processing according to Fig. 1 to the inverting input terminal of the amplifier F V is connected. In this inventive circuit arrangement according to the invention, a non-inverting input terminal G of the amplifier V forms the input terminal for the input signal voltage Ug. The output signal voltage Ue is tapped at the output terminal E of the amplifier V. Thus, the circuit 1 is shown in Fig. In the negative feedback path of the amplifier V geschal tet. It has been achieved that the input resistance at input terminal G is higher than the input resistance at terminal A, while the output resistance at output terminal E is lower than the resistance at output terminal C. In relation to the output voltage Uc, the output voltage Ue is increased by a few decibels. In contrast to the circuit according to FIG. 1, the phase position of the harmonics with respect to the fundamental oscillation is rotated by 180 ° after supplementation with the circuit according to FIG. 2. However, human hearing is sensitive to such a phase shift within audio vibrations.

If desired, the harmonics can be generated depending on certain frequency ranges of the audio input signal Ua or Ug. As can be seen from FIG. 3, the diode D is connected to a capacitor C1 in parallel, so that due to this low-pass design, harmonics are mainly generated at lower frequencies. Instead, as shown in FIG. 4, a capacitor C2 is connected in series with the diode D, so that this high-pass circuit mainly produces harmonics at high frequencies.

In Fig. 6 in a logarithmic representation of the harmonic distortion factor K (Ub) /% is the output voltage Ub of the Diodenbe shown Grenzer a function of the input voltage Ua / V for circuit arrangements according to FIGS. 1 and 2, and indeed for different resistance values R2.

Without the resistor R2 and with an input voltage of z. B. Ua = 1V, the Ub voltage distortion factor in the exemplary embodiment is K (Ub) = 10%. As already explained above, the input sensitivity of the diode limiter decreases due to the resistor R2 connected in parallel with the diode D. As can be seen from FIG. 6, the harmonic distortion curves shift to the right in the illustration when the resistance R2 is reduced.

Fig. 7 shows in a logarithmic representation the distortion factor of the output voltage Uc as a function of the input voltage Ua, for different values of the resistance R3.

With the resistor R3 and the input impedance of the Addie rers S, which consists of the resistors R4, R5 and R6, a voltage divider is formed, whereby the voltage Ub of the diode limiter of the output voltage of the linear transmission branch L is partially mixed. From Fig. 7 it can be seen that the harmonic distortion K (Uc) decreases with the increase in the resistance R3, so that the harmonic distortion curves move ver down in the illustration. It can be seen that in this way on the one hand the level reduction through the entire circuit arrangement remains low and that on the other hand harmonics or distortion factors can be set without changing other parameters of the output signals.

Claims (11)

1. Circuit arrangement for the electrical generation of audio signals sound / sound effects giving upper waves, comprising a non-linear transmission element, which adds an audio input signal (Ua) upper waves, so that the circuit has an upper audio output signal (Uc) brings, characterized in that the circuit arrangement has the non-linear transmission element having non-linear signal transmission branch (N) and a linear signal transmission branch (L) with a common input (A) for the two branches (N, L) and a signal Includes adder circuit (S), the two two (N, L) common input (A) being the input terminal for the audio input signal (Ua) and the outputs of the two transmission branches (N, L) with the adder circuit (S) are connected to the signals emitted by the two transmission branches (N, L) in the adder circuit (S), at the output (C) of which the audio off output signal (Uc) can be removed. 2. Circuit arrangement according to claim 1, characterized characterized that the signal on output level and / or the signal output level of the non-linear transmission branch (N) adjustable and / or are changeable. 3. Circuit arrangement according to claim 1 or 2, there characterized in that the linear transmission branch (L) signals in one Frequency range from 40 to 12 500 Hz transmits. 4. Circuit arrangement according to one of claims 1 to 3, characterized in that the linear transmission branch (L) is formed by a line bridge which leads the input signal (Ua) directly to an input of the adder circuit (S) ( Fig. 1). 5. Circuit arrangement according to one of claims 1 to 4, characterized in that in the non-linear transmission branch (N) for level adjustment to the transmission element this is a voltage divider (R1, R2) acted upon with the input signal (Ua) upstream ( Fig. 1) . 6. Circuit arrangement according to one of claims 1 to 5, characterized in that for level adjustment to the output signal of the linear transmission branch (L) between the output of the non-linear transmission element and the adder circuit (S), a resistor (R3) is connected, which in connection forms a voltage divider with an input resistor of the adder circuit (S) ( FIG. 1). 7. Circuit arrangement according to one of claims 1 to 6, characterized, that the adder circuit (S) two the output signal nale of the two transmission branches (N, L) additive Resistors (R4, R5) and a resistor (R6) points at which the added signals as output span voltage (Uc) at the adder circuit output (C) (Fig. 1). 8. Circuit arrangement according to one of claims 1 to 7, characterized in that the circuit arrangement comprises an amplifier (V) which is connected such that the common input terminal (A) of the two transmission branches (N, L) with an amplifier Output terminal (E) and the adder circuit output (C) are connected to an inverting (negative) amplifier input terminal (F), with a non-inverting (positive) amplifier input terminal (G) connecting to an audio input signal (Ug) of the total circuit forms, while the audio output signal (Ue) of the overall circuit at the amplifier output terminal (E) occurs ( Fig. 2). 9. Circuit arrangement according to one of claims 1 to 8, characterized in that the non-linear transmission element comprises at least one diode (D) for signal limitation ( Fig. 1). 10. Circuit arrangement according to claim 9, characterized in that the diode (D) for cutting high frequencies, a capacitor (C1) is connected in parallel ( Fig. 3). 11. Circuit arrangement according to claim 9 or 10, there characterized in that the Diode (D) for cutting low frequencies in Series with a capacitor (C2) is connected (Fig. 4).