DE2703249B1 - Circuit arrangement for adjusting the volume of a car receiver as a function of the driving noise - Google Patents

Description

The invention relates to a circuit arrangement for adjusting the volume of a car receiver Dependence on the driving noise, with a microphone that picks up the noise and an electrical signal t> o emits that via an amplifier, a rectifier and a time lag of the rectified Voltage causing circuit is fed to an actuator for adjusting the gain, which is in Low frequency channel of the receiver. b5

By the magazine "Elektor", June 1974, page 29 is a circuit arrangement for regulating the volume of a car radio is known, in which the signal of a below The hood-mounted crystal microphone after amplification and rectification the amplification of a regulates amplification lying in the low frequency channel. Thus, the degree of reinforcement always follows immediately the sampled noise level. This is a major disadvantage, because if there are brief changes in the noise level, the volume of the receiver follows immediately, that is when driving, especially in city traffic, fluctuates constantly.

By the magazine "elektronikpraxis", No. 5, May 1976, page 104, a circuit for a noise-controlled volume control of a car radio is known, which is constructed in principle like the circuit described above, but a timing element in the way of the having rectified output signal of the microphone, which has a time constant of about 10 seconds The timing element consists essentially of a /? C combination, so that the readjustment essentially takes place according to an exponential function. This has the Disadvantage that with sudden large reductions in the noise level, a sudden change in volume of the Recipient. It has been shown that this is disadvantageous in practice and bothers the driver there is also the disadvantage that the readjustment speed due to the e-function of the ftC element decreases with increasing approach of the respective ACTUAL volume to the TARGET volume. That means, that because of the large time constants that are the same for both the upregulation and the downregulation is, the volume required in each case is only reached very late. That is also in practice of Disadvantage, because of the well-known masking effect, due to which the information reproduced by the loudspeaker is already with the background noise small differences in level is covered and thus impaired to a high degree, to the greatest possible extent Fast adjustment of the playback volume in relation to the noise level.

The invention is based on the object of a circuit arrangement for adjusting the volume of a car receiver depending on the driving noise, with the disadvantages of the known Circuits are avoided, so such a tracking of the playback volume as a function of the sampled background noise takes place so that the driver is not burdened with annoying quick adjustments in the event of rapid changes in the noise level, nevertheless however, it is ensured that as little or no playback information as possible is lost when the noise level changes.

The object on which the invention is based is achieved in that the time lag of the rectified voltage causing circuit has a substantially linear characteristic.

This linear characteristic of the time-dependent circuit means that the tracking speed is constant if the 1ST value of the reproduced Volume does not coincide with the target value, which is caused by the sampled noise level is given. Due to the linear characteristic, tracking takes place compared to the previously known corresponding to an exponential function, a slower tracking in the start area, but one in the end area increasingly faster, so that in a z. B. the end value is reached by the time constant given so that the target and actual value of the reproduced volume match completely. When taking as a basis an exponential function, this correspondence becomes practical

reached very late, theoretically never, especially since constant changes in the noise level are assumed is.

The practical design of the time-dependent circuit such that a substantially linear characterization '-> ristik of the type described is achieved, is possible in different to those skilled in part known per se. An expedient possibility is that the circuit causing the time lag of the rectified voltage has a capacitor which is connected to the rectifier via a member which supplies a constant charging or discharging current.

Due to the constant charging current, there is a linear increase in the charging voltage of the capacitor. 1 ■ "> In doing so, however, care must be taken that if the TARGET and ACTUAL values match, the reproduced volume the charging or discharging is ended.

An expedient further development of this embodiment is that the rectified voltage with a series connection of one Resistor and the capacitor is connected, the one transistor with the emitter-collector path in parallel is connected, its base with the connection point - '~> between the resistor and the capacitor connected is. The transistor circuit enables a constant current charge and at the same time a complete termination of the charge or discharge due to their known characteristics. jo

Is the link a large ohmic resistance and the driving voltage is large compared to the maximum Voltage at the capacitor to be charged, this is used to terminate the charging of the capacitor if the TARGET and ACTUAL values of the s> reproduced volume match with a switch in Connected in series, which depends on the difference between that depending on the noise level electrical signal and the low-frequency output voltage of the receiver is operated, so at If the TARGET and ACTUAL values match, this opens and charging or discharging ends.

A particularly useful development of the invention, which is inventive in itself, is that the time-dependent circuit has two different timing elements, one of which is rising and one of which is other is effective when the electrical signal, which is dependent on the noise level, drops. This means in the Practice that the playback volume of the receiver with a noise level increase with a different speed> u is readjusted than when the noise level drops. This eliminates unnecessary volume changes and thus unnecessary burdens on the listener, but at the same time a loss of playback information is avoided. This has been confirmed by experiments * >> carried out in practice.

A further development of the invention consists in the fact that the time lag of the rectified Voltage effecting circuit includes a bias voltage source such that a threshold is formed which «> causes a delayed use of the regulation. Such a delayed use of the regulation has the effect that a regular use occurs only when there is the ratio of driving noise and playback volume makes necessary. This point is just before reaching · >> the overlap effect is achieved.

Because of the quick readjustment to the respective, which is possible and favorable with the invention best value, unnecessary short readjustments due to short-term noise level changes are avoided, if these changes in the noise level are kept within narrow limits, which are determined by the level of the set threshold can be determined.

The invention will be explained in more detail with the aid of a circuit example shown in the drawing will.

The signal emitted by a microphone 1, which picks up the background noise in the car, is fed via a potentiometer P \ and a capacitor Q to a transistor 71, to which a transistor T _{2 is} voltage-coupled. The operating point of the amplifier formed in this way is stabilized via a resistor Λ4. The two transistors 7) and T ₂ are fed via resistors R \ and R ₂ , which lead to a feed line with the voltage Ub .

The amplified signal emitted by the transistor T ₂ is rectified via a clamping stage formed by a capacitor C ₃ and a diode D \ to a voltage Ud 1, which is always positive.

This signal Ud ι arrives via a diode D ₃ to a charging stage consisting of resistors Re and Ri and a transistor Ti for a capacitor Q>, the charging voltage of which is denoted by Ua.

R? and T ₃ represent a constant current source for the capacitor Q. If the voltage drop across Ri, caused by the charging current for the capacitor Q, exceeds the base-emitter threshold voltage Übe, the transistor T ₃ opens and leads over its emitter-collector- Discharge just enough current so that it does not exceed Übe. This means that the voltage at Ri is constant and thus the current through this resistor is also constant. Below this value, the transistor T _{3 is to be} regarded as not being present. This applies to currents

U ₁

Bl:

The resistor Re only has the task of providing a minimum input resistance for the charging level described.

A charging process starts when the voltage difference is positive, ie Ua <Ud 1. If this prerequisite is not met, the case may arise that Ua = Ud 1. In this case nothing happens, that is, Q is neither charged nor discharged.

However, if Ua> Up \, a discharge stage is effective, which is formed from a transistor T *, resistors R $, /? 8, /? 9, capacitors C5 and Q, and a diode D ₂ . Since the voltage at D \ is not a direct voltage, but the clamped alternating voltage, it is first fed through the diode D ₂ to the parallel circuit of C5 and Rs , where the voltage Ur 5 is then applied, which is a measure of the current noise level . This direct voltage Ur 5 is used for the comparison with the voltage Ua .

With a voltage divider R \ oR » between the supply voltage Ue and Ur *, the reference voltage for the current source (base voltage for T ₄ ) is generated, which consists of the transistor T ₄ and the resistor R <> . This results in a multiple dependency of the discharge current on Ur ■>. If Ur ^ <U _C 6, then a discharge current flows through the collector-emitter path from T ₄ and R9 to /? ₅ . The maximum current through Rv adjusts itself so that Übe is not exceeded

where the reference voltage at the base of 7} depends on the difference between the voltages Ub-Urs (via the voltage divider R »R \ o) and Urs is also influenced by the discharge current from Q, through R% .

The voltage Ucb is fed through the filter element R \\ Q to the base of a transistor 7s, which is galvanically coupled to a transistor 7i connected as an emitter follower. The two transistors Ts and T ₆ are PNP and NPN transistors in the form shown.

The signal at the emitter of T _b is the control voltage, which is fed to a subsequent actuator for setting the gain via a potentiometer Pi and a resistor Rh.

The actuator essentially has an integrated amplifier IC , the output 6 of which is connected to an inverting input 2 via a resistor Rn. The maximum gain is determined by the ratio of resistances Rn and R \ t . A series circuit of a resistor Ru and a capacitor C _{9 is} parallel to R \% . This results in a frequency-dependent gain as a function of the divider ratio of the negative feedback network. In addition, the gain is determined by the current in the control input 5. 2 ^r > If this is so large that the no-load gain exceeds the value given by the negative feedback network, this gain is fully effective. Starting from this point, the transmission behavior is frequency-dependent due to the combination of Ä17C9.

The inverting input 2 is connected to a reference voltage via a resistor R \ g , which is formed by a voltage divider R ^ R \ 5 . This reference voltage becomes v> via a resistor λ19 non-inverting input 3 is supplied to which the input signal is also supplied via a capacitor Cn and a resistor /? 2t. A capacitor Go is used for frequency compensation. The output of the amplifier IC is led out via a capacitor Cn . Capacitor Cn is used to suppress possible oscillations.

The current for the basic gain (minimum gain) is supplied via a resistor / fat. If the voltage at the emitter of T _b rises, an additional current, the size of which can be changed by adjusting the potentiometer Pi , will flow into the control input 5 via the potentiometer Pi, resistor Rh and a diode D4. Since a further dependency of the gain on the volume actually set is desired, namely here inversely proportional, ie the louder, the less regulation, a possibility is provided to reduce the current supplied for the gain regulation of T _b. It does this in the following way.

The output voltage at the loudspeaker sockets is fed through C \ _b or Ci 7 and clamped to diodes D ₇ and D ». The negative half-waves of the signal are fed to the capacitor Ch _{via D 5} , A, and the resistor Ru. The voltage of this filter element is connected to the control input of the amplifier IC via a resistor R ₂₃ and Da , the value of the resistor Rn being the size of the outflowing current determined. The difference between the control current and the outflowing current essentially determines the control threshold. The symmetrical input circuit for the voltage coming from the loudspeaker facilitates subsequent connection to an existing receiver.

1 sheet of drawings

Claims (6)

Patent claims: 1. Circuit arrangement for adjusting the volume of a car receiver as a function of the driving noise, with a microphone that picks up the noise and emits an electrical signal that is used for an amplifier, a rectifier and a circuit causing the rectified voltage to lag behind - ι ο member for setting the gain is supplied, which is in the low frequency channel of the receiver, characterized in that the circuit (Q, Rj, T ₃ ) causing the time lag of the rectified voltage has an essentially linear characteristic 2. Circuit arrangement according to claim 1, characterized in that the circuit causing the time lag of the rectified voltage has a capacitor (Ce) which is connected to the rectifier (D ₃ ) via a member (Rj, A3) which has a constant charge - or provides discharge current. 3. Circuit arrangement according to claim 2, characterized in that the rectified voltage 2 ^r > is connected to a series circuit of a resistor (R ₇ ) and the capacitor (Q), which connects a transistor (T ₃ ) in parallel with the emitter-collector path whose base is connected to the connection point between the resistor (Rj) m and the capacitor (Q). 4. Circuit arrangement according to claim 2, characterized in that the member is a series circuit of a large resistor (T ₄ , R ₉ ) and a switch (T ₄ ) which is dependent on the r> difference between the electrical noise level dependent Signal and the low-frequency output voltage of the receiver is actuated. 5. Circuit arrangement according to claim 1, characterized in that the time-dependent circuit has two different timing elements (Q, A ₇ , T ₃ ; Q, T ₄ , R ₉ ) , one of which (Q, Ri, T ₃ ) when Rise and the other (Q, Γ ₄ , R ₉ ) is effective when the electrical signal, which is dependent on the noise level, falls 6. Circuit arrangement according to claim 1, characterized in that the circuit causing the time lag of the rectified voltage contains a bias voltage source (Di, D ₃ , A) such that a threshold is formed which causes a delayed use of the control.