CS272790B2 - Stereophonic radio receivers' crosstaik attenuation automatic regulation connection - Google Patents

Description

The invention relates to a circuit for automatic regulation of crosstalk attenuation of stereo receivers, in particular during the reception of frequency modulated signals.

An important quality parameter of stereo radios is crosstalk attenuation between the two channels. A significant crosstalk between the two channels arises in the radio after frequency modulation of the multiplex signal.

The hitherto used function of shielding stereos signals in receivers enables the attenuation of crosstalk with fixed value. This attenuation is solved between the two channels through the introduction of a capacitor. This solution has the disadvantage that it does not allow any continuous regulation of crosstalk attenuation in dependence on the field strength.

Further, the solution used in the integrated circuit of the TCA 4500 / A stereodecoder is known. In this connection, the crosstalk attenuation can be controlled by the DC voltage connected to the external IC terminal. With this DC voltage, the amplitude of the 19 kHz pilot signal can be varied substantially within the integrated circuit. However, the use of this circuit is not recommended in receivers intended to meet higher requirements because they achieve desirable decoder parameters in terms of crosstalk attenuation and harmonic distortion.

A solution is known in which a voltage is proportional to the amplitude of the center frequency signal, and this voltage changes the pulse width of the 38 kHz signal of the stereodecoder. Thereby, crosstalk attenuation dependent on the strength of the received field can be achieved at the output of the decoder.

In another known solution, a signal downstream of the frequency modulator is formed by knowing the rectifier connected behind the high-pass DC voltage that controls the amplifier.

This amplifier regulates the level of the 38 kHz subcarrier signal applied to the stereo decoder, whereby crosstalk attenuation dependent on the received field strength can be achieved.

These two solutions are characterized by a crosstalk attenuation through 38 kHz subcarrier signal changes. However, in commonly used integrated stereodecoders, there is no access to the 38 kHz subcarrier signal, and thus the solutions described in both patents are only feasible if they are integrated into the decoder beforehand.

It is an object of the present invention to improve the reception characteristics of distant and low field strength display signals in stereo radios in the case of frequency modulated signals, while avoiding the disadvantages and limitations of the solutions used hitherto.

Disturbance-limited sensitivity to best-quality stereo signals is in the range of 20 to 25 £ iV, while disturbance-limited sensitivity to mono signals is in the range of 0.8 to 1 (UV). Both limitations of receiving monaural and stereo signals depending on the field strength and thus improve the signal-to-noise ratio, it seems advisable to look for a solution that is independent of the stereo connection and is thus applicable to any stereo radio and retrofit .

The invention is based on the discovery that when a phase shifting circuit is connected downstream of a frequency modulated signal whose characteristic is not linear in the region between 19 kHz and 38 kHz, a stereo decoder between the pilot signal and the suppressed signal appears in the circuit

Auxiliary phase shifting. The phase deviation created in this way is proportional to the crosstalk attenuation value of both channels and thus improves the signal-to-noise ratio, thereby improving the reception quality.

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Based on this finding, the object of the invention is achieved by a wiring for automatic regulation of crosstalk attenuation of stereo receivers, particularly in the case of receiving frequency modulated signals, by connecting a phase shifter unit to the frequency modulator and the stereo decoder to which a control signal generating unit is connected. adjusting the crosstalk attenuation rate, wherein a control signal, preferably proportional to the field strength, is converted to the input of the control signal generating unit.

In one exemplary embodiment of the invention, the phase shifter unit is formed by a bridged filter member T, the bottom of which is formed by a controlled resistor.

The controlled resistor may advantageously be formed by a field-controlled transistor whose operating point is continuously variable by means of a DC voltage whose value varies proportionally to the magnitude of the field force. The base value of the controlled resistors can be determined by the reference setting unit.

BRIEF DESCRIPTION OF THE DRAWINGS The invention will now be described in more detail with reference to the accompanying drawings, in which: FIG. 1 is a block diagram of the invention; the ratio of the noise signal and the crosstalk attenuation curve depending on the field strength that can be obtained by the obtained wiring.

FIG. 1 is a block diagram of the invention in which the phase shifter unit is formed from a bypass filter element T as follows: The controlled resistor 11 and the lower capacitor 12, connected in series, form the lower portion of the bypass filter element T. the terminal of the controlled resistors 11 is connected to ground potential, while the second terminal of the lower capacitor 12 is connected to a common connection point of the upper input capacitor 15 and the upper output capacitor 13, which are also connected in series. The second output of the upper input capacitor 15 is supplied with an input frequency modulated stereomultiplex MPX signal, while the second output of the upper output capacitor 13 is provided with a phase-shifted output stereomultiplex MPX signal going towards the stereo decoder stage. A series resistor 14 is connected in parallel to the series connection formed from the upper input capacitor 15 and the upper output capacitor 13. The basic resonance of the controlled resistors 11 is determined by a reference setting unit 2 which is connected to the controlled resistor 11. The controlled resistor 11 is further connected to the unit. 3 P ^ro generate a control signal which is controlled by the £ for generating the control signal. The output voltage Ug of the control signal generating unit 6 is proportional to the field strength of the signal being received. With the aid of the stereoclone switch 31, the control signal generating unit 3 can be activated or switched off, thereby providing automatic crosstalk attenuation,

The internal structure of the illustrated wiring units together with the connections made between them are shown in more detail in FIG. 2. The controlled resistor 11 is formed in the following manner. It is formed by a field-controlled transistor 114 to which a resistor 111 is connected to a collector, the other terminal of the resistors 111 being connected to a capacitor 112 and a resistor

113. The capacitor 112 is connected via a second terminal to a gate of a field-controlled transistor

114, while the second terminal of resistors 113 is coupled to the emitter of the field-controlled transistor 114. To this point of connection is further connected a series connection consisting of resistors

115 and 116. While a common capacitor 117 is connected to the common wiring point of the resistors 115 and 116, a second capacitor as well as a second terminal of the resistors 116 is connected to ground potential.

The reference setting unit 2 is realized by means of a series connection consisting of the upper resistors 21, the potentiometer 22 and the lower resistors 23. The second terminal of the upper resistors 21 is provided at the supply voltage U1, while the second terminal of the lower resistor 23 is connected to ground potential. The slider contact of the potentiometer 22 is coupled to a gate controlled transistor 114 via a series of coupled coupling resistors 24 and 118.

The control signal generating unit 3 is provided with a transistor 33. The collector of transistor 33 is connected to the supply voltage γγ, while the emitter of transistor 33 is connected via a resistor 34 to ground potential.

The emitter of transistor 33 is further coupled to a resistor 35, the other terminal of which is connected to a common wiring point of coupling resistors 24 and 118. A resistor 36 is connected to the emitter of transistor 33, the other terminal of which is connected to a common wiring point of diodes 37 and resistors 38 The second terminal of resistors 38 is connected to the supply voltage Uy and to the collector of transistor 33. The cathode of diode 37- is connected to resistor 39 ^{and the} common wiring point of resistors 115 and 116. The second terminal of resistors 39 is connected to a with Uy power supply terminal. The base of transistor 53 is coupled via a resistor 32 to the output of the control signal generating unit 6 providing a signal proportional to the field strength.

FIG. 3 is a continuous line representation of the signal-to-noise ratio versus field strength achievable without using the circuitry of the present invention. According to the measurement conditions laid down by the Hungarian standards, the point £ determines the value by interference with limited stereosensitivity. In comparison, the signal-to-noise characteristic of the present invention is shown by a dashed line from which it is clear that the sensitivity of the receiving apparatus will improve upon the introduction of the phase shifting unit.

The crosstalk attenuation characteristic as a function of the field strength is shown for the circuit according to the invention in FIG. 3 by the dotted line, where point B determines the basic crosstalk attenuation value which can be established with the reference adjustment unit 2.

The circuit according to the invention described above operates as follows:

Based on the transistor 33, the applied and proportional field signal determines the DC voltage that drives the field-controlled transistor 114, which operates in the circuit described as a controlled resistor. The basic value of the DC voltage is determined by the reference setting unit 2. The connection and disconnection of the control signal is effected by means of a switch 31 of the stereo clones. The controlled resistor formed using the field controlled transistor 114 acts as the lower portion of the bridged filter element T. The bridged filter element T is designed to realize a phase shift between the 19 kHz and 38 kHz signals proportional to the varying value of the controlled resistors 11. reference demodulator. The degree of phase shift produced in this way varies in proportion to the crosstalk attenuation in the stereo decoder of the mutually separated signals.

As the most important advantage of the circuitry formed according to the invention, it can be considered that, as shown in FIG. 3, a crosstalk attenuation between 45 dB and 6 dB is connected in a pluggable and detachable manner. A further advantage of the wiring according to the invention is that this is independent of the wiring of the stereo decoder and can thus be used for any receiver.

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The wiring according to the invention can advantageously be implemented in those receivers which are subject to higher demands, when receiving a field strength transmission to automatically control the signal-to-noise ratio.

Claims (5)

SUBJECT OF THE INVENTION A circuit for automatically controlling crosstalk attenuation of stereo radio receivers provided with a frequency modulator and a stereo decoder, in particular in the case of receiving frequency modulated signals, characterized in that a adjustable phase shifter unit (1) is connected between the frequency modulator and the stereo decoder; 1) the phase shifter is connected to a control signal generating unit (3) for adjusting the crosstalk attenuation rate, while the control signal generating unit (4) is connected to the input of the control signal generating unit (4), preferably proportional to the received field strength . Connection according to Claim 1, characterized in that the controllable phase shifter unit (1) is a bridged filter element of the type T. 3. The circuit according to claim 2, wherein the lower resistor of the bridged filter member T is formed by a field-controlled transistor (114) forming a controlled resistor (11). Wiring according to claim 3, characterized in that the wiring is provided with a reference setting unit (2) for setting the basic value of the controlled resistor (11), the output of which is connected to the input of the controlled resistor (11). Connection according to Claim 4, characterized in that the control signal generating unit (3) is provided with a stereoclone switch (31) for switching the automatic control on and off.