DE4242548A1 - Automatic audio signal tuner for multiplex transmission systems - detects digital audio signal in dependence on PCM clock signal derived from multiplex type discrimination circuit - Google Patents

Abstract

Video signal from the IF detector (30) passes through an audio blocking circuit (40) to later video stages. An FM audio detector circuit (50) mixes (53) a 5.5 or 6 MHz FM carrier with a local oscillator signal (54). The type of transmission is distinguished by a decision circuit (60), switching (83) PAL FM blocking circuit outputs between band-pass filters (84,85) preceding a QPSK detector (86), and driving a clock generator (70) for a PCM detector (87). USE/ADVANTAGE - Video cassette recorders or TV receivers, device performs automatic demodulation with recognition of type of multiplex transmission by FM carrier detection.

Description

The present invention relates generally to a circuit for automatic tuning of audio signals from multiplex transmission systems, more precisely, a circuit to the au automatic tuning of audio signals from multiplex transmissions systems in a video cassette recorder, hereinafter referred to as VCR referred to, or a television receiver, hereinafter referred to as TV referred to, which is capable of multiplex transmission receive signals, with a digital audio signal of the Multiplex transmission signals automatically based on the Type of multiplex transmission system to which the digital Heard audio signal, can be tuned.

A near-instantaneous companding audio multiplex (NICAM) system is known as a multiplex transmission system. A multiplex transmission signal from the Nicam system contains an analog frequency modulation (FM) audio signal and a digital audio signal as a sub audio signal. FIGS. 1A and 1B show the baseband spectra of the NICAM multiplex transmission signal according to the PAL-B / D and PAL-I systems.

Referring to FIG. 1A is a color carrier CC within the rich loading of 5 MHz on the basis of an image carrier PC from hands. The FM audio signal is in a 5.5 MHz carrier band, while a pulse code modulation (PCM) audio signal as the digital audio signal is in a 5.85 MHz carrier band.

According to FIG. 1B, the color carrier CC in the range of 5 MHz on the basis of an image carrier PC available. The FM audio signal is in a 6.0 MHz carrier band, while the PCM audio signal as the digital audio signal is in a 6.552 MHz carrier band.

As explained above in connection with FIGS . 1A and 1B, in the Nicam transmission signal the FM audio signal and the PCM audio signal have different carriers according to the PAL-B / G and PAL-I system. This leads to the following problem. If a television receiver capable of receiving multiplex transmission signals is to receive the multiplex transmission signals of the two types of multiplex transmission systems and to receive desired audio components from the received transmission signals, the digital audio output signal may result from a mutual influence of the transmission signals and a discordance between the time constants originating from the different systems cannot be obtained. For this reason, the received transmission signals must be processed separately based on the types of the multiplex transmission systems in order to recover the FM audio signals and the PCM audio signals from the received transmission signals.

In other words, in the conventional circuit for Tu NEN of the audio signals of the multiplex transmission systems in a receiving system for multiplex transmission signals, such as  for example, a television set, after processing device of the video signals of the received multiplex transmission tion signals detected audio intermediate frequency signals ge filters so that the 5.5 MHz carrier in the PAL B / D system and the 6.0 MHz carrier in the PAL-1 system thereof based on the Types of multiplex transmission systems can be detected. The detected carriers are filtered so that a only carrier is detected, which from their mixture with a local oscillation frequency results. Hence who which the FM audio signals for demodulation from the single Carrier detected.

For the recovery of the PCM audio signal as digital Audio signals are two sets of digital audio signals Processing circuits required the audio intermediate filter frequency signals in order to detect carriers from them, which is based on the types of multiplex transmission systems, and to get the PCM audio signals from the detected carriers depending on PCM clock signals, which are based on the different types of multiplex Differentiate transmission systems from one another to detect ren. A way of detecting after video signal processing th audio intermediate frequency signals to one of the two digi tal audio signal processing circuits is by a Control signal selected depending on the choice of a user based on the types of multiplex over transmission systems is generated. A demodulation process of the PCM audio signals are processed by the digital audio signal processing circuit on the selected path based on the selected system type.

The conventional circuit described above has ever but the disadvantage that a selection of the user on the Based on the types of multiplex transmission systems required  is what leads to discomfort. Furthermore who which requires two hardware systems, increasing complexity the circuit rises.

The present invention has been made in view of the above designed problem described. The invention is the Task based on a circuit for automatic tuning of To create audio signals from multiplex transmission systems which is able to produce a digital audio signal Multiplex transmission signals based on the type of Multiplex transmission system to which the digital audio signal to automatically demodulate by using the Type of multiplex transmission system by detection of one FM carrier of the multiplex transmission signal differs.

The above object is achieved by the invention a circuit for automatic tuning of audio signals ei nes multiplex transmission system solved the following Components include: FM audio detection devices for de Detect an FM audio signal of a received transmission supply signal of the multiplex transmission system; Difference equipment related to the type of transmission to determine the type of multiplex transmission system the Transmission signals based on the FM audio code tection devices detected FM audio signals to un differentiate and a tax according to the determined result generate first signal; PCM clock generation devices for Generate PCM clock signals from different Oszilla tion frequencies depending on the control signal of the sub separation devices for the type of transmission system; Digital audio demodulation devices for detecting a digital audio signal of the transmission signal depending the control signal of the differentiators for the type of transmission system that has a PCM detection  of the detected digital audio signal depending on PCM clock signal from the PCM clock generators perform to demodulate a digital audio signal; and audio output devices for reshaping the demodulated digital audio signals from digital audio demodulations devices into an analog signal and for outputting the Ana log signals in the form of analog audio signals left and right channels.

Further developments of the invention result from the subclaims forth.

The inventions will now be described with reference to an embodiment game in connection with the drawing in detail tert. Show it:

Figs. 1A and 1B, the baseband spectra of a NICAM men multiplex transmission signal according to the PAL B / G and PAL-1-Syste; and

Fig. 2 shows a circuit for automatic tuning of Au diosignale of multiplex transmission systems according to the prior invention.

Fig. 2 shows a circuit for automatically tuning audio signals from multiplex transmission systems according to the present invention. As shown in this figure, the circuit constructed according to the invention has a tuner 20 for tuning a broadcast transmission signal received via an antenna 10 , an intermediate frequency detector 30 for detecting a video intermediate frequency signal and an audio intermediate frequency signal from the transmission signal tuned by the tuner 20 , an audio blocking circuit 40 for removing the audio intermediate frequency signal from an output signal of the intermediate frequency detector 30 to pass only the video intermediate frequency signal, an FM audio detection circuit 50 for filtering the audio intermediate frequency signal from the intermediate frequency detector 30 in order to pass FM audio carriers on two paths which are based on the PAL-B / G- and PAL-1 systems distinguish from each other, to unify the transmitted carrier as a single carrier and to detect an FM audio signal from the single carrier, a discriminating circuit 60 with respect to the type of the transmission system stems for detecting the presence of the carrier on a specific route of the two routes in the FM audio detection circuit 50 and for emitting a control signal in dependence on the detected result, a PCM clock generation circuit 70 for generating PCM clock signals of different oscillation frequencies in dependency from the control signal from the discriminating circuit 60 with respect to the type of the transmission system, a digital audio demodulation circuit 80 for removing the FM audio carrier from the audio intermediate frequency signal from the intermediate frequency detector 30 , for filtering the FM audio carrier removed from the signal to a digital audio carrier on the Ba to pass through the determined type of the transmission system depending on the control signal from the discriminating circuit 60 with respect to the transmission system and PCM detection from the digital audio carrier depending on the PCM clock signal from the PCM clock generation circuit 70 to demodulate a digital audio signal, and an audio output circuit 90 for converting the demodulated digital audio signal from the digital audio demodulation circuit 80 into an analog signal and for outputting the analog signal in the form of analog audio signals from left and right channels.

The FM audio detection circuit 50 comprises a first and a second bandpass 51 and 52 for detecting the FM carrier of 5.5 MHz and 6.0 MHz from the output signal from the intermediate frequency detector 30 on the two links, a mixer 53 for mixing an output signal from the first bandpass 51 or from the second bandpass 52 with an output signal from a local oscillator 54 in order to combine the output signals of the first and second bandpasses 51 and 52 as the only carrier with a common frequency band and to emit the FM audio signal of the single carrier, a third band pass 55 for filtering an output signal from the mixer 53 to pass the single carrier, and an FM audio detector 56 for detecting the FM audio signal from an output signal from the third band pass 55 .

The discriminating circuit 60 with respect to the type of the transmission system is designed to detect the type of the transmission system depending on the output signal from the first bandpass 51 or the second bandpass 52 in the FM audio detection circuit 50 and the control signal depending on the result obtained outputs to the PCM clock generation circuit 70 and the digital audio demodulation circuit 80 .

In the discriminating circuit 60 with respect to the type of the transmission system, the carrier is turned on on the specific route of the two routes of the FM audio detection circuit 50 through a connection point of resistors R1 and R2 which are connected in series between a voltage source and an earth terminal the base of a tran transistor TR1 leads. The collector of the transistor TR1 is jointly connected to one side of a capacitor C1, the other side of which is connected to the terminal of the voltage source, a coil L1 and a cathode of a diode D1, the anode of which is connected to the earth terminal. The common connection point is connected via a capacitor C2 to one side of a resistor R4, the other side of which is connected to the ground terminal and the base of a transistor TR2, whose collector is connected to the terminal of the voltage source and whose emitter is connected via a resistor R5 to a ground terminal connected. The control signal is thus emitted by the emitter of the transistor TR2.

The PCM clock generating circuit 70 has an oscillator 71 for oscillating a desired frequency, a frequency control unit 72 for controlling the frequency of the oscillator 71 depending on the control signal of the discrimination circuit 60 with respect to the type of the transmission system, and a PCM clock generator 73 for Divide the oscillation frequency of the oscillator 71 by a predetermined number to generate the PCM clock signal. The frequency control unit 72 is provided with a transistor TR3, whose base serves for inputting the control signal of the distinction circuit 60 in relation to the type of transmission system, the collector of which is connected via a resistor R6 to the terminal of the voltage source and the emitter of which is connected to the ground terminal is. In the frequency control unit 72 , a frequency control signal is output from the collector of the transistor TR3 via a variable capacitor C3.

The digital audio demodulation circuit 80 includes PAL-B / G and PAL-I-FM blocking circuits 81 and 82 for successively removing the corresponding FM audio carrier signals from the output signal of the intermediate frequency detector 30 , a switch 83 for selecting a route of an output signal from the FM blocking circuit 82 depending on the control signal from the discriminating circuit 60 with respect to the type of the transmission system, PAL-B / G and PAL-I bandpass filters 84 and 85 for filtering the output signal from the FM blocking circuit 82 on the by the Switch 83 selected route to pass the corresponding 5.85 MHz and 6.552 MHz digital audio carriers, a quadrature phase shift keying (QPSK) detector 86 for performing QPSK detection of an output signal from the bandpass filter 84 or from the bandpass filter 85 for demodulating a quadrature-modulated phase of the digital audio signal, a PCM detector 87 for carrying out the PC M detection of an output signal from the QPSK detector 86 in response to the PCM clock signal from the PCM clock generating circuit 70 for demodulating the digital output signal and an SRAM 88 for storing the PCM detection data from the PCM detector 87 in the PCM detection operation of the PCM detector 87 .

The audio output circuit 90 has a D / A converter 91 for converting the demodulated digital audio signal from the digital audio demodulation circuit 80 into the analog signal and a first and second low-pass filter 92 and 93 for filtering an output signal from the D / A converter 91 for outputting the analog Audio signals from a left and right channel.

The mode of operation of the invention described above trained circuit will now he in detail purifies.

When the transmission signal of the PAL-B / G or PAL-I system is received via the antenna 10 and then via the tuner 20, the intermediate frequency detector 30 detects the video intermediate frequency signal and the audio intermediate frequency signal from the received transmission signal. The output signal of the intermediate frequency detector 30 is applied to the audio blocking circuit 40 , which removes the audio intermediate frequency signal from the output signal of the intermediate frequency detector 30 and only passes on the video intermediate frequency signal.

The audio intermediate frequency signal of the intermediate frequency detector 30 is filtered by the first band pass 51 , which puts the 5.5 MHz carrier in the PAL-B / G system, or by the second band pass 52 , which puts the 6.0 MHz carrier in the PAL I system conducts. The output signal from the first or second bandpass 51 or 52 is applied to the mixer 53 . In the mixer 53 , the PAL-B / G carrier of 5.5 MHz from the first bandpass 51 or the PAL-I carrier of 6.0 MHz from the second bandpass filter 52 in an arithmetically progressive manner, such as addition, subtraction, multiplication etc., mixed with the oscillate the frequency signal (5.5 MHz + 6.0 MHz or 6.0 MHz-5.5 MHz) of the local oscillator 54 , so that the PAL-B / G carrier of 5.5 MHz and the 6.0 MHz PAL-I carrier are combined as the only carrier. The mixer 53 mixes the 5.5 MHz carrier and the 6.0 MHz carrier with the oscillating frequency signal of the local oscillator 54 in the corresponding cases, and thus outputs the FM audio signal which is the resulting single carrier of the common frequency bandes, regardless of the type of transmission system. Since the only carrier of the common frequency band is present in the output signal of the mixer 53 , regardless of the type of transmission system, a passing band of the bandpass filter 55 can optionally be set for filtering the output signal from the mixer 53 . For example, the pass band of the bandpass 55 can be 5.5 MHz or 6.0 MHz.

For example, in the case of the PAL-B / G transmission system, the mixer 53 mixes the 5.5 MHz carrier from the first bandpass 51 with the oscillating frequency of 500 KRz of the local oscillator 54 , so that the only carrier is therefore 6.0 MHz is delivered. Also in the PAL-I transmission system, the mixer directly outputs the 6.0 MHz carrier from the second bandpass filter 52 to output the 6.0 MHz single carrier. In other words, in the mixer 53 , the 5.5 MHz carrier and the 6.0 MHz carrier are emitted in the corresponding cases due to the mixing with the oscillating frequency of 500 kHz as the only carrier of 6.0 MHz. Then the bandpass filter 55 filters the output signal from the mixer 53 to pass the single carrier of 6.0 MHz regardless of the type of transmission system. As a result, the FM audio detector 56 detects the FM audio signal from the output signal or the single carrier of the band pass 55 .

On the other hand, the discriminating circuit 60 generates the control signal in response to the detection of the output signal of the PAL B / G band pass filter 51 in the FM audio detection circuit 50 with respect to the type of the transmission system. When the transmission signal of the PAL-B / G transmission system is received, the 5.5 MHz carrier is output from the bandpass 51 in the FM audio detection circuit 50 , whereby the discrimination circuit 60 with respect to the type of the transmission system is the control signal of the high level delivers. In other words, in the discriminating circuit 60 with respect to the type of the transmission system, the 5.5 MHz carrier from the bandpass 51 of the FM audio detection circuit 50 is applied to the base of the transistor TR1, thereby turning on the transistor TR1. Switching on the transistor TR1 leads to a resonance activity of the capacitor C1 and the coil L1. As a result, the collector voltage of the transistor TR1 becomes maximum. The maximum collector voltage of the transistor TR1 is applied to the base of the transistor TR2 via the capacitor C2, whereby the transistor TR2 is switched on. As a result, the high level control signal is output from the emitter of the transistor TR2.

In contrast, the transmission signal of the PAL-I transmission system is given no signal from the bandpass filter 51, the FM audio detecting circuit 50 upon reception, so that the write discriminating circuit 60 with respect to the type of Übertra supply system, the control signal of low level.

The control signal from the discriminating circuit 60 in train be on the type of the transmission system, the frequency control unit applied to the base of TR3 Tran sistors 72 in the PCM-stroke generating circuit 70th Depending on the control signal of the discriminating circuit 60 with respect to the type of the transmission system, the transistor TR3 of the frequency control unit 72 controls the oscillating frequency of the oscillator 71 in such a way that the PCM clock generator 73 can generate the PCM clock signal which the digital audio carrier ( 5.85 MHz) of the PAL-B / G transmission system or the digital audio carrier (6.552 MHz) of the PAL-I transmission system. The control signal from the discriminating circuit 60 with respect to the type of the transmission system is also applied as a selection signal to the switch 83 of the digital audio demodulation circuit 80 . Depending on the control signal from the discriminating circuit 60 in relation to the type of the transmission system, the switch 83 selects the route of the FM audio carrier removed from the signal such that the digital audio carrier (5.85 MHz) of the PAL-B / G transmission system or the digital audio carrier (6.552 MHz) of the PAL-I transmission system can be detected by this signal.

In the PCM clock generating circuit 70 , the transistor TR3 in the frequency control unit 72 is turned on by the control signal of the discriminating circuit 60 with respect to the type of the transmission system, thereby grounding one side of the capacitor C3 on the collector of the transistor TR3. As a result, the capacitance of the capacitor C3 is additionally applied to the oscillator 71 . In the oscillator 71 , the oscillating frequencies are different due to the presence of the capacitance of the capacitor C3. For this reason, the oscillating frequencies of the oscillator 71 are different depending on the types of transmission systems. The PCM clock generator 73 divides the oscillating frequency from the oscillator 71 by a predetermined number to generate the PCM clock signal for PCM detection, which is applied to the PCM detector 87 in the digital audio demodulation circuit 80 .

In the digital audio demodulation circuit 80 , the audio intermediate frequency signal from the intermediate frequency detector 30 is applied via a resistor R8 to the PAL-B / G and PAL-I-FM blocking circuits 81 and 82 , which successively remove the corresponding FM audio carriers from the received signal and that Apply digital intermediate audio signal to switch 83 . The switch 83 switches the FM audio carrier removed from the signal from the FM blocking circuit 82 to the PAL-B / G bandpass 84 or the PAL-I bandpass 85 depending on the control signal from the discrimination circuit 60 with respect to the type of Transmission system When, for example, the transmission signal of the PAL-B / G transmission system is received, the high level control signal from the discriminating circuit 60 relating to the type of the transmission system is applied to the switch 83 , whereby the switch 83 outputs the output from the FM blocking circuit 82 switches to bandpass 84 , which passes through the digital audio carrier (5.85 MHz) of the PAL-BIG transmission system. In contrast, when the transmission signal of the PAL-I transmission system is received, the control signal of the low level from the discrimination circuit 60 is applied to the switch 83 with respect to the type of the transmission system, whereby the switch 83 applies the output signal from the FM blocking circuit 82 switches the bandpass filter that passes the digital audio carrier (6.552 MHz) of the PAL-I transmission system.

The QPSK detector 86 performs the QPSK detection of the output signal from the PAL-B / G bandpass 84 or from the PAL-I bandpass 85 to demodulate the digital audio signal of the phase quadrature modulated during transmission and the PCM- Detector 87 performs the PCM detection of the output signal from the QPSK detector 86 as a function of the PCM clock signal from the PCM clock generation circuit 70 in order to demodulate the original digital audio signal. At this time, the PCM clock generating circuit 70 oscillates depending on the control signal from the discriminating circuit 60 with respect to the type of the transmission system that the PAL-B / G digital audio carrier (5.85 MHz) or the PAL-I digital audio carrier (6.552 MHz) corresponding frequency and divides the oscillating frequency by a predetermined number to generate the PCM clock signal which is applied to the PCM detector 87 as a reference clock signal. As a result, the PCM detector 87 regains the original digital audio signal in synchronization with the applied PCM clock signal based on the type of the transmission system, the PCM detection data being stored in the SRAM 88 .

The digital audio signal demodulated in this way based on the type of transmission system is applied to the audio output circuit 90 for the corresponding analog process. In the audio output circuit 90 , the digital / analog converter 91 converts the digital audio signal into the analog signal and outputs the analog signal to the first and second low-pass filters 92 and 93 , which filter the received analog signal and the analog audio signals for the left and right channels connect to the left and right output terminals L and R.

According to the invention, therefore, the discriminating circuit 60 differentiates with respect to the type of the transmission system, whether the type of the transmission system of the received transmission signals is a PAL-B / G or PAL-I system, and outputs the control signal depending on the result found . Depending on the control signal from the discriminating circuit 60 related to the type of the transmission system, the PCM clock generating circuit 70 generates the PCM clock signals of different oscillating frequencies, and the digital audio demodulating circuit 80 performs band filtering of the corresponding transmission system to thereby perform the digital one Demodulate audio signal. In other words, the type of transmission system can be determined automatically without selecting or switching the user, so that in this way the digital audio signal can be automatically demodulated on the basis of the corresponding transmission system.

As explained above, in differs according to the invention Way the discrimination circuit in relation to the type of Transmission system in case of receiving the transmission signals from the PAL-B / G system or from the PAL-I system in the NICAM System that is the digital sound system delt, the system type of the received transmission signal, and the digital audio signal is based on the ent  speaking transmission system depending on the fixge result demodulated. Therefore, the digital Au diosignal of the transmission signal of any type of PAL B / G and PAL-I transmission systems automatically in one Receiver can be tuned.

Claims (8)

1. Circuit for automatic tuning of audio signals from multiplex transmission systems, characterized by :
Means for discriminating the type of the multiplex transmission system of a received transmission signal based on an FM audio signal of the received transmission signal and for generating a control signal depending on the determined result; and
Means for detecting a digital audio signal of the broadcast signal in response to the control signal from the discriminator ( 60 ) related to the type of transmission system and for demodulating the digital audio signal in response to a PCM clock signal generated by the control signal from the discriminator related to the Type of transmission system is controlled. 2. A circuit according to claim 1, characterized in that it comprises: FM audio detection means ( 50 ) for detecting an FM audio signal of a received transmission signal of the multiplex transmission system;
Discriminating means ( 60 ) with respect to the type of the transmission system for discriminating the type of the multiplex transmission system of the transmission signal based on the detected FM audio signal from the FM audio detection means ( 50 ) and for generating a control signal depending on the detected one Result;
PCM clock generating means ( 70 ) for generating PCM clock signals of different oscillation frequencies depending on the control signal of the discriminating means related to the type of the transmission system;
Digital audio demodulation means ( 80 ) for detecting a digital audio signal of the transmission signal in dependence on the control signal from the differentiating means with respect to the type of the transmission system and for performing a PCM detection of the detected digital audio signal in dependence on the PCM clock signal from the PCM clock generation means ( 70 ) for demodulating a digital audio signal; and
Audio output devices ( 90 ) for converting the demodulated digital audio signal from the digital audio demodulation devices into an analog signal and for outputting the analog signal in the form of analog audio signals from a left and right channel. 3. Circuit according to claim 2, characterized in that the FM audio detection devices ( 50 ) comprise:
first and second band-pass filters ( 51 , 52 ) for detecting the FM audio signals of the respective transmission systems;
a local oscillator ( 54 ) for oscillating a desired frequency;
a mixer ( 53 ) for mixing an output signal of the first bandpass ( 51 ) or the second bandpass ( 52 ) with an output signal of the local oscillator ( 54 ) to unite the output signals of the first and second bandpasses ( 51 , 52 ) as a single carrier a common frequency band and to output the FM audio signal of the single carrier;
a third band pass filter ( 55 ) for filtering an output signal of the mixer ( 53 ) to pass the FM audio signal of the single carrier; and
an FM audio detector ( 56 ) for detecting the FM audio signal from an output signal of the third band pass ( 55 ). 4. A circuit according to claim 3, characterized in that the distinguishing devices ( 60 ) with respect to the type of transmission system, the type of transmission system of the received transmission signal depending on the output signal of the first band pass ( 51 ) in the FM audio detection devices ( 50 ) distinguish and the control signal depending on the determined result to the PCM clock generating devices ( 70 ) and the digital audio demodulation devices ( 80 ). 5. A circuit according to claim 3, characterized in that the differentiating means ( 60 ) with respect to the type of transmission system, the type of transmission system of the received transmission signal as a function of the output signal of the second bandpass filter ( 52 ) in the FM audio detection devices ( 50 ) divide and the control signal depending on the result found to the PCM clock generators ( 70 ) and the digital audio demodulation devices ( 80 ). 6. A circuit according to claim 2, characterized in that the PCM clock generating devices ( 70 ) comprise:
an oscillator ( 71 ) for oscillating a desired frequency;
a frequency control unit ( 72 ) for controlling the oscillation frequency of the oscillator ( 71 ) in response to the control signal from the discriminating means ( 60 ) with respect to the type of the transmission system; and
a PCM clock generator ( 73 ) for dividing the oscillation frequency of the oscillator ( 71 ) by a predetermined number to generate the PCM clock signal. 7. Circuit according to claim 2, characterized in that the digital audio demodulation devices ( 80 ) comprise:
a first and a second FM blocking circuit ( 81 , 82 ) for successively removing the corresponding FM signals from the received transmission signal;
first and second bandpass filters ( 84 , 85 ) for filtering an output signal from the second FM blocking circuit ( 82 ) for passing the digital audio signals of the respective transmission systems;
a switch ( 83 ) for switching the output signal of the second FM blocking circuit to the first bandpass or the second bandpass in response to the control signal from the discriminating means with respect to the type of the transmission system;
a QPSK detector ( 86 ) for performing QPSK detection of an output signal of the first bandpass or the second bandpass for demodulating a quadrature-modulated phase of the digital audio signal;
a PCM detector ( 87 ) for performing PCM detection on an output signal of the QPSK detector in dependence on the PCM clock signal of the PCM clock generating devices for demodulating the digital audio signal; and
an SRAM ( 88 ) for storing the PCM detection data of the PCM detector upon PCM detection of the PCM detector. 8. Circuit according to claim 2, characterized in that the audio output devices ( 90 ) comprise:
a D / A converter ( 91 ) for converting the demodulated digital output signal from the digital audio demodulation means into the analog signal; and
first and second low pass filters ( 92 , 93 ) for filtering an output signal from the D / A converter to output the left and right channel analog audio signals.