FR2649571A1 - Circuit for processing picture signals and for tuning by fine automatic adjustment in accordance with television broadcasting systems - Google Patents

Abstract

The invention relates to a circuit for processing picture signals and for tuning by fine automatic adjustment of television broadcasting systems. For the SECAM-L system, positive modulation with positive heterodyning and for the PAL-B/G system, negative modulation with negative heterodyning are used. The picture signals and fine automatic tuning signals are matched to the SECAM-L or PAL-B/G broadcasting systems. A fine automatic tuning device 33 carries out the phase modulation on the outward signals from the picture detector 32 and emits signals for fine automatic tuning. A switching device 36, 37 chooses the outward signals delivered by the amplifiers 34, 35 in accordance with a selection signal for the local oscillator. The picture signals delivered by a picture detector 32 and the signals for fine automatic tuning are delivered by a buffer device 39, 40, are chosen by a switching device 41, 42 depending upon the PAL/SECAM selection signal and are emitted as picture signals. Application to television circuits.

Description

CIRCUIT FOR PROCESSING IMAGE AND SIGNAL SIGNALS
TUNING IN AUTOMATIC TUNING ACCORDING TO
BROADCASTING SYSTEMS
The present invention relates to a circuit intended for processing image signals and tuning signals in automatic fine adjustment of a television set and more particularly relates to a circuit for processing image signals and fine automatic tuning. depending on the broadcasting systems which allow image signals and fine automatic tuning signals from the SECAM-L system or the PAL-B / G system to be transformed and transmitted in an appropriate manner.

Generally, for the SECAM-L system, a positive modulation device is used and for the PAL-B / G system, a negative modulation device and the frequencies of the broadcast signals are different for the two systems. Likewise, the local oscillator of the tuner for the SECAM-L system uses the upper heterodyning and the lower heterodyning depending on whether it is the low band VHF, the high band
VHF and UHF band, while upper heterodyning is used for the PAL-B / G system for any channel band. As mentioned above, the image signals processed in both systems broadcast as well as the fine automatic tuning signals used in the automatic search are different since the broadcast signals received by the SECAM-L system and by the system
PAL-B / G as well as the local tuning oscillator are different from each other, therefore, we are faced with the disadvantage that a television set using the SECAM-L system is only able to receive signals system broadcast
SECAM-L and process the corresponding fine picture and automatic tuning signals, and a television set using the PAL-B / G system is only capable of receiving broadcast signals from the system
PAL-B / G and to process the corresponding fine picture and automatic tuning signals.

 Consequently, the aim of the present invention is to provide circuits for image signal processing and fine automatic tuning as a function of the broadcasting systems capable of receiving the signals of the SECAM-L system and of the PAL-B / G system and to process image and fine tuning signals properly, according to the selection of the SECAM-L system or the PAL-B / G system.

 The object of the present invention is achieved in that it comprises a tuner for the SECAM system, a tuner for the PAL-B / G system, two intermediate frequency preamplifiers intended to amplify the output signals from the two tuners, two surface acoustic wave filters which filter surface acoustic waves at the output signals of the two intermediate frequency amplifiers, a selector switch SECAM-L / PAL which selects the output signals of the two surface acoustic filters with SECAM-L / PAL selection signals, an intermediate frequency video amplifier which amplifies the signal selected by the SECAM-L / PAL selection switch, an image or video detector which detects image signals from output, an inverting amplifier device which inverts and amplifies the image signals from the image detector, a buffer device acting as a buffer and amplifier for the image signals of the image detector, two switching devices which respectively select and transmit with the selection signal SECAM-L / PAL the output signals of the buffer device which buffers and amplifies the output signals from the inverting amplifier or the output signals from the buffer device which buffers and amplifies the image signals from the image detector, a fine automatic tuning device which transmits the fine tuning or automatic adjustment signals by performing phase modulation on the output signals from the image detector and the amplifier which buffers and amplifies the output signals from the fine automatic tuner, an inversion amplifier which inverts and amplifies the output signals again from the amplifier, and two switching means which select respectively with an oscillating selection signal local generator and output the output signals from the amplifier and the inverting amplifier.

 FIG. 1 shows a circuit for processing image signals and fine automatic tuning according to the present invention.

FIG. 2 represents output waveforms according to each of the parts of FIG. 1, and
FIG. 3 is a table showing the modifications of image signals and of fine automatic tuning signals used to explain the operating relationships as a function of the broadcasting systems of FIG. 1.

We will now describe the invention in detail with reference to the accompanying drawing in which
FIG. 1 is a circuit for processing image signals and fine automatic tuning according to the present invention. As shown in Figure 1, the present invention includes a tuner for the SECAM-L system which receives the outputs of the broadcast signals from the SECAM system, a tuner for the PAL-B / G system which receives and transmits the broadcast signals the PAL-B / G system, intermediate frequency preamplifiers 14, 24 which amplify the output signals from the tuner 10, 20, surface acoustic wave filters 15, 16 which filter the outputs from the intermediate frequency preamplifiers 14, 24, a SECAM-L / PAL selector switch (SWI) which chooses the outputs of the surface acoustic wave filters 15, 25 as a function of the selection signal
SECAM / PAL (CSO), an intermediate image frequency amplifier 31 which amplifies the intermediate image frequency from the signals chosen by the SECAM-L / PAL selector switch (SW1), the image detector 32 which detects and transmits image signals from the output signals of the intermediate image frequency amplifier 31, a fine automatic tuner 33 which transmits the fine automatic tuning signals by modulating the phase of the image detector output signals 32 an amplifier 34 which buffers and amplifies the output signals of the fine automatic tuner 33, an inverting amplifier 35 which reverses and amplifies the output signals of the amplifier 34, switching means 36, 37 which transmit to the fine automatic tuning signal output terminal (A) by selecting the output signals from amplifier 34 and inverting amplifier 35 according to the signal for selecting the local scanner applied to a control terminal (cl1), an inverting amplifier 36 which inverts and amplifies the image signals of the image detector 32, a buffer device 39 which buffers and amplifies the image signals of the image detector 32, a buffer 40 which buffers and amplifies the output signals of the inverting amplifier 38, and a switch 41, 42 which transmits to a terminal (B) for outputting image signals by choosing the output signals from buffer 39, 40 as a function of the SECAM / PAL selection signal applied to a control terminal (CS2), the switch (SW1) being short-circuited at the terminal or at the SECAM selection terminals when a SECAM / selection signal
PAL is entered at high potential at the control terminal, the switch (SW1) is short-circuited at the PAL selection terminal (P) when the selection signal SECAM /
PAL entered at low potential. A high potential is applied to the control terminal (CS1) when the local oscillator is in upper heterodyne and a low potential is applied to the terminal (CS1) when the local oscillator is in lower heterodyne. ) is applied at high potential with SECAM selection and at low potential with PAL system selection. We will now describe below the operation and the effects of the present invention with this type of configuration. When broadcast signals from the SECAM system are received in the tuner for the SECAM-L system by an antenna (ANT1), the broadcast signals are amplified at the high frequency amplifier 11, followed by the amplified frequencies reversed by a local oscillator. 12 and a mixer 13, and the intermediate frequencies of the broadcast signals are detected. As described above, the signals which are output after detection at the tuner for the system
SECAM-L are amplified by the intermediate frequency preamplifier 14, filtered by the surface acoustic wave filter 15 serving as a wide band filter, and applied to the SECAM selection switch (S) of the SECAM / PAL selector (SW1). Likewise, when broadcast signals from the PAL system are received in tuner 20 for the PAL-B / G system by an antenna (ANT2), the intermediate frequencies of the broadcast signals are received in tuner 20 for the system PAL-B / G, amplified by the intermediate frequency preamplifier 24, filtered at the surface acoustic wave filter 25 then applied to the PAL selection terminal (P) of the SECAM / PAL selection switch (SW1). At this time, the SECAM / PAL selection switch (SWl) is short-circuited to the SECAM selection switch (S) when the SECAM / PAL selection signal (CSO) is in the high potential state, that is i.e. a SECAM selection signal.

 As a result of this, the intermediate frequency signals from the SECAM system applied to the SECAM selection terminal (S) are amplified at the intermediate image frequency amplifier 31 by the SECAM / PAL selection switch (SW1) and applied to the image detector 32 so that the image signals from the SECAM system are detected and transmitted to the image detector 32.

While the SECAM / PAL selection signal (CSO) is in the low potential state, i.e. a PAL selection signal, the selection switch
SECAM / PAL (sil) is short-circuited at the PAL selection terminal (P).

 As a result of this, the PAL system intermediate frequency signals applied to the PAL selection terminal (P) are amplified at the intermediate image frequency amplifier 31 via the SECAM / PAL selection switch (SW1 ) and then are applied to the image sensor 32 so that the PAL system image signals are detected and output to the image sensor 32.

 Since the broadcast signals of the SECAM system are the positively modulated signals and the broadcast signals of the PAL system are the negatively modulated signals, the image signals of the PAL system emitted by the image detector 32 are the same as those shown in FIG. 2 (C), and the image signals of the SECAM system emitted by the image detector 32 are the same as those shown in FIG. 2 (D). Consequently, when a high potential signal which is a SECAM selection signal is applied to the control terminal (CS2) by choosing the SECAM system as just mentioned above, the high potential is applied to the base of the transistor (Q9) in the switching device 41 and the transistor (Q9) is energized so that the low potential is output to the collector of the transistor (Q9).

field effect transistor (FET4) is de-energized.

 In addition, at this time, the high potential applied to the control terminal (CS2) is applied to the base of the transistor (06) of the switching device 42 and the transistor (Q6) is energized so that a low potential went out to the collector of the transistor (Q6). Therefore, the transistor (Q7) is turned off. As a result of this, a high potential is output at the collector of the transistor (Q7) and the field effect transistor (FET3) is energized.

Therefore at this time, the SECAM system image signals which are output as shown in Figure 2 (D) are inverted and amplified at the inverting amplifier 38, buffered and amplified at the buffer 40, and sent to the image signal output terminal (V) by a capacitor (C3) of the switching device 42 and of the field effect transistor (FET3).

 When a low potential signal which is a SECAM selection signal is applied to the control terminal (CS2) by selecting the PAL system, the low potential is applied to the base of the transistor (09) in the switching device 41 so that the transistor (09) is switched off. Consequently, a high voltage is emitted at the collector of the transistor (09) and the high potential then activates the field effect transistor (FET4). Also at this time, the low potential applied to the control terminal (CS2) is applied to the base of the transistor (Q6) in the switching device 42 which turns the transistor off, therefore a high potential is emitted to the collector of the transistor (Q6) and this high potential energizes the transistor (Q7) so that a low potential is emitted to the collector of the transistor (07). Therefore, the field effect transistor (FET3) is turned off.

 It follows then that the image signals of the PAL system emitted by the image detector 32 as shown in FIG. 2 (C) are buffered and amplified at the level of the buffer 39, and emitted at the terminal of image signal output (V) by a capacitor (C5) in the switching device 41 and a field effect transistor (FET4).

 As a result, the waveform of image signals which is output to the image signal output terminal (V) is the same whether it is the SECAM system or the PAL system.

 Furthermore, the fine tuning or automatic adjustment device 33 transmits the fine automatic tuning signals with modulated output signals from the image detector (32). Note that the upper heterodyne is used independently of each band as the local oscillator for the PAL system and the upper heterodyne is used for the low VHF band in the SECAM system as the local oscillator. The waveform of fine automatic adjustment signals as shown in FIG. 2 (A) is emitted by the automatic fine tuning device 33 in the case where the local oscillator is the upper heterodyne as has been mentioned. above. And the lower heterodyne is used as a local oscillator for the high VHF band and the UHF band in the SECAM system. The fine tuning signal waveform as shown in Figure 2 (B) is output by the fine tuner 33 in the case where the local oscillator is the lower heterodyne as mentioned above.

 The fine automatic tuning signals which are output as mentioned above are buffered and amplified at amplifier 34, applied to a field effect transistor (FET2) in switching means 36 while the output signals of the amplifier 34 are inverted and amplified again at the inversion amplifier 35 and applied to a field effect transistor (FET1) in the switching means 37.

 Consequently, when a high potential signal is applied to the control terminal (CS1) by choosing the PAL system or the VHF low band of the SECAM system by using the higher heterodyne, the high potential is applied to the base of the transistor (Q1) in the switching device 37 to energize the transistor (01) so that a low potential is emitted to the collector of the transistor (Q1). Therefore, the field effect transistor (FET1) is turned off. In addition, at this time, the high potential applied to the control terminal (CS1) is applied to the base of the transistor (Q2) in the switching device 36 to energize the transistor (Q2). Therefore, a low potential is output at the collector of the transistor (02) to turn off the transistor (03) which turns on the field effect transistor (FET2) with a high potential output applied to the collector of the transistor (Q3). Consequently, at this time, the fine automatic tuning signals emitted by the fine automatic tuner 33 as shown in FIG. 2 (A) are buffered and amplified at the amplifier 34, then are transmitted to the terminal. of fine automatic tuning output (A) by the field effect transistor (FET2) in the switching means 36.

 In addition, when a low potential signal is applied to the control terminal (CS1) by selecting the high VHF band and the UHF band of the SECAM-L system using the lower heterodyne, the low potential turns on the transistor (Ql) of the switching device 37 off so that the field effect transistor.

 (FET1) is energized with a high potential output to the collector of the transistor (1). Likewise, a high potential is emitted to the collector of the transistor (02) since the low potential applied to the control terminal (CS1) de-energizes the transistor (02) in the switching device 36. Consequently, a low potential is sent to the collector of the transistor (03) since the high potential energizes the transistor (Q3) so that the field effect transistor (FET2) is de-energized. Therefore, the signals from automatic fine adjustment emitted by the automatic fine tuner 33 as shown in FIG. 2 (B) are buffered and amplified at buffer 34, inverted and amplified again at inverting amplifier 35 and transmitted to the terminal automatic fine adjustment output signal (A) by the field effect transistor (FETl) in the switching means 37. It follows that the automatic fine adjustment signals which are emitted at the automatic adjustment output terminal fine ticks (A) are emitted in the same waveform regardless of the local oscillator.

 The above description is summarized in a table shown in Figure 3.

 As described above in detail, the present invention receives broadcast signals from SECAM and PAL systems, outputs image signals from SECAM and PAL systems in the same waveforms according to the selections of SECAM and PAL and outputs the automatic fine tuning signals in the same wavelengths regardless of the local oscillator of the tuner used. The present invention is characterized in that it can receive and process the broadcast signals of the SECAM and PAL systems as if it were one and the same system.

Claims (1)

CLAIM 1. Circuit intended for processing image signals and fine automatic tuning signals according to television broadcasting systems, characterized in that it comprises tuning devices (10, 20) for the SECAM-L system and for the PAL-B / G system, which respectively receive and transmit broadcast signals from the SECAM and PAL systems of intermediate frequency preamplifiers (14, 24) which amplify output signals from the tuners (10, 20) of the filters with surface acoustic waves (15, 26) which filter the output signals of the intermediate frequency preamplifiers (14, 24) a selection switch SECAM / PAL which chooses the output signals of the surface acoustic wave filters (15, 25 ) according to the SECAM / PAL selection signals ;; an intermediate frequency image amplifier (31) which amplifies the signals selected at the SECAM / PAL selector switch (SW1); an image detector (32) which detects and outputs the image signals from the output signals of the intermediate image frequency amplifier (31) a fine automatic tuner (33) which performs the phase modulation on the image detector output signals (32) and emits fine automatic tuning signals an amplifier (34) which buffers and amplifies the fine automatic tuning signals an inverting amplifier (35) which inverts and amplifies the signals of amplifier outputs (34) a switching device (36,  37) which selects the output signals of the amplifier and an inverting amplifier (35) according to the selection signal of the local oscillator and outputs them as fine automatic tuning signals;  an inverting amplifier (38) which inverts and amplifies the image signals of the image detector (32):  a buffer device (39) which buffers and amplifies the image signals from the image detector (32);  a buffer device (40) which buffers and amplifies the output signals of the inverting amplifier (33); and  switching means (41, 42) which selects the output signals from the buffer device (39, 40) according to the selection signal SECAM / PAL and outputs them as image signals.