DE2310761A1 - DISCRIMINATOR CIRCUIT ARRANGEMENT - Google Patents

Description

Discriminator circuit arrangement The invention relates to signal discriminator circuit arrangements, and in particular arrangements for generating different output signals in Depending on the respective frequencies of applied input signals to a to distinguish predetermined input signal from other input signals.

A device is known in which a circuit arrangement or a mechanism corresponding to plural kinds of input signals in part which are regarded as input signals is changed to a predetermined one To achieve operation for any one of the information signals. With such a device when the respective information signals are different in frequency, or contain pilot signals and the like which are different in frequency, the information signals themselves or the pilot signals and the like Filter supplied whose pass band frequencies are different from each other so that the information signals can be distinguished in that one of the filters generates an output signal.

However, if the information or pilot signals to be distinguished have very low frequencies of e.g. 50 or 60 Hz, it is quite difficult to to distinguish them. Even in the case when such signals are to be distinguished Having high frequencies it is difficult to distinguish them by filters, though their frequencies are close together.

The invention is based on the object of a discriminator circuit arrangement to differentiate between several input signals of different frequencies to create that can be distinguished even if their frequency is relative is low or when their frequencies are relatively close together.

The signal discriminator circuitry according to the invention has an oscillator with an external synchronizing frequency in a predetermined Frequency domain, a comparator for comparing the output signal of the oscillator with an input signal, and a detector connected to the output of the comparator connected. The input signal goes to the oscillator and also to the comparator fed. The output signal of the oscillator is sent to the comparator for comparison of the output signal of the oscillator fed with the input signal and the compared The output signal is fed to the detector. The detector gives different output signals depending on whether the oscillator is synchronized with the frequency of the input signal is or not to perform the discrimination of the input signal.

The invention provides a discriminator circuit arrangement, which is simple in construction and can distinguish input signals even if theirs Frequencies are low, or when their frequencies are high but close together.

The invention also makes it possible to use a color television receiver for the reception and reproduction of color television signals to create the corresponding various systems using discriminator circuitry according to the invention for distinguishing between different color television signals and for setting the state of the receiver as a function of the received Has color television signal.

The invention is illustrated below with reference to FIGS. 1 to 10, for example explained. It shows: FIG. 1 a circuit diagram of an embodiment of a signal discriminator circuit arrangement According to the invention, FIGS. 2A to 3C show the time course of signals for explanation the circuit arrangement of Fig. 1, Figure 4, 5 and 6 vector diagrams for explanation of color television signals, Figure 7 is a circuit diagram of an example of a color television receiver with a signal discriminator circuit arrangement according to the invention, and FIG 8, 9 and 10 are vector diagrams to explain the operation of the color television receiver in Fig. 7.

In Fig. 1, 1 denotes an input terminal which has a first input signal with a frequency of e.g. 60 Hz or a second input signal with a frequency of e.g. 50 Hz. The input terminal 1 is connected to the base of a transistor 3 connected, which forms a pulse shaping circuit 2. A series connection Resistors 4 and 5 is connected to the collector of transistor 3 and the The connection point of the resistors 4 and 5 is via a furnishing element such as a Diode 6 with the input of an emitter-coupled oscillator 7, namely the emitter of a transistor 8 and the collector of a transistor 9 are connected. The exit of the oscillator 7, namely the emitter of the transistor 8, is connected to the base of a PNP transistor 11 connected to the gate control, which forms a comparator 10.

The collector of transistor 3 is also connected in parallel 12 from a resistor and a capacitor to the collector of the transistor 11 connected, which is connected via a transistor 13 connected as an emitter follower to a Detector is connected, from which an output terminal 15 is led to the outside. The construction is such that the oscillator 7 with one of the input signals, e.g. the first input signal is synchronized with the frequency 60 Hz, i.e. at the frequency of 60 Hz is phase-locked, while the oscillator 7 with the other Signal, i.e. the second input signal with a frequency of 50 Hz, is not synchronized will. This means that the synchronization frequency range of the oscillator 7 is 60 Hz, but does not contain 50 Hz. Therefore, assuming that if the oscillation frequency of the oscillator 7 or its natural frequency is between 51 Hz and 60 Hz, the oscillator is synchronized with the first input signal of 60 Hz, and when the natural frequency of the oscillator 7 is between 44 Ha and 50 Hz, the oscillator 7 with the second Input signal of 50 Hz is synchronized, it is sufficient to set the oscillation frequency of the oscillator 7, e.g. at 55 Hz.

The setting of the natural frequency of the oscillator 7 can be done by setting a setting resistor 16 can be achieved, which is connected to the base of the transistor 9 'is connected. By connecting a thermistor 17 to the setting resistor 16 in series with this can change the natural frequency of the oscillator 7 a temperature change can be avoided. When trained in the above manner Circuit arrangement the first input signal with the frequency of 60 Hz to the Input terminal 1 is given, a pulse P1 with the repetition frequency of 60 Hz can be obtained at the output or the collector of the transistor 3, as Fig. 2A shows. The oscillator 7, which receives the pulse P1, is phase-locked with the pulse P1 and oscillates at a frequency of 60 Hz and generates a pulse at its output P2 with the repetition frequency of 60 Hz in synchronism with the pulse P1, as shown in FIG. 2B. The pulse P2 is fed to the base of the transistor 11 in the comparator 10, to make the transistor 11 conductive on the arrival of each pulse P2. Of the Pulse P1 also becomes the collector of transistor 11 and the base of the transistor 13 supplied via the parallel circuit 12 from the collector of the transistor 13. Due to the fact that the pulse P1 is synchronous with the pulse P2 at the time When the transistor 11 conducts, the pulse P1 becomes the collector of the transistor 11 passed so that the potential at the collector of transistor 11 and at the Base of transistor 13 is not so low as to make the latter conductive. Of the Transistor 13 therefore does not generate an output signal at its emitter at this point in time, as shown in Fig. 2C, so that the detector 14 gives no output signal and the output terminal 15 holds at ground potential, which means that the first input signal of 60 Hz is on input terminal 1 is given.

If, on the other hand, the second input signal of 50 Hz to the input terminal 1 is given, a pulse P3 with a repetition rate of 50 Hz, as shown in FIG. 3A, is tapped from the collector of transistor 8. The oscillator 7, however, oscillates at its natural frequency of 55 Hz without being synchronized with the pulse P3 to become and generates a pulse P with the repetition frequency of 55 Hz, as Fig. 3B which is not synchronized with the pulse P3 and to the base of the transistor Ll is directed.

The pulse P3 is also applied to the collector via the parallel circuit 12 of transistor 21 and the base of transistor 13 are given. However, since in this If the pulse P3 is synchronous with the pulse P4, as can be seen from the figure is when transistor 11 is blocked, the pulse P3 on the base of the transistor 13 given. Therefore, the transistor 13 is made conductive by the pulse P3 and outputs a pulse P5 to its emitter, as shown in FIG. 3C. Dc detector 14, the receives the pulse P5, is at its output 1; a positive DC voltage, this means that the input terminal 1 receives the second input signal of 50 Hz.

As can be seen from the above description, the simple constructed circuit arrangement according to the invention can be distinguished which of several input signals is present or given to the input terminal 1 becomes even if the frequencies of multiple input signals are low lie close together.

The above description refers to the case where two input signals different frequencies are distinguished by the circuit arrangement of the invention will. It is obvious, however, that the invention should also be used to distinguish e narrow or multiple special signals of two or more than three input signals can be used.

A color television receiver according to the invention will now be described, in which the reception status is automatic according to an input color television signal Can be changed to either the PAL system or a color television signal according to the NTSC system.

Currently, the NTSC color television system is used in Japan, USA, etc. however, the PAL system in some European countries. When the color television signals are compared in both systems, the frame rate is in the NTSC system 60 Hz, but 50 Hz in the PAL system. The number of horizontal scanning lines is 525 in the NTSC system, but 625 in the PAL system, and the frequency of the color subcarrier is 3.58 MHz in the NTSC system, but 4.43 MHz in the PAL system.

In addition, in the NTSC system, the phase of the modulation axes is for the modulation of the color subcarrier with color difference signals R-Y, and B-Y set.

On the other hand, in the PAL system, the phase of the modulation axis becomes for the modulation of the subcarrier by a red color difference signal R-Y at each second line interval reversed in phase, as Fig. r lgt, and during a time interval, in which, corresponding to this, the phase of the modulation axis for the red color difference signal coincides with the (R-Y) axis, a burst signal becomes B + with a phase lead transmitted from 135 ° from the B-Y axis, whereas during a line interval, in which the phase of the modulation axis for the red color difference signal with the - (R-Y) axis coincides, a burst signal B- with a phase lag of 1350 from the B-Y axis is transmitted from, as Fig. 6 shows. In Fig. 5, Fn and Fn + 1 are modulated Signals in two consecutive lines and (ER-EY) n, (EB-EY) n, (ER-EY) n + 1 and (EB-EY) n + 1 are their respective components on each axis. In addition, the Line frequency 15.75 KHz in the NTSC system and 15.63 KHz in the PAL system.

To selectively reproduce one of the two color television signals, is it is necessary to change part of the circuitry of the color television receiver according to the to switch the respective television signals. To get this switchover automatically, it is necessary to distinguish which system an applied signal belongs to.

To make such a distinction can be considered are to take advantage of the fact that the frame rates and line rates the television signals are different in the two systems. As the frame rate 60 Hz in the NTSC system, but 50 Hz in the PAL system and these frequencies are very high are low, and the line frequency is 15.75 KHz in the former and 15.63 KHz in the latter and these frequencies are relatively high and close together, can it may be impossible to track the signals by applying the vertical sync signal or the Horizontal sync signal e.g. to filters with different pass bands to determine which filter is producing an output signal.

In the color television receiver according to the invention, the signal discriminating circuit is which is constructed in the above manner, used to distinguish the signals, which can be applied by taking the difference between the frame rates used in the systems.

An embodiment of a color television receiver according to the invention will now be described with reference to FIG.

The embodiment shown in Fig. 7 outputs the color television signals the NTSC system and the PAL system e.g. by means of a video tape recording again, whose color subcarriers are both converted to 4.43 MHz.

A color television signal applied to an input terminal 21, is successively a tuner 22, a video intermediate frequency amplifier 23 and a video detector 24 supplied. The transformed output signal of the video detector 24 is fed to a video amplifier 25 which transmits a luminance signal to a matrix circuit 26 there. The output of the video detector 24 is also passed to a band pass amplifier 27, from which a chrominance signal is obtained.

The chrominance signal of the band pass filter 27 becomes as it is given one input terminal of a circuit 28, but on its other Input terminal through a delay circuit 29 which converts an applied signal can delay a line interval of the PAL color television system. The output signal of the circuit 28 is via a band pass filter 30, demodulators 31 and 32 fed. The chrominance signal of the band pass amplifier 27 also becomes like it is fed to one input terminal of a second circuit 33, however its other input terminal via a phase inverter 34. The output signal of the circuit 33 is fed to a burst gate circuit 35, which then generates a burst signal generated and the burst signal to an oscillator 36 for its control. That The output signal of the oscillator 36 is applied to a third circuit 37. The output signal obtained at its one output terminal becomes the Demodulator 31 is fed via a phase shifter 38, which receives an applied signal can shift by 90 ° in phase, while the connection at its other output obtained signal is supplied to the same demodulator 31 as it is. That Chrominanzsignål of the bandpass amplifier 27 is also a burst gate circuit 39 supplied, which emits a burst signal to an oscillator 40 for its control. The output signal of the oscillator 40 is sent to the demodulator via a phase inverter 41 32 supplied.

The converted video output signal of the video detector 24 becomes also fed to a synchronizing signal separator 42 which has a vertical synchronizing signal to a vertical oscillator 43 for its control. The vibration output signal of the vertical oscillator 43 is fed to a vertical output circuit 44, which is a Vertical scanning signal generated. The vertical scanning signal is sent to a deflection device 51 given to a cathode ray tube 50. The horizontal sync signal of the sync signal separator 42 is fed to a horizontal oscillator 45 for its control. The vibration output signal of the horizontal oscillator 45 is fed to a horizontal output circuit 46, whose Horizontal scanning signal to a deflection device 51 of the cathode ray tube 50 is given.

The horizontal pulse of the horizontal output circuit 46 is on a High voltage rectifier 47 given, the output signal of which is high voltage the anode of the cathode ray tube 50 is passed. The horizontal sync pulse is also given to a flip-flop circuit 48 for its control, its output signal is given to the circuits 28 and 33 as a switching signal.

The vertical sync signal of the sync signal separator 42 is also given to a signal discriminator circuit 49 described above in connection with Fig. 1 to distinguish whether the signal is related to the color television signals of the NTSC or PAL system. The discriminated output signal of the signal discriminator circuit 49 is the flip-flop circuit 48 for controlling it in a later explained Way and also the circuit 37, the vertical oscillator 43 and the vertical output circuit 44 supplied to their control.

When an NTSC system color television signal at which the frequency its color subcarrier is converted to 4.43 MHz on the input terminal 21 e.g. a color television receiver is given, the input terminal receives of the signal discriminating circuit 49, the vertical synchronizing signal of 60 Hz, so that there is no output voltage at the output terminal of the discriminator circuit 49 as mentioned above. Therefore, it is recognized that the color television signal of the NTSC system is applied to the input terminal 21 of the receiver.

When the output voltage at the output terminal of the signal discriminating circuit 49 is zero, as mentioned above, the flip-flop circuit 48 can be in a constant Operating state can be maintained without being switched to by the horizontal pulse in which one of the transistors inevitably becomes non-conductive, the flip-flop circuit 48 forms. The switching circuits 28 and 33 thus remain in the switching position shown in FIG N and the switching circuit 37 is switched to the switching position N shown in FIG.

Therefore, when the color television signal of the NTSC system on the input terminal 21 is given, the chrominance signal of the band pass amplifier 27 is given to the demodulators 31 and 32 as it is supplied through the circuit 28 and the band pass amplifier 30. The burst signal B, the frequency of which is converted to 4.43 MHz and that in phase coincides with the - (B-Y) axis is obtained at the burst output gate circuit 35, and a reference signal having a phase equal to that of the former becomes at the oscillator 36 received. Since the reference signal is supplied to the phase shifter 38 via the switching circuit 37 which is switched to the position shown in Fig. 7 becomes a reference signal having a phase coincident with the R-Y axis from the phase shifter 38 and supplied to the demodulator 31. The burst signal similar to the previous one B is obtained from the burst gate circuit 39 and a reference signal with the same Phase is obtained from the oscillator 40. Hence you get a Reference signal, which coincides in phase with the B-Y axis from the phase inverter 41 which the demodulator 32 is supplied. Thus, predetermined color signals are demodulated generated by the demodulators 31 and 32.

These demodulated color signals are the matrix circuit 26 together with the luminance signal and the output signals of the matrix circuit 26 are then fed to the cathode ray tube 50.

When the output voltage at the output terminal of the signal discrimination circuit 49 is zero, as described above, the frequency of the output signal of the Vertical oscillator 43 is made equal to 60 Hz and the amplitude of the vertical scanning signal of the vertical output circle 44 and thus the size of the image and the linearity of the vertical scanning signal become corresponding to those of the color television signal of the NTSC system controlled.

The NTSC system color television signal sent to the input terminal 21 is given, is thus automatically on the screen of the recipient as in reproduced as an image to a receiver intended only for the NTSC system.

On the other hand, when a color television signal of the PAL system is fed to the input terminal 21 of the receiver is given, because the vertical sync signal of 50 Hz is given to the input terminal of the signal discriminating circuit 49, one positive DC voltage at the output terminal of the discriminator circuit 49. Hence it is determined that the color television signal of the PAL system on the input terminal 21 of the recipient is given.

When the positive DC voltage at the output terminal of the signal discriminating circuit 49 is obtained the flip-flop circuit at every line interval by the Borizontalimpuis of the horizontal output circuit 46 independent of the positive DC voltage of the discriminator circuit 49 switched. The circuits 28 and 33 are therefore switched at every line interval and the switching circuit 37 becomes switched to the position opposite to the position shown.

The circuits 28 and 33 are therefore in the form shown in FIG.

7 positions shown when the chrominance signal in the Phase of the modulation axis for the red color difference signal R-Y (hereinafter referred to as Plus signal) is obtained at the bandpass amplifier 27.

On the other hand, they become the positions opposite to those shown in FIG Positions switched when the chrominance signal at which the phase of the modulation axis for the red color difference signal - (R-Y) (hereinafter referred to as the minus signal) at the band pass amplifier 27 is obtained. In this case the circuit 28 signals issued, with the minus signal through the plus signal in front of each Line interval is replaced, that is, only the plus signals are consecutive received from circuit 28 and then passed to demodulators 31 and 32, while, as shown in Fig. 8, the burst signal B + in the plus signal and one signal B-; generated by reversing the phase of the burst signal B- in the minus signal is obtained from the burst gate circuit 35 alternately.

Therefore, a reference signal becomes S1 that has the same phase as the R-Y axis received exactly in the middle between the burst signals B + and B- from the oscillator 36, as Fig. 8 shows. The reference signal S1 is then sent to the demodulator 31 through the circuit 37, which is switched to the position opposite to that in Fig. 7 is shown. On the other hand, if the circuits 38 and 33 in the opposite are switched to the positions shown in Fig. 1 and the plus signal from the Band pass amplifier 27 is released and when these circuits 28 and 33 are in the positions shown are switched, signals in which the plus signal against the minus signa are replaced by a line interval, i.e. only the minus signals consecutively the demodulators 31 and 32 supplied from the circuit 28. In this case it will a signal B + which is generated by a phase reversal of the burst signal B +, and the burst signal B-, as shown in FIG. 9, alternately from the burst gate circuit 35 is output, and thus a reference signal S2 having the same phase as you - (R-Y) axis is given exactly in the middle between the burst signals B + and B- emitted by the oscillator 3b, as Fig. 9 shows. The reference signal S2 is the De: rodulator 31 via the circuit 37 which is switched to the position opposite to the In Fig. 7 is shown. The burst signals B + and B- shown in Fig. 10 become stead vo.) of the burst gate circuit 39 received alternately. and therefore, as shown in Fig. 10 shows a reference signal S3 having a phase coincident with that of the - (B-Y) axis, exactly between the burst signals B + and B- from the oscillator 40, therefore becomes a reference signal S4 with a phase coinciding with init: of the B-Y axis, As FIG. 1C shows, it is always passed from the phase shifter 41 to the demodulator 32 Therefore, the demodulators 31 and 32 always generate predetermined demodulated color signals.

When a positive DC voltage at the output terminal of the signal discriminating circuit 49 is generated, the frequency of the vibration output of the vertical oscillator becomes 43 50 Hz and the vertical output circuit 44 is controlled so that the amplitude of the Vertical scanning signal and thus the size of the image and the linearity of the vertical scanning signal can be made according to the color television signal of the PAL system.

The PAL system color television signal supplied to input terminal 21 of the receiver is automatically displayed as an image on the screen of the Receiver as with a receiver intended only for the PAL system.

In the previous description it was assumed that the frequency of the color television signal of the NTSC system is 4.43 MHz, i.e. the same as that of the color subcarrier of the color television signal of the PAL system, but it goes without saying that that the invention can also be applied to the case where the frequency of the color subcarrier of the color television signal of the NTSC system is equal to 3.58 MHz different from that of the color subcarrier of the color television signal of the PAL system is made. A system for generating a subcarrier signal from 3.58 MHz and a system for generating a subcarrier signal of 4.43 MHz separately can be provided and these systems can be used with the output of the signal discriminating circuit 49 can be switched.

As described above, according to the television receiver according to the invention several signals are necessarily differentiated. This is going through achieved the use of a special discriminator circuit and two television signals with synchronous signals different in frequency can be normal through automatic Switching of parts of the circuit arrangement of the television receiver with the output signal of the discriminator are reproduced.

Claims (7)

Claims D signal discriminator circuit arrangement, characterized by a Signal input connector, an oscillator driven by an external signal, which has a predetermined frequency range, a supply device for an input signal from a signal input terminal to the oscillator, a signal comparator, which is connected to the oscillator and the output signal of the oscillator and receives the input signal for comparing the two signals, and a detector device, to generate an output signal corresponding to the result of the comparison, the indicates whether the input signal is a particular signal with a frequency in the predetermined Range or not to distinguish between multiple input signals. 2. Circuit arrangement according to claim 1, characterized in that the oscillator produces a signal that is different in frequency from the input signal generated when its frequency is outside the predetermined frequency range, and generates a signal at the same frequency as the input signal if its Frequency is in the predetermined frequency range. 3. Circuit arrangement according to claim 2, characterized in that the feed device consists of a transistor, the input of which is connected to the signal input connection is connected, and its output is connected to the oscillator and the signal comparator is. 4. Circuit arrangement according to claim 3, characterized in that the detector comprises a one-way device and a capacitor for generating a DC voltage output signal as a function of the output signal of the signal comparator. 3. Color television receiver, characterized by a signal decoder for decoding a received color television signal to reproduce a color picture on a color cathode ray tube, the signal decoder in dependence states different from the transmission system of the received color television signal can decrease in order to correctly reproduce the respective received color television signals to decode, means for changing the state of the signal decoding means depending on the transmission system of the received color television signal, one Signal discriminator to differentiate between the transmission systems of the received color television signal, consisting of a signal input connector, an input signal in accordance with the received color television signal receives, an oscillator driven by an external signal, which has a frequency in a predetermined frequency range, a device for supplying the Input signal to the oscillator, the signal comparator with the oscillator is connected and the output signal of the oscillator and the input signal to the Comparison of the two signals received, and a detector device for generating an output signal in accordance with the result of the comparison indicating whether the input signal is a particular signal having a frequency in the predetermined Has frequency range or not to thereby allow between transmission systems of received color television signal to distinguish, and a control device for Change of the state of the signal decoder as a function of the output signal the signal discriminator. 6. color television receiver according to claim 5, characterized in that the signal decoding means is composed of a decoding circuit for selectively decoding the PAL color television signal and the NTSC color television signal with partial changes in the Circuitry to demodulate, and a device for changing the state the signal decoding device, consisting of a device for initiating the partial changes depending on the received color television signal, which is a PAL or an NTSC color television signal. 7. Color television receiver according to claim 6, characterized in that the signal discriminator also has a device for supplying a Vertical sync signal of the received color television signal to the signal input terminal as an input signal and that the predetermined frequency range to take away of the oscillator is selected so that it matches the frequency of the vertical sync signal which includes PAL and NTSC color television signals.