DE3808280A1 - Device for distinguishing between a first and a second frequency of signals - Google Patents

Abstract

This simple device comprises a pulse shaping stage (1) which is supplied by the signals and which supplies from these a pulse-shaped signal (on 6) with pulses of a particular duration (T) at a frequency corresponding to the frequency of the signals, an integration stage (2) for forming a mean value of the pulse-shaped signal (on 6) and a comparison stage (3) for comparing the mean value with a reference value and outputting an identification signal (on 8) as determined by the result of the comparison. <IMAGE>

Description

The invention relates to a device for Distinguish between a first and a second Frequency of signals.

From DE-PS 33 11 896 is a device for distinguishing between a first and a second frequency of signals known as the raster alternating frequency determination circuit to distinguish television signals with different grid change frequencies, such as B. 50 Hz and 60 Hz, is provided. In this Device will receive vertical sync pulses and horizontal sync pulses in more complicated Linked together to form a signal received, depending on the received raster change frequency assumes different levels.

The object of the invention is to be as simple as possible built device of the type mentioned create.

According to the invention, the object is achieved by a pulse shape stage, to which the signals are fed and the from this a pulse-shaped signal delivers with pulses certain duration and one corresponding to the frequency of the signals Frequency, an integration level for education an average of the pulse signal and a Comparison level for comparing the mean with a Reference value and for emitting a characteristic signal according to the requirements the result of the comparison.  

In the device according to the invention there is only one simple evaluation of only those that can be distinguished in their frequency Signals required; a further one Signals for the evaluation as in DE-PS 33 11 896 not necessary. The device according to the invention is simple built and can by setting the specific duration the pulses of the pulse-shaped signal, that of the comparison stage reference value to be supplied and if necessary one for averaging at the integration level effective time constants optimally to different Frequencies of the signals can be adjusted. The pulse shape level also offers one without additional effort considerable interference immunity.

The device according to the invention is advantageous with a Switchover waveform stage provided for delivering a Switching signal of a certain minimum duration if that Identification signal assumes a predetermined value and an impulse of the pulse-shaped signal occurs. In a simple one This switchover signal form stage is designed as a monostable Multivibrator trained. The switching waveform level is used to suppress Interferences that occur over several periods of the signals stop.

The pulse shape level to which the signals are fed basically allows the use of the invention Set up for any waveforms, for example with sinusoidal, rectangular or sawtooth-shaped Course, in any application. Particularly advantageous the device according to the invention is used when the signals from frame change pulses of a television signal are derived and the identification signal or the switching signal assumes different values depending on whether the image change pulses according to a first or a second standard  are formed. The device according to the invention can then especially for automatic switching of a television deflection device between these standards.

An embodiment of the device according to the invention is shown in the drawing and is described below explained in more detail.

Fig. 1 shows an example for an inventive device with a pulse shaping stage 1, an integration stage 2, a comparator 3, a Umschaltsignalformstufe. 4 The pulse shape stage 1 is fed via a signal input 5, the signals to be distinguished in their frequency. It emits a pulse-shaped signal at an output 6 with pulses of a certain duration and a frequency which overrides that of the signals supplied at signal input 5 . From the output 6 , the pulse-shaped signal is passed on the one hand via the integration stage 2 , which feeds the comparison stage 3 at an input 7 a signal which represents the mean value of the pulse-shaped signal. In the comparison stage 3 , this mean value is compared with a - internally generated - reference value and an identification signal is emitted at an output 8 in accordance with the result of the comparison. This identification signal is fed to a first input 9 of the switching signal form stage 4 . On the other hand, a second input is the Umschaltsignalformstufe 4, the pulse-shaped signal of the pulse shaping stage 1 directly supplied from the output 6 of the tenth The switchover signal form stage 4 forms a switchover signal from the signals fed to it at its inputs 9, 10 and outputs it at its output 11 .

In the embodiment of Fig. 1, the pulse shaping stage 1 comprises a monostable multivibrator 20 having an input 21 and an output 22. It is constructed in such a way that, triggered by a rising edge of the signal fed to its input 21, it outputs at its output a pulse of a time period which is determined by a frequency-determining resistor 23 and a frequency-determining capacitor 24 . The resistor 23 and the capacitor 24 are connected in a conventional manner to the multivibrator 20 and a supply voltage connection 25 . The output 22 of the flip-flop 20 is connected to the output 6 of the pulse shaping stage 1 and to an input 26 of an OR gate 27 , to the second input 28 of which the signal input 5 of the pulse shaping stage 1 leads. The OR gate is displayed in positive logic; the pulse at the output 22 of the flip-flop 20 is "positive", ie in the idle state of the flip-flop 20 there is a low potential at the output 22 , when the pulse is output, the output 22 is switched to high potential. The pulse shaping stage 1 thus represents in the present example a so-called non-retriggerable monostable multivibrator. The pulses at the output 22 and thus at the output 6 can thus be caused by further pulses arriving at the signal input 5 during their duration, such as, for. B. can be caused by disturbances, not changed in their duration.

The integration stage 2 comprises a series resistor 30 and a transverse capacitance 31 . Both elements are dimensioned in such a way that the integration stage 2 delivers a sufficiently smoothed signal to the input 7 of the downstream comparison stage 3 , so that the recharging processes due to the pulse-shaped signal at the output 6 are small compared to the mean value to which the transverse capacitance 31 is charged. The dimensioning is therefore chosen according to the required differentiation of the facility; the closer the frequencies to be distinguished are adjacent, the better the smoothing of the signal at input 7 must be. In addition, series resistor 30 and transverse capacitance 31 are dimensioned such that individual interference pulses at signal input 5 , which generate additional pulses at output 6 despite the interference suppression by pulse shaping stage 1 , do not influence comparison stage 3 .

FIG. 2 shows an example of some signal profiles in the device according to FIG. 1. In the left half of the diagrams according to FIG. 2, the signal at input 5 , which is shown as the uppermost curve and labeled accordingly, has a first frequency, in the right half of the diagram this frequency is doubled, for example. The rising edges of the signal at the signal input 5 marked with arrows trigger pulses of constant duration T , which form the pulse-shaped signal and are shown in the correspondingly marked second curve in the diagram according to FIG. 2.

In the present example, the comparison stage 3 contains a comparator 40 , preferably formed by a differential amplifier, to which the mean value of the pulse-shaped signal from the input 7 of the comparison stage 3 is fed at a non-inverting input. At the inverting input of the comparator 40 , a reference value is fed to it, which is generated by a reference source within the comparison stage 3 , which consists of a resistance voltage divider consisting of two resistors 41 , 42 and a capacitor 43 connected in parallel with the latter of the two resistors. This reference source 41, 42, 43 is arranged between the supply voltage connection 25 and ground, via which the comparator 40 is also fed. Furthermore, a supply resistor 44 leads from the supply voltage connection 25 to the comparator 40 connected to the output 8 of the comparator stage 3 , and from there a feedback resistor 45 is led to the non-inverting input of the comparator 40 .

In FIG. 2, the third curve shows the reference value Ref by a dash-dotted line which lies above the mean value of the pulse-shaped signal at the first frequency. Therefore, for a signal of this frequency, the comparison stage 3 delivers at its output 8 a characteristic signal with a low value, as shown in the fourth curve of the diagram in FIG. 2 in the left half. This identification signal is supplied via the first input 9 of the Umschaltsignalformstufe 4 and locks there via an AND gate 50, the supply of the pulse-shaped signal from the output 6 of the pulse shaping stage 1 via the second input 10 of the Umschaltsignalformstufe. 4

In the present example, the reference value Ref is below the mean value of the pulse-shaped signal at the second frequency, which here corresponds to twice the first frequency. Therefore, for a signal of the second frequency, the comparison stage 3 delivers at its output 8 a characteristic signal with a high value, as shown in the fourth curve of the diagram in FIG. 2 in the right half. This identification signal releases the supply of the pulse-shaped signal from the output 6 of the pulse shaping stage 1 via the AND gate 50 .

The switchover waveform stage 4 comprises a further monostable multivibrator 51 with an input 52 and an output 53 which is connected to the output 11 . The duration of the pulse emitted by the monostable multivibrator 51 at its output 53 , which represents the changeover signal, is determined by a frequency-determining resistor 54 and a frequency-determining capacitance 55 , which like the corresponding elements in the pulse shape stage 1 with the monostable multivibrator 51 and the supply voltage connection 25 are connected. The duration of the pulses of the switchover signal at output 53 is preferably a multiple of the period of the signal at signal input 5 , which has the lowest frequency of all the signals supplied here.

In this example, the switchover signal form stage 4 is designed as a so-called retriggerable monostable multivibrator, in which the switchover signal is triggered anew by each rising edge of the signal at input 52 . A permanent switchover signal thus arises at the output 11 when the AND gate 50 is released by the identification signal for the implementation of the pulse-shaped signal. The switchover signal is not influenced by disturbances and by failures of individual pulses of the pulse-shaped signal. Its course is shown in the fifth curve of the diagram according to FIG. 2, which in its right half shows an indication of the superimposition of the individual pulses on the permanent switching signal with a low level.

In a modification of the circuit arrangement according to FIG. 1, the inverting and the non-inverting input of the comparator 40 are interchanged and the AND gate 50 is replaced by an OR gate. The output 8 of the comparison stage 3 then has a high potential at low frequencies of the signal at signal input 5 and a low potential at high frequencies.

Fig. 3 illustrates very schematically a block diagram is for a television deflection system, in which designated by the reference numeral 60, inventive means for discriminating between a first and a second frequency of picture change pulses of a television signal is used. The television deflector includes a horizontal stage 61 , e.g. B. formed as a horizontal combination with pulse separation stage, which is supplied via a television signal input 62, a complete color television signal. The horizontal stage 61 separates a synchronizing signal from line synchronizing pulses and picture changing pulses. It is constructed in a manner known per se and comprises, for example, an integrated circuit of the TDA 2595 type.

The picture change pulses are fed via a picture change pulse line 63 to a vertical stage 64 which, for. B. is constructed in a manner known per se with an integrated circuit of the type TDA 2653A. Horizontal and vertical stages 61, 64 are used in a manner known per se for processing the synchronous signals of the television signal and for generating deflection voltages for a picture display device and are connected to one another and to other components, not shown, via lines 65 . Their function is not described in detail here.

Both the horizontal and the vertical stage 61, 64 contain circuit parts which, depending on the standard of the television signal at the television signal input 62 and the frequencies of the line sync and image change pulses which differ with these standards, have to be set or reversed and which also have to be used for operation to be matched to a specific standard. In particular, these are frequency-determining elements of oscillator circuits. For a simple and precise adjustment or a corresponding adjustment or switchover, the television deflection device according to FIG. 3 further comprises an adjustment stage 66 which is connected to the horizontal and vertical stages 61, 64 via adjustment lines 67 and 68 , respectively. The setting stage 66 is supplied with a number of setting data for the television deflection device via a digital control line 69 , preferably a data bus. The setting data are converted in the setting stage 66 into setting signals for the horizontal and vertical stages 61, 64 , and the setting signals are fed to these stages via the setting lines 67, 68 .

In order to obtain a fully automatic adjustment of the television deflection device to the norm of the television signal supplied to the television signal input 62 , ie to the frequency of the image change pulses contained therein, the image change pulse line 63 is connected to the signal input 5 of the device 60 according to FIG. 1. The device 60 then forms a changeover signal depending on the standard of the television signal. This switches standard-specific components in vertical stage 64 and setting stage 66 . These are, in particular, frequency-determining elements of oscillators.

In Fig. 1 an example of a switch group 70 is provided, via which the changeover signal changing over the standard-specific components referred to by the output 11 of the Umschaltsignalformstufe. 4 The switching group 70 contains four switches 71, 72, 73, 74 controlled by the changeover signal , all of which are connected on one side to ground. The switches 71, 72, 73, 74 are identified as mechanical switch contacts, but are preferably designed as electronic switches. The first switch 71 has a transverse capacitance 75 connected to ground with a first output connection 79 , the second switch 72 and the third switch 73 have a series capacitance 76 and 77, respectively, with a second and third output connection 80 and 81, and the fourth Switch 74 is connected to a fourth output terminal 82 via a transistor stage 78 . The transistor stage 78 comprises an npn transistor with a base bias divider consisting of two resistors 83, 84 connected between the supply voltage connection 25 and ground and a collector resistor 85 which is connected in series between the fourth output connection 82 and ground with the main current path of the npn transistor.

The first output connection 79 is connected via a series capacitance 86 , the second output connection 80 via a transverse capacitance 87 connected to ground, each with a connection of the setting stage 66 . Furthermore, the third output connection 81 is connected to a connection of the vertical stage 64 via a transverse capacitance 88 which is also connected to ground, the fourth output connection 82 is connected to a further connection of the vertical stage 64 via a transverse resistor 89 connected to ground. The transverse capacitors 75, 87, 88, the longitudinal capacitors 76, 77, 86 as well as the collector resistor 85 and the transverse resistor 89 are standard components of the vertical stage 64 and the setting stage 66 . In particular, elements 77, 88 and 85, 89 are connected to a vertical oscillator contained in vertical stage 64 as its frequency-determining elements. With the third and fourth switches 73, 74 conducting , the series capacitance 77 and the transverse capacitance 88 are connected in parallel, while the collector resistor 85 is ineffective. When the third and fourth switches 73, 74 are blocked, the series capacitance 77 is ineffective and the collector resistor 85 is connected in parallel with the transverse resistor 89 . Accordingly, the vertical oscillator in the vertical stage 64 operates at the first and the second frequency.

In a modification of the television deflection device according to FIG. 3, the fourth output connection 82 is connected to another connection of the vertical stage 64 , so that the transverse resistor 89 is eliminated and the collector resistance is dimensioned to a different value.

Corresponding frequency-determining capacitances are also switched for the setting stage 66 via the first and the second output connection 79, 80 .

The device described is for example for switching the television deflection device between a first standard in which the image change pulses have a frequency of essentially 50 or 60 Hz, and a second standard with image change pulses with a frequency of essentially 100 or 120 Hz, dimensioned. The components described were selected in accordance with the following dimensioning table (details in brackets refer to the variation described at the fourth output connection 82 ):

Dimensioning example

In this example, the pulse duration of the pulses emitted by the pulse shaping stage 1 is selected so that, at a frequency of the image change pulses at the signal input 5 of 50 Hz, it makes up just one third and over 100 Hz just two thirds of the period of the image change pulses. The limit for the frequency of the image change pulses still to be processed is then 147 Hz, so that image change pulses with a frequency of 120 Hz are still processed correctly. The pulse duration of the switchover signal comprises five image change pulse periods even at the lowest frequency of the image change pulses, as a result of which interference is very well eliminated. When image change pulses of the first standard occur, the output 11 is at a high potential and is switched to a low potential when a changeover signal occurs. This design is adapted to switches 71 to 74 ; in principle, other potentials can also be selected. In particular, the transistor stage 78 can be saved if the fourth switch 74 is switched to the blocked state when the first standard occurs.

The described device according to the invention enables a simple addition to existing circuit concepts prefabricated integrated components.

Instead of the switchover between 50 to 60 Hz and 100 to 120 Hz on the other hand, the invention Setup also for switching between 50 and 60 Hz or between 100 and 120 Hz. By combining several devices according to the invention and evaluation of the switching or identification signals can also make a further distinction can be easily made between more than two standards.

Claims (5)

1. A device for distinguishing between a first and a second frequency of signals, characterized by

• a pulse shaping stage ( 1 ), to which the signals are fed and which delivers a pulse-shaped signal (on 6 ) with pulses of a certain duration (T) and a frequency corresponding to the frequency of the signals,
• - An integration stage ( 2 ) for forming an average of the pulse-shaped signal (on 6 ) and
• - A comparison stage ( 3 ) for comparing the mean value with a reference value and for emitting a characteristic signal (on 8 ) in accordance with the result of the comparison.

2. Device according to claim 1, characterized by a switching signal shaping stage ( 4 ) for emitting a switching signal (on 11 ) of a certain minimum duration when the identification signal (on 8 ) assumes a predetermined value and a pulse of the pulse-shaped signal (on 6 ) occurs. 3. Device according to claim 1 or 2, characterized in that the signals are derived from image change pulses of a television signal and the identification signal (on 8 ) or the switching signal (on 11 ) assumes different values, depending on whether the image change pulses after a 1st or a 2nd norm are formed. 4. Device according to claim 3, characterized by a use to toggle one TV deflection device between the 1st and 2nd standards. 5. Device according to claim 3 or 4, characterized in that the image change pulses in the 1. Norm a frequency of essentially 50 to 60 Hz and in the 2nd standard from essentially 100 to 120 Hz exhibit.