DE1537560C - Circuit arrangement for a facsimile system for generating a pure black and white signal from the information to be scanned, regardless of the respective brightness value of the background - Google Patents

Description

The invention relates to a circuit arrangement for a facsimile system for generating a pure Black-and-white signal from the information to be scanned, regardless of the respective brightness value of the background, with a scanning device for generating a video signal corresponding to the information and the background, with a Background evaluation circuit part for generating an average brightness value of the Background proportional background signal and with an evaluation circuit for generating a Black-and-white signal from the video signal, which is controlled as a function of the background.

In conventional facsimile processes, the information contained on a document to be transmitted is normally converted into electrical signals by an electro-optical scanning device. In such an electro-optical scanning device, the document to be transmitted is scanned by a sharply bundled point of light that is generated, for example, by a cathode ray tube. The light rays reflected by the document, which are modulated according to the degree of reflection of the document, are thrown onto a light-sensitive evaluation device, which is formed, for example, from a photoelectron multiplier. The video signals generated by the evaluation device are brought into a suitable form and / or modulated, after which they are transmitted to a remote receiver via radio or telecommunications lines. In the receiver, the video signals, along with appropriate synchronization and phase signals, are used to control the selective actuation of a drawing device. Depending on the video and control signals received, this generates a facsimile of the original document.
• In facsimile systems in which a sharply focused light beam is used to scan the original document in the transmitter, the. analog signals generated by the light-sensitive evaluation device proportional to the degree of reflection of the document. a predetermined scanning grid. An undesirable property of an electro-optical scanning device and the circuit arrangements associated with it is that it is difficult to correctly distinguish between changes or shifts in the background level and changes in the amplitudes of the information signals of the document. For example, the background of an original document can be colored in one case. In other cases, the documents may have a white background with colored parts. Even if the scanning light rays are kept largely constant, a wide range of changes in the degree of reflection and the contrast ratios in the original document results in a wide range of amplitudes for the analog signals generated.

As is known in the art, it is for facsimile reception Anger for the exact reproduction of the original document required that the evaluation circuit in the transmitter a correct distinction between changes in the background level and Changes in the amplitude of the analog signal as a result of information printed on the original document can meet with appropriate accuracy. This problem of evaluation and correct Differentiating between the information and the changes in the subsurface is particularly important when if there are original documents with colored parts on which information is printed. If the video circuit of the transmitter is not able to detect the displacement of the subsurface and the Correctly differentiating information signals with such shifts results from a Cathode ray scanning means transmission in a system that is only responsive to two different levels the darker background in black color, eliminating the information printed on it get lost.

In a known facsimile system (magazine "Electronics", 1965, issue 9, pp. 277 to 279) is the Background determined according to the highest level value occurring in a scan line. One such The system is therefore not intended to differentiate between gray and colored parts of the normally white background urid information printed in black able.

In another, well-known facsimile system (magazine "radio mentor", 1958, issue 4, p. 206 bis 208), a 5 mm wide strip at the edge of the document to be transmitted is scanned around the Determine the background level. If outside of this test strip, for example in the middle of the document to be scanned, gray or colored background parts next to those printed in black If information occurs, this system must also fail.

There is also a facsimile system known (German Auslegeschrift 1 216 350), which is thereby distinguishes that when evaluating the original, the switchover from "black" to "white" and vice versa takes place after passing through a predetermined reflection factor difference, such that the voltage output by a photoelectric converter within the predetermined reflection factor difference is stored and when the predetermined reflection factor difference is exceeded is forwarded. For this purpose, a corresponding two-pole with a no linear characteristic is used. The aim of this process is to also print documents with low contrast to be able to evaluate. A prerequisite is, however, that the surface and the printed Information is monochrome; So here, too, we are dealing with a purely two-level system.

Various improved video circuits for facsimile devices are also described been (German Auslegeschriften P 14 37 272 and P 14 87 804), which to a limited extent in the Are able to distinguish colored parts of the underground from the printed information. While these circuits automatically adjust or compensate for changes in the reflectance Carrying out the background of a document, however, is a way of determining Video signals that differ from the background by only a low resolution are not given, when the level of the subsurface changes significantly at the same time. Another difficulty is if the video signal is partially noisy, with these circuits still in the safe determination of information signals that differ from the background due to a low resolution, and information signals that differ from the background by a high resolution.

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The invention is therefore based on the object, evaluation device can be designed in the form of a Fotoelekeine circuit arrangement for a facsimile system tronen-multiplier circuit and to create with black-and-white transmission that sets in the reflected, with the information moduder position, information with The video signal of the evaluation device 17 is used to determine if the brightness value of the display changes of three control signals used, which basically changes at any point in time, also easier evaluation or identification of the signals if the signal composed of the brightness values of the sub-parts of the video signal generated from the video signal and a background noise and the information serve io signal,
a noise is still superimposed. The first control signal is in a first and

The task is in the case of the second background evaluation circuit 19 and 21 circuit arrangement described above solved by the fact that the positive testifies and corresponds to the background level of the font Peak rectification of the video signal a bit. From the second underground evaluation scaler Detector circuit is provided, which a 15 device 21 is the first control signal a brightness first the positive rising edges of the video amplifier 23 supplied, which together with a signals proportional control signal generated, and a monitor 25 for the fluorescent noise and a first logic combination circuit is provided, this downstream noise suppression verdie through this first control signal and the sub-amplifier 27 a signal for controlling the brightness of the Basic signal is controlled and generates a first dynamic 20 scanning light beams. The strength of the scanning control signal which is the more positive the light rays by changing the Hellig value the signals fed to it corresponds to the speed of the light spot of the cathode ray tube for negative peak rectification of the controls.

Video signal, a second detector circuit is used to generate the second control signal can be seen which a second the negatively falling 25 generated by the evaluation device 17 analog edges of the video signal proportional control signal signal fed to a level converter 31, which is generated, and a noise detector which controls a first detector circuit 35 is provided. The first A voltage is generated which has the basic level of the detector circuit 35 generates a first the positive the control signal generated by the second detector circuit is proportional to the rising edges of the video signal by one of the noise amplitude of the scanning device 3 ° control signal. To generate the third control signal shifts the corresponding level value and thereby becomes the one generated by the evaluation device 17 second dynamic control signal generated that further analog signal of a second detector circuit 33 zuein second logic combination circuit presented, which a second, the negatively falling can be seen, the control signal proportional to the first dynamic control edges of the video signal signal and the second dynamic control signal a 35 is generated.

dynamic reference signal generated that each The structure and mode of operation of the two

more negative of the signals fed to it corresponds and detector circuits 33,35 are similar to one another and

the evaluation circuit for generating the black are described in detail below. Both

White signal from the video signal. Detector circuits 31,35 have a charging capacitor

An embodiment of the invention is based on 40. However, the load time constants are for

described below with reference to the drawings. There are positive rising edges and negative falling edges

shows edges of the video signal selected differently.

F i g. 1 is a block diagram of an embodiment. The output of the noise suppression game the circuit arrangement according to the invention, amplifier 27 is fed to a noise detector 37

Fig. 2 is a schematic circuit diagram of the essential 45 leads, which generates a voltage which a

borrowed circuit parts of the in F i g. 1 shown circuit part 39 is supplied. In the circuit

Circuit arrangement, part 39 becomes the base level of the second

F i g. 3 waveforms of signals that are generated by the control signal generated in detector circuit 33 by the

F i g. 2 are generated, the voltage generated by the noise detector 37

F i g. 4, 5 and 6 individual circuits of different 50 pushed.

Parts of the FIG. 1 and 2, the output signal of the first detector circuit

processing parts, 35 is a first logical linkage circuit

F i g. 7 signaling 41 shown over a time axis is supplied. The first logical link processes, which is a better comparison than that in detection circuit 41 is furthermore that in a level-F i g. 3 allow the waveforms shown. 55 converters 43 converted from the second underground F i g. 1 is supplied with the block diagram of a signal generated in accordance with the evaluation circuit 21. the Invention designed circuit arrangement dar- first logic combination circuit 41 generates a placed. In this circuit arrangement, a first dynamic control signal, which is the respective Document 11 by means of transport rollers 13 at a more positive value of the signals supplied to it moved past which the scanning beams 60 is speaking. This first dynamic control signal becomes 15 of a light source (cathode ray tube) onto the thereon a second logical combination scarf surface of the document are projected, value 45 is supplied. Furthermore, the second becomes logical with a scanning movement according to a grid instead of logic circuit 45 that in the circuit part finds. The second dynamic control signal generated by the cathode ray tube 39 is supplied. Light beams are through the on the document 65 The second logic combination circuit 45 er-11 The strength of the information contained therein is now modulated to produce a dynamic reference signal that corresponds to the and after reflection on the document, it is de-sensitive to a light-negative one of the signals fed to it Evaluation device 17 focused. This speaks. The dynamic reference signal is closed

loaned to a logic limiter circuit 29, which is part of an evaluation circuit for generating the black and white signal from the video signal.

The logic limiter circuit 29 also receives the unprocessed from the evaluation device 17 generated video signal supplied. The logic limiter circuit 29 now operates so that to each Point in time at which the instantaneous amplitude of the video signal is more positive than the dynamic reference signal, a black signal is generated. When on the other hand, if the instantaneous amplitude of the analog video signal is more negative than the dynamic reference signal, a white signal is generated. The output signal the logic limiter circuit 29 is fed to a trigger circuit 47 in which signals constant amplitude corresponding to the evaluated white and black parts of the original document be generated. The output of the trigger circuit 47 becomes a sync gate circuit 49 supplied, in which the black and white signals are combined with synchronization signals so that they can be transmitted to a remote recipient.

The dynamic reference signal generated by the second logic combination circuit 45 is together with the video signal generated by the evaluation device 17 from a black-and-white trigger circuit 24, which compares the two signals with one another. The output of the black and white trigger circuit 26 is fed to a delaying black-and-white limiter circuit 24. This generates the above-mentioned third control signal, which is fed to the first background evaluation circuit 19 will. The third control signal controls the first underground evaluation circuit 19 so that it does not step by step the respective value of the video signal generated by the evaluation unit 17 follows.

In detail, the above explanation boils down to the fact that the first underground evaluation circuit 19 contains a capacitor which is used to store a voltage which corresponds to the reflectance corresponds to the subsoil just previously evaluated. If the background is darker, the Scanning light beams amplified via the illustrated feedback path, so that the document is better is illuminated and a compensation for the change in the subsurface takes place. The stronger lighting also leads to the generation of stronger noise signals; the relationship is almost proportional. As will be explained in more detail later, the noise is evaluated in the noise detector 37 and the combination of the signal generated by the noise detector 37 in the circuit part 39 with the signal generated by the second detector circuit 33 to an automatic Compensation for the increasing noise due to the aforementioned reason in the composite video noise signal.

In Fig. 2 shows a basic circuit diagram of the invention. This circuit creates a dynamic Reference signal that dynamically follows the analog video signal, such that the dynamic reference signal when evaluating the background above the positive peaks determined by the background noise of the background signal and, when evaluating information, is below that caused by the background noise certain positive peaks of the background signal lies. In the latter case, the dynamic Reference signal just below the negative peaks determined by the background noise of the background signal. The dynamic reference signal makes information relevant Video signal part evaluated without loss of contrast resolution even with low contrast. Through this The evaluation of the video signal is independent of the application of the dynamic reference signal Signal frequency. In particular, signals with a low contrast to the background level can also be evaluated will.

As in Fig. 1 and 2 are shown, the unprocessed video signals of the evaluation device 17 is supplied to a first detector circuit 35 via a level converter 31. The level converter 31 ensures that the output signal of the first detector circuit 35 is more negative by a certain amount than the raw video signal. The level is converted by a voltage drop in the Video signal to two diodes 51 and a resistor 53. Because of this voltage drop this is the first detector circuit 35 supplied signal more negative than the instantaneous value of the unprocessed Video signal. The first detector circuit 35 includes a capacitor 55 which is proportional to the Output signal of the level shifter 31 is charged.

As shown in FIG. 3 b, the voltage shown by curve 57 rushes across the capacitor 55 in the first detector circuit 35 after the analog video signal. Increases the amplitude of the unprocessed Video signal positive, the capacitor 55 is via a resistor 59 and a parallel circuit from a diode 61, a Zener diode 63 connected in series with a resistor 62 and a resistor 65 is charged. If the amplitude falls below the Zener diode 63 Analog signal the threshold value of the Zener diode 63 in the negative direction, then the discharge takes place faster, since the Zener diode 63 has a lower resistance in this case. Below the mentioned threshold the Zener diode 63 is the time constant for discharging the capacitor through the series connection determined from the resistor 59 and the resistors 65 and 62 connected in parallel. The output signal the first detector circuit 35 is a first logic combination circuit 51 with Or character supplied. The second input signal for the second logic combination circuit 41 is fed to an input terminal 67. A background level signal from the second background evaluation circuit 21 (FIG. 1) is shown as curve 69 in FIG. 3 b shown. The curve 70 in F i g. 3c shows the output signal of the first logic combination circuit 41. The first logic combination circuit 41 generates a first dynamic control signal, whichever is the more positive value corresponds to the signals fed to it. The already mentioned second detector circuit 33 is under construction and functions like the first detector circuit 35. The second detector circuit 33 includes a Capacitor 71. The charge time constant and the discharge time constant for this capacitor are different chosen. In the case of negatively falling video signal edges, the time constant is through the resistance 79 determined. In the case of positive rising video signal edges, the time constant is due to the series connection determined from resistors 79 and 73,

when the video signal level is below the breakdown voltage of the Zener diode 77. If the Level exceeds the breakdown voltage, then is the time constant for positive rising edges by the series connection of the resistor 79 and the resistors 73 and 78 connected in parallel definitely. The voltage level across the capacitor 71 of the second detector circuit 73 is shown as curve 81 in Fig. 3 a shown.

The basic level of the output signal of the second detector circuit 33 can optionally be shifted in order to compensate for the noise generated by the light path of the cathode ray tube. The signal generated by the noise monitor 25 (FIG. 1), which is used to control the brightness of the cathode ray tube, is fed to the noise detector 37 via a connection 83. The output signal of the noise detector 37 is fed to a potentiometer 39. The output signal generated by the second detector circuit 33 is also fed to the potentiometer 39. As can be seen from the Figure 3a., The output signal 81, the second disassembly f tektorschaltung 33 by the output signal of the noise detector 37 to be moved selectively by moving the tap of the potentiometer 39 to positive. By combining the output signal of the noise detector 37 and the output signal of the second detector circuit 33 in the potentiometer 39, the output signal of the second detector circuit 33 is also automatically made more positive by a level that is proportional to the instantaneous value of the noise generated by the tracer of the cathode ray tube, since the Output signal of the second detector circuit 33 is related to the level of the output signal of the noise detector 37, as will be described below.

The shifted in its basic level in the circuit part formed by the potentiometer 39 The output signal of the second detector circuit 33 is referred to as the second dynamic reference signal. It is generated together with the first dynamic logic circuit 41 generated by the first Reference signal of the second logic combination circuit 45 is supplied. This second logical one Combination circuit 45 also has an OR character. The output of the second logical Combination circuit, also referred to as a dynamic reference signal, is shown as curve 87 in FIG. 3 b shown. The dynamic reference signal is added along with the noisy video signal 84 of the logic limiter circuit 29 (Fig. 1) fed. The output signal of the logic limiter circuit 29 is shown as curve 88 in FIG. 3 e shown. This output signal corresponds in his Information content of the scanned document.

In the F i g. 4, 5 and 6 are circuit examples for the circuit shown in FIG. 1 subcircuits specified in block form shown. For a better overview, the in the F i g. 4, 5 and 6 illustrated circuits in the in F i g. 1 and provided with reference numerals. The in F i g. 4 shown Circuit generates bias voltage for two similarly constructed transistor stages, which an identification of information signals in the analog video signal when scanning differently colored parts of the Enable original document. Furthermore, with this circuit, the background level of the document determined to be the voltage required to control the brightness of the scanning light beams to generate, whereby the analog signals remain within the range favorable for the circuit and correcting changes in light intensity of the cathode ray tube due to optical errors within a scan line are possible.

As already mentioned in connection with FIG. 1, the analog video signal of the evaluation device 17 is fed to the first detector circuit 35 via a level converter 31 and the second detector circuit 33. The aim is to generate a dynamic reference signal which can be compared in the logic limiter circuit 29 with the video signal. As shown in FIG. 4, the video signal is fed to the input terminal 89 and from here to the input of the first background evaluation circuit 19, to the input of the second detector circuit 33 and to the input of the level converter 31. The complementary emitter followers control the amplitude of the video signal Q 1 and Q 2 charge the capacitor 91 of the first underground evaluation circuit 19. A signal fed to the terminal 93 by the black-and-white delay circuit 24 controls the diode 95 in the forward direction, causing the negative amplitudes of the video signal to pass the capacitor 91 during the evaluation of information signals cannot charge. The output signal of the first background evaluation circuit 19 is fed to the input of the second background evaluation circuit 21 via the transistor Q 3 connected as a buffer stage. This also has two complementary emitter followers Q 4 and QS , which control the state of charge of the capacitor 97 as a function of the amplitude of the video signal when the state of charge of the capacitor 91 is changed. Depending on the charging time constants of the first background evaluation circuit 19 and the second background evaluation circuit 21, a DC voltage signal is generated which is proportional to the mean reflectivity of the background of the scanned document. The output signal of the second background evaluation circuit 21 is fed via the isolating amplifier Q 6 and the diode 99 to the input of the first logic combination circuit 41 with an OR character.

As already mentioned, the signal fed to the first logic combination circuit 41 via the diode 99 is a direct voltage signal which corresponds to the mean reflectance of the background of the scanned document. If no information signals are detected in the video signal, then the capacitor 91 is charged to the detected background level via the transistors Q1 and Ql. If, on the other hand, information signals are found in the unprocessed video signal, the transistors Q 1 and Q 2 are blocked because the voltage on the capacitor 91 is the reverse of the signal voltage which is fed to the terminal 93 by the video trigger circuit 47.

The voltage level of the second capacitor 97 corresponding to the background is fed to the input of the amplifier 23 for regulating the average brightness. In the absence of a control signal at terminal 103 which is used to control the cathode ray blank, the background signal at the base electrode of transistor Q1 results in a background signal

009 550/295

generates a corresponding signal for controlling the brightness of the cathode ray tube, whereby the strength of the scanning light rays changes as a function of the background signal. During the return of the cathode ray, a control signal 5 for dark control of the cathode ray is applied to the terminal 103. This blanking signal is supplied to the collector of transistor Ql and the base of the transistor Q 8 via the diode 105th The output signal of the amplifier 23 for brightness control is fed to the grid of the cathode ray tube via the terminal 107.

The analog video signal, which is fed to the input 89, also reaches the input of the second detector circuit 33. Corresponding to the positive rising edges of the unprocessed video signal, the capacitor 71 is charged via the series circuit of the resistor 79 and a resistor 73, the resistor 73 is still bridged by the series circuit consisting of the resistor 78 and the Zener diode 77. Zener diode 77 and resistor 78 are chosen so that capacitor 71 charges to about 3 volts in about 5 microseconds. Assuming that the thirst break voltage of the Zener diode 77 is not reached in the case of positively rising video signal edges, the change in charge takes place much more slowly; than in the opposite direction, i.e. with negatively falling video signal edges. Just 2 microseconds for charging on the aforementioned voltage level _required: sloping at negative video signal edges is done reloading of the capacitor due to the now conducting diode 75 only through the resistor 79. Comparatively are here. ■ .i ■■.

In order to prevent noise from being evaluated as information, the output signal is the second detector circuit 33 combined with the output signal of noise detector 37. To that To convert output signal of the second detector circuit 33 so that from the logic limiter circuit 29 only those signals can be identified as information signals which are opposite to that with noise applied background level are positive, the output signal of the second detector circuit 33 related to the noise voltage rectified by the noise detector 37.

The signal emitted by the brightness control amplifier 23 and corresponding to the noise is fed to the base of the transistor β 10 via the capacitor 109 and the resistor 111. The capacitor 113 serves to equalize the frequency of the emitter circuit formed by the resistor 115. The operating point of the transistor Q 10 is set by the resistors 117 and 119.

The output of transistor Q 10 is fed to primary winding 121 of transformer 123. The two secondary windings 125 and 127 are connected in series in order to achieve a voltage increase compared to the signal occurring on the primary winding. The signals occurring in the secondary windings are rectified by the rectifier 129 and fed to a capacitor 131 via a resistor 133. The capacitor 131 charges to the mean positive value of the noise peaks. The capacitor 71 of the second detector circuit 33 is connected so that it is discharged through the resistors 39 and 135 of the limiting level circuit to a level determined by the noise. Since the secondary winding of the transformer is coupled to the capacitor 71 of the second detector circuit 33, the output signal of the second detector circuit 33 can be shifted to the positive by a DC voltage which is directly proportional to the noise level present in the background signal.

The potentiometer 39 is used to shift the base level of the output signal of the second detector circuit 33. The output signal of the second detector circuit, shifted in its basic level 33 is fed to diode 137. This diode forms one input of the second logic combination circuit 45. As already described in connection with FIG. 1, the other input signal becomes for the second logic combination circuit 45 through the first logic combination circuit 41 generated.

As already described, the output signal generated by the second background evaluation circuit is fed ^{to one input of the first logic combination circuit 41 via the level converter 43 -:.} The input of the first logic interconnection circuit 41 is formed by the diode 99. The second input signal for the first logic circuit 41 is generated by the first detector circuit 35. The unprocessed video signal arrives at the input of the first detector circuit 35 via the level converter 31 and the resistor 139 , which are connected in parallel with the resistor 145, a negative shift in the video signal level by about 1 volt when the current flows in the forward direction of the diodes. This ensures that the signal and noise components of the video signal for the first detector circuit 35 are always more negative than the integrated output signal of the second detector circuit 33. This means that the level conversion in the level converter 31 must take place faster than the integrating effect of the charging of the capacitor 71 in the second detector circuit 33., f

The output signal of the level converter 31 is fed to the input of the first detector circuit 35 and serves there to change the state of charge of the capacitor 55. The one for the capacitor in the first detector circuit 35 selected time constants are essentially in terms of Polarity of the input signals with respect to those time constants for the capacitor 71 in the second detector circuit 33 apply, vice versa. In the first detector circuit 35, the capacitor 55 for positive rising input signal edges charged quickly, while the change in the state of charge of the capacitor 55 at negative falling Input signal edges take place more slowly.

In the case of positive amplitudes of the analog input signal, the capacitor 55 is essentially only charged through the resistor 59, since the diode 61 is switched in the forward direction. With negative signals at the length the capacitor 55 is discharged via the series circuit of the resistor 59 and the resistor 65, if the breakdown voltage of the Zener diode 63 has not yet reached is. On the other hand, when the breakdown voltage of the Zener diode is reached, the resistor

was 65 the resistor 62 connected in parallel. The output signal of the first detector circuit 35 is fed to the input of the transistor Q 11 of the first logic combination circuit 41 via the diode 147.

If signals are present at the anode sides of the diodes 99 and 147 of the first logic combination circuit, the most positive signal will appear at the emitter of the transistor Q 11 and be fed to the second logic combination circuit 45 via the diode 149 to the base of the transistor β 9. As has already been described, the second input signal from the tap on the potentiometer 39 is fed to the second logic combination circuit 45 via the diode 137. The second logic combination circuit 45 leads the most negative input signal to the emitter of the transistor β 9. The output signal of the second logic combination circuit 45 is the dynamic reference signal; it is fed to the logic limiter circuit 29 via the terminal 157. The logic limiter circuit 29 operates in such a way that any signal which exceeds the dynamic reference signal is identified as an information signal, while any signal which is below the dynamic reference signal is to be regarded as a noise signal or background signal.

In Fig. 5 is an embodiment of the logic Limiter circuit 29, the black-and-white delay circuit 24, the trigger circuit 26, the underground mixer 28 and the synchronization gate circuit 49 shown. The output signal of the Video trigger circuit 47 represents the black and white levels corresponding to the information characters and the background of the scanned document. After blanking, pulse stretching and onset of The output of the sync gate circuit 49 provides the final sync pulses The output of the black and white delay circuit As already described, 24 controls the first underground evaluation circuit 19 via the connection 94. Since it is prevented that the second background evaluation circuit 21 at the negative amplitudes ! When video information signals are detected, the video signal level cannot be more negative than that Background level. In order to achieve this, the information signals in particular are increased Resolution evaluated. This is done by the fact that higher information signals are present Resolution the duty cycle of the output signal generated by the black-and-white delay circuit 24 the duty cycle of the second background evaluation circuit reduced, whereby the charging of the charging capacitor 97 of the second background evaluation circuit 21 to a higher voltage level than the signal level is prevented.

The output signal of the second logic circuit 45 (FIG. 4) is fed to the connection terminal 153 for generating the emitter bias of the transistor β12 in the logic limiter circuit 29 and of the transistor β13 in the trigger circuit 26. The output signal of the second detector circuit 33 (FIG. 4) is fed to the transistor β14 of the underground mixer 28, which is connected as an emitter follower, via the connection terminal 155 as a collector voltage. The unprocessed video signal of the evaluation device 17 is fed to the base of the transistor β12 of the logic limiter circuit 29 via the connection terminal 157 and the equalization network consisting of the resistor 151 and the capacitor 159. The background mixer 28 combines the background noise signals with the bias level applied to the emitter of transistor Q 12 so that noise suppression is achieved and the clipping level can be adjusted to be in the range of the background noise. Will this be done by

ίο the reference signal generated by the second logic circuit 45 is fed to the emitter of the transistor Q 12 of the logic limiter circuit 29 and the video signal is fed to the base of this transistor, an output signal is always produced at the collector of the transistor β 12 when the video signal is more positive than the dynamic reference signal on Emitter - is. So the circuit actually works like a logic limiter circuit. The result of the interaction of the transistors Q 12 and β13 is that only background noise is mixed into the dynamic reference signal and the stronger black signals are not influenced.

If the dynamic reference signal is switched to the emitter and the unprocessed video signal to the base of the transistor β12 of the logic limiter circuit 29, the transistor Q 12 opens and blocks alternately depending on the respective instantaneous polarity of the signals at the base and at the emitter. The voltage divider formed from the resistors 163 and 165 transmits the output signal generated by the logic limiter circuit 29 to the trigger circuit 47, which converts the output signal of the logic limiter circuit into a two-level signal which corresponds to the black and white level.

The output signal of the video trigger circuit 47 passes from the collector of the transistor β16 to the Output terminal 167. From here the output signal of the video trigger 47 is fed to a positive-negative switch supplied, which will be described in more detail and with which the inverted and non-inverted operation can optionally be set. The two-level signal is inverted and fed from the terminal 169 to an input of the synchronization gate circuit 49 in a non-inverted form. The signal from a synchronization generator is sent to the other input of the synchronization gate circuit 49 fed through the terminal 171 and the diode 173. This signal comes through to the transistor β 17. The output signal of the synchronization gate circuit 49 is on Collector of transistor β 17 removed and forms the final output video signal at output terminal 110, which is fed to the input of the signal transmission device, which the. Facsimile sender connects to the facsimile receiver. The pending at terminal 172, the scanning corresponding control signal controls the video part of the synchronization gate circuit 49. This control signal is present during scanning, but not during retrace; at the return synchronization signals are generally introduced into the pulse train. The transistor β 27 serves as Inverter stage, and its output is connected to the synchronization gate circuit 49 via the diode 176. The synchronization gate circuit 49 is always activated when the video part one scan line occurs. The diode 176 and the

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Transistor β 27, on the other hand, locks the monitors 25 comes via the input terminal 187 Video signals before the input of the synchronization and the capacitor 189 to the transistor β 24 des gate circuit 49 when the return occurs. The noise suppression amplifier 27. The feedback terminal 174 can use any suitable control signal to branch this amplifier is set so that a similar control of the synchronization gates - 5 the ratio of the resistors 191, 193 and 195, Circuit 49 are supplied, then forming a voltage divider, the maintenance-effective circuit the synchronization gate circuit of a brightness control signal within a tion effected during the video portion of each scan line predetermined area. The outcome takes place. Control signal of the noise reduction amplifier 27

The in F i g. Threshold detector 273 io shown in FIG. 5 is connected to the control grid of the cathode ray tube is used to generate logic control and display- the capacitor 197 and the terminal 199 are supplied, signals. A signal from the first background evaluation in FIG. 7 is a composite voltage circuit 19 is shown to the transistor β18 of the threshold curve as a function of time, the value detector 273 via input terminal 274 to generate the dynamic reference signal guided. The control signals used during operation of the underground 15 are shown in FIG. The signal curve 201 evaluation circuit stored as a background level corresponds to a part of a typical video signal, negative signals control the transistor β18 in which the evaluation device 17 as a function of normal operation of the transmitter circuit conductive. By the modulated by the information and by the abden Conducting transistor β18 will also ersistor the trans-keyed document reflected light rays β19 conductive, which means that this 20 testifies to the collector. The normal video information signals lie A signal is generated that allows operation, for example, in the range of -3 volts, while the transistor the facility. For example, background or white signals between -9 and Gang 175 a lamp can be provided, which are the conductive -11 volts. Would all information signals be in the capable state of the transistor β19 indicates. A normal signal range could be in the normal signal range Way, the transistors β 20 and 25 ler reference signal level between the background and β 21 through the output signal of the first sub-information signal level for evaluating all information basic evaluation circuit, that the input of the transmission signals can be used well. The in Fig. 7 sistor β 18 is supplied, conductively controlled, both cases shown here make it clear that with signals by a signal with a corresponding level at 203 with low resolution and with signals 205 with Collector of the transistor β 21 and thus the corresponding signal level at the 30 high resolution Terminal 178 is generated, which indicates when the ent are not in the normal signal range. Such Speaking circuit parts effective or ineffective signals must, however, to generate a correct are sam. Facsimile copy can be evaluated correctly. How

In FIG. 6, an exemplary embodiment of the positive has been described, negative switch 177 and the noise suppression 35 dynamic control signals are generated according to the invention, namely in the reduction amplifier 27. With regard to the dependence on the amplitudes of the video signal. The positive-negative switch 177 has already been switched on. Control signals are linked in logic with FIG. 5 describes that the end circuitry for generating the dynamic reference valid video signal combines either normal or inverted signals. The signal curve 204 shows that can be transmitted. By switching on 40 through the background evaluation or the lower level of an inverter in the video circuit before its base level and represents a steady state, for example, the reproduction of blue voltage signal is possible, which is the average value of the documents in black and white. For this purpose, the degree of reflection of the background of the document is provided with a switch 179 which speaks the mode of operation. The signal curve 207 shows a signal that controls the transistor Q 22 either as an inverter or as a first detector circuit 35 as a function of the non-inverter. The video signal is supplied by the analog video signal 201. The output signal 207 video trigger circuit 47 (FIG. 5) is fed to the input of the first detector circuit 35 and the output terminal 181 and is applied to the base signal 204 of the second background evaluation circuit troden the transistors β 22 and β 23. The positive 21 are in the first logical linkage-negative switch 179 is connected via the diode 183 to the circuit 41 for generating the first dynamic base of the transistor β 22. Combined in the control signal 209 shown. This first dynamic switching position is the switch 179 in the control signal represents the more positive of the two non-inverted state. The output signal becomes input signals which are supplied to the first detector circuit 35 from the collector of the transistor β 23 via the terminal. The signal curve 211 corresponds to 185 the input of the synchronization gate circuit 55 is fed to the output signal of the second logic link 49 (FIG. 5) in the non-inverted state. The signal curve 213 corresponds. If the switch 179 is connected to ground, the positive-negative switch 177 operates in the inverted signal from the second detector circuit 33 for the output whose base level is shifted.
drove, and the information signals transmitted to the terminal As already discussed in connection with the F i g. 1 to 4 181 are supplied, are inverted and described by 60, the output signal of the collector of the transistor β 23 via the terminal 185 of the first logic circuit 41 and that of the input of the synchronization gate circuit 49 depending on the noise signal in its (F i g . 5) fed. Basic level shifted output signal of the second

As already mentioned in connection with FIG. 1 described detector circuit 33 in the second logical sequence, is the noise component of the sampling signal through 65 logic circuit for generating the dynamic detected by the noise monitor 25 and combined over the reference signal. The waveform 215 shows Cathode ray noise reduction amplifier - the dynamic reference signal. The dynamic touch fed. The output signal of the noise train signal, which depends on the amplitude

of the analog video signal is generated, follows the analog video signal within an envelope curve, which, when evaluating the background, is above the positive noise peaks of the background signal and when evaluating information somewhat more negative than the positive noise peaks of the background signal, d. H. is just below the negative noise peaks of the background signal. This allows the evaluation of signals 203 with a low level, even if the amplitude of the video signal is the normal video level not reached. Similarly, the dynamic reference signal enables the Evaluation of signals 205 with high resolution, even if the analog amplitudes between such Information signals do not reach the normal white or background level. How in connection with F i g. 2 represents that of the logic limiter circuit 29 and the video trigger circuit 47 is a digital signal. This digital signal corresponds to the information or black level corresponds to those amplitudes of the analog video signal that are above the dynamic reference signal.

A new type of circuit arrangement for evaluating signal parts of an analog Video signal described in which the background level changes over a wide range. Through Use of dynamic control signals that depend on the amplitudes of the video signal can be generated, and by combining these signals it is possible to evaluate the evaluation of a Facsimile equipment at low resolution without sacrificing the characteristics of the equipment high resolution.

Claims (12)

Patent claims: 1. Circuit arrangement for a facsimile system for generating a pure black and white signal from the information to be scanned, regardless of the respective brightness value of the Underground, with a scanning device for generating one of the information and the underground corresponding video signal, with an underground evaluation circuit part for generation a background signal proportional to the average brightness value of the background and with an evaluation circuit for generating a black-and-white signal from the Video signal which is controlled as a function of the underground signal, characterized in that that a first detector circuit for the positive peak rectification of the video signal (35) is provided, which is a first the positive rising edges of the video signal proportional control signal generated, and a first logic combination circuit (41) is provided which is controlled by this first control signal and the background signal and a first dynamic control signal generated, which corresponds to the more positive value of the supplied Signals corresponds to that further to the negative peak rectification of the video signal a second Detector circuit (33) is provided, which a second the negative falling edges of the Video signal proportional control signal generated, and a noise detector (37) is provided which generates a voltage which is the basic level of the generated by the second detector circuit (33) Control signal by one of the noise amplitude of the scanning device (17, 25, 27) corresponding Shifts level value and thereby generates a second dynamic control signal that also a second logic combination circuit (45) is provided, which consists of the first dynamic Control signal and the second dynamic control signal generates a dynamic reference signal, which corresponds to the more negative of the signals supplied to it and the evaluation circuit (29, 47) for generating the black-and-white signal from the video signal. 2. Circuit arrangement according to claim 1, characterized in that the polarity relationships are invertible. 3. Circuit arrangement according to claim 1 or 2, characterized in that the first Detector circuit (35) and the second detector circuit (33) each have a capacitor (55 or 71) and current direction-dependent switching elements (61, 63 or 75, 77) included to the Time constants for charging and discharging the capacitors (55 and 71) differ make, where the loading time constant for positive rising edges of the video signal for the Capacitor (55) of the first detector circuit (35) small and for the capacitor (71) of the second detector circuit (33) is selected to be large and the discharge time constant with negative falling Edges of the video signal for the capacitor (55) of the first detector circuit (35) are large and is selected to be small for the capacitor (71) of the second detector circuit (33). 4. Circuit arrangement according to one of claims 1 to 3, characterized in that the the first detector circuit (35) is preceded by a level converter (31) which determines the basic level of the video signal supplied to the first detection circuit (35) more negative. 5. Circuit arrangement according to one of claims 1 to 4, characterized in that the Sampling device (15, 17) a noise monitor determining the noise component of the video signal (25) is assigned, which controls the noise detector (37). 6. Circuit arrangement according to claim 5, characterized in that the noise detector (37) consists essentially of an amplifier element (QlO), of coupling switching elements (109, 111) for transmitting the output signal of the noise monitor (25) to the input of the amplifier element (QlO), a transformer (123) with a primary winding (121 ) connected to the output of the amplifier element (Q 10) and a secondary winding (125, 127) and a rectifier and filter arrangement (129, 131, 133) connected to the secondary winding (125, 127) ) and that an addition circuit (39) is also provided, to which the output signals of the second detector circuit (33) and the rectifier and filter arrangement (129, 131, 133) of the noise detector (37) are fed. 7. Circuit arrangement according to claim 6, characterized in that the addition circuit (39) is formed by a potentiometer (39), the rectifier and filter arrangement (129, 131, 133) forming the output of the noise detector with the two fixed terminals of the 009 550/295 Potentiometer (39) is connected, the output of the second detector circuit (33) with one of the fixed connections of the potentiometer (39) is connected and wherein the tap of the Potentiometer (39) with one input (137) of the second logic combination circuit (45) connected is. 8. Circuit arrangement according to claim 6 or 7, characterized in that a further controlled by the output signal of the second detection circuit (33) and the video signals Underground mixer (28) is provided, which is used for noise suppression in the evaluation circuit (29) supplied dynamic reference signal is used. 9. Circuit arrangement according to one of the preceding claims, characterized in that that the evaluation circuit (29, 47) consists of a logic limiter circuit (29) with two inputs and a video trigger circuit connected downstream of the logic limiter circuit (29) (47), one input of the logic limiter circuit being the dynamic reference signal and the other input being the video signal is supplied, wherein the logic limiter circuit (29) generates an output signal which corresponds to the more negative of the two input signals, and where the output signal the logic limiter circuit (29) is used to trigger the video trigger circuit (47) will. 10. Circuit arrangement according to claim 8 and 9, characterized in that the logic limiter circuit (29) and the underground mixer (28) are each formed by a transistor (Q 12, Q 14) which are of the opposite conductivity type, that resistors (e.g. B. 151) for transmitting the video signal to the base electrodes of the two transistors (Q 12, β 14) are provided and that the output signal of the second detector circuit (33) is fed to the collector of the transistor (Q 14) of the underground mixer (28). 11. Circuit arrangement according to one of the preceding claims, characterized in that the underground evaluation circuit part for generating the underground signal consists of a first underground evaluation circuit (19) and a second underground evaluation circuit (21) connected downstream thereof, that each of the two underground evaluation circuits (19, 21) has one Has charging capacitor (91, 97) and that each of the two underground evaluation circuits (19, 21) also has switching elements (Ql, Q 2 or β 4, Q 5) for controlling the charging and discharging of the capacitors (91, 97), wherein the voltage level at the capacitor (97) of the second background evaluation circuit (21) corresponds to the average reflectance of the background of the scanned document. 12. Circuit arrangement according to claim 4, characterized in that that of the first detector circuit (35) upstream level converter (31) at least one for positive video signal amplitudes in the forward direction polarized diode (141, 143). For this purpose 2 sheets of drawings