DE2140561C3 - Circuit arrangement for obtaining contour information from a video signal - Google Patents

Description

X-ray scanner, recorder, or any other device that provides similar information delivers, is delivered. This video signal is for two different line times in FIG. 2a put there

The input 1 is connected to an input of a video signal processing circuit 3 connected, the pulse signal input 5 with an output 7 of a pulse generator 9 is connected by a sync signal of the one connected to input 1 input 11 supplied video signal is synchronized,

In the video signal processing circuit 3, the DC component of the video signal is preserved or restored.

The input 5 of the video signal processing circuit 3 supplied pulse is a so-called window pulse, like this one in FIG. 2b is shown with the If desired, an unimportant part of the image to be examined can be blanked.

A video signal then appears at an output 13, as shown in FIG. 2c is shown

In the F ·. G. 2a and 2c are dashed by horizontal ones Lines indicated the levels on which in the two shown side by side, in different Parts of the image and consequently the video signals appearing in different line times have levels can, whereby a contour information would have to be obtained in order to properly utilize the same to be able to realize. These levels depend on the signal content of the video signal.

The correct contour information is maintained in a contour determination circuit 15 according to the Invention.

The contour determination circuit 15 has a video signal input 17, which is connected to the output 13 of the video signal processing circuit 3, and successively includes a buffer circuit 19 which has an erase circuit 21 and a read-only memory circuit 23, a level changing circuit 25, and a level comparing circuit 27.

The buffer memory circuit 19 receives at an input 29 that of the input 17 of the contour determination circuit 15 supplied video signal. This signal becomes the base of an emitter follower npn transistor 31 supplied and via a after a negative supply voltage of -12 V peschalten Emitterwiderstaiid 33 reproduced the collector of the Transiscors 31 is connected to a positive supply voltage of + 12V.

The video signal at the emitter resistor 33 is also at the base of a pnp transistor, the emitter of which is over a resistor 37 to an O-terminal of a supply source and whose collector is connected to a negative voltage of -6 V via a capacitor 35 is supplied by a voltage divider with a resistor 41 and a Zener diode 43. The condenser 39 is bridged by a field effect transistor 45 of the memory erase circuit 21

The transistor 35 now serves as a video signal current source and charges when a video signal occurs Capacitor 39, which thereby receives a charge and consequently a voltage that depends on the image content and in this case has an integrated value of the video signal stream. The course of the voltage on Capacitor 39 is shown in FIG. 2f

The field effect transistor 45 of the memory erase switch & 5 device 21 is connected to the control electrode via a resistor 47 to the collector of a pnp transistor 49. This collector is further connected to the supply voltage of -12 V via a resistor 51. This The base of the transistor 49 is connected to a supply voltage of +6 V and the emitter is connected to a resistor 53 at the supply voltage of + 12V. The emitter is also fed by an output 55 of the pulse generator 9 resulting pulse is supplied, each after the occurrence of the sync pulse in the video signal This is shown in FIG. 2d shown

The connection of the collector of the transistor 35 to the buffer storage capacitor 39 is further above a field effect transistor 57 with a capacitor 59 and with the control electrode of a field effect transistor 61 connected. The other side of the capacitor 59 is connected to an O line of the supply. The control electrode (gate) of the field effect transistor 57 is connected to the collector of a resistor 63 pnp transistor 65 connected. This collector is also connected to the supply voltage via a resistor 67 of -12 V. The emitter of the transistor 65 is connected to the +12 V supply voltage via a resistor 69 connected and also receives a pulse originating from an output 71 of the pulse generator 9 supplied, which is shown in FIG. 2e is shown. This Im pulse occurs at the leading edge of the sync pulse in the video signal and goes beyond the pulse according to FIG. 2d before.

The transistors 57, 61 and 65 and the capacitor 59 form part of the read-only memory circuit 23. One The output electrode of the transistor 61 is connected to the supply voltage -12 V via a resistor 73 and is further connected to an input 75 of the level change circuit 25, which is further connected to an input of a Differential amplifier 77 is located, the other input with an adjustable, through a capacitor 79 decoupled voltage divider 81, 83 between 0 and -12 V is connected.

The signal fed to the input 75 of the level changing circuit 25 is shown in FIG. 2g. Depending on the signal content of the preceding line trace time, a level value is obtained which is matched by the Voltage divider circuit 81, 83 determined value continued at an output 85 of the differential amplifier 77 delivered and fed to the emitter of a pnp transistor 87 serving as a clamp switch, the Base one occurring during the back porch of the sync pulse of the video signal Clamping pulse, which originates from an output 88 of the pulse generator 9, is supplied. The collector of transistor 87 is connected to a capacitor 98 and to an input 91 of the level comparator circuit 27 connected. The other side of the capacitor 98 is connected to a video signal input 93 of the level change circuit, which is connected to the output 13 of the video signal processing circuit 3. As a result of the clamp switch 87 becomes the black level in the video signal at the input 91 of the level comparison circuit 27 each clamped to a level that corresponds to the image content of the previous line time Video signal is dependent on which level occurs at the emitter of the clamp switch 87. This is in F i g. 2h, in which the level is indicated by a horizontal dashed line above which the Level comparison circuit 27 gives an output voltage. The output voltage of the level comparison circuit, which can be, for example, a limited differential voltage amplifier or a Schmitt trigger in Fig. 2i shown. This waveform contains the information related to the contours in the image that are necessary for

a surface determination of the part of interest of the recorded image are important.

This surface determination is further performed by a surface determination circuit 93, which is operated by a programming circuit 95. The programming circuit 95 is again from Pulse generator 9 controlled.

Further in FIG. 1 shows a picture display device 97 on which, if desired, the video signal can be converted into an image.

The mode of operation of the video contour determination circuit is now illustrated in FIG. 1 and 2 closer explained.

The video signal according to Fig.2c at the input 17 is Via the emitter follower 31 and the transistor 35 acting as a current source into a charging current of the capacitor 39 converted. This capacitor 39 is due to the pulses according to FIG. 2d initially discharged, after, as a result of the impulses according to FIG. 2e the voltage on the buffer storage capacitor 39 to the Read storage capacitor 59 has been transferred. This transfer of voltage takes place during the Period of time fi - ß or fii - fi2, in which the field effect transistor 57 as a result of the from the with the impulses according to Fig. 2e controlled transistor 65 delivered positive impulses is conductive. The subsequent discharge of the buffer storage capacitor 39 takes place during the period ft - to or / 13 - fn, in those of the field effect transistor 45 as a result of the from the with the pulses according to F i g. 2d controlled transistor 49 emitted positive impulses is conductive. During the rest of the time, the transistors 45 and 57 are blocked.

The current, which is supplied by the transistor 35 and is dependent on the amplitude of the video signal, to the buffer storage capacitor 39 in the time segment β-te or fts-fig causes the voltage across this capacitor to change, as shown in FIG. 2f is given up to one in time

during the period fs - te or fts - fie conductive and is therefore still blocked.

The voltage on the read storage capacitor 59 now always corresponds to that in the previous line time reached voltage at the buffer storage capacitor 39 and is connected to the input 75 via the transistor 61 of the differential amplifier 77 is supplied

Via the differential amplifier 77 , the voltage level obtained is increased in the opposite sense by the setting voltage of the voltage divider 81, 8; continuously transmitted to the terminal switch 87, which is conductive during the time segments ti - h or / 13 - η 4 and, as in FIG. 2h represents the level of the video signal at the input 91 of the level comparison circuit adapts each Weil to the picture content of the video signal of the previous line time, so that a quick correction of this level is obtained and the influence of interfering picture elements is corrected immediately.

In the above, the buffer storage capacitor 39 forms with the transistor 35 an integrator. Although If this is a favorable combination, it is also possible to set a maximum or To store minimum value or a mean value lying between the maximum or minimum if, instead of the integrator, one or more detection circuits in the buffer memory circuit IS be used.

Instead of always adjusting the level in the video signal, it is of course also possible to adjust the comparison level the level comparison circuit 27, which is now constantly on the in Figure 2h by dashed lines was held to adjust and the video signal at a constant level of the level comparison circuit 27 feed.

The blanking of the video signal outside the line retrace times can be omitted if desired.

A level determination that takes place every two or more lines is of course also possible, as well as a determination of an average level which takes place every two or more lines.

Because analog signals are used, capacitors are used as storage elements; should however, if for some reason it is desired to use digital signals, then, if so desired use other types of storage.

rCi Jit ve.wciiucien transistors and supply voltages it applies that these serve only as an example and are not essential for the invention per se.

Although the contour determining circuit has been used in a cardioplanimeter in this case, can be used in other areas of application, such as isodensity chart recorders, for which a correction of the isodensity level is desired.

For this purpose 2 sheets of drawings

Claims (3)

Patent claims: 1. Circuit arrangement for obtaining contour information from a video signal, which Circuit includes a level comparison circuit coupled to a video signal input thereof, to which a level changing circuit is coupled, whereby the level in the video signal to which the the level comparison circuit corresponds to contour information to be obtained from the video signal, can be changed and wherein the level comparison circuit is one with a video signal input of the video contour determination circuit coupled input, characterized in that with this input a buffer memory circuit (19) is coupled, to the output of which a read-only memory circuit (23) is coupled, which buffer memory circuit a memory erase circuit (21), while an output (75) of the read-only memory circuit is coupled to the level changing circuit (25) and wherein the read-only memory circuit (23) and the cancellation circuit (21) each with a pulse signal output (71, 55) of a pulse generation circuit (9) are coupled to which, in operation, one after the other with synchronizing signals in the video signal synchronized pulses occur. 2. Circuit arrangement according to claim 1, characterized in that the buffer memory circuit (19) is a power source circuit (35) which is controlled by the video signal and is coupled to a first capacitor (39), which first capacitor (39) is provided by an electronic switching element (45) which acts as a cancellation circuit ) is bridged, while the first capacitor (39) is connected via a further electronic switching element (57) to a second capacitor (59), which further electronic switching elements (59) and the second capacitor (59) forms the read-only memory circuit (23) and wherein a control input of each of the electronic switching elements (45, 57) is coupled to a corresponding output (55, 71) of the pulse generation circuit (9). 45 The invention relates to a circuit arrangement for maintaining contour information from a Video signal, which circuit has a level comparison circuit coupled to a video signal input of the same to which a level changing circuit is coupled, whereby the level in the video signal, to which the contour information to be obtained from the video signal by the level comparison circuit corresponds, is changeable and wherein the level comparison circuit is connected to a video signal input of the video contour determination circuit contains coupled input. From "Work in Progress", Issue 94, 1970, pp. 203 to 205, a circuit arrangement of the above-mentioned type is shown known, wherein the contour information obtained is used to maintain a measured variable that the surface within corresponds to the specific contour in the video signal to be displayed on a display tube. A manually adjustable level change circuit is provided in the level comparison circuit. A disadvantage of such circuits is that as a result the irregular image structure of the object from which the video signal is received and in which, for example unwanted parts of the image occur, a change that is also dependent on these unwanted parts of the image of the level in the video signal to which the contour information corresponds. The aim of the invention is to largely reduce this disadvantage. A video contour determination circuit of the type mentioned has according to the invention Indicates that a buffer circuit is coupled to the input of the level comparison circuit is, to the output of which a read-only memory circuit is coupled, which buffer memory circuit is a Memory clear circuit includes, while an output of the read memory circuit with the level changing circuit is coupled and wherein the read-only memory circuit and the erase circuit each with a pulse signal output a pulse generation circuit are coupled to which in operation one after the other with synchronizing signals synchronized pulses occur in the video signal. By using a buffer circuit in which a desired image content information, for example a maximum, minimum or mean value from the video signal from a line time is stored, the is a measure of the desired level change, and by using a read-only memory circuit, the this image content information can be extracted in a subsequent line time, while the buffer memory then, after deleting the same, it is filled with new information again, can be very quick and accurate level information is obtained which, after being supplied to the level comparison circuit, is sent to the Type of video signal adapted contour information results. To maintain maximum or minimum values or compositions of the same from the Video signal detector circuits can be used. It has been found that for cardioplanimetry /: wekken a favorable filling of the buffer memory through an integration of the video signal information about that Part of a line time in which this is important can be obtained. It should be noted that the use of a buffer memory circuit having a clear circuit and a Read memory circuit for a device in "Elektromedizin", Volume 12/1967, No. 3, p. 93 published X-ray video densitometer is known. In this case, this circuit combination is used to measure the influence a contrast agent used in x-rays. An embodiment of the invention is shown in the drawing and is described in more detail below. It shows F i g. 1 shows a schematic representation of a possible embodiment of a cardioplanimeter recorded video contour determination circuit according to the invention, F i g. Figure 2 is a plot of waveforms as a function of time in two different line times at different points in the circuit according to FIG. 1 occur. In Fig. 1, a video signal is fed to an input terminal 1 of a cardioplanimeter, which is transmitted by a X-ray image of a heart originates and, for example, from an X-ray television camera, a