NL8004514A - TELEVISION CAMERA. - Google Patents

Description

Ca / Sch / eh / 1153

Television camera.

The invention relates to a television camera and in particular a television camera, in which a so-called microcomputer is used for performing various corrections of a video signal and for providing remote control of a video tape device by means of a simple construction, such that when used in In conjunction with a video controller, the video signal from the camera can be easily normalized by the signal from the controller.

10 For example, when the white balance of a television camera is adjusted, the television camera first records a white object. Then, the level of the luminance signal Y in the color difference signals (R-Y) and (B-Y) is adjusted so that the level of the color difference signals coincides with that of the video signal during the blanking interval.

When only one television camera is used for one videotape device, the video signal and also a control signal for controlling the start, stop, etc. of the videotape device are supplied from the camera to the videotape device, while the videotape device provides a control to the camera -signal for commanding the ready-to-operate state, etc., is supplied. In this case, the signal lines for these signals are combined into a single cable and jointly connected to the camera by a number of pins.

Furthermore, there is the case where a number of the above-mentioned cameras are selectively used for recording an object or scene using a camera controller. In this case, the phase of the vertical and horizontal sync signals and subcarrier signals, ground levels, luminance levels, chroma levels, etc., of the different cameras should be the same. For this purpose, control signals for the above objects, etc. are supplied by the camera controller to the respective cameras.

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The dedicated signal lines are also bundled into a single cable and connected to the cameras.

Between the case where the cameras are connected to the videotape device and the case where the cameras 5 are connected to the camera controller, the content of the signals transferred therebetween differs from each other, so that the operations performed by the cameras also differ.

In general, a camera has only one output connector, so that the camera can only be connected to a videotape device or an earnera control unit (CCU = camera control unit).

With the above arrangement, when the video signal is processed and recorded in the case where the video signal of the camera is subjected to adjustment and adjustment operations, the prior art adjusts the level of the video signal manually, while also a control switch for the video tape apparatus for starting and stopping the tape transport is also manually operated. However, with these techniques, two operations are performed simultaneously, so that the operation is complicated and an incorrect operation can take place. There is also a drawback that the adjustment time and the adjustment time are not constant.

It is therefore an object of the invention to provide a tele vision camera, in which use is made of a microcomputer for carrying out various operations, for instance a balancing operation and a. alignment operation, etc., and has a simple construction.

Another object of the invention is to provide a television camera, which is preferably used in a case where, if some of the television cameras are selectively used for recording an object and processing the video formed on it -35 signals, after which the edited video signals are recorded on a videotape device, the synchronization relationship, the signal levels, etc., can be easily equalized between the different cameras by means of an 8004514-3 microcomputer without requiring manual operation of a user.

A further object of the invention is to provide a television camera in which a microcomputer is added. appropriate so that, if a number of cameras are used, the white balance of each camera and the level control of the color signals of the respective cameras can be easily adjusted by means of the microcomputer.

Yet a further object of the invention is to provide a television camera with a switch and a microcomputer, by means of which the start and stop operation of a videotape device can easily take place and also the control of the adjustment and adjustment of the camera. output signal can easily take place.

According to an aspect of the invention, a tele vision camera is provided for adjusting the video balance of a video signal output from a video recording tube, using a microcomputer with a central processing unit, an exclusively readable memory or ROM (read only memory) and a uniformly accessible memory or random access memory (RAM) with a number of addressable memory locations, comprising: a) adjustable video signal control means for providing a set or balanced video signal, which may vary under the influence of one of the said microcomputer · from control signal? b) first switching control means for selectively outputting to the microcomputer a data signal corresponding to the set video signal from the adjustable video signal control means or other input control means; c) digital / analog conversion means for converting a microcomputer digital data signal into an analog data control signal; D) signal holding means for holding the value of the analog data signal; e) second switching control means for selectively feeding the calculated data stored in the microcomputer to the signal holding means in relation to said different addressable memory locations of the microcomputer; f) an input connection of the television camera, 5 to which a supplied camera control signal to be calculated in the microcomputer is supplied by the connected control unit, for instance a tape device, a camera control unit and so on; and g) an output terminal of the television camera, 10 to which a microcomputer computed system control signal is available for the externally connected unit.

Further features and particulars of the invention will be mentioned and elucidated with reference to the accompanying. drawing. Herein: figure 1 shows a systematic block diagram of an embodiment of the television camera according to the invention; FIG. 2 is a waveform diagram of a series-coded signal from the camera control unit used in the exemplary embodiment of the invention of FIG. 1; and Figures 3-5 flow charts for explaining the operation of the exemplary embodiment of the invention shown in Figure 1.

Figure 1 shows an embodiment of the television camera according to the invention; herein the number 25 1 refers to a television camera, 2 to a VTR (video tape recorder * videotape device), 3 - to a CCU (camera control unit), and 4 to an object to be recorded.

The light coming from the object 4 is projected via an ifis diaphragm 10 and an optical lens 11 onto a pick-up tube 12. The horizontal and vertical synchronizing signals from a synchronizing signal generator 13 are supplied to the pick-up tube 12, which forms a video signal of the object 4 thereon. This video signal is supplied by an editing circuit 14 to an output terminal 1a, which is connected via a signal line 5a or 6a of a cable 5 or 6 to an input terminal 2a of the VTR 2 or an input terminal 3a of the CCU 3. A number of 8004514 - 5 - cameras 1 ,, 1 ,,, .... 1 is also connected to the CCU 3, and 12η a number of normalized video signals from the CCU 3 are sent via a switching unit or mixing unit 30, which serves for giving a special effect to an image to be displayed, fed to a VTR 31 for registration.

In the camera 1, the correction, and so on, of the video signal is performed by a microcomputer 15. This microcomputer 15 comprises a CPU (central processing unit = 51), a ROM 52, in which the processing program and so forth of the CPU 51 are stored a RAM 53 for storing data, etc., as well as an input and an output circuit 55 and the like. In this case, the CPU 51, the ROM 52 and the RAM 53 are interconnected by an address bus line 55, a data bus line 56 and a control bus line 57. The CPU 51 is connected via the data bus line 56 and the control bus line 57 to the input and output circuit. 54.

In this case, the above-mentioned elements are in the form of a 20-chip large-scale integrated circuit. (One chip LSI = large scale integrated circuit).

The color difference signals (RY) and (BY) originating from the processing circuit 14 are applied to a selection unit 56 at the contacts a and b, and serving a setting time for the adjustment time and the adjustment time. Potentiometer 17 voltage signal is applied to the selection unit 16 at the location of the contact c. This selection unit 16 is switched by a selection signal coming from the microcomputer 15 via a signal line L1. The signal from the selection unit 16 is applied to a hold circuit 18 and the signal therefrom is fed to a comparator 19. The content at a desired address of the RAK 53 in the microcomputer 15 is supplied to a D / A converter 20 (digital / analog converter) 35 for conversion into the corresponding analog signal, which is then also sent to comparator 19 is supplied. Its output signal is supplied to the microcomputer 15.

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The output of the D / A converter 20 is also supplied to a selection unit 21, which is switched under the influence of the selection signal from the computer 15 via a signal line L2. The signals 5 at the respective contact points a, b, ... i of the selection unit 21 are respectively applied to holding circuits 22a, 22b, ... 22i. The signals from the holding circuits 22a - 22f are supplied to the processing circuit 14, the signals from the holding circuits 22g and 22h are supplied to the synchronizing signal generator 13, and the signal from the holding circuit 22i is supplied to a control circuit circuit {not drawn) for the iris diaphragm 10. The processing circuit 14 comprises various correction and adjustment circuits for γ-correction of the recorded video signal, the white balance and the ground settings and so on, a synthesis circuit for the luminance signal and color difference signals , an NTSC encoder, and so on. The drawn block of the processing circuit 14 shows only a portion of the white balance adjuster.

The signal corresponding to the vertical blanking interval from the synchronizing signal generator 13 is applied to the computer 15 and during the interval of this signal, the values of the holding circuits 22a-22i are updated by the interrupt process.

A white balance adjustment switch 23 and a remote control switch 24 for the VTR 2 are connected to the computer 15. The signal from the computer 15 is supplied to an integrator 25.

A control signal is supplied to a terminal 3b of the CCU 3 for controlling the phase of the synchronization signal and subcarrier signal, the ground level and the luminance level, the chroma level, and so on. The terminal 3b is connected to the terminal 1b of the camera 1 via a control line 6b of the cable 6. The signal supplied to the terminal 1b is supplied to the computer 15. If in this case the above-mentioned control 8004514 · '· - 7 - signal is designed as digitally encoded series signal, a number of control signals can be transmitted via a single control line.

Figure 2B shows an embodiment of the series-5 signal. In this exemplary embodiment, after a start signal consisting of more than 2 bits, which continuously show a high level, a 4-bit identification code, a 3-bit address code and a 8-bit data code are sequentially arranged. On the basis of the identification code, it is determined by the computer 15 whether the camera 1 is controlled analogously or digitally for its operation. The analog editing control includes, for example, control of the iris diaphragm, ground level, chroma level, and phase shift of the color subcarrier signal, while digital editing control includes, for example, a white balance adjustment start signal for camera 1 switching. the address code, which operation is performed to adjust the ground level, the chroma level or the like for the video-20 signal. The 8-bit data code is also read in to determine the degree of control of the camera 1. If desired, the data code can be expanded or compressed. Furthermore, reading in the series signal is achieved for the interrupting process.

Figure 2A shows a series signal with a ground level setting code a, a chroma level setting code b and a white balance setting start command code c; Figure 2B shows the code a described above in detail. The above-described series signal can be transmitted at any time, at which the direction of the camera 1 is changed, the exposure state of a studio is changed, and so on.

The computer 15 outputs a signal associated with the operation of the switch 24 and this signal is applied to a T-flip-flop 26 at its trigger terminal 35 T. The output signal from the flip-flop 26 is output at its output Q a connection 1c, the potential signal at the location of which 8004514-8 is supplied to the computer. The terminal 1c is also connected to a terminal 2c of the VTR 2 via a line 5c of the cable 5 and the terminal 2c is in turn connected to a system control circuit 27 of the VTR 2. In this manner, the signal from the terminal 2c is supplied to the system control circuit 27 for controlling the start and stop of the VTR 2.

The connection 1c is also connected via a line 6c of the cable 6 to a connection 3c of the CCU 3 and the connection 3c is in turn connected to a return switch 28 of the CCU 3. When the return switch 28 is closed, the connection 3c gets a high potential or a high level. In this case, the number of return switches 28 is chosen equal to the number of cameras connected to, for example, the CCU 3, and only that camera, of which the corresponding return switch 28 is closed, is in operation. Further, when the return switch 28 is closed, a lamp disposed in the viewfinder of the corresponding camera is on to indicate that the command has been started by the CCU.

When the terminal lc of the camera 1 is connected to the terminal 2c of the VTR 2, since the terminal is. 2c is connected to the system control circuit 27 on its input side, its impedance high. On the other hand, when the terminal 1c is connected to the CCU 3, since the terminal 3c is connected to the return switch 28 on its output side, its impedance is low.

The program stored in ROM 52 will be described with reference to Figure 3.

When the power supply is turned on, the impedance at terminal 1c is first detected or checked at a step (1). When the detected impedance is low, a flag F of the controller operating state is set to the value "1" at a step (2), whereas, when the detected impedance is high, the flag F at a step (3) is given the value "0".

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Then, in a step (4), the switches, the memory, etc., are brought into starting position. Thus, at the step (4), the switches, for example the selection units 16, 21, 5 to be controlled by the computer 15, as well as the memory values of the respective memory areas of the RAM 51 of the computer 15, are set to predetermined values . The initial values can be changed by the external units, which are connected to the terminals 1a-1c of the camera 1.

10 At the stage of the step. (5) the flag P is discriminated against. If this flag F has the value "1", one is obtained in a step (6). state in which the interrupting process for reading in the series signal from the CCü 5 becomes possible. Therefore, when the series signal 15 is supplied by the CCU 3 to the computer 15 in a state where the interrupt process can take place, the main routine of the computer 15 jumps to such an interrupt process routine or program that the series signal is read in dominating and calculated. When the flag F has the value "0", the computer 15 is not operated by the series signal but by the manual switch and so on, associated with the camera 1.

In step (7), it is discriminated against or checked whether the white balance is adjusted or not. If the white balance is not adjusted, in a step (8) it is checked whether the switch 23 is operated or not. If switch 23 is actuated, the routine or process proceeds to an automatic white balance routine (100).

This routine 0.OQ) will be described in detail with reference to the flow chart according to figure 4. When the routine (100) is called up, at the location of a step (101) the selection units 16 and 21 are first switched to the RY side (contact a).

Then, at a step (102), the computer 15 outputs a digital reference value, for example "80" (in this case, the number enclosed in quotation marks represents the number in the ten-digit array); this value becomes. set in the hold circuit 22a via the D / A converter 20.

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Then, at a step (103), the sampling pulse corresponding to the blanking interval is applied to the selection unit 16.

Then, at a step (104), the level of the signal from the hold circuit 18 is stored at a first memory address of the RAM 53 in the computer 15. This memory is implemented by correcting the content of the first memory address. that the contents of the first memory address are read out through the D / A converter 20, its output voltage is compared by the comparator circuit 19 to the input level, and the comparison output signal is made zero such that both levels coincide.

In the next step (105), the sampling pulse corresponding to the video-15 interval is applied to the selection unit 16.

At step (106), the level of the signal from the hold circuit 18 is stored at the second memory address of the RAM 53 in the computer 15.

Thus, the level of the video signal in the blanking interval is stored at the first memory address of the RAM 53 and the level of the video signal in the video interval is stored at the second memory address of the RAM 53.

The following calculation takes place at the step (107).

- (the content at the location of the second memory address M2) - (the content at the location of the first memory address M1).

In this way, the value Δ corresponds to the deviation from the white balance.

At the step (108), an operation takes place in which the content of the second memory address is replaced by a value obtained by subtracting the value Δ from "80", if the above calculated value A is positive , but the value A is added to "80", ** A «* if the calculated value is negative.

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At the step (109), the content M2 is delivered to the output at the location of the second memory address and is supplied via the D / A converter 20 to the hold circuit 22a. In this manner, the potential corrected by the above calculation result is set in the hold circuit 22a. For example, the level of the luminance signal Δυγ to be added to the color difference signal (R-Y) is adjusted by the corrected potential such that the level of the color difference signal (R-Y) comes very close to the level during the blanking interval.

Up to the above processes, the white balance of the color difference signal (R-Y) is roughly adjusted. If necessary, the white balance is further fine-tuned by means of the following procedure.

At the next step (110), it is checked or discriminated whether the content M2 at the second memory address is within a predetermined, controllable interval or not.

If the content H2 is outside that interval, namely if the content M2 is excessive "00" or "FF" (F-15), at the location of a step (111) the indicator 25 presents an error. Then, the adjustment process for the color difference signal (RY) is not performed, and the process proceeds to a step (1201 for adjusting the color difference signal (BY). At this time, the computer 15 is no longer able to adjust the white balance, so that it is necessary to change the filter, etc., in the optical lens system of the camera 1 manually.

However, when the content M2 is within the controllable area, at the location of a step (112), the content M1 is output at the location of the first memory address, supplied through the D / A converter 20 to the comparator 19 and in level compared to the color difference signal (RY).

35 At a step (113), the comparison output signal is discriminated. When the level of the color difference signal (R-Y) is higher than the level.

o η n / R 1 λ - 12 - from the content Ml, at a step (101) the value "1" is subtracted from the content M2 of the second memory address, while, when the first level is lower than the latter, at the location of a step (jL 15), the value 111 ”is added to the content M2.

Furthermore, at a step (116), a repeated number N of the above operations is checked. If the number N is less than, for example, 15, the process returns to step (109).

If the 16th operation is detected at a step (116) (N = 16), the process proceeds to the step (120). As a side note, if the initial value is within the controllable range, the adjustment will be completed within 16 operations.

At the step (120), first of all, the respective selection units 16 and 21 are switched to the BY-side fur act b) and a similar setting as that of the color difference signal (RY) will be made for the color difference signal (BY ) using the first 20 and the third memory addresses.

By the above operations, in the operation circuit 14, the adjusted luminance signals, / Yr, are added to the color difference signals (R-Y) and (B-Y), respectively, so that the color video signal having the correct white balance is obtained.

When the adjustment of the color difference signal (B-Y) is completed, the process returns to the Htoofd routine.

Referring again to Figure 3r at location 30 of step (9), flag F is discriminated against. If F = 0, a step (10) is checked whether the switch 24 is operated or not. If this switch 24 is operated, the process proceeds to a routine (200) for controlling the VTR 2.

This routine (200) will be described in detail with reference to the flow chart of Figure 5. When the routine (200) is called, at an 8004514-13 step (201), the selection units 16 and 21 are switched to the contacts c. In this manner, the voltage set by potentiometer 17 is A / D converted and then stored at a fourth memory address 5 of RAM 53 in computer 15.

At the location of a step (202) it is discriminated whether or not the stored voltage M4 is higher than a certain value.

If the voltage M4 is lower than that particular value, the process proceeds to a step (203) and then the trigger signal is applied to the flip-flop 26.

At the next step (204), at the location of a fifth memory address of the RAM 53 in the computer 15, a digital value is set, for example, "FF", 15 which represents the gain of the gain control circuit for the adjustment and adjustment, present in the processing circuit 14, maximizes. This digital value M5 is applied through the D / A converter 20 to the hold circuit 22c for adjustment thereof. Then the process returns to the main routine.

At the step (202), when the voltage M4 is higher than a certain value, the process proceeds to a step (205) for checking whether or not the output of the flip-flop 26 is high.

When the output of the flip-flop 26 is low, the process is performed along the lines of the program, as well as in the following steps (206) - (210).

Namely, at the step (206), a digital value "00", which minimizes the gain of the gain control circuit, is set at the fifth memory address of the RAM 53. This digital value M5 is set by the intervention of the D / A converter 20 set in the hold circuit 22c.

At the step (207), the trigger pulse 35 is applied to the flip-flop 26.

At the step (208), the delay of (the content M4 at the fourth memory address) x N (ms) is performed.

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At the next step (209), the value "1" is added to the content M5 at the fifth memory address. This digital value is applied through the D / A converter 20 to the hold circuit 22c 5 for adjustment thereof.

At the step (210), it is discriminated whether or not the content M5 at the fifth memory address has the value "FF". If this content M5 is not "FF", the process returns to step (208). Since the content M4 at the fourth memory address corresponds to the signal representing the unit time of the balancing, balancing takes place for a predetermined time under the effect of completing steps 208-210.

If the content M5 at the location of the fifth memory address acquires the value "FF", the process returns to the main routine.

When the output of the flip-flop 26 at the step (205) has a high level, the 20 steps (211), (212) and (213), or the trimming program, are executed.

Namely, at the step (211), the delay of size (the content M4 at the fourth memory address) x N (ms) occurs.

At the location of the next step (212), the value "1" is subtracted from the content M5, after which the digital value thus obtained is applied via the D / A converter 20 to the hold circuit 22c.

At the step 213, it is discriminated whether or not the content M5 at the location of the fifth memory address has the value "00". If the content M5 is not "00", the process returns to the step (211).

When the content M5 obtains the value "00" at the step (213), the process proceeds to the step 35 (203) and the trigger signal is applied to the flip-flop 26.

At the step (204), the value "FF" is set at the fifth memory address, the corresponding voltage is set in the hold circuit 8004514 - 15 - circuit 22c, and then the process returns to the main routine . In this manner, the alignment operation is performed for a certain time interval at the steps (211) - (213).

As shown in Figure 3, at the location of a step (11), the various subroutines for controlling the VTR 2, the interrupt process, and so on, are executed, and then the process returns to the step (7).

The above operations can be simplified or summarized in the following manner: when the power of the camera 1 is turned on, it automatically discriminates whether the VTR 2 or the CCU 3 is connected thereto, after which the camera 1 is turned into the corresponding operating state set.

Furthermore, when the switch 23 is closed, while the camera 1 records a white object, the white balance of the video signal is set. When the color difference signal (BY) setting is completed, the respective correction signals for performing the white balance setting of the color difference signals (RY) and (BY) are stored at the second and third memory addresses of the RAM 53 in the computer 15, in the form of digital values.

If the switch 24 is opened while the VTR 2 is stopped, the digital value will cause the video signal level to be set to its minimum value at the fifth memory address of the RAM 53.

Then, the signal at the terminal 1c for controlling the VTRs is made high and at each time set by the potentiometer 17, the content at the fifth memory address increases. In contrast to the above, when the switch 24 is closed while the VTR 2 is driven and then brought into the stop operating state according to the VTR 2, at each time set by the potentiometer 17, the content at the location of the fifth memory address. After the digital 8004514-16 value has been reduced to its minimum, the signal at the terminal 1c for controlling the VTRs is low. Then, at the fifth memory address, the content returns to the maximum value.

These digital values are output sequentially in the interval of, for example, the vertical sync signal and set in the latches 22a, 22b, and 22c, whereby the white balance adjustment, balancing operation, and balancing operation can take place.

Furthermore, the various control signals from the CCU 3 are transferred to the camera 1 in the form of series signals and stored at the respective memory addresses of the RAM 53 of the computer 15. Subsequently, these digital signals are output at the output in sequence. the interval of the vertical sync signal, and set in the latches 22d-22i to perform the control of the respective parts of the camera 1.

According to the invention, it is possible to omit part of the main routine of the computer 15. For example, steps 1-3 can be omitted, discrimination of the external instruments connected to the terminal 1b of the camera can be performed by another method, without using a microcomputer, and the process continues from step (4 ).

As described above, various settings can be made according to the present invention. In the present case, a microcomputer is used according to the invention, so that complicated adjustments can easily be made on the basis of the program, so that the construction of the circuit as such can be simple.

The invention is not limited to the exemplary embodiments described above and shown in the drawing. Various changes in the components and their interrelationships can be made without thereby exceeding the scope of the invention.

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Claims (6)

Television camera for adjusting the video balance of a video signal output from a recording camera tube, comprising a microcomputer with a central processing unit, a read-only memory (ROM = 5) and a uniformly accessible memory (random access memory) = RAM) having a number of addressable memory locations, characterized by: a) adjustable video signal control means for outputting a set or balanced video signal, which may vary under the influence of a control signal from the microcomputer; b) first switching control means for selectively outputting a data signal corresponding to the set video signal from the adjustable control means or other input control means to the microcomputer; c) digital / analog converting means for converting a microcomputer-derived digital signal into an analog data control signal; D) signal holding means for holding the analog data signal; e) second switching control means for selectively supplying the calculated data stored in the microcomputer to the signal holding means in relation to said different addressable memory locations of the microcomputer; f) an input terminal of the television camera, to which a microcomputer calculated camera control signal is available from the connected control unit, for example a VTR, a camera control unit and so on; and 30 g) an output terminal of the television camera from which a microcomputer computed system control signal can be output to the externally connected unit. 2. Television camera according to claim 1, characterized in that the camera comprises a circuit for a main calculation routine for checking the type of externally connected unit, eg said VTR, the camera control unit. and other units, and setting an initial setting value of the memory location of the microcomputer depending on the control output signal. Television camera according to claim 1, characterized in that said camera comprises at least one circuit for the main calculation routine for setting a white balance of a composite video signal, consisting of a luminance component and a color difference signal component, under the influence of the determined sequence, as calculated by the microcomputer. Television camera according to claim 1, characterized in that the camera comprises at least one main calculation routine for controlling the operating state of said VTR, comprising an adjustment effect and / or an adjustment effect of the output video signal of the camera, in accordance with the operating condition of the VTR. Television camera control system, in which use is made of a television camera according to claim 1, characterized in that the system comprises the camera control unit connected to the television camera, which camera control unit is further connected to a number of cameras of the same type as the former camera all this such that the system outputs camera control signals to the respective television cameras to coincide the video balance of the output signals of the different cameras. 6. A television camera control system according to claim 5, characterized in that the camera control unit is adapted to generate and output camera control signals, for example a white balance control signal, a predetermined synchronization control signal and a ground level adjustment control signal, which control signals are coded in series. 35 8004514