DE2911117C2 - Focusing device for a color television camera - Google Patents

Description

The invention relates to a focusing device for a color television camera as required in the preamble of claim 1.

In color television cameras with several magnetically focused recording tubes, a number of associated picture tube parameters must be kept in precise coordination with one another in order to match the grid: These include the mechanical design of the focusing coil, the focusing coil current, and the voltage ratio G-ZIGA for each recording tube (where O-3 is the focus cylinder voltage and G-4 is the voltage for the field grid or mesh electrode) which affects the operating characteristics of the tube, such as beam landing error, the focus ratio between center and corners, and the geometry of the displayed image. Electronic focusing of the scanning beam of the image pickup tube can be achieved either

a) by adjusting the voltages O-3 and G-4 in agreement with each other so that a constant Ratio is maintained or

b) by adjusting the focus coil current.

From DE-AS 11 34 703 a circuit for achieving grid coverage in color television cameras is known in which the coverage of the three grids is achieved with a few, practically independent control steps in that all three deflection systems are connected to a low-resistance generator and the control the line deflection amplitude is carried out by changing the voltages of at least two of the recording tubes influencing the jet speed, the regulators used to regulate this acceleration voltage being coupled to the sharpness regulator of the respective tube in such a way that the tilting amplitude can be regulated without changing the sharpness. For this purpose, the focusing currents fed to the focusing coils of two of the pick-up tubes are changed simultaneously with the focusing voltages fed to these tubes by mechanically coupling a potentiometer for each tube that determines the focus current with a potentiometer that determines the focus voltage.In this way, two pick-up tubes can be adjusted to the third . Furthermore, it is known from US-PS 33 05 750 to bring the grid of three pick-up tubes of a color television camera to cover that the deflection coils in question are additionally supplied with adjustable symmetrizing currents, with the help of which the grid can be mutually shifted. These additional streams are derived from three secondary windings of a fed via a chopper transformer by rectification and stabilization by means of three zener diodes in parallel with each Zener diode is a potentiometer whose tap is guided at one end in each case one of the deflection coils, while d? *> Other end of the respective deflection coil is located on a center tap of the relevant secondary winding of the transformer mentioned

It is now desirable to have remote control of the focus of the camera by a digital control system to be provided using microprocessors. A digital control system which, for example works with an eight-bit binary code, can represent 256 control voltage values. In a typical The system carries the maximum voltage value 5 volts (-5

so up to +5 volts). Electronic focusing would require expansion from this 5 volt maximum to voltages on the order of 1000 volts required for voltages C-3 and G-4. The precision required for the G-3 / G-4 voltages is about 0.1 Vo. However, such large voltage expansions are subject to inaccuracies, so that such an arrangement is impractical when precision is required.
Alternatively, each tube can be focused by setting the current individually for each focusing coil. An advantage of this is that the setting means for each of the focusing coil control assemblies operating at relatively low voltage match well with the low voltage output of the digital control system, so that a large voltage increase with the associated inaccuracies is not necessary. A disadvantage of this system, however, is that between the

Focusing coil currents differential displacements may exist, which can lead to registration errors, since the three color tubes are then not in the right relationship with each other.

The object of the invention now is to provide a remote control device for focusing a color television camera by a digital control system, are in which registration errors avoided, as a result of the m dfferentiellen shifts can Fokussierspulenströmen occur.

This object is achieved by the features specified in the characterizing part of claim 1, further developments of the invention are characterized in the subclaims.

In the drawings shows

F i g. 1 the focusing coil system for a camera according to the invention and

F i g. Figure 2 is a sketch of a single tube focusing coil system.

A digital control system which works with an eight-bit binary code, for example, can represent 256 control voltage values. In a typical. System, the maximum voltage value is 5 volts (-5 to +5 volts). Electronic focusing would require expansion from this 5 volt maximum to voltages on the order of 1000 volts. The precision required for the G-3 / G-4 voltages is about 0.1%. However, such large voltage expansions are subject to inaccuracies, so that such an arrangement is impractical when precision is required.

Alternatively, each tube can be focused by setting the current individually for each focusing coil be effected. An advantage here is that the setting facilities for each of the with relatively lower Voltage working focus coil control assemblies work well with the low voltage output of the digital control system fit together, so that no strong increase in voltage associated with it Roughness is required. A disadvantage of this system, however, is that between the Focus coil currents differential displacements can exist, which can lead to registration errors can lead, since the three color tubes are then not in the right relationship to each other.

The invention described here now relates to a focusing system which greatly or completely eliminates the disadvantages of the two methods described. In Fig. 1, a compound focus coil system is illustrated. The red tube is designated by 10, the green tube by 11 and the blue tube by 13. The focusing cylinder and the field mesh electrode, which will be referred to below as the mesh electrode, are also shown for each of these receiving tubes. For the tube 10, the focusing cylinder has the reference number IOa and the mesh electrode has the reference number 10Z). Correspondingly, the focusing cylinder for the tube 11 is designated with 11a and the mesh electrode with Wb , or for the tube 13 the focusing cylinder with 13a and the mesh electrode with 13t. A common voltage source (GA) 15 is provided for the mesh electrode 10ύ, Wb and 136. This voltage is fed directly to the three mesh electrodes in parallel. The voltage from the source 15 is also fed to the focusing cylinders 10a, Ha and 13a in parallel from a tap of a voltage divider mi *, the resistors R \ and /? 2. The ratio of the voltages G-VG-A is a function of the ratio of the resistances R \ and Ri. This resistance ratio between R \ and Ri is selected so that a desired ratio G-3 / G-4 results, which has already been pointed out and which influences the operating properties such as beam landing errors, center-pull-corner focusing and the geometry of the display image

ίο volts for the mesh electrode.

The focus field for the tube is provided by focus coils which are associated with the yoke assembly. A focus coil shown in FIG. 1 is shown schematically by the coil 20, is mounted in the yoke arrangement surrounding the tube. The focusing coil 21 is mounted around the tube 11 and the focusing coil 23 is mounted around the tube 13 connected in series to a common current source 25 regulated to a fixed value. The bulk of the ^p okussierfeider for each tube is determined by the respectively associated three series-connected Hauptfokussierspulen (20, 21 or 23) provided, which are connected in series to a common regulated current source solid 25th Under the expression main share! it is to be understood that, for example, 95% of the total focusing field is supplied by these main focusing coils 20, 21 and 23 connected in series.

In addition, there are three separate fine-adjustment focus coils provided, one in each yoke focus coil assembly. These are represented by the coils 30, 31 in FIG. 1 and 33 respectively. The fine adjustment focus coils are connected to independent fine adjustment focus power sources 40, 41 and 43 connected. The coil 30 is connected between this fine adjustment power source 40 and ground or reference potential, the coil 31 between the Green focus power source 41 and ground and the coil 33 between the fine adjustment focus power source 43 and Dimensions. A red fine control signal from a Digii control system 50 becomes the fine focus power source 40 supplied. This signal is in the form of an eight-bit digital code, for example. the one of 256 levels, which are detected and in the

■ t5 fine adjustment focus current source 40 into an analog one Current level can be converted, which corresponds to the binary digital control signal. Similarly, a separate Eight bit code signal from control system 50 of green focus source 41 and a separate eight bit code signal fed from control system 50 to blue focus source 43. The digital control system 50 can be provided at the location of the operator or a camera setting unit. It contains for example three analog / digital converters, which respond to three separate voltage values, which can be set using potentiometer settings in order to achieve the To provide eight-bit digital code signals. At each of the fine adjustment focus sources 40, 41 or 43, a Digilal / Analog-Korr'erter be provided where the

μ eight-bit code is converted into an analog level. This represents the code which is fed directly to the coils in the form of a current value. This Code value could be modified to a suitable current value on a certain scale, which is then fed to the adjustable regulators.

Since 95% of the focus field of each of the main focus coils for red, green and blue is from one common bias source 25 is supplied

(with the main focus coils connected in series) there will be a differential drift between the individual focusing fields of the image pickup tubes reduced to zero as far as the main fields are concerned. There may be a relative drift between the fine adjustment fields, but since they are only small Add amount to the total required focus field, the overall stability problem is considerable decreased. The small number of turns of the fine adjustment coils results in a low coil impedance that is easy driven by a low level signal provided by the digital control system 50 can be.

F i g. FIG. 2 illustrates in cross section a tube with a yoke arrangement corresponding to the tubes of FIG Fig. I. The fine adjustment coil (in Fig. I with 30, 31 or 33) is formed by a single layer of fine wire (e.g. # 32 wire) that is passed through ciilC äütOiuätiäCiic iipütünWiCKcimääCiiiric ϋΠΠϊίίίέιύΰΓ onto the inner surface of a focus coil core 60 (in the general shape of a bobbin dielectric material). The only layer can be laid precisely and forms an exact one Cylinder over which the main focus coil is wedged. This main focus coil (in Fig. I with 20, 21 or 22) has, for example, six layers of relatively large diameter (for example, wire No. 23), which are wound directly onto the fine adjustment spool and the rest and the main part of the fill out the entire changing room. The large wire gauge

■ s ke. those to relatively few locations and relatively few Turns per layer, results in a winding configuration which is a precision winding by automatically working winding machines can be achieved. The advantage of using a large gauge wire for

winding a focusing coil is extraordinary meaningful for achieving a high winding precision. A coil not constructed as a composite coil However, using large wire gauge (low impedance) alone would not achieve the goal of one

Ii precision winding and easily realizable focus fine adjustment with high stability. The described system with fine adjustment and main focus coils has the added benefit of lower manufacturing ijci i'ui'icr riii / iMui'i.

The expression main proportion used above is not intended to be restricted to 95%, but rather to the Express the fact that the greater part of the focus field is supplied by the coils 20, 21 and 23. This greater part includes such a percentage that the

_> i differential shifts of the focus currents in the Fine tuning coils are negligible.

1 sheet of drawings

Claims (4)

Patent claims: 1. Focusing system for a color television camera with a plurality of image pick-up tubes, each provided with a yoke arrangement, and with a plurality of main focus coils, one on each of which surrounds each picture tube Yoke assembly is mounted, characterized in that that the main focus coils (20, 21, 23) are connected in series to a common regulated power source (25) and the The majority of the focus field for each image pickup tube (10, 11, 13) is provided by a plurality separate focus fine adjustment coils (30,31,33) are provided is, one of which is arranged on the yoke assembly around each image pickup tube (10, 11, 13) 1st and that a device (SO, 40, 41, 43) is provided which each fine adjustment coil one supplies separate adjustable current of low power at low voltage, such that only one small amount of the total required focusing field is supplied by the fine adjustment coils and electronic focusing using a low voltage source can be performed without stability problems. 2. Arrangement according to claim 1, characterized in that the separate focus fine adjustment coils (30,31,33) directly on the inner surface of the Yoke body (60) is wound and that the Hauptfokussizrspule (20, 21, 23) directly on the Fine adjustment coil is wound. 3. Arrangement according to claim. 1, characterized in that the fine adjustment coil (30, 31, 33) has a is the only layer of thin wire and that the main coil (20, 21, 23) has several layers of wire includes relatively large diameter. 4. Arrangement according to claim 1, characterized in that each tube (10, 11, 13) has a focusing cylinder electrode (10a, 11a, 13aj and a field grid or field mesh electrode (lOfc, lli>, 13oj) and that an arrangement (15, R \, R ₂ ) is provided for supplying such bias voltages for this electrode that the ratio of the focus cylinder and mesh electrode voltages is kept constant.