DE1203966B - Radar map indicator - Google Patents

Description

FEDERAL REPUBLIC OF GERMANY

GERMAN

PATENT OFFICE

EDITORIAL

Int. α .:

Number:
File number:
Registration date:
Display day:

GOIc

German: 42 c -39/10

1203 966 D21385IXb / 42c September 28, 1955 October 28, 1965

Radar map indicator

Applicant:

Decca Limited, London Representative:

Dr. M. Herzfeld, patent attorney, Düsseldorf, Kreuzstr. 32

Named inventor: Robert Matthews, London

The invention relates to radar imaging devices with a map display. When displaying such a picture Map indicator, a time deflection axis on the screen of a Braun tube becomes synchronous rotated with the revolution of an antenna. 5

In image displays of this type, it is known that the center of rotation is caused by the deflection devices decentering voltages or decentering currents from the center fed to the Braun tube

to move the tubular screen. It is also common practice that between successive time diversions There are pauses in the display beam during which the display beam does not experience any time deflection.

According to the present invention, a radar map indicator is characterized by switching devices

draws which the decentering voltages or

Decentering currents during the breaks between «
the successive time distractions of the arrival

Interrupt the pointing beam. Radar track in the required decentering position By interrupting the decentering span ao begins, whereby the starting value of the sawtooth current voltages or decentering currents during which the current supplied is the same. If in Pauses between the successive time drops of the control of the power tubes by age controls of the indicator beam, the average native circuits each power tube becomes a catholic Current in the deflectors has considerable resistance and reduces any alternate current, compared to that which has an amplifier tube and another in the circuit voltage with constant decentering deflection currents includes the circuit which the output of the required is. stronger with the control grid of the power tube. The invention can be applied to devices, then the arrangement according to the invention can be in which either electrostatic or electronic switching devices are chosen so that Magnetically deflected Braun tubes employ feedback loops between them in their actuation will. A radar map indicator, which has an electrode cathode of the power tubes and the control magnet The deflected Braun tube with fixed grids of the amplifier tubes are effective standing deflection coils and one deflection signal each - either only ohmic resistances or ohmic ones generator for each deflection coil, the resistors and capacitors included. In the first Power tube of each deflection signal generator two 35 cases a constant deflection current is achieved while- or several alternative circuits for the purpose of controlling the tube circuit in the second case tion of the associated deflection coil by the Lei sawtooth generator in the manner of a Miller integrator Stungsröhre supplied current are assigned, forms.

can be designed in application of the invention in such a way. The invention can also be used in a radar indicator that the switching devices are used on the alternator, which has an intermediate fade-in for native electrical circuits. Here, one of them can have a direction marking line.
For this purpose, there are four switching devices that are influenced by switching device alternative circuits supplied current deflection coil are supplied at the same time. If only two alternative circuits are provided, with one of these circuits being provided as a generator, the radar display is used for the time deflection, the second one is used to generate the sawtooth current for the time to decenter the radar display during a deflection of the radar track and the other to shorten the period before the start of each radar track, generation of a constant current, with which the third 50 as a time deflection generator for a direction the deflection coil is fed for a short period of time before the line marking line between the radar displays start of the scan in such a way that the and the fourth to decenter the direction mark.

marking line is used for a short period prior to the start of the display of this line.

In the last-described arrangement, the direction marker line can be separated from the radar display decentered, which makes it possible to use the direction marking line to determine the direction to determine between two targets appearing on the screen of the Braun tube.

It is easily possible to display more than one marking line in the interim display and to set each of these lines separately. both with respect to their starting point and their angular direction. to For this purpose, a correspondingly larger number of alternative circuits and switching devices according to the invention are provided.

An embodiment of the invention is shown schematically in the drawing.

F i g. 1 is a schematic diagram of a circuit associated with one of the deflection coils for a radar map indicator is connected in which an electromagnetically deflected Braun tube is used with fixed deflection coils;

F i g. 2 schematically illustrates some of the waveforms of the circuit of FIG.

According to FIG. 1, the deflection coil 10 is connected to the anode circuit of a power tube 11. Four alternate circuits, each including the tubes 12 to 15, are provided for the by to control the current passing through the tube 11. Each of the triodes 12 to 15 together with the Power tube 11 and the circuit interacting with it a closed deflection signal generator, which generates a current in the deflection coil 10, the amplitude of which is determined by the The voltage applied to the grid of the triodes is controlled and its waveform is determined by the type of the feedback circuit from the cathode of the tube 11 to the grid of the triodes. As follows To be explained in more detail, the tube 14 generates when connected to the power tube 11 is the sawtooth current for the time deflection of the radar display, while the tube 15 when it is connected to the tube 11, a deflection current for a superimposed between the radar displays Direction marker line generated. Through the tubes 12 and 13, currents are supplied that the Effect decentering and each immediately before the beginning of the direction marking line and the Radar track are needed. The four tubes 12 to 15 have a common cathode resistance 16, at which the output signal arises. After amplification in tubes 17 to 19, this signal becomes fed to the control grid of the tube 11.

The tubes 17 to 19 form a direct current amplifier. The first amplifier tube 17 is as Triode amplifier formed with a grounded grid, the output of which is fed to a pentode amplifier 18 will. The tube 19 is a triode connected as a “cathode follower” and is between the amplifier tube 18 and the power tube 11 are arranged to the effect of the input capacitance of the Power tube 11 to weaken the anode load of the pentode amplifier.

The tube 11 has a cathode resistor 20, and the power resistor falling across this resistor Voltage is fed back to the grid circles of tubes 12-15. The ones to the tubes 12 and 13 leading feedback loops contain only pure resistors 31 and 35, while the feedback circuits leading to the tubes 14 and 15 each include a capacitor 21 and 22. The feedbacks leading to these latter two tubes work together with of the power tube 11 the creation of sawtooth currents in the deflection coil 10. The mode of operation such a circuit is known and is described, for example, in British patent specification 679,723. The resistors 23, 24 connected in series with the capacitors 21, 22 have the effect that a linear increase in the deflection current is achieved, although the deflection coil 10 has a damping resistor 39 is connected in parallel.

The amplitude of the anode current of the tube part is set in accordance with control voltages V ₁ to F ₄ , which are applied to the control grids of the tubes 12 to 15 via matching resistors 30, 34, 37 and 40 and series resistors 42 to 45.

The switching devices according to the invention, which alternatively switch the tubes 12 to 15 into the operating state, are formed by diodes 33, 36, 38 and 41 which are connected to the control grids of the tubes. When a negative bias voltage is applied, the tubes are initially in a non-conductive state of rest. At the given moment, positive opening pulses G ₁ to G _{4 are} given via the diodes, their length and their temporal relationship from FIG. 2 can be seen.

During the duration of the pulse G ₁ a constant current flows through the coil 10 and the tube 11 in order _{to effect a decentering of the track in preparation for the start of the sawtooth current controlled by the opening pulse G 4} , the latter representing the time deflection for the direction marker line. After this sawtooth current has ended, the tube 11 is switched off until the pulse G ₂ generates a constant current, which serves to decenter the track, in preparation for the start of the _{sawtooth current controlled by the opening pulse G 3} for the time deflection of the radar track. The time course of the resulting current passing through the coil 10 is shown in FIG. 2 shown below.

Using the pulsed decentering system discussed above considerable energy savings can be achieved. In the case of a typical implementation, in which the full deflection current is about 100 milliamps and the inductance of the deflection coil is about 100 millihenries, and provided a repetition frequency of the pulses of 1 kHz for the representation of a large distance range with a sampling time of 960 microseconds (which is a range of about 80 nautical miles corresponds), the voltage drop across the coil is the product of the inductance and the Measure of change in current is about 10 volts. In the case of a representation for a small area with a sampling time of 60 microseconds (about 5 nautical miles) is the voltage drop across the coil about 166VoIt.

If the voltage drop in tube 11 at a current of 100 milliamps is 100 volts, one would use a voltage of 110 volts for the far-reaching display and 266 volts for the near

need area representation (with the simplicity half of the voltage drop across the resistor 20 is ignored). If you put the higher Tension and one pulls a decentering up to the edge of the screen, i. H. a decentering current of 100 milliamps are taken into account, would be 26.6 watts for this with constant decentering Purpose to be consumed. In the arrangement according to the invention, this current is only for one Only a fraction of the time is required, so that the energy savings - especially with the close-up display - is very important.

Claims (4)

Patent claims: 1. Radar position plan indicator with a Braun tube with a time deflection axis around a center of rotation is rotatable, the decentering voltages or decentering currents supplied by the deflection devices of the Braun tube can be shifted from the center of the tubular screen, and between the successive time deflections of the display beam are pauses in which the display beam does not experience any time distraction, marked by switching devices (33,36, 38, 41) which the decentering voltages or decentering currents during the pauses between successive time diversions interrupt the display beam. 2. Radar map indicator according to claim 1, which is an electromagnetically deflected Braunsche Tube with fixed deflection coils and one deflection signal generator for each deflection coil wherein the power tube of each deflection signal generator has two or more alternative circuits for the purpose of controlling the current supplied to the associated deflection coil through the power tube, characterized in that that the switching devices (33, 36, 38, 41) act on the alternative circuits. 3. Radar map indicator according to claim 2, wherein each power tube has a cathode resistor and each alternative circuit includes an amplifier tube and a further circuit which couples the output signal of the amplifier tube to the control grid of the power tube, characterized in that by actuating the switching devices (33, 36 , 38, 41) feedback circuits between the cathodes of the power tubes (11) and the control grids of the amplifier tubes (12 to 15) become effective, which either only have ohmic resistances (31, 35) or ohmic resistances (23, 24) and capacitances (21, 22) included. 4 radar position plan indicator according to claim 2 and 3, characterized in that four by the switching devices (33, 36, 38, 41) influenced alternative circuits for controlling the current supplied through each power tube (11) to its associated deflection coil (10) one of these circuits as a generator for the time deflection of the radar display, the second to decenter the radar display for a short period before the start of each radar lane, the third as a time deflection generator for a direction marker line between the radar tracks, and the fourth to decenter the direction marker line serves for a short period prior to the start of the display of this line. Considered publications:
Swiss Patent No. 293 285;
French Patent No. 1076 946;
British Patent No. 736 440;
Soller, Starr and Valley: Cathode Ray Tube Displays, New York, 1948, chap. 12 to 14. 1 sheet of drawings 509 719/104 10.65 © Bundesdruckerei Berlin