DE669377C - High frequency equipment, especially receivers - Google Patents

Description

High-frequency device, in particular a receiver, is the subject of the invention is a high frequency device, e.g. B. a wave meter or a radio receiver or other broadcasts in which the exact focus on the receiving wave not, as before, in a laborious manner by hand while observing through the ear or eye, but is carried out automatically, possibly after the Voting means by hand in the position only approximately corresponding to the vote (Coarse adjustment) have been brought.

So far, the focus was mostly done by adjusting the movable Parts of a condenser, variometer or the like. Manually made. There are also voting facilities became known for radiotelegraphic stations, in which by automatically Acting devices the moving system around the one corresponding to the receiving wave Resonance position around within certain adjustable limits on mechanical Paths is moved periodically. However, these devices cannot cause the coordination or its temporal mean value corresponds to that of the received wave automatically approaches optimal values, much more you have to do when you make a statement of the moving system (capacitor or variometer) to a desired value wants to achieve, the capacitor or the variometer to this desired value by means of a locking device or clamping device by hand. With the Need to adjust the moving parts of a condenser, variometer o. The like. Or the detection of such a movable system by means of a Getting hold of the locking device by hand are some inconveniences and Sources of error connected.

It is also an automatic control device for receiving equipment became known for superimposing reception, in which two auxiliary oscillation circuits are provided one of which is tuned to a frequency that is slightly larger than the normal beat frequency, and the other to a slightly lower frequency. Floating currents are fed to these two circles, whereby the two circles each contain a rectifier with a capacitor, which are connected to resistors in the Shunt. The resistances of both circles are arranged in series, and in such a way that with correct coordination there is no potential difference between their free Ends> prevails. These ends are connected to the grid and filament of a cathode tube tied together. If the frequency of the incoming oscillation changes, it approaches the beat frequency of the tuning of one of the auxiliary oscillating circuits. This requires a potential difference between the ends of the resistors and the the resulting change in resistance of the tube causes a change in the tuning e 'suitable oscillation circuit, whereby the correct tuning is restored earth.

The use of two detuned auxiliary oscillation circuits in this one known device is cumbersome. Also must for proper functioning this known arrangement, the requirement must be met that the electrical Properties of the two auxiliary oscillating circuits and the rectifiers contained therein are the same or at least in a relationship that is constant even in continuous operation are related to each other: Otherwise, when this relationship is changed, continuous operation occurs without changing the frequency to be recorded, a potential difference between the resistor ends and a change in the vote of the circle to be regulated, i.e. a desired one Detuning of the device in relation to the frequency to be recorded. Two oscillation circles, but in particular two rectifiers, which in continuous operation their electrical properties do not change or only change in exactly the same way, but are extremely difficult to manufacture, and the more difficult the higher the frequency in question. In particular The tube and crystal rectifiers available for high frequency are sufficient these conditions do not.

It is also a supposedly automatic adjustment device known with only one rectifier, which contains a driving system, its Position more precisely: rest position, a function of the current in the circuit to be controlled is and that by means of a suitable control system, the vote or the like the regulatory circle.

But if one assumes with this known arrangement that in a certain Moment all external circumstances would be so; that the arrangement the vote of the to be regulated to the correct place, it still causes a change the field strength recorded by the receiver z. B: with Fäding, a change in the current in the circle to be controlled and thereby a change in the rest position of the driving one System and the coordination of the circuit to be regulated. So the arrangement causes after the field strength change, the tuning of the circuit to be controlled is automatic is set in the wrong place. On the other hand, if you change any Size, which is independent of the control system, the coordination of the circuit to be controlled influenced, e.g. B. the capacitance of a coarse adjustment capacitor, this would have to be Changes can be compensated for by shifting the control system. These Shift should have the consequence that the vote and current intensity to be regulated Circles has the same value as f; üher, but then the driving stem would also be and the control system take the same position as before the change in the coarse adjustment capacity or the like. But this contradicts the requirement that a shift of the Control system must occur. So this well-known establishment is changing extremely dependent on the field strength to be received, a coarse adjustment capacity or the like and causes, except in a coincidental coincidence, which probably never occurs in practice various circumstances, no automatic adjustment of the vote to the correct one Job.

The automatic focusing device according to the invention works in contrast to known devices, without the use of two detuned auxiliary circuits, whereby various advantages are achieved, in particular simplification of the circuit and the elimination of the need to produce two rectifier circuits, their electrical properties in a constant relationship even with continuous operation stand .. In contrast to other known devices, works according to the invention Self-arming device also, as is necessary for proper functioning is required, regardless of the field strength picked up by the device and of Changes of any size that are independent of the control device's vote of the circuit to be controlled, e.g. the capacitance of a coarse adjustment capacitor.

To achieve these advantages, according to the invention, at most after the approximate setting, the vote is subject to periodic changes and synchronously with this, a sluggish relative to the frequency of these periodic changes Control organ influences, which is connected to a tuning element for fine tuning is. This regulating organ is on the one hand under the influence mentioned above and on the other hand under the influence of a known per se from the reception intensity in Dependence on brought current. These two influences work together in this way on the sluggish regulating body that it changes the vote until that of fluctuations in the reception The intensity-dependent current has the same effects in the opposite sense exercise the regulatory body. Then the exact resonance position is reached, and the regulating body as well as the fine-tuning means associated with it remain at rest. This works preferably the current of a suitable circuit of the Device directly or indirectly on a control element which is connected to a tuning element is. The sense of direction of this effect becomes the periodic one mentioned for each half-period Reverse changes. The regulating organ has suitable inertia and damping, see above that it adjusts itself according to the temporal mean value of the effects until the effects exerted in the opposite sense are equally great. This occurs when the exact match is achieved. The periodic reversals mentioned the sense of direction need not be in phase with the periodic changes mentioned the vote.

An exemplary embodiment of the invention will now be described. In the drawing, Fig. Z is the scheme of a high frequency receiving device according to the invention. Fig. 2 and 3 show resonance curves, Fig. Q. illustrates the various synchronously changing instantaneous values as functions of time. In the case of high-frequency receivers, the task of tuning is known to be to tune one or mostly several oscillating circuits to the frequency of the wave to be received or, in the case of superposition receivers, to tune the oscillator circuit to a frequency that is greater or lesser by the intermediate frequency. In Fig. R, for the sake of simplicity, only one receiving tube RV is shown, which is connected as a directional amplifier. Fig. 2 and 3 show their anode current as a function of the tuning capacitance. The received energy comes from the antenna A in an oscillating circuit consisting of the coil L and the capacitor C and the parallel capacitors C and C ". By means C of the oscillation circuit by hand is set approximately to the receiving shaft. An alternating current (control current) energizes a Magnet S, whereby a plate of the capacitor C is excited to oscillate at the frequency of the control current. Therefore, the capacitance C, .es resulting from C ', C and C "fluctuates periodically between the values Cl and C2 (see Fig. 2 to q.) back and forth. The tuning of the grid circle of the directional amplifier RV is therefore subject to periodic fluctuations. The current I of the anode circuit of this directional amplifier flows through the rotating coil 3, which acts as a control element and is connected to a tuning element, the capacitor C. Since the rotating coil is in a magnetic field excited by the control current, the anode current of the directional amplifier exerts a force on the coil The sense of direction of this force effect is reversed with every half cycle of the control current or the periodic fluctuations of the capacitance C and the grid circle tuning. During a half cycle of the alternating current (control current) the field in which the coil 3 is located is of a certain direction, and at the same time the total capacitance is increased, for example If the tuning with the central position of the capacitor C is now set, for example, to a higher frequency n than corresponds to the receiving frequency (Fig. 3), then the anode current of the directional amplifier and thus the current in sink 3, as Fig. q. shows, be smaller during the r, 3 "5 .... half-period al s during the 2, q., 6 .... half-period. The coil 3 then receives unequal size, opposite drives in the successive time segments, moves and adjusts the capacitor C "until the resonance position is reached (Fig.2). Then the anode current is the same in successive time segments, and the coil 3 receives opposite, equally large impulses remain at rest. It is assumed here that the curve which represents the anode current as a function of C "s runs symmetrically in the vicinity of the resonance position, which assumption is always fulfilled with a sufficient approximation for the present considerations . It does not matter whether the curve mentioned has a single maxima or several maxima in the vicinity of the resonance position (as shown in dashed lines in Fig. 2 and 3), since the adjustment is made to the middle of an interval. This is e.g. B. important for band filter arrangements. The exact frequency can optionally be read from the capacitor C and the scale 7 by means of the pointer 5. It can be seen that the setting is in the correct position, regardless of the field strength picked up by the apparatus and changes of any size which, e.g. B. the capacitance of the coarse adjustment capacitor, regardless of the control device affects the vote of the circuit to be controlled.

In the example shown, a plate of the capacitor C is designed as an oscillating tongue or membrane, which is influenced by a polarized magnet S excited by the control current. However, a rotating synchronous motor can also be used together with a rotating plate capacitor. Instead of the variable capacitor C parallel switch on the additional capacitors C and C ', and the stator can of Xondensators C be arranged pivotably and can be adjusted by the rotating coil 3. The vote must not d by changing 1 he carried capacitance or self-inductance. There are known vibration circles whose Natural frequency depends on an electrical voltage or current strength. (An example of a voltage-dependent oscillation circuit is the Barkhausen short circuit, whose natural frequency is known to depend on the voltages at the electrodes of the switched-on electron tube. Current-dependent natural frequencies have e.g. circles with iron core coils.) In In these cases the periodic fluctuations of the natural frequency of the circuit can be obtained by superimposing the alternating voltage or the current intensity of the control current on the voltage or the current intensity on which this natural frequency depends become T. A single or multi-stage amplifier can also be connected between the anode circuit of the rectifier and the control element, or the current supplied by a rectifier can be fed to one or more tubes, which are thereby automatically controlled and whose anode current flows through the control element.

Are the high frequency vibrations to be received modulated as it is z. B. is generally the case in wireless communications technology, so it is often favorable, the frequency of the control current, d. H. the periodic fluctuations the natural frequency of the circle, very different from the frequency of the oscillations to choose with which the high-frequency vibrations to be received are modulated.

By this measure and by the fact that the detuning size of the periodic Keeping tuning changes relatively small becomes a noticeable nuisance playback of the device avoided.

The mode of operation of the automatic adjustment device described for receiving devices can also be understood to mean that before the precise setting has been achieved an alternating current at the frequency of the control current in the anode circuit of the tube RV occurs. The phase of this current depends on whether the oscillation circuit is on a frequency is set too high or too low. This alternating current seeks in interaction with the "alternating field of the magnet i or the control current, the coil 3 to rotate in a direction dependent on its phase. When achieved more precisely Voting, the former alternating current disappears, and it only remains one Alternating current of double or higher frequency exist, which is common with the alternating field of the magnet i causes the coil 3 to drive opposite, equally large drives that cancel each other out (Fig. q.). Instead of the one shown in Fig. a dynamometer .ähnlichen instrument I, consisting of the magnet i, the winding 3 and the moving coil 3, any other device can be used in which the Direction of movement of a moving part from the phase shift of two alternating currents depends, e.g. B. an eddy current instrument (induction meter for alternating current, Ferrari instrument) analog device.

The invention is of course not directed to the setting of one Receiving device (wave measurement) or other measuring processes limited; but analogously also applicable to signaling, remote control and regulating devices, etc.

Claims (5)

PAT1: N CLAIM: i. High frequency device, e.g. B. Recipient, thereby characterized in that the vote is periodic for automatic sharpening Changes is subject to and synchronously with this a compared to the frequency of this periodic changes sluggish, with a tuning element connected control organ is influenced in such a way that it is under the joint effect of this influence and a current made dependent on the reception intensity, the tuning changes until the change caused by the periodic voting Fluctuations in this current have the same effect in the opposite sense on the regulating organ exercise, in which case the resonance position is reached. 2. High frequency device, e.g. B. Receiver, according to claim =, characterized in that the current of a suitable Circuit of the device acts on a control element connected to a tuning element, the sense of direction of this effect at each half-period of the periodic Changes are reversed and the regulating organ has such inertia and damping, that it is essentially according to the mean value of the chronological order exerted, opposite effects so long adjusted until these opposite Effects are equally large, which occurs when a sharp adjustment is achieved. 3. High frequency device according to claim i or 2, characterized in that the periodic tuning change and influencing the regulating organ or: reversing the sense of direction of the Effect on the same is caused by an alternating current (control current). , q .. High-frequency device according to claims i to 3, characterized in that that an electrodynamometer or one analogous to an eddy current instrument as a regulating element Organ is used, one winding of which is the control current and the other winding of the Current is supplied to a suitable circuit of the device. 5. High frequency device according to one of the preceding claims, characterized in that the periodic Changes, the tuning takes place with the help of tuning circles, whose resonance frequency, can be influenced purely electrically.