DE509527C - Low-frequency modulated tube transmitter - Google Patents

Description

The invention relates to systems or arrangements for transmitting Carrier waves and in particular to an arrangement in which a signal-modulated Carrier wave, which contains both the carrier frequency and the side frequencies, is to be transmitted.

If the carrier component and the subsequent side frequencies from a radio station are sent out, as in known radio systems, the amplitude of the carrier component remains unchanged while that of the side frequencies varies with the intensity of the signal (i.e. with the main amplitude the modulating wave) changes. If therefore in the spaces (intervals) If a weak signal or no signal is sent from the sending station, almost all of it will be in the receiving station station received energy from the carrier component of the shaft. As known, such a carrier wave is modulated by external influences, with the result, that noises are perceived in the receiver during the mentioned intervals. If, on the other hand, the signal from the transmitter is loud, then the intensity reaches the side frequencies (i.e. the major amplitude of the side frequencies or sidebands) such a value that the previous during the Intervals perceived noise in the receiver is essentially masked by the received signal.

One of the aims of the invention is to control the amplitude of the carrier component of the transmitted Wave in accordance with changes in the intensity of the side frequencies or the signal representing the side frequencies generates, controls and regulates. Such a regulating effect on the carrier component but would help increase the intensity of what is received in the receiving station Signal with reference to the intensity of the original output in the transmitting station Signal to change.

It is therefore a further purpose of the invention to reduce the usual amplitude of the side frequencies to change in the opposite sense to the change in the amplitude of the carrier frequency.

According to the invention, the amplitude of the carrier component is therefore reduced, while the intensity of the side frequencies is increased, in accordance with a decrease in signal intensity, and vice versa.

A signal-modulated carrier wave is therefore transmitted with which the intensity of the side frequency component is held substantially constant while the amplitude of the carrier component is changed so that a faithful reproduction is obtained of the original signal is obtained when the carrier component is in a known manner in a receiving station is reunited with the side frequencies.

The invention can be practiced in many ways, e.g. B. on the the following:

The carrier wave is impressed on an amplifier device, the degree of amplification in accordance with the signal intensity will be changed. The carrier wave is also pressed onto a modulating device, to which also the signal waves

ίο be directed, reducing page frequencies arise, the intensity of which is changed in accordance with the signal intensity. The modulating device is set up in such a way that it has the carrier component in its Output circuit suppressed. The side frequencies of the mentioned output circuit and the output wave of the mentioned amplifier device (which, as mentioned, changes in accordance with the signal intensity change) are merged and transmitted.

The change in sideband intensity can be achieved by changing the signal intensity or by changing the amplitude of the carrier pressed onto the modulating device be effected.

The method described below as an example uses a modulation system in which "both" carrier amplitude and signal intensity, as they would a modulating device can be changed in accordance with the original signal intensity. The degree of Change is in any case such that the above conditions are met without that it becomes necessary to have a complete system in separately controlled branches to share.

In the drawing, a known type of modulation system is shown in which two tubes can be used with a common anode power source. The carrier frequency wave is applied to the input circuit of a tube (the high frequency tube) and the signal wave to the input circuit the other tube (the low frequency tube). A choke coil is placed in the direct current path of the mentioned source turned on, causing changes in the anode-cathode space impedance of the low frequency tube cause corresponding changes in the plate potential of the high-frequency tube. This creates a corresponding Change of the high-frequency output

55 · current caused by this tube while the load on the anode current source is constant remain.

ι represents any source for carrier frequency oscillations, the output circuit of which is connected to the input circuit of the high-frequency tube 26 via a transformer T _{2 and a potentiometer 28.} The output lines of the tube 26 are connected to the antenna circuit AT via the transformer 34.

Signal waves are sent via the circuit L ₁ , which is connected to the input circuit of the low-frequency tube 27 via a transformer T _{1 and a potentiometer 29.}

The anode of the tube 27 is connected to the anode of the tube 26 (expediently by means of a high-frequency choke coil). The negative contact of the anode power source B is connected to a common connecting line for the filaments, while the positive contact is connected to the common connecting line of the anodes via a low-frequency choke coil 33. The modulated wave generated in this way is transmitted to the antenna AT .

A circuit is branched off from the line L ₁ and contains a rectifier R which can contain amplifier and filter devices. A substantially rectified current is supplied to the solenoid 30 from the output circuit of the rectifier R. The value of this current is proportional to the signal intensity. The devices for generating such a current from signal waves are known.

The solenoid 30 moves the arm 32 against the spring 31 and tries to compress it. The arm 32 carries contacts which are connected to the parts 28 and 29 and thus simultaneously via these parts be moved. The movable contact of the potentiometer 28 is with the grid of Tube 26, that of the potentiometer 29, is connected to the grid of tube 27. Of the Arm 32 is between both contacts and between each contact and spring 31 isolated.

Grids and filament heating batteries are of common shape and operate in well known ways Way.

The arrangement works as follows.

When there are no signal currents in line L ₁ , the line of rectifier R is zero, and therefore solenoid 30 is de-energized. The arm 32 influenced by the spring 31 'assumes its uppermost position, so that the entire potentiometer resistor 29 lies in the grid circuit of the tube 27, while the resistance of 28 is not in the grid circle of the tube 26. In this case, neither the carrier component nor the sideband is supplied to the antenna circuit AT.

It will be readily appreciated that arm 32 and its contacts move downward in line L _{1 in relation to the signal intensity.}

be pulled. Therefore, if the signals are weak, the potentiometer 29 causes an approximately maximum voltage transmission from the transformer T ₁ to the grid circuit of the tube zj, while the potentiometer 28 effects an approximately minimum transmission between the transformer T ₂ and the grid circuit of the tube 26. The carrier component delivered to the antenna circuit AT is therefore weak, and the intensity of the sideband remains at a value which is determined by the product of the carrier amplitude in the output circuit of the tube 26 and the signal current intensity in the output circuit of the tube 27. Since the potentiometers 28 and 29 act in opposite directions, the sideband intensity supplied to the antenna circuit will keep an approximately constant value, while the amplitude of the carrier component increases when the arm 32 moves downwards, i.e. when the signal intensity in the line L ₁ increases.

The potentiometers 28 and 29 are set so that this effect to the desired Grade occurs. The amplitude of the carrier wave that is transmitted when there is no modulation can be adjusted by setting of the potentiometer 28 can be set to a suitable low value.

About the correlation between sideband and signal intensities for all intensities of the original signal, it is necessary that the arrangement have a has an extremely wide gain range. In practice, however, this is not necessary since it, e.g. B. in broadcasting, there is a practical limit to the signal intensities that must be transferred.

The potentiometer 28 or 29 can be of any shape. It can e.g. B. consist of a tapped resistance element, which is connected to a number of conductors, which are operated by relays, in a certain order, depending on the amplitude of the rectifier R output current. This arrangement gives a limit intensity for signals at which the automatic control no longer influences the system. The potentiometers 28 and 29 can possibly be replaced in a known manner by anode-cathode path of a three-electrode tube whose impedance z. B. is regulated by the current output by a rectifier, the z. B. is passed through a resistor in the grid circuit.

The invention can of course in many other ways, including others Carrier wave systems, exploited Averden.

Claims (3)

Patent claims: 1. Low-frequency modulated tube transmitter, characterized in that the Modulation current the anode output circuit and the grid input circuit of the vibrator tube (26) at the same time affects the grid input circuit in such a way that a decrease or increase in the modulation energy 7 " corresponds to a decrease or increase in the control current amplitude. 2. Tube transmitter according to claim 1, characterized in that the modulation current also at the same time the amplitude of the modulation energy, which the anode output circuit of the vibrator tube (26) affects, in the opposite sense as the amplitude of the control current of the controlled Tube (26) changes. 3. Tube transmitter according to claim 1 and 2, characterized in that the Modulation energy via a rectifier actuates a relay which, via a lever arm, adjusts two Potentiometer changed in the opposite sense, one of which is in the control circuit of the vibrator tube (26) and the other in a go amplifier circuit of the modulation energy circuit which affects the anode output circuit of the vibrator tube (26). 1 sheet of drawings ÜERUN- GEIltllJCKT XH DE! »