DEP0032065DA - Super regenerative receiver - Google Patents

Description

For the reception of wireless transmissions, especially in the shortwave area, use is often made of the super-regenerative circuit or over-feedback circuit in cases when a particularly high sensitivity is to be achieved with as little effort as possible. The over-feedback circuit results in a particularly high gain, but not particularly good selectivity and linearity of the reproduction.

It is known that in the case of feedback reception, different working areas can be distinguished, which are usually referred to as the logarithmic area and the linear area and can only be obtained properly if one works with a separate oscillator for the pendulum frequency.

It is also known that a certain frequency ratio between the receiving frequency and the pendulum frequency must be maintained in order to achieve a correct operation of the circuit. If the pendulum frequency is chosen too high, the individual wave trains that are caused by the pendulum frequency begin to merge and the circuit then works in the coherent area. However, this area must be avoided as far as possible, since strong distortions occur and since the resonance curve then contains a larger number of maxima, which are separated from one another by the amount of the pendulum frequency.

When setting the reception to different reception conditions, e.g. different reception intensity and frequency, it can easily happen that the operating conditions are changed in such a way that working in undesired areas comes about. The receiver is therefore viewed as unstable and is generally only used with caution in certain cases.

One aim of the invention is to make the receiver stable for changing operating conditions and to modify it so that it always works in the desired linear or incoherent area even with strong fluctuations in the reception intensity and when tuning over larger frequency ranges.

According to the invention, a special rectifier circuit is preferably inductively coupled and the output energy is taken from this rectifier circuit, while at the same time a control voltage is derived from the rectifier, which has a stabilizing effect on the feedback tube. When using such a circuit, it is possible to change the coupling of the antenna, for example, without the receiver entering an undesired working area. Compliance with certain dimensions of the receiver or the individual parts of the oscillating circuits is no longer so critical. In addition, the pendulum frequency is kept away from the output circuit, since only the high frequency is decoupled by means of the rectifier circuit. This is also beneficial, since the oscillation frequency is undesirable in the output circuit in many cases.

An exemplary embodiment is shown in the circuit. The receiver is suitable for receiving shortwave transmissions, which can be in the m or dzm area. It allows, for example, the reception of police radio transmissions with very little effort, since only a few tubes are required. The recorded vibrations are transmitted via an antenna 1 and a winding 2 to the resonant circuit of the overfeedback tube 3. The resonant circuit of this tube consists of the inductance 4 and the capacitor 5. In the manner known from overfeedback reception, this tube alternates between an oscillating and a non-oscillating one State shifted. This is done in this case with the help of a pendulum oscillator with the tube 6. This oscillator oscillates at a frequency which is a fraction of the frequency of the oscillation received.

The frequency is fed from the anode circuit of the oscillator tube via a resistor 7 and an inductance 8 to the anode circuit of the tube 3. When the anode voltage is increased, the tube begins to vibrate; when it is lowered, the tube is prevented from vibrating. The individual high-frequency oscillations grow according to the damping of the oscillating circuit and decay again when the anode voltage of the tube is reduced. While the output voltage is now usually taken from the anode of the tube 3, according to the invention a special rectifier tube 9 is coupled to the resonant circuit 4 via the winding 10. In this tube 9, which can also be replaced by a detector, the high-frequency vibrations are rectified so that the rectified low voltage can be picked up at the output 11. In addition, part of the DC voltage is branched off via a resistor 12 and fed to the grid of the tube via a resistor 13. In this way, a regulating effect is achieved in that the grid voltage of the tube 3 is changed as a function of the signal voltage. Without the regulation, the receiver would be steered into the coherent or logarithmic area in the event of a large incident energy, since the oscillation trains under certain circumstances grow very strongly and are no longer properly separated from one another. The control voltage counteracts this. Conversely, if the incident energy is weak, the receiver is set to high sensitivity without leaving the incoherent working area. The control enables stable operation even with variable attenuation, e.g. due to antenna influences. It counteracts a change in attenuation in that the control strives to always set the receiver to the most sensitive range. The control circuit can also be used with a self-oscillating circuit, i.e. in overfeed receivers which do not have a separate oscillator tube, but in which the tube 3 simultaneously takes on the function of the pendulum oscillator.

The invention is not restricted to the particular type of utilization of the control voltage on the grid of the tube 3. A special control grid in the tube can be influenced; it is also possible to change the amplitude of the pendulum voltage with the aid of the control voltage or to influence the anode voltage.

Claims (2)

1. Super regenerative receiver, characterized in that the output circuit is connected via a preferably inductively coupled rectifier. 2. Super regenerative receiver according to claim 1, characterized in that a voltage taken from the rectifier is used to control the feedback tube.