DE614374C - Ultra-short wave transmission and reception arrangement - Google Patents

Description

In the main patent 540 338 a Sendebzw. Receiving arrangement described in the the direct current leads to the electrodes of an ultra-short wave tube through parallel wires are formed by a sector consisting of galvanically separated sectors Metal plate are shielded. The metal plate prevents the Ultra-high frequency energy on the remaining supply lines. By moving the metal plate the leads to the electrodes of the ultra-short wave tube can be adjusted to the ultra-high frequency generated in the tube or less, thereby influencing the energy as well as the wavelength also occurs.

The arrangement also has the following disadvantages: As a result of the different lengths of leads to the electrodes within the Tube, the supply lines to the cathode, grid or brake electrode, furthermore as a result of the different strengths of coupling of the supply lines to the actual ultra-high frequency oscillating circuit If the plate is in different positions, resonance tuning of individual supply line lengths occurs a. Due to the resonance, however, the supply lines absorb part of the radiation emitted by the resonant circuit, which is thereby withdrawn from the radiation field and is located on the supply lines between the tuning plate and the oscillating circuit runs dead or is emitted uselessly by these in an unfavorable direction of polarization. The leads short-circuited by the tuning plate for the ultra-high frequency to the electrodes and the ultra-high-frequency oscillation circuit in the tube are therefore oscillation systems with different Natural wavelengths, which are coupled to the transmission circuit in various ways and when coordinated in any one Fundamental or harmonics get into resonance and withdraw energy from the actual transmission circuit. The deprivation of energy through the leads that have come into resonance can even be so large that the excitation capacity of the oscillating circuit stops. Furthermore, a wavelength jump occurs at such a resonance point one, in such a way that the increase in the length of the supply line increases

G14374

When the resonance point is exceeded, the wavelength suddenly drops to a shorter value goes.

For example, it will be a three-electrode an-5 order with a short-circuited spiral circuit Provided as a resonant circuit with parallel leads and shielded by a common plate, the following occur oscillating circuits coupled to the spiral circle

ίο in appearance. The cathode with both of them Supply lines form a closed loop that is fairly tightly coupled to the lattice spiral circle Resonant circuit. The supply lines to the grid and the braking electrode form an open oscillating system that increases the capacitance between the grid and the braking electrode as a final capacitance. It also forms the cathode circle with the grid electrode lead an open oscillating system with the capacitance

ao acted between the cathode and the grid as the final capacitance. A further number of oscillation systems can be formed by combining them, but these are not experimentally included in Appearance.

The previous version of the transmitting or receiving arrangement was now such that at a certain plate position the above mentioned vibration systems different Possessed natural frequencies, whereby always

some oscillating system came close to the transmitter frequency with its natural frequency and absorbed energy. No plate position could be found where all Circles are optimally out of tune.

This deficiency is eliminated by the present improvement in the main patent. According to the invention all or some of the direct current leads to the electrodes, most simply within the Vacuum vessel, so provided with compensation lengths that the various oscillating structures have the same natural frequency with a fixed plate position. All the supply lines then represent an oscillation system that can be changed by the position of the plate and has only one natural wave is moved along the supply lines, resonance occurs only in such plate positions Supply line system, which are separated from each other by half a wavelength. Within of the two resonance points, the shielding plate can then be moved back and forth by a relatively large amount. It takes place only a small and steady change in transmitter energy and wavelength. the Changing the wavelength can be beneficial to both a transmitting and receiving arrangement can be used for resonance tuning. It has been found to be a particular advantage that within two Resonance points can change the length of the wave almost linearly with the length of the supply line, whereby the whole arrangement can be easily calibrated. If you work with a plate position that is almost in the middle between If there is two resonance positions, the connected supply line system is maximally out of tune. There is maximum power output at the transmitter and maximum power consumption at the receiver.

An embodiment of the invention is shown schematically in the figure. With ι the vacuum vessel, with 2 the grid electrode, with 3 the braking electrode and 4 with the cathode. HH denotes the cathode leads designed as parallel lines, B and G denote the leads to the grid and braking electrode parallel to the cathode leads. The metal plate P serves to coordinate the four feed lines together. To achieve a single-shaft feed line system, for example, the heating feed lines are provided with bulges at points 5-5, which lengthen the heating circuit by a certain amount. How large this extension must be can easily be determined experimentally.

Claims (1)

Claim: Ultra-short wave transmitting and receiving arrangement according to patent 540,338, consisting from a two-, three- and multi-electrode arrangement in magnetron or braking field circuit in connection with a parallel supply line system shielded by a common plate, thereby characterized in that all or some of the direct current leads to the electrodes, preferably within the tube, are provided with compensating lengths of such a size that the supply line system represents a single-wave oscillating structure, so that this through the shielding plate can be tuned to the transmission frequency or optimally detuned. 1 sheet of drawings