DE349355C - Arrangement for simultaneous sending and receiving with different or the same wavelength for wireless or line telephony - Google Patents

Description

In the field of simultaneous transmission and Received with the same antenna for wireless telegraphic and telephony are those The work of fessende is particularly important. Already in the patent 208750 this gives a solution to the two-way talk problem by attaining a voltage equalization in the connection points of the receiver with the help of a force absorbing system as a branch of a bridge circuit. In a similar way In recent times, the task of speaking through the arrangements is wise Bridge circuit in German patents 274925, 299094 and 308423 solved been. All bridge circuits have the disadvantage that when aligning the System antenna-earth through a system equal to the alternating current resistance expended Only half of the energy can be made usable and that means that the normal range of the Station is significantly reduced. The white

Refer to further methods given by Fessenden in patents 208748 and 242956 essentially relying on two-way communication by means of beat reception, bd which method the large differences in the amplitudes of the transmit and receive waves do not significantly interfere with reception when transmitting at the same time. However, have disturbing repercussions in the practical implementation of these two-way communication arrangements of the transmit circuit to the receive circuit when closing and opening the transmit button result; and to eliminate these disturbances - as indicated in patent 242956 —- a compensation transformer directly operated by the transmitting circuit in the receiving circuit (124, 126 in the drawing there) switched on.

Our arrangements offer to help with the solutions of the two-way talk problem bridge circuits have the advantage that they work without energy loss because we are with Arrangement of the compensation elements in the grid circle of hot cathode tubes Avoid force absorbing systems. Opposite the arrangements with beat reception the arrangements described below have the advantage that the stations speaking to one another can choose the wavelengths are completely independent. "

The following description of the simultaneous sending and Receiving is divided into two larger parts, the first of which is from the two-way communication different transmit and receive wave, the second from two-way talk with the same Transmit and receive wave acts.

If the reception wave is different from the transmission wave, the arrangement shown in FIG. 1 enables simultaneous transmission and reception with one antenna. The high-frequency generator 1 distributes the transmission energy to _{the oscillation circuit 2, which is tuned to the wavelength X 1.} The oscillation circuit 2 is on the one hand via a phase shift apparatus 5 with the circuit 6, which also j. is matched to X ₁ , coupled. In the lattice 1 circle of the tube 7 with the series: battery 8 and the oscillation circuit 6 is still i one behind the other the oscillation circuit 4; this ; is on the wavelength X _{2 of} the one to be received; Wave tuned. The very high at negative 'grid voltage resistor grid-cathode is any operation - for example ^by: galvanic coupling - the two oscillation circuits 4 and 6 is prevented each other. ; The oscillation circuit 2 is to be used as a transmit circuit, ^[ oscillation circuit 4 as a receive circuit! see. The advantage of the> compensation device described here over that stated by 'Fessenden in patent 242956 to compensate for the disruptive effects of transmitting organs on receiving organs when closing and opening the pushbutton is essentially that we do not use transformers to adjust the high frequency - i.e. aperiodic switching elements -, but through oscillating circuits - periodic switching elements - happens; This is only possible because the two oscillating _{circuits (4 of which are tuned to receive wavelength X 2} , the other 6 to transmit wavelength X ₁ ) are separated from tube 7 by the high resistance grid-cathode in the grid circle. Fig. 2 gives a comparative picture of the amplitude sizes of the vibrations which are caused on the one hand by the transmit wave X ₁ and on the other _{hand by the received wave X 2} in the oscillation circuits 2, 4 and 6.

The mode of operation of the circuit is now as follows:

If transmission waves from circle 2 matched to X ₁ go into the antenna, then because of the high amplitudes of the transmit oscillations («in circle 2) in the _{receive oscillation circuit 4, which is matched to the other wave line X 2} , amplitudes of the size c in Fig 2 can be generated. However, their effect on the grating of the first receiving tube 7 is canceled out by the fact that they are countered by vibrations of the same amplitude but opposite direction (e in Fig. 2) from the circle 6 matched _{to X 1.} These oscillations are fed to the circuit 6 in the correct size and direction via the phase shifter 5 by coupling with the transmission circuit 2. As a result of the transmitted oscillations, the potential of the grid of tube 7 against the cathode remains at rest. If, on the other hand, incoming waves of wavelength X ₂ hit the antenna, the receiving circuit 4 picks up these under optimum conditions (cf. d in Fig. 2) and passes them on to the grating of the pipe 7; ₁ tuned transmission circuit 2 is only excited up to amplitude b (Fig. 2), and already very weakened vibrations of wavelength X ₂ that are still passed on by circuit 2 are no longer picked up by compensation circuit 6 because it is also tuned _{to X 1} There is no longer any compensation effect for the incoming waves, rather the incoming waves are strictly separated from the outgoing waves by this circuit, if only the wavelength of the received wave differs from the transmitted wave.

The arrangement shown in Fig. 1 is for simultaneous sending and receiving, with

only one wavelength not usable; because the transmission circuit 2 and the compensation circuit 6 would be tuned to the same wavelength like receiving circuit 4, circuit 2 would be excited just as strongly by the incoming wave like circle 4 and its vibrations will communicate in full strength to circle 6, so that the incoming waves are compensated just like the sent out waves.

An arrangement for simultaneous transmission and reception with only one wavelength is shown by Fig. 3. The high-frequency vibrations come there via the long-distance line, as in line wave telephony 9; but the absorption and transmission of the vibrations could of course also take place through an antenna. The individual parts of the Circuit are as follows: 15 is the first tube of the receiver. 16 is a high frequency amplifier, 17 a high frequency rectifier. 20 indicates a so-called amplitude compensation tube which, due to its saturation current, wave trains of unequal Amplitudes reduced to a wave train with constant amplitude as soon as through the unequal amplitudes of the wave train to be adjusted each time the grid voltage is exceeded, which already causes the saturation current of the pipe. 21 is a End energy tube, which amplifies the vibrations coming from the amplitude compensation tube 20, which are then fed to the oscillating circuit 26 via the phase shifting apparatus 22. 18 is the transmission tube, its Grid 19 is usually only on the oscillating circuit 26 and on the coil 31, which but can be connected to the oscillating circuit 24 through the two-pole switch 23 via the high resistance 35, the resonant circuit 26 is then short-circuited. The high resistance 35 in the transmitter circuit used here - but also other tube transmitter circuits in its place can be used - is roughly equal to the mean grid-cathode resistance of i8, and it prevents a Short-circuiting the coil 31 via the self-induction of the oscillating circuit 24 (when switching of the switch 23 in the position shown in dashed lines). The coil 31 is for the purpose better setting a variable resistor 30 connected in parallel. The primary pages 32 and 33 of the two voice frequency transmitters 31, 32 and 33, 34 is the current in voice frequency supplied from the microphone 28. For the high frequency, the bypass capacitor 37 is connected in parallel to the coil 34, as well as at the calling station of the coil 31, nor the bridging capacitor 36 must be laid in parallel. The oscillation circles 24, 25 and 26 are tuned to one and the same wavelength. In the lattice

; circle of the first receiving tube 15 lie one behind the other the battery 29, the coil 34 and the oscillating circuit 25; these three eggs

, mente supply the control voltage of the pipe 15. The operation of the circuit is now the following:

The station shown is the one called; the switch 23 then has the one drawn in full Position. The incoming oscillations excite the oscillation circuit 25, and since this lies in the lattice circle of the pipe 15, becomes after passing the amplifier 16 and the rectifier 17 that of the other Station broadcast voice can be heard in telephone 27. Would go through now without further ado If the oscillation circuit 24 are sent by the station shown, then the immediate Impact on the receiver of the same station make further understanding of the other station impossible. To a The high-frequency vibrations are now used to cause the emissary to separate out what has been received of the emitted wave train in phase with the high-frequency oscillations of the same frequency as the incoming one Brought wave train. This happens' by the fact that after reinforcement of the incoming Oscillations, i.e. after 16, the oscillations to compensate for one and the same Amplitude are sent into the amplitude compensation pipe 20. After completing the task of 20 actuate the vibrations the end energy tube 21 and then excite after passing the phase shifter 22 the Oscillating circuit 26, which in turn is coupled to the grating 19 of the tube transmitter 18 is, so that the perfect synchronism of the incoming high-frequency oscillations 1 οΌ with the sent out is guaranteed by this arrangement. Now the The amplitudes of the waves given by the station shown are always around the amplitudes of incoming waves can be increased as illustrated in Fig. 4. 10 and 13 are those fluctuating around a certain - temporarily fixed - zero value 14 Amplitude heights of the transmitted waves, and ix on the one hand indicates the over- χ increases in these amplitudes by those resulting from the received waves. so is through the transformers 31, 32 and 33, 34 - which the simple voice frequency oscillations received from the microphone 28 - a device given that the the sent Voice frequency superimposed on waves, which is also controlled by the oscillation circuit 25 recorded and thus brought into the lattice circle of the tube 15, through opposite compensates for running voice frequency wave trains. Fig. ' 4 illustrates

do this as follows. 13,12,10 and 11 give the amplitude curves at the grid of 15 again when the action of the transducer 33 34 is intended to be switched; If, on the other hand, this comes into action, then there is the one evoked in 34 Current curve the previously thought constant mean value of the oscillations 12 the shape 12 ' - which is exactly the same as that of 13 - so that that of the The amplitude curve 10 resulting from speech now assumes the form io ', i.e. a straight line Line. The differences between 10 and 11 remain unaffected, so that we have cleaned the amplitude curve of the incoming waves in 10 '. There through the transformers in front of the telephone; 27 to this only the amplitude fluctuations to get to curve ii ', this will be the case here! Envoys from the other station heard undisturbed despite simultaneous transmission. the Operation of the transformer 33, 34 accordingly differs from the operation of the 124,126 transformer specified in patent 242956 - the high frequency transformer serves for simple adjustment of the high frequency - basically by the fact that 33, 34 in Fig. 3 is only a transformer built for voice frequency and for balancing the one changing in voice frequency; The amplitude curve of the high frequency is used, without that the high-frequency vibrations are destroyed, as is the case with expansion the circuit given by Fessenden in patent 242956 would be the case, as If the station shown is not the one called, but the calling one, the switch 23 must be set as it is indicated by dashed lines so that the grille 19 is placed directly on the resonant circuit 24 via the resistor 35 to a self-exciting Obtain high frequency generator. The other station then of course has the j Switch 23 in the solid j position. . . . .

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Claims (5)

Patent Claims: i. Arrangement for simultaneous transmission and reception with different or the same wavelength for "wireless or; line wave telephony using: a compensation circuit, characterized in that the compensating \ switching element with the receiving circuit, i its fluctuations (insofar as they come from the own transmitter ) are to be compensated, one behind the other with the grid-cathode resistance, which is kept very high by a negative grid potential, so that any influence on the receiving circuit by the compensation elements due to the very high grid-cathode resistance is prevented. 2. Arrangement for intercom with. different wavelength according to claim i, characterized in that an oscillating circuit is used as the switching element for compensation which is based on the wavelength of the vibrations emanating from the station is tuned and is actuated by these, and which with the · receiving oscillation circuit and the Resistance grid-cathode is connected in series. 3. Arrangement for two-way talk with one wavelength according to claim i, characterized characterized in that in the grid circle of the first receiving tube with the Reception circuit and the resistor grid-cathode in series the secondary coil of a Transformer for audio frequency is switched. which the transmitted speech wave in the way - used for adjustment that the amplitude curve of the transmitted high frequency wave at a constant value is brought, beyond the synchronous with the transmission wave, received Waves create fluctuations. 4. Connection of a tube transmitter for use in intercom stations according to Claim 3 with an oscillating circuit lying in the anode and one for Audio frequency built, for .Übermittung the speech serving transmitter in Lattice circle, characterized in that the secondary coil of the transformer is parallel to the resistance grid-cathode, with a mean alternating current resistance ^ Grid-cathode - approximately the same resistance in the lead of the grid and the secondary coil of the transformer is connected to the resonant circuit. - ... . . ; 5. Arrangement to achieve synchronism between the sent and received wave according to claim 3, characterized in that when using a tube transmitter in the called Station the grid of the transmission tube not from its own oscillation circuit, but actuated by the received waves brought to constant amplitude level by an amplitude equalization tube will. . For this purpose ι sheet of drawings