DE1056184B - Signal receivers for message transmission systems for receiving signals outside the transmission band, e.g. B. Call or election signs - Google Patents

Description

In carrier frequency communications systems, it is common to be outside the call channel Signals, e.g. B. for calling or dialing purposes to transmit. In the receiving station these signals are separated from the Naicbridhteniband and used to operate a signal receiver at its output a relay is present.

There are already known signal receivers, the amplitude or frequency modulated signals in direct current symbols convert. One edge of the signal at the output of the receiver is followed by a DC symbol (current) and the other edge of the signal indicated by a gap (no current).

The invention is based on the task of controlling the speech sensitivity of a signal receiver as a function of the attenuation fluctuations of the transmission line. Since the interference amplitudes are roughly evenly distributed in the frequency spectrum, useful and interference voltages are present at the same time at the signal frequency. The distance between these voltages is not subject to any significant fluctuations. However, the changes in attenuation on the line produce considerable fluctuations in the signal and interference level. Since the receiver still has to respond to weak useful input signals, it is generally dimensioned for high response sensitivity.

Receivers are also known in which the sensitivity depends on what is received Signal level is controlled. In these cases the output level remains independent of the input level almost constant.

Since at low line attenuation the interference level is in the order of magnitude of that at high line attenuation existing useful level can come, is with high sensitivity or with the mentioned Control circuit possibly simulated a non-existent signal by the interference level and evaluated by the recipient.

According to the invention, these difficulties are avoided in transmission systems in which so-called pilot frequencies are transmitted for monitoring purposes. In the case of a signal receiver for communication systems monitored by a pilot frequency that is also transmitted, which is used to receive amplitude or frequency modulated signals located outside the transmission band, e.g. B. call or election signs, is used and in which the modulated signals are converted into direct current characters in such a way that in each case from one signal edge a voltage to generate the character state and from the other signal flange another voltage to generate the Lückenzustan signal receiver for message transmission systems for reception
from outside the transfer belt
lying signals,
e.g. call or election signs

Applicant:
International
Standard Electric Corporation _r
New York, NY (V. St. A.)

Representative: Dipl.-Ing. H. Ciaessen, patent attorney,
Stuttgart-Zuffenhausen, Hellmuth-Hirth-Str. 42

Claimed priority:
Great Britain March 29, 1956

Hector Th. Prior and Ernest S. Simmonds ₁ London,
have been named as inventors

which is derived at the receiver output, according to the invention, the pilot voltage is converted into a direct voltage obtained and used to control the receiver so that the sensitivity of the Receiver changes depending on the pilot voltage fluctuations. The one from the pilot voltage derived DC voltage also controls the receiver so that in the absence of input signals a predefined status (character or space) is present at the receiver output. In the case of the signal receiver according to the invention, the modulated Signals a single current symbol and a counter voltage derived so that by combining the two Voltages double current signs arise. The DC voltage derived from the pilot voltage becomes interconnected via a rectifier with the counter voltage in such a way that the rectifier is blocked is when the reverse voltage is greater than the pilot DC voltage. In the outgoing circuit of the recipient A differential receiving relay is arranged, one winding of which is from the direct current signal and which a direct current derived from the anode supply flows through the other winding. -

909 508/290

1

The invention will now be explained in more detail using an exemplary embodiment and the drawings.

In Fig. 1, a receiving station of a carrier frequency telephone system is shown in a block diagram. The voice band has a frequency range of 300 to 3400 Hz, the signal frequency is 4300 Hz. A group of modulated sidebands corresponding to the channels in the frequency range of 60 to 108 kHz is received via line 1. This group is fed to the channel filters by one of which is shown as block 2. The arrows indicate the feed line 3 to the remaining channel filters. The channel sideband 2 is demodulated in the demodulator 4. The voice frequency band is then passed through a filter 5 to the voice amplifier 6. The signal frequency is transmitted to the the signal filter 7 and the receiving part is guided 8 existing signal receiver. in this receiver a transmitted with the channel group pilot frequency is also according to the invention passed. this frequency can be, for. example, be 61 kHz. the pilot frequency is screened through a filter 9 and rectified in the rectifier 10. The pilot DC voltage produced at the output 11 of this rectifier can also can be used to control the other signal receivers, so that the pilot filter 9 and the rectifier 10 need only be present once for each channel group.

The signal receiver is shown in Fig. 2 in detail. The voice band and the signal frequency are fed to the input terminals 12, 13 , which are connected to the primary winding of the transformer 14 via a capacitor 15 . The secondary winding of the transformer 14 is terminated by a resistor 16. The transformer is tuned to the signal frequency 4300 Hz by the capacitor 15. The resistor 16 is chosen so that a sufficient bandwidth is obtained.

The actual receiving part contains the tubes 17 and 18, which are supplied with anode current via the terminals 19 and 20. The tube 17 serves as a preamplifier. The tube 18 forms part of the conversion circuit for the modulated signals. In the anode circuit of the tube 18 there is a winding 21 of a differential relay in series with the primary winding of a transformer 27. The control grid of the tube 18 is connected to earth via the resistor 29 and the rectifier 30 connected in series with it: the rectifier 30 is polarized so that it is blocked when the lower connection point of the resistor 29 has positive potential. An adjustable resistor 31, which is not bridged by a capacitor and therefore causes negative feedback, is located between the cathode of the tube 18 and earth. With the help of this controllable resistor 31 , the anode current of the tube 18 can be adjusted.

The secondary winding of the transformer 27 , together with the elements 32 to 35, forms a bandpass filter which has a bandwidth of approximately 160 Hz and a center frequency of 4300 Hz. This bandpass serves both as a delay network and as a filter for the signal frequency. At the output of this filter there is a rectifier 37 which rectifies the signal frequency after a delay and which is polarized in such a way that the charging of the capacitor 39 causes a positive potential with respect to the common line 36 of the filter. The rectifiers 40 and 41 each rectify part of the signal frequency and thereby generate corresponding voltages on the capacitor 43. They are polarized so that

that the line 46 with respect to the line 36 receives a positive potential. As a result of the delay in the bandpass filter, there is also a time delay between the voltage given by the rectifier 40 and the voltage given by the rectifier 41.

The winding 47 of the differential relay is connected in series with two resistors 48 and 49 to the anode voltage source, which is connected at 19 and 20. The line 46 is connected to the common point of the resistors 48 and 49 and therefore has a fixed potential.

The tap of the potentiometer 38 is connected via a resistor 50 between the elements 29 and 30 , so that the direct voltages derived from the signal frequency are fed back to the input of the tube 18.

Sndung derived from the pilot-voltage direct voltage to the terminals 51, performed 52 ^- in this known circuit arrangement of the egg will now invention. The negative terminal 51 is connected to the line 46 via a potentiometer 53 , and the positive terminal 52 is at the connection point of the resistors 54,55, which are parallel to the anode voltage source. The tap of the potentiometer 53 is connected to the line 36 via a rectifier 56 , the polarity of which is such that it is blocked when the line 36 has a negative potential with respect to the potentiometer tap. The resistors 54 and 55 are chosen so that the potential at the resistor 55 is equal to the potential at the resistor 49 .

When there are no input signals, the potential applied to the grid of the tube 18 through the resistor 50 is low, so that the anode direct current is also small. The current through the winding 47 of the differential relay is adjusted by a suitable choice of the resistors 48 and 49 so that the relay contacts 57 are in the desired rest position when no input signals are present. This bias setting is used at the same time to generate the bias for line 46 , which can also be supplied with voltage via another voltage divider. When a signal arrives at the input of the receiver , the potential on the control grid via resistor 50 is increased, so that the anode direct current is also increased and the relay responds.
Instead of the contact set 57 , another contact set can of course also be used.

Figure 3 is a graph of the incoming and evaluated pulses. These pulses can be of different lengths, as shown in FIG. 3A. Since the transmission channel has a limited bandwidth, the pulses are no longer rectangular after rectification, but the edges are inclined, as shown by the dashed curves in FIG. 3 B is indicated. The signal channel can be viewed as a special form of a single-stream telegraphy channel and the state when there is no input signal (pulse voltage 0 '; Fig. 3 A) as a gap state and the state when an input signal is present (pulse voltage + V; Fig. 3 A) refer to the character status.

The duration of the pulse 59 is chosen so that the rising curve 65 has just reached the peak value + V when the falling curve 67 follows. Since the pulse 58 is shorter, the peak value + V is not reached in this case. To operate the relay, the voltage V ₂ is generally used, since the distance between the two inclined edges in this case

Claims (1)

Voltage corresponds to the duration of the original pulse. For this purpose, a fixed bias potential V2 is obtained by integration from the curve shown in FIG. 3C, which is added in the opposite direction to the potential of the rectified symbols, so that double-current symbols are obtained whose zero crossings correspond to the spacing of the original signal. In the case of short impulses, this counter-potential is too low. For this reason, two separate counter-voltage potentials are derived from both the leading and trailing pulse edges. This method is well known and is also used in the receiver shown in FIG. The rectifier 40 rectifies the voltage taken from the tap of the secondary winding of the transformer 27 and generates the dotted curves 70 and 71 shown in FIG. 3 D on the line 46, which correspond to the pulses 68 and 69 of FIG. 3C. These voltages are used as counter voltages for the leading edge of the pulses. The same but time-delayed voltages, which are represented by curves 72 and 73 in FIG. 3D, arise at rectifier 41. They are used as counter voltages for the trailing pulse edges. The time delay is selected so that the peaks of the counter-voltage curves 71, 73 appear approximately at the times when the amplitude of the pulse 69 is equal to +. For longer pulses the amplitude of the corresponding counter voltage is also '+ V2. According to the invention, these counter-voltage curves are now changed by the additionally introduced pilot voltage. As long as the counter voltage generated at the resistor 45 exceeds the value + P between the line 46 and the potentiometer tap 53, the rectifier 56 is blocked and the pilot control voltage has no effect on the operation of the circuit. If the counter voltage is less than + P, the rectifier 56 becomes conductive and the two rectifiers 40 and 41 are blocked. The counter voltage on the line 46 is therefore held at the + P potential. This potential is indicated in FIG. 3 D by the solid parts of the line 74. The rectifier 40 is blocked when the voltage at the rectifier 41 is greater, and vice versa. The peak values represented by the solid line of the curves 70 and 71 in FIG. 3D are thus generated by the rectifier 40 and the peak values of the curves 72 and 73 by the rectifier 41. When both rectifiers are blocked, the voltage shown by the dotted lines of the curves is created. The solid curve in FIG. 3 D thus shows the changes in the counter voltage present between lines 46 and 36, while the dotted lines indicate the voltage profile for the case that there are no potential differences between the rectifiers. In Fig. 3 E, the differences between the curves of FIGS. 3 C and 3 D are shown. This curve shows the voltage profile between the potentiometer tap 38 and the line 46. The zero crossings of this curve correspond approximately to the width of the original pulses. When there are no input signals, a constant potential - P is generated on line 46 by the pilot voltage. The potentiometer 38 should be set so that the amplitude generated is exactly V2 in accordance with the curve shown in FIG. 3D. The bias voltage of the control grid of the tube 18 is equal to the potential difference V between the potentiometer tap 38 'and the line 46 plus a constant positive potential Vv which is generated by the voltage drop across the resistor 49. If the cathode potential generated at the resistor 31 is referred to as V2, the grid-cathode potential of the tube 18 is equal to ν + V1-V2. This voltage, shifted downwards by the value V1 and V2, is shown in FIG. The rectifier 30 limits the potential supplied to the control grid. If this voltage is less than zero, the rectifier 30 becomes conductive and limits the grid voltage so that the smallest grid cathode potential is equal to −V2. The grid potential is limited to the positive side by using the grid current, so that the maximum grid-cathode potential is approximately zero. The resistor 50 'supports the limiting effect of the rectifier 30 and prevents an undesired influence of this rectifier on the other rectifiers. The resistor 29 prevents an undesired mutual influencing of the alternating voltages and the direct voltages at the control grid of the tube 18. Part of the grid voltage-anode current characteristic curve of the tube 18 is shown in FIG. The limit values of the grid-cathode voltage are marked with 0 'and - V2, the associated anode currents are I1 and J2. If there are no input signals, the negative grid-cathode potential determined by the pilot voltage is slightly less than - V2 and has e.g. B. the value marked 75. If signals are received, then the grid-cathode potential shifts to almost 0, as indicated by point 76. The anode current increases accordingly, and the bias voltage - V2 is determined by the resistor 31 so that the relay responds when the grid-cathode potential reaches the value - (V2 - P1), which is the zero crossing of the in Fig. 3 E corresponds to the voltage curve shown. The response current I is shown by the dotted line 77 in FIG. The relay thus reproduces the rectangular pulses 58 and 59 shown in FIG. 3A. Since the tube 18 is intended to amplify the input signal before rectification, the points 75 and 76 must lie on the straight part of the characteristic curve (FIG. 4). If there are no input signals, the relay is held in the idle state by the counter voltage applied to winding 47. The signal receiver according to the invention can also be used as a receiver for carrier telegraph signals without significant changes. In an AC telegraphy system, the carrier frequency is much closer to the signal frequency than in the telephony system described above. In this case, the smoothing of the current flowing through the rectifiers 37, 40 and 41 with the aid of the resistance capacitance elements will not be sufficient, and better filters must be used. Patent claims: 1. Signalemp'fänger for message transmission systems monitored by a pilot frequency that is also transmitted for receiving amplitude or frequency modulated signals lying outside the transmission band, e.g. B. Call or Elective symbol in which the modulated signals are converted into direct current symbols in such a way that