DE1229593B - Method for the transmission of sinusoidal oscillations of the same amplitude and frequency in the channels of a carrier frequency system - Google Patents

Description

Method for the transmission of sinusoidal oscillations of the same amplitude and frequency in the channels of a carrier frequency system The invention relates to a Method for the transmission of sinusoidal oscillations with the same amplitude and Frequency from one and the same generator in the low-frequency position into the channels a carrier frequency system are fed whose carrier frequencies are phase-locked are derived from a fundamental frequency, so that the sinusoidal oscillations in the carrier frequency Lay next to one another in a phase-locked manner at the same frequency spacing.

There are known carrier frequencies of the above type in which one and the same generator produces a sinusoidal oscillation with the same amplitude and frequency and phase feeds into all channels in the low-frequency position. In this The connection is made to the publications published by Siemens & Halske AG »Channel converter racks for TF telephone systems« c (published March 1962) and »carrier supply rack for carrier frequency telephone equipment Rel 13 C 8 au (published November 1956) referenced; these frames are used, among other things, to set up the carrier frequency systems mentioned above. These signal oscillations are used, for example, to switch calls (for dialing, Counting or for free or occupied display), or they can be used to monitor a Channel are used; after all, it can also be an alternating current telegraphic sign Act. The carrier frequency then arises in the common transmission channel A frequency mixture composed of phase-locked oscillations, whose frequencies have a constant distance from each other. As shown below the resulting oscillation has the property that its amplitude is short-lived assumes extremely large values, namely with n oscillations up to n times the value of single amplitude. This is a disadvantage because the pulse-shaped peaks are the amplifiers and modulators can override the common transmission value.

The sum R (t) of n sinusoidal oscillations with the amplitude 1, the frequency spacing fz and the phase position 0 ° at time t = 0 can be represented analytically in the following form: Here com equal to the center angular frequency of the spectrum formed from the n oscillations, and is the envelope with which the oscillation cos a) m, t is modulated.

If, for example, one and the same generator feeds a sinusoidal oscillation with a frequency of 3.825 kHz into n = 60 channels of a carrier frequency system of the type mentioned at the outset, in which the zero frequency spacing is, in the position of the basic secondary group, which extends from 312 to 552 kHz, there is a total oscillation with the following 60 frequencies: 315.825, 319.825, 323.825 ... 551.825 kHz. In this case, in the above formulas and the center frequency The envelope has the following properties: 1. For col t = 0, 2Z ';' 47r etc. becomes H (t) = n (main maximum). Here lies a peak value of n times the value, the amplitude of a single oscillation; it is repeated at a time interval of so z. B. every 250 [, s at f1 = 4 kHz. The duration of this main impulse is with n = 60 oscillations so 8.33 #zs.

2. For etc. there are zeros for H (t) , their time interval amounts to; for the above numerical values, A t2 = 4.17 g sharp. :; 3. For secondary maxima occur for H (t) , the height of which decreases rapidly for large values of n in the vicinity of the main maximum, namely by about -the -factors compared to the value of the main maximum the secondary maxima thus only one vanishing Compared to the main maximum contain small amounts of energy.

In the F i g. 1 and 2 is the envelope as a function of Colt, for n = 60 and for n = 960 oscillations. The figures clearly show that the amplitude of the first pulse (main maximum) is directly proportional to the number of oscillations, its duration is inversely proportional to the number of oscillations. In the vicinity of the main maximum, almost the energy of all partial vibrations is "condensed". At col t = n, ie in the middle between the main maxima, an average power is available over a longer period of time, which remains below the power of a single oscillation; So here there is extensive compensation of the vibrations. In a very large area, e.g. B. ranges from 5 to 355 ° with 960 oscillations (corresponding to 97.2% of the basic period ), the instantaneous power is below the mean power value (rms value Aeff) of all oscillations, the amounts to.

Of the. The invention is based on the task of feeding high peak voltages caused by sinusoidal oscillations from one and the same generator to reduce in the common transmission channel.

According to the invention, in a carrier frequency system of the type mentioned in the opening paragraph, channels of the system are subdivided into groups of approximately those channels, with approximately 2 between the values can be selected, and the sinusoidal oscillations are fed into the channels of each group with such a phase that the phase step within each group is the same and increases from group to group, so that the phase steps c9, 299 ... (m-1) 99, with the basic phase step p approximately equal in degree is.

Through these measures it is achieved -that the individual channel groups assigned cumulative curves are shifted against each other in time, whereby the peak amplitudes the main impulses of the individual groups smaller by a factor of m than without temporal ones Are staggering. The actual profit on the totals curve may vary depending on the Choice of the time shift and the position of the secondary maxima somewhat smaller than be the factor m.

The scheme of the phase angle assignment for m groups with n channels each is shown in the table below. In addition, the phase step A b and the fictitious running time -c are specified for each group; the phase step A b is the increase in the phase angle from channel to channel in each group, and the fictitious transit time corresponds to the time shift of the cumulative curves assigned to the individual groups. Group channel ... n From a 1 2 3 1 0 0 0 0 0 0 2 0 91 29 @ ... (n -1) g9 <p 27vf1 3 0 2q @ 4 99 ... 2 (n-1) p 299 299 2 ac f1 m 0 (yn -1) @p 2 (m -1) p (m- 1) (n- 1) m (m -1) cp (m 1) 9 ' 2n f, When choosing the group classification, the following should be noted: Is a whole number and one chooses the main impulses that are shifted in time of the individual groups seamlessly together. If you choose j so the main impulses move a little apart, for overlap. It is particularly advantageous to choose the basic phase step (p in degrees so that the quotient results in an integer. One then only needs to generate the multiples of p, which are less than 180 °, in terms of the circuit; the angles over 180 ° can be produced by simply reversing the polarity of the relevant supply line.

The invention is illustrated below with reference to FIGS. 3 to 5 in one Embodiment explained in more detail. The exemplary embodiment is a 60-channel group based on. In detail, FIG. 3 the individual channels in the respective Group assigned phase angle, F i g. 4 the connection of a three-phase signal generator to the carrier frequency system, F i g. 5 the envelope curve of the resulting total oscillation from 60 individual oscillations.

For the carrier frequency system under consideration, let the 60-channel group be built up in three modulation levels: In the first level there are three Channels combined into a pre-group (frequency range 12 to 24 kHz), in the In the second stage, four pre-groups are bundled into a 12-channel primary group (Frequency range 60 to 108 kHz), and the third stage finally consists of five Primary groups a 60-channel secondary group (frequency range 312 to 552 kHz). Of the Zero frequency spacing is f; = 4 kHz, and the signal frequency may. 3.825 kHz.

The five 12-channel groups are expediently used for the time grading of the peak voltages that develop, corresponding to the structure of the system from five primary groups. The value m = 5 for z = 60 also results approximately from the formula The relationships are easiest in the case of group Grl: As FIG. 4 shows, the signal generator G feeds the signal oscillations into all channels 1 to 12 of this group with the same phase. The envelope curve of the resulting oscillation, which arises from the summation of the twelve individual oscillations, can be seen from FIG. 5 (solid curve Grl). The process is repeated at intervals of One could now think of distributing the curves assigned to groups Grl to Gr5 evenly over the period T = 250 #Ls. The impulse peaks of the groups would increase in each case shifted in time, corresponding to a phase shift However, this would be unfavorable for two reasons: First, the second secondary maxima would overlap with the main maxima and increase them by 12%; Secondly, a phase step of 72 ° would mean considerable effort in distributing the signal voltages to the individual channels, since 72 ° cannot be whole-numbered into 180 ° (i.e. the multiples of 72 ° to be set that are greater than 180 ° cannot be by simply reversing the polarity of the respective supply line).

In the exemplary embodiment, 9p = 60 ° is therefore selected as the “basic phase step”. The scheme of the phase angle assignment is shown in FIG. 3 and the table below. Channel group 1 2 1 3 4 5 1 6 1 7 8 9 10 11 1 12 1 0 ° 0 ° 0 ° 0 ° 0 ° 0 ° 0 ° 0 ° 0 ° 0 ° 0 ° 0 ° 2 0 ° 60 ° 120 ° 180 ° 240 ° 300 ° 0 ° 60 ° 120 ° 180 ° 240 ° 300 ° 3 0 ° 120 ° 240 ° 0 ° 120 ° 240 ° 0 ° 120 ° 240 ° 0 ° 120 ° 240 ° 4 0 ° 180 ° 0 ° 180 ° 0 ° 180 ° 0 ° 180 ° 0 ° 180 ° 0 ° 180 ° 5 0 ° 240 ° 120 ° 0 ° 240 ° 120 ° 0 ° 240 ° 120 ° 0 ° 240 ° 120 ° In the diagram of FIG. 3, the numbers of the twelve channels and the assigned frequencies kfi [cf. Formula (1)], the phase angles 99 to be set can be read off in degrees on the ordinate. A "fictitious running time" can be seen very clearly from the figure recognize for each group to which the time shift of the five curves Grl to Gr5 in FIG. 5 corresponds. In the exemplary embodiment, the transit time zero is assigned to the channel group Grl. The group Gr2 has the term This results in fictitious transit times of 2 - 41.7 = 83.3 V, s, 3 - 41.7 = 125 &, s and 4 - 41.7 = 166.7 Vs for groups Gr3 to Gr5. Shift in this way the curves of the five groups increase by 60 ', 120 °, 180 ° and 240 ° of the basic interval T = 250 #ts, which results from the channel frequency spacing of 4 kHz.

With this scheme there is a gap of one sixth of the period 250 g, s, in which no main maximum falls, as can be seen from FIG. this means but no disadvantage; on the contrary, the peak amplitudes are particularly low, because the time-shifted vibration groups always have their main maximum at one Position that lies exactly between two secondary maxima.

The distribution of the sinusoidal voltages on the channels is shown in Fig. 4. Of the Signal generator G provides three Phase voltages with the phase angles 0, 60 and 120 °. The phase shifts 240 ° = 180 60 or 300 ° = 180 -I- 120 ° are generated in that the leads with the assigned phase angles 60 polarity reversal or 120 °; this is indicated in FIG. 4 by an X next to the respective supply line indicated.

An important field of application of the method according to the invention is alternating current telegraphy, in which each speech channel is supplied with, for example, 24 alternating current Telegraphy channels can be exploited. In known AC telegraphy systems the 24 telegraphy channels are the carrier frequencies at a distance of 120 Hz 420, 540, 660 ... 3180 Hz assigned. To generate these carrier vibrations are usually separate, free-swinging generators are used, d. H.,. the frequencies of the carrier vibrations are incommensurable.

Let us now say, for example, 60 speech channels of the carrier frequency system considered above with 24 such. - AC telegraphy channels are occupied, so will Proceed appropriately with each individual telegraphic carrier oscillation as this already described when feeding a single sinusoidal oscillation per channel became. So you need 24 freely oscillating generators for the frequencies 420, 540, 660 ... 3180 Hz, each of which emits a three-phase voltage, with the three Phases are assigned the phase angles 0, 60; = and 120 °. The distribution of each keyed carrier vibrations on the five groups of twelve speech channels each entirely correspondingly, as shown in Fig. 4 for the generator G; between The telegraphy touch-sensitive devices are located at the respective generator output and the speech channel input.

Claims (6)

Claims: 1. A method for the transmission of sinusoidal oscillations that are fed with the same amplitude and frequency by one and the same generator in the low-frequency position into the channels of a carrier frequency system, the carrier frequencies of which are derived phase-locked from a fundamental frequency, so that the sinusoidal oscillations in the carrier-frequency position are phase-locked side by side at the same frequency spacing, characterized in that z channels of the system are subdivided into -m groups of approximately n channels each, where m can be selected between the values 2 and approximately, and that the sinusoidal oscillations are fed into the channels of each group with such a phase that the phase step within each group is the same and grows from group to group, so that the phase steps 97, 2 , p . . . (m -1) g9, the basic phase step 99 being approximately the same in degree is. 2. The method according to claim 1, characterized in; that the basic phase n step 9p is chosen in degrees so that the quotient preferably results in an integer. 3. The method according to claim 1 or 2, characterized in that when the sinusoidal oscillations are fed into 60 channels of a carrier frequency system, five 12-channel groups are formed into which the sinusoidal oscillations are fed with the same phase step that increases from group to group, and that the basic phase step is 99 = 60 ' . 4. Device for performing the method according to claim 3, characterized in that the generator delivering the sinusoidal oscillations. one Three-phase voltage gives off and that the three phases the phase angles 0, 60 and 120 ° assigned. 5. Application of the method according to one of the preceding claims for the transmission of alternating current telegraphy with incommensurable telegraphy carrier frequencies over the speech channels of a carrier frequency system. Considered publications: Siemens & HalskeAG publication, »Channel converter racks for TF telephone systems«, March 1962, especially p. 6, section »Call and Dial Transfer«; Siemens publication & Halske AG, »Carrier supply frame for carrier frequency telephone equipment Rel 13 C 8 a ", November 1956, in particular pp. 2 to 4.