DE1537678C3 - Circuit arrangement for the transmission of sinusoidal oscillations of the same amph tude and frequency via channel converter racks with 120 speech circuits of a carrier frequency system - Google Patents

Description

The invention relates to a circuit arrangement for the transmission of sinusoidal oscillations, which are fed by one or more signal generators, each with the same amplitude, frequency and phase, into a large number of channels of a carrier frequency system, the carrier frequencies of which are preferably synchronized, using channel converter racks for 120 Speech circles in which, with the help of pre-group modulation, 12 voice bands are brought into the basic primary group position 60 to 108 kHz and in which the coherent feed of / sinusoidal oscillations in the common transmission. ^ away high pulse-shaped voltage peaks and disruptive intermodulation products, the signal oscillations in each channel converter rack according to a method according to patent 1487 443 according to the same group type with a leveled envelope, while the carrier oscillations are fed to the modulators within a group of 240 channels. 12-channel group to 12-channel group are supplied with different polarity, such that all carriers are switched on smoothly in the first channel converter rack, except for 12-channel groups 6 to 10, in which the channel carrier is switched on with a polarity reversal of 12 kHz , and the 12-channel groups 2 to 5 and 7 to 10, in which one of the pre-group carriers 120, 108, 96 and 84 kHz is switched on with reversed polarity.

The frequency plans of most SSB carrier frequency systems is based on the 12-channel basic primary group 60 to 108 kHz. Your Structure in the channel converter when using pre-group modulation is shown in FIG. 1. In the first modulo There are three language bands - each ranging from 300 to 3400 Hz - after implementation with the Channel carriers 12, 16 and 20 kHz combined into three-channel pre-group 12 to 24 kHz. Four of them Pre-groups are then in the second modulation stage after implementation with the pre-group carriers 84, 96, 108 and 120 kHz brought into the position of the basic primary group 60 to 108 kHz.

Newer design channel converter racks contain the facilities for 120 speech groups, i.e. ten Primary groups. A 12-channel primary group forms a device insert that is arranged vertically in the frame is (vertical construction). With this frame type, the channel and sub-assembly carriers and the 3850 Hz signal voltage generated in the carrier supply insert, which is designed for 240 to 600 channels; d. In other words, in addition to your own frame, you can have one to four frames with carrier voltages and with the Signal voltage 3850 Hz. The connection of the other racks to the supplying one The frame is done using multiple cables and plugs. Usually the base frequency is 4 kHz, off which the various carrier frequencies are derived, generated centrally in the terminal and the

Carrier supply inserts supplied. In this case, rigid phase angle relationships prevail Carrier in all supplied channel converter racks at the terminal. But it can also be used in every carrier supply operation its own 4 kHz generator

be built so that the phase rigidity extends only over 240 to 600 channels. In both cases they are Polarity reversal measures in the signal and / or carrier path specified in the main patent application are equally good 5 effective.

table

Signal voltage
after
Group type 1 2 3 4th 5 channels
6 7 8th 9 10 11 12 Gl X X X X

table

Channel converter 19 tfnml signal 12th 16 Carrier in kHz 120 108 96 84 Frame for Primary- voltage 120 speech JTl 1111dl after . 20th X . . circles gl lip Group type X 1 1 Gl . . X . 2 Gl . . X 3 Gl X • • • 4th Gl X X 5 Gl X . X . 6th Gl X . X . 7th Gl X • ■ · • • X 8th Gl X . ■ . 9 Gl . X • X . 10 Gl X . X 2 11th Gl X . X . 12th Gl X . X 13th Gl . . . 14th Gl . X . 15th Gl X . X . 16 Gl X . X . 17th Gl • • X • • • X 18th Gl X 19th Gl X 20th Gl

It mean

the symbol smooth connection of the respective supply line, the symbol χ polarity reversal of the respective supply line.

table

Carrier scheme 1 2 3 4th 5 channels
6 7 . X 8th 9 10 11th 12th TU X X . X TU X . X . • X . X . TlQ • • X • X . X • • X 7-20 X X X . • . ■ • Γ108 . X X X X Γ96 . . • X X . T84 • • • • • • X X X

Table 4

channel 12-channel Equivalent group type Gl TUO • Γ96 • Γ84 • Γ84 1 2 3 4th 5 V ^- Or läJc 8th 9 10 11th 12th converter Primary- Gl ■ TUO T "t ftß Γ84 _m X JVd.] 7th X _φ X frame group Eq 7-08 1 XUo
Γ96 Γ84 X X X • X 6th ■ X . X KUl 1 Eq ■ T96 Γ84 • Γ84 . X X . • X X 2 Gl · T84 ■ T96 X X . X . . X or. 3 Gl · TU TUO Γ108 • T96 • • • • X . X • X X • X 4th Gl ■ TU Γ108 T96- Γ84 X • • X X X • • X X X KUIl 5 T96 T96- Γ84 . X X X X X X X X X (Fig. 2 6th Gl · TU ■ T84 7-08 ■ Γ84 X X and 4) 7th Gl · TU ■ TU 7-08 • Γ96 X
X X X X W. X X
X X
X O Equation T16 TU ■ TUO X • • X X X • X • • X O
9 Eq ■ T16 ■ TU - 7-08 . X . . X X X X 10 Gl TU TU - T96 X . X • . X X X KUl 11th Gl-TU- TU - Γ84 X '. X X X X X (Fig. 2) 12th Gl - TU ■ TUO - 7-08 X '. . X . . . . 13th Gl TU - 7Ί08 · Γ96 · . X . . X X X X X X 14th Gl · TU ■ TUO ■ T96 ■ X X • X X . X X X 15th Gl TU TUO ■ 7-08 . · . X X . X X X X X . 16 Gl · TU ■ TUO ■ 7-08 X X . X X X X X X 17th Gl-TU- TU - TUO ■ X X X X X . . X . . 18th Gl ■ TU - TU ■ Γ108 · X X • X • . . X X • X X 19th Gl - TU ■ TU - TUO - X . X X X X X . X X X 20th Gl - TU - TU ■ TUO - . X • X X X X • X X X KUU 11th Gl ■ TU ■ TU ■ TUO · X . X . . X • X X X (Fig. 4) 12th Gl - TU - X X X X • X X X X X X 13th Gl ■ TU ■ X X X X X . . . 14th Gl ■ TU . . X . X X X X 15th Gl ■ TU ■ X X . X . X X 16 Gl - TU ■ . X X . . . X X 17th Gl ■ TU . X X . . X X X X 18th ■ • X • X X X • • X • 19th . • 20th •

According to the main patent application, groups of 240 channels - comprising two channel converter racks for 120 speech circuits - are formed in the construction of multi-channel carrier frequency systems, within which the carrier-frequency envelope is changed from 12-channel group to 12-channel group. The signal oscillations for all 12-channel groups are recorded according to one and the same group type with a leveled envelope curve - e.g. B. Gl - fed in; the circuit diagram for the group type Gl is shown in Table 1. The change in the envelope curves is achieved by suitable polarization of the carrier oscillations, as is indicated in Table 2 (corresponds to Table 2 in the main patent application). In this way, 20 different envelope curves are obtained in the carrier-frequency path, the combination of which to form the overall envelope curve prevents the voltage peaks from colliding.

From Table 2 it can be seen that the two channel converter racks 1 and 2 must be wired differently; but this is for manufacturing Sales and use of carrier frequency systems are disadvantageous.

The invention is based on the task of reversing the polarity in such a way that 20 different carrier-frequency envelopes are created for 20 primary groups of two channel converter racks each, but the channel converter inserts and the racks are wired in a completely uniform manner, so that there are no restrictions on their use .
In the circuit arrangement according to the invention, the polarity of the carrier in the first channel converter frame corresponds to the polarity proposed in the main patent application and given in Table 2. The present object is achieved according to the invention in that, with the same line routing in both channel converter frames, the polarity reversal

. - took in the second frame compared to the first in at least one carrier interchanged and be carried out in the same way for the other carriers.

There are channel converter racks known in which

. Carrier supply Carrier output transformer with secondary winding grounded on one side can be used. In this case, the polarity reversal measures are expediently opposite in the second channel converter frame the first frame only interchanged for the 16 kHz carrier and the same for the other carriers performed. There are five polarity reversers for polarity reversal within your own frame provided, which are assigned to the carriers 12, 120, 108, 96 and 84 kHz, while for the polarity reversal A further polarity reversal transformer is provided from frame to frame, which is assigned to the carrier 16 kHz.

Are in the carrier supply of the channel converter

Frames used output transformers that emit two voltages offset in phase by 180 °, see above the polarity reversal transformers can be omitted. In this case, it is particularly advantageous to use the second channel converter frame the polarity reversal measures compared to the first frame for the carriers 16,120,108, 96 and 84 kHz interchanged and made the same for carriers 12 and 20 kHz. Included the carriers 12 and 20kHz are smooth from frame to frame and the carriers 16, 120, 108, 96 and 84 kHz reversed polarity switched on.

The invention is explained in more detail below with reference to FIGS. 2 to 4 using two exemplary embodiments explained, It shows

2 shows the basic wiring of the carrier lines in two channel converter racks when using carrier output transformers with one-sided earthed secondary winding,

F i g. 3 a carrier output transformer that emits two voltages offset in phase by 180 °,

F i g. 4 the basic wiring of the carrier lines in two channel converter racks when used of carrier output transformers according to FIG. Turn of carrier - output transformers after F i g. 3.

F i g. 2 shows the basic wiring of the carrier lines in two channel converter racks for 120 speech circuits KUl and KUl. (The feeding of the 3850 Hz signal oscillations is not shown; it should - as suggested in the main patent and shown in Tables 1 and 2 - take place, for example, according to the group type Eq .) The first channel converter frame KUl contains the carrier supply TV, which also the second Frame KUl and possibly three further channel converter frames supplied. The carrier voltages are switched from frame to frame via multiple cables and plugs.

In the carrier supply TV are the output transformers UU, t / 16 and UlO for the channel carriers 12, 16 and 20 kHz and the output transformers t / 120, t / 108, U96 and t / 84 for the sub-carriers 120, 108, 96 and 84 kHz indicated. The secondary windings of these output transformers are each grounded at one end.,. · <, Since the carriers are fed to the modulators unbalanced to ground.

The two channel converter racks each contain ten primary group inserts, those with PG1 to PG10 and PGI1 to PG20 are designated. The beam clamps are shown as small circles, with a Crossed circle means that the polarity of the carrier at this terminal is reversed compared to the "white" terminals is.

Like F i g. 2 shows, in the first channel converter frame KUl, the polarity of the carrier corresponds to the polarity proposed in the main patent application and indicated in Table 2. The requirement for the same wiring of the carrier lines in both racks is due to the polarity of the channel carriers 12, 16 and 20 kHz deviating from Table 2

ίο realized in the second channel converter frame KUl .

In the second channel converter frame KUl , the

Polarity reversal measures compared to the first frame KUl are only exchanged against each other for the 16 kHz carrier and carried out in the same manner for the other carriers. For the polarity reversal within the own frame, the Umpolübertrager Ul are required to t / 5, which are assigned to 12 kHz and the Vorgruppenträgem 120, 108, 96 and 84 kHz the channel carrier. These carriers, as well as the channel carrier 20 kHz, are switched through smoothly from frame to frame. The polarity reversal transformer i / 6, which is assigned to the 16 kHz channel carrier, is provided for polarity reversal from frame to frame. In this way it is achieved that in all channel converter racks the wiring of the carrier feeds is completely identical, but each of the 20 primary groups is assigned a different carrier-frequency envelope. The polarities of all carriers in both racks now match, with the exception of the 16 kHz channel carrier, in which the polarity reversal transformer t / 6 ensures that polarity reversal occurs in every second rack.

The fact that 20 different carrier-frequency envelopes result from the polarity reversal measures according to the invention is shown particularly clearly in Table 4, which shows the resulting 20 different "equivalent polarity reversal schemes" for the channel converter racks KUl and KUl. The equivalent polarity reversal scheme is understood to mean the polarity reversal scheme related to the signal voltage with smooth connection of the carrier voltages. It is explained in detail in the main patent application that the equivalent polarity reversal scheme results from a symbolic multiplication of the group type with the carrier scheme. The carrier schemes that express the effect of the polarity reversal on the signal voltage in the respective channels are compiled in Table 3. For example, in the frame KUl for the primary group 2 the equivalent group type Gl 7Ί20 is obtained with the following scheme:

1 2 3 4 5 channels
6 7 8th 9 10 11th 12th Gl
Γ120 X X X X X • X • X • Eq ■ TIlO X X X X X • X • X

The polarity reversal transformers i / l to i / 6 in the channel converter racks according to FIG. 2 can be omitted if TV output transformers according to FIG. 3 are used in the carrier supply. The secondary winding of this transformer has a grounded center tap, so that two carrier voltages offset in phase by 180 ° are output to the channel converter via separate coaxial lines.
The circuit arrangement according to FIG. 4 shows the basic wiring of the carrier lines in two channel converter racks KUU and KUU, in whose carrier supply TV the output transformer UMH,

309 509/130

UMU, UMUO, UM1Q8, UM96 and UMM for the carriers 12, 16, 120, 108, 96 and 84 kHz according to FIG. 3 are switched. The channel carrier 20 kHz is assigned an output transformer £ / 20 without a center tap, since this carrier is not reversed in polarity in the channel converter racks.

The carrier poles in the channel converter racks KUIl and KUl are in principle completely the same. The carrier poles in the second frame KU12 could also be made in the same way as is the case with the frame KU1 . However, this would have the disadvantage that the two secondary partial windings of the output transformer with center tap would be unevenly loaded.

The polarity reversal measures compared to the first are therefore carried out in the second channel converter frame KU12

10

Frame KUIl for the carriers 16, 120, 108, 96 and 84 kHz interchanged and made the same for the carriers 12 and 20 kHz. The carriers 12 and 20 kHz are switched smoothly from frame to frame and the polarity is reversed for carriers 16, 120, 108, 96 and 84 kHz. In this way it is achieved that the carrier services required by two channel converter racks load the two phases of each carrier source equally. From Fig. 4th

ίο it can be seen that the wiring of the carrier leads in both racks is completely the same and that each of the 20 primary groups is assigned a different carrier polarity scheme. The 20 different "equivalent polarity reversal schemes" for the frames KUU and KU12 are shown in Table 4.

1 sheet of drawings,

Claims (3)

Claims:. ! .. Circuit arrangement for the transmission of sinusoidal oscillations, which are fed by one or more signal generators, each with the same amplitude, frequency and phase, into a large number of channels of a carrier frequency system, the carrier frequencies of which are preferably synchronized, using channel converter racks for 120 speech circuits, in those with the help of pre-group modulation (channel carriers 12, 16, 20 kHz, pre-group carriers 120, 108, 96, 84 kHz) respectively. 12 voice bands are brought into the basic primary group position 60 to 108 kHz and in which the signal oscillations in each channel converter frame according to a method are used to reduce the high pulse-shaped voltage peaks and disruptive intermodulation products that occur during the coherent feeding of sinusoidal oscillations in the common transmission path. according to patent 1487 443 according to the same group type with a flattened envelope curve, while the carrier oscillations are fed to the modulators within a group of 240th channels from 12-channel group to 12-channel group with different polarity, so that in the first channel converter Frame all carriers are switched on smoothly, with the exception of the 12-channel groups 6 to 10. in which the channel carrier 12 kHz is switched on with reversed polarity, and the 12-channel groups 2 to 5 and 7 to 10, in which one of the pre-group carriers 120, 108, 96 and 84 kHz is switched on with reversed polarity, characterized in that with the same cable routing In both channel converter racks, the polarity reversal measures in the second rack (KU2 or KU12) compared to the first rack ( KUl. or KUIl) are exchanged for at least one carrier and carried out in the same way for the other carriers. 2. Circuit arrangement according to claim 1, when using carrier output transformers in the carrier supply of a channel converter frame, the secondary winding of which is grounded at one end, characterized in that in the second channel converter frame (KU2) the polarity reversal measures compared to the first frame (KUl) only interchanged for the carrier 16 kHz and for the other carriers the same vorr that five polarity reversal transformers ( U1 to US) are provided for the polarity reversal, which are assigned to the carriers 12, 120, 108, 96 and 84 kHz , and that a further polarity reversal transformer (U6) is provided for the polarity reversal from frame to frame, which is assigned to the carrier 16 kHz (FIG. 2). 3. Circuit arrangement according to claim 1, when using carrier output transformers in the carrier supply of a channel converter frame, which emit two voltages offset by 180 ° in the phase, characterized in that the polarity reversal measures in relation to the second channel converter frame (KU 12) first frame (KUU) in the carriers 16, 120, 108, 96 and 84 kHz interchanged and made in accordance with the carriers 12 and 20 kHz, so that from frame to frame in each case the carrier 12 and 20 kHz smooth and the carrier 16, 120, 108, 96 and 84 kHz reversed polarity can be switched further (Fig. 4).