WO2003094397A1 - Method and device for producing at least one transponder in the satellite intermediate frequency plane - Google Patents

Abstract

The invention relates to an improved method and an improved device for producing at least one transponder (33) in the satellite intermediate frequency plane and for combining said transponder with the satellite intermediate frequency band. The improved method and device are characterised in that the mixing products of the local oscillators for the lower and upper satellite bands are outside the satellite intermediate frequency bands, the transponder (33, 33a, 33b, ) is produced by means of direct conversion into the desired frequency band, and the transponder and a selected frequency band are diverted onto a cable.

Description

Method and device for generating at least one transponder in the satellite intermediate frequency level

7. The invention relates to a method and a device for generating at least one transponder in the satellite intermediate frequency level according to the preamble of claims 1 and 7, respectively.

In conventional individual receiving systems, the converter can be controlled on the subscriber side in such a way that both the vertical and the horizontal polarizations can be received. The polarization is conventionally switched over by switching a supply voltage from 14 V (for the reception of the vertical polarizations) to 18 V (for the reception of the horizontal polarizations). Using newer systems, for example, a frequency tone of 22 kHz can also be used to switch from a lower to an upper frequency band, via which even more satellite programs can be received.

While with such a single reception system only one participant at a time via the connected receiver can receive the program selected by him, so-called twin converters (twin LNBs) enable the reception of both polarizations, and this, for example, both for the above-mentioned lower and for the upper frequency band. To do this, however, it is necessary that the input-receiving circuit arrangement comprising the converter circuit basically comprises two leads to the connected subscriber or receiver, in order then to receive a program, for example, on the connected television and via a video device (VCR) connected to the twin receiver. to be able to record another program fed in via the second antenna line.

From DE 197 13 124 C2, however, a satellite reception system has also become known, with which two subscribers can receive programs separately from one another on a single antenna derivative. For this purpose, according to the above-mentioned prior publication, it is proposed that two converters or one twin converter be used, the two converter outputs being connected at least indirectly, and a receiving module being connected in one of the two converter output lines, via which different satellite programs can be selected vertical or horizontal polarization can be received. The received satellite program is converted in this receiving module into a frequency signal assigned to this receiving module and fed into the subscriber antenna line. As usual, the other upper or lower vertically or horizontally polarized signal selected by the receiver and appropriately controlled in the converter is received via the other converter output in the IF plane. Otherwise, several participants can only receive several programs independently of one another via an antenna line if a so-called coupling station is used. So-called satellite frequency converters are used, so-called sat. IFL converters in which individual frequency ranges, for example transponders with a bandwidth of approximately 40 MHz, are selected and newly combined and transmitted on the single cable. Due to the available bandwidth of 950-2150 MHz and the required distances between the transponders, the number of transponders transmitted is limited. In contrast, the number of receivers that can be connected to the cable network is free.

However, if the transponders are selected by the receivers, i.e. that each receiver controls a set of Sat.-ZFl / Sat.-ZFl converter and the upstream matrix, the program selection is again unrestricted, although the number of receivers that can be connected is equal to the number of Sat. -ZFl / Sat. -ZFl converter is. If, on the other hand, only two or at least very few receivers are to be supplied with one cable, the combination of an implemented satellite is. -ZFl / Sat. IFL band for the receiver and a selected transponder for the second receiver an advantageous solution.

However, the satellite. -ZFl / Sat. -ZFl-converter for the selection of a transponder based on the known techniques very complex and expensive. For example, in the prior art, the Ku band (10700 MHz to 12750 MHz) is mixed into a satellite by mixing with a first local oscillator of 9750 MHz. IFL frequency range from 950 to 1950 MHz and with a second local oscillator from 10600 MHz at for example in a satellite. IFL frequency range from 1100 MHz to 2150 MHz implemented. This already has the one disadvantage that the selected local oscillator frequencies generate undesired mixed products that fall into the intermediate frequency level used.

In order to select individual transponders from these frequency bands, a matrix must be used for the selection of the frequency bands. Furthermore, a conversion to the intermediate frequency level with an IF frequency of 480 MHz must be carried out with a mixer and a tunable local oscillator with a tuning frequency of, for example, 1400 MHz to 2700 MHz. Because of the additional need for image rejection, a tunable bandpass filter must also be used before the mixer. The desired transponder is then selected using a downstream SAW filter of 480 MHz. In order to compensate for the attenuation of the SAW filter, an amplification must also be carried out. Finally, another mixer with another local oscillator has to be converted back into Sat. -ZFl level. As mentioned, the need to use two local oscillators and the necessary shielding and also the selection to avoid undesired mixed products is very disadvantageous.

It is therefore an object of the present invention, starting from the generic state of the art mentioned at the outset, to provide a transponder selection with significantly reduced expenditure and space requirements. Such a transponder selection should enable at least twin reception on a single-cable structure. The object is achieved according to the invention with respect to the method according to the features specified in claim 1 and with respect to the device according to the features specified in claim 7. Advantageous embodiments of the invention are specified in the subclaims.

It must be described as surprising that such a solution for one-cable structures can be implemented according to the invention with comparatively little effort. For a receiver, a specific program is implemented in a transponder area. This transponder can then be used with a satellite. -ZFl band can be combined, with the second participant receiving the programs received via this satellite. -ZFl band received received.

The advantages of the solution according to the invention become all the more evident when they are compared with the difficulties and disadvantages of the prior art. In the prior art, for example, the combination of a transponder with a lower frequency band range had to take place in the frequency range between 900-950 MHz because of the lower frequency limit of 950 MHz. If the transponder is combined with an upper frequency band, a crossover with very high selection must be used despite the high selection by the SAW filter when converting the transponder to suppress the unwanted signals below 1100 MHz. This is a not inconsiderable technical effort.

In contrast, according to the invention, a first implementation of the lower satellite intermediate frequency band with a local oscillator of preferably exactly 9550 MHz and a first Implementation of the upper satellite frequency band with a local oscillator of preferably exactly 1625 MHz is proposed. This results in a usable frequency range of approx. 900 to 1000 MHz for the new transponder frequency. The mixed products of the two local oscillators are then at 1075 and 2150 MHz exactly at the lower and upper limits of the satellite intermediate frequency bands, here at 1150 to 2150 MHz for the lower and 1075 to 2125 MHz for the upper band and interfere because of the protective distances the band limits no signal. Of course, values deviating from the above-mentioned local oscillators of preferably less than ± 200 MHz, preferably less than ± 100 MHz or less than ± 50 MHz or even less than + 10 MHz can also be used in order to at least approximately utilize the advantages according to the invention to be able to. In a preferred embodiment according to the features of subclaim 2 or 8, a first implementation of the lower satellite frequency band with a local oscillator of, for example, 9600 MHz and a first implementation of the upper satellite frequency band with a local oscillator of, for example, 13850 MHz is proposed. On the basis of these local oscillator frequencies, which are different from the prior art, it becomes possible for the lower limit for the lower frequency band (low band) to match the lower limit for the upper frequency band (high band), each with 1100 MHz. It can be seen from the above-mentioned description that a local oscillator frequency of, for example, 10600 MHz is not used for the second mixer, but instead a local oscillator frequency which lies above the upper end of the upper frequency band. As a result, according to the invention, an inverse implementation is carried out such that the frequency lying above the upper limit of the upper frequency band frequency range (ie above 12750 MHz) is converted into a range below 1100 MHz, which is otherwise completely free of transponders and satellite signals.

This allows a freely selectable transponder, for example with a satellite, to be implemented by simple implementation in the mixer using only a tunable oscillator and only a subsequent selection of a suitable bandpass filter. -ZFl / Sat. IFL medium frequency of 950 MHz can be implemented.

In a preferred embodiment, such a transponder is combined with a freely selectable satellite intermediate frequency band, preferably via a crossover network. This results in a frequency range of, for example, less than 1000 MHz for the converted frequency band, specifically with the desired transponder with the highest possible frequency without distortion by the lower frequency filter of the crossover. Accordingly, a terrestrial frequency range can also preferably be switched on with a crossover. This even results in a bandpass filter characteristic for the desired transponder.

From the description, there is a significant advantage that, for example, a tracking filter, a tunable bandpass filter is not required, since the image frequencies are always above the converted band ranges, which are implemented by the two local oscillators of the converter (LNB).

Since only a few components are required and only one In a preferred embodiment, the described converter and the crossover can also be installed directly in a converter (LNB). This means that with each cable connected to the converter (LNB) two receivers or one twin receiver can be connected for a complete, independent program selection.

For the sake of completeness, it is mentioned that in a multi-subscriber system, a converter with the two local oscillators is also spatially separated from a matrix with converters and a combination of the selected transponder with a selected satellite. -ZFl band can be positioned. Finally, according to the invention, it is also possible, in particular if the crossover and the filters used are of particular quality, e.g. also to combine two or three selected transponders with the unconverted satellite IF band. Finally, according to the invention, even several transponder bands can be combined without a combination with a satellite IF band.

Further advantages, details and features of the invention result below from the exemplary embodiments illustrated with the aid of drawings. The individual shows:

Figure 1: a representation of an improved LNB with improved selected local oscillator frequencies for the first and second

Local oscillator;

Figure la: a representation of an inventive

Universal twin LNBs with an improved Definition of local oscillators LO1 and L02;

Figure 2: a universal twin LNB according to the invention with additionally generated transponder, which with a freely selectable satellite. IFL band is combined via a crossover network and fed into a single-cable derivation;

FIG. 2a: schematic representation of a transponder with a transponder width of 40 MHz and a center frequency of 950 MHz;

Figure 3 is a schematic representation of the combination of the transponder with a satellite IFL band;

FIG. 4: a representation corresponding to FIG. 3 if a terrestrial frequency range is also connected;

Figure 5 shows a single-cable twin LNB;

Figure 6 shows a single-cable Quattro solution;

FIG. 7a a switching matrix according to the prior art;

FIG. 7b shows a switching matrix which has been expanded in accordance with the invention;

Figure 8 shows an example of a one-cable triple converter solution;

FIG. 9 shows a representation of the combination of two transponder areas with a satellite IFL band, as is obtained when a circuit according to FIG. 8 is implemented; Figure 10: An example of a single-cable quad LNB

Solution; and

Figure 11: a presen- tation regarding four combined transponders accordingly Circuit arrangement according to FIG. 10.

FIG. 1 shows a schematic arrangement of the basic structure of a satellite receiving system according to the invention with a so-called universal twin converter (LNB) 1. As is known from a satellite antenna, e.g. B. received via a so-called not shown horn, the vertically and horizontally polarized signals in an upper and lower frequency band and implemented via a polarization switch in two branches 1 'and 1 ".

In both branches 1 'and 1 "shown in FIG. 1, an amplifier arrangement 3 and a downstream bandpass filter 5 are provided, for example.

A mixer 7 is then arranged in each of the two branches. Furthermore, two local oscillators 9 and 11 are provided, via which the respective received satellite frequency is converted into a satellite intermediate frequency in the mixers 7. As is known, the downlink frequencies of the satellites in the Ku band in Europe are 10700 MHz to 12750 MHz. The lower frequency band (low band) ranges from 10700 MHz to about 11700 MHz. The upper frequency band (high band) extends from 11700 MHz to 12750 MHz. If the universal twin converter according to FIG. 1 in the upper branch 1 ′ is to be used to convert the lower frequency band into the satellite intermediate frequency band range, this will be done with the local oscillator frequency of 9550 MHz, that is to say with the local oscillator frequency of local oscillator 9 operating at a lower frequency is carried out in the respective associated mixer 7. This will be the lower one received Satellite frequency band of 10700 MHz to 11700 MHz vice ^¬ sets in a satellite-intermediate frequency of 1150 MHz to 2150 MHz.

If the upper frequency band range, for example the vertically or horizontally polarized received signals in the first or in the second branch 1 ', 1 ", is to be converted, this is done with the second local oscillator 11 with the high local oscillator frequency of 10625 MHz chosen according to the invention there is an inverse conversion of the received upper satellite frequency band from 11700 MHz to 12750 MHz into a satellite IF range from 1075 MHz to 2125 MHz.This means that the conversion takes place in such a way that the mixed product of the two local oscillator frequencies is not in the satellite IF level falls into it, but in the present case it is carried out in such a way that the lower and the upper received satellite frequency band are implemented at the upper end of the satellite intermediate frequency level. This also ensures that the mixed products of the two Local oscillator frequencies with 1075 MHz and 2150 MHz exactly at the below The upper and upper limits of the satellite intermediate frequency bands are 1150 to 2150 MHz for the lower and 1075 to 2125 MHz for the upper band and therefore do not interfere with any signal due to the protective distances at the band limits. This is made possible, among other things, by selecting the higher local oscillator frequency so that it lies higher than the lower end of the upper frequency band, i.e. at 13850 MHz it is higher than the lower end of the upper frequency band at 12750 MHz.

The local oscillators 7 can again one or more stage amplifier arrangements 8 may be connected downstream.

A universal twin LNB improved according to the invention is now shown with reference to FIG. The basic principle of this is similar to that of FIG. The only difference in this exemplary embodiment is that the first local oscillator frequency LO 1 is 9600 MHz and the second local oscillator frequency LO 2 is 13850 MHz. As a result, the lower satellite frequency band from 10700 to 11700 MHz is converted into a satellite IF from 1100 MHz to 2100 MHz. The upper satellite frequency band is also converted into a satellite intermediate frequency from 1100 MHz to 2150 MHz. In other words, the implementation takes place in such a way that the lower limit frequency for the lower frequency band is the same as for the received upper frequency band and in the exemplary embodiment shown is significantly higher than the lower frequency limit of the low band for a standard universal LNB.

In the exemplary embodiment shown in FIG. 1 a, the corresponding conversion of the upper satellite frequency band into the satellite IF level takes place using a local oscillator frequency that lies above the upper satellite frequency band.

At the two outputs 15 of the two branches 1 ', 1 ", a 2-x-2 matrix 19 is connected downstream, at whose two outputs 21a and 21b, as is known, one subscriber could be connected, the lower or upper one of the vertical or horizontal Could receive polarizations. According to the invention, however, a further mixer 23 is now connected to the one output, in the exemplary embodiment shown at output 21b, which is connected via a tunable oscillator 25 from, for example, 2025 to 3100 MHz with a subsequent selection, for example by means of a bandpass filter 26 at, for example, 950 MHz center frequency and a bandwidth of 40 MHz generates a freely selectable transponder, as shown with reference to Figure 2a.

The transponder branch 29b provided with the mixer 23 and a bandpass filter 26 can now be connected to the branch 29a connected to the other output 21a via a downstream crossover 27. The output 27a of the crossover 47 is thus connected to a single antenna cable 31, usually a coax cable. This single-cable solution then enables twin reception. As a result, the transponder 33 generated is combined with a freely selectable satellite IF band 35, as is shown schematically in FIG. 3. This results in the converted frequency band, i.e. H. for the transponder a frequency range of e.g. less than 1000 MHz, the frequency band representing the desired transponder with the highest possible frequency, specifically at a center frequency of e.g. 950 MHz without any distortion due to the low-pass filter of the crossover.

FIG. 4 shows that, for example, a terrestrial area 37 can also be connected via a further crossover, which connects below 862 MHz. This even results in a bandpass filter characteristic for the desired transponder 33. An extension of the principle explained in the sense of a one-cable-twin converter is described with reference to FIG. A converter structure is used here, which ultimately feeds a 4 × 4 matrix 19 via four branches 1 a to 1 d, so that at the output of this matrix the lower frequency band received via the vertical polarization and the one received via the vertical polarization in a known manner Upper frequency band, the lower frequency band received via the horizontal polarization and, for example, the upper frequency band received via the horizontal polarization, are each present separately and simultaneously. As a result, an arbitrarily high number of participants can be connected by appropriately linking several matrixes. In the exemplary embodiment shown, however, two outputs are connected together according to the invention at the outputs 21a to 21d of the matrix circuit 19 via a subsequent crossover 27, one output of the matrix being switched through directly with the input of the crossover over a path 29a and in the other branch a so-called transponder branch 29b is formed, in which a mixer 23 with a subsequent bandpass filter 26 is arranged and the mixer is operated with a tunable oscillator 25 with a suitable frequency band range. Twin operation can then be carried out at the outputs 27a of the two crossovers 27.

This principle can be expanded accordingly, as is explained, for example, using a 4 × 8 matrix 19 with reference to FIG. 6. With corresponding expansion at the four outputs 27a of the four crossovers 27, twin operation is possible in each case. 7a and 7b only show that the matrix can also be arranged spatially separated from the local oscillators of the converter (LNB). FIG. 7a shows a conventional converter, at the four outputs of which in the IF plane the upper and lower frequency bands of the signals received vertically and horizontally are applied. It is indicated in FIG. 7a that the two local oscillators 9 and 11 can operate with a local oscillator frequency of 9600 MHz or 13850 MHz, as shown with reference to FIG. La, or, as was explained with reference to FIG. 1, with one Local oscillator frequency of 9550 MHz and 10625 MHz. The implementation in the satellite intermediate frequency level then takes place accordingly, as was explained with reference to the exemplary embodiments according to FIG. 1 or FIG.

Spatially separated from this, for example, a changeover matrix 37, as is known from the prior art, can then be connected downstream of the converter shown in FIG. 7a. Several of the switching matrix arrangements can also be connected in series. In this case, as in the previous examples, two outputs, namely a first branch 29a and a transponder branch 29b, are again connected together at the outputs shown at the bottom in FIG. 7b, again via a crossover 27.

In this example too, similarly to the exemplary embodiment according to FIG. 4, the output 27a of the relevant crossover 27 is connected to the input of a further crossover, with a terrestrial one at the second input of the downstream crossover 39 Signal is fed. Twin operation can then again be carried out at the output 41 of these downstream crossovers 39, for which purpose an antenna cable 31 is usually connected in each case.

With reference to FIGS. 8 and 9, it is explained that not only a transponder band area can be combined with a satellite IF band area, but also a so-called one-cable triple converter solution is also possible in which, for example, two are offset horizontal transponder frequency ranges can be combined with a satellite IF band range.

In this case, using a 4x6 matrix, three outputs 21a, 21b, 21c on the one hand and 21d, 21e, 21f on the other hand are interconnected via three parallel lines of a downstream crossover network 27, with a branch 29a in each case between the matrix and the Crossover is switched through, in a second branch 29b again a mixer controlled by a local oscillator, preferably with a downstream bandpass filter for generating a first transponder 33, for example with a transponder center frequency of 950 MHz, and finally a mixer in the third branch line 29c is provided with a further local oscillator, the local oscillator frequency being selected such that a second transponder 33a with a transponder center frequency of, for example, 1020 MHz is generated via the mixer. According to the illustration according to FIG. 9, both transponder ranges are also at a distance below the lower limit of 1100 MHz of the satellite intermediate frequency band range which then adjoins upwards. Finally, the principle described could also be expanded in accordance with FIGS. 10 and 11 in such a way that a plurality of transponders spaced apart from one another are generated, and these transponder branches 29 are then combined via a crossover network. This allows multiple transponders to be fed onto a single common antenna line.

Claims

claims:

1. Method for generating at least one transponder (33) in the satellite intermediate frequency level (Sat. IF level) in combination with at least one further transponder (33a, 33b, ...) and / or in combination with one an upper or a lower satellite frequency band in the satellite. IF level converted frequency band (35), for which purpose a converter arrangement (1) with an integrated or downstream matrix (19, 37) with at least two outputs (21a, 21b) is used, the outputs (21a, 21b ) incoming signals, preferably via a summation circuit or a crossover (27), are fed into at least one connected antenna line (31), characterized by the following further features - the lower and the upper received satellite frequency band are sent to the upper end of the satellite intermediate frequency A local oscillator combination is used to convert the lower and the upper satellite frequency band into the satellite frequency level, such that the mixed products of the local oscillators do not fall within the assigned satellite frequency, and the transponder (33, 33a, 33b, ...) is by means of direct conversion preferably generated in the range of 950 to 1075 MHz.

2. The method according to claim 1, characterized in that a combination of subposition for the lower satellite frequency band and overlay for the upper satellite frequency band is used via the local oscillators.

3. The method according to any one of claims 1 to 2, characterized in that the lower frequency limit of the in

Satellite intermediate frequency level converted lower satellite frequency band and the lower frequency limit of the upper satellite frequency band implemented in the satellite intermediate frequency level is approximately 1100 MHz.

4. The method according to any one of claims 1 to 3, characterized in that the transponder (33) by simple implementation with a mixer (23) and a tunable oscillator (25) preferably with a frequency range from 2025 to 3100 MHz and preferably a subsequent selection is generated by means of a bandpass filter (26) or a lowpass filter.

5. The method according to any one of claims 1 to 4, characterized in that for generating at least a second

Transponders (33a) and, if appropriate, further transponders (33b, 33c ...) at correspondingly provided further outputs (21a, 21b, 21c ...) of a matrix (19, 37) connected downstream of the converter (1), each of which is used for simple implementation Mixers (25), each with a tunable local oscillator (25) and preferably each with a downstream selection in the form of a bandpass filter (26), are used, the so produced Transponders (33, 33a, 33b, ...) are preferably fed into a common antenna line (31) via a crossover (27).

6. The method according to any one of claims 1 to 5, characterized in that in addition to the at least one transponder (33) in the common antenna line (31) an upper or lower satellite frequency band (35) implemented in the satellite intermediate frequency level is fed whose lower frequency limit in the satellite

Intermediate frequency level above the transponder (33).

7. Device for generating at least one transponder (33) in the satellite intermediate frequency level (Sat.-IF-

Level) in combination with at least one further transponder (33a, 33b, ...) and / or in combination with one from an upper or a lower satellite frequency band into the satellite. IF level converted frequency band, with a converter arrangement preferably with an integrated or upstream matrix (19, 37) with at least two outputs (21a, 21b) for feeding in the signals present there, preferably via a downstream crossover (27) or a summation circuit in a connected antenna line (31), characterized by the following further features

the structure is such that the lower and the upper received satellite frequency band are implemented at the upper end of the satellite intermediate frequency level,

- The implementation of the lower and the upper satellite frequency band in the satellite frequency level is based on a Local oscillator combination such that the mixed products of the local oscillators do not fall within the occupied satellite frequency, and - the transponder (33, 33a, 33b, ...) can be generated by direct conversion into the desired frequency band.

8. The device according to claim 7, characterized in that the structure is such that a combination of underlaying for the lower satellite frequency band and overlaying for the upper satellite frequency band is used via the local oscillators.

9. The device according to claim 7 or 8, characterized in that the lower frequency limit of the in

Satellite intermediate frequency level converted lower satellite frequency band and the lower frequency limit of the upper satellite frequency band implemented in the satellite intermediate frequency level is approximately 1100 MHz.

10. Device according to one of claims 7 to 9, characterized in that the transponder (33) by simple implementation with a mixer (23) and a tunable oscillator (25) preferably with a frequency range from 2025 to 3100 MHz and preferably a subsequent selection can be generated by means of a bandpass filter (26).

11. The device according to one of claims 7 to 10, characterized in that for generating at least a second

Transponders (33a) and possibly further transponders (33b, 33c ...) at correspondingly provided further outputs (21a, 21b, 21c ...) of a converter (1) connected matrix (19, 37) further mixers (25) serving for simple implementation are provided, each with a tunable local oscillator (25), preferably with a downstream selection in the form of a bandpass filter (26), the transponders (33, 33a, 33b, ...) can preferably be fed via a crossover (27) into a common antenna line (31).

12. Device according to one of claims 7 to 11, characterized in that in addition to the at least one transponder (33) in the common antenna line (31), an upper or lower satellite frequency band implemented in the satellite frequency level, the lower of which can be fed Frequency limit in the satellite frequency level is above the transponder (33).