DE102007050914A1 - Frequency transmission system for receiving radio and multimedia services, has portable unit that transmits signal on fixed frequency in range of satellite intermediate frequency, where transmitted signal is conveyed to receiving device - Google Patents

Abstract

The system has a receiving device (90) for providing information for selection of certain transmission via an input connector (91). A portable unit (60) processes the information, and a stationary unit (20) receives the information, where a certain range of satellite-intermediate frequency is selected based on the information, and the selected range is limited in the band width. The unit (60) receives a transmitted signal of the stationary unit and transmits the signal on fixed frequency in the range of the intermediate frequency, where the transmitted signal is conveyed to the device.

Description

The The present invention shows an advantageous solution of common problem in satellite reception technology, namely the previous necessity of the wired Supply of the received signals from the antenna system to the receiving device.

The predominant Number of direct stationary reception radio and multimedia services in geostationary orbits at a height positioned about 36000 km above the equator.

The large distance to the satellites, as well as those limited in the universe available transmission power, set to receive Advanced antennas ahead. Mostly this will be antennas with parabolic reflectors with a diameter of about 60 cm to 90 cm used.

There in the meantime a multitude of satellites on neighboring locations positioned in orbit with overlapping frequencies, that must Antenna system additionally a selection of the desired Make satellite position. Because the selection is limited to fractions of a second must be done exactly, is a very precise orientation of the Antenna necessary.

by virtue of high frequencies of satellite broadcasts the penetration of building parts (eg of walls and blankets) almost impossible. It must therefore be a obstacle-free, direct route between the satellite and the Receiving antenna be present.

Around to allow a perfect reception, must have a Satellite antenna so in the outdoor area at one Location exactly aligned with direct line of sight to the satellite be installed. Thus separates a portable use indoors out.

satellite programs are in two different polarization planes, usually horizontal and vertical, broadcast. Because the different can separate polarized radiations when receiving, the limited existing frequency range can be used twice. The Both polarization levels are in the receive converter (Low Noise Block Converter, LNB) received separately and frequency converted into the area of the first satellite intermediate frequency, and stand separately at the output of the LNB on two jacks to disposal.

Of the Frequency range of the satellite transmission has been meanwhile extended so far (10700 MHz to 12750 MHz) that the feed in an antenna distribution network in a whole frequency block not makes more sense. Therefore, the frequency range has become so-called lower frequency band ("low band") and in an upper one Frequency band ("high band") divided, which by appropriate Frequency conversion in the LNB to almost equal output frequency ranges (950 MHz to 2150 MHz).

Consequently There are now four exits at each LNB available (vertical low, horizontal low, vertical high and horizontal high), which continuously the whole offer of the Satellite system in four parts on four parallel lines to Make available.

The receiving device must now be able to switch to one of these four lines, depending on the desired program to be received. This function is handled by a multi-switch, such as for example DE19728623C2 is known. Signaling is done by the receiving device by sending a voltage / audio signal combination to the output of the multiswitch associated with the receiver. Typically, a voltage of about 14 V is selected for the selection of the vertical programs, or about 18 V for the selection of the horizontal programs. If a voltage of about 22 kHz is superimposed on the voltage level, switching to the upper frequency band takes place. Without sound, the lower frequency band is selected. Modern receiving devices use for this signaling a serial data transmission (DiSEqO), which is based on the 22 kHz tone. DiSEqC also provides the necessary signaling to receive additional satellite systems.

These Type of selection and distribution only works if a separate, electrically conductive and for the frequency range suitable transmission medium is available. This is usually a coaxial cable, but which often does not exist or only with great effort to install.

ideal Therefore, the transmission of the first satellite intermediate frequency appears by radio waves.

The satellite broadcasts take place in a variety of transponders, divided into both polarization levels and frequency bands. Transponders have common bandwidths between 27 MHz and 36 MHz and may include, for example, an analog television broadcast or a variety of digital services. To represent a desired transmission, the tuner of the receiver is tuned to a particular frequency in the range of the first satellite intermediate frequency. Because the final selection of the desired transmission takes place only in the receiving device, the receiver would have the entire frequency spectrum available. Thus it would be necessary to transmit per radio plane a bandwidth of about 1200 MHz by radio. However, this is not sufficiently secure possible without affecting other radio services or even disturb. In addition, this method would waste scarce frequency resources.

A known solution to the problem of missing coaxial cable is, the receiving device in the vicinity of the receiving converter to relocate, and the audio and video signal of the receiving device by means of wirelessly transmit a modulator / demodulator combination. Although the transmission of image and sound is so fundamental possible, but only with quality losses. Also, the transmission of digital audio and video data, or even high-definition television, by commercial Modulator / demodulator combinations not provided. The reception encrypted services would also be complicated since the identification and authorization cards in the decoder must be in the receiving device.

The new method presented here avoids the disadvantages and solves the problem on a very frequency-economic Art.

The system consists of three parts: a stationary unit ( 20 ), a portable unit ( 60 ) and a software expansion in the inserted receiving device ( 90 ).

The stationary unit is equipped with an input socket ( 21 ) for connection to the satellite receiving antenna ( 10 ), as well as with connections for a power supply ( 11 ) and one transmission ( 50 ) and receiving antenna ( 51 ).

The portable unit ( 60 ) is connected to an output socket ( 70 ) for connection to the receiving device ( 90 ), as well as with connections for a transmission ( 53 ) and receiving antenna ( 52 ) fitted.

The extension of the used receiver ( 90 ) relates to the software, which is extended by functions, so as to provide information about the frequency and the polarization level of the respective desired transmission. Advantageously, this information is transmitted via the input socket ( 91 ) of the receiving device in the form of DiSEqC messages provided because the necessary functions and circuit parts are already present in most commercially available receivers today. In addition, the actual receiving part of the receiving device remains fixed at a certain frequency.

The receiving device ( 90 ) is connected to the portable unit ( 60 ) of the new system. The parameters of the desired transmission which the receiving device ( 90 ) via the standardized interface ( 91 ) are transmitted by the height and by modulation of the remote supply voltage of the receiving device. Through filters ( 71 . 72 ) this information is separated from the radio frequency and the remote supply voltage. From the remote supply voltage, the power supply of the portable unit is processed ( 73 ).

DiSEqC commands and the 22 kHz signaling tone are used for the microcontroller ( 75 ) by means of a DiSEqC receive modem ( 74 ) raised to standardized signal levels. The microcontroller ( 75 ) decodes the information and passes it as data to a modulator ( 76 ) further. The output signal of the modulator is determined by means of a bandpass filter ( 77 ) and via a terminal ( 78 ) a transmitting antenna ( 53 ). Thus, the data of the receiving device is forwarded via a narrow-band radio link to the stationary unit.

The stationary unit ( 20 ) receives by means of a to the input terminal ( 40 ) connected antenna ( 51 ) the signal. It is done by means of a bandpass ( 41 ) and by means of a demodulator ( 42 ) demodulated. The microcontroller ( 43 ) decodes the data, and controls the converter circuit ( 45 ), so that from the through the power supply ( 11 ) at the terminal ( 46 ) voltage is generated a voltage of a certain height. This is the DiSEqC modulator ( 44 ) supplied by the microcontroller ( 43 ) is driven. The thus generated control signal is transmitted by means of the switch ( 22 ) is combined with the high-frequency signal and the terminal ( 21 ). The control signal is sent to the LNB or multiswitch ( 10 ), so that this / this provides exactly the frequency spectrum which would have been supplied to the receiving device for displaying the program selected by the user wired.

Around realize the radio transmission frequency economics To be able to, the bandwidth of the first satellite intermediate frequency must be severely limited. Ideally, only exactly the part of the Frequency spectrum are transmitted by radio, which is currently required by the receiving device. For this purpose, the provided by the receiving device and passed through the portable unit to the stationary unit Information used.

In the stationary unit ( 20 ), the requested frequency spectrum is replaced by a switch ( 22 ) from the control signals and the remote feed chip free. The spectrum is sent to a mixer ( 23 ), as well as the signal of a tunable oscillator ( 24 ). Using the data received from the receiving device ( 90 ) via the portable unit ( 60 ) to the microcontroller ( 43 ) of the stationary unit ( 20 ), the divider ratio of a PLL ( 25 ) so that the oscillator ( 24 ) has the appropriate frequency so that the desired transmission into the center frequency of a bandpass filter ( 26 ) is implemented. This bandpass filter now filters as accurately as possible only the frequency block requested by the receiver from the spectrum of the first satellite intermediate frequency.

This frequency block is generated by means of another combination of oscillator ( 28 ), PLL ( 29 ) and mixers ( 27 ) converted into an available frequency range. A bandpass filter ( 30 ) only allows the desired signals to pass in the available frequency range. The signal is then amplified ( 32 ), filtered ( 33 ) and the output terminal ( 34 ). To the output terminal ( 34 ) of the stationary unit ( 20 ) is a transmitting antenna ( 50 ), which emits the signal. At the entrance ( 61 ) of the portable unit ( 60 ) is a receiving antenna ( 52 ), which transmit the broadcast antenna ( 50 ) of the stationary unit ( 20 ) receives. The received signal is amplified ( 62 ), filtered ( 63 ) and a mixer ( 64 ) to which one of a PLL ( 66 ) controlled oscillator ( 65 ) connected. The received signal is thus converted back into the range of the first satellite intermediate frequency and for the suppression of possible spectral interference by a bandpass ( 67 ) filtered. Then the signal is amplified by an amplifier ( 68 ) and via a switch ( 71 ) to the output terminal ( 70 ) of the portable unit. The receiving part of the receiving device so the requested transmission is supplied to a fixed frequency so that it can be demodulated by modules in the receiving device, decoded and displayed.

The entire system should advantageously be equipped with an automatic control of the transmission power, so that the field strength generated by the stationary unit can be kept as low as possible. For this purpose, in the portable unit by means of a coupler ( 80 ) a part of the output signal is coupled out, rectified ( 81 ) and compared to a reference value ( 82 ). The deviation is determined by the existing microcontroller ( 75 ) which processes the data of the receiving device to request the desired transmission for the narrow-band radio transmission from the portable unit to the stationary unit. The data is the information about the signal level at the tap ( 80 ) in the portable unit. In the stationary unit, with the transmitted level information, an adjustable attenuator ( 31 ). The transmission power of the stationary unit is set only so high that the field strength at the stationary unit is sufficient for the stable reception of the transmission.

QUOTES INCLUDE IN THE DESCRIPTION

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Cited patent literature

• DE 19728623 C2 [0010]

Claims (13)

Transmission system for selectively wirelessly transmitting frequencies of the first satellite intermediate frequency, comprising a stationary unit, a portable unit, and an extended function in the device connected to the portable unit receiver, characterized in - that the receiving device via the input terminal information for selecting a certain transmission is provided, - that this information is supplied to the portable unit, - that the portable unit prepares this information and forwards the information wirelessly to the stationary unit, - that the stationary unit receives the information of the portable unit and on the basis of the information one certain range of the first intermediate satellite frequency is selected, - that this selected range is limited in the bandwidth, - that this range is converted into an available frequency range and transmitted wirelessly, that the portable unit receives the transmissions of the stationary unit and converting to a fixed frequency in the range of the first satellite intermediate frequency, - and in that the set converted signal is supplied to the receiving device. Transmission system according to claim 1, characterized characterized in that the system for transmission is modified by cable television signals. Transmission system according to the claims 1 or 2, characterized in that for the wireless broadcasting selected different radio channels can be. Transmission system according to one of the claims 1 to 3, characterized in that the portable unit with the stationary unit by a unique identification code can be linked in terms of data. Transmission system according to one of the claims 1 to 4, characterized in that the system on the input side can be operated on a subscriber-controlled single-cable system. Transmission system according to one of the claims 1 to 5, characterized in that the stationary Unit Switch for signals of the first satellite IF may include. Transmission system according to one of the claims 1 to 6, characterized in that several transmission and selection units in one device can. Transmission system according to one of the claims 1 to 7, characterized in that the transmission the information for selecting a particular transmission from the receiving device to the portable unit the input jack of the receiving device takes place, but over a serial interface. Transmission system according to one of the claims 1 to 8, characterized in that the information for Selection of a specific transmission from the receiving device via an alternative medium directly to the stationary unit is directed. Transmission system according to one of the claims 1 to 9, characterized in that the transmission path is configured bidirectional for the selection information. Transmission system according to one of the claims 1 to 10, characterized in that the selection of the desired transmission in the stationary unit by mixing in a certain one Intermediate frequency and bandpass filtering this takes place. Transmission system according to one of the claims 1 to 11, characterized in that the transmission system is equipped with an amplitude control, so that the stationary unit continuously adjusts its transmission power, thus the field strength at the portable unit just for an undisturbed reception is sufficient. Transmission system according to one of the claims 1 to 12, characterized in that the stationary Unit ends its emissions when from the portable unit no signals were received for a certain time.