FR2947684A1 - Digital TV broadcasting signals receiver i.e. Triple-Play set-top box, for TV, has transceiver operated in circuit mode and packet mode so as to receive and transmit voice signals and Internet data signals - Google Patents

Abstract

The receiver i.e. Triple-play set-top box (101), has a tuner (104) for receiving digital broadcasting signals transmitted by a low noise hyper frequency block (103). Another tuner (105) receives Internet data signals transmitted by the block. A cellular radiotelephony transceiver formed of an antenna (119) and a modem (120) is operated in a circuit mode and a packet mode so as to receive and transmit voice signals and the Internet data signals, where the Internet data signals are received by the latter tuner and transmitted by the transceiver operating in the packet mode. The low noise hyper frequency block is operated based on UNICABLE(RTM: new satellite reception and distribution technology).

Description

Satellite signal receiver

The present invention relates to a receiver (referred to alternatively as Set Top Box or STB in the rest of the text) of signals received by satellite and more specifically to a receiver of digital radio and television signals received by satellite.

More and more homes are equipped with ADSL (Asynchronous Digital Subscriber Line) boxes allowing access to a service called Triple Play in English consisting of the grouping of three services: a given connection service (to connect to Internet), a multimedia service (for receiving television-type services) and a voice service (for making phone calls). These ADSL connection boxes thus appear to users as the waypoint centralizing all the communications of the home. These boxes are currently provided either by the fixed telephony operators (PSTN or Switched Telephone Network) or by the cable network operators (CATV or Cable TV). Today, satellite operators offer mainly offers for the transport of television channels. Most of these offerings do not include Internet access except for certain offers such as the ToowayTM offer which is a two-way access service to broadband satellite internet based on SurfBeamTM DOCSISTM technology. However, ToowayTM offers a limited number of users and also requires bulky equipment that is difficult to install (heavy antenna supports, the need to add a second antenna, or to replace the existing antenna and change from one or two additional coaxial cables). It should also be noted that none of the offers made by the satellite operators includes the three TV, Internet and consumer telephony services at the same time. In this context, the present invention aims to provide a receiver Set Top Box signals received by satellite to overcome the aforementioned problems by providing a triple play solution without passing through the fixed network PSTN or the cable network CATV.

To this end, the invention proposes a receiver of signals received by satellite comprising: a first tuner adapted to receive digital broadcast and broadcast signals transmitted by a low noise microwave block; a second tuner adapted to receive Internet data signals transmitted by a low noise microwave block; said receiver being characterized in that it further comprises a cellular-mode radio transmitter operating in circuit mode and in packet mode adapted to receive and transmit voice signals and Internet data signals, the Internet data being received by said second tuner and transmitted by said transceiver operating in packet mode. The receiver according to the invention may also have one or more of the following characteristics, considered individually or according to all the technically possible combinations: said cellular radiotelephone transceiver comprises a modem operating in circuit mode according to the standard GSM; said cellular radiotelephone transceiver comprises a modem operating in packet mode according to one of the following standards: o GPRS; o EDGE; o CDMA; o 3G; o 3+; o HSDPA o HSUPA; the receiver according to the invention is compatible with UNI-CABLETM technology, said receiver comprising an input adapted to receive a coaxial cable connected to an LNB receiving unit, the signal received by said input being transmitted to said first tuner then to said second tuner; the receiver according to the invention comprises an RJ45 type Ethernet interface and / or a WIFI interface. The present invention also relates to an installation comprising: an STB receiver according to the invention; an LNB microwave signal reception unit connected to said receiver via at least one coaxial cable. The installation according to the invention may also have one or more of the following characteristics, considered individually or in any technically possible combination: said LNB microwave signal receiving unit comprises two LNB blocks respectively incorporating a horn for the reception of microwave radio signals emitted by the Ka-band satellite and a horn for receiving signals transmitted by the Ku-band satellite; said LNB microwave signal receiving unit operates according to UNICABLETM technology. In all the figures, the common elements bear the same reference numbers.

FIG. 1 represents a first installation comprising a receiver according to the invention; Figures 2a and 2b illustrate a first embodiment of the pas-sage of a standard installation for receiving broadcast and broadcast signals to an installation incorporating a receiver se- ion of the invention. FIGS. 3a and 3b illustrate a second embodiment of the passage from a standard installation to an installation integrating a receiver according to the invention. FIG. 1 represents a first installation 100 integrating: a receiver or STB 101 according to the invention; an outdoor unit 102 including a parabolic reflector; a unit for receiving microwave signals LNB (Low Noise Block English) 103; a coaxial cable 108; devices connected to the STB 101 such as a television set 105, a personal computer 106 and an analog telephone 107. The installation 100 according to the invention preferably operates according to the so-called UNICABLETM technology, in particular described in the CENELEC standard EN 50494 or in the patent application FR2835368. By way of example, the outdoor unit 102 including the parabolic reflector receives signals from a Ku-band satellite (10.7 GHz - 12.75 GHz band) corresponding to an orbital position at 13 ° East and from a Ka-band satellite (19.7 GHz - 20.2 GHz band) corresponding to the same orbital position at 13 ° East. The LNB microwave signal reception unit 103 typically comprises two unrepresented LNB blocks respectively incorporating a horn for receiving microwave radio signals emitted by the Ka-band satellite and a horn for receiving signals transmitted by the Ku-band satellite. . It will be noted that the LNB receiving unit 103 may be in one piece with two concentric horns. The outdoor unit 102 focuses modulated microwave signals received on the horns of the receiving unit 103 which converts the received microwave signals into electrical signals in the intermediate 950-2150 MHz satellite band for transmission via the coaxial cable 108 to the receiver STB 101. The receiver 101 comprises: - a first tuner 104; a second tuner 105.

The STB 101 receiver operates at fixed frequencies and will have within the spectrum 950-2150 MHz two dedicated carriers (so-called user band): the content of each frequency is set at the receiving unit LNB 103 using the technology UNICABLETM. Thus, the content of each user band varies according to the command sent by the receiver to the LNB 103 UNICABLETM receiving unit. To do this, the receiving unit 103 LNB comprises a switching matrix with at least 6 inputs and a number of outputs sufficient to power the STB receivers 101 to serve. Such a technology has the advantage of only using a single coaxial cable 108 of descent to the STB receiver 101 to supply the two tuners 104 and 105. The six inputs of the switching matrix correspond to six possible states of the signals received. in Ku and Ka bands. Thus, in the case of a Ku-band diffusion and in rectilinear polarization, there are four possible states: a high frequency band in vertical polarization; a low frequency band in vertical polarization; a high frequency band in horizontal polarization; a low frequency band in horizontal polarization. In the case of Ka-band diffusion and circular polarization, there are two possible states: a left circular polarization frequency band; a frequency band in right circular polarization.

The Ku band is here for example allocated to the television and radio services while the Ka band is allocated to the Internet data broadcasting services. The first tuner 104 receives the signal transmitted by the LNB receiving unit 103 via the coaxial cable 108 and recovers a first channel corresponding to a first user band; this first channel comprises a modulated useful signal from the Ku band and allows the reception of television or radio channels. Once the first channel recovered by the first tuner 104, the signal from the LNB receiving unit 103 is transmitted to the second tuner 105 which retrieves a second modulated channel corresponding to a second user band; this second channel comprises a useful signal from the Ka band and allows the reception of Internet data. The first tuner 104 demodulates the modulated useful signal from the Ku band. The binary data of the wanted signal are then transmitted to a demultiplexer 109 which receives a bit stream of MPEG (Motion Pictures Expert Group) packets. The contents of the audio / video packets are then transmitted to an MPEG audio / video decoder 110. The data is then transmitted to an analog encoder AENC (Analog ENCoder) 111 which performs a digital-to-analog conversion and formats the audio / video signal for transmit it to the television 121 via a scart socket 112 for example. All these operations take place under the control of a microcontroller 113 which will program the demultiplexer 109 to extract the desired program and manage the rights of the user via the decoder 110. As such, the receiver 101 according to the invention may include a smart card reader 114 for managing the rights of the user. The second tuner 105 demodulates the modulated useful signal from the Ka band to obtain the Internet binary data of the wanted signal. The Internet data then passes through the microcontroller 113 and is then transmitted to the personal computer 106 via an Ethernet controller 115. The Ethernet controller 115 can transmit the Internet data to the computer 106 either via a WIFI interface 116 or via a remote control. RJ45 socket type Ethernet interface 117.

It will be noted that the STB receiver 101 according to the invention may also comprise an encoder 118 of the H264 type receiving the data of the MPEG audio / video decoder 110 for transmission of the radio / television data to the computer 106 via the Ethernet controller 115 and one of the interfaces WIFI 116 or RJ45 117.

The receiver STB 101 according to the invention furthermore comprises an antenna 119 and a modem 120 operating according to the GSM (Global System for Mobile) and GPRS (General Packet Radio Service) standards forming a working cellular radio-transceiver. in circuit mode and packet mode. The modem 120 GSM / GPRS is itself connected to the microcontroller 113. The microcontroller 113 controls all the operations of the modem 120 and ensures in particular the reproduction of the speech signals via a not shown speaker of the telephone 107 and the recovery of the signals The speech signals generated by the telephone 107 are transmitted via the antenna 119 of the STB receiver 101 according to the invention to a not shown base station. Conversely, the speech signals transmitted by the base station are received by the antenna 119 of the STB receiver 101 according to the invention.

The specificity of the receiver STB 101 according to the invention concerns the possibility of using the GPRS modem as the return path of the Internet data received in the forward channel by the Ka-band satellite. GPRS is a non-voice value-added service that transmits packet-based Internet data over the mobile network. Note that the GPRS modem can be replaced by a modem type EDGE (Enhanced Data Rates for GSM Evolution). It is also possible to use a modem compatible with both GPRS and EDGE technology. Note that it is also possible to replace the GPRS and / or EDGE modems by CDMA (Code Division Multiple Access), 3G / 3G +, High Speed Download Packet Access (HSDPA) or HSUPA (High Speed Upload) modems. Packet Access in English) The routing of the Internet data is thus the following: the data in the forward direction are received by the tuner 105. They are transmitted from a hub connected to the Internet and use a downlink channel in Ka band (possibly in Ku band in countries that do not have a Ka-band satellite); backhaul data is transmitted to the Internet through the 120 GPRS or EDGE modem. The receiver STB 101 according to the invention is therefore a triple play receiver allowing the user, thanks to the presence of the two tuners 104 and 105 and the modem 120 GSM / GPRS, to simultaneously access the radio / television services and Very high speed Internet, including GSM networks supporting only GPRS or EDGE technologies, as well as telephony via the GSM telephony network. This type of STB receiver is particularly interesting in regions where the fixed telephony networks RTC or the CATV cable networks are less developed than the cellular networks. The first tuner 104 allows the reception of radio and television channels while the other tuner 105 allows the reception of Internet data. It is the 120 GPRS modem that sends the data back to the Internet. The receiver STB 101 according to the invention makes it possible to obtain an excellent bit rate on the downlink, the data rate in the return path of the Internet data being determined according to the technology used (for example up to 44 kbit / s for a GPRS technology up to 384 kbps for EDGE technology and up to 3.5 Mbps for HSDPA technology). The receiver STB 101 may also include a Bluetooth® interface, a terrestrial digital television tuner or a USB interface for transferring files from another device (eg a USB key) to the receiver 101, to the television 121 or to PC 106. FIGS. 2a and 2b illustrate a first embodiment making it possible to switch from an installation 200 comprising a parabolic reflector 102 and a conventional STB receiver 201 for receiving the television to a facility 300 integrating an STB receiver. 101 according to the invention. According to FIG. 2a, the installation 200 comprises a conventional STB receiver 201 for the reception of signals on the television 121. This receiver 201 is connected via a coaxial cable 202 to a standard LNB block for receiving microwave signals. 203. The integration of an STB receiver 101 according to the invention is illustrated on the installation 300 shown in FIG. 2b. To do this, the standard microwave signal receiving unit LNB 203 is replaced by a LNB microwave signal receiving unit 103 such as that shown in FIG. 1 and operating according to the UNICABLETM technology. A coaxial cable 108 conforming to the cable 108 of FIG. 1 is also added. The LNB microwave signal receiving unit 103 has two outputs respectively for connecting the two coaxial cables 202 and 108, the coaxial cable 202 serving the conventional STB receiver. 201 (only for reception of radio / television signals on television 121, typically derived from Ku-band signals) and coaxial cable 108 serving a triple play receiver 101 STB identical to receiver 101 of Fig. 1 for the reception of broadcast services. radio / television on the television 121, Internet services on the computer 106 and telephony on the analog telephone 107. The installation 300 illustrated in FIG. 2b assumes the use of a parabolic reflector receiving the signals coming from satellites in bands Ku and Ka corresponding to the same orbital position, typically at 13 ° East. If the parabolic reflector of the initial installation 200 is a reflector adapted to the reception of signals from a Ku-band satellite at another orbital position, typically 7 ° East, it is then advisable to use an add-on device. a second microwave receiver (which will constitute the LNB microwave reception unit 103) on the parabolic receiver already equipped, pointed and adjusted without the need to modify the mounting or adjustment of the existing antenna. Such an adjunct device is for example described in document FR2913285. FIGS. 3a and 3b illustrate a second embodiment making it possible to switch from an installation 200 comprising a parabolic reflector 102 and a conventional STB receiver 201 for receiving the television to an installation 400 integrating an STB receiver 101 according to FIG. invention. Unlike the first embodiment described with reference to FIGS. 2a and 2b, this second mode makes it possible to retain not only the parabolic reflector 102 already installed but also not to add a second cable and to use the coaxial cable 202 already to do this. installed. In this exemplary embodiment, the user continues to use his conventional STB receiver 201 in the frequency band 950 at 2150 MHz while at least 2 user bands at the output of LNB 403 are converted in the band 2250 at 2450 MHz. or 460 to 860 MHz using the converter / coupler 406. The separator / converter 404 allows the reverse operation by restoring the 2 User Band carriers which are then transmitted to the receiver 101 object of the present invention. Of course, the invention is not limited to the embodiment just described. Thus, even if the invention finds a particularly interesting application for the reception of Ka and Ku bands using the UNICABLETM solution in its current configuration, it is also possible to use the invention for other frequency bands.

Similarly, even if the application has been more specifically described for television signals, it is understood that the receiver also allows the reception of radio signals. Moreover, even if the invention has been more specifically described using the UNICABLETM solution, the STB receiver according to the invention can also operate according to DiSEqC technology ("Digital Satellite Equipment Control") without the UNICABLETM technology; to do this, the receiver will then operate with two down cables respectively carrying radio / television data (eg from Ku-band signals) and Internet data (eg from Ka-band signals). The receiver according to the invention will then have two tuners each powered by a descent cable. Each tuner comprises a mixer receiving the filtered and amplified signals, the second input of the mixer being connected to a local oscillator, for the selection of the frequency. The STB receiver according to the invention can also advantageously use information received from the GSM network. Thanks to the cellular telephone network, it is indeed possible to know the GSM cell in which the receiver is located and therefore the longitude and latitude associated with the location of this cell. The receiver according to the invention may therefore comprise means for receiving information of frequency and polarization corresponding to the spot (high or low part of the frequency band and right or left circular circular polarization) integrating the GSM cell in which is located the receiver and means for sending commands to the LNB via the coaxial cable according to this information (typically a 13V or 18V voltage from the STB receiver powering and controlling the LNB to set vertical or horizontal polarization in Ku band or circular right or left circular Ka-band and a modulating signal 22kHz to indicate the high frequency band). The term "spot" refers to an elementary coverage area associated with a beam of a multibeam satellite.

Claims (8)

REVENDICATIONS1. Receiver (101) of signals received by satellite comprising: a first tuner (104) adapted to receive digital radiotelevision signals transmitted by a low noise microwave block (103); a second tuner (105) adapted to receive Internet data signals transmitted by a low noise microwave block (103); said receiver (101) being characterized in that it further comprises a cellular circuit-mode and packet-mode cellular radiotelephone (119, 120) adapted to receive and transmit voice signals and Internet data signals, the Internet data being received by said second tuner (105) and transmitted by said transceiver (119, 120) operating in packet mode. 2. Receiver (101) according to the preceding claim characterized in that said cellular radiotelephone transceiver comprises a modem operating in circuit mode according to the GSM standard. 3. Receiver (101) according to one of the preceding claims characterized in that said cellular radiotelephone transceiver comprises a modem operating in packet mode according to one of the following standards: - GPRS; EDGE; - CDMA; - 3G or 3+; HSDPA HSUPA 4. Receiver (101) according to one of the preceding claims characterized in that it is compatible with UNICABLETM technology, said receiver having an input adapted to receive a coaxial cable (108) connected to an LNB receiving unit ( 103), the signal received by said input being transmitted to said first tuner (104) then to said second tuner (105). 5. Receiver (101) according to one of the preceding claims characterized in that it comprises an Ethernet interface (117) type RJ45 and / or a WIFI interface (116). 6. Installation (100, 300, 400) comprising: a receiver (101) according to one of claims 1 to 5; a LNB microwave signal receiving unit (103, 403) connected to said receiver (101) via at least one coaxial cable (108, 202). 7. Installation (100, 300, 400) according to the preceding claim, characterized in that said LNB microwave signal receiving unit (103, 403) comprises two LNB blocks respectively incorporating a horn for receiving microwave radio signals emitted by the Ka-band satellite and a horn for receiving signals transmitted by the Ku-band satellite. 8. Installation (100, 300, 400) according to one of claims 6 to 7 characterized in that said LNB microwave signal receiving unit (103, 403) operates according to technology UNICABLETM20