KR100998315B1 - System and method for automatic selection and tracking broadband multi satellite - Google Patents

Abstract

A broadband multi-satellite automatic selection automatic tracking system and method is provided. According to the present invention, the automatic tracking system of the broadband multi-satellite automatic selection system includes a satellite tracking unit that tracks any one of a plurality of satellites, and the satellite tracking unit receives satellite broadcasts from the satellite being tracked. It includes a broadcast receiver for requesting the satellite tracking unit to track. This makes it possible to provide a user with a broadcast received from the satellite being tracked while automatically tracking the correct one of the various satellites present in the air within the moving object.

Broadband, Multi Satellite, Satellite Tracking, Satellite Broadcasting

Description

System and method for automatic selection and tracking broadband multi satellite}

TECHNICAL FIELD The present invention relates to a satellite tracking system, and more particularly, to a broadband multi-satellite automatic selection automatic tracking system and method for automatically tracking a satellite and providing a user with a broadcast received from the satellite being tracked.

Satellite broadcasting refers to broadcasting that broadcasts such as television and radio transmitted from the earth station can be received by individual or common receivers in a wide area by satellite.

Since there is no radio interference caused by buildings or mountains, such as terrestrial broadcasting, and can include a large area, it is suitable for dissolving astigmatism areas where distance is far from the transmitting side or where reception is difficult in terms of terrain.

In the case of providing a satellite broadcasting service using one satellite, the satellite broadcasting may be received while tracking only one satellite.

However, if the number of satellites that provide satellite broadcasting is many, simple satellite tracking is not enough, and it is required to select and track the correct satellite among several satellites, and the selection of the correct satellite should be done automatically rather than manually. Is requested.

In addition, in a moving object such as a vehicle, the relative positions of various satellites change in real time, and even in such a condition, it is required to automatically track the correct satellite.

The present invention has been made to solve the above problems, and an object of the present invention is to receive a broadcast received from a satellite being tracked while automatically tracking a desired correct satellite among several satellites in the air within a moving object. To provide a user with a broadband multi-satellite automatic selection automatic tracking system and method.

According to the present invention for achieving the above object, a broadband multi-satellite automatic selection automatic tracking system, Satellite tracking unit for tracking any one of a plurality of satellites; And a broadcast receiver configured to receive satellite broadcasts from the satellite being tracked by the satellite tracker, and requesting the satellite tracker to track another satellite if it is determined that the satellite tracker tracks the satellite incorrectly.

If it is determined that the satellite tracking unit tracks a satellite incorrectly, the satellite tracking unit may determine that the satellite broadcasting received from the satellite being tracked is not the satellite broadcasting of the channel selected by the user.

In addition, the satellite tracking unit, the antenna for receiving a satellite broadcast signal from the satellite being tracked; And a first low noise block down converter (LNB) for down-converting the satellite broadcast signal received by the antenna, wherein the broadcast receiver transmits a specific satellite broadcast signal among the satellite broadcast signals received by the antenna. It is preferable to generate a control signal for controlling the operation of the first LNB to receive and output the control signal to the first LNB.

If it is determined that the satellite tracking unit tracks a satellite incorrectly, the broadcast receiving unit inserts and outputs information for notifying that the satellite tracking is in error into the control signal, and outputs the control signal. When the information is inserted into the control signal, it is preferable to track a satellite different from the satellite currently being tracked.

The satellite tracking unit may change at least one of the direction and the position of the antenna to track the other satellites.

And, if the satellite tracking unit receives the control signal, and the information is not inserted into the control signal, it is preferable to continue tracking the satellite currently being tracked.

On the other hand, according to the present invention, a satellite receiving method, the first tracking step for the satellite antenna to track any one of the plurality of satellites; Receiving satellite broadcasting from the satellite being tracked by the satellite antenna in the first tracking step; And a second tracking step in which the satellite antenna automatically tracks another satellite if it is determined that the satellite antenna incorrectly tracks the satellite in the first tracking step.

In the case where it is determined that the satellite is incorrectly tracked in the first tracking step, it is preferable that the satellite broadcasting received from the satellite being tracked in the first tracking step is not the satellite broadcast of the channel selected by the user. Do.

The receiving step may include receiving a specific satellite broadcast signal among satellite broadcast signals received by the antenna using a specific control signal.

The second tracking step may include inserting and outputting information for notifying that the satellite tracking is wrong when it is determined that the satellite is incorrectly tracked in the first tracking step; And tracking the satellite that is different from the satellite currently being tracked when the information is inserted into the control signal.

In the second tracking step, at least one of the direction and the position of the antenna may be changed to track the other satellite.

The satellite tracking method may further include receiving the control signal and continuously tracking the satellite currently being tracked if the information is not inserted into the control signal.

As described above, according to the present invention, it is possible to provide a user with a broadcast received from the satellite being tracked while automatically tracking a desired correct satellite among several satellites present in the air in the moving object.

Hereinafter, with reference to the drawings will be described the present invention in more detail.

1 is a block diagram of a wideband multi-satellite automatic selection automatic tracking system according to an embodiment of the present invention. The broadband multi-satellite automatic selection automatic tracking system according to the present embodiment can be mounted and used on a moving object such as a vehicle.

According to the present invention, a system for automatically selecting a broadband multi-satellite system includes: 1) knowing a satellite providing a user-selected satellite broadcasting among a plurality of satellites in the air, and 2) automatically tracking a found satellite. And 3) provide the user with satellite broadcasting received from the satellite being tracked.

As shown in FIG. 1, in the wideband multi-satellite automatic selection system for automatically performing the above-described function, the STB (Set Top Box) 200, which is a kind of the satellite tracking unit 100 and the broadcasting receiver, is shown in FIG. 1. It is provided.

The satellite tracking unit 100 automatically tracks a specific satellite among a plurality of satellites and receives a satellite broadcast relayed by the tracking satellite.

The satellite tracking unit 100 includes a satellite antenna 110, an antenna driver 120, a dual low noise block down converter (LNB) 130, a tuner 140, a controller 150, and a DC / DC converter 160. And a TON converter 170.

The satellite antenna 110 receives satellite broadcasts from satellites. The antenna driver 120 drives the satellite antenna 110 so that the satellite antenna 110 can receive satellite broadcasts relayed by any one of several satellites.

Specifically, the antenna driver 120 drives the satellite antenna 110 so as to rotate the satellite receiving surface of the satellite antenna 110 or move the body of the satellite antenna 110 forward, backward, left, and right on a plane.

The operation of the antenna driver 120 to drive the satellite antenna 110 is under the control of the controller 150, and a detailed description thereof will be described later.

The dual-LNB 130 down-converts the satellite broadcast signal of the 10 GHz band received through the satellite antenna 110 to an intermediate frequency (IF) of about 1 GHz.

As shown in FIG. 1, the dual-LNB 130 includes an LNB-1 130-1 and an LNB-2 130-2.

The LNB-1 130-1 is a universal LNB and performs down-conversion only for a specific polarization of a specific band among satellite broadcast signals received through the satellite antenna 110. It is determined by the STB 200 whether the LNB-1 130-1 down-converts which polarization of which band.

Specifically, the STB 200 may include 1) 'horizontal polarization in the low band, which is the lower band of the wideband' (hereinafter, referred to as 'LH'), and 2) in the low band. Vertical polarization '(hereinafter referred to as' LV '), 3)' Horizontal polarization in the high band, the highest band of the broadband '(hereinafter referred to as' HH ') and 4)' The LNB-1 130-1 is controlled to perform down-conversion only for one of the vertical polarizations' (hereinafter, referred to as' HV ') in the high band.

For control of the LNB-1 130-1, the STB 200 outputs a TON signal containing information on which polarization of the LNB-1 130-1 performs down-conversion for which band.

The LNB-1 130-1 refers to the TON signal output from the STB 200 and down-converts only one of LH, LV, HH, and HV to output the same.

The LNB-2 130-2 down-converts the satellite broadcast signal received through the satellite antenna 110 and applies the down-converted satellite broadcast signal to the tuner 140.

Then, the tuner 140 tunes only the broadcast signal of a specific band among the satellite broadcast signals introduced from the LNB-2 130-2 and transmits the tuner 140 to the controller 150.

The TON converter 170 receives a TON signal output from the STB 200. As will be described later, satellite information may be inserted into the TON signal. When the TON signal in which the satellite information is inserted is received, the TON converter 170 extracts the satellite information from the TON signal and transfers the extracted satellite information to the controller 150.

The controller 150 controls the antenna driver 120 so that the satellite antenna 110 tracks the satellite indicated by the satellite information received from the TON converter 170. In addition, the controller 150 controls the antenna driver 120 to drive the satellite antenna 110 in a direction in which the reception strength of the satellite broadcast signal output from the tuner 140 increases.

Meanwhile, the DC / DC converter 160 also receives a TON signal output from the STB 200. The TON signal has a voltage of 13-18V. The DC / DC converter 160 reduces the voltage of the TON signal to about 5V to generate a 5V power supply, and supplies the 5V power supply to other devices that need this 5V power supply.

Hereinafter, a process of receiving satellite broadcast by the wideband multi-satellite automatic selection automatic tracking system shown in FIG. 1 will be described in detail with reference to FIG. 2. 2 is a flowchart provided to explain a satellite receiving method according to an embodiment of the present invention.

As shown in FIG. 2, first, the controller 150 controls the antenna driver 120 so that the satellite antenna 110 tracks a specific satellite among several satellites in the air (S310). Here, the specific satellite is a satellite providing satellite broadcasting of a channel selected by the user, that is, a satellite providing satellite broadcasting currently being viewed by the user.

The LNB-1 130-1 performs down-converting only for a specific polarization of a specific band among satellite broadcast signals received through the satellite antenna 110 (S320). Whether the LNB-1 130-1 down-converts which polarization of which band is determined by the TON signal output from the STB 200. As described above, the TON signal contains information about the band and polarization of the satellite broadcast signal for the channel selected by the user.

Then, the STB 200 reproduces the satellite broadcast by performing amplification, demodulation, decoding, and signal processing on the down-converted satellite broadcast signal output from the LNB-1 130-1 (S330). The satellite broadcast reproduced in step S330 is output from a display such as TV, navigation connected to the STB 200 is provided to the user.

Then, when the user changes the channel to watch (S340-Y), the STB 200 determines whether it is necessary to change the TON signal (S350). For the determination at step S350, the STB 200 refers to the satellite / TP / channel / signal information table as shown in FIG.

As shown in FIG. 3, when the current channel is "CH 51" and the channel to be changed by the user is "CH 250", the TON signal needs to be changed. This is because the signal information needs to be changed from "LH" to "HH". In other words, the satellite broadcast signal of "CH 51" is a horizontal polarization in the low band, while the satellite broadcast signal of "CH 250" is a horizontal polarization in the high band. have.

On the other hand, when the current channel is "CH 51" and the channel that the user wants to change is "CH 450", the TON signal does not need to be changed. This is because the signal information is both "LH".

If it is determined in step S350 it is necessary to change the TON signal (S350-Y). The STB 200 changes and outputs the output TON signal (S360). For example, if the current channel is "CH 51" and the channel to be changed by the user is "CH 250", in step S360, the STB 200 terminates the generation of the TON signal indicating "LH", and "HH". Generates and outputs a TON signal indicating "."

On the other hand, the STB 200 determines whether it is necessary to change the tracking satellite (S370). For the determination in step S370, the STB 200 refers to the satellite / TP / channel / signal information table as shown in FIG.

As shown in FIG. 3, when the current channel is "CH 51" and the channel to be changed by the user is "CH 250", it is not necessary to change the tracking satellite. Both are satellites that provide satellite broadcasting, "G1."

However, when the current channel is "CH 51" and the channel to be changed by the user is "CH 450", it is necessary to change the tracking satellite. This is because the satellite providing satellite broadcast of "CH 51" is "G1", while the satellite providing satellite broadcast of "CH 450" is "G2".

If it is determined in step S370 it is necessary to change the tracking satellite (S370-Y). The STB 200 inserts satellite information into the output TON signal (S380). For example, if the current channel is "CH 51" and the channel that the user wants to change is "CH 450", the STB 200 generates a TON signal in which information indicating "G2" is inserted in step S380. After the output, the TON signal is generated without outputting the information indicating "G2".

Then, the TON converter 170 extracts the satellite information contained in the TON signal, and transmits the extracted satellite information to the controller 150 (S390).

Then, the controller 150 controls the antenna driver 120 to track the satellite indicated by the satellite information received in step S390 (S400). For satellite tracking control in steps S310 and S400 described above, the controller 150 controls the antenna driver 120 and the tuner 140 with reference to the satellite / TP table shown in FIG. 4.

For example, if it is necessary to track the "G2" satellite, the controller 150 1) controls the tuner 140 to tune the band of TP 24, which is the TP corresponding to the "G2" satellite, on the satellite / TP table, and 2) The antenna driver 120 is controlled to drive the satellite antenna 110 in a position and / or direction in which reception strength of the TP 24 band satellite broadcast signal output from the tuner 140 increases.

Meanwhile, the LNB-1 130-1 performs down-converting only on the polarization of the band specified by the TON signal output from the STB 200 among the satellite broadcast signals received through the satellite antenna 110 ( S410).

The STB 200 reproduces the satellite broadcast signal output from the LNB-1 130-1 (S420). In this case, the STB 200 determines whether the satellite broadcast signal for the channel changed by the user is correctly received in step S340 (S430). The operation S430 may be determined by referring to the channel information stored in the satellite broadcast signal reproduced in operation S420.

If it is determined in step S430 that the satellite broadcasting signal for the channel changed by the user is not received (S430-N), the STB 200 inserts satellite information once more into the output TON signal (S440). In the case where the satellite broadcast signal for the channel changed by the user is not received in step S430, the satellite tracking is caused due to the wrong reason, because the bands used by the satellites may overlap at the edges. Therefore, the satellite tracked by the satellite tracking unit 100 as the "G2" satellite may actually be a "G3" satellite.

Meanwhile, in step S440, the STB 200 generates and outputs a TON signal in which satellite information is inserted once more, and then generates and outputs a TON signal in which satellite information is not inserted again. The TON signal into which the satellite information generated by the STB 200 is inserted in step S440 corresponds to a signal for notifying that the satellite tracking unit 100 is incorrectly tracking the current satellite.

Thereafter, the TON converter 170 extracts the satellite information contained in the TON signal and transmits the extracted satellite information to the controller 150 (S450). Then, the controller 150 controls the antenna driver 120 to change the direction and / or the position of the satellite antenna 110 (S460). This is to correct the direction and / or position of the wrong satellite antenna 110 to track the correct satellite, and then it is performed from step S410.

On the other hand, if it is determined in step S430 that the satellite broadcast signal for the channel changed by the user is correctly received (S430-Y), the process is performed from step S310. Accordingly, since the steps S440 to S460 are not performed, the satellite tracking unit 100 continues to track the satellite currently being tracked.

To date, a preferred embodiment has been described for the process of tracking a satellite providing a user-selected satellite broadcast among several satellites existing in the air and providing the user with a satellite broadcast received from the satellite being tracked. It was explained in detail.

The satellite / TP / channel / signal information table of FIG. 3 and the satellite / TP table of FIG. 4 presented in this embodiment correspond to an example for convenience of description. Therefore, the technical idea of the present invention may be applied even when a table different from that shown is used.

In addition, although the preferred embodiment of the present invention has been shown and described above, the present invention is not limited to the specific embodiments described above, but the technical field to which the invention belongs without departing from the spirit of the invention claimed in the claims. Of course, various modifications can be made by those skilled in the art, and these modifications should not be individually understood from the technical spirit or the prospect of the present invention.

1 is a block diagram of a wideband multi-satellite automatic selection automatic tracking system according to an embodiment of the present invention,

2 is a flowchart provided to explain a method for automatically tracking a wideband multi-satellite automatic selection according to an embodiment of the present invention;

3 is a diagram illustrating an example of a satellite / TP / channel / signal information table, and

4 is a diagram illustrating an example of a satellite / TP table.

Explanation of symbols on the main parts of the drawings

100: satellite tracking unit 110: satellite antenna

120: antenna driver 130: dual-LNB

131: LNB-1 132: LNB-2

140: tuner 150: control unit

160: DC / DC converter 170: TON converter

200: STB

Claims (12)

A satellite tracking unit for tracking any one of a plurality of satellites; And And a broadcast receiving unit receiving the satellite broadcasting from the satellite being tracked by the satellite tracking unit and requesting the satellite tracking unit to track another satellite if a satellite broadcasting signal for a channel changed by the satellite tracking unit is not received. In the broadband multi-satellite automatic selection automatic tracking system, The satellite tracking unit, An antenna for receiving satellite broadcast signals from the satellite being tracked; And And a first low noise block down converter (LNB) for down-converting the satellite broadcast signal received by the antenna. The broadcast receiver, In order to receive the satellite broadcast signal selected by the user among the satellite broadcast signals received by the antenna, a broadband multi-satellite satellite, characterized in that for generating a control signal for controlling the operation of the first LNB, and outputs to the first LNB. Optional automatic tracking system. The method of claim 1, The broadcast receiver, If the satellite tracking signal for the channel changed by the satellite tracking unit is not received, the satellite tracking unit inserts and outputs information for informing that the satellite tracking is wrong, and inserts the information into the control signal. The satellite tracking unit, Receiving the control signal, and when the information is inserted into the control signal, the broadband multi-satellite automatic selection automatic tracking system, characterized in that to track the satellite and other satellites currently being tracked. 3. The method of claim 2, The satellite tracking unit, And at least one of a direction and a position of the antenna to change the other satellites to track the other satellites. 3. The method of claim 2, The satellite tracking unit, And receiving the control signal, and continuously tracking the satellite currently being tracked if the information is not inserted in the control signal. A first tracking step of causing the satellite antenna to track any one of the plurality of satellites; Allowing the satellite antenna to receive satellite broadcasts from the satellite being tracked in the first tracking step; And And a second tracking step of causing the satellite antenna to automatically track another satellite when the satellite broadcasting signal for the channel changed by the user is not received in the first tracking step. In the automatic tracking method, The receiving step, And receiving a satellite broadcast signal selected by a user among satellite broadcast signals received by the satellite antenna using a specific control signal. The method of claim 5, The second tracking step, Inserting and outputting information for notifying that satellite tracking is wrong when the satellite broadcasting signal for the channel changed by the user in the first tracking step is not received; And And when the information is inserted into the control signal, tracking a satellite different from a satellite currently being tracked. The method of claim 6, The second tracking step, And tracking at least one of the satellites by changing at least one of a direction and a position of the antenna. The method of claim 6, And receiving the control signal and continuously tracking a satellite currently being tracked if the information is not inserted into the control signal. delete delete delete delete

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