KR20050017192A - RF relay station of Digital Multi-Media Broadcasting using 2.6 GHz frequency - Google Patents

Abstract

PURPOSE: A DMB(Digital Multimedia Broadcasting) RF(Radio Frequency) repeater for a 2.6GHz wide band satellite is provided to directly receive satellite signals for directly amplifying and re-projecting the signals in a fade area out of satellite service, thereby realizing the satellite service in every place. CONSTITUTION: A DMB RF repeater for a 2.6GHz wide band satellite includes a cassegrain antenna for receiving satellite DMB signals of 2.6GHz, and an input filter part for filtering unnecessary signals from the received DMB signals. A low-noise amplification part amplifies the filtered signals. A down-conversion part carries out down-conversion for frequency of the amplified signal. A signal processing part removes oscillating factors from the down-converted signals, and an up-conversion part carries out up-conversion for the frequency of the signals. A power amplification part amplifies power of the up-converted signals. An output filter part filters unnecessary signals from the amplified signals. A service antenna projects the filtered signals into fade areas.

Description

RF relay station of Digital Multi-Media Broadcasting using 2.6 GHz frequency

The present invention relates to a 2.6 GHz band satellite DMB RF repeater, which is used to make a shaded area of an unserviceable area of a 2.6 GHz band satellite service into a serviceable area.

Conventionally, satellite broadcasting has been conducted to overcome regional limitations in terrestrial broadcasting. In other words, in order to broadcast in a wide area on the ground, the broadcasting signals had to be transmitted through a plurality of base stations. However, since satellites can transmit broadcast signals over a large area, satellite broadcasting has begun to broadcast over a wider area.

As these satellite broadcasts started with digital broadcasting, satellite broadcasting gradually changed to digital broadcasting, and digital satellite broadcasting was started. Currently, many digital satellite broadcasting companies are transmitting satellite broadcasting signals.

As a feature of the above, there is a shaded area where satellite broadcasts have a wide broadcasting area, but satellite broadcasts cannot reach signals transmitted by satellite broadcasts due to obstacles such as high buildings or mountains. That is, in general urban areas or mountainous areas, high-rise buildings or high mountains may block the line of sight between the satellite and the terminal, and even if the user who owns the terminal is in the building. Similarly, a problem arises that the viewing distance between the satellite and the terminal is blocked. In addition, since the viewing distance is not made smoothly, the service is disconnected.

Direct repeater is used to solve this problem and easily solve the shadow area. In other words, in order to remove such shaded areas, a conventional method using a relay device for transmitting satellite broadcast signals back to the shaded areas is widely used. In other words, by processing the satellite broadcast signal and retransmitting the satellite signal toward the shadow area, it is possible to receive the satellite broadcast signal indirectly in the shadow area, and through this, the satellite broadcast can be viewed.

Satellite digital multi-media broadcasting (DMB) services provide services using two bands, the Ku band (12 GHz band) and the S band (2.6 GHz band).

The satellite uses Ku-band signal and S-band signal to service two types of signals. The modulation method of the service method using Ku-band is TDM method and the modulation method of service method using S-band is CDM method. Modulation method is used. Gap filter, a repeater using Ku band transmitted from satellite, receives weak signal of 12GHz band which is TDM Ku band and converts it into 2.6M band which is S-band of CDM. Will be done. In case of S-band transmitted from satellite, the terminal of the ground is directly received and used. In case of shadowed area, S-band signal transmitted from satellite is received by high-gain antenna to secure C / N (carrier to noise ratio). By amplifying and radiating the shadowed area, the system can be utilized economically.

In general, a wireless relay system has a problem in that a normal relay function is generated due to oscillation due to the signals fed back because the input and output frequencies are the same, thus making the service impossible and the use of other communication systems.

The present invention has been invented to solve the above-described problems, by directly receiving a satellite signal in a shaded area that is not serviced due to the building or topographical factors of the ground and directly amplifying it to reradiate the shadowed area to a minimum The investment aims to provide a 2.6GHz band satellite DMB RF relay that enables satellite services anywhere on the ground.

A casee grain antenna for receiving satellite DMB signals in the 2.6 GHz band to achieve the above object; An input filter unit receiving the received DMB signal and filtering an unnecessary signal; A low noise amplifier for amplifying the filtered signal; A down converter for down converting the frequency of the amplified signal; A signal processor which removes an element of oscillation from the down-converted signal; An up-converter configured to up-convert the frequency of the signal from which the oscillation element is removed; A power amplifier for amplifying the power of the upconverted signal; An output filter unit filtering out unnecessary signals in the amplified signal; An object of the present invention is to provide a 2.6 GHz band satellite DMB RF relay, comprising a service antenna for radiating the filtered signal into a shaded area.

1 is a block diagram of the present repeater, FIG. 2 is a diagram showing a change in frequency of the present repeater, FIG. 3A is a front view of a horn used for a receiving antenna among the present repeaters, and FIG. 3B is a present repeater 3C is a side view of the horn used for the reception antenna of the relay apparatus, and FIG. 4 is a view showing an embodiment of the reception antenna of the relay apparatus.

Looking at the present 2.6GHz band satellite DMB RF repeater shown in Figure 1, the repeater is largely composed of a receiving antenna, a direct DMB repeater (DDR), and a service antenna.

First of all, the reception antenna is made of a casee grain antenna using a HORN antenna. The structure is the same as general casee antenna, but HORN antenna using HORN is used as a large antenna in high frequency band, but in this repeater, it is manufactured as a small antenna in low frequency band which is not generally used to solve the isolation problem between antennas. Use it.

As for the isolation between the antennas, the conventional relay device has a problem that the normal communication function is performed by oscillating due to the signals fed back because the input and output frequencies are the same. Isolation is important. This is because the degree of isolation ensures that the equipment can function normally. In consideration of this, the horn antenna was manufactured in the form of a case-grain antenna to minimize the feedback of the signal due to fading, thereby securing the isolation between input and output to secure the stability of the device.

In other words, when a device with the same input and output frequencies is installed outdoors, the isolation between the input and output antennas is more than the gain of the device in order to prevent the device from unstable communication due to signal feedback. Satellite digital multi-media broadcast (DMB) using the 2.6 GHz band requires a lot of gain to amplify and service this signal because the signal to the ground is weak. Therefore, although it is very difficult to secure the isolation between the input and output antennas in the conventional repeater type antenna, the use of a casein grain antenna using a horn antenna is less affected by the fading, and the isolation is improved.

Next, the configuration of a direct DMB repeater (DDR) includes a power filter, a low noise amplifier, a down converter, a signal processor, an up converter, a power amplifier, and an output filter.

Looking at each configuration in detail, first the input filter unit is a device for filtering the signal received through the receiving antenna, and removes unnecessary signals. That is, it removes noise coming from the antenna or other unnecessary band signals.

The low noise amplification unit amplifies the filtered signal, lowers noise in the entire repeater, and amplifies the signal.

The down conversion unit is configured to down convert the frequency of the amplified signal to enable signal processing. This downconversion unit is intended to facilitate the processing of the signal in the relay apparatus by lowering the frequency, and in this embodiment down-converts the frequency to 80MHz in the present embodiment as shown in FIG.

Next, the signal processor is a device for removing the elements of the oscillation in the down-converted signal to the frequency of 80MHz, as shown in Figure 2 the signal downconverted to 80MHz through the signal processing unit 250MHz at the same time the removal of the oscillation element Is converted to.

The 250MHz signal from which the oscillation element is removed is sent to the upconverter, and the upconverter upconverts the frequency of the signal again. That is, the 250MHz signal is converted back to 2.6GHz, which is the same frequency as the received frequency.

The converted signal is amplified by the power amplifying unit and filtered once more to remove unnecessary signals from the output filter unit.

As described above, the signal processed in the DDR is transmitted to the service antenna, and the service antenna radiates the signal toward the shaded area.

FIG. 2 is a diagram illustrating conversion of a frequency used in the present embodiment, and since the configuration of the device has been described together, a separate description is omitted, and FIG. 3 illustrates a structure of a HORN used in the reception antenna. It is. The caseingrain antenna completed using the HORN shown in FIG. 3 is shown in FIG. 4.

As described above, the casee grain antenna for receiving a satellite DMB signal of the 2.6GHz band; An input filter unit receiving the received DMB signal and filtering an unnecessary signal; A low noise amplifier for amplifying the filtered signal; A down converter for down converting the frequency of the amplified signal; A signal processor which removes an element of oscillation from the down-converted signal; An up-converter configured to up-convert the frequency of the signal from which the oscillation element is removed; A power amplifying unit for amplifying the power of the signal which has been converted; An output filter unit filtering out unnecessary signals in the amplified signal; By including the service antenna radiating the filtered signal to the shaded area to produce a caseingrain antenna to reduce the impact of the fading to improve the isolation to remove the unstable elements of the device in the digital part of the device to improve the stability of the device Through this, satellite DMB service is possible in shadow area, and receiving antenna Casegrain antenna receives S-band satellite signal or Gap Filler signal on the ground and amplifies it and radiates it through service antenna. Direct relaying is possible by suppressing the reception of terrestrial service signals.

1 is a block diagram of the relay apparatus.

Fig. 2 is a diagram showing a change in frequency of the relay device.

3A is a front view of the horn used for the receiving antenna of the relay apparatus.

3B is a rear view of the horn used for the receiving antenna of the relay apparatus.

3C is a side view of a horn used for a receiving antenna of the relay apparatus.

4 is a view showing an embodiment of a receiving antenna of the relay device.

Claims (6)

A receiving antenna for receiving satellite DMB signals in a 2.6 GHz band; An input filter unit receiving the received DMB signal and filtering an unnecessary signal; A low noise amplifier for amplifying the filtered signal; A down converter for down converting the frequency of the amplified signal; A signal processor which removes an element of oscillation from the down-converted signal; An up-converter configured to up-convert the frequency of the signal from which the oscillation element is removed; A power amplifier for amplifying the power of the upconverted signal; An output filter unit filtering out unnecessary signals in the amplified signal; 2.6 GHz band satellite DMB RF repeater including a service antenna for emitting the filtered signal to the shadow area The method according to claim 1, The receiving antenna is a casee grain antenna 2.6GHz band satellite DMB RF repeater The method according to claim 2, The casee antenna is a 2.6GHz band satellite DMB RF repeater, characterized in that the horn (HORN) antenna in the form of a casee antenna The method according to claim 1, The downconversion unit 2.6GHz band satellite DMB RF repeater, characterized in that downconvert the frequency to 80MHz The method according to claim 1, The signal processor controls the components of the oscillation and at the same time converts the signal to 250MHz satellite DMB RF repeater, characterized in that The method according to claim 1, The up-conversion unit 2.6GHz band satellite DMB RF repeater, characterized in that up-converting the frequency of the signal to a signal of 2.6GHz band