KR200199818Y1 - Fm repeater for darc data service - Google Patents

Abstract

The present invention, as the existing FM broadcasting broadcasts due to obstacles such as mountains or buildings, the shadow area is generated, the FM broadcast service in the shadow area can not properly perform the function of DARC, FM additional broadcasting service. Therefore, it is a repeater for providing continuous, high quality FM DATA DARC information.

According to the present invention, the DARC repeater for FM DATA broadcasting amplifies, filters, and divides a broadcast signal input through an antenna with a low noise amplifier, and divides the divided signal into a plurality of DARC IF channel amplification modules (8). In the DARC IF channel amplification module 8 and the antenna 2 which amplify and filter the data broadcasting carriers from the multichannel amplification distribution module 6 and the multichannel amplification distribution module 6 to remove noise). A DARC detector module 12 and a plurality of DARC IF channels for detecting a frequency including a DARC signal among the input broadcast signals and transmitting data to the microprocessor 20 to control the DARC IF channel amplification module 8. Amplification module 8 includes a multi-channel synthesis module 10 for synthesizing a broadcast signal from which noise is amplified and filtered and a DARC carrier which is an FM DATA broadcast signal from the multi-channel synthesis module 10. The power amplifier 16 and the power amplifier 16 that power amplify the broadcast signal from the drive amplification module 14 and the drive amplification module 14 to amplify and filter the signal to be filtered to reduce noise in other bands. A system for automatically selectively amplifying and relaying only DARC signals among FM signals (88 to 108 MHz) input to a repeater composed of a power low pass filter (18) which prevents the occurrence of noise.

Description

DMC repeater for FM DATA broadcasting {FM REPEATER FOR DARC DATA SERVICE}

The present invention relates to an FM DATA broadcasting DARC repeater, and more particularly, to an FM DATA broadcasting DARC repeater which automatically selects and relays only a carrier including a DARC signal among FM broadcasting signals.

In general, the FM broadcast repeater is divided into a broadband amplification repeater that amplifies and relays an entire FM broadcast signal and a heterodyne method that demodulates and then modulates a signal received for each channel. The wideband method amplifies the 20 MHz full band, which is a broadcast band. If the level difference of the received input signal is large, the amplified signal is further amplified in the power amplification, and the low level signal is severely affected by noise and cannot relay the signal. Therefore, when the broadcast signal including the DARC subcarrier is significantly less than other broadcast signals, there is a disadvantage that relaying is impossible. In addition, since all broadcast band signals are relayed with the same gain, the DARC service for FM DATA broadcasting cannot be performed over a wide area due to the level difference of the DARC signals.

The heterodyne method demodulates the received broadcast signals for each channel carrier and then remodulates and transmits the DARC signal in this process. That is, the repeater of the heterodyne system cannot perform DARC service which is FM DIGITAL DATA broadcasting.

An object of the present invention is to provide a high quality DARC service in a shaded area where the DARC service, which is an FM DATA broadcast, is not provided. It is to broadcast high quality FM DATA by automatically selecting and relaying only a broadcast signal including a DARC sub-carrier for DATA communication, not a broadcast signal having only an existing voice signal.

Figure 1. A perspective view of a conventional FM broadcast repeater

Figure 2. Configuration of DARC Repeater for FM Data Broadcasting

Figure 3. Multichannel amplification distribution module (6).

Figure 4. DARC IF channel amplification module (8) and microprocessor (20) interface

Figure 5. Multichannel Synthesis Module (10)

<Description of the code | symbol about the principal part of drawing>

2. Antenna 4. Low noise amplification distribution module

6. Multichannel Amplification Distribution Module 8. DARC IF Channel Amplification Module

10. Multichannel Synthesis Module 12. DARC Detector Module

14. Drive Amplifier Module 16. Power Amplifier

18. Low pass filter 20. Microprocessor

22. Attenuator 24. Distributor

26. Variable structure distribution module

According to the present invention, in order to automatically select and relay a broadcast signal having a DARC subcarrier among many FM broadcast signals received, the broadcast signal received by the antenna 2 is passed through the low noise amplification distribution module 4 through the DARC detector module. 12 and the multichannel amplification distribution module 6, respectively. Next to the multi-channel amplification distribution module 6, a plurality of DARC IF channel amplification modules 8 are connected, and a multi-channel for synthesizing a broadcast signal including DARC signals from the plurality of DARC IF channel amplification modules 8 is provided. It is connected to the synthesis module (10). The broadcast signal from the multi-channel synthesis module 10 enters the power amplifier 16 via the drive amplification module 14. The power amplified DARC broadcast signal is connected to the antenna 2 via a power low pass filter 18 and relayed to a shaded area.

Hereinafter, the system configuration of the present invention will be described based on the accompanying drawings.

Figure 2 shows the configuration of the FM DATA broadcasting DARC repeater according to the present invention, the low noise amplification distribution module 4 amplifies and filters the FM broadcast signal to increase the selectivity, inserting the attenuator 22 bandpass filter And impedance matching between divider 24. In addition, the multi-channel amplification distribution module 6 for transmitting the low-noise amplification and distribution signals to the plurality of DARC IF channel amplification modules 8 is provided with a divider 24 and a divider 24, respectively. ) And a frequency having a DARC subcarrier for FM digital data broadcasting among the many broadcast signals in the FM band (88 MHz to 108 MHz) having a 200 KHz channel band and up to 100 broadcast channels, and transmitting data to the microprocessor 20. Are transmitted to the DARC detector module 12, which transmits and controls the DARC IF channel amplification module 8, respectively. The DARC detector module 12 always detects an FM broadcast band, finds a broadcast signal including a DARC sub-carrier in the broadcast band, and amplifies and filters the DARC IF channel amplification module 8 to the microprocessor 20. Information on a carrier including a DARC broadcast signal is given. Then, the microprocessor 20 controls the DARC IF channel amplification module 8 to allocate one broadcast signal including the DARC signal among the many FM broadcast signals to one DARC IF channel amplification module 8.

3 is a block diagram of the multi-channel amplification distribution module 6 according to the present invention, the multi-channel amplification distribution module 6 is a multi-channel card type channel amplification module for a wide DARC broadcast, and expanded This is easy. Basically, it is designed in four distribution structures, and is designed as a variable structure distribution module 26 that can accommodate up to 24 channels by connecting the distributor 24 to the distributor 24. In order to compensate the distribution loss due to the increase of the channel, an amplifier for the distribution loss compensation and an attenuator 22 for reducing the return loss are inserted into the module. DATA broadcast carriers from the multichannel amplification distribution module 6 enter the DARC IF channel amplification module 8 which amplifies and filters to remove noise.

FIG. 4 shows the configuration of the DARC IF channel amplification module 8 and the microprocessor interface. The DARC IF channel amplification module 8 is a multi-channel in mind that a plurality of broadcasters in the present and future will start the DARC broadcasting service. It is composed of a mold and designed to accommodate up to 24 channels. The DARC IF channel amplification module 8 amplifies the FM broadcast signal including the DARC sub_carrier of a single frequency, and must be able to flexibly respond to the new DARC broadcast by adding a module in the DARC broadcast service from another broadcaster. Since the DARC IF channel amplification module 8 is composed of up to 24, the level control is performed so that the signal from each DARC IF channel amplification module 8 can have a constant level by controlling the level of the broadcasting signal inputted to each. . If the DARC IF channel amplification module 8 is not controlled to a constant level, the power amplifier 16 cannot amplify the broadcast signal outputted at a constant level. Therefore, the DARC IF channel amplification module 8 controls the constant level as much as possible. do. A plurality of DARC broadcast signals from the DARC IF channel amplification module 8 enter the multi-channel synthesis module 10 for synthesizing the broadcast signal from which the noise is removed by filtering.

5 shows the configuration of the multi-channel synthesis module 10, the multi-channel synthesis module 10 includes an amplifier to compensate for the loss due to synthesis. Similar to the multi-channel divider 24, the synthesizer synthesizes the 8 divided DARC IF signal, and considers the expansion of the module in the future. Up to 24 channels can be synthesized, and to compensate for the loss due to the synthesis, it is designed as a variable synthesizer into which an amplifier and attenuator 22 can be inserted. The signal including the DARC carrier, which is the FM DATA broadcast signal from the multi-channel synthesis module 10, enters the amplifying drive amplification module 14 to match the input level of the power amplifier. The drive amplification module 14 is level controlled by the DARC IF channel amplification module 8, and amplifies and level controls signals obtained by bringing several carriers to a constant level, so as to match an input level required by the power amplifier 16, and a band. Pass filtering is used to amplify the broadcast band only. The broadcast signal from the drive amplification module 14 is amplified by the power amplifier 16. The DARC broadcast signal from the power amplifier 16 removes noise generated in other bands through the power low pass filter 16. The broadcast signal coming out of the power low pass filter 16 is a DARC repeater for FM data broadcasting transmitted to the antenna 2.

As described above, according to the present invention, in order to provide a high quality FM DATA communication DARC service not provided by the conventional repeater, the FM band (88MHz ~ 108MHz) having a 200KHz channel band and up to 100 broadcast channels Among many broadcast signals, a frequency having a DARC subcarrier for FM digital data broadcasting is automatically detected, and the frequency of the automatically detected carrier is amplified, filtered and level controlled by the DARC IF channel amplification module 8 to relay. The DARC IF channel amplification module 8 can flexibly cope with future expansion of DARC channels by broadcasters by expanding the module. Therefore, the DARC IF channel amplification module 8 is highly efficient and can provide not only a signal for data communication but also a signal including a DARC sub-carrier for data communication. By re-relay, simultaneous relaying of voice and data is easy, and it is useful in terms of frequency reuse by preventing unnecessary relay of radio waves.

Claims (1)

Low noise amplification distribution module 4 for amplifying and filtering broadcast signals input through antenna 2 with a low noise amplifier, and up to 24 distributed signals (basic 8 channels) DARC IF channel amplification module 8 Up to 24 channels for removing noise by amplifying and filtering the data broadcasting carriers from the multichannel amplification distribution module 6 and the multichannel amplification distribution module 6 of up to 24 channels (basic 8 channels) Channel) The DARC IF detects a frequency including the DARC signal among the FM broadcast signals input from the channel amplification module 8 and the antenna 2, and transmits data to the microprocessor 20 so that the microprocessor 20 DARC. DARC detector module 12 for controlling the IF channel amplification module 8 and up to 24 (basic 8-channel) DARC IF channel amplification module 8 for filtering up to 24 channels for synthesizing a broadcast signal from which noise is removed ( Basic 8 channel) The broadcast signal from the drive amplification module 14 and the drive amplification module 14 to amplify, level control, and filter the broadcast signal including the FM DARC subcarriers from the channel synthesis module 10 and the multichannel synthesis module 10. A system for automatically selectively amplifying and relaying only FM broadcast signals including a DARC signal comprising a power amplifier (16) for power amplification and a low pass filter (18) for filtering the broadcast signal from the power amplifier (16).