KR100466070B1 - Digital audio broadcasting tuner - Google Patents

Abstract

The present invention relates to a digital audio broadcast tuner, the present invention comprises: an RF splitter 10 for distributing a high frequency signal through an antenna; An L-band mixer stage 20 for lowering the frequency (1450-1490 MHz) of the L-band signal among the signals through the RF splitter 10; A bandIII RF AGC stage 30 for AGC amplifying a bandIII signal (170-240MHz) of the signals through the RF splitter 10 according to the provided AGC voltage; A switch circuit unit 40 for switching the output signal of the L-band mixer stage 20 and the output signal of the band III RF AGC stage 30; And an IF circuit section 50 for downgrading and amplifying the frequency of the signal through the switch circuit section 40 and providing the AGC voltage corresponding to the signal level to the band III RF AGC stage 30. .

Description

Digital audio broadcasting tuner {DIGITAL AUDIO BROADCASTING TUNER}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a digital audio broadcasting tuner, and in particular, digital audio broadcasting capable of selectively receiving satellite signals of L band (1450-1490 MHz) and terrestrial signals of band III (170-240 MHz) through digital audio broadcasting. It's about a tuner.

In general, conventional radio-related audio broadcasting services have been operated in an AM scheme or an FM scheme of frequency modulation. Both of these AM or FM methods are analog methods and have the following problems.

In the conventional analog audio broadcasting system, the AM / FM broadcasting system (AUDIO SERVICE) has a relatively low noise rejection capability compared to the digital service due to the characteristics of the modulation system. In particular, according to the analog audio broadcasting system, In deafness areas such as remote areas or mountainous terrain, there is a problem that it is impossible to listen in difficult or severe cases.

In order to solve this problem, conventional researches and developments on digital satellite audio broadcasting have been made. Among the present invention, L-band (1450-1490MHz) satellite signal and band III (170-240MHz) terrestrial signal We propose a tuner to selectively receive.

The present invention has been made to solve the above problems, and therefore, an object of the present invention is to select a L-band (1450-1490MHz) satellite signal and a band III (170-240MHz) terrestrial signal through digital audio broadcasting. To provide a digital audio broadcast tuner that can be received by.

1 is a block diagram of a digital audio broadcast tuner according to the present invention.

2 is a detailed view of the L-band mixer stage of FIG.

3 is a detailed view of the band III RF AGC stage of FIG.

4 is a detailed view of an IF circuit part of FIG. 1.

Explanation of symbols on the main parts of the drawings

10: RF splitter 20: L-band mixer stage

30: band III RF AGC stage 40: switch circuit

50: IF circuit part

As a technical means for achieving the above object of the present invention, the tuner of the present invention includes an RF splitter for distributing a high frequency signal through an antenna; An L band mixer stage for lowering a frequency (1450-1490 MHz) of an L band signal of the signal through the RF splitter; A band III RF AGC stage for AGC amplifying a band III signal (170-240 MHz) of the signal through the RF splitter according to the provided AGC voltage; A switch circuit unit for switching the output signal of the L-band mixer stage and the output signal of the band III RF AGC stage; And an IF circuit unit for downgrading and amplifying the frequency of the signal through the switch circuit unit and providing the AGC voltage corresponding to the signal level to the band III RF AGC stage.

Hereinafter, the structure and operation of the digital audio broadcast tuner according to the present invention will be described in detail with reference to the accompanying drawings. In the drawings referred to in the present invention, components having substantially the same configuration and function will use the same reference numerals.

1 is a block diagram of a digital audio broadcast tuner according to the present invention. Referring to FIG. 1, a digital audio broadcast tuner according to the present invention includes an RF splitter 10 for distributing a high frequency signal through an antenna and the RF splitter ( L-band mixer stage 20 for lowering the frequency (1450-1490 MHz) of the L-band signal among the signals through 10) and the signal of the band III in the signal through the RF divider 10 (170) according to the provided AGC voltage. A band III RF AGC stage 30 for AGC amplifying (240 MHz), a switch circuit unit 40 for switching the output signal of the L band mixer stage 20 and the output signal of the band III RF AGC stage 30; In addition, the frequency of the signal through the switch circuit unit 40 is down and amplified, and the IF circuit unit 50 provides the AGC voltage corresponding to the signal level to the band III RF AGC terminal 30.

The switch circuit unit 40 may be implemented as a manual switch operated by manual operation, or may be implemented as an electronic switch for switching operation under the control of the microcomputer in response to the remote control.

FIG. 2 is a detailed view of the L-band mixer stage of FIG. 1. Referring to FIG. 2, the L-band mixer stage 20 performs a first AGC amplifier 21 for AGC amplifying an input signal through the RF splitter 10. ), A band pass filter 22 for passing the output signal of the first AGC amplifier 21 to the L band, a second AGC amplifier 23 for AGC amplifying the output signal of the band pass filter 22, and And an L-band frequency converter 24 for lowering the frequency of the output signal of the second AGC amplifier 23 and an AGC detector 25 for providing an AGC voltage corresponding to the level of the output signal of the frequency converter 24. ) And an AGC buffer 26 that provides the AGC voltage by the AGC detector 25 as the bias voltages of the first and second AGC amplifiers 21, 23.

FIG. 3 is a detailed view of the band III RF AGC stage of FIG. 1. Referring to FIG. 3, the band III RF AGC stage 30 passes through the RF divider 10 at an amplification rate determined according to a bias voltage provided. An AGC amplifier 31 for AGC amplifying the signal, and a voltage amplifier 32 for amplifying the AGC voltage input for AGC and providing it as a bias voltage of the AGC amplifier 31. FIG. 4 is an IF of FIG. As a detailed view of the circuit section, referring to FIG. 4, the IF circuit section 50 includes a first AGC amplifier 51 for AGC amplifying a signal through the switch circuit section 40, and the first AGC amplifier 51. An IF frequency converter 52 for lowering the frequency of the output signal, a signal amplifier 53 for amplifying the output signal of the IF frequency converter 52, and a level of the output signal of the signal amplifier 53, and detecting the level. The AGC voltage corresponding to the detection level is transferred to the first AGC amplifier 51 and the band III RF AGC stage 30. A AGC amplifier for AGC amplifying the first AGC detector 54, a band pass filter 55 for passing the output signal of the signal amplifier 53 to a set band, and an output signal of the band pass filter 55; A second AGC detector 57 which detects the level of the output signal of the second AGC amplifier 56 and the second AGC amplifier 56 and provides the AGC voltage corresponding to the detection level to the second AGC amplifier 56; ).

Based on the accompanying drawings, the operation of the preferred embodiment of the present invention configured as described above will be described in detail below.

The present invention adds a terrestrial broadcast signal reception function to a digital audio broadcast tuner to selectively receive satellite signals of L band (1450-1490 MHz) and terrestrial signals of band III (170-240 MHz). The digital audio broadcast tuner of the present invention receives a signal from a low noise frequency converter (LNB) mounted to an antenna, the operation of which is described in detail below.

Referring to FIGS. 1 to 4, the operation of the digital audio broadcast tuner according to the present invention will be described first. Referring to FIG. 1, the RF splitter 10 of the digital audio broadcast tuner according to the present invention is a high frequency antenna. The signal is distributed to the L-band mixer stage 20 and the band III RF AGC stage 30, respectively, wherein the L-band mixer stage 20 is the frequency (1450) of the L-band satellite signal of the signal through the RF splitter 10. -1490MHz) to select the frequency down and output the band III RF AGC stage 30, AGC terrestrial signal (170-240MHz) of the band III of the signal through the RF splitter 10 according to the AGC voltage received Amplify.

At this time, the switch circuit 40 is switched according to the user's band selection, selects and outputs the output signal of the L-band mixer stage 20 or the output signal of the band III RF AGC stage 30, and then, IF The circuit unit 50 reduces the frequency of the signal through the switch circuit unit 40 and amplifies it, and provides an AGC voltage corresponding to the signal level to the band III RF AGC stage 30.

Referring to FIG. 2, the L-band mixer stage 20 will be described in detail. The first AGC amplifier 21 of the L-band mixer stage 20 performs AGC amplification of an input signal through the RF divider 10. The amplified signal is passed by the band pass filter 22 to the frequency band (1450-1490 MHz) of the satellite signal which is the set band, that is, the L band, and then AGC amplified by the second AGC amplifier 23. Thereafter, the L-band frequency converter 24 mixes the frequency (1450-1490 MHz) of the output signal of the second AGC amplifier 23 with the internal oscillation frequency (1261.568 MHz) to approximately 188 MHz-229 MHz corresponding to the difference frequency. Down.

The AGC detector 25 also provides an AGC voltage corresponding to the level of the output signal of the frequency converter 24, which is supplied through the AGC buffer 26 to the first and second AGC amplifiers 21. 23 is provided with a bias voltage. Accordingly, the gain is adjusted by the bias voltages provided with the first and second AGC amplifiers 21 and 23.

Referring to FIG. 3, the band III RF AGC stage 30 will be described in detail. The AGC voltage provided by the IF circuit unit 50 is amplified by the voltage amplifier 32 of the band III RF AGC stage 30. The AGC amplifier 31 of the band III RF AGC stage 30 AGC amplifies the terrestrial signal frequency (170-240 MHz) of the signal through the RF splitter 10.

Referring to FIG. 4, the IF circuit unit 50 will be described in detail. The first AGC amplifier 51 of the IF circuit unit 50 AGC-amplifies the signal selected through the switch circuit unit 40, and the amplified signal is amplified. The frequency of the signal (170-240 MHz or 188-229 MHz) is mixed with the internal oscillation frequency (208.912-278.912 MHz) of the IF frequency converter 52 and down to a frequency of 38.912 MHz, the difference frequency thereof, which is the IF frequency converter 52. The signal output from the amplified by the signal amplifier 53 is amplified by the signal amplifier 53. For example, 170 MHz of the 170-240 MHz corresponding to the band III and 208.912 MHz of the oscillation frequency are mixed and the difference frequency (208.912 MHz-170 MHz) is mixed. Down to the frequency of 38.912 MHz, and the frequency band of the L-band satellite signal is down, 190 MHz of 188-229 MHz and 228.912 MHz of the oscillation frequency are mixed, and the difference frequency (228.912 MHz to 190 MHz) of 38.912 MHz is mixed. Down to the frequency.

At this time, the first AGC detector 54 detects the level of the output signal of the signal amplifier 53 and sets the AGC voltage corresponding to the detection level to the first AGC amplifier 51 and the band III RF AGC stage 30. In this case, AGC amplification is performed in the first AGC amplifier 51 and the band III RF AGC stage 30.

Then, the band pass filter 55 bandpasses a frequency of approximately 38.912 MHz among the output signals of the signal amplifier 53, and then the second AGC amplifier 56 AGC amplifies the output signal of the band pass filter 55. do. The second AGC detector 57 detects the level of the output signal of the second AGC amplifier 56 and provides the AGC voltage corresponding to the detection level to the second AGC amplifier 56. Accordingly, the second AGC amplifier 56 performs AGC amplification.

According to the present invention as described above, it is possible to selectively receive satellite broadcast signals or terrestrial signals which are digital audio broadcasts.

According to the present invention as described above, it is possible to selectively receive the L-band (1450-1490MHz) satellite signal and the band III (170-240MHz) terrestrial signal through the digital audio broadcasting method, to the regional and environmental characteristics Therefore, the satellite or terrestrial signal is properly selected to listen to audio broadcasts.

The above description is only a description of specific embodiments of the present invention, and the present invention is not limited to these specific embodiments, and various changes and modifications of the configuration are possible from the above-described specific embodiments of the present invention. It will be apparent to those skilled in the art to which the present invention pertains.

Claims (4)

An RF splitter 10 for distributing a high frequency signal through the antenna; An L-band mixer stage 20 for lowering the frequency (1450-1490 MHz) of the L-band signal among the signals through the RF splitter 10; A bandIII RF AGC stage 30 for AGC amplifying a bandIII signal (170-240MHz) of the signals through the RF splitter 10 according to the provided AGC voltage; A switch circuit unit 40 for switching the output signal of the L-band mixer stage 20 and the output signal of the band III RF AGC stage 30; And And an IF circuit unit 50 for downgrading and amplifying the frequency of the signal through the switch circuit unit 40 and providing the AGC voltage corresponding to the signal level to the band III RF AGC stage 30. Audio broadcast tuner. The method of claim 1, wherein the L-band mixer stage 20 A first AGC amplifier 21 for AGC amplifying an input signal through the RF splitter 10; A band pass filter 22 through which the output signal of the first AGC amplifier 21 passes through the L band; A second AGC amplifier 23 for AGC amplifying the output signal of the band pass filter 22; An L-band frequency converter 24 for lowering the frequency of the output signal of the second AGC amplifier 23; An AGC detector 25 providing an AGC voltage corresponding to the level of the output signal of the frequency converter 24; And And an AGC buffer (26) for providing the AGC voltage by the AGC detector (25) as the bias voltages of the first and second AGC amplifiers (21, 23). The method of claim 1, wherein the band III RF AGC stage 30 is An AGC amplifier 31 for AGC amplifying the signal through the RF divider 10 at an amplification rate determined according to the bias voltage provided; And a voltage amplifier (32) for amplifying the AGC voltage input for AGC and providing it as a bias voltage of the AGC amplifier (31). According to claim 1, wherein the IF circuit section 50 A first AGC amplifier 51 for AGC amplifying the signal through the switch circuit unit 40; An IF frequency converter 52 for lowering the frequency of the output signal of the first AGC amplifier 51; A signal amplifier 53 for amplifying the output signal of the IF frequency converter 52; A first AGC detector 54 which detects a level of an output signal of the signal amplifier 53 and provides an AGC voltage corresponding to the detected level to the first AGC amplifier 51 and the band III RF AGC stage 30. ); A band pass filter 55 for passing the output signal of the signal amplifier 53 to a set band; A second AGC amplifier 56 for AGC amplifying the output signal of the band pass filter 55; And And a second AGC detector 57 which detects the level of the output signal of the second AGC amplifier 56 and provides the AGC voltage corresponding to the detection level to the second AGC amplifier 56. Digital Audio Broadcast Tuner.