KR20180090960A - Dmb and fm signal in-plant integrated-transmission system and dmb and fm signal selection amplifier - Google Patents

Abstract

The present invention relates to a DMB and FM signal in-plant integrated transmission system and a DMB and FM signal selection amplifier. According to an embodiment of the present invention, the DMB and FM signal in-plant integrated transmission system comprises: a head-end unit for receiving a plurality of external signals including a DMB signal and an FM signal through a plurality of antennas, processing the received signals, and synthesizing signals into a first high frequency synthesis signal including the processed DMB and FM signals to output the synthesized signal through a front-end transmission line; a signal selection amplification unit for receiving the first high frequency synthesis signal to selectively amplify the DMB signal and the FM signal, and synthesizing signals into a second high frequency synthesis signal to output the synthesized signal; an in-plant transmission line network including a transmission line for transmitting the second high frequency synthesis signal outputted from the signal selection amplification unit; and a plurality of low power repeaters cascade-connected on the transmission line of the in-plant transmission line network and wirelessly transmitting at least some signals included in the second high frequency synthesis signal with low power. In addition, a DMB and FM signal selection amplifier are disclosed.

Description

TECHNICAL FIELD [0001] The present invention relates to an integrated transmission system for a DMB and an FM signal, and a DMB and FM signal selection amplifier.

The present invention relates to a DMB and FM signal integrated transmission system and a DMB and FM signal selection amplifier.

An integrated transmission system in which an antenna receives a signal transmitted from a broadcasting station or a satellite in a large complex such as an apartment complex or a building, and transmits the amplified signal from the headend to the home of the coaxial cable network is implemented.

On the other hand, as the activities of people are increasing in the radio wave blocking area or the radio wave shading area such as a tunnel, an underground shopping street, a subway or an underground parking lot, the necessity of reception of broadcasting or FM signal is increasing. Accordingly, there is a demand for an on-premise integrated transmission system not only in a large-scale building, but also in such a radio-shaded area for intra-city transmission such as DMB broadcasting or FM signal.

In-house transmission systems such as DMB broadcasting and FM signals are constructed by receiving and processing external RF signals such as DMB signals and FM signals from the outside at the head end and installing a plurality of repeaters on the transmission lines.

Korean Registered Patent No. 10-0740588 (registered on July 11, 2007) Korean Patent Publication No. 10-2011-0114185 (published on October 19, 2011) Korean Patent Laid-Open Publication No. 10-2012-0110515 (published on October 10, 2012) Korean Patent Publication No. 10-2016-0005690 (published on January 15, 2016)

A large number of repeaters are installed on a transmission line in a large collection building such as a tunnel, an underground parking lot, an underground shopping mall, a subway, or a large complex such as an apartment complex or a building to transmit a plurality of RF signals such as a DMB signal and an FM signal. So that signal processing according to the characteristics of each signal is performed on the repeater.

If the signal processing according to the characteristic of each signal is performed in the repeater in the transmission network where a plurality of repeaters are required on the transmission line, the cost of the repeater is increased and the cost of implementing the transmission network system is increased.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide an integrated transmission system for DMB and FM signal in which a selective signal processing is performed on a required signal at a front end of a transmission line provided with a plurality of repeaters, The DMB and FM signal selection amplifiers which perform selective signal processing on necessary signals at the front end of the DMB and FM signal are proposed.

According to one aspect of the present invention, there is provided an apparatus for receiving a plurality of external signals including a DMB signal and an FM signal through a plurality of antennas, A head end unit which synthesizes the first high frequency composite signal and outputs the combined signal through a front end transmission line; A signal selection and amplification unit that receives the first high frequency composite signal, selectively amplifies the DMB signal and the FM signal, synthesizes the combined signal into a second high frequency composite signal, and outputs the synthesized signal; An internal transmission line network including a transmission line for transmitting a second high frequency composite signal output from the signal selection amplifying unit; And a plurality of small-power repeaters cascade-connected on a transmission line of a local transmission line network and transmitting at least a part of signals included in the second high-frequency composite signal by small-power wireless transmission.

At this time, in one example, the signal selection amplifying unit includes: a first amplifying unit amplifying the received first high frequency combining signal; A signal distributing unit for distributing the amplified signal from the first amplifying unit; A DMB selection and amplification unit for selecting and amplifying a DMB signal from one branch signal distributed from the signal distribution unit; An FM selection amplifier for selecting and amplifying an FM signal from another branch signal distributed from the signal distributor; A signal synthesizer for receiving a signal from the DMB selection amplifier and the FM selection amplifier and synthesizing the signal; And a second amplifying unit for amplifying and outputting the second high frequency synthesized signal synthesized by the signal synthesizing unit.

Further, at this time, in one example, the signal selection amplification unit further includes a signal level control unit for controlling the amplification degree in the first amplification unit to detect the level of the signal amplified in the second amplification unit and adjust the level of the amplified signal to the set signal level do.

In another example, the first amplification unit includes a first low-pass filter for filtering the received first high-frequency composite signal and a first amplifier for amplifying the filtered signal from the first low-pass filter, A DMB bandpass filter for band-filtering one branch signal to select a DMB signal, and a DMB signal amplifier for amplifying a signal selectively filtered by the DMB bandpass filter and providing the signal to the signal combiner, An FM bandpass filter for band-filtering a branch signal to select an FM signal, and an FM signal amplifier for amplifying a signal selectively filtered by an FM bandpass filter and providing the amplified signal to a signal synthesizer, A second amplifier for amplifying a second high frequency synthesized signal, and a second low pass filter for filtering and outputting a signal amplified by the second amplifier, Levels that the controller may control the amplification degree of the first amplifier in order to adjust the signal level that is set by detecting the level of a signal amplified by the second amplifier.

In addition, in one example, the intra-city transmission line network includes an integrated distributor for receiving a second high-frequency composite signal from the signal selection amplification unit and distributing the same, and a plurality of transmission lines connected to the integrated distributor, Small output relays are cascaded on at least one transmission line.

In another example, the head end unit includes an antenna unit including a DMB receiving antenna for receiving a DMB signal and an FM receiving antenna for receiving an FM signal, an antenna unit for receiving a plurality of external signals, a DMB signal processing unit for processing a received DMB signal A signal processing unit including a processor and an FM signal processor for signal processing an FM signal, and a signal synthesizing unit for synthesizing the signal processed signals in the signal processing unit into a first high frequency synthesized signal and outputting the combined signal, wherein the DMB signal processor comprises: a DMB A DMB low pass filter for filtering a DMB signal received from a receive antenna; A receiving DMB amplifier for amplifying the DMB signal filtered by the DMB low pass filter; A fixed channel band filter for filtering a signal amplified by the receiving DMB amplifier to pass a set channel signal; An intermediate DMB amplifier for amplifying the filtered signal in the fixed channel band filter; An output DMB amplifier for receiving the amplified signal from the intermediate DMB amplifier and for amplifying and outputting the amplified signal; A signal detector for detecting an output signal of the intermediate DMB amplifier; And an automatic gain controller for controlling the amplification gain of the reception DMB amplifier according to the detection result detected by the signal detector.

In another example, the head end unit may include an antenna unit including a DMB receiving antenna for receiving a DMB signal and an FM receiving antenna for receiving an FM signal, an antenna unit for receiving a plurality of external signals, a DMB A signal processing unit including a signal processor and an FM signal processor for signal processing the FM signal, and a signal synthesizing unit for synthesizing the signal processed signals in the signal processing unit into a first high frequency synthesized signal and outputting the synthesized signal, the DMB signal processor comprising: A first DMB low pass filter for filtering a DMB signal received from a DMB receive antenna; A local oscillator for outputting a local oscillation signal; A first mixer for mixing the filtered signal from the first DMB low pass filter and the output signal of the local oscillator; An intermediate frequency band filter for filtering the signal output to the first mixer and passing the set intermediate frequency signal; An intermediate frequency amplifier for amplifying the filtered signal in the intermediate frequency band filter; A second mixer for mixing the amplified signal from the intermediate frequency amplifier and the output signal of the local oscillator; A second DMB low-pass filter for filtering a signal output from the second mixer to pass a low-band frequency; And an output DMB amplifier for receiving a signal filtered by the second DMB low-pass filter and outputting the amplified signal, and the local oscillator outputs a local oscillation signal according to the frequency set according to the control.

Also, in one example, the small output relays are cascaded according to the set intervals, and each of the small output relays includes: a transmission loss compensation circuit part connected in series on the transmission line and compensating for transmission loss on the transmission line; An RF amplifier for receiving a signal from the transmission loss compensation circuit and amplifying the signal and outputting the amplified signal for a small output; And a radio transmission unit for receiving a signal from the RF amplifier unit and wirelessly transmitting the DMB signal and the FM signal, respectively, wherein the transmission loss compensation circuit unit receives the signal from the input terminal connected to the transmission line and amplifies A low noise amplifier, a signal distributor connected to the low noise amplifier, a signal distributor for dividing the signal, and an attenuator for attenuating and outputting a predetermined level of the divided output from the signal distributor, Can receive.

In another example, the small output repeaters are cascaded according to the set intervals, and each of the small output repeaters is connected in parallel on the transmission line, and includes an operational amplifier having a high input impedance and a low output impedance, an emitter follower, A high impedance circuit part including any one of the column-type and column-type followers and minimizing an insertion loss due to parallel insertion on a transmission line; An RF amplifier for receiving an output signal from the high impedance circuit and amplifying the output signal and outputting the amplified signal for a small output; A variable attenuator which receives the output of the high impedance circuit portion and inputs the attenuated signal to the RF amplifying portion; A signal detecting unit for detecting a signal at an output terminal of the RF amplifying unit; An automatic gain controller for adjusting the attenuation of the variable attenuator according to the detection result of the signal detector and controlling the output according to the gain set by the RF amplifier; And a radio transmitter for receiving a signal from the RF amplifier and wirelessly transmitting the DMB signal and the FM signal, respectively.

In one example, the radio transmitter receives a DMB signal and an FM signal from a diplexer filter and a diplexer filter, which are connected to an output terminal of the RF amplifier and receive a small output signal and separately output the DMB signal and the FM signal, And the antenna end includes a DMB antenna for wirelessly transmitting a DMB signal and an FM antenna for wirelessly transmitting an FM signal, or a dual band antenna including a diplexer filter and an antenna stage, Of the transmission antenna.

According to another aspect of the present invention, there is provided a method for processing a plurality of external reception signals including a DMB signal and an FM signal, A first amplifier for receiving and amplifying a synthesized signal transmitted from a head end of a DMB and FM signal selection amplifier for outputting a high frequency synthesized signal so that small output repeaters are transmitted through a cascade-connected transmission line; A signal distributing unit for distributing the amplified signal from the first amplifying unit; A DMB selection and amplification unit for selecting and amplifying a DMB signal from one branch signal distributed from the signal distribution unit; An FM selection amplifier for selecting and amplifying an FM signal from another branch signal distributed from the signal distributor; A signal synthesizer for receiving the amplified signal from the DMB selection amplifier and the FM selection amplifier and re-synthesizing the signal into a high frequency synthesized signal; A second amplifying unit for amplifying and outputting the synthesized high frequency synthesized signal in the signal synthesizing unit; And a signal level control unit for controlling the amplification degree of the first amplification unit to detect the level of the signal amplified by the second amplification unit and to adjust the level of the signal amplified by the second amplification unit to the set signal level .

In one example, the first amplification unit includes a first low-pass filter for receiving and filtering the composite signal and a first amplifier for amplifying the filtered signal from the first low-pass filter, And a DMB signal amplifier for amplifying a signal selectively filtered by the DMB bandpass filter and providing the signal to the signal combining unit, wherein the FM selection amplifying unit amplifies the other branched signal by band filtering An FM band-pass filter for selecting an FM signal, and an FM signal amplifier for amplifying a signal selectively filtered by the FM band-pass filter and providing the amplified signal to a signal synthesizer, wherein the second amplifier amplifies the high- And a second low-pass filter for filtering the signal amplified by the second amplifier, wherein the signal level control unit includes a second amplifier By detecting the level of the amplified signal from controls the amplification degree of the first amplifier to control to set the signal level.

According to one embodiment of the present invention, a selective signal processing for necessary signals is performed at a front end of a transmission line provided with a plurality of repeaters, thereby realizing a simple and economical implementation of an integrated transmission system of DMB signals and FM signals .

It is apparent that various effects not directly referred to in accordance with various embodiments of the present invention can be derived by those of ordinary skill in the art from the various configurations according to the embodiments of the present invention.

1 is a block diagram schematically illustrating an integrated transmission system in a DMB and FM signaling system according to an embodiment of the present invention.
2 is a circuit block diagram schematically showing an integrated transmission system in a DMB and FM signaling system according to another embodiment of the present invention.
3 is a block diagram schematically illustrating an integrated transmission system in a DMB and FM signaling system according to another embodiment of the present invention.
4 is a circuit block diagram schematically showing an integrated transmission system in a DMB and FM signaling system according to another embodiment of the present invention.
5 is a circuit block diagram schematically showing an integrated transmission system in a DMB and FM signaling system according to another embodiment of the present invention.
6 is a circuit block diagram schematically showing a small output repeater of the DMB and FM signal integrated transmission system according to another embodiment of the present invention.
7 is a circuit block diagram schematically showing a small output repeater of the DMB and FM signal integrated transmission system according to another embodiment of the present invention.
8 is a circuit block diagram schematically showing a DMB and FM signal selection amplifier according to another embodiment of the present invention.
9 is a circuit block diagram schematically showing a DMB and FM signal selection amplifier according to another embodiment of the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a block diagram showing the configuration of a first embodiment of the present invention; Fig. In the description, the same reference numerals denote the same components, and a detailed description may be omitted for the sake of understanding of the present invention to those skilled in the art.

As used herein, unless an element is described as being connected, coupled, or arranged with another element, it is understood that there is no need for any other form of " direct connection, But may also be in the form of being connected, bonded or disposed by intervening components. Also, where described in terms of direction and / or position in the present description, such terms are relative concepts as determined from the bases, wherein the bases may be described directly or not, Can be fully understood from the relationship between the configuration and the related configuration.

It should be noted that, although a singular expression is used in this specification, it can be used as a concept representing a plurality of constitutions as long as it is contrary to the concept of the invention or is not interpreted as being obviously different or contradictory. It is to be understood that the phrases "including", "having", "having", "comprising", etc. in this specification are intended to be additionally or interchangeable with one or more other elements or combinations thereof.

[ DMB  And FM  Integrated signal transmission system]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS First, an integrated transmission system of a DMB and an FM signal system according to one embodiment of the present invention will be described with reference to the drawings. In the drawings, the same reference numerals denote the same components, and reference numerals which are not shown in the drawings denote the same components as those in the other drawings.

FIG. 1 is a block diagram schematically showing an integrated transmission system in a DMB and FM signaling system according to an embodiment of the present invention. FIG. 2 is a block diagram schematically illustrating an integrated transmission system of a DMB and an FM signaling system according to another embodiment of the present invention. FIG. 3 is a block diagram schematically showing an integrated transmission system for a DMB and an FM signaling system according to another embodiment of the present invention, and FIG. 4 is a block diagram schematically showing a circuit block diagram according to another embodiment of the present invention. FIG. 5 is a circuit block diagram schematically illustrating an integrated transmission system in a DMB and FM signaling system according to another embodiment of the present invention. FIG. 5 is a circuit block diagram schematically showing an integrated transmission system in a DMB and FM signaling system.

1 to 5, the DMB and FM signal integrated transmission system according to one example includes a head end unit 10, a signal selection and amplification unit 30, a local transmission line network 50, and a plurality of small output relays 70).

At this time, the head end unit 10 receives a plurality of external signals including the DMB signal and the FM signal through the plurality of antennas 11, processes the signal, processes the first high-frequency composite signal including the DMB signal and the FM signal, And output through the front-end transmission line. The signal selection and amplification unit 30 receives the first high frequency composite signal from the head end unit 10, selectively amplifies the DMB signal and the FM signal, synthesizes the combined signal into a second high frequency composite signal, and outputs the combined signal. The intra-area transmission line network 50 includes a transmission line 1 for transmitting a second high-frequency composite signal output from the signal selection amplifying unit. The plurality of small-power repeaters 70 are cascade-connected on the transmission line 1 of the intra-area transmission line network 50 and wirelessly transmit at least some signals included in the second high-frequency composite signal.

Each configuration will be described in more detail with reference to the drawings. The head end unit 10, the signal selection amplifying unit 30, the full-path line network in the premises, and the small-power repeater 70 in this order.

Head end  unit

1 to 5, the head end unit 10 receives and processes a plurality of external signals including a DMB signal and an FM signal through a plurality of antennas 11. In addition, the head end unit 10 combines the signal-processed DMB signal and the FM signal into a first high-frequency composite signal, and outputs it through a front end transmission line.

4 and / or 5, in one example, the head end unit 10 may include an antenna unit 11, a signal processing unit 13, and a signal synthesis unit 15. [

At this time, the antenna unit 11 includes a DMB receiving antenna 11a for receiving a DMB signal and an FM receiving antenna 11b for receiving an FM signal, and receives a plurality of external signals. For example, the antenna unit 11 may further include an antenna such as a satellite TV (MATV) receiving antenna that receives a TV signal for public viewing such as terrestrial broadcasting in addition to the DMB receiving antenna 11a and the FM receiving antenna 11b .

Next, the signal processing unit 13 includes a DMB signal processor 13a for processing the DMB signal received from the antenna unit 11 and an FM signal processor 13b for signal processing of the FM signal. For example, when the antenna unit 11 includes a MATV reception antenna, the signal processing unit 13 may further include a MATV signal processor for amplifying and processing the MATV signal at the rear end of the MATV reception antenna. The DMB signal processor 13a is connected to the rear end of the DMB receiving antenna 11a. The FM signal processor 13b is connected to the rear end of the FM reception antenna 11b.

Next, the signal synthesizing unit 15 synthesizes the signal-processed signals in the signal processing unit 13 into a first high-frequency synthesized signal and outputs it. At this time, the first high-frequency composite signal including the DMB signal and the FM signal is provided to the signal selection and amplification unit 30 through the front end transmission line. For example, the front end transmission line is a coaxial cable.

Referring to FIG. 4, the DMB signal processor 13a included in the signal processing unit 13 will be described in detail with reference to an example. At this time, the DMB signal processor 13a includes a DMB low pass filter 131a, a reception DMB amplifier 132a, a fixed channel band filter 133a, an intermediate DMB amplifier 134a, an output DMB amplifier 135a, a signal detector 136a And an automatic gain controller 137a. The DMB low pass filter 131a filters the DMB signal received from the DMB receiving antenna 11a. At this time, the DMB low-pass filter 131a passes the DMB signal frequency band and cuts off the high frequency signal and filters the DMB signal.

Next, the reception DMB amplifier 132a amplifies the DMB signal filtered by the DMB low-pass filter 131a. For example, the receive DMB amplifier 132a may be a low noise amplifier.

The fixed channel band filter 133a filters the signal amplified by the reception DMB amplifier 132a and passes the set channel signal. Since the fixed channel band filter 133a is used, the signal for the fixed channel is filtered, and the signal processing performance can be improved. For example, the fixed channel bandpass filter 133a may be a SAW filter.

Next, the intermediate DMB amplifier 134a amplifies the filtered signal in the fixed channel band filter 133a.

Subsequently, the output DMB amplifier 135a receives the amplified signal from the intermediate DMB amplifier 134a, amplifies the amplified signal, and outputs the amplified signal. For example, the signal output from the output DMB amplifier 135a may be input to the signal synthesis unit 15 described above and combined with the FM signal, for example, as a first high-frequency composite signal. Although not shown, a low-pass filter (LPF) may be added to the output stage of the output DMB amplifier 135a.

Next, the signal detector 136a detects the output signal of the intermediate DMB amplifier 134a. Then, the automatic gain controller 137a controls the amplification gain of the reception DMB amplifier 132a according to the detection result detected by the signal detector 136a.

In this case, according to the present embodiment, the DMB signal processor 13a does not include a mixer, and the DMB signal processor 13a processes the DMB signal for the fixed channel to reduce the noise characteristic to about 2dB or less, To less than about 80dB and to reduce power consumption to less than about 2W.

Next, the DMB signal processor 13a in another example will be described with reference to FIG. At this time, the DMB signal processor 13a includes a first DMB low-pass filter 231a, a local oscillator 232a, a first mixer 233a, an intermediate frequency band filter 234a, an intermediate frequency amplifier 235a, A second DMB low pass filter 237a, and an output DMB amplifier 238a. The first DMB low pass filter 231a filters the DMB signal received from the DMB receiving antenna 11a. At this time, the first DMB low-pass filter 231a passes the DMB signal frequency band and cuts off the frequency signal higher than the DMB signal frequency and filters the signal. Although not shown, a low noise amplifier may be added to the downstream of the first DMB low-pass filter 231a to amplify the filtered signal and provide the amplified signal to the first mixer 233a.

The local oscillator 232a outputs a local oscillation signal. At this time, the local oscillator 232a outputs a local oscillation signal according to the frequency set according to the control. That is, for example, under the control of the CPU processor, the frequency of the local oscillation signal output from the local oscillator 232a is determined, and the present DMB signal processor 13a can perform signal processing on two or more channel signals.

Next, the first mixer 233a mixes the filtered signal from the first DMB low-pass filter 231a with the output signal of the local oscillator 232a. An intermediate frequency signal according to the difference between the local oscillation signal frequency and the filtered DMB signal frequency is generated by mixing the local oscillation signal and the signal filtered by the first DMB low pass filter 231a by the first mixer 233a.

The intermediate frequency band filter 234a filters the signal output to the first mixer 233a and passes the set intermediate frequency signal. For example, the intermediate frequency band filter 234a may be a band pass filter (BPF).

Next, the intermediate frequency amplifier 235a amplifies the filtered signal in the intermediate frequency band filter 234a.

Subsequently, the second mixer 236a mixes the signal amplified by the intermediate frequency amplifier 235a and the output signal of the local oscillator 232a. At this time, the output signal of the local oscillator 232a is the same frequency signal as the local oscillation signal provided to the first mixer 233a. Accordingly, a mixed signal including a channel frequency signal to be obtained by the frequency difference between the frequency of the local oscillation signal and the amplified intermediate frequency can be obtained. At this time, the second DMB low-pass filter 237a filters the signal output from the second mixer 236a to pass the low-band frequency. Accordingly, the channel frequency signal to be obtained by the DMB signal processor 13a can be filtered and passed.

Next, the output DMB amplifier 238a receives the filtered signal from the second DMB low-pass filter 237a, amplifies it, and outputs the amplified signal. For example, the signal output from the output DMB amplifier 238a may be input to the signal synthesis unit 15 described above and combined with the FM signal, for example, as a first high-frequency composite signal. Although not shown, a low-pass filter (LPF) may be added to the output stage of the output DMB amplifier 238a.

Signal selection amplifying unit

1 to 5, the signal selection and amplification unit 30 receives the first high-frequency composite signal from the head-end unit 10, selectively amplifies the DMB signal and the FM signal, synthesizes the combined signal into a second high- . For example, the signal selection and amplification unit 30 inputs a first high frequency composite signal including a DMB signal and an FM signal through a signal synthesis unit 15 of the head end unit 10, that is, a synthesizer to a front transmission line Receive.

1 to 5, in one example, the signal selection and amplification unit 30 includes a first amplification unit 31, a signal distribution unit 32, a DMB selection amplification unit 33, A signal combining unit 35, and a second amplifying unit 36. The signal combining unit 35 and the second amplifying unit 36 may be the same as those shown in FIG. The signal selection amplifier 30 shown in Figs. 8 to 9 may be a signal selection amplifying unit, and therefore, it will be described with reference to Figs. 8 to 9. Fig.

2, 3, 4, 5, 8, and / or 9, in another example, the signal selection amplifying unit may further include a signal level control unit 37. [ Each configuration will be described with reference to the drawings.

The first amplifying unit 31 amplifies the first high frequency composite signal received from the head end unit 10 through the front end transmission line. For example, referring to FIG. 9, in one example, the first amplifying unit 31 may include a first low-pass filter 31a and a first amplifier 31b. The first low-pass filter 31a filters the first high-frequency composite signal received from the head end unit 10 through the front-end transmission line, and the first amplifier 31b filters the first high- Amplifies the signal.

Next, the signal distribution unit 32 distributes the amplified signal from the first amplification unit 31. For example, the signal distributor 32 may be a two-distributor. The DMB selection amplifying unit 33 selects and amplifies the DMB signal from one branch signal distributed from the signal distributing unit 32. Further, the FM selection amplifier 34 selects and amplifies the FM signal from the other branch signal distributed from the signal distributor 32.

2, 4, 5, 8 and / or 9, in one example, the DMB selection amplifying unit 33 may include a DMB bandpass filter 33a and a DMB signal amplifier 33b . The DMB bandpass filter 33a band-filters one branch signal distributed from the signal distributor 32 to select a DMB signal and the DMB signal amplifier 33b filters the signal filtered and selected by the DMB bandpass filter 33a And provides the amplified signal to the signal combining unit 35. Subsequently, the FM selection amplifier 34 may include an FM bandpass filter 34a and an FM signal amplifier 34b. At this time, the FM bandpass filter 34a band-filters another branch signal distributed from the signal distributor 32 to select the FM signal, and the FM signal amplifier 34b selects the FM bandpass filter 34a And supplies the amplified filtered signal to the signal combining unit 35. [

Referring back to FIGS. 2, 3, 4, 5, 8 and / or 9, the signal combining unit 35 receives and synthesizes a signal from the DMB selection amplifying unit 33 and the FM selection amplifying unit 34. For example, the signal synthesis unit 35 may be composed of a synthesizer (combiner). A signal synthesized by the signal synthesizing unit 35 with the second high-frequency synthesized signal is input to the second amplifying unit 36. The second amplifying unit 36 amplifies and outputs the second high-frequency synthesized signal synthesized by the signal synthesizing unit 35. Referring to FIG. 9, in one example, the second amplifying unit 36 may include a second amplifier 36b and a second low-pass filter 36a. The second amplifier 36b amplifies the second high-frequency composite signal input from the signal combiner 35 and the second low-pass filter 36a filters and amplifies the signal amplified by the second amplifier 36b.

Next, referring to Figs. 2, 3, 4, 5, 8 and / or 9, in one example, the signal selection amplification unit may further include a signal level control unit 37. Fig. At this time, the signal level control unit 37 controls the amplification degree in the first amplification unit 31 to detect the level of the signal amplified by the second amplification unit 36 and adjust the level of the amplified signal to the set signal level. 9, in one example, the signal level controller 37 detects the level of the signal amplified by the second amplifier 36b and adjusts the level of the signal amplified by the first amplifier 31b The amplification degree can be controlled.

campus Transmission line network

The transmission line network 50 includes a transmission line 1 for transmitting a second high-frequency composite signal output from the signal-selection amplifying unit 30. For example, the transmission line 1 of the transmission line network 50 may be a coaxial cable. A plurality of small output repeaters 70, which will be described later, are cascade-connected on the transmission line 1.

3, 4 and / or 5, in one example, the on-premise transmission line network 50 includes an integrated distributor 51 and a plurality of transmission lines 1. The integrated distributor 51 receives the second high-frequency composite signal from the signal selection and amplification unit 30 and distributes it to a plurality of transmission lines 1 connected thereto. At this time, the small output relays 70 are cascade-connected on at least one transmission line 1 among the plurality of transmission lines 1. [ Although not shown, the integrated distributor 51 of FIG. 3 may also be included in the on-premises transmission line network 50 of FIGS. Alternatively, the integrated distributor 51 may be omitted in FIGS. 3, 4 and 5 and implemented as a local transmission line network 50 without the integrated distributor 51 as shown in FIGS. 1 and 2. FIG.

Small power repeaters

Next, a plurality of small power relays 70 will be described. 1 to 5, a plurality of small power relays 70 are cascade-connected on a transmission line 1 of an on-premise transmission line network 50 and wirelessly transmit at least some signals included in a second high-frequency composite signal.

6 is a circuit block diagram schematically showing a small output repeater 70 of an integrated transmission system in a DMB and FM signaling system according to another embodiment of the present invention. And a small-power repeater 70 of the integrated signal transmission system in the FM signaling system.

The small output relays 70 will be described in detail with reference to FIGS. 6 and / or 7. FIG. The small power relays 70 are cascaded in accordance with the interval set on the transmission line 1. [

6, in one example, each of the small output relays 70 may include a transmission loss compensation circuit 71a, an RF amplifier 73, and a radio transmitter 75. The transmission loss compensation circuit portion 71a is connected in series on the transmission line 1 and compensates for the transmission loss of the transmission line 1 on the transmission line. 7, in one example, the transmission loss compensation circuit portion 71a may include a low noise amplifier 711a, a signal distributor 712a, and an attenuator 713a. The low noise amplifier 711a receives a signal from an input terminal connected to the transmission line 1 and amplifies the signal to have a gain greater than the transmission loss. The signal distributor 712a is connected to the low noise amplifier 711a to distribute the signal. For example, the signal distributor 712a is a two-way distributor. The attenuator 713a receives one output of the divided signal from the signal distributor 712a and outputs the attenuated signal at a predetermined level. For example, the attenuator 713a is a fixed attenuator and may be, for example, a pi -type or T-type resistance attenuator. For example, the transmission loss compensation circuit 71a can compensate the transmission loss equal to or higher than the transmission loss value and output the cascade connection to the subsequent small output repeater 70. [

Subsequently, the RF amplifier 73 receives the signal from the transmission loss compensation circuit 71a, amplifies it, and outputs it as a signal for small output. The RF amplifier 73 receives the different outputs distributed to the signal distributor 712a.

The radio transmitter 75 receives a signal from the RF amplifier 73 and wirelessly transmits the DMB signal and the FM signal, respectively.

At this time, though not shown, in one example, the radio transmitter 75 includes a diplexer filter and an antenna stage. The diplexer filter is connected to the output terminal of the RF amplifier 73, receives the small output signal, and separates the output signal into a DMB signal and an FM signal. The antenna end receives the DMB signal and FM signal from the diplexer filter and wirelessly transmits it to the outside. At this time, although not shown, the antenna end may be formed of a DMB antenna for wirelessly transmitting a DMB signal and an FM antenna for wirelessly transmitting an FM signal. Alternatively, the antenna stage may be a transmission antenna of a dual band antenna including a diplexer filter and an antenna stage.

For example, although not shown, the small power repeater 70 according to one example may further include a trimming circuit. At this time, the trimming circuit unit may detect the signal at the output terminal of the RF amplifier unit 73, perform trimming control according to the detection result, and output according to the gain set by the RF amplifier unit 73 may be performed.

7, each of the small output relays 70 includes a high impedance circuit portion 71b, an RF amplifying portion 73, a variable attenuator 72, a signal detecting portion 74, (76) and a wireless transmission unit (75).

Specifically, the high impedance circuit portion 71b is connected in parallel on the transmission line 1. [ At this time, the high impedance circuit portion 71b includes any one of an OP amplifier, an emitter follower, and a cathode follower having a high input impedance and a low output impedance. The high impedance circuit portion 71b minimizes the insertion loss due to the parallel insertion on the transmission line 1.

Next, the RF amplifier 73 receives the output signal from the high impedance circuit portion 71b, amplifies it, and outputs it for the small output.

The variable attenuator 72 receives the output of the high impedance circuit portion 71b, attenuates it, and inputs it to the RF amplifier 73. The attenuation amount of the variable attenuator constituting the variable attenuator 72 is controlled by the automatic gain control unit 76, that is, the automatic gain controller (AGC).

Next, the signal detecting section 74 detects the signal at the output terminal of the RF amplifier section 73.

The automatic gain control unit 76 adjusts the attenuation amount of the variable attenuation unit 72 according to the detection result of the signal detection unit 74 and controls the RF amplification unit 73 to output according to the set gain.

The radio transmitter 75 receives a signal from the RF amplifier 73 and wirelessly transmits the DMB signal and the FM signal, respectively.

At this time, though not shown, in one example, the radio transmitter 75 includes a diplexer filter and an antenna stage. The diplexer filter is connected to the output terminal of the RF amplifier 73, receives the small output signal, and separates the output signal into a DMB signal and an FM signal. The antenna end receives the DMB signal and FM signal from the diplexer filter and wirelessly transmits it to the outside. At this time, although not shown, the antenna end may be formed of a DMB antenna for wirelessly transmitting a DMB signal and an FM antenna for wirelessly transmitting an FM signal. Alternatively, the antenna stage may be a transmission antenna of a dual band antenna including a diplexer filter and an antenna stage.

[ DMB  And FM  Signal selection amplifier]

Next, a DMB and FM signal selection amplifier 30 according to another embodiment of the present invention will be described with reference to the drawings. Since the DMB and FM signal selection amplifier 30 can be used in the DMB and FM signal integrated transmission system, the DMB and FM signal selection and amplification unit 30 among the embodiments of the DMB and FM signal integrated transmission system described above, 1, 2, 3, 4 and 5, and redundant description may be omitted.

FIG. 8 is a circuit block diagram schematically showing a DMB and FM signal selection amplifier according to another embodiment of the present invention. FIG. 9 schematically shows a DMB and FM signal selection amplifier according to another embodiment of the present invention. Fig.

1, 2, 3, 4 and 5, the DMB and FM signal selection amplifier 30 according to one example receives synthetic signal from the head end unit, that is, the head end unit 10, processes it, Frequency synthesized signal so as to be transmitted through the antenna 1. That is, the DMB and FM signal selection amplifier 30 processes a plurality of external reception signals including a DMB signal and an FM signal, processes the synthesized signals from the head end, processes them, and a plurality of small-power repeaters 70 performs cascade- And outputs a high-frequency composite signal to be transmitted through the coupled transmission line (1).

8 to 9, the DMB and FM signal selection amplifiers according to one example include a first amplification unit 31, a signal distribution unit 32, a DMB selection amplification unit 33, an FM selection and amplification unit 34, a signal combining unit 35, and a second amplifying unit 36. 8 to 9, in another example, the signal selection amplifier 30 may further include a signal level control unit 37. [ Each configuration will be described with reference to the drawings.

The first amplifying unit 31 receives and amplifies the composite signal transmitted from the head end unit, that is, the head end unit 10. For example, referring to FIG. 9, in one example, the first amplifying unit 31 may include a first low-pass filter 31a and a first amplifier 31b. The first low-pass filter 31a filters the synthesized signal from the head end, and the first amplifier 31b amplifies the signal filtered by the first low-pass filter 31a.

Next, the signal distribution unit 32 distributes the amplified signal from the first amplification unit 31. For example, the signal distributor 32 may be a two-distributor.

Next, the DMB selection amplifying unit 33 selects and amplifies the DMB signal from one branch signal distributed from the signal distributing unit 32. Further, the FM selection amplifier 34 selects and amplifies the FM signal from the other branch signal distributed from the signal distributor 32.

Referring to FIG. 9, in one example, the DMB selection amplifier 33 may include a DMB bandpass filter 33a and a DMB signal amplifier 33b. The DMB bandpass filter 33a band-filters one branch signal distributed from the signal distributor 32 to select a DMB signal and the DMB signal amplifier 33b filters the signal filtered and selected by the DMB bandpass filter 33a And provides the amplified signal to the signal combining unit 35. The DMB band pass filter 33a filters the DMB band signal. Subsequently, the FM selection amplifier 34 may include an FM bandpass filter 34a and an FM signal amplifier 34b. At this time, the FM bandpass filter 34a band-filters another branch signal distributed from the signal distributor 32 to select the FM signal, and the FM signal amplifier 34b selects the FM bandpass filter 34a And supplies the amplified filtered signal to the signal combining unit 35. [

Referring back to FIGS. 8 to 9, the signal combining unit 35 receives a signal from the DMB selection amplifying unit 33 and the FM selection amplifying unit 34 and re-synthesizes the signal into a high-frequency synthesized signal. The signal synthesized by the signal synthesizing unit 35 into the high-frequency synthesized signal is input to the second amplifying unit 36. The signal combining unit 35 is made up of a combiner.

The second amplifying unit 36 amplifies the high-frequency synthesized signal re-synthesized by the signal synthesizing unit 35 and outputs it. Referring to FIG. 9, in one example, the second amplifying unit 36 may include a second amplifier 36b and a second low-pass filter 36a. The second amplifier 36b amplifies the high-frequency composite signal input from the signal combiner 35 and the second low-pass filter 36a filters and amplifies the signal amplified by the second amplifier 36b.

Next, referring to FIGS. 8 to 9, in one example, the signal selection amplifier 30 may further include a signal level control unit 37. FIG. At this time, the signal level control unit 37 controls the amplification degree in the first amplification unit 31 to detect the level of the signal amplified by the second amplification unit 36 and adjust the level of the amplified signal to the set signal level. 9, in one example, the signal level controller 37 detects the level of the signal amplified by the second amplifier 36b and adjusts the level of the signal amplified by the first amplifier 31b The amplification degree can be controlled.

The foregoing embodiments and accompanying drawings are not intended to limit the scope of the present invention but to illustrate the present invention in order to facilitate understanding of the present invention by those skilled in the art. Embodiments in accordance with various combinations of the above-described configurations can also be implemented by those skilled in the art from the foregoing detailed description. Accordingly, various embodiments of the present invention may be embodied in various forms without departing from the essential characteristics thereof, and the scope of the present invention should be construed in accordance with the invention as set forth in the appended claims. Alternatives, and equivalents by those skilled in the art.

1: transmission line 10: head end unit
11: antenna unit 13: signal processing unit
15: Signal synthesis unit 30: Signal selection amplification unit or signal selection amplifier
31: first amplifying unit 31a: first low-pass filter
31b: first amplifier 32: signal distributor
33: DMB selection amplifying unit 33a: DMB band pass filter
33b: DMB signal amplifier 34: FM selection amplifier section
34a: FM bandpass filter 34b: FM signal amplifier
35: Signal synthesizer 36: Second amplifier
36a: second low-pass filter 36b: second amplifier
37: Signal level control section 51: Integrated distributor
53: transmission line 70: small output repeater
71a: transmission loss compensation circuit part 71b: high impedance circuit part
73: RF amplification unit 75: radio transmission unit
72: variable attenuator 74: signal detector
76: Automatic gain control section

Claims (13)

Synthesizing a plurality of external signals including a DMB signal and an FM signal through a plurality of antennas and synthesizing the signals into a first high frequency composite signal including the DMB signal and the FM signal processed and outputting through a front transmission line, End unit;
A signal selection and amplification unit that receives the first high frequency composite signal, selectively amplifies the DMB signal and the FM signal, synthesizes the combined signal into a second high frequency composite signal, and outputs the second high frequency composite signal;
An internal transmission line network including a transmission line for transmitting the second high-frequency composite signal output from the signal selection and amplification unit; And
And a plurality of small power repeaters cascade-connected on a transmission line of the intra-city transmission line network and wirelessly transmitting at least some signals included in the second high-frequency composite signal.
In claim 1,
The signal selection amplifying unit comprises:
A first amplifying unit amplifying the received first high frequency composite signal;
A signal distributor for distributing the amplified signal from the first amplifying unit;
A DMB selecting and amplifying unit for selecting and amplifying the DMB signal from one branch signal distributed in the signal distributor;
An FM selection amplifier for selecting and amplifying the FM signal from another branch signal distributed from the signal distributor;
A signal synthesizer for receiving a signal from the DMB selection amplifier and the FM selection amplifier and synthesizing the signal; And
And a second amplifying unit for amplifying and outputting the second high frequency synthesized signal synthesized by the signal synthesizing unit.
In claim 2,
Wherein the signal selection and amplification unit further comprises a signal level control unit for controlling the amplification degree of the first amplification unit to adjust the level of the signal amplified by the second amplification unit to a predetermined signal level, And FM signal integrated transmission system in the premises.
In claim 3,
Wherein the first amplifying unit includes a first low-pass filter for filtering the received first high-frequency composite signal and a first amplifier for amplifying a signal filtered in the first low-pass filter,
The DMB selection amplification unit includes a DMB bandpass filter for band-filtering the one branch signal to select the DMB signal, and a DMB signal amplifier for amplifying a signal selectively filtered by the DMB bandpass filter and providing the signal to the signal synthesizer ,
The FM selection amplifier includes an FM bandpass filter for band-filtering the other branch signal to select the FM signal, and an FM signal amplifier for amplifying the signal selectively filtered by the FM bandpass filter and providing the signal to the signal combiner and,
Wherein the second amplifying unit includes a second amplifier for amplifying the second high frequency composite signal input from the signal combining unit and a second low pass filter for filtering and outputting the signal amplified by the second amplifier,
Wherein the signal level control unit controls the amplification degree of the first amplifier to detect the level of the signal amplified by the second amplifier and to adjust the level of the signal amplified by the second amplifier to the set signal level.
In claim 3,
Wherein the internal transmission line network includes an integrated distributor for receiving the second high-frequency composite signal from the signal selection and amplification unit and distributing a plurality of signals, and a plurality of transmission lines connected to the integrated distributor,
And the small output repeaters are cascade-connected on at least one of the plurality of transmission lines.
The method according to any one of claims 1 to 5,
The head end unit includes an antenna unit for receiving the DMB signal and an FM receiving antenna for receiving the FM signal, an antenna unit for receiving the plurality of external signals, a DMB signal processor for signal processing the received DMB signal, A signal processing unit including an FM signal processor for signal processing the FM signal, and a signal synthesizing unit for synthesizing the signals processed by the signal processing unit into the first high-
The DMB signal processor includes:
A DMB low-pass filter for filtering the DMB signal received from the DMB receiving antenna;
A receiving DMB amplifier for amplifying the DMB signal filtered by the DMB low pass filter;
A fixed channel band filter for filtering a signal amplified by the reception DMB amplifier and passing a set channel signal;
An intermediate DMB amplifier for amplifying the filtered signal in the fixed channel band filter;
An output DMB amplifier for receiving the amplified signal from the intermediate DMB amplifier, amplifying the amplified signal, and outputting the amplified signal;
A signal detector for detecting an output signal of the intermediate DMB amplifier; And
And an automatic gain controller for controlling an amplification gain of the reception DMB amplifier according to a detection result detected by the signal detector.
The method according to any one of claims 1 to 5,
The head end unit includes an antenna unit for receiving the DMB signal and an FM receiving antenna for receiving the FM signal, an antenna unit for receiving the plurality of external signals, a DMB signal processor for signal processing the received DMB signal, A signal processing unit including an FM signal processor for signal processing the FM signal, and a signal synthesizing unit for synthesizing the signals processed by the signal processing unit into the first high-
The DMB signal processor includes:
A first DMB low-pass filter for filtering the DMB signal received from the DMB receiving antenna;
A local oscillator for outputting a local oscillation signal;
A first mixer for mixing a signal filtered by the first DMB low-pass filter and an output signal of the local oscillator;
An intermediate frequency band filter for filtering a signal output to the first mixer and passing the set intermediate frequency signal;
An intermediate frequency amplifier for amplifying the filtered signal in the intermediate frequency band filter;
A second mixer for mixing an amplified signal from the intermediate frequency amplifier and an output signal of the local oscillator;
A second DMB low pass filter for filtering a signal output from the second mixer to pass a low frequency band; And
And an output DMB amplifier for receiving a signal filtered by the second DMB low-pass filter, amplifying the received signal, and outputting the amplified signal,
Wherein the local oscillator outputs the local oscillation signal according to a frequency set according to the control.
The method according to any one of claims 1 to 5,
The small-power repeaters are cascade-connected according to a predetermined interval,
Each of the small power repeaters comprising:
A transmission loss compensation circuit part connected in series on the transmission line and compensating for a transmission loss on the transmission line;
An RF amplifier for receiving a signal from the transmission loss compensation circuit, amplifying the signal, and outputting the amplified signal for a small output; And
And a radio transmitter for receiving a signal from the RF amplifier and wirelessly transmitting the DMB signal and the FM signal,
Wherein the transmission loss compensation circuit comprises: a low noise amplifier for receiving a signal from an input terminal connected to the transmission line and amplifying the signal to have a gain greater than the transmission loss, a signal distributor connected to the low noise amplifier for distributing the signal, And an attenuator for attenuating and outputting a predetermined output,
And the RF amplifier unit receives the other output distributed to the signal distributor.
In claim 8,
The radio transmitter includes a diplexer filter connected to an output terminal of the RF amplifier for receiving a small output signal and separating and outputting the DMB signal and the FM signal, and a diplexer filter receiving the DMB signal and the FM signal from the diplexer filter, Comprising an antenna stage for wireless transmission,
The antenna end may be formed of a DMB antenna for wirelessly transmitting the DMB signal and an FM antenna for wirelessly transmitting the FM signal, or may be a transmission antenna of a dual band antenna including the diplexer filter and the antenna end And an integrated transmission system in the DMB and FM signaling premises.
The method according to any one of claims 1 to 5,
The small-power repeaters are cascade-connected according to a predetermined interval,
Each of the small power repeaters comprising:
Wherein the transmission line includes one of an operational amplifier, an emitter follower, and a column follower having a high input impedance and a low output impedance, the insertion loss being minimized by parallel insertion on the transmission line A high impedance circuit part;
An RF amplifier for receiving an output signal from the high impedance circuit and amplifying the output signal and outputting the amplified signal for a small output;
A variable attenuator which receives the output of the high impedance circuit part and inputs the attenuated signal to the RF amplifying part;
A signal detector for detecting a signal at an output terminal of the RF amplifier;
An automatic gain controller for adjusting an attenuation amount of the variable attenuator according to a detection result of the signal detector and controlling an output according to a gain set by the RF amplifier; And
And a radio transmitter for receiving a signal from the RF amplifier and wirelessly transmitting the DMB signal and the FM signal, respectively.
In claim 10,
The radio transmitter includes a diplexer filter connected to an output terminal of the RF amplifier for receiving a small output signal and separating and outputting the DMB signal and the FM signal, and a diplexer filter receiving the DMB signal and the FM signal from the diplexer filter, Comprising an antenna stage for wireless transmission,
The antenna end may be formed of a DMB antenna for wirelessly transmitting the DMB signal and an FM antenna for wirelessly transmitting the FM signal, or may be a transmission antenna of a dual band antenna including the diplexer filter and the antenna end And an integrated transmission system in the DMB and FM signaling premises.
DMB and FM, which output a high-frequency composite signal so that a plurality of external reception signals including a DMB signal and an FM signal are subjected to signal processing, a synthesized signal is received from a head end terminal, and a plurality of small output repeaters are transmitted through a cascade- In the signal selection amplifier,
A first amplifying unit receiving and amplifying a synthesized signal transmitted from the head end;
A signal distributor for distributing the amplified signal from the first amplifying unit;
A DMB selecting and amplifying unit for selecting and amplifying the DMB signal from one branch signal distributed in the signal distributor;
An FM selection amplifier for selecting and amplifying the FM signal from another branch signal distributed from the signal distributor;
A signal synthesizer for receiving the amplified signal from the DMB selection amplifier and the FM selection amplifier and re-synthesizing the signal into a high frequency synthesized signal;
A second amplifying unit for amplifying and outputting the high-frequency synthesized signal re-synthesized by the signal synthesizing unit; And
And a signal level control unit for controlling the amplification degree of the first amplification unit to detect the level of the signal amplified by the second amplification unit and adjust the level of the signal amplified by the second amplification unit to the set signal level.
In claim 12,
Wherein the first amplifying unit includes a first low-pass filter for receiving and filtering the synthesized signal, and a first amplifier for amplifying a signal filtered by the first low-pass filter,
The DMB selection amplification unit includes a DMB bandpass filter for band-filtering the one branch signal to select the DMB signal, and a DMB signal amplifier for amplifying a signal selectively filtered by the DMB bandpass filter and providing the signal to the signal synthesizer ,
The FM selection amplifier includes an FM bandpass filter for band-filtering the other branch signal to select the FM signal, and an FM signal amplifier for amplifying the signal selectively filtered by the FM bandpass filter and providing the signal to the signal combiner and,
Wherein the second amplifying unit includes a second amplifier for amplifying the high frequency recombination signal input from the signal combining unit and a second low-pass filter for filtering the signal amplified by the second amplifier,
Wherein the signal level control unit controls the amplification degree of the first amplifier to detect the level of the signal amplified by the second amplifier and to adjust the level of the signal amplified by the second amplifier to the set signal level.

Images