KR0144208B1 - Repeater - Google Patents

Abstract

The present invention relates to a mobile communication high-power relay apparatus that enables a high power small channel mobile communication service in a radio shade area of a mobile communication service. An object of the present invention is to enable a wireless communication service in a region where many mountainous areas, such as our country, do not receive communication services.

The present invention is composed of a link relay transceiver and a shadow area relay apparatus. The link relay transceiver is configured to relay a channel of n base stations to a radio shadow area mobile terminal so that a channel is allocated to the base station n channels. It transmits to the device and relays the new mobile terminal to continue to communicate on the same channel according to the radio shade area relay device instruction. By this configuration, the frequency of the newly allocated link relay transceiver is converted to an arbitrary frequency before being transmitted and converted by the shadow area relay to the original frequency of the base station. The converted frequency is sent to the mobile terminal to make a call. The concept of frequency switching maintains the smooth operation of the radio shader repeater as a means to prevent oscillation from feed back phenomenon due to the high power transmitted from the radio shader repeater.

Description

Mobile communication high power repeater

The present invention relates to a mobile communication high power relay device, in particular, a radio shade region is generated due to the bad conditions of geographical and environmental conditions in a mountainous area, such as Korea, and relates to a mobile communication high power relay device to solve this problem and enable smooth communication. .

In the conventional mobile communication relay apparatus, a forward frequency (transmission frequency) transmitted from a base station is received in front of a special radio shade area (for example, a tunnel) and amplified and transmitted into a radio shade area. In this type of mobile communication repeater, the output of the repeater is fed back to the input, which may cause oscillation, and the output is limited.

1 is a system diagram to which a general mobile communication relay apparatus and the apparatus of the present invention can be applied. As shown in the figure, the system includes a mobile communication base station area A through which radio waves can arrive; It is largely divided into radio shade areas (B), where radio waves cannot arrive, and consists of a relay that connects the two areas. The conventional mobile communication relay only plays a role of signal amplification and transmission.

Therefore, the existing repeater is amplified and transmitted as a signal received by all the channels of the adjacent base station has a problem that can not increase the output due to bad interference and cross-modulation characteristics.

The present invention has been made to solve the above-described problems, in particular, when the mobile enters the radio shading area, the mobile communication high-power repeater relays to a new frequency through frequency conversion to provide a good relay service without intermodulation Has its purpose.

In order to achieve the above object, the present invention provides a link relay transceiver for converting an original mobile communication base station region frequency into an authorized frequency not used for service; It is provided with a radio shader repeater which receives the converted frequency and converts it into the original used forward frequency and transmits the frequency to the radio shade area. In particular, it is characterized by using a microcontroller to enable transmission of remote control data and mobile terminal monitoring data between these link relay transmitters and receivers.

The above-mentioned configuration enables high-power service, and even if the radio shade area is wide, high-power broadband service is possible without installing a plurality of relay equipments, and even without natural shielding conditions, it can be easily installed without a separate physical shield and input frequency Since it is converted into and transmitted, it is possible to expand the service area under any environment in the radio shade area (eg, ground, underground tunnel, etc.).

1 is a schematic diagram of a mobile communication high power repeater.

2 is a block diagram of a link relay transceiver of the present invention.

Figure 3 is a block diagram of a radio shade zone relay of the present invention.

* Explanation of symbols for main parts of the drawings

A: Mobile communication base station area B: Radio shade area

a: Mobile communication base station transceiver b: Link relay transceiver

c: Mobile terminal in base station area d: Mobile communication radio shade area repeater

e, f: Mobile terminal in radio shade area relay device area

k1, k2, k3: Directional coupler 1: Mobile communication base station antenna

2: mobile terminal antenna in base station area

3: link relay transceiver relay antenna

4: antenna for radio wave repeater relay device

5: transmitting and receiving antenna of radio shade area repeater

6: Receive antenna of radio shade area repeater

7,8: mobile terminal transmission and reception antenna in the area of relay apparatus

100,100 ': duplexer I 101,101': low noise amplifier

102,102 ': n-distributor 103,103': Mixer I

104,104 ': Filter and intermediate frequency amplifier 105,105': Mixer II

106: high frequency amplifier and filter 107: n coupler

108,108 ': High Power Amplifier 109,109': Duplexer II

110,110 ': Reverse storage amplifier 111,111': Reverse n divider

112,112 ': Reverse Mixer II 113,113': Reverse filter and intermediate frequency amplifier

114,114 ': Reverse mixer I 115: Reverse high frequency amplifier and filter

116,116 ': Reverse n combiner 117,117': Reverse high power amplifier

118,118 ', 119,119', 120,120 ', 121,121': Local Oscillator

122: reception data detector 123,123 ': microcontroller

124,124 ': frequency controller 200: high power combiner

210: reverse duplexer 220: distributor

230: mobile terminal frequency scan receiver 240: transmitter

300,300 ': forward narrowband IF board 310,310': reverse narrowband IF board

Hereinafter, with reference to the accompanying drawings will be described in detail a mobile communication high-frequency relay device according to a preferred embodiment of the present invention.

1 briefly mentioned above, as well as FIGS. 2 and 3 will be described in detail.

First, FIG. 1 shows a schematic diagram of transmitting a frequency from a mobile communication base station area A to a radio wave shading area B. As shown in FIG. The forward frequency sent from the mobile communication base station transceiver a is transmitted to the link relay transceiver b as much as attenuated by the directional coupler k1 attached to the mobile communication base station antenna 1. The link relay transceiver b converts the transmitted frequency into a licensed frequency not used in the mobile communication base station area A and sends it to the link relay transceiver relay antenna 3.

The transmitted frequency is introduced into the radio shade area repeater relay antenna (4), and is converted to the original forward frequency used in the base station by the mobile communication shade area repeater (d), and then the radio shade area repeater transmit / receive antenna (5). Is transmitted to the radio shading area A and received by the mobile terminals e and f in the radio shading area relay area.

The reverse frequency transmitted from the mobile terminals (e) and (f) in the radio shadowing area relay area is received by the radio shadowing area relay device transmitting / receiving antenna (5) and the receiving antenna (6) of the radio shadowing area relay device. Converted to frequency by device d. This converted frequency is transmitted to the link relay transceiver b by the radio shade area relay relay 4. The transmitted frequency enters the link relay transceiver relay antenna (3), and is originally reversed by the link relay transceiver (b) from the mobile terminals (e) and (f) in the region of the radio shade area relay unit. Communication is performed by converting the frequency into the reverse receiver of the mobile communication base station transceiver a through the directional coupler k1.

Here, the frequency of use between the link relay transceiver 3 and the radio shade area relay relay antenna 4 is a licensed frequency not used by the mobile communication base station transceiver (a). b) is the frequency for transmission between the mobile communication shaded area relay (d). Between them, the remote control data and the mobile terminal monitoring data can be transmitted.

FIG. 2 is a block diagram of a link relay transceiver b which transmits a forward frequency and a reverse frequency from a mobile communication base station area A to a radio wave shading area B, and shows details of FIG.

The forward frequency sent from the mobile communication base station transceiver a is transmitted to the link weight transceiver b as much as attenuated by the directional coupler k1 attached to the mobile communication base station antenna 1. The forwarded frequency is sent and received by duplexer I (100). This separated forward frequency is low noise amplified by the low noise amplifier 101 and n divided by the n divider 102. the n-divided frequency is forward narrowband IF board 300; Mixer I 103; Filter and intermediate frequency amplifier 104; Mixer II 105; Each is frequency-converted by the high power amplifier and filter 106 and n coupled by an n combiner 107. The forward conversion frequency coupled by the combiner 107 is amplified by the high power amplifier 108 and transmitted by the relay antenna 3 via the duplexer II 109 and the directional coupler k2.

The reverse frequency sent from the mobile communication shade area repeater (d) is input through the link relay transceiver (3), and the reverse frequency is transmitted and received through the directional n combiner (k2) and the duplexer II (109). Separated and low noise amplified by the reverse low noise amplifier 110 and n distributed by the reverse n divider 111. Each of these distributed reverse frequencies is converted in the same manner as the above-described forward frequency conversion method. First, it is mixed with the frequency generated by the local oscillator 121 in the reverse mixer II (112). The mixed frequency is amplified in the reverse filter and the intermediate frequency amplifier 113 and mixed with the frequency oscillated in the local oscillator 120 in the reverse mixer I 114 and amplified by the reverse high frequency amplifier and the filter 115. The amplified frequency is combined by the reverse n combiner 116 and then transmitted and received by the duplexer I 100 amplified by the reverse high power amplifier 117. The separated frequency is sent to the mobile communication base station transceiver a.

The above-described frequency means the transmission of pure communication data, and in the present invention, the mobile communication high power repeater has a microcontroller 123 that controls each device to convert the frequency. Therefore, a data signal indicating the state of the mobile terminal exists in the reverse frequency. This frequency is introduced into the link relay transceiver relay antenna 3 and sent as attenuated by the directional coupler k2. The transmitted signal is detected by the received data detector 122 and transmitted to the microcontroller 123. .

The microcontroller 123, which is a central processing unit of the link relay transceiver (b), analyzes the transmitted data signal and the frequencies of the mobile terminals (e) and (f) in the region of the radio shade zone, the frequency controller 124. Provide information to

The frequency controller 124 receives this information and converts the oscillation frequencies of the local oscillators 118, 119, 120, and 121 so that they can be tuned to the forward and reverse frequencies corresponding to the frequency of the mobile terminal. Auto sync.

By this operation, the link relay transceiver b is easily detected by the reception data detector 122 even when the mobile terminal enters the mobile communication shade area relay device d while biting any channel among many channels of the base station. It is possible that the call will not end.

Next, FIG. 3 is a block diagram of the mobile communication shade area repeater d, which shows FIG. 1 (d) in detail.

3 is similar to the link relay transceiver b of FIG. 2.

The flow of the forward frequency and the reverse frequency of the mobile communication shade area repeater d is as follows.

First, the forward frequency is transmitted from the link relay transceiver 3 antenna to the radio shade area relay apparatus 4. The transmitted forward frequency is transmitted / received through the directional coupler (k3) and duplexer I (100 '), amplified by the low noise amplifier 101' and distributed in the n divider 102 '.

Each of the distributed radio waves is forward narrowband IF board 300 '; Mixer I 130 '; Filter and intermediate frequency amplifier 104 '; These are delivered in mixer II 105 'order and are each frequency converted by this forward narrowband IF board 300' and amplified by high output amplifier 108 'and then coupled by high output combiner 200.

The frequency coupled by the combiner 200 is transmitted / received by the duplexer II 109 'and transmitted by the radio shade area relay device transmit / receive antenna 5 to the radio shadow area B so that the mobile terminal in the radio shade area region Forward frequencies are transmitted to (e) and (f). In addition, the reverse frequency radiated from another mobile terminal is monitored and monitored by the mobile terminal frequency scan and reception apparatus 230.

This confirmed frequency is reported to the microcontroller 123 '. The microcontroller 123 'is designed to remotely transmit the self-diagnosis and status of the mobile communication shade area relay device d. In addition, the microcontroller 123' is provided in the mobile terminal frequency scan receiver 230. After analyzing the reported frequency, the forward narrowband IF board 300 'which is not used among the forward narrowband IF board 300' and the reverse narrowband IF board 310 'in the mobile communication shaded area repeater (d). And select the reverse narrowband IF board 310 'to match the frequency of the mobile terminal and give a control command to the frequency controller 124'. The microcontroller 123 'also indicates the same to the frequency controller 124'. Commanding that the link relay transceiver (b) in the radio wave shading area (B) converts the frequency and converts the channel frequency so as to correspond to the frequency of the mobile terminal (c) in the base station area. Automatic tuning to filter and intermediate frequency amplifier 104 'to tune to wave count.

By the above operation, the mobile terminal (c) in the base station area is automatically shaded by the mobile communication base station area (A) by automatically converting and controlling the channels of the mobile communication shadow area relay device (d) and the link relay transceiver (b). Co-channel communication is possible even when moving to area (B).

Channel assignment in the link relay transceiver (b) is performed by a new channel assignment command in the mobile communication shaded area relay (d), which is also a microcontroller 123 in the mobile communication shaded area relay (d). Is made by ').

The microcontroller 123 'drives the transmission device 240 when the mobile communication shaded area repeater d reaches the operation standby state, and a new channel is provided to the directional coupler k3 and the radio shade area repeater relay 4. The assignment command is transmitted to the link relay transceiver b. The transmitted frequency is detected by the receiving data detector 122 via the link relay transceiver 3 and the directional coupler k2, and is then transmitted from the link relay transceiver b to the mobile radio wave shade area repeater d. The frequency conversion is performed so that a new channel is allocated to the mobile station) so that the call between the mobile station and the base station can communicate on the same channel.

The above-mentioned matters are processed for a short time (less than 0.5 seconds), so the mobile terminal subscriber does not feel any change during the call and makes a call.

The mobile communication high power relay apparatus of the present invention is not limited to the above-described embodiments, and may be modified in various ways within the scope of the technical matters of the present invention.

According to the mobile communication high power relay as described above, a new channel between the link relay transceiver (b) in the mobile communication base station area (A) and the mobile communication radio shade area relay device (d) in the radio shade area (B). Because it allocates and relays, it eliminates interference with the communication frequency of many mobile terminals and can be easily installed without any physical shielding configuration, so that the service area can be expanded in any environment of the radio shadow area and the radio feed back phenomenon disappears. It has the advantage of being able to do high power relay.

Claims (4)

A link relay transceiver for modifying the forward and reverse frequencies of a mobile communication base station transceiver (a), having a forward narrowband IF board 300 and a reverse narrowband IF board 310 configured to prevent high power feedbacks. b) and a forward narrowband IF board 300 'and a reverse narrowband IF board 310' for modifying the forward and reverse frequencies of the link relay transceiver (b) of the mobile communication base station transceiver (a). A radio communication high-frequency repeater having a radio shade area repeater (d) for reproduction at forward and reverse frequencies and transmitting to mobile terminals (e) and (f) in the radio shade area relay area. The method according to claim 1, wherein the oscillator (118), (118 '), (119) to enable relaying of the frequency between the link relay transceiver (b) and the mobile communication shadow area relay (d) at a licensed frequency. And a frequency controller (124), (124 ') for automatically controlling the oscillation frequencies of (119'), (120), (121 '). The local oscillators 118, 118 ', and (119) according to claim 1, wherein the frequency between the link relay transceiver (b) and the mobile communication shaded area relay apparatus (d) can be relayed at a licensed frequency. And (119 '), (120), (120') a mobile communication high power repeater comprising a microcontroller (123), (123 ') for sending information to automatically control the oscillation frequency. The method of claim 1, wherein the forward narrowband IF boards 300, 300 'and the reverse narrowband IF boards 310, 310' are composed of a plurality of boards that operate independently according to respective frequencies. It is done.