KR20050032762A - Sender/Receiver Signal Radio Relay Device of Transceiver Using Time-Sharing System - Google Patents

Abstract

A wireless repeater for a transceiving signal of a wireless transceiving device having a time division method is provided to install a switching time generator for generating a time synchronous signal necessary for controlling a transceiving signal switch in a repeater of a shading area, thereby directly relaying a time division wireless transceiving signal. A transmission signal frequency converter(3) comprises as follows. A transmission signal processor(30) amplifies or attenuates a size of a forward transmission signal, and changes into the most appropriate signal size for frequency conversion. An up-frequency converter(31) mixes an input signal with a local oscillating frequency of a local oscillating signal generator(34), and converts the mixed frequency into a proper forward transmission frequency. A transmission signal band pass filter(32) removes a local oscillating signal and an image frequency. A power amplifier(33) amplifies a base station transmission signal converted into a forward transmission frequency. A shading area repeater(7) comprises as follows. A transmission signal band pass filter(90) filters forward transmission frequencies only from various signals. A down-frequency converter(91) mixes an input signal with a local oscillating frequency, and converts into a transmission frequency. A band pass filter(92) removes a local oscillating signal and an image frequency. A receiving signal processor(93) automatically compensates for various losses, and supplies a certain gain. A signal separator(96) separates an inputted signal into two paths. A switch time generator(97) extracts a forward transmission signal generation time. A forward transmission signal amplifier(98) amplifies a forward transmission signal transmitted to a shading area, and sends the amplified signal to a transceiving signal switch(72).

Description

Send / Receiver Signal Radio Relay Device of Transceiver Using Time-Sharing System}

The present invention enables the transmission of a radio signal in a wireless device that communicates transmission and reception in the time division manner with the same transmission / reception frequency, thereby enabling communication in a remote area or a shadow area where the radio signal of the base station cannot reach. The present invention relates to a wireless relay apparatus for transmitting / receiving signals of a time division wireless transmitter and receiver.

In the related art, no time division wireless transmission / reception apparatus technology for controlling transmission / reception frequency to match a base station has been developed. Thus, a device for directly relaying a wireless transmission / reception signal has not been developed.

In order to enable communication in the shaded area only, the present invention could enable communication in the shaded area by additionally installing a base station in the shaded area.

As such, the method of adding a base station must have a means for transmitting a switching center signal to a base station location, and have an infrastructure for a base station device, and in the case of a mobile Internet, a device for synchronizing time synchronization between base stations. There is a problem that must be equipped.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned general problems. In the time division wireless relay device, the switching time generator for generating the time synchronization signal required for the control of the transmission / reception signal switch for the shadow area side relay device is shaded. It is an object of the present invention to provide a radio relay apparatus for transmitting / receiving signals of a time division type radio transmitter / receiver that can be installed in a local relay apparatus to enable direct relaying of a radio frequency transceiver signal in a time division manner.

The object of the present invention described above is that the base station relay device transmits a signal to a shadow area relay device through a transmission signal terminal, a transmission signal frequency converter, a reverse reception signal terminal, a reception signal frequency converter, a transmission signal transmission / reception filter and a transmission path. It consists of a transmission signal antenna for transmitting a signal, and the shadow area relay device is a transmission signal antenna and transmission signal transmission and reception separation filter, transmission signal frequency converter, reception signal frequency converter, transmission and reception signal switch, band pass filter and shadow area service antenna Configured to transfer the transfer signal in time synchronization with the transmit / receive transfer of the base station, or generate the transfer signal by demodulating the transfer time information transmitted from the base station into a baseband signal, or forward the transfer signal transmitted from the base station. This can be achieved by detecting and generating the size of.

Therefore, in the time division type wireless relay device, the time division type wireless transmitter / receiver signal generating time synchronization signal required for the control of the transmission / reception signal switch for the shadow area relay device is installed in the shadow area relay device. Direct relaying is possible, and thus the time division wireless transmission / reception signal can be directly relayed in a wireless signal state to enable service in a shadow area without the need for additional base stations in a time division wireless transmission / reception apparatus such as a mobile Internet or a wireless LAN. In addition, it is possible to reduce the additional cost of the time synchronization device required for the base station expansion, the line between the base station and the switching center, and other base station facilities.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 shows a block diagram of an apparatus of the present invention.

According to this, the forward transmission signal terminal 1 for receiving the forward transmission signal input from the base station apparatus;

The transmission signal processor 30 converts the signal size of the forward transmission signal input through the transmission signal terminal 1 into a size most suitable for frequency conversion, and generates an input signal in the local oscillation signal generator 34. An uplink frequency converter (31) for mixing with the local oscillation frequency and converting it into a forward transmission frequency suitable for transmission in a shaded region, a transmission signal bandpass filter (32) for removing a local oscillation signal and an image frequency generated by the converter; A transmission signal frequency converter (3) comprising a power amplifier (33) for amplifying a base station transmission signal converted to a forward transmission frequency to a signal size suitable for transmission to a shadow area;

A transmission signal transmission / reception separator 50 for separating or combining a transmission frequency and a reception frequency to enable transmission and reception with one antenna;

A transmission signal antenna 51 for converting the input forward transmission frequency into an electromagnetic wave form and coupling it with the transmission path 6 in a spatial state;

The transmission signal bandpass filter 43 which filters only the reverse transmission frequency from various signals received through the antenna, and the input signal is mixed with the local oscillation frequency generated by the local oscillation signal generator 44, such as the transmission frequency of the subscriber. Downlink frequency converter 42 for converting into frequency, bandpass filter 41 for removing local oscillation signal and video frequency generated from converter, and removing noise generated in section of transmission path 6 and varying in the transmission section Receiving signal processor 40 and local oscillator reference which automatically compensates for the loss and provides a constant gain in the reverse receiving path, and amplifies the signal size to the reverse receiving signal terminal 2 by amplifying the signal size to an appropriate size for receiving signal processing of the base station. A received signal frequency converter 4 composed of a reference frequency generator 45 for generating a frequency;

The base station side relay apparatus 5 is constituted by a reverse reception signal terminal 2 for transmitting a reverse reception signal to a base station,

A transmission signal antenna 70 of the shadow area side device which receives the forward transmission frequency from the transmission path 6;

A transmission signal transmission and reception separator 71 for separating or combining a transmission frequency and a reception frequency to enable transmission and reception with a single antenna;

A shadow area service antenna 10 for receiving a reverse reception signal transmitted from a subscriber station in a shadow area;

A band pass filter 73 for preventing a frequency component other than the base station signal frequency component among the signal frequencies received through the antenna from being introduced into the shadow area side repeater;

A transmission and reception signal switching unit 72 for switching forward and backward reception signals to transmit and receive in synchronization with the transmission and reception signal times of the base station;

A shaded region by mixing the input signal with a local oscillation frequency generated by the local oscillation signal generator 84 and a transmission signal processor 83 that amplifies or attenuates the signal size of the received reverse reception signal to a size most suitable for frequency conversion. An uplink frequency converter 82 for converting into a reverse transmission frequency suitable for transmission to a transmission signal, a transmission signal bandpass filter 81 for removing a local oscillation signal and an image frequency generated by the converter, and a subscriber transmission signal converted to a reverse transmission frequency A transmission signal frequency converter 8 comprising a power amplifier 80 that amplifies to a signal size suitable for transmission to the base station;

The transmission signal bandpass filter 90 filtering only the forward transmission frequency from various signals received through the antenna and input through the transmission signal transmission / reception separator 71, and a local signal generated by the local oscillation signal generator 94. It is generated in the downlink frequency converter 91 for mixing with the oscillation frequency and converting it into the same frequency as the transmission frequency of the base station, the bandpass filter 92 for removing the local oscillation signal and the image frequency generated by the converter, and the transmission path 6. Receiving signal processor 93 for eliminating noise, and automatically compensating for various losses in the transmission section to provide a constant gain in the forward transmission path, and signal separator 96 for branching the input signal into two paths. Wow; Transfer time generator 97 for processing the signal received through the transmission path to extract the forward transmission signal generation time and amplifying the forward transmission signal transmitted to the shadow area to the size required for the service of the shadow area transmit and receive signal switch The shaded region-side relay device 7 is constituted by the reception signal frequency converter 9 composed of the forward transmission signal amplifier 98 transmitted to 72.

Referring to the operation and effect of the device of the present invention configured as described above are as follows.

First, the block functions and configurations related to the path of the forward transmission signal in the apparatus of the present invention will be described as follows.

The forward transmission signal inputted from the base station apparatus via the forward transmission signal terminal 1 is amplified or attenuated by the transmission signal processor 30 of the transmission signal frequency converter 3 in the base station side relay apparatus 5 to be most suitable for frequency conversion. After being changed to a suitable size, it is mixed with the local oscillation frequency generated by the local oscillation signal generator 34 by the uplink frequency converter 31 and converted into a forward transmission frequency suitable for transmission in the shaded region.

Subsequently, the local oscillation signal and the image frequency generated by the uplink frequency converter 31 are removed by the transmission signal bandpass filter 32 and then amplified to a signal size suitable for transmission to the shadow area through the power amplifier 33. After being transmitted to the transmission signal antenna 51 is separated through the transmission signal transmission and reception separator 50 for separating or combining the transmission frequency and the reception frequency to enable transmission and reception with a single antenna, in the transmission signal antenna 51 The input forward transmission frequency is converted into an electromagnetic wave form and combined with the transmission path 6 in a spatial state to be transmitted to the transmission signal antenna 70 of the shadow area side relay apparatus 7.

Therefore, in the transmission signal transmission / reception separator 71 which separates or combines a transmission frequency and a reception frequency so as to enable transmission and reception by one antenna, the forward signal received through the transmission signal antenna 70 is separated and the reception signal frequency converter 9 Since it is transmitted to the band pass filter 90 in the transmission signal, the transmission signal band pass filter (90) filters only the forward transmission frequency from the various signals received through the antenna to filter the input signal from the downlink frequency converter (91) Local oscillation frequency generated by the local oscillation signal generator 94 is mixed with the same frequency as the transmission frequency of the base station.

Subsequently, in the band pass filter 92, the local oscillation signal and the image frequency generated by the downlink frequency converter 31 are removed and transmitted to the reception signal processor 93, and thus the transmission path 6 is transmitted from the reception signal processor 93. In this section, the noise generated in the) section is eliminated and various losses in the transmission section are automatically compensated to provide a constant gain in the forward transmission path.

therefore. The signal splitter 96 splits the input signal into two paths and separates the forwarded signal into a forward transmission amplifier 98 that amplifies the signal to a size required for service in a shadow area. The time generator 97 processes the signal received through the transmission path, extracts the forward transmission signal generation time, and transfers it to the transmission / reception signal switcher 72, so that the transmission / reception signal switcher 72 reverses the forward transmission signal. The received signal can be switched to transmit and receive in synchronization with the transmission and reception signal times of the base station.

Subsequently, the forward signal passing through the transmission / reception signal switcher 72 passes through the band pass filter 73 to remove the output of signal frequency components other than the base station signal frequency. It is transmitted to the outside through the shadow area service antenna 10 that transmits and receives the reverse reception signal, and is transmitted to a mobile station terminal, which is a subscriber device.

On the other hand, the block function and configuration related to the path of the reverse reception signal in the apparatus of the present invention will be described.

First, when a reverse reception signal transmitted from a subscriber device in a shaded area is received through the shaded area service antenna 10, a frequency component other than the base station signal frequency component among the signal frequencies received through the antenna in the bandpass filter 73 is received. This prevents the entry into the shadow area relay.

Thereafter, the backward reception signal is switched by a transmission and reception signal switching unit 72 for switching forward transmission signal and reverse reception signal to transmit and receive in synchronization with the transmission and reception signal times of the base station. Amplified or attenuated by the transmission signal processor 83 in the inside, the amplified or attenuated size is changed to a size most suitable for frequency conversion, and then transferred to the uplink frequency converter 82 to be mixed with the local oscillation frequency generated by the local oscillation signal generator 84 to be shaded. It is converted to a reverse transmission frequency suitable for transmission to the area.

Subsequently, the local oscillation signal and the image frequency generated by the uplink frequency converter 82 are suitable for transmitting the subscriber transmission signal converted to the reverse transmission frequency to the base station after the local oscillation signal is removed through the band pass filter 81. It is transmitted to the transmission signal transmission and reception separator 71 through the power amplifier 80 to amplify the signal size.

Therefore, since the transmission signal transmission / reception separator 71 separates or combines a transmission frequency and a reception frequency to transmit and receive with one antenna, and transmits the transmission signal to the transmission signal antenna 70, the reverse direction input from the transmission signal antenna 70. The transmission frequency is converted into an electromagnetic wave form and transmitted to the base station side relay apparatus 5 through the transmission path 6 in a spatial state.

Therefore, the transmission signal antenna 51 of the base station side relay apparatus receiving the reverse transmission frequency from the transmission path 6 receives it and transmits it to the transmission signal transmission / reception separator 50 so that the transmission signal transmission / reception separator 50 is one. After separating or combining the transmission frequency and the reception frequency to transmit and receive by the antenna of the transmission signal bandpass filter 43 in the received signal frequency converter 4, the transmission signal bandpass filter 43 in the antenna Only the reverse transmission frequency is filtered out from the various signals received through.

Since the filtered reverse signal is mixed with the local oscillation frequency generated by the local oscillation signal generator 44 through the downlink frequency converter 42, is converted into the same frequency as the transmission frequency of the subscriber, and then transmitted to the bandpass filter 41, The band pass filter 41 removes the local oscillation signal and the image frequency generated by the downlink frequency converter 42 and transmits the image signal to the reception signal processor 40.

Accordingly, the reception signal processor 40 removes noise generated in the transmission path 6 section and automatically compensates for various losses that vary in the transmission section to provide a constant gain in the reverse reception path and to receive signal processing of the base station. After the signal size is amplified to an appropriate size, the reverse reception signal is transmitted to the base station through the reverse reception signal terminal 2.

At this time, the transmission and reception signal switching unit 72 in the shadow area side relay apparatus 7 needs to be switched in time synchronization with the transmission and reception switching of the base station, and the switching signal is generated by the transmission and reception switching time generator 97. The transfer signal may be generated by demodulating the transfer time information transmitted from the base station in the form of a baseband signal, and also transmit / receive for controlling the transmit / receive signal switcher 72 in a relay apparatus which switches in time synchronization with the transmit / receive switch of the base station. The transfer signal of the transfer time generator 97 may be generated by detecting the magnitude of the forward transmission signal transmitted from the base station.

That is, the apparatus of the present invention converts the transmission signal from the base station into a specific transmission frequency (referred to as 'frequency') in the base station side relay device 5 and passes the transmission path through the antenna, and then the shadow area relay device. In (7), the 'ga' frequency can be converted into the original transmission frequency signal and transmitted to the subscribers in the shadow area using the transmission / reception signal switcher 72 and the shadow area service antenna 10. The transmission signal from the subscriber is converted into a specific transmission frequency (referred to as 'I' frequency) from the shadow area relay device 7 via the service antenna 10 and the transmission / reception signal switcher 72 through the antenna. After passing through the transmission path, the base station side repeater 5 converts the original transmission frequency signal into a signal input terminal of the base station.

Such an apparatus of the present invention enables the relay of a wireless device having the same transmit / receive frequency, and thus requires the expansion of a base station having a high price, which is used for services such as a wireless LAN device and a portable Internet, which have the same transmit / receive frequency and are performing time division communication. It is possible to expand the communicable area by using the low-cost device of the present invention without any cost.

As described above, according to the present invention, in the time division wireless relay device, the transfer time generator for generating the time synchronization signal required for the control of the transmission / reception signal changer required for the shadow area relay device is installed in the shadow area relay device. This allows direct transmission of wireless transmission / reception signals in a time division manner, and by additionally relaying time division wireless transmission / reception signals in a wireless signal state, it is necessary to increase the base station in a time division wireless transmission / reception apparatus such as a mobile Internet or a wireless LAN. It is possible to provide services in the shadow area without saving, and it can also reduce the additional cost of the time synchronization device required for the base station expansion, the circuit between the base station and the switching center, and other base station facilities.

Particularly, in generating a switching signal for controlling a transmission / reception signal switch, a subscriber station used in a time division wireless transmission / reception apparatus for extracting time information for demodulating a signal transmitted from a base station to a baseband and using it as a switching signal. By removing the transmission function and using only the reception function as the device, it is possible to switch between the subscriber base station and all the subscriber devices related to the base station in precise time synchronization.

In addition, when detecting a magnitude of a transmission signal of a base station and generating a switching signal, a propagation delay may be generated by the time required to detect the magnitude of the signal, and thus the length of the transmission path may be shortened, but the detection of the switching signal is simple. In this case, it is a very useful invention such that the economic effect can be greatly obtained when the multi-stage relay is not performed.

1 is a block diagram of an apparatus of the present invention.

Explanation of symbols on the main parts of the drawings

1: Transmission Signal Terminal 2: Reverse Reception Signal Terminal

3,8: Transmit signal frequency converter 4,9,: Receive signal frequency converter

5: base station relay device 6: transmission path

7: shadow area relay device 10: shadow area service antenna

30,83: Transmission signal processor 31,82: Uplink frequency converter

32,43,81,90: Bandpass filter for transmission signal 33,80: Power amplifier

34,44,84,94: Local oscillation signal generator 40,93,98: Receive signal processor

41,73,92: Bandpass filter 42,91: Downconverter

45,95: reference signal generator

50,71: transmission signal transmission / reception filter 51,70: transmission signal antenna

72: transmitting and receiving signal switch 96: signal separator

97: transfer time generator 98: forward transmission signal amplifier

Claims (3)

A forward transmission signal terminal 1 for receiving a forward transmission signal input from the base station apparatus; The transmission signal processor 30 converts the signal size of the forward transmission signal input through the transmission signal terminal 1 into a size most suitable for frequency conversion, and generates an input signal in the local oscillation signal generator 34. An uplink frequency converter (31) for mixing with the local oscillation frequency and converting it into a forward transmission frequency suitable for transmission in a shaded region, a transmission signal bandpass filter (32) for removing a local oscillation signal and an image frequency generated by the converter; A transmission signal frequency converter (3) comprising a power amplifier (33) for amplifying a base station transmission signal converted to a forward transmission frequency to a signal size suitable for transmission to a shadow area; A transmission signal transmission / reception separator 50 for separating or combining a transmission frequency and a reception frequency to enable transmission and reception with one antenna; A transmission signal antenna 51 for converting the input forward transmission frequency into an electromagnetic wave form and coupling it with the transmission path 6 in a spatial state; The transmission signal bandpass filter 43 which filters only the reverse transmission frequency from various signals received through the antenna, and the input signal is mixed with the local oscillation frequency generated by the local oscillation signal generator 44, such as the transmission frequency of the subscriber. Downlink frequency converter 42 for converting into frequency, bandpass filter 41 for removing local oscillation signal and video frequency generated from converter, and removing noise generated in section of transmission path 6 and varying in the transmission section Receiving signal processor 40 and local oscillator reference which automatically compensates for the loss and provides a constant gain in the reverse receiving path, and amplifies the signal size to the reverse receiving signal terminal 2 by amplifying the signal size to an appropriate size for receiving signal processing of the base station. A received signal frequency converter 4 composed of a reference frequency generator 45 for generating a frequency; The base station side relay apparatus 5 is constituted by a reverse reception signal terminal 2 for transmitting a reverse reception signal to a base station, A transmission signal antenna 70 of the shadow area side device which receives the forward transmission frequency from the transmission path 6; A transmission signal transmission and reception separator 71 for separating or combining a transmission frequency and a reception frequency to enable transmission and reception with a single antenna; A shadow area service antenna 10 for receiving a reverse reception signal transmitted from a subscriber station in a shadow area; A band pass filter 73 for preventing a frequency component other than the base station signal frequency component among the signal frequencies received through the antenna from being introduced into the shadow area side repeater; A transmission and reception signal switching unit 72 for switching forward and backward reception signals to transmit and receive in synchronization with the transmission and reception signal times of the base station; A shaded region by mixing the input signal with a local oscillation frequency generated by the local oscillation signal generator 84 and a transmission signal processor 83 that amplifies or attenuates the signal size of the received reverse reception signal to a size most suitable for frequency conversion. An uplink frequency converter 82 for converting into a reverse transmission frequency suitable for transmission to a transmission signal, a transmission signal bandpass filter 81 for removing a local oscillation signal and an image frequency generated by the converter, and a subscriber transmission signal converted to a reverse transmission frequency A transmission signal frequency converter 8 comprising a power amplifier 80 that amplifies to a signal size suitable for transmission to the base station; The transmission signal bandpass filter 90 filtering only the forward transmission frequency from various signals received through the antenna and input through the transmission signal transmission / reception separator 71, and a local signal generated by the local oscillation signal generator 94. It is generated in the downlink frequency converter 91 for mixing with the oscillation frequency and converting it into the same frequency as the transmission frequency of the base station, the bandpass filter 92 for removing the local oscillation signal and the image frequency generated by the converter, and the transmission path 6. Receiving signal processor 93 for eliminating noise, and automatically compensating for various losses in the transmission section to provide a constant gain in the forward transmission path, and signal separator 96 for branching the input signal into two paths. Wow; Transfer time generator 97 for processing the signal received through the transmission path to extract the forward transmission signal generation time and amplifying the forward transmission signal transmitted to the shadow area to the size required for the service of the shadow area transmit and receive signal switch A transmission / reception signal wireless relay device of a time division type wireless transmission / reception device, characterized in that a shadow area side relay device (7) is constituted by a reception signal frequency converter (9) composed of a forward transmission signal amplifier (98) to be transmitted to (72). The method according to claim 1, The transfer signal for controlling the transmit / receive signal switcher 72 is generated by the transmit / receive transfer time generator 97 in the receive signal frequency converter 9, which transfers the transfer time information transmitted from the base station into a baseband signal form. Transmitting and receiving signal wireless relay device of a time division wireless transmission and reception device characterized in that the demodulation to generate. The method according to claim 1, The transfer signal for controlling the transmit / receive signal switch 72 is generated by the transmit / receive transfer time generator 97 in the receive signal frequency converter 9 and is generated by detecting the magnitude of the forward transmit signal transmitted from the base station. Transmitting and receiving signal wireless relay device of a time division wireless transmission and reception device characterized in that.