KR20010075985A - Radio transmitter/receiver in radio interfacing apparatus for radio interfacing exchange system - Google Patents

Abstract

PURPOSE: A wireless transmitter/receiver in a wireless interlocking device for interlocking a switch system by wireless is provided to improve the reliability of the switch system by effectively decreasing a transmission error rate of a wireless line when performing a high-speed transmission through the wireless transmitter/receiver. CONSTITUTION: An FEC(Forward Error Correction) coding unit(50) codes order wire data and a plurality of traffic data as a certain code, and outputs the coded order wire data as the first channel data and outputs a plurality of coded traffic data as the second channel data. A signal mixing unit(58) mixes a pilot data, the first channel data, and the second channel data with corresponding conversion codes and generates conversion codes. An adder(52) adds the converted signals. A mixer(54) mixes a carrier frequency with the added signal and outputs the mixed signal to an antenna. An interleaving unit(48) converts each sequence of the order wire data and the traffic data and outputs the interleaved order wire data and the interleaved traffic data to the FEC coding unit(50).

Description

Radio transmitter / receiver in radio interfacing apparatus for radio interfacing exchange system}

The present invention relates to a switching system, and more particularly, to a wireless transmitter / receiver in a wireless interworking apparatus for wireless interworking of a switching system.

In general, in order to wirelessly connect and operate a switching network, a wireless interworking device is required. The wireless interworking apparatus includes a wireless transmitter for converting and transmitting wired data into wireless data, and a wireless receiver for receiving and converting wireless data into wired data. Such a wireless interworking device enables wireless communication between a packet communicator (PCU) and a small exchange and wireless communication between mobile radio base stations. That is, one subscriber in the small exchange can talk to the other subscribers in the set of mobile radio base stations through relaying by the wireless interworking device.

1 is a circuit diagram schematically showing a radio transmitter in a conventional radio linkage device. The radio transmitter in the conventional radio interlocking device includes first to fourth mixers 10, 12, 14, and 18, an adder 16, and an oscillator 20.

Referring to FIG. 1, the first mixer 10 mixes a first transform code (Pseudo Random Code, PN1) with data input through a pilot channel (P_CH). The second mixer 12 mixes the second transform code (PN2) with the traffic data input to the traffic channel (T_CH). The third mixer 14 mixes the third transform code PN3 with data input through the order wire channel.

The adder 16 adds the converted signals respectively output from the first to third mixers 10 to 14.

The fourth mixer 18 mixes the carrier frequency fc generated by the oscillator 20 with the signal output from the adder 18, and outputs the mixed signal through the antenna.

On the other hand, as the transmission speed of the wireless companion device increases, the bit error rate of the wireless line increases significantly. However, the conventional radio transmitter shown in FIG. 1 transmits signals as it is without performing signal manipulation to reduce transmission errors. As such, when the wireless receiver receives a wireless signal in which a transmission error occurs, it is difficult to recover the data in which the error occurs.

An object of the present invention is to provide a wireless transmitter in a wireless interworking device that can reduce the transmission error.

Another object of the present invention is to provide a wireless receiver in a wireless interworking device that can reduce a transmission error.

1 is a circuit diagram schematically showing a radio transmitter in a conventional radio linkage device.

2 is a view schematically showing a radio transmitter in a wireless interworking device according to the present invention.

3 is a view schematically showing a wireless receiver in a wireless interworking device according to the present invention.

In order to achieve the above object, the radio transmitter according to the present invention for transmitting a radio signal through an external antenna in a radio interlocking device for radio interworking the switching system is to code the order wire data and a plurality of traffic data into a predetermined code, coding A forward error correction (FEC) coding unit for outputting a plurality of coded traffic data as first channel data and a plurality of second channel data, pilot data, first channel data and a plurality of second channels, respectively A mixer for mixing the data with a corresponding transform code, a signal mixer for generating the converted signals, an adder for adding the converted signals, a carrier frequency mixed with the signal added by the adder, and a mixer for outputting the mixed signal to the antenna Equipped.

In order to achieve the above another object, the wireless receiver according to the present invention for receiving a radio signal in a radio interlocking device for radio interworking the switching system is a radio signal received from an external antenna by mixing an intermediate frequency, included in the radio signal A mixer for recovering the original signal by removing the carrier frequency, and a signal mixer for extracting pilot data, a plurality of first channel data, and second channel data by mixing codes corresponding to each channel to the original signal restored by the mixer. And decoding each of the plurality of first channel data and the second channel data with a predetermined decode to correct an error, outputting the plurality of error corrected first channel data as a plurality of traffic data, and outputting the error corrected second channel. An FEC decoding section for outputting data as order wire data is provided.

Hereinafter, a wireless transmitter / receiver in a wireless interworking apparatus according to the present invention will be described with reference to the accompanying drawings.

2 is a view schematically showing a radio transmitter in a wireless interworking device according to the present invention. In the wireless interworking apparatus according to the present invention, the radio transmitter includes an interleaving unit 48, an FEC coding unit 50, a signal mixing unit 58, an adder 52, a mixer 54, and an oscillator 56. .

Referring to FIG. 2, the interleaving unit 48 performs an order of the order wire data and the first and second traffic data received from the order wire channel OW_CH and the first and second traffic channels T_CH1 and T_CH2. Convert. In addition, the interleaving unit 48 outputs the data for each channel, in which the order is converted, to the error correction unit 50 as interleaved order wire data and interleaved first and second traffic data. In this way, when interleaving the transmission data for each channel, even if a data error occurs continuously during transmission, the receiver recognizes that a data error occurs randomly. That is, recovery of error data becomes easy. Here, the first and second traffic channels T_CH1 and T_CH2 are channels through which actual data (eg, voice data) is transmitted after a communication channel between subscribers is formed. The order wire channel OW_CH may be used as an emergency channel, for example, as a data transmission channel until a communication channel between subscribers is completely formed.

The Forward Error Correction (FEC) coding unit 50 outputs interleaved first and second traffic data output from the interleaving unit 48 as first and second channel data by a convolution code. In addition, the FEC coding unit 50 codes the interleaved order wire data with a convolution code and outputs the third channel data. In this manner, the FEC coding unit 50 properly codes the received data with a convolution code, thereby facilitating error correction in the wireless receiver of the other subscriber.

The signal mixer 58 generates mixed signals by mixing pilot data and first to fourth conversion codes PN1 to PN4 corresponding to each of the first to third channel data from the pilot channel P_CH. . As such, the signals in which the first to fourth conversion codes PN1 to PN4 are mixed in the wireless transmitter are the first to fourth restoration codes PN1 to PN4 corresponding to the first to fourth conversion codes PN1 to PN4, respectively. The original signal can be restored by. Here, the pilot data is a channel through which a synchronization signal for synchronizing each channel is transmitted. In more detail, the signal mixer 58 is implemented as the second to fifth mixers 40 to 46.

The second mixer 40 mixes the first converted code PN1 and the pilot data to convert the pilot data.

The third and fourth mixers 42 and 44 mix the second and third conversion codes PN2 and PN3 with the first and second channel data, respectively, to convert the first and second channel data.

The fifth mixer 46 mixes the fourth code PN4 and the third channel data to convert the third channel data.

Subsequently, the adder 52 adds the converted signals output from the second to fifth mixers 40 to 46.

Oscillator 56 generates a carrier frequency fc for wireless transmission of the signal added in adder 52.

The first mixer 54 mixes the carrier frequency fc with the signal added by the adder 52.

As such, the mixed signal in the first mixer 54 is wirelessly transmitted to the subscriber connected via an external antenna.

3 is a view schematically showing a wireless receiver in a wireless interworking device according to the present invention. In a wireless interworking device according to the present invention, the radio receiver includes a deinterleaving unit 68, an FEC decoding unit 70, a signal mixer 78, a first mixer 74, and an oscillator 76.

Referring to FIG. 3, the oscillator 76 generates an intermediate frequency fi for removing a carrier frequency fc included in a radio signal received from an external antenna.

The first mixer 74 mixes the intermediate frequency fi generated by the oscillator 76 and the signal received from the external antenna to remove the carrier frequency included in the radio signal received from the external antenna. At this time, the signal output from the first mixer 74 is data to which pilot data, first and second traffic data, and order wire data are added.

The signal mixer 78 mixes the first to fourth restoration codes PN1 ′ to PN4 ′ corresponding to each channel to the signal generated by the first mixer 74, thereby pilot data and the first to third channels. Extract the data. Here, the first and second channel data are data restored by the FEC decoding unit 70 and the deinterleaving unit 68 as first and second traffic data through error correction and deinterleaving processes, respectively. In addition, the third channel data is data restored by the FEC decoding unit 70 and the deinterleaving unit 68 as order wire data through an error correction and deinterleaving process. In more detail, the signal mixer 78 is implemented with second to fifth mixers 60 to 66.

The second mixer 60 mixes the first restoration code PN1 ′ with the signal output from the first mixer 74, and extracts pilot data from the signal output from the first mixer 74. The extracted pilot data is output through the pilot channel P_CH. That is, the first restoration code PN1 ′ is a code corresponding to the first conversion code PN1 illustrated in FIG. 2, and corresponds to a signal in which pilot data, order wire data, and first and second traffic data are mixed. By mixing one restoration code PN1 ', only pilot data can be extracted.

The third and fourth mixers 62 and 64 mix the signals output from the first mixer 74 with the second and third restoration codes PN2 'and PN3', respectively, and thus output from the first mixer 74. The first and second channel data may be extracted from the signal to be used.

The fourth mixer 66 may mix the fourth restoration code PN4 'with the signal output from the first mixer 74 to extract third channel data from the signal output from the first mixer 74. .

Subsequently, the FEC decoding unit 70 corrects an error present in the first to third channel data by decoding the first to third channel data output from the signal mixing unit 78 using Viterbi decode. . The first to third channel data error corrected by the FEC decoding unit 70 are output to the deinterleaving unit 68. That is, the FEC decoding unit 70 performs error correction by the wireless receiver itself using Viterbi decode.

The deinterleaving unit 68 deinterleaves the error corrected first and second channel data from the FEC decoding unit 70 and arranges them in the original data order. As such, the deinterleaved signal is output as first and second traffic data through the first and second traffic channels T_CH1 and T_CH2, respectively. In addition, the deinterleaving unit 68 deinterleaves the error corrected third channel data from the FEC decoding unit 70 and arranges the data in the original data order. As such, the deinterleaved signal is output as order wire data through the order wire channel OW_CH.

As described above, in the case of using a radio transmitter including an interleaving unit 48 and an FEC coding unit 50 and a radio receiver including the deinterleaving unit 68 and the FEC decoding unit 70 in the radio interworking device, Transmission errors can be effectively reduced at high speeds. For example, if the transmission speed is changed to 256, 512 and 1024 kbps, and the signal strength is -70 dBm or -90 dBm, the transmission error rate is 10 ^-7 or 10 ^-8 at 256 kbps. In this case, the result is similar to that of the conventional transmission error rate.

When the transmission rate is 512kbps, the conventional wireless interworking device has a transmission error rate of 10 ^-5 to 10 ^-6 , but the wireless interworking device according to the present invention has a transmission error rate of 10 ^-7 . The transmission error rate is improved by about 10 ^-2 .

In addition, when the transmission rate is 1024kbps, the conventional wireless companion device has a transmission error rate of 10 ^-4 to 10 ^-5 , but the wireless companion device according to the present invention has a transmission error rate of 10 ^-6 . That is, the transmission error rate is improved by about 10 ⁻² compared with the conventional wireless companion device.

As described above, when the wireless interlocking device according to the present invention is used in the switching system, the transmission error rate can be effectively reduced at higher speed.

As described above, the radio interworking apparatus for radio interworking of the switching system according to the present invention includes a radio transmitter including an interleaving unit 48 and an FEC coding unit 50, a deinterleaving unit 68 and an FEC decoding unit ( Through the wireless receiver comprising a 70) it is possible to effectively reduce the transmission error rate of the wireless line during high-speed transmission, it is possible to improve the reliability of the switching system.

Claims (4)

A wireless transmitter for transmitting a radio signal through an external antenna in a wireless interworking device for wirelessly interworking a switching system, FEC (Forward Error Correction) which codes the order wire data and the plurality of traffic data with a predetermined code, and outputs the coded order wire data as the first channel data and the coded plurality of traffic data as the plurality of second channel data, respectively. Coding unit; A signal mixer for mixing pilot data, the first channel data, and the plurality of second channel data with corresponding conversion codes to generate converted signals; An adder for adding the converted signals; And And a mixer for mixing a carrier frequency to the signal added by the adder and outputting the mixed signal to the antenna. The interleaving unit of claim 1, wherein the wireless transmitter converts an order of each of the order wire data and the plurality of traffic data and outputs interleaved order wire data and the interleaved plurality of traffic data to the error correction unit, respectively. A wireless transmitter in a wireless interlocking device for wirelessly interworking a switching system, characterized in that it further comprises. In the wireless receiver for receiving a radio signal in a wireless interlocking device for wirelessly interworking a switching system, A mixer which mixes an intermediate frequency with a radio signal received from an external antenna and restores an original signal by removing a carrier frequency included in the radio signal; A signal mixer for mixing pilot codes, a plurality of first channel data, and second channel data by mixing codes corresponding to each channel to the original signal restored by the mixer; And Decode each of the plurality of first channel data and the second channel data with a predetermined decode to correct an error, output the plurality of error corrected first channel data as a plurality of traffic data, and output an error corrected second And a forward error correction (FEC) decoding unit for outputting channel data as order wire data. The wireless interworking apparatus of claim 3, further comprising a deinterleaving unit for deinterleaving the data output from the FEC decoding unit if the data output from the FEC decoding unit are interleaved data. receiving set.