KR100360490B1 - Wireless communication method and apparatus thereof - Google Patents

Abstract

PURPOSE: A wireless communication method and an apparatus thereof are provided to reduce a time delay by using a circular polarized wave antenna, thereby capable of transmitting data in speed. CONSTITUTION: Transmission and reception antennas are constructed by a right-handed rotation circular polarized wave antenna(11) and a left-handed rotation circular polarized wave antenna(12). An antenna switch(13) switches the right-handed rotation circular polarized wave antenna(11) and the left-handed rotation circular polarized wave antenna(12) according to a predetermined switch control signal. A transmission unit(100) transmits a predetermined switch data pattern by using repeatedly the right-handed rotation circular polarized wave antenna(11) and the left-handed rotation circular polarized wave antenna(12) at a point of time that a communication is performed at first. A reception unit(200) receives data transmitted from the transmission unit(100) by using repeatedly the right-handed rotation circular polarized wave antenna(11) and the left-handed rotation circular polarized wave antenna(12). The reception unit(12) produces a switch control signal in order to be connected an antenna having a low fault rate between the received data and a predetermined antenna switch data pattern among two antennas(11,12) and applies the switch signal to the antenna switch(13).

Description

Wireless communication method and device

The present invention relates to a method and apparatus for transmitting and receiving indoor high-speed wireless communication. In particular, the present invention relates to an indoor high-speed data transmission method by using a right-turning circular polarization antenna and a left-turning circular polarization antenna as a transmitting / receiving antenna to reduce the time delay of received radio waves. It relates to a wireless communication transmission and reception method and apparatus.

As the information society moves into a full-fledged information society, the information transfer between the central computer and the personal personal computer in the office is rapidly progressing in upgrading and speeding up information such as image data rather than the simple data transmission. As a result, the speed of LAN (Locla Area Network) is getting higher, and after that, it is expected to enter the era of Asynchronous Transfer Mode (ATM) serviced to terminals up to 155 Mbps.

On the other hand, most personal personal computers are now desk-top, but mobile notebooks are expected to be mainstream in the future. As a result, the spread of indoor wireless LANs is being made gradually.

However, indoor propagation environment inevitably causes delay spread of radio waves due to multiple reflections of radio waves caused by indoor walls, desks, floors, and cabinets, and thus, inter-symbol interference. ) Phenomenon occurs. This will be described in more detail with reference to FIGS. 1 to 4 as follows.

FIG. 1 shows a path through which radio waves radiated from a transmission antenna Tx are propagated to a reception antenna Rx indoors. Here, the path ① is a direct pi, the path ② is a single reflection pi, and the path ③ is a two reflected waves.

FIG. 2 shows an impulse string received at the reception antenna Rx when an impulse is transmitted at the transmission antenna Tx. The reason why such impulse heat is received is because the radio wave is continuously received as time delay due to multiple reflection in the wall or the like as in FIG. Here, impulse ① is an impulse received along path ①, impulse ② is an impulse received along path ②, and impulse ③ is an impulse received along path ③.

When continuous data is transmitted from the transmitting antenna (Tx), the delay of the impulse causes ISI phenomenon in which the first data affects the next data. Accordingly, the maximum transmittable data rate is closely related to the characteristics of the multiple reflection wave.

On the other hand, the polarization of the radio waves in the antenna is determined by the structure and the direction of the antenna. As shown in FIG. 3, the polarized wave propagated while the electric field rotates in the right direction perpendicular to the propagation direction of the electric wave is rotated in the right direction. It is called a left turn circular polarization.

As shown in FIG. 4, the reflection characteristic of the circularly polarized wave changes the rotation direction of the premise when incident on the conductor surface. In addition, when the incident angle is small even when incident on the reflective surface of the general material rather than the conductor, the rotation direction is changed. On the other hand, when the polarization between the transmitting antenna and the receiving antenna is different, the size of the received signal is received by a few tens of decibels (dB).

In FIG. 1, if the transmitting antenna Tx uses the right rotating circularly polarized antenna and the receiving antenna Rx also uses the right rotating circularly polarized antenna, the impulse sequence of FIG. 2 will be different. That is, the impulse ① received along the path ① is received as it is, but since the impulse ② received along the path ② is reflected once on the wall, the received power received through the right-turned circular polarization antenna is converted into a left-turned circular polarization antenna. Will be very small. On the other hand, since the impulse ③ received along the path ③ is reflected twice, the right-handed circularly polarized wave is received as it is.

In general, the reflected wave received next to the direct wave ① is a reflected wave received by being reflected once through a short path. In the case of linear polarization without polarization change caused by reflection, the received power is higher than the direct wave. Therefore, the effect on the time delay characteristics of the indoor channel is very large.

That is, in case of transmitting data at low speed, bit error rate is determined by reception power rather than inter-symbol interference of adjacent data, but in case of transmitting data at high speed, interference between adjacent symbols is larger than the received power. Compared with the bit error rate.

In order to solve this problem, a method of eliminating interference between symbols by using a spread spectrum method or a multicarrier modulation method which is insensitive to time delay in a modulator or a waveform equalizer is used. However, in this case, the transceiver structure is complicated and there are many difficulties in signal processing.

Accordingly, an object of the present invention is to provide a method and apparatus for transmitting and receiving indoor high speed wireless communication which enables high speed data transmission by using a circularly polarized antenna in an indoor high speed wireless communication system to solve the above problems. .

In addition, an object of the present invention is to provide a method and apparatus for indoor high-speed wireless communication using and polarization diversity to prevent the direct wave is blocked by the obstacles and the like, the reception power is sharply lowered.

In order to achieve the above object, the indoor high-speed wireless communication transmitting and receiving method according to the present invention is an indoor high-speed wireless communication transmitting and receiving device having a right-turning circular polarization antenna and a left-turning circular polarization antenna as a transmission / reception antenna.

Transmitting a predetermined antenna switching data pattern by repeatedly using the right-turning circularly polarized antenna and the left-turning circularly polarized antenna at the time when communication is first performed at a transmitting station;

Receiving process of receiving the data transmitted through the transmission process by using the right-turning circular polarization antenna and the left-turning circular polarization antenna repeatedly at the receiving station:

And a switching process of switching the two antennas so that an antenna having a low error rate between the data received through the receiving process and the predetermined antenna switching data pattern is connected.

Indoor high speed wireless communication transmission and reception apparatus according to the present invention to achieve the above objects

Transmission and reception antenna consisting of a right rotating circular polarized antenna and a left rotating circular polarized antenna;

An antenna switching switch for switching between the right rotating circularly polarized antenna and the left rotating circularly polarized antenna according to a predetermined switching control signal;

A transmitting unit for transmitting a predetermined antenna switching data pattern by repeatedly using the right-turning circularly polarized antenna and left-turning circularly polarized antenna at the time when communication is first performed at a transmitting station:

A receiving station repeatedly receives the data transmitted from the transmitter by repeatedly using the right-turning circular polarization antenna and the left-turning circular polarization antenna, and has a low error rate between the received data of the two antennas and the data pattern for switching the predetermined antenna. And a receiving unit generating a switching control signal for connecting the antenna to the antenna switching switch.

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

5 is a block diagram showing the indoor high-speed wireless communication transceiver according to the present invention, the transmission and reception antenna consisting of a right-turning circular polarization antenna 11 and a left-turning circular polarization antenna 12, a right-turning circular polarization antenna 11 and left turn An antenna switching switch 13 for switching the circularly polarized antenna 12 in accordance with a predetermined switching control signal, and a right-turning circular polarized antenna 11 with a predetermined antenna switching data pattern at the time when communication is first performed at the transmitting station. Data transmitted from the transmitting unit 100 by repeatedly using the left rotating circular polarized antenna 12 and the transmitting station 100 using the right rotating circular polarized antenna 11 and the left rotating circular polarized antenna 12 at the receiving station. Switching control for receiving an antenna having a low error rate between the received data of the two antennas 11 and 12 and a predetermined antenna switching data pattern Generating a call to be made up of an antenna change-over switch 13, the receiver 200, which roinga.

Here, the transmitter 100 includes a baseband signal processor 21, a controller 23, a data encoder 24, a demodulator 25, an intermediate frequency amplifier 26, a mixer 27, a local oscillator 28, and a band. It consists of a filter 29, a high output amplifier 30 and a circulator 14, and the receiver 200 includes a circulator 14, a band filter 15, a low noise amplifier 16, a mixer 17, a local oscillator 18 ), An intermediate frequency amplifier 19, a demodulator 20, a baseband signal processor 21, a data encoder 22 and a controller 23.

The operation and effect of the present invention will be described based on the configuration of FIG.

In general, a wireless communication transceiver includes a base station connected to a main computer and a remote station connected to a personal PC. Both stations have a structure similar to that of FIG. For convenience, the base station is called a transmitting station and the remote station is called a receiving station.

In the present invention, the diversity of the right rotating circularly polarized antenna 11 and the left rotating circularly polarized antenna 12 is used as a transmission / reception antenna in case a direct wave is not received. At this time, the two antennas 11 and 12 are connected to the antenna switching switch 13 for polarization diversity.

First, referring to the transmitter 100, the data input to the baseband signal processor 21 is digitally modulated by an arbitrary modulation scheme in the demodulator 25, amplified by an intermediate frequency (IF) amplifier 26, and then mixed again. 27) and the local oscillator 28 is frequency upconverted. The frequency up-converted signal is filtered only by the frequency components of the desired band in the band filter 29 and amplified by the high output amplifier 30 and then connected to the antenna selected by the antenna switching switch 13 through the circulator 14.

Next, referring to the receiver 200, the modulated signal input through the antenna selected by the antenna switching switch 13 is input to the band filter 15 through a circulator 14 to filter only frequency components of a desired band. do. The output signal of the bandpass filter 15 is amplified by a low noise amplifier (: 16) and then frequency downconverted by the mixer 17 and the local oscillator 18. The frequency downconverted signal is amplified again by an intermediate frequency amplifier 19 to demodulate data in the demodulator 20. The demodulated data in the demodulator 20 is time-synchronized by the baseband signal processor 21 and then output as complete data.

On the other hand, the transmitting station transmits the antenna switching data pattern determined from the data encoder 24 through the transmitter 100 at the initial time of communication. At this time, the transmission using the right rotating circularly polarized antenna 11, and the other transmission through the left rotating circularly polarized antenna 12.

Similarly, the receiving station repeatedly uses the right rotating circular polarization antenna 11 and the left rotating circular polarization antenna 12 to receive data through the receiving unit 200, and the data encoder 22 receives the received data and the predetermined antenna. The switching data pattern is compared and the comparison result is supplied to the control unit 23. On the basis of the results sent from the data decoder 22, the control unit 23 calculates an error rate between a predetermined antenna switching data pattern and received data when two polarized antennas are used, so that an antenna having a low error rate is connected. The control signal is sent to the antenna switching switch 13 to determine the antenna to be used.

Such polarization switching of the antenna must be made before the communication starts if the remote station changes its channel characteristics due to a change in position or sudden appearance of an obstacle. This greatly reduces the time delay by the use of circular polarization. In addition, even when the direct wave is not received by the obstacles around it, the reception power is lowered. To keep the receiving power constant.

As described above, in the indoor high-speed wireless communication transmitting and receiving method and apparatus according to the present invention, a right-turning circular polarization antenna and a left-turning circular polarization antenna are used as transmission / reception antennas, and data transmitted / received through two antennas and a predetermined antenna switching data pattern By controlling an antenna with a low error rate, the high-speed data can be transmitted by reducing the time delay of the received radio wave.

1 is a diagram showing multiple propagation paths in a room.

2 is a diagram illustrating a received impulse sequence compared to multiple propagation paths.

3 shows a circular rotation polarization.

4 is a diagram showing the reflection characteristics of circular rotating polarization.

5 is a block diagram showing an indoor high-speed wireless communication transceiver according to the present invention.

* Explanation of symbols for main parts of the drawings

11,12 ... right / left rotating circularly polarized antenna 13 ... antenna selector switch

14 ... circulator 15,29 ... band filter

16 ... low noise amplifier 17,27 ... mixer

18,28 ... local oscillator 19,26 ... intermediate frequency amplifier

20,25 ... demodulator 21 ... baseband signal processor

22, 24 ... data encoder 23 ... control unit

100 ... transmitter 200 ... receiver

Claims (2)

(a) transmitting a predetermined antenna switching signal having a predetermined pattern alternately using a right-turning circularly polarized antenna and a left-turning circularly polarized antenna at a time when communication is first performed at a transmitting station; (b) receiving, by a receiving station, the transmitted antenna switching signal by using a right-turning circularly polarized antenna and a left-turning circularly polarized antenna alternately; And (c) comparing the received signals with the antenna switching signal so that an antenna having received a signal having a low transmission error rate among the right rotating circular polarization antenna and the left rotating circular polarization antenna is connected to the receiving station. Wireless communication method characterized in that. An antenna portion comprising a right rotating circular polarized antenna and a left rotating circular polarized antenna A transmitter including a transmitter for transmitting a predetermined antenna switching signal having a predetermined turn at a time point at which communication is first performed by alternately using the right-turning circularly polarized antenna and the left-turning circularly polarized antenna; And An antenna unit including a right rotating circular polarized antenna and a left rotating circular polarized antenna; The antenna switching signal is received using the right rotating circularly polarized antenna and the left rotating circularly polarized antenna alternately, and the received signals are compared with the antenna switching signal to receive a signal having a lower transmission error rate among the two antennas. A receiver for generating a switching control signal for selecting an antenna; And a receiver including an antenna switch for connecting an antenna selected according to the switch control signal to the receiver.