KR101287496B1 - Ground wave mobile isdb-t receiver for vehicles - Google Patents

Abstract

The present invention relates to a diversity acquisition method of a terrestrial mobile ISD-T receiver for a vehicle, and more particularly, to a space-time diversity algorithm based on ISDB-T, which ensures stable broadcasting reception even in a high-speed mobile environment in a city. It relates to a vehicle terrestrial mobile DMB receiving apparatus used.
Diversity acquisition method for a vehicle terrestrial mobile ISDB-T receiving apparatus according to the present invention by transmitting two transmission signals to the other antenna using two adjacent antennas and receiving the received signal, and through the received signal Estimating a channel and inputting estimated channel coefficients to a maximum likelihood detector and a signal combiner, creating an estimated signal using the estimated channel coefficients in the signal combiner, and inputting the estimated channel coefficients to the ML detector; And detecting the signal by the maximum likelihood estimation through the estimated channel coefficient and the estimated signal in the ML detector.

Description

Diversity acquisition method of vehicle terrestrial mobile ISD-T receiver {GROUND WAVE MOBILE ISDB-T RECEIVER FOR VEHICLES}

The present invention relates to a diversity acquisition method of a terrestrial mobile ISD-T receiver for a vehicle, and more particularly, to a space-time diversity algorithm based on ISDB-T, which ensures stable broadcasting reception even in a high-speed mobile environment in a city. It relates to a vehicle terrestrial mobile DMB receiving apparatus used.

Orthogonal Frequency Division Multiplexing (OFDM) transmission technology is currently considered as a standard in various wireless networks due to the advantage of efficient transmission in a multipath fading channel environment.

In particular, it is used as a standard for terrestrial digital multimedia broadcasting such as wireless LAN standards such as IEEE802.11a and HIPERLAN / 2, digital audio broadcasting (DAB), digital video broadcasting (DVB), and integrated services digital broadcasting (ISDB).

The core of the ISDB is ISDB-S (satellite broadcasting), ISDB-T (terrestrial wave), ISDB-C (cable) and 2.6 GHz band mobile broadcasting. Based.

ISDB-T DMB (1 Seg) terminal, a Japanese digital terrestrial broadcasting standard, is a mobile broadcasting service device for terrestrial digital TV broadcasting using only one fixed frequency segment of 13 frequency segments.

The Japanese Broadcasting License mandates retransmission of fixed TV receiver-only programs to DMB terminals in real time, and uses BST (Band Segmented Transmission) OFDM based on multi-carrier transmission.

This ISDB-T can implement 1 digital TV or 3 SD TVs in 6Mhz bandwidth to enable multi-channel broadcasting.It uses OFDM-based transmission technology and time interleaving technology to provide multipath and noise noise. It can cope with (Impulse Noise) and shows some good performance even in mobile receiving environment.

However, the ISDB-T DMB terminal has a structure vulnerable to multipath fading and interference environment due to the characteristics of the mobile mobile terminal.

In other words, since ISDB-T DMB terminal is receiving while moving, deep fading that cannot be received for a long time due to problems such as multipath fading and shadowing caused by buildings and tunnels in urban areas. You can fall into the situation.

Therefore, there is a problem that it is difficult to satisfy the quality of service (Qos) in the high-speed mobile environment by the OFDM + time interleaving method used to improve the reliability.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and the diver of received signals by exchanging and utilizing DMB received signal information received between adjacent ISDB-T receiving apparatuses by using a Bluetooth method, for example. The purpose of the present invention is to provide a terrestrial mobile ISDB-T receiver and a diversity acquisition method for a vehicle capable of receiving broadcasts by acquiring diversity and ensuring a stable signal-to-noise ratio (SNR) of a received signal. .

In accordance with an aspect of the present invention, a terrestrial mobile ISDB-T receiver for a vehicle includes a tuner for tuning and amplifying an IF signal when an RF signal, which is a digital broadcast signal, is received and outputted;

An OFDM demodulator for demodulating the IF signal output from the tuner to generate a TS (Transport Stream) packet and outputting the same;

A decoder / demultiplexer for decoding and demultiplexing the TS packets to output audio and video signals, respectively;

An audio decoder for decoding the audio signal and outputting the audio signal; And

And a video decoder for decoding the video signal, generating an image, and outputting a video.

)를 수신하는 단계;In addition, the diversity acquisition method of a vehicle terrestrial mobile ISDB-T receiver according to an embodiment of the present invention transmits and receives a transmission signal (y ₁ , y ₂ ) to a counterpart antenna twice using two adjacent antennas. signal(

Receiving;

)를 ML 검출기(Maximum Likelihood Detector)와 신호 결합기(signal combiner)에 입력하는 단계;A channel coefficient estimated by estimating a channel through the received signal;

) Into an ML Like (Maximum Likelihood Detector) and a signal combiner;

)를 통해 추정 신호(

)를 만들어 ML 검출기에 입력하는 단계; 및The channel coefficient estimated by the signal combiner (

Through the estimated signal (

) And input into the ML detector; And

와 추정 신호

를 통해 최대우도 추정에 의해 신호(

)를 검출하는 단계를 포함하여 구성된다.Estimated Channel Coefficients in the ML Detector

And estimated signal

Signal by maximum likelihood estimation through

) Is detected.

According to the above-mentioned means of solving the problem, the DMB received signal information received between the adjacent ISDB-T receiving apparatuses is exchanged and utilized, for example, by using a Bluetooth method to obtain diversity of the received signal and thereby stable reception. The SNR of the signal can be guaranteed to ensure seamless broadcast reception.

1 is a block diagram of an ISDB-T receiving apparatus according to an embodiment of the present invention;
2 is a model for modeling space-time block diversity according to an embodiment of the present invention;
3 is a comparison graph of a signal-to-noise ratio and a bit error rate according to the prior art and the embodiment of FIG. 2;
Figure 4 is a product picture of the ISDB-T receiver produced by the embodiment of the present invention,
5 is a circuit for implementing a remote control function in the ISDB-T receiving apparatus shown in FIG.

Hereinafter, the configuration and operation of the present invention will be described with reference to the accompanying drawings.

1 is a block diagram of an ISDB-T receiving apparatus according to an embodiment of the present invention.

As shown, the ISDB-T receiver 100 is an RF signal processing means 110, the tuner 111, OFDM demodulator 112, decoder / demultiplexer 113, audio decoder 114, video decoder 115 And a CPU 123, a storage unit 122, an input / output unit 121, and an IF communication unit 124 as the control unit 120, the RF signal processing unit 110 and the control unit ( 120 is connected to the system bus 130.

Here, for example, the reception frequency is a UHF band of 470MHz ~ 770MHz, the antenna impedance is 50kHz, the voltage is 12 / 24V combined to power the vehicle (car, truck).

When the tuner 111 receives an RF signal (digital broadcast signal) having a reception frequency of 470MHz to 770MHz through an antenna (not shown), the tuner 111 outputs the signal to the OFDM demodulator 112 by tuning and amplifying the signal to an IF signal. .

The OFDM demodulator 112 receives and demodulates the IF signal output from the tuner 111 and outputs a TS (Transport Stream) packet to the decoder / demultiplexer 113.

The decoder / demultiplexer 113 decodes and demultiplexes the TS packet to separate an audio and video signal and outputs the same to the audio decoder 114 and the video decoder 115, respectively.

In particular, the audio signal is stereo processed using AAC (Advanced Audio Coding) technique, and main and sub sound output processing and volume are processed in 24 steps during multicasting.

The audio decoder 114 decodes the audio signal and outputs the audio signal through a speaker and through stereo audio.

The video decoder 115 decodes a video signal, generates an image, and sends the image to an LCD panel for display.

The display size of the video signal is, for example, ITU.R601 / 656, RGB888-24 bit QVGA (320x240), WQVGA (480x272) and the like.

In addition, the video decoder 115 processes bitmap fonts for display fonts such as characters, broadcast station names, and program information, and includes channel numbers, broadcast station names, program names (broadcast times), program content details, lists, and the like. To be processed and displayed on the LCD panel.

As such, the RF signal processing means 110 that performs signal and data processing communicates with the control means 120 and the system bus 130.

The CPU 123 of the control unit 120 operates the operating system in the storage unit 122 and performs overall control to process the received signal to play the multimedia file according to the operating system.

The storage unit 122 includes a RAM 122c as a main memory, a ROM 122b for storing fonts, and an NVRAM 122a as a nonvolatile memory.

The ISDB-T receiving apparatus 100 performs IF communication with the external remote controller 200 through the input / output unit 121, and the remote controller signal is processed by the IF communication unit 124 to select a channel from the remote controller and voice. The size (volume) adjustment and the EPG (Electronic Program Guide) signal may be received and processed by the ISDB-T receiver 100.

FIG. 2 illustrates a model of space-time block diversity according to an embodiment of the present invention, which models space-time block diversity (STBC) using two transmission antennas.

Since the antenna applied to the portable DMB terminal, that is, the ISDB-T receiver 100 has a non-directional characteristic, the SNR gain is lower than that of the directional antenna, and because the antenna operates at a height of about 1 m from the ground, the multipath effect due to the multipath signal ( multipath effect, i.e., the signal passes through several different paths and delays a little, reaching the antenna, so that the reception field becomes stronger or weaker by interference.

As a result, the reception sensitivity changes according to the movement direction of the reception device.

Accordingly, FIG. 2 proposes a diversity scheme that can reliably receive an OFDM signal.

First, at the time of transmission, the transmission signals y ₁ and y ₂ are transmitted to the counterpart antennas 140b and 140a twice using the two antennas 140a and 140b according to the rule of Equation 1 below.

At the next reception, the received signals x ₁ and x ₂ are received according to the following Equation 2 to maximize the SNR of the received signal.

)는 ML 검출기(Maximum Likelihood Detector)(142)와 신호 결합기(signal combiner)(141)에 입력되고, 상기 신호 결합기(141)는 상기 추정된 채널 계수(

)를 통해 추정 신호(

)를 만들어 ML 검출기(142)에 입력한다.The channel is estimated through the received signal having the maximized SNR, and the estimated channel coefficient (

) Is input to the maximum likelihood detector (142) and signal combiner (141), the signal combiner 141 is the estimated channel coefficient (

Through the estimated signal (

) Is input to the ML detector 142.

와 추정 신호

를 통해 최대우도 추정에 의해 신호(

)를 검출한다.The ML detector inputs estimated channel coefficient

And estimated signal

Signal by maximum likelihood estimation through

).

As such, the neighboring ISDB-T receiving apparatuses 100 exchange the received DMB received signal information with each other by using a Bluetooth method and utilize the same, thereby obtaining diversity to reliably receive the OFDM signal, and thereby Cooperative reception may be performed using the adjacent ISDB-T receiving apparatus 100 to ensure stable SNR of the received signal and seamless broadcast reception.

At this time, if the receiving quality is not good by exchanging the data information which is received and decided by itself, it can be adopted by changing the received data with better quality of the other party or by merging the two by using the channel information of the other party. Higher diversity can be obtained than the selective adoption, which can be seen by the graphs described below.

3 is a comparison graph of the signal-to-noise ratio according to the conventional embodiment and the embodiment of FIG. 2.

As shown, the bit error rate (BER) is 10 ⁻³ when the SNR is 30 dB in a single input single output (SISO) environment of the existing single antenna.

In addition, when the antenna transmission diversity of the Alamouti method of the conventional selective adoption is applied, the bit error rate is 10 ^-5 when the SNR is 30 dB, which is about 6 dB of gain compared to the conventional SISO environment. Can be.

In the case of using two pieces of reception information by using channel information of the other party through the maximum ratio combining (MRC) method according to the present invention, it can be seen that the BER is much reduced even when the SNR is relatively smaller than the conventional SISO environment or the Alamouti method. have.

4 is a product picture of the ISDB-T receiver manufactured according to the embodiment of the present invention, wherein the RF signal processing means 110, the control means 120, and a PCB equipped with a remote controller implementation circuit 150 to be described later ( The power terminal 420, the RGB video ports 430, 440, 450, the antenna port 460, and the remote control sensor (not shown) are exposed to the outside of the aluminum case 410 with the aluminum case 410 embedded therein. to be.

5 is a circuit for implementing a remote control function in the ISDB-T receiver shown in FIG.

As illustrated, the remote controller implementation circuit 150 includes a microcontroller 151, a diode D1, a filter circuit 152, an oscillator distribution 153, a microcomputer 154, and first and second ports 155 and 156. It is configured by.

The power supply VDD is supplied to the microcontroller 151 through pin 1 of the microcontroller 151. At this time, the diode D1 connected to the remote control power supply VCC blocks the reverse current of the remote control power supply VCC. (C1, C2) to block the over-power is supplied to the microcontroller 151 with the filter circuit unit 152 is configured in parallel connection.

When the IR wireless signal IR_SIGNAL of the external remote controller 200 is received through pin 17 of the microcontroller 151, the microcontroller is synchronized with the clock pulse 12C_CLK of pin 11 and according to the power signal Power_On of pin 15. 151 performs an ON / OFF and reset function.

Therefore, as the infrared wireless signal IR_SIGNAL of the remote controller 200 is received, the microcontroller 151 receives the external signal EX_INTO # such as volume control and channel change through pin 14 and transmits data through pin 13. 12C_DATA).

The microcontroller 151 oscillates and multiplies the frequency by controlling the oscillator distribution unit 153 consisting of the crystal oscillator (X1) and the connection of the two capacitors (C3, C4), the external volume such as the received volume control, channel change According to the signal EX_INTO #, the terminal channel is changed and the volume of the speaker is adjusted through the microcomputer 154.

In addition, the terminal circuit and the data control command are executed through the first port 155 and the second port 156 connected to the microcomputer 154. At this time, the first and second ports 155 and 156 receive power VDD. It operates while maintaining ON state.

100: ISDB-T receiver 110: RF signal processing means
111: tuner 112: OFDM demodulator
113: Decoder / Demultiplexer 114: Audio Decoder
115: video decoder 120: control means
130: system bus 150: remote control implementation circuit
151: microcontroller 152: filter circuit
153: oscillation body distribution 154: microcomputer
200: remote control

Claims (6)

delete delete delete By using two adjacent antennas 140a and 140b, the transmission signals y ₁ and y ₂ are transmitted to the other antennas 140b and 140a two times.

Receiving;
A channel coefficient estimated by estimating a channel through the received signal;

) Into the ML Like (Maximum Likelihood Detector) 142 and the signal combiner (141);
The channel coefficient estimated by the signal combiner 141

Through the estimated signal (

Create) and input it to the ML detector 142; And
Estimated channel coefficients in the ML detector 142

And estimated signal

Signal by maximum likelihood estimation through

Diversity acquisition method for a vehicle terrestrial mobile ISDB-T receiving apparatus comprising the step of detecting. delete delete

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