KR20080048564A - Diversity system of terrestrial dmb and method thereof - Google Patents

Abstract

A terrestrial DMB(Digital Multimedia Broadcasting) optimization diversity system and a method thereof are provided to measure receive sensitivity of preliminary antennas connected to another RF processor and switch a received signal to another RF processor and an antenna having the best receive sensitivity if deterioration of receive sensitivity is determined while receiving a broadcasting signal through antennas connected to one RF processor. Plural antennas(111-114) receive terrestrial DMB signals. Two RF(Radio Frequency) processors(131,132) are selectively connected with the plural antennas and classified into reproduction/preliminary RF processors. A first switch(121) connects the reproduction RF processor with one reproduction antenna of the plural antennas, and connects the preliminary RF processor with the rest antennas. Two baseband processors(141,142) are connected to the reproduction/preliminary RF processors to respectively form one group, and classified into reproduction/preliminary baseband processors. A multimedia chip(150) is connected to one baseband processor of the two baseband processors. A second switch(122) selectively connects one baseband processor of the two baseband processors with the multimedia chip.

Description

Terrestrial DMB Optimization Diversity System and Method

1 is a diagram illustrating a general terrestrial DMB 4CH antenna diversity system;

2 is a reception sensitivity and directivity graph of FIG.

3 is a configuration diagram of a terrestrial DMB 4CH antenna diversity system for reducing diver seat time;

4 is a diagram illustrating a relationship between terrestrial DMB reception sensitivity and BER and FIC_EFC for better understanding of the present invention.

5 is a configuration diagram of a terrestrial DMB 4CH antenna diversity system according to the present invention;

6 is a connection diagram after the diversity of the diversity system shown in FIG. 5;

7 is a table illustrating an ANT_RATE implementation for explaining the principle of operation according to the present invention.

<Description of the symbols for the main parts of the drawings>

111-114: Antenna 121,122: Switch

131, 132: RF processing unit 141, 142: baseband processing unit

150: multimedia chip 160: microcomputer

170: memory

The present invention relates to a terrestrial DMB optimized diversity system and method, and more particularly, an RF processor, two baseband processors, and one multimedia chip when a 4CH glass antenna is used to receive a terrestrial DMB in a vehicle. Therefore, the present invention relates to a terrestrial DMB optimized diversity system and method capable of maintaining good reception sensitivity and minimizing cost by performing diversity.

Diversity means diversity, and communication means various paths through which signals are transmitted.

Diversity having this meaning is intended to prevent reception quality degradation due to fading.

1 is a configuration diagram of a general terrestrial DMB 4CH antenna diversity system, and as shown, a terrestrial DMB receiver for a vehicle commonly uses 4CH glass antennas 1a to 1d of an analog TV.

This is because the reception sensitivity may be improved when a separate terrestrial DMB pole antenna is used, but the appearance of the vehicle is not good, and when the 1CH glass antenna dedicated to the terrestrial DMB is used, the directivity problem cannot be solved.

However, as shown in FIG. 1, any one of the 4CH glass antennas 1a to 1d having good reception sensitivity is connected to the RF processor 3 and the baseband processor 4 through the switch 2 and the multimedia chip 5 By outputting through), it is aesthetically pleasing and can solve the directivity problem as shown in FIG.

However, in the case of FIG. 1, when the reception sensitivity of the receiving glass antenna decreases, it takes about 2.5 seconds to change the channel of the glass antenna by searching for another glass antenna having good reception sensitivity, and it takes 7.5 seconds when changing the maximum 3CH.

That is, the user cannot see the screen for up to 7.5 seconds, which causes great inconvenience.

In order to reduce such diversity time, the RF processor 13a to 13d, the baseband processor 14a to 14d, and the multimedia chips 15a to 15d are connected to each of the glass antennas 11a to 11d as shown in FIG. Diversity system can be configured, but in this case there was a problem that takes too much cost.

The present invention has been made to solve the above problems, while implementing a diversity system using two RF processing units, a baseband processing unit and one multimedia chip, while receiving a broadcast signal through an antenna connected to one RF processing unit. If it is judged that the reception sensitivity is deteriorated, by measuring the reception sensitivity of the preliminary antennas connected to the other RF processing unit, the terrestrial wave can maintain the optimal reception sensitivity while reducing the cost by switching the reception signal to the antenna with the best reception sensitivity and the other RF processing unit. It is an object of the present invention to provide a DMB optimized diversity system and method.

In order to achieve the above object, a terrestrial DMB optimized diversity system according to an embodiment of the present invention includes a plurality of antennas for receiving a terrestrial DMB signal, and two antennas selectively connected to the plurality of antennas and separated into play / preparation. A pair of RF processors, a first antenna for connecting any one of the plurality of antennas to the regenerative RF processor and the plurality of antennas, a first switch connecting the preliminary RF processor and the remaining antennas, and a pair of the regenerative / preliminary RF processors respectively Two baseband processing units which are separated into playback / preparation, a multimedia chip connected to any one of the baseband processing units of the two baseband processing units, and a multimedia chip of any one of the two baseband processing units. It is configured to include a second switch for selectively connecting the;

If it is determined that the reception sensitivity is deteriorated while receiving the broadcast signal through the reproduction antenna, the reception operation is maintained and the reception signal is switched to the antenna having the best reception sensitivity by measuring the reception sensitivity of the antennas connected to the preliminary RF processing unit. In this case, the received signal is transferred in the order of the preliminary RF processor, the preliminary baseband processor, and the multimedia chip.

In addition, the terrestrial DMB optimized diversity method according to an embodiment of the present invention includes a plurality of antennas, a reproduction / preliminary RF processing unit, a reproduction / preliminary baseband processing unit, and a multimedia chip to switch the first and second switches. A diversity method for constructing a path of optimum reception sensitivity;

If the FIC_EFC value is greater than the threshold value based on the FIC_EFC value from the baseband processor, the reception sensitivity of the antenna is determined to be a decrease in reception sensitivity. The first switch maintains the currently connected antenna, and switches the remaining antennas to the preliminary RF processor and the preliminary baseband processor. When the first switch is in operation, the first switch detects an antenna having FIC_EFC <threshold. The rest of the antenna is switched to the preliminary RF processor and the preliminary baseband processor,

The preliminary RF processor and the preliminary baseband processor check the FIC_EFC of the antenna to connect the highest sensitivity antenna, and if the FIC_EFC> threshold of the highest sensitivity antenna is checked, check the FIC_EFC until the antenna having the FIC_EFC <threshold is detected. First, the antenna is connected below the threshold value.

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

First, FIC_EFC will be described to help understand the present invention. FIG. 4 is a diagram illustrating a relationship between terrestrial DMB reception sensitivity and BER and FIC_EFC to help understand the present invention. Terrestrial waves generally have a bit error rate (BER). When this 10E-4 is abnormal, the reception screen is broken or freezes.

However, the BER needs to know a reference signal but can calculate an accurate value, so most terrestrial receivers use a fast information channel_eff flag counter (FIC_EFC) value similar to BER and use it as a reference point for diversity.

As shown in FIG. 4, since FIC_EFC = 6,144 is at the same level as BER = 10E-4, when FIC_EFC is 6,144 or more, diversity is performed to change the antenna to the next antenna.

The FIC_EFC is generally known after decoding by the baseband processor, and since most baseband processors are updated every about 2.5 seconds, it takes about 2.5 seconds when one channel is changed.

 5 is a configuration diagram of a terrestrial DMB 4CH antenna diversity system according to the present invention.

As shown, the antenna 111 to 114, the switches 121 and 122, the RF processing units 131 and 132, the baseband processing units 141 and 142, the memory 170, the multimedia chip 150, and the microcomputer 160 are configured. .

The antennas 111 to 114 receive a DMB signal at 183 MHz, which is a terrestrial DMB frequency band. For example, any one of four antennas 111 is used as a reproduction antenna, and thus, two antennas are provided through the first switch 121. The RF processor 131, 132 is connected to the reproduction RF processor 131, and the remaining three antennas 112, 113, and 114 are connected to the preliminary RF processor 122 through the first switch 121 using the preliminary glass antenna.

Regeneration / preparation of the RF processing units 121 and 122 is alternately replaced as diversity is performed.

The switch is composed of a first switch 121 and a second switch 122, the first switch 121 switches between four antennas 111 to 114 and two RF processors 131 and 132, and the second switch 121 The switch 122 switches between the two baseband processors 141 and 142 and the multimedia chip 150.

The RF processing units 131 and 132 receive the intermediate frequency output from the antennas 111 to 114 to remove the DC component, and the baseband processing units 141 and 142 are connected to the reproduction / preliminary RF processing unit to form one pair, respectively. After receiving the intermediate frequency, it is converted into a digital signal and demodulated into a video signal, an audio signal, and a data signal (baseband signal) and transmitted to the multimedia chip 150.

Here, the video signal is MPEG-4AVC (aka H264) compression standard, the audio signal is MUSICAM, MPEG4 / BSAC, MPEG / Layer 2 technology, the data signal is PAD, NPAD, TDC, MOT, BWS, IP-TUNNING, etc. The description will be followed, and these techniques are already known and will not be described in further detail.

According to an embodiment of the present invention, the memory 170 may be further provided, and the memory 170 may be connected to the baseband processors 141 and 142 to store FIC_EFC values of the baseband processors 141 and 142.

The multimedia chip 150 reproduces baseband signals (video, audio, data signals) output to the baseband processing units 141 and 142 to output audio and video.

The microcomputer 160 switches the first and second switches 121 and 122, and when the FIC_EFC is greater than the threshold value of 6,144, the second switch 122 is switched to the preliminary RF processor 132 and the baseband processor 142. do.

In the above-described configuration, for example, when receiving sensitivity is deteriorated while receiving a broadcast signal through a reproduction antenna 111 connected to one reproduction RF processor 131, spare antennas connected to the preliminary RF processor 132 may be used. The reception sensitivity of the 112, 113, and 114 is measured to switch the received signal to the antenna having the best reception sensitivity (for example, the fourth antenna 114), and the preliminary RF processor 132, the preliminary baseband processor 142, and the multimedia chip ( 150, the received signal is switched, and the RF processor 131 and the remaining glass antennas 111, 112, and 113 switch to a standby state (see FIG. 6).

That is, it can be seen that the received signal received through the first antenna 111 is transmitted to and viewed in the processes of the first RF processor 131, the first baseband processor 141, and the multimedia chip 150 that are currently being reproduced.

At this time, the preliminary second RF processing unit 132 and the second baseband processing unit 142 receive the signals of the remaining second to fourth antennas 112, 113, and 114 ANT_RATE (receive sensitivity ranking according to the comparison of FIC_EFC). = 0) FIC_EFC value is calculated in order to store the value in the memory 170.

At this time, when the sensitivity of the first antenna 111 exceeds the threshold (FIC_EFC = 6,144) (when the reception sensitivity is lowered), the second antenna switch 122 switches to the fourth antenna 114 having the best reception sensitivity. The second baseband processor 142 is connected to the multimedia chip 150.

As a result, as shown in FIG. 6, the received signal is transmitted to the fourth antenna 113, the second RF processor 132, the second baseband processor 142, and the multimedia chip 150.

In more detail, the operation principle according to the above diversity process, if the reception sensitivity of the antenna (111 ~ 114) is based on the FIC_EFC value from the baseband processing unit (141,142), if FIC_EFC> threshold (6,144) It is judged that the reception sensitivity is deteriorated and diversity starts.

At this time, the second switch 122 immediately switches, the first switch 121 maintains the currently connected antenna when the first switch 121 is waiting for operation, and the remaining antennas are switched to the preliminary RF processor and the preliminary baseband processor. do.

The first switch 121 switches the remaining antennas to the preliminary RF processor and the preliminary baseband processor when the first switch 121 is in operation, when an antenna whose FIC_EFC < threshold is detected among the preliminary antennas.

By the operations of the first and second switches 121 and 122, the reproduction / preliminary RF processing unit and the reproduction / preliminary baseband processing unit are alternately changed as shown in FIGS. 5 and 6.

The preliminary RF processing unit and the baseband processing unit detect and connect the FIC_EFC of all the connected antennas basically according to ANT_RATE, and if the highest reception antenna is FIC_EFC> threshold, when the antenna having FIC_EFC <threshold appears. Continue to until FIC_EFC is checked and the fastest antenna is detected and connected.

The preliminary RF processing unit and the baseband processing unit find and connect the highest reception antenna with FIC_EFC <threshold, maintain the connection until the FIC_EFC> threshold of the currently connected antenna, and detect and restart the highest reception antenna when the reception sensitivity is reduced. Connect.

In addition, it is assumed that the electric field has changed after a certain period of time, and the FIC_EFC is checked again to reselect the highest reception sensitivity antenna.

7 is an exemplary ANT_RATE implementation table for explaining the operation principle according to the present invention, it will be described for the diversity operation according to the ANT_RATE.

ANT_RATE = 0 of the currently playing antenna and ANT_RATE = 1,2,3 according to the sensitivity ranking after checking FIC_EFC, and if the FIC_EFC> threshold value (when receiving sensitivity is deteriorated) of the playing antenna, ANT_RATE = Diversity with 1 antenna

The total ANT_RATE is stored in the memory 170 until the end of DMB, and the antenna whose total ANT_RATE is 0 at the end of DMB becomes the first antenna that is played at the beginning of the next DMB, and the FIC_EFC check of the antenna that is not being played at the time of update indicates that the ANT_RATE is 1, It is made in the order of 2,3,0.

In FIG. 7, the pink block represents an antenna connected to the first RF processor 131 and the first baseband processor 141, and the yellow block represents an antenna connected to the second RF processor 132 and the second baseband processor 142. Indicates.

At update 0 when the DMB starts, the first antenna 111 whose previously stored ANT_RATE = 0 becomes a reproduction antenna, and the received signal is transmitted to the first antenna 111, the first RF processor 131, and the first baseband processor 141. It is delivered to the multimedia chip 150 through.

ANT_RATE = 0 of the first antenna 111 being played back in Update 1 and 1,2,3 are results according to the reception sensitivity ranking after FIC_EFC check.

After the reception sensitivity of the first antenna 111 decreases between the update 1 and the update 2, the fourth antenna 114 having ANT_RATE = 1 according to the result of the update 1 is the second RF processor 132 and the second baseband processor. Decoded at 142, the signal is sent to the multimedia chip 150 by the second switch 122 to be reproduced.

At this time, the second antenna 112 with ANT_RATE = 2 is first connected and decoded by the first switch 121 according to the result of the date 1, and the FIC_EFC value is stored, and the third antenna 113 with ANT_RATE = 3. ) Is decoded to store the FIC_EFC value, and finally, the first antenna 111 having ANT_RATE = 0 is decoded to store the FIC_EFC value.

The ANT_RATE of the update 2 becomes ANT_TATE = 3 of the first antenna 111, ANT_RATE = 1 of the second antenna 112, and ANT_RATE = 2 of the third antenna 113 according to the stored FIC_EFC value.

After the reception sensitivity of the fourth antenna 114 decreases between the update 4 and the update 5, the second antenna 112 having ANT_RATE = 1 according to the result of the update 4 is the first RF processor 131 and the first baseband processor. Decoded at 141, the signal is sent to the multimedia chip 150 by the second switch 122 and reproduced.

Before the update 7, the ANT_RATE according to the FIC_EFC comparison between the first antenna 111, the third antenna 113, and the fourth antenna 114 in the second RF processor 132 and the second baseband processor 142 If not, check FIC_EFC in the order of receiving sensitivity in the previous update (ie update 6).

If the FIC_EFC of all the antennas is not checked, if there is an antenna having good reception sensitivity, the second switch 122 is already switched, and the first switch 121 continues until an antenna whose FIC_EFC < threshold is shown. All antennas will be checked.

When the antenna having FIC_EFC < threshold is detected, the antenna is connected to the current reproduction RF processor and the baseband processor, and the first switch connects the remaining antennas to the preliminary RF processor and the baseband processor.

As a result, ANT_RATE = 1 of the fourth antenna 114, and the first antenna 111 and the third antenna 113 that fail to check the remaining FIC-EFC have the memory 170 of the FIC-EFC value of the previous update 6. ), So that the value is compared, so that ANT_RATE = 2 of the first antenna 111 and ANT_RATE = 3 of the third antenna 113.

When the FIC_EFC> threshold value of the fourth antenna 114 being played between the update 10 and the update 11 becomes the FIC_EFC> threshold value, the second RF processor 132 when the remaining first, second and third antennas 111, 112, and 113 also have the FIC_EFC> threshold value. ) And the second baseband processor 142 repeats the FIC_EFC check in the order of the third antenna-> second antenna-> first antenna-> fourth antenna until an antenna having a threshold value or less comes out.

As a result, when the electric field is recovered after repeating the process several times, the fourth antenna 114 which is less than or equal to the threshold is first connected, and the result of the update 11 is stored.

As described above, according to the present invention, a diversity device is implemented using two RF processing units, a baseband processing unit, and one multimedia chip, and reception sensitivity deteriorates while receiving a broadcast signal through an antenna connected to one RF processing unit. If it is determined that the reception sensitivity of the preliminary antennas connected to the other RF processing unit is measured by switching the received signal to the antenna with the best reception sensitivity and the other RF processing unit can reduce the cost while maintaining the optimum reception sensitivity.

Claims (7)

A plurality of antennas for receiving terrestrial DMB signals; Two RF processing units selectively connected to the plurality of antennas and separated into reproduction / preliminary units; A first switch connecting the reproduction RF processor to any one of a plurality of antennas and connecting the preliminary RF processor to the remaining antennas; Two baseband processing units connected to each of the reproduction / preliminary RF processing units and separated into reproduction / preliminary units; A multimedia chip connected to any one of the two baseband processors; It comprises a second switch for selectively connecting the multimedia chip to any one of the baseband processing unit of the two baseband processing, If it is determined that the reception sensitivity is deteriorated while receiving the broadcast signal through the reproduction antenna, the reception operation is maintained and the reception signal is switched to the antenna having the best reception sensitivity by measuring the reception sensitivity of the antennas connected to the preliminary RF processing unit. Terrestrial DMB optimization diversity system, characterized in that the received signal is delivered in order of a preliminary RF processor, a preliminary baseband processor, and a multimedia chip. The method of claim 1, The antenna is a terrestrial DMB optimized diversity system, characterized in that the 4CH glass antenna of the analog TV provided in the glass of the vehicle. The method of claim 1, And a memory connected to the reproduction / preliminary baseband processing unit to store the FIC-EFC value outputted from the baseband processing unit. A diversity method comprising a plurality of antennas, a reproduction / preliminary RF processing unit, a reproduction / preliminary baseband processing unit, and a multimedia chip to form an optimal reception sensitivity path by switching operations of the first and second switches, If the FIC_EFC value is greater than the threshold value based on the FIC_EFC value from the baseband processor, the reception sensitivity of the antenna is determined to be a decrease in reception sensitivity. The first switch maintains the currently connected antenna, and switches the remaining antennas to the preliminary RF processor and the preliminary baseband processor. When the first switch is in operation, the first switch detects an antenna having FIC_EFC <threshold. The rest of the antenna is switched to the preliminary RF processor and the preliminary baseband processor, The preliminary RF processor and the preliminary baseband processor check the FIC_EFC value of the antenna to connect the highest sensitivity antenna, and if the FIC_EFC value of the highest sensitivity antenna is> threshold, the FIC_EFC value <FIC_EFC value until the antenna is detected Terrestrial DMB optimization diversity method characterized in that for connecting the antenna that is less than the first threshold checked after checking. The method of claim 4, wherein ANT_RATE = 1, 2, 3,... In order of receiving sensitivity according to the comparison of the FIC_EFC values. By ranking and determining ANT_RATE = 0 of the currently playing antenna, If the FIC_EFC value of the antenna with ANT_RATE = 0> threshold, the antenna is diversity with an antenna with ANT_RATE = 1, which is a lower priority, and the FIC_EFC value of the antenna that is not being reproduced at the time of updating is checked by And terrestrial DMB optimization diversity method according to the order of antennas of 0 and 0. The method of claim 5, wherein And the FIC_EFC value is totally stored until the end of the DMB, and then the antenna having the total ANT_RATE = 0 at the end is the antenna that is first reproduced when the next DMB signal is received. The method according to claim 4 or 5, The threshold value is 6,144 terrestrial DMB optimization diversity method.

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