KR102246965B1 - Transmitter, receiver and controlling method thereof - Google Patents

Abstract

The transmitting device is started. The transmission device includes a frame generator that generates a plurality of frames each including a preamble symbol and a data symbol, inserts a first pilot into the preamble symbol according to a preset first arrangement pattern, and a second arrangement pattern different from the first arrangement pattern. And a pilot insertion unit for inserting a second pilot into a data symbol and a transmission unit for transmitting a plurality of frames into which the first and second pilots are inserted. Accordingly, a memory required for storing pilots can be reduced, and synchronization can be accurately performed based on an extended number of pilots.

Description

Transmission device, reception device, and control method thereof {TRANSMITTER, RECEIVER AND CONTROLLING METHOD THEREOF}

The present invention relates to a transmission apparatus, a reception apparatus, and a control method thereof, and more particularly, to a transmission apparatus, a reception apparatus and a control method thereof using an OFDM scheme.

In the information society of the 21st century, broadcasting and communication services are entering the era of full-scale digitalization, multi-channelization, broadband and high quality. In particular, as the spread of high-definition digital TVs, PMPs, and portable broadcasting devices has recently increased, there is an increasing demand for digital broadcasting services to support various reception methods.

In response to these demands, the standard group has established various standards to provide various services that can satisfy the needs of users. Accordingly, it is requested to find a way to provide a better service to users through better performance.

In particular, when the channel environment is poor, or in order for a mobile device such as a mobile device to receive information stably, synchronization must be accurately performed. In addition, even when a large amount of information is received, it is necessary that the performance of performing synchronization does not deteriorate. Accordingly, an alternative must be presented to accurately perform synchronization and maintain optimal performance.

The present invention has been devised in accordance with the above-described necessity, and an object of the present invention is to provide a transmitting apparatus, a receiving apparatus, and a control method thereof for improving synchronization performance by increasing the number of pilots inserted into a frame.

According to an embodiment for achieving the above object, a transmission device includes a frame generator for generating a plurality of frames each including a preamble symbol and a data symbol, and a first pilot for the preamble symbol according to a preset first arrangement pattern. And a pilot insertion unit for inserting a second pilot into the data symbol according to a second arrangement pattern different from the first arrangement pattern, and a transmission unit for transmitting the plurality of frames into which the first and second pilots are inserted Includes.

Here, the pilot insertion unit may change the number of the second pilots and the insertion position of the second pilot in proportion to the FFT size of the data symbol.

Further, the FFT size of the data symbol is one of 8K, 16K, and 32K, and the pilot insertion unit inserts 90 second pilots into the data symbol according to the second arrangement pattern when the FFT size is 8K, and the When the FFT size is 16K, 180 second pilots are inserted into the data symbol according to the second arrangement pattern, and when the FFT size is 32K, 360 second pilots are inserted into the data symbol according to the second arrangement pattern. I can.

Further, a storage unit for storing information on the number of second pilots to be inserted and insertion position information for the data symbol having the largest first FFT size among the FFT sizes of the data symbols, wherein the pilot insertion unit comprises: the first When a data symbol having a second FFT size different from the FFT size is input, the number and insertion position information stored in the storage unit are changed according to a ratio between the first FFT size and the second FFT size, and the second FFT size It is possible to determine the number of second pilots to be inserted and the insertion position for the data symbol of.

Here, the first arrangement pattern is a table in which a subcarrier index indicating a position in which the first pilot is to be inserted in the preamble symbol is recorded, and the table has the form as shown in Table 2.

In addition, the second arrangement pattern is a table in which a subcarrier index indicating a position to which the second pilot is to be inserted in the data symbol is recorded, and the table has a form as shown in Table 3.

In addition, the second arrangement pattern is a table in which a subcarrier index indicating a position to which the second pilot is to be inserted in the data symbol is recorded, and the table may have a form as shown in Table 4.

In addition, the first arrangement pattern is a table in which a subcarrier index indicating a position to which the first pilot is to be inserted in the preamble symbol is recorded, and the table has the form as shown in Table 5.

In addition, the second arrangement pattern is a table in which a subcarrier index indicating a position to which the second pilot is to be inserted in the data symbol is recorded, and the table has a form as shown in Table 6.

In addition, the second arrangement pattern is a table in which a subcarrier index indicating a position to which the second pilot is to be inserted in the data symbol is recorded, and the table may have a form as shown in Table 7.

In addition, each of the first and second pilots is a continuous pilot having the same frequency band, and the pilot insertion unit may insert the continuous pilot so as not to overlap with a distributed pilot inserted into the data symbol.

On the other hand, the receiving apparatus according to an embodiment of the present invention provides a preamble symbol into which a first pilot is inserted according to a first arrangement pattern and a data symbol into which a second pilot is inserted according to a second patch pattern different from the first arrangement pattern. A receiver configured to receive a plurality of frames each including, respectively, detecting the first pilot and the second pilot based on the first and second arrangement patterns, and the preamble symbol using the detected first and second pilots And a signal processor for synchronizing each of the data symbols and detecting data from the data symbols.

Here, the first arrangement pattern is a table in which a subcarrier index indicating a position in which the first pilot is to be inserted in the preamble symbol is recorded, and the table has the form as shown in Table 2.

In addition, the second arrangement pattern is a table in which a subcarrier index indicating a position to which the second pilot is to be inserted in the data symbol is recorded, and the table has a form as shown in Table 3.

In addition, the second arrangement pattern is a table in which a subcarrier index indicating a position to which the second pilot is to be inserted in the data symbol is recorded, and the table may have a form as shown in Table 4.

In addition, the first arrangement pattern is a table in which a subcarrier index indicating a position to which the first pilot is to be inserted in the preamble symbol is recorded, and the table has the form as shown in Table 5.

In addition, the second arrangement pattern is a table in which a subcarrier index indicating a position to which the second pilot is to be inserted in the data symbol is recorded, and the table has a form as shown in Table 6.

In addition, the second arrangement pattern is a table in which a subcarrier index indicating a position to which the second pilot is to be inserted in the data symbol is recorded, and the table may have a form as shown in Table 7.

Meanwhile, in the control method of a transmitting apparatus according to an embodiment of the present invention, generating a plurality of frames each including a preamble symbol and a data symbol, inserting a first pilot into the preamble symbol according to a preset first arrangement pattern And inserting a second pilot into the data symbol according to a second arrangement pattern different from the first arrangement pattern, and transmitting the plurality of frames into which the first and second pilots are inserted.

Here, the inserting may change the number of the second pilots and the insertion position of the second pilot in proportion to the FFT size of the data symbol.

In addition, the FFT size of the data symbol is one of 8K, 16K, and 32K, and the inserting comprises: if the FFT size is 8K, 90 second pilots are inserted into the data symbol according to the second arrangement pattern, When the FFT size is 16K, 180 second pilots are inserted into the data symbol according to the second arrangement pattern, and when the FFT size is 32K, 360 second pilots are inserted into the data symbol according to the second arrangement pattern. can do.

Further, the step of storing information on the number of second pilots to be inserted and insertion position information for the data symbol having the largest first FFT size among the FFT sizes of the data symbols, wherein the inserting comprises: the first FFT When a data symbol of a second FFT size different from the size is input, the stored number and insertion position information are changed according to a ratio between the first FFT size and the second FFT size, and the data symbol of the second FFT size is changed. The number and insertion positions of the second pilots to be inserted may be determined.

Here, the first arrangement pattern is a table in which a subcarrier index indicating a position in which the first pilot is to be inserted in the preamble symbol is recorded, and the table has the form as shown in Table 2.

In addition, the second arrangement pattern is a table in which a subcarrier index indicating a position to which the second pilot is to be inserted in the data symbol is recorded, and the table has a form as shown in Table 3.

In addition, the second arrangement pattern is a table in which a subcarrier index indicating a position to which the second pilot is to be inserted in the data symbol is recorded, and the table may have a form as shown in Table 4.

In addition, the first arrangement pattern is a table in which a subcarrier index indicating a position to which the first pilot is to be inserted in the preamble symbol is recorded, and the table has the form as shown in Table 5.

In addition, the second arrangement pattern is a table in which a subcarrier index indicating a position to which the second pilot is to be inserted in the data symbol is recorded, and the table has a form as shown in Table 6.

In addition, the second arrangement pattern is a table in which a subcarrier index indicating a position to which the second pilot is to be inserted in the data symbol is recorded, and the table may have a form as shown in Table 7.

Here, each of the first and second pilots is a continuous pilot having the same frequency band, and the inserting may insert the continuous pilot so as not to overlap with a distributed pilot inserted into the data symbol.

Meanwhile, in the control method of the receiving apparatus according to an embodiment of the present invention, a preamble symbol in which a first pilot is inserted according to a first configuration pattern and a second pilot is inserted according to a second configuration pattern different from the first configuration pattern. Receiving a plurality of frames each including data symbols and detecting the first pilot and the second pilot respectively based on the first and second arrangement patterns, and using the detected first and second pilots And synchronizing the preamble symbol and the data symbol, respectively, and detecting data from the data symbol.

Here, the first arrangement pattern is a table in which a subcarrier index indicating a position in which the first pilot is to be inserted in the preamble symbol is recorded, and the table has the form as shown in Table 2.

In addition, the second arrangement pattern is a table in which a subcarrier index indicating a position to which the second pilot is to be inserted in the data symbol is recorded, and the table has a form as shown in Table 3.

In addition, the second arrangement pattern is a table in which a subcarrier index indicating a position in which the second pilot is to be inserted in the data symbol is recorded, and the table may have a form as shown in Table 4.

In addition, the first arrangement pattern is a table in which a subcarrier index indicating a position to which the first pilot is to be inserted in the preamble symbol is recorded, and the table has the form as shown in Table 5.

In addition, the second arrangement pattern is a table in which a subcarrier index indicating a position to which the second pilot is to be inserted in the data symbol is recorded, and the table has a form as shown in Table 6.

In addition, the second arrangement pattern is a table in which a subcarrier index indicating a position to which the second pilot is to be inserted in the data symbol is recorded, and the table may have a form as shown in Table 7.

As described above, according to various embodiments of the present disclosure, it is possible to reduce a memory required for storing pilots, and to accurately perform synchronization based on an extended number of pilots.

1 is a block diagram showing the configuration of a transmission device according to an embodiment of the present invention.
2 is a block diagram for explaining the configuration of the DVB-T2, which is the basis of the present invention.
3 is a diagram showing the structure of a T2 frame used in DVB-T2, which is the basis of the present invention.
4 is a diagram illustrating a frame into which a pilot is inserted according to an embodiment of the present invention.
5 is a diagram illustrating a pilot inserted into a preamble symbol according to an embodiment of the present invention.
6 is a diagram for explaining a process of inserting pilots into data symbols having different FFT sizes according to an embodiment of the present invention.
7 is a block diagram showing the configuration of a receiving device according to an embodiment of the present invention.
8 is a block diagram showing a detailed configuration of a receiving device according to an embodiment of the present invention.
9 is a block diagram showing a detailed configuration of a signal processing unit according to an embodiment of the present invention.
10 is a block diagram showing the configuration of a signaling processing unit according to an embodiment of the present invention.
11 is a flowchart illustrating a method of controlling a transmission device according to an embodiment of the present invention.
12 is a flowchart illustrating a method of controlling a reception device according to an embodiment of the present invention.

Hereinafter, various embodiments of the present invention will be described in detail with reference to the accompanying drawings. Further, in describing the present invention, when it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the subject matter of the present invention, a detailed description thereof will be omitted. In addition, terms to be described later are terms defined in consideration of functions in the present invention, which may vary according to the intention or custom of users or operators. Therefore, the definition should be made based on the contents throughout the present specification.

1 is a block diagram showing the configuration of a transmission device according to an embodiment of the present invention.

Referring to FIG. 1, the transmission apparatus 100 includes a frame generation unit 110, a pilot insertion unit 120, and a transmission unit 130.

The frame generator 110 may generate a plurality of frames each including a preamble symbol and a data symbol. As an embodiment, the DVB-T2 system applies the PLP concept to enable provision of various broadcast services having different modulation schemes, channel coding rates, times, and cell interleaving lengths, respectively, to one broadcast channel.

Here, PLP refers to a signal path that is independently processed. That is, each service (e.g., video, extended video, audio, data stream, etc.) can be transmitted and received through multiple RF channels, and the PLP is a path through which these services are transmitted or a stream transmitted through the path. . In addition, the PLP may be located in slots distributed with temporal intervals on a plurality of RF channels, or may be distributed with temporal intervals on one RF channel. That is, one PLP may be distributed and transmitted on one RF channel or a plurality of RF channels at a time interval.

The PLP structure consists of Input mode A that provides one PLP and Input mode B that provides multiple PLPs. In particular, when input mode B is supported, it is possible to provide a robust specific service, as well as distributed transmission of one stream. By doing so, it is possible to obtain a time diversity gain by increasing the time interleaving length. In addition, when only a specific stream is received, the receiver is powered off for the rest of the time, so it can be used with low power, which is suitable for providing portable and mobile broadcasting services.

Here, time diversity means that if the transmitting side transmits the same signal several times at a certain time interval in order to reduce the deterioration of the transmission quality in the mobile communication transmission path, the receiving side synthesizes these received signals again to obtain good transmission quality. It's technology.

In addition, transmission efficiency can be improved by including information that can be commonly transmitted to a plurality of PLPs in one PLP, and PLP0 plays this role, and this PLP is referred to as a common PLP (common PLP), and PLP0 is referred to as PLP0. Other PLPs can be used for data transmission, and this PLP is called a data PLP.

By using such a PLP, it is possible not only to receive HDTV programs at home, but also to provide SDTV programs while carrying and moving. In addition, it is possible to provide a variety of broadcasting services to viewers through a broadcasting station or a broadcasting content provider, as well as a differentiated service capable of receiving broadcasting even in a difficult-to-view area.

That is, the frame generator 110 may generate a plurality of frames each including a preamble symbol and a data symbol by mapping data to be transmitted to at least one signal processing path, respectively, and may perform signal processing for each path. . For example, signal processing includes Input Stream Synchronization, Delay Compensation, Null Packet Deletion, CRC Encoding, Header Insertion, and Coding. , Interleaving, and modulation may include at least one process. The signal-processed frames for each path are generated as one transmission frame together with signaling information, and the generated transmission frame is transmitted to a receiving device (not shown).

Meanwhile, according to an embodiment of the present invention, the preamble symbol may be used to synchronize the frame by indicating the start point of the frame. Particularly, in DVB-T2, the preamble symbol is divided into a P1 symbol and a P2 symbol. The P1 symbol indicates the start of a frame and the P2 symbol indicates a symbol including a signaling region.

However, as an example, the preamble symbol according to an embodiment of the present invention does not separately use the P1 symbol used in DVB-T2, and uses only the P2 symbol including the signaling region, but includes functions performed by the P1 symbol. I want to use the P2 symbol. That is, information indicating the start of a frame must be found through a synchronization operation in the time domain, and information for performing additional fine synchronization should be inserted into the P2 symbol, which can be realized by inserting a pilot, which will be described later. do.

In addition, the preamble symbol according to an embodiment of the present invention may correspond to a P2 symbol used in DVB-T2, but is not necessarily limited to a P2 symbol, and a preamble symbol including both a function of a P1 symbol and a function of a P2 symbol. This is enough.

2 is a block diagram for explaining the configuration of the DVB-T2, which is the basis of the present invention.

Referring to FIG. 2, the DVB-T2 transmission system 1000 may include an input processor 1100, a BICM encoder 1200, a frame builder 1300, and a modulator 1400.

In that the DVB-T2 transmission system 1000 is the same as the content defined in DVB-T2, one of the European digital broadcasting standards, each configuration will be schematically described. For more information, please refer to "Digital Video Broadcasting (DVB); Frame structure channel coding and modulation for a second generation digital terrestrial television broadcasting system (DVB-T2)".

The input processor 1100 generates a baseband frame (BBFRAME) from an input stream for data to be serviced. Here, the input stream may be MPEG-2 Transport Stream (TS), Generic Stream (GS), or the like.

The BICM encoder 1200 performs encoding by determining an FEC coding rate and a constellation order according to an area (Fixed PHY Frame or Mobile PHY Frame) in which data to be serviced is to be transmitted. The signaling information on the data to be serviced may be encoded through a separate BICM encoder (not shown) depending on the implementation, or may be encoded by sharing the BICM encoder 1200 with the data to be serviced.

The frame builder 1300 and modulator 1400 configure a frame by determining an OFDM parameter for a signaling region and an OFDM parameter for a region in which data to be serviced is to be transmitted, and generate a frame by adding a sync region. Further, modulation for modulating the generated frame into an RF signal is performed, and the RF signal is transmitted to a receiver.

Here, the modulator 1400 is a MISO processing unit (not shown), a pilot insertion unit (not shown), an IFFT unit (not shown), a PAPR reduction unit (not shown), a guard interval insertion unit (not shown), and a P1 symbol insertion unit. It includes a sub (not shown) and a D/A converter unit (not shown).

However, the transmission apparatus 100 according to an embodiment of the present invention does not include a P1 symbol insertion unit (not shown), and thus, a P1 symbol is not inserted into a plurality of frames generated by the frame generation unit 110. Does not.

Specifically, in DVB-T2, by inserting the P1 symbol into the T2 frame, the receiving device (not shown) performs synchronization in the time domain using the P1 symbol, and timing in the frequency domain using the continuous pilot inserted in the data symbol. Accurate synchronization can be achieved by adjusting the offset, sampling offset, and frequency offset. In contrast, a P1 symbol is not separately inserted into a plurality of frames generated by the frame generator 110 according to an embodiment of the present invention, that is, only a preamble symbol without distinction between a P1 symbol and a P2 symbol is inserted. , By using these preamble symbols to perform synchronization in the time domain, and by additionally inserting continuous pilots into the preamble symbols, the receiving device (not shown) performs synchronization in the frequency domain using the continuous pilots inserted into the preamble symbols and data symbols. You can do it. Accordingly, after performing synchronization in the time domain, the receiving device (not shown) can perform accurate synchronization by adjusting the timing offset, the sampling offset, and the frequency offset in the frequency domain.

Meanwhile, the frame generation described in FIG. 1 may be performed by the frame builder 1300, and pilot insertion to be described later may be performed by a pilot insertion unit (not shown) of the modulator 1400.

3 is a diagram showing the structure of a T2 frame used in DVB-T2, which is the basis of the present invention.

Referring to FIG. 3, a structure of a plurality of T2 frames in the time domain of DVB-T2 is shown. One T2 frame 310 includes a P1 symbol 311 and L1 (Layer1) indicating the start position of the frame. It may be composed of a P2 symbol 312 transmitting a signal and a data symbol 313 transmitting a broadcast signal.

Specifically, the P1 symbol 311 is located at the first part of the T2 frame and may be used to detect the start point of the T2 frame. In addition, the P1 symbol uses a 1K FFT size and is a signal in the form of a guard interval. In addition, the P1 symbol 311 in the frequency domain uses 384 subcarriers out of 853 subcarriers among 1K FFTs, and may transmit 7 bits of information.

Meanwhile, as described above, a frame generated by the frame generator 110 according to an embodiment of the present invention does not include the P1 symbol shown in FIG. 3.

The pilot insertion unit 120 may insert a first pilot into a preamble symbol according to a preset first arrangement pattern and insert a second pilot into a data symbol according to a second arrangement pattern different from the first arrangement pattern.

While the conventional DVB-T2 does not insert a pilot, particularly a continuous pilot, into a preamble symbol, the pilot insertion unit 120 according to an embodiment of the present invention may also insert a pilot into the preamble symbol. Accordingly, the receiving device (not shown) can accurately perform fine synchronization based on the continuous pilot inserted in the preamble symbol.

Also, the preset first and second arrangement patterns are different from each other, and accordingly, the insertion position of the first pilot inserted into the preamble symbol and the insertion position of the second pilot inserted into the data symbol are different from each other.

Meanwhile, the transmitter 130 may transmit a plurality of frames into which the first and second pilots are inserted.

4 is a diagram illustrating a frame into which a pilot is inserted according to an embodiment of the present invention.

Referring to FIG. 4, an OFDM symbol is illustrated based on the horizontal axis being the frequency axis and the vertical axis being the time axis. These OFDM symbols include a preamble symbol 410, a frame starting symbol 420, data 430, and a frame closing symbol 440, such as a frame start symbol 420, data The data symbol 450 including both the 430 and the frame closing symbol 440 is defined below.

Referring to FIG. 4, a pilot 460 is inserted into both the preamble symbol 410 and the data symbol 450. Here, the pilot 460 may be divided into a first pilot inserted into the preamble symbol 410 and a second pilot inserted into the data symbol 450, but the first pilot and the second pilot are the type of the inserted symbol and It is only classified according to the arrangement pattern, and it is a pilot that performs the same function.

Meanwhile, the pilot 460 means a continuous pilot, and the pilot 460 may be inserted at the same frequency position. That is, as described above, the continuous pilot is not inserted into the preamble symbol (P1 symbol and P2 symbol) of the existing DVB-T2, whereas the continuous pilot is inserted into the preamble symbol 410 according to an embodiment of the present invention.

Further, the preamble symbol 410 and the pilot 460 inserted into the data symbol 450 may be used to perform synchronization.

Meanwhile, the number of pilots 460 to be inserted may be increased twice as compared to the number of pilots used in the conventional DVB-T2. When the number of pilots increases, the receiving device (not shown) can perform synchronization more accurately due to the increased number of pilots.

For example, it is assumed that a receiving device (not shown) receives HD-class image data and UHD-class image data. Here, the amount of data in HD-class image data is relatively smaller than that of UHD-class image data, and accordingly, a receiving device (not shown) can sufficiently perform synchronization with only the number of pilots used in DVB-T2.

However, when UHD-level image data is received, the amount of data increases and the processing speed increases, and thus the need to perform synchronization more accurately and quickly increases. Accordingly, when the transmission device 100 inserts and transmits an increased number of pilots in a frame, the reception device (not shown) can perform synchronization more quickly and accurately using the increased number of pilots. In addition, the receiving device (not shown) performs synchronization by using the pilot inserted in the preamble symbol, thereby reducing the hassle of performing synchronization in the time domain and frequency domain used in DVB-T2, thereby reducing the processing speed. You will be able to improve it further. Here, the increased number of pilots will be defined as extended pilots.

For another example, when the receiving device (not shown) is a fixed device, that is, in the case of a TV, the robustness of the channel environment may be maintained compared to the case where the receiving device (not shown) is a mobile terminal device. When (not shown) is a mobile terminal device, the robustness to the channel environment is relatively inferior. Therefore, when the receiving device (not shown) is a mobile terminal device, as described above, when the transmitting device 100 inserts and transmits an extended pilot in a frame, the receiving device (not shown) accurately synchronizes using the extended pilot. It is possible to perform, and accordingly, it is possible to maintain the robustness of the channel environment.

This extended pilot may vary according to the FFT size of the symbol as shown in Table 1 below.

FFT mode Normal Mode Extended Mode +/- 32K 180 360 +180 16K 90 180 +90 8K 45 90 +45

Specifically, when the FFT size is 32K, the number of extended pilots may be 360, which is twice as many as 180, which is the number of previously inserted pilots.If the FFT size is 16K, the extended pilot is the number of previously inserted pilots. When the FFT size is 8K, the number of extended pilots may be 90, which is doubled from the number of previously inserted pilots of 45.

In addition, the increased number of extended pilots should be inserted at a position that does not overlap with the distributed pilots inserted in the data symbol 450.

The above-described extended pilot may be inserted into both the preamble symbol 410 and the data symbol 450, but 90 extended pilots are not inserted into the preamble symbol 410 having an FFT size of 8K according to an embodiment of the present invention. Instead, it will be defined that 45 pilots are inserted and extended pilots having different numbers according to the FFT size are inserted into the data symbol 450.

Meanwhile, a method for inserting the first pilot and the second pilot inserted into the preamble symbol 410 and the data symbol 450 into the same frequency position as shown in FIG. 4 will be described with reference to FIG. 5. Here, the meaning that the first pilot and the second pilot inserted into the preamble symbol 410 and the data symbol 450 are inserted at the same frequency position means not only that the first pilot and the second pilot are inserted at the same frequency position, It may also include the meaning of being inserted in a position covering the same frequency band. That is, even if the first pilot and the second pilot are not inserted in the same frequency position numerically, a frequency band that can be covered by one pilot may exist, and accordingly, the pilot is located in a position that can cover the same frequency band. When this is inserted, it becomes possible to perform the same function.

5 is a diagram illustrating a pilot inserted into a preamble symbol according to an embodiment of the present invention.

Referring to FIG. 5, data symbols 510, 520, and 530 having FFT sizes of 8K, 16K, and 32K exist, and the pilot insertion unit 120 includes data symbols 510, 520, and 530 having different sizes. The first pilot may be inserted into the preamble symbols 511, 512, and 513 based on the second pilot inserted in the.

Specifically, when the pilot insertion unit 120 inserts the first pilot into the preamble symbol 511 having an FFT size of 8K based on the second pilot inserted in the data symbol 510 having an FFT size of 8K, Since the FFT size of the data symbol 510 and the preamble symbol 511 is the same as 8K, the first pilot may be inserted at the same position as the position of the second pilot inserted in the data symbol 510.

Meanwhile, when the pilot insertion unit 120 inserts the first pilot into the preamble symbol 512 having an FFT size of 8K based on the second pilot inserted in the data symbol 520 having an FFT size of 16K, data Since the FFT size of the preamble symbol 512 is reduced by 50% compared to the symbol 520, the first pilot inserted into the preamble symbol 512 is 2 of the frequency band covered by the second pilot inserted into the data symbol 520. Cover the ship. In consideration of this point, the pilot insertion unit 120 may insert the first pilot into the preamble symbol 512 based on the position of the second pilot inserted into the data symbol 520.

In addition, when the pilot insertion unit 120 inserts the first pilot into the preamble symbol 513 having an FFT size of 8K based on the second pilot inserted in the data symbol 530 having an FFT size of 32K, data Since the FFT size of the preamble symbol 513 has been reduced to 25% compared to the symbol 530, the first pilot inserted into the preamble symbol 513 is of the frequency band covered by the second pilot inserted into the data symbol 530. It should cover 4 times. In consideration of this point, the pilot insertion unit 120 may insert the first pilot into the preamble symbol 513 based on the position of the second pilot inserted in the data symbol 530.

Meanwhile, the data symbols 510, 520, and 530 have different sizes of FFT sizes, and the pilot insertion unit 120 is proportional to the FFT size of the data symbol, and the number of second pilots and the insertion position of the second pilot Can be changed.

6 is a diagram for explaining a process of inserting pilots into data symbols having different FFT sizes according to an embodiment of the present invention.

6, the FFT size of the data symbols 610, 620, and 630 may be one of 8K, 16K, and 32K, and the pilot insertion unit 120 has each FFT size as shown in Table 1 above. According to this, a different number of second pilots may be inserted.

Specifically, if the FFT size of the data symbol is 8K, the pilot insertion unit 120 may insert 90 second pilots into the data symbol 630 according to the second arrangement pattern. If the FFT size of the data symbol is 16K, 180 Two second pilots can be inserted into the data symbol 620 according to the second arrangement pattern, and if the FFT size of the data symbol is 32K, 360 second pilots are inserted into the data symbol 610 according to the second arrangement pattern. I can.

Here, the transmission device 100 may further include a storage unit (not shown) for storing information on the number of second pilots to be inserted and insertion position information for the data symbol having the largest first FFT size among the FFT sizes of the data symbols. have.

In addition, when a data symbol having a second FFT size different from the first FFT size is input, the pilot insertion unit 120 stores the number and insertion position information stored in the storage unit (not shown) on the first FFT size and the second FFT size. By changing according to the ratio, the number of second pilots to be inserted and the insertion position of the data symbols of the second FFT size may be determined.

For example, referring to FIG. 6, information on the number of second pilots inserted into a data symbol 610 having an FFT size of 32K and insertion position information may be stored in a storage unit (not shown). In addition, when the data symbol 620 having the size of the FFT size of 16K is input, the pilot insertion unit 120 includes the number and insertion positions of the second pilots inserted into the data symbol 610 having the size of the FFT size of 32K. Based on the information, the second pilot may be inserted into the data symbol 620 having an FFT size of 16K.

Specifically, the data symbol 620 having the size of the FFT size of 16K is reduced by half compared to the data symbol 610 having the size of the FFT size of 32K, while the data symbol having the size of the FFT size of 16K The second pilot inserted in 620 must cover a frequency band twice as large as the second pilot inserted in the data symbol 610 having an FFT size of 32K. Accordingly, the pilot insertion unit 120 may insert the second pilot at a position divided by 2 by a frequency position of the second pilot inserted into the data symbol 610 having an FFT size of 32K. That is, the pilot insertion unit 120 inserts the second pilot at a frequency position calculated by adding 1 and dividing by 2 if the frequency position of the second pilot inserted into the data symbol 610 having an FFT size of 32K is odd. If the frequency position of the second pilot inserted into the data symbol 610 having an FFT size of 32K is an even number, the second pilot may be inserted at a frequency position calculated by dividing by two.

In addition, when a data symbol 630 having an FFT size of 8K is input, the pilot insertion unit 120 includes the number and insertion position of the second pilots inserted into the data symbol 610 having an FFT size of 32K. Based on the information, the second pilot may be inserted into the data symbol 630 having an FFT size of 8K.

Specifically, the data symbol 630 having a size of 8K FFT size is reduced to 1/4 of the FFT size compared to the data symbol 610 having a size of 32K FFT size, and has a size of 8K FFT size. The second pilot inserted into the data symbol 630 must cover a frequency band that is four times larger than the second pilot inserted into the data symbol 610 having an FFT size of 32K. Accordingly, if the frequency position of the second pilot inserted into the data symbol 610 having an FFT size of 32K is an odd number, the pilot inserting unit 120 adds 1 and divides it by 4 to place the second pilot at the calculated frequency position. If the frequency position of the second pilot inserted into the data symbol 610 having an FFT size of 32K is an even number, the second pilot may be inserted at a frequency position calculated by dividing by 4.

Accordingly, the transmission device 100 does not need to store all of the number of second pilots and insertion position information inserted into the data symbols 610, 620, and 630 having FFT sizes of 32K, 16K, and 8K. If only the number of second pilots inserted into the data symbol 610 having the FFT size and insertion position information are stored, the second pilot inserted into the data symbols 620 and 630 having the FFT sizes of 16K and 8K is stored based on this. The number and insertion position of the can be determined. Accordingly, it is possible to reduce the number of second pilots and a memory area for storing information on the insertion position.

On the other hand, if the memory area for storing the insertion position information is sufficiently secured, the FFT sizes of 16K and 8K, as well as the number and insertion position information of the second pilots inserted into the data symbol 610 having an FFT size of 32K, are determined. It is also possible to implement a method of simultaneously storing and using the number of second pilots inserted into the data symbols 620 and 630 and insertion position information in a storage unit (not shown).

Meanwhile, a first pilot inserted into the preamble symbol 410 may be inserted according to a first arrangement pattern, and a second pilot inserted into the data symbol 450 may be inserted according to a second arrangement pattern. As described above, the first pilot inserted into the preamble symbol 410 is not an extended pilot, and the second pilot inserted into the data symbol 450 is an extended pilot.

Here, the first arrangement pattern is a table in which a subcarrier index indicating a position in which the first pilot is to be inserted in the preamble symbol 410 is recorded, and may be defined as shown in Table 2 below.

Table 2 shows a table in which a subcarrier index indicating an insertion position of a first pilot inserted into the preamble symbol 410 according to an embodiment of the present invention is recorded, and the number of first pilots inserted as described above is As for 45, the subcarrier index indicating the insertion position of the extended pilot is not recorded.

Meanwhile, the second arrangement pattern is a table in which a subcarrier index indicating a position in which the second pilot is to be inserted in the data symbol 450 is recorded, and may be defined as shown in Table 3 below.

Table 3 shows a table in which a subcarrier index indicating an insertion position of a second pilot inserted into the data symbol 450 is recorded according to an embodiment of the present invention, and the insertion position of the second pilot has an FFT size of 32K, It indicates that 16K and 8K may be arranged in different positions and in different numbers depending on the case.

In addition, the subcarrier index when the FFT size is 32K is described as a source index, which means that the pilot insertion unit 120 uses the subcarrier index when the FFT size is 32K. It means to determine the insertion position.

In addition, Table 3 shows subcarrier indexes for 360 pilots when the FFT size is 32K, and displays subcarrier indexes for 180 pilots when the FFT size is 16K, and 90 when the FFT size is 8K. Subcarrier indices for 4 pilots are indicated, as described in Table 1.

On the other hand, when the memory area for storing the insertion location information is sufficiently secured, not only subcarrier index information when the FFT size is 32K, but also subcarrier index information when the FFT size is 16K and the FFT size is 8K. It is also possible to implement a method of simultaneously storing and using subcarrier index information in a storage unit (not shown).

Meanwhile, the second arrangement pattern may further include a table in which a subcarrier index indicating an insertion position different from the insertion position of the second pilot shown in Table 3 is recorded, and may be defined as shown in Table 4 below.

Table 4 shows a table in which a subcarrier index indicating the insertion position of the second pilot inserted into the data symbol 450 according to another embodiment of the present invention is recorded. Likewise, the insertion position of the second pilot has an FFT size. It indicates that 32K, 16K, and 8K can be arranged in different positions and in different numbers depending on the case.

Likewise, in addition, the subcarrier index when the FFT size is 32K is described as a source index, which corresponds to 16K and 8K based on the subcarrier index when the FFT size is 32K. It means to determine the insertion position of the pilot.

In addition, Table 4 shows subcarrier indexes for 360 pilots when the FFT size is 32K, and displays subcarrier indexes for 180 pilots when the FFT size is 16K, and 90 when the FFT size is 8K. Subcarrier indices for 4 pilots are indicated, as described in Table 1.

On the other hand, when the memory area for storing the insertion location information is sufficiently secured, not only subcarrier index information when the FFT size is 32K, but also subcarrier index information when the FFT size is 16K and the FFT size is 8K. It is also possible to implement a method of simultaneously storing and using subcarrier index information in a storage unit (not shown).

Meanwhile, the number and insertion positions of the first pilots and the second pilots defined in Tables 2, 3, and 4 described above are defined so as not to overlap with the distributed pilots inserted into the data symbol 450.

Accordingly, the pilot insertion unit 120 can insert the first pilot and the second pilot so as not to overlap with the distributed pilot inserted in the data symbol 450. In addition, the first pilot and the second pilot are continuous pilots, and the subcarrier indexes defined in Tables 2, 3, and 4 indicate the number and insertion positions of the continuous pilots.

Meanwhile, the pilot insertion unit 120 according to another embodiment of the present invention includes a first pilot having a number less than the number of the first pilot and the second pilot of the subcarrier index defined in Tables 2, 3, and 4 And a second pilot can be inserted. That is, in another embodiment of the present invention, the pilot insertion unit 120 inserts pilots according to subcarrier indexes including a smaller number of pilots than the subcarrier indexes defined in Tables 2, 3, and 4, Synchronous performance can be achieved.

Specifically, according to another embodiment of the present invention, the first arrangement pattern including the number of pilots smaller than the subcarrier index defined in Table 2 is a sub A table in which a carrier index is recorded, and may be defined as shown in Table 5 below.

Table 5 shows a table in which a subcarrier index indicating the insertion position of the first pilot inserted into the preamble symbol 410 according to another embodiment of the present invention is recorded, and the number of inserted first pilots is 44. , It can be seen that the number of pilots included in the subcarrier index defined in Table 2 is less than 45.

On the other hand, according to another embodiment of the present invention, the second arrangement pattern including the number of pilots less than the subcarrier index defined in Table 3 is a subcarrier indicating a position in which the second pilot is to be inserted. It is a table in which an index is recorded, and can be defined as shown in Table 6 below.

Table 6 shows a table in which a subcarrier index indicating the insertion position of the second pilot inserted into the data symbol 450 is recorded according to another embodiment of the present invention, and the number of the inserted second pilots is in the 32K mode. 356, 178 in 16K mode, 89 in 8K mode, less than 360 in 32K mode, 180 in 16K mode, and 90 in 8K mode, the number of pilots covered by the subcarrier index defined in Table 3 Can be seen.

In addition, the second arrangement pattern according to another embodiment of the present invention may further include a table in which a subcarrier index indicating an insertion position different from the insertion position of the second pilot shown in Table 6 is recorded, and Table 7 below. It can be defined as In addition, it can be seen that the number of second pilots included in the subcarrier index defined in Table 7 is smaller than the number of second pilots defined in Table 6.

Table 7 shows a table in which a subcarrier index indicating the insertion position of the second pilot inserted into the data symbol 450 is recorded according to another embodiment of the present invention, and the number of the inserted second pilots is in the 32K mode. 348, 176 in 16K mode, 87 in 8K mode, less than 356 in 32K mode, 178 in 16K mode, 89 in 8K mode, the number of pilots covered by the subcarrier index defined in Table 6. Can be seen.

That is, the pilot insertion unit 120 may insert the first pilot into the preamble symbol 410 according to one of the tables in which the subcarrier index defined in Tables 2 and 5 is recorded, and Tables 3, 4, and Tables The second pilot may be inserted into the data symbol 450 according to one of the tables in which the subcarrier index defined in Table 6 and Table 7 is recorded.

Meanwhile, as described in the subcarrier index defined in Tables 2, 3, and 4, the pilot insertion unit 120 has an FFT size of 32K for the subcarrier index defined in Tables 5, 6, and 7 The insertion positions of the pilots corresponding to 16K and 8K can be determined based on the subcarrier index in the case, and if a memory area for storing the insertion position information is sufficiently secured, subcarrier index information for all FFT sizes is simultaneously It can also be stored in a storage unit (not shown). In addition, as previously described in Tables 2, 3, and 4, the number and insertion positions of the first and second pilots defined in Tables 5, 6, and 7 are distributed pilots inserted into the data symbol 450. It is defined not to overlap with. That is, Tables 2 and Tables 2, except that the subcarrier indexes defined in Tables 5, 6, and 7 contain a relatively smaller number of pilots than the subcarrier indexes defined in Tables 2, 3, and 4 All functions and descriptions of the subcarrier index defined in Table 3 and Table 4 may be equally applied.

7 is a block diagram showing the configuration of a receiving device according to an embodiment of the present invention.

Referring to FIG. 7, the receiving device 700 includes a receiving unit 710 and a signal processing unit 720.

The receiver 710 may receive a plurality of frames each including a preamble symbol into which a first pilot is inserted according to a first configuration pattern and a data symbol into which a second pilot is inserted according to a second configuration pattern different from the first configuration pattern. I can.

In addition, the signal processing unit 720 detects the first pilot and the second pilot, respectively, based on the first and second arrangement patterns, and synchronizes the preamble symbol and the data symbol, respectively, using the detected first and second pilots. I can. That is, the signal processing unit 720 roughly performs synchronization using the preamble signal in the time domain, and then accurately synchronizes the preamble symbol and the data symbol using the first and second pilots detected in the frequency domain. have.

Specifically, in DVB-T2, the reception device 700 performs synchronization in the time domain using the P1 symbol, and for the data symbol, adjusts the timing offset, the sampling offset, and the frequency offset based on the continuous pilot inserted in the data symbol. However, the signal processing unit 720 according to an embodiment of the present invention performs rough synchronization in the time domain using the preamble symbol, and then performs fine synchronization based on the first pilot inserted into the preamble symbol. The data symbol may be roughly synchronized in the time domain, and fine synchronization may be performed based on the second pilot inserted in the data symbol, and the number of the first pilot and the second pilot is also DVB. Since it is more than the number of consecutive pilots used in -T2, synchronization can be performed much more accurately and quickly.

After synchronization is performed, the signal processing unit 720 may detect data from the data symbols. For example, the signal processor 720 may perform demodulation, frame de-builder, BICM decoding, and input de-processing.

Here, the first arrangement pattern is a table in which a subcarrier index indicating a position in which the first pilot is to be inserted in the preamble symbol is recorded, and is the same as the table shown in Table 2.

In addition, the second arrangement pattern is a table in which a subcarrier index indicating a position in which the second pilot is to be inserted in the data symbol is recorded, and is the same as the table shown in Table 3.

Meanwhile, the second arrangement pattern of another example is a table in which a subcarrier index indicating a position to which the second pilot is to be inserted in the data symbol is recorded, and is the same as the table shown in Table 4.

8 is a block diagram showing a detailed configuration of a receiving device according to an embodiment of the present invention.

Referring to FIG. 8, the receiving device 700 may further include a receiving unit 710 and a signal processing unit 720 as well as a signaling processing unit 730 that processes signaling information necessary for detecting data.

The signaling processing unit 730 may extract signaling information from the received frame. In particular, the signaling processing unit 730 may extract and decode L1 signaling required to detect data. A detailed description of the signaling processing unit 730 will be described later.

Meanwhile, the signal processing unit 720 may extract the PLP, perform FEC decoding, and generate an L2 packet from the error-corrected L1 packet based on the L1 signaling provided by the signaling processing unit 730.

9 is a block diagram showing a detailed configuration of a signal processing unit according to an embodiment of the present invention.

Referring to FIG. 9, the signal processing unit 720 includes a demodulator 721, a signal decoder 722, and a stream generator 723.

The demodulator 721 demodulates the received RF signal according to the OFDM parameter, performs sync detection, and when sync is detected, recognizes whether a mobile frame is being received or a fixed frame is being received from information stored in the sync area.

In this case, if OFDM parameters for the signaling region and the data region are not predetermined, OFDM parameters for the signaling region and data region stored in the sync region are obtained, and the signaling region and the data region immediately following the sync region are obtained. Demodulation may be performed by obtaining OFDM parameter information.

The decoder 722 decodes the input data. In this case, the signal decoder 722 may perform decoding by acquiring parameters such as an FEC method and a modulation method for data stored in each data region by using the signaling information. Also, the signal decoder 722 may calculate the start position of data based on data information included in configurable post signaling and dynamic post signaling. In other words, it is possible to calculate where the corresponding PLP is transmitted in the frame.

The stream generator 723 may generate data to be serviced by processing a BB frame received from the signal decoder 722.

The stream generator 723 may generate an L2 packet from an error-corrected L1 packet based on the L1 signaling provided by the signaling processing unit 730.

Specifically, the stream generator 723 may include de-jitter buffers, and the de-jitter buffers may regenerate an accurate timing for restoring an output stream based on the L1 signaling provided by the signaling processing unit 730. Accordingly, a delay for synchronization between a plurality of PLPs may be compensated.

10 is a block diagram showing the configuration of a signaling processing unit according to an embodiment of the present invention.

Referring to FIG. 10, the signaling processing unit 730 includes a demodulator 731, a mux 732, a deinterleaver 733, and a decoder 734.

The demodulator 731 receives and demodulates the signal transmitted from the transmission device 100. Specifically, the demodulator 731 demodulates the received signal to generate a value corresponding to the LDPC codeword, and outputs it to the mux 732.

In this case, the value corresponding to the LDPC codeword may be expressed as a channel value for the received signal. Here, there may be various methods of determining a channel value, and for example, may be a method of determining a Log Likelihood Ratio (LLR) value.

Here, the LLR value may be expressed as a value obtained by taking a log in the ratio of the probability that the bit transmitted from the transmission device 100 is 0 and the probability that it is 1. Alternatively, the LLR value may be a bit value itself determined according to a hard decision, and the LLR value is a representative value determined according to a section to which the probability that the bit transmitted from the transmitting device 100 is 0 or 1 belongs. It could be.

The mux 732 multiplexes the output value of the demodulator 221 and outputs it to the deinterleaver 733. Here, the output value of the demodulator 221 is a value corresponding to an LDPC codeword and may be, for example, an LLR value.

Specifically, the mux 732 is a component corresponding to a demux (not shown) provided in the transmission device 100 and may reversely perform a demultiplexing operation performed by the demux (not shown). That is, the mux 732 converts a value corresponding to the LDPC codeword output from the demodulator 731 in a parallel-to-serial manner, and multiplexes the value corresponding to the LDPC codeword.

The deinterleaver 733 deinterleaves the output value of the mux 732 and outputs it to the decoder 734.

Specifically, the deinterleaver 733 is a component corresponding to an interleaver (not shown) provided in the transmission device 100 and may reversely perform an operation performed by the interleaver (not shown). That is, the deinterleaver 733 may perform deinterleaving on a value corresponding to an LDPC codeword to correspond to an interleaving operation performed by an interleaver (not shown). Here, the value corresponding to the LDPC codeword may be an LLR value, for example.

The decoder 734 is a component corresponding to the FEC encoder (not shown) provided in the transmission device 100 and may reversely perform an operation performed by the FEC encoder (not shown). Specifically, the decoder 734 may output L1 signaling by performing decoding based on the deinterleaved LLR value.

11 is a flowchart illustrating a method of controlling a transmission device according to an embodiment of the present invention.

According to the control method of the transmission apparatus shown in FIG. 11, first, a plurality of frames each including a preamble symbol and a data symbol are generated (S1110).

Subsequently, a first pilot is inserted into the preamble symbol according to a preset first arrangement pattern, and a second pilot is inserted into the data symbol according to a second arrangement pattern different from the first arrangement pattern (S1120).

Thereafter, a plurality of frames into which the first and second pilots are inserted are transmitted (S1130).

Here, in the step of inserting, the number of second pilots and the insertion position of the second pilot may be changed in proportion to the FFT size of the data symbol.

In addition, the FFT size of the data symbol is one of 8K, 16K, and 32K, and the inserting step is to insert 90 second pilots into the data symbol according to the second arrangement pattern if the FFT size is 8K, and if the FFT size is 16K 180 second pilots are inserted into the data symbols according to the second configuration pattern, and if the FFT size is 32K, 360 second pilots may be inserted into the data symbols daughter of the second configuration pattern.

In addition, the control method of the transmitting apparatus illustrated in FIG. 11 may further include storing information on the number of second pilots to be inserted and insertion position information for a data symbol having the largest first FFT size among the FFT sizes of the data symbols. have.

And, in the step of inserting, when a data symbol having a second FFT size different from the first FFT size is input, the stored number and insertion position information are changed according to a ratio between the first FFT size and the second FFT size, and the second FFT is It is possible to determine the number of second pilots to be inserted and the insertion position for the data symbol of the size.

In addition, the first arrangement pattern is a table in which a subcarrier index indicating a position in which the first pilot is to be inserted in the preamble symbol is recorded, and the table is the same as the table shown in Table 2.

In addition, the second arrangement pattern is a table in which a subcarrier index indicating a position in which the second pilot is to be inserted in the data symbol is recorded, and the table is the same as the table shown in Table 3.

In addition, the second arrangement pattern is a table in which a subcarrier index indicating a position in which the second pilot is to be inserted in the data symbol is recorded, and the table is the same as the table shown in Table 4.

In addition, the first arrangement pattern is a table in which a subcarrier index indicating a position in which the first pilot is to be inserted in the preamble symbol is recorded, and the table is the same as the table shown in Table 5.

In addition, the second arrangement pattern is a table in which a subcarrier index indicating a position in which the second pilot is to be inserted in the data symbol is recorded, and the table is the same as the table shown in Table 6.

In addition, the second arrangement pattern is a table in which a subcarrier index indicating a position in which the second pilot is to be inserted in the data symbol is recorded, and the table is the same as the table shown in Table 7.

In addition, each of the first and second pilots is a continuous pilot having the same frequency band, and in the step of inserting, a continuous pilot may be inserted so as not to overlap with the distributed pilot inserted in the preamble symbol and the data symbol.

12 is a flowchart illustrating a method of controlling a reception device according to an embodiment of the present invention.

According to the control method of the receiving apparatus shown in FIG. 12, a preamble symbol into which a first pilot is inserted according to a first configuration pattern and a data symbol into which a second pilot is inserted according to a second configuration pattern different from the first configuration pattern are respectively A plurality of frames, including, are received (S1210).

Thereafter, the first pilot and the second pilot are respectively detected based on the first and second arrangement patterns, the preamble symbol and the data symbol are respectively synchronized using the detected first and second pilots, and data is obtained from the data symbols. It can be detected (S1220).

In addition, the first arrangement pattern is a table in which a subcarrier index indicating a position in which the first pilot is to be inserted in the preamble symbol is recorded, and the table is the same as the table shown in Table 2.

In addition, the second arrangement pattern is a table in which a subcarrier index indicating a position in which the second pilot is to be inserted in the data symbol is recorded, and the table is the same as the table shown in Table 3.

In addition, the second arrangement pattern is a table in which a subcarrier index indicating a position in which the second pilot is to be inserted in the data symbol is recorded, and the table is the same as the table shown in Table 4.

In addition, the first arrangement pattern is a table in which a subcarrier index indicating a position in which the first pilot is to be inserted in the preamble symbol is recorded, and the table is the same as the table shown in Table 5.

In addition, the second arrangement pattern is a table in which a subcarrier index indicating a position in which the second pilot is to be inserted in the data symbol is recorded, and the table is the same as the table shown in Table 6.

In addition, the second arrangement pattern is a table in which a subcarrier index indicating a position in which the second pilot is to be inserted in the data symbol is recorded, and the table is the same as the table shown in Table 7.

As described above, according to various embodiments of the present disclosure, it is possible to reduce a memory required for storing pilots, and to accurately perform synchronization based on an extended number of pilots.

Meanwhile, a non-transitory computer readable medium in which a program for sequentially performing the control method according to the present invention is stored may be provided.

As an example, generating a plurality of frames each including a preamble symbol and a data symbol, inserting a first pilot into a preamble symbol according to a preset first arrangement pattern, and according to a second arrangement pattern different from the first arrangement pattern A non-transitory computer readable medium in which a program for performing the step of inserting the second pilot into the data symbol is stored may be provided.

In addition, as an example, a first pilot and a second pilot are respectively detected based on the first and second arrangement patterns, the preamble symbol and the data symbol are respectively synchronized using the detected first and second pilots, and the data symbol A non-transitory computer readable medium in which a program for performing the step of detecting data from is stored may be provided.

The non-transitory readable medium refers to a medium that stores data semi-permanently and can be read by a device, not a medium that stores data for a short moment, such as a register, cache, and memory. Specifically, the above-described various applications or programs may be provided by being stored in a non-transitory readable medium such as a CD, DVD, hard disk, Blu-ray disk, USB, memory card, ROM, or the like.

In addition, although a bus is not shown in the above-described block diagram showing the transmitting device and the receiving device, communication between components in the transmitting device and the receiving device may be performed through a bus. In addition, each device may further include a processor such as a CPU or a microprocessor that performs the various steps described above.

In addition, although the preferred embodiments of the present invention have been illustrated and described above, the present invention is not limited to the specific embodiments described above, and the technical field to which the present invention belongs without departing from the gist of the present invention claimed in the claims. In addition, various modifications are possible by those of ordinary skill in the art, and these modifications should not be understood individually from the technical spirit or prospect of the present invention.

100: transmitting device 110: frame generating unit
120: pilot insertion unit 130: transmission unit

Claims (36)

A frame generator for generating a plurality of frames each including a preamble symbol and a data symbol;
A pilot that inserts a plurality of first pilots into a preamble symbol of a frame according to a preset first arrangement pattern, and inserts a plurality of second pilots into a data symbol of the frame according to a second arrangement pattern different from the first arrangement pattern Insertion part; And
Includes; a transmitter for transmitting the plurality of frames into which the first and second pilots are inserted,
The pilot insertion unit,
Identify the FFT size of the data symbol,
A transmitting apparatus for inserting the plurality of second pilots into data symbols of the frame based on the identified FFT size and the number of pilots corresponding to the maximum FFT size and insertion position information. The method of claim 1,
The pilot insertion unit,
And changing the number of the second pilots and the insertion position of the second pilot in proportion to the FFT size of the data symbol. The method of claim 2,
The FFT size of the data symbol is one of 8K, 16K, and 32K,
The pilot insertion unit,
If the FFT size is 8K, 90 second pilots are inserted into the data symbol according to the second arrangement pattern,
If the FFT size is 16K, 180 second pilots are inserted into the data symbol according to the second arrangement pattern,
When the FFT size is 32K, 360 second pilots are inserted into the data symbol according to the second arrangement pattern. The method of claim 2,
A storage unit for storing information on the number of second pilots to be inserted and insertion position information for the data symbol having the largest first FFT size among the FFT sizes of the data symbols,
The pilot insertion unit,
When a data symbol having a second FFT size different from the first FFT size is input, the number and insertion position information stored in the storage unit are changed according to a ratio between the first FFT size and the second FFT size, A transmitting apparatus, characterized in that for determining the number of second pilots to be inserted and the insertion position for data symbols of 2 FFT size. The method of claim 1,
The first arrangement pattern,
A table in which a subcarrier index indicating a position where the first pilot is to be inserted in the preamble symbol is recorded,
The table above,

Transmission device, characterized in that the form of. The method of claim 1,
The second arrangement pattern,
A table in which a subcarrier index indicating a position in which the second pilot is to be inserted is recorded in the data symbol,
The table above,

Transmission device, characterized in that the form of. The method of claim 1,
The second arrangement pattern,
A table in which a subcarrier index indicating a position in which the second pilot is to be inserted is recorded in the data symbol,
The table above,

Transmission device, characterized in that the form of. The method of claim 1,
The first arrangement pattern,
A table in which a subcarrier index indicating a position where the first pilot is to be inserted in the preamble symbol is recorded,
The table above,

Transmission device, characterized in that the form of. The method of claim 1,
The second arrangement pattern,
A table in which a subcarrier index indicating a position in which the second pilot is to be inserted is recorded in the data symbol,
The table above,

Transmission device, characterized in that the form of. The method of claim 1,
The second arrangement pattern,
A table in which a subcarrier index indicating a position in which the second pilot is to be inserted is recorded in the data symbol,
The table above,

Transmission device, characterized in that the form of. The method of claim 1,
Each of the first and second pilots is a continuous pilot having the same frequency band,
The pilot insertion unit,
And inserting the continuous pilot so as not to overlap with the distributed pilot inserted in the data symbol. Receiving a plurality of frames each including a preamble symbol into which a plurality of first pilots are inserted according to a first arrangement pattern and a data symbol into which a plurality of second pilots are inserted according to a second patch pattern different from the first arrangement pattern Receiver;
Each of the first and second pilots is detected based on the first and second arrangement patterns, and the preamble symbol and the data symbol are respectively synchronized using the detected first and second pilots, and the data symbol Includes; a signal processing unit for detecting data from,
The plurality of second pilots,
A reception device inserted into the data symbol of the frame based on the FFT size of the data symbol and the number of pilots corresponding to the maximum FFT size and insertion position information. The method of claim 12,
The first arrangement pattern,
A table in which a subcarrier index indicating a position where the first pilot is to be inserted in the preamble symbol is recorded,
The table above,

Receiving device, characterized in that the shape of. The method of claim 12,
The second arrangement pattern,
A table in which a subcarrier index indicating a position in which the second pilot is to be inserted is recorded in the data symbol,
The table above,

Receiving device, characterized in that the shape of. The method of claim 12,
The second arrangement pattern,
A table in which a subcarrier index indicating a position in which the second pilot is to be inserted is recorded in the data symbol,
The table above,

Receiving device, characterized in that the shape of. The method of claim 12,
The first arrangement pattern,
A table in which a subcarrier index indicating a position where the first pilot is to be inserted in the preamble symbol is recorded,
The table above,

Receiving device, characterized in that the shape of. The method of claim 12,
The second arrangement pattern,
A table in which a subcarrier index indicating a position in which the second pilot is to be inserted is recorded in the data symbol,
The table above,

Receiving device, characterized in that the shape of. The method of claim 12,
The second arrangement pattern,
A table in which a subcarrier index indicating a position in which the second pilot is to be inserted is recorded in the data symbol,
The table above,

Receiving device, characterized in that the shape of. Generating a plurality of frames each including a preamble symbol and a data symbol;
Inserting a first pilot into the preamble symbol according to a preset first arrangement pattern and inserting a second pilot into the data symbol according to a second arrangement pattern different from the first arrangement pattern; And
Transmitting the plurality of frames into which the first and second pilots are inserted; Including,
The step of inserting the second pilot,
Identify the FFT size of the data symbol,
A control method of a transmission apparatus for inserting the plurality of second pilots into data symbols of the frame based on the identified FFT size and the number of pilots corresponding to the maximum FFT size and insertion position information. The method of claim 19,
The inserting step,
And changing the number of the second pilots and the insertion position of the second pilot in proportion to the FFT size of the data symbol. The method of claim 20,
The FFT size of the data symbol is one of 8K, 16K, and 32K,
The inserting step,
If the FFT size is 8K, 90 second pilots are inserted into the data symbol according to the second arrangement pattern,
If the FFT size is 16K, 180 second pilots are inserted into the data symbol according to the second arrangement pattern,
If the FFT size is 32K, 360 second pilots are inserted into the data symbols according to the second arrangement pattern. The method of claim 20,
Storing information on the number of second pilots to be inserted and insertion position information for the data symbol having the largest first FFT size among the FFT sizes of the data symbols; and
The inserting step,
When data symbols of a second FFT size different from the first FFT size are input, the stored number and insertion position information are changed according to a ratio between the first FFT size and the second FFT size, and the second FFT size And determining the number and insertion positions of the second pilots to be inserted for the data symbols of. The method of claim 19,
The first arrangement pattern,
A table in which a subcarrier index indicating a position where the first pilot is to be inserted in the preamble symbol is recorded,
The table above,

A method for controlling a transmission device, characterized in that it has the same form as. The method of claim 19,
The second arrangement pattern,
A table in which a subcarrier index indicating a position in which the second pilot is to be inserted is recorded in the data symbol,
The table above,

A method for controlling a transmission device, characterized in that it has the same form as. The method of claim 19,
The second arrangement pattern,
A table in which a subcarrier index indicating a position in which the second pilot is to be inserted is recorded in the data symbol,
The table above,

A method for controlling a transmission device, characterized in that it has the same form as. The method of claim 19,
The first arrangement pattern,
A table in which a subcarrier index indicating a position where the first pilot is to be inserted in the preamble symbol is recorded,
The table above,

A method for controlling a transmission device, characterized in that it has the same form as. The method of claim 19,
The second arrangement pattern,
A table in which a subcarrier index indicating a position in which the second pilot is to be inserted is recorded in the data symbol,
The table above,

A method for controlling a transmission device, characterized in that it has the same form as. The method of claim 19,
The second arrangement pattern,
A table in which a subcarrier index indicating a position in which the second pilot is to be inserted is recorded in the data symbol,
The table above,

A method for controlling a transmission device, characterized in that it has the same form as. The method of claim 19,
Each of the first and second pilots is a continuous pilot having the same frequency band,
The inserting step,
And inserting the continuous pilot so as not to overlap with the distributed pilot inserted in the data symbol. Receiving a plurality of frames each including a preamble symbol into which a first pilot is inserted according to a first configuration pattern and a data symbol into which a second pilot is inserted according to a second configuration pattern different from the first configuration pattern; And
Each of the first and second pilots is detected based on the first and second arrangement patterns, and the preamble symbol and the data symbol are respectively synchronized using the detected first and second pilots, and the data symbol Including; detecting data from,
The plurality of second pilots,
A method of controlling a reception apparatus inserted into a data symbol of the frame based on the FFT size of the data symbol and the number of pilots corresponding to the maximum FFT size and insertion position information. The method of claim 30,
The first arrangement pattern,
A table in which a subcarrier index indicating a position where the first pilot is to be inserted in the preamble symbol is recorded,
The table above,

Control method of a receiving device, characterized in that the form of. The method of claim 30,
The second arrangement pattern,
A table in which a subcarrier index indicating a position in which the second pilot is to be inserted is recorded in the data symbol,
The table above,

Control method of a receiving device, characterized in that the form of. The method of claim 30,
The second arrangement pattern,
A table in which a subcarrier index indicating a position in which the second pilot is to be inserted is recorded in the data symbol,
The table above,

Control method of a receiving device, characterized in that the form of. The method of claim 30,
The first arrangement pattern,
A table in which a subcarrier index indicating a position where the first pilot is to be inserted in the preamble symbol is recorded,
The table above,

Control method of a receiving device, characterized in that the form of. The method of claim 30,
The second arrangement pattern,
A table in which a subcarrier index indicating a position in which the second pilot is to be inserted is recorded in the data symbol,
The table above,

Control method of a receiving device, characterized in that the form of. The method of claim 30,
The second arrangement pattern,
A table in which a subcarrier index indicating a position in which the second pilot is to be inserted is recorded in the data symbol,
The table above,

Control method of a receiving device, characterized in that the form of.

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