KR20120068705A - Method and apparatus for transmitting or receiving data in wireless broadcast system - Google Patents

Abstract

PURPOSE: An apparatus and a method for transmitting/receiving data are provided to transmit data including data stream in order to includes segment information of a frequency zone in a broadcasting system. CONSTITUTION: A TIF(Time Interleaving Frame) separation and FIZ(Frequency Interleaving Zone) mapping block(440) segments a data section for transferring data stream to a plurality of frequency zones. The TIF separation and FIZ mapping block maps the data stream to one frequency zone. A signal generation block(450) transmits signaling information. An OFDM(Orthogonal Frequency Division Multiplexing) generating unit(480) maps the data stream and signaling information to an OFDM resource.

Description

Apparatus and method for transmitting or receiving data in broadcasting system {METHOD AND APPARATUS FOR TRANSMITTING OR RECEIVING DATA IN WIRELESS BROADCAST SYSTEM}

TECHNICAL FIELD The present invention generally relates to broadcast systems, and more particularly, to a method and apparatus for transmitting and receiving data streams in a digital video broadcasting system.

Broadcast systems, such as Digital Video Broadcasting (DVB), transmit data in the form of a series of frames. Digital video broadcast systems, for example, conform to the DVB-T2 (Terrestrial 2nd Generation) standard. Thus, or operates in accordance with, for example, the Advanced Televisions Systems Committee (ATSC), Integrated Services Digital Broadcasting (ISDB), or Digital Multimedia Broadcasting (DMB) standard families. Each frame typically includes a preamble section and a data section that are time-multiplexed. The data portion may include data arranged in the form of a plurality of data streams, which may be referred to as physical layer pipes (PLP). At least one physical layer pipe may deliver a service such as a video channel provided to the user, for example. The reception of data from the frames and the reception of the data streams may be assisted by a kind of signaling protocol, typically called a "signaling" carried in the preamble of the frame, in which case the signaling May be referred to as "out-of-band (OB) signaling", and / or the signaling may be carried in a data portion, in which case the signaling is referred to as "in-band:". IB) signaling. The signaling may be referred to as physical layer signaling or "Layer 1 (L1) signaling". The signaling may indicate the modulation or coding scheme used to decode the data, and may also indicate, for example, the intervals of the data field to be decoded, or the location of the data stream within the data interval. .

As the use of signal compression techniques increases, the number of data streams carried by successive frames is potentially large, but by providing a lower data rate service that can be more robust, especially in mobile environments. It is sparse in the sense that a frame may not carry all data streams. Since signaling is typically required for each data stream for each frame, the signaling may represent a large overhead per frame in terms of receiver power consumption and data capacity in receiving the signaling. have. Moreover, since data streams are typically frequency-interleaved within the symbols transmitted in the data frame, it is necessary for the receiver to receive the full symbol bandwidth in order to receive the data stream. As a result, the sampling rate used in the receiver is typically required to be set sufficiently to receive the full symbol bandwidth, which creates a requirement for receiver power consumption related to the sampling rate. Power consumption is a particularly important parameter for battery powered digital broadcast receivers.

SUMMARY OF THE INVENTION An object of the present invention is to improve the problems in the prior art system, and to provide a technique for transmitting and receiving data in a broadcast system.

According to a first aspect of the invention, there is provided a method for transmitting data comprising a data stream in a broadcast system, the method comprising: a data stream for a super-frame comprising a plurality of frames; Each frame includes a preamble section and a data section, wherein the preamble section and the data section are time-multiplexed, the data section has a data stream, and the preamble section is at least signaling. And segmenting a data section of each of the plurality of frames into a plurality of frequency domains, each frequency domain having the same location in the frequency domain for each of the plurality of frames, Multiple frequency regions for each of the plurality of frames at least a portion of a data stream Generating a signaling information word that maps to a first frequency domain of and conveys a signaling signal relating to the location and bandwidth of at least the first frequency domain in one frequency domain to aid in the reception of the data stream. And including the signaling information word in a preamble section of at least one frame of the plurality of frames, transmitting the preamble section within a first frequency bandwidth, and transmitting the first frequency region within a second frequency bandwidth. And transmitting, wherein the first frequency bandwidth is larger than the second frequency bandwidth. The advantage of transmitting the first frequency region with a bandwidth smaller than the first bandwidth is that the receiver can use the reduced bandwidth, which reduces the sampling rate for receiving the data stream, thus reducing power consumption. A wider bandwidth may be used to receive the preamble interval to eliminate the need to copy the information of the preamble.

In one embodiment of the present invention, the method further comprises: signaling information relating to a location of a data stream in a frame later than the predetermined frame in the first frequency domain of a data period of the predetermined frame. The process further includes. This relates to in-band signaling and that such signaling information is received within the second bandwidth, allowing the receiver to maintain the second bandwidth for the reception of the data stream, thereby reducing power consumption. Has an advantage. In one embodiment of the invention, the method further comprises mapping each frequency domain to sub-carriers of consecutive transmission symbols in frequency. This has the peak that the frequency band occupied by the mapped frequency domain is minimized. In one embodiment of the present invention, the method further comprises applying frequency interleaving in the first frequency domain in dependence on at least bandwidth of the first frequency domain.

In one embodiment of the present invention, the frequency interleaving sequence changes from one orthogonal frequency division multiplexing (hereinafter referred to as "OFDM") symbol to another symbol. In one embodiment of the present invention, the method further includes inserting pilot tones into a transmission symbol in a pattern independent of segmentation of the respective data intervals of each of the plurality of frames into frequency domains. . This has the advantage that the implementation of the transmitter and receiver is simplified because the above segmentation may be performed independently of the arrangement of the physical layer. In one embodiment of the invention, the method determines a lower limit for the bandwidth of the first frequency domain based on including the arrangement of pilot tones mapped in the frequency domain, and at least the bandwidth of the first frequency domain. It further includes the step of setting to the value of the lower limit. This has the advantage that minimal robustness for transmission in the first frequency domain can be maintained since such robustness depends on the arrangement of pilot tones. Any number of pilot tones will need to be present in the portion of the symbol to which the first frequency region is mapped.

In one embodiment of the present invention, the method further comprises dividing a data interval of each of the plurality of frames at the logical frame level. This has the advantage that the implementation of the transmitter and receiver is simplified and the location and bandwidth of the frequency domains can be flexibly allocated. In one embodiment of the invention, the data stream comprises components of a scalable video coding technique, the method further comprising mapping the components delivered in a given frame into the same frequency domain. do. This has the advantage that the receiver may return to a more robust component or select a higher speed component without changing the bandwidth used by it.

In one embodiment of the invention, the method generates second signaling information identifying one frequency region to which a data stream is to be mapped, which is one of the plurality of frequency regions, and preamble of the predetermined frame. And including the second signaling information word in a section.

In one embodiment of the invention, the method maps at least a portion of the data stream to a plurality of time interleaving frames and maps the plurality of time interleaving frames to a plurality of time interleaving frame segments within the plurality of frames. Generating a third signaling information word for carrying a signaling signal related to at least one of the time interleaving frame segments within a predetermined frame, to aid in the reception of the data stream, and preamble interval of the predetermined frame The method may further include including the third signaling information word. The advantage of mapping time interleaving frames to time interleaving frame segments is that it avoids the need to add padding in the frequency domain of the frame, because the capacity of each time interleaving frame segment is Because it can be configured to fill the rest of the frame efficiently.

In one embodiment of the present invention, the method further comprises mapping each time interleaving frame segment to one frequency domain in a given frame. This has the advantage that the receiver can receive the data stream with reduced bandwidth and can also reduce power consumption by the reduced time. Bandwidth and time periods can be set up as a kind of trade-off between time and frequency diversity. In mobile environments, reducing frequency and gain-time diversity by reducing bandwidth and increasing transmission time. It may be advantageous.

In one embodiment of the present invention, the method may further comprise including information on timing of a subsequent time interleaving frame segment in a third signaling information word. This has the advantage that the receiver can suppress the reception of periods between time interleaving frame segments to reduce power consumption and be prepared to receive subsequent time interleaving frame segments.

In one embodiment of the present invention, the method includes the third signaling information word in a first signaling information field and a number of data streams for a given frame that is larger than any threshold in a second signaling information field. And dependently, including the third signaling information word. Here, the first signaling information field has the same size for each of the plurality of frames, and the second signaling information field has a variable size.

According to an embodiment of the present invention, the method comprises: fast Fourier transform size, number of pilot tones, pattern of pilot tones, multiple input multiple output (MIMO) scheme and guard interval ( dividing each of the plurality of frames into two or more physical layer regions having different physical layer characteristics in at least one of the guard intervals. This has the advantage that the same bandwidth can be used to receive one frequency domain within each physical layer region of a frame. According to one embodiment of the invention, the method further comprises mapping each time interleaving frame segment to one physical layer region in a given frame.

According to one embodiment of the invention, said step of mapping said at least a portion of the data stream to the first frequency domain further comprises mapping to successive portions of the data stream at a frequency within an OFDM symbol. This eventually leads to frequency-wise interleaving, so that successive portions of the data stream are mapped as frequencies across portions of the OFDM symbol, and then such mapping is typically portions of another OFDM symbol. To be mapped in frequency with respect to. Alternatively, the mapping of the at least a portion of the data stream to the first frequency domain further includes mapping consecutive portions of the data stream in time to some of the OFDM symbols within the frame. This eventually leads to time-wise interleaving so that successive portions of the data stream are mapped in time across successive OFDM symbols, and then such mapping is typically the other frequency portion of successive OFDM symbols. To be mapped in frequency.

According to a second aspect of the present invention, there is provided a transmitter for transmitting data comprising a data stream in a broadcast system, the transmitter being configured to map the data stream to a super-frame comprising a plurality of frames. Each frame includes a preamble section and a data section, wherein the preamble section and the data section are time-divided, the data section has a data stream, and the preamble section includes at least signaling information. Split the data interval into a plurality of frequency domains, each frequency domain configured to have the same location in the frequency domain for each of the plurality of frames, wherein at least a portion of the data stream is divided into a plurality of frames for each of the plurality of frames. To the first frequency domain of the frequency domains Generate a signaling information word for conveying a signaling signal relating to the location and bandwidth of at least the first frequency domain in the frequency domain, to aid in the reception of the data stream, and at least one of the plurality of frames. Include the signaling information in a preamble interval of a frame, and transmit the preamble interval within a first bandwidth and transmit the first frequency domain within a second bandwidth, wherein the first bandwidth is greater than the second bandwidth It is largely configured.

According to a third aspect of the invention, there is provided a method of receiving data comprising a data stream in a broadcast system, the data stream being mapped to a super-frame comprising a plurality of frames, each frame being A preamble section and a data section, wherein the preamble section and the data section are time-divided, the data section includes a data stream, and the preamble section includes at least signaling information, wherein each data section of the plurality of frames is multiple Wherein each frequency domain has the same location in the frequency domain for each of the plurality of frames, and at least a portion of the data stream is mapped to the first frequency domain, wherein the method comprises: Number of preamble intervals of a given frame within one frequency bandwidth Receive a signaling information word in a preamble period of the predetermined frame involving signaling of at least the location and bandwidth of the first frequency domain in the frequency domain, and within a second frequency bandwidth based on the signaling information word Receiving the first frequency domain, wherein the first frequency bandwidth is configured to be larger than the second frequency bandwidth.

Preferably, the predetermined frame is the first frame of the super-frame. This may have the advantage that the receiver may receive the given frame using a wider bandwidth, making the receiver bandwidth and sampling rate narrower for subsequent frame reception, thereby reducing power consumption.

According to an embodiment of the present invention, the method may further include receiving signaling information related to a location of a data stream in a frame later than the predetermined frame in a first frequency region of a data section of the predetermined frame, Using the signaling information regarding the location of the data stream to aid in the reception of the data stream in the later frame within a second bandwidth.

According to an embodiment of the present invention, the method further includes setting a sampling frequency suitable for the second bandwidth and a bandwidth of an analog filter based on the signaling information word. This has the advantage that the receiver can be configured for minimum power consumption in harmony with the second bandwidth. In an embodiment of the invention, at least a portion of the data stream within the plurality of frames is mapped to a plurality of time interleaving frames, and the plurality of time interleaving frames are mapped to time interleaving frame segments, the method comprising: And aiding in the reception of a data stream by receipt of a second signaling information word in a preamble of a predetermined frame carrying a signaling signal relating to at least one position of the time interleaving frame segments within a frame of. do.

According to one embodiment of the invention, the method receives information in the second signaling information word regarding timing of a later time interleaving frame segment, and is reduced in a period before reception of the later time interleaving frame segment. And setting the receiver to a power consumption mode. This has the advantage that the receiver can be set to a low power consumption mode during the period between time interleaving frame segments involving the data stream to be received.

In an embodiment of the present invention, each of the plurality of frames includes a fast Fourier transform size, a number of pilot tones, a pattern of pilot tones, a multiple input multiple output (MIMO) scheme, and In terms of at least one of the guard intervals, the method is divided into two or more physical layer regions having different physical layer characteristics, the method using the same frequency bandwidth for each physical layer region. Receiving each of the plurality of frequency domains. This has the advantage that the receiver does not need to change the reception bandwidth within the frame.

According to a fourth aspect of the invention, there is provided a receiver for receiving data comprising a data stream in a broadcast system, the data stream being mapped to a super-frame comprising a plurality of frames, each frame Includes a preamble section and a data section, wherein the preamble section and the data section are time-divided, the data portion includes a data stream, and the preamble section includes at least signaling information, wherein the data section of each of the plurality of frames 10. A receiver in which a plurality of frequency domains are divided, each frequency domain having the same location in the frequency domain for each of the plurality of frames, and wherein at least a portion of the data stream is mapped to a first frequency domain. Of the predetermined frame within the first frequency bandwidth Receiving a re-amble section and receiving at least signaling information word in the preamble section of the predetermined frame of the accompanying signaling signal the location and bandwidth of the first frequency range in the frequency domain, and, and

The first frequency domain is received within a second frequency bandwidth based on the signaling information word, and the first frequency bandwidth is configured to be larger than the first frequency bandwidth. In an embodiment of the invention, the broadcast system is a digital video broadcast system. In an embodiment of the invention, the plurality of data streams described above are physical layer pipes.

Further features and advantages of the present invention in addition to those described above will become apparent from the following description of the preferred embodiments of the present invention provided by way of example only.

1 is a schematic diagram illustrating a data frame according to an embodiment of the present invention.
2 is a schematic diagram illustrating signaling in a data frame according to an embodiment of the present invention.
3 is a schematic diagram illustrating the mapping of time interleaving frame segments to frequency interleaving regions in accordance with an embodiment of the present invention.
4 is a schematic diagram illustrating a transmitter system according to an embodiment of the present invention.
5 is a schematic diagram illustrating the mapping of frequency interleaving regions to physical layer regions according to an embodiment of the present invention.
6 is a schematic diagram illustrating a receiver according to an embodiment of the present invention.
7 is a schematic diagram illustrating another embodiment of a receiver according to another embodiment of the present invention.
8 is a schematic diagram illustrating mapping of frequency interleaving regions to physical layer regions in mode A according to an embodiment of the present invention.
9 is a schematic diagram illustrating mapping of frequency interleaving regions to physical layer regions in mode B according to an embodiment of the present invention.
FIG. 10 is a table showing L1-config signaling field according to an embodiment of the present invention. FIG.
11 is a table showing an L1-dynamic signaling field in one embodiment of the present invention.
12 is a table showing an L1-dynamic-Ext signaling field in one embodiment of the present invention.
FIG. 13 is a table illustrating L1-config signaling field according to an embodiment of the present invention. FIG.
14 is a table illustrating still another example of an L1-dynamic signaling field in one embodiment of the present invention.
15 is a table illustrating still another example of an L1-dynamic-Ext signaling field according to an embodiment of the present invention.
FIG. 16 is a table illustrating in-band signaling in an embodiment of the present invention. FIG.
FIG. 17 is a table showing L1-pre signaling field in one embodiment of the present invention. FIG.
18 is a table illustrating still another example of an L1-config signaling field according to an embodiment of the present invention.

In the following, the present embodiment of the invention, e.g., second-generation terrestrial ^{(2 nd generation terrestrial) DVB-} T2 next generation of portable digital video broadcasting based on system standard (Digital Video Broadcasting Next Generation Handheld ( DVB-NGH)) This will be explained in terms of.

However, it should be understood that this is merely exemplary and that other embodiments may involve other broadcast systems, and such embodiments are not limited to use for the transmission of digital video signals.

In an embodiment of the present invention, several data streams, which may be physical layer pipes, are mapped into super-frames consisting of a series of frames.

1 is a schematic diagram illustrating a data frame according to an embodiment of the present invention. Referring to FIG. 1, the frame includes a preamble section and a data section. The preamble section includes “P1” (8), “L1-pre” (10), “L1-config” (12), "L1-dynamic" 14, "L1-dynamic EXT" 16 and, in this embodiment, "Add parity AP1" 18a, and the indicated "Add parity AP2" 18b, "Add parity AP _It may include additional parity intervals such as _N ”18c. The data interval may include physical layer pipes PLP ₁ (4a), PLP ₂ (4b), etc. The physical layer pipes Although shown here are arranged in sequential order in time, in practice this does not need to be, and such physical layer pipes may overlap in time and may be multiplexed in frequency, for example.

Typically, the " L1-Pre " section contains at least signaling information related to the coding scheme and modulation required to receive the remainder of the preamble, the rest of the preamble section being the physical layer within the data section, in particular the data section. Information needed to receive the pipes, which may include, for example, the starting address of a physical layer pipe within the data interval, the signaling information in the preamble may be out-of-band. May be referred to as: OB) signaling.

The "L1-config" section typically carries valid information for each frame of the super-frame and is the same for each frame of that super-frame. From frame to frame, and to the decoding of physical layer pipes within a frame, which will typically include, for example, the starting address of the physical layer pipes. As lower data rates and more robust services are provided for reception by portable and mobile communication equipment users, the number of physical layer pipes mapped to super-frames is increasing, however, each physical layer pipe, namely, The data stream may not be mapped to every frame, with each physical layer pipe in each frame. The information about the signaling, in particular passing "L1-dynamic" information may involve significant overhead in terms of signaling information.

A first signaling information field is provided to assist in receiving the first number of data streams (L1-dynamic 14 in this example) and, if necessary, additional streams of data frames (L1-dynamic EXT 16 in this example). A second signaling information field is provided for assisting in the reception of. The signaling information carried in the signaling information field typically includes L1-dynamic information. The number of data streams in which the signaling information is carried in the first signaling information field is equal to or less than a limit applicable to each of the frames in the super-frame, and the first signaling information field is each of the frames in the super-frame. About the same size.

An advantage of the first signaling information field, which is the same size for each of the plurality of frames described above, is that the size can be set to a value large enough to provide robustness due to frequency diversity. . The advantage of including information in the second information field depending on the number of data streams for the given frame that is greater than any limit is that additional information may be transmitted beyond the capacity limit of the first signaling information field. . The first information field is thus kept large enough to provide robustness due to frequency diversity, while the second information field is able to accommodate the extra capability if necessary. The second information field will be less robust than the first information field if the size of the second field is smaller than the first field.

The first signaling information field may convey information on whether or not the second signaling information field is to be transmitted, and may also hold an indication regarding the length of the second signaling information field. This may enable the receiver to inhibit receiving the second signaling information field if it is not to be transmitted, and may prepare to receive the second signaling information field if it is to be transmitted. This has the advantage that the receiver can prohibit the reception of a frame that does not have a data stream that is required to be received, thus saving power.

The limitation on the number of data streams in which signaling information is carried in the first signaling information field is typically a statistical description of the number of active or idle data streams per frame for multiple frames. And based on at least robustness of the scheme used for transmission of the information and / or at least one of the first and second signaling information fields. The robustness scheme may include at least one of a modulation and coding scheme, a Multiple-Input Multiple-Output (MIMO) scheme, a Fast Fourier Transform (FFT) size, a pilot pattern, and a guard interval. . Therefore, the restriction on the number of data streams in which the information is carried in the first signaling information field is determined in consideration of the robustness of the field transmission, so that the lower limit on the size of the field takes into account the robustness and frequency diversity of the transmission scheme. Can be set to a size sufficient to provide adequate robustness. The field may also be set large enough to accommodate the expected amount of signaling information related to active and passive data streams per frame, such that an overflow of signaling information above the expected amount may occur. It may be carried on the second signaling information field. The indication of the limit may be included in the preamble portion of each frame, typically in the "L1-config" section.

As mentioned above, the first signaling information field has higher robustness than the second signaling information field due to the greater frequency diversity since the first signaling information field is typically interleaved over a larger frequency range. Therefore, there may be an advantage in including signaling information preferentially in the first signaling information related to data streams requiring higher robustness.

2 is a schematic diagram illustrating signaling in a data frame according to an embodiment of the present invention.

2, the vertical axis represents frequency and the horizontal axis represents time. In the physical layer, a frame consists of a series of Orthogonal Frequency Division Multiplexing (OFDM) symbols, each of which consists of a number of sub-carrier signals of different frequencies within the symbol's frequency band. (FIG. 1 in FIG. 1, 8 MHz in this example).

It can be seen that the preamble region 2 occupies the full width at the frequency of the symbol. The remainder of the frame is a data interval that contains a plurality of data streams to be mapped to the data interval. The data interval is divided into a plurality of frequency regions, referred to as frequency interleaving regions indicated by FIZ ₁ (3a), FIZ ₂ (3b) and FIZ _NFIZ (3c) in FIG. The preamble interval holds signaling information used to receive the data stream within the data interval. Each frequency domain has the same position in the frequency domain for each of the multiple frames in the super-frame.

Data streams are mapped to frequency domains, typically one data stream is mapped to one frequency domain. In particular, PLP ₁ 4a and PLP ₁ 4b map to FIZ ₁ 3a, PLP ₃ 4c and PLP4 4d map to FIZ ₁ 3b, and PLP ₅ 6 and PLP ₆ 6b map to FIZ _NFIZ .

Signaling information words conveying signaling relating to the location and bandwidth of at least the first frequency domain in the frequency domain to aid in the reception of the data stream are included in the preamble portion of at least the first frame of the super-frame, but typically It is included in the "L1-config" part of each frame.

Thus, it can be understood that the preamble comprising the signaling information word will be transmitted within a wider frequency bandwidth (typically corresponding to the full symbol bandwidth) than each frequency domain. This enables the receiver to use the reduced bandwidth, thus saving power by reducing the sampling rate of receiving the data stream. However, by using the full symbol bandwidth to receive the preamble interval, one can avoid the need to copy the information in the preamble between the frequency domains, which may be necessary if the receiver wants to use all the bandwidths of the frequency domains.

Another benefit of reducing the transmission bandwidth and consequently increasing the transmission time period will be an increase in robustness, especially in mobile communication environments. It is desirable to trade off the reduction in frequency-diversity to the gain of time diversity by doing some sort of trade-off in time and frequency diversity by increasing the transmission time period by reducing the bandwidth. You may.

     In-band signaling may be included in the data stream of the frame. This allows signaling information, in particular "L1-dyn", to be received within the bandwidth of the frequency domain, so that the receiver can maintain a second bandwidth for the reception of the data stream (a wider bandwidth, typically a first frame). After the initial reception of the preamble at < RTI ID = 0.0 >

      As can be seen in Figure 1, each frequency domain is mapped to sub-carriers of consecutive transmission symbols in frequency. This has the advantage that the frequency band occupied by the mapped frequency domain is minimized, leaving gaps in the frequency domain would be wasteful for receiver bandwidth.

      Data is typically interleaved in frequency, and the frequency interleaving order can vary with orthogonal frequency division modulation (OFDM) symbols. This can provide greater robustness. Typically pilot tones are inserted into transmission symbols in a pattern independent of segmenting each data interval of the plurality of frames into frequency domains. This simplifies the implementation of the transmitter and receiver because the above division can be performed independently of the configuration of the physical layer.

As part of the process of determining the bandwidth to be used for the frequency domain, which is typically done for a super-frame, one lower limit may be determined for the bandwidth of the frequency domain based on the configuration of pilot tones mapped to the frequency domain. . In this way, minimal robustness for transmission in the first frequency domain can be maintained because such robustness is dependent on the configuration of pilot tones. Any number of pilot tones will need to be present in the portion of the symbol to which the first frequency region is mapped.

The division of the data interval of each frame can be done at the logical frame level, thereby simplifying the implementation of the transmitter and receiver and allowing the location and bandwidth of the frequency domains to be allocated flexibly.

If the data stream contains elements of the scalable video coding scheme, it would be desirable to map those elements to the same frequency domain in a given frame. This allows the receiver to return to a more robust element or to select a higher speed element without changing the bandwidth used by the receiver.

In addition to dividing the data interval of each frame into frequency domains, namely frequency interleaving regions, the data interval may also be divided into multiple time domains or time interleaving frame segments. The data streams may first be mapped to time interleaving frames.

3 is a schematic diagram illustrating mapping of time interleaving frame segments to frequency interleaving regions according to an embodiment of the present invention.

As shown in FIG. 3, the time interleaving frame 22 may then be mapped to time interleaving frame segments 24a, 24b, 24c. A second signaling information word that carries signaling regarding the location of at least one of the time interleaving frame segments within a given frame may be included in the preamble interval of the given frame, typically in the “L1-config” field. .

If a time interleaving frame or a plurality of time interleaving frames are to be mapped directly to a frequency interleaving region, even if the amount of data carried by the time interleaving frame (s) is not equal to the capacity of the frequency interleaving region, the padding is at that frequency. It will need to be included in the interleaving area. The padding will be wasted capacity if it does not carry data. In one embodiment of the present invention, as a result of the mapping of the time interleaving frame to the time interleaving frame segments, it is possible to avoid the need to add padding in one frequency domain, since the capacity of each time interleaving frame segment is efficient Because it can be configured to fill the rest of one frame. For example, in FIG. 3, time interleaving frame 22 is mapped to two time interleaving frame segments, namely TIFS ₀ 24a and TIFS ₁ 24b. The first time interleaving frame segment TIFS ₀ ; 24a is mapped to fill the remaining capacity in the frequency interleaving region of the first frame 5a, and the second time interleaving frame segment TIFS1; 24b is a second frame ( 5b).

The mapping of the time interleaving frame 22 to the time interleaving frame segments 24a and 24b and the frames 5a and 5b can be performed in real time, so that flexible scheduling can be implemented. It is not necessary here to determine the number of time interleaving frame segments per frame, or how many frames 5a, 5b the time interleaving frame is mapped to. The time interleaving frame can be mapped to start and end at any point in one frame 5a and at any point in the super-frame without having to fix these points in advance.

The second signaling information word may convey information about the timing of subsequent time interleaving frame segments, thereby preventing the receiver from receiving periods between time interleaving frame segments, thereby reducing power consumption and allowing the receiver to Prepare to receive subsequent time interleaving frame segments.

4 is a schematic diagram illustrating a transmitter system according to an embodiment of the present invention.

4 shows the structure of a typical transmitter to enable division into frequency domains and time interleaving frame segments. The data stream consists of different physical layer pipes (hereinafter referred to as "PLPs") and each PLP 400, 420, and 430 is a contiguous Time Interleaving Frame (hereinafter referred to as "TIF"). It consists of For example, PLP_One400 TIF_1.0405, TIF_1.1(410) … TIF_1.NIt consists of 415 consecutive. Data of each TIF is interleaved according to a predefined time interleaver.

The TIF segmentation and frequency interleaving zone (FIZ) mapping block 440 arranges the plurality of PLPs 400, 415, 430 into specific FIZs 460, 465, 470, 475. Different PLPs of an FIZ are interleaved by a frequency interleaver predefined according to that FIZ.

Signal generation block 450 contains information about the logical frame structure associated with the PLP, TIF, and FIZ.

The OFDM generator 480 constitutes an OFDM cell block in frequency. This process is just the construction of an OFDM grid. The OFDM generator 480 receives the signaling information and the data stream, maps the signaling information, and maps the data stream to the OFDM resource. The pilot inserter also inserts pilots in the transmitted frame dependent pilot pattern.

Logic Frame Assembly (LFA) 490 includes a logical frame structure by combining different TIFs and FIZ. For example, FIG. 2 describes a logical frame structure that is the output of a logical frame assembly.

5 is a schematic diagram illustrating mapping of frequency interleaving regions to physical layer regions according to an embodiment of the present invention.

As shown in FIG. 5, each frame may be divided into two or three or more physical layer regions 24 and 26 having different physical layer characteristics. The characteristic typically varies between regions to provide different levels of robustness, such that a portable portable receiver can typically receive, for example, a more robust area, while a fixed receiver with a good antenna is better. High capacity area can be received. The physical properties vary between regions in terms of fast Fourier transform size, number and pattern of pilot tones, multiple input multiple output (MIMO) schemes, and guard intervals. You may. Preferably, each of the plurality of frequency regions maps for the same frequency bandwidth for each physical layer region. This allows the receiver to use the same bandwidth to receive the frequency domain within each physical layer region of a frame.

Each time interleaved frame segment may be mapped to one physical layer region within a predetermined time.

Interleaving in the frequency interleaving region and / or in the time interleaving frame segment may be frequency-wise interleaving, whereby successive portions of a data stream are divided into portions of an orthogonal frequency division modulation symbol. Mapped over frequency, and then the mapping typically proceeds to map as frequency for portions of another orthogonal frequency division modulation symbol. Alternatively, the mapping may be time-wise interleaving, whereby successive portions of a data stream are temporally mapped over a series of orthogonal frequency division modulation symbols, and then typically The mapping proceeds to map in time to other frequency portions of successive quadrature modulation symbols.

In the receiver, a sampling frequency suitable for the second bandwidth and a bandwidth of an analog filter may be set based on the signaling information word, so that the receiver is provided for a minimum power consumption that matches the bandwidth of the frequency domain to be received. There is a number.

6 is a schematic diagram illustrating a receiver according to an embodiment of the present invention.

6 shows an example of a receiver suitable for receiving data frames having variable bandwidth frequency regions. The receiver includes a signal processing unit, which typically includes a down-converter, which downlinks the received signal for baseband demodulation to IF1 (Intermediate Frequency 1) (IF1). 600) Convert to a signal. The received signal is downconverted on the desired frequency (f ₀ ) 610 that can be controlled by the controller 620. The downconverted signal is filtered through a band pass filter (BPF) 630, and the filtered signal has an 8 MHz bandwidth defined by a broadcasting system. The output of the bandpass filter is converted to an intermediate frequency 2 (IF2) 640 and filtered through a low pass filter (LPF) 660. In addition, the frequency of FIZ (f _FIZ ) 650 and IF2 640 are controlled by controller 620. The output signal of the LPF 660 has a narrow bandwidth of 1.7 to 3.5 MHz. Next, the analog-to-digital converter (ADC) 670 converts the analog output signal of the FIZ 650 into a digital signal. Finally, the digital signal is demodulated by a demodulator 680.

7 is a schematic diagram illustrating another embodiment of a receiver according to another embodiment of the present invention.

FIG. 7 illustrates an alternative configuration of the receiver for the receiver of FIG. 6, wherein the overall symbol bandwidth is the first frame of the super-frame, typically the full frame, or receives the preamble, or the rest of the super-frame. It may be used to effectively adjust the analog receive bandwidth to be suitable for receiving the frequency domain for the frames.

Referring to FIG. 7, the tuner 700 receives a radio broadcast by radio transmission of a radio wave and converts such radio broadcasts into a desired frequency signal. Channel and FIZ selector 720 controls tuner 700 to down-convert to desired frequency f ₀ . The output signals, I and Q components of the tuner 700 are input to a remodulator 710 to adjust the analog receive bandwidth. The output of the remodulator 710 is filtered through the LPF 730. The desired FIZ signal from the output of LPF 730 is selected at the BW selector 740 controlled by the channel and FIZ selector 720. The analog-to-digital converter (ADC) 750 converts the output of the BW selector 740, which converts the analog output signal of the desired FIZ allocated at f _sh into a digital signal. The converted digital signal is demodulated by the Next Generation Handheld (NGH) demodulator 760.

8 is a schematic diagram illustrating mapping of frequency interleaving regions to physical layer regions in mode A according to an embodiment of the present invention.

8 illustrates TIFS mapping mode A in which the TI-frame is composed of multiple CodeWords (CWs), which are divided into three Time Interleaving Frame Segments (TIFS) 24d, 24e, 24f. These are mapped to different frequency regions 3a, 3b, 3c of successive frames 5a, 5b, 5c. The L1 symbol signaling information on the frame structure is located at the beginning of the frame.

9 is a schematic diagram illustrating mapping of frequency interleaving regions to physical layer regions in mode B according to an embodiment of the present invention.

9 illustrates TIFS mapping mode B in which the TI-frame is composed of multiple CodeWords (CWs), which are divided into three Time Interleaving Frame Segments (TIFS) 24d, 24e, 24f. These may be mapped to different frequency regions 3a, 3b, 3c of certain frames 5d.

One TIFS mapping mode A means that it is transmitted on successive frames, and another TIFS mapping mode B implies that a TI-frame is transmitted on one frame.

10-18 show examples of signaling words that can be used in embodiments of the present invention.

FIG. 10 is a table illustrating L1-config signaling field according to an embodiment of the present invention. FIG.

10 shows an example of "L1-config" in the embodiment of the present invention. Portions indicated by reference numeral 30 are specific to the embodiment of the present invention. The total number of physical layer pipes used in the super-frame is indicated by "MUM_PLP", and each of the frames of the super-frame with respect to the number of physical layer pipes in which signaling information is carried in the first signaling information field is transmitted. The limit applicable to is passed by "NUM_PLP_IN_L1DYN".

11 is a table illustrating an L1-dynamic signaling field according to an embodiment of the present invention.

11 shows an example of an "L1-dynamic" word (referred to as a first signaling information field) in an embodiment of the present invention. The parts indicated by the reference numerals 32 and 34 are specific to the embodiments of the present invention. The portions indicated by reference numeral 32 relate to information about physical layer pipes, which are conveyed in the "L1 dynamic", ie signaling information field, rather than the "L1 dynamic-EXT" word. Most of the definitions of the signaling fields have been described in the DVB-T2 standard, and detailed signaling definitions related to the present invention are as follows.

NUM_PLP_IN_L1DYN : Number of data streams signaled as first signaling information in the current frame.

PLP_ID : This 8-bit field indicates the ID of the PLP that carries the data stream.

PLP_START This 22-bit field indicates the start (position) of the PLP in the frame.

PLP_NUM_BLOCKS : This 10-bit field indicates the number of FEC blocks encapsulated in the PLP.

The portions indicated by reference numeral 34 are "NUM_PLP_ext", which may indicate the number of physical layer pipes whose signaling information is carried in the "L1 dynamic-EXT" word, and "NUM_IDLE_PLP" is idle in the frame. It is related to the number of physical layer pipes of. The definition of signaling related to the present invention is as follows.

NUM_PLP_ext : This 8-bit field indicates the number of active PLPs in the second signaling portion (when the number of PLPs in the frame exceeds the threshold).

NUM_IDLE_PLP : This 8-bit field indicates the number of idle PLPs in the current frame.

12 is a table illustrating an L1-dynamic-Ext signaling field according to an embodiment of the present invention.

12 shows an example of an "L1 dynamic_EXT" word (referred to as a second signaling information field) in an embodiment of the present invention. The signaling word is specific to embodiments of the present invention. The portions indicated by reference numeral 36 carry signaling information about physical layer pipes that were not included in the "L1-dynamic" word and about physical layer pipes in an idle state. Signaling definitions related to the present invention are as follows.

PLP_ID, PLP_START, PLP_NUM_BLOCKS : Same as the signaling definition given in FIG. 12, but here for the PLP in the extended part.

PLP_DELTA : This 8-bit field indicates the relative timing at which the PLP in idle state will be activated again.

FIG. 13 is a table illustrating L1-config signaling field according to an embodiment of the present invention. FIG.

FIG. 13 shows another example of an " L1 config " signaling word in an embodiment of the present invention that includes signaling regarding time interleaving frame segments. The parts indicated by the reference numerals 38, 40 and 42 are specific to the embodiments of the present invention. Signaling definitions related to the present invention are as follows.

NUM_FIZ : This 3-bit field indicates the number of FIZs.

NUM_TIFS_a : This 8-bit field indicates the number of TIFS in the frame.

PLP_TIF_NUM_BLOCKS : This 10-bit field indicates the number of FEC blocks used in one time interleaving frame for a given PLP.

FIZ_LENGTH : This 10-bit field indicates the size of one FIZ in an OFDM cell.

FIZ_MAPPING_TYPE : This 1-bit field indicates the mapping type of the FIZ. This field is set to '1' when TIFS Mapping Mode A is applied and to '0' when TIFS Mapping Mode B is applied.

14 is a table illustrating still another example of an L1-dynamic signaling field according to an embodiment of the present invention.

14 shows another example of an "L1-dynamic" signaling word (referred to as a first signaling information field) in an embodiment of the present invention that includes signaling regarding time interleaving frame segments. The parts indicated by the reference numerals 44 and 46 are specific to the embodiments of the present invention. Signaling definitions related to the present invention are as follows.

PLP_ID : This 8-bit field indicates the ID of the PLP that carries the data stream.

PLP_TIFS_START : This 21-bit field indicates the starting position in the TIFS.

PLP_TIFS_LENGTH : This 15-bit field indicates the size of the PLP in the TIFS.

PLP_TIFS_TYPE : This 2-bit field indicates the type of PLP in the given TIFS (PLP Type 1 or Type 2).

PLP_TIFS_DRAME_IDX : This 1-bit field indicates the frame index of the PLP mapped for the TIFS.

PLP_TUFS_DELTA : This 4-bit field indicates the relative timing from the current TIFS to the next TIFS that will carry the PLP (PLP ID).

FIZ_ID : This 1-bit field indicates the ID of the FIZ accompanying the TIFS.

NUM_PLP_ext : This 8-bit field indicates the number of active PLPs in the second signaling part (if the number of PLPs in the frame exceeds the limit).

NUM_IDLE_PLP : This 8-bit field indicates the number of PLPs in the current frame.

FIG. 15 is a table illustrating still another example of an L1-dynamic-Ext signaling field according to an embodiment of the present invention. FIG.

FIG. 15 shows another example of an "L1-config-ext" signaling word (referred to as a second signaling information field) in an embodiment of the present invention including signaling regarding time interleaving frame segments. The signaling word is unique to embodiments of the present invention. For TIFS_ext these signaling fields are similar to the signaling fields in FIG. 14, but this time for extended TIFS. IDLE_PLP, PLP_ID and PLP_DELTA are similar to the definitions in FIG.

16 is a table illustrating in-band signaling in an embodiment of the present invention.

16 shows an example of an in-band signaling word in an embodiment of the present invention that includes signaling regarding time interleaving frame segments. The parts indicated by the reference numeral 50 are specific to the embodiments of the present invention. The signaling fields related to the present invention are similar to the definition of FIG. 14, but because they are in-band signaling here they are inserted into a given / desiring PLP.

17 shows a table representing an L1-pre signaling field according to an embodiment of the present invention.

17 shows an example of an " L1-pre " signaling word in an embodiment of the present invention that includes signaling relating to physical layer regions. Portions indicated by reference numeral 52 are specific to the embodiments of the present invention. The signaling definition related to the present invention is as follows.

PZ0_PILOT_PATTERN : This 4-bit field indicates the pilot pattern in physical zone 0 (the first physical zone).

PZ0_GUARD_INTERVAL : This 3-bit field indicates the guard interval used for physical zone 0 (the first physical zone).

NUM_PZ : This 3-bit field indicates the number of physical regions.

18 is a table illustrating still another example of an L1-config signaling field according to an embodiment of the present invention.

18 shows another example of an " L1-config " signaling word in an embodiment of the present invention that includes signaling relating to physical layer regions. The parts indicated by the reference numerals 60, 54, 56 and 58 are specific to the embodiments of the present invention. The signaling definition related to the present invention is as follows.

Reference numeral 54 is the same as in reference numeral 40.

FIZ_LENGTH : This 10-bit field indicates the number of cells (capability of frequency interleaving area).

FIZ_MAPPING_TYPE : This 1-bit field indicates whether frequency or time-to-method mapping is used (mode A or B).

PZ_FFT_SIZE : This 4-bit field indicates the FFT size of the physical area.

PZ_PILOT_PATTERN : This 1-bit field indicates the pilot pattern used for a given physical region.

PZ_GUARD_INTERVAL : This 1-bit field indicates the OFDM guard interval used for a given physical region.

Reference numeral 60 is the same as in reference 38.

The foregoing embodiments should be understood as merely illustrative of the invention. Those skilled in the art will appreciate that any feature (s) described in connection with any one embodiment, by itself or in combination with other features described, may also be combined with one or multiple features of any other of the foregoing embodiments. It will be appreciated that it may be used in combination with any of the other embodiments. Moreover, any equivalents and modifications not particularly described above may be utilized in the present invention without departing from the scope of the invention as defined by the following claims.

440: TIF segmentation and FIZ mapping block 450: Signal generation block
480: OFDM generator 490: logic frame assembly

Claims (20)

In the broadcast system, a data transmission method including a data stream,
Generating a frame comprising a preamble section carrying signaling information and a data section carrying a data stream; And
Transmitting the frame to a receiver,
Generating the frame
Segmenting the data section of the frame into a plurality of frequency zones; And
Mapping the data stream to one frequency zone of the plurality of frequency zones,
The signaling information includes segment information of the frequency zone. The method of claim 1,
The preamble is transmitted in a first frequency bandwidth, the data stream is transmitted in a frequency zone having a second frequency bandwidth,
And wherein the first frequency bandwidth is greater than the second frequency bandwidth. The method of claim 1,
The segment information includes numerical information of the frequency zone and size information of each frequency zone. The method of claim 1,
Inserting a pilot tone in a pattern in the frame independently of the segments. The method of claim 1,
Mapping a component carried in the frame to the same frequency zone,
The data stream includes a component of a scalable video coding scheme. The method of claim 1,
The preamble includes an L1-config section, an L1-dynamic section, and an L1-dynamic EXT section.
The L1-config section typically contains the same signaling information for each frame of the super frame, the L1-dynamic section contains the signaling information for receiving the first number of data streams, and the L1-dynamic EXT section. Is signaling information for receiving an additional data stream after the first time of the data stream. A method for receiving data including a data stream in a broadcasting system, the method comprising:
A preamble section carrying signaling information and a data section carrying a data stream, the data section comprising a frame segmented into a plurality of frequency zones. receiving a frame); And
Demodulating the frame;
The data stream is mapped to one frequency zone of the plurality of frequency zones,
The signaling information includes segment information of the frequency zone. The method of claim 7, wherein
The preamble is received in a first frequency bandwidth, the data stream is received in a frequency zone having a second frequency bandwidth,
And wherein the first frequency bandwidth is greater than the second frequency bandwidth. The method of claim 7, wherein
The segment information includes numerical information of the frequency zone and size information of each frequency zone. The method of claim 7, wherein
And the frame includes a pilot tone in a pattern independent of the segments. The method of claim 7, wherein
Mapping a component carried in the frame to the same frequency zone,
The data stream includes a component of a scalable video coding scheme. The method of claim 7, wherein
The preamble includes an L1-config section, an L1-dynamic section, and an L1-dynamic EXT section.
The L1-config section typically contains the same signaling information for each frame of the super frame, the L1-dynamic section contains the signaling information for receiving the first number of data streams, and the L1-dynamic EXT section. Is signaling information for receiving an additional data stream after the first time of the data stream. A transmitter for transmitting data including a data stream in a broadcasting system,
A segment and mapping section for segmenting a data section carrying a data stream in a frame into a plurality of frequency zones and mapping the data stream to one frequency zone of the plurality of frequency zones;
A signal generator for transmitting signaling information;
An OFDM generator for mapping the data stream and the signaling information to an orthogonal frequency division multiplexing (OFDM) resource,
The signaling information includes segment information of the frequency zone. The method of claim 13,
The signaling information is transmitted in a first frequency bandwidth, the data stream is transmitted in a frequency zone having a second frequency bandwidth, and the first frequency bandwidth is greater than the second frequency bandwidth. The method of claim 13,
The segment information includes numeric information of the frequency zone and size information of each frequency zone. The method of claim 13,
The signaling information includes an L1-config section, an L1-dynamic section, and an L1-dynamic EXT section.
The L1-config section typically contains the same signaling information for each frame of the super frame, the L1-dynamic section contains the signaling information for receiving the first number of data streams, and the L1-dynamic EXT section. Is signaling information for receiving an additional data stream after the first time of the data stream. A receiver for receiving data including a data stream in a broadcasting system, the receiver comprising:
Processing to decode the received signal, the received signal comprising at least one frame, the frame comprising a preamble section for carrying signaling information and a data section for carrying a data stream a data processor comprising: a signal processing unit segmented into a plurality of frequency zones;
A control unit which controls the signal processing unit to process the data stream received via the signaling information and the segmented frequency zones of a plurality of frequency zones;
A decoder which decodes the data stream and the signaling information,
And the signaling information includes segment information of the frequency zone. The method of claim 17,
Signaling information is transmitted in a first frequency bandwidth, the data stream is transmitted in a frequency zone having a second frequency bandwidth,
The first frequency bandwidth is greater than the second frequency bandwidth. The method of claim 17,
The segment information includes numeric information of the frequency zone and size information of each frequency zone. The method of claim 17,
The preamble includes an L1-config section, an L1-dynamic section, and an L1-dynamic EXT section.
The L1-config section typically contains the same signaling information for each frame of the super frame, the L1-dynamic section contains the signaling information for receiving the first number of data streams, and the L1-dynamic EXT section. Is signaling information for receiving an additional data stream after the first time of the data stream.

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