KR20090118812A - Method and apparatus for data transferring for time-slicing mode, and method and apparatus for data receiving by time-slicing mode - Google Patents

Abstract

PURPOSE: A method and an apparatus for transmitting data in a time division mode, and a method and an apparatus for receiving data in the time division mode are provided to selectively recover only data having information suitable for a device with various resolution by low power. CONSTITUTION: Data of the same layer among data of an original fame are rearranged. A transmission frame is generated(1210). The data of the original frame are classified in a layer structure in consideration of resolution. The layer structure can be classified according to a range as well as the resolution. The range includes data showing detailed information. A plurality of transmission frames corresponding to the original frames is transmitted to a transmission order in consideration of the layer structure(1220). The transmission order can be determined in consideration of the layer structure.

Description

Method and apparatus for transmitting data using time division method, and method and apparatus for receiving data using time division method {Method and apparatus for data transferring for time-slicing mode, and method and apparatus for data receiving by time-slicing mode}

The present invention relates to the transmission of data via a time division scheme and the reception of data by a time division scheme.

Compared to general CE (Customer Electoronic) devices, the data transmission / reception technology for mobile devices, which have low power and low information processing capability, uses time-slicing technology to reduce power consumption of the mobile devices, and After dividing the capacity into fixed time slots, packetized broadcast signals are carried in each time slot.

The present invention proposes a technique for reconstructing and transmitting data according to a hierarchical structure on a time axis, and demodulating and restoring data of at least one layer according to the hierarchical structure.

According to an embodiment of the present invention, a method of transmitting data through a time division method includes generating a transmission frame by rearranging data of the same layer among data of an original frame classified into a hierarchical structure considering resolution; And transmitting a plurality of transmission frames corresponding to the plurality of original frames in a transmission order considering the hierarchical structure.

In the data transmission method according to an embodiment, the original frame may include dividing the original frame into interval units including a predetermined number of data of the data of the original frame based on the hierarchical structure considering the resolution.

The generating of the transmission frame of the data transmission method according to an embodiment may include: generating a data group of the same position for each position in the interval from the data of the original frame; And generating a transmission frame in which the data groups for each location in the section are arranged according to the data location order in the section.

In the hierarchical structure classification step of the data transmission method according to an embodiment, if the data is image data, the data of the original frame may be divided in block units.

The data transmission method according to an embodiment may further include performing error correction coding on at least one layer of data of the original frame.

The transmitting step of the data transmission method according to an embodiment may include determining the transmission order in consideration of the hierarchical structure and the error correction coding.

In the error correction coding step of the data transmission method according to an embodiment, the strength of the error correction coding may vary according to a layer corresponding to the resolution.

The transmitting step of the data transmission method according to an embodiment may include: determining the transmission order such that data groups of the same layer among the plurality of transmission frames are continuously transmitted according to the transmission frame order; And determining the transmission order such that the data groups for each layer of the plurality of transmission frames are continuously transmitted according to the rank of the hierarchical structure. And transmitting the plurality of transmission frames according to the determined transmission order.

The transmitting step of the data transmission method according to an embodiment may include a step in which data groups for each layer of the rearranged transmission frame are allocated to a time-divided time slot and transmitted.

The data transmission method may further include classifying data of the original frame based on a hierarchical structure in consideration of resolution.

The transmitting step of the data transmission method according to an embodiment may include: determining the transmission order such that hierarchical data groups of one transmission frame are continuously transmitted according to the rank of the hierarchical structure; Determining the transmission order such that data of the plurality of transmission frames is continuously transmitted according to the transmission frame order; And transmitting the plurality of transmission frames according to the determined transmission order.

According to an embodiment of the present invention, a method of receiving data by a time division method includes: receiving data arranged according to a time division method based on a hierarchical structure considering resolution; Demodulating a data group of at least one layer of the received data; And combining the demodulated data to generate an output frame.

The demodulation step of the data reception method according to an embodiment may include: determining a demodulation period of the data based on the hierarchical structure; And demodulating a data group of at least one layer of the received data according to the determined demodulation period.

The data receiving step of the data receiving method according to an embodiment may receive data in units of frames in which data groups for each layer according to a hierarchical structure considering the resolution are arranged.

The determining of the demodulation period of the data receiving method according to an embodiment may include determining the demodulation period as a partial period during which a data group of at least one layer of the frame period is received, wherein the frame period is one A frame is received, and a plurality of frames may be received periodically according to the frame order.

The determining of the demodulation period of the data receiving method according to an embodiment may include determining the demodulation period as a layer period corresponding to at least one layer of data of a plurality of frames, wherein the layer period includes a plurality of frames. The data group of one layer among the data of the period is received, the data group for each layer can be received periodically periodically according to the rank of the hierarchy.

In the demodulation period determining step of the data receiving method according to an embodiment, the demodulation period may be determined as a period during which a data group of at least one layer corresponding to a predetermined resolution is received.

The output frame generating step of the data receiving method according to an embodiment may include generating an output frame divided into interval units for a predetermined number of data; Determining a data location in the section corresponding to the hierarchy of the hierarchy; And aligning a data group for each layer according to the hierarchical structure among the demodulated data to a data position corresponding to each section of the output frame.

In the data receiving method according to an embodiment, the section of the output frame may be a section including the same number of data as the number of demodulated layers.

The data receiving method according to an embodiment may further include decoding an error correction code on a data group of at least one layer of the demodulated data.

In the demodulation period determining step of the data receiving method according to an embodiment, the demodulation period of the data may be determined in consideration of the layer of the data group and whether the error correction coding is performed.

In the error correction code decoding step of the data reception method according to an embodiment, the strength of the error correction coding may be adjusted according to the hierarchy of the data group.

According to an embodiment of the present invention, an apparatus for transmitting data through a time division scheme includes: a hierarchical structure classifying unit classifying data of an original frame into a hierarchical structure considering resolution; A transmission frame generation unit for rearranging data of the same layer among the data of the original frame to generate a transmission frame; And a transmission unit transmitting a plurality of transmission frames corresponding to the plurality of original frames in a transmission order considering the hierarchical structure.

The apparatus for transmitting data according to an embodiment may further include an error correction coding unit configured to perform error correction coding on at least one layer of data of the original frame.

The data transmission apparatus according to an embodiment may include: a demultiplexer for rearranging data of the original frame based on the hierarchical structure and the order of the original frame; And at least one buffer for storing data of the transmission frame.

According to an embodiment of the present invention, an apparatus for receiving data by a time division method may include: a data receiving unit configured to receive data arranged according to a time division method based on a hierarchical structure considering resolution; A demodulator for demodulating a data group of at least one layer of the received data; And an output frame generator for generating an output frame by combining the demodulated data.

The demodulator of the data receiving apparatus according to an embodiment includes a demodulation period determiner configured to determine a demodulation period of the data based on the hierarchical structure, and includes a demodulation period determiner of at least one layer of the received data according to the determined demodulation period. The data group can be demodulated.

The data receiving apparatus according to an embodiment may further include an error correcting code decoding unit for decoding an error correcting code on the data group of at least one layer of the demodulated data.

The data receiving apparatus according to an embodiment may include: a demodulation power control unit controlling a voltage of the demodulation unit according to the demodulation period; A demultiplexer for constructing the output frame by arranging the data according to the order of the output frame and the data layer according to the hierarchical structure of the received data; And at least one buffer for storing the output frame.

The present invention includes a computer readable recording medium having recorded thereon a program for implementing a method of transmitting data through a time division method according to an embodiment of the present invention.

The present invention includes a computer-readable recording medium having recorded thereon a program for implementing a method of receiving data by a time division method according to an embodiment of the present invention.

1 is a block diagram of a data transmission apparatus according to an embodiment of the present invention.

According to an embodiment of the present invention, the data transmission apparatus 100 through a time division method includes a transmission frame generation unit 110 and a transmission unit 120. The data transmission apparatus 100 according to an embodiment may further include an error correction coding unit (not shown) that performs error correction coding on at least one layer of data of the original frame. In addition, the data transmission apparatus 100 may further include a hierarchical structure classifier (not shown) that classifies the original frame into a hierarchical structure considering resolution.

The hierarchical structure considering the resolution represents a hierarchical structure according to the ability to express more detailed information. The data of the original frame is divided into sections each including a predetermined number of data. At this time, the order or position of the data on each section indicates the hierarchy corresponding to the data by the hierarchical structure. Alternatively, a data range including at least one data on each section may correspond to a layer.

Data handled by the data transmission apparatus 100 may be various data such as sound and video, and is not limited to one category of data. For example, when the data of the original frame is 2D image data, the data of the original frame may be divided in block units.

For example, the original frame may be divided into N blocks, and each block may include M data. According to an example, if the data position in the interval corresponds one-to-one to the hierarchy, the position of k data in the block including the data of 1 to M indicates the hierarchy of the data (k is an integer of 1 to M).

The error correction coding unit (not shown) of the data transmission apparatus 100 may perform error correction coding on the data group of at least one layer for each layer. The error correction coding unit (not shown) may perform error correction coding on a data group corresponding to a predetermined layer determined that error correction coding is necessary according to a need to be protected from transmission errors.

Therefore, error correction coding may be performed on the data group of one layer or the data groups of several layers corresponding to the predetermined resolution. As another example, error correction coding may be performed on the data groups of all the layers, and the strength of the error correction coding may be adjusted according to the layer of the data group. For example, the strength of the error correction coding for the data group of the layer corresponding to the predetermined resolution having a high need for protection from errors may be adjusted so as to be stronger than the strength of the error correction coding for the data group of the remaining layers.

The transmission frame generation unit 110 rearranges data of original frames classified in a hierarchical structure for each layer, generates a transmission frame in which data of the same layer is arranged, and outputs the transmission frame to the transmission unit 120.

The transmission frame generation unit 110 may generate a data group of the same position for each location in the section of the data of the original frame, and generate a transmission frame in which the data groups for each location in the section are arranged according to the data location order in the section. . Referring to the example of the above-described image data, the transmission frame generation unit 110 selects data of data positions of 1 to M for each block, and includes data including the total number N of blocks for each data position. Create groups. The transmission frame generation unit 110 generates a transmission frame in which data groups for each data position are arranged according to the data position order (that is, 1, 2, ..., M).

The transmission unit 120 transmits data of a transmission frame in which data of a plurality of original frames is classified into a hierarchical structure and data of the same layer are arranged through the transmission frame generation unit 110. A transmission frame may correspond one-to-one to each original frame.

In this case, the transmission order of the transmission frame may be determined based on the hierarchical structure. In addition, when error correction coding is performed on the data through the error correction coding unit (not shown), the transmitter 120 may determine the transmission order in consideration of the hierarchical structure and the error correction coding.

The transmitting unit 120 first determines a transmission order such that data groups of the same layer of each frame among the plurality of transmission frames are continuously transmitted according to the transmission frame order, and the data groups for each layer are assigned to each hierarchical rank in a hierarchical structure. Therefore, the transmission order may be determined to be transmitted continuously. That is, after the data group of the k data positions of all the blocks of all the frames are transmitted in sequence in the frame order, the data group of the k + 1 (or k-1) data positions of all the blocks of all the frames in accordance with the frame order The transmission order is determined to be transmitted continuously, and data groups of the same layer of all frames may be collectively transmitted.

At this time, the data groups of a predetermined layer represent a set of data groups each of which is a data group which is a set of N data of a predetermined layer among 1 to M layers of a frame.

On the other hand, the transmitter 120 first determines a transmission order so that the data groups for each layer of a transmission frame may be continuously transmitted according to the hierarchical order, and the data of the plurality of transmission frames may be continuously transmitted according to the transmission frame order. The order of transmission may be determined. That is, all the data on one transmission frame are transmitted according to the hierarchical order, the transmission order is determined so that the data on the next transmission frame is transmitted, and data of the same frame can be transmitted.

Although not shown in FIG. 1, the data transmission apparatus 100 may include a demultiplexer for rearranging data of an original frame based on a hierarchical structure and an order of an original frame, and at least one storage space for storing data of a transmission frame. It may further include a buffer or memory.

2 is a block diagram of a data receiving apparatus according to an embodiment of the present invention.

According to an embodiment of the present invention, the data receiving apparatus 200 according to the time division method includes a data receiver 210, a demodulator 220, and an output frame generator 230. Although not shown in FIG. 2, another embodiment of the data receiving apparatus 200 may further include an error correction coding decoder.

The data receiver 210 receives the data arranged according to the time division method based on the hierarchical structure considering the resolution, and outputs the data to the demodulator 220. The received data is a form in which the data in the frame is rearranged according to a hierarchical structure.

The data receiver 210 of one embodiment may receive data in units of frames in which data groups for each layer according to a hierarchical structure are arranged. According to an embodiment of the data receiver 210, data groups of the same layer of all frames may be continuously received in the order of frames, and data groups of each layer may be continuously received according to the hierarchical order. Further, another embodiment of the data receiver 210 continuously receives the data groups for each layer of each frame according to the rank of the hierarchical structure, and receives the respective frame data in the frame order.

The demodulator 220 demodulates a data group of at least one layer among data received by the data receiver 210 and outputs the demodulated data to the output frame generator 230. The demodulator 220 according to an exemplary embodiment may include a demodulation period determiner (not shown) that determines a demodulation period of data based on a hierarchical structure. The demodulator 220 may demodulate a data group of at least one layer among data received according to a demodulation period determined by a demodulation period determiner (not shown). Another embodiment of the data receiving apparatus 200 may include a demodulation period determiner (not shown) as a subcomponent of the demodulator 220 as an independent component.

The demodulation period determiner (not shown) may determine the demodulation period as a partial period during which the data group of at least one layer of the frame period is received. The frame period is a period in which one frame is received, and the plurality of frames may be received periodically and continuously in a frame order. For example, a demodulation period determiner (not shown) may demodulate a data group of one layer corresponding to a predetermined resolution for each frame, or to demodulate data groups of several layers corresponding to a predetermined resolution. May be determined as some of every frame period.

The demodulation period determiner (not shown) may determine the demodulation period as a layer period corresponding to at least one layer of data of the plurality of frames. At this time, the hierarchical period indicates a period in which a data group of one layer is received when data groups of the same layer are continuously received among the data of a plurality of frames, and the data groups for each layer are periodically received according to the hierarchical order.

For example, a demodulation period determiner (not shown) may determine a demodulation period in a period in which all the frames are received so as to demodulate a data group of one layer or data groups of several layers corresponding to a predetermined resolution for each frame. The data group of the layer may be determined to be a partial interval in which the data groups are received.

The error correction coding decoding unit (not shown) of another embodiment performs decoding of the error correction code on the data group of at least one layer of the demodulated data. In another embodiment, the error correction code decoder (not shown) may have different strengths of the error correction coding according to the hierarchy of the data group, so that the decoding level of the error correction code may be adjusted. In addition, the error correction code decoding unit (not shown) of another embodiment may perform error correction code decoding only on the data group of some layers of the demodulated data.

According to an embodiment of the demodulation period determiner (not shown), an appropriate demodulation period may be selected to adjust a service reception amount or a restoration amount according to a channel environment or a communication standard.

The demodulation period determiner (not shown) of another embodiment may determine the demodulation period of the data in consideration of the hierarchical structure and the error correction coding. In order to determine the demodulation period in consideration of the region in which the error correction coding is performed, whether the error correction coding for the data group as well as the layer of the data group may affect the demodulation period of the data.

The data receiving apparatus 200 according to an exemplary embodiment may further include a demodulation power control unit controlling a voltage of the demodulator 220 according to a demodulation period of a demodulation period determiner (not shown) to adjust the amount of data to be demodulated. have. Demodulation period determination and control of the demodulation period are described in detail below with reference to FIGS. 3, 4 and 5.

The output frame generator 230 generates an output frame by combining the data demodulated by the demodulator 220 and outputs the output frame. An embodiment of the output frame generator 230 generates an output frame divided into sections for a predetermined number of data, and determines a data position in a section corresponding to a hierarchy of a hierarchical structure. One embodiment of the output frame generator 230 may include aligning a data group for each layer of the demodulated data to a data position corresponding to each section of the output frame.

According to an embodiment of the output frame generator 230, an interval of an output frame may be an interval including the same number of data as the number of demodulated layers. For example, if a data group of layers 1 to m of the layers 1 to M is demodulated, N × m data are demodulated by the demodulator 220 because the total number of sections N is included for each layer. Output to the generation unit 230. The output frame generator 230 is classified into a block that is a section including m data positions, and may generate an empty output frame including N blocks. The output frame generator 230 may generate an output frame by inserting a hierarchical data group of demodulated data for each block of an empty output frame at a data position corresponding to each layer.

In addition, another embodiment of the data receiving apparatus 200, the demultiplexer for configuring the output frame in which the data arranged according to the hierarchical structure of the received data in consideration of the order of the output frame and the data layer, output It may further include a storage unit, such as at least one buffer, a memory for storing the frame.

3 shows a waveform of a demodulation period for a time division communication scheme.

When the received data is a signal periodically and processes a predetermined task for data of a predetermined section in a time division manner, the waveform 300 of the voltage applied to the task processor may be controlled so that the voltage is periodically applied. That is, the voltage of the on state is applied only during the data processing period 320 of one period 310 of the received data, and the voltage of the off state is applied to the unprocessed data period 330.

4 illustrates a service by a time division communication method.

By the time division method, the data service is divided along the time axis, and the partitioning pattern is repeated periodically. That is, the data service 400 is divided into a service 1, a service 2, a service 3, and a service 4 along the time axis and is transmitted and received, and some of the services 1, 2, 3, and 4 of the service 1, service 2, service 3, and service 4 are continuous. It is sent and received. If only the service 1 of the service is to be processed by the time division method, the voltage applied to the demodulator only in the service 1 section 420 every cycle 410 is controlled to be turned on, and the remaining services 2, 3, In the period 430 of the service 4, the voltage applied to the demodulator is controlled to be in an off state.

5 shows a conceptual diagram of a DVB-H receiver according to another embodiment of the present invention.

The time division reception method may be applied to a receiver according to the DVB-H (Digital Video Broadcasting-Handheld) standard. The DVB-H standard combines the demodulation method of the Digital Video Broadcasting-Terrestrial (DVB-T) standard with the time division method.

For example, the receiver 500 according to the DVB-H standard includes a DVB-H demodulator 510 and a DVB-H terminal 520. The DVB-H demodulator 510 applies a time slicing (time division) technique 514 and a Multi Protocol Encapsulation-Forward Error Correction (MPE-FEC) technique 516 to the DVB-T demodulator 512. The time slicing technique 514 is to reduce the power consumption of the battery and the MPE-FEC technique 516 is to improve the impulse noise immunity.

The voltage is controlled such that the voltage is applied to the DVB-T demodulator 512 during the demodulation period of the burst data by the time slicing technique 514, and the demodulated burst data is each IP datagram by the MPE-FEC technique 516. It can be transmitted to the DVB-H terminal 520 in the form of ES inserted in the MPE (Multi Protocol Encapsulation). Not only time-division IP datagrams but also non-time-slicing TS packets may be transmitted to the DVB-H terminal 520.

The receiver 500 according to the DVB-H standard is turned on during a period in which a dedicated service is received at the front end including the DVB-T demodulator 512 and is received by a service that is not subject to demodulation. During the cycle, the voltage applied to the front end portion in the off state is controlled. This allows the DVB-H standard to reduce the total power consumption of the receiver, so it can be applied to receivers with low battery capacity.

6 to 13, the present invention proposes a method of transmitting data and a method of transmitting data when data is divided and transmitted using a time division method.

6 illustrates a data classification scheme according to an embodiment of the present invention.

For convenience of description, the following description will be made with reference to image data including a plurality of frames 620 from the A frame 610 to the Z frame 615. In units of blocks that include at least one data, each frame may be classified into at least one block.

Looking at the frame structure with reference to one of the plurality of frames 620, the A frame 610 is classified into data blocks of N blocks from A ₁ to A _N. Looking at each block with reference to the A _K block 620, it includes M data positions from A _{K , 1} to A _{K , M.} That is, since each frame includes N blocks and each block includes M data, each frame may include N × M data.

According to the present invention, a block of each frame is for adjusting a capacity of a data processing unit, and each data position in the block may correspond one-to-one to a hierarchy in a hierarchy. As another example, hierarchies may be classified according to the importance of information or data capacity of a data set including at least one data in a block. 7, 8, and 9 illustrate a case where hierarchies are classified according to data positions, and FIG. 11 illustrates a case where hierarchies are classified according to the importance of information.

7 illustrates a method of transmitting one frame according to an embodiment of the present invention.

An embodiment 700 of the transmission frame generator 110 rearranges data of the original frame for each layer through the demultiplexer 710 to generate a transmission frame in which data of the same layer is arranged in the buffer 720. Can be stored.

For each of the first to Nth blocks of the A frame 610, data of a predetermined data position among the first to Mth data positions is selected and arranged in block order. That is, AS ₁ 730 representing the data group in which the data of the first data position of each block is arranged in order, AS ₂ 740 representing the data group in which the data of the second data position is arranged, and the third data position. The AS ₃ 750 indicating the data group in which the data of the data is arranged, and the AS _M 760 indicating the data group in which the data of the Mth data position are arranged are stored in the buffer 720.

A data group of AS ₁ ,..., AS _M is inserted into the transmission frame stored in the buffer 720 according to the rank of the hierarchical structure. The embodiment of the transmitter 120 may transmit the data group of AS ₁ ,..., AS _M of the transmission frame according to the transmission order according to the rank of the hierarchical structure. The data groups 730, 740, 750, and 760 divided by layers may correspond to different resolutions and capacities of detailed information.

8 illustrates a method of transmitting several frames according to an embodiment of the present invention.

The embodiment 800 of the transmission frame generator 110 receives a plurality of original frames 600 and rearranges data of the plurality of original frames 600 by layers through the demultiplexer 810. A transmission frame in which data of the same layer is arranged may be generated and stored in the buffer 820.

Specifically, hierarchical data groups in which data groups of the same data position of each frame are arranged in the original frame order are stored in the buffer 820. That is, the data groups AS ₁ , BS ₁ , CS ₁ , ..., ZS ₁ 830 of the first data position of each frame are stored in the buffer 820 in the order A, B, C, ... Z. And similarly, the data groups AS ₂ , BS ₂ , CS ₂ , ..., ZS ₂ 840 of the second data position, the data groups AS ₃ , BS ₃ , CS ₃ , ... of the third data position. , ZS ₃ (850), the M data of the data group located AS _{M, M} BS, CS _M, ..., _M is stored in the ZS (860) a buffer (820).

Each layer-specific data group 830, 840, 850, and 860 may be simultaneously stored in a buffer. The data groups 830, 840, 850, and 860 may be stored in different spaces on the buffer 820 for each layer, and the data groups of each layer of one frame may be simultaneously stored in a storage space corresponding to each layer. Or stored sequentially. That is, AS ₁ , AS ₂ , AS ₃ , ..., AS _M may be stored at the same time or sequentially first of each storage space, and then BS ₁ , BS ₂ , BS ₃ , ..., BS _M may be stored. have.

According to an embodiment of the transmitter 120, the data group for each layer stored in the buffer 820 may be collected and transmitted in units of frames. For example, after transmitting AS ₁ , AS ₂ , AS ₃ , ..., AS _M , the transmission order is 870 in the order of transmitting BS ₁ , BS ₂ , BS ₃ , ..., BS _M. Can be determined. As another example, after collecting AS ₁ , BS ₁ , CS ₁ , ..., ZS ₁ in a hierarchical unit, The transmission order may be determined to transmit AS ₂ , BS ₂ , CS ₂ ,..., ZS ₂ . In this manner, even if a plurality of frames are transmitted and received, data may be classified according to a hierarchical structure, and thus the receiver may demodulate and restore only data of a layer having a desired condition such as resolution or amount of detailed information.

9 illustrates a method of transmitting several frames according to another embodiment of the present invention.

The data transmission apparatus 900 may include a separate demultiplexer and a buffer for each frame, and include a buffer for comprehensively storing the rearranged data according to the hierarchical structure of all frames, thereby storing the transmission frame in a multi-stage buffer. That is, the demultiplexer 910 for rearranging the data of the A frame 610 by the hierarchical structure, the buffer 920 for storing the transmission frame of the A frame 610, and the rearrangement of the data of the Z frame 615 for each hierarchical structure. A demultiplexer 915 and a buffer 925 for storing the transmission frame of the Z frame 615 may be provided separately.

The data group of AS ₁ 730, AS ₂ 740, AS ₃ 750, and AS _M 760 in which data of the A frame 610 is rearranged by the demultiplexer 910 is stored in the buffer 920. Similarly, the data of the Z frame 615 also includes the data group ZS ₁ 940 of the first data position rearranged by the demultiplexer 915, the data group ZS ₂ 950 of the second data position, and the third data position. Data group ZS ₃ 960 and data group ZS _M 970 of the Mth data position are stored in the buffer 925. The data on the transmission frame of the Z frame 615 stored in the buffer 925 are ZS ₁ 940, ZS ₂ 950, ZS ₃ 960, ..., ZS _M 970 according to the hierarchical rank of the data group. ) Is output according to the transmission order 980 of FIG.

The buffer 930 stores the data 770, 980, and the like rearranged by the layers of all the frames of the frames A through Z. According to an embodiment of the transmitter 120, a group of data of all frames is collected for each layer and transmitted (for example, after transmitting AS ₁ , ..., ZS ₁ and subsequently transmitting AS ₂ , ..., ZS ₂₎ . The transmission order may be determined. In addition, the data group for each layer stored in the buffer 930 may be transmitted in units of frames. That is, a transmission sequence for transmitting data of one frame for each layer and transmitting data for the next frame for each layer (for example, AS ₁ , ..., AS _M , then BS ₁ , ..., BS Transmission order for transmitting _M ) may be determined.

10 illustrates a method of determining a demodulation period according to an embodiment of the present invention.

The rearranged data service 1010 is transmitted according to the hierarchical structure classified into M layers from one embodiment of the data transmission device 100, and the data service 1010 is received according to an embodiment of the data reception device 200. Can be. For example, with the above-described image data, hierarchical services S1, S2, S3, ..., S _M are received during the frame period 1030 in which a plurality of sets of frames are transmitted and received.

The demodulation period determiner (not shown) of the data receiving apparatus 200 determines the demodulation period based on the hierarchical structure. The demodulation power control unit (not shown) may control the voltage applied to the demodulation unit 220 according to the demodulation period determined by the demodulation period determination unit (not shown). That is, the demodulation power control unit (not shown) determines the shape of the waveform 1020 of the voltage applied to the demodulation unit 220.

An embodiment of the demodulation period determiner (not shown) determines the demodulation period 1040 so that the data group of at least one layer is demodulated periodically. As shown in FIG. 10, a demodulation period 1040 may be determined such that only one layer of services of S ₁ , S _{M +1} ,... Alternatively, the demodulation period may be controlled to demodulate several layers of services by adjusting the width of the demodulation period 1040.

Therefore, when the demodulation period is extended, the amount of demodulated data or detailed information increases, so that a service including more information can be restored in the terminal of the receiver, but battery usage of the front end of the receiver increases. On the other hand, if the demodulation period is reduced, the battery usage of the front end portion is reduced, but the service of the terminal of the receiving end is restored. In this way, since the resolution or amount of information of the restored data can be adjusted under the control of the demodulation period, the demodulation period determiner (not shown) determines the demodulation period in consideration of a tradeoff between battery capacity and the accuracy of the restored information. Can be.

11 illustrates a data classification and transmission scheme according to an embodiment of the present invention.

When a plurality of frames, such as frame 0 1120, frame 1 1130, frame 2 1140, etc., are transmitted, an error correction coding unit (not shown) is a data group of a data layer having a high need for protection from transmission errors. Error correction coding may be performed on B1-0, B1-1, B1-2, ... 1150. According to an embodiment of the transmission frame generator 110, all data of the data group 1150 on which error correction coding is performed and the data group of the remaining layer on which error correction coding is not performed are rearranged 1110, and the transmission unit ( 120 may transmit 1160 the rearranged data in frame units (0, 1, 2,...).

The data receiver 210 receives the rearranged data 1160 based on whether the error correction coding is performed and the hierarchical structure, and the demodulation period determiner (not shown) demodulates only the data section of the layer where the error correction coding is performed. Determine the demodulation cycle. The demodulation power controller (not shown) may control the waveform 1170 of the voltage applied to the demodulator 220 according to the determined demodulation period. The demodulated data may be decoded by the error correction code by an error correction code decoding unit (not shown), and the service may be restored.

For example, error correction coding is performed to protect data groups of layers and data essential for data service restoration from transmission errors. The data layer (E1, E2, E3 .., EN) used to augment the details in the restoration process can improve the quality of the restoration service if demodulated, but is not necessary information for service restoration. It can be sent and received without. Therefore, the demodulation period determiner (not shown) may determine the demodulation period to demodulate only the data on which the error correction coding is performed in consideration of the durability of the data with respect to an error that may occur in the communication of the data service.

According to another embodiment, error correcting coding is performed on data of all layers, but a weak level of error correction coding is performed on a data group of a layer corresponding to relatively insignificant detail information, and the data that should be most error resistant. The more the group 1150, the stronger the error correction coding. Therefore, the demodulation period determiner (not shown) may determine the demodulation period in consideration of the level of error correction coding, the hierarchical structure, and the like.

Another embodiment of the data receiving apparatus 200 may demodulate all data received by the data receiving unit 210 and the demodulating unit 220, and thus the average value of data corresponding to at least one layer for each block (section). The output frame generator 230 arranges an average value corresponding to each block of each frame, thereby having lower resolution and lower signal-to-noise ratio (SNR) than the data of the original frame. You can create an output frame. Accordingly, various embodiments of the present invention can selectively recover only data having information suitable for devices of various resolutions using only a small power.

12 is a flowchart of a data transmission method according to an embodiment of the present invention.

In operation 1210, the transmission frame is generated by rearranging data of the same layer among data of the original frame classified into a hierarchical structure in consideration of resolution. The hierarchical structure may be classified according to the range including not only the resolution but also data representing more detailed information. Data of the original frame is divided into sub-sections, and a predetermined position or range of a data set in the sub-section may correspond to a layer.

When the data is an image frame, data at the same data position on a block is data of the same layer, and data groups for each layer are formed by collecting data at the same data position for each block. A transmission frame in which data groups for each layer are arranged according to rank in a hierarchical structure is generated.

In operation 1220, a plurality of transmission frames corresponding to the plurality of original frames are transmitted in a transmission order considering a hierarchical structure. According to the hierarchical structure, first, the hierarchical data group of a predetermined frame is continuously transmitted, and then the hierarchical data group of the next frame is continuously transmitted, or the data of all frames of a given layer is continuously transmitted and As in the examples of the transmission order in which the data group is transmitted, the transmission order may be determined in consideration of the hierarchical structure.

13 is a flowchart of a data receiving method according to an embodiment of the present invention.

In step 1310, data sorted according to a time division scheme is received based on the hierarchical structure considering the resolution. The hierarchical structure can be defined according to the resolution as well as the amount of information that can be recovered.

In step 1320, the data group of at least one layer of the received data is demodulated. Since the demodulation is performed only on the data section of the layer capable of restoring a desired amount of information on the receiver side, power consumption of the receiver may be saved. A demodulation period capable of demodulating data of at least one layer may be determined in consideration of a compensating relationship of power usage and accuracy of service restoration.

In step 1330, an output frame is generated by combining the demodulated data. Data of the demodulated layer is inserted in each section (block) of the output frame, so that a service having a predetermined resolution or a service including a predetermined amount of data can be restored.

Meanwhile, the above-described embodiments of the present invention can be written as a program that can be executed in a computer, and can be implemented in a general-purpose digital computer that operates the program using a computer-readable recording medium. The computer-readable recording medium may be a magnetic storage medium (for example, a ROM, a floppy disk, a hard disk, etc.), an optical reading medium (for example, a CD-ROM, a DVD, etc.) and a carrier wave (for example, the Internet). Storage medium).

So far I looked at the center of the preferred embodiment for the present invention. Those skilled in the art will appreciate that the present invention can be implemented in a modified form without departing from the essential features of the present invention. Therefore, the disclosed embodiments should be considered in descriptive sense only and not for purposes of limitation. The scope of the present invention is shown in the claims rather than the foregoing description, and all differences within the scope will be construed as being included in the present invention.

1 is a block diagram of a data transmission apparatus according to an embodiment of the present invention.

2 is a block diagram of a data receiving apparatus according to an embodiment of the present invention.

3 shows a waveform of a demodulation period for a time division communication scheme.

4 illustrates a service by a time division communication method.

5 shows a conceptual diagram of a DVB-H receiver according to another embodiment of the present invention.

6 illustrates a data classification scheme according to an embodiment of the present invention.

7 illustrates a method of transmitting one frame according to an embodiment of the present invention.

8 illustrates a method of transmitting several frames according to an embodiment of the present invention.

9 illustrates a method of transmitting several frames according to another embodiment of the present invention.

10 illustrates a method of determining a demodulation period according to an embodiment of the present invention.

11 illustrates a data classification and transmission scheme according to an embodiment of the present invention.

12 is a flowchart illustrating a data transmission method according to an embodiment of the present invention.

13 is a flowchart of a data receiving method according to an embodiment of the present invention.

Claims (27)

Generating a transmission frame by rearranging data of the same layer among data of the original frame classified into a hierarchical structure considering resolution; And And transmitting a plurality of transmission frames corresponding to a plurality of original frames in a transmission order considering the hierarchical structure. The method of claim 1, And the original frame is divided into interval units including a predetermined number of data of the original frame based on the hierarchical structure in consideration of the resolution. The method of claim 2, wherein the transmitting frame generation step, Generating a data group of the same position for each position in the section of data of the original frame; And And generating a transmission frame in which the data groups for each location in the section are arranged according to the order of the data positions in the section. According to claim 1, The data transmission method, And performing error correction coding on the data group of at least one layer of the original frame. The method of claim 4, wherein the transmitting step, And determining the transmission order in consideration of the hierarchical structure and the error correction coding. The method of claim 4, wherein the error correcting coding step comprises: And adjusting the strength of error correction coding according to the layer of the data group. The method of claim 1, wherein the transmitting step, Determining the transmission order such that data groups of the same layer of the plurality of transmission frames are continuously transmitted according to the transmission frame order; And Determining the transmission order such that the data groups for each layer of the plurality of transmission frames are continuously transmitted according to the rank of the hierarchical structure; And And transmitting the plurality of transmission frames according to the determined transmission order. The method of claim 1, wherein the transmitting step, Determining the transmission order such that layer-specific data groups of one of the plurality of transmission frames are continuously transmitted according to a hierarchical rank in the hierarchical structure; Determining the transmission order such that data of the plurality of transmission frames is continuously transmitted according to the transmission frame order; And And transmitting the plurality of transmission frames according to the determined transmission order. The method of claim 1, wherein the data transmission method using the time division scheme is: And classifying the data of the original frame into a hierarchical structure in consideration of the resolution. Receiving data arranged according to a time division scheme based on a hierarchical structure considering resolution; Demodulating a data group of at least one layer of the received data; And And a step of generating an output frame by combining the demodulated data. The method of claim 10, wherein the demodulation step, Determining a demodulation period of the data based on the hierarchical structure; And Demodulating a data group of at least one layer of the received data according to the determined demodulation period. The method of claim 11, wherein the demodulation period determination step, Determining the demodulation period as a partial period during which a data group of at least one layer of the frame period is received; The frame period is a period in which one frame is received, and a plurality of frames are received periodically according to the frame order. The method of claim 11, wherein the demodulation period determination step, Determining the demodulation period as a layer period corresponding to at least one layer of data of a plurality of frames; The hierarchical period is a period in which data groups of one layer among the data of the plurality of frames are continuously received, and the data according to the time division scheme is received periodically according to hierarchical order in the hierarchical structure. Receiving method. The method of claim 11, wherein the demodulation period determination step, And determining the demodulation period as a period during which the data group of at least one layer corresponding to a predetermined resolution is received. The method of claim 10, wherein the output frame generating step, Generating an output frame divided into interval units for a predetermined number of data; Determining a data location in the section corresponding to the hierarchy of the hierarchy; And And aligning the data group for each layer according to the hierarchical structure among the demodulated data at a data position corresponding to each section of the output frame. The method of claim 15, And a section of the output frame is a section including the same number of data as the number of demodulated layers. The data receiving method of claim 10, wherein the time division method comprises: And decoding an error correction code on the data group of at least one layer of the demodulated data. The method of claim 17, wherein the demodulation step, And determining a demodulation period of the data in consideration of the layer of the data group and whether the error correction coding is performed. 18. The method of claim 17, wherein in the error correction code decoding step, The strength of the error correction coding is adjusted according to the layer of the data group, characterized in that the data transmission method using the time division method. A transmission frame generation unit for rearranging data of the same layer among data of original frames classified into a hierarchical structure considering resolution to generate a transmission frame; And And a transmitter for transmitting a plurality of transmission frames corresponding to a plurality of original frames in a transmission order considering the hierarchical structure. The apparatus of claim 20, wherein the data transmission apparatus using the time division scheme comprises: And an error correction coding unit configured to perform error correction coding on the data group of at least one layer of the original frame. A data receiver configured to receive data arranged according to a time division scheme based on a hierarchical structure considering resolution; A demodulator for demodulating a data group of at least one layer of the received data; And And an output frame generation unit for generating an output frame by combining the demodulated data. The method of claim 22, wherein the demodulation unit, A demodulation period determiner configured to determine a demodulation period of the data based on the hierarchical structure; And demodulating data groups of at least one layer of the received data according to the determined demodulation period. The data receiving apparatus of claim 22, wherein the time division method comprises: And an error correction code decoding unit for decoding an error correction code on at least one layer of data of the demodulated data. The data receiving apparatus of claim 22, wherein the time division method comprises: A demodulation power control unit controlling a voltage of the demodulation unit according to a demodulation period of the received data; A demultiplexer for constructing the output frame by arranging the data according to the order of the output frame and the data layer according to the hierarchical structure of the received data; And And at least one buffer for storing the output frame. A computer-readable recording medium having recorded thereon a program for implementing a data transmission method using the time division method according to any one of claims 1 to 9. 20. A computer-readable recording medium having recorded thereon a program for implementing a method of receiving data by the time division method according to any one of claims 10 to 19.

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