KR20000037867A - Qam constellation of cable modem and method for mapping qam symbol - Google Patents

Abstract

PURPOSE: A QAM constellation of a cable modem and a method for mapping a QAM symbol are provided to reduce a size of a hardware by performing a symbol mapping using one 256 QAM constellation. CONSTITUTION: A QAM constellation of a cable modem composes 256 QAM constellation by adding data of 2 bits having values of 00, 01, 11, 10 to lower 2 bits of symbols of 6 bits corresponding to 64 QAM constellation coordinate by using a gray coding method. A method for mapping a QAM symbol comprises the steps of: generating a 256 QAM constellation by adding data of 2 bits having values of 00, 01, 11, 10 to lower 2 bits of symbols of 6 bits corresponding to 64 QAM constellation coordinate; performing a symbol mapping by the 256 QAM constellation if data of 8 bits are inputted; and performing the symbol mapping by ignoring 2 bits added to predetermined locations of each symbol of a 256 QAM constellation coordinate if data of 6 bits are inputted.

Description

Quadrature Amplitude Modulation Constellation and Symbol Mapping Method for Cable Modem

TECHNICAL FIELD The present invention relates to a cable modem, and in particular, a quadrature amplitude modulation constellation of a cable modem in which 64 QAM constellations are commonly used by one 256 QAM constellation during symbol mapping. And a symbol mapping method.

Currently, computer communication is actively used as a method for acquiring a lot of information using a computer at home or office.

Through such computer communication, it is possible to acquire not only text information but also image information, audio information, and the like, and to send and receive necessary information by communication with a counterpart.

Furthermore, video communication that can communicate while face-to-face with the other party has been developed, and in the future, it will be extended to areas such as video on demand.

As one of the most widely used computer communication schemes, as shown in FIG. 1, an analog modem 110 is built in or external to the computer 100 and connected to the telephone station 130 through the telephone line 120. 130 is connected to a service company in charge of a communication service to perform communication.

That is, when the user enters the telephone number of the service company through the computer 100 in order to communicate with the computer, the analog modem 110 dials it and transmits the telephone number to the telephone station 130 through the telephone line 120. do.

The telephone station 130 connects a line between the computer 100 and the service company by connecting to a communication service company corresponding to the telephone number dialed by the user.

Then, when the user inputs the data to be transmitted through the computer 100, the analog modem 110 converts it into an analog signal and transmits it to the telephone station 130 through the telephone line 120.

Therefore, the telephone station 130 transmits data input from the user to the communication service company to connect with other users.

Meanwhile, when the user receives data from the other party, the analog modem 110 receives the data through the telephone line 120 connected to the telephone station 130, and then converts the received data into a digital signal so that the user can enter the computer 100. ), You can check the received data.

By the way, when performing the communication through the telephone line 130 using the analog modem 110 as described above, the communication speed is limited, so that a large amount of data can be quickly exchanged, and there are many restrictions.

That is, the maximum speed that can transmit and receive data through the telephone line 130 is 56kbps is limited because of its characteristics, so the delay time is increased when sending and receiving video information, especially on-demand video, such as the service itself is impossible do.

Therefore, in order to solve such a problem, a communication scheme using a cable modem has recently been devised.

The cable modem is connected to a high-speed dedicated cable, for example, to be able to communicate by using a dedicated cable of a cable television currently being watched at home.

FIG. 2 is a circuit block diagram of a typical cable modem. When the data of the packet modem RS (Reed-Solomon) encoder 200 is inputted in the unit of packet data to be uploaded, error correction by RS code, that is, error of burst noise Correction is made.

This RS code is a code capable of correcting a large number of errors in a partition which is a kind of non-binary cyclic code, and has excellent ability to correct cluster errors.

Packet data corrected by the RS encoder 200 is applied to the scrambler 210 to perform scrambling, which is a receiver designed according to this rule by mixing a unique arrangement or characteristic of a digital signal into a promised rule. Only this signal can be restored to the original signal, to prevent the loss of bit boundary information of successive digital signals, and to prevent cross-modulation in the channel caused by a single frequency component caused by periodic data.

The output of the scrambler 210 is applied to the symbol mapping unit 220 and data input as symbols suitable for modulation are mapped and output. This will be described with reference to FIGS. 3, 5, and 6.

FIG. 3 is a detailed block diagram of the symbol mapping unit 220. When 6 bits of data are input from the scrambler 210, the 64 QAM symbol mapper 221 receives the 64 QAM cone as shown in FIG. 6-bit data input by the stealization is mapped and output. On the other hand, when 8-bit data is input, the 256-QAM constellation as shown in FIG. 6 is received by the 256 QAM symbol mapper 222. The 8-bit data input by MAP is mapped and output.

Accordingly, the outputs of the 64 QAM symbol mapper 221 and the 256 QAM symbol mapper 222 are selected by the switching means 223 and provided to the filter 230, and the filter 230 receives the frequency bandwidth. Filtering is performed to limit

The output of the filter 230 is applied to the modulator 240, modulated into a quadrature phase shift keying (QPSK) signal, and then transmitted to a cable modem termination system (CMTS) through a cable network.

Therefore, the CMTS receives the data transmitted from the cable modem and performs demodulation, descrambling, and RS decoding to restore the original data.

However, since a symbol mapper having different constellations is required for the number of bits of data input during symbol mapping in the cable modem, that is, the 64 QAM signal and the 256 QAM signal, each symbol mapper must be set up separately. There is a problem that the size and size of the hardware is increased.

Therefore, in view of the above problems of the related art, the present invention provides simplicity of design and hardware by mapping symbols using 64 QAM constellations in common by one 256 QAM constellation in symbol mapping. The purpose of the present invention is to provide a quadrature amplitude modulation constellation and symbol mapping method for a cable modem.

1 is a diagram for explaining a communication state of an analog modem using a general telephone line.

2 is a circuit block diagram of a typical cable modem.

3 is a detailed block diagram of a symbol mapping unit of FIG. 2;

4 illustrates a symbol mapping apparatus for realizing the present invention.

5 is a configuration diagram of a 64 QAM constellation.

6 is a configuration diagram of 256 QAM constellation.

7 illustrates a process of generating 256 QAM constellations by 64 QAM constellations in accordance with the present invention.

<Description of the code | symbol about the principal part of drawing>

200: RS encoder 210: scrambled part

220: symbol mapping unit 230: filter

240: modulator 300: QAM symbol mapper

310: bit selector

In order to achieve this purpose, the quadrature amplitude modulation constellation of a cable modem has a gray coding scheme at 00, 01, 11, 11 at a predetermined position of each 6-bit symbol corresponding to 64 QAM constellation coordinates. It is characterized by configuring 256 QAM constellations by adding two bits of data having a value of 10.

On the other hand, the quadrature amplitude modulation symbol mapping method of the cable modem using the quadrature amplitude modulation constellation of the cable modem of the present invention, 00, 01, 11, at a predetermined position of each 6-bit symbol corresponding to 64 QAM constellation coordinates; 256 QAM constellation is generated by adding 2 bits of data having a value of 10, and when 8 bits of data are input, symbol mapping is performed by the 256 QAM constellation, and 6 bits of data are inputted. In this case, symbol mapping is performed by ignoring 2 bits added to a predetermined position of each symbol of the 256 QAM constellation coordinates.

This will be described in detail with reference to the accompanying drawings.

First, the process of generating 256 QAM constellation by 64 QAM constellation according to the present invention will be described.

Two bits of data having values of 00, 01, 11, and 10 by gray coding as shown in FIG. 7A are placed below the symbols corresponding to the respective coordinates of the 64 QAM constellation as shown in FIG. In addition, each coordinate constitutes a 256 QAM constellation having an 8-bit symbol.

As an example, as shown in FIG. 7C, two bits of data having values of 00, 01, 11, and 10 are added to the value of 111111, which is the symbol value of the A position, and as shown in FIG. Generates an 8-bit symbol with

In this way, when applied to each coordinate of all 64 QAM constellations, 8-bit symbols for 256 coordinates are generated to form a new 256 QAM constellation.

The symbols 11111100, 11111101, 11111111, and 11111110 generated by the 111111 symbols of the 64 QAM constellation can be found in the circled portions of the general 256 QAM constellation shown in FIG.

That is, the symbols in which two bits are added to the six-bit symbol at each position of the 64 QAM constellation can be found in the 256 QAM constellation.

In the case of adding two bits of data to a six-bit symbol corresponding to each coordinate of the 64 QAM constellation, two bits of data may be added at any position even if it is not a lower bit.

For example, two bits of data may be added to an underlined part in a manner such as 1111110, 11101110, or 01101111, and the same rule should be applied to all six bits of a symbol.

Meanwhile, in the future, when an error occurs during symbol mapping, 256 QAM constellation may be configured using the following method in order to reduce the amount of error.

As shown in FIG. 7A, the gray coding scheme as shown in FIG. 7A may be flipped up and down and left and right as shown in FIG. 7B. When the A portion is flipped downward, gray codes are generated as in the case of B, and the side flips sideways. As in the case of C, gray code will be generated.

Therefore, in the case of adding 2 bits to the 111111 symbol of the 64 QAM constellation, an 8-bit symbol value as shown in FIG. 7D is generated to constitute 256 QAM constellation.

The 64 QAM symbol mapping and the 256 QAM symbol mapping method using the 256 QAM constellation configured as described above will be described with reference to FIGS. 2 and 4.

When 8-bit data, that is, 256 QAM data, is input from the scrambler 210, the bit selector 310 detects the number of bits and determines whether to perform symbol mapping for 64 QAM or symbol mapping for 256 QAM. To judge.

In this case, since the QAM symbol mapper 300 is configured with 256 QAM constellations according to the present invention, in the case of symbol mapping for 256 QAM, the QAM symbol mapper 300 can map a symbol for 8-bit data immediately input. The bit selector 310 outputs a command thereof to the QAM symbol mapper 300 to perform symbol mapping, and then provides the mapped result to the filter 230.

On the other hand, if 6-bit data, that is, 64 QAM data is input from the scrambler 210, the bit selector 310 determines that symbol mapping is performed for 64 QAM, and thus 256 QAM configured in the QAM symbol mapper 300. The QAM symbol mapper 300 performs symbol mapping on the 6-bit data input by ignoring the lower 2 bits of the 8-bit symbol for each coordinate of the constellation and only the upper 6-bit symbol. Will issue the command.

Accordingly, the QAM symbol mapper 300 ignores the lower two bits of data among the eight ratio symbols and maps the symbols by the upper six bits, and provides the mapped result to the filter 230.

In the case of ignoring 2 bits of data among 8 bits of symbols corresponding to the coordinates of 256 QAM constellation, when 2 bits of data are added at any position other than the lower bits, for all 8 bits of symbol Since two bits are added by the same rule, only two bits of the corresponding position among all 8-bit symbols need to be ignored.

As described above, the quadrature amplitude modulation constellation and symbol mapping method of the cable modem of the present invention uses 64 QAM constellations in common by one 256 QAM constellation in symbol mapping, thereby simplifying design and hardware. It has the effect of reducing the size of.

Claims (2)

256 QAM constellations by adding two bits of data with values 00, 01, 11, and 10 by gray coding to the lower two bits of each 6-bit symbol corresponding to 64 QAM constellation coordinates Right-angle amplitude modulation constellation of the cable modem, characterized in that the configuration. 256 QAM constellations are generated by adding two bits of data with the values 00, 01, 11, and 10 to the predetermined positions of each 6-bit symbol corresponding to the 64 QAM constellation coordinates, and 8 bits of data are input. Symbol mapping is performed by the 256 QAM constellation, and when 6-bit data is input, symbol mapping is performed by ignoring 2 bits added to a predetermined position of each symbol of the 256 QAM constellation coordinate. Quadrature amplitude modulation symbol mapping method of a cable modem, characterized in that.