KR20020006908A - Encoding Method For Reverse Rate Indicator In High Data Rate System - Google Patents

Abstract

PURPOSE: A method for encoding a reverse rate indicator(RRI) of a high data rate system is provided to convert an RRI symbol into an RRI code word(Walsh code). CONSTITUTION: In case that a data rate value is '0', an RRI code word with W0¬8(0000 0000) is assigned in an RRI symbol with 3 bits '000'. An RRI code word with -W0¬8(1111 1111) is assigned in an RRI symbol with 3 bits '001'. An RRI code word with W1¬8(0101 0101) is assigned in an RRI symbol with 3 bits '010', and an RRI code word with -W1¬8(1010 1010) is assigned in an RRI symbol with 3 bits '011'. An RRI code word with W2¬8(0011 0011) is assigned in an RRI symbol with 3 bits '100', and an RRI code word with -W2¬8(1100 1100) is assigned in an RRI symbol with 3 bits '101'. An RRI code word with -W3¬8(0110 0110) is assigned in an RRI symbol with 3 bits '110', and an RRI code word with -W3¬8(1001 1001) is assigned in an RRI symbol with 3 bits '111'.

Description

Encoding Method For Reverse Rate Indicator In High Data Rate System

The present invention relates to a RRI encoding method of a reverse link in a high speed wireless data communication (HDR) system.

In particular, the present invention encodes a reverse rate indicator (RRI) for informing a base station (or sector) of a reverse data rate in a high data rate (HDR) system. The present invention relates to a method for converting to a codeword.

As is known, the HDR system is a mobile data communication system for data communication services only. Basically, a voice communication service is not supported, and only a data communication service is supported.

However, since a mobile communication system including an HDR system has a poor channel (communication environment), various methods for overcoming a poor communication environment and providing a high speed and high quality service have been proposed.

In particular, much effort has been put into the construction of a stable communication line between a base station and a terminal and a high-speed, high quality information (signal) transmission technology through a stable communication line.

In particular, since the HDR system supports wireless data communication services, accurate and stable transmission of data is indispensable.

The process of data communication in the HDR system is summarized as follows.

Information from the base station (or sector) to the terminal is transmitted in the slot structure of the time division multiplexed form.

The terminal receives the information, and when receiving a pilot signal of the forward link from the base station (or sector) to the terminal, the terminal selects the base station (or sector) according to the strength (receive sensitivity) of the pilot signal.

In addition, the terminal determines the forward data rate from the pilot signal and loads the base station (or sector) selection information and the forward rate information on the DRC channel of the HDR reverse link and sends them to the base station (or sector).

The base station (or sector) determines the data rate to the terminal based on this forward rate and performs data transmission in accordance with the rate.

In this case, when the terminal transmits DRC information in the nth slot, the base station (or sector) performs data transmission using the forward data rate in the n + 2th slot, and the transmitted data receives the DRC information in the nth slot. A user (terminal) is distinguished by applying a Walsh code given to the transmitting user.

FIG. 1 illustrates the structure of a slot for describing a forward link of an HDR system, and FIG. 2 illustrates a MAC channel structure of a traffic channel for describing a reverse link of an HDR system, and FIG. 3 illustrates a reverse link of an HDR system. Coding table showing a method for encoding an RRI symbol in.

First, as shown in FIG. 1, when looking at the channel structure in the forward link of the HDR system, a pilot channel, a medium access control channel, and a data channel are provided in one slot. This time division multiplexed form is configured and transmitted.

The MAC channel is assigned a FA channel (Forward Activity Channel), RA channel (Reverse Activity Channel), RPC (Reverse Power Control).

In FIG. 1, one slot 101 has 2048 chips, and is divided into a first half slot 101a and a second half slot 101b.

The first half slot 101a is 1024 chips including the data 102 of 464 chips, the pilot 103 of 96 chips, and the data 104 of 464 chips. The second half slot 101b is 400 chips. Data 105, a 64-chip MAC channel 106, a 96-chip pilot 107, a 64-chip MAC channel 108, and a 400-chip data 109.

The pilot channels 103 and 107 are common channels that all users receive and are used to determine the data rate for transmitting data to the users. The MAC channels 106 and 108 are used to inform users of the forward and reverse link status and to power control the reverse link. Used.

The pilot channel and the MAC channel are transmitted to every user in every slot, and data is transmitted for a specific user (terminal).

The data channels 102, 104, 105, and 109 are transmitted to a specific user (terminal) at any one of data rates of 38.4 kbps, 76.8 kbps, ..., 2457.6 kbps through modulation schemes and coding schemes of QPSK, 8PSK, and 16QAM.

In an HDR system, data is transmitted over time through a channel having a structure as shown in FIG. 1 without allocating a dedicated channel to a user (time division multiplexed transmission).

That is, data is transmitted from one slot to several slots assigned to users (slot 1 to slot n), and users receiving data from a base station (or sector) are one of 32 Walsh codes of length 32. You will be given, and you will only receive data with the Walsh code assigned to you.

At this time, all channels transmitted in the forward direction are transmitted at the maximum power that the base station (or sector) can transmit without forward power control.

2 is a diagram illustrating a slot structure of a MAC channel for describing the HDR reverse link.

In the HDR reverse link, an access channel and a reverse traffic channel are formed.

The access channel consists of a pilot channel and a data channel, and the reverse traffic channel consists of a pilot channel, a medium access control (MAC) channel, an acknowledgment channel, and a data channel.

In the reverse traffic channel, the MAC channel includes an RRI channel and a data rate control channel (DRC), and the DRC channel 201 is a data rate of the forward link, that is, a user (terminal) at a base station (or sector). The base station (or sector) is used to inform the base station (or sector) of the transmission rate of the data to be transmitted to the base station (or sector), that is, the base station (or sector) to which the user (terminal) is to receive data communication service. It is used to indicate whether or not it is located. DRC information basically transmits the same information for one slot, and its contents are updated in units of slots.

The RRI channel 202 is used to inform the base station (or sector) of the reverse data rate, and provides a rate of 9.6kbps to 153.6kbps per terminal in the reverse direction.

The pilot channel 203 is used for power control of the reverse link.

The RRI channel 202 converts (encodes) an RRI codeword to transmit a reverse data rate to a base station (or sector).

The encoding method selects one of three predetermined RRI symbols corresponding to the data rate of the reverse link as shown in FIG. 3, and selects the selected RRI symbol through codeword repetition, mapping, and Walsh covering steps. It encodes and transmits one of the bi-orthognal code words (Wash code W _i ⁸ ).

Here, W _i ⁸ is a Walsh code of 8 chips in length and is composed of 8 codewords, which is used to inform the base station (or sector) of the data rate of the reverse link, that is, 9.6kbps to 153.6kbps. .

In FIG. 3, it can be seen that the minimum Hamming distance of the RRI codeword, d _min = 4, and the distance between the eight codewords are all '4'. For example, the distance between W ₀ ⁸ = (0000 0000) and W ₁ ⁸ = (0101 0101) is '4'.

In the DRC channel, a terminal measures a state of a received signal (pilot signal) and encodes and transmits a 4-bit DRC symbol by the same method as the RRI encoding, thereby allowing a total of 16 possible forward data rates (38.4kbps, 76.8). One of kbps, ..., 2457.6 kbps is sent to the base station (or sector).

As described above, in the HDR system, data communication is performed between a base station and a terminal through a time division multiplexed slot structure, and a channel of a base station (or sector) that forms an optimal communication environment by using channels of an HDR forward link and a reverse link. Selection, reverse power control, and data transfer with the terminal are being performed.

The present invention provides a method of encoding RRI information for informing a base station (or sector) of a data rate of a reverse link in a high-speed wireless data communication (HDR) system.

The present invention provides an RRI encoding method for maximizing a distance between codewords when encoding RRI information for informing a base station (or sector) of a data rate of a reverse link in a high-speed wireless data communication (HDR) system. To present.

According to the present invention, when encoding RRI information for informing a base station (or sector) of a data rate of a reverse link in a high-speed wireless data communication (HDR) system, a distance between codewords is '8' and weight = By encoding to have a codeword of '8', we propose an RRI encoding method that can improve encoding performance.

1 shows the structure of a basic slot for describing an HDR forward link

Figure 2 shows the structure of a slot to explain the HDR reverse link

3 is a view for explaining a conventional RRI encoding method

Figure 4 is a view for explaining the RRI encoding method of the present invention

Reverse rate indicator encoding method of the high-speed wireless data communication system of the present invention, (a). Constructing an RRI symbol indicative of each data rate corresponding to each data rate, (b). Allocating an orthogonal codeword for each of the RRI symbols, (c). When assigning an orthogonal codeword for each of the RRI symbols, if one codeword is W _i ^BW , the codeword -W _i ^BW having a distance 'BW' and a weight 'BW' from this codeword is assigned to the other codeword. Assigning; It is characterized by the encoding.

In the present invention, the RRI symbol is composed of three bits of data for each of the reverse data rates, and when i = 1,2,3 and BW = 8, this means (a). RRI symbol '000' = W ₀ ⁸ (0000 0000), (b). RRI symbol '001' = -W ₀ ⁸ (1111 1111), (c). RRI symbol '010' = W ₁ ⁸ (0101 0101), (d). RRI symbol '011' = -W ₁ ⁸ (1010 1010), (e). RRI symbol '100' = W ₂ ⁸ (0011 0011), (f). RRI symbol '101' = -W ₂ ⁸ (1100 1100), (g). RRI symbol '110' = W ₃ ⁸ (0110 0110), (h). RRI symbol '111' = -W ₃ ⁸ (1001 1001),; It is characterized by being encoded as.

Referring to Figure 4 the RRI encoding method of the present invention made as described above is as follows.

First, the data rate of the reverse link is selected from 9.6kbps, 19.2kbps, 38.4kbps, 76.8kbps, 153.6kbps.

Therefore, in consideration of '0' and reserved, RRI symbols of eight cases are mapped to 000 to 111, respectively.

RRI symbols 000 to 111 are encoded into eight codewords of eight chips in length.

That is, one of three predetermined RRI symbols corresponding to the data rate of the reverse link is selected, and the selected RRI symbol is subjected to an 8-bit orthogonal codeword (bi) through codeword repetition, mapping, and Walsh covering. and transmits the encoded code word to one of -orthognal) (Walsh code W _i ^8).

As shown in Fig. 4, when the data rate is '0', the RRI codeword of RRI symbol 3 bits '000' = W ₀ ⁸ (0000 0000) is allocated and the RRI symbol 3 Bit '001' = -W allocates the RRI codeword of ₀ ⁸ (1111 1111).

Allocates an RRI codeword of RRI symbol 3 bits '010' = W ₁ ⁸ (0101 0101) and allocates a codeword of RRI symbol 3 bits '011' = -W ₀ ⁸ (1010 1010).

Allocates an RRI codeword of RRI symbol 3 bits '100' = W ₂ ⁸ (0011 0011), and allocates an RRI codeword of RRI symbol 3 bits '101' = -W ₂ ⁸ (1100 1100).

Allocates an RRI codeword of RRI symbol 3 bits '110' = W ₃ ⁸ (0110 0110) and allocates an RRI codeword of RRI symbol 3 bits '111' = -W ₃ ⁸ (1001 1001).

When encoding as above, d _min = '4', which is the same as the conventional method, but the encoding performance is improved because there is a code word having a weight = '8' when the distance between codes is '8'.

For example, the distance between two codewords, W ₀ ⁸ (0000 0000) and -W ₀ ⁸ (1111 1111), becomes '8'.

According to the reverse rate indicator encoding method of the high-speed wireless data communication system of the present invention, orthogonal codeword encoded optimal RRI encoding is possible.

In addition, according to the reverse rate indicator encoding method of the high-speed wireless data communication system of the present invention, since the encoded RRI codeword has a codeword whose weight is '8' when the distance between the codewords is '8', encoding performance Brings an improvement.

Claims (3)

Allocating orthogonal codewords to RRI symbols indicating respective data rates corresponding to each of reverse data rates of an HDR system, and when assigning orthogonal codewords to each of the RRI symbols, any one of the codewords is W _i. ^BW when assigning a codeword -W _i ^BW on the other of the code word; And a reverse rate indicator encoding method of a high-speed wireless data communication system. 2. The method of claim 1, wherein i = 1,2,3 and BW = 8 in the codeword. The method according to claim 1 or 2, wherein the RRI symbol is composed of 3-bit data for each of reverse data rates, and when i = 1,2,3 and BW = 8, thereby (a). RRI symbol '000' = W ₀ ⁸ (0000 0000), (b). RRI symbol '001' = -W ₀ ⁸ (1111 1111), (c). RRI symbol '010' = W ₁ ⁸ (0101 0101), (d). RRI symbol '011' = -W ₁ ⁸ (1010 1010), (e). RRI symbol '100' = W ₂ ⁸ (0011 0011), (f). RRI symbol '101' = -W ₂ ⁸ (1100 1100), (g). RRI symbol '110' = W ₃ ⁸ (0110 0110), (h). RRI symbol '111' = -W ₃ ⁸ (1001 1001),; And a reverse rate indicator encoding method of a high speed wireless data communication system.