KR100580954B1 - Apparatus and method for detecting hs-scch of hsdpa - Google Patents

Abstract

1. TECHNICAL FIELD OF THE INVENTION

The present invention relates to a terminal and an identifier (ID) in a high speed shared control channel (HS-SCCH) transmitted from a base station in a terminal receiving unit of a wideband code division multiple access (W-CDMA) wireless communication system supporting High Speed Downlink Packet Access (HSDPA). ) Relates to a method and apparatus for detecting a matching channel.

2. The technical problem to be solved by the invention

The HSDPA-enabled terminal detects the high-speed shared control channel that matches its identifier, and when the high-speed shared control channel matches the ID, the receiver of the terminal transmits the high-speed downlink shared channel (HS-PDSCH). Demodulation is controlled to improve H-ARQ throughput. In addition, when the high-speed shared control channel having the same identifier is not transmitted, demodulation is not performed to prevent unnecessary power consumption and ultimately improve the performance of the receiver.

3. Summary of Solution to Invention

The received fast shared control channel data is masked by using a terminal identifier, then decoded, and the result is re-encoded to perform operation with the received fast shared control channel data and determine whether the detected signal is detected.

4. Important uses of the invention

Used to detect whether a high speed shared control channel is transmitted in a broadband code division multiple access wireless communication system supporting HSDPA.

W-CDMA, HSDPA, H-ARQ, HS-SCCH, UE ID Detection

Description

Apparatus and method for detecting a high speed shared control channel in a high speed packet data transmission system {APPARATUS AND METHOD FOR DETECTING HS-SCCH OF HSDPA}             

1 is a diagram illustrating a channel structure of a fast shared control channel.

2 is a flowchart illustrating a method of coding part 1 data of a fast shared control channel at a base station.

3 is a schematic block diagram according to a first embodiment of the present invention.

4 is a schematic block diagram of a second embodiment of the present invention.

5 is an operation flowchart according to an embodiment of the present invention.

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a receiver of a wideband code division multiple access wireless communication terminal supporting High Speed Data Packet Access (HSDPA). In particular, the present invention relates to a high speed shared control channel (HS-SCCH) that matches an identifier (ID) of a terminal. control channel (hereinafter referred to as a "high speed shared control channel") and a method and a method for detecting.

UMTS (Universal Mobile Telecommunications System), the third generation wireless communication system, was able to support data up to 2Mbps, but as the demand for high-speed packet data service increased, HSDPA mode was introduced in UMTS to support up to 10Mbps.

In the HSDPA mode, user data is transmitted through HS-DSCH (High Speed Downlink Shared Channel), and control data necessary for the high speed downlink shared channel is transmitted through the high speed downlink shared channel. The terminal receives the fast shared control channel and compares it with its identifier (ID) to know whether data is to be transmitted from the base station to the terminal through the fast downlink shared channel. One high-speed shared control channel is composed of three slots as shown in FIG. 1, transmitted for 2 ms, and composed of two parts as shown in FIG. In the first part, information about demodulation is masked with an identifier (ID) of a terminal and transmitted during one slot. In the second part, information on decoding is transmitted through two slots.

Accordingly, the terminal detects whether the fast shared control channel data masked with the same value as its identifier (ID) is transmitted in the first part of the fast shared control channel, and prepares to demodulate the fast downlink channel. If not, prepare to detect the next high speed shared control channel data. The high speed shared control channel can be transmitted by up to four base stations at the same time. Therefore, the high-speed downlink stores data corresponding to the first part of all (4) high-speed shared control channels to be demodulated and starts receiving two slots later than the first slot reception time of the fast shared control channel. Before receiving the shared channel, it is necessary to determine whether there is data masked with the same identifier as the terminal.

Several methods have been proposed to detect the identifier of the high speed shared control channel.

Symbol Error Rate (SER) is a method of masking the input data and bit-deciphering the input data and Viterbi decoding the input data and then convolutionally encoding them to compare the respective bits, and determining with a threshold according to the number of error bits. to be.

The zero state determines that the ID matches when the path metric for the last input data is the largest in the zero state. There are other ways to treat the Viterbi decoder with a slight modification. The performance of these methods can be assessed through values such as detection probability, false alarm probability (probability of not transmitting but not determined), and miss probability (probability of transmitting but not detected). . The higher the probability of detection and the lower the "miss probability" or "false alarm probability" under the same conditions, the better the algorithm.

The present invention proposes a method with better performance than existing methods.

An object of the present invention to solve the above problems is to provide an apparatus and method for improving the detection reliability of the identifier included in the fast shared control channel for the reception of the fast downlink shared channel.

In order to solve the above problems, the present invention provides a device for detecting an identifier of a control channel, comprising: a decoder for Viterbi decoding a received and masked signal, an encoder for convolutionally encoding a signal output from the decoder; A mapping unit for mapping a signal output from the encoder, a calculating unit calculating a difference between the received masked signal and a signal output from the mapping unit, and determining an identifier according to an output value of the calculating unit It is characterized by having a group.

2 is a flowchart illustrating a method of coding part 1 data of a fast shared control channel at a base station, FIG. 3 is a schematic block diagram according to a first embodiment of the present invention, and FIG. 4 is a second embodiment of the present invention. A schematic block diagram according to an example, and FIG. 5 is an operation flowchart according to an embodiment of the present invention.

Hereinafter, exemplary embodiments of the present invention will be described with reference to the accompanying drawings.

In general, in a UMTS system, a base station generates and transmits a fast shared control channel using an identifier of a user as shown in FIG. 2. The information that should be transmitted in part 1 is MUX convolutionally encoded, then rate matched and masked using the identifier of the terminal. The receiver of the terminal performs decoding in the reverse order of the procedure performed by the base station.

The apparatus according to the first embodiment of the present invention is shown in FIG. 3, and the receiving unit of the terminal masks the transmitted fast shared control channel data (100) and then performs rate de-matching and channel decoding (110). To get the transmitted information. However, since the base station can transmit up to four high-speed shared control channels, it is necessary to perform a detection process for determining whether there is a high-speed shared control channel transmitted to itself for each of the transmitted high-speed shared control channels. This detection is performed by encoding (120) the channel-decoded data again and processing the mapped 130 data and the high-speed shared control channel received data by the operator 140, and determines whether the detected by the determiner 150 with the result value. do.

The masking block 100 adds 8-bit tails 102 to the 16-bit terminal identifier 101 given in advance from the base station, then convolutionally encodes 103 at a coding rate 1/2 and rates 8 bits at a given position. Matching 104 performs multiplication with the input high-speed shared control channel data.

The decoding unit 110 includes a rate de-matching unit 111 and a Viterbi decoding unit 112, rate de-matching 111 by inserting '0' into the masked data, and performing Viterbi decoding 112. .

The encoder 120 includes convolutional encoders 121 and 122 and a rate matching unit 123. In general, the weaving encoders 121 and 122 are used in combination with the tail addition unit 121 and the kimssam encoding unit 122, but are separately shown in the embodiments of the present invention.

The information bits obtained by the Viterbi decoder 112 add 8 bits of tails 121 by the tail adder 121 as encoded by the base station, and undergo convolutional encoding 122 by 1/3 coding rate. Rate matching 123 is performed.

The mapping block 130 maps from the input 40-bit data so that '0' has a positive value and '1' has a negative value. For example, in case of mapping by 6 bits, it outputs by mapping "0" to "16" and "1" to "-16" by probabilistic statistics.

The received signal energy detector (not shown) detects and outputs signal energy of the received high speed shared control channel, and the output signal may be used as a reference signal of the determiner 150 as described above.

The mapped data and the received fast shared control channel data are input to the operator 140. The operator 140 calculates the difference between the two input data by the subtractor 141, squares the obtained difference by the squarer 142, and the squared value is added to the accumulator 143 by 40 symbols, which is the number of input data. Accumulate by The determiner 150 compares the calculated value with a threshold to determine it. In this case, the threshold value may be designed to be changed according to an environment of a wireless channel through which a signal is transmitted from a base station. As an example of such a design, as described above, by using the energy of the received signal that is changed according to the environment of the wireless channel through the received signal energy detector, when the energy value of the received signal rises, the threshold is increased, and the energy value of the received signal is increased. This decrease reduces the threshold.

3 and 5, the operation according to the first embodiment of the present invention will be described.

In step 500 of FIG. 5, the signal received through the masking unit 100 is masked, and the flow proceeds to step 510. In operation 510, the decoder 110 performs rate matching and Viterbi decoding. In step 520, the encoder 120 adds a tail bit to an input signal and performs 1/3 convolutional encoding and rate matching. In operation 530, the mapping unit 130 maps the input signal into a 6-bit symbol and outputs the mapped signal.

In operation 540, the operation unit 140 obtains the difference between the mapped data and the signal output from the masking unit 100, squares the difference, and accumulates as much as the number of input data. The determiner 150 checks whether the channel search of all channels is completed in step 560. As described above, since four high-speed shared control channels can be transmitted at the same time, if the search of all channels is not completed, the search continues. If the search of all channels is completed, the process proceeds to step 570. In operation 570, the determiner 150 determines whether the minimum value among the accumulated values of the respective channels falls below a predetermined threshold. When the minimum value is less than or equal to the threshold, it is determined which channel is the detected channel, and accordingly, demodulation is performed on subsequent data channels. If the minimum value is less than or equal to the threshold, it is determined that the channel is not detected. The search of the shared control channel is continuously performed.

The apparatus according to the second embodiment of the present invention is shown in FIG. 4, and the receiving unit of the terminal performs rate de-matching 210 to match the transmitted fast shared control channel data to 48 symbols, and masking unit. After masking by 200, channel decoding 220 is performed to obtain the transmitted information. Since the base station can transmit up to four high-speed shared control channels, it is necessary to perform a detection process for determining whether there is a high-speed shared control channel transmitted to itself for each of the transmitted high-speed shared control channels.

The masking block 200 adds 8-bit tails to the 16-bit terminal identifier 201 given from the base station in advance (202), convolutionally encodes (203) the code rate 1/2, and receives the rate matching 210. The signal is multiplied by the convolutional coded 203 signal.

Unlike the first embodiment, the decoder 220 includes only the Viterbi decoder 220.

The encoder 230 is a rate matching unit 123 of the first embodiment is deleted, it is composed of a tail adding unit 231 and the kimssam encoding unit 232.

The information bits obtained by the decoder 220 are added to the tail of the 8-bit tail 121 in the tail adding unit 231, as encoded by the base station, and convolutionally encoded (232) at 1/3 coding rate.

The mapping block 240 maps from the 40-bit data input so that '0' has a positive value and '1' has a negative value.

The received signal energy detector (not shown) detects and outputs energy of the received high speed shared control channel, and the output signal may be used as a reference signal of the determiner 260.

The mapped data and the received fast shared control channel data are input to the operator 250. The operator 250 calculates the difference between the two input data by the subtractor 251, squares the obtained difference by the squarer 252, and the squared value is added to the accumulator 253 by 48 symbols, which is the number of input data. Accumulate by The determiner 260 determines the result by comparing the calculated value with a threshold. The threshold value may be designed to be changed according to the environment (received signal energy) of a wireless channel through which a signal is transmitted from a base station.

Hereinafter, an operation according to a second embodiment of the present invention will be described with reference to FIGS. 4 and 5.

In step 500 of FIG. 5, the signal received through the masking unit 200 is masked, and the flow proceeds to step 510. In operation 510, the decoder 220 performs Viterbi decoding. In step 520, the encoder 230 adds a tail bit to an input signal and performs 1/3 convolutional encoding. In operation 530, the mapping unit 240 maps the input signal into a symbol and outputs the signal.

In operation 540, the operation unit 250 obtains the difference between the mapped data and the signal output from the masking unit 200, squares it, and accumulates as much as the number of input data. The determiner 260 checks whether the channel search of all channels is completed in step 560. If the search of all channels is not completed, the search continues. If the search of all channels is completed, the process proceeds to step 570. In operation 570, the determiner 260 determines whether the minimum value among the accumulated values of the respective channels is less than or equal to a predetermined threshold. When the minimum value is less than or equal to the threshold value, it detects which channel is the corresponding channel, and accordingly, demodulates a subsequent data channel. If the minimum value is less than or equal to the threshold value, it is determined that the channel is not detected. Search the control channel continuously.

As described above, the present invention improves H-ARQ throughput and power consumption by improving the detection capability of the high speed shared control channel in which the identifier matches the terminal in the receiver of the wideband code division multiple access wireless communication system supporting the HSDPA. There is an advantage to improve the terminal performance by saving.

Claims (9)

Apparatus for detecting a high speed shared control channel in a high speed packet data transmission system, A decoder for rate dematching and Viterbi decoding the masked received signal; An encoder convolutionally encoding the signal output from the decoder and performing rate matching; A mapping unit for mapping the signal output from the encoder; A calculating unit calculating a difference between the masked received signal and the signal output from the mapping unit; And And a determiner for detecting an identifier according to an output value of the computing unit. Apparatus for detecting a high speed shared control channel in a high speed packet data transmission system, A decoder for rate-dematching and masking the received signal by Viterbi; An encoder convolutionally encoding the signal output from the decoder; A mapping unit for mapping the signal output from the encoder; A calculating unit calculating a difference between the masked received signal and the signal output from the mapping unit; And And a determiner for detecting an identifier according to an output value of the computing unit. The method according to claim 1 or 2, The calculation unit, A high speed packet including a subtractor for outputting a difference between the masked signal and a signal output from the mapping unit, a squarer for squared subtracted values, and an accumulator for summing a squared output value for a predetermined period An apparatus for detecting a high speed shared control channel in a data transmission system. The method according to claim 1 or 2, And a received signal energy detection unit of a shared control channel which is input to the determiner to generate a reference signal used to detect an identifier. A method for detecting a high speed shared control channel in a high speed packet data transmission system, A first step of Viterbi decoding the masked received signal by the decoder; A second step of convolutionally encoding a signal output by Viterbi decoding by the decoder in the first step; A third step of mapping a convolutional coded signal output from the encoder in the second step; And, And a fourth step of determining whether a channel received by the masked received signal and the signal mapped and output by the mapping unit in the third step is a control channel of the corresponding terminal. Method for detecting high speed shared control channel in system. The method of claim 5, further comprising: performing rate dematching on the masked received signal and inputting an output thereof to the decoder for performing the first step before performing the first step; And, And a sixth step of inputting the convolutional coded signal in step 2 into the mapping unit to perform the third step, and performing rate matching on the convolutional coded signal. . The method according to claim 5 or 6, The fourth step, Detecting a high speed shared control channel in a high speed packet data transmission system, wherein the difference between the masked signal and the signal output from the mapping unit is squared and a predetermined period is added to determine whether a received channel is a control channel of a corresponding terminal. Way for you. The method according to claim 7, And determining the control channel based on a received signal energy value of a shared control channel. The method according to claim 7, In step 4, The method for detecting a high speed shared control channel in a high speed packet data transmission system, wherein the added value is obtained for every channel, and if the minimum value among the obtained values is less than or equal to a threshold, the minimum value channel is determined as a shared control channel.

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