KR100651442B1 - Apparatus and method for communicating using common packet channel in cdma system - Google Patents

Abstract

A method for allocating a common packet communication channel of a base station of a code division multiple access communication system includes: receiving a signature of an access preamble transmitted from a mobile station;

Determining a CA (Collision Avoidances) 1 signature for assigning a common packet channel and a CA (Collision Avoidances) 2 signature for CA1 signature error checking according to the received access preamble signature;

Allocating a common packet channel corresponding to the determined CA1 signature number, and determining a signature pair of CA1 / CA2 by pairing the CA2 signature corresponding to the CA1 signature and the CA1 signature to check the CA1 signature error. and,

And transmitting the signature pair of CA1 / CA2 to the mobile station through the CD / CA-ICH (Collision Detection / Collision Avoidances-Indicator Channel).

CPCH, CD / CA-ICH, signature,

Description

Apparatus and method for common packet channel communication in code division multiple access communication system {APPARATUS AND METHOD FOR COMMUNICATING USING COMMON PACKET CHANNEL IN CDMA SYSTEM}             

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a diagram illustrating a signal transmission / reception relationship between a reverse common path and a forward common packet channel in a code division multiple access communication system.

2 is a diagram illustrating a signal transmission / reception relationship between a reverse common path and a forward common packet channel in a code division multiple access communication system according to an embodiment of the present invention.

3 illustrates the preamble signature structure of FIG. 2. FIG.

4 illustrates an AICH frame structure.

5A through 5B are diagrams showing an example of implementation of a signature pair for channel assignment.

6 is a diagram illustrating a structure for selecting a collision detection signature and a channel allocation signature;

7 is a diagram illustrating a structure of a mobile station transmitting a message through a common channel in a code division multiple access communication system according to an embodiment of the present invention.

8 is a diagram illustrating a structure of a base station transmitting a message through a common channel in a code division multiple access communication system according to an embodiment of the present invention.

FIG. 9 illustrates a structure for generating a CD / CA-ICH signal in FIG. 8. FIG.

10 is a diagram illustrating a receiver structure of an AICH channel according to an embodiment of the present invention.

The present invention relates to a common channel communication apparatus and method of a code division multiple access communication system, and more particularly, to an apparatus and method for communicating data through a common packet channel in an asynchronous code division multiple access communication system.

A packet common channel communication method is used in a wideband code division multiple access (W-CDMA) communication system of an asynchronous method (or UMTS), which is a next generation mobile communication system.

1 is a diagram illustrating a signal transmission / reception relationship of a conventional asynchronous reverse common packet channel. In FIG. 1, the mobile station adjusts the timing of the forward link through a forward broadcasting channel or the like and obtains information on a common packet channel broadcast from the base station. The information on the reverse common packet channel includes the number of uplink spreading codes and signatures used for a reverse access preamble (AP), an Acquisition Indicator Channel (AICH) timing of a forward link corresponding to the reverse common packet channel control, and an AICH channel. Contains information about the identification code. When the mobile station needs to transmit a signal through the reverse common packet channel, as shown in 162 of FIG. 1, the base station determines an AP preamble, an AP-AICH, a CD preamble, and a CD / CA-ICH (Collision Detection / Collision Avoidances)- Indicator Channel) is used to allocate a common packet channel for use by the mobile station. The AP preamble is configured in the form of a specific signature and each signature is mapped to a maximum data rate that the mobile station will use when transmitting common packet data. Therefore, the relationship between the AP preamble and the data rate should be known to the base station and the terminal at the same time, and the relationship should be transmitted to the terminal or included in advance in the common channel information. The mobile station transmits a preamble AP composed of a signature sequence indicating a data rate of a common packet channel to be transmitted and a spread code for the preamble AP unique to the base station. Then, when the base station detects the preamble AP signal transmitted by the terminal to accommodate the data rate requested by the mobile station, that is, the other mobile station is not using a common packet channel that can use the data rate within the capacity range. And transmits an acquisition indication signal (AP-AICH) for the access preamble to the mobile station. If the base station fails to acquire the access preamble and the mobile station does not receive the AP-AICH, the mobile station ΔP at 164 P1 power (P1 = P0 + ΔP) of FIG. 1 after a certain time (tp-p). Increment by to send the access preamble AP again. In addition, if the base station acquires the access preamble but the capacity exceeds the data rate requested by the mobile station or there is no common packet channel that can support the data rate, the base station uses AP-AICH as the mobile station. Sends a negative acknowledgment (NACK) signal.

When the mobile station receives the acquisition indication signal, a collision detection preamble using the collision detection signature as shown in 166 of FIG. 1 to avoid a collision that may occur when another mobile station transmits an access preamble using the same signature at a similar point in time. Load it on a CD and send it. Since the collision detection signature is randomly selected among several signatures in each mobile station, even if the access preambles used by the two mobile stations are the same, the collision can be resolved. The CD preamble, which is the collision detection signal, is spread with a spread code different from that of the access preamble AP, and is transmitted by multiplying the spread code for the CD preamble and the signature for collision detection. The base station receives the collision detection preamble signal transmitted by the mobile station, checks the collision detection signature included in the collision detection signal, and multiplexes the collision detection signature and the channel assignment signature as shown in 122 of FIG. 1 to detect the collision. Transmit response / channel assignment signal (CD / CA-ICH). At this time, the conventional technology selects and transmits one signature corresponding to the collision detection response and the channel assignment signal.

The mobile station receives a collision detection response / channel assignment signal (CD / CA-ICH) received from the base station and determines a common packet channel designated by the base station using a relationship with the AP preamble transmitted by the mobile station. That is, the mobile station uses the relation between the AP preamble transmitted to the base station and the CD / CA-ICH received from the base station for the reverse channel separation code, spreading code, and power control of the mobile station at the base station. Determines the channel separation code used for the dedicated control channel used. The mobile station also allocates a control channel receiver for receiving power control information transmitted from the base station and a reverse packet common channel transmitter for transmitting messages. Thereafter, the mobile station transmits a message through the reverse packet common channel transmitter and controls the transmit power of the reverse common channel transmitter by the power control information received through the control channel receiver.

However, when a CD / CA-ICH signal is received by the base station due to signal degradation and noise caused by a radio channel during transmission of a collision detection response / channel assignment signal (CD / CA-ICH) sent by the base station, The mobile station may not properly receive the CD / CA-ICH sent by the base station and thus may not receive the channel assignment code and the spreading code correctly. At this time, the mobile station may incorrectly determine the channel allocation code sent by the base station as another channel allocation code, and may cause serious problems to the system if another mobile station is already using the incorrectly determined channel allocation code. That is, since the two mobile stations transmit and receive using the same common packet channel, the power control signal transmitted from the base station to the mobile station with which the base station is communicating is transmitted to the two mobile stations, thereby simultaneously increasing / decreasing power.

However, when the command of the power control channel received by the mobile station and the other mobile station is a command to increase the power of the mobile station, the mobile station and the other mobile station increase the power according to the command of the base station. Since the mobile station and the other mobile station transmit different data through the same channel, it is difficult for the base station to properly receive the data. Alternatively, when the signal transmitted from the mobile station and the other mobile station is weak, the base station transmits a command to the mobile station to increase the transmission power through the forward control channel so that both the mobile station and the other mobile station increase the power again to transmit the signal. As a result, the signals of the mobile station and other mobile stations act as interference signals for the adjacent mobile stations, thereby weakening the transmission signals of the adjacent mobile stations. The base station eventually sends a command to increase the transmission power to all mobile stations belonging to the cell of the base station, and conventionally, the overall cell signal power of the base station is increased. This, in turn, acts as an enormous signal interference for the neighboring cell, resulting in a situation that the mobile station transmit power of the entire mobile communication system is increased and power control of the entire mobile communication system is impossible.

Therefore, reducing the error probability of the forward channel assignment code (CA) sent by the base station may be a necessary requirement for the stable operation of the system as well as the efficient use of the common packet channel.

Accordingly, an object of the present invention is to provide an apparatus and method for transmitting a message through a common channel in a code division multiple access communication system.

It is an object of the present invention to provide a collision detection response / channel assignment signal of a forward link in which a receiver of a mobile station can receive a collision detection response / channel assignment signal with low complexity and low probability of error.

SUMMARY OF THE INVENTION An object of the present invention is to provide a mobile station reception method that can simplify detection of multiple signatures transmitted in a collision detection response / channel assignment signal of a forward link.

Another object of the present invention is to provide an apparatus and method for allocating a channel to transmit a message through a reverse common channel in an asynchronous code division multiple access communication system.

Another object of the present invention is to provide a method for reliably managing radio resources allocated to a reverse common channel.

It is still another object of the present invention to provide a method of reducing the probability that a mobile station erroneously judges information on common packet channel allocation informed by a base station.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

According to an embodiment of the present invention, when a message is transmitted on a reverse common channel, the mobile station transmits a preamble, the base station captures and responds, and the base station controls the reverse common channel and power of the reverse common channel to be used by the mobile station. Allocate a forward channel. In this case, the mobile station receives the channel assignment message from the base station after transmitting the preamble, infers the assigned channel by the combination of the preamble and the channel assignment message, transmits the message through the assigned channel, and also allocates the forward direction. The transmit power of the reverse common channel is controlled according to the power control command received through the channel. The rule in which the reverse and forward codes related to the common packet channel are determined by a specific preamble and channel assignment message may be treated separately from the contents of the present invention, and thus the description thereof will be omitted.

Here, the preamble transmitted from the mobile station may be a collision detection preamble collision detection preamble (CDP) and an access preamble AP, and the base station generates an AP-AICH in response to the access preamble AP and collides in response to the collision detection preamble CDP. Assume that a CD / CA-ICH for assigning a channel and a response to the detection preamble is assumed. In this case, two channel allocation signatures are used at the same time and the number of signatures that can be used at the same time may be further increased to compensate for the problems of the existing CD / CA-ICH.

2 is a diagram illustrating a signal flow between a mobile station and a base station for a reverse common packet channel or a reverse common channel proposed in an embodiment of the present invention. In the embodiment of the present invention, it is assumed that a common packet channel is used as an example of the reverse common channel. However, the reverse common channel may be applied to other common channels other than the common packet channel.

Referring to FIG. 2, the mobile station adjusts the timing of the forward link through a forward broadcasting channel and obtains information of the reverse common channel or common packet channel. The information on the reverse common channel includes information on the number of spreading codes and signatures used in the access preamble, the AICH of the forward link, the ICH timing, and the like. When the mobile station needs to transmit a signal through a common packet channel, it first transmits an access preamble AP as shown in 262 of FIG. 2. The access preamble AP may include the maximum data rate requested by the terminal and other information, and is spread with a spread code unique to the base station in the form of a specific signature and transmitted.

In an embodiment of the present invention, one bit of the signature is maintained for 256 chip intervals, and the 256 chip intervals are spread by spread codes designated for each base station. 3 is a signature of the preamble. Since each signature is represented by 16 bits, the time taken to transmit a specific signature corresponds to a 16 * 256 chip interval.

Referring to FIG. 3, the spread code may use a 256-length sequence, or may use a long code that is not repeated during the preamble length. In the W-CDMA system, since the reverse common channel is divided into a random access channel (RACH) and a common packet channel (CPCH), a spreading code and a common packet used for the random access channel RACH are used to distinguish them. The two channels may be distinguished by different spreading codes used for the channel CPCH. In addition, even if the same spreading code is used, two types of reverse common channels having different properties may be distinguished by different signatures for random access channel RACH and signatures for common packet channel CPCH.

If the mobile station intends to transmit data on the common packet channel CPCH, the mobile station transmits the access preamble AP at the initial power P0 as shown at 262 of FIG. If the base station detects this access preamble AP, it sends an ACK (Acknowledge) signal to the Acquisition Indicator Channel AICH corresponding to the access preamble AP. At this time, if the capacity of the reverse link of the base station is exceeded or if there is no more demodulator, it transmits a NACK signal to temporarily stop the reverse common channel transmission of the mobile station.

In another case, if the base station does not detect the access preamble AP, it is unable to send an ACK signal to the AICH as shown in 222. In this case, it is assumed that the embodiment of the present invention transmits nothing to the AICH.

Thus, after transmitting the access preamble, the mobile station monitors the AICH of the forward link. At this time, the mobile station demodulates the AICH corresponding to the transmitted access preamble AP. If the mobile station does not receive the AP-AICH from the base station (i.e., the base station transmits no signal), the mobile station may transmit a predetermined time (tp-p). After that, the power is increased by ΔP with the power of P1 (P1 = P0 + ΔP), and then the access preamble AP is transmitted again. If the base station transmits NACK, it does not transmit on the reverse common packet channel for a predetermined time and then tries again. Here, the predetermined time may be set to the same time as tp-p or a different time. However, when the base station detects the access preamble AP, it transmits an ACK to the AP-AICH as shown in 222. At this time, if the mobile station receives the ACK by the AP-AICH, the mobile station assumes that the base station has acquired the signal of the mobile station and performs the next step.

When the mobile station receives an ACK on the AP-AICH, it transmits a CD preamble on the reverse link. There may be several CD preambles, and the mobile station arbitrarily selects and transmits one of them. In an embodiment of the present invention, the CD preamble is transmitted with a spread code different from the access preamble AP. The reason for transmitting the CD preamble as described above is that even if two or more mobile stations transmit the same access preamble AP at the same moment, even if a collision occurs, the probability of selecting the same CD preamble is reduced. That is, if there are N2 CD preambles, the probability of collision is further reduced by 1 / N2.

When the mobile station transmits the CD preamble as described above, the base station detects and demodulates the CD preamble transmitted by the mobile station. At this time, when the base station detects the CD preamble, the base station assigns a response (CD-ICH signature) corresponding to the CD preamble transmitted by the mobile station and a base station for use by the mobile station as shown in 224 of FIG. 2. A CA-ICH signature pair that designates a channel allocation code of one forward control channel, a channel assignment code to be used for the reverse CPCH channel, and a reverse spreading code is transmitted on the forward link. The CD / CA-ICH generated as shown in 224 of FIG. 2 transmits a CD response signature for the CD preamble to the forward link, such as AP-AICH for transmitting a response for the access preamble AP, to inform the mobile station of the acquisition. It includes allocation information of the forward control channel and the reverse control channel allocated for power control of the common packet channel CPCH.

Here, the channel for transmitting the channel assignment command and the collision detection response is an AICH, which is a 20 ms long frame composed of 15 access slots (ASs) as shown in FIG. 4. Each access slot is composed of 20 symbols, that is, 40 bits, such as 432 of FIG. 4. It is assumed that one symbol interval is 256 chips long, and that AICH is transmitted only in 16 symbol intervals, that is, 32 bit intervals. Other values may be used for the length of the access slot, the number of bits constituting the access slot, the chip length, and the like.

Each of the slots may transmit zero or one or more signatures among 16 signatures. The AICH includes AP-AICH and CD / CA-ICH as shown in FIG. 2.

Accordingly, the channel assignment command transmitted as shown in FIG. 2 may be composed of 16 symbols (32 bits), and each symbol has a length of 256 chips. Each symbol is multiplied by one bit of the signature, a forward channel separation code, and a spreading code, and transmitted on the forward link, thereby ensuring orthogonality between the signatures.

In this case, the CD / CA-ICH may be spread using an orthogonal channel different from the AP-AICH, and thus, the CD / CA-ICH may be transmitted on a physical channel different from the AP-AICH. In addition, by using one orthogonal channel as time division, the CD / CA-ICH may be transmitted through the same channel as the AP-AICH.

In the embodiment of the present invention, a case of transmitting the CD / CA-ICH on a physical channel different from the AP-AICH will be described. In other words, it is assumed that both the CD / CA-ICH and the AP-AICH are spread with 256 length orthogonal spreading codes and transmitted on independent physical channels. The mobile station can then identify this CD / CA-ICH and transmit the common packet channel with a lower collision probability.

The structure of the signature used for this AICH is as shown in FIG. When the mobile station receives the AP-AICH, it only needs to detect one signature corresponding to the access preamble transmitted by the mobile station. However, when the mobile station receives the CD / CA-ICH, it attempts to detect all possible signatures. Therefore, it is necessary to design or arrange the signature structure of the AICH to reduce the complexity of the mobile station.

However, since one CD signature of 16 types and one or more CA signatures of 16 types are all expressed on one AICH channel using the 16 signatures of FIG. 3, 16 separate orthogonal codes are additionally required. However, if the 8 signatures of the 16 signatures of FIG. 3 are assigned to the CD signatures, the remaining 8 signatures are assigned to the CA signatures, and then multiplied by the sign of + 1 / -1 to create 32 signatures, the CA signatures 16 can be expressed in all 16 CD signatures. That is, 16 CD signatures are assigned with eighteen possible signatures and a sign of (+ 1 / -1) multiplied by the signature, and the sign (+ 1 / -1) is multiplied by the remaining eight signatures and signatures. Allocate CA signatures for 16 CPCH assignments. Orthogonality is maintained between these AICH signatures. Therefore, if the signatures allocated to the AICH are efficiently arranged, the mobile station can simply demodulate the CD / CA signature through a method such as Fast Hadamrd Transform (FHT).

The signature is expressed as Equation 1 below, and W _i ^N is a Walsh code of length N, which is an i-th codeword, and is generated as shown in Table 1 below. .

Here, S _i denotes 16 even numbers of Walsh codes having a length of 32 as shown in [Equation 1].

S _i i 0 One 2 3 4 5 6 7 8 9 10 11 12 13 14 15 0 A A A A A A A A A A A A A A A A One A -A A -A A -A A -A A -A A -A A -A A -A 2 A A -A -A A A -A -A A A -A -A A A -A -A 3 A -A -A A A -A -A A A -A -A A A -A -A A 4 A A A A -A -A -A -A A A A A -A -A -A -A 5 A -A A -A -A A -A A A -A A -A -A A -A A 6 A A -A A -A -A A A A A -A A -A -A A A 7 A -A -A A -A A A -A A -A -A A -A A A -A 8 A A A A A A A A -A -A -A -A -A -A -A -A 9 A -A A -A A -A A -A -A A -A A -A A -A A 10 A A -A -A A A -A -A -A -A A A -A -A A A 11 A -A -A A A -A -A A -A A A -A -A A A -A 12 A A A A -A -A -A -A -A -A -A -A A A A A 13 A -A A -A -A A -A A -A A -A A A -A A -A 14 A A -A A -A -A A A -A -A A -A A A -A -A 15 A -A -A A -A A A -A -A A A -A A -A -A A

이다.In Table 1 above

to be.

Among the 16 signatures of Equation 1, the CD signature and S _CD.i are allocated as shown in Equation 2 below.

The CA signature S _CA.i is configured as shown in [Equation 3] below.

As proposed by the present invention, a method of reducing the probability that a mobile station incorrectly determines a CA signature and uses a CA signature already used by another mobile station includes sending two pairs of CA signatures having a predetermined rule to the mobile station, Only when two signatures are correctly decoded at the same time is the mobile station selecting a common packet channel and the mobile station attempting to transmit the common packet channel. By using this method, it is possible to reduce the probability that an error occurs in the channel allocation information sent from the base station to the mobile station. The number of CAs used to allocate one common packet channel may be two or more, and the rule may be variously changed.

An example of a CA signature pair is shown in FIGS. 5A and 5B.

In the case of FIG. 5A, since there are eight CA-signature pairs, the channel allocated by the CA-ICH is one of eight, and the CA-signals belonging to each pair do not belong to the other CA-signature pair. Therefore, the base station _sends S _CA.2n and S _{CA.2n + 1} in pairs to the mobile station, which receives and decodes the two CA signatures sent by the base station, and decodes the two CAs. -Check whether the signature is done correctly with the CA-signature pair of FIG. 5A. If received correctly, frame transmission begins on the CPCH channel assigned by the corresponding CA-signature. If the CA signature pair, which the mobile station decodes, differs from that shown in FIG. 5A, the mobile station cannot trust the CA signature information it decoded, and discards and transmits again from the access preamble.

In another example of FIG. 5B, there are fewer CA signature pairs than in the conventional method of sending one CA-signature with 15 CA signatures. However, by sending two CA-signatures in pairs, the mobile station can verify that it has received the CA-signature correctly. This CA-signature pair has less confidence that the CA-signature decoded is correctly decoded than in the case of FIG. 5A, but can allocate one of 15 channels. This is because one CA-signature is contained in two pairs of CA-signature pairs. In addition, other rules can be used to achieve the same purpose.

An AICH carrying the above CA signature information is generated as shown in FIG. It is assumed that this AICH generator is an AICH generator that generates a channel allocation command for CD / CA-ICH. As described above, each slot of the AICH frame allocates a signature pair corresponding to a CPCH channel to be allocated to the mobile station among the 16 signatures. Referring to FIG. 6, the multipliers 601, 602, and 616 multiply 1 by two CA-signatures selected by the CA-signature selector 631 and 0 by the remaining CA-signatures. At this time, the selected two CA-signatures correspond to the CPCH channel to be assigned to the mobile station by the base station. The multipliers 671, 672, and 686 multiply 1 by one of the orthogonal codes S _CD.0 to S _CD.15 corresponding to the collision detection signature selected by the CD-signature selector 651, and 1 by the other. Therefore, the adder 620 adds the outputs of the multipliers 601, 602, 616 and 671, 672, and 686 and outputs the result as an AICH signal.

7 and 8 show a transceiver structure of a mobile station and a base station, respectively. 7 is a diagram illustrating a structure of a mobile station communicating a message through a reverse common channel according to an embodiment of the present invention.

Referring to FIG. 7, the AICH detector 711 receives and demodulates AICH signals of the forward link transmitted from the AICH generator of the base station under the control of the controller 720. The AICH detector 711 may include an AP-AICH demodulator and a CD / CA-ICH demodulator, respectively.

The data and control signal processor 713 is assigned a channel by the controller 720, and receives and processes data or control signals (including power control commands) received through the designated channel. The channel estimator 715 estimates the strength of the signal transmitted from the base station and received on the forward link, controls phase compensation and gain of the data and control signal processor 713, and assists in demodulation.

The controller 720 controls the overall operation of the forward link channel receiver and reverse link channel transmitters of the mobile station. In an embodiment of the present invention, the controller 720 controls the generation of the access preamble AP and the collision detection preamble CD when the base station is accessed, and processes the AICH signals transmitted from the base station. That is, the controller 720 controls the preamble generator 731 as shown in 251 of FIG. 2 to generate an access preamble AP and a collision detection preamble CD, and processes the AICH signals generated as shown in 211 of FIG. 2 by controlling the AICH demodulator 711.

The preamble generator 731 generates and outputs a preamble AP and a CD as shown in 251 of FIG. 2 under the control of the controller 720. A frame formatter 733 inputs preamble APs and CDs output from the preamble generator 731, packet data and pilot signals of a reverse link, and formats the frame data into frame data. The frame formatter 733 outputs a power control signal output from the controller 720. By controlling the transmission power of the reverse link. In this embodiment, the channel for outputting the encoded packet data may be a reverse common packet channel. A power control command may also be sent for controlling the power of the forward link on the reverse link.

8 is a diagram illustrating a structure of a base station for communicating a message through a reverse common channel according to an embodiment of the present invention.

Referring to FIG. 8, the preamble detector 811 detects the preamble AP and CD transmitted from the mobile station and received as shown in FIG. 2, and outputs the preamble AP and CD to the controller 820. The data and control signal processor 813 is assigned a channel by the controller 820 and receives and processes data or control signals received through the designated channel. The channel estimator 815 estimates the strength of the signal transmitted from the base station and received on the forward link to control the gain of the data and control signal processor 813.

The controller 820 controls the overall operation of the forward link channel transmitter and reverse link channel transmitters of the base station. In an embodiment of the present invention, the controller 820 controls the detection of the access preamble AP and the collision detection preamble CD generated when the mobile station accesses the base station, and the AICH signals for the response and the channel allocation command for the preamble AP and CD. Control the occurrence. That is, when the access preamble AP and the collision detection preamble CD received through the preamble detector 811 as shown in 251 of FIG. 2 are detected, the controller 820 controls the AICH generator 831 to generate AICH signals as shown in 211 of FIG. 2.

The AICH generator 831 generates AP-AICH and CD / CA-ICH which are response signals to the preamble signal under the control of the controller 820.

The frame formatter 833 inputs and formats the AP-AICH and CD / CA-AICH output from the AICH generator 831 and the control signals of the forward link, and outputs the formatted signals, by the power control command output from the controller 820. Control the transmit power of the reverse link. In addition, if a power control command for the forward link is transmitted to the reverse link, the power of the forward channel for controlling the common packet channel may be controlled according to the power control command.

First, the controller 720 of the mobile station of FIG. 7 determines an AP preamble signature corresponding to a desired data rate when communication is required through a common packet channel, and then multiplies the preamble generator 731 of FIG. 7 by the scrambling code and the chip unit using the determined signature. Transmit to base station via. The base station then checks the signature used by receiving the AP-preamble at the preamble detector 811 of FIG. The AP-AICH is transmitted through the 831 AICH generator of 8, and the AP-AICH is transmitted by using the signature value inverted phase of the received signature when the mobile station is in use or cannot accept the request. In this case, the base station generates a signature value of a phase inversion or in-phase signature of the corresponding signature from the response signal for the AP-preamble requested by another mobile station using different signatures, and then adds the signature values to generate the AP-AICH signal. It can send status about the signature. The mobile station detects any one of the CD signatures for collision detection in the 731 preamble generator of FIG. 7 in response to detecting the same signature as the AP-signature transmitted by the mobile station in the AICH signal transmitted from the base station in the 711 AICH detector of FIG. Transmit the CD preamble signal. When the base station receives the signature included in the CD preamble signal through the preamble detector 811 of FIG. 8, the controller 820 of the base station transmits from the memory 822 to an assignable channel of the CPCH channel corresponding to the data rate requested by the mobile station in the AP-preamble. The corresponding signature pair is selected to generate the CD / CA-ICH signal at 831 of FIG. The CD / CA-ICH signature information is then notified to the mobile station via signal generator 833 in FIG. The mobile station receiving the CD / CA-ICH signature information selects a common packet channel in the same manner using the signature information of the access preamble transmitted in the backward direction and the signature pair of the received CD / CA-ICH. .

The signature of the CD / CA-ICH shown in FIG. 3 may be generated in the CD / CA-ICH generator having the structure as shown in FIG. 9.

Referring to FIG. 9, the base station adds, in the adder 911, the CA signature pair including the signature of the detected CD preamble and information to be allocated to the mobile station by the adder 911, and then the channel separation code for CD / CA-ICH and the base station scrambling code. Multiply by and transmit to the mobile station.

When the mobile station receives the CD / CA-ICH transmitted by the base station, the mobile station can decode the corresponding CD and CA information in the CD / CA-ICH detector having the structure shown in FIG. If the decoded CD signature is in phase with the CD signature sent by the mobile station, the mobile station checks the CA1 signature and the CA2 signature information. If the CA signature pair follows the example of the mapping rule shown in Fig. 5, the mobile station recognizes that the CA signature pair is correctly formed and decoded, and transmits data through the CPCH channel allocated from the base station.

As described above, the conventional common packet channel allocation scheme may cause a serious problem in the overall system when the base station incorrectly recognizes a channel already used by another mobile station due to an error in a channel assignment signal transmitted to the mobile station. By using the channel allocation method according to the embodiment of the present invention, such error probability can be lowered.

Claims (4)

A common packet communication channel assignment apparatus for a mobile station in a code division multiple access communication system, An Acquisition Indicator Channel (AICH) detector for receiving a signature through a CD / CA-ICH (Collision Detection / Collision Avoidances-Indicator Channel) transmitted from a base station, And a controller for determining a corresponding common packet communication channel from the received signature number. A common packet communication channel allocation apparatus of a base station of a code division multiple access communication system, A preamble detector for receiving a signature of an access preamble transmitted from the mobile station; Determining a CA (Collision Avoidances) 1 signature for allocating a common packet communication channel according to the received access preamble signature, allocating a common packet channel corresponding to the determined CA1 signature number, and checking an error of the CA1 signature A controller for determining a signature pair of CA1 / CA2 by pairing a CA (Collision Avoidances) 2 signature corresponding to the CA1 signature with the CA1 signature; Common packet of a base station of a code division multiple access communication system comprising an Acquisition Indicator Channel (AICH) generator for transmitting the signature pair of CA1 / CA2 to a mobile station through a CD / CA-ICH (Collision Detection / Collision Avoidances-Indicator Channel) Communication channel allocator In the common packet communication channel allocation method of a base station of a code division multiple access communication system, Receiving a signature of an access preamble transmitted from a mobile station, Determining a CA (Collision Avoidances) 1 signature for assigning a common packet channel and a CA (Collision Avoidances) 2 signature for CA1 signature error checking according to the received access preamble signature; A signature pair of CA1 / CA2 is determined by allocating a common packet channel corresponding to the determined CA1 signature number and pairing the CA2 signature corresponding to the CA1 signature and the CA1 signature for checking the error of the CA1 signature. Process, A method of allocating a common packet communication channel of a base station of a code division multiple access communication system comprising transmitting a signature pair of CA1 / CA2 to a mobile station through a CD / CA-ICH (Collision Detection / Collision Avoidances-Indicator Channel). A method for allocating a common packet communication channel of a mobile station in a code division multiple access communication system, Fixing, by the mobile station, to transmit a signature among the signatures of the access preamble, In response to the signature of the access preamble, the base station selects a signature pair of CA (Collision Avoidances) 1 / Collision Avoidances (CA) 2 indicating a common packet communication channel allocated to the CD / CA-ICH (Collision Detection / Collision Avoidances-Indicator Channel). ), And And performing an error check on the CA1 / CA2 signature pair and allocating a corresponding common packet communication channel.

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