KR20010073313A - Allocation method for common packet channel - Google Patents

Abstract

PURPOSE: A method for allocating a CPCH(Common Packet Channel) is provided to transmit allocation information of the CPCH through the QPSK(Quadrature Phase Shift Keying), so that a mobile station can efficiently allocate the CPCH. CONSTITUTION: A mobile station requests the allocation of a CPCH(Common Packet Channel) to a base stations. The base station checks the possibility of the requested CPCH allocation. If possible, a CA-AICH(Channel Allocation-Acquisition Indication Channel) for informing the information of the CPCH is transmitted through the QPSK(Quadrature Phase Shift Keying). A message is transmitted through a corresponding physical channel, according to the transmitted CA-AICH.

Description

Allocation method for common packet channel

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to next generation mobile communication, and in particular, in a common packet channel (CPCH), a mobile station is common as a system transmits quadrature phase shift keying (QPSK) for allocation information of a common packet channel (CPCH). The present invention relates to a channel allocation method suitable for efficiently allocating a packet channel (CPCH).

According to the current third generation common project (3GPP) standards, the common packet channel (CPCH) is configured as shown in FIG. That is, the common packet channel status indication channel (CPCH Status Indicator Channel, hereinafter abbreviated as CSICH) for transmitting usable information of each physical common packet channel (hereinafter, referred to as PCPCH) message portion provided by the base station. A portion of an access preamble (AP) requesting the use of a specific PCPCH channel, an access preamble-acquisition indication channel (AP-AICH) transmitting a response to the access preamble (AP), collision detection and resolution ( Collision Detection Preamble (CD-P) part for Resolution, Collision Detection-Acquisition Indication Channel (CD-AICH) for transmitting a response to the Collision Detection Preamble (CD-P), Data Transfer 0 or 8 slot length Power Control Preamble (PC-P) portion to set the transmit power level in the downlink, downlink dedicated physical control channel (DL-DPCCH) to provide closed loop power control, User packet consists of the PCPCH message part for transmitting data. The PCPCH message portion is divided into a PCPCH message data portion and a PCPCH message control portion.

The conventional common packet channel (CPCH) is allocated according to the following seventh step procedure.

First, as a first step, the base station always broadcasts channel information of common packet channels it serves, that is, whether each channel is available to the mobile station through the CSICH. This CSICH is transmitted periodically, and the channel information transmitted by the CSICH is periodically updated. Then, the mobile station wishing to transmit the packet on the common packet channel (CPCH) may first receive the CSICH to provide its desired data rate and check whether there is a common packet channel (CPCH) available.

If there is a common packet channel (CPCH) available according to the check result, the mobile station selects one channel from the common packet channel (CPCH).

As a second step, a mobile station intending to use a common packet channel (CPCH) transmits an access preamble (AP) to a base station. At this time, the mobile station selects one access preamble signature (AP Signature) and one access slot (AS) and transmits the access preamble (AP) in synchronization with the start of the access slot (AS). In this case, the access preamble signature (AP Signature) selects and transmits the one corresponding to the common packet channel (CPCH) selected in the first step.

As such, the mobile station may use the maximum data rate or minimum spread factor (SF) of the message portion of the common packet channel (CPCH) required to transmit data through the access preamble signature (AP Signature) and the access slot (AS). Notify the base station.

Subsequently, when the acquisition response for the transmitted access preamble (AP) is not received by the base station from the base station, the mobile station repeatedly increases the transmission power of the access preamble (AP) up to a threshold number of times. .

As a third step, the base station receives an access preamble (AP) transmitted by the mobile station. At this time, the base station can know the maximum data rate or minimum spread rate (SF) for the common packet channel (CPCH) required by the mobile station. Then, the base station determines whether the mobile station can allocate the common packet channel (CPCH) in consideration of the channel resources and the total traffic amount of the common packet channel (CPCH) it currently has. The base station transmits an ACK signal if a common packet channel (CPCH) can be allocated, and a NAK signal if impossible.

At this time, when transmitting the ACK signal, the base station loads the access preamble signature (AP Signature) of the corresponding mobile station on the acquisition indication channel (AICH) and transmits the signal according to the start time of the access slot (AS). Complement of the access preamble signature (AP Signature) of the mobile station on the acquisition indication channel (AICH) is transmitted according to the start time of the access slot (AS). The ACK signal and the NAK signal become an access preamble-acquisition indication channel (AP-AICH).

In a fourth step, a mobile station receiving an access preamble-acquisition indication channel (AP-AICH) carrying an access preamble signature (AP Signature) transmitted by itself (ie, receiving an ACK signal) may receive a common packet channel (CPCH). In order to reduce collisions, we select one signature from the collision detection signature code set consisting of 16 signatures and apply a collision detection preamble (CD-P) to the base station. send. However, the mobile station receiving the NAK signal retransmits the access preamble (AP) to retry access to the base station.

As a fifth step, the base station selects the strongest reception strength for the collision detection preambles CD-Ps arriving at different signatures at the same time, and detects the collision detection preamble signature CD-P signature. Acquire and transmit on the acquisition indication channel (CD-AICH).

As a sixth step, the mobile station transmits a power control preamble (PC-P) to a base station on a physical channel corresponding to an access preamble signature (AP Signature) selected by the mobile station, and the base station transmits a downlink dedicated physical channel. (DL DPCH) is transmitted to the mobile station to perform closed loop power control.

As a seventh step, the mobile station transmits a message on an assigned common packet channel (CPCH), and the base station transmits a downlink dedicated physical control channel (DL DPCCH).

2 is a structural diagram of a conventional acquisition indication channel (AICH).

Referring to FIG. 2, an acquisition indication channel (AICH) such as the above-described access preamble-acquisition indication channel (AP-AICH) and collision detection-acquisition indication channel (CD-AICH) may include an Al portion and eight symbols of 32 symbols. It consists of unused parts of and is transmitted using Binary Phase Shift Keying (BPSK). At this time, Al section is comprised of part of the data is sent to the to a _0, ... a _31, an unused sector is a portion where the CSICH transmitted.

Then, each symbol may be represented as in Equation 1 below.

In Equation 1, the Al value is any one of -1, 1, 0, and the b value is determined according to the s value in the table shown in FIG. 7 shows a table composed of sixteen signatures of an acquisition indication channel (AICH). Therefore, according to Equation 1, 16 signatures of the acquisition indication channel (AICH) are present, which means that the acquisition indication channel (AICH) is transmitted using two phase shift keying (BPSK).

However, in the conventional common packet channel allocation method, the channel information broadcasted through the CSICH is periodically transmitted. This means that the channel information broadcasted through the CSICH does not match the current channel situation when the mobile station accesses it. May occur. Thus, in this case, there is a problem that the mobile station attempts unnecessary access to the base station.

In addition, in the conventional method for allocating a common packet channel (CPCH), although the base station transmits a NAK signal, there may occur a case where the common packet channel (CPCH) can be allocated because channel resources exist in the base station. However, in this case, in the conventional common packet channel (CPCH) allocation method, a method for allocating a common packet channel (CPCH) to a mobile station has not been proposed.

In addition, in the conventional common packet channel (CPCH) allocation method, the acquisition indication channel (AICH) is transmitted by using two-phase shift keying (BPSK) to limit the signature that can be used. There is a problem that cannot be used.

Accordingly, an object of the present invention is to provide a common packet channel allocation method capable of efficiently allocating a common packet channel (CPCH) in view of the above-described problems of the prior art.

Another object of the present invention is to provide a method for allocating a common packet channel that can efficiently use channel resources.

According to an aspect of the present invention for achieving the above object, the method for allocating a common packet channel requires a mobile station to allocate a common packet channel (CPCH) to a base station, and the base station requests the common packet channel (CPCH). Check whether or not) can be allocated. The base station performs a four phase shift modulation (QPSK) on a channel allocation-acquisition indication channel (CA-AICH) for informing information of a common packet channel (CPCH) to be allocated when the requested common packet channel (CPCH) can be allocated. The mobile station transmits a message through a corresponding physical channel according to the transmitted channel allocation-acquiring indication channel (CA-AICH).

Advantageously, the base station transmits the channel allocation-acquiring indication channel (CA-AICH) with a response to an access preamble (AP) transmitted from the mobile station upon request of the common packet channel (CPCH) or Transmit with a response to the Collision Detection Preamble (CD-P), which the mobile transmits to reduce collisions on the Common Packet Channel (CPCH). Further, when allocation of the common packet channel (CPCH) is impossible, the base station checks whether there is a channel resource available for the requested common packet channel (CPCH), and when the channel resource exists, the base station determines the The channel allocation-acquiring indication channel (CA-AICH) is transmitted to the mobile station together with the NAK signal.

According to another aspect of the present invention for achieving the other object as described above, the method for allocating a common packet channel, when the first mobile station and the second mobile station requests allocation of a common packet channel (CPCH) to the base station, It checks whether the required common packet channel (CPCH) can be allocated and transmits one of the ACK signal and the NAK signal to the first and second mobile stations according to the check result. Thereafter, when the first mobile station and the second mobile station receiving the response signal transmit the collision detection preamble (CD-P), the first mobile station and the second mobile station which have transmitted the collision detection preamble (CD-P) Upon receiving another response signal, the base station transmits a separate channel allocation-acquisition indication channel (CA-AICH) and a collision detection-acquisition indication channel (CD-AICH) to each of the mobile stations, and the channel allocation-acquisition. The indication channel (CA-AICH) transmits using four phase shift modulation. The mobile station transmits a message through the corresponding physical channel by using each transmitted channel allocation-acquisition indication channel (CA-AICH) and collision detection-acquisition indication channel (CD-AICH).

1 is a structural diagram of a conventional common packet channel (CPCH).

2 is a structural diagram of a conventional acquisition indication channel (AICH).

3 is a structural diagram of a common packet channel (CPCH) according to a first embodiment of the present invention;

4 is a structural diagram of a common packet channel (CPCH) according to a second embodiment of the present invention.

5 is a structural diagram of a common packet channel (CPCH) according to a third embodiment of the present invention.

6A to 6C are diagrams for explaining a four phase shift keying (QPSK) scheme of a channel allocation-acquisition indication channel (CA-AICH) according to the present invention.

7 shows sixteen signatures of an acquisition indication channel (AICH).

Hereinafter, a configuration and an operation according to an exemplary embodiment of the present invention will be described with reference to the accompanying drawings.

The present invention proposes a method for allocating a common packet channel that can efficiently allocate a common packet channel (CPCH) and can efficiently use channel resources.

To this end, the present invention additionally transmits channel allocation information for a common packet channel (CPCH) that can be used as a mobile station by a base station when allocating a common packet channel (CPCH). This channel assignment information is transmitted as a channel assignment-acquisition indication channel (CA-AICH), and this channel assignment-acquisition indication channel (CA-AICH) is an access preamble-acquisition indication channel (AP-AICH). Or with the Collision Detection-Acquisition Indication Channel (CD-AICH).

In particular, the present invention transmits the channel allocation-acquisition indication channel (CA-AICH) by four phase shift modulation (QPSK). Therefore, by increasing the number of signatures available for each acquisition indication channel (AICH), it is possible to efficiently utilize channel resources.

In the present invention, when transmitting an access preamble-acquisition indication channel (AP-AICH) in the process of allocating a common packet channel (CPCH), when the NAK signal is transmitted, the channel allocation-acquisition indication channel (CA-AICH) is recalled. Transmit with Access Preamble-Acquisition Indication Channel (AP-AICH) or Collision Detection-Acquisition Indication Channel (CD-AICH) to prevent mobile station from failing to allocate common packet channel (CPCH) due to monitoring error . However, transmission of a channel allocation-acquisition indication channel (CA-AICH) in such a NAK signal may substantially allocate channel resources that can be allocated to a common packet channel (CPCH) or allocate a common packet channel (CPCH) to a base station. It is executed when there is a situation.

In addition, according to the present invention, since the collision detection-acquisition indication channel (CD-AICH) and the channel allocation-acquisition indication channel (CA-AICH) are configured for each mobile station, the common packet channel ( CPCH) may be allocated. In the present invention, such a common packet channel (CPCH) is defined as multiple channels.

Meanwhile, in the present invention, the signature of the access preamble signature (AP Signature) or channel allocation-acquiring indication channel (CA-AICH) is mapped to a specific node of an orthogonal variable spreading rate code tree (OVSFcode tree). At this time, the access preamble signature (AP signature) and the signature of the channel assignment-acquisition indication channel (CA-AICH) may indicate the same node or may indicate different nodes, respectively.

In addition, in the present invention, the scrambling code and the channelization code of the channel assignment-acquisition indication channel (CA-AICH) are simultaneously transmitted. The AP-AICH or collision detection is transmitted. Use the same code as the Acquisition Indication Channel (CD-AICH). Here, the channel allocation-acquisition indication channel (CA-AICH) is composed of 32 symbols a ₀ ,... A ₃₁ , but its value is an access preamble-acquisition indication channel (AP-AICH) or a collision detection-acquisition indication channel ( CD-AICH).

First embodiment

3 is a structural diagram of a common packet channel (CPCH) according to a first embodiment of the present invention.

Referring to FIG. 3, in the first embodiment, a channel allocation-acquisition indication channel (CA-AICH) is transmitted simultaneously with an access preamble-acquisition indication channel (AP-AICH).

In this case, the signature for the channel allocation-acquisition indication channel CA-AICH is shown in Equation 2 below.

At this time, And b value is determined according to the s value in the table shown in FIG. In this case, Al = 1 or -1 means transmission of the channel allocation-acquisition indication channel (CA-AICH), and Al = 0 indicates no transmission of the channel allocation-acquisition indication channel (CA-AICH). .

According to Equation 2, there are 32 signatures for the channel allocation-acquisition indication channel (CA-AICH) and the access preamble-acquisition indication channel (AP-AICH). This means that the acquisition indication channel (AICH) is transmitted using four phase shift keying (QPSK) as shown in FIG. 6A. Referring to FIG. 6A, it can be seen that 16 signatures are used for the ACK signal and the NAK signal, and 32 signatures are used for the channel allocation-acquiring indication channel (CA-AICH).

Hereinafter, a procedure for assigning a common packet channel (CPCH) according to the first embodiment of the present invention will be described. The allocation procedure of the common packet channel (CPCH) according to the first embodiment of the present invention has seven steps.

First, as a first step, the base station always broadcasts channel information of common packet channels (CPCHs) it services, that is, whether each channel is available to the mobile station through the CSICH. The channel information transmitted by this CSICH is periodically updated, and the CSICH is periodically transmitted. Then, the mobile station which wants to transmit the packet on the common packet channel (CPCH) can receive the CSICH to provide its own desired data rate and check whether there is an available common packet channel (CPCH).

If there is a common packet channel (CPCH) available according to the check result, the mobile station selects one channel from the available common packet channel (CPCH).

As a second step, a mobile station intending to use a common packet channel (CPCH) transmits an access preamble (AP) to a base station. At this time, the mobile station transmits an access preamble signature (AP Signature) corresponding to the channel selected in the first step. The mobile station also selects one access slot from the 15 access slots (AS) and transmits an access preamble (AP) in synchronization with the start of the access slot (AS).

After that, when the acquisition response for the transmitted access preamble (AP) is not received from the base station by a predetermined time, the mobile station increases the transmission power of the access preamble (AP) and transmits it at the start of the access slot (AS). The operation is repeated until the threshold number of times.

As a third step, the base station receives an access preamble (AP) transmitted by the mobile station. At this time, the base station can know the common packet channel (CPCH) required by the mobile station, and can also know the maximum data rate or minimum spread rate (SF) for the requested common packet channel (CPCH).

Then, the base station determines whether the mobile station can allocate the common packet channel (CPCH) in consideration of the channel resources and the total traffic amount of the common packet channel (CPCH) it currently has. The base station transmits an ACK signal if a common packet channel (CPCH) can be allocated, and a NAK signal if impossible.

At this time, when transmitting the ACK signal, the base station loads the access preamble signature (AP Signature) of the corresponding mobile station on the acquisition indication channel (AICH) and transmits it according to the start time of the access slot (AS). In addition, when the acquisition indication channel (AICH) is transmitted, the channel allocation-acquisition indication channel (CA-AICH) is transmitted together to inform channel information available to the mobile station.

However, when the base station transmits the NAK signal, the base station carries a complement of the access preamble signature (AP Signature) of the mobile station on the acquisition indication channel (AICH) and transmits it according to the start time of the access slot (AS). Here, the reason for transmitting the NAK signal is that only the requested channel is being used, and if there is another available channel at this time, the base station transmits the NAK signal on the access preamble-acquisition indication channel (AP-AICH) and simultaneously the channel. An additional transmission of the acquisition-acquisition indication channel (CA-AICH) is provided to inform channel information available to the mobile station. Therefore, the mobile station is assigned a common packet channel (CPCH) that can be used through the channel-acquisition indication channel (CA-AICH) transmitted simultaneously even though the NAK signal is received.

However, the base station does not transmit a channel allocation-acquisition indication channel (CA-AICH) when there is no channel resource available.

Here, if there is no channel resource available to the base station when transmitting the NAK signal, the mobile station receiving the NAK signal retransmits the access preamble to retry access to the base station.

In a fourth step, a mobile station receiving an access preamble-acquisition indication channel (AP-AICH) carrying an access preamble signature (AP Signature) transmitted by itself (ie, receiving an ACK signal) may receive a common packet channel (CPCH). In order to reduce collisions, we select one signature from the collision detection signature code set consisting of 16 signatures and apply a collision detection preamble (CD-P) to the base station. send.

As a fifth step, the base station selects the strongest reception strength for the collision detection preambles (CD-Ps) arriving at different signatures at the same time, and detects the collision detection preamble signature (CD-P signature). Acquire and transmit on the acquisition indication channel (CD-AICH).

In a sixth step, the mobile station can control the power control preamble (Power Control Preamble) to a physical channel assigned to a physical channel or a channel allocation-acquisition indication channel (CA-AICH) corresponding to an access preamble signature (AP Signature) selected by the mobile station. PC-P) is transmitted to the base station, and the base station transmits a downlink dedicated physical channel (DL DPCH) to the mobile station to perform closed loop power control.

As a seventh step, the mobile station transmits a message on an assigned common packet channel (CPCH), and the base station transmits a downlink dedicated physical control channel (DL DPCCH).

Second embodiment

4 is a structural diagram of a common packet channel (CPCH) according to a second embodiment of the present invention.

Referring to FIG. 4, in the second embodiment, a channel allocation-acquisition indication channel (CA-AICH) is transmitted simultaneously with a collision detection-acquisition indication channel (CD-AICH).

In this case, the signature for the channel allocation-acquisition indication channel CA-AICH is shown in Equation 3 below.

At this time, or And b value is determined according to the s value in the table shown in FIG. In this case, Al = 1 or -1 means transmission of the channel allocation-acquisition indication channel (CA-AICH), and Al = 0 indicates non-transmission of the channel allocation-acquisition indication channel (CA-AICH). .

According to Equation 2, there are 48 signatures of the channel allocation-acquisition indication channel (CA-AICH) and 16 signatures of the collision detection-acquisition indication channel (CD-AICH) as shown in FIG. 6B. . This means that the acquisition indication channel (AICH) is transmitted using four phase shift keying (QPSK). Accordingly, it can be seen from FIG. 6B that 48 signatures are used for the channel allocation-acquisition indication channel (CA-AICH) and 16 signatures are used for the collision detection-acquisition indication channel (CD-AICH).

The following describes the allocation procedure of the common packet channel (CPCH) according to the second embodiment of the present invention. The allocation procedure of the common packet channel (CPCH) according to the second embodiment of the present invention has seven steps.

First, as a first step, the base station always broadcasts channel information of common packet channels (CPCHs) it services, that is, whether each channel is available to the mobile station through the CSICH. The channel information transmitted by this CSICH is periodically updated, and the CSICH is periodically transmitted. Then, the mobile station which wants to transmit the packet on the common packet channel (CPCH) can receive the CSICH to provide its own desired data rate and check whether there is an available common packet channel (CPCH).

If there is a common packet channel (CPCH) available according to the check result, the mobile station selects one channel from the available common packet channel (CPCH).

As a second step, a mobile station intending to use a common packet channel (CPCH) transmits an access preamble (AP) to a base station. At this time, the mobile station transmits an access preamble signature (AP Signature) corresponding to the channel selected in the first step. The mobile station also selects one access slot from the 15 access slots (AS) and transmits an access preamble (AP) in synchronization with the start of the access slot (AS).

After that, when the acquisition response for the transmitted access preamble (AP) is not received from the base station by a predetermined time, the mobile station increases the transmission power of the access preamble (AP) and transmits it at the start of the access slot (AS). The operation is repeated until the threshold number of times.

As a third step, the base station receives an access preamble (AP) transmitted by the mobile station. At this time, the base station can know the common packet channel (CPCH) required by the mobile station, and can also know the maximum data rate or minimum spread rate (SF) for the requested common packet channel (CPCH).

Then, the base station determines whether it can allocate the common packet channel (CPCH) requested by the mobile station in consideration of the channel resources and the total traffic volume of the common packet channel (CPCH) it currently has. The base station transmits an ACK signal if a common packet channel (CPCH) can be allocated, and a NAK signal if impossible.

At this time, when transmitting the ACK signal, the base station loads the access preamble signature (AP Signature) of the corresponding mobile station on the acquisition indication channel (AICH) and transmits it according to the start time of the access slot (AS).

However, when the base station transmits the NAK signal, the base station carries a complement of the access preamble signature (AP Signature) of the mobile station on the acquisition indication channel (AICH) and transmits it according to the start time of the access slot (AS). Here, the reason for transmitting the NAK signal is that only the requested channel is in use, and when there is another available channel, the base station transmits a NAK signal on the access preamble-acquisition indication channel (AP-AICH) and then detects a collision. The Acquisition Indication Channel (CD-AICH) additionally transmits a Channel Allocation-Acquisition Indication Channel (CA-AICH) during transmission to inform channel information available to the corresponding mobile station receiving the NAK signal. However, if there is no channel resource available, the base station does not transmit the channel allocation-acquisition indication channel (CA-AICH) during transmission of the collision detection-acquisition indication channel (CD-AICH).

In a fourth step, a mobile station receiving an access preamble-acquisition indication channel (AP-AICH) carrying an access preamble signature (AP Signature) transmitted by itself (ie, receiving an ACK signal) may receive a common packet channel (CPCH). In order to reduce the collisions, the system selects one signature from a collision detection signature code set consisting of 16 signatures and transmits a collision detection preamble (CD-P) to the base station. do. In addition, the mobile station receiving the NAK signal from the base station selects one signature from the signature code set and transmits a collision detection preamble (CD-P) to the base station.

As a fifth step, the base station selects the strongest reception strength for the collision detection preambles (CD-Ps) arriving at different signatures at the same time, and detects the collision detection preamble signature (CD-P signature). Acquire and transmit on the acquisition indication channel (CD-AICH). The base station also transmits a channel allocation-acquisition indication channel (CA-AICH) together with the collision detection-acquisition indication channel (CD-AICH) to inform the information of a common packet channel (CPCH) that can be used.

At this time, when the NAK signal is transmitted through the access preamble-acquisition indication channel (AP-AICH) and available channel resources exist in the base station, the base station together with the collision detection-acquisition indication channel (CD-AICH). A channel assignment-acquisition indication channel (CA-AICH) is transmitted to the mobile station that has received the NAK signal to indicate a channel that can be used by the mobile station that has received the NAK signal. Accordingly, the mobile station receiving the NAK signal is allocated a common packet channel (CPCH) that can be used using the channel allocation-acquiring indication channel (CA-AICH).

Here, if there is no channel resource available to the base station after transmitting the NAK signal in the third step, the base station does not transmit the channel allocation-acquisition indication channel (CA-AICH) to the mobile station that has received the NAK signal. Do not. Therefore, the mobile station receiving the NAK signal retransmits the access preamble to retry access to the base station.

In a sixth step, the mobile station can control the power control preamble (Power Control Preamble) to a physical channel assigned to a physical channel or a channel allocation-acquisition indication channel (CA-AICH) corresponding to an access preamble signature (AP Signature) selected by the mobile station. PC-P) is transmitted to the base station, and the base station transmits a downlink dedicated physical channel (DL DPCH) to the mobile station to perform closed loop power control.

As a seventh step, the mobile station transmits a message on an assigned common packet channel (CPCH), and the base station transmits a downlink dedicated physical control channel (DL DPCCH).

Third embodiment

5 is a structural diagram of a common packet channel (CPCH) according to a third embodiment of the present invention.

Referring to FIG. 5, a third channel allocation method will be described in the third embodiment.

The signature of the channel allocation-acquisition indication channel (CA-AICH) for the multi-channel allocation can be expressed by Equation 4 below.

At this time, And b value is determined according to the s value in the table shown in FIG. And the signature of the collision detection-acquisition indication channel (CD-AICH) for multi-channel allocation is ego, to be.

In this case, Al = 1 or -1 means transmission of the channel allocation-acquisition indication channel (CA-AICH), and Al = 0 indicates non-transmission of the channel allocation-acquisition indication channel (CA-AICH). .

According to Equation 2, there are 32 signatures of the channel allocation-acquisition indication channel (CA-AICH) and the collision detection-acquisition indication channel (CD-AICH) in the multi-channel allocation method, as shown in FIG. 6C. This means that the acquisition indication channel (AICH) is transmitted using four phase shift keying (QPSK). Accordingly, it can be seen from FIG. 6C that the first and second collision detection-acquisition indication channels (CD-AICH) and the first and second channel allocation-acquisition indication channels (CA-AICH) each use 16 signatures. .

When the multiple channels are allocated at the same time, when two mobile stations request channel allocation to the base station, a common packet channel (CPCH) can be simultaneously allocated to the two mobile stations that requested the channel allocation.

That is, when the first mobile station and the second mobile station request channel allocation, the first mobile station receives an ACK signal through an access preamble-acquisition indication channel (AP-AICH), and the second mobile station receives an access preamble. When a NAK signal is received through an acquisition indication channel (AP-AICH), the mobile station receiving the ACK signal includes a first collision detection-acquisition indication channel (CD-AICH) and a first channel allocation-acquisition indication channel (CA). A-channel is allocated and a mobile station that receives the NAK signal uses a second collision detection-acquisition indication channel (CD-AICH) and a second channel allocation-acquisition indication channel (CA-AICH). Allocate a channel.

As described above, the multi-channel allocation method according to the present invention provides a collision detection-acquisition indication channel (CD-AICH) and a channel allocation-acquisition indication channel (CA-AICH) together when transmitting a collision detection-acquisition indication channel (CA-AICH). CD-AICH) and channel allocation-acquisition indication channel (CA-AICH), respectively. Therefore, two collision detection-acquisition indication channels (CD-AICHs) and two channel allocation-acquisition indication channels (CA-AICHs) are transmitted.

Hereinafter, a multichannel allocation procedure according to the third embodiment of the present invention will be described. The multi-channel allocation procedure according to the third embodiment of the present invention has seven steps.

First, as a first step, the base station always broadcasts channel information of common packet channels (CPCHs) it serves, namely whether each channel is available to the mobile station through the CSICH. The channel information transmitted by this CSICH is periodically updated, and the CSICH is periodically transmitted. Then, the mobile stations wishing to transmit the packet on the common packet channel (CPCH) may receive the CSICH to provide a desired data rate and check whether there is a common packet channel (CPCH) available.

If there is a common packet channel (CPCH) available according to the check result, the mobile stations select one channel from the available common packet channel (CPCH).

As a second step, mobile stations wishing to use a common packet channel (CPCH) transmit an access preamble (AP) to a base station. At this time, the mobile stations transmit an access preamble signature (AP Signature) corresponding to the channel selected in the first step. The mobile stations also select one access slot from each of 15 access slots (ASs) and transmit an access preamble (AP) in synchronization with the start of the access slot (AS).

Subsequently, when the acquisition response for the transmitted access preamble (AP) from the base station is not received by a predetermined time, the mobile stations increase the transmission power of the access preamble (AP) to transmit the access slot according to the start of the access slot (AS). The operation is repeated until the threshold number of times.

As a third step, the base station receives an access preamble (AP) transmitted by the mobile stations. At this time, the base station can know the common packet channel (CPCH) required by the mobile station, and also can know the maximum data rate or minimum spread rate (SF) for the required common packet channel (CPCH).

Then, the base station determines whether the mobile station can allocate the common packet channel (CPCH) required by considering the channel resources and total traffic volume of the common packet channel (CPCH) it currently has. The base station transmits an ACK signal if the common packet channel (CPCH) can be allocated, and transmits a NAK signal if the common packet channel (CPCH) cannot be allocated.

At this time, when transmitting the ACK signal, the base station loads the access preamble signature (AP Signature) of the corresponding mobile station on the acquisition indication channel (AICH) and transmits it according to the start time of the access slot (AS).

However, when the base station transmits the NAK signal, the base station carries a complement of the access preamble signature (AP Signature) of the mobile station on the acquisition indication channel (AICH) and transmits it according to the start time of the access slot (AS).

Here, the reason for transmitting the NAK signal is that only the requested channel is in use, and when there is another available channel, the base station transmits a NAK signal on the access preamble-acquisition indication channel (AP-AICH) and then detects a collision. In the transmission of the acquisition indication channel (CD-AICH), the channel allocation-acquisition indication channel (CA-AICH) is additionally transmitted to inform channel information available to the corresponding mobile station receiving the NAK signal. However, if there is no channel resource available, the base station does not transmit the channel allocation-acquisition indication channel (CA-AICH) during transmission of the collision detection-acquisition indication channel (CD-AICH).

In a fourth step, a mobile station receiving an access preamble-acquisition indication channel (AP-AICH) carrying an access preamble signature (AP Signature) transmitted by itself (ie, receiving an ACK signal) may receive a common packet channel (CPCH). Collision Detection Preamble (CD-P) to a base station by selecting one signature s from a collision detection signature code set consisting of 16 signatures to reduce collisions Send it. In addition, the mobile station receiving the NAK signal from the base station selects one signature s from the collision detection signature code set and transmits a collision detection preamble (CD-P) to the base station.

As a fifth step, the base station selects the two having the strongest reception strengths for the collision detection preambles CD-Ps arriving at different signatures at the same time. It is assumed here that the selected collision detection preamble CD-P is a first collision detection preamble and a second collision detection preamble.

Then, the base station and the collision detection-acquisition indication channel (CD-AICH) with a _j = AI _s b _{s, j} (s = 0-7) with respect to the signature s of the first collision detection preamble (CD-P). transmit a channel assignment-acquisition indication channel (CA-AICH) with a _j = AI _s b _{s, j} (s = 8-15), and for a signature s of the second collision detection preamble (CD-P) collision detection-acquisition indication channel (CD-AICH) with _j = (-1) ^j b _{s, j} (S = 0-7) and a _j = (-1) ^j b _{s, j} (S = 8-15) In-Channel Allocation-Acquisition Indication Channel (CA-AICH) is transmitted. At this time, the signature s of the first collision detection preamble and the signature s of the second collision detection preamble must have different values to distinguish the selected first mobile station and the second mobile station, and the first and second collision detection- The acquisition indication channel (CD-AICH) and the first and second channel allocation-acquisition indication channels (CA-AICH) each have 16 signatures. This is possible because the acquisition indication channel (AICH) is transmitted using four phase shift keying (QPSK).

Thus, the first mobile station receives the first collision detection-acquisition indication channel (CD-AICH) and the first channel allocation-acquisition indication channel (CA-AICH), and the second mobile station receives the second collision detection-acquisition indication channel (CD-AICH). Receive a common channel (CPCH) by receiving an AICH and a second channel allocation-acquiring indication channel (CA-AICH).

However, if the base station transmits a NAK signal to the mobile station and there is no channel resource currently available, the base station transmits a collision detection-acquisition indication channel (CD-AICH) and a channel allocation-acquisition indication channel (CA-AICH) to the mobile station receiving the NAK signal. Do not send. Therefore, in this case, the mobile station receiving the NAK signal retransmits the access preamble (AP) and attempts to access the base station again.

In a sixth step, the mobile stations transmit a power control preamble (PC-P) to a base station on a physical channel allocated to the first or second channel allocation-acquisition indication channel (CA-AICH). The base station transmits a downlink dedicated physical channel (DL DPCH) to the mobile station to perform closed loop power control.

As a seventh step, corresponding mobile stations transmit messages on the assigned common packet channel (CPCH), respectively, and the base station transmits a downlink dedicated physical control channel (DL DPCCH).

As described above, the method for allocating a common packet channel according to the present invention has the following effects.

First, the channel allocation-acquisition indication channel (CA-AICH) is transmitted by using four phase shift keying (QPSK) to efficiently utilize channel resources. Accordingly, the allocation of common packet channels can be optimized according to the system situation. Can be.

Second, even if the mobile station requests a common packet channel (CPCH) already in use or receives a NAK signal due to an error in monitoring of the base station signal, the system may allocate another empty channel to increase system capacity.

Third, a common packet channel (CPCH) can be simultaneously allocated to mobile stations accessing simultaneously by transmitting a channel assignment-acquisition indication channel (CA-AICH) using a four-phase shift modulation scheme.

Claims (6)

A first step of the mobile station requesting assignment of a common packet channel (CPCH) to a base station; A second step of the base station checking whether the requested common packet channel (CPCH) can be allocated; When the requested common packet channel (CPCH) can be allocated, the channel allocation-acquisition indication channel (CA-AICH) for informing the information of the common packet channel (CPCH) to be allocated is transmitted through 4-phase shifted modulation (QPSK). With the third step, And a fourth step of transmitting a message through a corresponding physical channel according to the transmitted channel allocation-acquiring indication channel (CA-AICH). The method of claim 1, wherein in the third step, The base station transmits the channel allocation-acquiring indication channel (CA-AICH) with a response to an access preamble (AP) transmitted from the mobile station upon request of the common packet channel (CPCH) or the mobile station transmits a common packet. A method of allocating a common packet channel, characterized in that it is transmitted along with a response to a collision detection preamble (CD-P) to reduce collision of a channel (CPCH). The method of claim 1, wherein the allocation of the common packet channel (CPCH) is impossible, Checking whether there are other channel resources available for the requested common packet channel (CPCH), And transmitting, by the base station, the channel allocation-acquisition indication channel (CA-AICH) with the NAK signal to the mobile station when the channel resource exists. 4. The method of claim 3, further comprising: the base station transmitting a NAK signal to the mobile station; Transmitting, by the mobile station receiving the NAK signal, a collision detection preamble (CD-P) for reducing a collision of a common packet channel (CPCH); Checking, by the base station, whether there are other channel resources available to the mobile station that has transmitted the collision detection preamble (CD-P); And transmitting, by the base station, the channel allocation-acquiring indication channel (CA-AICH) to the mobile station when the channel resource exists. A first step in which the first mobile station and the second mobile station request assignment of a common packet channel (CPCH) to a base station; A second step of the base station checking whether the requested common packet channel (CPCH) can be allocated and transmitting one response signal of an ACK signal and a NAK signal to the first mobile station and the second mobile station according to a check result; , A third step of transmitting a collision detection preamble (CD-P) between a first mobile station and a second mobile station receiving the response signal; When the first mobile station and the second mobile station that have transmitted the collision detection preamble (CD-P) receive different response signals, the base station transmits a separate channel allocation-acquisition indication channel (CA-AICH) to each of the mobile stations. Transmitting a collision detection-acquisition indication channel (CD-AICH), respectively, wherein the channel allocation-acquiring indication channel (CA-AICH) is transmitted using four phase shift modulation; And a fifth step in which each mobile station transmits a message through a corresponding physical channel by using each transmitted channel-acquisition indication channel (CA-AICH) and a collision detection-acquisition indication channel (CD-AICH). A common packet channel allocation method. The method of claim 5, wherein the fourth step, Checking, by the base station, whether there is a mobile station which has received a NAK signal among mobile stations which have transmitted the collision detection preamble (CD-P); Checking whether there is a channel resource that can be allocated to the mobile station receiving the NAK signal when the mobile station receiving the NAK signal exists; When the channel resource exists, transmits the channel allocation-acquisition indication channel (CA-AICH) and the collision detection-acquisition indication channel (CD-AICH) to the mobile station that receives the NAK signal, and when the channel resource does not exist. And not transmitting the channel allocation-acquiring indication channel (CA-AICH) and the collision detection-acquiring indication channel (CD-AICH).