KR20020056046A - Method for management resourse code in CDMA mobile communication systems - Google Patents

Abstract

PURPOSE: A code resources management method in CDMA mobile communication system is provided to allocate the code resources with an orthogonal characteristic according to the transmission rate of a wireless channel, thereby accepting the wireless channel with various data transmission rates. CONSTITUTION: A Walsh layer and the number of Walsh code occupied at the Walsh layer according to a modulation and demodulation method of the required wireless channel and the data transmission rate are determined(S201). After determining the corresponding layer and the number of a horizontal equalization code of the allocating Walsh code, an idle code resource is extracted at the head of the idle code resource queue of the corresponding Walsh layer(S202). It is calculated whether the code resources including the idle code resource are idle states by the horizontal equalization code and the idle states of the all codes are confirmed(S203). It is discriminated whether the all horizontal equalization codes are idle states(S204). If the all horizontal equalization codes are not idle states, the effective orthogonal function value is increased by 1(S205). If the all horizontal equalization codes are idle states, an upper layer is changed to a vertical equalization code channel resource reservation state(S206). Thereafter, a lower layer is changed to a vertical equalization code channel resource reservation state(S207). Thereafter, a removing process is performed in the horizontal equalization code channel resource idle code channel queue and then a state is changed in a use state and thereafter connected to a use code channel queue and so the allocation is completed(S208).

Description

Method for management code in CDMA mobile communication system

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a CDMA mobile communication system, and in particular, a code channel resource allocated to a wireless channel has an orthogonal characteristic according to the transmission rate of the wireless channel, and thus the code resource is allocated to accommodate a wireless channel of various data rates. A code resource management method of a communication system.

In general, a synchronous code division multiple access mobile telephone system based on the EIA / TIA IS-95A / B standard spreads the baseband data rate of 9.6 Kbps or 14.4 Kbps by spreading the spectrum wirelessly.

As described above, the forward echo channel uses Walsh codes.

The Walsh code has 64 Walsh codes consisting of 64 bits, and the same Walsh code resource is used when the baseband data rate is 9.4 Kbps or 14.4 Kbps.

The Walsh code resource is managed using a queue, which is an idle code channel queue that manages codes that can be assigned to a call channel, and a use code channel that manages codes already assigned to a call channel. It consists of a queue.

The forward channel Walsh code resource management may include initializing a system and initializing a Walsh code resource for a call channel request by the mobile telephone user and returning a Walsh code resource allocated when the call channel is released. It is composed. When a mobile phone user requests an outgoing or incoming call, the system assigns a call channel to service it, in particular assigning a Walsh code to the forward call channel.

In the step of assigning the Walsh code, the system allocates a code channel at the head of the idle channel code queue and connects the code channel to the trailing end of the use code channel queue.

When the busy user hangs up, the Walsh code resource being used is returned.

The system removes the code resource from the usage code resource channel queue and connects to the tail of the idle code channel queue.

In order to support only one layer of Walsh code set and fixed data rate of 9.6 Kbps or 14.4 Kbps, each Walsh code resource is managed as one queue, so that multiple layers of Walsh code set, various data rates, and similar orthogonality are managed. It has a structure that is not suitable for supporting functions, and resource management such as allocating and freeing forward Walsh code resources that conform to the IS-2000 standard is not possible.

SUMMARY OF THE INVENTION An object of the present invention has been made in view of the above-mentioned problems of the prior art, and is a CDMA mobile management of Walsh code resources for distinguishing forward wireless channels in a synchronous mobile telephone system capable of serving wireless channels of various data rates. It is to provide a code resource management method of a communication system.

According to an aspect of the present invention for achieving the above object, the step of determining the equivalent code number in the Walsh layer and the layer, the equivalent code including the code channel obtained from the idle code channel queue in the corresponding Walsh layer Determining whether the resources are all idle; if there is no idle channel, increasing the pseudo orthogonal function to find Walsh code and pseudo orthogonal function resources; and having a vertical equivalent to the upper and lower hierarchies of the Walsh layer. Removing the code channel resource from the corresponding idle code resource queue, and connecting to a trailing end of the used code resource queue to complete allocation of the code channel.

Preferably, the number of equivalent codes is determined according to the modulation and demodulation method of the radio channel and the data rate of the code channel to be applied to the forward radio channel required by the terminal.

The code consists of two Walsh code sets and pseudo orthogonal functions of 64 and 128 bits in length and 64 and 128 code numbers, respectively.

In addition, the Walsh uses the idle code channel queue and the use code channel queue for the Walsh-64 layer and the Walsh-128 layer, and manages the queues by similar orthogonal functions, each queue having 64 or 128 Walsh codes. Code channel resources are configured in software to connect them sequentially.

1 is a diagram illustrating a Walsh code of a hierarchical structure according to the present invention.

2 is a diagram illustrating a code channel resource allocation procedure according to the present invention.

3 is a diagram illustrating a release procedure of a code channel resource according to the present invention.

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 provides a Walsh code resource having a hierarchical structure, a data structure for managing pseudo-orthogonal function resources, a Walsh code and pseudo-orthogonal function required to service the data structure initialization process and a forward call channel when required. And allocating resources and releasing resources occupied by the channel.

The data structure includes a set of channel code resources composed of Walsh codes and similar orthogonal functions for each Walsh layer, an idle code channel queue and a use code channel queue connecting the components of the channel code resource set.

The idle channel code queue is configured for each Walsh layer and for each similar orthogonal function, and unused Walsh code resources are sequentially connected to each queue.

In the same manner, the usage code channel queue is connected to resources already occupied sequentially.

The initialization process consists of sequentially connecting idle code resource queues by Walsh code order for each Walsh layer and similar pseudo-orthogonal functions, and using code resource queues empty.

In the IS-2000 specification, which evolved from IS-95A / B, the forward radio channel consists of Walsh codes and pseudo orthogonal functions.

The Walsh code is a Walsh 64 layer of 64 bits each and 64 in number, a Walsh-128 layer of 128 bits in length and 128 in number, and a Walsh 256-layer consisting of 256 codes in 256 bits. It consists of.

1 is a diagram illustrating a hierarchical Walsh code according to the present invention.

Referring to FIG. 1, the Walsh code of the Walsh-64 layer (W) is a Walsh code of the Walsh-128 layer (W), (W + 64), the Walsh code of the Walsh-256 layer (W), (W + 64). , (W + 128), and (W + 192) are considered the same code without the orthogonality.

The Walsh layer is composed of Walsh-32, Walsh-16, Walsh-8, Walsh-4, Walsh-2, and Walsh-1 layers, and the inter-layer relationship is as described above.

Similar orthogonal functions consist of four different codes for each Walsh code.

Therefore, the new code is formed by four times the number of Walsh codes by the combination of the Walsh codes and the pseudo orthogonal functions.

The pseudo orthogonal function has a value of 0,1,2,3, and the new code combined with the value of 0 is the same as the Walsh code.

The Walsh code has perfect orthogonality, but the code combined by the pseudo orthogonal codes 1,2,3 does not have perfect orthogonality.

In the IS-2000 standard, the modulation and demodulation method and the data rate of the radio channel determine the Walsh code and the Walsh code applied to the forward radio channel.

A wireless channel requiring nX times the basic data rate equivalently occupies n Walsh codes of the determined Walsh-W layer.

N is a multiplier of 2. And Walsh codes of n are (w), (w + W / n), (w + 2W / n), ..., (w + (n-1) W / n).

For example, in a Walsh-64 layer, a radio channel requiring a 4X transmission rate of the base rate may include at least four (w), (w + 16), (w + 32), and (w + 48) layers of the Walsh-64 layer. Occupy the Walsh code.

2 is a flowchart illustrating a code channel resource allocation procedure according to the present invention.

Referring to FIG. 2, a Walsh layer is first determined according to a required modulation method and data rate of a wireless channel, and the number n of Walsh codes occupied by the Walsh layer is determined (S201).

The determination is based on a data structure configured by configuring idle code channel queues for each similar orthogonal function for the Walsh-64 layer and Walsh-128 layer during initial operation of the base station, and using code channel queues and initializing the queues.

The usage code channel queue is left empty, and the idle code channel queue is connected in order from Walsh code 0 to Walsh code 63 or 127 to form a queue.

When the terminal requests a radio channel of a specific data rate, the base station determines which layer code of two Walsh layer codes should be used in consideration of the required modulation and demodulation method of the channel.

Then, the number of codes used equivalently in the determined Walsh layer is determined based on the data rate.

If the data rate is 1X equal to the base rate, one code should be used to provide the radio channel.

This is performed in the Walsh-64 layer and in the Walsh-128 layer if the modulation / demodulation method of the requested channel supports 64 Walsh codes. We then find assignable Walsh codes and similar orthogonal function values. In the initial search, the value of the pseudo orthogonal function is set to 0 to search sequentially from the head of the idle code channel queue of the corresponding Walsh layer.

When the corresponding Walsh code and the code value are (w) and the determined data rate is nX times the basic rate, the Walsh code having the same surplus as the surplus value for n of w is an equivalent code.

Thus, if all of these codes are available, the Walsh code w is available.

For example, an equivalent code of 4X data rate for the Walsh code of the Walsh-64 layer (5) is (5 + 64/4), (5 + 2 * 64/4), (5 + 3), including (5). * 64/4).

After determining the corresponding layer and the number of horizontal equivalent codes of the Walsh code to be allocated, the idle code resource is extracted from the head of the idle code resource queue of the corresponding Walsh layer (S202).

Next, a horizontal equivalent code is calculated to determine whether all equivalent code resources including the idle code resource are in an idle state (S203).

In operation S204, it is determined whether all of the horizontal equivalent codes are in an idle state.

As a result of the determination (S204), if all the horizontal equivalent codes are not in the idle state, the pseudo orthogonal function value is increased (S205).

Here, the pseudo-orthogonal function value is increased by one.

As a result of determining whether all the horizontal equivalent codes are in the idle state (S204), when all the horizontal equivalent codes are in the idle state, the state changes to the vertical equivalent code channel resource reservation state of the upper layer (S206).

After changing to the vertical equivalent code channel resource reservation state of the upper layer (S206), it is changed to the vertical equivalent code channel resource reservation state of the lower layer (S207).

Then, the horizontal equivalent code channel resource in the corresponding layer is removed from the idle code channel queue, changed to the used state, and connected to the used code channel queue to complete the allocation (S208).

If the code channel capable of satisfying the data rate requested by the UE is determined through the above steps S202, S203, and S205, the equivalent code channel resource in the upper Walsh layer and the lower Walsh layer is searched for this resource. Remove them from the idle code channel queue to prevent future use.

The number of code resources to be removed in the process is determined according to the number of horizontal equivalent codes determined in the process (S201).

The lower layer of the Walsh-64 layer is the Walsh-128 layer, whereas the upper layer of the Walsh-128 layer is the Walsh-64 layer. The number of horizontal equivalent codes for the lower Walsh layer is determined to be twice the number of horizontal equivalent codes determined in step S201, and the number of horizontal equivalent codes for the upper Walsh layer is determined for the horizontal equivalent code in step S201. It is determined by 1/2 of the number of codes.

In the same manner as in steps S202 and S203, the horizontal equivalent code in each layer is found in the idle code channel queue, and then removed from this queue and connected to the used code channel queue.

When performing steps S202, S203, and S205, if a Walsh code and a similar orthogonal function satisfying the condition without particular error are determined, the process is performed without special error.

The Walsh code channel determined through the above process and all code channel resources having a horizontal equivalent code relationship are removed from the idle code channel queue, and connected to the use code channel queue to be used to service the wireless channel requested by the terminal. Code channel resources are allocated.

3 is a flowchart illustrating a code channel resource release procedure according to the present invention.

Referring to FIG. 3, the corresponding layer of the Walsh code to be released and the number of horizontal equivalent codes are determined (S301).

The known Walsh code channel value and similar orthogonal function value are removed from the used code channel queue for the horizontal equivalent code and connected to the idle code channel queue.

After determining the corresponding layer and the horizontal equivalent code number of the Walsh code to be released, the corresponding code channel resource is returned (S302).

The code channel resource return is controlled by the use code channel queue, changed to an idle state, and then connected to the idle code channel queue.

After changing to the vertical equivalent code channel resource idle state of the lower layer, it connects to the idle code channel queue and returns a resource (S303).

After changing to the vertical equivalent code channel resource idle state of the lower layer, connected to the idle code channel queue to return the resource, after changing to the vertical equivalent code channel resource idle state of the upper layer, connected to the idle code channel queue Return the resource (S304).

As described above, the present invention can accommodate and allocate radio channels of various data rates required by the terminal, and by introducing an orthogonal function, the expansion of the number of code channels and the code channel resources can be performed vertically according to the orthogonal characteristics. By hierarchically and horizontally managing equivalent channels, it is possible to accommodate various transmission rates required by each call or each wireless channel and to reduce the probability of allocation failure.

Those skilled in the art will appreciate that various changes and modifications can be made without departing from the spirit of the present invention.

Therefore, the technical scope of the present invention should not be limited to the contents described in the examples, but should be defined by the claims.

Claims (4)

Determining a Walsh layer and an equivalent number of codes in the layer; Determining whether all equivalent code resources including the code channel obtained from the idle code channel queue are idle in the corresponding Walsh layer; If there is no idle channel, increasing a pseudo orthogonal function to find Walsh code and pseudo orthogonal function resources; Removing from the idle code resource queue the code channel resources that are vertically equivalent to the upper and lower layers of the Walsh layer; Connecting to a trailing end of the usage code resource queue and completing allocation of a code channel. The CDMA mobile communication system of claim 1, wherein the determining of the number of equivalent codes comprises determining a code channel to be applied to a forward wireless channel required by a terminal according to a modulation / demodulation method of a wireless channel and a data rate. Code resources management 3. The code of claim 2, wherein the code consists of two Walsh code sets and similar orthogonal functions of 64 and 128 bits in length and 64 and 128 code numbers, respectively. Resource management method The method of claim 1, wherein the Walsh uses idle code channel queues and use code channel queues for Walsh-64 layer and Walsh-128 layer, and manages the queues by similar orthogonal functions, each queue having 64 or A code resource management method of a CDMA mobile communication system, characterized in that the code channel resources are configured in software so as to sequentially connect 128 Walsh codes.