KR19990041062A - Dynamic Channel Allocation Method in Mobile Communication Networks - Google Patents

Abstract

The present invention relates to a dynamic channel allocation method in a base station of a mobile communication network. The present invention relates to a channel allocation request for a new call. According to the mobility characteristics (α) of the defined traffic, the channel allocation request probability is adaptively determined according to the number of channels currently in use, and radio is performed for handoff calls and new calls until the number of channels in use reaches a threshold. All handoff calls can be assigned channels for the remaining channels (CT) that share the channel and exceed the threshold, and the new call allocates only the channel allocation request probability generated by the channel allocation request probability generator. Even if the threshold is exceeded, it does not immediately block the request of a new call, but instead keeps it according to the probability of the channel allocation request. By assigning null, not only can we guarantee the call loss probability of handoff calls, but we can also reduce the call blocking probability of new calls and improve the channel utilization.

Description

Dynamic Channel Allocation Method in Mobile Communication Networks

The present invention relates to a method for allocating a radio channel in a CDMA-based mobile communication network. Specifically, the present invention relates to a new call based on the mobility characteristics of a handoff call and a new call in a base station, while guaranteeing a call loss probability of a handoff call in a CDMA-based mobile communication network. By dynamically determining the probability of the channel allocation requirement for the new call, we reduce the call blocking probability of the new call and improve the channel utilization.

In recent years, with the explosive increase in the number of mobile communication service users, the current macro cell-based cellular networks face limitations in subscriber acceptance. In particular, the quality of service (QoS) is very poor in some areas of high traffic volume due to more frequent loss of call establishment due to connection establishment (call blocking) and failure of handoff (call loss). As a result, cellular networks in the future will evolve into structures such as micro / pico cells to more efficiently use the capacity of limited wireless channels. As the cell size decreases, handoff occurs more frequently. When a handoff occurs according to the mobility of a terminal in a cellular network, handoff control that guarantees continuity of a call even if a radio resource (channel) allocated to a base station is changed is one of very important characteristics in cellular communication system design. If a handoff occurs when all available radio channels in the cell are occupied, the call is forcibly terminated resulting in call loss. This call loss results in greater dissatisfaction than call blocking, which incurs only a slight delay until the user establishes a new call connection. Therefore, QoS guarantees for handoff calls must be prioritized over new calls.

To date, various studies have been conducted to reduce the probability of call loss by giving channel allocation priority to handoff calls over new ones in cellular networks. The guard channel scheme reserves R channels after a certain threshold among the C available radio channels at one base station only for the handoff call to reduce the probability of call loss of the handoff call, and the remaining CR channels are reserved for the new call and hand. Share for call off. Although the guard channel scheme is simple and easy to implement, the channel is fixedly reserved for the handoff call without considering the mobility characteristics of the mobile call and the new call in the base station. Thus, if the percentage of handoff calls to total traffic is small, even if there are available free channels reserved for the handoff call, the connection setup of the new call is unacceptable, resulting in excessive call blocking probability and low utilization of the wireless channel. . On the other hand, if the proportion of handoff calls is relatively large, the call loss probability of the handoff call is increased proportionally and QoS cannot be satisfied. Therefore, in the cellular network, the allocation of the radio channel should fully consider the mobility characteristics of the traffic in the base station.

In order to solve the above-mentioned problems, the present invention reserves a fixed number of channels in a mobile communication network to guarantee the probability of loss of a handoff call, and at the same time, dynamically determines a channel allocation request probability of a new call according to the mobility characteristics of the traffic. It is therefore an object of the present invention to provide a dynamic channel allocation method for reducing call blocking probability and improving channel utilization.

1 is a basic conceptual diagram of a base station for wireless channel allocation.

2 is a channel allocation request probability diagram for a handoff call and a new call.

3 is a channel allocation procedure for handoff calls and new calls.

In order to achieve the above object, the present invention sets a threshold for dynamic channel allocation in a mobile communication network, the radio channel before the threshold is shared between the handoff call and the new call, and the radio channel after the threshold is the handoff call. In addition, by dynamically allocating a channel for a new call equal to the channel allocation request probability generated from the probability generator, the call loss probability of the handoff call is guaranteed, and the service rate of the new call is increased and the channel utilization is improved.

In addition, when the handoff call arrives at the base station of the mobile communication system, the dynamic channel allocation method according to the present invention allocates an available channel and performs a call processing service when the number of currently used channels is smaller than the total number of channels. Causing the call to be lost if there is no channel; Allocating a channel and performing a call processing service when the number of currently used channels is less than a threshold value when a new call arrives; Generating a channel allocation request probability P _r for dynamic channel allocation when the number of currently used channels is greater than a threshold; Requesting channel allocation as much as the generated channel allocation request probability P _r and performing a call processing service if a channel is available; If no channel is available and as many new calls as 1-P _r are made.

The preferred embodiment of the channel allocation request probability generation step includes the total number of channels available at the base station of the mobile communication network (C), the threshold value (T), the arrival rate of the handoff call (λ _h ), the arrival rate of the new call (λ _n ), the base station. It is characterized by generating a channel allocation request probability for dynamic channel allocation by receiving the number of channels (i) currently being used within the parameter.

The channel allocation request probability for the new call is adaptively determined according to the number of channels available at the base station, the threshold value, the ratio of the handoff call to the new call, and the number of channels currently in use. In addition, the dynamic channel allocation method allows the handoff call and the new call to share the radio channel before the threshold value. When the threshold value is exceeded, unlike the guard channel scheme, the dynamic channel allocation method provides for a new call equal to the channel allocation probability as well as the handoff call. By dynamically allocating channels, we can increase the service rate of new calls and improve channel utilization.

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

1 shows a basic conceptual diagram of a base station for wireless channel allocation. As shown, the total number of available channels is C, the arrival rate of the handoff call is λ _h , the arrival rate of the new call is λ _n , and the threshold is T. In the present invention, the handoff call and the new call share a radio channel until the number of channels being used reaches a threshold. On the other hand, all the handoff calls can be allocated to the channel for the remaining channel (CT) that exceeds the threshold, and the new call can be allocated only as much as the channel allocation request probability generated by the channel allocation request probability generator (12). have. In this way, even if the threshold is exceeded, the channel allocation probability can be reduced according to the channel allocation probability (Max (f (C, T, α, i), 0)) without immediately blocking the request of the new call. do. The channel allocation request probability generator is based on the total number of channels available at the base station (C), the threshold (T), the number of channels currently in use (i), and the ratio of the arrival rate of the handoff call to the arrival rate of the new call (λ _h / λ _n ). The channel allocation request probability of a new call is dynamically determined in consideration of the mobility characteristic (α) of the defined traffic. Accordingly, when the threshold is exceeded, the arrival rate of the new call is redefined as in Equation 1.

λ _n = Max (f (C, T, α, i), 0) × λ _n

2 shows the channel allocation request probability of a handoff call and a new call. As shown, the horizontal axis represents the number of channels currently being used by the base station, and the vertical axis represents the channel allocation request probability P _r of the handoff call and the new call. In area A before the number of channels in use reaches a threshold, the service probability (single line) of the handoff call and the service probability (dashed line) of the new call are both defined as 1. Thus, both handoff calls and new calls in area A may require channel allocation. In addition, since the service probability of the handoff call is 1 in the region B where the channel exceeds the threshold value, all requests for the handoff call in the region B are accepted. On the other hand, the new call request in area B is dynamically accommodated as follows.

CASE ①:

In area B, a channel allocation request probability of a new call is defined as 0. Thus, in area B, the radio channel is reserved only for handoff calls, and all new call requests are rejected. This is the same as the existing guard channel scheme without considering the mobility characteristics of the traffic, and the call loss rate of the handoff call can be reduced, but the call blocking probability of the new call is increased and the channel utilization is lowered. However, in the present invention, the base station operates in this manner only when the arrival rate of the new call is very small compared to the arrival rate of the handoff call (α 오프 ∞).

CASE ②:

This is the case where the handoff call and the new call are not distinguished by setting both the channel request probability of the handoff call and the new call to one. In the guard channel scheme, when the arrival rate of a new call is very large (α ≒ 0), the call blocking probability of the new call is increased and the channel utilization is low. Therefore, in the present invention, the service rate of the new call can be increased and the channel utilization can be improved by operating in this manner only when the arrival rate of the new call is very large compared to the arrival rate of the handoff call.

CASE ③:

The channel call probability of the new call is dynamically determined according to the arrival rate of the new call and the arrival rate of the handoff call, so that the channel is used as efficiently as possible. In the present invention, Equation 2 for determining a channel allocation request probability for a new call is defined as a function of C, T, α, and i as follows.

In Equation 2, γ may be determined using the total number of channels available in the base station, the threshold value, the mobility characteristics of the traffic, etc. to improve the channel utilization rate by reducing the call blocking probability while ensuring the call loss rate. However, in an actual system, the value of γ can be simplified by ½ or 1/4.

Equation 2 may have a value smaller than zero. However, since the minimum value of the channel allocation request probability must be 0, Equation 3 is defined.

In Equation 3, i is the number of channels currently in use.

3 shows a dynamic channel allocation procedure diagram for channel allocation of handoff calls and new calls based on the total number of channels, thresholds, and channel allocation request probabilities available at the base station. When a handoff call arrives (1) if the number of channels currently in use is less than the total number of channels (2), the base station allocates available channels (4) performs call processing (5) and releases the channels ( 6) Perform the service. If no channel is available then the call is lost (3). On the other hand, when a new call arrives (7), if the number of channels currently in use is less than the threshold (8), the channel is allocated (9), the call processing is performed (10) and the channel is released (11). If greater than the threshold, the new call generates a channel allocation request probability P _r for dynamic channel allocation through the probability generator and requests channel allocation as much as P _r (12). The occurrence of the channel allocation requirement probability is based on the total number of channels available at the base station of the mobile communication network, the threshold value T, the arrival rate of the handoff call (λ _h ), the arrival rate of the new call (λ _n ), and the current use within the base station. The number of channels i being used is input as a parameter to generate a channel allocation request probability for dynamic channel allocation.

If there is a channel available (13), the channel is allocated (9), otherwise the new call is blocked (14). And as many new calls as 1-P _r are unconditionally blocked (14).

According to the present invention, the service probability for the new call is adaptively determined according to the number of channels available at the base station, the threshold value, the ratio of the handoff call to the new call, and the number of channels currently in use. By not only guaranteeing the call loss probability of the handoff call, but also reducing the call blocking probability of the new call, improving the channel utilization and ensuring the call loss rate of the handoff call required by the cellular network, It reduces the call blocking probability of the call and improves the utilization of radio resources.

Claims (3)

In mobile networks, a threshold is set for dynamic channel allocation, the radio channel before the threshold is shared between the handoff call and the new call, and the radio channel after the threshold is the channel assignment generated from the probability generator as well as the handoff call. Dynamically assign channels for new calls as required, guaranteeing call loss probability for handoff calls without immediately blocking new calls even when the threshold is exceeded, increasing service rates for new calls and improving channel utilization. Dynamic Channel Allocation Method in Mobile Communication Networks In the dynamic channel allocation method in a mobile communication network, When the handoff call arrives at the base station of the mobile communication system, if the number of channels currently being used is less than the total number of channels, allocating an available channel and performing a call processing service, and causing the call to be lost when no channel is available. Wow; Allocating a channel and performing a call processing service when the number of currently used channels is less than a threshold value when a new call arrives; Generating a channel allocation request probability P _r for dynamic channel allocation when the number of currently used channels is greater than a threshold; Requesting channel allocation as much as the generated channel allocation request probability P _r and performing a call processing service if a channel is available; Dynamic channel allocation method in a mobile communication network characterized in that there is no channel available and the new call as 1-P _r is blocked. The method of claim 2, The channel allocation request probability generating step, The total number of channels available at the base station of the mobile communication network (C), the threshold value (T), the arrival rate of the handoff call (λ _h ), the arrival rate of the new call (λ _n ), and the number of channels currently in use in the base station (i). A dynamic channel allocation method in a mobile communication network, characterized in that it receives a parameter and generates a channel allocation request probability for dynamic channel allocation.