KR20020029166A - Reverse direction traffic channel assignment method of mobile communication system - Google Patents

Abstract

PURPOSE: A method for allocating reverse traffic channels in a mobile system is provided to effectively implement voice services and data services by allocating one reverse traffic channel to each voice channel and assigning the other allocable channels, except the traffic channels for voice services, to data services. CONSTITUTION: A BCP in a base station judges whether a channel allocation or release request signal is transferred from a mobile terminal(S1). In case that a channel allocation request signal is transferred, the BCP judges whether the transferred signal is a voice call or a data call(S2). If the transferred signal is a voice call, the BCP releases the voice call channel and changes a data call channel allocation state(S3). If the transferred signal is a data call, the BCP releases the data call channel and changes the data call channel allocation state(S4). However, if the transferred signal is a voice call for channel allocation(S5), the BSP judges whether the voice call meets condition #1(S6). If the voice call meets condition #1, the BSP allocates a channel to the voice call(S7). But if the voice call meets condition #2, the BSP allocates a channel to the voice call and changes the data call channel allocation state(S8,S10). If the voice call does not meet condition #2, the BSP disposes of the voice call(S9). Also, if the transferred signal is a data call for channel allocation(S5), the BSP judges whether the data call meets condition #3(S11). If the data call meets condition #3, the BSP allocates a channel to the data call(S12). But if the data call meets condition #4, the BSP allocates a channel to the data call after changing the data call channel allocation state(S14). If the data call does not meet condition #4, the BSP disposes of the data call(S15).

Description

REVERSE DIRECTION TRAFFIC CHANNEL ASSIGNMENT METHOD OF MOBILE COMMUNICATION SYSTEM}

The present invention relates to a CDMA mobile communication system, and in particular, it is possible to perform effective traffic channel control of a base station for simultaneous service of voice and data, and to use it for service discrimination of voice and data in a router of the Internet. The present invention relates to a reverse traffic channel allocation method of a mobile communication system.

Recently, the Internet service is rapidly spreading all over the world, and in the future, the Internet is expected to be used for communication of voice, data, video, etc. In order to enable this, a method of differentiating services by each service type is being studied.

However, there are few studies on how to effectively implement simultaneous voice and data services.

The present invention proposes an effective reverse traffic channel allocation method considering voice and data service characteristics for simultaneous voice and data service.

The voice service requires that one reverse traffic channel be allocated at the base station for the duration of the service.

This is to ensure a constant data rate for voice services, which is often the reason for including voice services in the service class of CBR.

In contrast, data transmitted through the Internet is a best effort service unlike a voice service.

Rather than saying that a constant bandwidth is continuously allocated for a service, data allocated on the Internet is determined by the amount of bandwidth that can be allocated for the service.

In view of the characteristics of the voice and data services, the present invention proposes a reverse traffic channel allocation method for effectively implementing a data service simultaneously with a voice service.

SUMMARY OF THE INVENTION The present invention solves this conventional problem, and an object of the present invention is to first allocate one reverse traffic channel as a means for each voice service for simultaneous service of voice and data, The present invention provides a method of equally allocating remaining assignable traffic channels except for traffic channels for each data service.

In addition, the present invention prioritizes a voice service by giving a voice service priority to the voice service when allocating a traffic channel, and simultaneously allocates the voice service so that the data service can be made fairly using the remaining assignable traffic channels. To provide a method.

1 is the present invention

2 is a flowchart in accordance with the present invention.

<Description of Symbols for Major Parts of Drawings>

10: base station 11: signal analysis unit

12: BCP 13: Channel card

14-16: Terminal

In order to achieve the above object, the present invention provides a method for allocating a traffic channel in a CDMA mobile communication, comprising: a first step of determining channel allocation or release, and a voice call or data call if the channel is released in the first step; In case of the voice call, the second step of changing the voice call channel release and data call channel assignment states, and in the case of the data call, changes the data call channel release and data call channel assignment states, and the first channel assignment. A third step of determining whether the call is a voice call or a data call; and in the third step, if the condition 1 is satisfied, the channel is allocated to the voice call. If the condition 2 is satisfied, the voice call channel is allocated and the data call is allocated. The fourth step of changing the channel assignment state and not satisfying condition 2, and losing the voice call, and if the data call is the third step, condition 3 If the group if when allocating a channel to the data call, and satisfies the condition 4, allocating a channel to the data call after the change data call channel allocated state and not satisfy the condition 4, characterized by made of an a fifth step of loss of the data call.

Hereinafter, the present invention will be described in detail with reference to the flowchart of FIG. 2.

FIG. 1 is a block diagram of the present invention, in which a signal analyzer 11, a BCPP 12, and a channel card 13 are provided in a base station 10, and a channel allocation or release signal is received from each terminal 14-16. It is configured to be delivered to the base station 10.

The operation of the present invention configured as described above will be described in detail with reference to FIG. 2, which is a flowchart of the present invention.

First, the number of voice calls and data calls being serviced by the base station at a given time is called N (V) and N (D), respectively, and the number of traffic channels being serviced by being assigned to N (D) data calls is M (i). ), i = 1, 2, ... N (D).

In addition, it is assumed that a voice call is serviced through one traffic channel per call, and a data call requires at least Lmin traffic channels per call for service and can be allocated up to Lmax traffic channels.

And each data call is assumed to be assigned as many traffic channels as possible as long as the traffic channel capacity is allowed.

Therefore, M (i), i = 1, 2, ... N (D) is greater than or equal to Lmin and less than or equal to Lmax.

If only the voice call is serviced, if the maximum number of voice calls that can be serviced simultaneously is C, the traffic channel capacity of the wireless section is increased by about 2 times due to soft handoff. It should be divided into arc and arc.

Assuming that voice calls are evenly distributed in the service area of the base station, it may be assumed that the number of voice calls in soft handoff is always maintained at a constant ratio among all voice calls.

Assuming QoS from this assumption, the maximum number C of voice calls that can be serviced simultaneously can be obtained.

In the same manner as described above, when only a data call is serviced, the number C (D) of maximum traffic channels that can be simultaneously allocated for data service can be obtained.

When the voice call and the data call are simultaneously serviced, call admission control can be achieved using Equation 1 below for some simple increment function f and some constant E (> 0).

f (N (V), M (1) + M (2) + ... + M (N (D))) = E

That is, when a new call is entered, the changed channel assignment state (N (V), M (i), i = 1, 2, ... N (D) satisfies the above expression and can accept a new call) Otherwise, the new call cannot be accepted.

Call admission control formula with assuming that a set of traffic channel assignment states (N (V), M (i), i = 1, 2, ..., N (D) satisfying Equation (1) is F The method for allocating traffic channels to voice calls and data calls will be described in more detail.

The traffic channel assignment status changes when two events occur: First, when a new call is made to request a traffic channel assignment from a corresponding base station or when a voice call or data call from a service area of another base station moves to the corresponding base station. This is a case where a traffic channel allocation is requested for off.

Second, the service is completed in the service area of the base station to which the voice or data call in service is requested to deallocate the allocated traffic channel, or the service area of another base station can be de-assigned for the allocated traffic channel. If you request.

Here, the traffic channel assignment state immediately before the first or second event occurs is N (V) = n (V), M (i) = m (i), i = 1,2 ...., N (D) = n (D).

Only when the voice call requests traffic channel allocation in the first case, (N (V) = n (V) +1, M (i) = m (i), i = 1, 2, ..., n (D) The traffic channel can be additionally allocated to the input voice call without changing the channel assignment state for the existing service data call belonging to this F.

By the way, (N (V) = n (V) + 1, M (i) = m (i), i = 1, 2, ..., n (D) does not belong to F, and (N (V) = n If (V) +1, M (i) = Lmin, i = 1, 2, ..., n (D) belongs to F, to allocate one traffic channel to the input voice call, You need to change the channel assignment status.

At this time, first, the traffic channel of the data call to which the maximum number of traffic channels among the existing data calls are allocated is de-assigned.

In this way, under the changed traffic channel allocation state, N (V) = n (V) = n (V) +1 and the changed data call channel allocation by unassigning the traffic channel of the data call to which the maximum number of traffic channels are allocated again. The base station accepts the new voice call by changing the channel assignment state of the data call until the state satisfies Equation (1).

If (N (V) = n (V) +1, M (i) = m (i), i = 1, 2, ..., n (D) does not belong to F and (N (V) = If n (V) +1, M (i) = Lmin (i), i = 1, 2, ..., n (D) does not belong to F, then the incoming voice call is a traffic channel due to insufficient capacity of the traffic channel. Is not allocated and is lost.

Now, in the first case, when the data call requests the traffic channel allocation to the base station, (N (V) = n (V) +1, M (i) = m (i), i = 1, 2, ..., n (D), if M (n (D) +1) = Lmin) belongs to F, at least Lmin traffic channels can be allocated to the input data call without changing the traffic channel allocation state of the existing data call. .

As long as extra capacity is allowed, up to Lmax traffic channels are allocated to the incoming data call.

By the way, (N (V) = n (V) +1, M (i) = m (i), i = 1, 2, ..., n (D), M (n (D) +1) = Lmin ) Does not belong to F and (N (V) = n (V) +1, M (i) = m (i), i = 1, 2, ..., n (D) +1 belongs to F) In order to newly assign Lmin traffic channels necessary to provide services to the input data call, the channel assignment state of the existing data call must be changed.

At this time, first, one of the existing maximum number of traffic channels among the service call data channel is to deallocate one traffic channel.

When N (V) = n (V) and M (n (D) + 1 = Lmin), under the changed traffic channel allocation state, the maximum number of traffic channels is de-assigned one traffic channel of the allocated data call. The base station accepts the new data call by changing the channel assignment state of the data call until the channel assignment state of the changed data call satisfies equation (1).

In this way, Lmin traffic channels can be allocated to the newly entered data call.

(N (V) = n (V) +1, M (i) = m (i), i = 1, 2, ..., n (D), M (n (D) +1) = Lmin) If the data call does not belong to this F and (N (V) = n (V), M (i) = Lmin, i = 1, 2, ..., n (D + 1) does not belong to F, then the incoming data call is traffic Due to lack of channel capacity, the Lmin traffic channels required for the service cannot be allocated and are lost.

In the second case of changing the traffic channel allocation state, consider a case where an existing in-service voice call requests traffic channel de-allocation.

Deassigning one traffic channel for an existing voice call (N (V) = n (V) -1, M (1) + M (2) + ... + M (N (D) = m (1)) ) + m (2) + ... + m (nD) +1) satisfies Equation (1), the traffic channel is assigned to the data call assigned the number of traffic channels less than Lmax. Can be allocated additionally.

In this case, N (V) = n (V) by first allocating an additional traffic channel to a data call to which the minimum number of traffic channels is allocated again under the minimum number of changed channel allocations among existing data calls. At -1, the channel assignment state of the data call is changed in a range in which the changed channel assignment state of the data call continuously satisfies Equation (1).

In the second case, if the existing in-service data call requests traffic channel de-allocation, if this data call was allocated m traffic channels, deallocating the traffic channel for this data call would increase m free capacity. M additional traffic channels may be allocated to the data call to which the number of traffic channels smaller than Lmax is allocated.

First, an additional traffic channel is allocated for the data call to which the minimum number of traffic channels are allocated, and then one additional traffic channel is allocated to the data call to which the minimum number of traffic channels is allocated again under the changed traffic channel assignment state. In addition, a total of m traffic channels are additionally allocated to the existing data call.

However, if all of the data calls in service are allocated Lmax traffic channels in this additional allocation process, no additional allocation is necessary.

In the present invention, the channel allocation method of FIG. 1 is considered to be implemented in the BCP 12 of the base station 10. For this purpose, a signal for requesting channel allocation or release from the terminal 14-16 is analyzed. The signal analyzer 11 is necessary.

2 is a flowchart of the present invention showing the above-described process, it is determined whether the channel allocation or channel release (S1), in the case of the channel release is determined whether the voice call or data call voice call channel release, The data call channel allocation state is changed, and in the case of a data call, the data call channel release state and the data call channel allocation state are changed (S2-S4). In case of call, if condition 1 is satisfied, channel is assigned to voice call. If condition 2 is satisfied, voice call channel is assigned and data call channel assignment status is changed. If condition 2 is not satisfied, voice call is lost (S5-S10). In case of the data call in step S5, if the condition 3 is satisfied, the channel is allocated to the data call. If the condition 4 is satisfied, the data call channel assignment state is changed. If the channel is assigned to the call and condition 4 is not satisfied, the data call is lost (S11-S15).

As described above, the present invention can effectively control the traffic channel of the base station for the simultaneous service of voice and data in a CDMA mobile communication system, and can also be effectively used for differentiating service between voice and data in a router of the Internet. There is this.

Claims (2)

In the traffic channel allocation method of CDMA mobile communication, A first step of determining channel assignment or channel release, In the first step, in case of channel release, it is determined whether a voice call or a data call is performed. In case of a voice call, the voice call channel release and data call channel allocation state are changed. In the case of a data call, the data call channel release and data call channel allocation are performed. The second step of changing the state, A third step of determining whether a voice call or a data call is allocated when the channel is allocated in the first step; In the third step, in the case of the voice call, if the condition 1 is satisfied, the channel is allocated to the voice call. If the condition 2 is satisfied, the voice call channel is allocated and the data call channel allocation state is changed. If the condition 2 is not satisfied, the voice call is lost. The fourth step, In the third step, in the case of the data call, if the condition 3 is satisfied, the channel is allocated to the data call. If the condition 4 is satisfied, the channel is allocated to the data call after the data call channel allocation state is changed. A method for allocating a reverse traffic channel of a mobile communication system, comprising the fifth step of loss. The method of claim 1, wherein the data service uses the remaining assignable traffic channels while processing the voice service by giving a voice service priority to the voice service when allocating traffic channels.