KR20010028048A - TCE element proportion system for high speed data transmission - Google Patents

Abstract

PURPOSE: A system for allocating TCE(Traffic Channel Element) resources for high-speed data transmissions is provided to allocate available TCEs after searching a general call slot according to a rule, which allocates sub nodes of slots of general call channels requested in IS-95B. CONSTITUTION: An optimum algorithm searches a slot having a usable general call channel, according to an additional call channel request. The algorithm retrieves whether an available TCE(Traffic Channel Element) exists in the searched slot, and allocates required additional call channels. If TCEs corresponding to the required additional call channels are not allocated, the algorithm searches a slot having a maximally-available TCE among other slots, and allocates the TCE. If an additional call channel request is generated, the algorithm searches a slot having general call channels, and retrieves the slot from a '0' sub node, then allocates an available resource as an additional call channel.

Description

TCE element proportion system for high speed data transmission

The present invention relates to a TCE resource allocation scheme for high-speed data transmission, and more particularly, to a TCE for high-speed data transmission for performing a coded channel function to perform a high-speed data transmission function, which is a requirement of IS-95B. It relates to a resource allocation method.

IS-95B (provisional standard for interoperability between digital cellular mobile communication systems using CDMA) defines a general call channel and an additional call channel. Here, the general call channel refers to a general channel commonly used in a call, and the additional call channel refers to an additional channel for transmitting data of 64K bytes.

In addition, a maximum of seven additional code channels are expandable, and in general, an additional code channel is allocated to a slot having a general call channel. If resources are insufficient, TCEs of other slots should be allocated.

The conventional TCE allocation method for the general call is a method of sequentially assigning each slot once, and a method of equalizing resource allocation per slot is applied.

When the additional channel function, which is a required function of the IS-95B, is performed using the conventional TCE allocation scheme, a message must be transmitted for each slot having the additional channel. Therefore, a minimum slot is generally used to increase message transmission efficiency. In principle, it is assumed that an additional code channel is allocated.

However, since the conventional TCE allocation method does not have an algorithm that can accommodate both TCE equal division and the coded channel function, the slot having the coded channel is increased, which is the best principle required by IS-95B. In addition to violating the above, since a message is transmitted for a large number of TCEs, there is a problem in that the message transmission efficiency is lowered and a time and economic loss occurs.

Accordingly, the present invention has been made to solve the above-mentioned conventional problems. The object of the present invention is to find a general call slot according to the principle of allocating a sub node in a slot of a general call channel required by IS-95B. By assigning useful TCEs later, it provides an optimal algorithm that can accommodate both TCE equalization and coded channel functions, and improves message transmission efficiency by reducing the number of slots with coded channels. To provide a TCE resource allocation scheme for.

1 is a control flowchart of a TCE resource allocation method for high speed data transmission according to the present invention.

A feature of the TCE resource allocation scheme for high-speed data transmission according to the present invention for achieving the above object is to find a slot having a general call channel usable according to an additional call channel request, and useful for the slot found above. Search for the presence of the TCE and allocating the required number of coded channels, and when the number of the required TCEs cannot be allocated, find and assign the slot having the maximum useful TCE among the other slots. Giving steps.

In addition, when the additional call channel request is received, the method may further include: finding a slot in which the general call channel is located, searching from sub node 0 to allocate useful resources to the additional call channel.

Hereinafter, a preferred embodiment of a TCE resource allocation scheme for high speed data transmission according to the present invention will be described in detail with reference to the accompanying drawings.

1 is a control flowchart of a TCE resource allocation method for high speed data transmission according to the present invention.

As shown, finding a slot having a general call channel available in accordance with the additional code channel request, searching for whether there is a useful TCE in the slot found above, and assigning the required number of additional code channels; And when the number of TCEs requested above is not allocated, finding and assigning a slot having the maximum useful TCE among other slots.

In addition, when the additional call channel request is received, the method may further include: finding a slot in which the general call channel is located, searching from sub node 0 to allocate useful resources to the additional call channel.

Here, for example, in general call processing, if there are 16 sub nodes in three slots, slot 1 sub node-1 slot 1 of sub node-3 slot 1 of sub node-2 slot 1 of slot 1 Sub-node-2 of slot 2, sub-node 2, slot 2 of sub-node method, and the additional call processing is if the general call is sub-node 4 of slot 3 and the required number of channels is 6, It refers to a method of allocating six useful ones from subnode 1 to subnode 16 to see if there are three useful subnodes. And then again accepts the general call scheme.

In more detail, it is a slot that is increased in general call processing, and the sub node is incremented and the slot is converted to an initial value only in the last slot. If the sub node is last, it is set to the initial value. It is the sub node to increase in the code processing, and the slot is incremented by 1 only when the last sub node is set, and the sub node is initialized. If the slot is last, it is set to the initial value.

Referring to the operation of the present invention in more detail as follows.

First, in a state of maintaining a sector, a slot, and a sub node (sector = a, slot = b, sub node = c), when a request for resource allocation comes, each routine is performed according to the type of call (S101).

First, in case of a resource allocation request of a general call channel, the corresponding traffic channel is found after increasing the index in units of sectors, slots, and subnodes (S102 to S103).

That is, the index is increased by determining "Are the last slot? (B = first_slot; c + = 1, b + = 1)" "Are it the last subnode? (B + = 1, c = first_subnode, b + = 1)" It is the slot that is incremented, and the subnode is incremented and the slot is converted to the initial value only in the last slot. If the sub node is last, it is set to the initial value.

Thereafter, if the traffic channel is not in a call, the traffic channel and frame offset are allocated, and if the traffic channel is in a call, the above process is repeated (S104 to S105).

Next, in case of an additional call channel, slot = x of a general call channel is obtained first. Reconfigure sectors, slots, and subnodes. After that, new sectors, slots, and subnodes are maintained. (Sector = a, slot = x, subnode = c = 0) (S106 to S108)

Accordingly, if the corresponding traffic channel is not in a call, the traffic channel and frame offset are allocated. If the corresponding traffic channel is in a call, the index is increased in units of sectors, sub nodes, and slots to find the corresponding traffic channel (S109 to S111). .

That is, the index is increased by determining "is it the last sub node? (X + = 1, c = first_subnode, c + = 1)" and "is it the last slot? (X = first_slot, c = first_subnode, c + = 1)" Incrementing is a sub node, incrementing the slot by 1 only when the last sub node is made, and making the sub node initial. If the slot is last, it is set to the initial value.

Therefore, the present invention can minimize the traffic loss of the transmission path in time due to the number of slots having a number of additional code that can be generated in the conventional manner, the message transmission as many as the number of slots.

As described above, according to the TCE resource allocation method for high-speed data transmission according to the present invention, a general call slot is useful after finding a general call slot according to the principle of allocating a sub node in a slot of a general call channel required by IS-95B. By allocating TCEs, we provide an optimal algorithm that can accommodate both TCE equalization and coded channel functions, and because the coded channels are not distributed in many slots, it enables a small number of packet communications in message delivery. Therefore, there are various effects to prevent time and economic loss by improving the message transmission efficiency.

Claims (2)

Finding a slot having a common call channel available according to an additional call channel request, Allocating the required number of additional code channels by searching for a useful TCE in the slot found above; and And when the number of TCEs requested above is not allocated, finding and allocating slots having the maximum available TCEs among other slots. 2. The method of claim 1, further comprising: when the additional call channel request arrives, finding a slot with the general call channel, searching from sub node 0, and allocating useful resources to the additional call channel. TCE resource allocation scheme.