JP3518426B2 - Code allocation method in CDMA mobile communication system - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to a code allocation method for radio resource management in a CDMA mobile communication system.

[0002]

2. Description of the Related Art Conventionally, a call in a CDMA mobile communication system has been only low-speed voice communication or a combination of low-speed voice communication and low-speed data communication. Since there is no possibility that one call uses a plurality of codes (multi-code transmission), simple codes such as fixedly distributing codes to two types of codes for voice and data in advance can be used. Wireless resource management is used.

[0003] Next generation CDM such as recent IMT-2000
In the A mobile communication system, a transmission speed of about 8 kbps to 2 Mbps is adopted. Accordingly, variable rate transmission for switching the transmission rate during communication and multicode transmission for allocating a plurality of codes to one call are supported.

A code allocation method in such a next-generation CDMA mobile communication system uses an N-layer orthogonal code C [i, j].
(I = 1 to N, j = 0 to 2 ⁱ -1) layer i and call transmission rate i (i = 1 to
N), and calls from layer 1 to N
And assigns the code C [i, j] of the hierarchy i to the call of the transmission rate i, sets a hierarchy according to the transmission speed when a call occurs, and assigns one or more codes of the hierarchy to the call; Reassign codes of different layers according to the change of transmission speed during communication,
The number of codes to be assigned is changed.

On the other hand, as a code allocation method used in a cellular phone system, Toshihito Kanai, "Autonomous distributed dynamic channel allocation method (ARP) in a microcell mobile communication system", IEICE, RCS91- There are 32 editions, pages 23 to 28 (hereinafter referred to as "ARP system"). This method is based on “selecting a communication channel according to the same priority order in all cells, and selecting an uplink and downlink desired wave-to-interference power ratio (C
IR) is used starting from the one with the threshold value or more. " According to this method, the effect that “the distance between the base station and the mobile station is the same for each channel, and each channel is reused at a minimum distance corresponding to the distance between the base station and the mobile station” is obtained. is there.

[0006]

SUMMARY OF THE INVENTION An object of the present invention is to provide an efficient code allocation method in a next generation CDMA mobile communication system.

[0007]

SUMMARY OF THE INVENTION Accordingly, the present invention provides a code allocation system for a next-generation CDMA mobile communication system which uses ARP.
This is a code assignment method to which the method can be applied.

[0008] In a first embodiment of the code assignment method of the present invention,
According to this, the allocation status of the N-layered orthogonal code is assigned to the allocation table.
The code C [i, j] is changed to “free”, “assigned”
Status (state in which the code itself is assigned) "and" blockade "
Status (because upper layer or lower layer code is assigned
State that cannot be assigned) "
M code allocation requests at layer n due to handover
Is generated, the code C [i, j] of the hierarchy n
J = 0 to 2ⁱSearch in ascending order of -1 and set as "free"
For the searched codes, m requests in ascending order of j are used in the request.
Assignment, the state of the m codes in the assignment table
Change to "assigned state", and branch destination of those m codes
On the allocation table of all codes of the lower hierarchy (i = n + 1 to N)
Is changed to the “blocked state”, and the m
Assignment table for all codes of the upper layer (i = 1 to n-1)
Basic code assignment step to change the state on the file to "blocked state"
And m codes in layer n by call connection and handover
When a code assignment request occurs, the code of layer n
When there are no m codes of the "state", C [i, j] Percent of
The state on this table j = 0 ~ Two ⁱ -1 Search in ascending order of
Function to assign the required number of required codes f ₀ (n, m) Determined by the
The code retrieved as "state" j In ascending order m ' Pieces
(m ' ≤ m) Assigned to the request m ' Division of sign
Change the status on this table to "assigned status"
La m ' Lower-level hierarchy ( i = n + 1 ~ N All)
Change the status on the code assignment table to "blocked status",
Those m ' Hierarchies from which the code is branched ( i = 1 ~ n-1 )
Changed the status of all codes in the assignment table to "blocked status"
Reduce the number of codes in the same layer
Assigning a code number reduction code assigning step.

[0009]

[0010] According to the third embodiment of the code allocation method of the present invention, when m code allocation requests are generated in layer n due to call connection and handover, the code for layer n is “unused”. If there are no m codes, the code number reduction code allocation step is executed in a layer (a lower layer n + 1) one layer lower than the layer n until code allocation succeeds or until the lowest layer N is reached. the upper limit of the allocation request code number in the function f ₂
(n, m, the number of layers from the layer n to the lower layer), and the code number decreasing code allocation step is repeated in the lower layer, and the lower layer code allocation is performed by lowering the layer and changing the number of codes. With stages.

According to the fourth embodiment of the code allocation method of the present invention, when a code release request is generated by call release and handover, the state of the allocation table is changed to “allocated” for the code to be released. From the `` state '' to the `` empty state '', and change all the codes in the lower hierarchy, which is the code branch destination, from the `` blocked state '' to the `` empty state '', and change all the codes in the upper hierarchy, which is the code branch source. From "blocked" to "empty"
To the code release stage.

According to a fifth embodiment of the code allocation method of the present invention, call connection, call release, handover or periodically,
In order to eliminate the situation in which codes in the "assigned state" are present at random, codes are re-assigned so that codes are assigned with priority on the lowest-numbered code (small j) for each layer. For this reason, the “free state” and “assigned state” in the same layer of the allocation table are sequentially assigned from the lowest layer N to the highest layer 1 in order in the allocation table until there is no target code.
, The code in the “allocated state” and j is the maximum is set as the switching source code, the code in the “empty state” and the j is the minimum is set as the switching destination code, and the switching source code is set as the switching destination code. There is a code reassignment step of performing “intra-hierarchical handover” for replacing codes, changing the allocation table of the switching destination code in the basic code allocation step, and changing the allocation table of the switching source code in the code release step.

According to the sixth embodiment of the code allocating method of the present invention, when an "inter-layer handover" from the layer n, the number of codes m to the layer o occurs, the allocation request code in the switching destination layer o The number is recalculated by the function f ₃ (n, m, the layer difference between the layer n and the layer o), the state of the layer o in the allocation table is searched in the order of j = 0 to 2 ⁿ⁻¹ , and The allocation table of the switching destination code is changed in the basic code allocation stage, and the allocation table of the switching source code is changed in the code release stage, so that the code allocation is performed with priority on the code having the smaller number (j is smaller). It has a handover stage.

According to the seventh embodiment of the code allocation method of the present invention, when m codes of layer n are allocated to a call, a "code release handover" request for releasing k codes is generated. In this case, the allocation table of the hierarchy n is j = 2 ⁿ -1 to
In the order of 0, a code in the “assigned state” for the call is one of a plurality of codes used for communication such that k codes are released from the side with the larger j in the code release step. A code release handover step of releasing only the code of the part.

According to the eighth embodiment of the code allocation method of the present invention, when the number of codes in the “free state” of the layer n becomes smaller than S, the code in the “free state” of the layer n In order to secure the number T or more, a layer n ′ higher than the layer n
, The code in the “assigned state” is (T−S) S2 (the number of layers n′−the number of layers n) or more (however,
n ′> n), the number of codes in the “assigned state” of the upper layer is reduced and the number of codes in the “free state” of the lower layer is secured so that “code release handover” is performed according to the code release handover stage. .

According to the ninth embodiment of the code allocation method of the present invention, when the number of codes in the “empty state” of the layer n becomes smaller than S, the code in the “empty state” of the layer n In order to secure the number T or more, a layer n ′ higher than the layer n
The code in the “assigned state” is assigned to the lower hierarchy n ″ (n <
n ″ <n ′) by performing an inter-layer handover that switches communication using an upper-layer code to a lower layer so as to perform “inter-layer handover” in the lower-layer code allocation stage, thereby providing a “free state” of the lower layer. A low-rate free code securing step for securing the number of codes.

According to a tenth embodiment of the code assignment method of the present invention, while a mobile station during soft handover is moving from a source base station to a destination base station, the source base station is assigned to the mobile station. It is checked that the allocated layer n and the number m of codes in the “allocated state” are “vacant” at the destination base station, and the m “vacant state” is stored at layer n in the destination base station. If there are codes, the target base station is added to the soft handover, and they are allocated by the basic code allocation stage as the layer and the number of allocated codes of the target base station after the handover. Has an "empty" sign, but the number m 'is m'<m,
By adding the target base station to the soft handover, the m ′ codes of layer n are allocated as the layer and the number of allocated codes after the handover of the source base station and the target base station by the basic code allocation step, When the destination base station does not have an “empty state” code in layer n, the function _f4 (n, m, n ′) is obtained from layer n ′ in which the source base station and the destination base station have an “empty state” code in common. )) As the code allocation after handover of the source base station and the target base station, and adding the target base station to the soft handover. The method includes a soft handover movement stage for performing code assignment in consideration of handover.

According to the eleventh embodiment of the code assignment method of the present invention, when the mobile station during soft handover is moving from the source base station to the destination base station, the anchor base station is connected to the destination base station. A handover control base station for transmitting and receiving radio control information or a base station with the smallest propagation loss or a base station with the best propagation environment defined as a base station with the best propagation environment, and after a soft handover, the target base station becomes a new anchor base station. In this case, according to the soft handover movement stage, the source base station and the destination base station are assigned a layer after handover and the number of allocated codes, and after the soft handover, the destination base station does not become a new anchor base station, and m When the number of “free” codes m ′> u of the layer n in the target base station is not added to the handover, the target base station is not added to the handover, and after the soft handover, Not a new anchor base station,
m—If the number of “free” codes of layer n in the destination base station is m ′ ≦ u, the destination base station is added to the soft handover, and the source base station moves with the source base station according to the soft handover movement stage. The layer after handover of the destination base station and the number of allocated codes are allocated, and code allocation is performed in consideration of soft handover.

According to another embodiment of the present invention, the up link and the down link can be performed independently.

[0020]

Embodiments of the present invention will be described below in detail with reference to the drawings.

FIG. 1 is an explanatory diagram of an N-layered orthogonal code. The hierarchical orthogonal code generates a lower layer code from a higher layer code. FIG. 1 shows the relationship of codes between layers in a tree structure, taking layers 3 to 7 as an example. For example, two codes of layer 4 can be generated from one code of layer 3, and two codes of layer 5 can be generated from one code of layer 4. In a CDMA mobile communication system, a layer of a hierarchical orthogonal code is used in association with a transmission rate. Accordingly, since the code of the upper layer has a small number of codes, C
Corresponds to a high transmission rate call in DMA. As the number of codes increases in the lower layers, the call is associated with a low transmission rate call.

Table 1 shows an example of the correspondence between hierarchies and transmission speeds.

[0023]

[Table 1]

Referring to FIG. 1, one code of layer 4 is:
It is a branch source of codes of layers 5 to 7 that branch off from the code. Therefore, the code of the layer 4 at the branch source is changed to a transmission speed of 256 k.
Assigning to a call of sps means that a code of a branch destination of lower layers 5 to 7 generated based on the code cannot be assigned to another call. On the other hand, layer 4
Is assigned to the call means that the codes of the upper layers 1 to 3 at the branch source of the code cannot be assigned to other calls.

The hierarchical code having a tree structure requires an allocation table for managing the allocation status of all layers.
However, the present invention is characterized in that each code has a “blocked state” in addition to the “empty state” and the “assigned state”. This table is used when a call is generated / released /
It is updated at the time of handover or the like. When each code is assigned to a call, the state of the code is changed from the empty state to the allocated state, and the branch source code and the branch destination code of the code are changed to the closed state.

"Available" means that the code is not assigned to a call. -"Assigned state" means that the code is assigned to the call and is in use. The “blocked state” means that the code cannot be used because the branch source code (upper layer code) and the branch destination code (lower layer code) of the code are allocated. . Such a state can be applied to any method of configuring a data management table having a tree structure.

FIG. 2 is a flowchart of the above-described first embodiment of the present invention. FIG. 2 shows a basic code allocation stage in a case where m code allocation requests are generated in layer n by call connection or handover.

First, a code in the "empty state" is searched in the hierarchy n, and m codes are assigned to the request in ascending order of the serial number of the code in the "empty state". The state of the m codes in the hierarchy n is changed from the “empty state” to the “assigned state”, and the states of the branch destination code branching from these codes to the lower hierarchy and the branch source code in the upper hierarchy are changed to “ Change from "empty" to "blocked".

FIG. 3 is a flowchart of the above-described second embodiment of the present invention. FIG. 3 shows a code number reduction code allocating step in a case where m codes are requested to be allocated in layer n due to call connection and handover, and there are no m codes in the “free state” among codes in layer n. ing.

In a multicode in which a call uses a plurality of codes, a call connection can be established even if a code smaller than the required number of codes is assigned. Therefore, if the number of “empty state” codes exists, the new allocation request code number m ′ is determined by the function f ₀ (n, m), and m ′ codes are allocated to perform call connection.
As the function f ₀ (n, m), a fixed value can be determined for each layer, or the maximum number of codes searched as “free” can be used.

FIG. 4 is a flowchart of the above-described third embodiment of the present invention. FIG. 4 shows a lower layer code allocation stage in a case where m codes are requested to be allocated in the layer n due to call connection and handover, and there are no m codes in the “empty state” among the codes for the layer n. ing.

FIG. 4 is not a method of reducing the number of codes as shown in FIG. 3, but a method of allocating codes having a lower transmission rate by lowering the number of layers. This is the lower layer code allocation stage.

When m allocations cannot be performed from the hierarchy n,
The layer is lowered to the layer where the “empty state” code exists, and the code allocation in the basic code allocation stage of FIG. 2 is attempted. At this time, the assigned code number m ′ at the point where the hierarchy is lowered is the function f ₂
(n: layer at the time of allocation occurrence, m: initial number of code requests, number of layers lower than layer n). It is also preferable that the function f ₂ is obtained by f ₂ = sm × 2 (the rank lowered from the hierarchy k) −1.

FIG. 5 shows an example of use of the first to third embodiments (FIGS. 2 to 4) when a code assignment request occurs. FIG. 5 shows an example at the time of transmission. The base station that has received the code allocation request performs the code allocation of FIGS. 2 to 4 and returns a response to the mobile station.

FIG. 6 is a flowchart of the above-described fourth embodiment of the present invention. FIG. 6 shows a code release stage when a code release request is generated by call release and handover. In this case, the code releasing step changes the state of the allocation table from the “allocated state” to the “empty state” for the code to be released, and replaces all the codes in the lower hierarchy to which the code branches. The state is changed from “blocked state” to “empty state”, and all the codes in the upper hierarchy from which the code branches are changed from “blocked state” to “empty state”.

FIG. 7 is a flowchart of the above-described fifth embodiment of the present invention. In FIGS. 2 to 4, the serial numbers j of the respective layers are assigned in order of priority from the lowest code. However, with the repetition of call connection / call release / handover, the allocation state according to the priority order from the youngest one is disturbed,
The codes in the “assigned state” in the hierarchy vary. FIG. 6 shows that in order to eliminate such variations,
At the time of call connection / call release / handover or periodically, a code reassignment step is performed.

FIG. 7 is a diagram showing a case where a code in the “assigned state” is randomly present in a call connection, a call release, a handover, or periodically, so that a lower number (j
The code is reassigned so that the code is assigned with priority over the code having the smaller value. This re-allocation is performed for each layer in order from the lowest layer N to the highest layer 1 until there is no target code, and randomization is eliminated.

FIG. 8 illustrates the timing of performing the code reassignment step of FIG.

FIG. 9 is a flowchart of the above-described sixth embodiment of the present invention. The hierarchy and the number of codes assigned at the time of call connection are changed during communication according to the network side or the user's will. For example, the hierarchy and the number of codes assigned at the time of call connection may be reduced at the time of line congestion, and may be restored when there is room in the line. FIG. 9 shows an inter-layer handover stage at the time of the inter-layer handover from the layer n to the layer o, which occurs in such a case.

The number of requested allocation codes of the switching destination layer o is represented by f ₃ (k,
m, the difference between the layer k and the layer o), and j of the layer o is the code of the “empty state” and f ₃ () starting from the youngest code are assigned as switching destination codes. An example of f ₃ () is shown below. f ₃ = m × 2 (floor lower than layer k) -1 f ₃ = Individual instruction from upper application

FIG. 10 is a flowchart of the above-described seventh embodiment of the present invention. The layer and the number of codes assigned at the time of call connection may be reduced during communication depending on the network side or the user's intention. FIG. 10 shows a code release handover stage when a "code release handover" request to release k codes occurs when m codes of layer n are allocated to a call. In this method, a code assigned to a call to be released is searched by searching the allocation table, and the serial number j in the “allocated state” is released preferentially from the code with the succeeding number.

FIG. 11 is a flowchart of the above-described eighth embodiment of the present invention. FIG. 11 shows a case where the number of codes in the “empty state” of the layer n becomes smaller than S. This is because, in order to secure T or more codes in the “empty state” of the layer n, the code in the “assigned state” in the layer n ′ higher than the layer n is (T−S) ÷ 2 ( The number of codes in the “assigned state” of the upper layer is reduced so that the “code release handover” is performed in accordance with the code release handover step by the number of layers n′−the number of layers n) (where n ′> n), The number of codes in the “empty state” of the lower hierarchy is secured.

FIG. 12 is a flowchart of the ninth embodiment of the present invention. FIG. 12 shows a low-rate free code securing stage when the number of codes in the “free state” of the layer n is smaller than S. In the low-rate free code securing step, the number of codes in the “free state” of the layer n is calculated.
In order to secure T or more, the code in the “assigned state” in the higher hierarchy n ′ than the hierarchy n is replaced with the lower hierarchy n ″ (n <
n ″ <n ′) by performing an inter-layer handover that switches communication using an upper-layer code to a lower layer so as to perform “inter-layer handover” in the lower-layer code allocation stage, thereby providing a “free state” of the lower layer. Secure the number of codes.

FIG. 13 is a flowchart of the above-described tenth embodiment of the present invention. Soft handover is
One mobile station sets a communication line simultaneously with a plurality of base stations. Therefore, in code allocation at the time of soft handover (such as when a new base station participates in soft handover, etc.), it is necessary to allocate a code that is "in an idle state" in common among a plurality of base stations. FIG. 13 illustrates code assignment after handover.

When the soft handover addition request is generated from the mobile station or the base station (FIG. 13 shows the case where the request is generated from the mobile station, the same applies to the case where the request is generated from the base station). Obtains the allocation table for each layer of the destination base station and compares it with its own allocation table. (Case 1) The source base station is in the “allocated state” with the layer n already allocated to the mobile station. If a certain number m of codes are in the “vacant state” in the destination base station, they are used as the hierarchy and the number of codes of the source base station and the destination base station after the handover.
Assign according to the basic code assignment stage. (Case 2) When there is an “empty state” code in layer n at the destination base station and the number m ′ is m ′ <m, m ′ in layer n
These codes are assigned according to the basic code assignment stage as the hierarchy and the number of codes of the source base station and the destination base station after the handover. (Case 3) When there is no “empty state” code in the layer n at the destination base station, the function f ₄ (from the layer n ′ having the “empty state” code in the source base station and the destination base station in common n, m,
The number of “empty state” codes determined by n ′) is allocated as the number of layers and the number of codes after the handover of the source base station and the destination base station according to the basic code allocation stage. Hierarchy n '
May be a layer higher than n or a layer lower than n. The function f ₄ (n, m, n ′) can also be as follows. If n> n ': f ₄ = m × 2 (floor lowered from hierarchy k) -1 If n <n': f ₄ = m × 2- (floor lowered from hierarchy k) -1

FIG. 13 shows an embodiment in which the above-described determination processing is performed in the source base station, but this embodiment is not limited to this range. In CDMA mobile communication, code allocation processing at the time of soft handover is performed in a source base station or in a base station management station provided independently of a source base station and a destination base station. It is implemented in the form of FIG. 13 shows the embodiment of the source base station. However, in the embodiment of the base station management station, only the station performing the allocation process moves to the base station management station. Applied as is.

FIG. 14 is a flowchart of the eleventh embodiment of the present invention. In this embodiment, the source base station and the destination base station are divided into an anchor base station and a non-anchor base station, and the anchor base station is referred to as a `` handover control base station in which the destination base station transmits and receives radio control information or ,
A base station with the smallest propagation loss or a base station with the best propagation environment "is defined. In the present embodiment, when the authority of the anchor base station is transferred from the source base station to the destination base station, codes are allocated after the handover. The mobile station during soft handover is moving from the source base station (anchor base station) to the destination base station, and (Case 1) the mobile station moves when the destination base station becomes the anchor base station after soft handover. By adding the destination base station to the soft handover, the layer and the number of codes after the handover are allocated according to the tenth embodiment of the present invention and * 1 in FIG. (Case 2) After the soft handover, if the target base station does not become the anchor base station but the number m−the number of “free” codes m ′> u of the hierarchy n in the target base station, the target base station Is not added to the handover. (Case 3) After the soft handover, if the target base station does not become the anchor base station and the number m−the number of “free” codes m ≦ u of layer n in the target base station, the target base station is As an addition to the handover, 10
According to this embodiment and * 1 in FIG. 13, the layer and the number of codes after the handover are allocated.

Similarly to the tenth embodiment of the present invention, the eleventh embodiment of the present invention is not limited to the mode in which the station performing the allocation process is performed in the source base station, but is performed in the base station management station. Also applies.

In all of the above-described embodiments of the present invention, the up link and the down link can be performed independently.

In the above-described embodiment of the code allocation method in the CDMA mobile communication system of the present invention, various changes, modifications and omissions of the technical idea and scope of the present invention can be easily performed by those skilled in the art. it can. The above description is merely an example and is not intended to be limiting.
The invention is limited only as defined by the following claims and equivalents thereof.

[0051]

As described above in detail, according to the present invention, in a code allocating method in a CDMA mobile communication system, a multi-code communication in which a plurality of codes are allocated and a variable code for changing a transmission rate during the communication. Code allocation and code release corresponding to code communication can be performed.

Further, even if the required hierarchy and the number of codes cannot be secured, code allocation such as reducing the number of codes, lowering the hierarchy, or increasing the number of codes by lowering the hierarchy can be performed.

Furthermore, by performing call connection / call release / handover / periodic code reassignment, it is possible to eliminate variations in code assignment and improve code assignment efficiency.

Further, codes can be assigned at the time of handover between layers.

Further, it is possible to perform a code release procedure at the time of code release handover during multicode communication.

Further, when the number of low transmission rate codes in the “empty state” becomes small, code release handover or inter-layer handover of high transmission rate codes is performed.
An "empty" code for low transmission rates can be reserved.

Further, when a soft handover addition request is generated, it is possible to allocate the added layer and the number of codes.

[Brief description of the drawings]

FIG. 1 is a tree structure diagram illustrating a hierarchical orthogonal code.

FIG. 2 is a flowchart according to a first embodiment of the present invention.

FIG. 3 is a flowchart according to a second embodiment of the present invention.

FIG. 4 is a flowchart according to a third embodiment of the present invention.

FIG. 5 is an explanatory diagram of a usage example of the embodiment of FIGS. 2 to 4;

FIG. 6 is a flowchart according to a fourth embodiment of the present invention.

FIG. 7 is a flowchart according to a fifth embodiment of the present invention.

FIG. 8 is an explanatory diagram of timing for performing the code reassignment step of FIG. 7;

FIG. 9 is a flowchart according to a sixth embodiment of the present invention.

FIG. 10 is a flowchart according to a seventh embodiment of the present invention.

FIG. 11 is a flowchart according to an eighth embodiment of the present invention.

FIG. 12 is a flowchart according to a ninth embodiment of the present invention.

FIG. 13 is a flowchart according to a tenth embodiment of the present invention.

FIG. 14 is a flowchart according to an eleventh embodiment of the present invention.

Continuation of the front page (56) References JP-A-11-266480 (JP, A) (58) Fields investigated (Int. Cl. ⁷ , DB name) H04B 7/24-7/26 H04Q 7/00-7 / 38

Claims (11)

(57) [Claims] 1. An N-layered orthogonal code C [i, j] (i = 1 to N, j = 0
22 ⁱ -1) is associated with the call transmission rate i (i = 1 to N), and calls 1 to N are assigned in order from the call having the highest transmission rate, and the code C [i, j] is assigned to a call having a transmission rate i, a layer is set according to the transmission rate when a call occurs, one or more codes of the layer are assigned to the call, and different layers are assigned according to a change in the transmission rate during communication. A code allocation method in a CDMA mobile communication system for performing communication using a CDMA method between a mobile station and a base station, in which the number of codes to be allocated is changed and the number of codes to be allocated is changed. The code C [i, j] is managed by using “empty state”, “allocated state (state in which the code itself is allocated)” and “blocked state (upper layer or lower layer code is allocated). Cannot be assigned because of the When the m code assignment request occurs in a hierarchical n by Ndooba searches codes C [i, j] of the hierarchy n the state on allocation table in ascending order of j = 0 to 2 ⁱ -1, "empty The codes retrieved as "states" are assigned m requests in ascending order of j to the request, the state of the m codes in the allocation table is changed to "assigned state", and the branching of the m codes is performed. The state in the allocation table of all codes of the lower hierarchy (i = n + 1 to N) is changed to “blocked state”, and the upper hierarchy (i = 1 to n) from which the m codes are branched is changed. -1) Basic code allocation stage for changing the state of all codes in the allocation table to "blocked state"
And m code divisions in layer n by call connection and handover
When this request is generated, the code of the layer n
When there are no m codes , the allocation table of the code C [i, j] of layer n
In the order of j = 0 to 2 ⁱ -1 in ascending order
The number of required codes is determined by the function f ₀ (n, m) , and “free”
Retrieved codes, m 'number (m' from ascending order of j as ≦ m)
Is assigned to the request, and an assignment table of those m ′ codes is assigned.
Changes the state of the on Le to "assigned state", they m 'number of
The division of all codes in the lower hierarchy ( i = n + 1 to N ) to which the code branches
Change the state on this table to "blockade state", they m '
All codes of the upper layer ( i = 1 to n-1 ) from which the codes are branched
To change the status on the allocation table to "blocked"
In the same hierarchy,
A code assignment method comprising the steps of : 2. Layer n by call connection and handover
When m code allocation requests are generated, and if there are no m codes in the “empty state” in the codes for the layer n, the code number reduction code allocation step is performed when the code allocation succeeds or the lowest. Until the layer N is reached, the process is performed in a layer (a lower layer n + 1) one lower than the layer n, and the upper limit of the number of allocation request codes in the lower layer is calculated by a function f
₂ (n, m, the number of layers from layer n to the lower layer), and repeats the code number reduction code allocation step in the lower layer to lower the layer and change the number of codes to perform code allocation. 2. The method according to claim 1 , further comprising the step of assigning a hierarchical code. 3. When a code release request is generated by call release and handover, the status of the allocation table is changed from “allocated status” to “empty status” for the code to be released, and Code release that changes all codes in the lower layer that is the branch destination from “blocked state” to “empty state” and changes all codes in the upper layer that is the branch source of the code from “blocked state” to “empty state” code allocation method according to claim 1 or 2 characterized by having a step. 4. In order to eliminate a situation in which a code in the “assigned state” is randomly present in a call connection, a call release, a handover, or periodically, a lower number (j is smaller) for each layer. In order to perform code reassignment so that codes are assigned with priority over codes, the same layer in the allocation table is sequentially assigned to each layer in order from the lowest layer N to the highest layer 1 until there is no target code. The code in the “empty state” and the “assigned state” is searched for, the code in the “assigned state” and j is the maximum is set as the switching source code, and the code in the “empty state” and j is the minimum As a switching destination code, performing "intra-hierarchy handover" of replacing the switching source code with the switching destination code, changing the allocation table of the switching destination code by the basic code allocating step, and changing the allocation table of the switching source code to the code Depending on the release phase Code allocation method according to claim 3, characterized in that it comprises a code re-allocation step of changing Te. 5. When an “inter-layer handover” from a layer n and a code number m to a layer o occurs, the number of allocation request codes in the switching destination layer o is calculated by a function f ₃ (n,
m, the hierarchy difference between the hierarchy n and the hierarchy o), and the state of the hierarchy o in the assignment table is searched in the order of j = 0 to 2 ^n−1. An inter-layer handover step of changing the allocation table of the switching destination code by the basic code allocation step and changing the allocation table of the switching source code by the code release step so that code allocation is performed preferentially. The code assignment method according to claim 3, wherein: 6. When a code release handover request for releasing k codes occurs when m codes of layer n are allocated to a call, the allocation table of layer n is set to j = 2 ⁿ Searching in the order of -1 to 0, a plurality of codes used for communication, such that the code in the "assigned state" for the call is released by the code release step from the side where j is larger than k. The code allocation method according to any one of claims 3 to 5 , further comprising a code release handover step of releasing only some of the codes. 7. The number of codes in the “empty state” of the layer n is S
If the number is less than T, in order to secure T or more codes in the “empty state” of the layer n, the codes in the “assigned state” in the layer n ′ higher than the layer n are replaced by (T-S ) ÷ 2 (number of layers n′−number of layers n) or more (however,
n ′> n), the number of codes in the “allocated state” of the upper layer is reduced and the number of codes in the “free state” of the lower layer is secured so that “code release handover” is performed according to the code release handover step. The code assignment method according to claim 6 , wherein 8. The code number in the “empty state” of the layer n is S
When the number is less than the number of codes in the “empty state” of the layer n, the codes in the “assigned state” in the higher layer n ′ than the layer n '
'(N <n''<n') by performing an inter-layer handover that switches communication using an upper-layer code to a lower layer such that “inter-layer handover” is performed by the lower-layer code allocation step. The code allocation method according to any one of claims 2 to 7 , further comprising a low-rate free code securing step for securing the number of "free" codes in the hierarchy. 9. A code indicating that a mobile base station in soft handover is in the “assigned state” with a layer n allocated to the mobile station while the mobile base station is moving from the source base station to the destination base station. Check that a few m are “vacant” at the destination base station, and if there are m “vacant” codes in layer n at the destination base station, move the destination base station to soft handover. In addition, they are allocated by the above-mentioned basic code allocating step as the layer and the number of allocated codes of the target base station after the handover. When 'is m'<m, the destination base station is added to the soft handover, and the m ′ codes of the layer n are assigned to the source base station and the destination base station after the handover. The basic code assignment stage as a number By the allocation, if in the destination base station "idle" code is not in the hierarchy n, "idle" in common with the target base station and the source base station
From the layer n ′ having a code, the number of `` free state '' codes determined by the function f ₄ (n, m, n ′) as the code allocation after the handover of the source base station and the destination base station, the destination base station 2. The method according to claim 1, further comprising a soft handover moving step of performing code assignment in consideration of soft handover by assigning the code in the basic code assignment step as an addition to soft handover.
9. The code assignment method according to any one of items 1 to 8 , above. 10. A mobile station during soft handover, while moving from a source base station to a destination base station, an anchor base station, a handover control base station through which the destination base station transmits and receives radio control information, Is defined as the smallest base station or the base station with the best propagation environment, and after the soft handover, if the destination base station becomes a new anchor base station, the source base After the handover of the station and the destination base station, the layer and the number of allocated codes are allocated. If the number of codes m ′> u, the target base station is not added to the handover, and after the soft handover, the target base station does not become a new anchor base station, and When the number of “empty state” codes m ′ ≦ u in layer n at the base station, the destination base station is added to the soft handover, and the source base station and the destination base station are added according to the soft handover moving step. The code allocation method according to claim 9 , wherein code allocation is performed in consideration of soft handover so as to allocate the layer after the handover and the number of allocated codes. 11. any one of claims 1, wherein the performing the upstream line and downstream line independently 10 1
The code assignment method according to the item.