KR100434291B1 - Method for operating searcher in communication system - Google Patents

Abstract

The present invention relates to a searcher operating method, and more particularly, to a searcher operating method in a communication system capable of supporting a plurality of channels with a plurality of searchers in an IS-2000 base station system. The searcher operating method in the communication system of the present invention provides priority to the channel search mode in a communication system having a plurality of channel search modes, and assigns an independent search queue to each channel search mode to search the channel. The searcher is allocated from the channels in the search queue of the high priority search mode.

Description

Method for operating searcher in communication system

The present invention relates to a searcher operating method, and more particularly, to a searcher operating method in a communication system capable of supporting a plurality of channels with a plurality of searchers in an IS-2000 base station system.

In general, a code-division multiple access (CDMA) wireless communication system includes a mobile station (MS) and a base station. The mobile communication signal modulated and transmitted from the mobile station is received by the base station, demodulated by the base station, and restored to the original signal. In this case, the mobile communication signal includes a pilot signal for time synchronization and power control. The pilot signal is a signal transmitted to the base station by spreading with a unique PN code for each terminal user. The base station can demodulate the received signal by finding the respective time delays, ie, PN offsets, of the multipath components of the pilot signal to search for the pilot signal. In order to find the PN offset, all the offsets of the received signal may be despread using the PN signal, the energy of the despread signal is calculated, an average value is calculated, and a specific threshold value among the plurality of energy values is obtained. Select the PN offset of the multipath signal with greater energy value. The device that performs this operation is called a "searcher."

In general, each dependent searcher exists for M channels.

However, the conventional technology has a structure in which each dependent searcher exists unconditionally for M channels, and thus the searcher cannot be shared with other channels, so there is a problem that the operation of the searcher is inefficient.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems of the prior art. Among the communication systems, a searcher operating method of a communication system capable of supporting a plurality of channels more than the number of searchers with a plurality of searchers in an IS-2000 base station system. It is to provide.

One example of the searcher operating method of the present invention communication system is to give priority to the channel search mode in a communication system having a plurality of channel search modes, and to assign an independent search queue to each channel search mode. The searcher is allocated from the channels in the discovery queue of the discovery mode having the highest priority among the channel discovery modes.

Preferably, when allocating the searcher, a search queue is operated in a manner in which the search order is determined by the channel order included in the search queue for channels in the search queue having the same priority.

If the channels have the same priority, searchers are allocated in the order of the channel after the search is over.

Preferably, a plurality of searchers are configured in the communication system to perform the channel search according to the priority of the plurality of channel search modes, and when the channel search ends, the search mode or the control unit is controlled by the central processing unit of the communication system. Perform a search for a new channel in the search queue.

Preferably, the communication system includes a system timer aligned with the communication system reference time to inform current time information, an interrupt controller for generating an interrupt in the central processing unit and controlling the interrupt so that the interrupt is cleared by the central processing unit; According to the control of the central processing unit, all the offsets of the received signal received by the communication system may be despread using the PN signal, the energy of the despread signal is calculated, an average value is calculated, and then a plurality of A plurality of searchers for selecting the PN offset of the multipath signal having an energy value greater than a specific threshold value of the energy value of the to perform a search for the channel.

Another example of a method of operating a searcher in the communication system as described above is to set the number of channels of the highest priority channel search queue to the remaining channel number, and if any searcher index is smaller than the total searcher index, the channel to be searched by the searcher is null ( null) to determine if the full window search is completed in the navigator if it is not null, and to determine if there is a remaining highest priority channel if the search for the entire window is complete and to determine the next priority. Determining whether there is a channel to be searched in the channel search queue having a channel; and if there is no channel to search in the channel search queue having the next priority, determining whether there is a channel to search in the channel search queue having the next priority. If the channel search queue with the next priority has a channel to search for, the current search channel is Searching.

Preferably, the highest priority channel discovery queue is a queue assigned to an enhanced access preamble discovery mode, the second priority channel discovery queue is a queue assigned to a traffic preamble discovery mode, and the third priority channel discovery queue is a traffic. Queue assigned to multipath search mode.

And if the searcher has not searched for the channel to be searched, issuing a search command for the next sector or the next window of the search channel and increasing the index of the searcher.

Another example of a searcher operating method in the communication system of the present invention as described above is a first step of initializing an index of an arbitrary searcher, a partial search start and a partial search end, and wherein the arbitrary searcher index is smaller than the index of all searchers. And if the search is completed, determining whether the search is completed, and if the search is completed, setting a channel allocated to the search as the current search channel; and determining whether the current search window and the sector are initialized. A third step of increasing the current search window by a rake width; a fourth step of determining whether the current search sector index is larger than the number of search sectors if the current search window is smaller than the sector window; and determining a current search mode. Then puts the current search channel into the current search mode queue and sets the search channel of the explorer to null. Claim 5 comprises a step of.

Preferably, copying or updating a search result in a search channel buffer according to whether the partial search is started between the third and fourth steps, and after the search mode is determined, whether the partial search is last in each search mode. Determining and setting the search channel to null after sending the current discovery channel to the end of the current discovery mode queue if it is the last partial discovery, and otherwise sending the current discovery channel to the front of the current discovery mode queue.

The method may further include starting a partial search when the current search window and the sector are initialized in the third step, and setting the current search window to 0 when the current search window is larger than the sector window in the fourth step. And further increasing the current search sector index by one, and if the current search sector index is greater than or equal to the number of search sectors in the fourth step, setting the current search sector index to zero and starting a partial search. do.

1 is a block diagram of a searcher and a searcher peripheral block of a base station system for explaining a searcher operating method according to the present invention;

2A and 2B are flowcharts for describing a search resource management subroutine in the searcher operating method according to the present invention.

3A and 3B are flowcharts illustrating a search completed subroutine in the searcher operating method according to the present invention.

* Description of the symbols for the main parts of the drawings *

10: interrupt control 20: system timer

30: searcher 40: central processing unit

Hereinafter, a searcher operating method according to the present invention will be described with reference to the accompanying drawings.

1 is a block diagram of a searcher and a searcher peripheral block of a base station system for explaining a searcher operating method according to the present invention.

According to an embodiment of the present invention, a searcher and a block around the searcher are arranged in a system reference time to generate an interrupt in a system timer 20 and a central processor 40 serving as a processor. And an interrupt control unit 10 for controlling the interrupt so that the interrupt is cleared by the central processing unit 40, and all offsets that the received signal received by the base station under the control of the central processing unit 40 may have. A searcher that executes despreading using the signal, calculates an average value by calculating energy of the despread signal, and then selects a PN offset of a multipath signal having an energy value larger than a specific threshold value among a plurality of energy values ( and a plurality of search units 30a, 30b ... 30n: 30 provided with a searcher.

At this time, the interrupt in the present invention performs a time tick interrupt. After performing a search done subroutine in this time tick interrupt, a search resource management subroutine is performed.

Although not shown, each search unit 30 has a search parameter buffer and a search result buffer, and a search start command includes a reference time of the search unit 30. The processing delay of the search unit is separated from the searcher reference time.

When any i-th searcher is occupied by a time slot to perform an offset-wise hyperthesis test for one search command, N searchers 30 and each search portion 30 has been assigned by each rake width: between (rake width R _X), holds the R ₁ + R ₂ + ‥‥ relationship R _N ≤R.

That is, within the total rake width (R), the number of search units 30 and the rake width of each search unit 30a, 30b ... 30n: 30 may dynamically change to occupy time slots. In the present invention, a fixed number of search units 30 and a rake width of each search unit 30 are fixed to use the method of operating the search unit 30.

The search unit for the IS-2000's channel operates in three modes.

Enhanced access channel preamble search mode (hereinafter abbreviated as EACH), traffic preamble search mode (hereinafter abbreviated as PAM), traffic multipath search mode (traffic multipath) search) (hereinafter abbreviated as MUL).

Each mode has a priority. The UE starts access only at slot boundaries, and a slot offset is determined according to a start time of an access probe, which is reflected in a long code mask. . Slot offset is obtained by modulo operation divided by the symbol time in PCG divided by the slot duration in PCG, and thus the slot duration. ) Can have up to 512 different values.

In addition, the slot boundary of EACH has a unique offset for each channel within the slot duration.

One slot includes a preamble section and a message capsule section in a frame unit in a basic access mode.

The EACH preamble search is performed in the preamble section of the slot. The preamble section is further configured as an additional preamble section after the preamble on section and the off section are repeated several times in sequence. .

The EACH preamble search is a search with the highest priority, so that the search is performed only in the preamble on section in order to efficiently operate the search unit. The next priority is traffic preamble search (PAM), and traffic multipath search (MUL) has the lowest priority.

In the present invention, the method of operating a search unit (hereinafter referred to as a searcher) assigns searchers in order of higher priority by giving priority to each channel to be searched, and if the priority is the same, the search order is the oldest channel order. Is to allocate an explorer.

In order to enable priority search, each search mode has an independent search queue and assigns it to the searcher from the items in the high priority queue. The search item operates the search queue in such a manner that the search order is determined by the order in which the queue is contained.

Items common to all channels in the search information list required for each M channel are as follows.

ChannelType: Shows whether it is an enhanced access channel or traffic channel.

Search Mode (SrchMode): Indicates whether it is EACH, PAM, or MUL.

NumSrchSector: The number of sectors on which the search should be performed.

Search Sector List (SrchSectorList): Search sector list (search source (SearchSectorIdx and antenna)) as many sectors as search should be performed (search source index (Idx) and antenna to be searched), and search start Provides information about offset and search window size (SearchStartOffset, SearchWindowSize).

Current Sector Sector Index (CurrSrchSectorIdx): Tells which sector to search in the Sector Sector List to search.

Finally, the current search window (CurrSrchWin): indicates the number of partial searches when searching by the search rake for a search to search by the search window size (SearchWindowSize).

The following is a list of discovery information required for an enhanced access channel.

EACHPamOnLen: EACH preamble-on length (in PCG).

EACHPamOffLen: EACH preamble-off length (in PCG).

EACHPamFracNum: Tells you how many times the EACH preamble is on or off.

EACHSlotSize: EACH slot size.

EACHSlotBoundaryOffset: The offset that the slot boundary of the EACH preamble has within the slot duration.

EACHSlotOffset: Slot offset number.

Finally, EACHLastSrchDoneTime: tells you when EACH last whole search was made.

And since IS-2000 base station uses reverse pilot for multipath search, it affects the way of coherent searcher among parameters related to traffic channel. There is nothing to give.

The searcher operation method proposed in the present invention can be largely divided into seven subroutines.

The first is a subroutine in channel setup.

The second is the search subroutine on channel release.

The third is the search subroutine when changing the search mode of the channel.

The fourth is a subroutine when setting softer handoff mode.

Fifth is the subroutine on softer handoff mode release.

Sixth is a search resource management subroutine.

Finally, the seventh is a search done subroutine.

First, the search subroutine when setting an arbitrary i-th channel is as follows.

First of all, in the first step,

Whether the enhanced access channel or the traffic channel is specified is specified in the channel type (ChannelType) of the discovery information list of any i-th channel.

The discovery mode (SrchMode) is set to EACH when setting an access channel and PAM when setting a traffic channel.

If the channel type is EACH, EACHPamOnLen, EACHPamOffLen, EACHPamFracNum, EACHSlotSize, EACHSlotBoundaryOffset, and EACHSlotOffset are set to the values assigned to each EACH, and EACHLastSrchDoneTime is initialized to zero.

In the second step, a search parameter such as a search source, a search start offset, and a search window size corresponding to an i-th channel is selected from the i-th channel. Is set in the first search sector list (SrchSectorList) from the search information list. The number of search sectors NumSearchSetcor is set to one.

In the third step, any i-th channel is registered as a search item in a search queue according to a search mode SrchMode.

The search subroutine on the second random i-th channel release is as follows.

First, the first step removes any i-th channel search item from a search queue according to the search mode SrchMode of any i-th channel.

In the next second step, the search sector list SrchSectorList of any i-th channel is flushed, and the number of search sectors NumSrchSector is zero.

When changing the search mode of the third arbitrary i-th channel, the subroutine is as follows.

In the case of a traffic channel, when switching from preamble search to multipath search, the search mode SrchMode is set to MUL from the search information list of any i-th channel.

In setting the soft handoff mode of the fourth arbitrary i-th channel, the subroutine is as follows.

Search Source, Search Window Size, and Search Start Offset information are searched for the sectors added from the search information list of any i-th Num. Add to SearchSectorList. The number of search sectors (NumSearchSector) is increased by one.

The subroutine upon release of softer handoff mode of the fifth arbitrary i-th channel is as follows.

The number of search sectors NumSrchSector is reduced by one from the search information list of any i-th channel. The search source (SearchSource), the search start offset (SearchStartOffset), and the search window size (SearchWindowSize) related to the removed sector are removed from the search sector list SrchSectorList.

Sixth, the discovery resource management subroutine will be described with reference to FIGS. 2A and 2B. Seventh, the discovery completion subroutine will be described with reference to FIGS. 3A and 3B.

2A and 2B are flowcharts illustrating a search resource management subroutine in the searcher operating method according to the present invention.

Set the number of items in EACH-Q to the remaining EACH count (remainEACHCnt), and set a pointer to EACH-Q as a link type to pEACHLink. The variable sIdx is initialized to 0 (S11).

Then, it is determined whether the variable sIdx is greater than or equal to the number N of sectors (S12) (S12), and returns when it is greater than or equal to.

However, when the determination result S12 variable sIdx is smaller than the number N of sectors, it is determined whether the search item of the searcher is null (S13). In this case, the search item of the searcher is either a full search for the channel or null after being searched at the preamble on of the EACH search.

If the result of the determination (S13) is null, the variable sIdx is increased by one, and the flow goes to step S12 (S16).

However, if the result of the determination (S13) is not null, it is determined whether the whole search of the entire window is completed in the sIdx-th searcher (S14).

As a result of determination (S14), if the complete search for the channel has not been performed, sIdx is increased by 1 and the flow proceeds to step S12.

However, if the determination result (S14) is a complete search, it is determined whether the remaining EACH count (remainEACHCnt) is greater than zero (S16).

If the determination result (S17) is large, the first item in EACH-Q, that is, the next item of pEACHLink is set as the current search item (CurrSrchItem) (S17).

Then, the remaining EACH count (remainEACHCnt) is reduced by one (S18).

Subsequently, it is determined whether the current time is the time to search EACH (S19). Here, the time to search for EACH is determined to be a time to issue a search command when EACH is preamble on while the EACH search is performed and the enhanced access channel last search completion time (EACHLastSrchDoneTime) is before the start time of the current slot.

Judgment result (S19) If it is not time to search for EACH, obtain the next item of pEACHLink and set as pEACHLink and go to step S16 (S20).

However, if the current time is the time to search EACH (S19), the current search item (CurrSrchItem) included as the first item (item) of EACH-Q is removed, and the item count of EACH-Q is reduced by one. Let's do it. At this time, the pointer of EACH-Q automatically points to the next item of the queue (S21).

Subsequently, an execution command is given to the sIdx-th explorer to search the current search item CurSrchItem, and the state of the explorer is made to be running (S22). Search start offset (SearchStartOffset) and search window size (SearchWindowSize) for the sector of the current sector index (CurrSectorIdx) of the search sector list (SrchSectorList) stored in the current search item (CurrSrchItem) among the search sector list stored by the current search item. Information about) applies.

Next, obtain the next item of pEACHLink, set it as pEACHLink (S23), and go to step S16.

However, the determination result (S16) it is determined whether the number of items (item) in the traffic preamble search queue (hereinafter PAM-Q) is greater than zero (S24).

If the determination result (S24) is large, the first item of the PAM-Q is separated and set as the current search item (CurrSrchItem), and the number of items of the PAM-Q is reduced by one (S25).

Subsequently, a command is issued to the explorer to search the current search item CurSrchItem, and the state of the explorer that issued the command is made to be running (S26).

However, if it is not greater than zero (S24), it is determined whether the number of items in the traffic multipath search queue (hereinafter, MUL-Q) is greater than zero (S27).

As a result of the determination (S27), if it is greater than 0, the method returns. If not, the first item of MUL-Q is separated and set as the current search item (CurrSrchItem), and the number of items of MUL-Q is reduced by one (S28).

Subsequently, an execution command is given to a searcher to search the current search item CurSSItem, and the state of the searcher is made to be running (S29), and the flow proceeds to step S16.

3A and 3B are flowcharts illustrating a search done subroutine in the searcher operating method according to the present invention.

The search completion subroutine first initializes the variable sIdx to 0 (S40). At this time, bStartPartialsearch and bLastPartialSearch are initialized to FALSE, respectively.

Next, it is determined whether the variable sidx is smaller than the number N of searchers, and returns if it is not small (S41).

However, if the determination result (S41) is small, it is determined whether the searcher is search done (S42), and if it is not search done, sIdx is increased by one (S43).

However, if it is determined that the search is completed (S42), the item assigned to the sIdx-th searcher is set as the current search item (CurrSrchItem), the number of search sectors (NumSrchSector), the current search window (CurrSrchWin), and the search in the search sector list. Information about a sector (CurrSrchSectorIdx) of one of sectors to be set is set as the current search item (CurrSrchItem) (S44).

Subsequently, it is determined whether CurSSrchSectorIdx is 0 and CurrSrchWin is 0 in the search information list of the current search item CurSrchItem (S45).

As a result of determination (S45), if CurrSrchSectorIdx is 0 and CurrSrchWin is 0, the partial search start (bStartPartialSearch) is set to TRUE (S46), and the current search window (CurrSrchWin) is increased by the rake width (RAKE-Width). S47) ..

However, if it is not the determination result (S45), the current search window (CurrSrchWin) is increased by the rake width (RAKE-Width) (S47).

Next, it is determined whether the current search window CurSrchWin is equal to or larger than the search window size SearchSearchSize for a sector of the current search sector index CurrSrchSectorIdx of the search sector list SrchSectorList (S48).

If the determination result (S48) is greater than or equal to, the current search window (CurrSrchWin) is set to 0, and the current search sector index (CurrSrchSectorIdx) is increased by one (S49).

However, if the determination result (S48) is not greater or equal, the current search sector index (CurrSrchSectorIdx) is compared with the number of search sectors (NumSrchSector) to determine whether it is larger or equal (S50). Set and start the partial search (bLastPartialSearch) (TRUE) (S51).

However, if the determination result (S48) is not greater than or equal to (S48), it is determined whether the partial search (bStartPartialSearch_ start is started (S52). If the partial search is started, the search result is copied to the buffer of the current search item (S53). The search result is updated (S54).

Next, the search mode is determined (S55).

If it is determined in S55 that the search mode SrchMode is MUL or PAM, it is determined whether the partial search is the last (S56). If the determination is the last (S56), the current search item is put at the end of the current search mode queue (S57). The search item of the searcher is null (S58).

However, if the determination result (S55) is EACH, it is determined whether or not it is the last search (S59), and if it is the last time, the current search item (CurrSrchItem) is put at the end of the current search mode queue (S60), and the search item of the searcher is added. Set to null (S62).

However, if the determination result (S59) is not the last, the current search item is put in front of the current search mode queue (S61), and the search item of the searcher is set to null (S62).

As described above, the present invention can share N searchers in M channels in time division during search operation in an IS-2000 base station system, and makes searchers more efficient by prioritizing search of each channel. It can be operated with.

Claims (11)

In a communication system having a plurality of channel search modes, Priority is given to the channel search mode, and an independent search queue is allocated to each channel search mode to allocate a searcher from a channel in the search queue of the search mode having the highest priority among the channel search modes. How to use Explorer in communication system. The search queue of claim 1, wherein a search order is determined for channels in a search queue having the same priority when allocating the searchers, according to a channel order included in the search queue. Explorer operating method in a communication system, characterized in that. The method of claim 1, wherein when the channels have the same priority, the searcher is allocated in the order of the channel after the search is over. The communication system of claim 1, wherein a plurality of searchers are configured in the communication system to perform the channel search according to the priority of the plurality of channel search modes, and when the channel search ends, the search is performed according to the control of the central processing unit of the communication system. A method for operating a searcher in a communication system, characterized by searching for a new channel of a search mode or a search queue. The system of claim 1, wherein the communication system generates an interrupt in a system timer aligned with the communication system reference time and reports current time information, generates an interrupt in the central processing unit, and controls the interrupt so that the interrupt is cleared by the central processing unit. According to the control of the interrupt control unit and the central processing unit, all the offsets of the received signal received by the communication system may be despread using the PN signal, and the average value is calculated by calculating the energy of the despread signal. Next, a searcher operating method in a communication system comprising a plurality of searchers for selecting a PN offset of a multipath signal having an energy value greater than a specific threshold value among a plurality of energy values to search for the channel. If the number of channels of the highest priority channel search queue is set to the number of remaining channels, and if any searcher index is smaller than the full searcher index, the searcher determines whether the channel to be searched is null. Determining whether window searching is completed; Determining whether there is a residual highest priority channel when the search for the entire window is completed, and if there is no channel to search in a channel search queue having a next priority, when there is no search; If there is no channel to search in the channel search queue having the next priority, it is determined whether there is a channel to search in the channel search queue having the next priority, and if there is a channel to search in the channel search queue having the next priority, A method for operating a searcher in a communication system, characterized in that the step of searching for a search channel. 7. The method of claim 6, wherein the highest priority channel discovery queue is a queue assigned to an enhanced access preamble discovery mode, the second priority channel discovery queue is a queue assigned to a traffic preamble discovery mode, and the third priority channel. The search queue is a searcher operating method in a communication system, characterized in that the queue is given to the traffic multipath search mode. The method of claim 6, further comprising: if the searcher has not searched for the channel to be searched, issuing a search command for the next sector or the next window of the search channel, and increasing the index of the searcher. Features an operation of the navigator in Hanne communication system. A first step of initializing an index of any searcher, a partial search start and a partial search end; Determining whether the search of the searcher is completed when the searcher index is smaller than the index of all searchers, and setting the channel assigned to the searcher as the current search channel when the search is completed; Determining whether the current search window and the sector are initialized, and increasing the current search window by a rake width; Determining whether the current search sector index is larger than the number of search sectors if the current search window is smaller than the sector window; And determining a current search mode and putting a current search channel into a current search mode queue and setting the search channel of the searcher to null. 10. The method of claim 9, further comprising: copying or updating a search result in a search channel buffer according to whether the partial search is started between the third and fourth steps; After determining the search mode, it is determined whether the partial search is the last in each search mode. If the partial search is the last, the current search channel is sent to the end of the current search mode queue, and if not, the current search channel is the current search mode queue. And setting the search channel to null after sending to the front of the searcher. 10. The method of claim 9, further comprising: starting a partial search if the current search window and the sector are initialized in the third step; Setting the current search window to zero and increasing the current search sector index by one if the current search window is larger than the sector window in the fourth step, And if the current search sector index is greater than or equal to the number of search sectors in the fourth step, setting the current search sector index to zero and starting a partial search.