JP4171745B2 - Overreach detection method and mobile device using the same - Google Patents

Description

  The present invention relates to an overreach detection method and a mobile device using the same, and more particularly to a method for detecting overreach during standby and a mobile device using the method.

In a CDMA (Code Division Multiple Access) type mobile communication system, different spreading codes are assigned to base stations placed at a short distance, and the same spreading code is assigned to base stations separated by a predetermined interval.
In the mobile communication system shown in FIG. 1, adjacent base stations 10, 11, 12, 13, and 14 are assigned different spreading codes, and the base station 15 having a predetermined interval is spread to the same spreading as the base station 14, for example. A code is assigned.
Allocation of the spread code of the base station is performed in consideration of the radio wave propagation characteristics due to surrounding terrain etc., but in places where the propagation environment changes significantly, the mobile device does not receive the radio waves of the nearby base station, There may be overreach to receive radio waves from a distant base station. In particular, when the mobile device 20 is handed over in a building street, if reception sensitivity from a nearby base station 14 is poor, reception of a signal from the base station 14 is stopped and May be received.
In the CDMA system, when signals having significantly different power levels are multiplexed, a large power signal gives a large interference to a small power signal, so that the number of lines that can be accommodated (system capacity) decreases. In order to solve this problem, in the CDMA system, when there are a plurality of mobile stations in the same cell, the transmission power of each synchronization is controlled to average the reception level at the base station of the cell.
However, when the above-described overreach occurs, the mobile device 20 transmits a large power signal to the distant base station 15, and the distant base station 15 transmits a large power signal to the mobile device 20. . Therefore, there is a problem that the system capacity is greatly deteriorated by giving large interference to other cells and sectors.
Conventional overreach detection is performed at a base station as described in Patent Document 1.
JP 2002-44006 A

However, since there is no judgment on whether the mobile device is in a state where overreach occurs or not, even if the reception state of the currently connected cell is good, it is possible to talk and communicate with a long-distance base station. I often go.
In particular, during a handover in a building street, if the reception sensitivity to a nearby base station is poor, reception of a signal from a distant base station is stopped by stopping signal reception from the nearby base station. If it is far away, the reception sensitivity is deteriorated, so that there is a problem that the base station transmission power is increased by the outer loop control and may interfere with other terminals.

It is a general object of the present invention to provide an overreach detection method capable of performing overreach detection on a mobile station side and improving a call maintenance rate, and a mobile station using the same.
In order to achieve this object, the present invention provides an overreach detection method in a mobile communication system adopting a code division multiple access method, and performs power measurement of a received signal during standby, and the power measurement result is a threshold value. If it is lower, one or more preamble transmissions are performed, and when there is no response from the base station to the preamble transmission, the base station is detected as overreach.
According to such an overreach detection method, it is possible to perform overreach detection on the mobile device side, and it is possible to improve the call maintenance rate by excluding the base station that has detected overreach from the serving cell.

FIG. 1 is a schematic diagram of a mobile communication system.
FIG. 2 is a conceptual diagram of a protocol architecture between a base station and a mobile device.
FIG. 3 is a block diagram of an embodiment of the overreach detection function of the present invention.
FIG. 4 is a flowchart of processing executed by the overreach detection function of the present invention.
FIG. 5 is a flowchart of the overreach detection process.
FIG. 6 is a diagram illustrating a preamble signature.

Embodiments of the present invention will be described below with reference to the drawings.
FIG. 2 shows a conceptual diagram of a protocol architecture between a base station and a mobile station. In the figure, a mobile device (UE) 20 includes a physical layer (L1) unit 21, a MAC (Medium Access Control) layer unit 22 and a RLC (Radio Link Control) layer unit 23, which are sublayers of the data link layer, and a network. The layer is composed of a layer RRC (Radio Resource Control) layer unit 24. The base station radio access network (UTRAN) 30 includes a physical layer unit 31, a MAC layer unit 32 and an RLC layer unit 33, which are sublayers of the data link layer, and an RRC layer unit 34 of the network layer. .
The physical layer units 21 and 31 perform multiplexing, channel coding, spreading, modulation, and the like. The MAC layer units 22 and 32 perform scheduling of a user's request in consideration of the usage status of the wireless line, monitoring of the traffic volume, and the like. The RLC layer units 23 and 33 control error data and retransmit data, and add retransmission control information to the signaling messages from the RRC layer units 24 and 34 so that they can be transmitted correctly.
The RRC layer units 24 and 34 generate and terminate signaling information such as system information and outgoing / incoming messages, and acquire measurement data from the physical layer units 21 and 31 and the MAC layer units 22 and 32, respectively. 31 and MAC layer units 22 and 32 are controlled.
The overreach detection function built in the mobile device 20 of the present invention is roughly divided into two processing functions. From the two processing results, it is recognized whether or not overreach has been detected. When overreach is detected, control is performed so as to stop communication with the base station.
As a first processing function, the physical layer unit 21 performs communication quality determination (detection S: Squal [quality], Srxlev [level]) by a cell monitoring (cell reselection) function, and a threshold value is determined by path loss threshold determination processing. If the measured path loss is lower than that, there is a possibility of a long distance, so overreach detection is performed by the second processing function.
When the measured path loss value is lower than the threshold value, the second processing function performs preambles for each serving cell in order to confirm whether the communication state is possible by calling / incoming calls using the common channel in the MAC layer unit 22. Send. If the timer times out without receiving a response (Ack) from the cell's base station, or if the response is not received from the base station side after a certain number of processing cycles for transmitting the preamble again The MAC layer unit 22 of the device 20 determines that the corresponding serving cell is overreach and excludes it from the candidates for the standby base station. A serving cell whose overreach has not been detected is set as a standby candidate.
FIG. 3 shows a block diagram of an embodiment of the overreach detection function of the present invention. This overreach detection function uses a cell monitoring function during cell transition. The purpose of the cell monitoring function is to select a cell with sufficiently good quality as a serving cell, even if it is not always the best cell, so that it can be awaited.
When waiting, the mobile device 30 monitors appropriate system information and performs measurements necessary for cell monitoring evaluation. The cell monitoring evaluation process is a process for finding out if there is a better cell, which is performed when the mobile's internal trigger or system information is changed.
When hierarchical cells are used, it is possible to further limit the range of cells to be measured by setting only cells having a high hierarchical cell priority level (HCS_PRIO) as processing targets. In this case, the measurement is performed for cells that have a lower or equal hierarchical cell priority level than the serving cell.
In FIG. 3, the measurement unit 40 measures the level of the serving cell. Based on the measurement result supplied from the measurement unit 40, the path loss calculation unit 42 performs path loss calculation according to the following equation. The path loss actual value Passloss is calculated using the following equation.
Passloss = Primary CPICH Tx power
-CPICH RSCP (1)
However, for Primary CPICH Tx power, IE “Primary CPICH” [dBm] included in the layer 3 information of the system information is used. CPICH RSCP is signal code power [dBm] after despreading of a common pilot channel CPICH (Common Pilot Channel).
The filter unit 44 performs filtering of each of the measurement value and the path loss actual value supplied from the measurement unit 40 to remove noise components. The detection S calculation unit 46 calculates the detection S by the following equation. The detection S, that is, Squal or Srxlev is calculated by the following equation. Further, threshold values Sintrasearch and Sintersearch are reported from the base station 30 by system information.
Squal = Qqualmeas-Qqualmin (2)
Srxlev = Qrxlevmeas-Qrxlevmin
-Pcompensation (3)
However, the measured cell quality value Qqualmeas is Ec / N0 [dB] of CPICH (Common Pilot Channel), and Qqualmin is the minimum required quality level [dB] in the cell. The measured cell reception level value Qrxlevmeas is CPICH RSCP (signal code power after CPICH despreading) [dBm], Qrxlevmin is the lowest required reception level [dBm] in the cell, and Pcompensation is a RACH (Random Access Channel) by the mobile station. ), The value obtained by subtracting the maximum high frequency output power [dBm] of the mobile device from the maximum allowable transmission power [dBm] when accessing the cell, or 0, whichever is larger.
The detection S determination unit 48 is a process for determining whether or not to perform the measurement of the serving cell, and performs the following determination using Squal (or Srxlev).
When Squal (or Srxlev)> Sintrasearch, it is determined that the S determination is good and no measurement is performed on the same frequency cell.
In the case of Squal (or Srxlev)> Sintersearch, the measurement is not performed on the different frequency cell as an S determination failure.
The path loss actual value Passloss obtained by the path loss calculation unit 42 is filtered by the filter unit 44 and supplied to the overreach detection processing unit 50, and the overreach detection processing unit 50 obtains the path loss actual value Passloss from the base station 30. When the actual path loss value is lower than the threshold value of the system information as compared with the threshold value notified by the system information, an overreach detection process is executed.
Incidentally, the measurement unit 40, the path loss calculation unit 42, the filter unit 44, and the detection S calculation unit 46 in FIG. 3 belong to the physical layer unit 21, and the overreach detection processing unit 50 belongs to the MAC layer unit 22.
FIG. 4 shows a flowchart of processing executed by the overreach detection function of the present invention. This process is executed for each serving cell at a predetermined time interval such as 2.56 sec. In the figure, the level of each serving cell is measured by the measuring unit 40 in step S10. Next, in step S12, the detection S calculation unit 46 and the detection S determination unit 48 perform detection S calculation and detection S determination of each serving cell.
Next, in step S14, the overreach detection processing unit 50 determines whether or not the actual path loss value is lower than the threshold value of the system information. If the actual path loss value is lower than the threshold value, the overreach detection process of each serving cell is performed in step S16. Execute.
When the overreach detection process is completed, it is determined in step S18 whether or not overreach of each serving cell has been detected, and the serving cell in which overreach has been detected cannot communicate by calling / incoming calls through the common channel. In S20, the value 1 is set in the overreach flag in the corresponding serving cell column of the cell table provided in the physical layer unit 31. In the cell table, the frequency to be used, the scramble code, the measurement value of the measurement unit 40, the detection S, the actual path loss value, etc. are registered for each serving cell.
On the other hand, for the serving cell in which no overreach has been detected, the corresponding serving cell column (frequency to be used, scramble code, measured value of measuring unit 40, detected S, actual measured path loss, etc.) is updated in step S22. . At this time, the overreach flag has a value of 0, indicating that it is not overreach.
Even if the actual path loss value is larger than the system information threshold value by the overreach detection processing unit 50 in step S14, the corresponding serving cell column (frequency to be used, scramble code, measurement value of the measurement unit 40, The detection S, the actual measured path loss value, etc.) are updated. Also in this case, the overreach flag has a value of 0, indicating that it is not overreach.
After the above steps S20 and S22, only the serving cell whose overreach flag registered in the cell table in step S24 has a value of 0 is notified to the upper RRC layer unit 24 of the measured value, detected S, actual measured path loss, etc. This process is terminated.
FIG. 5 shows a flowchart of the overreach detection process executed by the overreach detection processing unit 50 in step S16. This process is performed for each serving cell. In the figure, the overreach detection processing unit 50 resets the number of transmissions to 0 in step S30, and then performs preamble transmission to the corresponding serving cell in step S32. This preamble transmission is performed to confirm whether or not communication is possible by calling / incoming calls using the common channel, and using the RACH (corresponding to PRACH in the physical layer) that is an uplink common transport channel. Done.
The preamble is a 4096-chip signal composed of 16 types of signatures. Each of 16-chip signatures P _{0 to} P ₁₅ shown in FIG. 6 is repeated 256 times to form a preamble.
Thereafter, the timer reset in step S34 is started, and in step S35, it is determined whether there is no response (Ack) from the base station 30 of the corresponding serving cell for the preamble transmission and the timer has timed out. If the timer has timed out, the number of transmissions is incremented by 1 in step S36.
Thereafter, in step S38, it is determined whether or not the number of transmissions is greater than or equal to a threshold value such as 32. If the number of transmissions is less than the threshold value, the process proceeds to step S32 and preamble transmission is repeated. If the number of transmissions is equal to or greater than the threshold, the process proceeds to step S40.
Note that the power of preamble transmission starts from a power smaller than the optimum transmission power estimated from the measurement of the downlink common pilot channel, and sequentially increases as the number of transmissions increases.
In step S40, since communication cannot be performed by calling / incoming calls through the common channel, this processing is terminated as overreach detection for the base station 30 of the serving cell.
On the other hand, if there is a response from the base station 30 to the preamble transmission before the number of transmissions exceeds the threshold in step S38, the process proceeds to step S42, and this process is terminated as no overreach is detected.
As described above, since the serving cell in which overreach is detected is not notified to the RRC layer unit 24, the serving cell in which the overreach is detected in the RRC layer unit 24 cannot be communicated by outgoing / incoming calls through the common channel. Exclude from serving cell candidates. For this reason, only serving cells that have not been overreached remain, and the call connection maintenance rate of the remaining serving cells can be increased.
Steps S10 and S12 correspond to the power measuring means described in the claims, step S32 corresponds to the preamble transmission means, step S40 corresponds to the overreach detection means, and steps S20 and S24 correspond to the cell exclusion means. .

Claims (8)

An overreach detection method in a mobile communication system employing a code division multiple access method,
While waiting, measure the power of the received signal,
If the power measurement result is lower than the threshold, perform one or more preamble transmissions,
An overreach detection method in which the base station detects overreach when there is no response from the base station to the preamble transmission. The overreach detection method according to claim 1,
An overreach detection method for excluding a base station detected as overreach from a serving cell that performs standby. The overreach detection method according to claim 1,
The received signal power measurement is an overreach detection method for measuring signal code power after despreading of a common pilot channel. The overreach detection method according to claim 3.
The overreach detection method, wherein the threshold is a value notified by system information. A mobile communication system adopting a code division multiple access method,
Power measurement means for measuring the power of the received signal during standby;
Preamble transmission means for performing preamble transmission one or more times when the power measurement result is lower than a threshold;
A mobile device comprising overreach detection means for detecting when the base station does not respond to the preamble transmission as overreach. The mobile device according to claim 5, wherein
A mobile device comprising cell excluding means for excluding a base station detected as overreach from a serving cell for standby. The mobile device according to claim 5, wherein
The power measurement of the received signal is a mobile device that measures the signal code power after despreading of the common pilot channel. The mobile device according to claim 6, wherein
The threshold value is a mobile device that is a value notified by system information.

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