JP3570398B2 - Method for adjusting missing section in mobile station, method for controlling handoff speed of wireless communication system, and mobile station - Google Patents

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
TECHNICAL FIELD The present invention relates to a method for adjusting an interval during which a mobile station is lost, a method for controlling a handoff speed of a wireless communication system, and a mobile station, and more particularly, to an improvement in handoff control in a wireless communication system.
[0002]
BACKGROUND OF THE INVENTION
As described in TIA / EIA, IS-95, "Mobile Station-Base Station Compatibility Standard for Dual Mode Broadband Spread Spectrum Cellular Systems", published in July 1993, a code division multiple access (CDMA) cellular system. Cellular phones work with various standards, including telephony systems. CDMA is a spread spectrum multiple access digital communication technology that creates a channel using a unique code sequence. In a CDMA system, a signal can be received even when a high level of interference exists, and the signal is actually received. Although the practical constraints on signal reception depend on channel conditions, CDMA reception in systems described in the IS-95 standard described above can be achieved with 18 dB more interference than signals for static channels. It is feasible. Generally, this system works with low levels of interference and dynamic channel conditions.
[0003]
A mobile station using the CDMA standard always searches for a pilot channel of a neighboring base station for a pilot sufficiently stronger than the threshold. When a mobile station moves from a range covered by one base station to a range of another base station, the mobile station promotes a pilot from a neighbor set (a set of neighbors) to a candidate set (a set of candidates), and The promotion from the neighbor set to the candidate set is notified to one or a plurality of base stations via a pilot strength measurement message (Pilot Strength Measurement Message). The base station determines an active set (Active Set) according to the pilot strength measurement message, and notifies the mobile station of the new active set via a handoff instruction message. A "soft handoff" has occurred when a mobile station starts communicating with a new base station in a new active set before terminating communication with a previous base station.
[0004]
The drop threshold is determined based on the relative strength of the pilot signal received by the mobile unit. This drop threshold is then used to determine whether to initiate a drop in connection with a particular base station (drop: remove base station from each set). In such a determination, the strength or relative strength of each pilot signal is compared with the drop threshold. The drop threshold is determined based on the strength of one or more pilot signals from the connected base station received by the mobile unit. The _TTDROP timer is a timer that keeps track of when the pilot falls below the drop threshold. The purpose of the _TTDROP timer is to avoid falsely removing a strong pilot whose measured energy has been weakened due to short-term changes in the propagation environment, such as a fast fade. However, the duration of the _TTDROP timer is preset regardless of signal level, interference, dynamic changes and other parameters.
[0005]
Summary of the Invention
In this application, the delay associated with a handoff decision is reduced or extended. The handoff decision is based on the time during which the energy from the pilot is below a set threshold. This time is dynamically controlled to adjust the delay based on local parameters. This time may be specific to a particular pilot or common to all pilots. Parameters that affect this time include pilot energy level variations, mobile station dynamic changes, and each pilot energy level. This time may be adjusted based on a look-up table or calculated using a calculation formula.
[0006]
The present application discloses a method for adjusting a drop time period in a mobile station. The method includes measuring a control parameter and adjusting a missing section based on the control parameter. The method also includes a change in the missing interval when the variation level of the pilot signal changes or when the future energy level of the pilot signal can be well estimated.
[0007]
The present application discloses a method for controlling a handoff speed of a wireless communication system. The method includes selecting one or more control parameters and determining a target missing interval based on the values of the control parameters. Next, the missing section is adjusted. The method comprises determining a target missing interval based on a look-up table or formula.
[0008]
The present application discloses a mobile station for use in a wireless communication system. The mobile station includes a missing section timer for controlling a handoff speed, and an adjusting unit. The adjusting means changes the value of the missing section based on the selected control parameter.
[0009]
Note that the present invention specifically has various features as described in the claims, and those features and effects will be apparent from embodiments described later.
[0010]
BEST MODE FOR CARRYING OUT THE INVENTION
FIG. 1 shows elements of an example of a wireless communication system. An exchange (mobile switching center) 102 communicates with base stations 104a-104k (only one connection is shown). The base stations 104a to 104k (collectively 104) transmit and receive data to and from the mobile stations 106 in the cells 108a to 108k (collectively 108). The cell 108 is an approximately hexagonal geographic area with a radius of up to 35 kilometers or more, if possible.
[0011]
The mobile station 106 can transmit and receive data to and from the base station 104. In one embodiment, mobile station 106 sends and receives data according to the code division multiple access (CDMA) standard. CDMA is a communication standard that allows users of mobile wireless communication devices to exchange data with a telephone system in which wireless signals carry data to and from wireless devices.
[0012]
According to the CDMA standard, additional cells 108a, 108c, 108d, 108e adjacent to cell 108b allow mobile station 106 to cross cell boundaries without interrupting communications. This is because the base stations 104a, 104c, 104d, and 104e of the neighboring cells take on the task of transmitting and receiving data for the mobile station 106. The exchange 102 coordinates all communications with the mobile station 106 in multiple cell ranges. Thus, switching center 102 can communicate with multiple base stations 104.
[0013]
The mobile station 106 is free to move within the cell 108 while transmitting voice or data. The mobile station 106 searches for transmissions of the base station 104 in the cell 108 to detect calls and paging messages directed to the mobile station 106, even when not in active communication with other telephone system users.
[0014]
One example of this type of mobile station 106 is a cellular telephone used by pedestrians who turn on a cellular telephone in anticipation of a call while walking in a cell 108. The cellular telephone scans a certain frequency (a well-known frequency used in CDMA) to synchronize communication with the base station 104. The cellular telephone then registers with switching center 102 to indicate that it is an active user in the CDMA network.
[0015]
In detecting a call, the cellular telephone scans data frames sent from the base station 104 to detect telephone calls and paging messages directed to the cellular telephone. In this call detection mode, the cellular telephone receives, stores, and examines the paging message data to determine whether the data includes a mobile station identifier that matches the cellular telephone identifier. If a match is detected, the cellular telephone establishes a call with switching center 102 via mobile station 104. If no match is detected, the cellular telephone enters an idle state for a predetermined period of time, and then exits the idle state to receive another paging message data transmission.
[0016]
Sometimes it is desirable for another base station 104 to communicate with this mobile station 106. This may be due to the first base station 104 losing signal strength, the mobile station 106 getting out of range of the first base station 104, or other factors. When the mobile station changes base station 104, this is called a handoff. Currently, one technique for determining whether to handoff is to monitor the energy level of a pilot signal from a base station. When the energy level of the pilot signal falls below a predetermined threshold for a certain time, the mobile station 106 starts handoff. FIG. 2 illustrates a process for determining whether a handoff is required according to a conventional process. FIG. 2 is a graph 200 showing how the energy level of pilot signal 205 changes over time. The energy level of pilot signal 205 is compared to a predetermined threshold level 210 ( _IDROP threshold). When the energy of pilot signal 205 falls below predetermined threshold level 210 for a set time 225 (T _TDROP ), mobile station 106 initiates a handoff to switch base station 104. As seen at point 220, when the energy level of pilot signal 205 reaches a predetermined threshold 210, a threshold timer ( _TTDROP timer) starts _running . The threshold timer runs for a time determined by the value of _TTDROP . Next, mobile station 106 determines the value of the energy level of pilot signal 205 shown at point 230. If the energy level of pilot signal 205 remains below predetermined threshold value 210 as shown in FIG. 2, mobile station 106 starts handoff. However, when the energy level of pilot signal 205 rises above predetermined threshold 210 again, mobile station 106 maintains its connection with the current base station.
[0017]
FIG. 3 is a graph 300 showing the energy level of pilot signal 305 that changes rapidly with time. When the energy level of pilot signal 305 changes abruptly, the preset time value T _TDROP does not provide the desired result. For example, at point 320, when the energy of pilot signal 305 falls below predetermined threshold level 310, the time of T _TDROP 225 begins. This time then ends, and at point 325 the energy level of pilot signal 305 is determined. At this point 325, mobile station 106 maintains a connection with base station 104 because the energy level of pilot signal 305 is above predetermined threshold 310. However, the sudden change in the energy level of pilot signal 305 indicates that mobile station 104 has been operating at a lower energy level 330 for some time. Further, the energy level falls below the predetermined threshold 310 again in the range 335.
[0018]
The present invention _adjusts the value of the time T _TDROP based on the change in the parameter. By dynamically adjusting the time used by the mobile station 106 to make a handoff decision, handoff delays can be reduced. The dynamic change time may be specific to each pilot signal or common to all pilots. The parameters used for time adjustment include temporal variations in pilot energy levels, dynamic changes in mobile station 106 including location and speed and direction of travel, and energy levels for each pilot.
[0019]
Temporal variations in pilot energy level 305 are used for time adjustment. If the energy level 305 changes abruptly, it is desirable to reduce the time so that the mobile station 106 can quickly connect to the new base station 104. This is illustrated in FIG. In the first range 336, the energy level 305 changes rapidly. In order to enable a quick change to a new base station, the missing section T _TDROP1 340 is shortened. In the second range 338, the energy level 305 does not change rapidly. Therefore, the missing time section T _TDROP2 345 is longer than the missing time section T _TDROP1 340.
[0020]
FIG. 4 is a flowchart illustrating the dynamic adjustment of the missing interval process 400 used by the mobile station 106. Process 400 begins with a "start" state 405. Proceeding to state (step) 410, the mobile station 106 determines the current missing section. The current missing section may be a preset amount at the time of initialization of the mobile station 106 or a result of final adjustment of the missing section. This value is typically stored in the memory of the mobile station 106.
[0021]
Proceeding to a state 415, the mobile station 106 selects and measures control parameters. As described above, the mobile station 106 uses various parameters to control the missing section. These parameters include, but are not limited to, temporal variations in pilot energy levels, dynamic changes in mobile station 106 including location and speed of travel, and each pilot energy level. The specific parameter used varies between mobile stations 106 and may be a predetermined value or a value adjusted by dynamic changes. Further, the mobile station 106 adjusts the missing section using a combination of parameters.
[0022]
Proceeding to state 420, the target missing segment is determined based on the selected parameters. The details of the new missing interval calculation are outside the scope of the present disclosure, and will not be described in detail here. However, in general, a mobile station 106 moving at high speed needs to make a handoff decision faster than a stationary mobile station. It is extended to make it unnecessary. As a result, within a very short time, re-addition of the missing pilot is subsequently required. Further, when the energy level of the pilot is high, the missing time section is extended because it is not necessary to make many handoff decisions.
[0023]
The determination of the target missing section can be obtained in various ways. The mobile station 106 may use a look-up table that uses the measured parameter values as input parameters. The target missing section may change stepwise within the preset range, or may be calculated using a calculation formula using the measured parameter value as an input variable. Further, a weight value to be added to each parameter or parameter set at the time of studying the section determination at the time of missing may be set or controlled by the network. The base station 104 can set the stage, speed, and time at which the missing section is adjusted. For example, the base station 104 can request that no adjustment be made to the dynamic change of the mobile station 106, but the variation in pilot energy value be adjusted.
[0024]
Proceeding to state 425, the mobile station 106 adjusts the missing section to the target missing section. It is possible that the current missing section is equal to the target missing section, in which case no change is made. After the missing section is adjusted, the mobile station 106 starts operating in a new missing section. The process then ends at "end" state 430.
[0025]
The present invention can be easily modified and changed in various ways. Thus, the present invention may be embodied in other specific forms without departing from its spirit or essential characteristics.
[Brief description of the drawings]
FIG. 1 is a diagram illustrating elements of an example of a wireless communication system used in an embodiment of the present invention.
FIG. 2 is a graph illustrating a drop threshold determination performed in the prior art.
FIG. 3 is a graph illustrating a dynamic change drop threshold determination performed according to an embodiment of the present invention.
FIG. 4 is a flowchart illustrating a missing section determination process according to an embodiment of the present invention;
[Explanation of symbols]
102 ... exchange station, 104a-104k ... base station,
108a to 108k: cell, 106: mobile station.

Claims (22)

A method for adjusting the missing section of the mobile station , which determines whether a handoff for changing the base station is necessary based on whether or not the energy level of the pilot signal from the base station is below a predetermined missing section and a threshold level. Law,
Wherein the state of the mobile station and the base station is connected before performing the handoff, to obtain the value of the control parameter used to adjust the missing time slot, the missing time slot based on the value of the control parameter characterized by dynamically adjusting the method of adjusting the missing time slot in the mobile station. Before SL control parameter A method according to claim 1, characterized in that it comprises a variation of the energy level of the pilot signal. 3. The method according to claim 2, wherein when the fluctuation level of the pilot signal decreases, the missing interval is shortened . Before SL control parameter A method according to claim 1, characterized in that it comprises a dynamic change of the mobile station. Before SL control parameter A method according to claim 1, characterized in that it comprises a signal strength of the pilot signal. The method according to claim 1, characterized in that receiving a set of pre-Symbol control parameters from the base station. The method of claim 1 , wherein the handoff is performed at the end of the missing section. Energy level is predetermined missing time interval of the pilot signal from the base station, depending on whether is below a threshold level, controls the speed of the handoff of a wireless communication system for determining whether it is necessary to handoff to change the base station A way to
Before performing the handoff from the state where the mobile station and the base station are connected , obtain the value of the control parameter used for adjustment of the missing section, the target missing section based on the value of the control parameter Determining , adjusting the missing time section to the determined target missing time section, and starting an operation of determining whether the handoff is required by the adjusted new missing time section, A method for controlling a handoff speed of a wireless communication system . The method of claim 8, wherein the determining based on the previous SL target missing time slot in a look-up table. The method of claim 8, wherein the determining based on the previous SL target missing time slot in the formula. Before SL control parameter A method according to claim 8, characterized in that it comprises a variation of the energy level of the pilot signal. Before SL control parameter A method according to claim 8, characterized in that it comprises a dynamic change of the mobile station. The method of claim 8, wherein the control parameter comprises a signal strength of the pilot signal. The method of claim 8, wherein receiving a set of pre-Symbol control parameters from the base station. The method of claim 8, wherein: performing the handoff at the end of the previous SL missing time interval. In the mobile station to determine whether the handoff to change the base station is necessary, based on whether or not the energy level of the pilot signal from the base station is lower than the predetermined loss interval or the threshold level,
A missing section timer in which the value of the missing section is set ;
Wherein the state of the mobile station and the base station is connected before performing the handoff, to obtain the value of the control parameter used to adjust the missing time slot, based on the value of the control parameter, said missing and adjusting means for dynamically changing the value of the missing time interval which is set when the interval timer, with a transfer Dokyoku. Before SL adjusting means, the mobile station according to claim 16, wherein changing the value of the missing time slot determines a target missing time slot based on a lookup table from the value of the control parameter. Before SL adjusting means, the mobile station according to claim 16, wherein changing the value of the missing time slot determines a target missing time interval based on the calculation formula from the values of the control parameters. Before SL adjusting means, the mobile station according to claim 16, wherein the energy level of the pilot signal to vary the value of the missing time slot so as to shorten the missing time slot to be estimated. Before SL control parameters, the mobile station according to claim 16, characterized in that it comprises a variation of the energy level of the pilot signal. Before SL control parameters, the mobile station according to claim 16, characterized in that it comprises a dynamic change of the mobile station. Before SL control parameters, the mobile station according to claim 16, characterized in that it comprises a signal strength of the pilot signal.

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