JP3035497B2 - Mobile station mode switching method - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a mobile station mode switching method suitable for mobile communication in which service areas of different communication systems are used in an overlapping manner.

[0002]

2. Description of the Related Art In mobile communication in which service areas are overlapped by different communication systems, it is necessary to select which communication system to communicate. The selection of the communication method is called the mode selection. A conventional mode selection method will be described with reference to FIG. In the figure, the communication systems of mobile communication systems A and B are different from each other.
The service area 1 of the mobile communication system B is provided so as to partially overlap the service area 1 of the mobile communication system B. It is assumed that the mobile station MS in the service area 2 moves from the position 31 to the position 32 in the overlapping area, and further moves to the position 33 in the service area to which only the mobile communication system A is applied. In the conventional mode switching method, the system in which the mobile station MS is located is autonomously determined based on the received electric field strength.

[0003] In this case, the mobile station MS monitors signals transmitted from the base stations of the systems A and B, and determines whether to enter or leave the area based on the received electric field strength at this time. That is, assuming that the received electric field strength of the signal transmitted from the base station of the system A at the mobile station MS is PA and the received electric field strength of the signal transmitted from the base station of the system B at the mobile station MS is PB, When the strength PA exceeds a certain fixed value pa1 predetermined as a system parameter, it is determined that the vehicle has entered the system A, and when the received electric field strength PA falls below the system parameter and a certain predetermined fixed value pa2. It is determined that the system A is out of the service area. Similarly, when the reception electric field strength PB exceeds a certain fixed value pb1 which is predetermined as a system parameter, it is determined that the vehicle has entered the system B, and the reception electric field strength PB is a certain fixed value which is predetermined as a system parameter. When the value falls below pb2, it is determined that the system B is out of the service area. The received electric field strength of the mobile station MS located at the position 31 in the system B is PA <pa2PB> pb1. In this case, since the mobile station MS is located in the service area of the system B and is out of the service area of the system A, the mobile station MS selects the mode of the system B.

Next, when the mobile station MS moves from the position 31 to the overlapping area of the two areas 1 and 2 and reaches the position 32, the received electric field strength is PA> pa1 PB> pb1. Although it is possible to be in the service area, normally, a plurality of modes are not selected at the same time, and the mode selected first is prioritized. That is, the mobile station MS selects the mode for the system B.

Further, when the mobile station MS moves from the position 32 to the area of only the system A and reaches the position 33, the received electric field strength of the mobile station MS is PA> pa1 PB <pb2. In this case, since the mobile station MS is located in the service area of the system A and is out of the service area of the system B, the mode of the system A is selected.

Next, an example in which one service area is included in the other service area is shown in FIG.
Shown in In the figure, it is assumed that a service area 1 of a mobile communication system A includes a service area 2 of a system B different from the system A. In this example, it is assumed that system B has a higher priority than system A in mode selection, and mode switching is performed when the mobile station MS sequentially moves from position 31 to position 32 and from position 32 to position 33. I will give it. Mobile station M at location 31
The reception electric field strength of S is PA> pa1 PB> pb1, and the mobile station MS is located in both service areas of the systems A and B, but selects the mode of the system B in order to give priority to the system B. .

Next, when the mobile station MS moves to the position 32,
The reception electric field strength of the mobile station MS is PA> pa1 PB <pb2. In this case, since the mobile station MS is out of the service area of the system B, the mobile station MS selects the mode of the system A. Further, when the mobile station MS moves to the position 33, the received electric field strength of the mobile station MS becomes PA <pa2 PB <pb2. The mobile station MS is out of the service area of both systems A and B.

Further, when the mobile station MS moves from the position 33 to the position 32 again, the received electric field strength of the mobile station MS is PA> pa1 PB <pb2, and the mobile station MS is located in the service area of the system A. Out of service area. Therefore, the mode of the system A is selected. Further, when the mobile station MS moves to the position 31, the reception electric field strength of the mobile station MS is PA> pa1 PB> pb1, and the mobile station MS is located in both the service areas of the systems A and B, but the system B has priority. Therefore, the mode of the system B is selected.

[0009]

However, in the above prior art, when the service area is discontinuous or when the mobile station MS is at the end of the service area, the mode switching is repeated, so-called "fluttering" occurs. . When a large number of such mobile stations MS are present, location registration for mode switching is repeated for each mobile station MS, and the traffic of the control channel increases to the limit of the processing capacity of the equipment or more, and so-called congestion occurs. was there.

The above problem will be described with reference to FIG. In this figure, the service area 2 of the mobile communication system B is included in the service area 1 of the mobile communication system A as in FIG. included. Also in this case, system B has priority over system A. An example is given in which the mobile station MS in the area 2 moves from the position 31 to a position 32 outside the area 2 and within the area 1, and further moves from the position 32 to a position 33 in the area 21.

The reception electric field strength of the mobile station MS at the position 31 is PA> pa1 PB> pb1. The mobile station MS can select both modes of the systems A and B, but selects the mode of the system B in order to give priority to the system B. At this time, temporary shadowing, that is, radio waves from the base station,
When the received electric field strength of the mobile station MS at the position 31 becomes PA> pa1 PB <pb2 due to the shadow of a mountain or the like, the mobile station MS determines that the mobile station MS is out of the B mode area, switches the mode, and registers the location in the system A.

When the mobile station MS recovers from the temporary shadowing, the received electric field strength of the mobile station MS becomes PA> pa1 PB> pb1. The mobile station MS at the position 31 switches the mode again and registers the position with the system B in order to give priority to the system B.

Next, when the mobile station MS moves to the position 32, the received electric field strength of the mobile station MS is PA> pa1 PB <pb2. The mobile station MS at the position 32 selects the mode of the system A because it is out of the mode area of the system B. further,
When the mobile station MS moves from the position 32 to the position 33, the reception electric field strength of the mobile station MS is PA> pa1 PB> pb1. In this case, the mobile station MS is located in both service areas of the systems A and B, but selects the B mode to give priority to the system B. At this time, the service area 21 is an enclave of the service area of the system B, and a very small area is expected. When the mobile station MS moves slightly to the position 32, it must switch to the A mode and make the location registration to the system A through the system A control channel. Furthermore, when the mobile station MS moves slightly and comes to the position 33 again, the mode is switched to the B mode, and the position registration is made to the system B through the control channel of the system B.

When there are a large number of mobile stations MS that cause such fluttering, the control channel may be congested due to the traffic for location registration, and a heavy load is imposed on network management. Such fluttering also occurs for the mobile station MS located on the boundary of the service area 2 of the system B. Conventionally, the mode entry level and the mode outside level are fixedly stored in the mobile station MS as system parameters, and therefore cannot be easily changed.

SUMMARY OF THE INVENTION The present invention has been made in view of the above circumstances, and has as its object to suppress fluttering when selecting a mode and suppress an increase in control channel traffic.

[0016]

According to the first aspect of the present invention, a service area of the first mobile communication system partially overlaps a service area of the second mobile communication system. A mode switching method for a mobile station that performs communication by switching between a first mode connected to the first mobile communication system and a second mode connected to the second mobile communication system. Transmitting information having a parameter for mode switching from at least one of the base stations to the mobile station, and the mobile station switches between the first and second modes based on the received parameter of the information. It is characterized by.

In the invention according to claim 2,
A mode switching method for a mobile station, wherein the parameter includes at least a field strength threshold, the mobile station detects a reception field strength, and compares the detected reception field strength with the field strength threshold. Then, the first and second modes are switched based on the comparison result. In the invention according to claim 3, there is provided a mode switching method for a mobile station, wherein the parameter includes a quality of a received signal, and the mobile station detects a quality of the received signal and detects the quality of the received signal. And comparing the parameters with the parameters and switching between the first and second modes based on the comparison result.

Further, in the invention according to claim 4,
A mode switching method for a mobile station, wherein the information includes:
The mobile station includes edge information indicating that the mobile station is located in a boundary area of a service area, and the mobile station determines whether the mobile station is in the first or second area based on the presence or absence of the edge information and a parameter of the received information. The mode is switched. Further, in the invention according to claim 5, there is provided a mode switching method for a mobile station, wherein the mobile station performs the mode switching until a predetermined time elapses from when a mode switching condition is satisfied. The mode switching is executed when the condition (1) is maintained.

In the invention according to claim 6,
A mode switching method for a mobile station, wherein the information includes time information indicating a time, and the mobile station includes:
The predetermined time is set based on the time information. In the invention according to claim 7,
A mode switching method for a mobile station, wherein the first mobile communication system is a terrestrial cellular communication system, the second mobile communication system is a satellite communication system, and a mode is switched from the terrestrial cellular communication system to the satellite communication system. The parameter for switching and the parameter for switching the mode from the satellite communication system to the terrestrial cellular communication system are each selected such that the terrestrial cellular communication system has priority.

Further, in the invention according to claim 8,
A method of switching modes of a mobile station, wherein the first mobile communication system is a terrestrial cellular communication system, the second mobile communication system is a satellite communication system, and the electric field strength threshold is set to a value at which the mobile station is input. The mobile station comprises an entry threshold value referred to when the mobile station is referred to, and an exit threshold value referred to when the mobile station exits the service area. When the mobile station is located in a boundary area of the service area, the mobile station , The entry threshold is set to be large or the entry threshold is set to be small, as compared with the case where is not in the boundary area of the service area.

In the invention according to claim 9,
A mode switching method for a mobile station, wherein the first mobile communication system is a terrestrial cellular communication system, the second mobile communication system is a satellite communication system, and a mode is switched from the terrestrial cellular communication system to the satellite communication system. The predetermined time for switching is set longer than the predetermined time for switching the mode from the satellite communication system to the terrestrial cellular communication system. In the invention according to claim 10, a mode switching method of a mobile station, wherein the first mobile communication system is a terrestrial cellular communication system, and the second mobile communication system is a satellite communication system. The predetermined time when the edge information is detected is shorter than the predetermined time when the edge information is not detected.

[0022]

BEST MODE FOR CARRYING OUT THE INVENTION

A: First Embodiment Hereinafter, a first embodiment will be described with reference to the drawings. In FIG. 4, a service area 2 of a mobile communication system B different from the system A is included in a service area 1 of a certain mobile communication system A, and the service area 2 includes a plurality of zones 21 to 28. Zone 21 is an enclave of service area 2. Further, the mode of the system B is selected prior to the system A. Zone 2 with diagonal lines
1, 22, 23, 24, 25, 26, and 27 are system B
In this embodiment, information indicating the end of the service area is added to the broadcast information transmitted from the base station or the control channel during a call. Further, since the zone 28 is not a zone constituting a service area end, information indicating the service area end is not added to the broadcast information or the control channel during a call, or information indicating the non-service area end is added.

The mode switching threshold level p
a1, pa2, pb1, and pb2 are different from the entry / exit level of the mobile station MS that switches modes and does not perform communication. The mobile station MS is configured to be able to change the threshold level based on the received signal. The reception electric field strength of the mobile station MS located at the position 31 in the zone 28 is PA> pa1 PB> pb1. Therefore, the mobile station MS can select both modes of the systems A and B, but selects the B mode in order to give priority to the system B. At this time, zone 28
When the mobile station MS receives temporary shadowing or the like at the position 31 within the area 31 and PA> pa1 PB <pb2, the mobile station MS is notified by the broadcast information that the zone 28 is not the end of the service area. MS
Does not switch the mode to system A.

Next, when the mobile station MS moves from the position 31 to the position 32 in the zone 26 at the end of the service area, the reception electric field strength of the mobile station MS at the position 32 is PA> pa1 PB> pb1. Since the mobile station MS gives priority to system B, B
Mode remains. At this time, the position 32 in the zone 26
When PA> pa1 PB <pb2 due to shadowing, etc., the mobile station MS may have moved out of the B-mode area because the zone 26 has been notified by the broadcast information that it is at the end of the service area. . However, in the process of actually switching the mode to the system A, the switching is provided with hysteresis using a timer. That is, the mobile station MS executes the mode switching when the mode switching condition is maintained from when the mode switching condition is satisfied until a predetermined time elapses. As a result, unnecessary mode switching is not performed even if the level changes due to temporary shadowing.

Further, when the mobile station MS moves from the position 32 to a position 33 inside the area 1 and outside the area 2,
The reception electric field strength of the mobile station MS at the position 33 is PA> pa1 PB <pb2, and the mobile station MS switches the mode to the system A. In this case, the mode switching is delayed using a timer to provide hysteresis. Thereby, the system B
At the edge of the service area. Also, the mobile station MS that is fluttering
The switching threshold level p for the zone in which
a1, pa2, pb1, and pb2 are changed, and the mode switching is forcibly caused by the base station to the mobile station MS. In other words, pb2 is set low using the control channel from the base station, and PA> pa1 PB> pb2 is satisfied even in the mobile station MS at the position 32 of the zone 26 at the same end, and the mode of the system B can be maintained. Becomes

There are, for example, the following two methods for determining the fluttering of the mode switching. First, the first method detects a traffic amount of the common control channel, and if the value exceeds a predetermined value, determines that fluttering has occurred. On the other hand, the value of the detected traffic amount Is smaller than the predetermined value, it is determined that no flutter has occurred.

In the second method, in the terrestrial communication system, the base station measures the time when the signal transmitted from the mobile station MS deviates from the reference signal, and based on this time deviation, the mobile station MS Is estimated, and the flutter is determined based on the estimated position. In this case, in the base station of the system B, the signal S1 for position registration transmitted from the mobile station MS is:
It measures how much it deviates from the reference signal (the timing of receiving the uplink channel from the mobile station MS when there is no deviation). Here, the shift time Ta from the reference signal when the signal S1 transmitted by the mobile station MS is received by the base station is represented by the following equation. Ta = 2 · b / C (b: distance between mobile station and base station,
(C: speed of light) If Ta is larger than a value determined as a parameter, the mobile station MS is located far from the base station and near the boundary of the service area, so that it is determined that there is a possibility of fluttering. On the other hand, if Ta is smaller than the value determined as a parameter, the mobile station MS is located close to the base station and has sufficiently entered the service area, so it is determined that the possibility of fluttering is small.

Next, the mobile station MS moves from the position 33 to the positions 34 and 32 in the zones 21 and 26 at the end of the service area 2.
, The received electric field strength of the mobile station MS there is PA> pa1 PB> pb1. In this case, the mobile station MS can select the mode for both the systems A and B. However, in order to avoid mode switching due to enclaves, the mobile station MS uses a timer to provide hysteresis until the mode is actually switched. Alternatively, if zone 21 is recognized as an enclave by the system, zone 2
If the entry threshold pb1 of 1 is reported as a value larger than the radio wave level from the base station of the system B which is normally received, the mobile station MS at the position 34 cannot select the mode to the system B. For example, when the transmission level from the base station is 10 dB, a value exceeding this (for example, 1
5 dB) may be notified. Further, if the entry threshold pb1 is controlled according to the traffic of the control channel, mode switching can be permitted with a certain probability without causing congestion.

If the mode is switched when the reception line quality is degraded simultaneously with the reception electric field strength, the mode selection can be accurately determined. Alternatively, the reception line quality can be used instead of the reception electric field strength. In addition, if the timer value is notified by the notification information, the value of the hysteresis can be changed.

B: Second Embodiment Configuration of Second Embodiment Hereinafter, the configuration of the second embodiment will be described with reference to the drawings. FIG. 5 shows a system configuration of the second embodiment of the present invention. In this example, a service area 1 for terrestrial cellular telephone is included in a service area 1 for satellite communication. It is assumed that a mobile station 30 capable of switching between these service areas 1 and 2 and communicating with either a satellite communication system or a terrestrial cellular telephone system moves and receives any service of both systems.

The satellite communication radio base station 40 is connected to an exchange 44 via a satellite communication line control station 42, and the terrestrial cellular telephone base station 41 is connected to the terrestrial cellular telephone line control station 4.
3 to the exchange 44. Both control stations 42, 4
Numeral 3 allows access to the location registration memory 45. The exchange 44 is connected to a general telephone network 46.
70 denotes a radio base station antenna for satellite communication, 71 denotes a radio base station antenna of a terrestrial cellular telephone, and 120 denotes a communication satellite.

The mobile station 30 has a radio base station 40 for satellite communication.
, And broadcast information transmitted from the terrestrial cellular telephone base station 41, and selects either the satellite mode or the terrestrial mode. When the satellite mode is selected, the location registration information is transmitted via the communication satellite 120. The satellite communication radio base station 40 sends the position registration transmitted from the mobile station 30 to the satellite communication line control station 42, and the satellite communication line control station 42
Registers that the mobile station 30 is operating in the satellite mode in the position recording memory 45. Similarly, when the mobile station 30 selects the terrestrial mode, the mobile station 30 transmits location registration information to the terrestrial cellular telephone base station 41. The terrestrial cellular telephone base station 41 sends the location registration transmitted from the mobile station 30 to the terrestrial cellular telephone network controller 43, and the terrestrial cellular telephone network controller 43 stores the location registration memory 45 in the mobile station 30. Register that it is operating in mode.

When a call arrives at the mobile station 30, the switching station 44 accesses the location registration memory 45 of the mobile station 30 through the satellite communication line control station 42 or the terrestrial cellular telephone line control station 43, and the mobile station 30 operates in the satellite mode. It reads out whether it is registered in the or ground mode. When registered in the satellite mode, an incoming call is made to the mobile station 30 through the satellite communication radio base station 40, and when registered in the terrestrial mode, an incoming call is made to the mobile station 30 through the terrestrial cellular telephone base station 41. Multiply. That is, the caller can make an incoming call to the mobile station 30 without being aware of the mode in which the mobile station 30 operates.

FIG. 6 shows a configuration example of the mobile station 30. The mobile station 30 comprises a mobile station 34 for satellite communication and a mobile station 35 for terrestrial cellular telephone. In the mobile station for satellite communication 34, a transmitter 55 and a receiver 56 are connected to a satellite communication antenna 72 through a duplexer 80, and a speech coding circuit 91 and a control signal generation circuit 92 are provided on the input side of the transmitter 55. The control signal decoding circuit 93 and the audio decoding circuit 94 are connected to the output side of the receiver 56. The satellite mobile device control circuit 101 controls the transmitter 55, the receiver 56, the voice coding circuit 91, the control signal generation circuit 92, the control signal decoding circuit 93, and the voice decoding circuit 94.

In the terrestrial cellular telephone mobile unit 35, a transmitter 57 and a receiver 58 are connected to an antenna 73 via a duplexer 81, and a speech coding circuit 95 and a control signal generator are provided on the input side of the transmitter 57. A circuit 92 is connected, and a control signal decoding circuit 96, a speech decoding circuit 97,
The reception level detection circuit 99 is connected. Then, the transmitter 57 and the receiver 5 are controlled by the cellular mobile device control circuit 102.
8, a speech encoding circuit 95, a control signal generation circuit 92, a control signal decoding circuit 96, and a speech decoding circuit 97 are controlled.

In this example, a dual mode control circuit 100 is provided in the mobile station 34 for satellite communication, and a dual timer 98 is connected to this. Audio encoding circuits 91 and 9
5, an output side of the audio decoding circuits 94 and 97, a satellite mobile station control circuit 101, a cellular mobile station control circuit 102,
Dual mode control circuit 100 and handset 1
10 are interconnected via a bus 66.

FIG. 7 shows a configuration example of the base stations 40 and 41.
In the satellite communication radio base station 40, the transmitter 51 and the receiver 5
2 is connected to the antenna 70 via the duplexer 82,
A frame configuration circuit 60 is connected to the input side of the transmitter 51. Broadcast information, a call processing signal, mode switching information, and edge information are input to the frame configuration circuit 60. Here, the edge information is information indicating that the mobile station is located at the edge of the service area. In the terrestrial cellular telephone base station 41, a transmitter 53 and a receiver 54 are connected to an antenna 71 via a duplexer 83, and a frame configuration circuit 61 similar to the frame configuration circuit 60 is connected to the input side of the transmitter 53. You. When the mobile station 30 separates the mobile station 34 for satellite communication and operates the terrestrial cellular telephone mobile station 35 in the terrestrial cellular telephone single mode, it becomes a terrestrial cellular telephone mobile station. In the radio base station for satellite communication 40 and the terrestrial cellular telephone base station 41, in addition to the broadcast information, mode switching information and edge information are formed into radio frames by the frame configuration circuits 60 and 61, respectively, and transmitted on the common control channel. FIG.
Shows an example of the configuration of a radio frame. FIG. 8 shows an example in which the edge information, the dual entry level, the dual exit level, and the timer value are transmitted as the mode switching information. However, the mode switching information and the edge information are transmitted only when it is necessary to broadcast the information, and when not transmitted, the mode is idle. Note that the order of transmitting the mode switching information may be changed.

As shown in FIG. 9, a circuit related to dual mode control, that is, a dual mode control circuit 1
00, a dual timer 98 may be provided in the terrestrial cellular telephone mobile unit 35. Further, as shown in FIG. 10, a line quality detection circuit 111 may be connected to the receiver 58 to use the line quality (reception position) as a condition for mode switching. Further, the circuit configuration of the mobile station 30 can be realized by software.

2. Operation of Second Embodiment Next, the operation of the second embodiment will be described with reference to the drawings. FIG. 11 shows the operation when switching from the satellite mode to the terrestrial mode in the second embodiment. Mobile station 30 has selected the satellite mode (S _1), waits for the reception of broadcast information terrestrial cellular telephone mobile station 35 in this state is transmitted from the ground system cellular telephone base station 41 (S _2). Mobile station 3
0 receives the broadcast information, the mode switching information included in the broadcast information is transmitted to the dual mode control circuit 1 of the mobile station 30.
It is checked whether or not the mode switching information is different from the mode switching information stored in 01 (S ₃ ). If it is different, the mode switching information is changed (S ₄ ). Thereby, the dual entry level, the dual exit level, the timer value, and the like can be controlled from the base station side.

Next, it is checked whether or not the level received by the terrestrial cellular telephone mobile unit 35 is higher than the dual mode entry level (S ₅ ). If the level is higher, the edge information is confirmed (S ₆ ). By the edge information, if not a service area end of the ground-based cellular telephone is confirmed, it starts the timer 98 of the dual-mode switching (S _7). The timer value in this case is, for example, about one minute. Thereafter, the system waits for reception of the broadcast information transmitted from the terrestrial cellular telephone base station 41 again (S ₈ ), and the mode switching information of the received broadcast information is transmitted to the dual mode control circuit 1.
It is checked whether it is different from the one stored in 00 (S ₉ ). If different, the dual mode control circuit 10
0 is updated (S
₁₀ ).

Next, it is checked whether or not the level of the signal received from the terrestrial cellular telephone base station 41 is equal to or higher than the dual terrestrial entrance level (S ₁₁ ). If Iriken level or higher, whether the service area terminal of terrestrial-based cellular telephone examined by reference to the edge information (S _12). If service area end, the timer value of the timer 98 is checked whether or larger than the timer value of the broadcast information (S _13). If there is no greater return to the step S _8, step S from step S ₈
Repeat the process up to ₁₃ . When the timer value of the timer 98 is greater than the timer value of the broadcast information, performs location registration on the ground-based cellular telephone switches the mode to the ground system cellular mode (S _14).

Next, a case where the mobile station 30 selecting the terrestrial cellular mode selects the satellite mode will be described with reference to FIG. The mobile station 30 is a terrestrial cellular telephone mobile 35
The reception is performed in the ground mode (S ₁ ), and it is monitored whether the reception level is lower than the dual service level (S ₂ ).
If the level falls below the dual service level, the edge information in the broadcast information of the transmitting ground base station is confirmed (S ₃ ). If it is confirmed from the edge information that the current zone is the end of the terrestrial cellular telephone service area, the satellite communication mobile unit 34 transmits the satellite communication radio base station 40 via the communication satellite. It receives the broadcast information (S _4). If you can not receive the broadcast information transmitted here from satellite radio base station 40, satellite communication, and out of range of each service area of the terrestrial system cellular (S _5).

On the other hand, when the broadcast information transmitted from the satellite communication radio base station 40 is received by the mobile station, the broadcast mode switching information differs from the mode switching information stored in the dual mode control circuit 101. Is checked (S ₆ ). If different, the dual mode control circuit 101
Changing the mode switching information of the inner (S _7). When the notification has been mode switching information matches the mode switching information is stored, checks whether the line quality of the ground system is deteriorated (S _10), if degraded to start a dual-mode timer 98 (S ₁₁ ). This timer value is, for example, about one minute.

[0044] or then the reception level falls below the dual ground system decene level is monitored (S _12). When the reception level falls below decene level, determine to indicate that the edge information in the broadcast information is a service area end of the ground-based cellular (S _13). If the service area terminal checks whether it receives broadcast information from a satellite communication (S _14). If you can receive updates on the received mode switching information that mode switching information in the broadcast information examines whether different which is stored in the dual-mode control circuit 100 (S _15), if different (S _16). Here, when the broadcast information from the satellite communication cannot be received, the mobile station 3
0, it is determined that out of range of each service area of the satellite communication system and ground system cellular system (S _20). When the notification has been mode switching information matches the mode switching information stored in the line quality of the signal from the ground-based cellular base station checks whether or not degraded below a predetermined value (S _17). Dual timer 9 if line quality is degraded
Timer value of 8 is examined whether or become greater than the timer value in the broadcast information (S _18), if not become a large return to the step S _12, the timer value of the dual timer 98 is greater than the timer value in the broadcast information and until, step S from the step S ₁₂
Repeat the process up to ₁₈ . After that, the mobile station 3 for satellite communication
4 by shifts to communication, switching from ground mode to satellite mode (S _19). That is, when the above-described mode switching condition is continuously satisfied and the timer value becomes larger than the timer value of the dual mode switching information, the mode is switched to the satellite mode and the position registration by the satellite communication is performed.

In the above description with reference to FIGS. 11 and 12, an example in which the reception level, line quality, edge information, and timer value are used as the mode switching conditions has been described. One or more arbitrary mode switching information among the reception level, the line quality, the edge information, and the timer value can be used as the mode switching condition. In that case, the conditions described in FIGS. 11 and 12 may be excluded. In the description of FIGS. 11 and 12, the terrestrial cellular telephone mode and the satellite mode can be switched. Furthermore, the satellite communication can be read as another terrestrial cellular telephone different from the terrestrial cellular telephone, and used as a mode switching determination method between two terrestrial cellular telephones.

Next, FIGS. 13 and 14 show examples in which the base station controls dual mode control on a zone basis. The vertical axis represents the reception level of the mobile station 30 and the intersection with the horizontal axis. Indicates the input and output level in the single mode, and the horizontal axis indicates the position of the mobile station 30. Also, the state of the change of the reception level when moving from the zone 21 forming the service area end of the terrestrial cellular telephone to the zone 26 which is not the service area end of the terrestrial cellular telephone is shown.

FIG. 13 shows a conventional case, in which the dual mode entry level is set higher than the dual mode exit level, but these are relatively close. Therefore, in the zone 21, the mode of the mobile station 30 is repeatedly switched between the satellite system and the terrestrial cellular telephone. If there are a large number of mobile stations 30 performing such an operation, the traffic of the control channel may increase and the control channel may become congested. Therefore, in this embodiment, in such a case, the mode switching information (see FIG. 8) transmitted from the base stations 41 in the zones 21 and 26 is changed.
Specifically, as shown in FIG. 14, the dual mode entry level is set to be high, and the dual mode exit level is set to be small.
As a result, a mobile station that has selected the mode for the terrestrial cellular telephone in the zone 21 cannot switch the mode to the satellite mode, and the mobile station that has selected the satellite mode does not switch the mode to the terrestrial cellular telephone. Switching cannot be performed.

The dual mode entry level and the dual mode exit level are changed in the following procedure. First, the terrestrial cellular telephone network controller 43 monitors the traffic of the control channel, and if the traffic exceeds a predetermined value, newly sets the dual-mode entry level and the dual-mode entry level, and sets these to the zones 21 and 26. To the terrestrial cellular telephone base station 41. Thereafter, the newly set dual-mode entry level and the dual-mode entry level are notified from the terrestrial cellular telephone base station 41 to the mobile stations 30 in the zones 21 and 26 as mode switching information. The mode switching parameter is reported from the terrestrial cellular communication base station for the edge information, but the other information may be transmitted from any of the terrestrial cellular communication and the satellite communication base station.

Further, according to the edge information and the use mode,
The timer value for providing hysteresis (delay) for mode switching can also be changed. That is, when the mobile station 30 is in the terrestrial cellular mode and detects the edge information, the timer value is set to, for example, about 1 minute, but when the mobile station 30 detects the edge information in the satellite mode, In this case, the timer value is, for example, about 8 seconds. Thereby, the terrestrial cellular mode is set as much as possible. The timer value when the edge information is not detected in the terrestrial cellular mode is, for example, about 3 minutes, and the timer value when the edge information is detected is longer than about 1 minute. Terrestrial cellular communication is used more preferably than communication.

[0050]

As described above, according to the present invention, when a communication mode is selected, there is an effect that it is possible to suppress fluttering and suppress an increase in control channel traffic due to location registration.

[Brief description of the drawings]

FIG. 1 is a diagram illustrating a state in which service areas of two mobile communication systems partially overlap each other for explaining a conventional technique.

FIG. 2 is a diagram showing a state in which a service area of one mobile communication system includes a service area of another mobile communication system for explaining a conventional technique.

FIG. 3 is a diagram showing a state where there is an enclave in the included service area of FIG. 2;

FIG. 4 is a diagram illustrating an example of a service area of a mobile communication system according to the first embodiment of the present invention.

FIG. 5 is a block diagram illustrating a configuration example of a system according to a second embodiment of the present invention.

FIG. 6 is a block diagram showing a configuration example of a mobile station according to the embodiment.

FIG. 7 is a block diagram showing a configuration example of a base station according to the embodiment.

FIG. 8 is a diagram showing a configuration example of a radio frame according to the embodiment.

FIG. 9 is a block diagram showing another configuration example of the mobile station used in the embodiment.

FIG. 10 is a block diagram showing still another example of the mobile station used in the embodiment.

FIG. 11 is a flowchart showing processing when switching from the satellite mode to the terrestrial mode in the embodiment.

FIG. 12 is a flowchart showing processing when switching from the terrestrial mode to the satellite mode in the embodiment.

FIG. 13 is a diagram illustrating an example of a change in reception level and a mode switching state in a conventional method.

FIG. 14 is a diagram illustrating an example of a change in reception level and a mode switching state when the second embodiment is applied.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Satellite communication system (2nd mobile communication system) 2 Terrestrial cellular communication system (1st mobile communication system) 30 Mobile station 40 Satellite communication radio base station (base station) 41 Terrestrial system cellular telephone base station (base station)

Continuation of front page (72) Inventor Shunichi Kumichi 2-10-1 Toranomon, Minato-ku, Tokyo Inside NTT Mobile Communication Network Co., Ltd. (56) References JP-A-7-226973 (JP, A JP-A-9-116949 (JP, A) JP-A-6-260990 (JP, A) JP-A-3-274926 (JP, A) JP-A-4-185026 (JP, A) (58) Field (Int.Cl. ⁷ , DB name) H04B ^7/ 24-7/26 102 H04Q ^7/ 00-7/38

Claims (10)

(57) [Claims] 1. A service area of a first mobile communication system and a second
The service area of a mobile communication system partially overlaps, and a mode switching of a mobile station that performs communication by switching between a first mode connected to the first mobile communication system and a second mode connected to the second mobile communication system In the method, information having a parameter for mode switching is transmitted from at least one of the first and second mobile communication systems to the mobile station, and the mobile station is configured to transmit the information based on the received parameter of the information. And switching between the first and second modes. 2. The mobile station mode switching method according to claim 1, wherein the parameter includes at least a field strength threshold, wherein the mobile station detects a reception field strength, and detects the detected reception field. A mode switching method for a mobile station, comprising: comparing a strength with the electric field strength threshold, and performing switching between the first and second modes based on a result of the comparison. 3. The mobile station mode switching method according to claim 1, wherein the parameter includes a quality of a received signal, wherein the mobile station detects a quality of the received signal, and detects the quality of the received signal. A mode switching method for a mobile station, wherein the mode is compared with the parameter, and the first and second modes are switched based on a result of the comparison. 4. The mobile station mode switching method according to claim 1, wherein the information includes edge information indicating that the mobile station is located in a boundary area of a service area. The mode switching method for a mobile station, wherein the mobile station switches the first and second modes based on the presence or absence of the edge information and a parameter of the received information. 5. The mode switching method for a mobile station according to claim 2, wherein the mobile station performs a mode switching from when a mode switching condition is satisfied until a predetermined time elapses. A mode switching method for a mobile station, wherein the mode switching is performed when the mode switching condition is maintained. 6. The mobile station mode switching method according to claim 5, wherein the information includes time information indicating a time,
The mode switching method for a mobile station, wherein the mobile station sets the predetermined time based on the time information. 7. The mode switching method for a mobile station according to claim 2, wherein the first mobile communication system is a terrestrial cellular communication system, the second mobile communication system is a satellite communication system, The parameter when switching the mode from the terrestrial cellular communication system to the satellite communication system and the parameter when switching the mode from the satellite communication system to the terrestrial cellular communication system, such that the terrestrial cellular communication system is prioritized. , A mode switching method of a mobile station, wherein each mode is selected. 8. The mode switching method for a mobile station according to claim 2, wherein the first mobile communication system is a terrestrial cellular communication system, the second mobile communication system is a satellite communication system, The strength threshold includes an entry threshold referred to when the mobile station enters, and an exit threshold referred to when the mobile station exits. When the mobile station is not located in the boundary area of the service area, the mobile station may increase the entry threshold or decrease the exit threshold when the mobile station is not located in the boundary area of the service area. Station mode switching method. 9. The mode switching method for a mobile station according to claim 5, wherein the first mobile communication system is a terrestrial cellular communication system, the second mobile communication system is a satellite communication system, The predetermined time when switching the mode from the terrestrial cellular communication system to the satellite communication system is longer than the predetermined time when switching the mode from the satellite communication system to the terrestrial cellular communication system. Mobile station mode switching method. 10. The mode switching method for a mobile station according to claim 5, wherein the first mobile communication system is a terrestrial cellular communication system, the second mobile communication system is a satellite communication system, The mode switching method for a mobile station, wherein the predetermined time when the edge information is detected is shorter than the predetermined time when the edge information is not detected.