JP2005109899A - Radio communication terminal - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a mobile radio terminal capable of making reconnection in a short period of time by eliminating a non-communication state when changing communication systems to make connection in a dual terminal. <P>SOLUTION: This mobile radio terminal is provided with a first communication means for communicating with a first communication system, a second communication means for communicating with a second communication system different from the first communication means, and a control means for transmitting a signal which makes the first communication means to maintain or reestablish a session each time a prescribed period of time passes if the line of data communication is changed to the second communication means when the first communication means establishes the session and performs the data communication with the first communication system. By this, a mobile radio terminal which eliminates a non-communication state and can make reconnection in a short period of time when changing communication systems to make connection is obtained. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to a wireless communication terminal that switches between a plurality of wireless communication functions.

A LAN, which is a network in a company or a home, is particularly popular because of its ease of use. In particular, IEEE802.11b, which is a wireless LAN standard, has become widely used due to higher transmission speeds, lower prices for access points and mobile terminals, and the widespread use of ADSL at home. . In addition, street corner spot services have also been started as a method of using wireless LAN outdoors.
The wireless LAN is a wireless LAN that replaces the conventional connection between terminals with a wired cable. Although the transmission speed of IEEE802.11b is as high as 11 Mbps at maximum, the area of one access point is as narrow as 50 to 100 m in radius. Therefore, the street corner spot service using the wireless LAN is a service in a very limited place.

  On the other hand, mobile phones are becoming more wideband year by year, and third-generation mobile phones achieve a maximum downlink speed of 2.4 Mbps, but are still slower than wireless LANs. However, the service area of one access point in a mobile phone is as wide as about 2 km in radius.

By the way, in the wireless LAN, there is a mobile IP technology in which many access points are installed like a mobile phone and the mobile node can continuously access the mobile node without changing the IP address while walking around the access point ( (See FIG. 7).
Mobile IP includes a home agent (Home Agent) that has an interface on the home link of the mobile node, and a foreign agent (Foreign Agent) that is a router that has an interface on the link to which the mobile node is moving. Have When the mobile node moves, a care-of address is acquired on the destination link, and this care-of address is registered in the home agent via the foreign agent as the destination care-of address. The home agent encapsulates the packet transmitted from the server to the mobile node and transmits it to the care-of address. The foreign agent receives this encapsulated packet and forwards it to the IP address of the mobile node. Therefore, it is possible to transmit a packet to the mobile node existing on the destination link without changing the IP address of the mobile node.

  Some mobile IPs update the road information of the car navigation system using wireless communication. In this case, a method is considered in which a wireless LAN communication unit and a mobile phone are connected to a mobile router of a communication device in a vehicle, and a wireless communication mode to be connected is adaptively switched. When the car enters an area where wireless LAN communication is possible, the mobile router changes the transfer route by registering the care-of address acquired by the wireless LAN from the external link with the home agent. Similarly, when the vehicle is out of the area where wireless LAN communication is possible, the mobile router obtains a care-of address from an external link of mobile phone communication and registers it with the home agent to change the transfer route. This makes it possible to change the transfer route using a plurality of wireless modes without changing the IP address of the communication device in the vehicle.

Based on the above technology, consider a dual mobile radio terminal that connects to a network while switching between a wireless LAN and 1xEV-DO, which is one of the communication specifications of mobile phones. When entering an area where wireless LAN communication is possible, switching from 1xEV-DO to wireless LAN communication can be performed immediately. On the other hand, when switching from wireless LAN communication to 1xEV-DO, if the terminal is not connected to the base station, the connection procedure takes time and a relatively long no-communication state occurs.
However, even if the physical layer is disconnected, it is possible to keep the session without disconnecting, so if 1xEV-DO has established the session, it can be reconnected in a relatively short time. .

Summarizing the switching time from wireless LAN communication to 1xEV-DO, it is the earliest when the physical layer is connected, then the state where the physical layer is disconnected but the session is secured, and finally completely It is in a disconnected state. In order to ensure communication completely, connection of the physical layer must be ensured, and communication must be continuously maintained. Further, 1xEV-DO is disclosed in Patent Document 1 below.
JP 2002-300634 A

  However, if communication is continued continuously, the power of the terminal is consumed. On the other hand, in order to reduce the power consumption of the terminal, it is only necessary to perform communication only when necessary. However, when a connection request is generated from wireless LAN communication to 1xEV-DO, a non-communication state occurs as described above. Will do. For this reason, in order to reduce the power consumption and shorten the no-communication time at the time of switching, it is considered to be excellent to always keep the session even if the physical layer is disconnected.

  The present invention has been made in view of such a point. In a dual terminal, for example, when switching from wireless LAN communication to 1xEV-DO and connecting, it is possible to eliminate the no-communication state and reconnect in a short time. An object of the present invention is to provide a mobile radio terminal that can be used.

  The invention according to claim 1 is a first communication means for communicating with the first communication system, a second communication means for communicating with a second communication system different from the first communication means, and the first communication. Control means for controlling the first communication means and the second communication means so as to be able to communicate with a plurality of communication systems by switching the means and the second communication means, and the first communication means is in session with the first communication system In addition, when the control means switches the first communication means to the second communication means and communicates with the second communication system, the second communication means is changed to the first communication each time a predetermined time elapses. Proposed is a wireless communication terminal comprising: communication control means for switching from the first communication means to transmit a signal for switching to the communication means to maintain the session of the first communication means.

  According to a second aspect of the present invention, in the wireless communication terminal according to the first aspect, the communication control means transmits a signal for maintaining a session of the first communication means, and a signal from the first communication system for the signal. A radio communication terminal is proposed in which the time interval of the predetermined time is controlled based on the response time.

  According to the present invention, for example, when a wireless communication terminal that can be connected to a different communication system such as 1xEV-DO and wireless LAN is in a call by wireless communication other than 1xEV-DO, the base station of 1xEV-DO Since the 1xEV-DO session is continuously secured by controlling the signal transmission interval based on the signal transmission / reception time and the return transmission / reception time, There is an effect that the communication time can be eliminated and the switching time can be shortened.

  Hereinafter, embodiments of the present invention will be described in detail with reference to FIGS. 1 to 7.

  FIG. 1 is a block diagram showing a schematic configuration of a wireless communication terminal 1 according to an embodiment of the present invention. A CPU 10 controls each unit of the wireless communication terminal 1. Reference numeral 11 denotes a 1xEV-DO communication unit, and reference numeral 12 denotes a wireless LAN communication unit, which transmits and receives data using each communication method. A memory 13 stores various data. Reference numeral 14 denotes a ROM (read only memory) for storing an operation program of the CPU 10, and 15 denotes a RAM (random access memory) for temporary data storage. Reference numeral 16 denotes an operation unit such as operation keys, 17 denotes a display unit, and 18 denotes an audio processing unit.

  Next, the operation of the wireless communication terminal 1 configured as described above will be described. The CPU 10 searches for each base station and access point using the 1xEV-DO communication unit 11 and the wireless LAN communication unit 12. When a connectable wireless LAN access point is found, the wireless LAN communication unit 12 starts connection to the access point. When the connection is completed, the wireless LAN communication unit 12 receives data from the outside and sends it to the memory 13 via the CPU 10. In addition, the transmission data stored in the memory 13 is transmitted.

If the CPU 10 cannot find a wireless LAN access point and finds a connectable 1xEV-DO base station, the 1xEV-DO communication unit 11 connects to that base station. Then, similarly to the wireless LAN communication, external data is received and sent to the memory 13, and transmission data stored in the memory 13 is transmitted.
Further, during connection to the 1xEV-DO base station, the CPU 10 periodically searches for a wireless LAN access point via the wireless LAN communication unit 12.

Next, when the 1xEV-DO communication unit 11 is connected to the base station and the wireless communication terminal communicates with a server on the Internet via the 1xEV-DO communication unit 11, the 1xEV-DO communication unit 11 A communication connection request, that is, a session establishment request is made to the station. The base station that has received the session establishment request performs PPP (Point-to-Point Protocol) connection processing to connect to the IP network. This PPP connection processing requires a predetermined time. When the PPP connection process ends, the wireless communication terminal and the server start data communication.
After that, when the wireless LAN communication unit 12 connects to the access point, the CPU 10 of the wireless communication terminal switches the communication path performed with the server to the wireless LAN communication unit 12 via the 1xEV-DO communication unit 11. At this time, the data communication path is switched to the wireless LAN communication unit 12, but the 1xEV-DO communication unit 11 and the base station still establish a session. When the 1xEV-DO communication unit 11 and the base station establish a session, when the wireless LAN communication unit 12 is disconnected from the access point, the time for switching the communication path to the 1xEV-DO communication unit 11 It takes a short time. Therefore, a method for maintaining or re-establishing the session of the 1xEV-DO communication unit 11 to always establish the session of the 1xEV-DO communication unit 11 will be described below.

  When communicating via a wireless LAN, the CPU 10 intermittently transmits a signal attached with a transmission time to a server on the network via the 1xEV-DO communication unit 11. The server on the receiving side sends a response signal for the received signal back to the mobile phone 1. The transmission time described in the signal received from the wireless communication terminal 1 is attached to the response signal.

  The CPU 10 that has received the response signal from the server via the 1xEV-DO communication unit 11 calculates the transmission / reception time from the transmission time attached to the response signal and the reception time of the response signal. Since the signal is transmitted and received intermittently, the transmission time interval between the previous signal and the current signal is controlled based on the calculated transmission / reception time of each signal.

  Here, the approximate reconnection time when the 1xEV-DO communication unit 11 transmits a signal will be described with reference to FIG. In FIG. 2, the transmission time of the signal transmitted by the 1xEV-DO communication unit 11 is Sc (t), the reception time of the response signal to Sc (t) is Rc (t), and before the time of Sc (t), the physical layer Is connected. Rc (t + 1) where Sc (t + 1) is the transmission time of a signal transmitted with a time interval Sw (t + 1), and Rc (t + 1) is the reception time of the response signal to Sc (t + 1). ) Includes a signal transmission interval Sw (t + 1) and an approximate time C (t + 1) required for reconnection. That is, C (t + 1) = (Rc (t + 1) −Rc (t)) − Sw (t + 1).

  A relationship diagram of the reconnection time C with respect to the signal transmission interval time Sw (t) is shown in FIG. Assuming that the transmission interval at which the physical layer connection is continued is T1, the reconnection time is very short as C0 at the transmission interval where Sw (t) is T1 or less. On the other hand, if the transmission interval at which the connection is completely disconnected in both the physical layer and the session layer is T2, the reconnection time is very long as C2 at the transmission interval where Sw (t) is T2 or more. When Sw (t) is a transmission interval between T1 and T2, it becomes C1, which is longer than C0 and shorter than C2.

Next, the operation for controlling the signal transmission interval will be described with reference to FIG.
The first row of FIG. 4 is a graph showing the relationship between the signal transmission time t and the transmission interval Sw (t), the second row is a graph showing the relationship between the signal transmission time t and the reconnection time, and the third row is It is the graph which showed the connection time with the access point required at the time t when switching to 1xEV-DO occurred. Note that the vertical axis of the second graph indicates a value obtained by subtracting the previous reconnection time from the current reconnection time.

  The connection in the session layer of 1xEV-DO is disconnected due to timeout on the base station side when there is no signal transmission / reception for a certain period of time. Assuming that the time when switching from 1xEV-DO communication to wireless LAN connection communication is t1, the CPU 10 gradually increases the transmission time interval of signals transmitted to the 1xEV-DO base station, and the 1xEV-DO communication unit 11 A transmission time interval that does not completely disconnect the connection with the base station is searched. In the present embodiment, the time interval for transmitting a signal is increased to twice the time interval for transmitting the previous signal.

From the second graph, the difference in reconnection time from the previous time is C1-C0 at time t3, so the CPU 10 recognizes that the physical layer of 1xEV-DO has been disconnected. The time interval between times t2 and t3 at this time is determined from the relational expression of (t3−t2) = (t2−t1) * 2.
Further, at time t4, the difference in reconnection time from the previous time is C2-C1. The CPU 10 recognizes that the 1xEV-DO communication unit 11 is completely disconnected from the base station at time t4. The time interval between times t3 and t4 at this time is determined from the relational expression of (t4−t3) = (t3−t2) * 2. The CPU 10 sets the signal transmission time interval short based on this result.

  The transmission time t5 of the next signal adjusts the increment of the time interval based on the time interval (t3−t2) in which the physical layer is disconnected but the connection is not completely disconnected. Specifically, the time interval between times t4 and t5 is (t5−t4) = (t4−t3) − (t3−t2) / 2.

From the second graph, the difference in reconnection time from the previous time at time t5 is zero. This means that the signal transmission time interval is still too much, the connection is cut off, and it is not improved. Therefore, the increment of the time interval is further reduced and the transmission interval is shortened again.
From the second graph, the difference in reconnection time from the previous time at time t6 is − (C2−C1). At time t6, it indicates that the connection was established at C1 earlier than the reconnection time at the previous time t5, and the connection was not completely disconnected. At this time, the time interval between the times t5 and t6 is (t6−t5) = (t5−t4) − (t3−t2) / 4. That is, an operation is performed so as to search for an interval approaching C2 without exceeding C2 from the time when C2 is exceeded.

The graph in the third row shows the connection time with the base station required when switching to 1xEV-DO occurs at time t. The reconnection time in the time zone in which both the physical layer and the session layer are connected is C0. When a predetermined time elapses without the 1xEV-DO communication unit 11 transmitting / receiving a signal, the physical layer is disconnected, and a time zone (light shaded portion) for maintaining the connection in the session layer is generated. The reconnection time at this time is C1. Further, even if a predetermined time elapses, the 1xEV-DO communication unit 11 does not transmit / receive a signal, and when the connection in the session layer times out by the base station, a time zone (dark shaded portion) in which the connection is disconnected occurs. The reconnection time at this time is C2.
Since the time interval for transmitting the signal is adjusted so as to maintain the connection of the session layer as described above, the time period in which the connection is completely disconnected becomes shorter as time elapses.

  As described above, according to the present embodiment, a signal is intermittently transmitted to a 1xEV-DO base station during a wireless LAN communication to secure a 1xEV-DO session. The time required for reconnection is shortened compared to the case where nothing is secured. Further, the occurrence of no communication time, which has been a problem in the method for switching from the wireless LAN to the 1xEV-DO according to the conventional method shown in FIG. 6, can be solved as shown in FIG. In addition, since the reconnection time is calculated from the signal transmission time and the response signal reception time, and the signal transmission time interval is controlled, communication is performed when necessary so that the session is not disconnected, thereby reducing power consumption. Can do.

As mentioned above, although embodiment of this invention was explained in full detail with reference to drawings, the specific structure is not restricted to this embodiment, The design change etc. of the range which does not deviate from the summary of this invention are included.
In addition, the 1xEV-DO communication unit 11 and the wireless LAN communication unit 12 of the present embodiment may be built in the wireless communication terminal or may be attached to and detached from the wireless communication terminal as a card or a module. The wireless communication terminal includes a portable information terminal (for example, PDA), a mobile phone, a personal computer, and the like.

It is a block diagram which shows schematic structure of the radio | wireless communication terminal 1 which concerns on the Example of this invention. It is a figure which shows the rough reconnection time when the 1xEV-DO communication part 11 transmits the signal in the Example. It is a relationship diagram of reconnection time C with respect to signal transmission interval time Sw (t) in the same embodiment. In the embodiment, the signal transmission time and transmission interval Sw (t), the signal transmission time and reconnection time, and the connection time with the base station required at the time t when switching to 1xEV-DO occurs, respectively. It is the shown graph. It is a graph of the connection switching time in the Example. It is a graph of the conventional connection switching time. It is a conceptual diagram of mobile IP.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Wireless communication terminal, 10 ... CPU, 11 ... 1xEV-DO communication part, 12 ... Wireless LAN communication part, 13 ... Memory, 14 ... ROM, 15 ... RAM, 16 ... Operation part, 17 ... Display part, 18 ... Audio | voice Processing unit 100 ... Home agent 101 ... Internet service provider 102 ... Server 103 ... Public network 104 ... External agent 105 ... Router 106 ... External agent 107 ... Router 108 ... Wireless LAN access point 109 ... 1xEV-DO base station, 110 ... 1xEV-DO access terminal, 111 ... wireless LAN mobile node, 112 ... mobile router, 113 ... 1xEV-DO access terminal, 114 ... wireless LAN mobile node, 115 ... Mobile router

Claims (2)

First communication means for communicating with the first communication system;
Second communication means for communicating with a second communication system different from the first communication means;
When the first communication means establishes a session and performs data communication with the first communication system, the data communication path is switched to the second communication means. A wireless communication terminal comprising: a control unit that transmits a signal for maintaining or re-establishing the session to the first communication unit each time it elapses. The communication control unit controls a time interval of the predetermined time based on a transmission time of a signal for maintaining or re-establishing a session of the first communication unit and a response time from the first communication system to the signal. The wireless communication terminal according to claim 1.

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