JPH07107560A - Mobile communications system - Google Patents

Abstract

PURPOSE:To enable continuous speaking by providing an auxiliary system to perform communication mutually between mobile stations, automatically stopping a service by a slave set when there is no disconnecting request by a user and automatically starting an outgoing operation again. CONSTITUTION:When a user generates a call request to a mobile station PS2 by operating an operation key 8, a mobile station PS1 requests connection to the mobile station PS2 by using SCCH and sets the timer start of an alarm report timer. When the elapse of time of two minutes and fifty seconds from the operation state of the alarm report timer is decided, it is informed to a user by a display or a sound that almost three minutes has past after the start of connection between slave sets, and 10 seconds after, the transmission to the mobile station PS2 is temporarily stopped and 2 seconds after, the call is automatically started again. Thus, the connecting and disconnecting operation between the mutual mobile stations are automatically performed, and the operator can continue speech without performing the call operation again.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a mobile communication system, for example, a PHP (Personal Handy Phon) known as a second generation cordless telephone system.
It is used for e).

[0002]

2. Description of the Related Art In recent years, mobile communication systems such as car phones and mobile phones have been put into practical use due to the rapid acquisition of information and the increasing demand for communication tools that can move in space. At present, the development of a second-generation digital cordless telephone (PHP), which is a widely used household / office analog cordless telephone, has been digitized and the function of which has been expanded so that it can be used outdoors, is being advanced.

Further, although the conventional analog cordless telephone supports the call between mobile stations via the base station, in the above mobile communication system (PHP), the transmission method is the TDD method (base station-mobile station). Since the same frequency is time-divisionally processed for upstream and downstream, the direct call between mobile stations (not through the base station) can be easily realized.

[0004]

However, in the above-mentioned mobile communication system, the deterioration of the communication state due to the movement of the mobile station, the avoidance of the interference for preventing the radio wave interference caused by the obstacles, or the communication of the mobile station. In order to prevent monopoly regarding wireless channel allocation, the wireless line must be disconnected once within 3 minutes from the call transmission of the inter-slave communication, and a pause of 2 seconds or more must be taken.

Therefore, the present invention has been made in view of the above problems, and when there is no disconnection request from the user,
It is an object of the present invention to provide a mobile communication system in which a handset automatically stops a call and automatically makes a call again to enable continuous call.

[0006]

Therefore, the present invention provides a mobile system which enables communication between a plurality of mobile stations by receiving a radio channel for communication from a base station having a predetermined communication area, An auxiliary system is provided for communicating between mobile stations without going through the base station, and the auxiliary system has a communication connection state for detecting the communication connection state between the mobile station and the other mobile station communicating with the mobile station. Detecting means, disconnecting means for disconnecting communication connection between the partner mobile station and the mobile station, connecting means for connecting communication between the partner mobile station and the mobile station, and connection of communication by the connection state detecting means The mobile communication system is characterized by including control means for controlling the disconnecting means and the connecting means at a predetermined cycle based on the state.

[0007]

With the above construction, the communication connection state detection means detects the connection state between the mobile stations, and the control means controls the connection means or the disconnection means based on the detected connection state. At this time, the control means connects or disconnects the mobile station and the partner mobile station at a predetermined cycle according to the timing control means. Therefore, unless there is a disconnection request from the operator, the connection and disconnection operations between the mobile stations are automatically performed.

[0008]

As described above, in the present invention, connection and disconnection operations between mobile stations are automatically performed unless disconnection is requested from the operator, and disconnection between mobile stations is once performed. Even if it is performed, the operator does not need to make a call operation again, and there is an excellent effect of providing a mobile communication system capable of continuous communication.

[0009]

The present invention will be described below based on the embodiments shown in the drawings. In this embodiment, a case where the present invention is applied to a PHP system known as a second generation cordless telephone will be described. The block configuration diagram shown in FIG. 1 includes a TDMA method in which one frequency is time-division multiplexed and a time slot is assigned to each telephone, and a TDD method in which the same frequency is used for uplink and downlink between a base station and a mobile station. Is a mobile communication system that employs a multi-carrier TDMA / TDD system of four-channel multiplexing that can multiplex and use a maximum of four lines in one frequency.

In FIG. 1, the mobile station PS1 has a CPU
2, ROM4, RAM6, operation keys 8 for inputting telephone numbers and various commands, a gate array unit 10 including a communication logic circuit group for processing communication data, and an analog signal from the microphone 12 are converted into digital signals. Gate array unit 1
0, and the audio processing unit 16 that converts the digital audio signal from the gate array unit 10 into an analog signal and outputs the analog signal to the speaker 14, and the communication data from the gate array unit 10 at a radio frequency of 1.9 GHz band by π. / 4 shift QPSK (Quadrature Phase Shift Keying) modulation and transmitting from the antenna 18, demodulating the received signal from the antenna 18 and outputting to the gate array unit 10.
A radio section 20 including a demodulation circuit, a reception level detection section 22 for detecting a reception level of a signal received from the antenna 18,
It is configured as a cordless telephone equipped with.

The gate array section 10 is a CPU
2, the control data generated by the CPU 2 and the call voice data converted into the digital signal by the microphone 12 and the voice processing circuit 16 are converted into the communication data for the TDMA transmission, and the wireless unit. 20
Output to. In addition, the reception signal demodulated by the wireless unit 20 is taken in, the call voice data is taken out from the received signal and outputted to the voice processing unit 16, and various control signals are taken out and outputted to the CPU 2.
Then, the CPU 2 controls the gate array unit 10 in accordance with a predetermined process set in advance, based on a command input from the operation key 8 and control data for controlling incoming and outgoing calls from the mobile station PS2. The mobile station 1 and the mobile station 2 shown in FIG. 1 have the same configuration.

Next, the operation of the direct call between the mobile station PS1 and the mobile station PS2 will be described with reference to the flow chart shown in FIG. First, the mobile station PS1 and the mobile station PS2 of the present embodiment enter an idle scan state when the power switch is turned on, detect information regarding all wireless channels, and detect all of the frequencies assigned to the inter-slave communication. By receiving the area, it is detected whether or not there is a request message from another child device. Then, when the user operates the operation key 8 to issue a call request to the mobile station PS2, the processing operation of the flowchart shown in FIG. 2 is started.

In step 100, the mobile station PS1
Starts a connection sequence in the wireless section as shown below in order to obtain an allocation of a channel for voice communication (transmission of voice data, transmission of information necessary for communication) to the mobile station PS2. First, as shown in FIG. 3, the mobile station PS1 sends the mobile station PS2 an SCCH (a point-to-point bidirectional channel that transfers information necessary for call connection between the mobile station and the mobile station). Connection request using mobile station PS
2 to the call message M1. Then, when the calling message M1 is transmitted, the timer start of the warning notification timer in step 110 is set. The warning notification timer is a timer for notifying that the mobile station will be temporarily stopped after a predetermined time has elapsed from the start of the connection sequence with the partner mobile station. The warning notification timer is omitted in the block diagram shown in FIG.

Next, the mobile station PS2 receives this mobile station PS1.
When the paging message M1 from the mobile station PS1 is received,
To notify the mobile station P of the receipt of the paging message M1 by using the SCCH.
Send to S1. When the mobile station PS1 receives this synchronization message M2, it sends a synchronization message M3 using SCCH to notify the mobile station PS2 that the synchronization message M2 has been received. Then, the mobile station PS2 recognizes that the mobile station PS1 has received the synchronization message M2 by receiving the synchronization message M3, and transmits a response message M4 to the mobile station PS1 using the SCCH. Furthermore, the response message M
The mobile station PS1 that has received 4 uses TCH (both point-to-point channel for transferring user information),
Idle burst for frequency and time synchronization is performed. In addition, regarding the call message M1, the maximum transmission time is set to 10 in consideration of battery saving.
Seconds, and the transmission ends when the synchronization message is received from the other party.

In step 120, if the connection is successful based on the state of the connection sequence between the mobile station PS1 and the mobile station PS2 described above, the mobile stations can communicate with each other, and the process proceeds to step 130. If the connection is unsuccessful, the process proceeds to step 135, the warning notification timer is stopped, the idle scan state is set, and information about all wireless channels is detected.

Then, in step 130, it is judged whether or not the preset 2 minutes and 50 seconds have been reached since the operation of the warning notification timer was started. Here, when it is determined that the time from the start of operation of the warning notification timer has reached 2 minutes and 50 seconds, the process proceeds to step 140. When a disconnection request is generated through the operation key 8 between step 100 and step 130, transmission is stopped as an interrupt process and the idle scan state is entered.

In step 140, the user is notified that the connection between the handset units is close to 3 minutes (2 minutes and 50 seconds) from the start of the connection between the handset units by a not-shown display or voice. Therefore, the user has 3
It is possible to recognize that it is close to the lapse of minutes, and to know in advance the stop for 2 seconds that will occur thereafter, so that it is possible to prevent problems due to the stop for 2 seconds.

In step 150, the timer start of the 10 second timer is set. Then, in step 160, it is determined whether 10 seconds have elapsed, and when it is determined that 10 seconds have elapsed, the process proceeds to the next step 170. In step 170, it is determined whether or not a call disconnect request has been issued by the user operating the operation keys 8 or the like for 10 seconds from the start to the end of the 10-second timer. Here, if it is determined that the disconnection request has not occurred, the process proceeds to step 180, and if it is determined that the disconnection request has occurred, step 1
In step 85, the transmission is stopped and the idle scan state is entered.

In step 180, the transmission to the mobile station PS2 is stopped once, and the process proceeds to step 190.
Then, in step 190, the timer start of the 2-second timer is set, and in step 200, it is determined whether or not 2 seconds have elapsed. Here, when it is determined that two seconds have passed, the process proceeds to step 210 and the mobile station P
It is determined whether S1 is the calling side. Then, when the mobile station PS1 is the calling side, the process proceeds to step 220, and at the time of returning to step 100, the mobile station PS2 is automatically set as the partner to be called, and step 10
Return to 0. (On the other hand, when the mobile station PS1 is the receiving side, the process proceeds to step 225, sets only the receivable partner as the mobile station PS2, enters the idle scan state, and waits for a call message from the mobile station PS2. Note that while the call is continuing, step 10
The processing operation from 0 to step 220 is repeated, and the processing operation according to the flowchart is repeated until a disconnection request is issued by the user. Then, when the disconnection request by the user is generated, the transmission is stopped, and the idle scan state is entered.

Therefore, in the present embodiment, the user is informed that the call time limit will be reached, and if there is no disconnection request from the user, the mobile station automatically stops the call,
The call is automatically sent again. Therefore, as long as there is no disconnection request from the operator, the connection and disconnection operations between the mobile stations are automatically performed, and the continuous call can be made possible without the operator again making a call operation.

Further, in the present embodiment, if the disconnection request cannot be detected at the time point 3 minutes after the connection is started, the mobile station PS1 on the transmitting side, in order to smooth the reconnection start operation, The station number of the mobile station PS2 is maintained, and the mobile station PS2, which is the called side, accepts only the call origination request from the mobile station PS1 which has been talking.

In this embodiment, the CPU 2 corresponds to the control means, the reception level detecting section 22 corresponds to the communication connection state detecting means, and step 100 corresponds to the connecting means.
Step 180 corresponds to cutting means.

[Brief description of drawings]

FIG. 1 is a block diagram showing an embodiment of the present invention.

FIG. 2 is a flow chart showing an operation between mobile stations of the present embodiment.

FIG. 3 is a diagram showing a signal flow between mobile stations according to the present embodiment.

[Explanation of symbols]

 2 CPU 22 Reception level detector

Claims (2)

[Claims] 1. A mobile system that enables communication between a plurality of mobile stations by allocating a radio channel for communication from a base station having a predetermined communication area, wherein the mobile system moves without passing through the base station. An auxiliary system for communicating between stations is provided, and in this auxiliary system, a communication connection state detecting means for detecting a communication connection state between the mobile station and a mobile station communicating with the mobile station; Disconnecting means for disconnecting communication connection with the mobile station, connection means for connecting communication between the mobile station and the mobile station, based on the connection state of the communication by the connection state detecting means,
A mobile communication system, comprising: a control unit that controls the disconnection unit and the connection unit at a predetermined cycle. 2. A first elapsed time detecting means for detecting an elapsed time from the start of connection of communication between the partner mobile station and the mobile station; and a disconnection start of communication between the partner mobile station and the mobile station. Second elapsed time detecting means for detecting the elapsed time of, and the cutting means is operated according to the elapsed time detected by the first elapsed time detecting means, and the second elapsed time detecting means detects the elapsed time. The mobile communication system according to claim 1, wherein the control means is provided with timing control means for operating the connection means according to elapsed time.