JP2006339916A - Communication equipment and communication method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide communication equipment and a communication method, enabling easy reception of BCMCS streaming data. <P>SOLUTION: From a 1x base station 30 to each terminal, a page message is transmitted for each slot cycle (64 slots=5.12 sec), of which transmission timing is restricted into a portion of a period (R slot period) in one slot cycle. Further, BCMCS data transmission from an EV-DO base station 20 is performed in another period not overlapped with the above R slot period. In a mobile communication unit 10, when page message reception timing arrives during BCMCS data reception, the communication system of the mobile communication unit 10 is switched from EV-DO to 1x, and the page message is received in the above R slot period. Thereafter, the communication system of the mobile communication unit 10 is restored to 1x, and the BCMCS data reception is resumed. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention can communicate with a base station by switching between different communication methods such as the cdma2000 1x method and the 1xEV-DO method, and can receive broadcast data that is not retransmitted even if a transfer error occurs. The present invention relates to a communication device and its communication method.

  In recent years, mobile phones have become increasingly multifunctional, and high-speed data communication has become possible in addition to voice calls. For example, in addition to a communication method called cdma2000 1x (hereinafter referred to as “1x”) mainly used for voice calls, cdma2000 with an increased data transmission rate in the downlink direction (direction from the base station to the mobile phone). A hybrid type mobile communication system capable of performing high-speed data communication by a communication method called 1xEV-DO (hereinafter referred to as “EV-DO”) is known.

  A terminal that supports this hybrid communication system generally uses one antenna by switching between two communication methods. That is, circuits (hereinafter referred to as RF circuits) that perform processing such as amplification, modulation, demodulation, etc. on RF (radio frequency) signals are provided separately for 1x and EV-DO, respectively. A switching circuit is inserted between the antenna and one antenna. When one RF circuit is connected to the antenna, the other RF circuit is disconnected from the antenna, and therefore cannot communicate simultaneously by two communication methods.

  The above terminal communicates with the base station of the other communication method every 5.12 seconds so that the terminal can receive an incoming call by the other communication method even during the communication of one of the 1x and EV-DO. Is going. For example, when EV-DO data communication is performed, the antenna is switched from the EV-DO RF circuit to the 1x RF circuit every 5.12 seconds, and the communication channel is called a page channel. A message (page message) from the 1x base station to be transmitted is received. In addition, when a 1x voice call is performed, the antenna is switched from the 1x RF circuit to the EV-DO RF circuit every 5.12 seconds to switch to a communication channel called a control channel. A message (overhead message) transmitted from the EV-DO base station is received.

Here, the switching timing from EV-DO to 1x will be described.
Hereinafter, a value in which a time of 5.12 seconds for confirming a message from the base station is expressed in slot units (1 slot = 80 ms) is referred to as a slot cycle. One slot cycle corresponds to 64 slots.

The timing of switching from EV-DO to 1x is determined by a numerical value called “PGSLOT” calculated based on IMSI (international mobile subscriber identity), which is one of numbers for identifying terminals.
The 1x base station divides the time from when the system is started into every 5.12 seconds, and the page message at the time when the above PGSLOT (unit: 80 ms) is offset from the starting point of each division (1 slot cycle). Send. At this time, the terminal communicating with 1x monitors the page channel for one slot (80 ms) and receives a page message to the terminal itself. A terminal communicating with EV-DO also needs to receive the above-described page message from the 1x base station every slot cycle.
FIG. 7 is a diagram illustrating a state in which a message is transmitted from the 1x base station to the page channel at a cycle of 5.12 seconds.

  The reception timing of the page message transmitted from the 1x base station is calculated by the following calculation formula.

  In Equation (1), “t” represents the CDMA system time, and “T” is an integer 4.

  PGSLOT in Formula (1) is calculated by the following calculation formula.

  Each variable in Formula (1) is represented by the following formula.

The IMSI of each terminal is a number for uniquely identifying the user of the communication network, and has a different value for each terminal. Therefore, the switching timing from EV-DO to 1x is uniformly distributed in the range of 5.12 seconds, for example, as shown in FIG.
5. If the page message received every 12 seconds fails several times, the terminal determines that the terminal is out of the communication range of the 1x base station and searches for the 1x base station.
JP 2002-171555 A

  Incidentally, a protocol called BCMCS (broadcast multicast service) that transmits the same data to specific / unspecified terminals on the EV-DO communication network is known. In BCMCS, since the same data can be transmitted to a plurality of terminals using a common communication channel, the communication channel should be used more effectively than when data is transmitted using a different communication channel for each terminal. Can do. Therefore, it is possible to deliver a large amount of data such as news and moving images by streaming.

  The streaming data transmitted by the BCMCS is a continuous packet group that is not interrupted from the beginning to the end, and is transmitted using a protocol such as RTP (real-time transport protocol). In addition, the streaming data is not retransmitted even if a transmission error occurs as in normal 1x or EV-DO communication.

  For example, in the above-described hybrid communication system, when BCMCS streaming data is transmitted by EV-DO, a terminal that receives the streaming data needs to continue to receive data that is not allowed to be retransmitted. Therefore, while receiving streaming data, the antenna cannot be switched to the 1x RF circuit, and there is a high possibility that the page message from the 1x base station will be missed as shown in FIG. If the page message is missed many times, the terminal determines that the terminal has fallen out of the communication range of the 1x base station, and processing such as searching for the base station is started. As a result, reception of streaming data becomes unstable, and a phenomenon occurs in which video and audio data are interrupted.

  The present invention has been made in view of such circumstances, and an object of the present invention is to switch between different communication schemes to communicate with two base stations and to periodically transmit from one base station. A communication device that can stably receive data such as broadcasts transmitted from the other base station while receiving a message, and a communication system in which such a portable communication device can stably transmit data to and from the base station Is to provide.

  A 1st viewpoint of this invention is related with a communication apparatus provided with the 1st communication part which receives broadcast of content intermittently, and the 2nd communication part which switches to the said 1st communication part and is periodically monitored. The communication device includes a switching unit that switches between the first communication unit and the second communication unit, and a control unit that controls the switching.

  Preferably, the control unit estimates a switching time from the intermittent period of the first communication unit and the monitoring time of the second communication unit.

  The estimation may be estimation based on a monitoring timing of the second communication unit.

  The said control part may be made to receive in a 1st communication part based on the program information of the received 1st communication part, and may start the said estimation after completion | finish of reception.

  The monitoring time of the second communication unit may be longer than the reception time of the second communication unit.

  A second aspect of the present invention relates to a communication method using a first communication system that intermittently receives content broadcasts and a second communication system that is switched to the first communication system and periodically monitored. This communication method is characterized in that the switching timing is estimated from the intermittent period of the first communication method and the monitoring time of the second communication method, and the switching is controlled.

  According to the present invention, it is possible to perform communication with two base stations by switching between different communication schemes, and transmit messages from the other base station while receiving messages periodically transmitted from one base station. Data such as broadcasts can be stably received.

FIG. 1 is a diagram illustrating an example of a configuration of a communication system according to an embodiment of the present invention.
The communication system illustrated in FIG. 1 includes a mobile communication device 10, an EV-DO base station 20, and a 1x base station 30.

The portable communication device 10 is connected to the 1x base station 30 by wireless communication, and performs a voice call with another telephone from the 1x base station 30 via a circuit switching network (not shown).
The mobile communication device 10 is connected to the EV-DO base station 20 by wireless communication, and performs data communication with other communication terminals and server devices via a packet switching network such as an IP (internet protocol) network.

  The mobile communication device 10 can perform wireless communication with either one of the EV-DO or 1x base stations, and cannot perform wireless communication simultaneously with both base stations. When a voice call is performed using 1x, the communication method is switched from 1x to EV-DO every 1 slot cycle (64 slots = 5.12 seconds), the control channel is monitored, and transmission is performed from the EV-DO base station 20 Receive messages. When data communication is performed by EV-DO, the communication mode is switched from EV-DO to 1x every slot cycle, the page channel is monitored, and a message transmitted from the 1x base station 30 is received.

FIG. 2 is a diagram illustrating an example of the configuration of the mobile communication device 10.
A mobile communication device 10 illustrated in FIG. 2 includes an antenna 101, an RF switching unit 102, an EV-DO signal processing unit 103, a 1x signal processing unit 104, a CPU 105, and a storage unit 113. Further, as functional blocks realized by software processing of the CPU 105, an EV-DO protocol processing unit 106, a 1x protocol processing unit 107, a stream processing unit 108, a program information control unit 109, a timing calculation unit 110, a timing A detection unit 111 and a control unit 112 are included.

  The EV-DO signal processing unit 103 performs signal processing such as amplification, frequency conversion, analog-digital conversion, demodulation, and the like on the EV-DO reception signal input from the antenna 101 via the RF switching unit 102 and performs the signal processing. The EV-DO reception data obtained as a result of the above is input to the CPU 105. Further, EV-DO transmission data output from the CPU 105 is subjected to signal processing such as modulation, digital-analog conversion, frequency conversion, amplification, and the like, and an RF band transmission signal obtained as a result of the signal processing is transmitted to the RF switching unit 102. To the antenna 101.

  The 1x signal processing unit 104 performs signal processing such as amplification, frequency conversion, analog-digital conversion, demodulation, and the like on the 1x reception signal input from the antenna 101 via the RF switching unit 102, and is obtained as a result of the signal processing. 1x received data is input to the CPU 105. Further, signal processing such as modulation, digital-analog conversion, frequency conversion, and amplification is performed on 1x transmission data output from the CPU 105, and an RF band transmission signal obtained as a result of the signal processing is transmitted from the RF switching unit 102 to the antenna. 101.

  The RF switching unit 102 selects either the EV-DO signal processing unit 103 or the 1x signal processing unit 104 according to the control of the CPU 105 and connects to the antenna 101.

  The CPU 105 performs various processes and controls according to the program code stored in the storage unit 113. For example, functions such as an EV-DO protocol processing unit 106, a 1x protocol processing unit 107, a stream processing unit 108, a program information control unit 109, a timing calculation unit 110, a timing detection unit 111, and a control unit 112 described later are realized by software processing.

  The storage unit 113 stores the program code of the CPU 105 and various data (variable data, constant data, etc.) used in the process of the CPU 105. For example, IMSI or the like is stored as identification information used for terminal identification.

The EV-DO protocol processing unit 106 and the 1x protocol processing unit 107 perform processes related to the EV-DO and 1x communication protocols, respectively. For example, processing such as radio control message processing, framing, and link control is performed.
The four blocks of the RF switching unit 102, the EV-DO signal processing unit 103, the 1x signal processing unit 104, the EV-DO protocol processing unit 106, and the 1x protocol processing unit 107 perform processing from the physical layer to the application layer related to wireless communication. Control.

  The program information control unit 109 obtains available BCMCS program data from the BCMCS controller 80 via the currently connected EV-DO base station 20, and performs BCMCS communication according to the contents of the obtained program data. Control the protocol. The program data includes, for example, information such as transmission start time and end time of BCMCS data, data format, and identification number.

  The stream processing unit 108 decodes image data and audio data included in the BCMCS streaming data acquired from the BCMCS content server 70 via the EV-DO base station 20. Also, a process of displaying the decoded image data as an image on a display device (not shown) and a process of outputting the decoded audio data as a sound on a speaker (not shown) are performed.

  The timing calculation unit 110 calculates the reception timing of the page message transmitted from the 1x base station 30.

FIG. 3 is a diagram for explaining the transmission / reception timing of the page message.
3A to 3D show an example in which the transmission / reception timing of the page message is determined based on the PGSLOT shown in the equation (1). In this case, since the transmission / reception timing is uniformly distributed over the entire period of one slot cycle (64 slots = 5.12 seconds), when the BCMCS streaming data is transmitted seamlessly from the EV-DO base station (FIG. 3 ( A)) The page message transmission by the 1x base station and the streaming data transmission by the EV-DO base station are simultaneously performed (FIGS. 3B to 3D). Since the terminal cannot receive the 1x page message and the EV-DO streaming data at the same time, if both are transmitted at the same time, one of the data is surely missed.

  On the other hand, FIGS. 3E to 3H show examples in which the transmission / reception timing of the page message is limited to a part of the period instead of the entire period of one slot cycle. This is realized, for example, by determining the transmission / reception timing of the page message based on the PGSLOT shown in the following formula (3) instead of the PGSLOT shown in the formula (2).

In the equation (3), “PGSLOT _normal ” indicates the PGSLOT calculated by the equation (2).
'R' is a numerical value indicating a period in which transmission / reception of a page message is performed in one slot cycle (64 slots = 5.12 seconds), and the unit is a slot (1 slot = 80 ms). 'R' is set to a positive integer less than 64.
“Offset” is a numerical value indicating how far the starting point of the period indicated by “R” is separated from the starting point of one slot cycle in time, and the unit is a slot.

When the transmission / reception timing of the page message is determined by PGSLOT shown in Expression (3), the timing of each terminal (portable communication device 10) is changed from the entire period of one slot cycle (64 slots) to a part of the period (period of R slot). (FIGS. 3F to 3H).
As shown in FIG. 3E, the EV-DO base station 20 temporarily stops BCMCS data transmission during the period of the R slot, so that the mobile communication device 10 is receiving BCMCS streaming data. Even if a page message is received, streaming data is not lost.

  For example, the timing calculation unit 110 calculates the PGSLOT represented by the equation (1) based on the IMSI stored in the storage unit 113, and further converts the calculation result into the PGSLOT represented by the equation (3). As a result, the page message reception timing limited to a part of one slot cycle (64 slots) (R slot period) is calculated.

When communication with the 1x base station 30 is started, the timing detection unit 111 detects the arrival of the reception timing of the page message calculated by the timing calculation unit 110.
For example, the timing detection unit 111 acquires the timing of the starting point of the slot cycle from the 1x base station 30 when communication with the 1x base station 30 is started. The timing of this starting point is detected using, for example, a timer function provided in the CPU 105. 5. When the start point of the slot cycle is detected every 5 seconds (64 slots), the timing detection unit 111 further detects a time point away from the start point by the PGSLOT calculated by the timing calculation unit 110, and this is detected as a page. The control unit 112 is notified of the message reception timing.

The control unit 105 performs various processes related to the overall operation of the mobile terminal device 10.
For example, processing related to a communication protocol such as PPP (point-to-point protocol), IP (internet protocol), and TCP (transmission control protocol) is applied to transmission / reception data processed in the EV-DO protocol processing unit 106 and the 1x protocol processing unit 107 I do.

  In addition, when the EV-DO signal processing unit 103 and the EV-DO protocol processing unit 106 are receiving BCMCS data from the EV-DO base station 20, the control unit 112 receives the page message from the timing detection unit 111. When the arrival of timing is detected, the RF switching unit 102 is controlled to switch the connection destination of the antenna 101 from the EV-DO signal processing unit 103 to the 1x signal processing unit 104, and the 1x signal processing unit 104 and the 1x protocol processing unit 107 are switched. Starts receiving operation. Then, the 1x page channel is monitored for a certain time (1 slot), and a page message transmitted from the 1x base station 30 is received. Thereafter, the RF switching unit 102 is controlled so that the connection destination of the antenna 101 is returned from the 1x signal processing unit 104 to the EV-DO signal processing unit 103, and the EV-DO signal processing unit 103 and the EV-DO protocol processing unit 106 Resuming reception of BCMCS data.

  The above is the description of the mobile communication device 10.

Returning to FIG.
The 1x base station 30 establishes a connection with a terminal (mobile communication device 10) by 1x wireless communication, and performs a voice call between the terminal and another telephone via a circuit switching network (not shown). Relay.

The 1x base station 30 transmits a page message every one slot cycle (64 slots = 5.12 seconds) to each connected terminal in order to notify the terminal (mobile communication device 10) of the incoming call. As shown in FIGS. 3F to 3H, the transmission timing of this page message is limited to a partial period (R slot period) in one slot cycle.
For example, the 1x base station 30 acquires the IMSI from each terminal when starting a connection, and calculates the PGSLOT shown in Expression (3) for each terminal based on the IMSI. Then, the transmission timing of the page message for each terminal is determined based on the PGSLOT calculated for each terminal.

  The EV-DO base station 20 establishes a connection with a terminal (mobile communication device 10) by 1x wireless communication, and data communication is performed between the terminal and another terminal or server device via a packet switching network. Relay.

For example, as shown in FIG. 1, network devices such as a PCF 40, a BSN 50, a BCMCS content provider 60, a BCMCS content server 70, and a BCMCS controller 80 are connected to the data communication network to which the EV-DO base station 20 is connected. ing.
The PCF 40 manages EV-DO sessions.
The BSN 50 is a conversion gateway between an IP network and a wireless network corresponding to BCMCS.
The BCMCS content provider 60 is an intermediate server that performs streaming content framing, encryption, encoding processing, and the like.
The BCMCS content server 70 is a streaming content generation point.
The BCMCS controller 80 manages BCMCS sessions and program table data.
The EV-DO base station 20 has a function of transferring BCMCS data sent from the PCF 40 to EV-DO radio frames and transmitting them as radio data.

In addition, when the EV-DO base station 20 transmits the BCMCS data, the BCMCS data is transmitted in a part of one slot cycle (R slot period) in which the page message is transmitted by the 1x base station 30. Transmission is temporarily stopped (FIG. 3E). When the transmission / reception timing of the page message is defined by PGSLOT shown in Expression (3), the period during which the EV-DO base station 20 transmits the BCMCS data is “Offset” to “Offset + R” from the start of one slot cycle;
It is set so as not to overlap with the period of the R slot in the range.

FIG. 4 is a diagram illustrating an example of the configuration of the EV-DO base station 20.
The EV-DO base station 20 includes an antenna 201, an EV-DO signal processing unit 202, a CPU 203, and a storage unit 207, for example, as shown in FIG. In addition, as a functional block realized by software processing of the CPU 203, an EV-DO protocol processing unit 204, a timing control unit 205, and an application processing unit 206 are included.

  The EV-DO signal processing unit 202 performs signal processing such as amplification, frequency conversion, analog-digital conversion, demodulation, etc. on the EV-DO reception signal generated in the antenna 201, and EV-DO obtained as a result of the signal processing The received data is input to the CPU 203. Further, EV-DO transmission data output from the CPU 203 is subjected to signal processing such as modulation, digital-analog conversion, frequency conversion, and amplification, and an RF band transmission signal obtained as a result of the signal processing is supplied to the antenna 201. To do.

  The CPU 203 performs various processes and controls according to the program code stored in the storage unit 207. For example, functions such as an EV-DO protocol processing unit 204, a timing control unit 205, and an application processing unit 206 described later are realized by software processing.

  The storage unit 207 stores the program code of the CPU 203 and various data (variable data, constant data, etc.) used in the process of the CPU 203. For example, the BCMCS data transmitted from the BCMCS content server 70 described above to the terminal is temporarily stored.

  The EV-DO protocol processing unit 204 performs processing related to the EV-DO communication protocol. For example, processing such as radio control message processing, framing, and link control is performed. Two blocks of the EV-DO signal processing unit 202 and the EV-DO protocol processing unit 204 control processing from a physical layer to an application layer related to EV-DO wireless communication.

  The application processing unit 206 performs processing related to a communication protocol such as PPP (point-to-point protocol), IP (internet protocol), and TCP (transmission control protocol) on transmission / reception data processed in the EV-DO protocol processing unit 204. .

  The timing control unit 205 performs processing for instructing the transmission timing of the BCMCS data. For example, as shown in FIG. 3E, the BCMCS data transmission timing is instructed so that it does not overlap with a part of the period of one slot cycle during which the page message is transmitted (period of R slot).

  Here, the operation of the mobile communication device 10 shown in FIG. 2 having the above-described configuration will be described with reference to the flowchart shown in FIG.

Step ST1:
The control unit 112 initializes various internal parameters when the power supply is activated.
When this initialization is performed, the control unit 112 next controls the RF switching unit 102 so that the antenna 101 and the 1x signal processing unit 104 are connected, and the 1x signal processing unit 104 and the 1x protocol processing unit 107 perform the control. 1x communication operation is started. Then, the neighboring 1x base station 30 is searched and negotiated to establish a 1x communication session.

Step ST2:
When the communication session with the 1x base station 30 is established, the timing calculation unit 110 calculates the PGSLOT shown in Expression (3) based on the IMSI stored in the storage unit 113 and stores the result in the storage unit 113.

Step ST3:
Next, the control unit 112 controls the RF switching unit 102 so that the antenna 101 and the EV-DO signal processing unit 103 are connected, and EV-DO by the EV-DO signal processing unit 103 and the EV-DO protocol processing unit 106. Start DO communication operation. Then, the neighboring EV-DO base station 20 is searched and negotiated to establish an EV-DO communication session.

Steps ST4, ST5 and ST6:
The program information control unit 109 acquires program guide data (program information) for receiving BCMCS data from the BCMCS controller 80 via the currently connected EV-DO base station 20 (step ST4). Then, the EV-DO base station 20 is requested for a desired program that can be received from the acquired program guide data (step ST5). In response to this request, the BCMCS data transmitted from the BCMCS content server 70 is transmitted to the mobile communication device 10 via the EV-DO base station 20, and the EV-DO signal processing unit 103 and the EV-DO protocol processing unit 106 are transmitted. This is input to the control unit 112 through the reception process. Then, it is supplied to the stream processing unit 108 under the control of the control unit 112 and reproduced as image data or audio data (step ST6).

Steps ST7 and ST8:
The control unit 112 determines whether or not reception of BCMCS data has been completed. When the reception is completed, the state transits to a predetermined standby state.

Step ST9:
When the reception of BCMCS data has not ended, the timing detection unit 111 monitors whether the current time is a time separated by PGSLOT from the starting point of the slot cycle. If this time has not been reached, the process returns to step ST6 and continues to receive BCMCS data.

Steps ST10, ST11, ST12:
When the timing detection unit 111 detects that the current time is a time separated from the starting point of the slot cycle by PGSLOT, the control unit 112 controls the RF switching unit 102 to switch the antenna 101 to the 1x signal processing unit 104. (Step ST10) The page channel is monitored for a predetermined time (for example, during one slot), and a page message transmitted from the 1x base station 30 is received (step ST11). Thereafter, the RF switching unit 102 is controlled to switch the antenna 101 to the EV-DO signal processing unit 103 again, and the process returns to step ST6 (step ST12).
In step ST9, when it is within the range of the expression (3), the above operation is not performed and the process returns to step ST6.

As described above, according to this embodiment, a page message is transmitted every 1 slot cycle (64 slots = 5.12 seconds) from the 1x base station 30 to each terminal, and the transmission timing is 1 slot cycle. It is limited to a part of the period (R slot period). The reception timing of the page message in the mobile communication device 10 is determined by the PGSLOT of Equation (3) calculated based on the unique identification information (IMSI). The transmission of BCMCS data by the EV-DO base station 20 is performed in another period that does not overlap with the period of the R slot. When the mobile communication device 10 is receiving BCMCS data, when the reception timing specified by PGSLOT in Expression (3) arrives, the communication method of the mobile communication device 10 is switched from EV-DO to 1x, and the R The page message is received during the slot period. Thereafter, the communication method of the mobile communication device 10 returns from EV-DO to 1x, and reception of BCMCS data is resumed.
For this reason, the mobile communication device 10 periodically transmits the BCMCS data that is not subjected to retransmission processing, such as streaming data, periodically from the 1x base station 30 without missing the data. Page message can be received. Thereby, the BCMCS data from the EV-DO base station 20 can be stably received in a state where the connection with the 1x base station 30 is established.

  As mentioned above, although one Embodiment of this invention was described, this invention is not limited only to said form, A various change is possible.

  For example, in the above embodiment, an example using 1x and EV-DO as a communication method with the base station is shown, but the present invention is not limited to this, and the communication method with the base station is arbitrary. is there. Also, the communication method for transmitting streaming data from the base station to the mobile communication terminal is not limited to BCMCS and is arbitrary.

In the switching of the communication method in the RF switching unit 102, there is actually a transition time as shown by 'T _DO ' or 'T _1x ' in FIG. Therefore, it is desirable that EV-DO and 1x reception operations are not performed during this transition time. That is, the EV-DO base station 20 may provide an interval period longer than at least the transition time before and after the R slot period, and stop transmission of BCMCS data during this interval period. Thereby, it is possible to more reliably reduce data loss.

  Since transmission of BCMCS data is stopped during the R slot period, the control unit 112 may temporarily stop the reception process of the EV-DO signal processing unit 103 during this period. Thereby, power consumption can be reduced.

It is a figure which shows an example of a structure of the communication system which concerns on embodiment of this invention. It is a figure which shows an example of a structure of a portable communication apparatus. It is a figure for demonstrating the timing of transmission / reception of a page message. It is a figure which shows an example of a structure of EV-DO base station. It is a flowchart for demonstrating operation | movement of a portable communication apparatus. It is a figure for demonstrating the transition time which arises at the time of switching of the communication system by RF switching part. It is the figure which illustrated a mode that a message was transmitted to a page channel with a 5.12 second period from 1x base station. It is the figure which illustrated a mode that the transmission timing of the page message with respect to each terminal was distributed uniformly in the period of 5.12 seconds. FIG. 6 is a diagram illustrating a situation in which a page message is missed when BCMCS streaming data is received.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 10 ... Portable communication apparatus, 20 ... EV-DO base station, 30 ... 1x base station, 101, 201 ... Antenna, 102 ... RF switching part, 103, 202 ... EV-DO signal processing part, 104 ... 1x signal processing part, 105, 203 ... CPU, 113,207 ... storage unit, 106,204 ... EV-DO protocol processing unit, 107 ... 1x protocol processing unit, 108 ... stream processing unit, 109 ... program information control unit, 110 ... timing calculation unit, 111: Timing detection unit, 112: Control unit, 206: Application processing unit

Claims (6)

A first communication unit that intermittently receives content broadcasts;
In a communication apparatus comprising: a second communication unit that is switched to the first communication unit and periodically monitored.
A switching unit that switches between the first communication unit and the second communication unit;
And a control unit that controls the switching. The communication device according to claim 1, wherein the control unit estimates a switching time from an intermittent period of the first communication unit and a monitoring time of the second communication unit. The communication device according to claim 1, wherein the estimation is estimated based on a monitoring timing of the second communication unit. The said control part makes a 1st communication part receive based on the program information of the received 1st communication part, and starts the said estimation after completion | finish of reception. Communication equipment. The communication device according to any one of claims 1 to 4, wherein the monitoring time of the second communication unit is longer than the reception time of the second communication unit. A first communication method for intermittently receiving content broadcasts;
In the communication method using the first communication method and the second communication method to be monitored periodically by switching,
Estimating the switching time from the intermittent period of the first communication method and the monitoring time of the second communication method,
The communication method characterized by controlling the switching.

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