JP3485479B2 - Mobile communication terminal - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention is advantageously applied to a mobile communication terminal, more specifically a PHS (Personal Handy-Phone System) terminal, and a mobile communication terminal capable of selecting an optimum base station. Regarding

[0002]

2. Description of the Related Art In a so-called mobile communication system such as a mobile phone and a car phone, there is a great feature that communication is possible even when a mobile communication terminal is moving, and it has been rapidly spread in recent years. . As is well known, in a mobile communication system, a base station capable of good communication is appropriately selected from regularly arranged public base stations in order to enable communication even while moving. In wireless communication, such base station selection processing is extremely important for ensuring line quality because the propagation of radio waves is affected by the surrounding conditions and the propagation state of radio waves greatly affects the connection status. Is. Therefore, the mobile communication terminal periodically monitors the incoming control channel burst signals from some public base stations during standby, and performs the standby operation for the base station having the strongest received electric field strength among them. Is programmed to.

Specifically, the mobile communication terminal sequentially monitors a burst signal from a plurality of, for example, about 10 base stations during standby, and a pair of the ID, which is the identification number of the base station, and the received electric field strength. Store each. Then, the mobile communication terminal extracts and selects the ID of the base station having the highest received field strength from the stored received field strengths. After that, the base station of this ID is used as a base station on which the communication terminal waits, and receives all the information notified from this and performs a waiting process. In this way, once the base station is selected, the base station that performs standby processing for this base station until the received electric field strength with this base station falls below a predetermined value or until the power is turned on again. And

On the other hand, a zone within one base station is a waiting zone (holding level), and is a zone in which a telephone call can be made. It is preferable that a base station having a high received electric field strength is selected when an actual telephone call is made. On the other hand, 1
The zones outside the two base stations are handover zones,
When the communication condition is the worst zone and the mobile communication terminal enters this zone, only the control signal transmitted from another base station can be received.

FIG. 6 is an explanatory view showing a state of selecting a base station of a PHS mobile phone in the prior art. In FIG. 6, areas Aa, Ba, and Ca surrounded by dotted circles represent standby zone areas of the base stations A, B, and C, respectively. When the power of the PHS mobile phone 50 is turned on at the point (1), the base station A has the highest received electric field strength here. Therefore, as a result of the monitoring, the base station A is selected and the standby process is started.

While the PHS mobile phone 50 is moving from the point (1) to the point (2), the base station A is provided between the points D ₁ and D _2.
The communication area Aa and the communication area Ba of the base station B overlap each other, but the telephone set 50 selects the base station A until the point D ₂ is passed. Then, when the point D ₂ is passed, the monitoring is performed again, the base station B is selected, and the standby process is started.

Similarly, when the PHS mobile phone 50 moves from the point (2) to the point (3), it moves from the point D _{3 to the} point D _4.
Although the communication area Ba of the base station B and the communication area Ca of the base station C overlap between the points, the telephone set 50 selects the base station B until the point D ₄ is passed. Then, after passing the point D ₄ , the monitoring is performed again, the base station C is selected, and the standby process is started.

[0008]

As described above, in the PHS portable telephone 50 in the prior art, once the base station is selected and in the standby state, the base station of the base station can be operated unless it is out of the communication area of the selected base station. No choice was made.
Therefore, even if the base station having a high received electric field strength is changed due to the movement of the mobile phone 50, the base station is not selected in the place where the communication areas overlap each other, so that the call is not always performed with the optimum call quality. There was a problem that is not always.

The present invention solves the problems of the prior art as described above, and regardless of the reception level of the currently receiving base station,
An object of the present invention is to provide a mobile communication terminal capable of selecting an optimum base station having a high received electric field strength and expecting an improvement in call quality during communication.

[0010]

In order to solve the above-mentioned problems, the present invention relates to a mobile communication terminal which performs monitoring after selecting a power source and selects an optimum base station for standby processing.
It has a base station selection key for selecting an optimum base station having the highest received electric field level among receivable base stations. And
When the base station selection key is operated, new monitoring is performed even during the standby process, and the optimum base station selection process is performed.

Further, according to the present invention, a method for selecting a base station of a mobile communication terminal for performing a standby process by monitoring after selecting the optimum base station after power is turned on is a method for selecting a base station of a mobile communication terminal. It is detected whether or not it is lower, and when it is lower, monitoring is performed to select the base station having the highest received electric field level among the receivable base stations, and the transmission processing is performed to the selected base station.

Further, according to the present invention, in the method of selecting a base station of a mobile communication terminal for performing monitoring and selecting an optimum base station to perform standby processing, the mobile communication terminal has a function of performing data communication with a data terminal. Is equipped with. When the mobile communication terminal receives from the data terminal a data communication start signal indicating that the mobile terminal starts data communication with the data terminal, monitoring is performed and the base station with the highest received electric field level is selected from among the receivable base stations. To do.

Further, according to the present invention, in the method of selecting a base station for a mobile communication terminal for monitoring, selecting an optimum base station and performing standby processing, the mobile communication terminal is mounted on a charger for charging. Then, monitoring is performed to select the base station having the highest received electric field level among the receivable base stations.

[0014]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of a mobile communication terminal according to the present invention will be described in detail with reference to the accompanying drawings. FIG. 1 shows a mobile communication terminal according to the present invention as a PHS mobile phone 1.
It is a functional block diagram which shows 1st Embodiment when applied to 0. The antenna 12 radiates or receives a radio wave in order to exchange data with a public base station (not shown) corresponding to the standby zone. This antenna 1
The RF unit 14 is connected to the unit 2.

The RF unit 14 amplifies and frequency-converts the signal received by the antenna 12 and outputs a demodulation signal to the baseband unit 16, and the baseband unit 1.
And a transmission circuit that amplifies and frequency-converts the voice modulation signal from 6 and outputs it to the antenna 12.
The baseband unit 16 includes a CPU 18 and a codec 28.
The RF signal received from the antenna 12 including the voice signal and the caller number is demodulated under the control of the CPU 18. The baseband unit 16 also notifies the CPU 18 of the ID, which is the identification number of the public base station received by the RF receiving circuit during standby when the power is on, and the received electric field strength thereof.

The codec 28 is a converter that converts a digital signal into an analog signal and an analog signal into a digital signal. That is, the codec 28 is the CPU 1
Under the control of 8, the digital audio signal input from the baseband unit 16 or the CPU 18 is converted into an analog signal and output to the speaker (SP) 26, and the microphone (MI
C) The analog voice signal input from 24 is converted into a digital voice signal and output to the baseband unit 16. The codec 28 is also connected to the DTMF receiver 30, converts the digital signal input from the baseband unit 16 into an analog signal, and outputs the analog signal to the DTMF receiver 30. DT
When the signal input from the codec 28 is a DTMF signal, the MF receiver 30 outputs the content to the CPU 18.

The CPU 18 is a control unit that controls the entire mobile communication terminal, and includes a ROM 18a, which is a non-volatile memory in which programs and the like are written, and a RAM.
18b is built in. The RAM 18b temporarily stores various information including information on the base station selected as the base station during standby. The CPU 18 has a display unit 20 for displaying a telephone number or the like and a received electric field strength of the base station.
And an input key or power key to enter a phone number, letters, etc.
A key input unit 22 composed of various keys such as a call key for performing a call process is connected.

The CPU 18 has a base station selection key 21
Are connected. When the base station selection key 21 is operated, the CPU 18 newly performs monitoring even during standby, and selects the base station having the highest received electric field level among the receivable base stations. Then, the selected base station is newly stored in the RAM 18b as a standby base station. Although the base station selection key 21 is shown as a single key in FIG. 1, a hook switch or the like for making or answering a call may be used instead of such a single key. When the hook switch is used, the base station is selected by, for example, pressing the switch twice in succession.

FIG. 2 shows the PHS mobile phone 10 shown in FIG.
3 is a flowchart showing the operation of the first embodiment of FIG. The operation of the first embodiment will be described below with reference to FIGS. 1 and 2. When the PHS mobile phone 10 shown in FIG. 1 is powered on (S102), the PHS mobile phone 10 performs the following processing in order to select a base station in the wireless radio zone.

The PHS mobile phone 10 is capable of communicating 10
Sequentially monitoring the number of public base stations (S10
4) Obtain the monitored base station ID and its received electric field strength. The process of step S104 is performed until the base station search time expires (S106), and a pair of the base station ID and its received electric field strength, which are the monitor results obtained as a result, are stored in the RAM 18b in the CPU 18 (S108). . If an abnormality is detected in step S106, the monitoring is performed again (S12).
2) and returns to step S104.

When the monitoring result is stored in the RAM 18b, the number of monitored base stations and the electric field strength are determined (S110). As a result of the determination, if there is no base station that can be monitored or if the electric field strength or the like does not reach the threshold value, out-of-range processing is performed (S124). If the out-of-range process is a monitoring process when the power is turned on, after the out-of-range timer time expires (S126), the process returns to step S104 again to perform monitoring. Further, in the case of the monitoring process by the base station selection key 21 described later, when the out-of-service process of step S124 is performed, the display unit 20 displays that it is out of service, and then again performs step S1.
Return to 04 for monitoring. On the other hand, step S11
When it is determined that there is a base station that can be monitored at 0, it is determined whether or not the number of base stations is appropriate (S112).

In the first embodiment, about 10 base stations are monitored. Therefore, if the number to be monitored exceeds 10, the control data for selecting the base station is changed (S130). When the number of base stations is appropriate in step S112, the best base station is selected from the selected base stations (S114), and the selected base station is RA.
It is stored in M18b as a base station for performing the standby process (S116). If the base station selection key 21 is operated during the standby process of step S116 (S
117), the process returns to step S104, and the standby process is executed again to select the base station having the highest reception electric field level among the receivable base stations.

If an incoming / outgoing call is received during the standby process of step S116 (S118), step S1
The communication channel is established by the base station selected in the standby process of 16, and the call is started (S128).
If it is after the operation of the base station selection key 21 in step S117, the communication channel establishment process is performed by the base station selected thereby, and the call is started. On the other hand, when there is no incoming / outgoing call in step S118 and the received electric field strength of this base station becomes equal to or lower than the threshold value (S120), the process returns to step S104 and the process of selecting a base station to newly perform the standby process is executed again.

FIG. 3 is an explanatory diagram showing how a base station is selected when the PHS mobile phone 10 according to the first embodiment is used. In FIG. 3, areas Aa, Ba, and Ca surrounded by dotted circles represent standby zone areas of the base stations A, B, and C, respectively. PHS mobile phone 1
For 0, when the power is turned on at the point (1), the base station A has the highest received electric field strength here, and as a result of the monitoring, the base station A is selected and the standby process is started.

While the PHS mobile phone 10 is moving from the point (1) to the point (2), the base station A is provided between the points D ₁ and D _2.
The communication area Aa of B and the communication area Ba of the base station B overlap. In the prior art, in this area, the base station A is selected as the base station that performs the standby process, but in the present embodiment, the base station selection key 21 (see FIG. 1) is selected in this area.
When is operated, one of the base stations A or B having a higher received electric field strength is appropriately selected. Therefore, a more stable and favorable call can be made as compared with the related art. When the base station A is selected when the PHS mobile phone 10 passes through the point D _{2, the} monitoring is performed again as in the conventional technique, and the base station B having the highest received electric field strength is selected to perform the standby processing. to go into.

Next, the PHS mobile phone 10 is at the point (2).
Moving the point (3) from the communication from the D ₃ point D ₄ point between the communication areas Ba and the base station C of the base station B Area C
a overlaps. Therefore, when the base station selection key 21 is operated in this area in the same manner as described above, one of the base stations B or C having a higher received electric field strength is selected. Then, when the base station B is selected when passing the point D ₄ , the monitoring is performed again, and the base station C having the highest received electric field strength at this point is selected and the standby process is started.

As described above, according to the above embodiment, the PH
By operating the base station selection key 21 while the S mobile phone 10 is on standby, regardless of the received electric field level of the base station that is currently receiving, this mobile phone 10 is the most receivable base station at that location. A base station having a high received electric field level is selected to perform a standby operation. Therefore, the PHS mobile phone 10 can be operated by simply operating the base station selection key 21.
It is possible to select the base station that can make the most stable call.

When a new base station is selected by operating the base station selection key 21 again and a new base station is selected, the level change with the reception electric field strength of the previously set standby base station is displayed on the display section. 20 may be displayed, or by displaying a display indicating that it is the optimum standby base station on the display unit 20, it is possible to inform the user that the call quality has been appropriately improved.

FIG. 4 and FIG. 5 show operation flows showing a second embodiment in which the mobile communication terminal according to the present invention is applied to a PHS mobile phone. In the embodiment shown in these figures, the base station selection key 21 as shown in FIG.
If the received electric field strength is lower than a predetermined level and is unstable at the time of calling, the base station monitoring processing is automatically performed and a base station having a stable received electric field strength is automatically selected.

The circles A and B in FIG. 4 and FIG. 5 are connected to each other to form a series of operation flows. Further, in FIGS. 4 and 5, steps having the same reference numerals as those in FIG. 2 are the same processing, and therefore, duplicated description will be omitted here. Further, the second embodiment has a configuration excluding the base station selection key 21 of FIG. 1 and the other components are the same, so description using the functional block diagram is omitted here.

After the power is turned on, when a transmission operation is performed in the standby process of step S116 (S140), it is detected whether the received electric field level is lower than a preset set value (S144). This set value is set in step S120.
It is set to a value higher than the threshold value shown in. Specifically, for example, one bar and 0 indicating the received electric field strength next to the antenna mark displayed on the display unit of the PHS mobile phone are displayed.
Set to a value between the books.

If the received electric field level is lower than the preset value in step S144, the receivable base stations are monitored and the base station having the highest received electric field level is selected (S146). And step S
By the base station selected in the re-standby processing of 146,
A communication channel is established and a call is started (S14).
8). Specifically, in step S144, step S1
The processing shown in 04 to S116 until the standby base station is selected is performed. Then, the base station having the highest received electric field level selected by this processing performs the control channel establishment processing and performs the transmission operation.

FIG. 7 shows a mobile communication terminal according to the present invention.
It is a functional block diagram which shows 3rd Embodiment applied to the S mobile telephone. The PHS mobile phone 50 according to this embodiment has a function of performing data communication with a data terminal (not shown) such as a personal computer, and transmits data received from the data terminal by the PHS mobile phone 50 or via a network. The received data can be transmitted to the data terminal. In order to realize such a function,
The PHS mobile phone 50 includes a baseband unit 16 and a CPU.
A data communication connector 19 is provided which is connected to 18 and has an interface connectable to a data terminal.

The terminal of the data communication connector 19 has a PH
S A data signal transmitted / received via the mobile phone 50, a signal for controlling incoming / outgoing call of the mobile phone 50, and a data communication start signal for notifying the mobile phone 50 of activation at the start of data communication are input. . The data signal input to the terminal of the data communication connector 19 is sent to the baseband unit 16, and the signal for controlling incoming / outgoing call and the data communication start signal which are also input to this terminal are the CPU.
Sent to 18.

When data communication is performed using the PHS mobile phone 50, a data communication start signal is sent from the data terminal to the mobile phone 50 side prior to starting communication.
When the CPU 18 receives this data communication start signal, C
The PU 18 performs the same process as when the base station selection key 21 is pressed, that is, performs monitoring to select an optimum base station.

As described above, according to the third embodiment,
Since monitoring is performed at the time of starting the data communication and the optimum base station selection processing is performed, optimum data communication with few errors becomes possible when actually starting the communication. Note that, in the processing flow of the third embodiment, if "data communication start signal" is received instead of "press base station selection key" in step S117 shown in FIG. Since the operation is the same as the operation described above, duplicate description will be omitted here.

FIG. 8 shows a mobile communication terminal according to the present invention as P.
It is a functional block diagram which shows 4th Embodiment applied to the HS mobile telephone. The PHS mobile phone 60 according to this embodiment includes the charge detection unit 23 that notifies the CPU 18 that the PHS mobile phone 60 is attached to the charger. This charge detector 2
3, one end is connected to the CPU 18, and the other end is connected to the charging terminal and the battery anode.

The charging detection unit 23 is a PHS mobile phone 60.
When is attached to the charger, it detects that the battery is in a charged state based on the voltage applied to the charging terminal, and notifies the CPU 18. When the CPU 18 detects this notification, the PHS mobile phone 60 performs monitoring to select the optimum base station.

When the PHS mobile phone is charged, for example, at home or in the office, the mobile phone is usually in a standby mode so that it can be answered when an incoming call arrives. Since the mobile phone does not move when it is mounted on the charger, the mobile phone selects the base station captured before being mounted on the charger as the standby base station. Therefore, in the related art, even if there is another base station having a strong electric field strength at the location where the charger is installed, the optimum base station is not selected.

In consideration of such a situation, in the fourth embodiment, monitoring is performed at the time when the mobile phone 60 is attached to the charger, and the optimum base station is selected. Therefore, even if there is an incoming call during charging, it is possible to always make a call with optimum call quality. In the case of the fourth embodiment as well, if "attach to charger" is used instead of "press base station selection key" in step S117 shown in FIG. 2, other operations will be described using FIG. Since it will be the same as the operation you did,
Overlapping description will be omitted here.

As described above, the present invention can be applied to any of the first to fourth embodiments.
Although the embodiments have been described as examples, these embodiments may be combined as appropriate to be incorporated as a function of one mobile communication terminal. Further, in these embodiments, the present invention is
Although the present invention is applied to the HS mobile phone, the present invention is not particularly limited to the PHS mobile phone, and can be applied to, for example, a PHS personal digital assistant (PDA). Furthermore, PH
It is also applicable to mobile phones other than S or mobile information terminals.

[0042]

As described above, according to the present invention, the mobile communication terminal can select the optimum base station having a high received electric field strength regardless of the reception level of the base station currently receiving. Therefore, it becomes possible to select a more appropriate base station as compared with the conventional technique, and it is expected that a more stable call can be performed.

[Brief description of drawings]

FIG. 1 is a functional block diagram showing a first embodiment in which a mobile communication terminal according to the present invention is applied to a PHS mobile phone.

FIG. 2 is a flowchart showing an operation in the embodiment shown in FIG.

FIG. 3 is an explanatory diagram showing how a base station is selected according to the present embodiment.

FIG. 4 is a flowchart showing a second embodiment in which the mobile communication terminal according to the present invention is applied to a PHS mobile phone.

FIG. 5 is a flowchart showing a second embodiment in which the mobile communication terminal according to the present invention is applied to a PHS mobile phone.

FIG. 6 is an explanatory diagram showing how a base station is selected in the conventional technique.

FIG. 7 is a functional block diagram showing a third embodiment in which the mobile communication terminal according to the present invention is applied to a PHS mobile phone.

FIG. 8 is a functional block diagram showing a fourth embodiment in which the mobile communication terminal according to the present invention is applied to a PHS mobile phone.

[Explanation of symbols]

14 RF section 16 Baseband section 17 Data communication connector 18 CPU 18a ROM 18b RAM 20 Display 21 Base station selection key 22 Key input section 23 Charge detector 25 battery

─────────────────────────────────────────────────── ─── Continuation of the front page (56) Reference JP-A-2-206232 (JP, A) JP-A-5-48528 (JP, A) JP-A-8-294174 (JP, A) JP-A-7- 284142 (JP, A) JP 7-322357 (JP, A) JP 9-121379 (JP, A) (58) Fields investigated (Int.Cl. ⁷ , DB name) H04Q 7/00-7 / 38

Claims (4)

(57) [Claims] 1. A method of selecting a base station for a mobile communication terminal, which performs monitoring after power-on and selects an optimum base station to perform standby processing, in a method of determining whether a received electric field level is lower than a preset value at the time of transmission. If the detected value is low, the monitoring is performed to select a base station having the highest received electric field level among receivable base stations, and a transmission process is performed to the selected base station. Method for selecting base station of communication terminal. 2. The base station selection method according to claim 1 , wherein the value preset as the reception electric field level is such that the reception electric field strength of the base station selected during the standby processing falls below a threshold value, and A method for selecting a base station for a mobile communication terminal, wherein the value is higher than this threshold value for starting monitoring. 3. A method of selecting a base station for a mobile communication terminal, which monitors and selects an optimum base station to perform standby processing, wherein the mobile communication terminal has a function of performing data communication with a data terminal, When the communication terminal receives from the data terminal a data communication start signal indicating that the communication terminal starts data communication with the data terminal, the monitoring is performed to select the base station having the highest received electric field level among the receivable base stations. A base station selection method for a mobile communication terminal, comprising: 4. A method of selecting a base station for a mobile communication terminal which performs monitoring and selects an optimum base station to perform standby processing, wherein when the mobile communication terminal is attached to a charger for charging, the monitoring is performed. A method of selecting a base station for a mobile communication terminal, comprising selecting a base station having the highest received electric field level among receivable base stations.