JP2004165979A - Mobile communication terminal device and mobile communication method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a mobile communication terminal device which can stabilize the connection of a radio link, and also to provide a mobile communication method therefor. <P>SOLUTION: A data receiver 106 receives a signal using a frequency f1 allocated to its own cell, generates receive data, and outputs it to a controller 110. The controller 110 decides whether or not transmission of a random access channel (RACH) is expected to end in failure on the basis of the receive data. The controller 110, according to a result of the decision, temporarily stops the RACH transmission, and generates a control signal to control the execution or non-execution of self searching operation using a frequency different from the frequency f1 during the stop period of the RACH transmission. A random access channel transmitter 104 transmits the RACH according to the control signal. A self searcher 108 executes the self searching operation using the frequency different from the frequency f1 during the stop period of the RACH transmission according to the control signal. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a mobile communication terminal device and a mobile communication method in a mobile communication system.
[0002]
[Prior art]
The mobile communication system has a configuration (cell configuration) in which a service area is covered by a plurality of base station devices. Prior to cell switching (handover) due to movement, a mobile communication terminal apparatus (mobile station apparatus) searches and measures neighboring cells (hereinafter referred to as “cell search”) to select a cell to be switched. In a mobile communication system using a code division multiple access (CDMA) system, communication with a plurality of cells (soft handover) can be performed simultaneously at the time of handover. For this reason, the normal cell search is performed using the same frequency as the frequency assigned to the cell in communication. On the other hand, in the case of a mobile communication system in which a mobile communication system in which allocated frequencies have different configurations between cells and a mobile communication system using different frequencies are adjacent to each other, it is necessary to perform a cell search using each of a plurality of frequencies. There is.
[0003]
When establishing a wireless link connection with a base station apparatus, a conventional mobile communication terminal apparatus transmits a random access channel (RACH), which is an uplink common channel, to the base station apparatus (for example, see Patent Document 1). ). The base station apparatus transmits a synchronization detection indication channel (AICH: Acquisition Indication Channel), which is a downlink common channel, to the mobile communication terminal apparatus in response to the RACH transmission, and notifies the mobile communication terminal apparatus whether or not the RACH has arrived. I do. When transmitting the RACH, the mobile communication terminal device needs to receive the AICH at the frequency allocated to the currently connected cell (hereinafter, referred to as “own cell”). When the mobile communication terminal apparatus has only one receiving system, it is impossible to perform a cell search for a cell to which a frequency different from that of the own cell is allocated at the time of RACH transmission.
[0004]
Here, a cell search using each of a plurality of frequencies in a conventional mobile communication terminal device will be described with reference to the drawings.
[0005]
FIG. 6 is a block diagram showing an example of a configuration of a conventional mobile communication terminal device. Mobile communication terminal apparatus 600 shown in FIG. 6 includes antenna 602, transmitting section 604, receiving section 606, cell search section 608, random access control section 610, and cell search control section 612.
[0006]
Transmitting section 604 transmits RACH via antenna 602. The random access control section 610 controls the transmission section 604. Further, when controlling the transmission section 604, the random access control section 610 notifies the cell search control section 612 that a RACH transmission process is to be performed. Cell search control section 612 controls cell search section 608 based on the notification from random access control section 610. Receiving section 606 receives a signal (AICH) transmitted from the base station apparatus via antenna 602 and generates reception data. The cell search unit 608 performs a cell search.
[0007]
Next, the operation of mobile communication terminal apparatus 600 having the above configuration will be described. FIG. 7 is a diagram for explaining an example of a RACH transmission and a cell search operation using each of a plurality of frequencies in a conventional mobile communication terminal apparatus.
[0008]
The cell search unit 608 performs a cell search using each of a plurality of frequencies. Specifically, as shown in FIG. 7, the cell search unit 608 performs a cell search for the cell to which the frequency f1 has been assigned using the frequency f1 assigned to the own cell in a predetermined period. Then, the cell search unit 608 repeats the cell search for the cell to which the frequency f1 is assigned at a predetermined interval. The cell search unit 608 performs a cell search for a cell to which a frequency different from the frequency f1 is assigned in the interval. Hereinafter, a plurality of frequencies different from the frequency f1 will be described as frequencies fN, fN + 1,... (N is an integer of 2 or more).
[0009]
The random access control unit 610 controls the transmitting unit 604 so as to transmit the RACH, which is an uplink common channel, when there is a request for transmission of the RACH. The RACH transmitted by the transmitting unit 604 is composed of a preamble and a message as shown in FIG. In response to the transmission of the preamble, the base station apparatus of the own cell transmits the AICH, which is a downlink common channel. The receiving unit 606 needs to receive the AICH using the frequency f1 of the own cell. Therefore, first, random access control section 610 notifies cell search control section 612 that the RACH will be transmitted. Then, based on the notification from the random access control unit 610, the cell search control unit 612 does not perform the cell search for the cells to which the frequencies fN, fN + 1,. The cell search unit 608 is controlled to perform only That is, the conventional mobile communication terminal apparatus 600 always unconditionally sets the transmission of the RACH to the base station apparatus of the own cell rather than the cell search for the cell to which a frequency fN, fN + 1,... Has priority.
[0010]
[Patent Document 1]
JP 2001-313968 A (pages 4-6)
[0011]
[Problems to be solved by the invention]
However, under a bad propagation environment, the RACH transmitted from the mobile communication terminal device may not reach the base station device of the own cell, and the mobile communication terminal device may have a different frequency from the current own cell to the current own cell. Although it may be easier to establish the connection of the radio link by transmitting the RACH after switching to the cell to which is assigned, since only the frequency of the own cell can be used during the transmission of the RACH, However, there has been a problem that establishment of a wireless link connection is unstable.
[0012]
The present invention has been made in view of the above, and an object of the present invention is to provide a mobile communication terminal device and a mobile communication method capable of stably establishing a wireless link connection.
[0013]
[Means for Solving the Problems]
The mobile communication terminal device according to the present invention includes: a cell search unit that performs a cell search using each of a plurality of frequencies; and a reception unit that receives a signal using one of the plurality of frequencies to generate reception data. Transmitting means for transmitting a random access channel, and temporarily stopping transmission processing of the random access channel based on the reception data generated by the receiving means, and setting the plurality of frequencies during a suspension period of the transmission processing. And a control means for controlling the transmission means and the cell search means so as to control whether or not to perform a cell search using another frequency.
[0014]
According to this configuration, not only the transmitting unit that transmits the random access channel based on the reception data generated by the receiving unit but also the cell search unit that performs the cell search using each of the plurality of frequencies is controlled. Since it is possible to prioritize the transmission process of the random access channel and the cell search using other frequencies depending on whether the transmission process of the random access channel is expected to fail based on the received data, The establishment of a wireless link connection can be stabilized.
[0015]
In the mobile communication terminal device of the present invention, in the above configuration, the control unit includes a reception level measurement unit that measures a reception level based on the reception data generated by the reception unit. The transmission process of the random access channel is temporarily stopped when the measured reception level is equal to or less than a predetermined value, and a cell search is performed using another frequency of the plurality of frequencies during a suspension period of the transmission process. A configuration is employed in which the transmission means and the cell search means are controlled so as to be performed.
[0016]
According to this configuration, in addition to the above effects, the reception level is measured based on the reception data, and when the measured reception level is equal to or lower than a predetermined value, the transmission process of the random access channel is temporarily stopped to perform transmission. Since the transmission means and the cell search means are controlled to perform a cell search using another frequency of the plurality of frequencies during the suspension period of the processing, the transmission processing of the random access channel fails based on the measured reception level. In such a case, the cell search using another frequency can be prioritized over the transmission processing of the random access channel, so that the establishment of the wireless link connection can be stabilized.
[0017]
In the mobile communication terminal device of the present invention, in the above-described configuration, the control unit includes a reception quality measurement unit that measures reception quality based on the reception data generated by the reception unit. When the measured reception quality is equal to or less than a predetermined value, temporarily stop transmission processing of the random access channel, and perform a cell search using another frequency of the plurality of frequencies during a suspension period of the transmission processing. A configuration is employed in which the transmission means and the cell search means are controlled so as to be performed.
[0018]
According to this configuration, in addition to the above effects, the reception quality is measured based on the reception data, and when the measured reception quality is equal to or less than a predetermined value, the transmission process of the random access channel is temporarily stopped and transmitted. Since the transmitting means and the cell searching means are controlled to perform a cell search using another frequency of the plurality of frequencies during the suspension period of the processing, the transmission processing of the random access channel fails based on the measured reception quality. In such a case, the cell search using another frequency can be prioritized over the transmission processing of the random access channel, so that the establishment of the wireless link connection can be stabilized.
[0019]
In the mobile communication terminal device of the present invention, in the above configuration, the control means includes a propagation loss calculating means for calculating a propagation loss based on the received data generated by the receiving means, and When the calculated propagation loss is equal to or greater than a predetermined value, temporarily stop the transmission process of the random access channel and perform a cell search using another frequency of the plurality of frequencies during a suspension period of the transmission process. A configuration is employed in which the transmission means and the cell search means are controlled so as to be performed.
[0020]
According to this configuration, in addition to the above effects, a transmission loss is calculated based on the received data, and the transmission process of the random access channel is temporarily stopped when the calculated transmission loss is equal to or more than a predetermined value. In order to control the transmission means and the cell search means to perform the cell search using other frequencies of the plurality of frequencies during the suspension period of the transmission processing, the transmission processing of the random access channel is performed based on the calculated propagation loss. When the failure is expected, the cell search using another frequency can be prioritized over the transmission processing of the random access channel, so that the establishment of the wireless link connection can be stabilized.
[0021]
In the mobile communication terminal device of the present invention, in the above-described configuration, the control unit calculates a probability that the transmission process of the transmission unit has succeeded based on the reception data generated by the reception unit, and calculates a transmission success rate. A transmission success rate calculating means for generating, and when the transmission success rate generated by the transmission success rate calculation means is equal to or less than a predetermined value, temporarily suspends the transmission processing of the random access channel and performs the transmission processing The transmission means and the cell search means are controlled so that a cell search is performed by using another frequency of the plurality of frequencies during the suspension period of.
[0022]
According to this configuration, in addition to the above effects, a probability of successful transmission processing is calculated based on the received data to generate a transmission success rate, and when the generated transmission success rate is equal to or less than a predetermined value, a random In order to control the transmitting means and the cell search means to temporarily stop the transmission processing of the access channel and perform the cell search using other frequencies of the plurality of frequencies during the stop period of the transmission processing, If the random access channel transmission process is expected to fail based on the transmission success rate, cell search using another frequency can be prioritized over the random access channel transmission process, thus establishing a wireless link connection Can be stabilized.
[0023]
The mobile communication method of the present invention is a cell search step of performing a cell search using each of a plurality of frequencies, and a receiving step of receiving a signal using one of the plurality of frequencies to generate reception data, A transmitting step of transmitting a random access channel, and temporarily stopping transmission processing of the random access channel based on the reception data generated in the receiving step, and stopping the transmission processing of the plurality of frequencies during a stop period of the transmission processing. And a control step of controlling the cell search in the cell search step and the transmission process in the transmission step so as to perform the cell search using another frequency.
[0024]
According to this method, in order to control not only the transmission process of the random access channel in the transmission step but also the cell search process using each of a plurality of frequencies in the cell search step based on the reception data generated in the reception step, for example, It is possible to prioritize any one of the random access channel transmission process and the cell search using another frequency depending on whether or not the random access channel transmission process is expected to fail based on the generated reception data. Therefore, the establishment of the wireless link connection can be stabilized.
[0025]
BEST MODE FOR CARRYING OUT THE INVENTION
The gist of the present invention is a cell that uses a plurality of frequencies that are different from the frequency at which a signal is received among a plurality of frequencies during a suspension period of a transmission process by temporarily stopping transmission processing of a random access channel based on received data. This is to control whether or not to perform a search.
[0026]
Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
[0027]
(Embodiment 1)
FIG. 1 is a block diagram showing a configuration of a mobile communication terminal according to Embodiment 1 of the present invention.
[0028]
The mobile communication terminal device 100 shown in FIG. 1 includes an antenna 102, a random access channel transmission unit 104, a data reception unit 106, a cell search unit 108, and a control unit 110.
[0029]
An input terminal of the random access channel transmitting section 104 is connected to the control section 110. An output terminal of the random access channel transmitting section 104 is connected to the antenna 102. An input terminal of the data receiving unit 106 is connected to the antenna 102. The input terminal of cell search section 108 is connected to antenna 102 and control section 110. The input terminal of the control unit 110 is connected to the data receiving unit 106.
[0030]
Data receiving section 106 receives a signal transmitted from the base station apparatus of the own cell via antenna 102 using frequency f1 assigned to the own cell, and generates received data. Data receiving section 106 outputs the generated reception data to control section 110. Further, when a random access channel (hereinafter, referred to as “RACH”) is transmitted from random access channel transmitting section 104, data receiving section 106 receives a synchronization detection indication channel (hereinafter, referred to as “RACH”) transmitted from the base station apparatus for RACH transmission. “AICH” is received via the antenna 102 using the frequency allocated to the own cell (hereinafter, referred to as “frequency f1”).
[0031]
Random access channel transmitting section 104 transmits the RACH to the base station apparatus of its own cell via antenna 102 based on the control signal from control section 110. Random access channel transmitting section 104 transmits RACH when a predetermined control signal (hereinafter referred to as “RACH control signal”) is obtained from control section 110. Here, the RACH to be transmitted is composed of a preamble and a message as shown in FIG. Further, random access channel transmitting section 104 does not transmit RACH when it does not receive a RACH control signal from control section 110.
[0032]
When random access is requested, control section 110 generates a RACH control signal and outputs it to random access channel transmitting section 104.
[0033]
Here, an example of an operation for recognizing whether random access is requested will be described. The first operation example is an operation when there is an incoming call to the mobile communication terminal device 100. In this case, the random access request is transmitted from the base station device. Then, data receiving section 106 receives the random access request via antenna 102, generates received data including the random access request, and outputs the data to control section 110. Then, control section 110 recognizes the random access request based on the received data obtained from the data receiving section, and outputs a RACH control signal to random access channel transmitting section 104. The second operation example is an operation in the case where the mobile communication terminal device 100 makes a call. In this case, control unit 110 receives a call request by a user operation of mobile communication terminal device 100. Then, control section 110 recognizes the random access request by obtaining a transmission request by a user operation, and outputs a RACH control signal to random access channel transmitting section 104. In the third operation example, the random access is also requested when the mobile communication terminal apparatus 100 needs to perform location registration with respect to the communication network due to the movement. In this case, control section 110 recognizes a random access request when location registration is required, and outputs a RACH control signal to random access channel transmitting section 104.
[0034]
Further, control section 110 controls random access channel receiving section 106 and cell search section 108 based on the received data obtained from data receiving section 106.
[0035]
Specifically, based on the received data, control unit 110 is expected to fail the RACH transmission by random access channel transmission unit 104 (that is, the transmitted RACH does not reach the base station device of its own cell). Is determined. If the random access channel transmitting section 104 determines that the RACH transmission is not expected to fail, the control section 110 returns the first control signal (hereinafter, “first cell”) if the RACH transmission is not expected to fail. (Referred to as "search control signal") to cell search section 108. On the other hand, if the RACH transmission is expected to fail, the control unit 110 temporarily stops the output of the RACH control signal to the random access channel transmission unit 104, and during the suspension period, outputs the second control signal (hereinafter, “ (Referred to as “second cell search control signal”) to cell search section 108.
[0036]
Cell search section 108 performs a cell search using each of a plurality of frequencies based on a control signal from control section 110. Specifically, the cell search unit 108 performs a cell search for the cell to which the frequency f1 is assigned by using the frequency f1 when the first cell search control signal is obtained from the control unit 110. Further, when the second cell search control signal is obtained from the control unit 110, the cell search unit 108 uses each of a plurality of frequencies fN, fN + 1, ... (N is an integer of 2 or more) different from the frequency f1, and Cell search is performed on a cell to which each of a plurality of frequencies fN, fN + 1,.
[0037]
That is, when it is not expected that the RACH transmission will fail, the cell search using the frequency f1 is executed by giving priority to the transmission process of the RACH. On the other hand, if the RACH transmission is expected to fail, the RACH transmission process can be stopped and the cell search using each of the plurality of frequencies fN, fN + 1,... Different from the frequency f1 can be performed with priority.
[0038]
Thus, according to Embodiment 1, since not only random access channel transmitting section 104 but also cell search section 108 are controlled based on the received data generated by data receiving section 106, random access channel transmitting section 104 Since it is possible to give priority to the RACH transmission processing and the cell search using each of the plurality of frequencies fN, fN + 1,... Different from the frequency f1, depending on whether the RACH transmission is expected to fail, The establishment of link connection can be stabilized.
[0039]
(Embodiment 2)
FIG. 2 is a block diagram showing a configuration of a mobile communication terminal according to Embodiment 2 of the present invention. Note that mobile communication terminal apparatus 200 according to Embodiment 2 has the same basic configuration as mobile communication terminal apparatus 100 according to Embodiment 1, and the same components are denoted by the same reference characters. The description is omitted.
[0040]
The mobile communication terminal device 200 shown in FIG. 2 includes a control unit 202 instead of the control unit 110 in the mobile communication terminal device 100. The control unit 202 includes a random access control unit 204, a reception level measurement unit 206, a cell search control unit 208, and a reception level determination unit 210.
[0041]
An input terminal of the random access channel transmitting section 104 is connected to the random access control section 204. An output terminal of the random access channel transmitting section 104 is connected to the antenna 102. An input terminal of the data receiving unit 106 is connected to the antenna 102. The input terminal of cell search section 108 is connected to antenna 102 and cell search control section 208. An input terminal of the random access control unit 204 is connected to the reception level judgment unit 210. An input terminal of the reception level measuring section 206 is connected to the data receiving section 106. The input terminal of cell search control section 208 is connected to reception level determination section 210. The input terminal of reception level determination section 210 is connected to reception level measurement section 206.
[0042]
When random access is requested, random access control section 204 generates a RACH control signal and outputs it to random access channel transmitting section 104. Further, when receiving a stop signal from the reception level determination unit 210, the random access control unit 204 temporarily stops outputting the RACH control signal to the random access channel transmission unit 104.
[0043]
Here, an example of a configuration for recognizing that random access is requested and an operation thereof will be described.
[0044]
First, as a first example, the random access control unit 204 may have a configuration including a call processing unit that recognizes a random access request transmitted from the base station device. In this case, an input terminal of the random access control unit 204 is connected to the data receiving unit 106. In such a configuration, when the random access request is transmitted from the base station device, data receiving section 106 receives the random access request via antenna 102. Then, it generates received data including the received random access request and outputs it to the call processing unit. The call processing unit recognizes that there is a random access request from the received data obtained from the data receiving unit 106 and generates a request signal. Then, random access control section 204 generates a RACH control signal based on the request signal generated by the call processing section, and outputs the RACH control signal to random access channel transmitting section 104.
[0045]
As a second example, the random access control unit 204 may be configured to include a call processing unit that recognizes a random access request by acquiring a call request by a user operation of the mobile communication terminal device 200. In this case, the call processing unit recognizes the random access request when acquiring the outgoing call request by the user operation, and generates a request signal. Then, random access control section 204 generates a RACH control signal based on the request signal generated by the call processing section, and outputs the RACH control signal to random access channel transmitting section 104.
[0046]
As a third example, the random access control unit 204 may be configured to include a device for recognizing that the movement of the mobile communication terminal device 200 has made it necessary to perform location registration with respect to a communication network. . In this case, this device recognizes a random access request when the mobile communication terminal device 200 needs to perform location registration with respect to a communication network due to movement, and generates a request signal. Then, random access control section 204 generates a RACH control signal based on the request signal generated by this device, and outputs it to random access channel transmission section 104.
[0047]
Reception level measurement section 206 measures the reception level based on the reception data obtained from data reception section 106. The reception level includes, for example, Ec / Io (signal power to interference power density ratio per chip), RSCP (Received Signal Code Power: reception power of a specific channel), and SIR (Signal to Interference Power Ratio: desired). Wave signal power to interference wave signal power ratio) [see the standard 3GPP (3rd Generation Partnership Project) TS25.215]. Reception level measurement section 206 outputs the measured reception level to reception level determination section 210.
[0048]
In Embodiment 2, the reception level is measured based on the reception data obtained from data reception section 106, but is not limited to this configuration. For example, reception level measurement section 206 may use the reception level measured when cell search section 108 performs a cell search. In this case, the input terminal of reception level measurement section 206 is connected to cell search section 108.
[0049]
Reception level determination section 210 compares reception level obtained from reception level measurement section 206 with a predetermined value stored in advance to determine whether RACH transmission by random access channel transmission section 104 is expected to fail. Is determined. If the RACH transmission is not expected to fail in the determination of whether the RACH transmission is expected to fail (that is, if the reception level is higher than a predetermined value), the reception level determination unit 210 generates a first instruction signal. Then, it outputs to cell search control section 208.
[0050]
On the other hand, when the RACH transmission is expected to fail (that is, when the reception level is equal to or lower than the predetermined value), reception level determination section 210 temporarily stops the output of the RACH control signal to random access channel transmission section 104. Thus, a stop signal for controlling the random access control unit 204 is generated. Then, reception level determining section 210 outputs the generated stop signal to random access control section 204. In addition, reception level determining section 210 generates a second instruction signal and outputs it to cell search control section 208.
[0051]
When receiving the first instruction signal from reception level determining section 210, cell search control section 208 outputs a first cell search control signal to cell search section. When receiving the second instruction signal from reception level determining section 210, cell search control section 208 outputs a second cell search control signal to cell search section.
[0052]
Cell search section 108 performs a cell search using each of a plurality of frequencies based on a control signal from cell search control section 208. Specifically, the cell search unit 108 performs a cell search on the cell to which the frequency f1 is assigned, using the frequency f1 when the first cell search control signal is obtained from the cell search control unit 208. Further, the cell search unit 108 uses a plurality of frequencies fN, fN + 1,... Different from the frequency f1 when the second cell search control signal is obtained from the cell search control unit 208, and uses a plurality of frequencies fN different from the frequency f1. , FN + 1,... Are cell-searched.
[0053]
That is, when it is not expected that the RACH transmission will fail, the cell search using the frequency f1 is executed by giving priority to the transmission process of the RACH. On the other hand, if the RACH transmission is expected to fail, the RACH transmission process can be stopped and the cell search using each of the plurality of frequencies fN, fN + 1,... Different from the frequency f1 can be performed with priority.
[0054]
As described above, according to the second embodiment, the reception level is measured based on the reception data, and when the measured reception level is equal to or lower than the predetermined value, the RACH transmission process is temporarily stopped to perform the transmission process. In order to control the random access channel transmission unit 104 and the cell search unit 108 to perform the cell search using each of the plurality of frequencies fN, fN + 1,... Different from the frequency f1 during the suspension period, the measured reception level If the RACH transmission process is expected to fail based on the radio link, the cell search using each of the plurality of frequencies fN, fN + 1,... Different from the frequency f1 can be prioritized over the RACH transmission process. Connection establishment can be stabilized.
[0055]
Note that, in the second embodiment, the configuration for stopping the RACH transmission process and preferentially performing the cell search using each of the plurality of frequencies fN, fN + 1,... Different from the frequency f1 is as described above. Not limited. For example, control section 202 determines the frequency of RACH transmission processing and the frequency of cell search using each of a plurality of frequencies fN, fN + 1,... Different from frequency f1, based on the measured reception level of the own cell. May be provided with a device for performing the above.
[0056]
Further, in Embodiment 2, whether or not to execute the cell search using each of frequencies fN, fN + 1,... Is determined based on the reception level of the own cell, but is not limited to this. For example, the reception level measurement unit 206 may be configured to measure the reception level of a cell other than the own cell.
[0057]
(Embodiment 3)
FIG. 3 is a block diagram showing a configuration of a mobile communication terminal according to Embodiment 3 of the present invention. The mobile communication terminal device according to Embodiment 3 has the same basic configuration as mobile communication terminal device 200 according to Embodiment 2, and the same components are denoted by the same reference numerals. , The description of which will be omitted.
[0058]
The mobile communication terminal device 300 shown in FIG. 3 includes a control unit 302 instead of the control unit 202 in the mobile communication terminal device 200. The control unit 302 includes a reception quality measurement unit 304 and a reception quality determination unit 306 in place of the reception level measurement unit 206 and the reception level determination unit 210 in the control unit 202.
[0059]
An input terminal of the random access channel transmitting section 104 is connected to the random access control section 204. An output terminal of the random access channel transmitting section 104 is connected to the antenna 102. The input terminal of the data receiving unit 106 is connected to the antenna 102. The input terminal of cell search section 108 is connected to antenna 102 and cell search control section 208. An input terminal of the random access control unit 204 is connected to the reception quality judgment unit 306. The input terminal of reception quality measuring section 304 is connected to data receiving section 106. The input terminal of cell search control section 208 is connected to reception quality determination section 306. The input terminal of reception quality determination section 306 is connected to reception quality measurement section 304.
[0060]
Reception quality measurement section 304 measures reception quality based on the reception data obtained from data reception section 106. Note that the reception quality includes, for example, a bit error rate (BER: Bit Error Rate), a block error rate (BLER: BLOCK Error Rate), a frame error rate (FER: Frame Error Rate), and the like. Reception quality measurement section 304 outputs the measured reception quality to reception quality determination section 306.
[0061]
The reception quality determination unit 306 compares the reception quality obtained from the reception quality measurement unit 304 with a predetermined value stored in advance, so that it is expected that RACH transmission by the random access channel transmission unit 104 will fail. Determine whether or not. If the RACH transmission is not expected to fail in the determination of whether the RACH transmission is expected to fail (that is, if the reception quality is larger than a predetermined value), the reception quality determination unit 306 generates a first instruction signal. Then, it outputs to cell search control section 208.
[0062]
On the other hand, when it is expected that the RACH transmission will fail (that is, when the reception quality is equal to or less than a predetermined value), reception quality determination section 306 temporarily stops the output of the RACH control signal to random access channel transmission section 104. Thus, a stop signal for controlling the random access control unit 204 is generated. Then, reception quality determining section 306 outputs the generated stop signal to random access control section 204. Further, reception quality determining section 306 generates a second instruction signal, and outputs it to cell search control section 208.
[0063]
Cell search section 108 performs a cell search using each of a plurality of frequencies based on a control signal from cell search control section 208. Specifically, the cell search unit 108 performs a cell search on the cell to which the frequency f1 is assigned, using the frequency f1 when the first cell search control signal is obtained from the cell search control unit 208. Further, the cell search unit 108 uses a plurality of frequencies fN, fN + 1,... Different from the frequency f1 when the second cell search control signal is obtained from the cell search control unit 208, and uses a plurality of frequencies fN different from the frequency f1. , FN + 1,... Are cell-searched.
[0064]
That is, when it is not expected that the RACH transmission will fail, the cell search using the frequency f1 is executed by giving priority to the transmission process of the RACH. On the other hand, if the RACH transmission is expected to fail, the RACH transmission process can be stopped and the cell search using each of the plurality of frequencies fN, fN + 1,... Different from the frequency f1 can be performed with priority.
[0065]
As described above, according to the third embodiment, the reception quality is measured based on the reception data, and when the measured reception quality is equal to or less than a predetermined value, the RACH transmission processing is temporarily stopped to stop the transmission processing. During the suspension period, the random access channel transmitting section 104 and the cell searching section 108 are controlled so as to perform a cell search using each of the plurality of frequencies fN, fN + 1,... Different from the frequency f1. If the RACH transmission process is expected to fail based on the radio link, the cell search using each of the plurality of frequencies fN, fN + 1,... Different from the frequency f1 can be prioritized over the RACH transmission process. Connection establishment can be stabilized.
[0066]
Note that, in the third embodiment, the configuration for stopping the RACH transmission process and preferentially executing the cell search using each of the plurality of frequencies fN, fN + 1,... Different from the frequency f1 is as described above. Not limited. For example, control section 302 determines the frequency of RACH transmission processing and the frequency of cell search using each of a plurality of frequencies fN, fN + 1,... Different from frequency f1, based on the measured reception quality of the own cell. May be provided with a device for performing the above.
[0067]
(Embodiment 4)
FIG. 4 is a block diagram showing a configuration of a mobile communication terminal according to Embodiment 4 of the present invention. The mobile communication terminal apparatus according to Embodiment 4 has the same basic configuration as mobile communication terminal apparatus 200 according to Embodiment 2, and the same components are denoted by the same reference numerals. , The description of which will be omitted.
[0068]
A mobile communication terminal device 400 shown in FIG. 4 includes a control unit 402 instead of the control unit 202 in the mobile communication terminal device 200. The control unit 402 includes a propagation loss calculation unit 404 and a propagation loss determination unit 406 instead of the reception level determination unit 210 in the control unit 202.
[0069]
An input terminal of the random access channel transmitting section 104 is connected to the random access control section 204. An output terminal of the random access channel transmitting section 104 is connected to the antenna 102. The input terminal of the data receiving unit 106 is connected to the antenna 102. The input terminal of cell search section 108 is connected to antenna 102 and cell search control section 208. An input terminal of the random access control unit 204 is connected to the propagation loss determination unit 406. An input terminal of the reception level measuring section 206 is connected to the data receiving section 106. An input terminal of the propagation loss calculator 404 is connected to the data receiver 106 and the reception level measuring unit 206. The input terminal of cell search control section 208 is connected to propagation loss determination section 406. The input terminal of the propagation loss determination unit 406 is connected to the propagation loss calculation unit 404.
[0070]
Propagation loss calculation section 404 calculates a propagation loss based on the reception data obtained from data reception section 106 and the reception level obtained from reception level measurement section 206. Specifically, propagation loss calculating section 404 acquires transmission power information indicating the value of the transmission power of the base station apparatus based on the reception data obtained from data receiving section 106. Then, propagation loss calculation section 404 calculates the propagation loss using the acquired transmission power information and the reception level obtained from reception level measurement section 206. By calculating the propagation loss in this way, the distance from mobile communication terminal apparatus 400 to the base station apparatus can be estimated. Furthermore, since the distance to the base station device can be estimated, it is possible to estimate the ease with which the transmitted RACH reaches the base station device. Then, propagation loss calculating section 404 outputs the calculated propagation loss to propagation loss determining section 406.
[0071]
The propagation loss determination unit 406 compares the propagation loss obtained from the propagation loss calculation unit 404 with a predetermined value stored in advance, so that it is expected that RACH transmission by the random access channel transmission unit 104 will fail. Determine whether or not.
[0072]
If the RACH transmission is not expected to fail in the determination of whether or not the RACH transmission is expected to fail (that is, if the propagation loss is less than a predetermined value), the propagation loss determining unit 406 generates the first instruction signal. Then, it outputs to cell search control section 208.
[0073]
On the other hand, when RACH transmission is expected to fail (that is, when the propagation loss is equal to or more than a predetermined value), propagation loss determining section 406 temporarily stops outputting the RACH control signal to random access channel transmitting section 104. Thus, a stop signal for controlling the random access control unit 204 is generated. Then, propagation loss determining section 406 outputs the generated stop signal to random access control section 204. Further, propagation loss determining section 406 generates a second instruction signal, and outputs it to cell search control section 208.
[0074]
Cell search section 108 performs a cell search using each of a plurality of frequencies based on a control signal from cell search control section 208. Specifically, the cell search unit 108 performs a cell search on the cell to which the frequency f1 is assigned, using the frequency f1 when the first cell search control signal is obtained from the cell search control unit 208. Further, the cell search unit 108 uses a plurality of frequencies fN, fN + 1,... Different from the frequency f1 when the second cell search control signal is obtained from the cell search control unit 208, and uses a plurality of frequencies fN different from the frequency f1. , FN + 1,... Are cell-searched.
[0075]
That is, when it is not expected that the RACH transmission will fail, the cell search using the frequency f1 is executed by giving priority to the transmission process of the RACH. On the other hand, if the RACH transmission is expected to fail, the RACH transmission process can be stopped and the cell search using each of the plurality of frequencies fN, fN + 1,... Different from the frequency f1 can be performed with priority.
[0076]
As described above, according to Embodiment 4, the transmission loss is calculated based on the received data, and when the calculated transmission loss is equal to or more than a predetermined value, the RACH transmission process is temporarily stopped to perform the transmission process. , The random access channel transmitting section 104 and the cell search section 108 are controlled to perform the cell search using each of the plurality of frequencies fN, fN + 1,... , It is possible to give priority to cell search using each of a plurality of frequencies fN, fN + 1,... Different from the frequency f1 over the RACH transmission processing when the transmission processing of the RACH is expected to fail. Connection establishment can be stabilized.
[0077]
Note that, in the fourth embodiment, the configuration for stopping the RACH transmission process and preferentially executing the cell search using each of the plurality of frequencies fN, fN + 1,... Different from the frequency f1 is as described above. Not limited. For example, the control unit 402 determines the frequency of the RACH transmission process and the frequency of the cell search using each of a plurality of frequencies fN, fN + 1,... Different from the frequency f1, based on the calculated propagation loss. May be provided.
[0078]
(Embodiment 5)
FIG. 5 is a block diagram showing a configuration of the mobile communication terminal apparatus according to Embodiment 5. The mobile communication terminal apparatus according to Embodiment 5 has the same basic configuration as mobile communication terminal apparatus 200 according to Embodiment 2, and the same components are denoted by the same reference numerals. , The description of which will be omitted.
[0079]
A mobile communication terminal device 500 shown in FIG. 5 includes a control unit 502 instead of the control unit 202 in the mobile communication terminal device 200. The control unit 502 includes a transmission success rate calculation unit 504 and a transmission success rate determination unit 506 instead of the reception level measurement unit 206 and the reception level determination unit 210 in the control unit 202.
[0080]
An input terminal of the random access channel transmitting section 104 is connected to the random access control section 204. An output terminal of the random access channel transmitting section 104 is connected to the antenna 102. The input terminal of the data receiving unit 106 is connected to the antenna 102. The input terminal of cell search section 108 is connected to antenna 102 and cell search control section 208. An input terminal of the random access control unit 204 is connected to the transmission success rate determination unit 506. An input terminal of the transmission success rate calculation unit 504 is connected to the data reception unit 106. An input terminal of the cell search control unit 208 is connected to the transmission success rate determination unit 506. An input terminal of the transmission success rate determination unit 506 is connected to the transmission success rate calculation unit 504.
[0081]
Transmission success rate calculation section 504 extracts transmission success information indicating that RACH transmission by random access channel transmission section 104 has been successful, from the reception data obtained from data reception section 106. The information indicating that the RACH transmission was successful includes, for example, an acknowledgment (ACK: ACKnowledgement) on the AICH transmitted from the base station apparatus with respect to the transmission of the preamble, and the base station apparatus with respect to the transmission of the message. , A response signal transmitted from Then, transmission success rate calculation section 504 calculates the probability of successful RACH transmission using the extracted transmission success information, and generates a transmission success rate. The transmission success rate calculation section 504 outputs the generated transmission success rate to the transmission success rate determination section 506.
[0082]
By comparing the transmission success rate obtained from transmission success rate calculation section 504 with a predetermined value stored in advance, transmission success rate determination section 506 predicts that RACH transmission by random access channel transmission section 104 will fail. It is determined whether or not it is performed.
[0083]
If the RACH transmission is not expected to fail in the determination of whether or not the RACH transmission is expected to fail (that is, if the transmission success rate is greater than a predetermined value), the transmission success rate determination unit 506 outputs the first instruction signal. Generated and output to cell search control section 208.
[0084]
On the other hand, when the RACH transmission is expected to fail (that is, when the transmission success rate is equal to or less than a predetermined value), transmission success rate determination section 506 temporarily outputs the RACH control signal to random access channel transmission section 104. A stop signal for controlling the random access control unit 204 to stop is generated. Then, transmission success rate determining section 506 outputs the generated stop signal to random access control section 204. Further, transmission success rate determining section 506 generates a second instruction signal and outputs the second instruction signal to cell search control section 208.
[0085]
Cell search section 108 performs a cell search using each of a plurality of frequencies based on a control signal from cell search control section 208. Specifically, the cell search unit 108 performs a cell search on the cell to which the frequency f1 is assigned, using the frequency f1 when the first cell search control signal is obtained from the cell search control unit 208. Further, the cell search unit 108 uses a plurality of frequencies fN, fN + 1,... Different from the frequency f1 when the second cell search control signal is obtained from the cell search control unit 208, and uses a plurality of frequencies fN different from the frequency f1. , FN + 1,... Are cell-searched.
[0086]
That is, when it is not expected that the RACH transmission will fail, the cell search using the frequency f1 is executed by giving priority to the transmission process of the RACH. On the other hand, if the RACH transmission is expected to fail, the RACH transmission process can be stopped and the cell search using each of the plurality of frequencies fN, fN + 1,... Different from the frequency f1 can be performed with priority.
[0087]
As described above, according to Embodiment 5, the transmission success rate is generated based on the received data, and when the generated transmission success rate is equal to or less than a predetermined value, the RACH transmission processing is temporarily stopped. In order to control the random access channel transmission unit 104 and the cell search unit 108 to perform a cell search using each of a plurality of frequencies fN, fN + 1,... Different from the frequency f1 during the suspension period of the transmission process. If the RACH transmission processing is expected to fail based on the transmission success rate, the cell search using each of the plurality of frequencies fN, fN + 1,... Different from the frequency f1 can be prioritized over the RACH transmission processing. Establishing a wireless link connection can be stabilized.
[0088]
In the fifth embodiment, the configuration for stopping the RACH transmission process and preferentially executing a cell search using each of a plurality of frequencies fN, fN + 1,... Different from frequency f1 is as described above. Not limited. For example, the control unit 502 determines the frequency of the RACH transmission process and the frequency of the cell search using each of the plurality of frequencies fN, fN + 1,... Different from the frequency f1, based on the generated transmission success rate. A configuration including a device may be employed.
[0089]
【The invention's effect】
As described above, according to the present invention, the transmission process of the random access channel is temporarily stopped based on the reception data, and is different from the frequency at which a signal is received among a plurality of frequencies during the stop period of the transmission process. Since it is controlled whether or not to perform a cell search using a plurality of frequencies, it is possible to stably establish a wireless link connection.
[Brief description of the drawings]
FIG. 1 is a block diagram showing a configuration of a mobile communication terminal device according to Embodiment 1 of the present invention.
FIG. 2 is a block diagram showing a configuration of a mobile communication terminal device according to Embodiment 2 of the present invention.
FIG. 3 is a block diagram showing a configuration of a mobile communication terminal according to Embodiment 3 of the present invention.
FIG. 4 is a block diagram showing a configuration of a mobile communication terminal apparatus according to Embodiment 4 of the present invention.
FIG. 5 is a block diagram showing a configuration of a mobile communication terminal according to Embodiment 5 of the present invention.
FIG. 6 is a block diagram showing an example of a configuration of a conventional mobile communication terminal device.
FIG. 7 is a diagram for explaining an example of the operation of a conventional mobile communication terminal device.
[Explanation of symbols]
100, 200, 300, 400, 500 mobile communication terminal devices
102 antenna
104 Random Access Channel Transmitter
106 data receiving unit
108 Cell Search Unit
110, 202, 302, 402, 502 control unit
204 random access control unit
206 reception level measurement unit
208 Cell Search Control Unit
210 reception level judgment unit
304 reception quality measurement unit
306 reception quality judgment unit
404 Propagation loss calculator
406 Propagation loss determination unit
504 Transmission success rate calculation unit
506 Transmission success rate judgment unit

Claims (6)

Cell search means for performing a cell search using each of the plurality of frequencies,
Reception means for receiving a signal using one of the plurality of frequencies to generate reception data,
Transmitting means for transmitting a random access channel;
A transmission process of the random access channel is temporarily stopped based on the reception data generated by the reception unit, and a cell search is performed using another frequency of the plurality of frequencies during a suspension period of the transmission process. Control means for controlling the transmission means and the cell search means to control whether or not to allow,
A mobile communication terminal device comprising: The control means includes:
A reception level measurement unit that measures a reception level based on the reception data generated by the reception unit,
When the reception level measured by the reception level measurement unit is equal to or less than a predetermined value, the transmission process of the random access channel is temporarily stopped, and the other frequencies of the plurality of frequencies are stopped during the suspension period of the transmission process. The mobile communication terminal device according to claim 1, wherein the transmission means and the cell search means are controlled so as to perform a cell search by using a mobile terminal. The control means includes:
A reception quality measurement unit that measures reception quality based on the reception data generated by the reception unit,
When the reception quality measured by the reception quality measurement unit is equal to or less than a predetermined value, the transmission process of the random access channel is temporarily stopped, and the other frequencies of the plurality of frequencies are stopped during the suspension period of the transmission process. The mobile communication terminal device according to claim 1, wherein the transmission means and the cell search means are controlled so as to perform a cell search by using a mobile terminal. The control means includes:
Providing a propagation loss calculating means for calculating a propagation loss based on the received data generated by the receiving means,
The transmission process of the random access channel is temporarily stopped when the propagation loss calculated by the propagation loss calculation means is equal to or more than a predetermined value, and the other frequencies of the plurality of frequencies are temporarily stopped during the suspension period of the transmission process. The mobile communication terminal device according to claim 1, wherein the transmission means and the cell search means are controlled so as to perform a cell search by using a mobile terminal. The control means includes:
A transmission success rate calculation unit that calculates a probability that the transmission process of the transmission unit succeeded based on the reception data generated by the reception unit and generates a transmission success rate,
When the transmission success rate generated by the transmission success rate calculation means is equal to or less than a predetermined value, the transmission processing of the random access channel is temporarily stopped, and the plurality of frequencies are temporarily stopped during the transmission processing stop period. 2. The mobile communication terminal device according to claim 1, wherein said transmitting means and said cell search means are controlled so as to perform a cell search using said frequency. A cell search step of performing a cell search using each of the plurality of frequencies;
A receiving step of receiving a signal using one of the plurality of frequencies to generate reception data,
A transmitting step of transmitting a random access channel;
A transmission process of the random access channel is temporarily stopped based on the reception data generated in the reception step, and a cell search is performed using another frequency of the plurality of frequencies during a suspension period of the transmission process. A control step of controlling the cell search in the transmission processing and the cell search step in the transmission step,
A mobile communication method, comprising:

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